From 5fa06e1e20ceff38d400b79932642283f64e8867 Mon Sep 17 00:00:00 2001 From: brynemorgan Date: Wed, 6 Mar 2024 18:25:55 -0800 Subject: [PATCH] Refactoring --- .../AMF_AA-Net_BIF_CCBY4_20220811.csv | 95829 ---------------- .../fluxtower/AMF_Supplementary_Metadata.csv | 9 - .../BASE_MeasurementHeight_20220811.csv | 13096 --- .../FFP_Python/FFP_readme_Python.pdf | Bin 123076 -> 0 bytes ecflux/fluxtower/FFP_Python/__init__.py | 0 .../FFP_Python/calc_footprint_FFP.py | 514 - .../calc_footprint_FFP_climatology.py | 734 - ecflux/fluxtower/FFP_Python/license.txt | 15 - ecflux/fluxtower/__init__.py | 9 - ecflux/fluxtower/amf_tower.py | 240 - ecflux/fluxtower/csi_tower.py | 75 - ecflux/fluxtower/ep_tower.py | 349 - ecflux/fluxtower/fluxtower.py | 353 - ecflux/fluxtower/footprint.py | 153 - ecflux/fluxtower/utils.py | 166 - ecflux/fluxtower/variables.csv | 24 - ecflux/tower_preproc.py | 113 - 17 files changed, 111679 deletions(-) delete mode 100644 ecflux/fluxtower/AMF_AA-Net_BIF_CCBY4_20220811.csv delete mode 100644 ecflux/fluxtower/AMF_Supplementary_Metadata.csv delete mode 100644 ecflux/fluxtower/BASE_MeasurementHeight_20220811.csv delete mode 100755 ecflux/fluxtower/FFP_Python/FFP_readme_Python.pdf delete mode 100644 ecflux/fluxtower/FFP_Python/__init__.py delete mode 100755 ecflux/fluxtower/FFP_Python/calc_footprint_FFP.py delete mode 100755 ecflux/fluxtower/FFP_Python/calc_footprint_FFP_climatology.py delete mode 100755 ecflux/fluxtower/FFP_Python/license.txt delete mode 100644 ecflux/fluxtower/__init__.py delete mode 100644 ecflux/fluxtower/amf_tower.py delete mode 100644 ecflux/fluxtower/csi_tower.py delete mode 100644 ecflux/fluxtower/ep_tower.py delete mode 100644 ecflux/fluxtower/fluxtower.py delete mode 100644 ecflux/fluxtower/footprint.py delete mode 100644 ecflux/fluxtower/utils.py delete mode 100644 ecflux/fluxtower/variables.csv delete mode 100644 ecflux/tower_preproc.py diff --git a/ecflux/fluxtower/AMF_AA-Net_BIF_CCBY4_20220811.csv b/ecflux/fluxtower/AMF_AA-Net_BIF_CCBY4_20220811.csv deleted file mode 100644 index 1df53bd..0000000 --- a/ecflux/fluxtower/AMF_AA-Net_BIF_CCBY4_20220811.csv +++ /dev/null @@ -1,95829 +0,0 @@ -SITE_ID,GROUP_ID,VARIABLE_GROUP,VARIABLE,DATAVALUE -AR-TF1,27001056,GRP_COUNTRY,COUNTRY,Argentina -AR-TF1,87122,GRP_DOI,DOI,10.17190/AMF/1543389 -AR-TF1,87122,GRP_DOI,DOI_CITATION,"Lars Kutzbach (2021), AmeriFlux BASE AR-TF1 Rio Moat bog, Ver. 2-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1543389" -AR-TF1,87122,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -AR-TF1,86902,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -AR-TF1,86902,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Lars Kutzbach -AR-TF1,86902,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -AR-TF1,86902,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,lars.kutzbach@uni-hamburg.de -AR-TF1,86902,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Universität Hamburg -AR-TF1,86919,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Universität Hamburg -AR-TF1,86919,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -AR-TF1,86918,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,DFG -AR-TF1,86918,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -AR-TF1,86258,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -AR-TF1,86258,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -AR-TF1,86258,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201601311800 -AR-TF1,86258,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,201805171700 -AR-TF1,86258,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -AR-TF1,86263,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -AR-TF1,86263,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -AR-TF1,86263,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201601311800 -AR-TF1,86263,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,201805171700 -AR-TF1,86263,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -AR-TF1,86255,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -AR-TF1,86255,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -AR-TF1,86255,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201601311800 -AR-TF1,86255,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,201805171700 -AR-TF1,86255,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -AR-TF1,23001056,GRP_HEADER,SITE_NAME,Rio Moat bog -AR-TF1,86271,GRP_IGBP,IGBP,WET -AR-TF1,86271,GRP_IGBP,IGBP_COMMENT,"Astelia pumila and Donatia fascicularis dominated. Also: Caltha dioneifolia, C. appendiculata, Carex antarctica, Drosera uniflora, Empetrum rubrum, Tetroncium magellanicum} and stunted Nothofagus spp." -AR-TF1,86256,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -AR-TF1,86260,GRP_LOCATION,LOCATION_LAT,-54.9733 -AR-TF1,86260,GRP_LOCATION,LOCATION_LONG,-66.7335 -AR-TF1,86260,GRP_LOCATION,LOCATION_ELEV,40 -AR-TF1,86270,GRP_NETWORK,NETWORK,AmeriFlux -AR-TF1,1700004395,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Holl, D., Pancotto, V., Heger, A., Camargo, S. J., Kutzbach, L. (2019) Cushion Bogs Are Stronger Carbon Dioxide Net Sinks Than Moss-Dominated Bogs As Revealed By Eddy Covariance Measurements On Tierra Del Fuego, Argentina, Biogeosciences, 16(17), 3397-3423" -AR-TF1,1700004395,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.5194/BG-16-3397-2019 -AR-TF1,1700004395,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -AR-TF1,86264,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,Carbon dioxide and energy exchange -AR-TF1,86266,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,Veronica PancottoCentro Austral de Investigaciones CientíficasCADIC-CONICETBernardo Houssay 200 (V9410BFD) UshuaiaTierra del Fuego- ARGENTINA -AR-TF1,86267,GRP_SITE_CHAR,TERRAIN,Flat -AR-TF1,86267,GRP_SITE_CHAR,ASPECT,FLAT -AR-TF1,86267,GRP_SITE_CHAR,WIND_DIRECTION,NNW -AR-TF1,86267,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,200 -AR-TF1,86261,GRP_SITE_DESC,SITE_DESC,Astelia pumila and Donatia fascicularis dominated cushion bog -AR-TF1,86254,GRP_SITE_FUNDING,SITE_FUNDING,DFG -AR-TF1,86259,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Lars Kutzbach -AR-TF1,86259,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -AR-TF1,86259,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,lars.kutzbach@uni-hamburg.de -AR-TF1,86259,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Universität Hamburg -AR-TF1,98428,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Veronica Pancotto -AR-TF1,98428,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -AR-TF1,98428,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,pancotto@cadic-conicet.gob.ar -AR-TF1,98428,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,CADIC-CONICET -AR-TF1,86268,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,David Holl -AR-TF1,86268,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,DataManager -AR-TF1,86268,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,david.holl@uni-hamburg.de -AR-TF1,86268,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Universität Hamburg -AR-TF1,86265,GRP_TOWER_POWER,TOWER_POWER,Solar panels -AR-TF1,86253,GRP_TOWER_POWER,TOWER_POWER,Wind generator -AR-TF1,86262,GRP_TOWER_TYPE,TOWER_TYPE,tripod -AR-TF1,24001056,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/AR-TF1 -AR-TF1,86257,GRP_UTC_OFFSET,UTC_OFFSET,-3 -AR-TF2,86279,GRP_CLIM_AVG,MAT,5.5 -AR-TF2,86279,GRP_CLIM_AVG,MAP,530 -AR-TF2,27001055,GRP_COUNTRY,COUNTRY,Argentina -AR-TF2,87126,GRP_DOI,DOI,10.17190/AMF/1543388 -AR-TF2,87126,GRP_DOI,DOI_CITATION,"Lars Kutzbach (2019), AmeriFlux BASE AR-TF2 Rio Pipo bog, Ver. 1-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1543388" -AR-TF2,87126,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -AR-TF2,86901,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -AR-TF2,86901,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Lars Kutzbach -AR-TF2,86901,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -AR-TF2,86901,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,lars.kutzbach@uni-hamburg.de -AR-TF2,86901,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Universität Hamburg -AR-TF2,86917,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Universität Hamburg -AR-TF2,86917,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -AR-TF2,86916,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,DFG -AR-TF2,86916,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -AR-TF2,86280,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -AR-TF2,86280,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -AR-TF2,86280,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201602081500 -AR-TF2,86280,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,201804171500 -AR-TF2,86280,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -AR-TF2,86287,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -AR-TF2,86287,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -AR-TF2,86287,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201602081500 -AR-TF2,86287,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,201804171500 -AR-TF2,86287,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -AR-TF2,86273,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -AR-TF2,86273,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -AR-TF2,86273,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201602081500 -AR-TF2,86273,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,201804171500 -AR-TF2,86273,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -AR-TF2,23001055,GRP_HEADER,SITE_NAME,Rio Pipo bog -AR-TF2,86285,GRP_IGBP,IGBP,WET -AR-TF2,86285,GRP_IGBP,IGBP_COMMENT,"Sphagnum magellanicum dominated peatland. Also: Empetrum rubrum, Marsippospermum grandiflorum,Tetroncium magellanicum, Gaultheria antarctica, Nothofagus antarctica, Carex magellanica, Rostkovia magellanica, Nanodea muscosa and Pernettya pumila" -AR-TF2,86272,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -AR-TF2,86272,GRP_LAND_OWNERSHIP,LAND_OWNER,National Park -AR-TF2,86288,GRP_LOCATION,LOCATION_LAT,-54.8269 -AR-TF2,86288,GRP_LOCATION,LOCATION_LONG,-68.4549 -AR-TF2,86288,GRP_LOCATION,LOCATION_ELEV,60 -AR-TF2,86274,GRP_NETWORK,NETWORK,AmeriFlux -AR-TF2,1700007971,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Holl, D., Pancotto, V., Heger, A., Camargo, S. J., Kutzbach, L. (2019) Cushion Bogs Are Stronger Carbon Dioxide Net Sinks Than Moss-Dominated Bogs As Revealed By Eddy Covariance Measurements On Tierra Del Fuego, Argentina, Biogeosciences, 16(17), 3397-3423" -AR-TF2,1700007971,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.5194/BG-16-3397-2019 -AR-TF2,1700007971,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -AR-TF2,86282,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,Carbon dioxide and energy exchange -AR-TF2,86290,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,Veronica PancottoCentro Austral de Investigaciones CientíficasCADIC-CONICETBernardo Houssay 200 (V9410BFD) UshuaiaTierra del Fuego- ARGENTINA -AR-TF2,86277,GRP_SITE_CHAR,TERRAIN,Valley -AR-TF2,86277,GRP_SITE_CHAR,ASPECT,FLAT -AR-TF2,86277,GRP_SITE_CHAR,WIND_DIRECTION,WNW -AR-TF2,86277,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,200 -AR-TF2,86278,GRP_SITE_DESC,SITE_DESC,Pristine Sphagnum magellanicum dominated bog located in Parque Nacional Tierra del Fuego. The peatland extends about 60 ha. -AR-TF2,86286,GRP_SITE_FUNDING,SITE_FUNDING,DFG -AR-TF2,86291,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Lars Kutzbach -AR-TF2,86291,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -AR-TF2,86291,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,lars.kutzbach@uni-hamburg.de -AR-TF2,86291,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Universität Hamburg -AR-TF2,98450,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Veronica Pancotto -AR-TF2,98450,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -AR-TF2,98450,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,pancotto@cadic-conicet.gob.ar -AR-TF2,98450,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,CADIC-CONICET -AR-TF2,86284,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,David Holl -AR-TF2,86284,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,DataManager -AR-TF2,86284,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,david.holl@uni-hamburg.de -AR-TF2,86284,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Universität Hamburg -AR-TF2,86283,GRP_TOWER_POWER,TOWER_POWER,Solar panels -AR-TF2,86275,GRP_TOWER_POWER,TOWER_POWER,Wind generator -AR-TF2,86281,GRP_TOWER_TYPE,TOWER_TYPE,tripod -AR-TF2,24001055,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/AR-TF2 -AR-TF2,86289,GRP_UTC_OFFSET,UTC_OFFSET,-3 -BR-CST,86508,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,"CNPq, FACEPE, CAPES (grants n° 465764/2014-2, APQ-0532-5.01/14, 441305/2017-2)" -BR-CST,86508,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT_COMMENT,The foundations listed above support the National Observatory of Water and Carbon in the Caatinga Biome (INCT-NOWCDCB) which this tower belongs. -BR-CST,86509,GRP_CLIM_AVG,MAT,25.2 -BR-CST,86509,GRP_CLIM_AVG,MAP,642 -BR-CST,86509,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Bsh -BR-CST,27001064,GRP_COUNTRY,COUNTRY,Brazil -BR-CST,87986,GRP_DOI,DOI,10.17190/AMF/1562386 -BR-CST,87986,GRP_DOI,DOI_CITATION,"Antonio Antonino (2019), AmeriFlux BASE BR-CST Caatinga Serra Talhada, Ver. 1-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1562386" -BR-CST,87986,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -BR-CST,87965,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -BR-CST,87965,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Antonio Antonino -BR-CST,87965,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -BR-CST,87965,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,acdantonino@gmail.com -BR-CST,87965,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Federal University of Pernambuco -BR-CST,87981,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Federal University of Pernambuco -BR-CST,87981,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -BR-CST,87973,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,"CNPq, FACEPE, CAPES" -BR-CST,87973,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -BR-CST,86510,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Drought -BR-CST,86511,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -BR-CST,86511,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -BR-CST,86511,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201406141000 -BR-CST,86511,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -BR-CST,86514,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -BR-CST,86514,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -BR-CST,86514,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201406141000 -BR-CST,86514,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -BR-CST,86512,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -BR-CST,86512,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -BR-CST,86512,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201406141000 -BR-CST,86512,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -BR-CST,86513,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Other -BR-CST,86513,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,Other -BR-CST,86513,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201406141000 -BR-CST,86513,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -BR-CST,86513,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,Meteorological Variables -BR-CST,23001064,GRP_HEADER,SITE_NAME,Caatinga Serra Talhada -BR-CST,86515,GRP_IGBP,IGBP,DNF -BR-CST,86516,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -BR-CST,86516,GRP_LAND_OWNERSHIP,LAND_OWNER,Mr. Homem Bom Magalhães -BR-CST,86517,GRP_LOCATION,LOCATION_LAT,-7.9682 -BR-CST,86517,GRP_LOCATION,LOCATION_LONG,-38.3842 -BR-CST,86517,GRP_LOCATION,LOCATION_ELEV,468 -BR-CST,86517,GRP_LOCATION,LOCATION_DATE_START,201401010000 -BR-CST,86518,GRP_NETWORK,NETWORK,AmeriFlux -BR-CST,86519,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,Land use change -BR-CST,86520,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"Av. Gregório Ferraz Nogueira, s/n, CEP 56909-535, Serra Talhada-PE, Brazil" -BR-CST,86521,GRP_SITE_CHAR,TERRAIN,"Medium Slope (>2 %, <5%)" -BR-CST,86521,GRP_SITE_CHAR,WIND_DIRECTION,SW -BR-CST,86521,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,1300 -BR-CST,86521,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,0 -BR-CST,86522,GRP_SITE_DESC,SITE_DESC,"This tower is located in a seasonal tropical dry forest (caatinga) in the semi-arid region of Brazil. There is no wood extraction for at least 50 years, and because it is an open area, there is cattle grazing during the wet season." -BR-CST,86523,GRP_SITE_FUNDING,SITE_FUNDING,"CNPq, FACEPE, CAPES" -BR-CST,86524,GRP_STATE,STATE,Pernambuco -BR-CST,86526,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Antonio Antonino -BR-CST,86526,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -BR-CST,86526,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,acdantonino@gmail.com -BR-CST,86526,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Federal University of Pernambuco -BR-CST,86526,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Av. Professor Luiz Freire, 1000, CEP 50740-545, Recife-PE, Brazil" -BR-CST,86525,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Eduardo Souza -BR-CST,86525,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -BR-CST,86525,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,eduardo.souza.rd@gmail.com -BR-CST,86525,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Federal Rural University of Pernambuco -BR-CST,86525,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Av. Gregório Ferraz Nogueira, s/n, CEP 56909-535, Serra Talhada-PE, Brazil" -BR-CST,86528,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,José Romualdo Lima -BR-CST,86528,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -BR-CST,86528,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,romualdo_solo@yahoo.com.br -BR-CST,86528,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Federal Rural University of Pernambuco -BR-CST,86528,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Av. Bom Pastor, s/n, CEP 55292-278, Garanhuns - PE, Brazil" -BR-CST,93314,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Rodolfo Souza -BR-CST,93314,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,DataManager -BR-CST,93314,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,rodolfomssouza@gmail.com -BR-CST,93314,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,ONDACBC -BR-CST,86529,GRP_TOWER_POWER,TOWER_POWER,Solar panels -BR-CST,86530,GRP_TOWER_TYPE,TOWER_TYPE,other -BR-CST,86531,GRP_URL,URL,https://ondacbc.eco.br/ -BR-CST,24001064,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/BR-CST -BR-CST,86532,GRP_UTC_OFFSET,UTC_OFFSET,-3 -BR-Npw,86494,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,"Brazilian National Institute for Science and Technology in Wetlands (INCT-INAU), Federal University of Mato Grosso (UFMT - PGFA and PGAT), University of Cuiabá (UNIC) and SESC-Pantanal." -BR-Npw,86498,GRP_CLIM_AVG,MAT,24.9 -BR-Npw,86498,GRP_CLIM_AVG,MAP,1486 -BR-Npw,86498,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Aw -BR-Npw,27001063,GRP_COUNTRY,COUNTRY,Brazil -BR-Npw,90053,GRP_DOI,DOI,10.17190/AMF/1579716 -BR-Npw,90053,GRP_DOI,DOI_CITATION,"George Vourlitis, Higo Dalmagro, José de S. Nogueira, Mark Johnson, Paulo Arruda (2019), AmeriFlux BASE BR-Npw Northern Pantanal Wetland, Ver. 1-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1579716" -BR-Npw,90053,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -BR-Npw,90012,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -BR-Npw,90012,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,George Vourlitis -BR-Npw,90012,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -BR-Npw,90012,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,georgev@csusm.edu -BR-Npw,90012,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"California State University, San Marcos" -BR-Npw,90013,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -BR-Npw,90013,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Higo Dalmagro -BR-Npw,90013,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -BR-Npw,90013,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,higojdalmagro@gmail.com -BR-Npw,90013,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Universidade de Cuiabá -BR-Npw,90015,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -BR-Npw,90015,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,José de S. Nogueira -BR-Npw,90015,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -BR-Npw,90015,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,nogueira@ufmt.br -BR-Npw,90015,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Universidade Federal de Mato Grosso -BR-Npw,90011,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -BR-Npw,90011,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Mark Johnson -BR-Npw,90011,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -BR-Npw,90011,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,mark.johnson@ubc.ca -BR-Npw,90011,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of British Columbia -BR-Npw,90014,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -BR-Npw,90014,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Paulo Arruda -BR-Npw,90014,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -BR-Npw,90014,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,paulo.zanella@gmail.com -BR-Npw,90014,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Universidade Federal de Mato Grosso -BR-Npw,90031,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,"California State University, San Marcos" -BR-Npw,90031,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -BR-Npw,90033,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Universidade de Cuiabá -BR-Npw,90033,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -BR-Npw,90036,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Universidade Federal de Mato Grosso -BR-Npw,90036,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -BR-Npw,90025,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,University of British Columbia -BR-Npw,90025,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -BR-Npw,93420,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,CNPq -BR-Npw,93420,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -BR-Npw,93426,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,INCT-INAU -BR-Npw,93426,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -BR-Npw,90019,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,"INCT-INAU, CNPq" -BR-Npw,90019,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -BR-Npw,86492,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Hydrologic event -BR-Npw,86503,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -BR-Npw,86503,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -BR-Npw,86503,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201312051030 -BR-Npw,86503,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -BR-Npw,89418,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -BR-Npw,89418,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CH4 -BR-Npw,89418,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201312051030 -BR-Npw,89418,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,201706291200 -BR-Npw,89418,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -BR-Npw,89418,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,"The gap-filled CH4 data archived on AmeriFlux was performed using the random forest method as detailed in Kim et al., 2019, doi: 10.1111/gcb.14845. Gap-filled CH4 data using MDS previously presented in Dalmagro et al., 2019, doi: 10.1111/gcb.14615 are available at https://dataverse.scholarsportal.info/dataverse/UBC_EH" -BR-Npw,86501,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -BR-Npw,86501,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -BR-Npw,86501,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201312051030 -BR-Npw,86501,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -BR-Npw,86486,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -BR-Npw,86486,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -BR-Npw,86486,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201312051030 -BR-Npw,86486,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -BR-Npw,23001063,GRP_HEADER,SITE_NAME,Northern Pantanal Wetland -BR-Npw,86493,GRP_IGBP,IGBP,WSA -BR-Npw,86493,GRP_IGBP,IGBP_DATE_START,201312051030 -BR-Npw,86493,GRP_IGBP,IGBP_COMMENT,"The vegetation is typical of the successional forests of the region, with an average height of 6 m, dominated by Combretum lanceolatum (Combretaceae)." -BR-Npw,86504,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -BR-Npw,86504,GRP_LAND_OWNERSHIP,LAND_OWNER,"Serviço Social do Comércio SESC, Base Avançada da UFMT" -BR-Npw,86496,GRP_LOCATION,LOCATION_LAT,-16.4980 -BR-Npw,86496,GRP_LOCATION,LOCATION_LONG,-56.4120 -BR-Npw,86496,GRP_LOCATION,LOCATION_ELEV,120 -BR-Npw,86496,GRP_LOCATION,LOCATION_DATE_START,201312051030 -BR-Npw,86506,GRP_NETWORK,NETWORK,AmeriFlux -BR-Npw,1700001200,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Dalmagro, H. J., Zanella de Arruda, P. H., Vourlitis, G. L., Lathuillière, M. J., de S. Nogueira, J., Couto, E. G., Johnson, M. S. (2019) Radiative Forcing Of Methane Fluxes Offsets Net Carbon Dioxide Uptake For A Tropical Flooded Forest, Global Change Biology, 25(6), 1967-1981" -BR-Npw,1700001200,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/GCB.14615 -BR-Npw,1700001200,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -BR-Npw,1700006906,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Kim, Y., Johnson, M. S., Knox, S. H., Black, T. A., Dalmagro, H. J., Kang, M., Kim, J., Baldocchi, D. (2019) Gap‐Filling Approaches For Eddy Covariance Methane Fluxes: A Comparison Of Three Machine Learning Algorithms And A Traditional Method With Principal Component Analysis, Global Change Biology, 25(6), 1967-1981" -BR-Npw,1700006906,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/GCB.14845 -BR-Npw,1700006906,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -BR-Npw,86484,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"Carbon fluxes, wetland processes" -BR-Npw,86495,GRP_SITE_CHAR,TERRAIN,Flat -BR-Npw,86495,GRP_SITE_CHAR,ASPECT,FLAT -BR-Npw,86495,GRP_SITE_CHAR,WIND_DIRECTION,N -BR-Npw,86495,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,1000 -BR-Npw,86495,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,0 -BR-Npw,86499,GRP_SITE_DESC,SITE_DESC,The site is located in the northern Pantanal in central South America. The site is subject to seasonal flooding with distinct wet seasons (November to April) and dry seasons (May to October). -BR-Npw,86491,GRP_SITE_FUNDING,SITE_FUNDING,"INCT-INAU, CNPq" -BR-Npw,86489,GRP_STATE,STATE,Mato Grosso -BR-Npw,86487,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,George Vourlitis -BR-Npw,86487,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -BR-Npw,86487,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,georgev@csusm.edu -BR-Npw,86487,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"California State University, San Marcos" -BR-Npw,86487,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Biological Sciences Department, California State University, San Marcos (CSUSM), California, 92078, USA" -BR-Npw,86497,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Higo Dalmagro -BR-Npw,86497,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -BR-Npw,86497,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,higojdalmagro@gmail.com -BR-Npw,86497,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Universidade de Cuiabá -BR-Npw,86497,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Programa de Pós-Graduação em Ciências Ambiental, Universidade de Cuiabá (UNIC), Cuiabá, Mato Grosso, 78025-300, Brazil" -BR-Npw,86533,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,José de S. Nogueira -BR-Npw,86533,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -BR-Npw,86533,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,nogueira@ufmt.br -BR-Npw,86533,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Universidade Federal de Mato Grosso -BR-Npw,86533,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Programa de Pós-Graduação em Física Ambiental, Universidade Federal de Mato Grosso (UFMT), Cuiabá, Mato Grosso, 78060-900, Brazil" -BR-Npw,86488,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Mark Johnson -BR-Npw,86488,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -BR-Npw,86488,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,mark.johnson@ubc.ca -BR-Npw,86488,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of British Columbia -BR-Npw,86488,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Institute for Resources, Environment and Sustainability,University of British Columbia (UBC), Vancouver, British Columbia, V6T 1Z4, Canada" -BR-Npw,86502,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Paulo Arruda -BR-Npw,86502,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -BR-Npw,86502,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,paulo.zanella@gmail.com -BR-Npw,86502,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Universidade Federal de Mato Grosso -BR-Npw,86502,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Programa de Pós-Graduação em Física Ambiental, Universidade Federal de Mato Grosso (UFMT), Cuiabá, Mato Grosso, 78060-900, Brazil" -BR-Npw,86505,GRP_TOWER_POWER,TOWER_POWER,Direct power -BR-Npw,86490,GRP_TOWER_POWER,TOWER_POWER,Solar panels -BR-Npw,86500,GRP_TOWER_TYPE,TOWER_TYPE,walk-up -BR-Npw,24001063,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/BR-Npw -BR-Npw,89419,GRP_UTC_OFFSET,UTC_OFFSET,-4 -BR-Npw,89419,GRP_UTC_OFFSET,UTC_OFFSET_DATE_START,20131206 -BR-Npw,89419,GRP_UTC_OFFSET,UTC_OFFSET_COMMENT,"The original data were in GMT -0, which we adjusted to local time (GMT -4). Daylight savings was not in effect for our first timestamp, and data were not adjusted to daylight savings when it came into effect in Oct 2013." -CA-ARB,33712,GRP_CLIM_AVG,MAT,-1.3 -CA-ARB,33712,GRP_CLIM_AVG,MAP,700 -CA-ARB,33712,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfb -CA-ARB,27000719,GRP_COUNTRY,COUNTRY,Canada -CA-ARB,85253,GRP_DOI,DOI,10.17190/AMF/1480319 -CA-ARB,85253,GRP_DOI,DOI_CITATION,"Aaron Todd, Elyn Humphreys (2018), AmeriFlux BASE CA-ARB Attawapiskat River Bog, Ver. 1-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1480319" -CA-ARB,85253,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -CA-ARB,83449,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -CA-ARB,83449,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Aaron Todd -CA-ARB,83449,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -CA-ARB,83449,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,aaron.todd@ontario.ca -CA-ARB,83449,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Ministry of Environment and Climate Change -CA-ARB,83450,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -CA-ARB,83450,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Elyn Humphreys -CA-ARB,83450,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -CA-ARB,83450,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,elynhumphreys@cunet.carleton.ca -CA-ARB,83450,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Carleton University -CA-ARB,83457,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Carleton University -CA-ARB,83457,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -CA-ARB,83456,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Ministry of Environment and Climate Change -CA-ARB,83456,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -CA-ARB,31179,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Undisturbed -CA-ARB,31180,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -CA-ARB,31180,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -CA-ARB,31180,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20100901 -CA-ARB,31180,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -CA-ARB,31182,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -CA-ARB,31182,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -CA-ARB,31182,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20100901 -CA-ARB,31182,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -CA-ARB,31183,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -CA-ARB,31183,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -CA-ARB,31183,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20100901 -CA-ARB,31183,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -CA-ARB,31181,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -CA-ARB,31181,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CH4 -CA-ARB,31181,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20110401 -CA-ARB,31181,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Growing season operation only -CA-ARB,23000719,GRP_HEADER,SITE_NAME,Attawapiskat River Bog -CA-ARB,31184,GRP_IGBP,IGBP,WET -CA-ARB,31185,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -CA-ARB,31185,GRP_LAND_OWNERSHIP,LAND_OWNER,Government -CA-ARB,31186,GRP_LOCATION,LOCATION_LAT,52.6950 -CA-ARB,31186,GRP_LOCATION,LOCATION_LONG,-83.9452 -CA-ARB,31186,GRP_LOCATION,LOCATION_ELEV,90 -CA-ARB,31187,GRP_NETWORK,NETWORK,AmeriFlux -CA-ARB,1700007809,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(), 108350" -CA-ARB,1700007809,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -CA-ARB,1700007809,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-ARB,31188,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,Peatland carbon and energy exchange with the atmosphere -CA-ARB,31189,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"B349 LA, 1125 Colonel By Dr., Ottawa, ON K1S 5B6" -CA-ARB,31190,GRP_SITE_CHAR,TERRAIN,Flat -CA-ARB,31190,GRP_SITE_CHAR,ASPECT,FLAT -CA-ARB,31190,GRP_SITE_CHAR,WIND_DIRECTION,NW -CA-ARB,31190,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,300 -CA-ARB,31190,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,205 -CA-ARB,33713,GRP_SITE_DESC,SITE_DESC,"Ontario Ministry of Environment and Climate Change's Environmental Monitoring and Reporting Branch has -established five carbon flux monitoring towers in Ontario’s Far North as part of its Climate Change Modelling and Monitoring program. These long term monitoring stations measure carbon exchange and a suite of soil and meteorological parameters over peatland ecosystems to better understand carbon cycling in Ontario’s Far North. Information produced by these monitoring stations will assist the province in land use planning and the development of climate change adaptation strategies." -CA-ARB,31192,GRP_STATE,STATE,Ontario -CA-ARB,33711,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Aaron Todd -CA-ARB,33711,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -CA-ARB,33711,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,aaron.todd@ontario.ca -CA-ARB,33711,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Ministry of Environment and Climate Change -CA-ARB,33711,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Etobicoke, Ontario, Canada" -CA-ARB,31193,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Elyn Humphreys -CA-ARB,31193,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -CA-ARB,31193,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,elynhumphreys@cunet.carleton.ca -CA-ARB,31193,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Carleton University -CA-ARB,31193,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Ottawa, Ontario, Canada" -CA-ARB,31197,GRP_TOWER_POWER,TOWER_POWER,Solar panels -CA-ARB,31195,GRP_TOWER_TYPE,TOWER_TYPE,other -CA-ARB,24000719,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/CA-ARB -CA-ARB,81375,GRP_UTC_OFFSET,UTC_OFFSET,-5 -CA-ARF,33714,GRP_CLIM_AVG,MAT,-1.3 -CA-ARF,33714,GRP_CLIM_AVG,MAP,700 -CA-ARF,33714,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfb -CA-ARF,27000718,GRP_COUNTRY,COUNTRY,Canada -CA-ARF,85249,GRP_DOI,DOI,10.17190/AMF/1480318 -CA-ARF,85249,GRP_DOI,DOI_CITATION,"Aaron Todd, Elyn Humphreys (2018), AmeriFlux BASE CA-ARF Attawapiskat River Fen, Ver. 1-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1480318" -CA-ARF,85249,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -CA-ARF,83447,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -CA-ARF,83447,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Aaron Todd -CA-ARF,83447,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -CA-ARF,83447,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,aaron.todd@ontario.ca -CA-ARF,83447,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Ministry of Environment and Climate Change -CA-ARF,83448,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -CA-ARF,83448,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Elyn Humphreys -CA-ARF,83448,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -CA-ARF,83448,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,elynhumphreys@cunet.carleton.ca -CA-ARF,83448,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Carleton University -CA-ARF,83455,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Carleton University -CA-ARF,83455,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -CA-ARF,83454,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Ministry of Environment and Climate Change -CA-ARF,83454,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -CA-ARF,31159,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Undisturbed -CA-ARF,31160,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -CA-ARF,31160,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -CA-ARF,31160,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20101001 -CA-ARF,31160,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -CA-ARF,31163,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -CA-ARF,31163,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -CA-ARF,31163,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20101001 -CA-ARF,31163,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -CA-ARF,31161,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -CA-ARF,31161,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -CA-ARF,31161,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20101001 -CA-ARF,31161,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -CA-ARF,31162,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -CA-ARF,31162,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CH4 -CA-ARF,31162,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20110401 -CA-ARF,31162,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Growing season operation only -CA-ARF,23000718,GRP_HEADER,SITE_NAME,Attawapiskat River Fen -CA-ARF,31164,GRP_IGBP,IGBP,WET -CA-ARF,31165,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -CA-ARF,31165,GRP_LAND_OWNERSHIP,LAND_OWNER,Government -CA-ARF,31166,GRP_LOCATION,LOCATION_LAT,52.7008 -CA-ARF,31166,GRP_LOCATION,LOCATION_LONG,-83.9550 -CA-ARF,31166,GRP_LOCATION,LOCATION_ELEV,88 -CA-ARF,31167,GRP_NETWORK,NETWORK,AmeriFlux -CA-ARF,1700008367,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(), 108350" -CA-ARF,1700008367,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -CA-ARF,1700008367,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-ARF,31168,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,Peatland carbon and energy exchange with the atmosphere -CA-ARF,31169,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"B349 LA, 1125 Colonel By Dr., Ottawa, ON K1S 5B6" -CA-ARF,31170,GRP_SITE_CHAR,TERRAIN,Flat -CA-ARF,31170,GRP_SITE_CHAR,ASPECT,FLAT -CA-ARF,31170,GRP_SITE_CHAR,WIND_DIRECTION,NW -CA-ARF,31170,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,300 -CA-ARF,31170,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,205 -CA-ARF,33716,GRP_SITE_DESC,SITE_DESC,"Ontario Ministry of Environment and Climate Change's Environmental Monitoring and Reporting Branch has -established five carbon flux monitoring towers in Ontario’s Far North as part of its Climate Change Modelling and Monitoring program. These long term monitoring stations measure carbon exchange and a suite of soil and meteorological parameters over peatland ecosystems to better understand carbon cycling in Ontario’s Far North. Information produced by these monitoring stations will assist the province in land use planning and the development of climate change adaptation strategies." -CA-ARF,31172,GRP_STATE,STATE,Ontario -CA-ARF,33715,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Aaron Todd -CA-ARF,33715,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -CA-ARF,33715,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,aaron.todd@ontario.ca -CA-ARF,33715,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Ministry of Environment and Climate Change -CA-ARF,33715,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Etobicoke, Ontario, Canada" -CA-ARF,31173,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Elyn Humphreys -CA-ARF,31173,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -CA-ARF,31173,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,elynhumphreys@cunet.carleton.ca -CA-ARF,31173,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Carleton University -CA-ARF,31173,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Ottawa, Ontario, Canada" -CA-ARF,31177,GRP_TOWER_POWER,TOWER_POWER,Solar panels -CA-ARF,31175,GRP_TOWER_TYPE,TOWER_TYPE,other -CA-ARF,24000718,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/CA-ARF -CA-ARF,81376,GRP_UTC_OFFSET,UTC_OFFSET,-5 -CA-BOU,91943,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,We would like to thank Hydro-Quebec and more specifically Dr. Alain Tremblay (Environment) for the important logistic support -CA-BOU,91946,GRP_CLIM_AVG,MAT,1.5 -CA-BOU,91946,GRP_CLIM_AVG,MAP,1011 -CA-BOU,91946,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Cwc -CA-BOU,27001137,GRP_COUNTRY,COUNTRY,Canada -CA-BOU,100811,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -CA-BOU,100811,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -CA-BOU,100811,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201806131200 -CA-BOU,100811,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20201010 -CA-BOU,100811,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -CA-BOU,100812,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -CA-BOU,100812,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CH4 -CA-BOU,100812,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201806131200 -CA-BOU,100812,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20201010 -CA-BOU,100812,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -CA-BOU,100813,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -CA-BOU,100813,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -CA-BOU,100813,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201806131200 -CA-BOU,100813,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20201010 -CA-BOU,100813,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -CA-BOU,100814,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -CA-BOU,100814,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -CA-BOU,100814,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201806131200 -CA-BOU,100814,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20201010 -CA-BOU,100814,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -CA-BOU,23001137,GRP_HEADER,SITE_NAME,Bouleau Peatland -CA-BOU,91962,GRP_IGBP,IGBP,WET -CA-BOU,91962,GRP_IGBP,IGBP_COMMENT,"Ombrotrophic peatland with pools. Sphagnum fuscum, S. capillifolium, and Cladonia rangiferina dominate the hummock microforms while S. magellanicum, S. rubellum, S. cuspidatum and Trichophorum cespitosum are found on lawns and S. majus and S. pulchrum on wet hollows." -CA-BOU,91953,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -CA-BOU,91945,GRP_LOCATION,LOCATION_LAT,50.5244 -CA-BOU,91945,GRP_LOCATION,LOCATION_LONG,-63.2064 -CA-BOU,91945,GRP_LOCATION,LOCATION_ELEV,108 -CA-BOU,91945,GRP_LOCATION,LOCATION_DATE_START,201806131200 -CA-BOU,91949,GRP_NETWORK,NETWORK,AmeriFlux -CA-BOU,91942,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"Flux data processing, instrument QA/QC" -CA-BOU,91958,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"201 Avenue du Président-Kennedy, Montréal, QC H2X 3Y7" -CA-BOU,91955,GRP_SITE_CHAR,TERRAIN,Flat -CA-BOU,91955,GRP_SITE_CHAR,WIND_DIRECTION,NE -CA-BOU,91955,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,200 -CA-BOU,91955,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,210 -CA-BOU,91959,GRP_SITE_DESC,SITE_DESC,This tower is located in a 1.5km2 ombrotrophic peatland covered at 60% by lichen in Northeast Quebec. -CA-BOU,91963,GRP_SITE_FUNDING,SITE_FUNDING,NSERC-CRD -CA-BOU,91941,GRP_STATE,STATE,Quebec -CA-BOU,91954,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Michelle Garneau -CA-BOU,91954,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -CA-BOU,91954,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,garneau.michelle@uqam.ca -CA-BOU,91954,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Université du Québec a Montréal -CA-BOU,91954,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"201 Avenue du Président-Kennedy, Montréal, QC H2X 3Y7" -CA-BOU,100830,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Pierre Taillardat -CA-BOU,100830,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,DataManager -CA-BOU,100830,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,taillardat.pierre@nus.edu.sg -CA-BOU,91952,GRP_TOWER_POWER,TOWER_POWER,Solar panels -CA-BOU,91951,GRP_TOWER_TYPE,TOWER_TYPE,tripod -CA-BOU,24001137,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/CA-BOU -CA-BOU,91944,GRP_UTC_OFFSET,UTC_OFFSET,-4 -CA-BOU,91944,GRP_UTC_OFFSET,UTC_OFFSET_DATE_START,201806131200 -CA-BOU,91944,GRP_UTC_OFFSET,UTC_OFFSET_COMMENT,initially following time zone hour of the site -CA-BOU,100810,GRP_UTC_OFFSET,UTC_OFFSET,-4 -CA-BOU,100810,GRP_UTC_OFFSET,UTC_OFFSET_DATE_START,201809021200 -CA-Ca1,26202,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER,12 -CA-Ca1,26202,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_ORGAN,Total -CA-Ca1,26202,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_PHEN,Mixed/unknown -CA-Ca1,26202,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_UNIT,gC m-2 -CA-Ca1,26202,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_DATE,20021108 -CA-Ca1,26202,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_COMMENT,"269-312/2002; C content assumed 50% for all veg except Douglas-fir, 50.5%" -CA-Ca1,25693,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB,22 -CA-Ca1,25693,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_ORGAN,Total -CA-Ca1,25693,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_PHEN,Mixed/unknown -CA-Ca1,25693,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_UNIT,gC m-2 -CA-Ca1,25693,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_DATE,20021108 -CA-Ca1,25693,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_COMMENT,"269-312/2002; C content assumed 50% for all veg except Douglas-fir, 50.5%" -CA-Ca1,26201,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,1238 -CA-Ca1,26201,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Foliage -CA-Ca1,26201,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -CA-Ca1,26201,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -CA-Ca1,26201,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,20021108 -CA-Ca1,26201,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,"269-312/2002; C content assumed 50% for all veg except Douglas-fir, 50.5%" -CA-Ca1,25820,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,12538 -CA-Ca1,25820,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Wood -CA-Ca1,25820,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -CA-Ca1,25820,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -CA-Ca1,25820,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,20021108 -CA-Ca1,25820,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,"269-312/2002; C content assumed 50% for all veg except Douglas-fir, 50.5%" -CA-Ca1,25692,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,13776 -CA-Ca1,25692,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Total -CA-Ca1,25692,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -CA-Ca1,25692,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -CA-Ca1,25692,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,20021108 -CA-Ca1,25692,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,"269-312/2002; C content assumed 50% for all veg except Douglas-fir, 50.5%" -CA-Ca1,25821,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS,105 -CA-Ca1,25821,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_UNIT,gC m-2 -CA-Ca1,25821,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_DATE,2004 -CA-Ca1,25821,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_COMMENT,estimated from 27 0.189 m2 litter traps every 90 days from 2002 to 2005 -CA-Ca1,25694,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS,127 -CA-Ca1,25694,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_UNIT,gC m-2 -CA-Ca1,25694,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_DATE,2003 -CA-Ca1,25694,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_COMMENT,estimated from 27 0.189 m2 litter traps every 90 days from 2002 to 2005 -CA-Ca1,26585,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS,142 -CA-Ca1,26585,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_UNIT,gC m-2 -CA-Ca1,26585,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_DATE,2002 -CA-Ca1,26585,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_COMMENT,estimated from 27 0.189 m2 litter traps every 90 days from 2002 to 2005 -CA-Ca1,25323,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS,90 -CA-Ca1,25323,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_UNIT,gC m-2 -CA-Ca1,25323,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_DATE,2005 -CA-Ca1,25323,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_COMMENT,estimated from 27 0.189 m2 litter traps every 90 days from 2002 to 2005 -CA-Ca1,25447,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT,105 -CA-Ca1,25822,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT,127 -CA-Ca1,26330,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT,142 -CA-Ca1,25823,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT,90 -CA-Ca1,25447,GRP_AG_LIT_PROD,AG_LIT_PROD_UNIT,gC m-2 -CA-Ca1,25822,GRP_AG_LIT_PROD,AG_LIT_PROD_UNIT,gC m-2 -CA-Ca1,25823,GRP_AG_LIT_PROD,AG_LIT_PROD_UNIT,gC m-2 -CA-Ca1,26330,GRP_AG_LIT_PROD,AG_LIT_PROD_UNIT,gC m-2 -CA-Ca1,26330,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_START,2002 -CA-Ca1,25822,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_START,2003 -CA-Ca1,25447,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_START,2004 -CA-Ca1,25823,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_START,2005 -CA-Ca1,25447,GRP_AG_LIT_PROD,AG_LIT_PROD_COMMENT,estimated from 27 0.189 m2 litter traps every 90 days from 2002 to 2005 -CA-Ca1,25822,GRP_AG_LIT_PROD,AG_LIT_PROD_COMMENT,estimated from 27 0.189 m2 litter traps every 90 days from 2002 to 2005 -CA-Ca1,25823,GRP_AG_LIT_PROD,AG_LIT_PROD_COMMENT,estimated from 27 0.189 m2 litter traps every 90 days from 2002 to 2005 -CA-Ca1,26330,GRP_AG_LIT_PROD,AG_LIT_PROD_COMMENT,estimated from 27 0.189 m2 litter traps every 90 days from 2002 to 2005 -CA-Ca1,25444,GRP_BIOMASS_CHEM,BIOMASS_C,5.05 -CA-Ca1,26203,GRP_BIOMASS_CHEM,BIOMASS_C,5.1 -CA-Ca1,26331,GRP_BIOMASS_CHEM,BIOMASS_N,0.135 -CA-Ca1,25444,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -CA-Ca1,26203,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -CA-Ca1,26331,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -CA-Ca1,25444,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -CA-Ca1,26203,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -CA-Ca1,26331,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -CA-Ca1,25444,GRP_BIOMASS_CHEM,BIOMASS_SPP,PSME (NRCS plant code) -CA-Ca1,26203,GRP_BIOMASS_CHEM,BIOMASS_SPP,PSME (NRCS plant code) -CA-Ca1,26331,GRP_BIOMASS_CHEM,BIOMASS_SPP,PSME (NRCS plant code) -CA-Ca1,26203,GRP_BIOMASS_CHEM,BIOMASS_DATE,2004 -CA-Ca1,26331,GRP_BIOMASS_CHEM,BIOMASS_DATE,2004 -CA-Ca1,26203,GRP_BIOMASS_CHEM,BIOMASS_COMMENT,from foliar C measurements of shoots used in LMA measurement -CA-Ca1,26331,GRP_BIOMASS_CHEM,BIOMASS_COMMENT,from foliar N measurements of shoots used in LMA measurement -CA-Ca1,25444,GRP_BIOMASS_CHEM,BIOMASS_COMMENT,"from Lamlom, S.H., Savidge, R.A. 2003." -CA-Ca1,23602,GRP_CLIM_AVG,MAT,9.93 -CA-Ca1,23602,GRP_CLIM_AVG,MAP,1369 -CA-Ca1,23602,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Cfb -CA-Ca1,27000051,GRP_COUNTRY,COUNTRY,Canada -CA-Ca1,6192,GRP_DM_PLANTING,DM_PLANTING,Planting live trees -CA-Ca1,85010,GRP_DOI,DOI,10.17190/AMF/1480300 -CA-Ca1,85010,GRP_DOI,DOI_CITATION,"T. Andrew Black (2018), AmeriFlux BASE CA-Ca1 British Columbia - 1949 Douglas-fir stand, Ver. 1-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1480300" -CA-Ca1,85010,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -CA-Ca1,81651,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -CA-Ca1,81651,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,T. Andrew Black -CA-Ca1,81651,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -CA-Ca1,81651,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,andrew.black@ubc.ca -CA-Ca1,81651,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of British Columbia -CA-Ca1,81656,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,University of British Columbia -CA-Ca1,81656,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -CA-Ca1,23603,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Forestry -CA-Ca1,23604,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -CA-Ca1,23604,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -CA-Ca1,23604,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,1997 -CA-Ca1,23604,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -CA-Ca1,23000051,GRP_HEADER,SITE_NAME,British Columbia - 1949 Douglas-fir stand -CA-Ca1,25445,GRP_HEIGHTC,HEIGHTC,32.5 -CA-Ca1,25445,GRP_HEIGHTC,HEIGHTC_COMMENT,"Gilbert Ethier, personal communications in Morgenstern et al., 2004." -CA-Ca1,23605,GRP_IGBP,IGBP,ENF -CA-Ca1,23605,GRP_IGBP,IGBP_COMMENT,57-year-old Douglas-fir with 17% red cedar and 3% western hemlock -CA-Ca1,25584,GRP_LAI,LAI_TYPE,LAI -CA-Ca1,25584,GRP_LAI,LAI_CLUMP,0.81 -CA-Ca1,25584,GRP_LAI,LAI_METHOD,Other -CA-Ca1,25584,GRP_LAI,LAI_APPROACH,TRAC + LAI-2000 -CA-Ca1,25584,GRP_LAI,LAI_DATE,2004 -CA-Ca1,25584,GRP_LAI,LAI_COMMENT,"Growing season; Chen et al., 2006" -CA-Ca1,25584,GRP_LAI,LAI_TOT,7.3 -CA-Ca1,23606,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -CA-Ca1,23606,GRP_LAND_OWNERSHIP,LAND_OWNER,TimberWest -CA-Ca1,25448,GRP_LMA,LMA,104 -CA-Ca1,25448,GRP_LMA,LMA_SPP,PSME (NRCS plant code) -CA-Ca1,25448,GRP_LMA,LMA_DATE,2004 -CA-Ca1,25448,GRP_LMA,LMA_COMMENT,estimates from LA (cm2) and dry weight measurements (g) using CNFI NPP data on CCP DIS -CA-Ca1,23607,GRP_LOCATION,LOCATION_LAT,49.8673 -CA-Ca1,23607,GRP_LOCATION,LOCATION_LONG,-125.3336 -CA-Ca1,23607,GRP_LOCATION,LOCATION_ELEV,300 -CA-Ca1,25196,GRP_NEP,NEP,379000 -CA-Ca1,25196,GRP_NEP,NEP_DATE_START,1998 -CA-Ca1,25196,GRP_NEP,NEP_DATE_END,1999 -CA-Ca1,25196,GRP_NEP,NEP_COMMENT,"Jan/Dec; Chen et al., 2008" -CA-Ca1,25324,GRP_NEP,NEP,382000 -CA-Ca1,25324,GRP_NEP,NEP_DATE_START,1999 -CA-Ca1,25324,GRP_NEP,NEP_DATE_END,2000 -CA-Ca1,25324,GRP_NEP,NEP_COMMENT,"Jan/Dec; Chen et al., 2008" -CA-Ca1,25697,GRP_NEP,NEP,400000 -CA-Ca1,25697,GRP_NEP,NEP_DATE_START,2000 -CA-Ca1,25697,GRP_NEP,NEP_DATE_END,2001 -CA-Ca1,25697,GRP_NEP,NEP_COMMENT,"Jan/Dec; Chen et al., 2008" -CA-Ca1,25827,GRP_NEP,NEP,410000 -CA-Ca1,25827,GRP_NEP,NEP_DATE_START,2001 -CA-Ca1,25827,GRP_NEP,NEP_DATE_END,2002 -CA-Ca1,25827,GRP_NEP,NEP_COMMENT,"Jan/Dec; Chen et al., 2008" -CA-Ca1,26454,GRP_NEP,NEP,277000 -CA-Ca1,26454,GRP_NEP,NEP_DATE_START,2002 -CA-Ca1,26454,GRP_NEP,NEP_DATE_END,2003 -CA-Ca1,26454,GRP_NEP,NEP_COMMENT,"Jan/Dec; Chen et al., 2008" -CA-Ca1,26455,GRP_NEP,NEP,353000 -CA-Ca1,26455,GRP_NEP,NEP_DATE_START,2003 -CA-Ca1,26455,GRP_NEP,NEP_DATE_END,2004 -CA-Ca1,26455,GRP_NEP,NEP_COMMENT,"Jan/Dec; Chen et al., 2008" -CA-Ca1,26106,GRP_NEP,NEP,267000 -CA-Ca1,26106,GRP_NEP,NEP_DATE_START,2004 -CA-Ca1,26106,GRP_NEP,NEP_DATE_END,2005 -CA-Ca1,26106,GRP_NEP,NEP_COMMENT,"Jan/Dec; Chen et al., 2008" -CA-Ca1,25590,GRP_NEP,NEP,355000 -CA-Ca1,25590,GRP_NEP,NEP_DATE_START,2005 -CA-Ca1,25590,GRP_NEP,NEP_DATE_END,2006 -CA-Ca1,25590,GRP_NEP,NEP_COMMENT,"Jan/Dec; Chen et al., 2008" -CA-Ca1,25941,GRP_NEP,NEP,386000 -CA-Ca1,25941,GRP_NEP,NEP_DATE_START,2006 -CA-Ca1,25941,GRP_NEP,NEP_DATE_END,2007 -CA-Ca1,25941,GRP_NEP,NEP_COMMENT,"Jan/Dec; Chen et al., 2008" -CA-Ca1,25450,GRP_NEP,NEP,552000 -CA-Ca1,25450,GRP_NEP,NEP_DATE_START,2007 -CA-Ca1,25450,GRP_NEP,NEP_DATE_END,2008 -CA-Ca1,25450,GRP_NEP,NEP_COMMENT,"Jan/Dec; Chen et al., 2008" -CA-Ca1,23609,GRP_NETWORK,NETWORK,AmeriFlux -CA-Ca1,23608,GRP_NETWORK,NETWORK,Fluxnet-Canada -CA-Ca1,26104,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,BudBreak -CA-Ca1,26104,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,PSME (NRCS plant code) -CA-Ca1,26104,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20080502 -CA-Ca1,26104,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,"Gilbert Ethier, personal communications 2008 field notes" -CA-Ca1,25589,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,Leaf senescence -CA-Ca1,25589,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,(Unknown) -CA-Ca1,25589,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,Will be estimated from NDVI maximum in growing season (GS) indicating PSME and deciduous understory combined. -CA-Ca1,26105,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,Maximum leaf expansion -CA-Ca1,26105,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,(Unknown) -CA-Ca1,26105,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,deciduous understory -CA-Ca1,1700002100,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Arain, M. A., Restrepo-Coupe, N. (2005) Net Ecosystem Production In A Temperate Pine Plantation In Southeastern Canada, Agricultural And Forest Meteorology, 128(3-4), 223-241" -CA-Ca1,1700002100,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2004.10.003 -CA-Ca1,1700002100,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Ca1,1700000951,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Barr, A., Richardson, A., Hollinger, D., Papale, D., Arain, M., Black, T., Bohrer, G., Dragoni, D., Fischer, M., Gu, L., Law, B., Margolis, H., McCaughey, J., Munger, J., Oechel, W., Schaeffer, K. (2013) Use Of Change-Point Detection For Friction–Velocity Threshold Evaluation In Eddy-Covariance Studies, Agricultural And Forest Meteorology, 171-172(7), 31-45" -CA-Ca1,1700000951,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2012.11.023 -CA-Ca1,1700000951,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Ca1,1700008511,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chen, J. M., Ju, W., Cihlar, J., Price, D., Liu, J., Chen, W., Pan, J., Black, A., Barr, A. (2003) Spatial Distribution Of Carbon Sources And Sinks In Canada's Forests, Tellus Series B-Chemical and Physical Meteorology, 55(2), 622-641" -CA-Ca1,1700008511,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1034/J.1600-0889.2003.00036.X -CA-Ca1,1700008511,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Ca1,1700000099,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Baldocchi, D. D., Poindexter, C., Abraha, M., Desai, A. R., Bohrer, G., Arain, M. A., Griffis, T., Blanken, P. D., O'Halloran, T. L., Thomas, R. Q., Zhang, Q., Burns, S. P., Frank, J. M., Christian, D., Brown, S., Black, T. A., Gough, C. M., Law, B. E., Lee, X., Chen, J., Reed, D. E., Massman, W. J., Clark, K., Hatfield, J., Prueger, J., Bracho, R., Baker, J. M., Martin, T. A. (2018) Temporal Dynamics Of Aerodynamic Canopy Height Derived From Eddy Covariance Momentum Flux Data Across North American Flux Networks, Geophysical Research Letters, 45(2), 9275–9287" -CA-Ca1,1700000099,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018GL079306 -CA-Ca1,1700000099,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Ca1,1700007638,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Baldocchi, D. D., Poindexter, C., Abraha, M., Desai, A. R., Bohrer, G., Arain, M. A., Griffis, T., Blanken, P. D., O'Halloran, T. L., Thomas, R. Q., Zhang, Q., Burns, S. P., Frank, J. M., Christian, D., Brown, S., Black, T. A., Gough, C. M., Law, B. E., Lee, X., Chen, J., Reed, D. E., Massman, W. J., Clark, K., Hatfield, J., Prueger, J., Bracho, R., Baker, J. M., Martin, T. A. (2018) Temporal Dynamics Of Aerodynamic Canopy Height Derived From Eddy Covariance Momentum Flux Data Across North American Flux Networks, Geophysical Research Letters, 45(3), 9275–9287" -CA-Ca1,1700007638,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018GL079306 -CA-Ca1,1700007638,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Ca1,1700004521,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(7), 108350" -CA-Ca1,1700004521,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -CA-Ca1,1700004521,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Ca1,1700006210,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Coursolle, C., Margolis, H. A., Barr, A. G., Black, T. A., Amiro, B. D., McCaughey, J. H., Flanagan, L. B., Lafleur, P. M., Roulet, N. T., Bourque, C. P., Arain, M. A., Wofsy, S. C., Dunn, A., Morgenstern, K., Orchansky, A. L., Bernier, P. Y., Chen, J. M., Kidston, J., Saigusa, N., Hedstrom, N. (2006) Late-Summer Carbon Fluxes From Canadian Forests And Peatlands Along An East-–West Continental Transect, Canadian Journal Of Forest Research, 36(3), 783-800" -CA-Ca1,1700006210,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1139/X05-270 -CA-Ca1,1700006210,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Ca1,1700003474,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Dennis Baldocchi, Cove Sturtevant (2015) Does day and night sampling reduce spurious correlation between canopy photosynthesis and ecosystem respiration?, Agricultural and Forest Meteorology, 207(3), 117-126" -CA-Ca1,1700003474,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2015.03.010 -CA-Ca1,1700003474,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Ca1,1700003225,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Drewitt, G., Black, T., Nesic, Z., Humphreys, E., Jork, E., Swanson, R., Ethier, G., Griffis, T., Morgenstern, K. (2002) Measuring Forest Floor CO2 Fluxes In A Douglas-Fir Forest, Agricultural And Forest Meteorology, 110(4), 299-317" -CA-Ca1,1700003225,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/S0168-1923(01)00294-5 -CA-Ca1,1700003225,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Ca1,1700003078,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Humphreys, E. R., Black, T. A., Morgenstern, K., Cai, T., Drewitt, G. B., Nesic, Z., Trofymow, J. (2006) Carbon Dioxide Fluxes In Coastal Douglas-Fir Stands At Different Stages Of Development After Clearcut Harvesting, Agricultural And Forest Meteorology, 140(1-4), 6-22" -CA-Ca1,1700003078,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2006.03.018 -CA-Ca1,1700003078,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Ca1,1700001656,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Humphreys, E., Black, T., Ethier, G., Drewitt, G., Spittlehouse, D., Jork, E., Nesic, Z., Livingston, N. (2003) Annual And Seasonal Variability Of Sensible And Latent Heat Fluxes Above A Coastal Douglas-Fir Forest, British Columbia, Canada, Agricultural And Forest Meteorology, 115(1-2), 109-125" -CA-Ca1,1700001656,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/S0168-1923(02)00171-5 -CA-Ca1,1700001656,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Ca1,1700008037,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Jassal, R. S., Black, T. A., Novak, M. D., Gaumont-Guay, D., Nesic, Z. (2008) Effect Of Soil Water Stress On Soil Respiration And Its Temperature Sensitivity In An 18-Year-Old Temperate Douglas-Fir Stand, Global Change Biology, 14(6), 1305-1318" -CA-Ca1,1700008037,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/J.1365-2486.2008.01573.X -CA-Ca1,1700008037,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Ca1,1700007866,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Jassal, R., Black, A., Novak, M., Morgenstern, K., Nesic, Z., Gaumont-Guay, D. (2005) Relationship Between Soil CO2 Concentrations And Forest-Floor CO2 Effluxes, Agricultural And Forest Meteorology, 130(3-4), 176-192" -CA-Ca1,1700007866,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2005.03.005 -CA-Ca1,1700007866,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Ca1,1700005742,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Krishnan, P., Black, T. A., Jassal, R. S., Chen, B., Nesic, Z. (2009) Interannual Variability Of The Carbon Balance Of Three Different-Aged Douglas-Fir Stands In The Pacific Northwest, Journal Of Geophysical Research, 114(G4), 9275–9287" -CA-Ca1,1700005742,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2008JG000912 -CA-Ca1,1700005742,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Ca1,1700002853,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Matheny, A. M., Bohrer, G., Stoy, P. C., Baker, I. T., Black, A. T., Desai, A. R., Dietze, M. C., Gough, C. M., Ivanov, V. Y., Jassal, R. S., Novick, K. A., Schäfer, K. V., Verbeeck, H. (2014) Characterizing The Diurnal Patterns of Errors in The Prediction of Evapotranspiration by Several Land-Surface Models: An Nacp Analysis, Journal Of Geophysical Research: Biogeosciences, 119(7), 1458-1473" -CA-Ca1,1700002853,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/2014JG002623 -CA-Ca1,1700002853,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Ca1,1700004704,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Ponton, S., Flanagan, L. B., Alstad, K. P., Johnson, B. G., Morgenstern, K., Kljun, N., Black, T. A., Barr, A. G. (2006) Comparison Of Ecosystem Water-Use Efficiency Among Douglas-Fir Forest, Aspen Forest And Grassland Using Eddy Covariance And Carbon Isotope Techniques, Global Change Biology, 12(2), 294-310" -CA-Ca1,1700004704,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/J.1365-2486.2005.01103.X -CA-Ca1,1700004704,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Ca1,1700000720,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Warren, C. R., Ethier, G. J., Livingston, N. J., Grant, N. J., Turpin, D. H., Harrison, D. L., Black, T. A. (2003) Transfer Conductance In Second Growth Douglas-Fir (Pseudotsuga Menziesii (Mirb.)Franco) Canopies, Plant, Cell And Environment, 26(8), 1215-1227" -CA-Ca1,1700000720,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1046/J.1365-3040.2003.01044.X -CA-Ca1,1700000720,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Ca1,1700008559,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Xu, B., Arain, M. A., Black, T. A., Law, B. E., Pastorello, G. Z., Chu, H. (2020) Seasonal Variability Of Forest Sensitivity To Heat And Drought Stresses: A Synthesis Based On Carbon Fluxes From North American Forest Ecosystems, Global Change Biology, 26(2), 901-918" -CA-Ca1,1700008559,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/GCB.14843 -CA-Ca1,1700008559,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Ca1,26098,GRP_ROOT_BIOMASS,ROOT_BIOMASS_CRS,875 -CA-Ca1,26098,GRP_ROOT_BIOMASS,ROOT_BIOMASS_FINE,375 -CA-Ca1,26098,GRP_ROOT_BIOMASS,ROOT_BIOMASS_TOT,1250 -CA-Ca1,26098,GRP_ROOT_BIOMASS,ROOT_BIOMASS_UNIT,gC m-2 -CA-Ca1,26098,GRP_ROOT_BIOMASS,ROOT_BIOMASS_DATE,2004 -CA-Ca1,26098,GRP_ROOT_BIOMASS,ROOT_BIOMASS_COMMENT,"modelled for this stand in Jassal et al., 2004" -CA-Ca1,25322,GRP_SA,SA,54 -CA-Ca1,25322,GRP_SA,SA_DATE,2008 -CA-Ca1,25322,GRP_SA,SA_COMMENT,"Morgernstern, et al., 2004, mean age + 4 years" -CA-Ca1,25443,GRP_SA,SA_DATE,2008 -CA-Ca1,25443,GRP_SA,SA_COMMENT,CCP DIS estimate for 2002 data + 6 years -CA-Ca1,25443,GRP_SA,SA_MAX,66 -CA-Ca1,23620,GRP_SITE_CHAR,TERRAIN,"Significant Slope (>5%, <10%)" -CA-Ca1,23620,GRP_SITE_CHAR,ASPECT,NE -CA-Ca1,23620,GRP_SITE_CHAR,WIND_DIRECTION,SE -CA-Ca1,23620,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,800 -CA-Ca1,23621,GRP_SITE_DESC,SITE_DESC,"1949 Douglas-fir stand; Tower Type 20"" triangular tower; Latitude/Longitude 49.86725N 125.33360W (GPS survey, 2003. Coordinates updated/corrected May, 2006); Elevation 320 m; North-east facing terrain, 5-10 deg slope; Mean Air Temp. 8.3 °C* ; Mean Annual Precipitation 1461 mm * ; Date Operations Began June 1997 ; Frequency of EC Measurements 20.83 Hz; Frequency of Other Met. Sensors 1 - 4 sec, year round ; Soil Respiration Measurements 30 min., automated soil respiration system in 2000, periodically during growing season using portable system in 2002 ; * 1998-2001 averages from the 1948 Douglas-fir stand meteorological tower" -CA-Ca1,25940,GRP_SNAG_MASS,SNAG_MASS,1 -CA-Ca1,25940,GRP_SNAG_MASS,SNAG_MASS_UNIT,gC m-2 -CA-Ca1,25940,GRP_SNAG_MASS,SNAG_MASS_DATE,20021108 -CA-Ca1,25940,GRP_SNAG_MASS,SNAG_MASS_COMMENT,269-312/2002;calculated from CNFI data on CCP DIS -CA-Ca1,25449,GRP_SOIL_CHEM,SOIL_CHEM_C_ORG,120 -CA-Ca1,25824,GRP_SOIL_CHEM,SOIL_CHEM_C_ORG,30 -CA-Ca1,25825,GRP_SOIL_CHEM,SOIL_CHEM_N_TOT,116.5 -CA-Ca1,25695,GRP_SOIL_CHEM,SOIL_CHEM_N_TOT,24 -CA-Ca1,25586,GRP_SOIL_CHEM,SOIL_CHEM_PH_SALT,5 -CA-Ca1,26450,GRP_SOIL_CHEM,SOIL_CHEM_BD,0.896948061219539 -CA-Ca1,26451,GRP_SOIL_CHEM,SOIL_CHEM_BD,1.18643500485884 -CA-Ca1,26100,GRP_SOIL_CHEM,SOIL_CHEM_BD,1.41680367847163 -CA-Ca1,26097,GRP_SOIL_CHEM,SOIL_CHEM_BD,1.44277162990307 -CA-Ca1,26099,GRP_SOIL_CHEM,SOIL_CHEM_BD,1.49797775053015 -CA-Ca1,26101,GRP_SOIL_CHEM,SOIL_CHEM_BD,1.57857045054169 -CA-Ca1,25824,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,0 -CA-Ca1,25825,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,0 -CA-Ca1,26450,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,0 -CA-Ca1,26097,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,1500 -CA-Ca1,26099,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,2500 -CA-Ca1,25449,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,3 -CA-Ca1,25586,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,3 -CA-Ca1,25695,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,3 -CA-Ca1,26100,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,3500 -CA-Ca1,26101,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,4500 -CA-Ca1,26451,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,500 -CA-Ca1,25449,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,103 -CA-Ca1,25586,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,103 -CA-Ca1,25695,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,103 -CA-Ca1,26451,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,1500 -CA-Ca1,26097,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,2500 -CA-Ca1,25824,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,3 -CA-Ca1,25825,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,3 -CA-Ca1,26099,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,3500 -CA-Ca1,26100,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,4500 -CA-Ca1,26450,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,500 -CA-Ca1,26101,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,6500 -CA-Ca1,25449,GRP_SOIL_CHEM,SOIL_CHEM_DATE,2002 -CA-Ca1,25586,GRP_SOIL_CHEM,SOIL_CHEM_DATE,2002 -CA-Ca1,25695,GRP_SOIL_CHEM,SOIL_CHEM_DATE,2002 -CA-Ca1,25824,GRP_SOIL_CHEM,SOIL_CHEM_DATE,2002 -CA-Ca1,25825,GRP_SOIL_CHEM,SOIL_CHEM_DATE,2002 -CA-Ca1,26097,GRP_SOIL_CHEM,SOIL_CHEM_DATE,2002 -CA-Ca1,26099,GRP_SOIL_CHEM,SOIL_CHEM_DATE,2002 -CA-Ca1,26100,GRP_SOIL_CHEM,SOIL_CHEM_DATE,2002 -CA-Ca1,26101,GRP_SOIL_CHEM,SOIL_CHEM_DATE,2002 -CA-Ca1,26450,GRP_SOIL_CHEM,SOIL_CHEM_DATE,2002 -CA-Ca1,26451,GRP_SOIL_CHEM,SOIL_CHEM_DATE,2002 -CA-Ca1,25586,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,calculated from CNFI data on CCP DIS -CA-Ca1,26097,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,"measurements by Jassal, P." -CA-Ca1,26099,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,"measurements by Jassal, P." -CA-Ca1,26100,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,"measurements by Jassal, P." -CA-Ca1,26101,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,"measurements by Jassal, P." -CA-Ca1,26450,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,"measurements by Jassal, P." -CA-Ca1,26451,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,"measurements by Jassal, P." -CA-Ca1,25449,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,mineral -CA-Ca1,25825,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,N taken as mean of range in table 1. Humphrey et al. 2006 -CA-Ca1,25695,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,N taken as mean of range in table 1. Humphrey et al. 2007 -CA-Ca1,25824,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,organic -CA-Ca1,25053,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION,Humoferric Podzols -CA-Ca1,25053,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION_TAXONOMY,Other -CA-Ca1,25053,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION_COMMENT," -Quelle: Humphreys_et_al_AgricForestMeteorol_2006(140):6-22" -CA-Ca1,24290,GRP_SOIL_DEPTH,SOIL_DEPTH,15 -CA-Ca1,24290,GRP_SOIL_DEPTH,SOIL_DEPTH_COMMENT,"Werte bezogen auf oberste 15cm -Quelle: Humphreys_et_al_AgricForestMeteorol_2006(140):6-22" -CA-Ca1,24544,GRP_SOIL_DEPTH,SOIL_DEPTH,10.1 -CA-Ca1,24544,GRP_SOIL_DEPTH,SOIL_DEPTH_COMMENT,"(range 0.009-0.193) -source Humphreys_et_al_AgricForestMeteorol_2006(140):6-22" -CA-Ca1,25194,GRP_SOIL_TEX,SOIL_TEX_SAND,69.25 -CA-Ca1,26332,GRP_SOIL_TEX,SOIL_TEX_SAND,80.9 -CA-Ca1,25696,GRP_SOIL_TEX,SOIL_TEX_SAND,83.75 -CA-Ca1,26102,GRP_SOIL_TEX,SOIL_TEX_SAND,87.55 -CA-Ca1,26103,GRP_SOIL_TEX,SOIL_TEX_SAND,87.8 -CA-Ca1,25195,GRP_SOIL_TEX,SOIL_TEX_SAND,88 -CA-Ca1,25826,GRP_SOIL_TEX,SOIL_TEX_SAND,88.35 -CA-Ca1,26333,GRP_SOIL_TEX,SOIL_TEX_SAND,89.8 -CA-Ca1,25195,GRP_SOIL_TEX,SOIL_TEX_SILT,10.45 -CA-Ca1,25696,GRP_SOIL_TEX,SOIL_TEX_SILT,15.65 -CA-Ca1,26332,GRP_SOIL_TEX,SOIL_TEX_SILT,16.85 -CA-Ca1,25194,GRP_SOIL_TEX,SOIL_TEX_SILT,22.65 -CA-Ca1,26103,GRP_SOIL_TEX,SOIL_TEX_SILT,9.15 -CA-Ca1,26333,GRP_SOIL_TEX,SOIL_TEX_SILT,9.3 -CA-Ca1,25826,GRP_SOIL_TEX,SOIL_TEX_SILT,9.65 -CA-Ca1,26102,GRP_SOIL_TEX,SOIL_TEX_SILT,9.8 -CA-Ca1,25696,GRP_SOIL_TEX,SOIL_TEX_CLAY,0.6 -CA-Ca1,26333,GRP_SOIL_TEX,SOIL_TEX_CLAY,0.85 -CA-Ca1,25195,GRP_SOIL_TEX,SOIL_TEX_CLAY,1.5 -CA-Ca1,25826,GRP_SOIL_TEX,SOIL_TEX_CLAY,2 -CA-Ca1,26332,GRP_SOIL_TEX,SOIL_TEX_CLAY,2.3 -CA-Ca1,26102,GRP_SOIL_TEX,SOIL_TEX_CLAY,2.65 -CA-Ca1,26103,GRP_SOIL_TEX,SOIL_TEX_CLAY,3.05 -CA-Ca1,25194,GRP_SOIL_TEX,SOIL_TEX_CLAY,8.1 -CA-Ca1,26453,GRP_SOIL_TEX,SOIL_TEX_WATER_HOLD_CAP,24.3 -CA-Ca1,26452,GRP_SOIL_TEX,SOIL_TEX_WATER_HOLD_CAP,24.9 -CA-Ca1,25194,GRP_SOIL_TEX,SOIL_TEX_PROFILE_MIN,0 -CA-Ca1,26452,GRP_SOIL_TEX,SOIL_TEX_PROFILE_MIN,0 -CA-Ca1,26453,GRP_SOIL_TEX,SOIL_TEX_PROFILE_MIN,0 -CA-Ca1,26332,GRP_SOIL_TEX,SOIL_TEX_PROFILE_MIN,10 -CA-Ca1,25195,GRP_SOIL_TEX,SOIL_TEX_PROFILE_MIN,20 -CA-Ca1,26333,GRP_SOIL_TEX,SOIL_TEX_PROFILE_MIN,30 -CA-Ca1,25696,GRP_SOIL_TEX,SOIL_TEX_PROFILE_MIN,40 -CA-Ca1,25826,GRP_SOIL_TEX,SOIL_TEX_PROFILE_MIN,50 -CA-Ca1,26102,GRP_SOIL_TEX,SOIL_TEX_PROFILE_MIN,60 -CA-Ca1,26103,GRP_SOIL_TEX,SOIL_TEX_PROFILE_MIN,70 -CA-Ca1,25194,GRP_SOIL_TEX,SOIL_TEX_PROFILE_MAX,10 -CA-Ca1,26332,GRP_SOIL_TEX,SOIL_TEX_PROFILE_MAX,20 -CA-Ca1,26452,GRP_SOIL_TEX,SOIL_TEX_PROFILE_MAX,3 -CA-Ca1,25195,GRP_SOIL_TEX,SOIL_TEX_PROFILE_MAX,30 -CA-Ca1,26333,GRP_SOIL_TEX,SOIL_TEX_PROFILE_MAX,40 -CA-Ca1,25696,GRP_SOIL_TEX,SOIL_TEX_PROFILE_MAX,50 -CA-Ca1,25826,GRP_SOIL_TEX,SOIL_TEX_PROFILE_MAX,60 -CA-Ca1,26102,GRP_SOIL_TEX,SOIL_TEX_PROFILE_MAX,70 -CA-Ca1,26453,GRP_SOIL_TEX,SOIL_TEX_PROFILE_MAX,70 -CA-Ca1,26103,GRP_SOIL_TEX,SOIL_TEX_PROFILE_MAX,90 -CA-Ca1,26452,GRP_SOIL_TEX,SOIL_TEX_COMMENT,"Field capacity (-10kPa); contact Jassal, P. of UBC biomet Note reported in % not mm." -CA-Ca1,26453,GRP_SOIL_TEX,SOIL_TEX_COMMENT,Field capacity (-1500kPa) Note reported in % not mm. -CA-Ca1,25696,GRP_SOIL_TEX,SOIL_TEX_COMMENT,"loamy sand; contact Jassal, P. of UBC biomet" -CA-Ca1,26332,GRP_SOIL_TEX,SOIL_TEX_COMMENT,"loamy sand; contact Jassal, P. of UBC biomet" -CA-Ca1,25195,GRP_SOIL_TEX,SOIL_TEX_COMMENT,"sand; contact Jassal, P. of UBC biomet" -CA-Ca1,25826,GRP_SOIL_TEX,SOIL_TEX_COMMENT,"sand; contact Jassal, P. of UBC biomet" -CA-Ca1,26102,GRP_SOIL_TEX,SOIL_TEX_COMMENT,"sand; contact Jassal, P. of UBC biomet" -CA-Ca1,26103,GRP_SOIL_TEX,SOIL_TEX_COMMENT,"sand; contact Jassal, P. of UBC biomet" -CA-Ca1,26333,GRP_SOIL_TEX,SOIL_TEX_COMMENT,"sand; contact Jassal, P. of UBC biomet" -CA-Ca1,25194,GRP_SOIL_TEX,SOIL_TEX_COMMENT,"sandy loam; contact Jassal, P. of UBC biomet" -CA-Ca1,26449,GRP_SPP_O,SPP_O,PSME (NRCS plant code) -CA-Ca1,26449,GRP_SPP_O,SPP_O_PERC,77 -CA-Ca1,26449,GRP_SPP_O,SPP_COMMENT,"Understory species were sparse. Others include Berbis nervosa Pursh., Achlys triphylla (Smith) DC. As well as various ferns and mosses (Morgenstern et al., 2004)" -CA-Ca1,26329,GRP_SPP_U,SPP_U,CHANA2 (NRCS plant code) -CA-Ca1,26329,GRP_SPP_U,SPP_COMMENT,"Understory species were sparse. Others include Berbis nervosa Pursh., Achlys triphylla (Smith) DC. As well as various ferns and mosses (Morgenstern et al., 2004)" -CA-Ca1,25585,GRP_STUMP_MASS,STUMP_MASS,2 -CA-Ca1,25585,GRP_STUMP_MASS,STUMP_MASS_UNIT,gC m-2 -CA-Ca1,25585,GRP_STUMP_MASS,STUMP_MASS_COMMENT,calculated from Canadian National Forest Inventory (CNFI) data on the Canadian Carbon Program Data Information System (CCP DIS) -CA-Ca1,23622,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,T. Andrew Black -CA-Ca1,23622,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -CA-Ca1,23622,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,andrew.black@ubc.ca -CA-Ca1,23622,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of British Columbia -CA-Ca1,29786,GRP_TOWER_POWER,TOWER_POWER,Gasoline generator -CA-Ca1,23623,GRP_TOWER_TYPE,TOWER_TYPE,triangle -CA-Ca1,23624,GRP_URL,URL,http://www.fluxnet-canada.ca/ -CA-Ca1,24000051,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/CA-Ca1 -CA-Ca1,23625,GRP_UTC_OFFSET,UTC_OFFSET,-8 -CA-Ca1,25446,GRP_WD_BIOMASS,WD_BIOMASS_CRS,5700 -CA-Ca1,25446,GRP_WD_BIOMASS,WD_BIOMASS_UNIT,gC m-2 -CA-Ca1,25446,GRP_WD_BIOMASS,WD_BIOMASS_DATE,20021108 -CA-Ca1,25446,GRP_WD_BIOMASS,WD_BIOMASS_COMMENT,~312/2002; TBF;CWD represents total woody debris (coarse and fine) taken as mean of range in table 1. Humphrey et al. 2006 -CA-Ca2,28491,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER,7 -CA-Ca2,28491,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_ORGAN,Total -CA-Ca2,28491,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_PHEN,Mixed/unknown -CA-Ca2,28491,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_UNIT,gC m-2 -CA-Ca2,28491,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_APPROACH,"average of 6 400 m plot estimates, using PLOTBIO_FOLIAGE_LIVE column in BC-DF49,HDF00,HDF88,HDF90_FC-GP_LTP_HEADER_2002.csv plus BC-DF49,HDF00,HDF88,HDF90_FC-GP_STP_HEADER_2002.csv. From Eco&SiteCharacteristicsDF1988Groundplot_2002 on CCP DIS" -CA-Ca2,28491,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_DATE,20021106 -CA-Ca2,28491,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_COMMENT,"265-310/2002; C content assumed 50% for all veg except Douglas-fir, 50.5%" -CA-Ca2,28261,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB,128 -CA-Ca2,28261,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_ORGAN,Total -CA-Ca2,28261,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_PHEN,Mixed/unknown -CA-Ca2,28261,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_UNIT,gC m-2 -CA-Ca2,28261,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_APPROACH,"average of 6 400 m plot estimates, using PLOTBIO_FOLIAGE_LIVE column in BC-DF49,HDF00,HDF88,HDF90_FC-GP_LTP_HEADER_2002.csv plus BC-DF49,HDF00,HDF88,HDF90_FC-GP_STP_HEADER_2002.csv. From Eco&SiteCharacteristicsDF1988Groundplot_2002 on CCP DIS" -CA-Ca2,28261,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_DATE,20021106 -CA-Ca2,28261,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_COMMENT,"265-310/2002; C content assumed 50% for all veg except Douglas-fir, 50.5%" -CA-Ca2,26694,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,27 -CA-Ca2,26694,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Wood -CA-Ca2,26694,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -CA-Ca2,26694,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -CA-Ca2,26694,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,"average of 6 400 m plot estimates, using PLOTBIO_FOLIAGE_LIVE column in BC-DF49,HDF00,HDF88,HDF90_FC-GP_LTP_HEADER_2002.csv plus BC-DF49,HDF00,HDF88,HDF90_FC-GP_STP_HEADER_2002.csv. From Eco&SiteCharacteristicsDF1988Groundplot_2002 on CCP DIS" -CA-Ca2,26694,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,20021106 -CA-Ca2,26694,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,"265-310/2002; C content assumed 50% for all veg except Douglas-fir, 50.5%" -CA-Ca2,28260,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,3 -CA-Ca2,28260,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Foliage -CA-Ca2,28260,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -CA-Ca2,28260,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -CA-Ca2,28260,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,"average of 6 400 m plot estimates, using PLOTBIO_FOLIAGE_LIVE column in BC-DF49,HDF00,HDF88,HDF90_FC-GP_LTP_HEADER_2002.csv plus BC-DF49,HDF00,HDF88,HDF90_FC-GP_STP_HEADER_2002.csv. From Eco&SiteCharacteristicsDF1988Groundplot_2002 on CCP DIS" -CA-Ca2,28260,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,20021106 -CA-Ca2,28260,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,"265-310/2002; C content assumed 50% for all veg except Douglas-fir, 50.5%" -CA-Ca2,26695,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,30 -CA-Ca2,26695,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Total -CA-Ca2,26695,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -CA-Ca2,26695,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -CA-Ca2,26695,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,"average of 6 400 m plot estimates, using PLOTBIO_FOLIAGE_LIVE column in BC-DF49,HDF00,HDF88,HDF90_FC-GP_LTP_HEADER_2002.csv plus BC-DF49,HDF00,HDF88,HDF90_FC-GP_STP_HEADER_2002.csv. From Eco&SiteCharacteristicsDF1988Groundplot_2002 on CCP DIS" -CA-Ca2,26695,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,20021106 -CA-Ca2,26695,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,"265-310/2002; C content assumed 50% for all veg except Douglas-fir, 50.5%" -CA-Ca2,28151,GRP_BIOMASS_CHEM,BIOMASS_C,5.005 -CA-Ca2,29451,GRP_BIOMASS_CHEM,BIOMASS_C,5.2 -CA-Ca2,26974,GRP_BIOMASS_CHEM,BIOMASS_N,0.1 -CA-Ca2,26974,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -CA-Ca2,28151,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -CA-Ca2,29451,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -CA-Ca2,26974,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -CA-Ca2,28151,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -CA-Ca2,29451,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -CA-Ca2,26974,GRP_BIOMASS_CHEM,BIOMASS_SPP,PSME (NRCS plant code) -CA-Ca2,28151,GRP_BIOMASS_CHEM,BIOMASS_SPP,PSME (NRCS plant code) -CA-Ca2,29451,GRP_BIOMASS_CHEM,BIOMASS_SPP,PSME (NRCS plant code) -CA-Ca2,26974,GRP_BIOMASS_CHEM,BIOMASS_DATE,2004 -CA-Ca2,29451,GRP_BIOMASS_CHEM,BIOMASS_DATE,2004 -CA-Ca2,29451,GRP_BIOMASS_CHEM,BIOMASS_COMMENT,from foliar C measurements of shoots used in LMA measurement -CA-Ca2,26974,GRP_BIOMASS_CHEM,BIOMASS_COMMENT,from foliar N measurements of shoots used in LMA measurement -CA-Ca2,28151,GRP_BIOMASS_CHEM,BIOMASS_COMMENT,"from Lamlom, S.H., Savidge, R.A. 2003." -CA-Ca2,23585,GRP_CLIM_AVG,MAT,9.86 -CA-Ca2,23585,GRP_CLIM_AVG,MAP,1474 -CA-Ca2,23585,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Cfb -CA-Ca2,27000052,GRP_COUNTRY,COUNTRY,Canada -CA-Ca2,4509,GRP_DM_FORESTRY,DM_FORESTRY,Clearcutting -CA-Ca2,4509,GRP_DM_FORESTRY,DM_DATE,1999 -CA-Ca2,2826,GRP_DM_PLANTING,DM_PLANTING,Planting live trees -CA-Ca2,2826,GRP_DM_PLANTING,DM_DATE,1999 -CA-Ca2,85009,GRP_DOI,DOI,10.17190/AMF/1480301 -CA-Ca2,85009,GRP_DOI,DOI_CITATION,"T. Andrew Black (2018), AmeriFlux BASE CA-Ca2 British Columbia - Clearcut Douglas-fir stand (harvested winter 1999/2000), Ver. 1-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1480301" -CA-Ca2,85009,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -CA-Ca2,81652,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -CA-Ca2,81652,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,T. Andrew Black -CA-Ca2,81652,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -CA-Ca2,81652,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,andrew.black@ubc.ca -CA-Ca2,81652,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"University of British Columbia, Vancouver" -CA-Ca2,81657,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,"University of British Columbia, Vancouver" -CA-Ca2,81657,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -CA-Ca2,23586,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Forestry -CA-Ca2,23587,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -CA-Ca2,23587,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -CA-Ca2,23587,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,2000 -CA-Ca2,23587,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -CA-Ca2,23000052,GRP_HEADER,SITE_NAME,British Columbia - Clearcut Douglas-fir stand (harvested winter 1999/2000) -CA-Ca2,27261,GRP_HEIGHTC,HEIGHTC,1 -CA-Ca2,27261,GRP_HEIGHTC,HEIGHTC_DATE,2000 -CA-Ca2,27261,GRP_HEIGHTC,HEIGHTC_COMMENT,logical esimate for that time -CA-Ca2,23588,GRP_IGBP,IGBP,ENF -CA-Ca2,23588,GRP_IGBP,IGBP_COMMENT,8-year-old Douglas-fir with (93%) and western red cedar plug stock (7%) -CA-Ca2,26699,GRP_LAI,LAI_TYPE,LAI -CA-Ca2,26700,GRP_LAI,LAI_TYPE,LAI -CA-Ca2,26977,GRP_LAI,LAI_TYPE,LAI -CA-Ca2,26978,GRP_LAI,LAI_TYPE,LAI -CA-Ca2,26979,GRP_LAI,LAI_TYPE,LAI -CA-Ca2,26980,GRP_LAI,LAI_TYPE,LAI -CA-Ca2,26981,GRP_LAI,LAI_TYPE,LAI -CA-Ca2,27265,GRP_LAI,LAI_TYPE,LAI -CA-Ca2,27266,GRP_LAI,LAI_TYPE,LAI -CA-Ca2,27267,GRP_LAI,LAI_TYPE,LAI -CA-Ca2,27268,GRP_LAI,LAI_TYPE,LAI -CA-Ca2,27269,GRP_LAI,LAI_TYPE,LAI -CA-Ca2,27541,GRP_LAI,LAI_TYPE,LAI -CA-Ca2,27542,GRP_LAI,LAI_TYPE,LAI -CA-Ca2,27543,GRP_LAI,LAI_TYPE,LAI -CA-Ca2,27895,GRP_LAI,LAI_TYPE,LAI -CA-Ca2,27896,GRP_LAI,LAI_TYPE,LAI -CA-Ca2,28155,GRP_LAI,LAI_TYPE,LAI -CA-Ca2,28264,GRP_LAI,LAI_TYPE,LAI -CA-Ca2,28265,GRP_LAI,LAI_TYPE,LAI -CA-Ca2,28266,GRP_LAI,LAI_TYPE,LAI -CA-Ca2,28494,GRP_LAI,LAI_TYPE,LAI -CA-Ca2,28495,GRP_LAI,LAI_TYPE,LAI -CA-Ca2,29095,GRP_LAI,LAI_TYPE,LAI -CA-Ca2,29453,GRP_LAI,LAI_TYPE,LAI -CA-Ca2,29454,GRP_LAI,LAI_TYPE,LAI -CA-Ca2,29455,GRP_LAI,LAI_TYPE,LAI -CA-Ca2,26699,GRP_LAI,LAI_METHOD,Other -CA-Ca2,26700,GRP_LAI,LAI_METHOD,Other -CA-Ca2,26977,GRP_LAI,LAI_METHOD,Other -CA-Ca2,26978,GRP_LAI,LAI_METHOD,Other -CA-Ca2,26979,GRP_LAI,LAI_METHOD,Other -CA-Ca2,26980,GRP_LAI,LAI_METHOD,Other -CA-Ca2,26981,GRP_LAI,LAI_METHOD,Other -CA-Ca2,27265,GRP_LAI,LAI_METHOD,Other -CA-Ca2,27266,GRP_LAI,LAI_METHOD,Other -CA-Ca2,27267,GRP_LAI,LAI_METHOD,Other -CA-Ca2,27268,GRP_LAI,LAI_METHOD,Other -CA-Ca2,27269,GRP_LAI,LAI_METHOD,Other -CA-Ca2,27541,GRP_LAI,LAI_METHOD,Other -CA-Ca2,27542,GRP_LAI,LAI_METHOD,Other -CA-Ca2,27543,GRP_LAI,LAI_METHOD,Other -CA-Ca2,27895,GRP_LAI,LAI_METHOD,Other -CA-Ca2,27896,GRP_LAI,LAI_METHOD,Other -CA-Ca2,28155,GRP_LAI,LAI_METHOD,Other -CA-Ca2,28264,GRP_LAI,LAI_METHOD,Other -CA-Ca2,28265,GRP_LAI,LAI_METHOD,Other -CA-Ca2,28266,GRP_LAI,LAI_METHOD,Other -CA-Ca2,28494,GRP_LAI,LAI_METHOD,Other -CA-Ca2,28495,GRP_LAI,LAI_METHOD,Other -CA-Ca2,29095,GRP_LAI,LAI_METHOD,Other -CA-Ca2,29453,GRP_LAI,LAI_METHOD,Other -CA-Ca2,29454,GRP_LAI,LAI_METHOD,Other -CA-Ca2,29455,GRP_LAI,LAI_METHOD,Other -CA-Ca2,29453,GRP_LAI,LAI_DATE,20000501 -CA-Ca2,28264,GRP_LAI,LAI_DATE,20010501 -CA-Ca2,27265,GRP_LAI,LAI_DATE,20020417 -CA-Ca2,27266,GRP_LAI,LAI_DATE,20020606 -CA-Ca2,27267,GRP_LAI,LAI_DATE,20020627 -CA-Ca2,27268,GRP_LAI,LAI_DATE,20020725 -CA-Ca2,26977,GRP_LAI,LAI_DATE,20020821 -CA-Ca2,27541,GRP_LAI,LAI_DATE,20020925 -CA-Ca2,26978,GRP_LAI,LAI_DATE,20021103 -CA-Ca2,29454,GRP_LAI,LAI_DATE,20030529 -CA-Ca2,28265,GRP_LAI,LAI_DATE,20030626 -CA-Ca2,28494,GRP_LAI,LAI_DATE,20030724 -CA-Ca2,26699,GRP_LAI,LAI_DATE,20030821 -CA-Ca2,26700,GRP_LAI,LAI_DATE,20030919 -CA-Ca2,28495,GRP_LAI,LAI_DATE,20031105 -CA-Ca2,26979,GRP_LAI,LAI_DATE,20040424 -CA-Ca2,27542,GRP_LAI,LAI_DATE,20040519 -CA-Ca2,26980,GRP_LAI,LAI_DATE,20040615 -CA-Ca2,29095,GRP_LAI,LAI_DATE,20040627 -CA-Ca2,28155,GRP_LAI,LAI_DATE,20040713 -CA-Ca2,27895,GRP_LAI,LAI_DATE,20040909 -CA-Ca2,27896,GRP_LAI,LAI_DATE,20050420 -CA-Ca2,27269,GRP_LAI,LAI_DATE,20050504 -CA-Ca2,29455,GRP_LAI,LAI_DATE,20050512 -CA-Ca2,28266,GRP_LAI,LAI_DATE,20050701 -CA-Ca2,27543,GRP_LAI,LAI_DATE,20050817 -CA-Ca2,26981,GRP_LAI,LAI_DATE,20051108 -CA-Ca2,26981,GRP_LAI,LAI_COMMENT,LAI-2000 -CA-Ca2,27269,GRP_LAI,LAI_COMMENT,LAI-2000 -CA-Ca2,27543,GRP_LAI,LAI_COMMENT,LAI-2000 -CA-Ca2,27896,GRP_LAI,LAI_COMMENT,LAI-2000 -CA-Ca2,28266,GRP_LAI,LAI_COMMENT,LAI-2000 -CA-Ca2,29095,GRP_LAI,LAI_COMMENT,LAI-2000 -CA-Ca2,29455,GRP_LAI,LAI_COMMENT,LAI-2000 -CA-Ca2,26699,GRP_LAI,LAI_COMMENT,Point quadrat -CA-Ca2,26700,GRP_LAI,LAI_COMMENT,Point quadrat -CA-Ca2,26977,GRP_LAI,LAI_COMMENT,Point quadrat -CA-Ca2,26978,GRP_LAI,LAI_COMMENT,Point quadrat -CA-Ca2,26979,GRP_LAI,LAI_COMMENT,Point quadrat -CA-Ca2,27265,GRP_LAI,LAI_COMMENT,Point quadrat -CA-Ca2,27266,GRP_LAI,LAI_COMMENT,Point quadrat -CA-Ca2,27267,GRP_LAI,LAI_COMMENT,Point quadrat -CA-Ca2,27268,GRP_LAI,LAI_COMMENT,Point quadrat -CA-Ca2,27541,GRP_LAI,LAI_COMMENT,Point quadrat -CA-Ca2,27542,GRP_LAI,LAI_COMMENT,Point quadrat -CA-Ca2,27895,GRP_LAI,LAI_COMMENT,Point quadrat -CA-Ca2,28155,GRP_LAI,LAI_COMMENT,Point quadrat -CA-Ca2,28264,GRP_LAI,LAI_COMMENT,Point quadrat -CA-Ca2,28265,GRP_LAI,LAI_COMMENT,Point quadrat -CA-Ca2,28494,GRP_LAI,LAI_COMMENT,Point quadrat -CA-Ca2,28495,GRP_LAI,LAI_COMMENT,Point quadrat -CA-Ca2,29453,GRP_LAI,LAI_COMMENT,Point quadrat -CA-Ca2,29454,GRP_LAI,LAI_COMMENT,Point quadrat -CA-Ca2,26980,GRP_LAI,LAI_COMMENT,Point Quadrat -CA-Ca2,29453,GRP_LAI,LAI_TOT,0.254 -CA-Ca2,27265,GRP_LAI,LAI_TOT,0.591 -CA-Ca2,28495,GRP_LAI,LAI_TOT,0.68 -CA-Ca2,28264,GRP_LAI,LAI_TOT,0.817 -CA-Ca2,26979,GRP_LAI,LAI_TOT,0.881 -CA-Ca2,26978,GRP_LAI,LAI_TOT,0.994 -CA-Ca2,26700,GRP_LAI,LAI_TOT,1.004 -CA-Ca2,29455,GRP_LAI,LAI_TOT,1.104 -CA-Ca2,27896,GRP_LAI,LAI_TOT,1.196 -CA-Ca2,26699,GRP_LAI,LAI_TOT,1.242 -CA-Ca2,27541,GRP_LAI,LAI_TOT,1.285 -CA-Ca2,27269,GRP_LAI,LAI_TOT,1.504 -CA-Ca2,27542,GRP_LAI,LAI_TOT,1.608 -CA-Ca2,26977,GRP_LAI,LAI_TOT,1.771 -CA-Ca2,27266,GRP_LAI,LAI_TOT,1.933 -CA-Ca2,29095,GRP_LAI,LAI_TOT,2.041 -CA-Ca2,29454,GRP_LAI,LAI_TOT,2.063 -CA-Ca2,26981,GRP_LAI,LAI_TOT,2.075 -CA-Ca2,27895,GRP_LAI,LAI_TOT,2.12 -CA-Ca2,28266,GRP_LAI,LAI_TOT,2.17 -CA-Ca2,27268,GRP_LAI,LAI_TOT,2.171 -CA-Ca2,26980,GRP_LAI,LAI_TOT,2.181 -CA-Ca2,28494,GRP_LAI,LAI_TOT,2.225 -CA-Ca2,28155,GRP_LAI,LAI_TOT,2.351 -CA-Ca2,27267,GRP_LAI,LAI_TOT,2.354 -CA-Ca2,27543,GRP_LAI,LAI_TOT,2.557 -CA-Ca2,28265,GRP_LAI,LAI_TOT,2.732 -CA-Ca2,23589,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -CA-Ca2,23589,GRP_LAND_OWNERSHIP,LAND_OWNER,Island Timberland -CA-Ca2,28492,GRP_LMA,LMA,100 -CA-Ca2,28492,GRP_LMA,LMA_SPP,PSME (NRCS plant code) -CA-Ca2,28492,GRP_LMA,LMA_DATE,2004 -CA-Ca2,28492,GRP_LMA,LMA_COMMENT,estimates from LA (cm2) and dry weight measurements (g) -CA-Ca2,23590,GRP_LOCATION,LOCATION_LAT,49.8705 -CA-Ca2,23590,GRP_LOCATION,LOCATION_LONG,-125.2909 -CA-Ca2,23590,GRP_LOCATION,LOCATION_ELEV,300 -CA-Ca2,26833,GRP_NEP,NEP,-533000 -CA-Ca2,26833,GRP_NEP,NEP_APPROACH,8 -CA-Ca2,26833,GRP_NEP,NEP_DATE_START,2001 -CA-Ca2,26833,GRP_NEP,NEP_DATE_END,2002 -CA-Ca2,26833,GRP_NEP,NEP_COMMENT,Jan/Dec; method differs from the CCP protocol in that we use exponential relationship and not a logistic to model nighttime respiration. -CA-Ca2,26696,GRP_NEP,NEP,-564000 -CA-Ca2,26696,GRP_NEP,NEP_APPROACH,8 -CA-Ca2,26696,GRP_NEP,NEP_DATE_START,2002 -CA-Ca2,26696,GRP_NEP,NEP_DATE_END,2003 -CA-Ca2,26696,GRP_NEP,NEP_COMMENT,Jan/Dec; method differs from the CCP protocol in that we use exponential relationship and not a logistic to model nighttime respiration. -CA-Ca2,26697,GRP_NEP,NEP,-597000 -CA-Ca2,26697,GRP_NEP,NEP_APPROACH,8 -CA-Ca2,26697,GRP_NEP,NEP_DATE_START,2003 -CA-Ca2,26697,GRP_NEP,NEP_DATE_END,2004 -CA-Ca2,26697,GRP_NEP,NEP_COMMENT,Jan/Dec; method differs from the CCP protocol in that we use exponential relationship and not a logistic to model nighttime respiration. -CA-Ca2,26698,GRP_NEP,NEP,-592000 -CA-Ca2,26698,GRP_NEP,NEP_APPROACH,8 -CA-Ca2,26698,GRP_NEP,NEP_DATE_START,2004 -CA-Ca2,26698,GRP_NEP,NEP_DATE_END,2005 -CA-Ca2,26698,GRP_NEP,NEP_COMMENT,Jan/Dec; method differs from the CCP protocol in that we use exponential relationship and not a logistic to model nighttime respiration. -CA-Ca2,28988,GRP_NEP,NEP,-420000 -CA-Ca2,28988,GRP_NEP,NEP_APPROACH,8 -CA-Ca2,28988,GRP_NEP,NEP_DATE_START,2005 -CA-Ca2,28988,GRP_NEP,NEP_DATE_END,2006 -CA-Ca2,28988,GRP_NEP,NEP_COMMENT,Jan/Dec; method differs from the CCP protocol in that we use exponential relationship and not a logistic to model nighttime respiration. -CA-Ca2,29093,GRP_NEP,NEP,-417000 -CA-Ca2,29093,GRP_NEP,NEP_APPROACH,8 -CA-Ca2,29093,GRP_NEP,NEP_DATE_START,2006 -CA-Ca2,29093,GRP_NEP,NEP_DATE_END,2007 -CA-Ca2,29093,GRP_NEP,NEP_COMMENT,Jan/Dec; method differs from the CCP protocol in that we use exponential relationship and not a logistic to model nighttime respiration. -CA-Ca2,28150,GRP_NEP,NEP,-353000 -CA-Ca2,28150,GRP_NEP,NEP_APPROACH,8 -CA-Ca2,28150,GRP_NEP,NEP_DATE_START,2007 -CA-Ca2,28150,GRP_NEP,NEP_DATE_END,2008 -CA-Ca2,28150,GRP_NEP,NEP_COMMENT,Jan/Dec; method differs from the CCP protocol in that we use exponential relationship and not a logistic to model nighttime respiration. -CA-Ca2,23591,GRP_NETWORK,NETWORK,AmeriFlux -CA-Ca2,23592,GRP_NETWORK,NETWORK,Fluxnet-Canada -CA-Ca2,1700003024,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Barr, A., Richardson, A., Hollinger, D., Papale, D., Arain, M., Black, T., Bohrer, G., Dragoni, D., Fischer, M., Gu, L., Law, B., Margolis, H., McCaughey, J., Munger, J., Oechel, W., Schaeffer, K. (2013) Use Of Change-Point Detection For Friction–Velocity Threshold Evaluation In Eddy-Covariance Studies, Agricultural And Forest Meteorology, 171-172(G4), 31-45" -CA-Ca2,1700003024,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2012.11.023 -CA-Ca2,1700003024,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Ca2,1700000495,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chen, J. M., Govind, A., Sonnentag, O., Zhang, Y., Barr, A., Amiro, B. (2006) Leaf Area Index Measurements At Fluxnet-Canada Forest Sites, Agricultural And Forest Meteorology, 140(1-4), 257-268" -CA-Ca2,1700000495,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2006.08.005 -CA-Ca2,1700000495,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Ca2,1700003945,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Baldocchi, D. D., Poindexter, C., Abraha, M., Desai, A. R., Bohrer, G., Arain, M. A., Griffis, T., Blanken, P. D., O'Halloran, T. L., Thomas, R. Q., Zhang, Q., Burns, S. P., Frank, J. M., Christian, D., Brown, S., Black, T. A., Gough, C. M., Law, B. E., Lee, X., Chen, J., Reed, D. E., Massman, W. J., Clark, K., Hatfield, J., Prueger, J., Bracho, R., Baker, J. M., Martin, T. A. (2018) Temporal Dynamics Of Aerodynamic Canopy Height Derived From Eddy Covariance Momentum Flux Data Across North American Flux Networks, Geophysical Research Letters, 45(2), 9275–9287" -CA-Ca2,1700003945,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018GL079306 -CA-Ca2,1700003945,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Ca2,1700008112,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Baldocchi, D. D., Poindexter, C., Abraha, M., Desai, A. R., Bohrer, G., Arain, M. A., Griffis, T., Blanken, P. D., O'Halloran, T. L., Thomas, R. Q., Zhang, Q., Burns, S. P., Frank, J. M., Christian, D., Brown, S., Black, T. A., Gough, C. M., Law, B. E., Lee, X., Chen, J., Reed, D. E., Massman, W. J., Clark, K., Hatfield, J., Prueger, J., Bracho, R., Baker, J. M., Martin, T. A. (2018) Temporal Dynamics Of Aerodynamic Canopy Height Derived From Eddy Covariance Momentum Flux Data Across North American Flux Networks, Geophysical Research Letters, 45(3), 9275–9287" -CA-Ca2,1700008112,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018GL079306 -CA-Ca2,1700008112,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Ca2,1700001965,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(G4), 108350" -CA-Ca2,1700001965,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -CA-Ca2,1700001965,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Ca2,1700001587,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Coursolle, C., Margolis, H. A., Barr, A. G., Black, T. A., Amiro, B. D., McCaughey, J. H., Flanagan, L. B., Lafleur, P. M., Roulet, N. T., Bourque, C. P., Arain, M. A., Wofsy, S. C., Dunn, A., Morgenstern, K., Orchansky, A. L., Bernier, P. Y., Chen, J. M., Kidston, J., Saigusa, N., Hedstrom, N. (2006) Late-Summer Carbon Fluxes From Canadian Forests And Peatlands Along An East-–West Continental Transect, Canadian Journal Of Forest Research, 36(3), 783-800" -CA-Ca2,1700001587,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1139/X05-270 -CA-Ca2,1700001587,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Ca2,1700007110,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Dennis Baldocchi, Cove Sturtevant (2015) Does day and night sampling reduce spurious correlation between canopy photosynthesis and ecosystem respiration?, Agricultural and Forest Meteorology, 207(3), 117-126" -CA-Ca2,1700007110,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2015.03.010 -CA-Ca2,1700007110,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Ca2,1700004848,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Humphreys, E. R., Black, T. A., Morgenstern, K., Cai, T., Drewitt, G. B., Nesic, Z., Trofymow, J. (2006) Carbon Dioxide Fluxes In Coastal Douglas-Fir Stands At Different Stages Of Development After Clearcut Harvesting, Agricultural And Forest Meteorology, 140(1-4), 6-22" -CA-Ca2,1700004848,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2006.03.018 -CA-Ca2,1700004848,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Ca2,1700003915,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Jassal, R. S., Black, T. A., Novak, M. D., Gaumont-Guay, D., Nesic, Z. (2008) Effect Of Soil Water Stress On Soil Respiration And Its Temperature Sensitivity In An 18-Year-Old Temperate Douglas-Fir Stand, Global Change Biology, 14(6), 1305-1318" -CA-Ca2,1700003915,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/J.1365-2486.2008.01573.X -CA-Ca2,1700003915,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Ca2,1700001332,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Krishnan, P., Black, T. A., Jassal, R. S., Chen, B., Nesic, Z. (2009) Interannual Variability Of The Carbon Balance Of Three Different-Aged Douglas-Fir Stands In The Pacific Northwest, Journal Of Geophysical Research, 114(G4), 9275–9287" -CA-Ca2,1700001332,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2008JG000912 -CA-Ca2,1700001332,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Ca2,1700006819,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Xu, B., Arain, M. A., Black, T. A., Law, B. E., Pastorello, G. Z., Chu, H. (2020) Seasonal Variability Of Forest Sensitivity To Heat And Drought Stresses: A Synthesis Based On Carbon Fluxes From North American Forest Ecosystems, Global Change Biology, 26(2), 901-918" -CA-Ca2,1700006819,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/GCB.14843 -CA-Ca2,1700006819,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Ca2,27893,GRP_SA,SA,8 -CA-Ca2,27893,GRP_SA,SA_COMMENT,date of planting -CA-Ca2,23596,GRP_SITE_CHAR,TERRAIN,Gentle slope (<2 %) -CA-Ca2,23596,GRP_SITE_CHAR,ASPECT,ESE -CA-Ca2,23596,GRP_SITE_CHAR,WIND_DIRECTION,E -CA-Ca2,23596,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,200 -CA-Ca2,23597,GRP_SITE_DESC,SITE_DESC,"Tower Type: 10"" triangular tower; Latitude/Longitude 49.87048N -125.29087W (GPS survey, 2003. Coordinates updated/corrected May, 2006); Elevation approx. 180m; Mean Air Temp. (for the growing season) 8.3 C*; Mean Annual Precipitation 1461 mm *; Date Operations Began August 2000; Frequency of EC Measurements 7.7 Hz (2000 ­ 2001), 20 Hz (2002); Frequency of Other Met. Sensors 4 sec, year round; Soil Respiration Measurements Periodically during growing season using portable system in 2002; * 1998-2001 averages from the 1948 Douglas-fir stand meteorological tower" -CA-Ca2,29450,GRP_SNAG_MASS,SNAG_MASS,0 -CA-Ca2,29450,GRP_SNAG_MASS,SNAG_MASS_UNIT,gC m-2 -CA-Ca2,29450,GRP_SNAG_MASS,SNAG_MASS_DATE,20021108 -CA-Ca2,29450,GRP_SNAG_MASS,SNAG_MASS_COMMENT,269-312/2002; calculated from CNFI data on CCP DIS -CA-Ca2,29094,GRP_SOIL_CHEM,SOIL_CHEM_C_ORG,30.0417 -CA-Ca2,26976,GRP_SOIL_CHEM,SOIL_CHEM_C_ORG,58.9333 -CA-Ca2,26975,GRP_SOIL_CHEM,SOIL_CHEM_C_ORG,88.9833 -CA-Ca2,26834,GRP_SOIL_CHEM,SOIL_CHEM_PH_SALT,5 -CA-Ca2,27262,GRP_SOIL_CHEM,SOIL_CHEM_BD,1.07937374793929 -CA-Ca2,28152,GRP_SOIL_CHEM,SOIL_CHEM_BD,1.12498004663815 -CA-Ca2,27263,GRP_SOIL_CHEM,SOIL_CHEM_BD,1.29881704232794 -CA-Ca2,27894,GRP_SOIL_CHEM,SOIL_CHEM_BD,1.51492870775319 -CA-Ca2,27540,GRP_SOIL_CHEM,SOIL_CHEM_BD,1.65722628258956 -CA-Ca2,26975,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,0 -CA-Ca2,27262,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,0 -CA-Ca2,29094,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,0 -CA-Ca2,28152,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,10 -CA-Ca2,27263,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,20 -CA-Ca2,26834,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,30 -CA-Ca2,26976,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,30 -CA-Ca2,27894,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,30 -CA-Ca2,27540,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,40 -CA-Ca2,27262,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,10 -CA-Ca2,26834,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,100 -CA-Ca2,26975,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,100 -CA-Ca2,26976,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,100 -CA-Ca2,28152,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,20 -CA-Ca2,27263,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,30 -CA-Ca2,29094,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,30 -CA-Ca2,27894,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,40 -CA-Ca2,27540,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,50 -CA-Ca2,27262,GRP_SOIL_CHEM,SOIL_CHEM_DATE,2002 -CA-Ca2,26834,GRP_SOIL_CHEM,SOIL_CHEM_DATE,20020927 -CA-Ca2,26975,GRP_SOIL_CHEM,SOIL_CHEM_DATE,20020927 -CA-Ca2,26976,GRP_SOIL_CHEM,SOIL_CHEM_DATE,20020927 -CA-Ca2,29094,GRP_SOIL_CHEM,SOIL_CHEM_DATE,20020927 -CA-Ca2,28152,GRP_SOIL_CHEM,SOIL_CHEM_DATE,2003 -CA-Ca2,27263,GRP_SOIL_CHEM,SOIL_CHEM_DATE,2004 -CA-Ca2,27894,GRP_SOIL_CHEM,SOIL_CHEM_DATE,2005 -CA-Ca2,27540,GRP_SOIL_CHEM,SOIL_CHEM_DATE,2006 -CA-Ca2,29094,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,CC_MIN -CA-Ca2,26976,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,CC_ORG -CA-Ca2,26975,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,CC_TOTAL -CA-Ca2,27262,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,"measurements by Jassal, P." -CA-Ca2,27263,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,"measurements by Jassal, P." -CA-Ca2,27540,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,"measurements by Jassal, P." -CA-Ca2,27894,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,"measurements by Jassal, P." -CA-Ca2,28152,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,"measurements by Jassal, P." -CA-Ca2,26834,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,mineral layer -CA-Ca2,24540,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION,Humoferric Podzols -CA-Ca2,24540,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION_TAXONOMY,Other -CA-Ca2,24540,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION_COMMENT," -Quelle: Humphreys_et_al_AgricForestMeteorol_2006(140):6-22" -CA-Ca2,24161,GRP_SOIL_DEPTH,SOIL_DEPTH,8.9 -CA-Ca2,24161,GRP_SOIL_DEPTH,SOIL_DEPTH_COMMENT,"(range 0.006-0.172) -source Humphreys_et_al_AgricForestMeteorol_2006(140):6-22" -CA-Ca2,24934,GRP_SOIL_DEPTH,SOIL_DEPTH,15 -CA-Ca2,24934,GRP_SOIL_DEPTH,SOIL_DEPTH_COMMENT,"Werte bezogen auf oberste 15cm -Quelle: Humphreys_et_al_AgricForestMeteorol_2006(140):6-22" -CA-Ca2,28153,GRP_SOIL_TEX,SOIL_TEX_SAND,74.3 -CA-Ca2,27264,GRP_SOIL_TEX,SOIL_TEX_SAND,75.85 -CA-Ca2,28262,GRP_SOIL_TEX,SOIL_TEX_SAND,84.3 -CA-Ca2,28493,GRP_SOIL_TEX,SOIL_TEX_SAND,89.65 -CA-Ca2,29452,GRP_SOIL_TEX,SOIL_TEX_SAND,92.4 -CA-Ca2,28262,GRP_SOIL_TEX,SOIL_TEX_SILT,13.9 -CA-Ca2,27264,GRP_SOIL_TEX,SOIL_TEX_SILT,21.15 -CA-Ca2,28153,GRP_SOIL_TEX,SOIL_TEX_SILT,22.45 -CA-Ca2,29452,GRP_SOIL_TEX,SOIL_TEX_SILT,6.85 -CA-Ca2,28493,GRP_SOIL_TEX,SOIL_TEX_SILT,8.45 -CA-Ca2,29452,GRP_SOIL_TEX,SOIL_TEX_CLAY,0.8 -CA-Ca2,28262,GRP_SOIL_TEX,SOIL_TEX_CLAY,1.75 -CA-Ca2,28493,GRP_SOIL_TEX,SOIL_TEX_CLAY,1.95 -CA-Ca2,27264,GRP_SOIL_TEX,SOIL_TEX_CLAY,3.05 -CA-Ca2,28153,GRP_SOIL_TEX,SOIL_TEX_CLAY,3.2 -CA-Ca2,28154,GRP_SOIL_TEX,SOIL_TEX_WATER_HOLD_CAP,25 -CA-Ca2,28263,GRP_SOIL_TEX,SOIL_TEX_WATER_HOLD_CAP,33 -CA-Ca2,28153,GRP_SOIL_TEX,SOIL_TEX_PROFILE_MIN,0 -CA-Ca2,28154,GRP_SOIL_TEX,SOIL_TEX_PROFILE_MIN,0 -CA-Ca2,28263,GRP_SOIL_TEX,SOIL_TEX_PROFILE_MIN,0 -CA-Ca2,27264,GRP_SOIL_TEX,SOIL_TEX_PROFILE_MIN,10 -CA-Ca2,28262,GRP_SOIL_TEX,SOIL_TEX_PROFILE_MIN,20 -CA-Ca2,28493,GRP_SOIL_TEX,SOIL_TEX_PROFILE_MIN,30 -CA-Ca2,29452,GRP_SOIL_TEX,SOIL_TEX_PROFILE_MIN,40 -CA-Ca2,28153,GRP_SOIL_TEX,SOIL_TEX_PROFILE_MAX,10 -CA-Ca2,27264,GRP_SOIL_TEX,SOIL_TEX_PROFILE_MAX,20 -CA-Ca2,28263,GRP_SOIL_TEX,SOIL_TEX_PROFILE_MAX,2000 -CA-Ca2,28262,GRP_SOIL_TEX,SOIL_TEX_PROFILE_MAX,30 -CA-Ca2,28493,GRP_SOIL_TEX,SOIL_TEX_PROFILE_MAX,40 -CA-Ca2,29452,GRP_SOIL_TEX,SOIL_TEX_PROFILE_MAX,50 -CA-Ca2,28154,GRP_SOIL_TEX,SOIL_TEX_PROFILE_MAX,5000 -CA-Ca2,28154,GRP_SOIL_TEX,SOIL_TEX_COMMENT,Field Capcity (-10kPa) -CA-Ca2,28263,GRP_SOIL_TEX,SOIL_TEX_COMMENT,Field Capcity (-1500kPa) -CA-Ca2,27264,GRP_SOIL_TEX,SOIL_TEX_COMMENT,"measurements by Jassal, P.; organic plus mineral layer" -CA-Ca2,28153,GRP_SOIL_TEX,SOIL_TEX_COMMENT,"measurements by Jassal, P.; organic plus mineral layer" -CA-Ca2,28262,GRP_SOIL_TEX,SOIL_TEX_COMMENT,"measurements by Jassal, P.; organic plus mineral layer" -CA-Ca2,28493,GRP_SOIL_TEX,SOIL_TEX_COMMENT,"measurements by Jassal, P.; organic plus mineral layer" -CA-Ca2,29452,GRP_SOIL_TEX,SOIL_TEX_COMMENT,"measurements by Jassal, P.; organic plus mineral layer" -CA-Ca2,28149,GRP_SPP_O,SPP_O,PSME (NRCS plant code) -CA-Ca2,28149,GRP_SPP_O,SPP_O_PERC,93 -CA-Ca2,28149,GRP_SPP_O,SPP_APPROACH,observation field visit 269/2002 -CA-Ca2,28149,GRP_SPP_O,SPP_DATE,2004 -CA-Ca2,28149,GRP_SPP_O,SPP_COMMENT,understory species were dense and included BENE2 and GATR3 -CA-Ca2,26972,GRP_SPP_U,SPP_U,CHANA2 (NRCS plant code) -CA-Ca2,26972,GRP_SPP_U,SPP_U_PERC,100 -CA-Ca2,26972,GRP_SPP_U,SPP_APPROACH,observation field visit 269/2003 -CA-Ca2,26972,GRP_SPP_U,SPP_DATE,2004 -CA-Ca2,26972,GRP_SPP_U,SPP_COMMENT,understory species were dense and included BENE2 and GATR3 -CA-Ca2,28987,GRP_STUMP_MASS,STUMP_MASS,3 -CA-Ca2,28987,GRP_STUMP_MASS,STUMP_MASS_UNIT,gC m-2 -CA-Ca2,28987,GRP_STUMP_MASS,STUMP_MASS_COMMENT,calculated from Canadian National Forest Inventory (CNFI) data on the Canadian Carbon Program Data Information System (CCP DIS) -CA-Ca2,23598,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,T. Andrew Black -CA-Ca2,23598,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -CA-Ca2,23598,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,andrew.black@ubc.ca -CA-Ca2,23598,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"University of British Columbia, Vancouver" -CA-Ca2,29787,GRP_TOWER_POWER,TOWER_POWER,Solar + generator -CA-Ca2,23599,GRP_TOWER_TYPE,TOWER_TYPE,triangle -CA-Ca2,23600,GRP_URL,URL,http://www.fluxnet-canada.ca/ -CA-Ca2,24000052,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/CA-Ca2 -CA-Ca2,23601,GRP_UTC_OFFSET,UTC_OFFSET,-8 -CA-Ca2,26973,GRP_WD_BIOMASS,WD_BIOMASS_CRS,5.3 -CA-Ca2,26973,GRP_WD_BIOMASS,WD_BIOMASS_UNIT,gC m-2 -CA-Ca2,26973,GRP_WD_BIOMASS,WD_BIOMASS_DATE,20021108 -CA-Ca2,26973,GRP_WD_BIOMASS,WD_BIOMASS_COMMENT,"Total, not CWD or FWD; ~312/2002; CWD represents total woody debris (coarse and fine) taken as mean of range in table 1. Humphrey et al. 2006" -CA-Ca3,29098,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER,14 -CA-Ca3,29098,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_ORGAN,Total -CA-Ca3,29098,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_PHEN,Mixed/unknown -CA-Ca3,29098,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_UNIT,gC m-2 -CA-Ca3,29098,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_APPROACH,"average of 6 400 m plot estimates, using PLOTBIO_FOLIAGE_LIVE column in BC-DF49,HDF00,HDF88,HDF90_FC-GP_LTP_HEADER_2002.csv plus BC-DF49,HDF00,HDF88,HDF90_FC-GP_STP_HEADER_2002.csv. From Eco&SiteCharacteristicsDF1988Groundplot_2002 on CCP DIS" -CA-Ca3,29098,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_DATE,20021105 -CA-Ca3,29098,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_COMMENT,"C content assumed 50% for all veg except Douglas-fir, 50.5%" -CA-Ca3,27271,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB,295 -CA-Ca3,27271,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_ORGAN,Total -CA-Ca3,27271,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_PHEN,Mixed/unknown -CA-Ca3,27271,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_UNIT,gC m-2 -CA-Ca3,27271,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_APPROACH,"average of 6 400 m plot estimates, using PLOTBIO_FOLIAGE_LIVE column in BC-DF49,HDF00,HDF88,HDF90_FC-GP_LTP_HEADER_2002.csv plus BC-DF49,HDF00,HDF88,HDF90_FC-GP_STP_HEADER_2002.csv. From Eco&SiteCharacteristicsDF1988Groundplot_2002 on CCP DIS" -CA-Ca3,27271,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_DATE,20021105 -CA-Ca3,27271,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_COMMENT,"C content assumed 50% for all veg except Douglas-fir, 50.5%" -CA-Ca3,27544,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,220 -CA-Ca3,27544,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Foliage -CA-Ca3,27544,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -CA-Ca3,27544,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -CA-Ca3,27544,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,"average of 6 400 m plot estimates, using PLOTBIO_FOLIAGE_LIVE column in BC-DF49,HDF00,HDF88,HDF90_FC-GP_LTP_HEADER_2002.csv plus BC-DF49,HDF00,HDF88,HDF90_FC-GP_STP_HEADER_2002.csv. From Eco&SiteCharacteristicsDF1988Groundplot_2002 on CCP DIS" -CA-Ca3,27544,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,20021105 -CA-Ca3,27544,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,"C content assumed 50% for all veg except Douglas-fir, 50.5%" -CA-Ca3,28990,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,610 -CA-Ca3,28990,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Wood -CA-Ca3,28990,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -CA-Ca3,28990,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -CA-Ca3,28990,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,"average of 6 400 m plot estimates, using PLOTBIO_FOLIAGE_LIVE column in BC-DF49,HDF00,HDF88,HDF90_FC-GP_LTP_HEADER_2002.csv plus BC-DF49,HDF00,HDF88,HDF90_FC-GP_STP_HEADER_2002.csv. From Eco&SiteCharacteristicsDF1988Groundplot_2002 on CCP DIS" -CA-Ca3,28990,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,20021105 -CA-Ca3,28990,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,"C content assumed 50% for all veg except Douglas-fir, 50.5%" -CA-Ca3,29456,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,830 -CA-Ca3,29456,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Total -CA-Ca3,29456,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -CA-Ca3,29456,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -CA-Ca3,29456,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,"average of 6 400 m plot estimates, using PLOTBIO_FOLIAGE_LIVE column in BC-DF49,HDF00,HDF88,HDF90_FC-GP_LTP_HEADER_2002.csv plus BC-DF49,HDF00,HDF88,HDF90_FC-GP_STP_HEADER_2002.csv. From Eco&SiteCharacteristicsDF1988Groundplot_2002 on CCP DIS" -CA-Ca3,29456,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,20021105 -CA-Ca3,29456,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,"C content assumed 50% for all veg except Douglas-fir, 50.5%" -CA-Ca3,29099,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS,21 -CA-Ca3,29099,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_UNIT,gC m-2 -CA-Ca3,29099,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_DATE,2003 -CA-Ca3,29099,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_COMMENT,estimated from 17 0.189 m2 litter traps every 90 days from 2002 to 2005 -CA-Ca3,26982,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS,22 -CA-Ca3,26982,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_UNIT,gC m-2 -CA-Ca3,26982,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_DATE,2002 -CA-Ca3,26982,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_COMMENT,estimated from 17 0.189 m2 litter traps every 90 days from 2002 to 2005 -CA-Ca3,29100,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS,28 -CA-Ca3,29100,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_UNIT,gC m-2 -CA-Ca3,29100,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_DATE,2005 -CA-Ca3,29100,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_COMMENT,estimated from 17 0.189 m2 litter traps every 90 days from 2002 to 2005 -CA-Ca3,28267,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS,31 -CA-Ca3,28267,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_UNIT,gC m-2 -CA-Ca3,28267,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_DATE,2004 -CA-Ca3,28267,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_COMMENT,estimated from 17 0.189 m2 litter traps every 90 days from 2002 to 2005 -CA-Ca3,27272,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT,21 -CA-Ca3,27897,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT,22 -CA-Ca3,27273,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT,28 -CA-Ca3,28157,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT,31 -CA-Ca3,27272,GRP_AG_LIT_PROD,AG_LIT_PROD_UNIT,gC m-2 -CA-Ca3,27273,GRP_AG_LIT_PROD,AG_LIT_PROD_UNIT,gC m-2 -CA-Ca3,27897,GRP_AG_LIT_PROD,AG_LIT_PROD_UNIT,gC m-2 -CA-Ca3,28157,GRP_AG_LIT_PROD,AG_LIT_PROD_UNIT,gC m-2 -CA-Ca3,27897,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_START,2002 -CA-Ca3,27272,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_START,2003 -CA-Ca3,28157,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_START,2004 -CA-Ca3,27273,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_START,2005 -CA-Ca3,27897,GRP_AG_LIT_PROD,AG_LIT_PROD_COMMENT,2002; estimated from ? 0.189 m2 litter traps every 90 days from 2002 to 2005 -CA-Ca3,27272,GRP_AG_LIT_PROD,AG_LIT_PROD_COMMENT,2003; estimated from ? 0.189 m2 litter traps every 90 days from 2002 to 2005 -CA-Ca3,28157,GRP_AG_LIT_PROD,AG_LIT_PROD_COMMENT,2004; estimated from ? 0.189 m2 litter traps every 90 days from 2002 to 2005 -CA-Ca3,27273,GRP_AG_LIT_PROD,AG_LIT_PROD_COMMENT,2005; estimated from ? 0.189 m2 litter traps every 90 days from 2002 to 2005 -CA-Ca3,29102,GRP_BIOMASS_CHEM,BIOMASS_C,5.05 -CA-Ca3,27545,GRP_BIOMASS_CHEM,BIOMASS_C,5.2 -CA-Ca3,26983,GRP_BIOMASS_CHEM,BIOMASS_N,0.1 -CA-Ca3,26983,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -CA-Ca3,27545,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -CA-Ca3,29102,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -CA-Ca3,26983,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -CA-Ca3,27545,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -CA-Ca3,29102,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -CA-Ca3,26983,GRP_BIOMASS_CHEM,BIOMASS_SPP,PSME (NRCS plant code) -CA-Ca3,27545,GRP_BIOMASS_CHEM,BIOMASS_SPP,PSME (NRCS plant code) -CA-Ca3,29102,GRP_BIOMASS_CHEM,BIOMASS_SPP,PSME (NRCS plant code) -CA-Ca3,26983,GRP_BIOMASS_CHEM,BIOMASS_DATE,2004 -CA-Ca3,27545,GRP_BIOMASS_CHEM,BIOMASS_DATE,2004 -CA-Ca3,27545,GRP_BIOMASS_CHEM,BIOMASS_COMMENT,from foliar C measurements of shoots used in LMA measurement -CA-Ca3,26983,GRP_BIOMASS_CHEM,BIOMASS_COMMENT,from foliar N measurements of shoots used in LMA measurement -CA-Ca3,29102,GRP_BIOMASS_CHEM,BIOMASS_COMMENT,"from Lamlom, S.H., Savidge, R.A. 2003." -CA-Ca3,23567,GRP_CLIM_AVG,MAT,9.94 -CA-Ca3,23567,GRP_CLIM_AVG,MAP,1676 -CA-Ca3,23567,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Cfb -CA-Ca3,27000053,GRP_COUNTRY,COUNTRY,Canada -CA-Ca3,5377,GRP_DM_FORESTRY,DM_FORESTRY,Clearcutting -CA-Ca3,5377,GRP_DM_FORESTRY,DM_DATE,1987 -CA-Ca3,7073,GRP_DM_PLANTING,DM_PLANTING,Planting live trees -CA-Ca3,7073,GRP_DM_PLANTING,DM_DATE,1987 -CA-Ca3,85012,GRP_DOI,DOI,10.17190/AMF/1480302 -CA-Ca3,85012,GRP_DOI,DOI_CITATION,"T. Andrew Black (2022), AmeriFlux BASE CA-Ca3 British Columbia - Pole sapling Douglas-fir stand, Ver. 4-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1480302" -CA-Ca3,85012,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -CA-Ca3,81653,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -CA-Ca3,81653,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,T. Andrew Black -CA-Ca3,81653,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -CA-Ca3,81653,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,andrew.black@ubc.ca -CA-Ca3,81653,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"University of British Columbia, Vancouver" -CA-Ca3,81658,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,"University of British Columbia, Vancouver" -CA-Ca3,81658,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -CA-Ca3,23568,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Forestry -CA-Ca3,96736,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -CA-Ca3,96736,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -CA-Ca3,96736,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,2001 -CA-Ca3,96736,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -CA-Ca3,96736,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,"(1) New 4-m x 4-m scaffolding tower installed in 2017 -(2) Flux measurement height raised to 31-m on 10 July 2017. -(3) New soil heat flux plates since 2017, total eight." -CA-Ca3,23000053,GRP_HEADER,SITE_NAME,British Columbia - Pole sapling Douglas-fir stand -CA-Ca3,27270,GRP_HEIGHTC,HEIGHTC,7.57 -CA-Ca3,27270,GRP_HEIGHTC,HEIGHTC_DATE,20021105 -CA-Ca3,27270,GRP_HEIGHTC,HEIGHTC_COMMENT,NFI contribution to CCP DIS -CA-Ca3,23570,GRP_IGBP,IGBP,ENF -CA-Ca3,23570,GRP_IGBP,IGBP_COMMENT,"18-yr-old Douglas-fir stand (75%), 21% western red cedar, 4% grand-fir" -CA-Ca3,29097,GRP_LAI,LAI_TYPE,LAI -CA-Ca3,29097,GRP_LAI,LAI_CLUMP,0.89 -CA-Ca3,29097,GRP_LAI,LAI_METHOD,LAI_2000 -CA-Ca3,29097,GRP_LAI,LAI_COMMENT,"Growing season 2004; LAI-2000 for LAI and DHP for clumping index; Chen et al., 2006" -CA-Ca3,29097,GRP_LAI,LAI_TOT,4.7 -CA-Ca3,23571,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -CA-Ca3,23571,GRP_LAND_OWNERSHIP,LAND_OWNER,Island Timberland -CA-Ca3,26984,GRP_LMA,LMA,104 -CA-Ca3,26984,GRP_LMA,LMA_SPP,PSME (NRCS plant code) -CA-Ca3,26984,GRP_LMA,LMA_DATE,2004 -CA-Ca3,26984,GRP_LMA,LMA_COMMENT,estimates from LA (cm2) and dry weight measurements (g) using CNFI NPP data on CCP DIS -CA-Ca3,23572,GRP_LOCATION,LOCATION_LAT,49.5346 -CA-Ca3,23572,GRP_LOCATION,LOCATION_LONG,-124.9004 -CA-Ca3,26836,GRP_NEP,NEP,-120000 -CA-Ca3,26836,GRP_NEP,NEP_APPROACH,"Jassal, P." -CA-Ca3,26836,GRP_NEP,NEP_DATE_START,2002 -CA-Ca3,26836,GRP_NEP,NEP_DATE_END,2003 -CA-Ca3,26836,GRP_NEP,NEP_COMMENT,Jan/Dec; method differs from the CCP protocol in that UBC Biomet use exponential relationship and not a logistic to model nighttime respiration. -CA-Ca3,29101,GRP_NEP,NEP,-99000 -CA-Ca3,29101,GRP_NEP,NEP_APPROACH,"Jassal, P." -CA-Ca3,29101,GRP_NEP,NEP_DATE_START,2003 -CA-Ca3,29101,GRP_NEP,NEP_DATE_END,2004 -CA-Ca3,29101,GRP_NEP,NEP_COMMENT,Jan/Dec; method differs from the CCP protocol in that UBC Biomet use exponential relationship and not a logistic to model nighttime respiration. -CA-Ca3,28268,GRP_NEP,NEP,-131000 -CA-Ca3,28268,GRP_NEP,NEP_APPROACH,"Jassal, P." -CA-Ca3,28268,GRP_NEP,NEP_DATE_START,2004 -CA-Ca3,28268,GRP_NEP,NEP_DATE_END,2005 -CA-Ca3,28268,GRP_NEP,NEP_COMMENT,Jan/Dec; method differs from the CCP protocol in that UBC Biomet use exponential relationship and not a logistic to model nighttime respiration. -CA-Ca3,27274,GRP_NEP,NEP,22000 -CA-Ca3,27274,GRP_NEP,NEP_APPROACH,"Jassal, P." -CA-Ca3,27274,GRP_NEP,NEP_DATE_START,2005 -CA-Ca3,27274,GRP_NEP,NEP_DATE_END,2006 -CA-Ca3,27274,GRP_NEP,NEP_COMMENT,Jan/Dec; method differs from the CCP protocol in that UBC Biomet use exponential relationship and not a logistic to model nighttime respiration. -CA-Ca3,27898,GRP_NEP,NEP,15000 -CA-Ca3,27898,GRP_NEP,NEP_APPROACH,"Jassal, P." -CA-Ca3,27898,GRP_NEP,NEP_DATE_START,2006 -CA-Ca3,27898,GRP_NEP,NEP_DATE_END,2007 -CA-Ca3,27898,GRP_NEP,NEP_COMMENT,Jan/Dec; method differs from the CCP protocol in that UBC Biomet use exponential relationship and not a logistic to model nighttime respiration. -CA-Ca3,27899,GRP_NEP,NEP,138000 -CA-Ca3,27899,GRP_NEP,NEP_APPROACH,"Jassal, P." -CA-Ca3,27899,GRP_NEP,NEP_DATE_START,2007 -CA-Ca3,27899,GRP_NEP,NEP_DATE_END,2008 -CA-Ca3,27899,GRP_NEP,NEP_COMMENT,Jan/Dec; method differs from the CCP protocol in that UBC Biomet use exponential relationship and not a logistic to model nighttime respiration. -CA-Ca3,23574,GRP_NETWORK,NETWORK,AmeriFlux -CA-Ca3,23573,GRP_NETWORK,NETWORK,Fluxnet-Canada -CA-Ca3,86940,GRP_NETWORK,NETWORK,Phenocam -CA-Ca3,1700004107,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Barr, A., Richardson, A., Hollinger, D., Papale, D., Arain, M., Black, T., Bohrer, G., Dragoni, D., Fischer, M., Gu, L., Law, B., Margolis, H., McCaughey, J., Munger, J., Oechel, W., Schaeffer, K. (2013) Use Of Change-Point Detection For Friction–Velocity Threshold Evaluation In Eddy-Covariance Studies, Agricultural And Forest Meteorology, 171-172(G4), 31-45" -CA-Ca3,1700004107,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2012.11.023 -CA-Ca3,1700004107,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Ca3,1700002250,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Briegel, F., Lee, S. C., Black, T. A., Jassal, R. S., Christen, A. (2020) Factors Controlling Long-Term Carbon Dioxide Exchange Between A Douglas-Fir Stand And The Atmosphere Identified Using An Artificial Neural Network Approach, Ecological Modelling, 435(2), 109266" -CA-Ca3,1700002250,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.ECOLMODEL.2020.109266 -CA-Ca3,1700002250,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Ca3,1700002715,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chen, J. M., Govind, A., Sonnentag, O., Zhang, Y., Barr, A., Amiro, B. (2006) Leaf Area Index Measurements At Fluxnet-Canada Forest Sites, Agricultural And Forest Meteorology, 140(1-4), 257-268" -CA-Ca3,1700002715,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2006.08.005 -CA-Ca3,1700002715,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Ca3,1700005874,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Baldocchi, D. D., Poindexter, C., Abraha, M., Desai, A. R., Bohrer, G., Arain, M. A., Griffis, T., Blanken, P. D., O'Halloran, T. L., Thomas, R. Q., Zhang, Q., Burns, S. P., Frank, J. M., Christian, D., Brown, S., Black, T. A., Gough, C. M., Law, B. E., Lee, X., Chen, J., Reed, D. E., Massman, W. J., Clark, K., Hatfield, J., Prueger, J., Bracho, R., Baker, J. M., Martin, T. A. (2018) Temporal Dynamics Of Aerodynamic Canopy Height Derived From Eddy Covariance Momentum Flux Data Across North American Flux Networks, Geophysical Research Letters, 45(2), 9275–9287" -CA-Ca3,1700005874,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018GL079306 -CA-Ca3,1700005874,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Ca3,1700006549,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Baldocchi, D. D., Poindexter, C., Abraha, M., Desai, A. R., Bohrer, G., Arain, M. A., Griffis, T., Blanken, P. D., O'Halloran, T. L., Thomas, R. Q., Zhang, Q., Burns, S. P., Frank, J. M., Christian, D., Brown, S., Black, T. A., Gough, C. M., Law, B. E., Lee, X., Chen, J., Reed, D. E., Massman, W. J., Clark, K., Hatfield, J., Prueger, J., Bracho, R., Baker, J. M., Martin, T. A. (2018) Temporal Dynamics Of Aerodynamic Canopy Height Derived From Eddy Covariance Momentum Flux Data Across North American Flux Networks, Geophysical Research Letters, 45(3), 9275–9287" -CA-Ca3,1700006549,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018GL079306 -CA-Ca3,1700006549,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Ca3,1700000234,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(2), 108350" -CA-Ca3,1700000234,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -CA-Ca3,1700000234,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Ca3,1700003138,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Coursolle, C., Margolis, H. A., Barr, A. G., Black, T. A., Amiro, B. D., McCaughey, J. H., Flanagan, L. B., Lafleur, P. M., Roulet, N. T., Bourque, C. P., Arain, M. A., Wofsy, S. C., Dunn, A., Morgenstern, K., Orchansky, A. L., Bernier, P. Y., Chen, J. M., Kidston, J., Saigusa, N., Hedstrom, N. (2006) Late-Summer Carbon Fluxes From Canadian Forests And Peatlands Along An East-–West Continental Transect, Canadian Journal Of Forest Research, 36(3), 783-800" -CA-Ca3,1700003138,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1139/X05-270 -CA-Ca3,1700003138,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Ca3,1700000690,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Dennis Baldocchi, Cove Sturtevant (2015) Does day and night sampling reduce spurious correlation between canopy photosynthesis and ecosystem respiration?, Agricultural and Forest Meteorology, 207(3), 117-126" -CA-Ca3,1700000690,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2015.03.010 -CA-Ca3,1700000690,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Ca3,1700008670,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Humphreys, E. R., Black, T. A., Morgenstern, K., Cai, T., Drewitt, G. B., Nesic, Z., Trofymow, J. (2006) Carbon Dioxide Fluxes In Coastal Douglas-Fir Stands At Different Stages Of Development After Clearcut Harvesting, Agricultural And Forest Meteorology, 140(1-4), 6-22" -CA-Ca3,1700008670,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2006.03.018 -CA-Ca3,1700008670,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Ca3,1700003609,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Jassal, R. S., Black, T. A., Novak, M. D., Gaumont-Guay, D., Nesic, Z. (2008) Effect Of Soil Water Stress On Soil Respiration And Its Temperature Sensitivity In An 18-Year-Old Temperate Douglas-Fir Stand, Global Change Biology, 14(6), 1305-1318" -CA-Ca3,1700003609,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/J.1365-2486.2008.01573.X -CA-Ca3,1700003609,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Ca3,1700007806,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Krishnan, P., Black, T. A., Jassal, R. S., Chen, B., Nesic, Z. (2009) Interannual Variability Of The Carbon Balance Of Three Different-Aged Douglas-Fir Stands In The Pacific Northwest, Journal Of Geophysical Research, 114(G4), 9275–9287" -CA-Ca3,1700007806,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2008JG000912 -CA-Ca3,1700007806,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Ca3,1700006228,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Lee, S., Black, T. A., Jassal, R. S., Christen, A., Meyer, G., Nesic, Z. (2020) Long-Term Impact Of Nitrogen Fertilization On Carbon And Water Fluxes In A Douglas-Fir Stand In The Pacific Northwest, Forest Ecology And Management, 455(2), 117645" -CA-Ca3,1700006228,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.FORECO.2019.117645 -CA-Ca3,1700006228,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Ca3,1700003843,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Lee, S., Christen, A., Black, T. A., Jassal, R. S., Ketler, R., Nesic, Z. (2020) Partitioning Of Net Ecosystem Exchange Into Photosynthesis And Respiration Using Continuous Stable Isotope Measurements In A Pacific Northwest Douglas-Fir Forest Ecosystem, Agricultural And Forest Meteorology, 292-293(2), 108109" -CA-Ca3,1700003843,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2020.108109 -CA-Ca3,1700003843,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Ca3,1700005667,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"McKendry, I. G., Christen, A., Lee, S., Ferrara, M., Strawbridge, K. B., O'Neill, N., Black, A. (2019) Impacts Of An Intense Wildfire Smoke Episode On Surface Radiation, Energy And Carbon Fluxes In Southwestern British Columbia, Canada, Atmospheric Chemistry And Physics, 19(2), 835-846" -CA-Ca3,1700005667,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.5194/ACP-19-835-2019 -CA-Ca3,1700005667,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Ca3,1700008430,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Xu, B., Arain, M. A., Black, T. A., Law, B. E., Pastorello, G. Z., Chu, H. (2020) Seasonal Variability Of Forest Sensitivity To Heat And Drought Stresses: A Synthesis Based On Carbon Fluxes From North American Forest Ecosystems, Global Change Biology, 26(2), 901-918" -CA-Ca3,1700008430,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/GCB.14843 -CA-Ca3,1700008430,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Ca3,29096,GRP_SA,SA,19 -CA-Ca3,29096,GRP_SA,SA_COMMENT,"planted 1988; Humphreys etal., 2006" -CA-Ca3,29096,GRP_SA,SA_MAX,19 -CA-Ca3,23579,GRP_SITE_CHAR,TERRAIN,"Medium Slope (>2 %, <5%)" -CA-Ca3,23579,GRP_SITE_CHAR,ASPECT,SE -CA-Ca3,23579,GRP_SITE_CHAR,WIND_DIRECTION,SE -CA-Ca3,23579,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,400 -CA-Ca3,99152,GRP_SITE_DESC,SITE_DESC,"Site: 1988 Harvested Douglas Fir (Pole-sapling); Tower Type 10"" triangular tower; Latitude/Longitude 49.53462N -124.90044W (GPS survey, 2003. Coordinates updated/corrected May, 2006); Elevation approx. 170 m; Mean Air Temp. (for the growing season) 9.7 C *; Mean Annual Precipitation 1179 mm *; Date Operations Began: September 2001; Frequency of EC Measurements 20 Hz; Frequency of Other Met. Sensors 4 sec, year round; Soil Respiration Measurements Periodically during growing season using portable system in 2002; * 30-yr climate normals from the Comox Airport" -CA-Ca3,26835,GRP_SNAG_MASS,SNAG_MASS,0 -CA-Ca3,26835,GRP_SNAG_MASS,SNAG_MASS_UNIT,gC m-2 -CA-Ca3,26835,GRP_SNAG_MASS,SNAG_MASS_DATE,20021108 -CA-Ca3,26835,GRP_SNAG_MASS,SNAG_MASS_COMMENT,269-312/2002; calculated from CNFI data on CCP DIS -CA-Ca3,26837,GRP_SOIL_CHEM,SOIL_CHEM_C_ORG,140.667 -CA-Ca3,28497,GRP_SOIL_CHEM,SOIL_CHEM_C_ORG,48.95 -CA-Ca3,26838,GRP_SOIL_CHEM,SOIL_CHEM_C_ORG,91.7167 -CA-Ca3,26839,GRP_SOIL_CHEM,SOIL_CHEM_PH_SALT,5 -CA-Ca3,26987,GRP_SOIL_CHEM,SOIL_CHEM_BD,0.696754670543706 -CA-Ca3,26985,GRP_SOIL_CHEM,SOIL_CHEM_BD,0.751615494140867 -CA-Ca3,27547,GRP_SOIL_CHEM,SOIL_CHEM_BD,0.763609358409072 -CA-Ca3,27546,GRP_SOIL_CHEM,SOIL_CHEM_BD,0.953438173123137 -CA-Ca3,26986,GRP_SOIL_CHEM,SOIL_CHEM_BD,1.01259309627311 -CA-Ca3,26837,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,0 -CA-Ca3,26985,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,0 -CA-Ca3,28497,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,0 -CA-Ca3,27546,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,10 -CA-Ca3,26986,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,20 -CA-Ca3,26838,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,3 -CA-Ca3,26839,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,3 -CA-Ca3,27547,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,30 -CA-Ca3,26987,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,40 -CA-Ca3,26985,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,10 -CA-Ca3,26837,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,100 -CA-Ca3,26838,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,100 -CA-Ca3,26839,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,103 -CA-Ca3,27546,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,20 -CA-Ca3,28497,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,3 -CA-Ca3,26986,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,30 -CA-Ca3,27547,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,40 -CA-Ca3,26987,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,50 -CA-Ca3,26839,GRP_SOIL_CHEM,SOIL_CHEM_DATE,2002 -CA-Ca3,26985,GRP_SOIL_CHEM,SOIL_CHEM_DATE,2002 -CA-Ca3,26986,GRP_SOIL_CHEM,SOIL_CHEM_DATE,2002 -CA-Ca3,26987,GRP_SOIL_CHEM,SOIL_CHEM_DATE,2002 -CA-Ca3,27546,GRP_SOIL_CHEM,SOIL_CHEM_DATE,2002 -CA-Ca3,27547,GRP_SOIL_CHEM,SOIL_CHEM_DATE,2002 -CA-Ca3,26837,GRP_SOIL_CHEM,SOIL_CHEM_DATE,20020927 -CA-Ca3,26838,GRP_SOIL_CHEM,SOIL_CHEM_DATE,20020927 -CA-Ca3,28497,GRP_SOIL_CHEM,SOIL_CHEM_DATE,20020927 -CA-Ca3,26839,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,calculated from CNFI data on CCP DIS -CA-Ca3,28497,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,CC_MIN -CA-Ca3,26838,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,CC_ORG -CA-Ca3,26837,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,CC_TOTAL -CA-Ca3,26985,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,"measurements by Jassal, P." -CA-Ca3,26986,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,"measurements by Jassal, P." -CA-Ca3,26987,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,"measurements by Jassal, P." -CA-Ca3,27546,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,"measurements by Jassal, P." -CA-Ca3,27547,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,"measurements by Jassal, P." -CA-Ca3,24156,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION,Humoferric Podzols -CA-Ca3,24156,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION_TAXONOMY,Other -CA-Ca3,24156,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION_COMMENT," -Quelle: Humphreys_et_al_AgricForestMeteorol_2006(140):6-22" -CA-Ca3,23912,GRP_SOIL_DEPTH,SOIL_DEPTH,6.7 -CA-Ca3,23912,GRP_SOIL_DEPTH,SOIL_DEPTH_COMMENT,"(range 0.019-0.115) -source Humphreys_et_al_AgricForestMeteorol_2006(140):6-22" -CA-Ca3,24935,GRP_SOIL_DEPTH,SOIL_DEPTH,15 -CA-Ca3,24935,GRP_SOIL_DEPTH,SOIL_DEPTH_COMMENT,"Werte bezogen auf oberste 15cm -Quelle: Humphreys_et_al_AgricForestMeteorol_2006(140):6-22" -CA-Ca3,27900,GRP_SOIL_TEX,SOIL_TEX_SAND,39.8 -CA-Ca3,29457,GRP_SOIL_TEX,SOIL_TEX_SAND,39.9 -CA-Ca3,28269,GRP_SOIL_TEX,SOIL_TEX_SAND,40.3 -CA-Ca3,29103,GRP_SOIL_TEX,SOIL_TEX_SAND,42.2 -CA-Ca3,28991,GRP_SOIL_TEX,SOIL_TEX_SAND,42.5 -CA-Ca3,26701,GRP_SOIL_TEX,SOIL_TEX_SAND,44.6 -CA-Ca3,26701,GRP_SOIL_TEX,SOIL_TEX_SILT,36.7 -CA-Ca3,28991,GRP_SOIL_TEX,SOIL_TEX_SILT,38.4 -CA-Ca3,29457,GRP_SOIL_TEX,SOIL_TEX_SILT,39.9 -CA-Ca3,28269,GRP_SOIL_TEX,SOIL_TEX_SILT,40.7 -CA-Ca3,29103,GRP_SOIL_TEX,SOIL_TEX_SILT,41.5 -CA-Ca3,27900,GRP_SOIL_TEX,SOIL_TEX_SILT,43.7 -CA-Ca3,29103,GRP_SOIL_TEX,SOIL_TEX_CLAY,16.3 -CA-Ca3,27900,GRP_SOIL_TEX,SOIL_TEX_CLAY,16.5 -CA-Ca3,26701,GRP_SOIL_TEX,SOIL_TEX_CLAY,18.7 -CA-Ca3,28269,GRP_SOIL_TEX,SOIL_TEX_CLAY,19 -CA-Ca3,28991,GRP_SOIL_TEX,SOIL_TEX_CLAY,19.1 -CA-Ca3,29457,GRP_SOIL_TEX,SOIL_TEX_CLAY,20.2 -CA-Ca3,29104,GRP_SOIL_TEX,SOIL_TEX_WATER_HOLD_CAP,0.29 -CA-Ca3,29104,GRP_SOIL_TEX,SOIL_TEX_PROFILE_MIN,0 -CA-Ca3,29457,GRP_SOIL_TEX,SOIL_TEX_PROFILE_MIN,0 -CA-Ca3,28991,GRP_SOIL_TEX,SOIL_TEX_PROFILE_MIN,10 -CA-Ca3,26701,GRP_SOIL_TEX,SOIL_TEX_PROFILE_MIN,20 -CA-Ca3,29103,GRP_SOIL_TEX,SOIL_TEX_PROFILE_MIN,30 -CA-Ca3,28269,GRP_SOIL_TEX,SOIL_TEX_PROFILE_MIN,40 -CA-Ca3,27900,GRP_SOIL_TEX,SOIL_TEX_PROFILE_MIN,50 -CA-Ca3,29457,GRP_SOIL_TEX,SOIL_TEX_PROFILE_MAX,10 -CA-Ca3,28991,GRP_SOIL_TEX,SOIL_TEX_PROFILE_MAX,20 -CA-Ca3,26701,GRP_SOIL_TEX,SOIL_TEX_PROFILE_MAX,30 -CA-Ca3,29103,GRP_SOIL_TEX,SOIL_TEX_PROFILE_MAX,40 -CA-Ca3,28269,GRP_SOIL_TEX,SOIL_TEX_PROFILE_MAX,50 -CA-Ca3,29104,GRP_SOIL_TEX,SOIL_TEX_PROFILE_MAX,50 -CA-Ca3,27900,GRP_SOIL_TEX,SOIL_TEX_PROFILE_MAX,60 -CA-Ca3,29104,GRP_SOIL_TEX,SOIL_TEX_COMMENT,"Field capacity (-10kPa); contact Jassal, P. of UBC biomet" -CA-Ca3,26701,GRP_SOIL_TEX,SOIL_TEX_COMMENT,"Loam; contact Jassal, P. of UBC biomet" -CA-Ca3,27900,GRP_SOIL_TEX,SOIL_TEX_COMMENT,"Loam; contact Jassal, P. of UBC biomet" -CA-Ca3,28269,GRP_SOIL_TEX,SOIL_TEX_COMMENT,"Loam; contact Jassal, P. of UBC biomet" -CA-Ca3,28991,GRP_SOIL_TEX,SOIL_TEX_COMMENT,"Loam; contact Jassal, P. of UBC biomet" -CA-Ca3,29103,GRP_SOIL_TEX,SOIL_TEX_COMMENT,"Loam; contact Jassal, P. of UBC biomet" -CA-Ca3,29457,GRP_SOIL_TEX,SOIL_TEX_COMMENT,"Loam; contact Jassal, P. of UBC biomet" -CA-Ca3,28989,GRP_SPP_O,SPP_O,PSME (NRCS plant code) -CA-Ca3,28989,GRP_SPP_O,SPP_O_PERC,75 -CA-Ca3,28989,GRP_SPP_O,SPP_APPROACH,observation field visit 269/2002 -CA-Ca3,28989,GRP_SPP_O,SPP_COMMENT,"understory species were dense and included PTAQ and POMU; Humphreys etal., 2006;" -CA-Ca3,28290,GRP_SPP_U,SPP_U,CHANA2 (NRCS plant code) -CA-Ca3,26862,GRP_SPP_U,SPP_U,POMU (NRCS plant code) -CA-Ca3,28529,GRP_SPP_U,SPP_U,PTAQ (NRCS plant code) -CA-Ca3,26862,GRP_SPP_U,SPP_U_PERC,20 -CA-Ca3,28529,GRP_SPP_U,SPP_U_PERC,20 -CA-Ca3,28290,GRP_SPP_U,SPP_U_PERC,40 -CA-Ca3,26862,GRP_SPP_U,SPP_COMMENT,"understory species were dense and included PTAQ and POMU; Humphreys etal., 2006;" -CA-Ca3,28290,GRP_SPP_U,SPP_COMMENT,"understory species were dense and included PTAQ and POMU; Humphreys etal., 2006;" -CA-Ca3,28529,GRP_SPP_U,SPP_COMMENT,"understory species were dense and included PTAQ and POMU; Humphreys etal., 2006;" -CA-Ca3,28156,GRP_STUMP_MASS,STUMP_MASS,5 -CA-Ca3,28156,GRP_STUMP_MASS,STUMP_MASS_UNIT,gC m-2 -CA-Ca3,28156,GRP_STUMP_MASS,STUMP_MASS_COMMENT,calculated from Canadian National Forest Inventory (CNFI) data on the Canadian Carbon Program Data Information System (CCP DIS) -CA-Ca3,23581,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,T. Andrew Black -CA-Ca3,23581,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -CA-Ca3,23581,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,andrew.black@ubc.ca -CA-Ca3,23581,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"University of British Columbia, Vancouver" -CA-Ca3,99142,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Zoran Nesic -CA-Ca3,99142,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -CA-Ca3,99142,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,zoran.nesic@ubc.ca -CA-Ca3,99142,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,UBC Vancouver -CA-Ca3,99161,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Paul Jassal -CA-Ca3,99161,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,BADMContact -CA-Ca3,99161,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,rachhpal.jassal@ubc.ca -CA-Ca3,99161,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,UBC Vancouver -CA-Ca3,29788,GRP_TOWER_POWER,TOWER_POWER,Solar + generator -CA-Ca3,23582,GRP_TOWER_TYPE,TOWER_TYPE,triangle -CA-Ca3,23583,GRP_URL,URL,http://www.fluxnet-canada.ca/ -CA-Ca3,24000053,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/CA-Ca3 -CA-Ca3,23584,GRP_UTC_OFFSET,UTC_OFFSET,-8 -CA-Ca3,28496,GRP_WD_BIOMASS,WD_BIOMASS_CRS,3 -CA-Ca3,28496,GRP_WD_BIOMASS,WD_BIOMASS_UNIT,gC m-2 -CA-Ca3,28496,GRP_WD_BIOMASS,WD_BIOMASS_DATE,20021108 -CA-Ca3,28496,GRP_WD_BIOMASS,WD_BIOMASS_COMMENT,"Total, not CWD or FWD; ~312/2002; CWD represents total woody debris (coarse and fine) taken as mean of range in table 1. Humphrey et al. 2006" -CA-Cbo,4232,GRP_CLIM_AVG,MAT,6.66 -CA-Cbo,4232,GRP_CLIM_AVG,MAP,876.34 -CA-Cbo,4232,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfb -CA-Cbo,27000054,GRP_COUNTRY,COUNTRY,Canada -CA-Cbo,86008,GRP_DOI,DOI,10.17190/AMF/1498755 -CA-Cbo,86008,GRP_DOI,DOI_CITATION,"Ralf Staebler (2021), AmeriFlux BASE CA-Cbo Ontario - Mixed Deciduous, Borden Forest Site, Ver. 5-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1498755" -CA-Cbo,86008,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -CA-Cbo,85035,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -CA-Cbo,85035,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Ralf Staebler -CA-Cbo,85035,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -CA-Cbo,85035,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,Ralf.Staebler@ec.gc.ca -CA-Cbo,85035,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Environment and Climate Change Canada -CA-Cbo,85036,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Environment and Climate Change Canada -CA-Cbo,85036,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -CA-Cbo,79225,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -CA-Cbo,79225,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -CA-Cbo,79225,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,1995 -CA-Cbo,79225,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -CA-Cbo,79225,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,added by AMF Data Team based on imports from Fluxnet-Canada -CA-Cbo,79227,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -CA-Cbo,79227,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -CA-Cbo,79227,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,1995 -CA-Cbo,79227,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -CA-Cbo,79227,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,added by AMF Data Team based on imports from Fluxnet-Canada -CA-Cbo,79226,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -CA-Cbo,79226,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -CA-Cbo,79226,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,1995 -CA-Cbo,79226,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -CA-Cbo,79226,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,added by AMF Data Team based on imports from Fluxnet-Canada -CA-Cbo,23000054,GRP_HEADER,SITE_NAME,"Ontario - Mixed Deciduous, Borden Forest Site" -CA-Cbo,8,GRP_IGBP,IGBP,DBF -CA-Cbo,8382,GRP_LOCATION,LOCATION_LAT,44.3167 -CA-Cbo,8382,GRP_LOCATION,LOCATION_LONG,-79.9333 -CA-Cbo,8382,GRP_LOCATION,LOCATION_ELEV,120 -CA-Cbo,11383,GRP_NETWORK,NETWORK,AmeriFlux -CA-Cbo,79224,GRP_NETWORK,NETWORK,Fluxnet-Canada -CA-Cbo,1700002916,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Barr, A. G., Griffis, T. J., Black, T. A., Lee, X., Staebler, R. M., Fuentes, J. D., Chen, Z., Morgenstern, K. (2002) Comparing The Carbon Budgets Of Boreal And Temperate Deciduous Forest Stands, Canadian Journal Of Forest Research, 32(5), 813-822" -CA-Cbo,1700002916,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1139/X01-131 -CA-Cbo,1700002916,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Cbo,1700005961,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Baldocchi, D. D., Poindexter, C., Abraha, M., Desai, A. R., Bohrer, G., Arain, M. A., Griffis, T., Blanken, P. D., O'Halloran, T. L., Thomas, R. Q., Zhang, Q., Burns, S. P., Frank, J. M., Christian, D., Brown, S., Black, T. A., Gough, C. M., Law, B. E., Lee, X., Chen, J., Reed, D. E., Massman, W. J., Clark, K., Hatfield, J., Prueger, J., Bracho, R., Baker, J. M., Martin, T. A. (2018) Temporal Dynamics Of Aerodynamic Canopy Height Derived From Eddy Covariance Momentum Flux Data Across North American Flux Networks, Geophysical Research Letters, 45(1-2), 9275–9287" -CA-Cbo,1700005961,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018GL079306 -CA-Cbo,1700005961,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Cbo,1700007245,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Baldocchi, D. D., Poindexter, C., Abraha, M., Desai, A. R., Bohrer, G., Arain, M. A., Griffis, T., Blanken, P. D., O'Halloran, T. L., Thomas, R. Q., Zhang, Q., Burns, S. P., Frank, J. M., Christian, D., Brown, S., Black, T. A., Gough, C. M., Law, B. E., Lee, X., Chen, J., Reed, D. E., Massman, W. J., Clark, K., Hatfield, J., Prueger, J., Bracho, R., Baker, J. M., Martin, T. A. (2018) Temporal Dynamics Of Aerodynamic Canopy Height Derived From Eddy Covariance Momentum Flux Data Across North American Flux Networks, Geophysical Research Letters, 45(8), 9275–9287" -CA-Cbo,1700007245,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018GL079306 -CA-Cbo,1700007245,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Cbo,1700003216,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(1-2), 108350" -CA-Cbo,1700003216,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -CA-Cbo,1700003216,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Cbo,1700004887,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Croft, H., Chen, J. M., Froelich, N. J., Chen, B., Staebler, R. M. (2015) Seasonal Controls Of Canopy Chlorophyll Content On Forest Carbon Uptake: Implications For Gpp Modeling, Journal Of Geophysical Research: Biogeosciences, 120(8), 1576-1586" -CA-Cbo,1700004887,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/2015JG002980 -CA-Cbo,1700004887,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Cbo,1700007284,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Froelich,N.J., Croft,H., Gonsamo,A., Staebler,R.M. (2015) Trends of carbon fluxes and climate over a mixed temperate–boreal transition forest in southern Ontario, Canada, Agricultural and Forest Meteorology, 211(1-2), 72-84" -CA-Cbo,1700007284,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Cbo,1700003852,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Fuentes, J. D., Wang, D. (1999) On The Seasonality Of Isoprene Emissions From A Mixed Temperate Forest, Ecological Applications, 9(4), 1118-1131" -CA-Cbo,1700003852,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1890/1051-0761(1999)009[1118:OTSOIE]2.0.CO;2 -CA-Cbo,1700003852,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Cbo,1700007476,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Fuentes, J., Gillespie, T., den Hartog, G., Neumann, H. (1992) Ozone Deposition Onto A Deciduous Forest During Dry And Wet Conditions, Agricultural And Forest Meteorology, 62(1-2), 1-18" -CA-Cbo,1700007476,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/0168-1923(92)90002-L -CA-Cbo,1700007476,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Cbo,1700003177,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Fuentes, J., Wang, D., Den Hartog, G., Neumann, H., Dann, T., Puckett, K. (1995) Modelled And Field Measurements Of Biogenic Hydrocarbon Emissions From A Canadian Deciduous Forest, Atmospheric Environment, 29(21), 3003-3017" -CA-Cbo,1700003177,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/1352-2310(95)00120-N -CA-Cbo,1700003177,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Cbo,1700002541,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Gu, L., Fuentes, J. D., Shugart, H. H., Staebler, R. M., Black, T. A. (1999) Responses Of Net Ecosystem Exchanges Of Carbon Dioxide To Changes In Cloudiness: Results From Two North American Deciduous Forests, Journal Of Geophysical Research: Atmospheres, 104(D24), 31421-31434" -CA-Cbo,1700002541,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/1999JD901068 -CA-Cbo,1700002541,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Cbo,1700008547,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Lee, X., Barr, A. G. (1998) Climatology Of Gravity Waves In A Forest, Quarterly Journal Of The Royal Meteorological Society, 124(549), 1403-1419" -CA-Cbo,1700008547,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/QJ.49712454904 -CA-Cbo,1700008547,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Cbo,1700006114,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Lee, X., Black, T., den Hartog, G., Neumann, H. H., Nesic, Z., Olejnik, J. (1996) Carbon Dioxide Exchange And Nocturnal Processes Over A Mixed Deciduous Forest, Agricultural And Forest Meteorology, 81(1-2), 13-29" -CA-Cbo,1700006114,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/0168-1923(95)02310-0 -CA-Cbo,1700006114,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Cbo,1700008709,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Lee, X., Fuentes, J. D., Staebler, R. M., Neumann, H. H. (1999) Long-Term Observation Of The Atmospheric Exchange Of CO2 With A Temperate Deciduous Forest In Southern Ontario, Canada, Journal Of Geophysical Research: Atmospheres, 104(D13), 15975-15984" -CA-Cbo,1700008709,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/1999JD900227 -CA-Cbo,1700008709,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Cbo,1700004236,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Luo, X., Croft, H., Chen, J. M., Bartlett, P., Staebler, R., Froelich, N. (2018) Incorporating Leaf Chlorophyll Content Into A Two-Leaf Terrestrial Biosphere Model For Estimating Carbon And Water Fluxes At A Forest Site, Agricultural And Forest Meteorology, 248(8), 156-168" -CA-Cbo,1700004236,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2017.09.012 -CA-Cbo,1700004236,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Cbo,1700004815,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Makar, P. A., Fuentes, J. D., Wang, D., Staebler, R. M., Wiebe, H. A. (1999) Chemical Processing Of Biogenic Hydrocarbons Within And Above A Temperate Deciduous Forest, Journal Of Geophysical Research: Atmospheres, 104(D3), 3581-3603" -CA-Cbo,1700004815,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/1998JD100065 -CA-Cbo,1700004815,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Cbo,1700008595,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Moon, Z., Fuentes, J. D., Staebler, R. M. (2020) Impacts Of Spectrally Resolved Irradiance On Photolysis Frequency Calculations Within A Forest Canopy, Agricultural And Forest Meteorology, 291(10), 108012" -CA-Cbo,1700008595,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2020.108012 -CA-Cbo,1700008595,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Cbo,1700006867,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Rogers, C. A., Chen, J. M., Zheng, T., Croft, H., Gonsamo, A., Luo, X., Staebler, R. M. (2020) The Response Of Spectral Vegetation Indices And Solar‐Induced Fluorescence To Changes In Illumination Intensity And Geometry In The Days Surrounding The 2017 North American Solar Eclipse, Journal Of Geophysical Research: Biogeosciences, 125(10), 1576-1586" -CA-Cbo,1700006867,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2020JG005774 -CA-Cbo,1700006867,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Cbo,1700008502,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Santos, M., Santos, E., Wagner-Riddle, C., Brown, S., Stropes, K., Staebler, R., Nippert, J. (2019) Evaluating A Lagrangian Inverse Model For Inferring Isotope Co2 Exchange In Plant Canopies, Agricultural And Forest Meteorology, 276-277(10), 107651" -CA-Cbo,1700008502,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2019.107651 -CA-Cbo,1700008502,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Cbo,5100,GRP_SITE_DESC,SITE_DESC,Mixed deciduous forest from natural regrowth. -CA-Cbo,97729,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Ralf Staebler -CA-Cbo,97729,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -CA-Cbo,97729,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,Ralf.Staebler@ec.gc.ca -CA-Cbo,97729,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Environment and Climate Change Canada -CA-Cbo,95913,GRP_URL,URL,https://www.canada.ca/en/environment-climate-change/services/air-pollution/research-science/applications/borden-forest-station.html -CA-Cbo,24000054,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/CA-Cbo -CA-Cbo,33535,GRP_UTC_OFFSET,UTC_OFFSET,-5 -CA-Cbo,33535,GRP_UTC_OFFSET,UTC_OFFSET_COMMENT,Added by AMF data processing team for data QAQC checks. -CA-Cha,7672,GRP_CLIM_AVG,MAT,3.46 -CA-Cha,7672,GRP_CLIM_AVG,MAP,971.68 -CA-Cha,7672,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfb -CA-Cha,27000055,GRP_COUNTRY,COUNTRY,Canada -CA-Cha,81565,GRP_DOI,DOI,10.17190/AMF/1436317 -CA-Cha,81565,GRP_DOI,DOI_CITATION,"Charles Bourque (2018), AmeriFlux BASE CA-Cha New Brunswick - Charlie Lake site 01 (immature balsam fir forest to be thinned in year 3), Ver. 1-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1436317" -CA-Cha,81565,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -CA-Cha,81527,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -CA-Cha,81527,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Charles Bourque -CA-Cha,81527,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -CA-Cha,81527,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,cbourque@unb.ca -CA-Cha,81527,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of New Brunswick -CA-Cha,81528,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,University of New Brunswick -CA-Cha,81528,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -CA-Cha,79230,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -CA-Cha,79230,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -CA-Cha,79230,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,2004 -CA-Cha,79230,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,2005 -CA-Cha,79230,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -CA-Cha,79230,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,added by AMF Data Team based on imports from Fluxnet-Canada -CA-Cha,79228,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -CA-Cha,79228,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -CA-Cha,79228,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,2004 -CA-Cha,79228,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,2005 -CA-Cha,79228,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -CA-Cha,79228,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,added by AMF Data Team based on imports from Fluxnet-Canada -CA-Cha,79229,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -CA-Cha,79229,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -CA-Cha,79229,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,2004 -CA-Cha,79229,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,2005 -CA-Cha,79229,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -CA-Cha,79229,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,added by AMF Data Team based on imports from Fluxnet-Canada -CA-Cha,23000055,GRP_HEADER,SITE_NAME,New Brunswick - Charlie Lake site 01 (immature balsam fir forest to be thinned in year 3) -CA-Cha,8482,GRP_IGBP,IGBP,MF -CA-Cha,53,GRP_LOCATION,LOCATION_LAT,45.8847 -CA-Cha,53,GRP_LOCATION,LOCATION_LONG,-67.3569 -CA-Cha,53,GRP_LOCATION,LOCATION_ELEV,341 -CA-Cha,11384,GRP_NETWORK,NETWORK,AmeriFlux -CA-Cha,2943,GRP_NETWORK,NETWORK,Fluxnet-Canada -CA-Cha,6781,GRP_SITE_DESC,SITE_DESC,mature balsam fir forest -CA-Cha,33601,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Charles Bourque -CA-Cha,33601,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -CA-Cha,33601,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,cbourque@unb.ca -CA-Cha,33601,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of New Brunswick -CA-Cha,2654,GRP_URL,URL,http://www.fluxnet-canada.ca/ -CA-Cha,24000055,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/CA-Cha -CA-Cha,33536,GRP_UTC_OFFSET,UTC_OFFSET,-4 -CA-Cha,33536,GRP_UTC_OFFSET,UTC_OFFSET_COMMENT,Added by AMF data processing team for data QAQC checks. -CA-DB2,91497,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,Metro Vancouver -CA-DB2,27001133,GRP_COUNTRY,COUNTRY,Canada -CA-DB2,97420,GRP_DOI,DOI,10.17190/AMF/1811362 -CA-DB2,97420,GRP_DOI,DOI_CITATION,"Sara Knox (2021), AmeriFlux BASE CA-DB2 Delta Burns Bog 2, Ver. 1-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1811362" -CA-DB2,97420,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -CA-DB2,97414,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -CA-DB2,97414,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Sara Knox -CA-DB2,97414,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -CA-DB2,97414,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,sara.knox@ubc.ca -CA-DB2,97414,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,The University of British Columbia -CA-DB2,97418,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,The University of British Columbia -CA-DB2,97418,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -CA-DB2,97416,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,"NSERC, CFI" -CA-DB2,97416,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -CA-DB2,91499,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Hydrologic event -CA-DB2,91491,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -CA-DB2,91491,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -CA-DB2,91491,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201911191500 -CA-DB2,91491,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -CA-DB2,91494,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -CA-DB2,91494,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CH4 -CA-DB2,91494,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201911191500 -CA-DB2,91494,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -CA-DB2,91500,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -CA-DB2,91500,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -CA-DB2,91500,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201911191500 -CA-DB2,91500,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -CA-DB2,91490,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -CA-DB2,91490,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -CA-DB2,91490,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201911191500 -CA-DB2,91490,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -CA-DB2,23001133,GRP_HEADER,SITE_NAME,Delta Burns Bog 2 -CA-DB2,91489,GRP_IGBP,IGBP,WET -CA-DB2,91493,GRP_LOCATION,LOCATION_LAT,49.1190 -CA-DB2,91493,GRP_LOCATION,LOCATION_LONG,-122.9951 -CA-DB2,91493,GRP_LOCATION,LOCATION_ELEV,4 -CA-DB2,91493,GRP_LOCATION,LOCATION_DATE_START,201911191500 -CA-DB2,91496,GRP_NETWORK,NETWORK,AmeriFlux -CA-DB2,91502,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,This research takes advantage of the paired flux tower approach in Burns Bog to assess how carbon and greenhouse gas fluxes vary at different stages of ecological recovery following disturbance. -CA-DB2,91503,GRP_SITE_CHAR,TERRAIN,Flat -CA-DB2,91503,GRP_SITE_CHAR,ASPECT,FLAT -CA-DB2,91503,GRP_SITE_CHAR,WIND_DIRECTION,ESE -CA-DB2,91503,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,5 -CA-DB2,91498,GRP_SITE_DESC,SITE_DESC,"The Burns Bog Ecological Conservancy Area (BBECA) in the metro Vancouver area presents a unique opportunity for insight into greenhouse gas dynamics post restoration. The bog was significantly disturbed for peat mining, development and agriculture over the last century, however since 2005 there has been both active restoration and natural regeneration occurring within the bog. Hence areas of bog are at varying stages of ecological recovery. This site is a Pine-Sphagnum low shrub site characteristic of a later successional stage. Conversely, CA-DBB, another AmeriFlux site in BBECA, is a Beakrush-Sphagnum site characteristic of an earlier successional stage." -CA-DB2,91492,GRP_SITE_FUNDING,SITE_FUNDING,"NSERC, CFI" -CA-DB2,91506,GRP_STATE,STATE,British Columbia -CA-DB2,91495,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Sara Knox -CA-DB2,91495,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -CA-DB2,91495,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,sara.knox@ubc.ca -CA-DB2,91495,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,The University of British Columbia -CA-DB2,91504,GRP_TOWER_POWER,TOWER_POWER,Solar panels -CA-DB2,91505,GRP_TOWER_TYPE,TOWER_TYPE,walk-up -CA-DB2,24001133,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/CA-DB2 -CA-DB2,91501,GRP_UTC_OFFSET,UTC_OFFSET,-8 -CA-DBB,30781,GRP_CLIM_AVG,MAT,10 -CA-DBB,30781,GRP_CLIM_AVG,MAP,1128 -CA-DBB,30781,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Csb -CA-DBB,27000706,GRP_COUNTRY,COUNTRY,Canada -CA-DBB,87120,GRP_DOI,DOI,10.17190/AMF/1543378 -CA-DBB,87120,GRP_DOI,DOI_CITATION,"Andreas Christen, Sara Knox (2021), AmeriFlux BASE CA-DBB Delta Burns Bog, Ver. 2-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1543378" -CA-DBB,87120,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -CA-DBB,86894,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -CA-DBB,86894,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Andreas Christen -CA-DBB,86894,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -CA-DBB,86894,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,andreas.christen@ubc.ca -CA-DBB,86894,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of British Columbia -CA-DBB,86893,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -CA-DBB,86893,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Sara Knox -CA-DBB,86893,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -CA-DBB,86893,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,sara.knox@ubc.ca -CA-DBB,86893,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of British Columbia -CA-DBB,86906,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,University of British Columbia -CA-DBB,86906,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -CA-DBB,86905,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,"Natural Sciences and Engineering Research Council (NSERC), Canada Foundation for Innovation, Metro Vancouver" -CA-DBB,86905,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -CA-DBB,30782,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Hydrologic event -CA-DBB,30784,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -CA-DBB,30784,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -CA-DBB,30784,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201407100000 -CA-DBB,30784,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -CA-DBB,30785,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -CA-DBB,30785,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -CA-DBB,30785,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201407100000 -CA-DBB,30785,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -CA-DBB,30783,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -CA-DBB,30783,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -CA-DBB,30783,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201407100000 -CA-DBB,30783,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -CA-DBB,30786,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -CA-DBB,30786,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CH4 -CA-DBB,30786,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201606160000 -CA-DBB,30786,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -CA-DBB,23000706,GRP_HEADER,SITE_NAME,Delta Burns Bog -CA-DBB,30928,GRP_IGBP,IGBP,WET -CA-DBB,30928,GRP_IGBP,IGBP_COMMENT,Restored and rewetted raised bog ecosystem dominated by Sphagnum spp. and Rhynchospora alba -CA-DBB,30788,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -CA-DBB,30788,GRP_LAND_OWNERSHIP,LAND_OWNER,Metro Vancouver Park Board -CA-DBB,30789,GRP_LOCATION,LOCATION_LAT,49.1293 -CA-DBB,30789,GRP_LOCATION,LOCATION_LONG,-122.9849 -CA-DBB,30789,GRP_LOCATION,LOCATION_ELEV,4 -CA-DBB,30789,GRP_LOCATION,LOCATION_DATE_START,201509211430 -CA-DBB,30790,GRP_NETWORK,NETWORK,AmeriFlux -CA-DBB,1700003381,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Christen, A., Jassal, R.S., Black, T.A., Grant, N.J., Hawthorne, I, Johnson, M.S., Lee, S.-C., Merkens, M. (2016) Summertime greenhouse gas fluxes from an urban bog undergoing restoration through rewetting, Mires And Peat, (17), 1-24" -CA-DBB,1700003381,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.19189/MAP.2015.OMB.207 -CA-DBB,1700003381,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-DBB,1700002850,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Christen, A., Jassal, R.S., Black, T.A., Grant, N.J., Hawthorne, I, Johnson, M.S., Lee, S.-C., Merkens, M. (2016) Summertime greenhouse gas fluxes from an urban bog undergoing restoration through rewetting, Mires And Peat, 301-302(17), 1-24" -CA-DBB,1700002850,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.19189/MAP.2015.OMB.207 -CA-DBB,1700002850,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-DBB,1700006483,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(4), 108350" -CA-DBB,1700006483,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -CA-DBB,1700006483,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-DBB,1700003966,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"D′Acunha, B., Morillas, L., Black, T. A., Christen, A., Johnson, M. S. (2019) Net Ecosystem Carbon Balance Of A Peat Bog Undergoing Restoration: Integrating Co 2 And Ch 4 Fluxes From Eddy Covariance And Aquatic Evasion With Doc Drainage Fluxes, Journal Of Geophysical Research: Biogeosciences, 124(4), 884-901" -CA-DBB,1700003966,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2019JG005123 -CA-DBB,1700003966,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-DBB,1700003309,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Lee, S.-C., Christen, A., Black, T.A., Johnson, M.S., Jassal, R.S., Ketler, R., Nesic, Z., Merkens, M. (2017) Annual greenhouse gas budget for a bog ecosystem undergoing restoration by rewetting, Biogeosciences, 14(11), 2799-2814" -CA-DBB,1700003309,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.5194/BG-14-2799-2017 -CA-DBB,1700003309,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Primary_Citation -CA-DBB,1700006747,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"McKendry, I. G., Christen, A., Lee, S., Ferrara, M., Strawbridge, K. B., O'Neill, N., Black, A. (2019) Impacts Of An Intense Wildfire Smoke Episode On Surface Radiation, Energy And Carbon Fluxes In Southwestern British Columbia, Canada, Atmospheric Chemistry And Physics, 19(2), 835-846" -CA-DBB,1700006747,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.5194/ACP-19-835-2019 -CA-DBB,1700006747,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-DBB,1700001449,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Tortini, R., Coops, N. C., Nesic, Z., Christen, A., Lee, S. C., Hilker, T. (2017) Remote Sensing Of Seasonal Light Use Efficiency In Temperate Bog Ecosystems, Scientific Reports, 7(1), 2799-2814" -CA-DBB,1700001449,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1038/S41598-017-08102-X -CA-DBB,1700001449,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-DBB,30793,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"Greenhouse gas (CO2, CH4) fluxes, energy and water balance, and ecohydrology of a disturbed and rewetted ecosystem undergoing ecological restoration." -CA-DBB,30794,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"1984 West Mall, Vancouver, BC, Canada, V6T1Z2" -CA-DBB,30795,GRP_SITE_CHAR,TERRAIN,Flat -CA-DBB,30795,GRP_SITE_CHAR,ASPECT,S -CA-DBB,30795,GRP_SITE_CHAR,WIND_DIRECTION,SSE -CA-DBB,30795,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,340 -CA-DBB,30795,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,10 -CA-DBB,30796,GRP_SITE_DESC,SITE_DESC,Disturbed raised bog ecosystem (peat harvesting 1957 to 1963). Site has been restored and rewetted in 2007 by ditch blocking. -CA-DBB,30797,GRP_SITE_FUNDING,SITE_FUNDING,"Natural Sciences and Engineering Research Council (NSERC), Canada Foundation for Innovation, Metro Vancouver" -CA-DBB,30798,GRP_STATE,STATE,British Columbia -CA-DBB,30799,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Andreas Christen -CA-DBB,30799,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -CA-DBB,30799,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,andreas.christen@ubc.ca -CA-DBB,30799,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of British Columbia -CA-DBB,30799,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1984 West Mall, Vancouver, BC, Canada, V6T1Z2" -CA-DBB,86534,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Sara Knox -CA-DBB,86534,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -CA-DBB,86534,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,sara.knox@ubc.ca -CA-DBB,86534,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of British Columbia -CA-DBB,86534,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"235-1984 W Mall, Vancouver BC Canada, V6T1Z2" -CA-DBB,30930,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Andrew T. Black -CA-DBB,30930,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Affiliate -CA-DBB,30930,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,andrew.black@ubc.ca -CA-DBB,30930,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of British Columbia -CA-DBB,30930,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"136-2357 Main Mall, Vancouver, BC, Canada, V6T1Z4" -CA-DBB,30929,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Mark S. Johnson -CA-DBB,30929,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Affiliate -CA-DBB,30929,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,mark.johnson@ubc.ca -CA-DBB,30929,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of British Columbia -CA-DBB,30929,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"2202 Main Mall, Vancouver, BC, Canada, V6T1Z2" -CA-DBB,30805,GRP_TOWER_POWER,TOWER_POWER,Solar panels -CA-DBB,30802,GRP_TOWER_TYPE,TOWER_TYPE,walk-up -CA-DBB,30803,GRP_URL,URL,http://ibis.geog.ubc.ca/~achristn/research/Burns-Bog/ -CA-DBB,24000706,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/CA-DBB -CA-DBB,30804,GRP_UTC_OFFSET,UTC_OFFSET,-8 -CA-DL1,12614,GRP_CLIM_AVG,MAT,-9 -CA-DL1,12614,GRP_CLIM_AVG,MAP,250 -CA-DL1,12614,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfc -CA-DL1,27000534,GRP_COUNTRY,COUNTRY,Canada -CA-DL1,12615,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Undisturbed -CA-DL1,12616,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -CA-DL1,12616,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -CA-DL1,12616,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20040515 -CA-DL1,12616,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Growing season operation only -CA-DL1,12631,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -CA-DL1,12631,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -CA-DL1,12631,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20040515 -CA-DL1,12631,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Growing season operation only -CA-DL1,23000534,GRP_HEADER,SITE_NAME,Daring Lake - Mixed Tundra -CA-DL1,12617,GRP_IGBP,IGBP,OSH -CA-DL1,12618,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -CA-DL1,12618,GRP_LAND_OWNERSHIP,LAND_OWNER,Government -CA-DL1,12619,GRP_LOCATION,LOCATION_LAT,64.8689 -CA-DL1,12619,GRP_LOCATION,LOCATION_LONG,-111.5748 -CA-DL1,12619,GRP_LOCATION,LOCATION_ELEV,425 -CA-DL1,12620,GRP_NETWORK,NETWORK,AmeriFlux -CA-DL1,1700001923,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Campeau, A. B., Lafleur, P. M., Humphreys, E. R. (2014) Landscape-Scale Variability In Soil Organic Carbon Storage In The Central Canadian Arctic, Canadian Journal Of Soil Science, 94(4), 477-488" -CA-DL1,1700001923,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.4141/CJSS-2014-018 -CA-DL1,1700001923,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-DL1,1700007704,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Humphreys, E. R., Lafleur, P. M. (2011) Does Earlier Snowmelt Lead To Greater CO2 Sequestration In Two Low Arctic Tundra Ecosystems?, Geophysical Research Letters, 38(9), n/a-n/a" -CA-DL1,1700007704,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2011GL047339 -CA-DL1,1700007704,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-DL1,1700000678,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Lafleur, P.M., Humphreys, E.R. (2008) Spring Warming And Carbon Dioxide Exchange Over Low Arctic Tundra In Central Canada, Global Change Biology, 14(4), 740-756" -CA-DL1,1700000678,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/J.1365-2486.2007.01529.X -CA-DL1,1700000678,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Primary_Citation -CA-DL1,12622,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,Tundra carbon and energy exchange with the atmosphere -CA-DL1,12623,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"B349 LA, 1125 Colonel By Dr., Ottawa, ON K1S 5B6" -CA-DL1,12624,GRP_SITE_CHAR,TERRAIN,Gentle slope (<2 %) -CA-DL1,12624,GRP_SITE_CHAR,ASPECT,SE -CA-DL1,12624,GRP_SITE_CHAR,WIND_DIRECTION,NW -CA-DL1,12624,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,200 -CA-DL1,12624,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,205 -CA-DL1,12625,GRP_SITE_DESC,SITE_DESC,"Low Arctic government research station approximately 70 km north of treeline. The government run weather station began recording in 1996. The flux tower footprint includes a topographically-driven mix of Low shrub and Tussock, sedge- dwarf shrub tundra types." -CA-DL1,12626,GRP_SITE_FUNDING,SITE_FUNDING,"NSERC, CFCAS, CFI" -CA-DL1,12627,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Elyn Humphreys -CA-DL1,12627,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -CA-DL1,12627,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,elyn.humphreys@carleton.ca -CA-DL1,12627,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Carleton University -CA-DL1,12627,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Ottawa, Ontario, Canada" -CA-DL1,12633,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Peter Lafleur -CA-DL1,12633,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -CA-DL1,12633,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,plafleur@trentu.ca -CA-DL1,12633,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Trent University -CA-DL1,12633,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Peterborough, Ontario, Canada" -CA-DL1,29868,GRP_TOWER_POWER,TOWER_POWER,Solar panels -CA-DL1,12628,GRP_TOWER_TYPE,TOWER_TYPE,tripod -CA-DL1,12629,GRP_URL,URL,http://www.trentu.ca/academic/bluelab/research_daringlake.html -CA-DL1,24000534,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/CA-DL1 -CA-DL1,12630,GRP_UTC_OFFSET,UTC_OFFSET,-6 -CA-DL2,12635,GRP_CLIM_AVG,MAT,-9 -CA-DL2,12635,GRP_CLIM_AVG,MAP,250 -CA-DL2,12635,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfc -CA-DL2,27000535,GRP_COUNTRY,COUNTRY,Canada -CA-DL2,12636,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Undisturbed -CA-DL2,12656,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Chambers -CA-DL2,12656,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CH4 -CA-DL2,12656,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20060515 -CA-DL2,12656,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Intermittent -CA-DL2,12637,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -CA-DL2,12637,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -CA-DL2,12637,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20060515 -CA-DL2,12637,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Growing season operation only -CA-DL2,12651,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -CA-DL2,12651,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -CA-DL2,12651,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20060515 -CA-DL2,12651,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Growing season operation only -CA-DL2,12654,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -CA-DL2,12654,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CH4 -CA-DL2,12654,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20090701 -CA-DL2,12654,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Intermittent -CA-DL2,23000535,GRP_HEADER,SITE_NAME,Daring Lake - Fen -CA-DL2,12638,GRP_IGBP,IGBP,WET -CA-DL2,12639,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -CA-DL2,12639,GRP_LAND_OWNERSHIP,LAND_OWNER,Government -CA-DL2,12640,GRP_LOCATION,LOCATION_LAT,64.8648 -CA-DL2,12640,GRP_LOCATION,LOCATION_LONG,-111.5677 -CA-DL2,12640,GRP_LOCATION,LOCATION_ELEV,416 -CA-DL2,12641,GRP_NETWORK,NETWORK,AmeriFlux -CA-DL2,1700007674,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Campeau, A. B., Lafleur, P. M., Humphreys, E. R. (2014) Landscape-Scale Variability In Soil Organic Carbon Storage In The Central Canadian Arctic, Canadian Journal Of Soil Science, 94(4), 477-488" -CA-DL2,1700007674,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.4141/CJSS-2014-018 -CA-DL2,1700007674,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-DL2,1700004095,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Humphreys, E. R., Lafleur, P. M. (2011) Does Earlier Snowmelt Lead To Greater CO2 Sequestration In Two Low Arctic Tundra Ecosystems?, Geophysical Research Letters, 38(9), n/a-n/a" -CA-DL2,1700004095,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2011GL047339 -CA-DL2,1700004095,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Primary_Citation -CA-DL2,1700008169,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Wilson, K. S., Humphreys, E. R. (2010) Carbon Dioxide And Methane Fluxes From Arctic Mudboils, Canadian Journal Of Soil Science, 90(3), 441-449" -CA-DL2,1700008169,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.4141/CJSS09073 -CA-DL2,1700008169,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-DL2,12643,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,Tundra carbon and energy exchange with the atmosphere -CA-DL2,12644,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"B349 LA, 1125 Colonel By Dr., Ottawa, ON K1S 5B6" -CA-DL2,12645,GRP_SITE_CHAR,TERRAIN,Flat -CA-DL2,12645,GRP_SITE_CHAR,ASPECT,FLAT -CA-DL2,12645,GRP_SITE_CHAR,WIND_DIRECTION,NW -CA-DL2,12645,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,300 -CA-DL2,12645,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,205 -CA-DL2,12646,GRP_SITE_DESC,SITE_DESC,Low Arctic government research station approximately 70 km north of treeline. The government run weather station began recording in 1996. The flux tower footprint includes a wet sedge meadow with short palsa-like birch shrub mounds -CA-DL2,12647,GRP_SITE_FUNDING,SITE_FUNDING,"NSERC, CFCAS, CFI" -CA-DL2,12648,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Elyn Humphreys -CA-DL2,12648,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -CA-DL2,12648,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,elyn.humphreys@carleton.ca -CA-DL2,12648,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Carleton University -CA-DL2,12648,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Ottawa, Ontario, Canada" -CA-DL2,12653,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Peter Lafleur -CA-DL2,12653,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -CA-DL2,12653,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,plafleur@trentu.ca -CA-DL2,12653,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Trent University -CA-DL2,12653,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Peterborough, Ontario, Canada" -CA-DL2,29869,GRP_TOWER_POWER,TOWER_POWER,Solar panels -CA-DL2,12649,GRP_TOWER_TYPE,TOWER_TYPE,tripod -CA-DL2,24000535,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/CA-DL2 -CA-DL2,12650,GRP_UTC_OFFSET,UTC_OFFSET,-6 -CA-ER1,81328,GRP_CLIM_AVG,MAT,6.7 -CA-ER1,81328,GRP_CLIM_AVG,MAP,946 -CA-ER1,81328,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfb -CA-ER1,27000966,GRP_COUNTRY,COUNTRY,Canada -CA-ER1,90038,GRP_DOI,DOI,10.17190/AMF/1579541 -CA-ER1,90038,GRP_DOI,DOI_CITATION,"Claudia Wagner-Riddle (2021), AmeriFlux BASE CA-ER1 Elora Research Station, Ver. 3-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1579541" -CA-ER1,90038,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -CA-ER1,88181,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -CA-ER1,88181,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Claudia Wagner-Riddle -CA-ER1,88181,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -CA-ER1,88181,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,cwagnerr@uoguelph.ca -CA-ER1,88181,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of Guelph -CA-ER1,88187,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,University of Guelph -CA-ER1,88187,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -CA-ER1,88182,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,"Various for different time periods. OMAFRA, NSERC, AAFC" -CA-ER1,88182,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -CA-ER1,81331,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Agriculture -CA-ER1,81329,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -CA-ER1,81329,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -CA-ER1,81329,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201506171600 -CA-ER1,81329,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -CA-ER1,81337,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -CA-ER1,81337,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -CA-ER1,81337,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201506171600 -CA-ER1,81337,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -CA-ER1,81330,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -CA-ER1,81330,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -CA-ER1,81330,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201506171600 -CA-ER1,81330,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -CA-ER1,23000966,GRP_HEADER,SITE_NAME,Elora Research Station -CA-ER1,81343,GRP_IGBP,IGBP,CRO -CA-ER1,81343,GRP_IGBP,IGBP_DATE_START,1960 -CA-ER1,81334,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -CA-ER1,81334,GRP_LAND_OWNERSHIP,LAND_OWNER,"Ontario Ministry of Agriculture, Food, and Rural Affairs" -CA-ER1,81345,GRP_LOCATION,LOCATION_LAT,43.6405 -CA-ER1,81345,GRP_LOCATION,LOCATION_LONG,-80.4123 -CA-ER1,81345,GRP_LOCATION,LOCATION_ELEV,370 -CA-ER1,81345,GRP_LOCATION,LOCATION_DATE_START,201506171600 -CA-ER1,81346,GRP_NETWORK,NETWORK,AmeriFlux -CA-ER1,1700004638,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Baldocchi, D. D., Poindexter, C., Abraha, M., Desai, A. R., Bohrer, G., Arain, M. A., Griffis, T., Blanken, P. D., O'Halloran, T. L., Thomas, R. Q., Zhang, Q., Burns, S. P., Frank, J. M., Christian, D., Brown, S., Black, T. A., Gough, C. M., Law, B. E., Lee, X., Chen, J., Reed, D. E., Massman, W. J., Clark, K., Hatfield, J., Prueger, J., Bracho, R., Baker, J. M., Martin, T. A. (2018) Temporal Dynamics Of Aerodynamic Canopy Height Derived From Eddy Covariance Momentum Flux Data Across North American Flux Networks, Geophysical Research Letters, 45(), 9275–9287" -CA-ER1,1700004638,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018GL079306 -CA-ER1,1700004638,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-ER1,1700006174,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(), 108350" -CA-ER1,1700006174,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -CA-ER1,1700006174,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-ER1,81342,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"Evaluating effects of fertilizer treatments, best management practices, etc on GHG fluxes" -CA-ER1,81348,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"Claudia Wagner-Riddle, c/o Dave Wells, University of Guelph, Elora Research Station, 6182 2nd Line, Pilkington Township, RR#2 Arris, Ontario, Canada, N0B 1B0" -CA-ER1,81339,GRP_SITE_CHAR,TERRAIN,Flat -CA-ER1,81339,GRP_SITE_CHAR,ASPECT,FLAT -CA-ER1,81339,GRP_SITE_CHAR,WIND_DIRECTION,W -CA-ER1,81339,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,400 -CA-ER1,81339,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,70 -CA-ER1,81335,GRP_SITE_DESC,SITE_DESC,This is an agricultural site that typically grows corn. It is part of a larger research project on N2O fluxes from different fertilizer treatments. The site is relatively flat and homogenous. The site has been managed as agricultural land since the 1960’s and records exist of the previously-grown crops. -CA-ER1,81332,GRP_SITE_FUNDING,SITE_FUNDING,"Various for different time periods. OMAFRA, NSERC, AAFC" -CA-ER1,81333,GRP_STATE,STATE,Ontario -CA-ER1,81344,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Claudia Wagner-Riddle -CA-ER1,81344,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -CA-ER1,81344,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,cwagnerr@uoguelph.ca -CA-ER1,81344,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Guelph -CA-ER1,81338,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Shannon Brown -CA-ER1,81338,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -CA-ER1,81338,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,sbrown06@uoguelph.ca -CA-ER1,81338,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Guelph -CA-ER1,81336,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Sean Jordan -CA-ER1,81336,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Technician -CA-ER1,81336,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,sjordan@uoguelph.ca -CA-ER1,81336,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Guelph -CA-ER1,81347,GRP_TOWER_POWER,TOWER_POWER,Direct power -CA-ER1,81341,GRP_TOWER_TYPE,TOWER_TYPE,triangle -CA-ER1,24000966,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/CA-ER1 -CA-ER1,81340,GRP_UTC_OFFSET,UTC_OFFSET,-5 -CA-ER1,81340,GRP_UTC_OFFSET,UTC_OFFSET_DATE_START,201506171600 -CA-ER1,81340,GRP_UTC_OFFSET,UTC_OFFSET_COMMENT,Always in EST -CA-ER2,98799,GRP_CLIM_AVG,MAT,6.7 -CA-ER2,98799,GRP_CLIM_AVG,MAP,946 -CA-ER2,98799,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfb -CA-ER2,27001213,GRP_COUNTRY,COUNTRY,Canada -CA-ER2,98804,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Agriculture -CA-ER2,98809,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -CA-ER2,98809,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -CA-ER2,98809,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201505071200 -CA-ER2,98809,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -CA-ER2,98803,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -CA-ER2,98803,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -CA-ER2,98803,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201505071200 -CA-ER2,98803,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -CA-ER2,98796,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -CA-ER2,98796,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -CA-ER2,98796,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201505071200 -CA-ER2,98796,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -CA-ER2,23001213,GRP_HEADER,SITE_NAME,Elora Research Station -CA-ER2,98802,GRP_IGBP,IGBP,CRO -CA-ER2,98802,GRP_IGBP,IGBP_DATE_START,1960 -CA-ER2,98810,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -CA-ER2,98810,GRP_LAND_OWNERSHIP,LAND_OWNER,"Ontario Ministry of Agriculture, Food, and Rural Affairs" -CA-ER2,98808,GRP_LOCATION,LOCATION_LAT,43.6419 -CA-ER2,98808,GRP_LOCATION,LOCATION_LONG,-80.4140 -CA-ER2,98808,GRP_LOCATION,LOCATION_ELEV,370 -CA-ER2,98808,GRP_LOCATION,LOCATION_DATE_START,201505071200 -CA-ER2,98800,GRP_NETWORK,NETWORK,AmeriFlux -CA-ER2,98801,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"Evaluating effects of fertilizer treatments, best management practices, etc on GHG fluxes" -CA-ER2,98806,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"Claudia Wagner-Riddle, c/o Dave Wells, University of Guelph, Elora Research Station, 6182 2nd Line, Pilkington Township, RR#2 Arris, Ontario, Canada, N0B 1B0" -CA-ER2,98794,GRP_SITE_CHAR,TERRAIN,Flat -CA-ER2,98794,GRP_SITE_CHAR,ASPECT,FLAT -CA-ER2,98794,GRP_SITE_CHAR,WIND_DIRECTION,W -CA-ER2,98794,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,400 -CA-ER2,98794,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,70 -CA-ER2,98795,GRP_SITE_DESC,SITE_DESC,This is an agricultural site that typically grows corn. It is part of a larger research project on N2O fluxes from different fertilizer treatments. The site is relatively flat and homogenous. The site has been managed as agricultural land since the 1960’s and records exist of the previously-grown crops. -CA-ER2,98798,GRP_SITE_FUNDING,SITE_FUNDING,"Various for different time periods. OMAFRA, NSERC, AAFC" -CA-ER2,98797,GRP_STATE,STATE,Ontario -CA-ER2,98811,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Claudia Wagner-Riddle -CA-ER2,98811,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -CA-ER2,98811,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,cwagnerr@uoguelph.ca -CA-ER2,98811,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Guelph -CA-ER2,98805,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Shannon Brown -CA-ER2,98805,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -CA-ER2,98805,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,sbrown06@uoguelph.ca -CA-ER2,98805,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Guelph -CA-ER2,98807,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Sean Jordan -CA-ER2,98807,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Technician -CA-ER2,98807,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,sjordan@uoguelph.ca -CA-ER2,98807,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Guelph -CA-ER2,98813,GRP_TOWER_POWER,TOWER_POWER,Direct power -CA-ER2,98918,GRP_TOWER_TYPE,TOWER_TYPE,pole -CA-ER2,24001213,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/CA-ER2 -CA-ER2,98812,GRP_UTC_OFFSET,UTC_OFFSET,-5 -CA-ER2,98812,GRP_UTC_OFFSET,UTC_OFFSET_DATE_START,201505071200 -CA-ER2,98812,GRP_UTC_OFFSET,UTC_OFFSET_COMMENT,Always in EST -CA-KLP,33717,GRP_CLIM_AVG,MAT,-1.1 -CA-KLP,33717,GRP_CLIM_AVG,MAP,680 -CA-KLP,33717,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfb -CA-KLP,27000720,GRP_COUNTRY,COUNTRY,Canada -CA-KLP,31228,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Undisturbed -CA-KLP,31229,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -CA-KLP,31229,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -CA-KLP,31229,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20090801 -CA-KLP,31229,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -CA-KLP,31231,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -CA-KLP,31231,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -CA-KLP,31231,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20090801 -CA-KLP,31231,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -CA-KLP,31230,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -CA-KLP,31230,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -CA-KLP,31230,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20090801 -CA-KLP,31230,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -CA-KLP,23000720,GRP_HEADER,SITE_NAME,Kinoje Lake Peatland -CA-KLP,31232,GRP_IGBP,IGBP,WET -CA-KLP,31233,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -CA-KLP,31233,GRP_LAND_OWNERSHIP,LAND_OWNER,Government -CA-KLP,31234,GRP_LOCATION,LOCATION_LAT,51.5902 -CA-KLP,31234,GRP_LOCATION,LOCATION_LONG,-81.7684 -CA-KLP,31234,GRP_LOCATION,LOCATION_ELEV,71 -CA-KLP,31235,GRP_NETWORK,NETWORK,AmeriFlux -CA-KLP,31236,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,Peatland carbon and energy exchange with the atmosphere -CA-KLP,31237,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"B349 LA, 1125 Colonel By Dr., Ottawa, ON K1S 5B6" -CA-KLP,31238,GRP_SITE_CHAR,TERRAIN,Flat -CA-KLP,31238,GRP_SITE_CHAR,ASPECT,FLAT -CA-KLP,31238,GRP_SITE_CHAR,WIND_DIRECTION,NW -CA-KLP,31238,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,300 -CA-KLP,31238,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,205 -CA-KLP,33718,GRP_SITE_DESC,SITE_DESC,Ontario Ministry of Environment and Climate Change's Environmental Monitoring and Reporting Branch has established five carbon flux monitoring towers in Ontario’s Far North as part of its Climate Change Modelling and Monitoring program. These long term monitoring stations measure carbon exchange and a suite of soil and meteorological parameters over peatland ecosystems to better understand carbon cycling in Ontario’s Far North. Information produced by these monitoring stations will assist the province in land use planning and the development of climate change adaptation strategies. -CA-KLP,31240,GRP_STATE,STATE,Ontario -CA-KLP,33719,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Aaron Todd -CA-KLP,33719,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -CA-KLP,33719,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,aaron.todd@ontario.ca -CA-KLP,33719,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Ministry of Environment and Climate Change -CA-KLP,33719,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"125 Resources Road, M9P 3V6, Etobicoke, ON" -CA-KLP,31241,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Elyn Humphreys -CA-KLP,31241,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -CA-KLP,31241,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,elynhumphreys@cunet.carleton.ca -CA-KLP,31241,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Carleton University -CA-KLP,31241,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"B349 LA, 1125 Colonel By Dr., Ottawa, ON K1S 5B6" -CA-KLP,31245,GRP_TOWER_POWER,TOWER_POWER,Solar panels -CA-KLP,31243,GRP_TOWER_TYPE,TOWER_TYPE,tripod -CA-KLP,24000720,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/CA-KLP -CA-KLP,31244,GRP_UTC_OFFSET,UTC_OFFSET,-6 -CA-LP1,91287,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,Supported by NSERC and BIOCAP. -CA-LP1,91273,GRP_CLIM_AVG,MAT,2 -CA-LP1,91273,GRP_CLIM_AVG,MAP,570 -CA-LP1,91273,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Csa -CA-LP1,27001132,GRP_COUNTRY,COUNTRY,Canada -CA-LP1,93757,GRP_DOI,DOI,10.17190/AMF/1660337 -CA-LP1,93757,GRP_DOI,DOI_CITATION,"Thomas Andrew Black (2021), AmeriFlux BASE CA-LP1 British Columbia - Mountain pine beetle-attacked lodgepole pine stand , Ver. 2-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1660337" -CA-LP1,93757,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -CA-LP1,93703,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -CA-LP1,93703,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Thomas Andrew Black -CA-LP1,93703,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -CA-LP1,93703,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,andrew.black@ubc.ca -CA-LP1,93703,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of British Columbia -CA-LP1,93737,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,University of British Columbia -CA-LP1,93737,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -CA-LP1,93722,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,"NSERC, BIOCAP" -CA-LP1,93722,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -CA-LP1,91291,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Land cover change -CA-LP1,91286,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Pests and disease -CA-LP1,91275,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -CA-LP1,91275,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -CA-LP1,91275,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20070101 -CA-LP1,91275,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -CA-LP1,23001132,GRP_HEADER,SITE_NAME,British Columbia - Mountain pine beetle-attacked lodgepole pine stand -CA-LP1,91274,GRP_IGBP,IGBP,ENF -CA-LP1,91280,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -CA-LP1,91713,GRP_LOCATION,LOCATION_LAT,55.1119 -CA-LP1,91713,GRP_LOCATION,LOCATION_LONG,-122.8414 -CA-LP1,91713,GRP_LOCATION,LOCATION_ELEV,751 -CA-LP1,91713,GRP_LOCATION,LOCATION_DATE_START,2007 -CA-LP1,91713,GRP_LOCATION,LOCATION_COMMENT,"About 35 km southeast of Mackenzie at Kennedy Siding, BC, Canada ." -CA-LP1,91290,GRP_NETWORK,NETWORK,AmeriFlux -CA-LP1,91283,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"Flux data processing, instrument QA/QC" -CA-LP1,91281,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"Faculty of land and Food Systems, University of British Columbia, vancouver BC V6T 1Z4" -CA-LP1,91279,GRP_SITE_CHAR,TERRAIN,Gentle slope (<2 %) -CA-LP1,91279,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,1000 -CA-LP1,91279,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,0 -CA-LP1,91289,GRP_SITE_DESC,SITE_DESC,"This tower is located at an mountain pine beetle (MPB)-attacked almost pure lodgepole pine stand, 15 tall, approximately 35 km southeast of Mackenzie at Kennedy Siding ." -CA-LP1,91277,GRP_SITE_FUNDING,SITE_FUNDING,"NSERC, BIOCAP" -CA-LP1,91285,GRP_STATE,STATE,British Columbia -CA-LP1,91282,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Thomas Andrew Black -CA-LP1,91282,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -CA-LP1,91282,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,andrew.black@ubc.ca -CA-LP1,91282,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of British Columbia -CA-LP1,91282,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Faculty of land and Food Systems, University of British Columbia, vancouver BC V6T 1Z4" -CA-LP1,91278,GRP_TOWER_POWER,TOWER_POWER,Solar panels -CA-LP1,91276,GRP_TOWER_TYPE,TOWER_TYPE,other -CA-LP1,24001132,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/CA-LP1 -CA-LP1,91284,GRP_UTC_OFFSET,UTC_OFFSET,-8 -CA-MA1,22312,GRP_CLIM_AVG,MAT,2.6 -CA-MA1,22312,GRP_CLIM_AVG,MAP,514 -CA-MA1,22312,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfb -CA-MA1,27000671,GRP_COUNTRY,COUNTRY,Canada -CA-MA1,91683,GRP_DOI,DOI,10.17190/AMF/1617701 -CA-MA1,91683,GRP_DOI,DOI_CITATION,"Brian Amiro (2020), AmeriFlux BASE CA-MA1 Manitoba Agricultural Site 1, Ver. 1-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1617701" -CA-MA1,91683,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -CA-MA1,91532,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -CA-MA1,91532,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Brian Amiro -CA-MA1,91532,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -CA-MA1,91532,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,brian_amiro@umanitoba.ca -CA-MA1,91532,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of Manitoba -CA-MA1,91639,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,University of Manitoba -CA-MA1,91639,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -CA-MA1,91635,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,"Canada Natural Sciences and Engineering Research Council; Canadian Foundation for Innovation; Manitoba Agricultural Sustainable Practices Program and Growing Forward (Manitoba Agriculture, Food and Rural Initiatives); University of Manitoba GETS program; Agriculture and Agri-Food Canada Agricultural Greenhouse Gas Program" -CA-MA1,91635,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -CA-MA1,22313,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Agriculture -CA-MA1,22314,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -CA-MA1,22314,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -CA-MA1,22314,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20090603 -CA-MA1,22314,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20111125 -CA-MA1,22314,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Growing season operation only -CA-MA1,22314,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,"Note that flux measurements were attempted in the winter of 2009/2010, but success was sporadic because of cold temperatures causing power failures. Winter fluxes were not attempted during the winter of 2010/2011." -CA-MA1,22315,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -CA-MA1,22315,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -CA-MA1,22315,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20090603 -CA-MA1,22315,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20111125 -CA-MA1,22315,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Growing season operation only -CA-MA1,22315,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,"Note that flux measurements were attempted in the winter of 2009/2010, but success was sporadic because of cold temperatures causing power failures. Winter fluxes were not attempted during the winter of 2010/2011." -CA-MA1,22316,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -CA-MA1,22316,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -CA-MA1,22316,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20090603 -CA-MA1,22316,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20111125 -CA-MA1,22316,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Growing season operation only -CA-MA1,22316,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,"Note that flux measurements were attempted in the winter of 2009/2010, but success was sporadic because of cold temperatures causing power failures. Winter fluxes were not attempted during the winter of 2010/2011." -CA-MA1,23000671,GRP_HEADER,SITE_NAME,Manitoba Agricultural Site 1 -CA-MA1,22317,GRP_IGBP,IGBP,CRO -CA-MA1,22317,GRP_IGBP,IGBP_DATE_START,20080801 -CA-MA1,22317,GRP_IGBP,IGBP_COMMENT,"This field had been in perennial forages (grass with small amount of legume) for several decades. Field size = 39 ha. In 2008, the producer tilled the land so that part of the summer had perennial forage, and the remainder was fallow. In 2009, oats were planted. In 2010, canola was planted. In 2011, oats were planted. See Table 3 in Taylor et al (2013) describing site management practices." -CA-MA1,22318,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -CA-MA1,22318,GRP_LAND_OWNERSHIP,LAND_OWNER,H. Heuging -CA-MA1,29677,GRP_LOCATION,LOCATION_LAT,50.1645 -CA-MA1,29677,GRP_LOCATION,LOCATION_LONG,-97.8762 -CA-MA1,29677,GRP_LOCATION,LOCATION_ELEV,261 -CA-MA1,29677,GRP_LOCATION,LOCATION_COMMENT,"Background: This site was part of a comparison among three fields, closely located together in Manitoba. The objective was to investigate the effect of conversion of perennial hay/pasture lands to annual crops. This practice is being done by some producers, especially when grain prices are up and cattle prices are down." -CA-MA1,22320,GRP_NETWORK,NETWORK,AmeriFlux -CA-MA1,1700000165,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Fraser, T. J., Amiro, B. D. (2013) Initial Carbon Dynamics Of Perennial Grassland Conversion For Annual Cropping In Manitoba, Canadian Journal Of Soil Science, 93(3), 379-391" -CA-MA1,1700000165,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.4141/CJSS2012-109 -CA-MA1,1700000165,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-MA1,1700002664,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Taylor, A. M., Amiro, B. D., Fraser, T. J. (2013) Net Co2 Exchange And Carbon Budgets Of A Three-Year Crop Rotation Following Conversion Of Perennial Lands To Annual Cropping In Manitoba, Canada, Agricultural And Forest Meteorology, 182-183(3), 67-75" -CA-MA1,1700002664,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2013.07.008 -CA-MA1,1700002664,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Primary_Citation -CA-MA1,22323,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"Agriculture, cropping systems, land-use change; perennial crop" -CA-MA1,22324,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"Department of Soil Science, University of Manitoba, Winnipeg, MB, Canada, R3T2N2" -CA-MA1,22325,GRP_SITE_CHAR,TERRAIN,Flat -CA-MA1,22325,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,300 -CA-MA1,22326,GRP_SITE_DESC,SITE_DESC,"This field had been in perennial forages (grass with small amount of legume) for several decades. Field size = 39 ha. In 2008, the producer tilled the land so that part of the summer had perennial forage, and the remainder was fallow. In 2009, oats were planted. In 2010, canola was planted. In 2011, oats were planted. See Table 3 in Taylor et al (2013) describing site management practices." -CA-MA1,22327,GRP_SITE_FUNDING,SITE_FUNDING,"Canada Natural Sciences and Engineering Research Council; Canadian Foundation for Innovation; Manitoba Agricultural Sustainable Practices Program and Growing Forward (Manitoba Agriculture, Food and Rural Initiatives); University of Manitoba GETS program; Agriculture and Agri-Food Canada Agricultural Greenhouse Gas Program" -CA-MA1,22328,GRP_STATE,STATE,Manitoba -CA-MA1,22329,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Brian Amiro -CA-MA1,22329,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -CA-MA1,22329,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,brian_amiro@umanitoba.ca -CA-MA1,22329,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Manitoba -CA-MA1,29923,GRP_TOWER_POWER,TOWER_POWER,Solar panels -CA-MA1,29924,GRP_TOWER_POWER,TOWER_POWER,Wind generator -CA-MA1,22330,GRP_TOWER_TYPE,TOWER_TYPE,triangle -CA-MA1,24000671,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/CA-MA1 -CA-MA1,90973,GRP_UTC_OFFSET,UTC_OFFSET,-6 -CA-MA2,22290,GRP_CLIM_AVG,MAT,2.6 -CA-MA2,22290,GRP_CLIM_AVG,MAP,514 -CA-MA2,22290,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfb -CA-MA2,27000672,GRP_COUNTRY,COUNTRY,Canada -CA-MA2,91697,GRP_DOI,DOI,10.17190/AMF/1617702 -CA-MA2,91697,GRP_DOI,DOI_CITATION,"Brian Amiro (2020), AmeriFlux BASE CA-MA2 Manitoba Agricultural Site 2, Ver. 1-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1617702" -CA-MA2,91697,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -CA-MA2,91533,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -CA-MA2,91533,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Brian Amiro -CA-MA2,91533,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -CA-MA2,91533,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,brian_amiro@umanitoba.ca -CA-MA2,91533,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of Manitoba -CA-MA2,91647,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,University of Manitoba -CA-MA2,91647,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -CA-MA2,91625,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,"Canada Natural Sciences and Engineering Research Council; Canadian Foundation for Innovation; Manitoba Agricultural Sustainable Practices Program and Growing Forward (Manitoba Agriculture, Food and Rural Initiatives); University of Manitoba GETS program; Agriculture and Agri-Food Canada Agricultural Greenhouse Gas Program" -CA-MA2,91625,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -CA-MA2,22291,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Agriculture -CA-MA2,22294,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -CA-MA2,22294,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -CA-MA2,22294,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20090603 -CA-MA2,22294,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20111125 -CA-MA2,22294,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Growing season operation only -CA-MA2,22294,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,"Note that flux measurements were attempted in the winter of 2009/2010, but success was sporadic because of cold temperatures causing power failures. Winter fluxes were not attempted during the winter of 2010/2011." -CA-MA2,22293,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -CA-MA2,22293,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -CA-MA2,22293,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20090603 -CA-MA2,22293,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20111125 -CA-MA2,22293,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Growing season operation only -CA-MA2,22293,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,"Note that flux measurements were attempted in the winter of 2009/2010, but success was sporadic because of cold temperatures causing power failures. Winter fluxes were not attempted during the winter of 2010/2011." -CA-MA2,22292,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -CA-MA2,22292,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -CA-MA2,22292,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20090603 -CA-MA2,22292,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20111125 -CA-MA2,22292,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Growing season operation only -CA-MA2,22292,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,"Note that flux measurements were attempted in the winter of 2009/2010, but success was sporadic because of cold temperatures causing power failures. Winter fluxes were not attempted during the winter of 2010/2011." -CA-MA2,23000672,GRP_HEADER,SITE_NAME,Manitoba Agricultural Site 2 -CA-MA2,22296,GRP_IGBP,IGBP,GRA -CA-MA2,22296,GRP_IGBP,IGBP_DATE_START,1980 -CA-MA2,22296,GRP_IGBP,IGBP_COMMENT,"This field had been in perennial forages (grass with small amount of legume) for several decades. Field size = 60 ha. In 2009, the producer tilled the land so that part of the summer had perennial forage, and the remainder was fallow (see effect outlined by Fraser and Amiro 2013). In 2010, oats were planted. In 2011, the field was too wet to plant and remained fallow. Cattle were in the field for a brief period in June 2011to feed on weeds. See Table 2 in Taylor et al (2013) describing site management practices." -CA-MA2,22295,GRP_IGBP,IGBP,CRO -CA-MA2,22295,GRP_IGBP,IGBP_DATE_START,20090828 -CA-MA2,22297,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -CA-MA2,22297,GRP_LAND_OWNERSHIP,LAND_OWNER,H. Heuging -CA-MA2,29678,GRP_LOCATION,LOCATION_LAT,50.1710 -CA-MA2,29678,GRP_LOCATION,LOCATION_LONG,-97.8762 -CA-MA2,29678,GRP_LOCATION,LOCATION_ELEV,261 -CA-MA2,29678,GRP_LOCATION,LOCATION_COMMENT,"Background: This site was part of a comparison among three fields, closely located together in Manitoba. The objective was to investigate the effect of conversion of perennial hay/pasture lands to annual crops. This practice is being done by some producers, especially when grain prices are up and cattle prices are down." -CA-MA2,22299,GRP_NETWORK,NETWORK,AmeriFlux -CA-MA2,1700002613,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Fraser, T. J., Amiro, B. D. (2013) Initial Carbon Dynamics Of Perennial Grassland Conversion For Annual Cropping In Manitoba, Canadian Journal Of Soil Science, 93(3), 379-391" -CA-MA2,1700002613,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.4141/CJSS2012-109 -CA-MA2,1700002613,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-MA2,1700008769,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Taylor, A. M., Amiro, B. D., Fraser, T. J. (2013) Net Co2 Exchange And Carbon Budgets Of A Three-Year Crop Rotation Following Conversion Of Perennial Lands To Annual Cropping In Manitoba, Canada, Agricultural And Forest Meteorology, 182-183(3), 67-75" -CA-MA2,1700008769,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2013.07.008 -CA-MA2,1700008769,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Primary_Citation -CA-MA2,22302,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"Agriculture, cropping systems, land-use change; perennial crop" -CA-MA2,22303,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"Department of Soil Science, University of Manitoba, Winnipeg, MB, Canada, R3T2N2" -CA-MA2,22304,GRP_SITE_CHAR,TERRAIN,Flat -CA-MA2,22304,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,300 -CA-MA2,22305,GRP_SITE_DESC,SITE_DESC,"This field had been in perennial forages (grass with small amount of legume) for several decades. Field size = 60 ha. In 2009, the producer tilled the land so that part of the summer had perennial forage, and the remainder was fallow (see effect outlined by Fraser and Amiro 2013). In 2010, oats were planted. In 2011, the field was too wet to plant and remained fallow. Cattle were in the field for a brief period in June 2011to feed on weeds. See Table 2 in Taylor et al (2013) describing site management practices." -CA-MA2,22306,GRP_SITE_FUNDING,SITE_FUNDING,"Canada Natural Sciences and Engineering Research Council; Canadian Foundation for Innovation; Manitoba Agricultural Sustainable Practices Program and Growing Forward (Manitoba Agriculture, Food and Rural Initiatives); University of Manitoba GETS program; Agriculture and Agri-Food Canada Agricultural Greenhouse Gas Program" -CA-MA2,22307,GRP_STATE,STATE,Manitoba -CA-MA2,22308,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Brian Amiro -CA-MA2,22308,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -CA-MA2,22308,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,brian_amiro@umanitoba.ca -CA-MA2,22308,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Manitoba -CA-MA2,29925,GRP_TOWER_POWER,TOWER_POWER,Solar panels -CA-MA2,29926,GRP_TOWER_POWER,TOWER_POWER,Wind generator -CA-MA2,22309,GRP_TOWER_TYPE,TOWER_TYPE,triangle -CA-MA2,24000672,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/CA-MA2 -CA-MA2,90976,GRP_UTC_OFFSET,UTC_OFFSET,-6 -CA-MA3,22269,GRP_CLIM_AVG,MAT,2.6 -CA-MA3,22269,GRP_CLIM_AVG,MAP,514 -CA-MA3,22269,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfb -CA-MA3,27000673,GRP_COUNTRY,COUNTRY,Canada -CA-MA3,91698,GRP_DOI,DOI,10.17190/AMF/1617703 -CA-MA3,91698,GRP_DOI,DOI_CITATION,"Brian Amiro (2020), AmeriFlux BASE CA-MA3 Manitoba Agricultural Site 3, Ver. 1-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1617703" -CA-MA3,91698,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -CA-MA3,91534,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -CA-MA3,91534,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Brian Amiro -CA-MA3,91534,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -CA-MA3,91534,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,brian_amiro@umanitoba.ca -CA-MA3,91534,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of Manitoba -CA-MA3,91661,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,University of Manitoba -CA-MA3,91661,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -CA-MA3,91611,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,"Canada Natural Sciences and Engineering Research Council; Canadian Foundation for Innovation; Manitoba Agricultural Sustainable Practices Program and Growing Forward (Manitoba Agriculture, Food and Rural Initiatives); University of Manitoba GETS program; Agriculture and Agri-Food Canada Agricultural Greenhouse Gas Program" -CA-MA3,91611,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -CA-MA3,22270,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Grazing -CA-MA3,22272,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -CA-MA3,22272,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -CA-MA3,22272,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20090603 -CA-MA3,22272,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20111125 -CA-MA3,22272,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Growing season operation only -CA-MA3,22272,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,"Note that flux measurements were attempted in the winter of 2009/2010, but success was sporadic because of cold temperatures causing power failures. Winter fluxes were not attempted during the winter of 2010/2011." -CA-MA3,22273,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -CA-MA3,22273,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -CA-MA3,22273,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20090603 -CA-MA3,22273,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20111125 -CA-MA3,22273,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Growing season operation only -CA-MA3,22273,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,"Note that flux measurements were attempted in the winter of 2009/2010, but success was sporadic because of cold temperatures causing power failures. Winter fluxes were not attempted during the winter of 2010/2011." -CA-MA3,22271,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -CA-MA3,22271,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -CA-MA3,22271,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20090603 -CA-MA3,22271,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20111125 -CA-MA3,22271,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Growing season operation only -CA-MA3,22271,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,"Note that flux measurements were attempted in the winter of 2009/2010, but success was sporadic because of cold temperatures causing power failures. Winter fluxes were not attempted during the winter of 2010/2011." -CA-MA3,23000673,GRP_HEADER,SITE_NAME,Manitoba Agricultural Site 3 -CA-MA3,22274,GRP_IGBP,IGBP,GRA -CA-MA3,22274,GRP_IGBP,IGBP_DATE_START,1980 -CA-MA3,22274,GRP_IGBP,IGBP_COMMENT,"This field has been in perennial forages (grass (timothy, fescue, brome) with small amount of legume) for several decades. Field size = 40 ha. Hay was harvested once each year. Cattle were placed in the field each autumn to graze. See Table 1 in Taylor et al (2013) describing site management practices." -CA-MA3,22275,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -CA-MA3,22275,GRP_LAND_OWNERSHIP,LAND_OWNER,H. Heuging -CA-MA3,29679,GRP_LOCATION,LOCATION_LAT,50.1774 -CA-MA3,29679,GRP_LOCATION,LOCATION_LONG,-97.8686 -CA-MA3,29679,GRP_LOCATION,LOCATION_ELEV,261 -CA-MA3,29679,GRP_LOCATION,LOCATION_COMMENT,"Background: This site was part of a comparison among three fields, closely located together in Manitoba. The objective was to investigate the effect of conversion of perennial hay/pasture lands to annual crops. This practice is being done by some producers, especially when grain prices are up and cattle prices are down." -CA-MA3,22277,GRP_NETWORK,NETWORK,AmeriFlux -CA-MA3,1700007974,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Fraser, T. J., Amiro, B. D. (2013) Initial Carbon Dynamics Of Perennial Grassland Conversion For Annual Cropping In Manitoba, Canadian Journal Of Soil Science, 93(3), 379-391" -CA-MA3,1700007974,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.4141/CJSS2012-109 -CA-MA3,1700007974,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-MA3,1700002229,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Taylor, A. M., Amiro, B. D., Fraser, T. J. (2013) Net Co2 Exchange And Carbon Budgets Of A Three-Year Crop Rotation Following Conversion Of Perennial Lands To Annual Cropping In Manitoba, Canada, Agricultural And Forest Meteorology, 182-183(3), 67-75" -CA-MA3,1700002229,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2013.07.008 -CA-MA3,1700002229,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Primary_Citation -CA-MA3,22280,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"Agriculture, cropping systems, land-use change; perennial crop" -CA-MA3,22281,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"Department of Soil Science, University of Manitoba, Winnipeg, MB, Canada, R3T2N2" -CA-MA3,22282,GRP_SITE_CHAR,TERRAIN,Flat -CA-MA3,22282,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,300 -CA-MA3,22283,GRP_SITE_DESC,SITE_DESC,"This field has been in perennial forages (grass (timothy, fescue, brome) with small amount of legume) for several decades. Field size = 40 ha. Hay was harvested once each year. Cattle were placed in the field each autumn to graze. See Table 1 in Taylor et al (2013) describing site management practices." -CA-MA3,22284,GRP_SITE_FUNDING,SITE_FUNDING,"Canada Natural Sciences and Engineering Research Council; Canadian Foundation for Innovation; Manitoba Agricultural Sustainable Practices Program and Growing Forward (Manitoba Agriculture, Food and Rural Initiatives); University of Manitoba GETS program; Agriculture and Agri-Food Canada Agricultural Greenhouse Gas Program" -CA-MA3,22285,GRP_STATE,STATE,Manitoba -CA-MA3,22286,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Brian Amiro -CA-MA3,22286,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -CA-MA3,22286,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,brian_amiro@umanitoba.ca -CA-MA3,22286,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Manitoba -CA-MA3,29927,GRP_TOWER_POWER,TOWER_POWER,Solar panels -CA-MA3,29928,GRP_TOWER_POWER,TOWER_POWER,Wind generator -CA-MA3,22287,GRP_TOWER_TYPE,TOWER_TYPE,triangle -CA-MA3,24000673,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/CA-MA3 -CA-MA3,90974,GRP_UTC_OFFSET,UTC_OFFSET,-6 -CA-Man,9338,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,"The data collection was funded by many sources, including: the DOE Terrestrial Carbon Program, NASA Terrestrial Ecosystem Program, the Fluxnet Canada Research Network and the Canadian Carbon Program (supported by the Canadian National Science and Engineering Research Council (NSERC), the Canadian Foundation for Climate and Atmospheric Sciences and the BIOCAP Canada Foundation)." -CA-Man,9338,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT_COMMENT,When heavily using this site in a paper. -CA-Man,25753,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER,97 -CA-Man,25753,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_ORGAN,Total -CA-Man,25753,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_PHEN,Mixed/unknown -CA-Man,25753,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_UNIT,gC m-2 -CA-Man,25753,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_DATE,1994 -CA-Man,25753,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_COMMENT,"data from Gower et al. (1997, J Geophy Res 102, 29029-29041)" -CA-Man,25982,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER,97 -CA-Man,25982,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_ORGAN,Total -CA-Man,25982,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_PHEN,Mixed/unknown -CA-Man,25982,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_UNIT,kgDM m-2 -CA-Man,25982,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_COMMENT,"Above-ground understory total biomass; data from Gower et al. (1997, J Geophy Res 102, 29029-29041)" -CA-Man,25489,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB,0 -CA-Man,25489,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_ORGAN,Total -CA-Man,25489,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_PHEN,Mixed/unknown -CA-Man,25489,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_UNIT,gC m-2 -CA-Man,25489,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_DATE,1994 -CA-Man,25489,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_COMMENT,"data from Gower et al. (1997, J Geophy Res 102, 29029-29041)" -CA-Man,26381,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,396 -CA-Man,26381,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Foliage -CA-Man,26381,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -CA-Man,26381,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -CA-Man,26381,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,1994 -CA-Man,26381,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,"data from Gower et al. (1997, J Geophy Res 102, 29029-29041)" -CA-Man,25860,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,5228 -CA-Man,25860,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Wood -CA-Man,25860,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -CA-Man,25860,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -CA-Man,25860,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,1994 -CA-Man,25860,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,"data from Gower et al. (1997, J Geophy Res 102, 29029-29041)" -CA-Man,25752,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,5624 -CA-Man,25752,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Total -CA-Man,25752,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -CA-Man,25752,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -CA-Man,25752,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,1994 -CA-Man,25752,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,"data from Gower et al. (1997, J Geophy Res 102, 29029-29041)" -CA-Man,26511,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT,30 -CA-Man,25646,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT,40 -CA-Man,25646,GRP_AG_LIT_PROD,AG_LIT_PROD_UNIT,gC m-2 -CA-Man,26511,GRP_AG_LIT_PROD,AG_LIT_PROD_UNIT,gC m-2 -CA-Man,25646,GRP_AG_LIT_PROD,AG_LIT_PROD_COMMENT,"Data from Dunn et al. (2007, Global Change Biology 13, 577-590)" -CA-Man,26511,GRP_AG_LIT_PROD,AG_LIT_PROD_COMMENT,"Data from Dunn et al. (2007, Global Change Biology 13, 577-590)" -CA-Man,25491,GRP_AG_PROD_OTHER,AG_PROD_OTHER,12 -CA-Man,25491,GRP_AG_PROD_OTHER,AG_PROD_OTHER_ORGAN,Total -CA-Man,25491,GRP_AG_PROD_OTHER,AG_PROD_OTHER_UNIT,gC m-2 -CA-Man,25491,GRP_AG_PROD_OTHER,AG_PROD_DATE_START,1994 -CA-Man,25491,GRP_AG_PROD_OTHER,AG_PROD_COMMENT,"data from Gower et al. (1997, J Geophy Res 102, 29029-29041)" -CA-Man,26382,GRP_AG_PROD_SHRUB,AG_PROD_SHRUB,1 -CA-Man,26382,GRP_AG_PROD_SHRUB,AG_PROD_SHRUB_ORGAN,Total -CA-Man,26382,GRP_AG_PROD_SHRUB,AG_PROD_SHRUB_UNIT,gC m-2 -CA-Man,26382,GRP_AG_PROD_SHRUB,AG_PROD_DATE_START,1994 -CA-Man,26382,GRP_AG_PROD_SHRUB,AG_PROD_COMMENT,"data from Gower et al. (1997, J Geophy Res 102, 29029-29041)" -CA-Man,25861,GRP_AG_PROD_TREE,AG_PROD_TREE,5 -CA-Man,25861,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Foliage -CA-Man,25861,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -CA-Man,25861,GRP_AG_PROD_TREE,AG_PROD_DATE_START,1994 -CA-Man,25861,GRP_AG_PROD_TREE,AG_PROD_COMMENT,"data from Gower et al. (1997, J Geophy Res 102, 29029-29041)" -CA-Man,26501,GRP_AG_PROD_TREE,AG_PROD_TREE,5 -CA-Man,26501,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Foliage -CA-Man,26501,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -CA-Man,26501,GRP_AG_PROD_TREE,AG_PROD_DATE_START,1993 -CA-Man,26501,GRP_AG_PROD_TREE,AG_PROD_COMMENT,"data from Gower et al. (1997, J Geophy Res 102, 29029-29041)" -CA-Man,26146,GRP_AG_PROD_TREE,AG_PROD_TREE,66 -CA-Man,26146,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Wood -CA-Man,26146,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -CA-Man,26146,GRP_AG_PROD_TREE,AG_PROD_DATE_START,1993 -CA-Man,26146,GRP_AG_PROD_TREE,AG_PROD_COMMENT,"data from Gower et al. (1997, J Geophy Res 102, 29029-29041)" -CA-Man,26147,GRP_AG_PROD_TREE,AG_PROD_TREE,71 -CA-Man,26147,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Total -CA-Man,26147,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -CA-Man,26147,GRP_AG_PROD_TREE,AG_PROD_DATE_START,1993 -CA-Man,26147,GRP_AG_PROD_TREE,AG_PROD_COMMENT,"data from Gower et al. (1997, J Geophy Res 102, 29029-29041)" -CA-Man,25490,GRP_AG_PROD_TREE,AG_PROD_TREE,73 -CA-Man,25490,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Wood -CA-Man,25490,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -CA-Man,25490,GRP_AG_PROD_TREE,AG_PROD_DATE_START,1994 -CA-Man,25490,GRP_AG_PROD_TREE,AG_PROD_COMMENT,"data from Gower et al. (1997, J Geophy Res 102, 29029-29041)" -CA-Man,26640,GRP_AG_PROD_TREE,AG_PROD_TREE,78 -CA-Man,26640,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Total -CA-Man,26640,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -CA-Man,26640,GRP_AG_PROD_TREE,AG_PROD_DATE_START,1994 -CA-Man,26640,GRP_AG_PROD_TREE,AG_PROD_COMMENT,"data from Gower et al. (1997, J Geophy Res 102, 29029-29041)" -CA-Man,25762,GRP_BIOMASS_CHEM,BIOMASS_N,0.079 -CA-Man,25762,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -CA-Man,25762,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -CA-Man,25762,GRP_BIOMASS_CHEM,BIOMASS_SPP,(Unknown) -CA-Man,25762,GRP_BIOMASS_CHEM,BIOMASS_COMMENT,data from Bergeron et al. (2007) -CA-Man,5908,GRP_CLIM_AVG,MAT,-3.2 -CA-Man,5908,GRP_CLIM_AVG,MAP,520 -CA-Man,5908,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfc -CA-Man,27000058,GRP_COUNTRY,COUNTRY,Canada -CA-Man,1971,GRP_DM_FIRE,DM_FIRE,Nature induced burn -CA-Man,1971,GRP_DM_FIRE,DM_COMMENT,natural regeneration -CA-Man,15759,GRP_DOI,DOI,10.17190/AMF/1245997 -CA-Man,15759,GRP_DOI,DOI_CITATION,"Brian Amiro (2016), AmeriFlux BASE CA-Man Manitoba - Northern Old Black Spruce (former BOREAS Northern Study Area), Ver. 2-1, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1245997" -CA-Man,15759,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -CA-Man,31845,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -CA-Man,31845,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Brian Amiro -CA-Man,31845,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -CA-Man,31845,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,Brian_Amiro@umanitoba.ca -CA-Man,31845,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of Manitoba -CA-Man,31847,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,University of Manitoba -CA-Man,31847,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -CA-Man,31846,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,"DOE, NSF, Canadian Foundation for Climate and Atmospsheric Science, BIOCAP Canada" -CA-Man,31846,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -CA-Man,5079,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Fire -CA-Man,7610,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -CA-Man,7610,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -CA-Man,7610,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,1994 -CA-Man,7610,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,2008 -CA-Man,7610,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -CA-Man,7610,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,Decommissioned -CA-Man,23000058,GRP_HEADER,SITE_NAME,Manitoba - Northern Old Black Spruce (former BOREAS Northern Study Area) -CA-Man,88188,GRP_HEIGHTC,HEIGHTC,9.1 -CA-Man,88188,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -CA-Man,88188,GRP_HEIGHTC,HEIGHTC_DATE,1994 -CA-Man,88188,GRP_HEIGHTC,HEIGHTC_COMMENT,"Mean diameter at breast height (cm) 8.5; Stand density (#/ha) 5450; Gower et al. (1997, J Geophy Res 102, 29029-29041)" -CA-Man,4501,GRP_IGBP,IGBP,ENF -CA-Man,4501,GRP_IGBP,IGBP_COMMENT,naturally regenerated forest stand after wild fire -CA-Man,25859,GRP_LAI,LAI_TYPE,LAI -CA-Man,26251,GRP_LAI,LAI_TYPE,LAI -CA-Man,26251,GRP_LAI,LAI_METHOD,Other -CA-Man,26251,GRP_LAI,LAI_APPROACH,LAI-3000 and TRAC -CA-Man,25859,GRP_LAI,LAI_DATE,1994 -CA-Man,26251,GRP_LAI,LAI_DATE,2003 -CA-Man,25859,GRP_LAI,LAI_COMMENT,"Gower et al. (1997, J Geophy Res 102, 29029-29041)" -CA-Man,26251,GRP_LAI,LAI_COMMENT,"Gower et al. (1997, J Geophy Res 102, 29029-29041)" -CA-Man,25859,GRP_LAI,LAI_TOT,4.2 -CA-Man,26251,GRP_LAI,LAI_TOT,4.8 -CA-Man,3667,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -CA-Man,8454,GRP_LOCATION,LOCATION_LAT,55.8796 -CA-Man,8454,GRP_LOCATION,LOCATION_LONG,-98.4808 -CA-Man,8454,GRP_LOCATION,LOCATION_ELEV,259 -CA-Man,26151,GRP_NEP,NEP,41000 -CA-Man,26151,GRP_NEP,NEP_DATE_START,1995 -CA-Man,26151,GRP_NEP,NEP_DATE_END,1996 -CA-Man,26151,GRP_NEP,NEP_COMMENT,"Jan-Dec; Data from Dunn et al. (2007, Global Change Biology 13, 577-590)" -CA-Man,26504,GRP_NEP,NEP,84000 -CA-Man,26504,GRP_NEP,NEP_DATE_START,1996 -CA-Man,26504,GRP_NEP,NEP_DATE_END,1997 -CA-Man,26504,GRP_NEP,NEP_COMMENT,"Jan-Dec; Data from Dunn et al. (2007, Global Change Biology 13, 577-590)" -CA-Man,25869,GRP_NEP,NEP,39000 -CA-Man,25869,GRP_NEP,NEP_DATE_START,1997 -CA-Man,25869,GRP_NEP,NEP_DATE_END,1998 -CA-Man,25869,GRP_NEP,NEP_COMMENT,"Jan-Dec; Data from Dunn et al. (2007, Global Change Biology 13, 577-590)" -CA-Man,25232,GRP_NEP,NEP,-7000 -CA-Man,25232,GRP_NEP,NEP_DATE_START,1998 -CA-Man,25232,GRP_NEP,NEP_DATE_END,1999 -CA-Man,25232,GRP_NEP,NEP_COMMENT,"Jan-Dec; Data from Dunn et al. (2007, Global Change Biology 13, 577-590)" -CA-Man,26255,GRP_NEP,NEP,-7000 -CA-Man,26255,GRP_NEP,NEP_DATE_START,1999 -CA-Man,26255,GRP_NEP,NEP_DATE_END,2000 -CA-Man,26255,GRP_NEP,NEP_COMMENT,"Jan-Dec; Data from Dunn et al. (2007, Global Change Biology 13, 577-590)" -CA-Man,25988,GRP_NEP,NEP,-3000 -CA-Man,25988,GRP_NEP,NEP_DATE_START,2000 -CA-Man,25988,GRP_NEP,NEP_DATE_END,2001 -CA-Man,25988,GRP_NEP,NEP_COMMENT,"Jan-Dec; Data from Dunn et al. (2007, Global Change Biology 13, 577-590)" -CA-Man,25497,GRP_NEP,NEP,-23000 -CA-Man,25497,GRP_NEP,NEP_DATE_START,2001 -CA-Man,25497,GRP_NEP,NEP_DATE_END,2002 -CA-Man,25497,GRP_NEP,NEP_COMMENT,"Jan-Dec; Data from Dunn et al. (2007, Global Change Biology 13, 577-590)" -CA-Man,26645,GRP_NEP,NEP,-27000 -CA-Man,26645,GRP_NEP,NEP_DATE_START,2002 -CA-Man,26645,GRP_NEP,NEP_DATE_END,2003 -CA-Man,26645,GRP_NEP,NEP_COMMENT,"Jan-Dec; Data from Dunn et al. (2007, Global Change Biology 13, 577-590)" -CA-Man,26259,GRP_NEP,NEP,-58000 -CA-Man,26259,GRP_NEP,NEP_DATE_START,2003 -CA-Man,26259,GRP_NEP,NEP_DATE_END,2004 -CA-Man,26259,GRP_NEP,NEP_COMMENT,"Jan-Dec; Data from Dunn et al. (2007, Global Change Biology 13, 577-590)" -CA-Man,26646,GRP_NEP,NEP,-21000 -CA-Man,26646,GRP_NEP,NEP_DATE_START,2004 -CA-Man,26646,GRP_NEP,NEP_DATE_END,2005 -CA-Man,26646,GRP_NEP,NEP_COMMENT,"Jan-Dec; Data from Dunn et al. (2007, Global Change Biology 13, 577-590)" -CA-Man,5061,GRP_NETWORK,NETWORK,AmeriFlux -CA-Man,9351,GRP_NETWORK,NETWORK,Fluxnet-Canada -CA-Man,1700004554,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Amiro, B., MacPherson, J. I., Desjardins, R. L. (1999) Boreas Flight Measurements Of Forest-Fire Effects On Carbon Dioxide And Energy Fluxes, Agricultural And Forest Meteorology, 96(4), 199-208" -CA-Man,1700004554,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/S0168-1923(99)00050-7 -CA-Man,1700004554,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Man,1700004884,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Bakwin, P. S., Davis, K. J., Yi, C., Wofsy, S. C., Munger, J. W., Haszpra, L., Barcza, Z. (2004) Regional Carbon Dioxide Fluxes From Mixing Ratio Data, Tellus Series B-Chemical and Physical Meteorology, 56(4), 301-311" -CA-Man,1700004884,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.3402/TELLUSB.V56I4.16446 -CA-Man,1700004884,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Man,1700005133,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Baldocchi, D., Penuelas, J. (2018) The Physics And Ecology Of Mining Carbon Dioxide From The Atmosphere By Ecosystems, Global Change Biology, 45(1), 9275–9287" -CA-Man,1700005133,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/GCB.14559 -CA-Man,1700005133,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Man,1700008652,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Baldocchi, D., Penuelas, J. (2018) The Physics And Ecology Of Mining Carbon Dioxide From The Atmosphere By Ecosystems, Global Change Biology, 45(2), 9275–9287" -CA-Man,1700008652,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/GCB.14559 -CA-Man,1700008652,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Man,1700006357,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Bergeron, O., Margolis, H. A., Black, T. A., Coursolle, C., Dunn, A. L., Barr, A. G., Wofsy, S. C. (2007) Comparison Of Carbon Dioxide Fluxes Over Three Boreal Black Spruce Forests In Canada, Global Change Biology, 13(1), 89-107" -CA-Man,1700006357,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/J.1365-2486.2006.01281.X -CA-Man,1700006357,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Man,1700000642,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Bond-Lamberty, B., Wang, C., Gower, S. T. (2004) A Global Relationship Between The Heterotrophic And Autotrophic Components Of Soil Respiration?, Global Change Biology, 10(10), 1756-1766" -CA-Man,1700000642,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/J.1365-2486.2004.00816.X -CA-Man,1700000642,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Man,1700000552,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Bond-Lamberty, B., Wang, C., Gower, S. T. (2004) Net Primary Production And Net Ecosystem Production Of A Boreal Black Spruce Wildfire Chronosequence, Global Change Biology, 10(4), 473-487" -CA-Man,1700000552,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/J.1529-8817.2003.0742.X -CA-Man,1700000552,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Man,1700001995,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Bond-Lamberty, B., Wang, C., Gower, S. T., Norman, J. (2002) Leaf Area Dynamics Of A Boreal Black Spruce Fire Chronosequence, Tree Physiology, 22(14), 993-1001" -CA-Man,1700001995,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1093/TREEPHYS/22.14.993 -CA-Man,1700001995,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Man,1700000879,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Brooks, J. R., Flanagan, L. B., Varney, G. T., Ehleringer, J. R. (1997) Vertical Gradients In Photosynthetic Gas Exchange Characteristics And Refixation Of Respired CO2 Within Boreal Forest Canopies, Tree Physiology, 17(1), 1-12" -CA-Man,1700000879,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1093/TREEPHYS/17.1.1 -CA-Man,1700000879,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Man,1700003477,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Baldocchi, D. D., Poindexter, C., Abraha, M., Desai, A. R., Bohrer, G., Arain, M. A., Griffis, T., Blanken, P. D., O'Halloran, T. L., Thomas, R. Q., Zhang, Q., Burns, S. P., Frank, J. M., Christian, D., Brown, S., Black, T. A., Gough, C. M., Law, B. E., Lee, X., Chen, J., Reed, D. E., Massman, W. J., Clark, K., Hatfield, J., Prueger, J., Bracho, R., Baker, J. M., Martin, T. A. (2018) Temporal Dynamics Of Aerodynamic Canopy Height Derived From Eddy Covariance Momentum Flux Data Across North American Flux Networks, Geophysical Research Letters, 45(1), 9275–9287" -CA-Man,1700003477,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018GL079306 -CA-Man,1700003477,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Man,1700001467,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Baldocchi, D. D., Poindexter, C., Abraha, M., Desai, A. R., Bohrer, G., Arain, M. A., Griffis, T., Blanken, P. D., O'Halloran, T. L., Thomas, R. Q., Zhang, Q., Burns, S. P., Frank, J. M., Christian, D., Brown, S., Black, T. A., Gough, C. M., Law, B. E., Lee, X., Chen, J., Reed, D. E., Massman, W. J., Clark, K., Hatfield, J., Prueger, J., Bracho, R., Baker, J. M., Martin, T. A. (2018) Temporal Dynamics Of Aerodynamic Canopy Height Derived From Eddy Covariance Momentum Flux Data Across North American Flux Networks, Geophysical Research Letters, 45(2), 9275–9287" -CA-Man,1700001467,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018GL079306 -CA-Man,1700001467,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Man,1700007587,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(7458), 108350" -CA-Man,1700007587,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -CA-Man,1700007587,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Man,1700004584,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Coursolle, C., Margolis, H. A., Barr, A. G., Black, T. A., Amiro, B. D., McCaughey, J. H., Flanagan, L. B., Lafleur, P. M., Roulet, N. T., Bourque, C. P., Arain, M. A., Wofsy, S. C., Dunn, A., Morgenstern, K., Orchansky, A. L., Bernier, P. Y., Chen, J. M., Kidston, J., Saigusa, N., Hedstrom, N. (2006) Late-Summer Carbon Fluxes From Canadian Forests And Peatlands Along An East-–West Continental Transect, Canadian Journal Of Forest Research, 36(3), 783-800" -CA-Man,1700004584,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1139/X05-270 -CA-Man,1700004584,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Man,1700006876,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Dang, Q., Margolis, H. A., Coyea, M. R., Sy, M., Collatz, G. J. (1997) Regulation Of Branch-Level Gas Exchange Of Boreal Trees: Roles Of Shoot Water Potential And Vapor Pressure Difference, Tree Physiology, 17(8-9), 521-535" -CA-Man,1700006876,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1093/TREEPHYS/17.8-9.521 -CA-Man,1700006876,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Man,1700008055,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Dunn, A. L., Barford, C. C., Wofsy, S. C., Goulden, M. L., Daube, B. C. (2007) A Long-Term Record Of Carbon Exchange In A Boreal Black Spruce Forest: Means, Responses To Interannual Variability, And Decadal Trends, Global Change Biology, 13(3), 577-590" -CA-Man,1700008055,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/J.1365-2486.2006.01221.X -CA-Man,1700008055,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Primary_Citation -CA-Man,1700006060,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Gower, S. T., Krankina, O., Olson, R. J., Apps, M., Linder, S., Wang, C. (2001) Net Primary Production And Carbon Allocation Patterns Of Boreal Forest Ecosystems, Ecological Applications, 11(5), 1395-1411" -CA-Man,1700006060,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.2307/3060928 -CA-Man,1700006060,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Man,1700000732,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Gower, S. T., Vogel, J. G., Norman, J. M., Kucharik, C. J., Steele, S. J., Stow, T. K. (1997) Carbon Distribution And Aboveground Net Primary Production In Aspen, Jack Pine, And Black Spruce Stands In Saskatchewan And Manitoba, Canada, Journal Of Geophysical Research: Atmospheres, 102(D24), 29029-29041" -CA-Man,1700000732,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/97JD02317 -CA-Man,1700000732,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Man,1700002016,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Hirsch, A. I., Trumbore, S. E., Goulden, M. L. (2004) The Surface CO2 Gradient And Pore-Space Storage Flux In A High-Porosity Litter Layer, Tellus Series B-Chemical and Physical Meteorology, 56(4), 312-321" -CA-Man,1700002016,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/J.1600-0889.2004.00113.X -CA-Man,1700002016,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Man,1700008049,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Joiner, D. W., McCaughey, J. H., Lafleur, P. M., Bartlett, P. A. (1999) Water And Carbon Dioxide Exchange At A Boreal Young Jack Pine Forest In The BOREAS Northern Study Area, Journal Of Geophysical Research: Atmospheres, 104(D22), 27641-27652" -CA-Man,1700008049,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/1999JD900368 -CA-Man,1700008049,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Man,1700004302,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Keenan, T. F., Hollinger, D. Y., Bohrer, G., Dragoni, D., Munger, J. W., Schmid, H. P., Richardson, A. D. (2013) Increase In Forest Water-Use Efficiency As Atmospheric Carbon Dioxide Concentrations Rise, Nature, 499(7458), 324-327" -CA-Man,1700004302,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1038/NATURE12291 -CA-Man,1700004302,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Man,1700004572,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Kimball, J. S., Thornton, P. E., White, M. A., Running, S. W. (1997) Simulating Forest Productivity And Surface-Atmosphere Carbon Exchange In The BOREAS Study Region, Tree Physiology, 17(8-9), 589-599" -CA-Man,1700004572,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1093/TREEPHYS/17.8-9.589 -CA-Man,1700004572,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Man,1700003930,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Kucharik, C. J., Norman, J. M., Gower, S. T. (1999) Characterization Of Radiation Regimes In Nonrandom Forest Canopies: Theory, Measurements, And A Simplified Modeling Approach, Tree Physiology, 19(11), 695-706" -CA-Man,1700003930,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1093/TREEPHYS/19.11.695 -CA-Man,1700003930,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Man,1700004377,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Lavigne, M. B., Ryan, M. G. (1997) Growth And Maintenance Respiration Rates Of Aspen, Black Spruce And Jack Pine Stems At Northern And Southern BOREAS Sites, Tree Physiology, 17(8-9), 543-551" -CA-Man,1700004377,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1093/TREEPHYS/17.8-9.543 -CA-Man,1700004377,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Man,1700000525,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Margolis, H. A., Ryan, M. G. (1997) A Physiological Basis For Biosphere-Atmosphere Interactions In The Boreal Forest: An Overview, Tree Physiology, 17(8-9), 491-499" -CA-Man,1700000525,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1093/TREEPHYS/17.8-9.491 -CA-Man,1700000525,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Man,1700001569,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Nakamura, R., Mahrt, L. (2001) Similarity Theory For Local And Spatially Averaged Momentum Fluxes, Agricultural And Forest Meteorology, 108(4), 265-279" -CA-Man,1700001569,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/S0168-1923(01)00250-7 -CA-Man,1700001569,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Man,1700000828,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Nichol, C. J., Huemmrich, K. F., Black, T., Jarvis, P. G., Walthall, C. L., Grace, J., Hall, F. G. (2000) Remote Sensing Of Photosynthetic-Light-Use Efficiency Of Boreal Forest, Agricultural And Forest Meteorology, 101(2-3), 131-142" -CA-Man,1700000828,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/S0168-1923(99)00167-7 -CA-Man,1700000828,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Man,1700007437,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Reich, P. B., Turner, D. P., Bolstad, P. (1999) An Approach To Spatially Distributed Modeling Of Net Primary Production (NPP) At The Landscape Scale And Its Application In Validation Of EOS NPP Products, Remote Sensing Of Environment, 70(1), 69-81" -CA-Man,1700007437,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/S0034-4257(99)00058-9 -CA-Man,1700007437,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Man,1700003969,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Soloway, A.D., B.D. AMIRO, A.L. Dunn, and S.C. Wofsy. (2017) Carbon neutral or a sink? Uncertainty caused by gapfilling long-term flux measurements for an old-growth boreal black spruce forest., Agricultural and Forest Meteorology, 233(1), 110-121" -CA-Man,1700003969,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Man,1700004515,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Soloway, A.D., B.D. AMIRO, A.L. Dunn, and S.C. Wofsy. (2017) Carbon neutral or a sink? Uncertainty caused by gapfilling long-term flux measurements for an old-growth boreal black spruce forest., Agricultural and Forest Meteorology, 233(2), 110-121" -CA-Man,1700004515,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Man,1700005922,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Steele, S. J., Gower, S. T., Vogel, J. G., Norman, J. M. (1997) Root Mass, Net Primary Production And Turnover In Aspen, Jack Pine And Black Spruce Forests In Saskatchewan And Manitoba, Canada, Tree Physiology, 17(8-9), 577-587" -CA-Man,1700005922,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1093/TREEPHYS/17.8-9.577 -CA-Man,1700005922,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Man,1700000039,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Wang, C., Bond-Lamberty, B., Gower, S. T. (2003) Carbon Distribution Of A Well- And Poorly-Drained Black Spruce Fire Chronosequence, Global Change Biology, 9(7), 1066-1079" -CA-Man,1700000039,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1046/J.1365-2486.2003.00645.X -CA-Man,1700000039,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Man,1700007038,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Xu, B., Arain, M. A., Black, T. A., Law, B. E., Pastorello, G. Z., Chu, H. (2020) Seasonal Variability Of Forest Sensitivity To Heat And Drought Stresses: A Synthesis Based On Carbon Fluxes From North American Forest Ecosystems, Global Change Biology, 26(2), 901-918" -CA-Man,1700007038,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/GCB.14843 -CA-Man,1700007038,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Man,26379,GRP_SA,SA,155 -CA-Man,26379,GRP_SA,SA_DATE,1994 -CA-Man,26379,GRP_SA,SA_COMMENT,"Gower et al. (1997, J Geophy Res 102, 29029-29041)" -CA-Man,3347,GRP_SITE_CHAR,TERRAIN,Flat -CA-Man,6221,GRP_SITE_DESC,SITE_DESC,"55.880° N, 98.481° W, elevation of 259 m, Boreal coniferous: Black spruce; occasional larch present in poorly-drained areas. Groundcover is moss (feathermosses and Sphagnum), Labrador Tea, Vaccinium, and willows are a main component of the understory. It was established in 1993 as a BOREAS site." -CA-Man,8450,GRP_SITE_FUNDING,SITE_FUNDING,"DOE, NSF, Canadian Foundation for Climate and Atmospsheric Science, BIOCAP Canada" -CA-Man,26500,GRP_SNAG_MASS,SNAG_MASS,381 -CA-Man,26500,GRP_SNAG_MASS,SNAG_MASS_UNIT,gC m-2 -CA-Man,26500,GRP_SNAG_MASS,SNAG_MASS_DATE,1994 -CA-Man,26500,GRP_SNAG_MASS,SNAG_MASS_COMMENT,"data from Gower et al. (1997, J Geophy Res 102, 29029-29041)" -CA-Man,25238,GRP_SOIL_CHEM,SOIL_CHEM_C_ORG,11.94 -CA-Man,26260,GRP_SOIL_CHEM,SOIL_CHEM_C_ORG,14.9992 -CA-Man,25239,GRP_SOIL_CHEM,SOIL_CHEM_C_ORG,32.2217 -CA-Man,25992,GRP_SOIL_CHEM,SOIL_CHEM_C_ORG,77.5289 -CA-Man,25500,GRP_SOIL_CHEM,SOIL_CHEM_C_ORG,827.032 -CA-Man,25991,GRP_SOIL_CHEM,SOIL_CHEM_C_ORG,9.02119 -CA-Man,26647,GRP_SOIL_CHEM,SOIL_CHEM_N_TOT,0.145909 -CA-Man,26261,GRP_SOIL_CHEM,SOIL_CHEM_N_TOT,0.22704 -CA-Man,26161,GRP_SOIL_CHEM,SOIL_CHEM_N_TOT,0.2456 -CA-Man,26162,GRP_SOIL_CHEM,SOIL_CHEM_N_TOT,1.69563 -CA-Man,26514,GRP_SOIL_CHEM,SOIL_CHEM_N_TOT,1.94739 -CA-Man,26513,GRP_SOIL_CHEM,SOIL_CHEM_N_TOT,2.11 -CA-Man,26159,GRP_SOIL_CHEM,SOIL_CHEM_PH_SALT,1.466666667 -CA-Man,25647,GRP_SOIL_CHEM,SOIL_CHEM_PH_SALT,2.175 -CA-Man,26512,GRP_SOIL_CHEM,SOIL_CHEM_PH_SALT,2.475 -CA-Man,26160,GRP_SOIL_CHEM,SOIL_CHEM_PH_SALT,6.075 -CA-Man,25648,GRP_SOIL_CHEM,SOIL_CHEM_PH_SALT,6.909090909 -CA-Man,25499,GRP_SOIL_CHEM,SOIL_CHEM_PH_SALT,7.985714286 -CA-Man,26512,GRP_SOIL_CHEM,SOIL_CHEM_BD,0.02 -CA-Man,25647,GRP_SOIL_CHEM,SOIL_CHEM_BD,0.04 -CA-Man,26159,GRP_SOIL_CHEM,SOIL_CHEM_BD,0.06 -CA-Man,26160,GRP_SOIL_CHEM,SOIL_CHEM_BD,0.866 -CA-Man,25648,GRP_SOIL_CHEM,SOIL_CHEM_BD,1.113333333 -CA-Man,25499,GRP_SOIL_CHEM,SOIL_CHEM_BD,1.235 -CA-Man,25647,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,-12.5 -CA-Man,26260,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,-12.5 -CA-Man,26261,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,-12.5 -CA-Man,25991,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,-22.25 -CA-Man,26512,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,-22.25 -CA-Man,26647,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,-22.25 -CA-Man,25238,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,-4.5 -CA-Man,26159,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,-4.5 -CA-Man,26161,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,-4.5 -CA-Man,25239,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,0 -CA-Man,26160,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,0 -CA-Man,26162,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,0 -CA-Man,25648,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,11 -CA-Man,25992,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,11 -CA-Man,26513,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,11 -CA-Man,25499,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,37.73 -CA-Man,25500,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,37.73 -CA-Man,26514,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,37.73 -CA-Man,25991,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,-12.5 -CA-Man,26512,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,-12.5 -CA-Man,26647,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,-12.5 -CA-Man,25647,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,-4.5 -CA-Man,26260,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,-4.5 -CA-Man,26261,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,-4.5 -CA-Man,25238,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,0 -CA-Man,26159,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,0 -CA-Man,26161,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,0 -CA-Man,25239,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,11 -CA-Man,26160,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,11 -CA-Man,26162,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,11 -CA-Man,25648,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,37.73 -CA-Man,25992,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,37.73 -CA-Man,26513,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,37.73 -CA-Man,25499,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,74.43 -CA-Man,25500,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,74.43 -CA-Man,26514,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,74.43 -CA-Man,25239,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,A -CA-Man,26160,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,A -CA-Man,26162,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,A -CA-Man,25648,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,B -CA-Man,25992,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,B -CA-Man,26513,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,B -CA-Man,25499,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,C -CA-Man,25500,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,C -CA-Man,26514,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,C -CA-Man,25647,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,F -CA-Man,26260,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,F -CA-Man,26261,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,F -CA-Man,25238,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,H -CA-Man,26159,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,H -CA-Man,26161,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,H -CA-Man,25991,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,L -CA-Man,26512,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,L -CA-Man,26647,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,L -CA-Man,25238,GRP_SOIL_CHEM,SOIL_CHEM_DATE,1994 -CA-Man,25239,GRP_SOIL_CHEM,SOIL_CHEM_DATE,1994 -CA-Man,25499,GRP_SOIL_CHEM,SOIL_CHEM_DATE,1994 -CA-Man,25500,GRP_SOIL_CHEM,SOIL_CHEM_DATE,1994 -CA-Man,25647,GRP_SOIL_CHEM,SOIL_CHEM_DATE,1994 -CA-Man,25648,GRP_SOIL_CHEM,SOIL_CHEM_DATE,1994 -CA-Man,25991,GRP_SOIL_CHEM,SOIL_CHEM_DATE,1994 -CA-Man,25992,GRP_SOIL_CHEM,SOIL_CHEM_DATE,1994 -CA-Man,26159,GRP_SOIL_CHEM,SOIL_CHEM_DATE,1994 -CA-Man,26160,GRP_SOIL_CHEM,SOIL_CHEM_DATE,1994 -CA-Man,26161,GRP_SOIL_CHEM,SOIL_CHEM_DATE,1994 -CA-Man,26162,GRP_SOIL_CHEM,SOIL_CHEM_DATE,1994 -CA-Man,26260,GRP_SOIL_CHEM,SOIL_CHEM_DATE,1994 -CA-Man,26261,GRP_SOIL_CHEM,SOIL_CHEM_DATE,1994 -CA-Man,26512,GRP_SOIL_CHEM,SOIL_CHEM_DATE,1994 -CA-Man,26513,GRP_SOIL_CHEM,SOIL_CHEM_DATE,1994 -CA-Man,26514,GRP_SOIL_CHEM,SOIL_CHEM_DATE,1994 -CA-Man,26647,GRP_SOIL_CHEM,SOIL_CHEM_DATE,1994 -CA-Man,26514,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,(0.043285714 gN/100g); soil thickness 0.364286m; measured by BOREAS -CA-Man,26162,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,(0.178 gN/100g); ; soil thickness 0.11m; measured by BOREAS -CA-Man,26261,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,(0.7095 gN/100g); soil thickness 0.08m; measured by BOREAS -CA-Man,26647,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,(0.74825 gN/100g); soil thickness 0.0975m; measured by BOREAS -CA-Man,26161,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,(0.818666667 gN/100g); soil thickness 0.05m; measured by BOREAS -CA-Man,25500,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,(18.38285714 gC/100g); soil thickness 0.267273m; measured by BOREAS -CA-Man,25992,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,(2.605455 gC/100g); soil thickness 0.267273m; measured by BOREAS -CA-Man,25239,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,(3.3825 gC/100g); soil thickness 0.11m; measured by BOREAS -CA-Man,25238,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,(39.8 gC/100g); soil thickness 0.05m; measured by BOREAS -CA-Man,25991,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,(46.2625 gC/100g); soil thickness 0.0975m; measured by BOREAS -CA-Man,26260,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,(46.8725 gC/100g); soil thickness 0.08m; measured by BOREAS -CA-Man,26513,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,0.070909091 gN/100g); soil thickness 0.267273m; measured by BOREAS -CA-Man,26159,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,soil thickness 0.05m; measured by BOREAS -CA-Man,25647,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,soil thickness 0.08m; measured by BOREAS -CA-Man,26512,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,soil thickness 0.0975m; measured by BOREAS -CA-Man,26160,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,soil thickness 0.11m; measured by BOREAS -CA-Man,25648,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,soil thickness 0.267273m; measured by BOREAS -CA-Man,25499,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,soil thickness 0.364286m; measured by BOREAS -CA-Man,23644,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION,peaty-phase orthic gleysol -CA-Man,23644,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION_TAXONOMY,Other -CA-Man,23913,GRP_SOIL_DEPTH,SOIL_DEPTH,40 -CA-Man,23913,GRP_SOIL_DEPTH,SOIL_DEPTH_COMMENT,"(range 0.3-0.5) - -Stele_et_al_TreePhysiol_1997 -NSA Study Area" -CA-Man,26374,GRP_SOIL_TEX,SOIL_TEX_SAND,0.627272727 -CA-Man,25641,GRP_SOIL_TEX,SOIL_TEX_SAND,1.742857143 -CA-Man,26515,GRP_SOIL_TEX,SOIL_TEX_SAND,2.516666667 -CA-Man,26515,GRP_SOIL_TEX,SOIL_TEX_SILT,10.66666667 -CA-Man,25641,GRP_SOIL_TEX,SOIL_TEX_SILT,22.54285714 -CA-Man,26374,GRP_SOIL_TEX,SOIL_TEX_SILT,4.372727273 -CA-Man,25641,GRP_SOIL_TEX,SOIL_TEX_CLAY,75.84285714 -CA-Man,26515,GRP_SOIL_TEX,SOIL_TEX_CLAY,86.94166667 -CA-Man,26374,GRP_SOIL_TEX,SOIL_TEX_CLAY,95.13636364 -CA-Man,26515,GRP_SOIL_TEX,SOIL_TEX_HORIZON,A -CA-Man,26374,GRP_SOIL_TEX,SOIL_TEX_HORIZON,B -CA-Man,25641,GRP_SOIL_TEX,SOIL_TEX_HORIZON,C -CA-Man,25641,GRP_SOIL_TEX,SOIL_TEX_COMMENT,measured by BOREAS -CA-Man,26374,GRP_SOIL_TEX,SOIL_TEX_COMMENT,measured by BOREAS -CA-Man,26515,GRP_SOIL_TEX,SOIL_TEX_COMMENT,measured by BOREAS -CA-Man,26639,GRP_SPP_O,SPP_O,PIMA (NRCS plant code) -CA-Man,26639,GRP_SPP_O,SPP_O_PERC,90 -CA-Man,26639,GRP_SPP_O,SPP_DATE,1994 -CA-Man,26639,GRP_SPP_O,SPP_COMMENT,"Gower et al. (1997, J Geophy Res 102, 29029-29041)" -CA-Man,26380,GRP_SPP_U,SPP_U,HYLOC2 (NRCS plant code) -CA-Man,26250,GRP_SPP_U,SPP_U,PLEUR10 (NRCS plant code) -CA-Man,26250,GRP_SPP_U,SPP_DATE,1994 -CA-Man,26380,GRP_SPP_U,SPP_DATE,1994 -CA-Man,26250,GRP_SPP_U,SPP_COMMENT,"Gower et al. (1997, J Geophy Res 102, 29029-29041)" -CA-Man,26380,GRP_SPP_U,SPP_COMMENT,"Gower et al. (1997, J Geophy Res 102, 29029-29041)" -CA-Man,8446,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Brian Amiro -CA-Man,8446,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -CA-Man,8446,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,Brian_Amiro@umanitoba.ca -CA-Man,8446,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Manitoba -CA-Man,4145,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Steve Wofsy -CA-Man,4145,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,AncContact -CA-Man,4145,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,swofsy@seas.harvard.edu -CA-Man,4145,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Harvard University -CA-Man,3340,GRP_URL,URL,http://daac.ornl.gov/BOREAS/bhs/Sites/NSA-OBS.html -CA-Man,24000058,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/CA-Man -CA-Man,7612,GRP_UTC_OFFSET,UTC_OFFSET,-6 -CA-Mer,25453,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER,101.5 -CA-Mer,25453,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_ORGAN,Total -CA-Mer,25453,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_PHEN,Mixed/unknown -CA-Mer,25453,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_UNIT,gC m-2 -CA-Mer,25453,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_DATE,20030831 -CA-Mer,26458,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER,95.5 -CA-Mer,26458,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_ORGAN,Total -CA-Mer,26458,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_PHEN,Mixed/unknown -CA-Mer,26458,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_UNIT,gC m-2 -CA-Mer,26458,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_DATE,19990808 -CA-Mer,26458,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_COMMENT,"~220/1999; data from Moore et al. (2002, Journal of Ecology 90, 25-36). Assumed that carbon account for 50% of biomass" -CA-Mer,26457,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB,126.12 -CA-Mer,26457,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_ORGAN,Total -CA-Mer,26457,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_PHEN,Mixed/unknown -CA-Mer,26457,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_UNIT,gC m-2 -CA-Mer,26457,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_DATE,20030831 -CA-Mer,26209,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB,148 -CA-Mer,26209,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_ORGAN,Total -CA-Mer,26209,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_PHEN,Mixed/unknown -CA-Mer,26209,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_UNIT,gC m-2 -CA-Mer,26209,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_DATE,19990808 -CA-Mer,26209,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_COMMENT,"~220/1999; data from Moore et al. (2002, Journal of Ecology 90, 25-36). Assumed that carbon account for 50% of biomass" -CA-Mer,25198,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB,59.07 -CA-Mer,25198,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_ORGAN,Foliage -CA-Mer,25198,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_PHEN,Mixed/unknown -CA-Mer,25198,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_UNIT,gC m-2 -CA-Mer,25198,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_DATE,20030831 -CA-Mer,25592,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB,67.05 -CA-Mer,25592,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_ORGAN,Wood -CA-Mer,25592,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_PHEN,Mixed/unknown -CA-Mer,25592,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_UNIT,gC m-2 -CA-Mer,25592,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_DATE,20030831 -CA-Mer,25706,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB,72.5 -CA-Mer,25706,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_ORGAN,Foliage -CA-Mer,25706,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_PHEN,Mixed/unknown -CA-Mer,25706,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_UNIT,gC m-2 -CA-Mer,25706,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_DATE,19990808 -CA-Mer,25706,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_COMMENT,"~220/1999; data from Moore et al. (2002, Journal of Ecology 90, 25-36). Assumed that carbon account for 50% of biomass" -CA-Mer,25830,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB,75.5 -CA-Mer,25830,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_ORGAN,Wood -CA-Mer,25830,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_PHEN,Mixed/unknown -CA-Mer,25830,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_UNIT,gC m-2 -CA-Mer,25830,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_DATE,19990808 -CA-Mer,25830,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_COMMENT,"~220/1999; data from Moore et al. (2002, Journal of Ecology 90, 25-36). Assumed that carbon account for 50% of biomass" -CA-Mer,26460,GRP_AG_PROD_OTHER,AG_PROD_OTHER,102 -CA-Mer,26460,GRP_AG_PROD_OTHER,AG_PROD_OTHER_ORGAN,Total -CA-Mer,26460,GRP_AG_PROD_OTHER,AG_PROD_OTHER_UNIT,gC m-2 -CA-Mer,26338,GRP_AG_PROD_SHRUB,AG_PROD_SHRUB,90 -CA-Mer,26338,GRP_AG_PROD_SHRUB,AG_PROD_SHRUB_ORGAN,Total -CA-Mer,26338,GRP_AG_PROD_SHRUB,AG_PROD_SHRUB_UNIT,gC m-2 -CA-Mer,26338,GRP_AG_PROD_SHRUB,AG_PROD_COMMENT,"data from Moore et al. (2002, Journal of Ecology 90, 25-36). Assumed that carbon account for 50% of biomass; data are the mean of 8 literatures. Assumed the carbon concentration is 50%." -CA-Mer,25593,GRP_BIOMASS_CHEM,BIOMASS_C,4.31 -CA-Mer,25594,GRP_BIOMASS_CHEM,BIOMASS_C,4.32 -CA-Mer,25708,GRP_BIOMASS_CHEM,BIOMASS_C,4.32 -CA-Mer,25330,GRP_BIOMASS_CHEM,BIOMASS_C,4.63 -CA-Mer,25946,GRP_BIOMASS_CHEM,BIOMASS_C,5.06 -CA-Mer,25329,GRP_BIOMASS_CHEM,BIOMASS_N,0.041 -CA-Mer,25593,GRP_BIOMASS_CHEM,BIOMASS_N,0.081 -CA-Mer,25594,GRP_BIOMASS_CHEM,BIOMASS_N,0.085 -CA-Mer,25708,GRP_BIOMASS_CHEM,BIOMASS_N,0.094 -CA-Mer,26461,GRP_BIOMASS_CHEM,BIOMASS_N,0.108 -CA-Mer,25329,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -CA-Mer,25330,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -CA-Mer,25593,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -CA-Mer,25594,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -CA-Mer,25708,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -CA-Mer,25946,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -CA-Mer,26461,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -CA-Mer,25329,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -CA-Mer,25330,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -CA-Mer,25593,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -CA-Mer,25594,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -CA-Mer,25708,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -CA-Mer,25946,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -CA-Mer,26461,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -CA-Mer,25329,GRP_BIOMASS_CHEM,BIOMASS_SPP,CHCA2 (NRCS plant code) -CA-Mer,25330,GRP_BIOMASS_CHEM,BIOMASS_SPP,CHCA2 (NRCS plant code) -CA-Mer,25946,GRP_BIOMASS_CHEM,BIOMASS_SPP,CHCA2 (NRCS plant code) -CA-Mer,26461,GRP_BIOMASS_CHEM,BIOMASS_SPP,CHCA2 (NRCS plant code) -CA-Mer,25708,GRP_BIOMASS_CHEM,BIOMASS_SPP,POST70 (NRCS plant code) -CA-Mer,25593,GRP_BIOMASS_CHEM,BIOMASS_SPP,SPCA70 (NRCS plant code) -CA-Mer,25594,GRP_BIOMASS_CHEM,BIOMASS_SPP,SPMA70 (NRCS plant code) -CA-Mer,25329,GRP_BIOMASS_CHEM,BIOMASS_DATE,20030831 -CA-Mer,25330,GRP_BIOMASS_CHEM,BIOMASS_DATE,20030831 -CA-Mer,25593,GRP_BIOMASS_CHEM,BIOMASS_DATE,20030831 -CA-Mer,25594,GRP_BIOMASS_CHEM,BIOMASS_DATE,20030831 -CA-Mer,25708,GRP_BIOMASS_CHEM,BIOMASS_DATE,20030831 -CA-Mer,25946,GRP_BIOMASS_CHEM,BIOMASS_DATE,20030831 -CA-Mer,26461,GRP_BIOMASS_CHEM,BIOMASS_DATE,20030831 -CA-Mer,25329,GRP_BIOMASS_CHEM,BIOMASS_COMMENT,"values from litter sample. Carlo Erba NC-2500 elemental analyzer, Moore et al. (2007, Ecosystems 10, 949-963)" -CA-Mer,25330,GRP_BIOMASS_CHEM,BIOMASS_COMMENT,"values from litter sample. Carlo Erba NC-2500 elemental analyzer, Moore et al. (2007, Ecosystems 10, 949-963)" -CA-Mer,25593,GRP_BIOMASS_CHEM,BIOMASS_COMMENT,"values from litter sample. Carlo Erba NC-2500 elemental analyzer, Moore et al. (2007, Ecosystems 10, 949-963)" -CA-Mer,25594,GRP_BIOMASS_CHEM,BIOMASS_COMMENT,"values from litter sample. Carlo Erba NC-2500 elemental analyzer, Moore et al. (2007, Ecosystems 10, 949-963)" -CA-Mer,25708,GRP_BIOMASS_CHEM,BIOMASS_COMMENT,"values from litter sample. Carlo Erba NC-2500 elemental analyzer, Moore et al. (2007, Ecosystems 10, 949-963)" -CA-Mer,25946,GRP_BIOMASS_CHEM,BIOMASS_COMMENT,"values from litter sample. Carlo Erba NC-2500 elemental analyzer, Moore et al. (2007, Ecosystems 10, 949-963)" -CA-Mer,26461,GRP_BIOMASS_CHEM,BIOMASS_COMMENT,"values from litter sample. Carlo Erba NC-2500 elemental analyzer, Moore et al. (2007, Ecosystems 10, 949-963)" -CA-Mer,33721,GRP_CLIM_AVG,MAT,6 -CA-Mer,33721,GRP_CLIM_AVG,MAP,943 -CA-Mer,33721,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfb -CA-Mer,27000059,GRP_COUNTRY,COUNTRY,Canada -CA-Mer,7022,GRP_DM_GENERAL,DM_GENERAL,Other -CA-Mer,7022,GRP_DM_GENERAL,DM_COMMENT,natural regeneration -CA-Mer,33722,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Undisturbed -CA-Mer,4645,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -CA-Mer,4645,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -CA-Mer,4645,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,1998 -CA-Mer,4645,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -CA-Mer,23000059,GRP_HEADER,SITE_NAME,"Ontario - Eastern Peatland, Mer Bleue" -CA-Mer,26459,GRP_HEIGHTC,HEIGHTC,0.25 -CA-Mer,261,GRP_IGBP,IGBP,WET -CA-Mer,261,GRP_IGBP,IGBP_COMMENT,Fluxnet Canada for details -CA-Mer,25829,GRP_LAI,LAI_TYPE,LAI -CA-Mer,26208,GRP_LAI,LAI_TYPE,LAI -CA-Mer,26208,GRP_LAI,LAI_METHOD,LAI_2000 -CA-Mer,25829,GRP_LAI,LAI_METHOD,Other -CA-Mer,25829,GRP_LAI,LAI_DATE,19990808 -CA-Mer,26208,GRP_LAI,LAI_DATE,20030831 -CA-Mer,25829,GRP_LAI,LAI_COMMENT,~220/1999; calculated from the leaf mass and density for individual species -CA-Mer,26208,GRP_LAI,LAI_COMMENT,"measrued followed Fluxnet-Canada protocol; also see Bubier et al. (2006, Can. J. Bot. 84, 910-23)" -CA-Mer,26208,GRP_LAI,LAI_TOT,1.2 -CA-Mer,25829,GRP_LAI,LAI_TOT,1.3 -CA-Mer,7021,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -CA-Mer,24537,GRP_LMA,LMA,192 -CA-Mer,24537,GRP_LMA,LMA_SPP,(All) -CA-Mer,24537,GRP_LMA,LMA_COMMENT,"Moore, T.R.et al 2002. Journal of Ecology. 90, 25-36." -CA-Mer,33726,GRP_LOCATION,LOCATION_LAT,45.4094 -CA-Mer,33726,GRP_LOCATION,LOCATION_LONG,-75.5186 -CA-Mer,33726,GRP_LOCATION,LOCATION_ELEV,70 -CA-Mer,25831,GRP_NEP,NEP,57000 -CA-Mer,25831,GRP_NEP,NEP_DATE_START,1999 -CA-Mer,25831,GRP_NEP,NEP_DATE_END,2000 -CA-Mer,25831,GRP_NEP,NEP_COMMENT,"Jan-Dec; measrued followed Fluxnet-Canada protocol, using eddy covariance technique" -CA-Mer,26210,GRP_NEP,NEP,25000 -CA-Mer,26210,GRP_NEP,NEP_DATE_START,2000 -CA-Mer,26210,GRP_NEP,NEP_DATE_END,2001 -CA-Mer,26210,GRP_NEP,NEP_COMMENT,"Jan-Dec; measrued followed Fluxnet-Canada protocol, using eddy covariance technique" -CA-Mer,26339,GRP_NEP,NEP,-8000 -CA-Mer,26339,GRP_NEP,NEP_DATE_START,2001 -CA-Mer,26339,GRP_NEP,NEP_DATE_END,2002 -CA-Mer,26339,GRP_NEP,NEP_COMMENT,"Jan-Dec; measrued followed Fluxnet-Canada protocol, using eddy covariance technique" -CA-Mer,26340,GRP_NEP,NEP,9000 -CA-Mer,26340,GRP_NEP,NEP_DATE_START,2002 -CA-Mer,26340,GRP_NEP,NEP_DATE_END,2003 -CA-Mer,26340,GRP_NEP,NEP_COMMENT,"Jan-Dec; measrued followed Fluxnet-Canada protocol, using eddy covariance technique" -CA-Mer,26341,GRP_NEP,NEP,15000 -CA-Mer,26341,GRP_NEP,NEP_DATE_START,2003 -CA-Mer,26341,GRP_NEP,NEP_DATE_END,2004 -CA-Mer,26341,GRP_NEP,NEP_COMMENT,"Jan-Dec; measrued followed Fluxnet-Canada protocol, using eddy covariance technique" -CA-Mer,26342,GRP_NEP,NEP,113000 -CA-Mer,26342,GRP_NEP,NEP_DATE_START,2004 -CA-Mer,26342,GRP_NEP,NEP_DATE_END,2005 -CA-Mer,26342,GRP_NEP,NEP_COMMENT,"Jan-Dec; measrued followed Fluxnet-Canada protocol, using eddy covariance technique" -CA-Mer,25454,GRP_NEP,NEP,75000 -CA-Mer,25454,GRP_NEP,NEP_DATE_START,2005 -CA-Mer,25454,GRP_NEP,NEP_DATE_END,2006 -CA-Mer,25454,GRP_NEP,NEP_COMMENT,"Jan-Dec; measrued followed Fluxnet-Canada protocol, using eddy covariance technique" -CA-Mer,25945,GRP_NEP,NEP,138000 -CA-Mer,25945,GRP_NEP,NEP_DATE_START,2006 -CA-Mer,25945,GRP_NEP,NEP_DATE_END,2007 -CA-Mer,25945,GRP_NEP,NEP_COMMENT,"Jan-Dec; measrued followed Fluxnet-Canada protocol, using eddy covariance technique" -CA-Mer,25707,GRP_NEP,NEP,80000 -CA-Mer,25707,GRP_NEP,NEP_DATE_START,2007 -CA-Mer,25707,GRP_NEP,NEP_DATE_END,2008 -CA-Mer,25707,GRP_NEP,NEP_COMMENT,"Jan-Dec; measrued followed Fluxnet-Canada protocol, using eddy covariance technique" -CA-Mer,11387,GRP_NETWORK,NETWORK,AmeriFlux -CA-Mer,420,GRP_NETWORK,NETWORK,Fluxnet-Canada -CA-Mer,86942,GRP_NETWORK,NETWORK,Phenocam -CA-Mer,1700007725,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Barr, A., Richardson, A., Hollinger, D., Papale, D., Arain, M., Black, T., Bohrer, G., Dragoni, D., Fischer, M., Gu, L., Law, B., Margolis, H., McCaughey, J., Munger, J., Oechel, W., Schaeffer, K. (2013) Use Of Change-Point Detection For Friction–Velocity Threshold Evaluation In Eddy-Covariance Studies, Agricultural And Forest Meteorology, 171-172(2), 31-45" -CA-Mer,1700007725,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2012.11.023 -CA-Mer,1700007725,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Mer,1700002352,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Berry, S. C., Varney, G. T., Flanagan, L. B. (1997) Leaf δ13C In Pinus Resinosa Trees And Understory Plants: Variation Associated With Light And CO2 Gradients, Oecologia, 109(4), 499-506" -CA-Mer,1700002352,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1007/S004420050110 -CA-Mer,1700002352,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Mer,1700007431,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Dennis Baldocchi, Cove Sturtevant (2015) Does day and night sampling reduce spurious correlation between canopy photosynthesis and ecosystem respiration?, Agricultural and Forest Meteorology, 207(D3), 117-126" -CA-Mer,1700007431,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2015.03.010 -CA-Mer,1700007431,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Mer,1700005682,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Fraser, C., Roulet, N., Lafleur, M. (2001) Groundwater Flow Patterns In A Large Peatland, Journal Of Hydrology, 246(1-4), 142-154" -CA-Mer,1700005682,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/S0022-1694(01)00362-6 -CA-Mer,1700005682,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Mer,1700007071,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Frolking, S. E., Bubier, J. L., Moore, T. R., Ball, T., Bellisario, L. M., Bhardwaj, A., Carroll, P., Crill, P. M., Lafleur, P. M., McCaughey, J. H., Roulet, N. T., Suyker, A. E., Verma, S. B., Waddington, J. M., Whiting, G. J. (1998) Relationship Between Ecosystem Productivity And Photosynthetically Active Radiation For Northern Peatlands, Global Biogeochemical Cycles, 12(1), 115-126" -CA-Mer,1700007071,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/97GB03367 -CA-Mer,1700007071,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Mer,1700000429,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Frolking, S., Roulet, N. T., Moore, T. R., Lafleur, P. M., Bubier, J. L., Crill, P. M. (2002) Modeling Seasonal To Annual Carbon Balance Of Mer Bleue Bog, Ontario, Canada, Global Biogeochemical Cycles, 16(3), 1-21" -CA-Mer,1700000429,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2001GB001457 -CA-Mer,1700000429,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Mer,1700002535,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Ham, J. M., Benson, E. J. (2004) On The Construction And Calibration Of Dual-Probe Heat Capacity Sensors, Soil Science Society Of America Journal, 68(4), 1185-1190" -CA-Mer,1700002535,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.2136/SSSAJ2004.1185 -CA-Mer,1700002535,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Mer,1700001899,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Lafleur, P. M., Roulet, N. T., Admiral, S. W. (2001) Annual Cycle Of CO2 Exchange At A Bog Peatland, Journal Of Geophysical Research: Atmospheres, 106(D3), 3071-3081" -CA-Mer,1700001899,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2000JD900588 -CA-Mer,1700001899,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Mer,1700002478,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Lafleur, P. M., Roulet, N. T., Bubier, J. L., Frolking, S., Moore, T. R. (2003) Interannual Variability In The Peatland-Atmosphere Carbon Dioxide Exchange At An Ombrotrophic Bog, Global Biogeochemical Cycles, 17(2), n/a-n/a" -CA-Mer,1700002478,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2002GB001983 -CA-Mer,1700002478,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Primary_Citation -CA-Mer,1700005343,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Moore, T. R., Bubier, J. L., Frolking, S. E., Lafleur, P. M., Roulet, N. T. (2002) Plant Biomass And Production And CO2 Exchange In An Ombrotrophic Bog, Journal Of Ecology, 90(1), 25-36" -CA-Mer,1700005343,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1046/J.0022-0477.2001.00633.X -CA-Mer,1700005343,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Mer,1700003342,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Qiu, C., Zhu, D., Ciais, P., Guenet, B., Krinner, G., Peng, S., Aurela, M., Bernhofer, C., Brümmer, C., Bret-Harte, S., Chu, H., Chen, J., Desai, A. R., Dušek, J., Euskirchen, E. S., Fortuniak, K., Flanagan, L. B., Friborg, T., Grygoruk, M., Gogo, S., Grünwald, T., Hansen, B. U., Holl, D., Humphreys, E., Hurkuck, M., Kiely, G., Klatt, J., Kutzbach, L., Largeron, C., Laggoun-Défarge, F., Lund, M., Lafleur, P. M., Li, X., Mammarella, I., Merbold, L., Nilsson, M. B., Olejnik, J., Ottosson-Löfvenius, M., Oechel, W., Parmentier, F. W., Peichl, M., Pirk, N., Peltola, O., Pawlak, W., Rasse, D., Rinne, J., Shaver, G., Schmid, H. P., Sottocornola, M., Steinbrecher, R., Sachs, T., Urbaniak, M., Zona, D., Ziemblinska, K. (2018) Orchidee-Peat (Revision 4596), A Model For Northern Peatland Co&Lt;Sub&Gt;2&Lt;/Sub&Gt;, Water, And Energy Fluxes On Daily To Annual Scales, Geoscientific Model Development, 11(2), 497-519" -CA-Mer,1700003342,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.5194/GMD-11-497-2018 -CA-Mer,1700003342,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Mer,1700007947,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Turunen, J., Roulet, N. T., Moore, T. R., Richard, P. J. (2004) Nitrogen Deposition And Increased Carbon Accumulation In Ombrotrophic Peatlands In Eastern Canada, Global Biogeochemical Cycles, 18(3), n/a-n/a" -CA-Mer,1700007947,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2003GB002154 -CA-Mer,1700007947,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Mer,26108,GRP_ROOT_BIOMASS,ROOT_BIOMASS_CRS,1050 -CA-Mer,26108,GRP_ROOT_BIOMASS,ROOT_BIOMASS_FINE,150 -CA-Mer,26108,GRP_ROOT_BIOMASS,ROOT_BIOMASS_TOT,1200 -CA-Mer,26108,GRP_ROOT_BIOMASS,ROOT_BIOMASS_UNIT,gC m-2 -CA-Mer,26108,GRP_ROOT_BIOMASS,ROOT_BIOMASS_DATE,1999 -CA-Mer,26108,GRP_ROOT_BIOMASS,ROOT_BIOMASS_COMMENT,assumed the carbon concentration is 50% -CA-Mer,25709,GRP_ROOT_CHEM,ROOT_C,4.59 -CA-Mer,25709,GRP_ROOT_CHEM,ROOT_N,0.027 -CA-Mer,25709,GRP_ROOT_CHEM,ROOT_SPP,(Unknown) -CA-Mer,25709,GRP_ROOT_CHEM,ROOT_DATE,20030831 -CA-Mer,25709,GRP_ROOT_CHEM,ROOT_COMMENT,"values from litter sample. Carlo Erba NC-2500 elemental analyzer, Moore et al. (2007, Ecosystems 10, 949-963)" -CA-Mer,33724,GRP_SITE_CHAR,TERRAIN,Flat -CA-Mer,7900,GRP_SITE_DESC,SITE_DESC,"The Mer Bleue peatland is primarily a large ombrotrophic bog located in the Ottawa River Valley, 10 km east of Ottawa, Ontario, Canada (45.40º N lat., 75.50º W long.). Mean annual temperature is 6.3ºC ranging from -10.5ºC in January to 21.0ºC in July. Mean annual precipitation is 943 mm, 268 mm of which falls during the summer months (Environment Canada; climate normals). Peat began to form approximately 8500 years ago, but the bog phase began later, about 6400 years ago (Lafleur et al., 2003; Richard, pers. comm.). The peat depth now ranges from 2 m at the edge to >5 m in the middle. Beaver ponds are found at the lagg margin of the bog. The bog is dominated by plant communities comprised primarily of the ericaceous shrubs Chamaedaphne calyculata (L.) Moench, Ledum groenlandicum Oeder, and Kalmia angustifolia L. Clusters of the deciduous shrub Vaccinium myrtilloides Michx. and the tufted sedge Eriophorum vaginatum L. are fairly common across the bog. The most common tree species found in the bog are Larix laricina (Duroi) K. Koch., Betula populifolia Marshall and Picea mariana (Miller) BSP occurring less frequently. In the poor fen, located to the north of the bog proper, community composition is primarily composed of the ericaceous shrubs listed above, including higher densities of K. angustifolia and Andromeda glaucophylla Link. The primary sedge in this area is Carex oligosperma Michx. All sites are dominated by an under story of bryophytes, mainly Sphagnum magellanicum Brid., Sphagnum capillifolium (Ehrh.) Hedw., and Polytrichum strictum Brid. in the bog, with Sphagnum papillosum Lindb., and Sphagnum fallax (Klinggr.) Klinggr. common in the wetter portions of the poor fen" -CA-Mer,27417,GRP_SOIL_CHEM,SOIL_CHEM_C_ORG,185.556 -CA-Mer,29356,GRP_SOIL_CHEM,SOIL_CHEM_C_ORG,185.556 -CA-Mer,29358,GRP_SOIL_CHEM,SOIL_CHEM_C_ORG,188.893 -CA-Mer,29242,GRP_SOIL_CHEM,SOIL_CHEM_C_ORG,196.397 -CA-Mer,28029,GRP_SOIL_CHEM,SOIL_CHEM_C_ORG,199.905 -CA-Mer,28375,GRP_SOIL_CHEM,SOIL_CHEM_C_ORG,199.905 -CA-Mer,29357,GRP_SOIL_CHEM,SOIL_CHEM_C_ORG,226.303 -CA-Mer,27414,GRP_SOIL_CHEM,SOIL_CHEM_C_ORG,24.9862 -CA-Mer,28026,GRP_SOIL_CHEM,SOIL_CHEM_C_ORG,25.7884 -CA-Mer,27757,GRP_SOIL_CHEM,SOIL_CHEM_C_ORG,42.3973 -CA-Mer,28642,GRP_SOIL_CHEM,SOIL_CHEM_C_ORG,42.3973 -CA-Mer,28880,GRP_SOIL_CHEM,SOIL_CHEM_C_ORG,43.1469 -CA-Mer,28709,GRP_SOIL_CHEM,SOIL_CHEM_C_ORG,43.3721 -CA-Mer,28027,GRP_SOIL_CHEM,SOIL_CHEM_C_ORG,43.6188 -CA-Mer,28881,GRP_SOIL_CHEM,SOIL_CHEM_C_ORG,45.2123 -CA-Mer,29568,GRP_SOIL_CHEM,SOIL_CHEM_C_ORG,46.8898 -CA-Mer,28374,GRP_SOIL_CHEM,SOIL_CHEM_C_ORG,51.7217 -CA-Mer,28028,GRP_SOIL_CHEM,SOIL_CHEM_C_ORG,54.4722 -CA-Mer,28030,GRP_SOIL_CHEM,SOIL_CHEM_N_TOT,0.497127 -CA-Mer,27658,GRP_SOIL_CHEM,SOIL_CHEM_N_TOT,0.663454 -CA-Mer,27659,GRP_SOIL_CHEM,SOIL_CHEM_N_TOT,0.94478 -CA-Mer,28710,GRP_SOIL_CHEM,SOIL_CHEM_N_TOT,0.997274 -CA-Mer,28882,GRP_SOIL_CHEM,SOIL_CHEM_N_TOT,1.01213 -CA-Mer,28883,GRP_SOIL_CHEM,SOIL_CHEM_N_TOT,1.1158 -CA-Mer,27758,GRP_SOIL_CHEM,SOIL_CHEM_N_TOT,1.11661 -CA-Mer,29243,GRP_SOIL_CHEM,SOIL_CHEM_N_TOT,1.16394 -CA-Mer,29244,GRP_SOIL_CHEM,SOIL_CHEM_N_TOT,1.1693 -CA-Mer,29359,GRP_SOIL_CHEM,SOIL_CHEM_N_TOT,1.51828 -CA-Mer,27660,GRP_SOIL_CHEM,SOIL_CHEM_N_TOT,10.2808 -CA-Mer,28031,GRP_SOIL_CHEM,SOIL_CHEM_N_TOT,10.2808 -CA-Mer,28376,GRP_SOIL_CHEM,SOIL_CHEM_N_TOT,13.0328 -CA-Mer,28643,GRP_SOIL_CHEM,SOIL_CHEM_N_TOT,13.0328 -CA-Mer,27117,GRP_SOIL_CHEM,SOIL_CHEM_N_TOT,6.00445 -CA-Mer,27418,GRP_SOIL_CHEM,SOIL_CHEM_N_TOT,6.00445 -CA-Mer,28032,GRP_SOIL_CHEM,SOIL_CHEM_N_TOT,6.31121 -CA-Mer,29360,GRP_SOIL_CHEM,SOIL_CHEM_N_TOT,9.94995 -CA-Mer,27414,GRP_SOIL_CHEM,SOIL_CHEM_BD,0.05481 -CA-Mer,28026,GRP_SOIL_CHEM,SOIL_CHEM_BD,0.0583 -CA-Mer,29356,GRP_SOIL_CHEM,SOIL_CHEM_BD,0.0752977777777778 -CA-Mer,29358,GRP_SOIL_CHEM,SOIL_CHEM_BD,0.07765 -CA-Mer,28375,GRP_SOIL_CHEM,SOIL_CHEM_BD,0.0791692307692308 -CA-Mer,28642,GRP_SOIL_CHEM,SOIL_CHEM_BD,0.0794461538461538 -CA-Mer,29242,GRP_SOIL_CHEM,SOIL_CHEM_BD,0.0821923076923077 -CA-Mer,28709,GRP_SOIL_CHEM,SOIL_CHEM_BD,0.08259 -CA-Mer,28880,GRP_SOIL_CHEM,SOIL_CHEM_BD,0.08286 -CA-Mer,27657,GRP_SOIL_CHEM,SOIL_CHEM_BD,0.0829916666666667 -CA-Mer,27417,GRP_SOIL_CHEM,SOIL_CHEM_BD,0.0830166666666667 -CA-Mer,27757,GRP_SOIL_CHEM,SOIL_CHEM_BD,0.08413 -CA-Mer,28881,GRP_SOIL_CHEM,SOIL_CHEM_BD,0.08453 -CA-Mer,28029,GRP_SOIL_CHEM,SOIL_CHEM_BD,0.0867538461538462 -CA-Mer,28027,GRP_SOIL_CHEM,SOIL_CHEM_BD,0.08966 -CA-Mer,29568,GRP_SOIL_CHEM,SOIL_CHEM_BD,0.08994 -CA-Mer,29357,GRP_SOIL_CHEM,SOIL_CHEM_BD,0.0910333333333334 -CA-Mer,28374,GRP_SOIL_CHEM,SOIL_CHEM_BD,0.10004 -CA-Mer,28028,GRP_SOIL_CHEM,SOIL_CHEM_BD,0.10841 -CA-Mer,28373,GRP_SOIL_CHEM,SOIL_CHEM_BD,0.442691666666667 -CA-Mer,27414,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,0 -CA-Mer,28030,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,0 -CA-Mer,27658,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,10 -CA-Mer,28026,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,10 -CA-Mer,27418,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,100 -CA-Mer,29356,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,100 -CA-Mer,28031,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,150 -CA-Mer,28375,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,150 -CA-Mer,28027,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,20 -CA-Mer,29243,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,20 -CA-Mer,28643,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,200 -CA-Mer,29357,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,200 -CA-Mer,28032,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,250 -CA-Mer,29242,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,250 -CA-Mer,28028,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,30 -CA-Mer,29359,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,30 -CA-Mer,29358,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,300 -CA-Mer,29360,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,300 -CA-Mer,27117,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,350 -CA-Mer,28642,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,350 -CA-Mer,28374,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,40 -CA-Mer,29244,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,40 -CA-Mer,27417,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,400 -CA-Mer,27660,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,400 -CA-Mer,28029,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,450 -CA-Mer,28376,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,450 -CA-Mer,27758,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,50 -CA-Mer,29568,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,50 -CA-Mer,27657,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,500 -CA-Mer,28373,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,550 -CA-Mer,28880,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,60 -CA-Mer,28882,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,60 -CA-Mer,28881,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,70 -CA-Mer,28883,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,70 -CA-Mer,28709,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,80 -CA-Mer,28710,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,80 -CA-Mer,27659,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,90 -CA-Mer,27757,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,90 -CA-Mer,27414,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,10 -CA-Mer,28030,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,10 -CA-Mer,27659,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,100 -CA-Mer,27757,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,100 -CA-Mer,27418,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,150 -CA-Mer,29356,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,150 -CA-Mer,27658,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,20 -CA-Mer,28026,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,20 -CA-Mer,28031,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,200 -CA-Mer,28375,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,200 -CA-Mer,28643,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,250 -CA-Mer,29357,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,250 -CA-Mer,28027,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,30 -CA-Mer,29243,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,30 -CA-Mer,28032,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,300 -CA-Mer,29242,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,300 -CA-Mer,29358,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,350 -CA-Mer,29360,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,350 -CA-Mer,28028,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,40 -CA-Mer,29359,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,40 -CA-Mer,27117,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,400 -CA-Mer,28642,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,400 -CA-Mer,27417,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,450 -CA-Mer,27660,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,450 -CA-Mer,28374,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,50 -CA-Mer,29244,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,50 -CA-Mer,28029,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,500 -CA-Mer,28376,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,500 -CA-Mer,27657,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,550 -CA-Mer,27758,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,60 -CA-Mer,29568,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,60 -CA-Mer,28373,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,600 -CA-Mer,28880,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,70 -CA-Mer,28882,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,70 -CA-Mer,28881,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,80 -CA-Mer,28883,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,80 -CA-Mer,28709,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,90 -CA-Mer,28710,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,90 -CA-Mer,28030,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,(0.90700 gN/100g); soil thickeness 0.1 m -CA-Mer,27659,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,(1.12300 gN/100g); soil thickeness 0.1 m -CA-Mer,27658,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,(1.13800 gN/100g); soil thickeness 0.1 m -CA-Mer,29244,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,(1.16883 gN/100g); soil thickeness 0.1 m -CA-Mer,28710,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,(1.20750 gN/100g); soil thickeness 0.1 m -CA-Mer,28882,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,(1.22150 gN/100g); soil thickeness 0.1 m -CA-Mer,27758,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,(1.24150 gN/100g); soil thickeness 0.1 m -CA-Mer,29243,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,(1.29817 gN/100g); soil thickeness 0.1 m -CA-Mer,28883,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,(1.32000 gN/100g); soil thickeness 0.1 m -CA-Mer,29359,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,(1.40050 gN/100g); soil thickeness 0.1 m -CA-Mer,28376,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,(1.52600 gN/100g); soil thickeness 0.5m -CA-Mer,27117,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,(1.53531 gN/100g); soil thickeness 0.5m -CA-Mer,28032,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,(1.53572 gN/100g); soil thickeness 0.5m -CA-Mer,27418,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,(1.59485 gN/100g); soil thickeness 0.5m -CA-Mer,29360,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,(2.56277 gN/100g); soil thickeness 0.5m -CA-Mer,28031,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,(2.59718 gN/100g); soil thickeness 0.5m -CA-Mer,28643,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,(2.86331 gN/100g); soil thickeness 0.5m -CA-Mer,28026,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,(44.234 gC/100g); soil thickness 0.1 m -CA-Mer,27414,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,(45.587 gC/100g); soil thickness 0.1 m -CA-Mer,28642,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,(47.60154 gC/100g); soil thickness 0.5 m -CA-Mer,29242,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,(47.78954 gC/100g); soil thickness 0.5 m -CA-Mer,27417,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,(47.85731 gC/100g); soil thickness 0.5 m -CA-Mer,28029,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,(48.61923 gC/100g); soil thickness 0.5 m -CA-Mer,28027,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,(48.64917 gC/100g); soil thickness 0.1 m -CA-Mer,29358,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,(48.6523076923077 gC/100g); soil thickness 0.5 m -CA-Mer,29356,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,(49.28604 gC/100g); soil thickness 0.5 m -CA-Mer,29357,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,(49.71872 gC/100g); soil thickness 0.5 m -CA-Mer,27660,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,(5.65731 gN/100g); soil thickeness 0.5m -CA-Mer,28028,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,(50.2465 gC/100g); soil thickness 0.1 m -CA-Mer,27757,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,(50.395 gC/100g); soil thickness 0.1 m -CA-Mer,28375,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,(50.50065 gC/100g); soil thickness 0.5 m -CA-Mer,28374,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,(51.701 gC/100g); soil thickness 0.1 m -CA-Mer,28880,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,(52.072 gC/100g); soil thickness 0.1 m -CA-Mer,29568,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,(52.1345 gC/100g); soil thickness 0.1 m -CA-Mer,28709,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,(52.515 gC/100g); soil thickness 0.1 m -CA-Mer,28881,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,(53.48667 gC/100g); soil thickness 0.1 m -CA-Mer,27657,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,soil thickness 0.5 m -CA-Mer,28373,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,soil thickness 0.5 m -CA-Mer,24663,GRP_SOIL_DEPTH,SOIL_DEPTH,550 -CA-Mer,24663,GRP_SOIL_DEPTH,SOIL_DEPTH_COMMENT,"(range 5-6) Moore, T.R.et al 2002. Journal of Ecology. 90, 25-36." -CA-Mer,25704,GRP_SPP_O,SPP_O,CHCA2 (NRCS plant code) -CA-Mer,26592,GRP_SPP_O,SPP_O,KAAN (NRCS plant code) -CA-Mer,25705,GRP_SPP_O,SPP_O,LEGL (NRCS plant code) -CA-Mer,25704,GRP_SPP_O,SPP_DATE,2003 -CA-Mer,25705,GRP_SPP_O,SPP_DATE,2003 -CA-Mer,26592,GRP_SPP_O,SPP_DATE,2003 -CA-Mer,25704,GRP_SPP_O,SPP_COMMENT,"Moore et al. (2002, Ecology 90, 25-36) (2007, Ecosystems 10,949-963)" -CA-Mer,25705,GRP_SPP_O,SPP_COMMENT,"Moore et al. (2002, Ecology 90, 25-36) (2007, Ecosystems 10,949-963)" -CA-Mer,26592,GRP_SPP_O,SPP_COMMENT,"Moore et al. (2002, Ecology 90, 25-36) (2007, Ecosystems 10,949-963)" -CA-Mer,26337,GRP_SPP_U,SPP_U,SPCA70 (NRCS plant code) -CA-Mer,26593,GRP_SPP_U,SPP_U,SPFU70 (NRCS plant code) -CA-Mer,26337,GRP_SPP_U,SPP_DATE,2003 -CA-Mer,26593,GRP_SPP_U,SPP_DATE,2003 -CA-Mer,26337,GRP_SPP_U,SPP_COMMENT,"Moore et al. (2002, Ecology 90, 25-36) (2007, Ecosystems 10,949-963)" -CA-Mer,26593,GRP_SPP_U,SPP_COMMENT,"Moore et al. (2002, Ecology 90, 25-36) (2007, Ecosystems 10,949-963)" -CA-Mer,33723,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Elyn Humphreys -CA-Mer,33723,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -CA-Mer,33723,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,elyn.humphreys@carleton.ca -CA-Mer,33723,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Carleton University -CA-Mer,33723,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Department of Geography & Environmental Studies, 1125 Colonel By Dr., Ottawa, ON K1S 5B6" -CA-Mer,656,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Peter Lafleur -CA-Mer,656,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -CA-Mer,656,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,plafleur@trentu.ca -CA-Mer,656,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION, -CA-Mer,33725,GRP_TOWER_POWER,TOWER_POWER,Direct power -CA-Mer,33720,GRP_TOWER_TYPE,TOWER_TYPE,triangle -CA-Mer,6885,GRP_URL,URL,http://www.trentu.ca/academic/bluelab/research_merbleue.html -CA-Mer,24000059,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/CA-Mer -CA-Mer,8728,GRP_UTC_OFFSET,UTC_OFFSET,-5 -CA-Na1,13,GRP_CLIM_AVG,MAT,7.09 -CA-Na1,13,GRP_CLIM_AVG,MAP,1102.7 -CA-Na1,13,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfb -CA-Na1,27000060,GRP_COUNTRY,COUNTRY,Canada -CA-Na1,81562,GRP_DOI,DOI,10.17190/AMF/1436319 -CA-Na1,81562,GRP_DOI,DOI_CITATION,"Charles P.-A. Bourque (2018), AmeriFlux BASE CA-Na1 New Brunswick - 1967 Balsam Fir - Nashwaak Lake Site 01 (Mature balsam fir forest), Ver. 1-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1436319" -CA-Na1,81562,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -CA-Na1,81530,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -CA-Na1,81530,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Charles P.-A. Bourque -CA-Na1,81530,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -CA-Na1,81530,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,cbourque@unb.ca -CA-Na1,9755,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -CA-Na1,9755,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -CA-Na1,9755,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,2003 -CA-Na1,9755,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -CA-Na1,23000060,GRP_HEADER,SITE_NAME,New Brunswick - 1967 Balsam Fir - Nashwaak Lake Site 01 (Mature balsam fir forest) -CA-Na1,5157,GRP_IGBP,IGBP,ENF -CA-Na1,23891,GRP_LAI,LAI_TYPE,LAI -CA-Na1,23891,GRP_LAI,LAI_COMMENT,"source: -Chen_et_al AFM_2006 -" -CA-Na1,23891,GRP_LAI,LAI_TOT,8.4 -CA-Na1,2602,GRP_LOCATION,LOCATION_LAT,46.4722 -CA-Na1,2602,GRP_LOCATION,LOCATION_LONG,-67.1000 -CA-Na1,2602,GRP_LOCATION,LOCATION_ELEV,341 -CA-Na1,2602,GRP_LOCATION,LOCATION_COMMENT," -Xing_et_al_TreePhysiol_2005" -CA-Na1,11388,GRP_NETWORK,NETWORK,AmeriFlux -CA-Na1,7186,GRP_NETWORK,NETWORK,Fluxnet-Canada -CA-Na1,1700003414,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chen, J. M., Govind, A., Sonnentag, O., Zhang, Y., Barr, A., Amiro, B. (2006) Leaf Area Index Measurements At Fluxnet-Canada Forest Sites, Agricultural And Forest Meteorology, 140(1-4), 257-268" -CA-Na1,1700003414,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2006.08.005 -CA-Na1,1700003414,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Na1,1700004995,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(9), 108350" -CA-Na1,1700004995,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -CA-Na1,1700004995,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Na1,1700008667,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Xing, Z., Bourque, C. P., Swift, D. E., Clowater, C. W., Krasowski, M., Meng, F. (2005) Carbon And Biomass Partitioning In Balsam Fir (Abies Balsamea), Tree Physiology, 25(9), 1207-1217" -CA-Na1,1700008667,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1093/TREEPHYS/25.9.1207 -CA-Na1,1700008667,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Na1,24813,GRP_SA,SA,35 -CA-Na1,24813,GRP_SA,SA_COMMENT,(range 32-37) 32_37 -CA-Na1,25077,GRP_SA,SA_MAX,37 -CA-Na1,5101,GRP_SITE_DESC,SITE_DESC,immature balsam fir forest -CA-Na1,24667,GRP_SOIL_DEPTH,SOIL_DEPTH,6.5 -CA-Na1,24667,GRP_SOIL_DEPTH,SOIL_DEPTH_COMMENT,"(range 0.06-0.07) -Xing_et_al_TreePhysiol_2005" -CA-Na1,24947,GRP_SPP_O,SPP_O,Balsam Fir (Abies balsamea) -CA-Na1,24947,GRP_SPP_O,SPP_COMMENT,is comprised of predominantly balsam fir of 32-37 years old; basal area is 26 m2/ha -CA-Na1,8307,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Charles P.-A. Bourque -CA-Na1,8307,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -CA-Na1,8307,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,cbourque@unb.ca -CA-Na1,8307,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION, -CA-Na1,6886,GRP_URL,URL,http://www.fluxnet-canada.ca/ -CA-Na1,24000060,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/CA-Na1 -CA-Na1,33538,GRP_UTC_OFFSET,UTC_OFFSET,-4 -CA-Na1,33538,GRP_UTC_OFFSET,UTC_OFFSET_COMMENT,Added by AMF data processing team for data QAQC checks. -CA-Oas,29563,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER,330 -CA-Oas,29563,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_ORGAN,Total -CA-Oas,29563,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_PHEN,Mixed/unknown -CA-Oas,29563,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_UNIT,kgDM m-2 -CA-Oas,29563,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_COMMENT,Above-ground understory total biomass ; Data from Alison Deanne Theede (2007) -CA-Oas,25698,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER,70 -CA-Oas,25698,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_ORGAN,Total -CA-Oas,25698,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_PHEN,Mixed/unknown -CA-Oas,25698,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_UNIT,kgDM m-2 -CA-Oas,25698,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_COMMENT,Above-ground understory total biomass ; Data from Alison Deanne Theede (2007) -CA-Oas,25451,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB,330 -CA-Oas,25451,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_ORGAN,Total -CA-Oas,25451,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_PHEN,Mixed/unknown -CA-Oas,25451,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_UNIT,gC m-2 -CA-Oas,25451,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_DATE,2004 -CA-Oas,25451,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_COMMENT,Data from Alison Deanne Theede (2007) -CA-Oas,25591,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB,70 -CA-Oas,25591,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_ORGAN,Total -CA-Oas,25591,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_PHEN,Mixed/unknown -CA-Oas,25591,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_UNIT,gC m-2 -CA-Oas,25591,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_DATE,1994 -CA-Oas,25591,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_COMMENT,Data from Alison Deanne Theede (2007) -CA-Oas,27105,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,140 -CA-Oas,27105,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_SPATIAL_VARIABILITY,17 -CA-Oas,27105,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Foliage -CA-Oas,27105,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -CA-Oas,27105,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -CA-Oas,27105,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2004 -CA-Oas,27105,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,Data from Alison Deanne Theede (2007) -CA-Oas,29348,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,160 -CA-Oas,29348,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_SPATIAL_VARIABILITY,22 -CA-Oas,29348,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Foliage -CA-Oas,29348,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -CA-Oas,29348,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -CA-Oas,29348,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,1994 -CA-Oas,29348,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,Data from Alison Deanne Theede (2007) -CA-Oas,29236,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,7410 -CA-Oas,29236,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_SPATIAL_VARIABILITY,16 -CA-Oas,29236,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Wood -CA-Oas,29236,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -CA-Oas,29236,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -CA-Oas,29236,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2004 -CA-Oas,29236,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,Data from Alison Deanne Theede (2007) -CA-Oas,27409,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,7540 -CA-Oas,27409,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_SPATIAL_VARIABILITY,18 -CA-Oas,27409,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Wood -CA-Oas,27409,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -CA-Oas,27409,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -CA-Oas,27409,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,1994 -CA-Oas,27409,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,Data from Alison Deanne Theede (2007) -CA-Oas,28018,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,7550 -CA-Oas,28018,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_SPATIAL_VARIABILITY,17 -CA-Oas,28018,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Total -CA-Oas,28018,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -CA-Oas,28018,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -CA-Oas,28018,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2004 -CA-Oas,28018,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,Data from Alison Deanne Theede (2007) -CA-Oas,28635,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,7700 -CA-Oas,28635,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_SPATIAL_VARIABILITY,18 -CA-Oas,28635,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Total -CA-Oas,28635,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -CA-Oas,28635,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -CA-Oas,28635,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,1994 -CA-Oas,28635,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,Data from Alison Deanne Theede (2007) -CA-Oas,25587,GRP_AG_PROD_SHRUB,AG_PROD_SHRUB,53 -CA-Oas,25587,GRP_AG_PROD_SHRUB,AG_PROD_SHRUB_ORGAN,Total -CA-Oas,25587,GRP_AG_PROD_SHRUB,AG_PROD_SHRUB_UNIT,gC m-2 -CA-Oas,25587,GRP_AG_PROD_SHRUB,AG_PROD_COMMENT,Data from Alison Deanne Theede (2007) -CA-Oas,25452,GRP_AG_PROD_TREE,AG_PROD_TREE,185 -CA-Oas,25452,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Wood -CA-Oas,25452,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -CA-Oas,25452,GRP_AG_PROD_TREE,AG_PROD_COMMENT,Data from Alison Deanne Theede (2007) -CA-Oas,26335,GRP_AG_PROD_TREE,AG_PROD_TREE,185 -CA-Oas,26335,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Total -CA-Oas,26335,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -CA-Oas,26335,GRP_AG_PROD_TREE,AG_PROD_COMMENT,Data from Alison Deanne Theede (2007) -CA-Oas,25942,GRP_BIOMASS_CHEM,BIOMASS_C,4.61 -CA-Oas,26207,GRP_BIOMASS_CHEM,BIOMASS_C,4.62 -CA-Oas,26456,GRP_BIOMASS_CHEM,BIOMASS_C,4.89 -CA-Oas,25701,GRP_BIOMASS_CHEM,BIOMASS_C,4.97 -CA-Oas,25327,GRP_BIOMASS_CHEM,BIOMASS_C,5.15 -CA-Oas,25828,GRP_BIOMASS_CHEM,BIOMASS_C,5.74 -CA-Oas,25828,GRP_BIOMASS_CHEM,BIOMASS_N,0.179 -CA-Oas,26456,GRP_BIOMASS_CHEM,BIOMASS_N,0.182 -CA-Oas,25700,GRP_BIOMASS_CHEM,BIOMASS_N,0.228 -CA-Oas,25942,GRP_BIOMASS_CHEM,BIOMASS_N,0.247 -CA-Oas,25701,GRP_BIOMASS_CHEM,BIOMASS_N,0.251 -CA-Oas,26207,GRP_BIOMASS_CHEM,BIOMASS_N,0.302 -CA-Oas,25327,GRP_BIOMASS_CHEM,BIOMASS_N,0.322 -CA-Oas,25327,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -CA-Oas,25700,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -CA-Oas,25701,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -CA-Oas,25828,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -CA-Oas,25942,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -CA-Oas,26207,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -CA-Oas,26456,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -CA-Oas,25327,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -CA-Oas,25700,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -CA-Oas,25701,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -CA-Oas,25828,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -CA-Oas,25942,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -CA-Oas,26207,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -CA-Oas,26456,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -CA-Oas,25942,GRP_BIOMASS_CHEM,BIOMASS_SPP,COCO6 (NRCS plant code) -CA-Oas,26207,GRP_BIOMASS_CHEM,BIOMASS_SPP,COCO6 (NRCS plant code) -CA-Oas,26456,GRP_BIOMASS_CHEM,BIOMASS_SPP,COCO6 (NRCS plant code) -CA-Oas,25327,GRP_BIOMASS_CHEM,BIOMASS_SPP,POTR5 (NRCS plant code) -CA-Oas,25700,GRP_BIOMASS_CHEM,BIOMASS_SPP,POTR5 (NRCS plant code) -CA-Oas,25701,GRP_BIOMASS_CHEM,BIOMASS_SPP,POTR5 (NRCS plant code) -CA-Oas,25828,GRP_BIOMASS_CHEM,BIOMASS_SPP,POTR5 (NRCS plant code) -CA-Oas,25327,GRP_BIOMASS_CHEM,BIOMASS_DATE,19940611 -CA-Oas,26207,GRP_BIOMASS_CHEM,BIOMASS_DATE,19940611 -CA-Oas,25701,GRP_BIOMASS_CHEM,BIOMASS_DATE,19940803 -CA-Oas,25942,GRP_BIOMASS_CHEM,BIOMASS_DATE,19940803 -CA-Oas,25828,GRP_BIOMASS_CHEM,BIOMASS_DATE,19940902 -CA-Oas,26456,GRP_BIOMASS_CHEM,BIOMASS_DATE,19940902 -CA-Oas,25700,GRP_BIOMASS_CHEM,BIOMASS_DATE,20060816 -CA-Oas,25327,GRP_BIOMASS_CHEM,BIOMASS_COMMENT,"data from Middleton et al. 1997 (J Geophy Res 102, 28831-28844)" -CA-Oas,25701,GRP_BIOMASS_CHEM,BIOMASS_COMMENT,"data from Middleton et al. 1997 (J Geophy Res 102, 28831-28844)" -CA-Oas,25828,GRP_BIOMASS_CHEM,BIOMASS_COMMENT,"data from Middleton et al. 1997 (J Geophy Res 102, 28831-28844)" -CA-Oas,25942,GRP_BIOMASS_CHEM,BIOMASS_COMMENT,"data from Middleton et al. 1997 (J Geophy Res 102, 28831-28844)" -CA-Oas,26207,GRP_BIOMASS_CHEM,BIOMASS_COMMENT,"data from Middleton et al. 1997 (J Geophy Res 102, 28831-28844)" -CA-Oas,26456,GRP_BIOMASS_CHEM,BIOMASS_COMMENT,"data from Middleton et al. 1997 (J Geophy Res 102, 28831-28844)" -CA-Oas,25700,GRP_BIOMASS_CHEM,BIOMASS_COMMENT,Varian SpectrAA 220 Atomic Absorbtion -CA-Oas,5959,GRP_CLIM_AVG,MAT,0.34 -CA-Oas,5959,GRP_CLIM_AVG,MAP,428.53 -CA-Oas,5959,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfc -CA-Oas,27000070,GRP_COUNTRY,COUNTRY,Canada -CA-Oas,2791,GRP_DM_FIRE,DM_FIRE,Nature induced burn -CA-Oas,2791,GRP_DM_FIRE,DM_DATE,1919 -CA-Oas,2791,GRP_DM_FIRE,DM_COMMENT,natural regeneration -CA-Oas,33540,GRP_DOI,DOI,10.17190/AMF/1375197 -CA-Oas,33540,GRP_DOI,DOI_CITATION,"T. Andrew Black (2016), AmeriFlux BASE CA-Oas Saskatchewan - Western Boreal, Mature Aspen, Ver. 1-1, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1375197" -CA-Oas,33540,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -CA-Oas,31872,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -CA-Oas,31872,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,T. Andrew Black -CA-Oas,31872,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -CA-Oas,31872,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,andrew.black@ubc.ca -CA-Oas,31872,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,The University of British Columbia -CA-Oas,31873,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,The University of British Columbia -CA-Oas,31873,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -CA-Oas,29682,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Drought -CA-Oas,29683,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Pests and disease -CA-Oas,2098,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -CA-Oas,2098,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -CA-Oas,2098,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,1997 -CA-Oas,2098,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -CA-Oas,23000070,GRP_HEADER,SITE_NAME,"Saskatchewan - Western Boreal, Mature Aspen" -CA-Oas,88192,GRP_HEIGHTC,HEIGHTC,21 -CA-Oas,88192,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -CA-Oas,88192,GRP_HEIGHTC,HEIGHTC_DATE,1996 -CA-Oas,7020,GRP_IGBP,IGBP,DBF -CA-Oas,7020,GRP_IGBP,IGBP_COMMENT,"mature even-aged aspen with a few balsam poplar, thick hazel understory" -CA-Oas,27111,GRP_LAI,LAI_TYPE,LAI -CA-Oas,27112,GRP_LAI,LAI_TYPE,LAI -CA-Oas,27113,GRP_LAI,LAI_TYPE,LAI -CA-Oas,27114,GRP_LAI,LAI_TYPE,LAI -CA-Oas,27115,GRP_LAI,LAI_TYPE,LAI -CA-Oas,27412,GRP_LAI,LAI_TYPE,LAI -CA-Oas,27413,GRP_LAI,LAI_TYPE,LAI -CA-Oas,27653,GRP_LAI,LAI_TYPE,LAI -CA-Oas,27654,GRP_LAI,LAI_TYPE,LAI -CA-Oas,27655,GRP_LAI,LAI_TYPE,LAI -CA-Oas,27753,GRP_LAI,LAI_TYPE,LAI -CA-Oas,27754,GRP_LAI,LAI_TYPE,LAI -CA-Oas,27755,GRP_LAI,LAI_TYPE,LAI -CA-Oas,27756,GRP_LAI,LAI_TYPE,LAI -CA-Oas,28021,GRP_LAI,LAI_TYPE,LAI -CA-Oas,28022,GRP_LAI,LAI_TYPE,LAI -CA-Oas,28023,GRP_LAI,LAI_TYPE,LAI -CA-Oas,28371,GRP_LAI,LAI_TYPE,LAI -CA-Oas,28639,GRP_LAI,LAI_TYPE,LAI -CA-Oas,28640,GRP_LAI,LAI_TYPE,LAI -CA-Oas,28641,GRP_LAI,LAI_TYPE,LAI -CA-Oas,28705,GRP_LAI,LAI_TYPE,LAI -CA-Oas,28706,GRP_LAI,LAI_TYPE,LAI -CA-Oas,29237,GRP_LAI,LAI_TYPE,LAI -CA-Oas,29238,GRP_LAI,LAI_TYPE,LAI -CA-Oas,29351,GRP_LAI,LAI_TYPE,LAI -CA-Oas,29352,GRP_LAI,LAI_TYPE,LAI -CA-Oas,29353,GRP_LAI,LAI_TYPE,LAI -CA-Oas,29564,GRP_LAI,LAI_TYPE,LAI -CA-Oas,29565,GRP_LAI,LAI_TYPE,LAI -CA-Oas,29566,GRP_LAI,LAI_TYPE,LAI -CA-Oas,27111,GRP_LAI,LAI_CLUMP,0.98 -CA-Oas,27112,GRP_LAI,LAI_CLUMP,0.98 -CA-Oas,27113,GRP_LAI,LAI_CLUMP,0.98 -CA-Oas,27114,GRP_LAI,LAI_CLUMP,0.98 -CA-Oas,27115,GRP_LAI,LAI_CLUMP,0.98 -CA-Oas,27412,GRP_LAI,LAI_CLUMP,0.98 -CA-Oas,27413,GRP_LAI,LAI_CLUMP,0.98 -CA-Oas,27653,GRP_LAI,LAI_CLUMP,0.98 -CA-Oas,27654,GRP_LAI,LAI_CLUMP,0.98 -CA-Oas,27655,GRP_LAI,LAI_CLUMP,0.98 -CA-Oas,27753,GRP_LAI,LAI_CLUMP,0.98 -CA-Oas,27754,GRP_LAI,LAI_CLUMP,0.98 -CA-Oas,27755,GRP_LAI,LAI_CLUMP,0.98 -CA-Oas,27756,GRP_LAI,LAI_CLUMP,0.98 -CA-Oas,28021,GRP_LAI,LAI_CLUMP,0.98 -CA-Oas,28022,GRP_LAI,LAI_CLUMP,0.98 -CA-Oas,28023,GRP_LAI,LAI_CLUMP,0.98 -CA-Oas,28371,GRP_LAI,LAI_CLUMP,0.98 -CA-Oas,28639,GRP_LAI,LAI_CLUMP,0.98 -CA-Oas,28640,GRP_LAI,LAI_CLUMP,0.98 -CA-Oas,28641,GRP_LAI,LAI_CLUMP,0.98 -CA-Oas,28705,GRP_LAI,LAI_CLUMP,0.98 -CA-Oas,28706,GRP_LAI,LAI_CLUMP,0.98 -CA-Oas,29237,GRP_LAI,LAI_CLUMP,0.98 -CA-Oas,29238,GRP_LAI,LAI_CLUMP,0.98 -CA-Oas,29351,GRP_LAI,LAI_CLUMP,0.98 -CA-Oas,29352,GRP_LAI,LAI_CLUMP,0.98 -CA-Oas,29353,GRP_LAI,LAI_CLUMP,0.98 -CA-Oas,29564,GRP_LAI,LAI_CLUMP,0.98 -CA-Oas,29565,GRP_LAI,LAI_CLUMP,0.98 -CA-Oas,29566,GRP_LAI,LAI_CLUMP,0.98 -CA-Oas,27111,GRP_LAI,LAI_METHOD,Other -CA-Oas,27112,GRP_LAI,LAI_METHOD,Other -CA-Oas,27113,GRP_LAI,LAI_METHOD,Other -CA-Oas,27114,GRP_LAI,LAI_METHOD,Other -CA-Oas,27115,GRP_LAI,LAI_METHOD,Other -CA-Oas,27412,GRP_LAI,LAI_METHOD,Other -CA-Oas,27413,GRP_LAI,LAI_METHOD,Other -CA-Oas,27653,GRP_LAI,LAI_METHOD,Other -CA-Oas,27654,GRP_LAI,LAI_METHOD,Other -CA-Oas,27655,GRP_LAI,LAI_METHOD,Other -CA-Oas,27753,GRP_LAI,LAI_METHOD,Other -CA-Oas,27754,GRP_LAI,LAI_METHOD,Other -CA-Oas,27755,GRP_LAI,LAI_METHOD,Other -CA-Oas,27756,GRP_LAI,LAI_METHOD,Other -CA-Oas,28021,GRP_LAI,LAI_METHOD,Other -CA-Oas,28022,GRP_LAI,LAI_METHOD,Other -CA-Oas,28023,GRP_LAI,LAI_METHOD,Other -CA-Oas,28371,GRP_LAI,LAI_METHOD,Other -CA-Oas,28639,GRP_LAI,LAI_METHOD,Other -CA-Oas,28640,GRP_LAI,LAI_METHOD,Other -CA-Oas,28641,GRP_LAI,LAI_METHOD,Other -CA-Oas,28705,GRP_LAI,LAI_METHOD,Other -CA-Oas,28706,GRP_LAI,LAI_METHOD,Other -CA-Oas,29237,GRP_LAI,LAI_METHOD,Other -CA-Oas,29238,GRP_LAI,LAI_METHOD,Other -CA-Oas,29351,GRP_LAI,LAI_METHOD,Other -CA-Oas,29352,GRP_LAI,LAI_METHOD,Other -CA-Oas,29353,GRP_LAI,LAI_METHOD,Other -CA-Oas,29564,GRP_LAI,LAI_METHOD,Other -CA-Oas,29565,GRP_LAI,LAI_METHOD,Other -CA-Oas,29566,GRP_LAI,LAI_METHOD,Other -CA-Oas,28705,GRP_LAI,LAI_DATE,19970515 -CA-Oas,28706,GRP_LAI,LAI_DATE,19970529 -CA-Oas,27111,GRP_LAI,LAI_DATE,19970606 -CA-Oas,27653,GRP_LAI,LAI_DATE,19970612 -CA-Oas,29237,GRP_LAI,LAI_DATE,19970619 -CA-Oas,29351,GRP_LAI,LAI_DATE,19970717 -CA-Oas,28021,GRP_LAI,LAI_DATE,19970812 -CA-Oas,28639,GRP_LAI,LAI_DATE,19970821 -CA-Oas,27412,GRP_LAI,LAI_DATE,19970904 -CA-Oas,28022,GRP_LAI,LAI_DATE,19970906 -CA-Oas,29352,GRP_LAI,LAI_DATE,19970925 -CA-Oas,27112,GRP_LAI,LAI_DATE,19980611 -CA-Oas,29353,GRP_LAI,LAI_DATE,19980618 -CA-Oas,28371,GRP_LAI,LAI_DATE,19980819 -CA-Oas,27654,GRP_LAI,LAI_DATE,19980820 -CA-Oas,27753,GRP_LAI,LAI_DATE,19981008 -CA-Oas,27754,GRP_LAI,LAI_DATE,19990507 -CA-Oas,27755,GRP_LAI,LAI_DATE,19990527 -CA-Oas,27756,GRP_LAI,LAI_DATE,19990730 -CA-Oas,29564,GRP_LAI,LAI_DATE,20000809 -CA-Oas,27113,GRP_LAI,LAI_DATE,20010831 -CA-Oas,29565,GRP_LAI,LAI_DATE,20020515 -CA-Oas,27114,GRP_LAI,LAI_DATE,20020604 -CA-Oas,27413,GRP_LAI,LAI_DATE,20020618 -CA-Oas,28640,GRP_LAI,LAI_DATE,20020704 -CA-Oas,28023,GRP_LAI,LAI_DATE,20020828 -CA-Oas,28641,GRP_LAI,LAI_DATE,20030509 -CA-Oas,27115,GRP_LAI,LAI_DATE,20040803 -CA-Oas,29566,GRP_LAI,LAI_DATE,20040804 -CA-Oas,29238,GRP_LAI,LAI_DATE,20040909 -CA-Oas,27655,GRP_LAI,LAI_DATE,20050726 -CA-Oas,27115,GRP_LAI,LAI_COMMENT,"LAI 2000 + TRAC, POTR5, n=1" -CA-Oas,27753,GRP_LAI,LAI_COMMENT,"LAI 2000 + TRAC, POTR5, n=1" -CA-Oas,28021,GRP_LAI,LAI_COMMENT,"LAI 2000 + TRAC, POTR5, n=1" -CA-Oas,28641,GRP_LAI,LAI_COMMENT,"LAI 2000 + TRAC, POTR5, n=1" -CA-Oas,28705,GRP_LAI,LAI_COMMENT,"LAI 2000 + TRAC, POTR5, n=1" -CA-Oas,28706,GRP_LAI,LAI_COMMENT,"LAI 2000 + TRAC, POTR5, n=1" -CA-Oas,27114,GRP_LAI,LAI_COMMENT,"LAI 2000 + TRAC, POTR5, n=2" -CA-Oas,27413,GRP_LAI,LAI_COMMENT,"LAI 2000 + TRAC, POTR5, n=2" -CA-Oas,28023,GRP_LAI,LAI_COMMENT,"LAI 2000 + TRAC, POTR5, n=2" -CA-Oas,28640,GRP_LAI,LAI_COMMENT,"LAI 2000 + TRAC, POTR5, n=2" -CA-Oas,29565,GRP_LAI,LAI_COMMENT,"LAI 2000 + TRAC, POTR5, n=2" -CA-Oas,29566,GRP_LAI,LAI_COMMENT,"LAI 2000 + TRAC, POTR5, n=2" -CA-Oas,27111,GRP_LAI,LAI_COMMENT,"LAI 2000 + TRAC, POTR5, n=3" -CA-Oas,27113,GRP_LAI,LAI_COMMENT,"LAI 2000 + TRAC, POTR5, n=3" -CA-Oas,27654,GRP_LAI,LAI_COMMENT,"LAI 2000 + TRAC, POTR5, n=3" -CA-Oas,29352,GRP_LAI,LAI_COMMENT,"LAI 2000 + TRAC, POTR5, n=3" -CA-Oas,29353,GRP_LAI,LAI_COMMENT,"LAI 2000 + TRAC, POTR5, n=3" -CA-Oas,27653,GRP_LAI,LAI_COMMENT,"LAI 2000 + TRAC, POTR5, n=4" -CA-Oas,28022,GRP_LAI,LAI_COMMENT,"LAI 2000 + TRAC, POTR5, n=4" -CA-Oas,28639,GRP_LAI,LAI_COMMENT,"LAI 2000 + TRAC, POTR5, n=4" -CA-Oas,29237,GRP_LAI,LAI_COMMENT,"LAI 2000 + TRAC, POTR5, n=4" -CA-Oas,27754,GRP_LAI,LAI_COMMENT,"LAI 2000 + TRAC, POTR5, n=5" -CA-Oas,28371,GRP_LAI,LAI_COMMENT,"LAI 2000 + TRAC, POTR5, n=5" -CA-Oas,27112,GRP_LAI,LAI_COMMENT,"LAI 2000 + TRAC, POTR5, n=6" -CA-Oas,27655,GRP_LAI,LAI_COMMENT,"LAI 2000 + TRAC, POTR5, n=6" -CA-Oas,27756,GRP_LAI,LAI_COMMENT,"LAI 2000 + TRAC, POTR5, n=6" -CA-Oas,29238,GRP_LAI,LAI_COMMENT,"LAI 2000 + TRAC, POTR5, n=6" -CA-Oas,29351,GRP_LAI,LAI_COMMENT,"LAI 2000 + TRAC, POTR5, n=6" -CA-Oas,27412,GRP_LAI,LAI_COMMENT,"LAI 2000 + TRAC, POTR5, n=7" -CA-Oas,27755,GRP_LAI,LAI_COMMENT,"LAI 2000 + TRAC, POTR5, n=7" -CA-Oas,29564,GRP_LAI,LAI_COMMENT,"LAI 2000 + TRAC, POTR5, n=7" -CA-Oas,29565,GRP_LAI,LAI_TOT,0.03 -CA-Oas,28641,GRP_LAI,LAI_TOT,0.05 -CA-Oas,27753,GRP_LAI,LAI_TOT,0.09 -CA-Oas,27114,GRP_LAI,LAI_TOT,0.23 -CA-Oas,28705,GRP_LAI,LAI_TOT,0.61 -CA-Oas,27754,GRP_LAI,LAI_TOT,0.87 -CA-Oas,29353,GRP_LAI,LAI_TOT,1.57 -CA-Oas,28371,GRP_LAI,LAI_TOT,1.63 -CA-Oas,27755,GRP_LAI,LAI_TOT,1.71 -CA-Oas,28706,GRP_LAI,LAI_TOT,1.72 -CA-Oas,28640,GRP_LAI,LAI_TOT,1.79 -CA-Oas,29352,GRP_LAI,LAI_TOT,1.82 -CA-Oas,29238,GRP_LAI,LAI_TOT,1.91 -CA-Oas,28021,GRP_LAI,LAI_TOT,1.93 -CA-Oas,28022,GRP_LAI,LAI_TOT,1.97 -CA-Oas,27413,GRP_LAI,LAI_TOT,2.02 -CA-Oas,29566,GRP_LAI,LAI_TOT,2.04 -CA-Oas,27112,GRP_LAI,LAI_TOT,2.13 -CA-Oas,27653,GRP_LAI,LAI_TOT,2.15 -CA-Oas,29237,GRP_LAI,LAI_TOT,2.19 -CA-Oas,27111,GRP_LAI,LAI_TOT,2.22 -CA-Oas,28639,GRP_LAI,LAI_TOT,2.23 -CA-Oas,28023,GRP_LAI,LAI_TOT,2.34 -CA-Oas,29351,GRP_LAI,LAI_TOT,2.34 -CA-Oas,27655,GRP_LAI,LAI_TOT,2.43 -CA-Oas,27412,GRP_LAI,LAI_TOT,2.47 -CA-Oas,27115,GRP_LAI,LAI_TOT,2.52 -CA-Oas,27654,GRP_LAI,LAI_TOT,2.55 -CA-Oas,29564,GRP_LAI,LAI_TOT,2.66 -CA-Oas,27756,GRP_LAI,LAI_TOT,2.72 -CA-Oas,27113,GRP_LAI,LAI_TOT,3.04 -CA-Oas,27111,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.01 -CA-Oas,27113,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.01 -CA-Oas,27754,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.01 -CA-Oas,29565,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.01 -CA-Oas,27114,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.02 -CA-Oas,28023,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.02 -CA-Oas,27413,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.04 -CA-Oas,27756,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.05 -CA-Oas,27755,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.07 -CA-Oas,28640,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.07 -CA-Oas,29238,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.08 -CA-Oas,28371,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.09 -CA-Oas,29353,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.09 -CA-Oas,28022,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.11 -CA-Oas,29566,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.13 -CA-Oas,27654,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.25 -CA-Oas,27412,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.26 -CA-Oas,29351,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.31 -CA-Oas,27655,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.32 -CA-Oas,28639,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.45 -CA-Oas,29564,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.45 -CA-Oas,27112,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.54 -CA-Oas,27653,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.59 -CA-Oas,29237,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.65 -CA-Oas,29352,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,1.14 -CA-Oas,8742,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -CA-Oas,27106,GRP_LMA,LMA,18.4 -CA-Oas,27106,GRP_LMA,LMA_SPATIAL_VARIABILITY,5.3 -CA-Oas,27106,GRP_LMA,LMA_SPP,COCO6 (NRCS plant code) -CA-Oas,27106,GRP_LMA,LMA_DATE,1994 -CA-Oas,27106,GRP_LMA,LMA_COMMENT,C accounts for 50% of biomass -CA-Oas,27650,GRP_LMA,LMA,38.8 -CA-Oas,27650,GRP_LMA,LMA_SPATIAL_VARIABILITY,10 -CA-Oas,27650,GRP_LMA,LMA_SPP,POTR5 (NRCS plant code) -CA-Oas,27650,GRP_LMA,LMA_DATE,1994 -CA-Oas,27650,GRP_LMA,LMA_COMMENT,C accounts for 50% of biomass -CA-Oas,5822,GRP_LOCATION,LOCATION_LAT,53.6289 -CA-Oas,5822,GRP_LOCATION,LOCATION_LONG,-106.1978 -CA-Oas,5822,GRP_LOCATION,LOCATION_ELEV,530 -CA-Oas,5822,GRP_LOCATION,LOCATION_COMMENT,Luyssaert -CA-Oas,26588,GRP_NEP,NEP,206000 -CA-Oas,26588,GRP_NEP,NEP_DATE_START,1994 -CA-Oas,26588,GRP_NEP,NEP_DATE_END,1995 -CA-Oas,26588,GRP_NEP,NEP_COMMENT,"Jan-Dec; measured using eddy covariance, followed Fluxnet-Canada protocol" -CA-Oas,26205,GRP_NEP,NEP,55000 -CA-Oas,26205,GRP_NEP,NEP_DATE_START,1996 -CA-Oas,26205,GRP_NEP,NEP_DATE_END,1997 -CA-Oas,26205,GRP_NEP,NEP_COMMENT,"Jan-Dec; measured using eddy covariance, followed Fluxnet-Canada protocol" -CA-Oas,26589,GRP_NEP,NEP,131000 -CA-Oas,26589,GRP_NEP,NEP_DATE_START,1997 -CA-Oas,26589,GRP_NEP,NEP_DATE_END,1998 -CA-Oas,26589,GRP_NEP,NEP_COMMENT,"Jan-Dec; measured using eddy covariance, followed Fluxnet-Canada protocol" -CA-Oas,25325,GRP_NEP,NEP,261000 -CA-Oas,25325,GRP_NEP,NEP_DATE_START,1998 -CA-Oas,25325,GRP_NEP,NEP_DATE_END,1999 -CA-Oas,25325,GRP_NEP,NEP_COMMENT,"Jan-Dec; measured using eddy covariance, followed Fluxnet-Canada protocol" -CA-Oas,26336,GRP_NEP,NEP,119000 -CA-Oas,26336,GRP_NEP,NEP_DATE_START,1999 -CA-Oas,26336,GRP_NEP,NEP_DATE_END,2000 -CA-Oas,26336,GRP_NEP,NEP_COMMENT,"Jan-Dec; measured using eddy covariance, followed Fluxnet-Canada protocol" -CA-Oas,25197,GRP_NEP,NEP,158000 -CA-Oas,25197,GRP_NEP,NEP_DATE_START,2000 -CA-Oas,25197,GRP_NEP,NEP_DATE_END,2001 -CA-Oas,25197,GRP_NEP,NEP_COMMENT,"Jan-Dec; measured using eddy covariance, followed Fluxnet-Canada protocol" -CA-Oas,25326,GRP_NEP,NEP,367000 -CA-Oas,25326,GRP_NEP,NEP_DATE_START,2001 -CA-Oas,25326,GRP_NEP,NEP_DATE_END,2002 -CA-Oas,25326,GRP_NEP,NEP_COMMENT,"Jan-Dec; measured using eddy covariance, followed Fluxnet-Canada protocol" -CA-Oas,26590,GRP_NEP,NEP,144000 -CA-Oas,26590,GRP_NEP,NEP_DATE_START,2002 -CA-Oas,26590,GRP_NEP,NEP_DATE_END,2003 -CA-Oas,26590,GRP_NEP,NEP_COMMENT,"Jan-Dec; measured using eddy covariance, followed Fluxnet-Canada protocol" -CA-Oas,26206,GRP_NEP,NEP,104000 -CA-Oas,26206,GRP_NEP,NEP_DATE_START,2003 -CA-Oas,26206,GRP_NEP,NEP_DATE_END,2004 -CA-Oas,26206,GRP_NEP,NEP_COMMENT,"Jan-Dec; measured using eddy covariance, followed Fluxnet-Canada protocol" -CA-Oas,11390,GRP_NETWORK,NETWORK,AmeriFlux -CA-Oas,9786,GRP_NETWORK,NETWORK,Fluxnet-Canada -CA-Oas,87076,GRP_NETWORK,NETWORK,Phenocam -CA-Oas,1700005829,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Barr, A. G., Black, T., Hogg, E., Kljun, N., Morgenstern, K., Nesic, Z. (2004) Inter-Annual Variability In The Leaf Area Index Of A Boreal Aspen-Hazelnut Forest In Relation To Net Ecosystem Production, Agricultural And Forest Meteorology, 126(3-4), 237-255" -CA-Oas,1700005829,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2004.06.011 -CA-Oas,1700005829,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Oas,1700005517,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Barr, A. G., Griffis, T. J., Black, T. A., Lee, X., Staebler, R. M., Fuentes, J. D., Chen, Z., Morgenstern, K. (2002) Comparing The Carbon Budgets Of Boreal And Temperate Deciduous Forest Stands, Canadian Journal Of Forest Research, 32(5), 813-822" -CA-Oas,1700005517,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1139/X01-131 -CA-Oas,1700005517,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Oas,1700008241,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Barr, A., Richardson, A., Hollinger, D., Papale, D., Arain, M., Black, T., Bohrer, G., Dragoni, D., Fischer, M., Gu, L., Law, B., Margolis, H., McCaughey, J., Munger, J., Oechel, W., Schaeffer, K. (2013) Use Of Change-Point Detection For Friction–Velocity Threshold Evaluation In Eddy-Covariance Studies, Agricultural And Forest Meteorology, 171-172(7), 31-45" -CA-Oas,1700008241,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2012.11.023 -CA-Oas,1700008241,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Oas,1700002337,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Blanken, P. D., Black, T. A., Yang, P. C., Neumann, H. H., Nesic, Z., Staebler, R., den Hartog, G., Novak, M. D., Lee, X. (1997) Energy Balance And Canopy Conductance Of A Boreal Aspen Forest: Partitioning Overstory And Understory Components, Journal Of Geophysical Research: Atmospheres, 102(D24), 28915-28927" -CA-Oas,1700002337,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/97JD00193 -CA-Oas,1700002337,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Oas,1700001056,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Blanken, P., Black, T., Neumann, H., den Hartog, G., Yang, P., Nesic, Z., Lee, X. (2001) The Seasonal Water And Energy Exchange Above And Within A Boreal Aspen Forest, Journal Of Hydrology, 245(1-4), 118-136" -CA-Oas,1700001056,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/S0022-1694(01)00343-2 -CA-Oas,1700001056,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Oas,1700004749,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Bond-Lamberty, B., Wang, C., Gower, S. T. (2004) A Global Relationship Between The Heterotrophic And Autotrophic Components Of Soil Respiration?, Global Change Biology, 10(10), 1756-1766" -CA-Oas,1700004749,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/J.1365-2486.2004.00816.X -CA-Oas,1700004749,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Oas,1700001215,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Braghiere, R. K., Quaife, T., Black, E., Ryu, Y., Chen, Q., De Kauwe, M. G., Baldocchi, D. (2020) Influence Of Sun Zenith Angle On Canopy Clumping And The Resulting Impacts On Photosynthesis, Agricultural And Forest Meteorology, 291(2), 108065" -CA-Oas,1700001215,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2020.108065 -CA-Oas,1700001215,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Oas,1700004698,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Brooks, J. R., Flanagan, L. B., Varney, G. T., Ehleringer, J. R. (1997) Vertical Gradients In Photosynthetic Gas Exchange Characteristics And Refixation Of Respired CO2 Within Boreal Forest Canopies, Tree Physiology, 17(1), 1-12" -CA-Oas,1700004698,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1093/TREEPHYS/17.1.1 -CA-Oas,1700004698,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Oas,1700005895,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chen, J. M., Govind, A., Sonnentag, O., Zhang, Y., Barr, A., Amiro, B. (2006) Leaf Area Index Measurements At Fluxnet-Canada Forest Sites, Agricultural And Forest Meteorology, 140(1-4), 257-268" -CA-Oas,1700005895,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2006.08.005 -CA-Oas,1700005895,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Oas,1700002667,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chen, J. M., Ju, W., Cihlar, J., Price, D., Liu, J., Chen, W., Pan, J., Black, A., Barr, A. (2003) Spatial Distribution Of Carbon Sources And Sinks In Canada's Forests, Tellus Series B-Chemical and Physical Meteorology, 55(2), 622-641" -CA-Oas,1700002667,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1034/J.1600-0889.2003.00036.X -CA-Oas,1700002667,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Oas,1700000378,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chen, W. J., Black, T. A., Yang, P. C., Barr, A. G., Neumann, H. H., Nesic, Z., Blanken, P. D., Novak, M. D., Eley, J., Ketler, R. J., Cuenca, R. (1999) Effects Of Climatic Variability On The Annual Carbon Sequestration By A Boreal Aspen Forest, Global Change Biology, 5(1), 41-53" -CA-Oas,1700000378,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1046/J.1365-2486.1998.00201.X -CA-Oas,1700000378,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Oas,1700004338,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Baldocchi, D. D., Poindexter, C., Abraha, M., Desai, A. R., Bohrer, G., Arain, M. A., Griffis, T., Blanken, P. D., O'Halloran, T. L., Thomas, R. Q., Zhang, Q., Burns, S. P., Frank, J. M., Christian, D., Brown, S., Black, T. A., Gough, C. M., Law, B. E., Lee, X., Chen, J., Reed, D. E., Massman, W. J., Clark, K., Hatfield, J., Prueger, J., Bracho, R., Baker, J. M., Martin, T. A. (2018) Temporal Dynamics Of Aerodynamic Canopy Height Derived From Eddy Covariance Momentum Flux Data Across North American Flux Networks, Geophysical Research Letters, 45(2), 9275–9287" -CA-Oas,1700004338,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018GL079306 -CA-Oas,1700004338,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Oas,1700005403,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Baldocchi, D. D., Poindexter, C., Abraha, M., Desai, A. R., Bohrer, G., Arain, M. A., Griffis, T., Blanken, P. D., O'Halloran, T. L., Thomas, R. Q., Zhang, Q., Burns, S. P., Frank, J. M., Christian, D., Brown, S., Black, T. A., Gough, C. M., Law, B. E., Lee, X., Chen, J., Reed, D. E., Massman, W. J., Clark, K., Hatfield, J., Prueger, J., Bracho, R., Baker, J. M., Martin, T. A. (2018) Temporal Dynamics Of Aerodynamic Canopy Height Derived From Eddy Covariance Momentum Flux Data Across North American Flux Networks, Geophysical Research Letters, 45(8-9), 9275–9287" -CA-Oas,1700005403,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018GL079306 -CA-Oas,1700005403,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Oas,1700001245,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(2), 108350" -CA-Oas,1700001245,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -CA-Oas,1700001245,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Oas,1700004635,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Dennis Baldocchi, Cove Sturtevant (2015) Does day and night sampling reduce spurious correlation between canopy photosynthesis and ecosystem respiration?, Agricultural and Forest Meteorology, 207(8-9), 117-126" -CA-Oas,1700004635,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2015.03.010 -CA-Oas,1700004635,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Oas,1700007395,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Gastellu-Etchegorry, J., Guillevic, P., Zagolski, F., Demarez, V., Trichon, V., Deering, D., Leroy, M. (1999) Modeling BRFAnd Radiation Regime Of Boreal And Tropical Forests, Remote Sensing Of Environment, 68(3), 281-316" -CA-Oas,1700007395,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/S0034-4257(98)00119-9 -CA-Oas,1700007395,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Oas,1700000222,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"GAUMONT-GUAY, D., BLACK, T. A., MCCAUGHEY, H., BARR, A. G., KRISHNAN, P., JASSAL, R. S., NESIC, Z. (2009) Soil Co2efflux In Contrasting Boreal Deciduous And Coniferous Stands And Its Contribution To The Ecosystem Carbon Balance, Global Change Biology, 15(5), 1302-1319" -CA-Oas,1700000222,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/J.1365-2486.2008.01830.X -CA-Oas,1700000222,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Oas,1700007884,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Grant, R. F., Black, T. A., den Hartog, G., Berry, J. A., Neumann, H. H., Blanken, P. D., Yang, P. C., Russell, C., Nalder, I. A. (1999) Diurnal And Annual Exchanges Of Mass And Energy Between An Aspen-Hazelnut Forest And The Atmosphere: Testing The Mathematical Model Ecosys With Data From The BOREAS Experiment, Journal Of Geophysical Research: Atmospheres, 104(D22), 27699-27717" -CA-Oas,1700007884,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/1998JD200117 -CA-Oas,1700007884,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Oas,1700000063,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Griffis, T., Black, T., Gaumont-Guay, D., Drewitt, G., Nesic, Z., Barr, A., Morgenstern, K., Kljun, N. (2004) Seasonal Variation And Partitioning Of Ecosystem Respiration In A Southern Boreal Aspen Forest, Agricultural And Forest Meteorology, 125(3-4), 207-223" -CA-Oas,1700000063,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2004.04.006 -CA-Oas,1700000063,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Oas,1700002994,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Griffis, T., Black, T., Morgenstern, K., Barr, A., Nesic, Z., Drewitt, G., Gaumont-Guay, D., McCaughey, J. (2003) Ecophysiological Controls On The Carbon Balances Of Three Southern Boreal Forests, Agricultural And Forest Meteorology, 117(1-2), 53-71" -CA-Oas,1700002994,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/S0168-1923(03)00023-6 -CA-Oas,1700002994,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Oas,1700007701,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Gu, L., Falge, E. M., Boden, T., Baldocchi, D. D., Black, T., Saleska, S. R., Suni, T., Verma, S. B., Vesala, T., Wofsy, S. C., Xu, L. (2005) Objective Threshold Determination For Nighttime Eddy Flux Filtering, Agricultural And Forest Meteorology, 128(3-4), 179-197" -CA-Oas,1700007701,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2004.11.006 -CA-Oas,1700007701,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Oas,1700006717,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Gu, L., Shugart, H. H., Fuentes, J. D., Black, T., Shewchuk, S. R. (1999) Micrometeorology, Biophysical Exchanges And NEE Decomposition In A Two-Story Boreal Forest — Development And Test Of An Integrated Model, Agricultural And Forest Meteorology, 94(2), 123-148" -CA-Oas,1700006717,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/S0168-1923(99)00006-4 -CA-Oas,1700006717,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Oas,1700003912,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Hogg, E. H., Hurdle, P. A. (1997) Sap Flow In Trembling Aspen: Implications For Stomatal Responses To Vapor Pressure Deficit, Tree Physiology, 17(8-9), 501-509" -CA-Oas,1700003912,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1093/TREEPHYS/17.8-9.501 -CA-Oas,1700003912,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Oas,1700004422,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Kimball, J. S., Thornton, P. E., White, M. A., Running, S. W. (1997) Simulating Forest Productivity And Surface-Atmosphere Carbon Exchange In The BOREAS Study Region, Tree Physiology, 17(8-9), 589-599" -CA-Oas,1700004422,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1093/TREEPHYS/17.8-9.589 -CA-Oas,1700004422,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Oas,1700006768,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Krishnan, P., Black, T. A., Grant, N. J., Barr, A. G., Hogg, E. (., Jassal, R. S., Morgenstern, K. (2006) Impact Of Changing Soil Moisture Distribution On Net Ecosystem Productivity Of A Boreal Aspen Forest During And Following Drought, Agricultural And Forest Meteorology, 139(3-4), 208-223" -CA-Oas,1700006768,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2006.07.002 -CA-Oas,1700006768,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Oas,1700004005,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Lavigne, M. B., Ryan, M. G. (1997) Growth And Maintenance Respiration Rates Of Aspen, Black Spruce And Jack Pine Stems At Northern And Southern BOREAS Sites, Tree Physiology, 17(8-9), 543-551" -CA-Oas,1700004005,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1093/TREEPHYS/17.8-9.543 -CA-Oas,1700004005,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Oas,1700008268,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Lerdau, M., Litvak, M., Palmer, P., Monson, R. (1997) Controls Over Monoterpene Emissions From Boreal Forest Conifers, Tree Physiology, 17(8-9), 563-569" -CA-Oas,1700008268,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1093/TREEPHYS/17.8-9.563 -CA-Oas,1700008268,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Oas,1700000207,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Mahrt, L., Lee, X., Black, A., Neumann, H., Staebler, R. (2000) Nocturnal Mixing In A Forest Subcanopy, Agricultural And Forest Meteorology, 101(1), 67-78" -CA-Oas,1700000207,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/S0168-1923(99)00161-6 -CA-Oas,1700000207,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Oas,1700006273,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Mahrt, L., Vickers, D. (2002) Relationship Of Area-Averaged Carbon Dioxide And Water Vapour Fluxes To Atmospheric Variables, Agricultural And Forest Meteorology, 112(3-4), 195-202" -CA-Oas,1700006273,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/S0168-1923(02)00079-5 -CA-Oas,1700006273,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Oas,1700007104,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Margolis, H. A., Ryan, M. G. (1997) A Physiological Basis For Biosphere-Atmosphere Interactions In The Boreal Forest: An Overview, Tree Physiology, 17(8-9), 491-499" -CA-Oas,1700007104,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1093/TREEPHYS/17.8-9.491 -CA-Oas,1700007104,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Oas,1700005868,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Matheny, A. M., Bohrer, G., Stoy, P. C., Baker, I. T., Black, A. T., Desai, A. R., Dietze, M. C., Gough, C. M., Ivanov, V. Y., Jassal, R. S., Novick, K. A., Schäfer, K. V., Verbeeck, H. (2014) Characterizing The Diurnal Patterns of Errors in The Prediction of Evapotranspiration by Several Land-Surface Models: An Nacp Analysis, Journal Of Geophysical Research: Biogeosciences, 119(7), 1458-1473" -CA-Oas,1700005868,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/2014JG002623 -CA-Oas,1700005868,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Oas,1700003645,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Nakamura, R., Mahrt, L. (2001) Similarity Theory For Local And Spatially Averaged Momentum Fluxes, Agricultural And Forest Meteorology, 108(4), 265-279" -CA-Oas,1700003645,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/S0168-1923(01)00250-7 -CA-Oas,1700003645,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Oas,1700001857,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Nichol, C. J., Huemmrich, K. F., Black, T., Jarvis, P. G., Walthall, C. L., Grace, J., Hall, F. G. (2000) Remote Sensing Of Photosynthetic-Light-Use Efficiency Of Boreal Forest, Agricultural And Forest Meteorology, 101(2-3), 131-142" -CA-Oas,1700001857,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/S0168-1923(99)00167-7 -CA-Oas,1700001857,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Oas,1700003483,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Ponton, S., Flanagan, L. B., Alstad, K. P., Johnson, B. G., Morgenstern, K., Kljun, N., Black, T. A., Barr, A. G. (2006) Comparison Of Ecosystem Water-Use Efficiency Among Douglas-Fir Forest, Aspen Forest And Grassland Using Eddy Covariance And Carbon Isotope Techniques, Global Change Biology, 12(2), 294-310" -CA-Oas,1700003483,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/J.1365-2486.2005.01103.X -CA-Oas,1700003483,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Oas,1700004452,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Richardson, A. D., Anderson, R. S., Arain, M. A., Barr, A. G., Bohrer, G., Chen, G., Chen, J. M., Ciais, P., Davis, K. J., Desai, A. R., Dietze, M. C., Dragoni, D., Garrity, S. R., Gough, C. M., Grant, R., Hollinger, D. Y., Margolis, H. A., McCaughey, H., Migliavacca, M., Monson, R. K., Munger, J. W., Poulter, B., Raczka, B. M., Ricciuto, D. M., Sahoo, A. K., Schaefer, K., Tian, H., Vargas, R., Verbeeck, H., Xiao, J., Xue, Y. (2012) Terrestrial Biosphere Models Need Better Representation Of Vegetation Phenology: Results From The North American Carbon Program Site Synthesis, Global Change Biology, 18(2), 566-584" -CA-Oas,1700004452,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/J.1365-2486.2011.02562.X -CA-Oas,1700004452,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Oas,1700009066,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Steele, S. J., Gower, S. T., Vogel, J. G., Norman, J. M. (1997) Root Mass, Net Primary Production And Turnover In Aspen, Jack Pine And Black Spruce Forests In Saskatchewan And Manitoba, Canada, Tree Physiology, 17(8-9), 577-587" -CA-Oas,1700009066,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1093/TREEPHYS/17.8-9.577 -CA-Oas,1700009066,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Oas,1700008676,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Xu, B., Arain, M. A., Black, T. A., Law, B. E., Pastorello, G. Z., Chu, H. (2020) Seasonal Variability Of Forest Sensitivity To Heat And Drought Stresses: A Synthesis Based On Carbon Fluxes From North American Forest Ecosystems, Global Change Biology, 26(2), 901-918" -CA-Oas,1700008676,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/GCB.14843 -CA-Oas,1700008676,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Oas,25699,GRP_ROOT_BIOMASS,ROOT_BIOMASS_CRS,900 -CA-Oas,26587,GRP_ROOT_BIOMASS,ROOT_BIOMASS_CRS,960 -CA-Oas,25699,GRP_ROOT_BIOMASS,ROOT_BIOMASS_FINE,170 -CA-Oas,26587,GRP_ROOT_BIOMASS,ROOT_BIOMASS_FINE,20 -CA-Oas,25699,GRP_ROOT_BIOMASS,ROOT_BIOMASS_TOT,1070 -CA-Oas,26587,GRP_ROOT_BIOMASS,ROOT_BIOMASS_TOT,980 -CA-Oas,25699,GRP_ROOT_BIOMASS,ROOT_BIOMASS_UNIT,gC m-2 -CA-Oas,26587,GRP_ROOT_BIOMASS,ROOT_BIOMASS_UNIT,gC m-2 -CA-Oas,26587,GRP_ROOT_BIOMASS,ROOT_BIOMASS_DATE,1994 -CA-Oas,25699,GRP_ROOT_BIOMASS,ROOT_BIOMASS_DATE,2004 -CA-Oas,25699,GRP_ROOT_BIOMASS,ROOT_BIOMASS_COMMENT,Data from Alison Deanne Theede (2007) -CA-Oas,26587,GRP_ROOT_BIOMASS,ROOT_BIOMASS_COMMENT,Data from Alison Deanne Theede (2007) -CA-Oas,25588,GRP_ROOT_PROD,ROOT_PROD_CRS,26 -CA-Oas,25588,GRP_ROOT_PROD,ROOT_PROD_FINE,81 -CA-Oas,25588,GRP_ROOT_PROD,ROOT_PROD_TOT,107 -CA-Oas,25588,GRP_ROOT_PROD,ROOT_PROD_UNIT,gC m-2 -CA-Oas,25588,GRP_ROOT_PROD,ROOT_PROD_COMMENT,Data from Alison Deanne Theede (2007) -CA-Oas,26204,GRP_SA,SA,85 -CA-Oas,26204,GRP_SA,SA_DATE,2004 -CA-Oas,7019,GRP_SITE_DESC,SITE_DESC,"53.62889° N, 106.19779° W, elabation of 600.63 m,BOREAS 1994, 1996, BERMS climate and flux measurements began Dec. 1996" -CA-Oas,28019,GRP_SNAG_MASS,SNAG_MASS,610 -CA-Oas,28019,GRP_SNAG_MASS,SNAG_MASS_SPATIAL_VARIABILITY,159 -CA-Oas,28019,GRP_SNAG_MASS,SNAG_MASS_UNIT,gC m-2 -CA-Oas,28019,GRP_SNAG_MASS,SNAG_MASS_DATE,2004 -CA-Oas,28019,GRP_SNAG_MASS,SNAG_MASS_COMMENT,Data from Alison Deanne Theede (2007) -CA-Oas,28636,GRP_SNAG_MASS,SNAG_MASS,860 -CA-Oas,28636,GRP_SNAG_MASS,SNAG_MASS_SPATIAL_VARIABILITY,160 -CA-Oas,28636,GRP_SNAG_MASS,SNAG_MASS_UNIT,gC m-2 -CA-Oas,28636,GRP_SNAG_MASS,SNAG_MASS_DATE,1994 -CA-Oas,28636,GRP_SNAG_MASS,SNAG_MASS_COMMENT,Data from Alison Deanne Theede (2007) -CA-Oas,27410,GRP_SOIL_CHEM,SOIL_CHEM_C_ORG,20.9563 -CA-Oas,27107,GRP_SOIL_CHEM,SOIL_CHEM_C_ORG,25.9024 -CA-Oas,27108,GRP_SOIL_CHEM,SOIL_CHEM_C_ORG,29.7677 -CA-Oas,27651,GRP_SOIL_CHEM,SOIL_CHEM_C_ORG,36.4409 -CA-Oas,27652,GRP_SOIL_CHEM,SOIL_CHEM_C_ORG,41.3784 -CA-Oas,27411,GRP_SOIL_CHEM,SOIL_CHEM_C_ORG,52.3973 -CA-Oas,27108,GRP_SOIL_CHEM,SOIL_CHEM_C_ORG_SPATIAL_VARIABILITY,1.3 -CA-Oas,27652,GRP_SOIL_CHEM,SOIL_CHEM_C_ORG_SPATIAL_VARIABILITY,12.2 -CA-Oas,27411,GRP_SOIL_CHEM,SOIL_CHEM_C_ORG_SPATIAL_VARIABILITY,12.5 -CA-Oas,27107,GRP_SOIL_CHEM,SOIL_CHEM_C_ORG_SPATIAL_VARIABILITY,19.6 -CA-Oas,27410,GRP_SOIL_CHEM,SOIL_CHEM_C_ORG_SPATIAL_VARIABILITY,2.4 -CA-Oas,27651,GRP_SOIL_CHEM,SOIL_CHEM_C_ORG_SPATIAL_VARIABILITY,5 -CA-Oas,27109,GRP_SOIL_CHEM,SOIL_CHEM_N_TOT,0.5796 -CA-Oas,28875,GRP_SOIL_CHEM,SOIL_CHEM_N_TOT,1.40686 -CA-Oas,27752,GRP_SOIL_CHEM,SOIL_CHEM_N_TOT,1.50242 -CA-Oas,28876,GRP_SOIL_CHEM,SOIL_CHEM_N_TOT,1.7724 -CA-Oas,28877,GRP_SOIL_CHEM,SOIL_CHEM_N_TOT,2.71411 -CA-Oas,28704,GRP_SOIL_CHEM,SOIL_CHEM_N_TOT,3.2214 -CA-Oas,27109,GRP_SOIL_CHEM,SOIL_CHEM_N_TOT_SPATIAL_VARIABILITY,0.1 -CA-Oas,27752,GRP_SOIL_CHEM,SOIL_CHEM_N_TOT_SPATIAL_VARIABILITY,0.1 -CA-Oas,28877,GRP_SOIL_CHEM,SOIL_CHEM_N_TOT_SPATIAL_VARIABILITY,0.1 -CA-Oas,28876,GRP_SOIL_CHEM,SOIL_CHEM_N_TOT_SPATIAL_VARIABILITY,0.8 -CA-Oas,28875,GRP_SOIL_CHEM,SOIL_CHEM_N_TOT_SPATIAL_VARIABILITY,1 -CA-Oas,28704,GRP_SOIL_CHEM,SOIL_CHEM_N_TOT_SPATIAL_VARIABILITY,1.1 -CA-Oas,28638,GRP_SOIL_CHEM,SOIL_CHEM_PH_SALT,6.33 -CA-Oas,29349,GRP_SOIL_CHEM,SOIL_CHEM_PH_SALT,6.42 -CA-Oas,29350,GRP_SOIL_CHEM,SOIL_CHEM_PH_SALT,6.48 -CA-Oas,27110,GRP_SOIL_CHEM,SOIL_CHEM_PH_SALT,6.52 -CA-Oas,28637,GRP_SOIL_CHEM,SOIL_CHEM_PH_SALT,6.56 -CA-Oas,28020,GRP_SOIL_CHEM,SOIL_CHEM_PH_SALT,8.225 -CA-Oas,28637,GRP_SOIL_CHEM,SOIL_CHEM_PH_SALT_SPATIAL_VARIABILITY,0.18 -CA-Oas,29350,GRP_SOIL_CHEM,SOIL_CHEM_PH_SALT_SPATIAL_VARIABILITY,0.28 -CA-Oas,28020,GRP_SOIL_CHEM,SOIL_CHEM_PH_SALT_SPATIAL_VARIABILITY,0.29 -CA-Oas,28638,GRP_SOIL_CHEM,SOIL_CHEM_PH_SALT_SPATIAL_VARIABILITY,0.29 -CA-Oas,29349,GRP_SOIL_CHEM,SOIL_CHEM_PH_SALT_SPATIAL_VARIABILITY,0.31 -CA-Oas,27110,GRP_SOIL_CHEM,SOIL_CHEM_PH_SALT_SPATIAL_VARIABILITY,0.36 -CA-Oas,27651,GRP_SOIL_CHEM,SOIL_CHEM_BD,0.14 -CA-Oas,27107,GRP_SOIL_CHEM,SOIL_CHEM_BD,0.22 -CA-Oas,27411,GRP_SOIL_CHEM,SOIL_CHEM_BD,0.39 -CA-Oas,27410,GRP_SOIL_CHEM,SOIL_CHEM_BD,1.32 -CA-Oas,27652,GRP_SOIL_CHEM,SOIL_CHEM_BD,1.44 -CA-Oas,27108,GRP_SOIL_CHEM,SOIL_CHEM_BD,1.52 -CA-Oas,27110,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,-4.2 -CA-Oas,27411,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,-4.2 -CA-Oas,28704,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,-4.2 -CA-Oas,27107,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,-7.2 -CA-Oas,28875,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,-7.2 -CA-Oas,29350,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,-7.2 -CA-Oas,27651,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,-9.6 -CA-Oas,28637,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,-9.6 -CA-Oas,28876,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,-9.6 -CA-Oas,27410,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,0 -CA-Oas,27752,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,0 -CA-Oas,29349,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,0 -CA-Oas,27108,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,21.2 -CA-Oas,28638,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,21.2 -CA-Oas,28877,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,21.2 -CA-Oas,27109,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,69 -CA-Oas,27652,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,69 -CA-Oas,28020,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,69 -CA-Oas,27107,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,-4.2 -CA-Oas,28875,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,-4.2 -CA-Oas,29350,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,-4.2 -CA-Oas,27651,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,-7.2 -CA-Oas,28637,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,-7.2 -CA-Oas,28876,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,-7.2 -CA-Oas,27110,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,0 -CA-Oas,27411,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,0 -CA-Oas,28704,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,0 -CA-Oas,27410,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,21.2 -CA-Oas,27752,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,21.2 -CA-Oas,29349,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,21.2 -CA-Oas,27108,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,69 -CA-Oas,28638,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,69 -CA-Oas,28877,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,69 -CA-Oas,27109,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,82.5 -CA-Oas,27652,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,82.5 -CA-Oas,28020,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,82.5 -CA-Oas,27410,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,A -CA-Oas,27752,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,A -CA-Oas,29349,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,A -CA-Oas,27108,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,B -CA-Oas,28638,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,B -CA-Oas,28877,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,B -CA-Oas,27109,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,C -CA-Oas,27652,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,C -CA-Oas,28020,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,C -CA-Oas,27107,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,F -CA-Oas,28875,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,F -CA-Oas,29350,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,F -CA-Oas,27110,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,H -CA-Oas,27411,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,H -CA-Oas,28704,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,H -CA-Oas,27651,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,L -CA-Oas,28637,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,L -CA-Oas,28876,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,L -CA-Oas,27107,GRP_SOIL_CHEM,SOIL_CHEM_DATE,1993 -CA-Oas,27108,GRP_SOIL_CHEM,SOIL_CHEM_DATE,1993 -CA-Oas,27109,GRP_SOIL_CHEM,SOIL_CHEM_DATE,1993 -CA-Oas,27110,GRP_SOIL_CHEM,SOIL_CHEM_DATE,1993 -CA-Oas,27410,GRP_SOIL_CHEM,SOIL_CHEM_DATE,1993 -CA-Oas,27411,GRP_SOIL_CHEM,SOIL_CHEM_DATE,1993 -CA-Oas,27651,GRP_SOIL_CHEM,SOIL_CHEM_DATE,1993 -CA-Oas,27652,GRP_SOIL_CHEM,SOIL_CHEM_DATE,1993 -CA-Oas,27752,GRP_SOIL_CHEM,SOIL_CHEM_DATE,1993 -CA-Oas,28020,GRP_SOIL_CHEM,SOIL_CHEM_DATE,1993 -CA-Oas,28637,GRP_SOIL_CHEM,SOIL_CHEM_DATE,1993 -CA-Oas,28638,GRP_SOIL_CHEM,SOIL_CHEM_DATE,1993 -CA-Oas,28704,GRP_SOIL_CHEM,SOIL_CHEM_DATE,1993 -CA-Oas,28875,GRP_SOIL_CHEM,SOIL_CHEM_DATE,1993 -CA-Oas,28876,GRP_SOIL_CHEM,SOIL_CHEM_DATE,1993 -CA-Oas,28877,GRP_SOIL_CHEM,SOIL_CHEM_DATE,1993 -CA-Oas,29349,GRP_SOIL_CHEM,SOIL_CHEM_DATE,1993 -CA-Oas,29350,GRP_SOIL_CHEM,SOIL_CHEM_DATE,1993 -CA-Oas,27109,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,(0.02875 gN/100g); sigma is in gN/100g; soil thickness 0.14 m; measured by BOREAS -CA-Oas,28877,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,(0.0372 gN/100g); sigma is in gN/100g; soil thickness 0.48 m; measured by BOREAS -CA-Oas,27752,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,(0.0542 gN/100g); sigma is in gN/100g; soil thickness 0.212 m; measured by BOREAS -CA-Oas,27108,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,(0.408 gC/100g); sigma is in gC/100g; soil thickness 0.48 m; measured by BOREAS -CA-Oas,27410,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,(0.756 gC/100g); sigma is in gC/100g; soil thickness 0.0212 m; measured by BOREAS -CA-Oas,27652,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,(2.0525 gC/100g); sigma is in gC/100g; soil thickness 0.14 m; measured by BOREAS -CA-Oas,28704,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,(2.065 gN/100g); sigma is in gN/100g; soil thickness 0.04 m; measured by BOREAS -CA-Oas,28876,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,(2.11 gN/100g); sigma is in gN/100g; soil thickness 0.06 m; measured by BOREAS -CA-Oas,28875,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,(2.1316 gN/100g); sigma is in gN/100g; soil thickness 0.03 m; measured by BOREAS -CA-Oas,27411,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,(33.588 gC/100g); sigma is in gC/100g; soil thickness 0.04 m; measured by BOREAS -CA-Oas,27107,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,(39.246 gC/100g); sigma is in gC/100g; soil thickness 0.03 m; measured by BOREAS -CA-Oas,27651,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,(43.382 gC/100g); sigma is in gC/100g; soil thickness 0.06 m; measured by BOREAS -CA-Oas,29350,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,soil thickness 0.03 m; measured by BOREAS -CA-Oas,27110,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,soil thickness 0.04 m; measured by BOREAS -CA-Oas,28637,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,soil thickness 0.06 m; measured by BOREAS -CA-Oas,28020,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,soil thickness 0.14 m; measured by BOREAS -CA-Oas,29349,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,soil thickness 0.21 m; measured by BOREAS -CA-Oas,28638,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,soil thickness 0.48 m; measured by BOREAS -CA-Oas,24541,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION,Orthic Gray Luvisol -CA-Oas,24541,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION_TAXONOMY,Other -CA-Oas,24932,GRP_SOIL_DEPTH,SOIL_DEPTH,9 -CA-Oas,24932,GRP_SOIL_DEPTH,SOIL_DEPTH_COMMENT,(range 0.08-0.1) Barr et al 2004 -CA-Oas,25943,GRP_SOIL_TEX,SOIL_TEX_SAND,48.62 -CA-Oas,26107,GRP_SOIL_TEX,SOIL_TEX_SAND,48.771 -CA-Oas,25702,GRP_SOIL_TEX,SOIL_TEX_SAND,53.5575 -CA-Oas,25702,GRP_SOIL_TEX,SOIL_TEX_SILT,24.315 -CA-Oas,26107,GRP_SOIL_TEX,SOIL_TEX_SILT,26.988 -CA-Oas,25943,GRP_SOIL_TEX,SOIL_TEX_SILT,41.314 -CA-Oas,25943,GRP_SOIL_TEX,SOIL_TEX_CLAY,10.054 -CA-Oas,25702,GRP_SOIL_TEX,SOIL_TEX_CLAY,22.1125 -CA-Oas,26107,GRP_SOIL_TEX,SOIL_TEX_CLAY,24.228 -CA-Oas,25703,GRP_SOIL_TEX,SOIL_TEX_WATER_HOLD_CAP,12.41637312 -CA-Oas,25944,GRP_SOIL_TEX,SOIL_TEX_WATER_HOLD_CAP,3.127928125 -CA-Oas,26591,GRP_SOIL_TEX,SOIL_TEX_WATER_HOLD_CAP,4.65611328 -CA-Oas,25703,GRP_SOIL_TEX,SOIL_TEX_PROFILE_MIN,0 -CA-Oas,25944,GRP_SOIL_TEX,SOIL_TEX_PROFILE_MIN,0 -CA-Oas,26591,GRP_SOIL_TEX,SOIL_TEX_PROFILE_MIN,0 -CA-Oas,25944,GRP_SOIL_TEX,SOIL_TEX_PROFILE_MAX,14 -CA-Oas,26591,GRP_SOIL_TEX,SOIL_TEX_PROFILE_MAX,21 -CA-Oas,25703,GRP_SOIL_TEX,SOIL_TEX_PROFILE_MAX,48 -CA-Oas,25943,GRP_SOIL_TEX,SOIL_TEX_HORIZON,A -CA-Oas,26107,GRP_SOIL_TEX,SOIL_TEX_HORIZON,B -CA-Oas,25702,GRP_SOIL_TEX,SOIL_TEX_HORIZON,C -CA-Oas,25702,GRP_SOIL_TEX,SOIL_TEX_COMMENT,measured by BOREAS -CA-Oas,25703,GRP_SOIL_TEX,SOIL_TEX_COMMENT,measured by BOREAS -CA-Oas,25943,GRP_SOIL_TEX,SOIL_TEX_COMMENT,measured by BOREAS -CA-Oas,25944,GRP_SOIL_TEX,SOIL_TEX_COMMENT,measured by BOREAS -CA-Oas,26107,GRP_SOIL_TEX,SOIL_TEX_COMMENT,measured by BOREAS -CA-Oas,26591,GRP_SOIL_TEX,SOIL_TEX_COMMENT,measured by BOREAS -CA-Oas,26586,GRP_SPP_O,SPP_O,POTR5 (NRCS plant code) -CA-Oas,26586,GRP_SPP_O,SPP_O_PERC,90 -CA-Oas,26586,GRP_SPP_O,SPP_COMMENT,measured followed Fluxnet-Canada protocol -CA-Oas,26334,GRP_SPP_U,SPP_U,COCO6 (NRCS plant code) -CA-Oas,29680,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,T. Andrew Black -CA-Oas,29680,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -CA-Oas,29680,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,andrew.black@ubc.ca -CA-Oas,29680,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,The University of British Columbia -CA-Oas,29789,GRP_TOWER_POWER,TOWER_POWER,Direct power -CA-Oas,29681,GRP_TOWER_TYPE,TOWER_TYPE,walk-up -CA-Oas,6058,GRP_URL,URL,http://berms.ccrp.ec.gc.ca/Sites/e-sites-oa.htm -CA-Oas,24000070,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/CA-Oas -CA-Oas,2776,GRP_UTC_OFFSET,UTC_OFFSET,-6 -CA-Oas,28703,GRP_WD_BIOMASS,WD_BIOMASS_CRS,1380 -CA-Oas,28873,GRP_WD_BIOMASS,WD_BIOMASS_CRS,970 -CA-Oas,28703,GRP_WD_BIOMASS,WD_BIOMASS_CRS_SPATIAL_VARIABILITY,360 -CA-Oas,28873,GRP_WD_BIOMASS,WD_BIOMASS_CRS_SPATIAL_VARIABILITY,910 -CA-Oas,28703,GRP_WD_BIOMASS,WD_BIOMASS_UNIT,gC m-2 -CA-Oas,28873,GRP_WD_BIOMASS,WD_BIOMASS_UNIT,gC m-2 -CA-Oas,28873,GRP_WD_BIOMASS,WD_BIOMASS_DATE,1994 -CA-Oas,28703,GRP_WD_BIOMASS,WD_BIOMASS_DATE,2004 -CA-Oas,28703,GRP_WD_BIOMASS,WD_BIOMASS_COMMENT,Data from Alison Deanne Theede (2007) -CA-Oas,28873,GRP_WD_BIOMASS,WD_BIOMASS_COMMENT,Data from Alison Deanne Theede (2007) -CA-Obs,26596,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER,111 -CA-Obs,26596,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_ORGAN,Total -CA-Obs,26596,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_PHEN,Mixed/unknown -CA-Obs,26596,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_UNIT,kgDM m-2 -CA-Obs,26596,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_COMMENT,"Above-ground understory total biomass (gC/m2); Gower et al. (1997, J Geophy Res, 29029-29041)" -CA-Obs,25710,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER,60 -CA-Obs,25710,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_ORGAN,Total -CA-Obs,25710,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_PHEN,Mixed/unknown -CA-Obs,25710,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_UNIT,gC m-2 -CA-Obs,25710,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_DATE,1993 -CA-Obs,25710,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_COMMENT,"Gower et al. (1997, J Geophy Res, 29029-29041)" -CA-Obs,26110,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB,51 -CA-Obs,26110,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_ORGAN,Total -CA-Obs,26110,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_PHEN,Mixed/unknown -CA-Obs,26110,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_UNIT,gC m-2 -CA-Obs,26110,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_DATE,1993 -CA-Obs,26110,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_COMMENT,"Gower et al. (1997, J Geophy Res, 29029-29041)" -CA-Obs,26213,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,4308 -CA-Obs,26213,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Wood -CA-Obs,26213,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -CA-Obs,26213,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -CA-Obs,26213,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,1993 -CA-Obs,26213,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,"Gower et al. (1997, J Geophy Res, 29029-29041)" -CA-Obs,26595,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,4813 -CA-Obs,26595,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Total -CA-Obs,26595,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -CA-Obs,26595,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -CA-Obs,26595,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,1993 -CA-Obs,26595,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,"Gower et al. (1997, J Geophy Res, 29029-29041)" -CA-Obs,26594,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,505 -CA-Obs,26594,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Foliage -CA-Obs,26594,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -CA-Obs,26594,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -CA-Obs,26594,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,1993 -CA-Obs,26594,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,"Gower et al. (1997, J Geophy Res, 29029-29041)" -CA-Obs,25200,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT,53 -CA-Obs,25456,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT,59 -CA-Obs,25200,GRP_AG_LIT_PROD,AG_LIT_PROD_UNIT,gC m-2 -CA-Obs,25456,GRP_AG_LIT_PROD,AG_LIT_PROD_UNIT,gC m-2 -CA-Obs,25200,GRP_AG_LIT_PROD,AG_LIT_PROD_COMMENT,"Gower et al. (1997, J Geophy Res, 29029-29041)" -CA-Obs,25456,GRP_AG_LIT_PROD,AG_LIT_PROD_COMMENT,"Gower et al. (1997, J Geophy Res, 29029-29041)" -CA-Obs,26464,GRP_AG_PROD_OTHER,AG_PROD_OTHER,12 -CA-Obs,26464,GRP_AG_PROD_OTHER,AG_PROD_OTHER_ORGAN,Total -CA-Obs,26464,GRP_AG_PROD_OTHER,AG_PROD_OTHER_UNIT,gC m-2 -CA-Obs,26464,GRP_AG_PROD_OTHER,AG_PROD_DATE_START,1994 -CA-Obs,26464,GRP_AG_PROD_OTHER,AG_PROD_COMMENT,"Gower et al. (1997, J Geophy Res, 29029-29041)" -CA-Obs,25333,GRP_AG_PROD_SHRUB,AG_PROD_SHRUB,13 -CA-Obs,25333,GRP_AG_PROD_SHRUB,AG_PROD_SHRUB_ORGAN,Total -CA-Obs,25333,GRP_AG_PROD_SHRUB,AG_PROD_SHRUB_UNIT,gC m-2 -CA-Obs,25333,GRP_AG_PROD_SHRUB,AG_PROD_DATE_START,1994 -CA-Obs,25333,GRP_AG_PROD_SHRUB,AG_PROD_COMMENT,"Gower et al. (1997, J Geophy Res, 29029-29041)" -CA-Obs,25331,GRP_AG_PROD_TREE,AG_PROD_TREE,7 -CA-Obs,25331,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Foliage -CA-Obs,25331,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -CA-Obs,25331,GRP_AG_PROD_TREE,AG_PROD_DATE_START,1993 -CA-Obs,25331,GRP_AG_PROD_TREE,AG_PROD_COMMENT,"Gower et al. (1997, J Geophy Res, 29029-29041)" -CA-Obs,25711,GRP_AG_PROD_TREE,AG_PROD_TREE,78 -CA-Obs,25711,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Wood -CA-Obs,25711,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -CA-Obs,25711,GRP_AG_PROD_TREE,AG_PROD_DATE_START,1993 -CA-Obs,25711,GRP_AG_PROD_TREE,AG_PROD_COMMENT,"Gower et al. (1997, J Geophy Res, 29029-29041)" -CA-Obs,25712,GRP_AG_PROD_TREE,AG_PROD_TREE,8 -CA-Obs,25712,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Foliage -CA-Obs,25712,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -CA-Obs,25712,GRP_AG_PROD_TREE,AG_PROD_DATE_START,1994 -CA-Obs,25712,GRP_AG_PROD_TREE,AG_PROD_COMMENT,"Gower et al. (1997, J Geophy Res, 29029-29041)" -CA-Obs,26597,GRP_AG_PROD_TREE,AG_PROD_TREE,80 -CA-Obs,26597,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Wood -CA-Obs,26597,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -CA-Obs,26597,GRP_AG_PROD_TREE,AG_PROD_DATE_START,1994 -CA-Obs,26597,GRP_AG_PROD_TREE,AG_PROD_COMMENT,"Gower et al. (1997, J Geophy Res, 29029-29041)" -CA-Obs,25947,GRP_AG_PROD_TREE,AG_PROD_TREE,85 -CA-Obs,25947,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Total -CA-Obs,25947,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -CA-Obs,25947,GRP_AG_PROD_TREE,AG_PROD_DATE_START,1993 -CA-Obs,25947,GRP_AG_PROD_TREE,AG_PROD_COMMENT,"Gower et al. (1997, J Geophy Res, 29029-29041)" -CA-Obs,25332,GRP_AG_PROD_TREE,AG_PROD_TREE,88 -CA-Obs,25332,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Total -CA-Obs,25332,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -CA-Obs,25332,GRP_AG_PROD_TREE,AG_PROD_DATE_START,1994 -CA-Obs,25332,GRP_AG_PROD_TREE,AG_PROD_COMMENT,"Gower et al. (1997, J Geophy Res, 29029-29041)" -CA-Obs,26598,GRP_BIOMASS_CHEM,BIOMASS_C,5.09 -CA-Obs,26343,GRP_BIOMASS_CHEM,BIOMASS_C,5.24 -CA-Obs,25833,GRP_BIOMASS_CHEM,BIOMASS_C,5.33 -CA-Obs,26598,GRP_BIOMASS_CHEM,BIOMASS_N,0.076 -CA-Obs,25833,GRP_BIOMASS_CHEM,BIOMASS_N,0.084 -CA-Obs,26343,GRP_BIOMASS_CHEM,BIOMASS_N,0.085 -CA-Obs,25713,GRP_BIOMASS_CHEM,BIOMASS_N,0.087 -CA-Obs,25713,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -CA-Obs,25833,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -CA-Obs,26343,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -CA-Obs,26598,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -CA-Obs,25713,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -CA-Obs,25833,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -CA-Obs,26343,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -CA-Obs,26598,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -CA-Obs,25713,GRP_BIOMASS_CHEM,BIOMASS_SPP,PIMA (NRCS plant code) -CA-Obs,25833,GRP_BIOMASS_CHEM,BIOMASS_SPP,PIMA (NRCS plant code) -CA-Obs,26343,GRP_BIOMASS_CHEM,BIOMASS_SPP,PIMA (NRCS plant code) -CA-Obs,26598,GRP_BIOMASS_CHEM,BIOMASS_SPP,PIMA (NRCS plant code) -CA-Obs,26598,GRP_BIOMASS_CHEM,BIOMASS_DATE,19940601 -CA-Obs,26343,GRP_BIOMASS_CHEM,BIOMASS_DATE,19940728 -CA-Obs,25833,GRP_BIOMASS_CHEM,BIOMASS_DATE,19940913 -CA-Obs,25713,GRP_BIOMASS_CHEM,BIOMASS_DATE,20050830 -CA-Obs,25713,GRP_BIOMASS_CHEM,BIOMASS_COMMENT,"Middleton et al. 1997(J Geophy Res 102, 28831-28844)" -CA-Obs,25833,GRP_BIOMASS_CHEM,BIOMASS_COMMENT,"Middleton et al. 1997(J Geophy Res 102, 28831-28844)" -CA-Obs,26343,GRP_BIOMASS_CHEM,BIOMASS_COMMENT,"Middleton et al. 1997(J Geophy Res 102, 28831-28844)" -CA-Obs,26598,GRP_BIOMASS_CHEM,BIOMASS_COMMENT,"Middleton et al. 1997(J Geophy Res 102, 28831-28844)" -CA-Obs,7648,GRP_CLIM_AVG,MAT,0.79 -CA-Obs,7648,GRP_CLIM_AVG,MAP,405.6 -CA-Obs,7648,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfc -CA-Obs,27000071,GRP_COUNTRY,COUNTRY,Canada -CA-Obs,8744,GRP_DM_FIRE,DM_FIRE,Nature induced burn -CA-Obs,8744,GRP_DM_FIRE,DM_DATE,1894 -CA-Obs,8744,GRP_DM_FIRE,DM_COMMENT,natural regeneration -CA-Obs,33541,GRP_DOI,DOI,10.17190/AMF/1375198 -CA-Obs,33541,GRP_DOI,DOI_CITATION,"T. Andrew Black (2016), AmeriFlux BASE CA-Obs Saskatchewan - Western Boreal, Mature Black Spruce, Ver. 1-1, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1375198" -CA-Obs,33541,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -CA-Obs,31874,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -CA-Obs,31874,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,T. Andrew Black -CA-Obs,31874,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -CA-Obs,31874,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,andrew.black@ubc.ca -CA-Obs,31874,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,The University of British Columbia -CA-Obs,31875,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,The University of British Columbia -CA-Obs,31875,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -CA-Obs,29686,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Drought -CA-Obs,8892,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -CA-Obs,8892,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -CA-Obs,8892,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,1999 -CA-Obs,8892,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -CA-Obs,23000071,GRP_HEADER,SITE_NAME,"Saskatchewan - Western Boreal, Mature Black Spruce" -CA-Obs,89119,GRP_HEIGHTC,HEIGHTC,11 -CA-Obs,89119,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -CA-Obs,89119,GRP_HEIGHTC,HEIGHTC_DATE,1993 -CA-Obs,89119,GRP_HEIGHTC,HEIGHTC_COMMENT,"Stand density (#/ha) 5900; Gower et al. (1997, J Geophy Res, 29029-29041)" -CA-Obs,262,GRP_IGBP,IGBP,ENF -CA-Obs,25457,GRP_LAI,LAI_TYPE,LAI -CA-Obs,25458,GRP_LAI,LAI_TYPE,LAI -CA-Obs,25599,GRP_LAI,LAI_TYPE,LAI -CA-Obs,25600,GRP_LAI,LAI_TYPE,LAI -CA-Obs,25836,GRP_LAI,LAI_TYPE,LAI -CA-Obs,26216,GRP_LAI,LAI_TYPE,LAI -CA-Obs,26469,GRP_LAI,LAI_TYPE,LAI -CA-Obs,26470,GRP_LAI,LAI_TYPE,LAI -CA-Obs,25457,GRP_LAI,LAI_CLUMP,0.899 -CA-Obs,25458,GRP_LAI,LAI_CLUMP,0.899 -CA-Obs,25599,GRP_LAI,LAI_CLUMP,0.899 -CA-Obs,25600,GRP_LAI,LAI_CLUMP,0.899 -CA-Obs,25836,GRP_LAI,LAI_CLUMP,0.899 -CA-Obs,26216,GRP_LAI,LAI_CLUMP,0.899 -CA-Obs,26469,GRP_LAI,LAI_CLUMP,0.899 -CA-Obs,26470,GRP_LAI,LAI_CLUMP,0.899 -CA-Obs,25457,GRP_LAI,LAI_DATE,19970823 -CA-Obs,25836,GRP_LAI,LAI_DATE,19971005 -CA-Obs,26216,GRP_LAI,LAI_DATE,19980717 -CA-Obs,26469,GRP_LAI,LAI_DATE,20010515 -CA-Obs,25599,GRP_LAI,LAI_DATE,20010717 -CA-Obs,25600,GRP_LAI,LAI_DATE,20010817 -CA-Obs,26470,GRP_LAI,LAI_DATE,20040428 -CA-Obs,25458,GRP_LAI,LAI_DATE,20040806 -CA-Obs,25457,GRP_LAI,LAI_COMMENT,LAI-2000 + TRAC -CA-Obs,25458,GRP_LAI,LAI_COMMENT,LAI-2000 + TRAC -CA-Obs,25599,GRP_LAI,LAI_COMMENT,LAI-2000 + TRAC -CA-Obs,25600,GRP_LAI,LAI_COMMENT,LAI-2000 + TRAC -CA-Obs,25836,GRP_LAI,LAI_COMMENT,LAI-2000 + TRAC -CA-Obs,26216,GRP_LAI,LAI_COMMENT,LAI-2000 + TRAC -CA-Obs,26469,GRP_LAI,LAI_COMMENT,LAI-2000 + TRAC -CA-Obs,26470,GRP_LAI,LAI_COMMENT,LAI-2000 + TRAC -CA-Obs,26216,GRP_LAI,LAI_TOT,1.89 -CA-Obs,26470,GRP_LAI,LAI_TOT,2.58 -CA-Obs,26469,GRP_LAI,LAI_TOT,2.81 -CA-Obs,25599,GRP_LAI,LAI_TOT,2.98 -CA-Obs,25458,GRP_LAI,LAI_TOT,3.09 -CA-Obs,25457,GRP_LAI,LAI_TOT,3.23 -CA-Obs,25600,GRP_LAI,LAI_TOT,3.33 -CA-Obs,25836,GRP_LAI,LAI_TOT,3.41 -CA-Obs,1947,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -CA-Obs,26466,GRP_LMA,LMA,115.4 -CA-Obs,26466,GRP_LMA,LMA_SPP,PIMA (NRCS plant code) -CA-Obs,26466,GRP_LMA,LMA_DATE,19940601 -CA-Obs,26466,GRP_LMA,LMA_COMMENT,"Middleton et al. 1997(J Geophy Res 102, 28831-28844). Assumed that C account for 50% of biomass" -CA-Obs,25597,GRP_LMA,LMA,72.1 -CA-Obs,25597,GRP_LMA,LMA_SPP,PIMA (NRCS plant code) -CA-Obs,25597,GRP_LMA,LMA_DATE,19940913 -CA-Obs,25597,GRP_LMA,LMA_COMMENT,"Middleton et al. 1997(J Geophy Res 102, 28831-28844). Assumed that C account for 50% of biomass" -CA-Obs,26467,GRP_LMA,LMA,83.6 -CA-Obs,26467,GRP_LMA,LMA_SPP,PIMA (NRCS plant code) -CA-Obs,26467,GRP_LMA,LMA_DATE,19940728 -CA-Obs,26467,GRP_LMA,LMA_COMMENT,"Middleton et al. 1997(J Geophy Res 102, 28831-28844). Assumed that C account for 50% of biomass" -CA-Obs,3284,GRP_LOCATION,LOCATION_LAT,53.9872 -CA-Obs,3284,GRP_LOCATION,LOCATION_LONG,-105.1178 -CA-Obs,3284,GRP_LOCATION,LOCATION_ELEV,628.94 -CA-Obs,3284,GRP_LOCATION,LOCATION_COMMENT,"Bergeron, et al 2006 Global Change Biology. 12, 1-19 / Luyssaert: 520" -CA-Obs,25199,GRP_NEP,NEP,38000 -CA-Obs,25199,GRP_NEP,NEP_DATE_START,1999 -CA-Obs,25455,GRP_NEP,NEP,56000 -CA-Obs,25455,GRP_NEP,NEP_DATE_START,2000 -CA-Obs,25455,GRP_NEP,NEP_DATE_END,2001 -CA-Obs,25455,GRP_NEP,NEP_COMMENT,"Jan-Dec; measured followed Fluxnet-Canada protocol, using eddy covariance technique" -CA-Obs,25832,GRP_NEP,NEP,77000 -CA-Obs,25832,GRP_NEP,NEP_DATE_START,2001 -CA-Obs,25832,GRP_NEP,NEP_DATE_END,2002 -CA-Obs,25832,GRP_NEP,NEP_COMMENT,"Jan-Dec; measured followed Fluxnet-Canada protocol, using eddy covariance technique" -CA-Obs,26214,GRP_NEP,NEP,29000 -CA-Obs,26214,GRP_NEP,NEP_DATE_START,2002 -CA-Obs,26214,GRP_NEP,NEP_DATE_END,2003 -CA-Obs,26214,GRP_NEP,NEP_COMMENT,"Jan-Dec; measured followed Fluxnet-Canada protocol, using eddy covariance technique" -CA-Obs,25948,GRP_NEP,NEP,76000 -CA-Obs,25948,GRP_NEP,NEP_DATE_START,2003 -CA-Obs,25948,GRP_NEP,NEP_DATE_END,2004 -CA-Obs,25948,GRP_NEP,NEP_COMMENT,"Jan-Dec; measured followed Fluxnet-Canada protocol, using eddy covariance technique" -CA-Obs,25596,GRP_NEP,NEP,36000 -CA-Obs,25596,GRP_NEP,NEP_DATE_START,2004 -CA-Obs,25596,GRP_NEP,NEP_DATE_END,2005 -CA-Obs,25596,GRP_NEP,NEP_COMMENT,"Jan-Dec; measured followed Fluxnet-Canada protocol, using eddy covariance technique" -CA-Obs,26111,GRP_NEP,NEP,45000 -CA-Obs,26111,GRP_NEP,NEP_DATE_START,2005 -CA-Obs,26111,GRP_NEP,NEP_DATE_END,2006 -CA-Obs,26111,GRP_NEP,NEP_COMMENT,"Jan-Dec; measured followed Fluxnet-Canada protocol, using eddy covariance technique" -CA-Obs,26112,GRP_NEP,NEP,68000 -CA-Obs,26112,GRP_NEP,NEP_DATE_START,2006 -CA-Obs,26112,GRP_NEP,NEP_DATE_END,2007 -CA-Obs,26112,GRP_NEP,NEP_COMMENT,"Jan-Dec; measured followed Fluxnet-Canada protocol, using eddy covariance technique" -CA-Obs,26465,GRP_NEP,NEP,50000 -CA-Obs,26465,GRP_NEP,NEP_DATE_START,2007 -CA-Obs,26465,GRP_NEP,NEP_DATE_END,2008 -CA-Obs,26465,GRP_NEP,NEP_COMMENT,"Jan-Dec; measured followed Fluxnet-Canada protocol, using eddy covariance technique" -CA-Obs,11391,GRP_NETWORK,NETWORK,AmeriFlux -CA-Obs,8084,GRP_NETWORK,NETWORK,Fluxnet-Canada -CA-Obs,87077,GRP_NETWORK,NETWORK,Phenocam -CA-Obs,1700000561,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Barr, A., Richardson, A., Hollinger, D., Papale, D., Arain, M., Black, T., Bohrer, G., Dragoni, D., Fischer, M., Gu, L., Law, B., Margolis, H., McCaughey, J., Munger, J., Oechel, W., Schaeffer, K. (2013) Use Of Change-Point Detection For Friction–Velocity Threshold Evaluation In Eddy-Covariance Studies, Agricultural And Forest Meteorology, 171-172(5), 31-45" -CA-Obs,1700000561,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2012.11.023 -CA-Obs,1700000561,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Obs,1700008586,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Bergeron, O., Margolis, H. A., Black, T. A., Coursolle, C., Dunn, A. L., Barr, A. G., Wofsy, S. C. (2007) Comparison Of Carbon Dioxide Fluxes Over Three Boreal Black Spruce Forests In Canada, Global Change Biology, 13(1), 89-107" -CA-Obs,1700008586,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/J.1365-2486.2006.01281.X -CA-Obs,1700008586,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Obs,1700007749,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Bisbee, K., Gower, S., Norman, J., Nordheim, E. (2001) Environmental Controls On Ground Cover Species Composition And Productivity In A Boreal Black Spruce Forest, Oecologia, 129(2), 261-270" -CA-Obs,1700007749,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1007/S004420100719 -CA-Obs,1700007749,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Obs,1700002814,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Bond-Lamberty, B., Wang, C., Gower, S. T. (2004) A Global Relationship Between The Heterotrophic And Autotrophic Components Of Soil Respiration?, Global Change Biology, 10(10), 1756-1766" -CA-Obs,1700002814,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/J.1365-2486.2004.00816.X -CA-Obs,1700002814,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Obs,1700008904,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Brooks, J. R., Flanagan, L. B., Varney, G. T., Ehleringer, J. R. (1997) Vertical Gradients In Photosynthetic Gas Exchange Characteristics And Refixation Of Respired CO2 Within Boreal Forest Canopies, Tree Physiology, 17(1), 1-12" -CA-Obs,1700008904,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1093/TREEPHYS/17.1.1 -CA-Obs,1700008904,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Obs,1700008955,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chen, J. M., Ju, W., Cihlar, J., Price, D., Liu, J., Chen, W., Pan, J., Black, A., Barr, A. (2003) Spatial Distribution Of Carbon Sources And Sinks In Canada's Forests, Tellus Series B-Chemical and Physical Meteorology, 55(2), 622-641" -CA-Obs,1700008955,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1034/J.1600-0889.2003.00036.X -CA-Obs,1700008955,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Obs,1700005058,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Baldocchi, D. D., Poindexter, C., Abraha, M., Desai, A. R., Bohrer, G., Arain, M. A., Griffis, T., Blanken, P. D., O'Halloran, T. L., Thomas, R. Q., Zhang, Q., Burns, S. P., Frank, J. M., Christian, D., Brown, S., Black, T. A., Gough, C. M., Law, B. E., Lee, X., Chen, J., Reed, D. E., Massman, W. J., Clark, K., Hatfield, J., Prueger, J., Bracho, R., Baker, J. M., Martin, T. A. (2018) Temporal Dynamics Of Aerodynamic Canopy Height Derived From Eddy Covariance Momentum Flux Data Across North American Flux Networks, Geophysical Research Letters, 45(1), 9275–9287" -CA-Obs,1700005058,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018GL079306 -CA-Obs,1700005058,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Obs,1700006915,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Baldocchi, D. D., Poindexter, C., Abraha, M., Desai, A. R., Bohrer, G., Arain, M. A., Griffis, T., Blanken, P. D., O'Halloran, T. L., Thomas, R. Q., Zhang, Q., Burns, S. P., Frank, J. M., Christian, D., Brown, S., Black, T. A., Gough, C. M., Law, B. E., Lee, X., Chen, J., Reed, D. E., Massman, W. J., Clark, K., Hatfield, J., Prueger, J., Bracho, R., Baker, J. M., Martin, T. A. (2018) Temporal Dynamics Of Aerodynamic Canopy Height Derived From Eddy Covariance Momentum Flux Data Across North American Flux Networks, Geophysical Research Letters, 45(2), 9275–9287" -CA-Obs,1700006915,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018GL079306 -CA-Obs,1700006915,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Obs,1700004068,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. 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(2003) Comparison Of Net Primary Production And Light-Use Dynamics Of Two Boreal Black Spruce Forest Communities, Ecosystems, 6(3), 236-247" -CA-Obs,1700001281,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1007/PL00021510 -CA-Obs,1700001281,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Obs,1700008178,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Pierrat, Z., Magney, T., Parazoo, N. C., Grossmann, K., Bowling, D. R., Seibt, U., Johnson, B., Helgason, W., Barr, A., Bortnik, J., Norton, A., Maguire, A., Frankenberg, C., Stutz, J. (2022) Diurnal And Seasonal Dynamics Of Solar‐Induced Chlorophyll Fluorescence, Vegetation Indices, And Gross Primary Productivity In The Boreal Forest, Journal Of Geophysical Research: Biogeosciences, 127(2), 901-918" -CA-Obs,1700008178,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2021JG006588 -CA-Obs,1700008178,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Obs,1700007485,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Pierrat, Z., Nehemy, M. F., Roy, A., Magney, T., Parazoo, N. 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(2001) Environmental Regulation Of Carbon Dioxide Exchange At The Forest Floor In A Boreal Black Spruce Ecosystem, Agricultural And Forest Meteorology, 108(3), 165-181" -CA-Obs,1700003699,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/S0168-1923(01)00243-X -CA-Obs,1700003699,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Obs,1700006441,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Turner, D. P., Urbanski, S., Bremer, D., Wofsy, S. C., Meyers, T., Gower, S. T., Gregory, M. (2003) A Cross-Biome Comparison Of Daily Light Use Efficiency For Gross Primary Production, Global Change Biology, 9(3), 383-395" -CA-Obs,1700006441,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1046/J.1365-2486.2003.00573.X -CA-Obs,1700006441,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Obs,1700003159,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Whitehead, D., Gower, S. T. 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(2020) Seasonal Variability Of Forest Sensitivity To Heat And Drought Stresses: A Synthesis Based On Carbon Fluxes From North American Forest Ecosystems, Global Change Biology, 26(2), 901-918" -CA-Obs,1700003129,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/GCB.14843 -CA-Obs,1700003129,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-Obs,26211,GRP_SA,SA,111 -CA-Obs,26211,GRP_SA,SA_DATE,2005 -CA-Obs,26211,GRP_SA,SA_COMMENT,Mean stand age comments -CA-Obs,1948,GRP_SITE_DESC,SITE_DESC,"53.98717° N, 105.11779° W, elavation of 628.94 m, BOREAS 1994, 1996, BERMS climate measurements began Dec. 1996 and flux measurements in Apr. 1999" -CA-Obs,26212,GRP_SNAG_MASS,SNAG_MASS,616 -CA-Obs,26212,GRP_SNAG_MASS,SNAG_MASS_UNIT,gC m-2 -CA-Obs,26212,GRP_SNAG_MASS,SNAG_MASS_DATE,1993 -CA-Obs,26212,GRP_SNAG_MASS,SNAG_MASS_COMMENT,"Gower et al. (1997, J Geophy Res, 29029-29041)" -CA-Obs,28879,GRP_SOIL_CHEM,SOIL_CHEM_C_ORG,4.233 -CA-Obs,29239,GRP_SOIL_CHEM,SOIL_CHEM_C_ORG,4.25 -CA-Obs,29354,GRP_SOIL_CHEM,SOIL_CHEM_C_ORG,4.6968 -CA-Obs,29567,GRP_SOIL_CHEM,SOIL_CHEM_C_ORG,43.45 -CA-Obs,28878,GRP_SOIL_CHEM,SOIL_CHEM_C_ORG,457.72 -CA-Obs,28707,GRP_SOIL_CHEM,SOIL_CHEM_C_ORG,5.81 -CA-Obs,29240,GRP_SOIL_CHEM,SOIL_CHEM_C_ORG,9.1632 -CA-Obs,28708,GRP_SOIL_CHEM,SOIL_CHEM_N_TOT,0.15 -CA-Obs,29355,GRP_SOIL_CHEM,SOIL_CHEM_N_TOT,0.19152 -CA-Obs,29241,GRP_SOIL_CHEM,SOIL_CHEM_N_TOT,0.2075 -CA-Obs,28025,GRP_SOIL_CHEM,SOIL_CHEM_N_TOT,0.2241 -CA-Obs,28372,GRP_SOIL_CHEM,SOIL_CHEM_N_TOT,0.43824 -CA-Obs,27656,GRP_SOIL_CHEM,SOIL_CHEM_N_TOT,1.028 -CA-Obs,28024,GRP_SOIL_CHEM,SOIL_CHEM_N_TOT,1.3575 -CA-Obs,25835,GRP_SOIL_CHEM,SOIL_CHEM_PH_SALT,4.3 -CA-Obs,26215,GRP_SOIL_CHEM,SOIL_CHEM_PH_SALT,4.3 -CA-Obs,25714,GRP_SOIL_CHEM,SOIL_CHEM_PH_SALT,4.9 -CA-Obs,26113,GRP_SOIL_CHEM,SOIL_CHEM_PH_SALT,5.8 -CA-Obs,25834,GRP_SOIL_CHEM,SOIL_CHEM_PH_SALT,6.31666666666667 -CA-Obs,26344,GRP_SOIL_CHEM,SOIL_CHEM_PH_SALT,6.35 -CA-Obs,26468,GRP_SOIL_CHEM,SOIL_CHEM_PH_SALT,6.8 -CA-Obs,29239,GRP_SOIL_CHEM,SOIL_CHEM_BD,1.25 -CA-Obs,29354,GRP_SOIL_CHEM,SOIL_CHEM_BD,1.52 -CA-Obs,28707,GRP_SOIL_CHEM,SOIL_CHEM_BD,1.66 -CA-Obs,28879,GRP_SOIL_CHEM,SOIL_CHEM_BD,1.66 -CA-Obs,29240,GRP_SOIL_CHEM,SOIL_CHEM_BD,1.66 -CA-Obs,26344,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,-10 -CA-Obs,27656,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,-10 -CA-Obs,29567,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,-10 -CA-Obs,25834,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,-20 -CA-Obs,28024,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,-20 -CA-Obs,28878,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,-20 -CA-Obs,26215,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,0 -CA-Obs,28708,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,0 -CA-Obs,29239,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,0 -CA-Obs,26113,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,17 -CA-Obs,28707,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,17 -CA-Obs,29241,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,17 -CA-Obs,25835,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,2 -CA-Obs,29354,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,2 -CA-Obs,29355,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,2 -CA-Obs,26468,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,42 -CA-Obs,28025,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,42 -CA-Obs,28879,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,42 -CA-Obs,25714,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,5 -CA-Obs,28372,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,5 -CA-Obs,29240,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,5 -CA-Obs,26344,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,-20 -CA-Obs,27656,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,-20 -CA-Obs,29567,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,-20 -CA-Obs,25834,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,0 -CA-Obs,28024,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,0 -CA-Obs,28878,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,0 -CA-Obs,25714,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,17 -CA-Obs,28372,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,17 -CA-Obs,29240,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,17 -CA-Obs,26215,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,2 -CA-Obs,28708,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,2 -CA-Obs,29239,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,2 -CA-Obs,26113,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,42 -CA-Obs,28707,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,42 -CA-Obs,29241,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,42 -CA-Obs,25835,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,5 -CA-Obs,29354,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,5 -CA-Obs,29355,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,5 -CA-Obs,26468,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,72 -CA-Obs,28025,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,72 -CA-Obs,28879,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,72 -CA-Obs,25835,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,AB -CA-Obs,29354,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,AB -CA-Obs,29355,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,AB -CA-Obs,26215,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,Ae -CA-Obs,28708,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,Ae -CA-Obs,29239,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,Ae -CA-Obs,26113,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,Bfj -CA-Obs,28707,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,Bfj -CA-Obs,29241,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,Bfj -CA-Obs,25714,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,Bt -CA-Obs,28372,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,Bt -CA-Obs,29240,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,Bt -CA-Obs,26468,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,Ck -CA-Obs,28025,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,Ck -CA-Obs,28879,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,Ck -CA-Obs,25834,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,peat -CA-Obs,26344,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,peat -CA-Obs,27656,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,peat -CA-Obs,28024,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,peat -CA-Obs,28878,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,peat -CA-Obs,29567,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,peat -CA-Obs,27656,GRP_SOIL_CHEM,SOIL_CHEM_DATE,19050616 -CA-Obs,28024,GRP_SOIL_CHEM,SOIL_CHEM_DATE,19050616 -CA-Obs,28025,GRP_SOIL_CHEM,SOIL_CHEM_DATE,19050616 -CA-Obs,28372,GRP_SOIL_CHEM,SOIL_CHEM_DATE,19050616 -CA-Obs,28707,GRP_SOIL_CHEM,SOIL_CHEM_DATE,19050616 -CA-Obs,28708,GRP_SOIL_CHEM,SOIL_CHEM_DATE,19050616 -CA-Obs,28878,GRP_SOIL_CHEM,SOIL_CHEM_DATE,19050616 -CA-Obs,28879,GRP_SOIL_CHEM,SOIL_CHEM_DATE,19050616 -CA-Obs,29239,GRP_SOIL_CHEM,SOIL_CHEM_DATE,19050616 -CA-Obs,29240,GRP_SOIL_CHEM,SOIL_CHEM_DATE,19050616 -CA-Obs,29241,GRP_SOIL_CHEM,SOIL_CHEM_DATE,19050616 -CA-Obs,29354,GRP_SOIL_CHEM,SOIL_CHEM_DATE,19050616 -CA-Obs,29355,GRP_SOIL_CHEM,SOIL_CHEM_DATE,19050616 -CA-Obs,29567,GRP_SOIL_CHEM,SOIL_CHEM_DATE,19050616 -CA-Obs,25714,GRP_SOIL_CHEM,SOIL_CHEM_DATE,1994 -CA-Obs,25834,GRP_SOIL_CHEM,SOIL_CHEM_DATE,1994 -CA-Obs,25835,GRP_SOIL_CHEM,SOIL_CHEM_DATE,1994 -CA-Obs,26113,GRP_SOIL_CHEM,SOIL_CHEM_DATE,1994 -CA-Obs,26215,GRP_SOIL_CHEM,SOIL_CHEM_DATE,1994 -CA-Obs,26344,GRP_SOIL_CHEM,SOIL_CHEM_DATE,1994 -CA-Obs,26468,GRP_SOIL_CHEM,SOIL_CHEM_DATE,1994 -CA-Obs,28025,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,(0.0045 gN/100g); soil thickness 0.30; measured by BOREAS -CA-Obs,29241,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,(0.005 gN/100g); soil thickness 0.25; measured by BOREAS -CA-Obs,28372,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,(0.022 gN/100g); soil thickness 0.12; measured by BOREAS -CA-Obs,29355,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,(0.042 gN/100g); soil thickness 0.03; measured by BOREAS -CA-Obs,28708,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,(0.06 gN/100g)oil thickness 0.02; measured by BOREAS -CA-Obs,28879,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,(0.085 gC/100g); soil thickness 0.30 m; measured by BOREAS -CA-Obs,28707,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,(0.14 gC/100g); soil thickness 0.25 m; measured by BOREAS -CA-Obs,29240,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,(0.46 gC/100g); soil thickness 0.12 m; measured by BOREAS -CA-Obs,27656,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,(1.028 gN/100g); soil thickness 0.1; measured by BOREAS -CA-Obs,29354,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,(1.03 gC/100g); soil thickness 0.03 m; measured by BOREAS -CA-Obs,28024,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,(1.3575 gN/100g); soil thickness 0.2; measured by BOREAS -CA-Obs,29239,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,(1.7 gC/100g); soil thickness 0.02 m; measured by BOREAS -CA-Obs,29567,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,(43.45 gC/100g); soil thickness 0.1 m; measured by BOREAS -CA-Obs,28878,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,(45.772 gC/100g); soil thickness 0.2 m; measured by BOREAS -CA-Obs,26215,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,soil thickness 0.02; measured by BOREAS -CA-Obs,25835,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,soil thickness 0.03; measured by BOREAS -CA-Obs,26344,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,soil thickness 0.1; measured by BOREAS -CA-Obs,25714,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,soil thickness 0.12; measured by BOREAS -CA-Obs,25834,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,soil thickness 0.2; measured by BOREAS -CA-Obs,26113,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,soil thickness 0.25; measured by BOREAS -CA-Obs,26468,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,soil thickness 0.30; measured by BOREAS -CA-Obs,23914,GRP_SOIL_DEPTH,SOIL_DEPTH,25 -CA-Obs,23914,GRP_SOIL_DEPTH,SOIL_DEPTH_COMMENT,"(range 0.2-0.3) Bergeron, O., H.A. Margolis, T.A. Black, C. Coursolle, A.L. Dunn, A.G. Barr and S.C. Wofsy. 2006. Comparison of carbon fluxes over three boreal black spruce forests in Canada. Global Change Biology. 12, 1-19" -CA-Obs,26462,GRP_SOIL_TEX,SOIL_TEX_SAND,64.6 -CA-Obs,25595,GRP_SOIL_TEX,SOIL_TEX_SAND,72.79 -CA-Obs,26599,GRP_SOIL_TEX,SOIL_TEX_SAND,75.56 -CA-Obs,25598,GRP_SOIL_TEX,SOIL_TEX_SAND,95.525 -CA-Obs,26114,GRP_SOIL_TEX,SOIL_TEX_SAND,95.98 -CA-Obs,26114,GRP_SOIL_TEX,SOIL_TEX_SILT,1.9 -CA-Obs,26599,GRP_SOIL_TEX,SOIL_TEX_SILT,19.96 -CA-Obs,25598,GRP_SOIL_TEX,SOIL_TEX_SILT,2.875 -CA-Obs,25595,GRP_SOIL_TEX,SOIL_TEX_SILT,21.42 -CA-Obs,26462,GRP_SOIL_TEX,SOIL_TEX_SILT,28.7 -CA-Obs,25949,GRP_SOIL_TEX,SOIL_TEX_CLAY,1.585 -CA-Obs,26114,GRP_SOIL_TEX,SOIL_TEX_CLAY,2.1 -CA-Obs,26599,GRP_SOIL_TEX,SOIL_TEX_CLAY,4.47 -CA-Obs,25595,GRP_SOIL_TEX,SOIL_TEX_CLAY,5.77 -CA-Obs,26462,GRP_SOIL_TEX,SOIL_TEX_CLAY,6.68 -CA-Obs,26599,GRP_SOIL_TEX,SOIL_TEX_PROFILE_MIN,0 -CA-Obs,26114,GRP_SOIL_TEX,SOIL_TEX_PROFILE_MIN,17 -CA-Obs,25595,GRP_SOIL_TEX,SOIL_TEX_PROFILE_MIN,2 -CA-Obs,25598,GRP_SOIL_TEX,SOIL_TEX_PROFILE_MIN,42 -CA-Obs,25949,GRP_SOIL_TEX,SOIL_TEX_PROFILE_MIN,42 -CA-Obs,26462,GRP_SOIL_TEX,SOIL_TEX_PROFILE_MIN,5 -CA-Obs,26462,GRP_SOIL_TEX,SOIL_TEX_PROFILE_MAX,17 -CA-Obs,26599,GRP_SOIL_TEX,SOIL_TEX_PROFILE_MAX,2 -CA-Obs,26114,GRP_SOIL_TEX,SOIL_TEX_PROFILE_MAX,42 -CA-Obs,25595,GRP_SOIL_TEX,SOIL_TEX_PROFILE_MAX,5 -CA-Obs,25598,GRP_SOIL_TEX,SOIL_TEX_PROFILE_MAX,72 -CA-Obs,25949,GRP_SOIL_TEX,SOIL_TEX_PROFILE_MAX,72 -CA-Obs,25595,GRP_SOIL_TEX,SOIL_TEX_HORIZON,AB -CA-Obs,26599,GRP_SOIL_TEX,SOIL_TEX_HORIZON,Ae -CA-Obs,26114,GRP_SOIL_TEX,SOIL_TEX_HORIZON,Bfj -CA-Obs,26462,GRP_SOIL_TEX,SOIL_TEX_HORIZON,Bt -CA-Obs,25598,GRP_SOIL_TEX,SOIL_TEX_HORIZON,Ck -CA-Obs,25949,GRP_SOIL_TEX,SOIL_TEX_HORIZON,Ck -CA-Obs,25595,GRP_SOIL_TEX,SOIL_TEX_COMMENT,measured by BOREAS -CA-Obs,25598,GRP_SOIL_TEX,SOIL_TEX_COMMENT,measured by BOREAS -CA-Obs,26114,GRP_SOIL_TEX,SOIL_TEX_COMMENT,measured by BOREAS -CA-Obs,26462,GRP_SOIL_TEX,SOIL_TEX_COMMENT,measured by BOREAS -CA-Obs,26599,GRP_SOIL_TEX,SOIL_TEX_COMMENT,measured by BOREAS -CA-Obs,25328,GRP_SPP_O,SPP_O,PIMA (NRCS plant code) -CA-Obs,25328,GRP_SPP_O,SPP_O_PERC,100 -CA-Obs,25328,GRP_SPP_O,SPP_DATE,2000 -CA-Obs,25328,GRP_SPP_O,SPP_COMMENT,followed Fluxnet-Canada protocol -CA-Obs,26109,GRP_SPP_U,SPP_U,PLEUR10 (NRCS plant code) -CA-Obs,26109,GRP_SPP_U,SPP_DATE,2000 -CA-Obs,26109,GRP_SPP_U,SPP_COMMENT,followed Fluxnet-Canada protocol -CA-Obs,29684,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,T. Andrew Black -CA-Obs,29684,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -CA-Obs,29684,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,andrew.black@ubc.ca -CA-Obs,29684,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,The University of British Columbia -CA-Obs,29790,GRP_TOWER_POWER,TOWER_POWER,Direct power -CA-Obs,29685,GRP_TOWER_TYPE,TOWER_TYPE,walk-up -CA-Obs,7748,GRP_URL,URL,http://berms.ccrp.ec.gc.ca/Sites/e-sites-obs.htm -CA-Obs,24000071,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/CA-Obs -CA-Obs,4443,GRP_UTC_OFFSET,UTC_OFFSET,-6 -CA-SF1,6738,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,"The data collection was funded by the Canadian Forest Service (Natural Resources Canada) and by Parks Canada as part of the BERMS (Boreal Ecosystem Research and Monitoring Sites) initiative in collaboration with the Fluxnet Canada Research Network and the Canadian Carbon Program (supported by the Canadian National Science and Engineering Research Council (NSERC), the Canadian Foundation for Climate and Atmospheric Sciences and the BIOCAP Canada Foundation)." -CA-SF1,6738,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT_COMMENT,When heavily using this site in a paper. -CA-SF1,23762,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER,4.08 -CA-SF1,23762,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_ORGAN,Total -CA-SF1,23762,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_PHEN,Mixed/unknown -CA-SF1,23762,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_UNIT,kgDM m-2 -CA-SF1,23762,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_COMMENT,"Live above ground -Carbon biomass (tC/ha): 20,4 -additional data see extra data sheet" -CA-SF1,26771,GRP_BIOMASS_CHEM,BIOMASS_N,0.095 -CA-SF1,26771,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -CA-SF1,26771,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -CA-SF1,26771,GRP_BIOMASS_CHEM,BIOMASS_SPP,(Unknown) -CA-SF1,26771,GRP_BIOMASS_CHEM,BIOMASS_COMMENT,+/- 0.06 -CA-SF1,3346,GRP_CLIM_AVG,MAT,0.4 -CA-SF1,3346,GRP_CLIM_AVG,MAP,470 -CA-SF1,3346,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfc -CA-SF1,27000075,GRP_COUNTRY,COUNTRY,Canada -CA-SF1,15622,GRP_DOI,DOI,10.17190/AMF/1246006 -CA-SF1,15622,GRP_DOI,DOI_CITATION,"Brian Amiro (2020), AmeriFlux BASE CA-SF1 Saskatchewan - Western Boreal, forest burned in 1977, Ver. 2-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1246006" -CA-SF1,15622,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -CA-SF1,31884,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -CA-SF1,31884,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Brian Amiro -CA-SF1,31884,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -CA-SF1,31884,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,Brian_Amiro@umanitoba.ca -CA-SF1,31884,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of Manitoba -CA-SF1,31886,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,University of Manitoba -CA-SF1,31886,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -CA-SF1,31885,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,"Canadian Forest Service, NSERC, BIOCAP Canada, Canadian Foundation for Climate and Atmospheric Science, Parks Canada" -CA-SF1,31885,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -CA-SF1,4157,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -CA-SF1,4157,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -CA-SF1,4157,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,2004 -CA-SF1,4157,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,2006 -CA-SF1,4157,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -CA-SF1,4157,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,Decommisioned -CA-SF1,23000075,GRP_HEADER,SITE_NAME,"Saskatchewan - Western Boreal, forest burned in 1977" -CA-SF1,88190,GRP_HEIGHTC,HEIGHTC,6 -CA-SF1,88190,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -CA-SF1,88190,GRP_HEIGHTC,HEIGHTC_DATE,20030701 -CA-SF1,88190,GRP_HEIGHTC,HEIGHTC_COMMENT,Described in Mkhabela et al. 2009. Agricultural and Forest Meteorology 149:783-794 -CA-SF1,2506,GRP_IGBP,IGBP,ENF -CA-SF1,24404,GRP_LAI,LAI_TYPE,LAI -CA-SF1,24404,GRP_LAI,LAI_COMMENT,2005 -CA-SF1,24404,GRP_LAI,LAI_TOT,3.4 -CA-SF1,1657,GRP_LOCATION,LOCATION_LAT,54.4850 -CA-SF1,1657,GRP_LOCATION,LOCATION_LONG,-105.8176 -CA-SF1,1657,GRP_LOCATION,LOCATION_ELEV,536 -CA-SF1,5062,GRP_NETWORK,NETWORK,AmeriFlux -CA-SF1,2510,GRP_NETWORK,NETWORK,Fluxnet-Canada -CA-SF1,1700006657,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Amiro, B. (2009) Measuring Boreal Forest Evapotranspiration Using The Energy Balance Residual, Journal Of Hydrology, 366(1-4), 112-118" -CA-SF1,1700006657,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.JHYDROL.2008.12.021 -CA-SF1,1700006657,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-SF1,1700006051,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Amiro, B. (2010) Estimating Annual Carbon Dioxide Eddy Fluxes Using Open-Path Analysers For Cold Forest Sites, Agricultural And Forest Meteorology, 150(10), 1366-1372" -CA-SF1,1700006051,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2010.06.007 -CA-SF1,1700006051,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-SF1,1700004284,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Amiro, B., Barr, A., Black, T., Iwashita, H., Kljun, N., Mccaughey, J., Morgenstern, K., Murayama, S., Nesic, Z., Orchansky, A. (2006) Carbon, Energy And Water Fluxes At Mature And Disturbed Forest Sites, Saskatchewan, Canada, Agricultural And Forest Meteorology, 136(3-4), 237-251" -CA-SF1,1700004284,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2004.11.012 -CA-SF1,1700004284,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-SF1,1700004368,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Amiro, B., Orchansky, A., Barr, A., Black, T., Chambers, S., Chapin III, F., Goulden, M., Litvak, M., Liu, H., McCaughey, J., McMillan, A., Randerson, J. (2006) The Effect Of Post-Fire Stand Age On The Boreal Forest Energy Balance, Agricultural And Forest Meteorology, 140(1-4), 41-50" -CA-SF1,1700004368,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2006.02.014 -CA-SF1,1700004368,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-SF1,1700007122,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Amiro, B.D., Barr, A.G., Barr, J.G., Black, T.A., Bracho, R., Brown, M., Chen, J., Clark, K.L., Davis, K.J., Desai, A.R., Dore, S., Engel, V., Fuentes, J.D., Goldstein, A.H., Goulden, M.L., Kolb, T.E., Lavigne, M.B., Law, B.E., Margolis, H.A., Martin, T., McCaughey, J.H., Misson, L., Montes-Helu, M., Noormets, A., Randerson, J.T., Starr, G., Xiao, J. (2010) Ecosystem Carbon Dioxide Fluxes After Disturbance In Forests Of North America, Journal Of Geophysical Research, 115(G00K02), n/a-n/a" -CA-SF1,1700007122,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2010JG001390 -CA-SF1,1700007122,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-SF1,1700002511,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Baldocchi, D., Penuelas, J. (2018) The Physics And Ecology Of Mining Carbon Dioxide From The Atmosphere By Ecosystems, Global Change Biology, 301-302(1-4), 108350" -CA-SF1,1700002511,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/GCB.14559 -CA-SF1,1700002511,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-SF1,1700000162,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Baldocchi, D., Penuelas, J. (2018) The Physics And Ecology Of Mining Carbon Dioxide From The Atmosphere By Ecosystems, Global Change Biology, 366(1-4), 112-118" -CA-SF1,1700000162,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/GCB.14559 -CA-SF1,1700000162,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-SF1,1700009063,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(1-4), 108350" -CA-SF1,1700009063,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -CA-SF1,1700009063,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-SF1,1700008427,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Mkhabela, M., Amiro, B., Barr, A., Black, T., Hawthorne, I., Kidston, J., McCaughey, J., Orchansky, A., Nesic, Z., Sass, A., Shashkov, A., Zha, T. (2009) Comparison Of Carbon Dynamics And Water Use Efficiency Following Fire And Harvesting In Canadian Boreal Forests, Agricultural And Forest Meteorology, 149(5), 783-794" -CA-SF1,1700008427,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2008.10.025 -CA-SF1,1700008427,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Primary_Citation -CA-SF1,24819,GRP_SA,SA,30 -CA-SF1,24819,GRP_SA,SA_COMMENT,Template: … regenerated after 1977 fire -CA-SF1,1654,GRP_SITE_CHAR,TERRAIN,Flat -CA-SF1,5902,GRP_SITE_DESC,SITE_DESC,"Regenerated jack pine (Pinus banksiana) following fire in 1977; canopy height 6 m and LAI = 2.8. Some black spruce understory developing. Trees tend to be clumpy, with some clear spaces that can be easily walked thorugh, and other areas are thick. Fire killed coarse woody debris on the ground, that is soft and decomposing. Very few perched trunks. Understory are short shrubs such as Vaccinium and Arctostaphylus uva-ursi." -CA-SF1,10184,GRP_SITE_FUNDING,SITE_FUNDING,"Canadian Forest Service, NSERC, BIOCAP Canada, Canadian Foundation for Climate and Atmospheric Science, Parks Canada" -CA-SF1,26916,GRP_SOIL_CHEM,SOIL_CHEM_N_TOT,1.43 -CA-SF1,23923,GRP_SPP_O,SPP_O,"Jackpine (7m tall) and Black Spruce (2-3 m), regenerated after 1977 fire" -CA-SF1,1647,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Brian Amiro -CA-SF1,1647,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -CA-SF1,1647,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,Brian_Amiro@umanitoba.ca -CA-SF1,1647,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Manitoba -CA-SF1,24000075,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/CA-SF1 -CA-SF1,794,GRP_UTC_OFFSET,UTC_OFFSET,-6 -CA-SF2,2496,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,"The data collection was funded by the Canadian Forest Service (Natural Resources Canada) and by Parks Canada as part of the BERMS (Boreal Ecosystem Research and Monitoring Sites) initiative in collaboration with the Fluxnet Canada Research Network and the Canadian Carbon Program (supported by the Canadian National Science and Engineering Research Council (NSERC), the Canadian Foundation for Climate and Atmospheric Sciences and the BIOCAP Canada Foundation)." -CA-SF2,2496,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT_COMMENT,When heavily using this site in a paper. -CA-SF2,23632,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER,1.686 -CA-SF2,23632,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_ORGAN,Total -CA-SF2,23632,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_PHEN,Mixed/unknown -CA-SF2,23632,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_UNIT,kgDM m-2 -CA-SF2,23632,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_COMMENT,"Live above ground -Carbon biomass (tC/ha): 8,43 -additional data see extra data sheet" -CA-SF2,28830,GRP_BIOMASS_CHEM,BIOMASS_N,0.107 -CA-SF2,28830,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -CA-SF2,28830,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -CA-SF2,28830,GRP_BIOMASS_CHEM,BIOMASS_SPP,(Unknown) -CA-SF2,28830,GRP_BIOMASS_CHEM,BIOMASS_COMMENT,+/-0.03; deciduous and coniferous trees -CA-SF2,785,GRP_CLIM_AVG,MAT,0.4 -CA-SF2,785,GRP_CLIM_AVG,MAP,470 -CA-SF2,785,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfc -CA-SF2,27000076,GRP_COUNTRY,COUNTRY,Canada -CA-SF2,15649,GRP_DOI,DOI,10.17190/AMF/1246007 -CA-SF2,15649,GRP_DOI,DOI_CITATION,"Brian Amiro (2019), AmeriFlux BASE CA-SF2 Saskatchewan - Western Boreal, forest burned in 1989, Ver. 3-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1246007" -CA-SF2,15649,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -CA-SF2,31887,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -CA-SF2,31887,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Brian Amiro -CA-SF2,31887,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -CA-SF2,31887,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,Brian_Amiro@umanitoba.ca -CA-SF2,31887,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of Manitoba -CA-SF2,31889,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,University of Manitoba -CA-SF2,31889,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -CA-SF2,31888,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,"Canadian Forest Service, Canadian Foundation for Climate and Atmospheric Science, NSERC, Parks Canada, BIOCAP Canada" -CA-SF2,31888,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -CA-SF2,3354,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -CA-SF2,3354,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -CA-SF2,3354,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,2001 -CA-SF2,3354,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,2005 -CA-SF2,3354,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -CA-SF2,3354,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,Decommissioned -CA-SF2,23000076,GRP_HEADER,SITE_NAME,"Saskatchewan - Western Boreal, forest burned in 1989" -CA-SF2,88191,GRP_HEIGHTC,HEIGHTC,4 -CA-SF2,88191,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -CA-SF2,88191,GRP_HEIGHTC,HEIGHTC_DATE,20030701 -CA-SF2,88191,GRP_HEIGHTC,HEIGHTC_COMMENT,Described in Mkhabela et al. 2009. Agricultural and Forest Meteorology 149:783-794 -CA-SF2,1655,GRP_IGBP,IGBP,ENF -CA-SF2,23892,GRP_LAI,LAI_TYPE,LAI -CA-SF2,23892,GRP_LAI,LAI_COMMENT,2005 -CA-SF2,23892,GRP_LAI,LAI_TOT,3 -CA-SF2,790,GRP_LOCATION,LOCATION_LAT,54.2539 -CA-SF2,790,GRP_LOCATION,LOCATION_LONG,-105.8775 -CA-SF2,790,GRP_LOCATION,LOCATION_ELEV,520 -CA-SF2,780,GRP_NETWORK,NETWORK,AmeriFlux -CA-SF2,8458,GRP_NETWORK,NETWORK,Fluxnet-Canada -CA-SF2,1700002373,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Amiro, B. (2009) Measuring Boreal Forest Evapotranspiration Using The Energy Balance Residual, Journal Of Hydrology, 366(1-4), 112-118" -CA-SF2,1700002373,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.JHYDROL.2008.12.021 -CA-SF2,1700002373,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-SF2,1700003084,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Amiro, B. (2010) Estimating Annual Carbon Dioxide Eddy Fluxes Using Open-Path Analysers For Cold Forest Sites, Agricultural And Forest Meteorology, 150(10), 1366-1372" -CA-SF2,1700003084,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2010.06.007 -CA-SF2,1700003084,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-SF2,1700004785,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Amiro, B. D. (2001) Paired-Tower Measurements Of Carbon And Energy Fluxes Following Disturbance In The Boreal Forest, Global Change Biology, 7(3), 253-268" -CA-SF2,1700004785,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1046/J.1365-2486.2001.00398.X -CA-SF2,1700004785,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-SF2,1700006207,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Amiro, B. D., Ian MacPherson, J., Desjardins, R. L., Chen, J. M., Liu, J. (2003) Post-Fire Carbon Dioxide Fluxes In The Western Canadian Boreal Forest: Evidence From Towers, Aircraft And Remote Sensing, Agricultural And Forest Meteorology, 115(1-2), 91-107" -CA-SF2,1700006207,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/S0168-1923(02)00170-3 -CA-SF2,1700006207,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-SF2,1700000078,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Amiro, B., Barr, A., Black, T., Iwashita, H., Kljun, N., Mccaughey, J., Morgenstern, K., Murayama, S., Nesic, Z., Orchansky, A. (2006) Carbon, Energy And Water Fluxes At Mature And Disturbed Forest Sites, Saskatchewan, Canada, Agricultural And Forest Meteorology, 136(3-4), 237-251" -CA-SF2,1700000078,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2004.11.012 -CA-SF2,1700000078,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-SF2,1700000348,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Amiro, B., Orchansky, A., Barr, A., Black, T., Chambers, S., Chapin III, F., Goulden, M., Litvak, M., Liu, H., McCaughey, J., McMillan, A., Randerson, J. (2006) The Effect Of Post-Fire Stand Age On The Boreal Forest Energy Balance, Agricultural And Forest Meteorology, 140(1-4), 41-50" -CA-SF2,1700000348,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2006.02.014 -CA-SF2,1700000348,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-SF2,1700004662,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Amiro, B.D., Barr, A.G., Barr, J.G., Black, T.A., Bracho, R., Brown, M., Chen, J., Clark, K.L., Davis, K.J., Desai, A.R., Dore, S., Engel, V., Fuentes, J.D., Goldstein, A.H., Goulden, M.L., Kolb, T.E., Lavigne, M.B., Law, B.E., Margolis, H.A., Martin, T., McCaughey, J.H., Misson, L., Montes-Helu, M., Noormets, A., Randerson, J.T., Starr, G., Xiao, J. (2010) Ecosystem Carbon Dioxide Fluxes After Disturbance In Forests Of North America, Journal Of Geophysical Research, 115(G00K02), n/a-n/a" -CA-SF2,1700004662,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2010JG001390 -CA-SF2,1700004662,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-SF2,1700005436,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Baldocchi, D., Penuelas, J. (2018) The Physics And Ecology Of Mining Carbon Dioxide From The Atmosphere By Ecosystems, Global Change Biology, 26(2), 901-918" -CA-SF2,1700005436,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/GCB.14559 -CA-SF2,1700005436,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-SF2,1700008298,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Baldocchi, D., Penuelas, J. (2018) The Physics And Ecology Of Mining Carbon Dioxide From The Atmosphere By Ecosystems, Global Change Biology, 366(1-4), 112-118" -CA-SF2,1700008298,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/GCB.14559 -CA-SF2,1700008298,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-SF2,1700001677,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(1-4), 108350" -CA-SF2,1700001677,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -CA-SF2,1700001677,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-SF2,1700008067,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Mkhabela, M., Amiro, B., Barr, A., Black, T., Hawthorne, I., Kidston, J., McCaughey, J., Orchansky, A., Nesic, Z., Sass, A., Shashkov, A., Zha, T. (2009) Comparison Of Carbon Dynamics And Water Use Efficiency Following Fire And Harvesting In Canadian Boreal Forests, Agricultural And Forest Meteorology, 149(5), 783-794" -CA-SF2,1700008067,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2008.10.025 -CA-SF2,1700008067,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Primary_Citation -CA-SF2,1700004929,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Rayment, M. B., Jarvis, P. G. (1999) Seasonal Gas Exchange Of Black Spruce Using An Automatic Branch Bag System, Canadian Journal Of Forest Research, 29(10), 1528-1538" -CA-SF2,1700004929,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1139/CJFR-29-10-1528 -CA-SF2,1700004929,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-SF2,1700008175,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Xu, B., Arain, M. A., Black, T. A., Law, B. E., Pastorello, G. Z., Chu, H. (2020) Seasonal Variability Of Forest Sensitivity To Heat And Drought Stresses: A Synthesis Based On Carbon Fluxes From North American Forest Ecosystems, Global Change Biology, 26(2), 901-918" -CA-SF2,1700008175,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/GCB.14843 -CA-SF2,1700008175,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-SF2,24429,GRP_SA,SA,17 -CA-SF2,24429,GRP_SA,SA_COMMENT,Template: … regenerated after 1989 fire -CA-SF2,787,GRP_SITE_CHAR,TERRAIN,Flat -CA-SF2,5058,GRP_SITE_DESC,SITE_DESC,"Amiro_et_al_2006, AFM/136:...The 1989 burn site (F89) was northeast of Prince Albert National Park, Saskatchewan, with the humancaused fire covering 13,500 ha. Parts of the area had been logged prior to the fire, and slash residues would have been burned in some locations. Parts of the area were aerially seeded with jack pine seeds in the winter of 1990. The present tree canopy was composed of balsam poplar (Populus balsamifera L.), jack pine, trembling aspen, and birch (Betula papyrifera Marsh.) and prior to the fire, the stand consisted of these same species aswell asblack spruce.Deadsnags of black spruce and jack pinewere still standing, althoughmost had fallen over and formed a leaningmix of dry, dead tree boles. The understory vegetation consisted mostly of black spruce saplings, saplings of the tree overstory species, bearberry, blueberry (Vaccinium myrtilloides Michx.), raspberry (Rubus idaeus L.), rose (Rosa acicularis Lindl.), bunchberry (Cornus canadensis L.), and reed grass (Calamagrostis canadensis (Michx.) Nutt.)." -CA-SF2,9347,GRP_SITE_FUNDING,SITE_FUNDING,"Canadian Forest Service, Canadian Foundation for Climate and Atmospheric Science, NSERC, Parks Canada, BIOCAP Canada" -CA-SF2,28831,GRP_SOIL_CHEM,SOIL_CHEM_N_TOT,1.93 -CA-SF2,28831,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,+/-0.046 -CA-SF2,24423,GRP_SPP_O,SPP_O,"Young jackpine, black spruce, trembling poplar, balsam poplar, regenerated after 1989 fire" -CA-SF2,7603,GRP_STATE,STATE,Saskatchewan -CA-SF2,3345,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Brian Amiro -CA-SF2,3345,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -CA-SF2,3345,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,Brian_Amiro@umanitoba.ca -CA-SF2,3345,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Manitoba -CA-SF2,24000076,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/CA-SF2 -CA-SF2,6748,GRP_UTC_OFFSET,UTC_OFFSET,-6 -CA-SF3,1646,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,"The data collection was funded by the Canadian Forest Service (Natural Resources Canada) and by Parks Canada as part of the BERMS (Boreal Ecosystem Research and Monitoring Sites) initiative in collaboration with the Fluxnet Canada Research Network and the Canadian Carbon Program (supported by the Canadian National Science and Engineering Research Council (NSERC), the Canadian Foundation for Climate and Atmospheric Sciences and the BIOCAP Canada Foundation)." -CA-SF3,1646,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT_COMMENT,When heavily using this site in a paper. -CA-SF3,24656,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER,0.13 -CA-SF3,24656,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_ORGAN,Total -CA-SF3,24656,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_PHEN,Mixed/unknown -CA-SF3,24656,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_UNIT,kgDM m-2 -CA-SF3,24656,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_COMMENT,"Live above ground -Carbon biomass (tC/ha): 0,65 -additional data see extra data sheet" -CA-SF3,26772,GRP_BIOMASS_CHEM,BIOMASS_N,0.135 -CA-SF3,26772,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -CA-SF3,26772,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -CA-SF3,26772,GRP_BIOMASS_CHEM,BIOMASS_SPP,(Unknown) -CA-SF3,26772,GRP_BIOMASS_CHEM,BIOMASS_COMMENT,+/-0.14; young deciduous and coniferous trees -CA-SF3,8453,GRP_CLIM_AVG,MAT,0.4 -CA-SF3,8453,GRP_CLIM_AVG,MAP,470 -CA-SF3,8453,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfc -CA-SF3,27000077,GRP_COUNTRY,COUNTRY,Canada -CA-SF3,15655,GRP_DOI,DOI,10.17190/AMF/1246008 -CA-SF3,15655,GRP_DOI,DOI_CITATION,"Brian Amiro (2020), AmeriFlux BASE CA-SF3 Saskatchewan - Western Boreal, forest burned in 1998, Ver. 2-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1246008" -CA-SF3,15655,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -CA-SF3,31890,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -CA-SF3,31890,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Brian Amiro -CA-SF3,31890,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -CA-SF3,31890,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,Brian_Amiro@umanitoba.ca -CA-SF3,31890,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of Manitoba; Canadian Forest Service -CA-SF3,31892,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,University of Manitoba; Canadian Forest Service -CA-SF3,31892,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -CA-SF3,31891,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,"Canadian Forest Service, NSERC, Canadian Foundation for Climate and Atmospheric Science, BIOCAP Canada, Parks Canada" -CA-SF3,31891,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -CA-SF3,3355,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -CA-SF3,3355,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -CA-SF3,3355,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,2001 -CA-SF3,3355,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,2006 -CA-SF3,3355,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -CA-SF3,3355,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,Decommissioned -CA-SF3,23000077,GRP_HEADER,SITE_NAME,"Saskatchewan - Western Boreal, forest burned in 1998" -CA-SF3,88189,GRP_HEIGHTC,HEIGHTC,18 -CA-SF3,88189,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -CA-SF3,88189,GRP_HEIGHTC,HEIGHTC_DATE,20030701 -CA-SF3,88189,GRP_HEIGHTC,HEIGHTC_COMMENT,"This is the height of the dead tree canopy, caused by fire. There was a new growing understory of about 1 m height in 2003. Described in Mkhabela et al. 2009. Agricultural and Forest Meteorology 149:783-794" -CA-SF3,6517,GRP_IGBP,IGBP,OSH -CA-SF3,6517,GRP_IGBP,IGBP_COMMENT,Brian Amiro - site dominated by small shrubs so this should be the primary classification. ENF is the minor classification. (Deb) -CA-SF3,24272,GRP_LAI,LAI_TYPE,LAI -CA-SF3,24272,GRP_LAI,LAI_COMMENT,": -2004" -CA-SF3,24272,GRP_LAI,LAI_TOT,1.1 -CA-SF3,8455,GRP_LOCATION,LOCATION_LAT,54.0916 -CA-SF3,8455,GRP_LOCATION,LOCATION_LONG,-106.0053 -CA-SF3,8455,GRP_LOCATION,LOCATION_ELEV,540 -CA-SF3,10183,GRP_NETWORK,NETWORK,AmeriFlux -CA-SF3,5073,GRP_NETWORK,NETWORK,Fluxnet-Canada -CA-SF3,1700006981,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Amiro, B. (2009) Measuring Boreal Forest Evapotranspiration Using The Energy Balance Residual, Journal Of Hydrology, 366(1-4), 112-118" -CA-SF3,1700006981,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.JHYDROL.2008.12.021 -CA-SF3,1700006981,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-SF3,1700008952,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Amiro, B. (2010) Estimating Annual Carbon Dioxide Eddy Fluxes Using Open-Path Analysers For Cold Forest Sites, Agricultural And Forest Meteorology, 150(10), 1366-1372" -CA-SF3,1700008952,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2010.06.007 -CA-SF3,1700008952,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-SF3,1700005502,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Amiro, B. D. (2001) Paired-Tower Measurements Of Carbon And Energy Fluxes Following Disturbance In The Boreal Forest, Global Change Biology, 7(3), 253-268" -CA-SF3,1700005502,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1046/J.1365-2486.2001.00398.X -CA-SF3,1700005502,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-SF3,1700003435,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Amiro, B. D., Ian MacPherson, J., Desjardins, R. L., Chen, J. M., Liu, J. (2003) Post-Fire Carbon Dioxide Fluxes In The Western Canadian Boreal Forest: Evidence From Towers, Aircraft And Remote Sensing, Agricultural And Forest Meteorology, 115(1-2), 91-107" -CA-SF3,1700003435,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/S0168-1923(02)00170-3 -CA-SF3,1700003435,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-SF3,1700004455,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Amiro, B., Barr, A., Black, T., Iwashita, H., Kljun, N., Mccaughey, J., Morgenstern, K., Murayama, S., Nesic, Z., Orchansky, A. (2006) Carbon, Energy And Water Fluxes At Mature And Disturbed Forest Sites, Saskatchewan, Canada, Agricultural And Forest Meteorology, 136(3-4), 237-251" -CA-SF3,1700004455,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2004.11.012 -CA-SF3,1700004455,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-SF3,1700005688,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Amiro, B., Orchansky, A., Barr, A., Black, T., Chambers, S., Chapin III, F., Goulden, M., Litvak, M., Liu, H., McCaughey, J., McMillan, A., Randerson, J. (2006) The Effect Of Post-Fire Stand Age On The Boreal Forest Energy Balance, Agricultural And Forest Meteorology, 140(1-4), 41-50" -CA-SF3,1700005688,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2006.02.014 -CA-SF3,1700005688,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-SF3,1700002637,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Amiro, B.D., Barr, A.G., Barr, J.G., Black, T.A., Bracho, R., Brown, M., Chen, J., Clark, K.L., Davis, K.J., Desai, A.R., Dore, S., Engel, V., Fuentes, J.D., Goldstein, A.H., Goulden, M.L., Kolb, T.E., Lavigne, M.B., Law, B.E., Margolis, H.A., Martin, T., McCaughey, J.H., Misson, L., Montes-Helu, M., Noormets, A., Randerson, J.T., Starr, G., Xiao, J. (2010) Ecosystem Carbon Dioxide Fluxes After Disturbance In Forests Of North America, Journal Of Geophysical Research, 115(G00K02), n/a-n/a" -CA-SF3,1700002637,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2010JG001390 -CA-SF3,1700002637,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-SF3,1700002799,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Baldocchi, D., Penuelas, J. (2018) The Physics And Ecology Of Mining Carbon Dioxide From The Atmosphere By Ecosystems, Global Change Biology, 301-302(1-4), 108350" -CA-SF3,1700002799,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/GCB.14559 -CA-SF3,1700002799,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-SF3,1700008463,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Baldocchi, D., Penuelas, J. (2018) The Physics And Ecology Of Mining Carbon Dioxide From The Atmosphere By Ecosystems, Global Change Biology, 366(1-4), 112-118" -CA-SF3,1700008463,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/GCB.14559 -CA-SF3,1700008463,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-SF3,1700006087,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(1-4), 108350" -CA-SF3,1700006087,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -CA-SF3,1700006087,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-SF3,1700000483,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Mkhabela, M., Amiro, B., Barr, A., Black, T., Hawthorne, I., Kidston, J., McCaughey, J., Orchansky, A., Nesic, Z., Sass, A., Shashkov, A., Zha, T. (2009) Comparison Of Carbon Dynamics And Water Use Efficiency Following Fire And Harvesting In Canadian Boreal Forests, Agricultural And Forest Meteorology, 149(5), 783-794" -CA-SF3,1700000483,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2008.10.025 -CA-SF3,1700000483,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Primary_Citation -CA-SF3,1700005760,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Rayment, M. B., Jarvis, P. G. (1999) Seasonal Gas Exchange Of Black Spruce Using An Automatic Branch Bag System, Canadian Journal Of Forest Research, 29(10), 1528-1538" -CA-SF3,1700005760,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1139/CJFR-29-10-1528 -CA-SF3,1700005760,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-SF3,24820,GRP_SA,SA,9 -CA-SF3,24820,GRP_SA,SA_COMMENT,"Template: Young jackpine, black spruce and trembling aspen following 1998 fire" -CA-SF3,10187,GRP_SITE_CHAR,TERRAIN,Flat -CA-SF3,5059,GRP_SITE_DESC,SITE_DESC,"The 1998 burn site (F98) was in the east part of -Prince Albert National Park, Saskatchewan, in the -Waskesiu Fire, ignited by lightning that burned about -1700 ha in July 1998. The pre-fire forest consisted of -jack pine and black spruce stands, with some intermixed -aspen. The fire was severe, consuming much of the top layer of organic soil and killing all trees. In 2001, much -of the regenerating vegetation consisted of aspen -saplings about 1 m tall and shorter jack pine and black -spruce seedlings. An overstory of dead, leafless jack -pine trees dominated at a height of 18 m. Sparse grass -and herbs, such as fireweed (Epilobium angustifolium -L.) covered the ground. There were a large number of -fallen dead trees, mostly perched above the ground and -not decomposing quickly." -CA-SF3,8451,GRP_SITE_FUNDING,SITE_FUNDING,"Canadian Forest Service, NSERC, Canadian Foundation for Climate and Atmospheric Science, BIOCAP Canada, Parks Canada" -CA-SF3,27612,GRP_SOIL_CHEM,SOIL_CHEM_N_TOT,0.17 -CA-SF3,27612,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,+/-0.027; 0-50cm depth -CA-SF3,24812,GRP_SPP_O,SPP_O,"Young jackpine, black spruce and trembling aspen following 1998 fire" -CA-SF3,6742,GRP_STATE,STATE,Saskatchewan -CA-SF3,4149,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Brian Amiro -CA-SF3,4149,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -CA-SF3,4149,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,Brian_Amiro@umanitoba.ca -CA-SF3,4149,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Manitoba; Canadian Forest Service -CA-SF3,24000077,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/CA-SF3 -CA-SF3,7614,GRP_UTC_OFFSET,UTC_OFFSET,-6 -CA-TP1,28170,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER,66 -CA-TP1,28170,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_ORGAN,Total -CA-TP1,28170,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_PHEN,Mixed/unknown -CA-TP1,28170,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_UNIT,gC m-2 -CA-TP1,28170,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_APPROACH,Canadian national forest inventory protocol: clipping of 12 microplots (each 1m2). -CA-TP1,28170,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_DATE,20041001 -CA-TP1,28510,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER,86.6 -CA-TP1,28510,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_ORGAN,Total -CA-TP1,28510,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_PHEN,Mixed/unknown -CA-TP1,28510,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_UNIT,gC m-2 -CA-TP1,28510,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_APPROACH,Canadian national forest inventory protocol: clipping of 12 microplots (each 1m2). -CA-TP1,28510,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_DATE,20071016 -CA-TP1,29468,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,12.6933781131057 -CA-TP1,29468,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Foliage -CA-TP1,29468,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -CA-TP1,29468,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -CA-TP1,29468,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,"destructive tree sampling, upscaled to stand level using 1) site specific allometric equation [foliage biomass=0.011*(Diameter at base)^2.67] and 2) stem density (1683 stems ha-1) from inventory data" -CA-TP1,29468,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,20041001 -CA-TP1,27285,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,13.2052815210096 -CA-TP1,27285,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Wood -CA-TP1,27285,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -CA-TP1,27285,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -CA-TP1,27285,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,"destructive tree sampling, upscaled to stand level using 1) site specific allometric equation [stem biomass=0.006*(Diameter at base)^2.813] [branch biomass=0.004*(Diameter at base)^2.76] and 2) stem density (1683 stems ha-1) from inventory data" -CA-TP1,27285,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,20041001 -CA-TP1,26997,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,137.115397943449 -CA-TP1,26997,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Total -CA-TP1,26997,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -CA-TP1,26997,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -CA-TP1,26997,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,"destructive tree sampling, upscaled to stand level using 1) site specific allometric equation [aboveground live biomass=0.021*(Diameter at base)^2.73] and 2) stem density (1683 stems ha-1) from inventory data" -CA-TP1,26997,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,20050928 -CA-TP1,29469,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,145.293563420699 -CA-TP1,29469,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Foliage -CA-TP1,29469,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -CA-TP1,29469,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -CA-TP1,29469,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,"destructive tree sampling, upscaled to stand level using 1) site specific allometric equation [foliage biomass=0.011*(Diameter at base)^2.67] and 2) stem density (1683 stems ha-1) from inventory data" -CA-TP1,29469,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,20061002 -CA-TP1,29002,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,169.031896058935 -CA-TP1,29002,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Wood -CA-TP1,29002,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -CA-TP1,29002,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -CA-TP1,29002,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,"destructive tree sampling, upscaled to stand level using 1) site specific allometric equation [stem biomass=0.006*(Diameter at base)^2.813] [branch biomass=0.004*(Diameter at base)^2.76] and 2) stem density (1683 stems ha-1) from inventory data" -CA-TP1,29002,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,20061002 -CA-TP1,26848,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,222.212702795202 -CA-TP1,26848,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Foliage -CA-TP1,26848,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -CA-TP1,26848,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -CA-TP1,26848,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,"destructive tree sampling, upscaled to stand level using 1) site specific allometric equation [foliage biomass=0.011*(Diameter at base)^2.67] and 2) stem density (1683 stems ha-1) from inventory data" -CA-TP1,26848,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,20071016 -CA-TP1,28169,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,25.9681258325829 -CA-TP1,28169,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Total -CA-TP1,28169,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -CA-TP1,28169,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -CA-TP1,28169,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,"destructive tree sampling, upscaled to stand level using 1) site specific allometric equation [aboveground live biomass=0.021*(Diameter at base)^2.73] and 2) stem density (1683 stems ha-1) from inventory data" -CA-TP1,28169,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,20041001 -CA-TP1,28509,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,263.668796831788 -CA-TP1,28509,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Wood -CA-TP1,28509,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -CA-TP1,28509,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -CA-TP1,28509,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,"destructive tree sampling, upscaled to stand level using 1) site specific allometric equation [stem biomass=0.006*(Diameter at base)^2.813] [branch biomass=0.004*(Diameter at base)^2.76] and 2) stem density (1683 stems ha-1) from inventory data" -CA-TP1,28509,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,20071016 -CA-TP1,28508,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,313.426839743818 -CA-TP1,28508,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Total -CA-TP1,28508,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -CA-TP1,28508,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -CA-TP1,28508,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,"destructive tree sampling, upscaled to stand level using 1) site specific allometric equation [aboveground live biomass=0.021*(Diameter at base)^2.73] and 2) stem density (1683 stems ha-1) from inventory data" -CA-TP1,28508,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,20061002 -CA-TP1,26712,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,483.849835247765 -CA-TP1,26712,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Total -CA-TP1,26712,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -CA-TP1,26712,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -CA-TP1,26712,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,"destructive tree sampling, upscaled to stand level using 1) site specific allometric equation [aboveground live biomass=0.021*(Diameter at base)^2.73] and 2) stem density (1683 stems ha-1) from inventory data" -CA-TP1,26712,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,20071016 -CA-TP1,28171,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,64.6881286174318 -CA-TP1,28171,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Foliage -CA-TP1,28171,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -CA-TP1,28171,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -CA-TP1,28171,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,"destructive tree sampling, upscaled to stand level using 1) site specific allometric equation [foliage biomass=0.011*(Diameter at base)^2.67] and 2) stem density (1683 stems ha-1) from inventory data" -CA-TP1,28171,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,20050928 -CA-TP1,27558,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,72.5165120038327 -CA-TP1,27558,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Wood -CA-TP1,27558,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -CA-TP1,27558,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -CA-TP1,27558,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,"destructive tree sampling, upscaled to stand level using 1) site specific allometric equation [stem biomass=0.006*(Diameter at base)^2.813] [branch biomass=0.004*(Diameter at base)^2.76] and 2) stem density (1683 stems ha-1) from inventory data" -CA-TP1,27558,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,20050928 -CA-TP1,27286,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS,82.8 -CA-TP1,27286,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_UNIT,gC m-2 -CA-TP1,27286,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_DATE,20040609 -CA-TP1,27286,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_COMMENT,LFH layer consist almost entirely of decomposing annual herbs -CA-TP1,28172,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS,93 -CA-TP1,28172,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_UNIT,gC m-2 -CA-TP1,28172,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_DATE,20070721 -CA-TP1,28172,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_COMMENT,LFH layer consist almost entirely of decomposing annual herbs -CA-TP1,28175,GRP_AG_PROD_OTHER,AG_PROD_OTHER,101 -CA-TP1,28175,GRP_AG_PROD_OTHER,AG_PROD_OTHER_ORGAN,Total -CA-TP1,28175,GRP_AG_PROD_OTHER,AG_PROD_OTHER_UNIT,gC m-2 -CA-TP1,28175,GRP_AG_PROD_OTHER,AG_PROD_DATE_START,20061002 -CA-TP1,28175,GRP_AG_PROD_OTHER,AG_PROD_COMMENT,total aboveground production is estimated from separate allom. Eq.- not as the sum of foliage + wood -CA-TP1,28512,GRP_AG_PROD_OTHER,AG_PROD_OTHER,101 -CA-TP1,28512,GRP_AG_PROD_OTHER,AG_PROD_OTHER_ORGAN,Total -CA-TP1,28512,GRP_AG_PROD_OTHER,AG_PROD_OTHER_UNIT,gC m-2 -CA-TP1,28512,GRP_AG_PROD_OTHER,AG_PROD_DATE_START,20050928 -CA-TP1,28512,GRP_AG_PROD_OTHER,AG_PROD_COMMENT,total aboveground production is estimated from separate allom. Eq.- not as the sum of foliage + wood -CA-TP1,29116,GRP_AG_PROD_OTHER,AG_PROD_OTHER,120 -CA-TP1,29116,GRP_AG_PROD_OTHER,AG_PROD_OTHER_ORGAN,Total -CA-TP1,29116,GRP_AG_PROD_OTHER,AG_PROD_OTHER_UNIT,gC m-2 -CA-TP1,29116,GRP_AG_PROD_OTHER,AG_PROD_DATE_START,20071016 -CA-TP1,29116,GRP_AG_PROD_OTHER,AG_PROD_COMMENT,total aboveground production is estimated from separate allom. Eq.- not as the sum of foliage + wood -CA-TP1,28173,GRP_AG_PROD_TREE,AG_PROD_TREE,112.405543115895 -CA-TP1,28173,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Total -CA-TP1,28173,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -CA-TP1,28173,GRP_AG_PROD_TREE,AG_PROD_APPROACH,difference between annual standing aboveground biomass stock -CA-TP1,28173,GRP_AG_PROD_TREE,AG_PROD_DATE_START,20050928 -CA-TP1,28173,GRP_AG_PROD_TREE,AG_PROD_COMMENT,total aboveground production is estimated from separate allom. Eq.- not as the sum of foliage + wood -CA-TP1,28514,GRP_AG_PROD_TREE,AG_PROD_TREE,172.35231243418 -CA-TP1,28514,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Total -CA-TP1,28514,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -CA-TP1,28514,GRP_AG_PROD_TREE,AG_PROD_APPROACH,difference between annual standing aboveground biomass stock -CA-TP1,28514,GRP_AG_PROD_TREE,AG_PROD_DATE_START,20071016 -CA-TP1,28514,GRP_AG_PROD_TREE,AG_PROD_COMMENT,total aboveground production is estimated from separate allom. Eq.- not as the sum of foliage + wood -CA-TP1,29004,GRP_AG_PROD_TREE,AG_PROD_TREE,178.307420386788 -CA-TP1,29004,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Total -CA-TP1,29004,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -CA-TP1,29004,GRP_AG_PROD_TREE,AG_PROD_APPROACH,difference between annual standing aboveground biomass stock -CA-TP1,29004,GRP_AG_PROD_TREE,AG_PROD_DATE_START,20061002 -CA-TP1,29004,GRP_AG_PROD_TREE,AG_PROD_COMMENT,total aboveground production is estimated from separate allom. Eq.- not as the sum of foliage + wood -CA-TP1,28279,GRP_AG_PROD_TREE,AG_PROD_TREE,53 -CA-TP1,28279,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Foliage -CA-TP1,28279,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -CA-TP1,28279,GRP_AG_PROD_TREE,AG_PROD_APPROACH,difference between annual standing foliage biomass stock -CA-TP1,28279,GRP_AG_PROD_TREE,AG_PROD_DATE_START,20050928 -CA-TP1,28279,GRP_AG_PROD_TREE,AG_PROD_COMMENT,total aboveground production is estimated from separate allom. Eq.- not as the sum of foliage + wood -CA-TP1,29115,GRP_AG_PROD_TREE,AG_PROD_TREE,59.6860561639001 -CA-TP1,29115,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Wood -CA-TP1,29115,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -CA-TP1,29115,GRP_AG_PROD_TREE,AG_PROD_APPROACH,difference between annual standing wood biomass stock -CA-TP1,29115,GRP_AG_PROD_TREE,AG_PROD_DATE_START,20050928 -CA-TP1,29115,GRP_AG_PROD_TREE,AG_PROD_COMMENT,total aboveground production is estimated from separate allom. Eq.- not as the sum of foliage + wood -CA-TP1,28513,GRP_AG_PROD_TREE,AG_PROD_TREE,77.7899220844034 -CA-TP1,28513,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Foliage -CA-TP1,28513,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -CA-TP1,28513,GRP_AG_PROD_TREE,AG_PROD_APPROACH,difference between annual standing foliage biomass stock -CA-TP1,28513,GRP_AG_PROD_TREE,AG_PROD_DATE_START,20071016 -CA-TP1,28513,GRP_AG_PROD_TREE,AG_PROD_COMMENT,total aboveground production is estimated from separate allom. Eq.- not as the sum of foliage + wood -CA-TP1,27908,GRP_AG_PROD_TREE,AG_PROD_TREE,81.5179491595306 -CA-TP1,27908,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Foliage -CA-TP1,27908,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -CA-TP1,27908,GRP_AG_PROD_TREE,AG_PROD_APPROACH,difference between annual standing foliage biomass stock -CA-TP1,27908,GRP_AG_PROD_TREE,AG_PROD_DATE_START,20061002 -CA-TP1,27908,GRP_AG_PROD_TREE,AG_PROD_COMMENT,total aboveground production is estimated from separate allom. Eq.- not as the sum of foliage + wood -CA-TP1,26851,GRP_AG_PROD_TREE,AG_PROD_TREE,95.2336551643891 -CA-TP1,26851,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Wood -CA-TP1,26851,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -CA-TP1,26851,GRP_AG_PROD_TREE,AG_PROD_APPROACH,difference between annual standing wood biomass stock -CA-TP1,26851,GRP_AG_PROD_TREE,AG_PROD_DATE_START,20071016 -CA-TP1,26851,GRP_AG_PROD_TREE,AG_PROD_COMMENT,total aboveground production is estimated from separate allom. Eq.- not as the sum of foliage + wood -CA-TP1,27560,GRP_AG_PROD_TREE,AG_PROD_TREE,97.124463949211 -CA-TP1,27560,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Wood -CA-TP1,27560,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -CA-TP1,27560,GRP_AG_PROD_TREE,AG_PROD_APPROACH,difference between annual standing wood biomass stock -CA-TP1,27560,GRP_AG_PROD_TREE,AG_PROD_DATE_START,20061002 -CA-TP1,27560,GRP_AG_PROD_TREE,AG_PROD_COMMENT,total aboveground production is estimated from separate allom. Eq.- not as the sum of foliage + wood -CA-TP1,26715,GRP_BIOMASS_CHEM,BIOMASS_N,0.213 -CA-TP1,26715,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -CA-TP1,26715,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -CA-TP1,26715,GRP_BIOMASS_CHEM,BIOMASS_SPP,PIST (NRCS plant code) -CA-TP1,26715,GRP_BIOMASS_CHEM,BIOMASS_DATE,20050920 -CA-TP1,12125,GRP_CLIM_AVG,MAT,8 -CA-TP1,12125,GRP_CLIM_AVG,MAP,1036 -CA-TP1,12125,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfb -CA-TP1,27000082,GRP_COUNTRY,COUNTRY,Canada -CA-TP1,1129,GRP_DM_INS_PATH,DM_INS_PATH,Other -CA-TP1,1129,GRP_DM_INS_PATH,DM_DATE,2004 -CA-TP1,5378,GRP_DM_PLANTING,DM_PLANTING,Planting live trees -CA-TP1,5378,GRP_DM_PLANTING,DM_DATE,20020501 -CA-TP1,15648,GRP_DOI,DOI,10.17190/AMF/1246009 -CA-TP1,15648,GRP_DOI,DOI_CITATION,"M. Altaf Arain (2018), AmeriFlux BASE CA-TP1 Ontario - Turkey Point 2002 Plantation White Pine, Ver. 3-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1246009" -CA-TP1,15648,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -CA-TP1,31893,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -CA-TP1,31893,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,M. Altaf Arain -CA-TP1,31893,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -CA-TP1,31893,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,arainm@mcmaster.ca -CA-TP1,31893,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,McMaster University -CA-TP1,31895,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,McMaster University -CA-TP1,31895,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -CA-TP1,92922,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Canadian Foundation for Climate and Atmospheric Sciences (CFCAS) -CA-TP1,92922,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -CA-TP1,92929,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Canadian Foundation of Innovation (CFI) -CA-TP1,92929,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -CA-TP1,92932,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Global Water Futures (GWF) Program -CA-TP1,92932,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -CA-TP1,92935,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Natural Sciences and Engineering Research Council (NSREC) of Canada -CA-TP1,92935,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -CA-TP1,92930,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Ontario Innovation Trust (OIT) -CA-TP1,92930,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -CA-TP1,92921,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,"Ontario Ministry of the Environment, Conservation and Parks (MOECP)" -CA-TP1,92921,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -CA-TP1,12140,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Forestry -CA-TP1,12126,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Pests and disease -CA-TP1,12127,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -CA-TP1,12127,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -CA-TP1,12127,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,2003 -CA-TP1,12127,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -CA-TP1,12144,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -CA-TP1,12144,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -CA-TP1,12144,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,2003 -CA-TP1,12144,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -CA-TP1,12141,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -CA-TP1,12141,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -CA-TP1,12141,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,2003 -CA-TP1,12141,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -CA-TP1,23000082,GRP_HEADER,SITE_NAME,Ontario - Turkey Point 2002 Plantation White Pine -CA-TP1,89099,GRP_HEIGHTC,HEIGHTC,0.95 -CA-TP1,89099,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -CA-TP1,89099,GRP_HEIGHTC,HEIGHTC_DATE,20041001 -CA-TP1,89103,GRP_HEIGHTC,HEIGHTC,1.37 -CA-TP1,89103,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -CA-TP1,89103,GRP_HEIGHTC,HEIGHTC_DATE,20050928 -CA-TP1,89096,GRP_HEIGHTC,HEIGHTC,2.01 -CA-TP1,89096,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -CA-TP1,89096,GRP_HEIGHTC,HEIGHTC_DATE,20061002 -CA-TP1,89097,GRP_HEIGHTC,HEIGHTC,2.83 -CA-TP1,89097,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -CA-TP1,89097,GRP_HEIGHTC,HEIGHTC_DATE,20071016 -CA-TP1,89098,GRP_HEIGHTC,HEIGHTC,3.57 -CA-TP1,89098,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -CA-TP1,89098,GRP_HEIGHTC,HEIGHTC_DATE,20081025 -CA-TP1,89102,GRP_HEIGHTC,HEIGHTC,3.81 -CA-TP1,89102,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -CA-TP1,89102,GRP_HEIGHTC,HEIGHTC_DATE,20091116 -CA-TP1,89104,GRP_HEIGHTC,HEIGHTC,5.07 -CA-TP1,89104,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -CA-TP1,89104,GRP_HEIGHTC,HEIGHTC_DATE,20111015 -CA-TP1,89101,GRP_HEIGHTC,HEIGHTC,5.79 -CA-TP1,89101,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -CA-TP1,89101,GRP_HEIGHTC,HEIGHTC_DATE,20121026 -CA-TP1,89100,GRP_HEIGHTC,HEIGHTC,6.5 -CA-TP1,89100,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -CA-TP1,89100,GRP_HEIGHTC,HEIGHTC_DATE,20151020 -CA-TP1,12128,GRP_IGBP,IGBP,ENF -CA-TP1,12128,GRP_IGBP,IGBP_COMMENT,Plantation -CA-TP1,29001,GRP_LAI,LAI_TYPE,LAI -CA-TP1,29001,GRP_LAI,LAI_METHOD,LAI_2000 -CA-TP1,29001,GRP_LAI,LAI_DATE,20040517 -CA-TP1,29001,GRP_LAI,LAI_COMMENT,clumping index not accounted in LAI estimates -CA-TP1,29001,GRP_LAI,LAI_TOT,0.45 -CA-TP1,12129,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -CA-TP1,12129,GRP_LAND_OWNERSHIP,LAND_OWNER,Bruce Whitside -CA-TP1,25050,GRP_LMA,LMA,20.08 -CA-TP1,25050,GRP_LMA,LMA_SPP,(All) -CA-TP1,12130,GRP_LOCATION,LOCATION_LAT,42.6609 -CA-TP1,12130,GRP_LOCATION,LOCATION_LONG,-80.5595 -CA-TP1,12130,GRP_LOCATION,LOCATION_ELEV,265 -CA-TP1,23774,GRP_N_DEP,N_DEP_WET,0.7 -CA-TP1,23774,GRP_N_DEP,N_DEP_COMMENT,"7 (Canadian Acid Deposition Assessment 2004 ;Environment Canada, 2004)" -CA-TP1,26714,GRP_NEP,NEP,47020 -CA-TP1,26714,GRP_NEP,NEP_APPROACH,eddy-covariance technique -CA-TP1,26714,GRP_NEP,NEP_DATE_START,20020601 -CA-TP1,26714,GRP_NEP,NEP_DATE_END,20070601 -CA-TP1,12142,GRP_NETWORK,NETWORK,AmeriFlux -CA-TP1,12131,GRP_NETWORK,NETWORK,Fluxnet-Canada -CA-TP1,86943,GRP_NETWORK,NETWORK,Phenocam -CA-TP1,1700006420,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Arain, M. A., Restrepo-Coupe, N. (2005) Net Ecosystem Production In A Temperate Pine Plantation In Southeastern Canada, Agricultural And Forest Meteorology, 128(3-4), 223-241" -CA-TP1,1700006420,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2004.10.003 -CA-TP1,1700006420,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-TP1,1700007299,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Arain, M.A., Xu, B., Brodeur, J.J., Khomik, M., Peichl, M., Beamesderfer, E., Restrepo‑Coupe, N., Thorne, R. (2022) Heat and drought impact on carbon exchange in an age‑sequence of temperate pine forests, Ecological Processes, 11(7), 108350" -CA-TP1,1700007299,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1186/S13717-021-00349-7 -CA-TP1,1700007299,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-TP1,1700003855,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Arain, M.A., Xu, B., Brodeur, J.J., Khomik, M., Peichl, M., Beamesderfer, E., Restrepo‑Coupe, N., Thorne, R. (2022) Heat and drought impact on carbon exchange in an age‑sequence of temperate pine forests, Ecological Processes, 11(7), 9275–9287" -CA-TP1,1700003855,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1186/S13717-021-00349-7 -CA-TP1,1700003855,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-TP1,1700007509,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chan, F. C., Altaf Arain, M., Khomik, M., Brodeur, J. J., Peichl, M., Restrepo-Coupe, N., Thorne, R., Beamesderfer, E., McKenzie, S., Xu, B., Croft, H., Pejam, M., Trant, J., Kula, M., Skubel, R. (2018) Carbon, Water And Energy Exchange Dynamics Of A Young Pine Plantation Forest During The Initial Fourteen Years Of Growth, Forest Ecology And Management, 410(2), 12-26" -CA-TP1,1700007509,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.FORECO.2017.12.024 -CA-TP1,1700007509,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-TP1,1700005697,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chan, F. C., Altaf Arain, M., Khomik, M., Brodeur, J. J., Peichl, M., Restrepo-Coupe, N., Thorne, R., Beamesderfer, E., McKenzie, S., Xu, B., Croft, H., Pejam, M., Trant, J., Kula, M., Skubel, R. (2018) Carbon, Water And Energy Exchange Dynamics Of A Young Pine Plantation Forest During The Initial Fourteen Years Of Growth, Forest Ecology And Management, 410(7), 12-26" -CA-TP1,1700005697,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.FORECO.2017.12.024 -CA-TP1,1700005697,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-TP1,1700006504,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Baldocchi, D. D., Poindexter, C., Abraha, M., Desai, A. R., Bohrer, G., Arain, M. A., Griffis, T., Blanken, P. D., O'Halloran, T. L., Thomas, R. Q., Zhang, Q., Burns, S. P., Frank, J. M., Christian, D., Brown, S., Black, T. A., Gough, C. M., Law, B. E., Lee, X., Chen, J., Reed, D. E., Massman, W. J., Clark, K., Hatfield, J., Prueger, J., Bracho, R., Baker, J. M., Martin, T. A. (2018) Temporal Dynamics Of Aerodynamic Canopy Height Derived From Eddy Covariance Momentum Flux Data Across North American Flux Networks, Geophysical Research Letters, 45(18), 9275–9287" -CA-TP1,1700006504,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018GL079306 -CA-TP1,1700006504,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-TP1,1700003798,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Baldocchi, D. D., Poindexter, C., Abraha, M., Desai, A. R., Bohrer, G., Arain, M. A., Griffis, T., Blanken, P. D., O'Halloran, T. L., Thomas, R. Q., Zhang, Q., Burns, S. P., Frank, J. M., Christian, D., Brown, S., Black, T. A., Gough, C. M., Law, B. E., Lee, X., Chen, J., Reed, D. E., Massman, W. J., Clark, K., Hatfield, J., Prueger, J., Bracho, R., Baker, J. M., Martin, T. A. (2018) Temporal Dynamics Of Aerodynamic Canopy Height Derived From Eddy Covariance Momentum Flux Data Across North American Flux Networks, Geophysical Research Letters, 45(3), 9275–9287" -CA-TP1,1700003798,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018GL079306 -CA-TP1,1700003798,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-TP1,1700006744,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(3), 108350" -CA-TP1,1700006744,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -CA-TP1,1700006744,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-TP1,1700000177,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Coursolle, C., Margolis, H. A., Barr, A. G., Black, T. A., Amiro, B. D., McCaughey, J. H., Flanagan, L. B., Lafleur, P. M., Roulet, N. T., Bourque, C. P., Arain, M. A., Wofsy, S. C., Dunn, A., Morgenstern, K., Orchansky, A. L., Bernier, P. Y., Chen, J. M., Kidston, J., Saigusa, N., Hedstrom, N. (2006) Late-Summer Carbon Fluxes From Canadian Forests And Peatlands Along An East-–West Continental Transect, Canadian Journal Of Forest Research, 36(3), 783-800" -CA-TP1,1700000177,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1139/X05-270 -CA-TP1,1700000177,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-TP1,1700004398,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Coursolle, C., Margolis, H., Giasson, M., Bernier, P., Amiro, B., Arain, M., Barr, A., Black, T., Goulden, M., McCaughey, J., Chen, J., Dunn, A., Grant, R., Lafleur, P. (2012) Influence Of Stand Age On The Magnitude And Seasonality Of Carbon Fluxes In Canadian Forests, Agricultural And Forest Meteorology, 165(7-8), 136-148" -CA-TP1,1700004398,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2012.06.011 -CA-TP1,1700004398,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-TP1,1700002193,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Khomik, M., Arain, M. A., Brodeur, J. J., Peichl, M., Restrepo-Coupé, N., McLaren, J. D. (2010) Relative Contributions Of Soil, Foliar, And Woody Tissue Respiration To Total Ecosystem Respiration In Four Pine Forests Of Different Ages, Journal Of Geophysical Research: Biogeosciences, 115(G03024), n/a-n/a" -CA-TP1,1700002193,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2009JG001089 -CA-TP1,1700002193,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-TP1,1700006426,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"McKenzie, S. M., Pisaric, M. F., Arain, M. A. (2021) Comparison Of Tree-Ring Growth And Eddy Covariance-Based Ecosystem Productivities In Three Different-Aged Pine Plantation Forests, Trees, 35(2), 583-595" -CA-TP1,1700006426,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1007/S00468-020-02061-Z -CA-TP1,1700006426,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-TP1,1700006267,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"McLaren, J. D., Arain, M.A., Khomik, M., Peichl, M., Brodeur, J. (2008) Water Flux Components And Soil Water-Atmospheric Controls In A Temperate Pine Forest Growing In A Well-Drained Sandy Soil, Journal Of Geophysical Research, 113(G4), n/a-n/a" -CA-TP1,1700006267,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2007JG000653 -CA-TP1,1700006267,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-TP1,1700000270,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Peichl, M., Arain, M. A. (2006) Above- And Belowground Ecosystem Biomass And Carbon Pools In An Age-Sequence Of Temperate Pine Plantation Forests, Agricultural And Forest Meteorology, 140(1-4), 51-63" -CA-TP1,1700000270,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2006.08.004 -CA-TP1,1700000270,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-TP1,1700001380,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Peichl, M., Arain, M. A. (2007) Allometry And Partitioning Of Above- And Belowground Tree Biomass In An Age-Sequence Of White Pine Forests, Forest Ecology And Management, 253(1-3), 68-80" -CA-TP1,1700001380,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.FORECO.2007.07.003 -CA-TP1,1700001380,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-TP1,1700000558,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Peichl, M., Arain, M. A., Brodeur, J. J. (2010) Age Effects On Carbon Fluxes In Temperate Pine Forests, Agricultural And Forest Meteorology, 150(7-8), 1090-1101" -CA-TP1,1700000558,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2010.04.008 -CA-TP1,1700000558,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-TP1,1700001515,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Peichl, M., Arain, M.A., Ullah, S., Moore, T. (2010) Carbon Dioxide, Methane, And Nitrous Oxide Exchanges In An Age-Sequence Of Temperate Pine Forests, Global Change Biology, 16(8), 2198-2212" -CA-TP1,1700001515,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/J.1365-2486.2009.02066.X -CA-TP1,1700001515,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-TP1,1700001821,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Peichl, M., Brodeur, J. J., Khomik, M., Arain, M. A. (2010) Biometric And Eddy-Covariance Based Estimates Of Carbon Fluxes In An Age-Sequence Of Temperate Pine Forests, Agricultural And Forest Meteorology, 150(7-8), 952-965" -CA-TP1,1700001821,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2010.03.002 -CA-TP1,1700001821,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Primary_Citation -CA-TP1,1700003501,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Peichl, M., Moore, T. R., Arain, M. A., Dalva, M., Brodkey, D., McLaren, J. (2007) Concentrations And Fluxes Of Dissolved Organic Carbon In An Age-Sequence Of White Pine Forests In Southern Ontario, Canada, Biogeochemistry, 86(1), 1-17" -CA-TP1,1700003501,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1007/S10533-007-9138-7 -CA-TP1,1700003501,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-TP1,1700001359,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Restrepo, N. C., Arain, M. A. (2005) Energy And Water Exchanges From A Temperate Pine Plantation Forest, Hydrological Processes, 19(1), 27-49" -CA-TP1,1700001359,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/HYP.5758 -CA-TP1,1700001359,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-TP1,1700001761,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Skubel, R., Arain, M. A., Peichl, M., Brodeur, J. J., Khomik, M., Thorne, R., Trant, J., Kula, M. (2015) Age Effects On The Water-Use Efficiency And Water-Use Dynamics Of Temperate Pine Plantation Forests, Hydrological Processes, 29(18), 4100-4113" -CA-TP1,1700001761,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/HYP.10549 -CA-TP1,1700001761,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-TP1,1700006018,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Xu, B., Arain, M. A., Black, T. A., Law, B. E., Pastorello, G. Z., Chu, H. (2020) Seasonal Variability Of Forest Sensitivity To Heat And Drought Stresses: A Synthesis Based On Carbon Fluxes From North American Forest Ecosystems, Global Change Biology, 26(2), 901-918" -CA-TP1,1700006018,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/GCB.14843 -CA-TP1,1700006018,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-TP1,1700004740,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Yuan, F., Arain, M. A., Barr, A. G., Black, T. A., Bourque, C. P., Coursolle, C., Margolis, H. A., Mccaughey, J. H., Wofsy, S. C. (2008) Modeling Analysis Of Primary Controls On Net Ecosystem Productivity Of Seven Boreal And Temperate Coniferous Forests Across A Continental Transect, Global Change Biology, 14(8), 1765-1784" -CA-TP1,1700004740,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/J.1365-2486.2008.01612.X -CA-TP1,1700004740,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-TP1,28278,GRP_ROOT_BIOMASS,ROOT_BIOMASS_CRS,107.233018817814 -CA-TP1,26713,GRP_ROOT_BIOMASS,ROOT_BIOMASS_CRS,163.949961102859 -CA-TP1,29114,GRP_ROOT_BIOMASS,ROOT_BIOMASS_CRS,47.771599742635 -CA-TP1,26999,GRP_ROOT_BIOMASS,ROOT_BIOMASS_CRS,9.38541300878125 -CA-TP1,28511,GRP_ROOT_BIOMASS,ROOT_BIOMASS_FINE,10 -CA-TP1,26999,GRP_ROOT_BIOMASS,ROOT_BIOMASS_TOT,19.4 -CA-TP1,26713,GRP_ROOT_BIOMASS,ROOT_BIOMASS_UNIT,gC m-2 -CA-TP1,26999,GRP_ROOT_BIOMASS,ROOT_BIOMASS_UNIT,gC m-2 -CA-TP1,28278,GRP_ROOT_BIOMASS,ROOT_BIOMASS_UNIT,gC m-2 -CA-TP1,28511,GRP_ROOT_BIOMASS,ROOT_BIOMASS_UNIT,gC m-2 -CA-TP1,29114,GRP_ROOT_BIOMASS,ROOT_BIOMASS_UNIT,gC m-2 -CA-TP1,26713,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MIN,0 -CA-TP1,26999,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MIN,0 -CA-TP1,28278,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MIN,0 -CA-TP1,28511,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MIN,0 -CA-TP1,29114,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MIN,0 -CA-TP1,26713,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MAX,100 -CA-TP1,26999,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MAX,100 -CA-TP1,28278,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MAX,100 -CA-TP1,29114,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MAX,100 -CA-TP1,28511,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MAX,55 -CA-TP1,26713,GRP_ROOT_BIOMASS,ROOT_BIOMASS_APPROACH,"destructive tree sampling, upscaled to stand level using 1) site specific allometric equation (root biomass = 0.008 (Dbase) ^ 2.67) and 2) inventory data (1683 stems ha-1)" -CA-TP1,26999,GRP_ROOT_BIOMASS,ROOT_BIOMASS_APPROACH,"destructive tree sampling, upscaled to stand level using 1) site specific allometric equation (root biomass = 0.008 (Dbase) ^ 2.67) and 2) inventory data (1683 stems ha-1)" -CA-TP1,28278,GRP_ROOT_BIOMASS,ROOT_BIOMASS_APPROACH,"destructive tree sampling, upscaled to stand level using 1) site specific allometric equation (root biomass = 0.008 (Dbase) ^ 2.67) and 2) inventory data (1683 stems ha-1)" -CA-TP1,29114,GRP_ROOT_BIOMASS,ROOT_BIOMASS_APPROACH,"destructive tree sampling, upscaled to stand level using 1) site specific allometric equation (root biomass = 0.008 (Dbase) ^ 2.67) and 2) inventory data (1683 stems ha-1)" -CA-TP1,28511,GRP_ROOT_BIOMASS,ROOT_BIOMASS_APPROACH,soil coring -CA-TP1,26999,GRP_ROOT_BIOMASS,ROOT_BIOMASS_DATE,20041001 -CA-TP1,28511,GRP_ROOT_BIOMASS,ROOT_BIOMASS_DATE,20041001 -CA-TP1,29114,GRP_ROOT_BIOMASS,ROOT_BIOMASS_DATE,20050928 -CA-TP1,28278,GRP_ROOT_BIOMASS,ROOT_BIOMASS_DATE,20061002 -CA-TP1,26713,GRP_ROOT_BIOMASS,ROOT_BIOMASS_DATE,20071016 -CA-TP1,26999,GRP_ROOT_BIOMASS,ROOT_BIOMASS_COMMENT,"date is for Cr >2mm from allometric equation, FR <2mm from soil coring on DOY 184" -CA-TP1,28511,GRP_ROOT_BIOMASS,ROOT_BIOMASS_COMMENT,"date is for Cr >2mm from allometric equation, FR <2mm from soil coring on DOY 184" -CA-TP1,28174,GRP_ROOT_PROD,ROOT_PROD_CRS,38 -CA-TP1,28280,GRP_ROOT_PROD,ROOT_PROD_CRS,56 -CA-TP1,27909,GRP_ROOT_PROD,ROOT_PROD_CRS,58 -CA-TP1,27909,GRP_ROOT_PROD,ROOT_PROD_UNIT,gC m-2 -CA-TP1,28174,GRP_ROOT_PROD,ROOT_PROD_UNIT,gC m-2 -CA-TP1,28280,GRP_ROOT_PROD,ROOT_PROD_UNIT,gC m-2 -CA-TP1,27909,GRP_ROOT_PROD,ROOT_PROD_PROFILE_MIN,0 -CA-TP1,28174,GRP_ROOT_PROD,ROOT_PROD_PROFILE_MIN,0 -CA-TP1,28280,GRP_ROOT_PROD,ROOT_PROD_PROFILE_MIN,0 -CA-TP1,27909,GRP_ROOT_PROD,ROOT_PROD_PROFILE_MAX,100 -CA-TP1,28174,GRP_ROOT_PROD,ROOT_PROD_PROFILE_MAX,100 -CA-TP1,28280,GRP_ROOT_PROD,ROOT_PROD_PROFILE_MAX,100 -CA-TP1,27909,GRP_ROOT_PROD,ROOT_PROD_APPROACH,difference between annual root biomass stock -CA-TP1,28174,GRP_ROOT_PROD,ROOT_PROD_APPROACH,difference between annual root biomass stock -CA-TP1,28280,GRP_ROOT_PROD,ROOT_PROD_APPROACH,difference between annual root biomass stock -CA-TP1,28174,GRP_ROOT_PROD,ROOT_PROD_DATE_START,20050928 -CA-TP1,27909,GRP_ROOT_PROD,ROOT_PROD_DATE_START,20061002 -CA-TP1,28280,GRP_ROOT_PROD,ROOT_PROD_DATE_START,20071016 -CA-TP1,27909,GRP_ROOT_PROD,ROOT_PROD_COMMENT,total and coarse roots is >2mm -CA-TP1,28174,GRP_ROOT_PROD,ROOT_PROD_COMMENT,total and coarse roots is >2mm -CA-TP1,28280,GRP_ROOT_PROD,ROOT_PROD_COMMENT,total and coarse roots is >2mm -CA-TP1,29000,GRP_SA,SA_DATE,2008 -CA-TP1,29000,GRP_SA,SA_COMMENT,even-aged stand -CA-TP1,29000,GRP_SA,SA_MAX,6 -CA-TP1,29111,GRP_SA,SA,6 -CA-TP1,29111,GRP_SA,SA_DATE,2008 -CA-TP1,29111,GRP_SA,SA_COMMENT,Stand age in 2008 -CA-TP1,12133,GRP_SITE_CHAR,TERRAIN,Undulated/Variable -CA-TP1,12134,GRP_SITE_DESC,SITE_DESC,"Plantation established in 2002 on a former sandy agricultural field, which was abandoned three years prior to planting" -CA-TP1,12135,GRP_SITE_FUNDING,SITE_FUNDING,"Natural Sciences and Engineering Research Council (NSREC) of Canada, Ministry of Environment (MOE), Canadian Foundation for Climate and Atmospheric Sciences (CFCAS), Canadian Foundation of Innovation (CFI), Ontario Innovation Trust (OIT)" -CA-TP1,26849,GRP_SNAG_MASS,SNAG_MASS,0 -CA-TP1,26849,GRP_SNAG_MASS,SNAG_MASS_UNIT,gC m-2 -CA-TP1,26849,GRP_SNAG_MASS,SNAG_MASS_DATE,20061002 -CA-TP1,26850,GRP_SNAG_MASS,SNAG_MASS,0 -CA-TP1,26850,GRP_SNAG_MASS,SNAG_MASS_UNIT,gC m-2 -CA-TP1,26850,GRP_SNAG_MASS,SNAG_MASS_DATE,20071016 -CA-TP1,29003,GRP_SNAG_MASS,SNAG_MASS,0 -CA-TP1,29003,GRP_SNAG_MASS,SNAG_MASS_UNIT,gC m-2 -CA-TP1,29003,GRP_SNAG_MASS,SNAG_MASS_DATE,20050928 -CA-TP1,29113,GRP_SNAG_MASS,SNAG_MASS,0 -CA-TP1,29113,GRP_SNAG_MASS,SNAG_MASS_UNIT,gC m-2 -CA-TP1,29113,GRP_SNAG_MASS,SNAG_MASS_DATE,20041001 -CA-TP1,29117,GRP_SOIL_CHEM,SOIL_CHEM_C_ORG,37 -CA-TP1,28515,GRP_SOIL_CHEM,SOIL_CHEM_N_TOT,0.86 -CA-TP1,28516,GRP_SOIL_CHEM,SOIL_CHEM_PH_SALT,6 -CA-TP1,26716,GRP_SOIL_CHEM,SOIL_CHEM_PH_SALT,6.3 -CA-TP1,29005,GRP_SOIL_CHEM,SOIL_CHEM_BD,1.44 -CA-TP1,26716,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,0 -CA-TP1,28515,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,0 -CA-TP1,29005,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,0 -CA-TP1,29117,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,0 -CA-TP1,28516,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,10 -CA-TP1,28515,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,10 -CA-TP1,26716,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,20 -CA-TP1,29005,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,20 -CA-TP1,28516,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,30 -CA-TP1,29117,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,55 -CA-TP1,29005,GRP_SOIL_CHEM,SOIL_CHEM_DATE,20040702 -CA-TP1,29117,GRP_SOIL_CHEM,SOIL_CHEM_DATE,20040702 -CA-TP1,26716,GRP_SOIL_CHEM,SOIL_CHEM_DATE,20060706 -CA-TP1,28515,GRP_SOIL_CHEM,SOIL_CHEM_DATE,20060706 -CA-TP1,28516,GRP_SOIL_CHEM,SOIL_CHEM_DATE,20060706 -CA-TP1,26716,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,pH (CaCl) -CA-TP1,28516,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,pH (CaCl) -CA-TP1,24282,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION,brunisolic grey brown luvisol -CA-TP1,24282,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION_TAXONOMY,Other -CA-TP1,24282,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION_COMMENT," ->3m" -CA-TP1,29006,GRP_SOIL_DEPTH,SOIL_DEPTH,300 -CA-TP1,29317,GRP_SOIL_DEPTH,SOIL_DEPTH,300 -CA-TP1,27561,GRP_SOIL_TEX,SOIL_TEX_SAND,98 -CA-TP1,27561,GRP_SOIL_TEX,SOIL_TEX_SILT,2 -CA-TP1,27561,GRP_SOIL_TEX,SOIL_TEX_CLAY,0 -CA-TP1,27561,GRP_SOIL_TEX,SOIL_TEX_COMMENT,sieving method -CA-TP1,29467,GRP_SPP_O,SPP_O,PIST (NRCS plant code) -CA-TP1,29467,GRP_SPP_O,SPP_O_PERC,100 -CA-TP1,29467,GRP_SPP_O,SPP_APPROACH,Canadian national forest inventory protocol: full inventory of 3 plots (each 400m2) -CA-TP1,29467,GRP_SPP_O,SPP_DATE,20041001 -CA-TP1,29467,GRP_SPP_O,SPP_COMMENT,inventory -CA-TP1,26708,GRP_SPP_U,SPP_U,CONYZ (NRCS plant code) -CA-TP1,26847,GRP_SPP_U,SPP_U,DISA (NRCS plant code) -CA-TP1,26709,GRP_SPP_U,SPP_U,TRIFO (NRCS plant code) -CA-TP1,26709,GRP_SPP_U,SPP_U_PERC,28 -CA-TP1,26847,GRP_SPP_U,SPP_U_PERC,31 -CA-TP1,26708,GRP_SPP_U,SPP_U_PERC,32 -CA-TP1,26708,GRP_SPP_U,SPP_APPROACH,Canadian national forest inventory protocol: full inventory of 3 plots (each 400m2) -CA-TP1,26709,GRP_SPP_U,SPP_APPROACH,Canadian national forest inventory protocol: full inventory of 3 plots (each 400m2) -CA-TP1,26847,GRP_SPP_U,SPP_APPROACH,Canadian national forest inventory protocol: full inventory of 3 plots (each 400m2) -CA-TP1,26708,GRP_SPP_U,SPP_DATE,20041001 -CA-TP1,26709,GRP_SPP_U,SPP_DATE,20041001 -CA-TP1,26847,GRP_SPP_U,SPP_DATE,20041001 -CA-TP1,26708,GRP_SPP_U,SPP_COMMENT,inventory -CA-TP1,26709,GRP_SPP_U,SPP_COMMENT,inventory -CA-TP1,26847,GRP_SPP_U,SPP_COMMENT,inventory -CA-TP1,12136,GRP_STATE,STATE,Ontario -CA-TP1,26998,GRP_STUMP_MASS,STUMP_MASS,0 -CA-TP1,26998,GRP_STUMP_MASS,STUMP_MASS_UNIT,gC m-2 -CA-TP1,26998,GRP_STUMP_MASS,STUMP_MASS_DATE,20050928 -CA-TP1,27288,GRP_STUMP_MASS,STUMP_MASS,0 -CA-TP1,27288,GRP_STUMP_MASS,STUMP_MASS_UNIT,gC m-2 -CA-TP1,27288,GRP_STUMP_MASS,STUMP_MASS_DATE,20071016 -CA-TP1,27559,GRP_STUMP_MASS,STUMP_MASS,0 -CA-TP1,27559,GRP_STUMP_MASS,STUMP_MASS_UNIT,gC m-2 -CA-TP1,27559,GRP_STUMP_MASS,STUMP_MASS_DATE,20061002 -CA-TP1,29470,GRP_STUMP_MASS,STUMP_MASS,0 -CA-TP1,29470,GRP_STUMP_MASS,STUMP_MASS_UNIT,gC m-2 -CA-TP1,29470,GRP_STUMP_MASS,STUMP_MASS_DATE,20041001 -CA-TP1,12137,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,M. Altaf Arain -CA-TP1,12137,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -CA-TP1,12137,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,arainm@mcmaster.ca -CA-TP1,12137,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,McMaster University -CA-TP1,12137,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"McMaster University -School of Geography and Earth Sciences -1280 Main Steert West -Hamilton Ontario, Canada L8S4K1" -CA-TP1,81513,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Jason J. Brodeur -CA-TP1,81513,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,DataManager -CA-TP1,81513,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,brodeujj@mcmaster.ca -CA-TP1,81513,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,McMaster University -CA-TP1,81513,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"McMaster University, Mills Memorial Library, Rm 104/B -1280 Main Street West, Hamilton, ON L8S4L6" -CA-TP1,29791,GRP_TOWER_POWER,TOWER_POWER,Direct power -CA-TP1,12138,GRP_TOWER_TYPE,TOWER_TYPE,walk-up -CA-TP1,24000082,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/CA-TP1 -CA-TP1,12139,GRP_UTC_OFFSET,UTC_OFFSET,-5 -CA-TP1,27287,GRP_WD_BIOMASS,WD_BIOMASS_CRS,0 -CA-TP1,27907,GRP_WD_BIOMASS,WD_BIOMASS_CRS,0 -CA-TP1,27287,GRP_WD_BIOMASS,WD_BIOMASS_FINE,0 -CA-TP1,27907,GRP_WD_BIOMASS,WD_BIOMASS_FINE,0 -CA-TP1,27287,GRP_WD_BIOMASS,WD_BIOMASS_UNIT,gC m-2 -CA-TP1,27907,GRP_WD_BIOMASS,WD_BIOMASS_UNIT,gC m-2 -CA-TP1,27287,GRP_WD_BIOMASS,WD_BIOMASS_DATE,20040609 -CA-TP1,27907,GRP_WD_BIOMASS,WD_BIOMASS_DATE,20070721 -CA-TP2,28520,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER,11.5 -CA-TP2,28520,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_ORGAN,Total -CA-TP2,28520,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_PHEN,Mixed/unknown -CA-TP2,28520,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_UNIT,gC m-2 -CA-TP2,28520,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_APPROACH,Canadian national forest inventory protocol: clipping of 12 microplots (each 1m2). -CA-TP2,28520,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_DATE,20070927 -CA-TP2,28520,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_COMMENT,Total aboveground (TT) includes bark; -CA-TP2,29122,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER,6.47 -CA-TP2,29122,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_ORGAN,Total -CA-TP2,29122,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_PHEN,Mixed/unknown -CA-TP2,29122,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_UNIT,gC m-2 -CA-TP2,29122,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_APPROACH,Canadian national forest inventory protocol: clipping of 12 microplots (each 1m2). -CA-TP2,29122,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_DATE,20040923 -CA-TP2,29122,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_COMMENT,Total aboveground (TT) includes bark; -CA-TP2,27001,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB,0 -CA-TP2,27001,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_ORGAN,Total -CA-TP2,27001,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_PHEN,Mixed/unknown -CA-TP2,27001,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_UNIT,gC m-2 -CA-TP2,27001,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_APPROACH,Canadian national forest inventory protocol: clipping of 12 microplots (each 1m2). -CA-TP2,27001,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_DATE,20070927 -CA-TP2,27001,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_COMMENT,Total aboveground (TT) includes bark; -CA-TP2,28519,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB,0 -CA-TP2,28519,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_ORGAN,Total -CA-TP2,28519,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_PHEN,Mixed/unknown -CA-TP2,28519,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_UNIT,gC m-2 -CA-TP2,28519,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_APPROACH,Canadian national forest inventory protocol: clipping of 12 microplots (each 1m2). -CA-TP2,28519,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_DATE,20040923 -CA-TP2,28519,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_COMMENT,Total aboveground (TT) includes bark; -CA-TP2,27290,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,2596.34713505405 -CA-TP2,27290,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Wood -CA-TP2,27290,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -CA-TP2,27290,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -CA-TP2,27290,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,"destructive tree sampling, upscaled to stand level using 1) site specific allometric equation [stem biomass=0.0258*(DBH)^2.451] + [branch biomass=0.0014*(DBH)^3.356] and 2) stem density (1317 stems ha-1) from inventory data" -CA-TP2,27290,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,20040923 -CA-TP2,27290,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,Total aboveground (TT) includes bark; -CA-TP2,28281,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,2849.34936427494 -CA-TP2,28281,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Wood -CA-TP2,28281,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -CA-TP2,28281,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -CA-TP2,28281,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,"destructive tree sampling, upscaled to stand level using 1) site specific allometric equation [stem biomass=0.0258*(DBH)^2.451] + [branch biomass=0.0014*(DBH)^3.356] and 2) stem density (1317 stems ha-1) from inventory data" -CA-TP2,28281,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,20050926 -CA-TP2,28281,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,Total aboveground (TT) includes bark; -CA-TP2,28178,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,3134.63154472368 -CA-TP2,28178,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Total -CA-TP2,28178,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -CA-TP2,28178,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -CA-TP2,28178,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,"destructive tree sampling, upscaled to stand level using 1) site specific allometric equation [total aboveground biomass=0.0275*(DBH)^2.712 minus dead branches (= 0.0115*(DBH)^2.239] and 2) stem density (1317 stems ha-1) from inventory data" -CA-TP2,28178,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,20040923 -CA-TP2,28178,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,Total aboveground (TT) includes bark; -CA-TP2,28517,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,3149.25385305409 -CA-TP2,28517,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Wood -CA-TP2,28517,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -CA-TP2,28517,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -CA-TP2,28517,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,"destructive tree sampling, upscaled to stand level using 1) site specific allometric equation [stem biomass=0.0258*(DBH)^2.451] + [branch biomass=0.0014*(DBH)^3.356] and 2) stem density (1317 stems ha-1) from inventory data" -CA-TP2,28517,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,20061026 -CA-TP2,28517,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,Total aboveground (TT) includes bark; -CA-TP2,28179,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,3429.8517667658 -CA-TP2,28179,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Wood -CA-TP2,28179,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -CA-TP2,28179,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -CA-TP2,28179,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,"destructive tree sampling, upscaled to stand level using 1) site specific allometric equation [stem biomass=0.0258*(DBH)^2.451] + [branch biomass=0.0014*(DBH)^3.356] and 2) stem density (1317 stems ha-1) from inventory data" -CA-TP2,28179,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,20070927 -CA-TP2,28179,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,Total aboveground (TT) includes bark; -CA-TP2,28176,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,3433.86420854702 -CA-TP2,28176,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Total -CA-TP2,28176,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -CA-TP2,28176,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -CA-TP2,28176,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,"destructive tree sampling, upscaled to stand level using 1) site specific allometric equation [total aboveground biomass=0.0275*(DBH)^2.712 minus dead branches (= 0.0115*(DBH)^2.239] and 2) stem density (1317 stems ha-1) from inventory data" -CA-TP2,28176,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,20050926 -CA-TP2,28176,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,Total aboveground (TT) includes bark; -CA-TP2,26719,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,3786.40489238314 -CA-TP2,26719,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Total -CA-TP2,26719,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -CA-TP2,26719,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -CA-TP2,26719,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,"destructive tree sampling, upscaled to stand level using 1) site specific allometric equation [total aboveground biomass=0.0275*(DBH)^2.712 minus dead branches (= 0.0115*(DBH)^2.239] and 2) stem density (1317 stems ha-1) from inventory data" -CA-TP2,26719,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,20061026 -CA-TP2,26719,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,Total aboveground (TT) includes bark; -CA-TP2,26854,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,4110.36032130042 -CA-TP2,26854,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Total -CA-TP2,26854,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -CA-TP2,26854,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -CA-TP2,26854,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,"destructive tree sampling, upscaled to stand level using 1) site specific allometric equation [total aboveground biomass=0.0275*(DBH)^2.712 minus dead branches (= 0.0115*(DBH)^2.239] and 2) stem density (1317 stems ha-1) from inventory data" -CA-TP2,26854,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,20070927 -CA-TP2,26854,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,Total aboveground (TT) includes bark; -CA-TP2,27289,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,481.241600229226 -CA-TP2,27289,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Foliage -CA-TP2,27289,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -CA-TP2,27289,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -CA-TP2,27289,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,"destructive tree sampling, upscaled to stand level using 1) site specific allometric equation [foliage biomass=0.0026*(DBH)^2.85] and 2) stem density (1317 stems ha-1) from inventory data" -CA-TP2,27289,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,20040923 -CA-TP2,27289,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,Total aboveground (TT) includes bark; -CA-TP2,26855,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,528.155329371326 -CA-TP2,26855,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Foliage -CA-TP2,26855,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -CA-TP2,26855,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -CA-TP2,26855,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,"destructive tree sampling, upscaled to stand level using 1) site specific allometric equation [foliage biomass=0.0026*(DBH)^2.85] and 2) stem density (1317 stems ha-1) from inventory data" -CA-TP2,26855,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,20050926 -CA-TP2,26855,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,Total aboveground (TT) includes bark; -CA-TP2,28177,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,583.68942232659 -CA-TP2,28177,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Foliage -CA-TP2,28177,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -CA-TP2,28177,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -CA-TP2,28177,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,"destructive tree sampling, upscaled to stand level using 1) site specific allometric equation [foliage biomass=0.0026*(DBH)^2.85] and 2) stem density (1317 stems ha-1) from inventory data" -CA-TP2,28177,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,20061026 -CA-TP2,28177,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,Total aboveground (TT) includes bark; -CA-TP2,29118,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,635.476098713809 -CA-TP2,29118,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Foliage -CA-TP2,29118,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -CA-TP2,29118,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -CA-TP2,29118,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,"destructive tree sampling, upscaled to stand level using 1) site specific allometric equation [foliage biomass=0.0026*(DBH)^2.85] and 2) stem density (1317 stems ha-1) from inventory data" -CA-TP2,29118,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,20070927 -CA-TP2,29118,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,Total aboveground (TT) includes bark; -CA-TP2,27292,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS,714 -CA-TP2,27292,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_UNIT,gC m-2 -CA-TP2,27292,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_DATE,20070721 -CA-TP2,29473,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS,745 -CA-TP2,29473,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_UNIT,gC m-2 -CA-TP2,29473,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_DATE,20040609 -CA-TP2,28524,GRP_AG_LIT_CHEM,AG_LIT_C,5.213 -CA-TP2,28524,GRP_AG_LIT_CHEM,AG_LIT_N,0.073 -CA-TP2,28524,GRP_AG_LIT_CHEM,AG_LIT_DATE,20071123 -CA-TP2,29010,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT,257 -CA-TP2,29010,GRP_AG_LIT_PROD,AG_LIT_PROD_UNIT,gC m-2 -CA-TP2,29010,GRP_AG_LIT_PROD,AG_LIT_PROD_COMMENT,mean of 3 years (2005-2007) -CA-TP2,28185,GRP_AG_PROD_OTHER,AG_PROD_OTHER,11.5 -CA-TP2,28185,GRP_AG_PROD_OTHER,AG_PROD_OTHER_ORGAN,Total -CA-TP2,28185,GRP_AG_PROD_OTHER,AG_PROD_OTHER_UNIT,gC m-2 -CA-TP2,28185,GRP_AG_PROD_OTHER,AG_PROD_DATE_START,20070927 -CA-TP2,29123,GRP_AG_PROD_OTHER,AG_PROD_OTHER,6.5 -CA-TP2,29123,GRP_AG_PROD_OTHER,AG_PROD_OTHER_ORGAN,Total -CA-TP2,29123,GRP_AG_PROD_OTHER,AG_PROD_OTHER_UNIT,gC m-2 -CA-TP2,29123,GRP_AG_PROD_OTHER,AG_PROD_DATE_START,20050926 -CA-TP2,27563,GRP_AG_PROD_SHRUB,AG_PROD_SHRUB,0 -CA-TP2,27563,GRP_AG_PROD_SHRUB,AG_PROD_SHRUB_ORGAN,Total -CA-TP2,27563,GRP_AG_PROD_SHRUB,AG_PROD_SHRUB_UNIT,gC m-2 -CA-TP2,27563,GRP_AG_PROD_SHRUB,AG_PROD_DATE_START,20050926 -CA-TP2,27917,GRP_AG_PROD_SHRUB,AG_PROD_SHRUB,0 -CA-TP2,27917,GRP_AG_PROD_SHRUB,AG_PROD_SHRUB_ORGAN,Total -CA-TP2,27917,GRP_AG_PROD_SHRUB,AG_PROD_SHRUB_UNIT,gC m-2 -CA-TP2,27917,GRP_AG_PROD_SHRUB,AG_PROD_DATE_START,20061026 -CA-TP2,29125,GRP_AG_PROD_SHRUB,AG_PROD_SHRUB,0 -CA-TP2,29125,GRP_AG_PROD_SHRUB,AG_PROD_SHRUB_ORGAN,Total -CA-TP2,29125,GRP_AG_PROD_SHRUB,AG_PROD_SHRUB_UNIT,gC m-2 -CA-TP2,29125,GRP_AG_PROD_SHRUB,AG_PROD_DATE_START,20070927 -CA-TP2,26856,GRP_AG_PROD_TREE,AG_PROD_TREE,254.41583424736 -CA-TP2,26856,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Wood -CA-TP2,26856,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -CA-TP2,26856,GRP_AG_PROD_TREE,AG_PROD_APPROACH,difference between annual standing wood biomass stock -CA-TP2,26856,GRP_AG_PROD_TREE,AG_PROD_DATE_START,20050926 -CA-TP2,27298,GRP_AG_PROD_TREE,AG_PROD_TREE,280.198988638818 -CA-TP2,27298,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Wood -CA-TP2,27298,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -CA-TP2,27298,GRP_AG_PROD_TREE,AG_PROD_APPROACH,difference between annual standing wood biomass stock -CA-TP2,27298,GRP_AG_PROD_TREE,AG_PROD_DATE_START,20070927 -CA-TP2,27004,GRP_AG_PROD_TREE,AG_PROD_TREE,292.970633872384 -CA-TP2,27004,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Total -CA-TP2,27004,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -CA-TP2,27004,GRP_AG_PROD_TREE,AG_PROD_APPROACH,difference between annual standing aboveground biomass stock -CA-TP2,27004,GRP_AG_PROD_TREE,AG_PROD_DATE_START,20050926 -CA-TP2,27005,GRP_AG_PROD_TREE,AG_PROD_TREE,301.070591345682 -CA-TP2,27005,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Wood -CA-TP2,27005,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -CA-TP2,27005,GRP_AG_PROD_TREE,AG_PROD_APPROACH,difference between annual standing wood biomass stock -CA-TP2,27005,GRP_AG_PROD_TREE,AG_PROD_DATE_START,20061026 -CA-TP2,28284,GRP_AG_PROD_TREE,AG_PROD_TREE,317.269605715004 -CA-TP2,28284,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Total -CA-TP2,28284,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -CA-TP2,28284,GRP_AG_PROD_TREE,AG_PROD_APPROACH,difference between annual standing aboveground biomass stock -CA-TP2,28284,GRP_AG_PROD_TREE,AG_PROD_DATE_START,20070927 -CA-TP2,27297,GRP_AG_PROD_TREE,AG_PROD_TREE,345.187116846817 -CA-TP2,27297,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Total -CA-TP2,27297,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -CA-TP2,27297,GRP_AG_PROD_TREE,AG_PROD_APPROACH,difference between annual standing aboveground biomass stock -CA-TP2,27297,GRP_AG_PROD_TREE,AG_PROD_DATE_START,20061026 -CA-TP2,28521,GRP_AG_PROD_TREE,AG_PROD_TREE,46.9137291420995 -CA-TP2,28521,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Foliage -CA-TP2,28521,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -CA-TP2,28521,GRP_AG_PROD_TREE,AG_PROD_APPROACH,difference between annual standing foliage biomass stock -CA-TP2,28521,GRP_AG_PROD_TREE,AG_PROD_DATE_START,20050926 -CA-TP2,27918,GRP_AG_PROD_TREE,AG_PROD_TREE,51.7866763872187 -CA-TP2,27918,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Foliage -CA-TP2,27918,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -CA-TP2,27918,GRP_AG_PROD_TREE,AG_PROD_APPROACH,difference between annual standing foliage biomass stock -CA-TP2,27918,GRP_AG_PROD_TREE,AG_PROD_DATE_START,20070927 -CA-TP2,29124,GRP_AG_PROD_TREE,AG_PROD_TREE,55.5340929552646 -CA-TP2,29124,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Foliage -CA-TP2,29124,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -CA-TP2,29124,GRP_AG_PROD_TREE,AG_PROD_APPROACH,difference between annual standing foliage biomass stock -CA-TP2,29124,GRP_AG_PROD_TREE,AG_PROD_DATE_START,20061026 -CA-TP2,28523,GRP_BIOMASS_CHEM,BIOMASS_N,0.134 -CA-TP2,28523,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -CA-TP2,28523,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -CA-TP2,28523,GRP_BIOMASS_CHEM,BIOMASS_SPP,PIST (NRCS plant code) -CA-TP2,28523,GRP_BIOMASS_CHEM,BIOMASS_DATE,20050920 -CA-TP2,12157,GRP_CLIM_AVG,MAT,8 -CA-TP2,12157,GRP_CLIM_AVG,MAP,1036 -CA-TP2,12157,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfb -CA-TP2,27000083,GRP_COUNTRY,COUNTRY,Canada -CA-TP2,3671,GRP_DM_PLANTING,DM_PLANTING,Planting live trees -CA-TP2,3671,GRP_DM_PLANTING,DM_DATE,1989 -CA-TP2,15611,GRP_DOI,DOI,10.17190/AMF/1246010 -CA-TP2,15611,GRP_DOI,DOI_CITATION,"M. Altaf Arain (2018), AmeriFlux BASE CA-TP2 Ontario - Turkey Point 1989 Plantation White Pine, Ver. 2-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1246010" -CA-TP2,15611,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -CA-TP2,31896,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -CA-TP2,31896,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,M. Altaf Arain -CA-TP2,31896,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -CA-TP2,31896,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,arainm@mcmaster.ca -CA-TP2,31896,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,McMaster University -CA-TP2,31898,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,McMaster University -CA-TP2,31898,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -CA-TP2,31897,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,"Natural Sciences and Engineering Research Council (NSREC) of Canada, Ministry of Environment (MOE), Canadian Foundation for Climate and Atmospheric Sciences (CFCAS), Canadian Foundation of Innovation (CFI), Ontario Innovation Trust (OIT)" -CA-TP2,31897,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -CA-TP2,12158,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Forestry -CA-TP2,12159,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -CA-TP2,12159,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -CA-TP2,12159,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,2003 -CA-TP2,12159,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20080612 -CA-TP2,12159,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -CA-TP2,12175,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -CA-TP2,12175,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -CA-TP2,12175,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,2003 -CA-TP2,12175,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20080612 -CA-TP2,12175,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -CA-TP2,12172,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -CA-TP2,12172,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -CA-TP2,12172,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,2003 -CA-TP2,12172,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20080612 -CA-TP2,12172,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -CA-TP2,23000083,GRP_HEADER,SITE_NAME,Ontario - Turkey Point 1989 Plantation White Pine -CA-TP2,89105,GRP_HEIGHTC,HEIGHTC,9.1 -CA-TP2,89105,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -CA-TP2,89105,GRP_HEIGHTC,HEIGHTC_DATE,20040923 -CA-TP2,89106,GRP_HEIGHTC,HEIGHTC,11.5 -CA-TP2,89106,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -CA-TP2,89106,GRP_HEIGHTC,HEIGHTC_DATE,20070927 -CA-TP2,12160,GRP_IGBP,IGBP,ENF -CA-TP2,12160,GRP_IGBP,IGBP_COMMENT,Plantation -CA-TP2,29471,GRP_LAI,LAI_TYPE,LAI -CA-TP2,29471,GRP_LAI,LAI_CLUMP,1 -CA-TP2,29471,GRP_LAI,LAI_METHOD,LAI_2000 -CA-TP2,29471,GRP_LAI,LAI_DATE,20050716 -CA-TP2,29471,GRP_LAI,LAI_COMMENT,"LAI estimates with LAI2000 and TRAC, see Chen et al 2006" -CA-TP2,29471,GRP_LAI,LAI_TOT,12.8 -CA-TP2,12161,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -CA-TP2,12161,GRP_LAND_OWNERSHIP,LAND_OWNER,Frank Bahula -CA-TP2,23902,GRP_LMA,LMA,87.27 -CA-TP2,23902,GRP_LMA,LMA_SPP,(All) -CA-TP2,12162,GRP_LOCATION,LOCATION_LAT,42.7744 -CA-TP2,12162,GRP_LOCATION,LOCATION_LONG,-80.4588 -CA-TP2,12162,GRP_LOCATION,LOCATION_ELEV,212 -CA-TP2,23641,GRP_N_DEP,N_DEP_WET,0.7 -CA-TP2,23641,GRP_N_DEP,N_DEP_COMMENT,"7 (Canadian Acid Deposition Assessment 2004 ;Environment Canada, 2004)" -CA-TP2,26857,GRP_NEP,NEP,748000 -CA-TP2,26857,GRP_NEP,NEP_APPROACH,eddy-covariance technique -CA-TP2,26857,GRP_NEP,NEP_DATE_START,20020601 -CA-TP2,26857,GRP_NEP,NEP_DATE_END,20070601 -CA-TP2,12173,GRP_NETWORK,NETWORK,AmeriFlux -CA-TP2,12163,GRP_NETWORK,NETWORK,Fluxnet-Canada -CA-TP2,1700006279,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Arain, M. A., Restrepo-Coupe, N. (2005) Net Ecosystem Production In A Temperate Pine Plantation In Southeastern Canada, Agricultural And Forest Meteorology, 128(3-4), 223-241" -CA-TP2,1700006279,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2004.10.003 -CA-TP2,1700006279,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-TP2,1700003687,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chen, J. M., Govind, A., Sonnentag, O., Zhang, Y., Barr, A., Amiro, B. (2006) Leaf Area Index Measurements At Fluxnet-Canada Forest Sites, Agricultural And Forest Meteorology, 140(1-4), 257-268" -CA-TP2,1700003687,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2006.08.005 -CA-TP2,1700003687,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-TP2,1700009015,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Coursolle, C., Margolis, H., Giasson, M., Bernier, P., Amiro, B., Arain, M., Barr, A., Black, T., Goulden, M., McCaughey, J., Chen, J., Dunn, A., Grant, R., Lafleur, P. (2012) Influence Of Stand Age On The Magnitude And Seasonality Of Carbon Fluxes In Canadian Forests, Agricultural And Forest Meteorology, 165(7-8), 136-148" -CA-TP2,1700009015,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2012.06.011 -CA-TP2,1700009015,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-TP2,1700001953,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Khomik M., Arain A. M.: Liaw K. L., McCaughey H. J. (2009) Debut Of A Flexible Model For Simulating Soil Respiration–Soil Temperature Relationship: Gamma Model, Journal Of Geophysical Research, 114(G3), n/a-n/a" -CA-TP2,1700001953,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2008JG000851 -CA-TP2,1700001953,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-TP2,1700000393,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Khomik, M., Arain, A.M., Brodeur, J.J., Peichl, M., Restrepo-Coupé, N., McLaren, J.D. (2010) Relative Contributions Of Soil, Foliar, And Woody Tissue Respiration To Total Ecosystem Respiration In Four Pine Forests Of Different Ages, Journal Of Geophysical Research, 115(G3), n/a-n/a" -CA-TP2,1700000393,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2009JG001089 -CA-TP2,1700000393,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-TP2,1700003063,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Peichl, M., Arain, M. A. (2006) Above- And Belowground Ecosystem Biomass And Carbon Pools In An Age-Sequence Of Temperate Pine Plantation Forests, Agricultural And Forest Meteorology, 140(1-4), 51-63" -CA-TP2,1700003063,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2006.08.004 -CA-TP2,1700003063,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-TP2,1700001119,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Peichl, M., Arain, M. A. (2007) Allometry And Partitioning Of Above- And Belowground Tree Biomass In An Age-Sequence Of White Pine Forests, Forest Ecology And Management, 253(1-3), 68-80" -CA-TP2,1700001119,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.FORECO.2007.07.003 -CA-TP2,1700001119,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-TP2,1700003876,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Peichl, M., Arain, M. A., Brodeur, J. J. (2010) Age Effects On Carbon Fluxes In Temperate Pine Forests, Agricultural And Forest Meteorology, 150(7-8), 1090-1101" -CA-TP2,1700003876,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2010.04.008 -CA-TP2,1700003876,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-TP2,1700001956,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Peichl, M., Arain, M.A., Ullah, S., Moore, T. (2010) Carbon Dioxide, Methane, And Nitrous Oxide Exchanges In An Age-Sequence Of Temperate Pine Forests, Global Change Biology, 16(8), 2198-2212" -CA-TP2,1700001956,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/J.1365-2486.2009.02066.X -CA-TP2,1700001956,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-TP2,1700002499,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Peichl, M., Brodeur, J. J., Khomik, M., Arain, M. A. (2010) Biometric And Eddy-Covariance Based Estimates Of Carbon Fluxes In An Age-Sequence Of Temperate Pine Forests, Agricultural And Forest Meteorology, 150(7-8), 952-965" -CA-TP2,1700002499,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2010.03.002 -CA-TP2,1700002499,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-TP2,1700006297,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Xu, B., Arain, M. A., Black, T. A., Law, B. E., Pastorello, G. Z., Chu, H. (2020) Seasonal Variability Of Forest Sensitivity To Heat And Drought Stresses: A Synthesis Based On Carbon Fluxes From North American Forest Ecosystems, Global Change Biology, 26(2), 901-918" -CA-TP2,1700006297,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/GCB.14843 -CA-TP2,1700006297,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-TP2,28184,GRP_ROOT_BIOMASS,ROOT_BIOMASS_CRS,1046.57949904064 -CA-TP2,27294,GRP_ROOT_BIOMASS,ROOT_BIOMASS_CRS,782.248379372381 -CA-TP2,27295,GRP_ROOT_BIOMASS,ROOT_BIOMASS_CRS,861.51482245336 -CA-TP2,27296,GRP_ROOT_BIOMASS,ROOT_BIOMASS_CRS,956.122432936277 -CA-TP2,27003,GRP_ROOT_BIOMASS,ROOT_BIOMASS_FINE,175 -CA-TP2,27294,GRP_ROOT_BIOMASS,ROOT_BIOMASS_TOT,957.248379372381 -CA-TP2,27003,GRP_ROOT_BIOMASS,ROOT_BIOMASS_UNIT,gC m-2 -CA-TP2,27294,GRP_ROOT_BIOMASS,ROOT_BIOMASS_UNIT,gC m-2 -CA-TP2,27295,GRP_ROOT_BIOMASS,ROOT_BIOMASS_UNIT,gC m-2 -CA-TP2,27296,GRP_ROOT_BIOMASS,ROOT_BIOMASS_UNIT,gC m-2 -CA-TP2,28184,GRP_ROOT_BIOMASS,ROOT_BIOMASS_UNIT,gC m-2 -CA-TP2,27003,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MIN,0 -CA-TP2,27294,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MIN,0 -CA-TP2,27295,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MIN,0 -CA-TP2,27296,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MIN,0 -CA-TP2,28184,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MIN,0 -CA-TP2,27294,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MAX,100 -CA-TP2,27295,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MAX,100 -CA-TP2,27296,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MAX,100 -CA-TP2,28184,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MAX,100 -CA-TP2,27003,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MAX,55 -CA-TP2,27294,GRP_ROOT_BIOMASS,ROOT_BIOMASS_APPROACH,"destructive tree sampling, upscaled to stand level using 1) site specific allometric equation [root biomass=0.0028*(DBH)^2.998] and 2) stem density (1317 stems ha-1) from inventory data" -CA-TP2,27295,GRP_ROOT_BIOMASS,ROOT_BIOMASS_APPROACH,"destructive tree sampling, upscaled to stand level using 1) site specific allometric equation [root biomass=0.0028*(DBH)^2.998] and 2) stem density (1317 stems ha-1) from inventory data" -CA-TP2,27296,GRP_ROOT_BIOMASS,ROOT_BIOMASS_APPROACH,"destructive tree sampling, upscaled to stand level using 1) site specific allometric equation [root biomass=0.0028*(DBH)^2.998] and 2) stem density (1317 stems ha-1) from inventory data" -CA-TP2,28184,GRP_ROOT_BIOMASS,ROOT_BIOMASS_APPROACH,"destructive tree sampling, upscaled to stand level using 1) site specific allometric equation [root biomass=0.0028*(DBH)^2.998] and 2) stem density (1317 stems ha-1) from inventory data" -CA-TP2,27003,GRP_ROOT_BIOMASS,ROOT_BIOMASS_APPROACH,soil coring -CA-TP2,27003,GRP_ROOT_BIOMASS,ROOT_BIOMASS_DATE,20040923 -CA-TP2,27294,GRP_ROOT_BIOMASS,ROOT_BIOMASS_DATE,20040923 -CA-TP2,27295,GRP_ROOT_BIOMASS,ROOT_BIOMASS_DATE,20050926 -CA-TP2,27296,GRP_ROOT_BIOMASS,ROOT_BIOMASS_DATE,20061026 -CA-TP2,28184,GRP_ROOT_BIOMASS,ROOT_BIOMASS_DATE,20070927 -CA-TP2,27003,GRP_ROOT_BIOMASS,ROOT_BIOMASS_COMMENT,"date is for Cr >2mm from allometric equation, FR <2mm from soil coring on DOY 184" -CA-TP2,27294,GRP_ROOT_BIOMASS,ROOT_BIOMASS_COMMENT,"date is for Cr >2mm from allometric equation, FR <2mm from soil coring on DOY 184" -CA-TP2,29126,GRP_ROOT_PROD,ROOT_PROD_CRS,79.2664430809791 -CA-TP2,28522,GRP_ROOT_PROD,ROOT_PROD_CRS,90.4570661043584 -CA-TP2,26722,GRP_ROOT_PROD,ROOT_PROD_CRS,94.6076104829163 -CA-TP2,26722,GRP_ROOT_PROD,ROOT_PROD_UNIT,gC m-2 -CA-TP2,28522,GRP_ROOT_PROD,ROOT_PROD_UNIT,gC m-2 -CA-TP2,29126,GRP_ROOT_PROD,ROOT_PROD_UNIT,gC m-2 -CA-TP2,26722,GRP_ROOT_PROD,ROOT_PROD_PROFILE_MIN,0 -CA-TP2,28522,GRP_ROOT_PROD,ROOT_PROD_PROFILE_MIN,0 -CA-TP2,29126,GRP_ROOT_PROD,ROOT_PROD_PROFILE_MIN,0 -CA-TP2,26722,GRP_ROOT_PROD,ROOT_PROD_PROFILE_MAX,100 -CA-TP2,28522,GRP_ROOT_PROD,ROOT_PROD_PROFILE_MAX,100 -CA-TP2,29126,GRP_ROOT_PROD,ROOT_PROD_PROFILE_MAX,100 -CA-TP2,26722,GRP_ROOT_PROD,ROOT_PROD_APPROACH,difference between annual standing root biomass stock -CA-TP2,28522,GRP_ROOT_PROD,ROOT_PROD_APPROACH,difference between annual standing root biomass stock -CA-TP2,29126,GRP_ROOT_PROD,ROOT_PROD_APPROACH,difference between annual standing root biomass stock -CA-TP2,29126,GRP_ROOT_PROD,ROOT_PROD_DATE_START,20050926 -CA-TP2,26722,GRP_ROOT_PROD,ROOT_PROD_DATE_START,20061026 -CA-TP2,28522,GRP_ROOT_PROD,ROOT_PROD_DATE_START,20070927 -CA-TP2,26722,GRP_ROOT_PROD,ROOT_PROD_COMMENT,coarse root is >2mm -CA-TP2,28522,GRP_ROOT_PROD,ROOT_PROD_COMMENT,coarse root is >2mm -CA-TP2,29126,GRP_ROOT_PROD,ROOT_PROD_COMMENT,coarse root is >2mm -CA-TP2,26717,GRP_SA,SA_DATE,2008 -CA-TP2,26717,GRP_SA,SA_COMMENT,Trees are even-aged -CA-TP2,26717,GRP_SA,SA_MAX,19 -CA-TP2,26852,GRP_SA,SA,19 -CA-TP2,26852,GRP_SA,SA_DATE,2008 -CA-TP2,26852,GRP_SA,SA_COMMENT,Stand age in 2008 -CA-TP2,12165,GRP_SITE_CHAR,TERRAIN,Flat -CA-TP2,12165,GRP_SITE_CHAR,WIND_DIRECTION,SW -CA-TP2,12166,GRP_SITE_DESC,SITE_DESC,Plantation established in 1989 over sandy agriculture land -CA-TP2,12167,GRP_SITE_FUNDING,SITE_FUNDING,"Natural Sciences and Engineering Research Council (NSREC) of Canada, Ministry of Environment (MOE), Canadian Foundation for Climate and Atmospheric Sciences (CFCAS), Canadian Foundation of Innovation (CFI), Ontario Innovation Trust (OIT)" -CA-TP2,27293,GRP_SNAG_MASS,SNAG_MASS,11 -CA-TP2,27293,GRP_SNAG_MASS,SNAG_MASS_UNIT,gC m-2 -CA-TP2,27293,GRP_SNAG_MASS,SNAG_MASS_DATE,20061026 -CA-TP2,27916,GRP_SNAG_MASS,SNAG_MASS,11 -CA-TP2,27916,GRP_SNAG_MASS,SNAG_MASS_UNIT,gC m-2 -CA-TP2,27916,GRP_SNAG_MASS,SNAG_MASS_DATE,20040923 -CA-TP2,28183,GRP_SNAG_MASS,SNAG_MASS,11 -CA-TP2,28183,GRP_SNAG_MASS,SNAG_MASS_UNIT,gC m-2 -CA-TP2,28183,GRP_SNAG_MASS,SNAG_MASS_DATE,20050926 -CA-TP2,27002,GRP_SNAG_MASS,SNAG_MASS,28 -CA-TP2,27002,GRP_SNAG_MASS,SNAG_MASS_UNIT,gC m-2 -CA-TP2,27002,GRP_SNAG_MASS,SNAG_MASS_DATE,20070927 -CA-TP2,28525,GRP_SOIL_CHEM,SOIL_CHEM_C_ORG,33.9 -CA-TP2,28526,GRP_SOIL_CHEM,SOIL_CHEM_N_TOT,0.94 -CA-TP2,28527,GRP_SOIL_CHEM,SOIL_CHEM_PH_SALT,4.3 -CA-TP2,26858,GRP_SOIL_CHEM,SOIL_CHEM_PH_SALT,4.9 -CA-TP2,29474,GRP_SOIL_CHEM,SOIL_CHEM_BD,1.45 -CA-TP2,28525,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,0 -CA-TP2,28526,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,0 -CA-TP2,28527,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,0 -CA-TP2,29474,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,0 -CA-TP2,26858,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,20 -CA-TP2,28526,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,10 -CA-TP2,28527,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,10 -CA-TP2,29474,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,20 -CA-TP2,26858,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,30 -CA-TP2,28525,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,55 -CA-TP2,28525,GRP_SOIL_CHEM,SOIL_CHEM_DATE,20040702 -CA-TP2,29474,GRP_SOIL_CHEM,SOIL_CHEM_DATE,20040702 -CA-TP2,26858,GRP_SOIL_CHEM,SOIL_CHEM_DATE,20060706 -CA-TP2,28526,GRP_SOIL_CHEM,SOIL_CHEM_DATE,20060706 -CA-TP2,28527,GRP_SOIL_CHEM,SOIL_CHEM_DATE,20060706 -CA-TP2,26858,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,pH (CaCl) -CA-TP2,28527,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,pH (CaCl) -CA-TP2,23905,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION,brunisolic grey brown luvisol -CA-TP2,23905,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION_TAXONOMY,Other -CA-TP2,23905,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION_COMMENT," ->3m" -CA-TP2,28816,GRP_SOIL_DEPTH,SOIL_DEPTH,300 -CA-TP2,29475,GRP_SOIL_DEPTH,SOIL_DEPTH,300 -CA-TP2,27006,GRP_SOIL_TEX,SOIL_TEX_SAND,98 -CA-TP2,27006,GRP_SOIL_TEX,SOIL_TEX_SILT,2 -CA-TP2,27006,GRP_SOIL_TEX,SOIL_TEX_CLAY,0 -CA-TP2,27910,GRP_SPP_O,SPP_O,PIST (NRCS plant code) -CA-TP2,27910,GRP_SPP_O,SPP_O_PERC,97 -CA-TP2,27910,GRP_SPP_O,SPP_APPROACH,Canadian national forest inventory protocol: full inventory of 3 plots (each 400m2) -CA-TP2,27910,GRP_SPP_O,SPP_DATE,20040923 -CA-TP2,27910,GRP_SPP_O,SPP_COMMENT,inventory -CA-TP2,26853,GRP_SPP_U,SPP_U,PIRE (NRCS plant code) -CA-TP2,26718,GRP_SPP_U,SPP_U,QUVE (NRCS plant code) -CA-TP2,26718,GRP_SPP_U,SPP_U_PERC,1 -CA-TP2,26853,GRP_SPP_U,SPP_U_PERC,2 -CA-TP2,26718,GRP_SPP_U,SPP_APPROACH,Canadian national forest inventory protocol: full inventory of 3 plots (each 400m2) -CA-TP2,26853,GRP_SPP_U,SPP_APPROACH,Canadian national forest inventory protocol: full inventory of 3 plots (each 400m2) -CA-TP2,26718,GRP_SPP_U,SPP_DATE,20040923 -CA-TP2,26853,GRP_SPP_U,SPP_DATE,20040923 -CA-TP2,26718,GRP_SPP_U,SPP_COMMENT,inventory -CA-TP2,26853,GRP_SPP_U,SPP_COMMENT,inventory -CA-TP2,12168,GRP_STATE,STATE,Ontario -CA-TP2,26721,GRP_STUMP_MASS,STUMP_MASS,0 -CA-TP2,26721,GRP_STUMP_MASS,STUMP_MASS_UNIT,gC m-2 -CA-TP2,26721,GRP_STUMP_MASS,STUMP_MASS_DATE,20040923 -CA-TP2,12169,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,M. Altaf Arain -CA-TP2,12169,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -CA-TP2,12169,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,arainm@mcmaster.ca -CA-TP2,12169,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,McMaster University -CA-TP2,12169,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"McMaster University -School of Geography and Earth Sciences -1280 Main Steert West -Hamilton Ontario, Canada L8S4K1" -CA-TP2,81514,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Jason J. Brodeur -CA-TP2,81514,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,DataManager -CA-TP2,81514,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,brodeujj@mcmaster.ca -CA-TP2,81514,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,McMaster University -CA-TP2,81514,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"McMaster University, Mills Memorial Library, Rm 104/B -1280 Main Street West, Hamilton, ON L8S4L6" -CA-TP2,29792,GRP_TOWER_POWER,TOWER_POWER,Direct power -CA-TP2,12170,GRP_TOWER_TYPE,TOWER_TYPE,triangle -CA-TP2,9478,GRP_URL,URL,http://www.fluxnet-canada.ca/visionneuse.php?page=components_fsmp_tp -CA-TP2,24000083,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/CA-TP2 -CA-TP2,12171,GRP_UTC_OFFSET,UTC_OFFSET,-5 -CA-TP2,28182,GRP_WD_BIOMASS,WD_BIOMASS_CRS,0 -CA-TP2,28283,GRP_WD_BIOMASS,WD_BIOMASS_CRS,0 -CA-TP2,28283,GRP_WD_BIOMASS,WD_BIOMASS_FINE,35 -CA-TP2,28182,GRP_WD_BIOMASS,WD_BIOMASS_FINE,50 -CA-TP2,28182,GRP_WD_BIOMASS,WD_BIOMASS_UNIT,gC m-2 -CA-TP2,28283,GRP_WD_BIOMASS,WD_BIOMASS_UNIT,gC m-2 -CA-TP2,28283,GRP_WD_BIOMASS,WD_BIOMASS_DATE,20040609 -CA-TP2,28182,GRP_WD_BIOMASS,WD_BIOMASS_DATE,20070802 -CA-TP3,27011,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER,22.23 -CA-TP3,27011,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_ORGAN,Total -CA-TP3,27011,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_PHEN,Mixed/unknown -CA-TP3,27011,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_UNIT,gC m-2 -CA-TP3,27011,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_APPROACH,Canadian national forest inventory protocol: clipping of 12 microplots (each 1m2). -CA-TP3,27011,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_DATE,20071104 -CA-TP3,27011,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_COMMENT,Total aboveground (TT) includes bark; non-woody biomass is almost 100% moss biomass -CA-TP3,28288,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER,25.56 -CA-TP3,28288,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_ORGAN,Total -CA-TP3,28288,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_PHEN,Mixed/unknown -CA-TP3,28288,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_UNIT,gC m-2 -CA-TP3,28288,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_APPROACH,Canadian national forest inventory protocol: clipping of 12 microplots (each 1m2). -CA-TP3,28288,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_DATE,20040927 -CA-TP3,28288,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_COMMENT,Total aboveground (TT) includes bark; non-woody biomass is almost 100% moss biomass -CA-TP3,28189,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB,0.01 -CA-TP3,28189,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_ORGAN,Total -CA-TP3,28189,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_PHEN,Mixed/unknown -CA-TP3,28189,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_UNIT,gC m-2 -CA-TP3,28189,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_APPROACH,Canadian national forest inventory protocol: clipping of 12 microplots (each 1m2). -CA-TP3,28189,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_DATE,20040927 -CA-TP3,28189,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_COMMENT,Total aboveground (TT) includes bark; non-woody biomass is almost 100% moss biomass -CA-TP3,29014,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB,0.03 -CA-TP3,29014,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_ORGAN,Total -CA-TP3,29014,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_PHEN,Mixed/unknown -CA-TP3,29014,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_UNIT,gC m-2 -CA-TP3,29014,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_APPROACH,Canadian national forest inventory protocol: clipping of 12 microplots (each 1m2). -CA-TP3,29014,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_DATE,20071104 -CA-TP3,29014,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_COMMENT,Total aboveground (TT) includes bark; non-woody biomass is almost 100% moss biomass -CA-TP3,29128,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,287 -CA-TP3,29128,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Foliage -CA-TP3,29128,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -CA-TP3,29128,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -CA-TP3,29128,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,"destructive tree sampling, upscaled to stand level using 1) site specific allometric equation [foliage biomass=0.00005*(DBH)^4.01448] and 2) stem density (1633 stems ha-1) from inventory data" -CA-TP3,29128,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,20040927 -CA-TP3,29128,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,Total aboveground (TT) includes bark; non-woody biomass is almost 100% moss biomass -CA-TP3,27565,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,297 -CA-TP3,27565,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Foliage -CA-TP3,27565,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -CA-TP3,27565,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -CA-TP3,27565,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,"destructive tree sampling, upscaled to stand level using 1) site specific allometric equation [foliage biomass=0.00005*(DBH)^4.01448] and 2) stem density (1633 stems ha-1) from inventory data" -CA-TP3,27565,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,20050926 -CA-TP3,27565,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,Total aboveground (TT) includes bark; non-woody biomass is almost 100% moss biomass -CA-TP3,27925,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,315 -CA-TP3,27925,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Foliage -CA-TP3,27925,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -CA-TP3,27925,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -CA-TP3,27925,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,"destructive tree sampling, upscaled to stand level using 1) site specific allometric equation [foliage biomass=0.00005*(DBH)^4.01448] and 2) stem density (1633 stems ha-1) from inventory data" -CA-TP3,27925,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,20061024 -CA-TP3,27925,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,Total aboveground (TT) includes bark; non-woody biomass is almost 100% moss biomass -CA-TP3,27010,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,332 -CA-TP3,27010,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Foliage -CA-TP3,27010,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -CA-TP3,27010,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -CA-TP3,27010,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,"destructive tree sampling, upscaled to stand level using 1) site specific allometric equation [foliage biomass=0.00005*(DBH)^4.01448] and 2) stem density (1633 stems ha-1) from inventory data" -CA-TP3,27010,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,20071104 -CA-TP3,27010,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,Total aboveground (TT) includes bark; non-woody biomass is almost 100% moss biomass -CA-TP3,26860,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,4702.52955456656 -CA-TP3,26860,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Wood -CA-TP3,26860,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -CA-TP3,26860,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -CA-TP3,26860,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,"destructive tree sampling, upscaled to stand level using 1) site specific allometric equation [stem biomass=0.037*(DBH)^2.513] + [branch biomass=0.0001*(DBH)^4.217] and 2) stem density (1633 stems ha-1) from inventory data" -CA-TP3,26860,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,20040927 -CA-TP3,26860,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,Total aboveground (TT) includes bark; non-woody biomass is almost 100% moss biomass -CA-TP3,28190,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,4819.57206973857 -CA-TP3,28190,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Wood -CA-TP3,28190,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -CA-TP3,28190,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -CA-TP3,28190,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,"destructive tree sampling, upscaled to stand level using 1) site specific allometric equation [stem biomass=0.037*(DBH)^2.513] + [branch biomass=0.0001*(DBH)^4.217] and 2) stem density (1633 stems ha-1) from inventory data" -CA-TP3,28190,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,20050926 -CA-TP3,28190,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,Total aboveground (TT) includes bark; non-woody biomass is almost 100% moss biomass -CA-TP3,28287,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,5015 -CA-TP3,28287,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Total -CA-TP3,28287,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -CA-TP3,28287,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -CA-TP3,28287,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,"destructive tree sampling, upscaled to stand level using 1) site specific allometric equation [total aboveground biomass=0.0201*(DBH)^2.926 minus dead branches (= 0.0051*(DBH)^2.641] and 2) stem density (1633 stems ha-1) from inventory data" -CA-TP3,28287,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,20040927 -CA-TP3,28287,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,Total aboveground (TT) includes bark; non-woody biomass is almost 100% moss biomass -CA-TP3,27926,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,5028.81522795488 -CA-TP3,27926,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Wood -CA-TP3,27926,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -CA-TP3,27926,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -CA-TP3,27926,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,"destructive tree sampling, upscaled to stand level using 1) site specific allometric equation [stem biomass=0.037*(DBH)^2.513] + [branch biomass=0.0001*(DBH)^4.217] and 2) stem density (1633 stems ha-1) from inventory data" -CA-TP3,27926,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,20061024 -CA-TP3,27926,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,Total aboveground (TT) includes bark; non-woody biomass is almost 100% moss biomass -CA-TP3,27924,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,5146 -CA-TP3,27924,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Total -CA-TP3,27924,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -CA-TP3,27924,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -CA-TP3,27924,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,"destructive tree sampling, upscaled to stand level using 1) site specific allometric equation [total aboveground biomass=0.0201*(DBH)^2.926 minus dead branches (= 0.0051*(DBH)^2.641] and 2) stem density (1633 stems ha-1) from inventory data" -CA-TP3,27924,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,20050926 -CA-TP3,27924,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,Total aboveground (TT) includes bark; non-woody biomass is almost 100% moss biomass -CA-TP3,29129,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,5179.51853012583 -CA-TP3,29129,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Wood -CA-TP3,29129,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -CA-TP3,29129,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -CA-TP3,29129,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,"destructive tree sampling, upscaled to stand level using 1) site specific allometric equation [stem biomass=0.037*(DBH)^2.513] + [branch biomass=0.0001*(DBH)^4.217] and 2) stem density (1633 stems ha-1) from inventory data" -CA-TP3,29129,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,20071104 -CA-TP3,29129,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,Total aboveground (TT) includes bark; non-woody biomass is almost 100% moss biomass -CA-TP3,27566,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,5379 -CA-TP3,27566,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Total -CA-TP3,27566,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -CA-TP3,27566,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -CA-TP3,27566,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,"destructive tree sampling, upscaled to stand level using 1) site specific allometric equation [total aboveground biomass=0.0201*(DBH)^2.926 minus dead branches (= 0.0051*(DBH)^2.641] and 2) stem density (1633 stems ha-1) from inventory data" -CA-TP3,27566,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,20061024 -CA-TP3,27566,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,Total aboveground (TT) includes bark; non-woody biomass is almost 100% moss biomass -CA-TP3,29013,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,5551 -CA-TP3,29013,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Total -CA-TP3,29013,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -CA-TP3,29013,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -CA-TP3,29013,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,"destructive tree sampling, upscaled to stand level using 1) site specific allometric equation [total aboveground biomass=0.0201*(DBH)^2.926 minus dead branches (= 0.0051*(DBH)^2.641] and 2) stem density (1633 stems ha-1) from inventory data" -CA-TP3,29013,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,20071104 -CA-TP3,29013,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,Total aboveground (TT) includes bark; non-woody biomass is almost 100% moss biomass -CA-TP3,29015,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS,405 -CA-TP3,29015,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_UNIT,gC m-2 -CA-TP3,29015,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_DATE,20070721 -CA-TP3,29476,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS,545 -CA-TP3,29476,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_UNIT,gC m-2 -CA-TP3,29476,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_DATE,20040604 -CA-TP3,27007,GRP_AG_LIT_CHEM,AG_LIT_C,5.27 -CA-TP3,27007,GRP_AG_LIT_CHEM,AG_LIT_N,0.063 -CA-TP3,27007,GRP_AG_LIT_CHEM,AG_LIT_DATE,20071123 -CA-TP3,28186,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT,137 -CA-TP3,28186,GRP_AG_LIT_PROD,AG_LIT_PROD_UNIT,gC m-2 -CA-TP3,28186,GRP_AG_LIT_PROD,AG_LIT_PROD_COMMENT,mean of 3 years (2005-2007) -CA-TP3,29121,GRP_AG_PROD_OTHER,AG_PROD_OTHER,22.3 -CA-TP3,29121,GRP_AG_PROD_OTHER,AG_PROD_OTHER_ORGAN,Total -CA-TP3,29121,GRP_AG_PROD_OTHER,AG_PROD_OTHER_UNIT,gC m-2 -CA-TP3,29121,GRP_AG_PROD_OTHER,AG_PROD_DATE_START,20071104 -CA-TP3,29120,GRP_AG_PROD_OTHER,AG_PROD_OTHER,25.6 -CA-TP3,29120,GRP_AG_PROD_OTHER,AG_PROD_OTHER_ORGAN,Total -CA-TP3,29120,GRP_AG_PROD_OTHER,AG_PROD_OTHER_UNIT,gC m-2 -CA-TP3,29120,GRP_AG_PROD_OTHER,AG_PROD_DATE_START,20040927 -CA-TP3,27562,GRP_AG_PROD_SHRUB,AG_PROD_SHRUB,0 -CA-TP3,27562,GRP_AG_PROD_SHRUB,AG_PROD_SHRUB_ORGAN,Total -CA-TP3,27562,GRP_AG_PROD_SHRUB,AG_PROD_SHRUB_UNIT,gC m-2 -CA-TP3,27562,GRP_AG_PROD_SHRUB,AG_PROD_DATE_START,20040927 -CA-TP3,28180,GRP_AG_PROD_SHRUB,AG_PROD_SHRUB,0 -CA-TP3,28180,GRP_AG_PROD_SHRUB,AG_PROD_SHRUB_ORGAN,Total -CA-TP3,28180,GRP_AG_PROD_SHRUB,AG_PROD_SHRUB_UNIT,gC m-2 -CA-TP3,28180,GRP_AG_PROD_SHRUB,AG_PROD_DATE_START,20071104 -CA-TP3,28181,GRP_AG_PROD_SHRUB,AG_PROD_SHRUB,0 -CA-TP3,28181,GRP_AG_PROD_SHRUB,AG_PROD_SHRUB_ORGAN,Total -CA-TP3,28181,GRP_AG_PROD_SHRUB,AG_PROD_SHRUB_UNIT,gC m-2 -CA-TP3,28181,GRP_AG_PROD_SHRUB,AG_PROD_DATE_START,20050926 -CA-TP3,27913,GRP_AG_PROD_TREE,AG_PROD_TREE,111.637590591224 -CA-TP3,27913,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Wood -CA-TP3,27913,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -CA-TP3,27913,GRP_AG_PROD_TREE,AG_PROD_APPROACH,difference between annual standing wood biomass stock -CA-TP3,27913,GRP_AG_PROD_TREE,AG_PROD_DATE_START,20040927 -CA-TP3,27914,GRP_AG_PROD_TREE,AG_PROD_TREE,127.871829324731 -CA-TP3,27914,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Total -CA-TP3,27914,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -CA-TP3,27914,GRP_AG_PROD_TREE,AG_PROD_APPROACH,difference between annual standing aboveground biomass stock -CA-TP3,27914,GRP_AG_PROD_TREE,AG_PROD_DATE_START,20040927 -CA-TP3,29009,GRP_AG_PROD_TREE,AG_PROD_TREE,146.715277225621 -CA-TP3,29009,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Wood -CA-TP3,29009,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -CA-TP3,29009,GRP_AG_PROD_TREE,AG_PROD_APPROACH,difference between annual standing wood biomass stock -CA-TP3,29009,GRP_AG_PROD_TREE,AG_PROD_DATE_START,20071104 -CA-TP3,27915,GRP_AG_PROD_TREE,AG_PROD_TREE,16.2334672648144 -CA-TP3,27915,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Foliage -CA-TP3,27915,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -CA-TP3,27915,GRP_AG_PROD_TREE,AG_PROD_APPROACH,difference between annual standing foliage biomass stock -CA-TP3,27915,GRP_AG_PROD_TREE,AG_PROD_DATE_START,20071104 -CA-TP3,27291,GRP_AG_PROD_TREE,AG_PROD_TREE,169.417680847871 -CA-TP3,27291,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Total -CA-TP3,27291,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -CA-TP3,27291,GRP_AG_PROD_TREE,AG_PROD_APPROACH,difference between annual standing aboveground biomass stock -CA-TP3,27291,GRP_AG_PROD_TREE,AG_PROD_DATE_START,20071104 -CA-TP3,28282,GRP_AG_PROD_TREE,AG_PROD_TREE,17.7834624422623 -CA-TP3,28282,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Foliage -CA-TP3,28282,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -CA-TP3,28282,GRP_AG_PROD_TREE,AG_PROD_APPROACH,difference between annual standing foliage biomass stock -CA-TP3,28282,GRP_AG_PROD_TREE,AG_PROD_DATE_START,20050926 -CA-TP3,29472,GRP_AG_PROD_TREE,AG_PROD_TREE,199.72283601038 -CA-TP3,29472,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Wood -CA-TP3,29472,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -CA-TP3,29472,GRP_AG_PROD_TREE,AG_PROD_APPROACH,difference between annual standing wood biomass stock -CA-TP3,29472,GRP_AG_PROD_TREE,AG_PROD_DATE_START,20050926 -CA-TP3,27000,GRP_AG_PROD_TREE,AG_PROD_TREE,228.424377298351 -CA-TP3,27000,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Total -CA-TP3,27000,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -CA-TP3,27000,GRP_AG_PROD_TREE,AG_PROD_APPROACH,difference between annual standing aboveground biomass stock -CA-TP3,27000,GRP_AG_PROD_TREE,AG_PROD_DATE_START,20050926 -CA-TP3,26720,GRP_AG_PROD_TREE,AG_PROD_TREE,9.83156452701963 -CA-TP3,26720,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Foliage -CA-TP3,26720,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -CA-TP3,26720,GRP_AG_PROD_TREE,AG_PROD_APPROACH,difference between annual standing foliage biomass stock -CA-TP3,26720,GRP_AG_PROD_TREE,AG_PROD_DATE_START,20040927 -CA-TP3,29011,GRP_BIOMASS_CHEM,BIOMASS_N,0.113 -CA-TP3,29011,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -CA-TP3,29011,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -CA-TP3,29011,GRP_BIOMASS_CHEM,BIOMASS_SPP,PIST (NRCS plant code) -CA-TP3,29011,GRP_BIOMASS_CHEM,BIOMASS_DATE,20050920 -CA-TP3,12185,GRP_CLIM_AVG,MAT,8 -CA-TP3,12185,GRP_CLIM_AVG,MAP,1036 -CA-TP3,12185,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfb -CA-TP3,27000084,GRP_COUNTRY,COUNTRY,Canada -CA-TP3,7947,GRP_DM_PLANTING,DM_PLANTING,Planting live trees -CA-TP3,7947,GRP_DM_PLANTING,DM_DATE,1974 -CA-TP3,15707,GRP_DOI,DOI,10.17190/AMF/1246011 -CA-TP3,15707,GRP_DOI,DOI_CITATION,"M. Altaf Arain (2018), AmeriFlux BASE CA-TP3 Ontario - Turkey Point 1974 Plantation White Pine, Ver. 3-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1246011" -CA-TP3,15707,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -CA-TP3,31899,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -CA-TP3,31899,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,M. Altaf Arain -CA-TP3,31899,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -CA-TP3,31899,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,arainm@mcmaster.ca -CA-TP3,31899,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,McMaster University -CA-TP3,31901,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,McMaster University -CA-TP3,31901,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -CA-TP3,92928,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Canadian Foundation for Climate and Atmospheric Sciences (CFCAS) -CA-TP3,92928,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -CA-TP3,92913,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Canadian Foundation of Innovation (CFI) -CA-TP3,92913,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -CA-TP3,92925,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Global Water Futures (GWF) Program -CA-TP3,92925,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -CA-TP3,92918,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Natural Sciences and Engineering Research Council (NSREC) of Canada -CA-TP3,92918,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -CA-TP3,92915,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Ontario Innovation Trust (OIT) -CA-TP3,92915,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -CA-TP3,92914,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,"Ontario Ministry of the Environment, Conservation and Parks (MOECP)" -CA-TP3,92914,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -CA-TP3,12186,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Forestry -CA-TP3,12187,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -CA-TP3,12187,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -CA-TP3,12187,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,2003 -CA-TP3,12187,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -CA-TP3,12203,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -CA-TP3,12203,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -CA-TP3,12203,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,2003 -CA-TP3,12203,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -CA-TP3,12200,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -CA-TP3,12200,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -CA-TP3,12200,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,2003 -CA-TP3,12200,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -CA-TP3,23000084,GRP_HEADER,SITE_NAME,Ontario - Turkey Point 1974 Plantation White Pine -CA-TP3,89107,GRP_HEIGHTC,HEIGHTC,11.2 -CA-TP3,89107,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -CA-TP3,89107,GRP_HEIGHTC,HEIGHTC_DATE,20040927 -CA-TP3,89108,GRP_HEIGHTC,HEIGHTC,12.5 -CA-TP3,89108,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -CA-TP3,89108,GRP_HEIGHTC,HEIGHTC_DATE,20071104 -CA-TP3,89109,GRP_HEIGHTC,HEIGHTC,16.2 -CA-TP3,89109,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -CA-TP3,89109,GRP_HEIGHTC,HEIGHTC_DATE,20121016 -CA-TP3,12188,GRP_IGBP,IGBP,ENF -CA-TP3,12188,GRP_IGBP,IGBP_COMMENT,Plantation -CA-TP3,28518,GRP_LAI,LAI_TYPE,LAI -CA-TP3,28518,GRP_LAI,LAI_CLUMP,0.99 -CA-TP3,28518,GRP_LAI,LAI_METHOD,LAI_2000 -CA-TP3,28518,GRP_LAI,LAI_DATE,20050716 -CA-TP3,28518,GRP_LAI,LAI_COMMENT,"LAI estimates with LAI2000 and TRAC, see Chen et al 2006" -CA-TP3,28518,GRP_LAI,LAI_TOT,5.9 -CA-TP3,12189,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -CA-TP3,12189,GRP_LAND_OWNERSHIP,LAND_OWNER,Ontario Ministry of Natural Resources -CA-TP3,24277,GRP_LMA,LMA,46.01 -CA-TP3,24277,GRP_LMA,LMA_SPP,(All) -CA-TP3,12190,GRP_LOCATION,LOCATION_LAT,42.7068 -CA-TP3,12190,GRP_LOCATION,LOCATION_LONG,-80.3483 -CA-TP3,12190,GRP_LOCATION,LOCATION_ELEV,184 -CA-TP3,23775,GRP_N_DEP,N_DEP_WET,0.7 -CA-TP3,23775,GRP_N_DEP,N_DEP_COMMENT,"7 (Canadian Acid Deposition Assessment 2004 ;Environment Canada, 2004)" -CA-TP3,27300,GRP_NEP,NEP,451000 -CA-TP3,27300,GRP_NEP,NEP_APPROACH,eddy-covariance technique -CA-TP3,27300,GRP_NEP,NEP_DATE_START,20020601 -CA-TP3,27300,GRP_NEP,NEP_DATE_END,20070601 -CA-TP3,12201,GRP_NETWORK,NETWORK,AmeriFlux -CA-TP3,12191,GRP_NETWORK,NETWORK,Fluxnet-Canada -CA-TP3,86944,GRP_NETWORK,NETWORK,Phenocam -CA-TP3,1700005472,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Arain, M. A., Restrepo-Coupe, N. (2005) Net Ecosystem Production In A Temperate Pine Plantation In Southeastern Canada, Agricultural And Forest Meteorology, 128(3-4), 223-241" -CA-TP3,1700005472,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2004.10.003 -CA-TP3,1700005472,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-TP3,1700004623,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Arain, M.A., Xu, B., Brodeur, J.J., Khomik, M., Peichl, M., Beamesderfer, E., Restrepo‑Coupe, N., Thorne, R. (2022) Heat and drought impact on carbon exchange in an age‑sequence of temperate pine forests, Ecological Processes, 11(7), 108350" -CA-TP3,1700004623,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1186/S13717-021-00349-7 -CA-TP3,1700004623,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-TP3,1700008844,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Arain, M.A., Xu, B., Brodeur, J.J., Khomik, M., Peichl, M., Beamesderfer, E., Restrepo‑Coupe, N., Thorne, R. (2022) Heat and drought impact on carbon exchange in an age‑sequence of temperate pine forests, Ecological Processes, 11(7), 9275–9287" -CA-TP3,1700008844,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1186/S13717-021-00349-7 -CA-TP3,1700008844,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-TP3,1700001389,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Bodo, A. V., Arain, M. A. (2022) Effects Of Variable Retention Harvesting On Canopy Transpiration In A Red Pine Plantation Forest, Ecological Processes, 11(1), 4100-4113" -CA-TP3,1700001389,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1186/S13717-022-00366-0 -CA-TP3,1700001389,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-TP3,1700002121,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chen, J. M., Govind, A., Sonnentag, O., Zhang, Y., Barr, A., Amiro, B. (2006) Leaf Area Index Measurements At Fluxnet-Canada Forest Sites, Agricultural And Forest Meteorology, 140(1-4), 257-268" -CA-TP3,1700002121,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2006.08.005 -CA-TP3,1700002121,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-TP3,1700006405,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Baldocchi, D. D., Poindexter, C., Abraha, M., Desai, A. R., Bohrer, G., Arain, M. A., Griffis, T., Blanken, P. D., O'Halloran, T. L., Thomas, R. Q., Zhang, Q., Burns, S. P., Frank, J. M., Christian, D., Brown, S., Black, T. A., Gough, C. M., Law, B. E., Lee, X., Chen, J., Reed, D. E., Massman, W. J., Clark, K., Hatfield, J., Prueger, J., Bracho, R., Baker, J. M., Martin, T. A. (2018) Temporal Dynamics Of Aerodynamic Canopy Height Derived From Eddy Covariance Momentum Flux Data Across North American Flux Networks, Geophysical Research Letters, 45(1), 9275–9287" -CA-TP3,1700006405,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018GL079306 -CA-TP3,1700006405,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-TP3,1700003318,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(1), 108350" -CA-TP3,1700003318,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -CA-TP3,1700003318,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-TP3,1700002835,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Coursolle, C., Margolis, H. A., Barr, A. G., Black, T. A., Amiro, B. D., McCaughey, J. H., Flanagan, L. B., Lafleur, P. M., Roulet, N. T., Bourque, C. P., Arain, M. A., Wofsy, S. C., Dunn, A., Morgenstern, K., Orchansky, A. L., Bernier, P. Y., Chen, J. M., Kidston, J., Saigusa, N., Hedstrom, N. (2006) Late-Summer Carbon Fluxes From Canadian Forests And Peatlands Along An East-–West Continental Transect, Canadian Journal Of Forest Research, 36(3), 783-800" -CA-TP3,1700002835,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1139/X05-270 -CA-TP3,1700002835,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-TP3,1700003678,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Coursolle, C., Margolis, H., Giasson, M., Bernier, P., Amiro, B., Arain, M., Barr, A., Black, T., Goulden, M., McCaughey, J., Chen, J., Dunn, A., Grant, R., Lafleur, P. (2012) Influence Of Stand Age On The Magnitude And Seasonality Of Carbon Fluxes In Canadian Forests, Agricultural And Forest Meteorology, 165(7-8), 136-148" -CA-TP3,1700003678,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2012.06.011 -CA-TP3,1700003678,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-TP3,1700001791,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Khomik, M., Arain, M. A., Brodeur, J. J., Peichl, M., Restrepo-Coupé, N., McLaren, J. D. (2010) Relative Contributions Of Soil, Foliar, And Woody Tissue Respiration To Total Ecosystem Respiration In Four Pine Forests Of Different Ages, Journal Of Geophysical Research: Biogeosciences, 115(G03024), n/a-n/a" -CA-TP3,1700001791,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2009JG001089 -CA-TP3,1700001791,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-TP3,1700006642,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"McKenzie, S. M., Pisaric, M. F., Arain, M. A. (2021) Comparison Of Tree-Ring Growth And Eddy Covariance-Based Ecosystem Productivities In Three Different-Aged Pine Plantation Forests, Trees, 35(2), 583-595" -CA-TP3,1700006642,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1007/S00468-020-02061-Z -CA-TP3,1700006642,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-TP3,1700000873,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"McLaren, J. D., Arain, M.A., Khomik, M., Peichl, M., Brodeur, J. (2008) Water Flux Components And Soil Water-Atmospheric Controls In A Temperate Pine Forest Growing In A Well-Drained Sandy Soil, Journal Of Geophysical Research, 113(G4), n/a-n/a" -CA-TP3,1700000873,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2007JG000653 -CA-TP3,1700000873,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-TP3,1700001242,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Peichl, M., Arain, M. A. (2006) Above- And Belowground Ecosystem Biomass And Carbon Pools In An Age-Sequence Of Temperate Pine Plantation Forests, Agricultural And Forest Meteorology, 140(1-4), 51-63" -CA-TP3,1700001242,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2006.08.004 -CA-TP3,1700001242,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-TP3,1700008934,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Peichl, M., Arain, M. A. (2007) Allometry And Partitioning Of Above- And Belowground Tree Biomass In An Age-Sequence Of White Pine Forests, Forest Ecology And Management, 253(1-3), 68-80" -CA-TP3,1700008934,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.FORECO.2007.07.003 -CA-TP3,1700008934,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-TP3,1700006417,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Peichl, M., Arain, M. A., Brodeur, J. J. (2010) Age Effects On Carbon Fluxes In Temperate Pine Forests, Agricultural And Forest Meteorology, 150(7-8), 1090-1101" -CA-TP3,1700006417,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2010.04.008 -CA-TP3,1700006417,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-TP3,1700008412,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Peichl, M., Arain, M.A., Ullah, S., Moore, T. (2010) Carbon Dioxide, Methane, And Nitrous Oxide Exchanges In An Age-Sequence Of Temperate Pine Forests, Global Change Biology, 16(8), 2198-2212" -CA-TP3,1700008412,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/J.1365-2486.2009.02066.X -CA-TP3,1700008412,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-TP3,1700002460,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Peichl, M., Brodeur, J. J., Khomik, M., Arain, M. A. (2010) Biometric And Eddy-Covariance Based Estimates Of Carbon Fluxes In An Age-Sequence Of Temperate Pine Forests, Agricultural And Forest Meteorology, 150(7-8), 952-965" -CA-TP3,1700002460,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2010.03.002 -CA-TP3,1700002460,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Primary_Citation -CA-TP3,1700004566,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Peichl, M., Moore, T. R., Arain, M. A., Dalva, M., Brodkey, D., McLaren, J. (2007) Concentrations And Fluxes Of Dissolved Organic Carbon In An Age-Sequence Of White Pine Forests In Southern Ontario, Canada, Biogeochemistry, 86(1), 1-17" -CA-TP3,1700004566,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1007/S10533-007-9138-7 -CA-TP3,1700004566,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-TP3,1700004578,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Restrepo, N. C., Arain, M. A. (2005) Energy And Water Exchanges From A Temperate Pine Plantation Forest, Hydrological Processes, 19(1), 27-49" -CA-TP3,1700004578,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/HYP.5758 -CA-TP3,1700004578,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-TP3,1700001431,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Skubel, R. A., Khomik, M., Brodeur, J. J., Thorne, R., Arain, M. A. (2017) Short‐Term Selective Thinning Effects On Hydraulic Functionality Of A Temperate Pine Forest In Eastern Canada, Ecohydrology, 10(1), e1780" -CA-TP3,1700001431,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/ECO.1780 -CA-TP3,1700001431,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-TP3,1700005943,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Skubel, R., Arain, M. A., Peichl, M., Brodeur, J. J., Khomik, M., Thorne, R., Trant, J., Kula, M. (2015) Age Effects On The Water-Use Efficiency And Water-Use Dynamics Of Temperate Pine Plantation Forests, Hydrological Processes, 29(18), 4100-4113" -CA-TP3,1700005943,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/HYP.10549 -CA-TP3,1700005943,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-TP3,1700008820,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Xu, B., Arain, M. A., Black, T. A., Law, B. E., Pastorello, G. Z., Chu, H. (2020) Seasonal Variability Of Forest Sensitivity To Heat And Drought Stresses: A Synthesis Based On Carbon Fluxes From North American Forest Ecosystems, Global Change Biology, 26(2), 901-918" -CA-TP3,1700008820,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/GCB.14843 -CA-TP3,1700008820,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-TP3,1700008373,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Yuan, F., Arain, M. A., Barr, A. G., Black, T. A., Bourque, C. P., Coursolle, C., Margolis, H. A., Mccaughey, J. H., Wofsy, S. C. (2008) Modeling Analysis Of Primary Controls On Net Ecosystem Productivity Of Seven Boreal And Temperate Coniferous Forests Across A Continental Transect, Global Change Biology, 14(8), 1765-1784" -CA-TP3,1700008373,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/J.1365-2486.2008.01612.X -CA-TP3,1700008373,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-TP3,29008,GRP_ROOT_BIOMASS,ROOT_BIOMASS_CRS,1015 -CA-TP3,27302,GRP_ROOT_BIOMASS,ROOT_BIOMASS_CRS,1048 -CA-TP3,28286,GRP_ROOT_BIOMASS,ROOT_BIOMASS_CRS,945 -CA-TP3,27564,GRP_ROOT_BIOMASS,ROOT_BIOMASS_CRS,970 -CA-TP3,27303,GRP_ROOT_BIOMASS,ROOT_BIOMASS_FINE,300 -CA-TP3,28286,GRP_ROOT_BIOMASS,ROOT_BIOMASS_TOT,1245 -CA-TP3,27302,GRP_ROOT_BIOMASS,ROOT_BIOMASS_UNIT,gC m-2 -CA-TP3,27303,GRP_ROOT_BIOMASS,ROOT_BIOMASS_UNIT,gC m-2 -CA-TP3,27564,GRP_ROOT_BIOMASS,ROOT_BIOMASS_UNIT,gC m-2 -CA-TP3,28286,GRP_ROOT_BIOMASS,ROOT_BIOMASS_UNIT,gC m-2 -CA-TP3,29008,GRP_ROOT_BIOMASS,ROOT_BIOMASS_UNIT,gC m-2 -CA-TP3,27302,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MIN,0 -CA-TP3,27303,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MIN,0 -CA-TP3,27564,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MIN,0 -CA-TP3,28286,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MIN,0 -CA-TP3,29008,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MIN,0 -CA-TP3,27302,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MAX,100 -CA-TP3,27564,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MAX,100 -CA-TP3,28286,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MAX,100 -CA-TP3,29008,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MAX,100 -CA-TP3,27303,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MAX,55 -CA-TP3,27302,GRP_ROOT_BIOMASS,ROOT_BIOMASS_APPROACH,"destructive tree sampling, upscaled to stand level using 1) site specific allometric equation [root biomass=0.0028*(DBH)^2.998] and 2) stem density (1633 stems ha-1) from inventory data" -CA-TP3,27564,GRP_ROOT_BIOMASS,ROOT_BIOMASS_APPROACH,"destructive tree sampling, upscaled to stand level using 1) site specific allometric equation [root biomass=0.0028*(DBH)^2.998] and 2) stem density (1633 stems ha-1) from inventory data" -CA-TP3,28286,GRP_ROOT_BIOMASS,ROOT_BIOMASS_APPROACH,"destructive tree sampling, upscaled to stand level using 1) site specific allometric equation [root biomass=0.0028*(DBH)^2.998] and 2) stem density (1633 stems ha-1) from inventory data" -CA-TP3,29008,GRP_ROOT_BIOMASS,ROOT_BIOMASS_APPROACH,"destructive tree sampling, upscaled to stand level using 1) site specific allometric equation [root biomass=0.0028*(DBH)^2.998] and 2) stem density (1633 stems ha-1) from inventory data" -CA-TP3,27303,GRP_ROOT_BIOMASS,ROOT_BIOMASS_APPROACH,soil coring -CA-TP3,27303,GRP_ROOT_BIOMASS,ROOT_BIOMASS_DATE,20040927 -CA-TP3,28286,GRP_ROOT_BIOMASS,ROOT_BIOMASS_DATE,20040927 -CA-TP3,27564,GRP_ROOT_BIOMASS,ROOT_BIOMASS_DATE,20050926 -CA-TP3,29008,GRP_ROOT_BIOMASS,ROOT_BIOMASS_DATE,20061024 -CA-TP3,27302,GRP_ROOT_BIOMASS,ROOT_BIOMASS_DATE,20071104 -CA-TP3,27303,GRP_ROOT_BIOMASS,ROOT_BIOMASS_COMMENT,"date is for Cr >2mm from allometric equation, FR <2mm from soil coring on DOY 184" -CA-TP3,28286,GRP_ROOT_BIOMASS,ROOT_BIOMASS_COMMENT,"date is for Cr >2mm from allometric equation, FR <2mm from soil coring on DOY 184" -CA-TP3,27919,GRP_ROOT_PROD,ROOT_PROD_CRS,24.8563444977905 -CA-TP3,27920,GRP_ROOT_PROD,ROOT_PROD_CRS,33.2771660303901 -CA-TP3,27299,GRP_ROOT_PROD,ROOT_PROD_CRS,44.4226706124685 -CA-TP3,27299,GRP_ROOT_PROD,ROOT_PROD_UNIT,gC m-2 -CA-TP3,27919,GRP_ROOT_PROD,ROOT_PROD_UNIT,gC m-2 -CA-TP3,27920,GRP_ROOT_PROD,ROOT_PROD_UNIT,gC m-2 -CA-TP3,27299,GRP_ROOT_PROD,ROOT_PROD_PROFILE_MIN,0 -CA-TP3,27919,GRP_ROOT_PROD,ROOT_PROD_PROFILE_MIN,0 -CA-TP3,27920,GRP_ROOT_PROD,ROOT_PROD_PROFILE_MIN,0 -CA-TP3,27299,GRP_ROOT_PROD,ROOT_PROD_PROFILE_MAX,100 -CA-TP3,27919,GRP_ROOT_PROD,ROOT_PROD_PROFILE_MAX,100 -CA-TP3,27920,GRP_ROOT_PROD,ROOT_PROD_PROFILE_MAX,100 -CA-TP3,27299,GRP_ROOT_PROD,ROOT_PROD_APPROACH,difference between annual standing root biomass stock -CA-TP3,27919,GRP_ROOT_PROD,ROOT_PROD_APPROACH,difference between annual standing root biomass stock -CA-TP3,27920,GRP_ROOT_PROD,ROOT_PROD_APPROACH,difference between annual standing root biomass stock -CA-TP3,27919,GRP_ROOT_PROD,ROOT_PROD_DATE_START,20040927 -CA-TP3,27299,GRP_ROOT_PROD,ROOT_PROD_DATE_START,20050926 -CA-TP3,27920,GRP_ROOT_PROD,ROOT_PROD_DATE_START,20071104 -CA-TP3,27299,GRP_ROOT_PROD,ROOT_PROD_COMMENT,coarse root is >2mm -CA-TP3,27919,GRP_ROOT_PROD,ROOT_PROD_COMMENT,coarse root is >2mm -CA-TP3,27920,GRP_ROOT_PROD,ROOT_PROD_COMMENT,coarse root is >2mm -CA-TP3,26859,GRP_SA,SA_DATE,2008 -CA-TP3,26859,GRP_SA,SA_COMMENT,Trees are even-aged -CA-TP3,26859,GRP_SA,SA_MAX,34 -CA-TP3,29119,GRP_SA,SA,34 -CA-TP3,29119,GRP_SA,SA_DATE,2008 -CA-TP3,29119,GRP_SA,SA_COMMENT,Stand age in 2008 -CA-TP3,12193,GRP_SITE_CHAR,TERRAIN,Flat -CA-TP3,12193,GRP_SITE_CHAR,WIND_DIRECTION,SW -CA-TP3,12194,GRP_SITE_DESC,SITE_DESC,White pine plantation established in 1974 over sandy abandoned land -CA-TP3,12195,GRP_SITE_FUNDING,SITE_FUNDING,"Ontario Innovation Trust (OIT), Natural Sciences and Engineering Research Council (NSREC) of Canada, Ministry of Environment (MOE), Canadian Foundation for Climate and Atmospheric Sciences (CFCAS), Canadian Foundation of Innovation (CFI)" -CA-TP3,28188,GRP_SNAG_MASS,SNAG_MASS,43 -CA-TP3,28188,GRP_SNAG_MASS,SNAG_MASS_UNIT,gC m-2 -CA-TP3,28188,GRP_SNAG_MASS,SNAG_MASS_DATE,20071104 -CA-TP3,27304,GRP_SNAG_MASS,SNAG_MASS,8 -CA-TP3,27304,GRP_SNAG_MASS,SNAG_MASS_UNIT,gC m-2 -CA-TP3,27304,GRP_SNAG_MASS,SNAG_MASS_DATE,20050926 -CA-TP3,28191,GRP_SNAG_MASS,SNAG_MASS,8 -CA-TP3,28191,GRP_SNAG_MASS,SNAG_MASS_UNIT,gC m-2 -CA-TP3,28191,GRP_SNAG_MASS,SNAG_MASS_DATE,20040927 -CA-TP3,29007,GRP_SNAG_MASS,SNAG_MASS,9 -CA-TP3,29007,GRP_SNAG_MASS,SNAG_MASS_UNIT,gC m-2 -CA-TP3,29007,GRP_SNAG_MASS,SNAG_MASS_DATE,20061024 -CA-TP3,27923,GRP_SOIL_CHEM,SOIL_CHEM_C_ORG,36.4 -CA-TP3,29012,GRP_SOIL_CHEM,SOIL_CHEM_N_TOT,0.67 -CA-TP3,29127,GRP_SOIL_CHEM,SOIL_CHEM_PH_SALT,3.7 -CA-TP3,27009,GRP_SOIL_CHEM,SOIL_CHEM_PH_SALT,4.2 -CA-TP3,27922,GRP_SOIL_CHEM,SOIL_CHEM_BD,1.33 -CA-TP3,27922,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,0 -CA-TP3,27923,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,0 -CA-TP3,29012,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,0 -CA-TP3,29127,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,0 -CA-TP3,27009,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,20 -CA-TP3,29012,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,10 -CA-TP3,29127,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,10 -CA-TP3,27922,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,20 -CA-TP3,27009,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,30 -CA-TP3,27923,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,55 -CA-TP3,27922,GRP_SOIL_CHEM,SOIL_CHEM_DATE,20040702 -CA-TP3,27923,GRP_SOIL_CHEM,SOIL_CHEM_DATE,20040702 -CA-TP3,27009,GRP_SOIL_CHEM,SOIL_CHEM_DATE,20060706 -CA-TP3,29012,GRP_SOIL_CHEM,SOIL_CHEM_DATE,20060706 -CA-TP3,29127,GRP_SOIL_CHEM,SOIL_CHEM_DATE,20060706 -CA-TP3,27009,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,pH (CaCl) -CA-TP3,29127,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,pH (CaCl) -CA-TP3,24412,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION,brunisolic grey brown luvisol -CA-TP3,24412,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION_TAXONOMY,Other -CA-TP3,24412,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION_COMMENT," ->3m" -CA-TP3,27927,GRP_SOIL_DEPTH,SOIL_DEPTH,300 -CA-TP3,28438,GRP_SOIL_DEPTH,SOIL_DEPTH,300 -CA-TP3,27921,GRP_SOIL_TEX,SOIL_TEX_SAND,98 -CA-TP3,27921,GRP_SOIL_TEX,SOIL_TEX_SILT,2 -CA-TP3,27921,GRP_SOIL_TEX,SOIL_TEX_CLAY,0 -CA-TP3,28285,GRP_SPP_O,SPP_O,PIST (NRCS plant code) -CA-TP3,28285,GRP_SPP_O,SPP_O_PERC,94 -CA-TP3,28285,GRP_SPP_O,SPP_APPROACH,Canadian national forest inventory protocol: full inventory of 3 plots (each 400m2) -CA-TP3,28285,GRP_SPP_O,SPP_DATE,20040927 -CA-TP3,28285,GRP_SPP_O,SPP_COMMENT,inventory -CA-TP3,28528,GRP_SPP_U,SPP_U,PIBA2 (NRCS plant code) -CA-TP3,27008,GRP_SPP_U,SPP_U,QUVE (NRCS plant code) -CA-TP3,27008,GRP_SPP_U,SPP_U_PERC,1 -CA-TP3,28528,GRP_SPP_U,SPP_U_PERC,5 -CA-TP3,27008,GRP_SPP_U,SPP_APPROACH,Canadian national forest inventory protocol: full inventory of 3 plots (each 400m2) -CA-TP3,28528,GRP_SPP_U,SPP_APPROACH,Canadian national forest inventory protocol: full inventory of 3 plots (each 400m2) -CA-TP3,27008,GRP_SPP_U,SPP_DATE,20040927 -CA-TP3,28528,GRP_SPP_U,SPP_DATE,20040927 -CA-TP3,27008,GRP_SPP_U,SPP_COMMENT,inventory -CA-TP3,28528,GRP_SPP_U,SPP_COMMENT,inventory -CA-TP3,12196,GRP_STATE,STATE,Ontario -CA-TP3,26861,GRP_STUMP_MASS,STUMP_MASS,0.17 -CA-TP3,26861,GRP_STUMP_MASS,STUMP_MASS_UNIT,gC m-2 -CA-TP3,26861,GRP_STUMP_MASS,STUMP_MASS_DATE,20040927 -CA-TP3,12197,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,M. Altaf Arain -CA-TP3,12197,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -CA-TP3,12197,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,arainm@mcmaster.ca -CA-TP3,12197,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,McMaster University -CA-TP3,12197,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"McMaster University -School of Geography and Earth Sciences -1280 Main Steert West -Hamilton Ontario, Canada L8S4K1" -CA-TP3,81515,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Jason J. Brodeur -CA-TP3,81515,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,DataManager -CA-TP3,81515,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,brodeujj@mcmaster.ca -CA-TP3,81515,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,McMaster University -CA-TP3,81515,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"McMaster University, Mills Memorial Library, Rm 104/B -1280 Main Street West, Hamilton, ON L8S4L6" -CA-TP3,29793,GRP_TOWER_POWER,TOWER_POWER,Direct power -CA-TP3,12198,GRP_TOWER_TYPE,TOWER_TYPE,walk-up -CA-TP3,24000084,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/CA-TP3 -CA-TP3,12199,GRP_UTC_OFFSET,UTC_OFFSET,-5 -CA-TP3,28289,GRP_WD_BIOMASS,WD_BIOMASS_CRS,0 -CA-TP3,29477,GRP_WD_BIOMASS,WD_BIOMASS_CRS,0 -CA-TP3,29477,GRP_WD_BIOMASS,WD_BIOMASS_FINE,111 -CA-TP3,29016,GRP_WD_BIOMASS,WD_BIOMASS_FINE,74 -CA-TP3,28289,GRP_WD_BIOMASS,WD_BIOMASS_UNIT,gC m-2 -CA-TP3,29016,GRP_WD_BIOMASS,WD_BIOMASS_UNIT,gC m-2 -CA-TP3,29477,GRP_WD_BIOMASS,WD_BIOMASS_UNIT,gC m-2 -CA-TP3,29016,GRP_WD_BIOMASS,WD_BIOMASS_DATE,20040604 -CA-TP3,28289,GRP_WD_BIOMASS,WD_BIOMASS_DATE,20040713 -CA-TP3,29477,GRP_WD_BIOMASS,WD_BIOMASS_DATE,20070802 -CA-TP4,26266,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER,8.5 -CA-TP4,26266,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_ORGAN,Total -CA-TP4,26266,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_PHEN,Mixed/unknown -CA-TP4,26266,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_UNIT,gC m-2 -CA-TP4,26266,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_DATE,20040927 -CA-TP4,26266,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_COMMENT,Total aboveground (TT) includes bark -CA-TP4,26392,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB,16.6 -CA-TP4,26392,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_ORGAN,Total -CA-TP4,26392,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_PHEN,Mixed/unknown -CA-TP4,26392,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_UNIT,gC m-2 -CA-TP4,26392,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_DATE,20040927 -CA-TP4,26392,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_COMMENT,Total aboveground (TT) includes bark -CA-TP4,26166,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,10129.9333782516 -CA-TP4,26166,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Wood -CA-TP4,26166,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -CA-TP4,26166,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -CA-TP4,26166,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,20071024 -CA-TP4,26166,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,Total aboveground (TT) includes bark -CA-TP4,26393,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,10916.1543567165 -CA-TP4,26393,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Total -CA-TP4,26393,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -CA-TP4,26393,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -CA-TP4,26393,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,20040927 -CA-TP4,26393,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,Total aboveground (TT) includes bark -CA-TP4,25504,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,10960.8023226852 -CA-TP4,25504,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Total -CA-TP4,25504,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -CA-TP4,25504,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -CA-TP4,25504,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,20051009 -CA-TP4,25504,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,Total aboveground (TT) includes bark -CA-TP4,25654,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,11141.7244836555 -CA-TP4,25654,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Total -CA-TP4,25654,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -CA-TP4,25654,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -CA-TP4,25654,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,20061024 -CA-TP4,25654,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,Total aboveground (TT) includes bark -CA-TP4,26167,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,11288.8312548001 -CA-TP4,26167,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Total -CA-TP4,26167,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -CA-TP4,26167,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -CA-TP4,26167,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,20071024 -CA-TP4,26167,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,Total aboveground (TT) includes bark -CA-TP4,25381,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,181.887518977798 -CA-TP4,25381,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Foliage -CA-TP4,25381,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -CA-TP4,25381,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -CA-TP4,25381,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,20040927 -CA-TP4,25381,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,Total aboveground (TT) includes bark -CA-TP4,25503,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,182.931674604518 -CA-TP4,25503,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Foliage -CA-TP4,25503,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -CA-TP4,25503,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -CA-TP4,25503,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,20051009 -CA-TP4,25503,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,Total aboveground (TT) includes bark -CA-TP4,26650,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,187.91680341376 -CA-TP4,26650,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Foliage -CA-TP4,26650,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -CA-TP4,26650,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -CA-TP4,26650,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,20061024 -CA-TP4,26650,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,Total aboveground (TT) includes bark -CA-TP4,26523,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,191.40579705428 -CA-TP4,26523,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Foliage -CA-TP4,26523,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -CA-TP4,26523,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -CA-TP4,26523,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,20071024 -CA-TP4,26523,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,Total aboveground (TT) includes bark -CA-TP4,25245,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,9789.081398075 -CA-TP4,25245,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Wood -CA-TP4,25245,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -CA-TP4,25245,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -CA-TP4,25245,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,20040927 -CA-TP4,25245,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,Total aboveground (TT) includes bark -CA-TP4,26649,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,9829.70677702144 -CA-TP4,26649,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Wood -CA-TP4,26649,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -CA-TP4,26649,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -CA-TP4,26649,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,20051009 -CA-TP4,26649,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,Total aboveground (TT) includes bark -CA-TP4,26267,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,9995.88651420698 -CA-TP4,26267,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Wood -CA-TP4,26267,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -CA-TP4,26267,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -CA-TP4,26267,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,20061024 -CA-TP4,26267,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,Total aboveground (TT) includes bark -CA-TP4,25244,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS,1024 -CA-TP4,25244,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_UNIT,gC m-2 -CA-TP4,25244,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_DATE,20040604 -CA-TP4,25981,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS,847 -CA-TP4,25981,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_UNIT,gC m-2 -CA-TP4,25981,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_DATE,20070721 -CA-TP4,26145,GRP_AG_LIT_CHEM,AG_LIT_C,5.337 -CA-TP4,26145,GRP_AG_LIT_CHEM,AG_LIT_N,0.064 -CA-TP4,26145,GRP_AG_LIT_CHEM,AG_LIT_DATE,20071123 -CA-TP4,25997,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT,189 -CA-TP4,25997,GRP_AG_LIT_PROD,AG_LIT_PROD_UNIT,gC m-2 -CA-TP4,25997,GRP_AG_LIT_PROD,AG_LIT_PROD_COMMENT,mean of 3 years (2005-2007) -CA-TP4,26526,GRP_AG_PROD_OTHER,AG_PROD_OTHER,-9999 -CA-TP4,26526,GRP_AG_PROD_OTHER,AG_PROD_OTHER_ORGAN,Total -CA-TP4,26526,GRP_AG_PROD_OTHER,AG_PROD_OTHER_UNIT,gC m-2 -CA-TP4,26526,GRP_AG_PROD_OTHER,AG_PROD_DATE_START,20061024 -CA-TP4,26526,GRP_AG_PROD_OTHER,AG_PROD_COMMENT,"total aboveground production estimated with separate allom. Eq., not from the sum of foliage + wood; Litter production estimated from net change in standing foliage biomass; shrub production includes understorey trees with DBH <9cm" -CA-TP4,26395,GRP_AG_PROD_OTHER,AG_PROD_OTHER,12 -CA-TP4,26395,GRP_AG_PROD_OTHER,AG_PROD_OTHER_ORGAN,Total -CA-TP4,26395,GRP_AG_PROD_OTHER,AG_PROD_OTHER_UNIT,gC m-2 -CA-TP4,26395,GRP_AG_PROD_OTHER,AG_PROD_DATE_START,20071024 -CA-TP4,26395,GRP_AG_PROD_OTHER,AG_PROD_COMMENT,"total aboveground production estimated with separate allom. Eq., not from the sum of foliage + wood; Litter production estimated from net change in standing foliage biomass; shrub production includes understorey trees with DBH <9cm" -CA-TP4,26517,GRP_AG_PROD_OTHER,AG_PROD_OTHER,8.5 -CA-TP4,26517,GRP_AG_PROD_OTHER,AG_PROD_OTHER_ORGAN,Total -CA-TP4,26517,GRP_AG_PROD_OTHER,AG_PROD_OTHER_UNIT,gC m-2 -CA-TP4,26517,GRP_AG_PROD_OTHER,AG_PROD_DATE_START,20051009 -CA-TP4,26517,GRP_AG_PROD_OTHER,AG_PROD_COMMENT,"total aboveground production estimated with separate allom. Eq., not from the sum of foliage + wood; Litter production estimated from net change in standing foliage biomass; shrub production includes understorey trees with DBH <9cm" -CA-TP4,26265,GRP_AG_PROD_SHRUB,AG_PROD_SHRUB,31 -CA-TP4,26265,GRP_AG_PROD_SHRUB,AG_PROD_SHRUB_ORGAN,Total -CA-TP4,26265,GRP_AG_PROD_SHRUB,AG_PROD_SHRUB_UNIT,gC m-2 -CA-TP4,26265,GRP_AG_PROD_SHRUB,AG_PROD_DATE_START,20051009 -CA-TP4,26265,GRP_AG_PROD_SHRUB,AG_PROD_COMMENT,"total aboveground production estimated with separate allom. Eq., not from the sum of foliage + wood; Litter production estimated from net change in standing foliage biomass; shrub production includes understorey trees with DBH <9cm" -CA-TP4,26394,GRP_AG_PROD_SHRUB,AG_PROD_SHRUB,31 -CA-TP4,26394,GRP_AG_PROD_SHRUB,AG_PROD_SHRUB_ORGAN,Total -CA-TP4,26394,GRP_AG_PROD_SHRUB,AG_PROD_SHRUB_UNIT,gC m-2 -CA-TP4,26394,GRP_AG_PROD_SHRUB,AG_PROD_DATE_START,20061024 -CA-TP4,26394,GRP_AG_PROD_SHRUB,AG_PROD_COMMENT,"total aboveground production estimated with separate allom. Eq., not from the sum of foliage + wood; Litter production estimated from net change in standing foliage biomass; shrub production includes understorey trees with DBH <9cm" -CA-TP4,26527,GRP_AG_PROD_SHRUB,AG_PROD_SHRUB,31 -CA-TP4,26527,GRP_AG_PROD_SHRUB,AG_PROD_SHRUB_ORGAN,Total -CA-TP4,26527,GRP_AG_PROD_SHRUB,AG_PROD_SHRUB_UNIT,gC m-2 -CA-TP4,26527,GRP_AG_PROD_SHRUB,AG_PROD_DATE_START,20071024 -CA-TP4,26527,GRP_AG_PROD_SHRUB,AG_PROD_COMMENT,"total aboveground production estimated with separate allom. Eq., not from the sum of foliage + wood; Litter production estimated from net change in standing foliage biomass; shrub production includes understorey trees with DBH <9cm" -CA-TP4,25651,GRP_AG_PROD_TREE,AG_PROD_TREE,1.01298680204255 -CA-TP4,25651,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Foliage -CA-TP4,25651,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -CA-TP4,25651,GRP_AG_PROD_TREE,AG_PROD_DATE_START,20051009 -CA-TP4,25651,GRP_AG_PROD_TREE,AG_PROD_COMMENT,"total aboveground production estimated with separate allom. Eq., not from the sum of foliage + wood; Litter production estimated from net change in standing foliage biomass; shrub production includes understorey trees with DBH <9cm" -CA-TP4,26269,GRP_AG_PROD_TREE,AG_PROD_TREE,134.257369115123 -CA-TP4,26269,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Wood -CA-TP4,26269,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -CA-TP4,26269,GRP_AG_PROD_TREE,AG_PROD_DATE_START,20071024 -CA-TP4,26269,GRP_AG_PROD_TREE,AG_PROD_COMMENT,"total aboveground production estimated with separate allom. Eq., not from the sum of foliage + wood; Litter production estimated from net change in standing foliage biomass; shrub production includes understorey trees with DBH <9cm" -CA-TP4,26651,GRP_AG_PROD_TREE,AG_PROD_TREE,143.995597744051 -CA-TP4,26651,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Total -CA-TP4,26651,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -CA-TP4,26651,GRP_AG_PROD_TREE,AG_PROD_DATE_START,20071024 -CA-TP4,26651,GRP_AG_PROD_TREE,AG_PROD_COMMENT,"total aboveground production estimated with separate allom. Eq., not from the sum of foliage + wood; Litter production estimated from net change in standing foliage biomass; shrub production includes understorey trees with DBH <9cm" -CA-TP4,25998,GRP_AG_PROD_TREE,AG_PROD_TREE,166.432219566227 -CA-TP4,25998,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Wood -CA-TP4,25998,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -CA-TP4,25998,GRP_AG_PROD_TREE,AG_PROD_DATE_START,20061024 -CA-TP4,25998,GRP_AG_PROD_TREE,AG_PROD_COMMENT,"total aboveground production estimated with separate allom. Eq., not from the sum of foliage + wood; Litter production estimated from net change in standing foliage biomass; shrub production includes understorey trees with DBH <9cm" -CA-TP4,26268,GRP_AG_PROD_TREE,AG_PROD_TREE,177.058738799335 -CA-TP4,26268,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Total -CA-TP4,26268,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -CA-TP4,26268,GRP_AG_PROD_TREE,AG_PROD_DATE_START,20061024 -CA-TP4,26268,GRP_AG_PROD_TREE,AG_PROD_COMMENT,"total aboveground production estimated with separate allom. Eq., not from the sum of foliage + wood; Litter production estimated from net change in standing foliage biomass; shrub production includes understorey trees with DBH <9cm" -CA-TP4,25246,GRP_AG_PROD_TREE,AG_PROD_TREE,3.38484457662409 -CA-TP4,25246,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Foliage -CA-TP4,25246,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -CA-TP4,25246,GRP_AG_PROD_TREE,AG_PROD_DATE_START,20071024 -CA-TP4,25246,GRP_AG_PROD_TREE,AG_PROD_COMMENT,"total aboveground production estimated with separate allom. Eq., not from the sum of foliage + wood; Litter production estimated from net change in standing foliage biomass; shrub production includes understorey trees with DBH <9cm" -CA-TP4,25996,GRP_AG_PROD_TREE,AG_PROD_TREE,4.83631899403994 -CA-TP4,25996,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Foliage -CA-TP4,25996,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -CA-TP4,25996,GRP_AG_PROD_TREE,AG_PROD_DATE_START,20061024 -CA-TP4,25996,GRP_AG_PROD_TREE,AG_PROD_COMMENT,"total aboveground production estimated with separate allom. Eq., not from the sum of foliage + wood; Litter production estimated from net change in standing foliage biomass; shrub production includes understorey trees with DBH <9cm" -CA-TP4,25652,GRP_AG_PROD_TREE,AG_PROD_TREE,40.689355275346 -CA-TP4,25652,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Wood -CA-TP4,25652,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -CA-TP4,25652,GRP_AG_PROD_TREE,AG_PROD_DATE_START,20051009 -CA-TP4,25652,GRP_AG_PROD_TREE,AG_PROD_COMMENT,"total aboveground production estimated with separate allom. Eq., not from the sum of foliage + wood; Litter production estimated from net change in standing foliage biomass; shrub production includes understorey trees with DBH <9cm" -CA-TP4,26164,GRP_AG_PROD_TREE,AG_PROD_TREE,43.7043694655337 -CA-TP4,26164,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Total -CA-TP4,26164,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -CA-TP4,26164,GRP_AG_PROD_TREE,AG_PROD_DATE_START,20051009 -CA-TP4,26164,GRP_AG_PROD_TREE,AG_PROD_COMMENT,"total aboveground production estimated with separate allom. Eq., not from the sum of foliage + wood; Litter production estimated from net change in standing foliage biomass; shrub production includes understorey trees with DBH <9cm" -CA-TP4,26525,GRP_BIOMASS_CHEM,BIOMASS_N,0.1385 -CA-TP4,26525,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -CA-TP4,26525,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -CA-TP4,26525,GRP_BIOMASS_CHEM,BIOMASS_SPP,PIST (NRCS plant code) -CA-TP4,26525,GRP_BIOMASS_CHEM,BIOMASS_DATE,20050920 -CA-TP4,12217,GRP_CLIM_AVG,MAT,8 -CA-TP4,12217,GRP_CLIM_AVG,MAP,1036 -CA-TP4,12217,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfb -CA-TP4,27000085,GRP_COUNTRY,COUNTRY,Canada -CA-TP4,7943,GRP_DM_FORESTRY,DM_FORESTRY,Thinning/pruning -CA-TP4,7943,GRP_DM_FORESTRY,DM_DATE,1983 -CA-TP4,9644,GRP_DM_PLANTING,DM_PLANTING,Planting live trees -CA-TP4,9644,GRP_DM_PLANTING,DM_DATE,1939 -CA-TP4,9644,GRP_DM_PLANTING,DM_COMMENT,0.2 -CA-TP4,15693,GRP_DOI,DOI,10.17190/AMF/1246012 -CA-TP4,15693,GRP_DOI,DOI_CITATION,"M. Altaf Arain (2018), AmeriFlux BASE CA-TP4 Ontario - Turkey Point 1939 Plantation White Pine, Ver. 4-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1246012" -CA-TP4,15693,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -CA-TP4,31902,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -CA-TP4,31902,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,M. Altaf Arain -CA-TP4,31902,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -CA-TP4,31902,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,arainm@mcmaster.ca -CA-TP4,31902,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,McMaster University -CA-TP4,31904,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,McMaster University -CA-TP4,31904,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -CA-TP4,92919,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Canadian Foundation for Climate and Atmospheric Sciences (CFCAS) -CA-TP4,92919,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -CA-TP4,92923,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Canadian Foundation of Innovation (CFI) -CA-TP4,92923,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -CA-TP4,92920,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Global Water Futures (GWF) Program -CA-TP4,92920,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -CA-TP4,92927,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Natural Sciences and Engineering Research Council (NSREC) of Canada -CA-TP4,92927,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -CA-TP4,92934,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Ontario Innovation Trust (OIT) -CA-TP4,92934,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -CA-TP4,92931,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,"Ontario Ministry of the Environment, Conservation and Parks (MOECP)" -CA-TP4,92931,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -CA-TP4,12218,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Forestry -CA-TP4,12219,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -CA-TP4,12219,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -CA-TP4,12219,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20030101 -CA-TP4,12219,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -CA-TP4,12235,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -CA-TP4,12235,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -CA-TP4,12235,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20030101 -CA-TP4,12235,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -CA-TP4,12232,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -CA-TP4,12232,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -CA-TP4,12232,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20030101 -CA-TP4,12232,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -CA-TP4,12237,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Chambers -CA-TP4,12237,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -CA-TP4,12237,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20080701 -CA-TP4,12237,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -CA-TP4,23000085,GRP_HEADER,SITE_NAME,Ontario - Turkey Point 1939 Plantation White Pine -CA-TP4,89111,GRP_HEIGHTC,HEIGHTC,20.3 -CA-TP4,89111,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -CA-TP4,89111,GRP_HEIGHTC,HEIGHTC_DATE,20040927 -CA-TP4,89110,GRP_HEIGHTC,HEIGHTC,21.8 -CA-TP4,89110,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -CA-TP4,89110,GRP_HEIGHTC,HEIGHTC_DATE,20071024 -CA-TP4,89112,GRP_HEIGHTC,HEIGHTC,23.4 -CA-TP4,89112,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -CA-TP4,89112,GRP_HEIGHTC,HEIGHTC_DATE,20121015 -CA-TP4,12220,GRP_IGBP,IGBP,ENF -CA-TP4,12220,GRP_IGBP,IGBP_COMMENT,Plantation -CA-TP4,25764,GRP_LAI,LAI_TYPE,LAI -CA-TP4,25764,GRP_LAI,LAI_CLUMP,0.98 -CA-TP4,25764,GRP_LAI,LAI_METHOD,LAI_2000 -CA-TP4,25764,GRP_LAI,LAI_DATE,20050716 -CA-TP4,25764,GRP_LAI,LAI_COMMENT,"LAI estimates with LAI2000 and TRAC, see Chen et al 2006" -CA-TP4,25764,GRP_LAI,LAI_TOT,8 -CA-TP4,12221,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -CA-TP4,12221,GRP_LAND_OWNERSHIP,LAND_OWNER,Ontario Ministry of Natural Resources -CA-TP4,25051,GRP_LMA,LMA,28.55 -CA-TP4,25051,GRP_LMA,LMA_SPP,(All) -CA-TP4,12222,GRP_LOCATION,LOCATION_LAT,42.7102 -CA-TP4,12222,GRP_LOCATION,LOCATION_LONG,-80.3574 -CA-TP4,12222,GRP_LOCATION,LOCATION_ELEV,184 -CA-TP4,24928,GRP_N_DEP,N_DEP_WET,0.7 -CA-TP4,24928,GRP_N_DEP,N_DEP_COMMENT,"7 (Canadian Acid Deposition Assessment 2004 ;Environment Canada, 2004)" -CA-TP4,25656,GRP_NEP,NEP,124000 -CA-TP4,25656,GRP_NEP,NEP_DATE_START,20020601 -CA-TP4,25656,GRP_NEP,NEP_DATE_END,20070601 -CA-TP4,12233,GRP_NETWORK,NETWORK,AmeriFlux -CA-TP4,12223,GRP_NETWORK,NETWORK,Fluxnet-Canada -CA-TP4,86945,GRP_NETWORK,NETWORK,Phenocam -CA-TP4,1700004332,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Arain, M. A., Restrepo-Coupe, N. (2005) Net Ecosystem Production In A Temperate Pine Plantation In Southeastern Canada, Agricultural And Forest Meteorology, 128(3-4), 223-241" -CA-TP4,1700004332,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2004.10.003 -CA-TP4,1700004332,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Primary_Citation -CA-TP4,1700000834,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Arain, M.A., Xu, B., Brodeur, J.J., Khomik, M., Peichl, M., Beamesderfer, E., Restrepo‑Coupe, N., Thorne, R. (2022) Heat and drought impact on carbon exchange in an age‑sequence of temperate pine forests, Ecological Processes, 11(7), 108350" -CA-TP4,1700000834,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1186/S13717-021-00349-7 -CA-TP4,1700000834,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-TP4,1700000396,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Arain, M.A., Xu, B., Brodeur, J.J., Khomik, M., Peichl, M., Beamesderfer, E., Restrepo‑Coupe, N., Thorne, R. (2022) Heat and drought impact on carbon exchange in an age‑sequence of temperate pine forests, Ecological Processes, 11(7), 31-45" -CA-TP4,1700000396,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1186/S13717-021-00349-7 -CA-TP4,1700000396,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-TP4,1700004365,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Barr, A., Richardson, A., Hollinger, D., Papale, D., Arain, M., Black, T., Bohrer, G., Dragoni, D., Fischer, M., Gu, L., Law, B., Margolis, H., McCaughey, J., Munger, J., Oechel, W., Schaeffer, K. (2013) Use Of Change-Point Detection For Friction–Velocity Threshold Evaluation In Eddy-Covariance Studies, Agricultural And Forest Meteorology, 171-172(1), 31-45" -CA-TP4,1700004365,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2012.11.023 -CA-TP4,1700004365,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-TP4,1700008217,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Beamesderfer, E. R., Arain, M. A., Khomik, M., Brodeur, J. J., Burns, B. M. (2020) Response Of Carbon And Water Fluxes To Meteorological And Phenological Variability In Two Eastern North American Forests Of Similar Age But Contrasting Species Composition – A Multiyear Comparison, Biogeosciences, 17(13), 3563-3587" -CA-TP4,1700008217,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.5194/BG-17-3563-2020 -CA-TP4,1700008217,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-TP4,1700008442,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Bodo, A. V., Arain, M. A. (2022) Effects Of Variable Retention Harvesting On Canopy Transpiration In A Red Pine Plantation Forest, Ecological Processes, 11(1), 4100-4113" -CA-TP4,1700008442,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1186/S13717-022-00366-0 -CA-TP4,1700008442,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-TP4,1700001599,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Brümmer, C., Black, T. A., Jassal, R. S., Grant, N. J., Spittlehouse, D. L., Chen, B., Nesic, Z., Amiro, B. D., Arain, M. A., Barr, A. G., Bourque, C. P., Coursolle, C., Dunn, A. L., Flanagan, L. B., Humphreys, E. R., Lafleur, P. M., Margolis, H. A., McCaughey, J. H., Wofsy, S. C. (2012) How Climate And Vegetation Type Influence Evapotranspiration And Water Use Efficiency In Canadian Forest, Peatland And Grassland Ecosystems, Agricultural And Forest Meteorology, 153(8), 14-30" -CA-TP4,1700001599,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2011.04.008 -CA-TP4,1700001599,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-TP4,1700005445,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chen, J. M., Govind, A., Sonnentag, O., Zhang, Y., Barr, A., Amiro, B. (2006) Leaf Area Index Measurements At Fluxnet-Canada Forest Sites, Agricultural And Forest Meteorology, 140(1-4), 257-268" -CA-TP4,1700005445,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2006.08.005 -CA-TP4,1700005445,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-TP4,1700000630,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Baldocchi, D. D., Poindexter, C., Abraha, M., Desai, A. R., Bohrer, G., Arain, M. A., Griffis, T., Blanken, P. D., O'Halloran, T. L., Thomas, R. Q., Zhang, Q., Burns, S. P., Frank, J. M., Christian, D., Brown, S., Black, T. A., Gough, C. M., Law, B. E., Lee, X., Chen, J., Reed, D. E., Massman, W. J., Clark, K., Hatfield, J., Prueger, J., Bracho, R., Baker, J. M., Martin, T. A. (2018) Temporal Dynamics Of Aerodynamic Canopy Height Derived From Eddy Covariance Momentum Flux Data Across North American Flux Networks, Geophysical Research Letters, 45(1), 9275–9287" -CA-TP4,1700000630,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018GL079306 -CA-TP4,1700000630,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-TP4,1700007581,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(1), 108350" -CA-TP4,1700007581,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -CA-TP4,1700007581,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-TP4,1700008496,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Coursolle, C., Margolis, H. A., Barr, A. G., Black, T. A., Amiro, B. D., McCaughey, J. H., Flanagan, L. B., Lafleur, P. M., Roulet, N. T., Bourque, C. P., Arain, M. A., Wofsy, S. C., Dunn, A., Morgenstern, K., Orchansky, A. L., Bernier, P. Y., Chen, J. M., Kidston, J., Saigusa, N., Hedstrom, N. (2006) Late-Summer Carbon Fluxes From Canadian Forests And Peatlands Along An East-–West Continental Transect, Canadian Journal Of Forest Research, 36(3), 783-800" -CA-TP4,1700008496,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1139/X05-270 -CA-TP4,1700008496,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-TP4,1700004374,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Coursolle, C., Margolis, H., Giasson, M., Bernier, P., Amiro, B., Arain, M., Barr, A., Black, T., Goulden, M., McCaughey, J., Chen, J., Dunn, A., Grant, R., Lafleur, P. (2012) Influence Of Stand Age On The Magnitude And Seasonality Of Carbon Fluxes In Canadian Forests, Agricultural And Forest Meteorology, 165(7-8), 136-148" -CA-TP4,1700004374,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2012.06.011 -CA-TP4,1700004374,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-TP4,1700004464,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Dennis Baldocchi, Cove Sturtevant (2015) Does day and night sampling reduce spurious correlation between canopy photosynthesis and ecosystem respiration?, Agricultural and Forest Meteorology, 207(1), 117-126" -CA-TP4,1700004464,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2015.03.010 -CA-TP4,1700004464,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-TP4,1700003999,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Huang, S., Arain, M. A., Arora, V. K., Yuan, F., Brodeur, J., Peichl, M. (2011) Analysis Of Nitrogen Controls On Carbon And Water Exchanges In A Conifer Forest Using The CLASS-CTEMN+ Model, Ecological Modelling, 222(20-22), 3743-3760" -CA-TP4,1700003999,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.ECOLMODEL.2011.09.008 -CA-TP4,1700003999,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-TP4,1700005244,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Khomik, M., Arain, M. A., Brodeur, J. J., Peichl, M., Restrepo-Coupé, N., McLaren, J. D. (2010) Relative Contributions Of Soil, Foliar, And Woody Tissue Respiration To Total Ecosystem Respiration In Four Pine Forests Of Different Ages, Journal Of Geophysical Research: Biogeosciences, 115(G03024), n/a-n/a" -CA-TP4,1700005244,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2009JG001089 -CA-TP4,1700005244,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-TP4,1700008148,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"MacKay, S. L., Arain, M. A., Khomik, M., Brodeur, J. J., Schumacher, J., Hartmann, H., Peichl, M. (2012) The Impact Of Induced Drought On Transpiration And Growth In A Temperate Pine Plantation Forest, Hydrological Processes, 26(12), 1779-1791" -CA-TP4,1700008148,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/HYP.9315 -CA-TP4,1700008148,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-TP4,1700002730,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"McKenzie, S. M., Pisaric, M. F., Arain, M. A. (2021) Comparison Of Tree-Ring Growth And Eddy Covariance-Based Ecosystem Productivities In Three Different-Aged Pine Plantation Forests, Trees, 35(2), 583-595" -CA-TP4,1700002730,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1007/S00468-020-02061-Z -CA-TP4,1700002730,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-TP4,1700005070,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"McLaren, J. D., Arain, M.A., Khomik, M., Peichl, M., Brodeur, J. (2008) Water Flux Components And Soil Water-Atmospheric Controls In A Temperate Pine Forest Growing In A Well-Drained Sandy Soil, Journal Of Geophysical Research, 113(G4), n/a-n/a" -CA-TP4,1700005070,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2007JG000653 -CA-TP4,1700005070,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-TP4,1700002694,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Peichl, M., Arain, M. A. (2006) Above- And Belowground Ecosystem Biomass And Carbon Pools In An Age-Sequence Of Temperate Pine Plantation Forests, Agricultural And Forest Meteorology, 140(1-4), 51-63" -CA-TP4,1700002694,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2006.08.004 -CA-TP4,1700002694,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-TP4,1700001743,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Peichl, M., Arain, M. A. (2007) Allometry And Partitioning Of Above- And Belowground Tree Biomass In An Age-Sequence Of White Pine Forests, Forest Ecology And Management, 253(1-3), 68-80" -CA-TP4,1700001743,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.FORECO.2007.07.003 -CA-TP4,1700001743,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-TP4,1700000915,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Peichl, M., Arain, M. A., Brodeur, J. J. (2010) Age Effects On Carbon Fluxes In Temperate Pine Forests, Agricultural And Forest Meteorology, 150(7-8), 1090-1101" -CA-TP4,1700000915,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2010.04.008 -CA-TP4,1700000915,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-TP4,1700006096,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Peichl, M., Arain, M.A., Ullah, S., Moore, T. (2010) Carbon Dioxide, Methane, And Nitrous Oxide Exchanges In An Age-Sequence Of Temperate Pine Forests, Global Change Biology, 16(8), 2198-2212" -CA-TP4,1700006096,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/J.1365-2486.2009.02066.X -CA-TP4,1700006096,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-TP4,1700001860,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Peichl, M., Brodeur, J. J., Khomik, M., Arain, M. A. (2010) Biometric And Eddy-Covariance Based Estimates Of Carbon Fluxes In An Age-Sequence Of Temperate Pine Forests, Agricultural And Forest Meteorology, 150(7-8), 952-965" -CA-TP4,1700001860,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2010.03.002 -CA-TP4,1700001860,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-TP4,1700004383,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Peichl, M., Moore, T. R., Arain, M. A., Dalva, M., Brodkey, D., McLaren, J. (2007) Concentrations And Fluxes Of Dissolved Organic Carbon In An Age-Sequence Of White Pine Forests In Southern Ontario, Canada, Biogeochemistry, 86(1), 1-17" -CA-TP4,1700004383,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1007/S10533-007-9138-7 -CA-TP4,1700004383,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-TP4,1700003156,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Restrepo, N. C., Arain, M. A. (2005) Energy And Water Exchanges From A Temperate Pine Plantation Forest, Hydrological Processes, 19(1), 27-49" -CA-TP4,1700003156,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/HYP.5758 -CA-TP4,1700003156,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-TP4,1700008742,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Skubel, R. A., Khomik, M., Brodeur, J. J., Thorne, R., Arain, M. A. (2017) Short‐Term Selective Thinning Effects On Hydraulic Functionality Of A Temperate Pine Forest In Eastern Canada, Ecohydrology, 10(1), e1780" -CA-TP4,1700008742,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/ECO.1780 -CA-TP4,1700008742,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-TP4,1700008424,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Skubel, R., Arain, M. A., Peichl, M., Brodeur, J. J., Khomik, M., Thorne, R., Trant, J., Kula, M. (2015) Age Effects On The Water-Use Efficiency And Water-Use Dynamics Of Temperate Pine Plantation Forests, Hydrological Processes, 29(18), 4100-4113" -CA-TP4,1700008424,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/HYP.10549 -CA-TP4,1700008424,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-TP4,1700005469,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Thorne, R., Khomik, M., Hayman, E., Arain, A. (2020) Response Of Soil Co2 Efflux To Shelterwood Harvesting In A Mature Temperate Pine Forest, Forests, 11(3), 304" -CA-TP4,1700005469,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.3390/F11030304 -CA-TP4,1700005469,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-TP4,1700000912,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Xu, B., Arain, M. A., Black, T. A., Law, B. E., Pastorello, G. Z., Chu, H. (2020) Seasonal Variability Of Forest Sensitivity To Heat And Drought Stresses: A Synthesis Based On Carbon Fluxes From North American Forest Ecosystems, Global Change Biology, 26(2), 901-918" -CA-TP4,1700000912,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/GCB.14843 -CA-TP4,1700000912,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-TP4,1700001326,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Yuan, F., Arain, M. A., Barr, A. G., Black, T. A., Bourque, C. P., Coursolle, C., Margolis, H. A., Mccaughey, J. H., Wofsy, S. C. (2008) Modeling Analysis Of Primary Controls On Net Ecosystem Productivity Of Seven Boreal And Temperate Coniferous Forests Across A Continental Transect, Global Change Biology, 14(8), 1765-1784" -CA-TP4,1700001326,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/J.1365-2486.2008.01612.X -CA-TP4,1700001326,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-TP4,25650,GRP_ROOT_BIOMASS,ROOT_BIOMASS_CRS,2693.59299868456 -CA-TP4,26168,GRP_ROOT_BIOMASS,ROOT_BIOMASS_CRS,2709.15482602293 -CA-TP4,26524,GRP_ROOT_BIOMASS,ROOT_BIOMASS_CRS,2783.63268323452 -CA-TP4,25876,GRP_ROOT_BIOMASS,ROOT_BIOMASS_CRS,2835.64789560017 -CA-TP4,25502,GRP_ROOT_BIOMASS,ROOT_BIOMASS_FINE,170 -CA-TP4,25650,GRP_ROOT_BIOMASS,ROOT_BIOMASS_TOT,2863.59299868456 -CA-TP4,25502,GRP_ROOT_BIOMASS,ROOT_BIOMASS_UNIT,gC m-2 -CA-TP4,25650,GRP_ROOT_BIOMASS,ROOT_BIOMASS_UNIT,gC m-2 -CA-TP4,25876,GRP_ROOT_BIOMASS,ROOT_BIOMASS_UNIT,gC m-2 -CA-TP4,26168,GRP_ROOT_BIOMASS,ROOT_BIOMASS_UNIT,gC m-2 -CA-TP4,26524,GRP_ROOT_BIOMASS,ROOT_BIOMASS_UNIT,gC m-2 -CA-TP4,25502,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MIN,0 -CA-TP4,25650,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MIN,0 -CA-TP4,25876,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MIN,0 -CA-TP4,26168,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MIN,0 -CA-TP4,26524,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MIN,0 -CA-TP4,25650,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MAX,100 -CA-TP4,25876,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MAX,100 -CA-TP4,26168,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MAX,100 -CA-TP4,26524,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MAX,100 -CA-TP4,25502,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MAX,55 -CA-TP4,25502,GRP_ROOT_BIOMASS,ROOT_BIOMASS_DATE,20040927 -CA-TP4,25650,GRP_ROOT_BIOMASS,ROOT_BIOMASS_DATE,20040927 -CA-TP4,26168,GRP_ROOT_BIOMASS,ROOT_BIOMASS_DATE,20051009 -CA-TP4,26524,GRP_ROOT_BIOMASS,ROOT_BIOMASS_DATE,20061024 -CA-TP4,25876,GRP_ROOT_BIOMASS,ROOT_BIOMASS_DATE,20071024 -CA-TP4,25502,GRP_ROOT_BIOMASS,ROOT_BIOMASS_COMMENT,"date is for Cr >2mm from allometric equation, FR <2mm from soil coring on DOY 184" -CA-TP4,25650,GRP_ROOT_BIOMASS,ROOT_BIOMASS_COMMENT,"date is for Cr >2mm from allometric equation, FR <2mm from soil coring on DOY 184" -CA-TP4,25876,GRP_ROOT_BIOMASS,ROOT_BIOMASS_COMMENT,"date is for Cr >2mm from allometric equation, FR <2mm from soil coring on DOY 184" -CA-TP4,26168,GRP_ROOT_BIOMASS,ROOT_BIOMASS_COMMENT,"date is for Cr >2mm from allometric equation, FR <2mm from soil coring on DOY 184" -CA-TP4,26524,GRP_ROOT_BIOMASS,ROOT_BIOMASS_COMMENT,"date is for Cr >2mm from allometric equation, FR <2mm from soil coring on DOY 184" -CA-TP4,26263,GRP_ROOT_PROD,ROOT_PROD_CRS,14.6379749202388 -CA-TP4,25655,GRP_ROOT_PROD,ROOT_PROD_CRS,48.9272472649711 -CA-TP4,26497,GRP_ROOT_PROD,ROOT_PROD_CRS,70.0563617800912 -CA-TP4,25655,GRP_ROOT_PROD,ROOT_PROD_UNIT,gC m-2 -CA-TP4,26263,GRP_ROOT_PROD,ROOT_PROD_UNIT,gC m-2 -CA-TP4,26497,GRP_ROOT_PROD,ROOT_PROD_UNIT,gC m-2 -CA-TP4,25655,GRP_ROOT_PROD,ROOT_PROD_PROFILE_MIN,0 -CA-TP4,26263,GRP_ROOT_PROD,ROOT_PROD_PROFILE_MIN,0 -CA-TP4,26497,GRP_ROOT_PROD,ROOT_PROD_PROFILE_MIN,0 -CA-TP4,25655,GRP_ROOT_PROD,ROOT_PROD_PROFILE_MAX,100 -CA-TP4,26263,GRP_ROOT_PROD,ROOT_PROD_PROFILE_MAX,100 -CA-TP4,26497,GRP_ROOT_PROD,ROOT_PROD_PROFILE_MAX,100 -CA-TP4,26263,GRP_ROOT_PROD,ROOT_PROD_DATE_START,20051009 -CA-TP4,26497,GRP_ROOT_PROD,ROOT_PROD_DATE_START,20061024 -CA-TP4,25655,GRP_ROOT_PROD,ROOT_PROD_DATE_START,20071024 -CA-TP4,25655,GRP_ROOT_PROD,ROOT_PROD_COMMENT,coarse root is >2mm -CA-TP4,26263,GRP_ROOT_PROD,ROOT_PROD_COMMENT,coarse root is >2mm -CA-TP4,26497,GRP_ROOT_PROD,ROOT_PROD_COMMENT,coarse root is >2mm -CA-TP4,25243,GRP_SA,SA,69 -CA-TP4,25243,GRP_SA,SA_DATE,2008 -CA-TP4,25243,GRP_SA,SA_COMMENT,Stand age in 2008 -CA-TP4,25380,GRP_SA,SA_DATE,2008 -CA-TP4,25380,GRP_SA,SA_COMMENT,dominant trees are even-aged -CA-TP4,25380,GRP_SA,SA_MAX,69 -CA-TP4,12225,GRP_SITE_CHAR,TERRAIN,Flat -CA-TP4,12225,GRP_SITE_CHAR,WIND_DIRECTION,SW -CA-TP4,12226,GRP_SITE_DESC,SITE_DESC,White pine plantation established in 1939 over sandy abandoned land -CA-TP4,12227,GRP_SITE_FUNDING,SITE_FUNDING,"Natural Sciences and Engineering Research Council (NSREC) of Canada, Ministry of Environment (MOE), Canadian Foundation for Climate and Atmospheric Sciences (CFCAS), Canadian Foundation of Innovation (CFI), Ontario Innovation Trust (OIT)" -CA-TP4,26157,GRP_SNAG_MASS,SNAG_MASS,55 -CA-TP4,26157,GRP_SNAG_MASS,SNAG_MASS_UNIT,gC m-2 -CA-TP4,26157,GRP_SNAG_MASS,SNAG_MASS_DATE,20040927 -CA-TP4,26158,GRP_SNAG_MASS,SNAG_MASS,82 -CA-TP4,26158,GRP_SNAG_MASS,SNAG_MASS_UNIT,gC m-2 -CA-TP4,26158,GRP_SNAG_MASS,SNAG_MASS_DATE,20051009 -CA-TP4,25637,GRP_SNAG_MASS,SNAG_MASS,85 -CA-TP4,25637,GRP_SNAG_MASS,SNAG_MASS_UNIT,gC m-2 -CA-TP4,25637,GRP_SNAG_MASS,SNAG_MASS_DATE,20061024 -CA-TP4,25855,GRP_SNAG_MASS,SNAG_MASS,85 -CA-TP4,25855,GRP_SNAG_MASS,SNAG_MASS_UNIT,gC m-2 -CA-TP4,25855,GRP_SNAG_MASS,SNAG_MASS_DATE,20071024 -CA-TP4,25486,GRP_SOIL_CHEM,SOIL_CHEM_C_ORG,36.7 -CA-TP4,25873,GRP_SOIL_CHEM,SOIL_CHEM_N_TOT,0.67 -CA-TP4,25760,GRP_SOIL_CHEM,SOIL_CHEM_PH_SALT,4.1 -CA-TP4,25987,GRP_SOIL_CHEM,SOIL_CHEM_PH_SALT,4.2 -CA-TP4,25382,GRP_SOIL_CHEM,SOIL_CHEM_BD,1.35 -CA-TP4,25382,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,0 -CA-TP4,25486,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,0 -CA-TP4,25760,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,0 -CA-TP4,25873,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,0 -CA-TP4,25987,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,20 -CA-TP4,25760,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,10 -CA-TP4,25873,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,10 -CA-TP4,25382,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,20 -CA-TP4,25987,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,30 -CA-TP4,25486,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,55 -CA-TP4,25382,GRP_SOIL_CHEM,SOIL_CHEM_DATE,20040702 -CA-TP4,25486,GRP_SOIL_CHEM,SOIL_CHEM_DATE,20040702 -CA-TP4,25760,GRP_SOIL_CHEM,SOIL_CHEM_DATE,20060706 -CA-TP4,25873,GRP_SOIL_CHEM,SOIL_CHEM_DATE,20060706 -CA-TP4,25987,GRP_SOIL_CHEM,SOIL_CHEM_DATE,20060706 -CA-TP4,25760,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,pH (CaCl) -CA-TP4,25987,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,pH (CaCl) -CA-TP4,24283,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION,brunisolic grey brown luvisol -CA-TP4,24283,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION_TAXONOMY,Other -CA-TP4,24283,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION_COMMENT," ->3m" -CA-TP4,26644,GRP_SOIL_DEPTH,SOIL_DEPTH,300 -CA-TP4,28943,GRP_SOIL_DEPTH,SOIL_DEPTH,300 -CA-TP4,26636,GRP_SOIL_TEX,SOIL_TEX_SAND,98 -CA-TP4,26636,GRP_SOIL_TEX,SOIL_TEX_SILT,2 -CA-TP4,26636,GRP_SOIL_TEX,SOIL_TEX_CLAY,0 -CA-TP4,26165,GRP_SPP_O,SPP_O,PIST (NRCS plant code) -CA-TP4,26165,GRP_SPP_O,SPP_O_PERC,82 -CA-TP4,26165,GRP_SPP_O,SPP_DATE,20040927 -CA-TP4,26165,GRP_SPP_O,SPP_COMMENT,inventory -CA-TP4,26518,GRP_SPP_U,SPP_U,ABBA (NRCS plant code) -CA-TP4,26519,GRP_SPP_U,SPP_U,ACRU (NRCS plant code) -CA-TP4,26520,GRP_SPP_U,SPP_U,PRSE2 (NRCS plant code) -CA-TP4,25653,GRP_SPP_U,SPP_U,QUVE (NRCS plant code) -CA-TP4,26520,GRP_SPP_U,SPP_U_PERC,1 -CA-TP4,26518,GRP_SPP_U,SPP_U_PERC,11 -CA-TP4,26519,GRP_SPP_U,SPP_U_PERC,2 -CA-TP4,25653,GRP_SPP_U,SPP_U_PERC,4 -CA-TP4,25653,GRP_SPP_U,SPP_DATE,20040927 -CA-TP4,26518,GRP_SPP_U,SPP_DATE,20040927 -CA-TP4,26519,GRP_SPP_U,SPP_DATE,20040927 -CA-TP4,26520,GRP_SPP_U,SPP_DATE,20040927 -CA-TP4,25653,GRP_SPP_U,SPP_COMMENT,inventory -CA-TP4,26518,GRP_SPP_U,SPP_COMMENT,inventory -CA-TP4,26519,GRP_SPP_U,SPP_COMMENT,inventory -CA-TP4,26520,GRP_SPP_U,SPP_COMMENT,inventory -CA-TP4,12228,GRP_STATE,STATE,Ontario -CA-TP4,25874,GRP_STUMP_MASS,STUMP_MASS,0.84 -CA-TP4,25874,GRP_STUMP_MASS,STUMP_MASS_UNIT,gC m-2 -CA-TP4,12229,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,M. Altaf Arain -CA-TP4,12229,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -CA-TP4,12229,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,arainm@mcmaster.ca -CA-TP4,12229,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,McMaster University -CA-TP4,12229,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"McMaster University -School of Geography and Earth Sciences -1280 Main Steert West -Hamilton Ontario, Canada L8S4K1" -CA-TP4,81516,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Jason J. Brodeur -CA-TP4,81516,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,DataManager -CA-TP4,81516,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,brodeujj@mcmaster.ca -CA-TP4,81516,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,McMaster University -CA-TP4,81516,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"McMaster University, Mills Memorial Library, Rm 104/B -1280 Main Street West, Hamilton, ON L8S4L6" -CA-TP4,29794,GRP_TOWER_POWER,TOWER_POWER,Direct power -CA-TP4,12230,GRP_TOWER_TYPE,TOWER_TYPE,walk-up -CA-TP4,9479,GRP_URL,URL,http://www.fluxnet-canada.ca/visionneuse.php?page=components_fsmp_tp -CA-TP4,24000085,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/CA-TP4 -CA-TP4,12231,GRP_UTC_OFFSET,UTC_OFFSET,-5 -CA-TP4,26375,GRP_WD_BIOMASS,WD_BIOMASS_CRS,115 -CA-TP4,26163,GRP_WD_BIOMASS,WD_BIOMASS_CRS,85 -CA-TP4,25649,GRP_WD_BIOMASS,WD_BIOMASS_FINE,115 -CA-TP4,26375,GRP_WD_BIOMASS,WD_BIOMASS_FINE,135 -CA-TP4,25649,GRP_WD_BIOMASS,WD_BIOMASS_UNIT,gC m-2 -CA-TP4,26163,GRP_WD_BIOMASS,WD_BIOMASS_UNIT,gC m-2 -CA-TP4,26375,GRP_WD_BIOMASS,WD_BIOMASS_UNIT,gC m-2 -CA-TP4,25649,GRP_WD_BIOMASS,WD_BIOMASS_DATE,20040604 -CA-TP4,26163,GRP_WD_BIOMASS,WD_BIOMASS_DATE,20040707 -CA-TP4,26375,GRP_WD_BIOMASS,WD_BIOMASS_DATE,20070802 -CA-TPD,12253,GRP_CLIM_AVG,MAT,8 -CA-TPD,12253,GRP_CLIM_AVG,MAP,1036 -CA-TPD,12253,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfb -CA-TPD,27000524,GRP_COUNTRY,COUNTRY,Canada -CA-TPD,15671,GRP_DOI,DOI,10.17190/AMF/1246152 -CA-TPD,15671,GRP_DOI,DOI_CITATION,"M. Altaf Arain (2018), AmeriFlux BASE CA-TPD Ontario - Turkey Point Mature Deciduous, Ver. 2-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1246152" -CA-TPD,15671,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -CA-TPD,32386,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -CA-TPD,32386,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,M. Altaf Arain -CA-TPD,32386,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -CA-TPD,32386,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,arainm@mcmaster.ca -CA-TPD,32386,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,McMaster University -CA-TPD,32388,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,McMaster University -CA-TPD,32388,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -CA-TPD,92933,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Canadian Foundation for Climate and Atmospheric Sciences (CFCAS) -CA-TPD,92933,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -CA-TPD,92924,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Canadian Foundation of Innovation (CFI) -CA-TPD,92924,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -CA-TPD,92912,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Global Water Futures (GWF) Program -CA-TPD,92912,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -CA-TPD,92917,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Natural Sciences and Engineering Research Council (NSREC) of Canada -CA-TPD,92917,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -CA-TPD,92916,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Ontario Innovation Trust (OIT) -CA-TPD,92916,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -CA-TPD,92926,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,"Ontario Ministry of the Environment, Conservation and Parks (MOECP)" -CA-TPD,92926,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -CA-TPD,12254,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Forestry -CA-TPD,12255,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -CA-TPD,12255,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -CA-TPD,12255,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20120105 -CA-TPD,12255,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -CA-TPD,12269,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -CA-TPD,12269,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -CA-TPD,12269,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20120105 -CA-TPD,12269,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -CA-TPD,12267,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -CA-TPD,12267,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -CA-TPD,12267,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20120105 -CA-TPD,12267,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -CA-TPD,12270,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Chambers -CA-TPD,12270,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -CA-TPD,12270,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20140704 -CA-TPD,12270,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -CA-TPD,23000524,GRP_HEADER,SITE_NAME,Ontario - Turkey Point Mature Deciduous -CA-TPD,88369,GRP_HEIGHTC,HEIGHTC,25.7 -CA-TPD,88369,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -CA-TPD,88369,GRP_HEIGHTC,HEIGHTC_DATE,20120105 -CA-TPD,12256,GRP_IGBP,IGBP,DBF -CA-TPD,12257,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -CA-TPD,12257,GRP_LAND_OWNERSHIP,LAND_OWNER,"Long Point Region Conservation Authority (LPRCA), Ontario Ministry of Natural Resources (OMNR) and Private Land Owners." -CA-TPD,12258,GRP_LOCATION,LOCATION_LAT,42.6353 -CA-TPD,12258,GRP_LOCATION,LOCATION_LONG,-80.5577 -CA-TPD,12258,GRP_LOCATION,LOCATION_ELEV,260 -CA-TPD,12268,GRP_NETWORK,NETWORK,AmeriFlux -CA-TPD,12259,GRP_NETWORK,NETWORK,Fluxnet-Canada -CA-TPD,86946,GRP_NETWORK,NETWORK,Phenocam -CA-TPD,1700000939,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Beamesderfer, E. R., Arain, M. A., Khomik, M., Brodeur, J. J. (2020) The Impact Of Seasonal And Annual Climate Variations On The Carbon Uptake Capacity Of A Deciduous Forest Within The Great Lakes Region Of Canada, Journal Of Geophysical Research: Biogeosciences, 125(9), 108350" -CA-TPD,1700000939,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2019JG005389 -CA-TPD,1700000939,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-TPD,1700006195,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Beamesderfer, E. R., Arain, M. A., Khomik, M., Brodeur, J. J. (2020) The Impact Of Seasonal And Annual Climate Variations On The Carbon Uptake Capacity Of A Deciduous Forest Within The Great Lakes Region Of Canada, Journal Of Geophysical Research: Biogeosciences, 125(9), 9275–9287" -CA-TPD,1700006195,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2019JG005389 -CA-TPD,1700006195,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-TPD,1700002238,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Beamesderfer, E. R., Arain, M. A., Khomik, M., Brodeur, J. J., Burns, B. M. (2020) Response Of Carbon And Water Fluxes To Meteorological And Phenological Variability In Two Eastern North American Forests Of Similar Age But Contrasting Species Composition – A Multiyear Comparison, Biogeosciences, 17(13), 3563-3587" -CA-TPD,1700002238,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.5194/BG-17-3563-2020 -CA-TPD,1700002238,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-TPD,1700006294,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Baldocchi, D. D., Poindexter, C., Abraha, M., Desai, A. R., Bohrer, G., Arain, M. A., Griffis, T., Blanken, P. D., O'Halloran, T. L., Thomas, R. Q., Zhang, Q., Burns, S. P., Frank, J. M., Christian, D., Brown, S., Black, T. A., Gough, C. M., Law, B. E., Lee, X., Chen, J., Reed, D. E., Massman, W. J., Clark, K., Hatfield, J., Prueger, J., Bracho, R., Baker, J. M., Martin, T. A. (2018) Temporal Dynamics Of Aerodynamic Canopy Height Derived From Eddy Covariance Momentum Flux Data Across North American Flux Networks, Geophysical Research Letters, 45(), 9275–9287" -CA-TPD,1700006294,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018GL079306 -CA-TPD,1700006294,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-TPD,1700008322,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Baldocchi, D. D., Poindexter, C., Abraha, M., Desai, A. R., Bohrer, G., Arain, M. A., Griffis, T., Blanken, P. D., O'Halloran, T. L., Thomas, R. Q., Zhang, Q., Burns, S. P., Frank, J. M., Christian, D., Brown, S., Black, T. A., Gough, C. M., Law, B. E., Lee, X., Chen, J., Reed, D. E., Massman, W. J., Clark, K., Hatfield, J., Prueger, J., Bracho, R., Baker, J. M., Martin, T. A. (2018) Temporal Dynamics Of Aerodynamic Canopy Height Derived From Eddy Covariance Momentum Flux Data Across North American Flux Networks, Geophysical Research Letters, 45(13), 9275–9287" -CA-TPD,1700008322,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018GL079306 -CA-TPD,1700008322,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-TPD,1700006006,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(), 108350" -CA-TPD,1700006006,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -CA-TPD,1700006006,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CA-TPD,12260,GRP_SITE_CHAR,TERRAIN,Undulated/Variable -CA-TPD,12260,GRP_SITE_CHAR,WIND_DIRECTION,SW -CA-TPD,12261,GRP_SITE_DESC,SITE_DESC,"The forest is approximately 90 years old. Naturally regenerated on sandy terrain and abandoned agricultural land. Predominantly hardwood species with a few scattered conifers. Site has been managed (thinned) in the past. It has a high biodiversity with 573 tree and plant species, 102 bird species, 23 mamal species and 22 reptile and amphibian species (SWALSREP Report, 1999). The dominant tree species is white oak (Quercus alba), with other scattered broadleaf Carolinian species including sugar and red maple (Acer saccharum, A. rubrum), American beech (Fagus grandifolia), black and red oak (Q. velutina, Q. rubra) and white ash (Fraxinus americana) . There are also scattered conifers, mostly white and red pine (Pinus strobes, P. resinosa), comprising about 5% of the trees. Average tree height is 25.7 m with a stand density of 504 ± 18 trees per hectare. Average tree diameter at breast height is 22.3 cm and basal area is 0.06 m2 or approximately 29 square meters per hectare." -CA-TPD,12262,GRP_SITE_FUNDING,SITE_FUNDING,"Natural Sciences and Engineering Research Council (NSREC) of Canada, Ministry of Environment (MOE), Canadian Foundation for Climate and Atmospheric Sciences (CFCAS), Canadian Foundation of Innovation (CFI), Ontario Innovation Trust (OIT)" -CA-TPD,12263,GRP_STATE,STATE,Ontario -CA-TPD,12264,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,M. Altaf Arain -CA-TPD,12264,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -CA-TPD,12264,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,arainm@mcmaster.ca -CA-TPD,12264,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,McMaster University -CA-TPD,12264,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"McMaster University -School of Geography and Earth Sciences -1280 Main Steert West -Hamilton Ontario, Canada L8S4K1" -CA-TPD,81517,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Jason J. Brodeur -CA-TPD,81517,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,DataManager -CA-TPD,81517,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,brodeujj@mcmaster.ca -CA-TPD,81517,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,McMaster University -CA-TPD,81517,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"McMaster University, Mills Memorial Library, Rm 104/B -1280 Main Street West, Hamilton, ON L8S4L6" -CA-TPD,29865,GRP_TOWER_POWER,TOWER_POWER,Direct power -CA-TPD,12265,GRP_TOWER_TYPE,TOWER_TYPE,walk-up -CA-TPD,24000524,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/CA-TPD -CA-TPD,12266,GRP_UTC_OFFSET,UTC_OFFSET,-5 -CL-ACF,91978,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,Funding provided by the National Commission for Scientific and Technological Research (Chile) through grants FONDEQUIP EQM120039 and FONDECYT 1171496; the National Forestry Servce (CONAF) for the permission to work at the Alerce Costero National Park -CL-ACF,91964,GRP_CLIM_AVG,MAT,7.3 -CL-ACF,91964,GRP_CLIM_AVG,MAP,4500 -CL-ACF,91964,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Cfb -CL-ACF,27000858,GRP_COUNTRY,COUNTRY,Chile -CL-ACF,91968,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Fire -CL-ACF,91975,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -CL-ACF,91975,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -CL-ACF,91975,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20180130 -CL-ACF,91975,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -CL-ACF,91975,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,CPEC200 -CL-ACF,91984,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -CL-ACF,91984,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -CL-ACF,91984,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20180130 -CL-ACF,91984,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -CL-ACF,91984,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,CPEC200 -CL-ACF,91969,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Chambers -CL-ACF,91969,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -CL-ACF,91969,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20190719 -CL-ACF,91969,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -CL-ACF,91969,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,LiCOR -CL-ACF,23000858,GRP_HEADER,SITE_NAME,Alerce Costero Forest -CL-ACF,91967,GRP_IGBP,IGBP,ENF -CL-ACF,91967,GRP_IGBP,IGBP_COMMENT,Coniferous stand developed post-fire dominated by Fitzroya cupressoindes in a landscape of vegetation mosaics with broadleaved evergreen species -CL-ACF,91979,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -CL-ACF,91979,GRP_LAND_OWNERSHIP,LAND_OWNER,Corporación Nacional Forestal (CONAF) -CL-ACF,91983,GRP_LOCATION,LOCATION_LAT,-40.1726 -CL-ACF,91983,GRP_LOCATION,LOCATION_LONG,-73.4439 -CL-ACF,91983,GRP_LOCATION,LOCATION_ELEV,822 -CL-ACF,91983,GRP_LOCATION,LOCATION_DATE_START,20180130 -CL-ACF,91983,GRP_LOCATION,LOCATION_COMMENT,"The station is located in the Coastal Range 25 km west of La Unión, Los Lagos Region" -CL-ACF,91973,GRP_NETWORK,NETWORK,AmeriFlux -CL-ACF,1700008163,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Urrutia-Jalabert, R., Malhi, Y., Lara, A. (2015) The Oldest, Slowest Rainforests In The World? Massive Biomass And Slow Carbon Dynamics Of Fitzroya Cupressoides Temperate Forests In Southern Chile, Plos One, 10(9), e0137569" -CL-ACF,1700008163,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1371/JOURNAL.PONE.0137569 -CL-ACF,1700008163,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CL-ACF,1700001188,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Urrutia-Jalabert, R., Rossi, S., Deslauriers, A., Malhi, Y., Lara, A. (2015) Environmental Correlates Of Stem Radius Change In The Endangered Fitzroya Cupressoides Forests Of Southern Chile, Agricultural And Forest Meteorology, 200(9), 209-221" -CL-ACF,1700001188,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2014.10.001 -CL-ACF,1700001188,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CL-ACF,1700003045,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Urrutia‐Jalabert, R., Malhi, Y., Barichivich, J., Lara, A., Delgado‐Huertas, A., Rodríguez, C. G., Cuq, E. (2015) Increased Water Use Efficiency But Contrasting Tree Growth Patterns In Fitzroya Cupressoides Forests Of Southern Chile During Recent Decades, Journal Of Geophysical Research: Biogeosciences, 120(12), 2505-2524" -CL-ACF,1700003045,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/2015JG003098 -CL-ACF,1700003045,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CL-ACF,91977,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,Greenhouse gas balance and water cycle -CL-ACF,91976,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"Independencia 641, Valdivia, Chile" -CL-ACF,91982,GRP_SITE_CHAR,TERRAIN,"Significant Slope (>5%, <10%)" -CL-ACF,91982,GRP_SITE_CHAR,ASPECT,N -CL-ACF,91982,GRP_SITE_CHAR,WIND_DIRECTION,SW -CL-ACF,91982,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,80 -CL-ACF,91982,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,5 -CL-ACF,91980,GRP_SITE_DESC,SITE_DESC,Tower located in an old-growth coniferous rainforest (~300 years) at the Alerce Costero National Park. The forest is locally known as Alerce type. -CL-ACF,91965,GRP_SITE_FUNDING,SITE_FUNDING,National Commission for Scientific & Technological Research of Chile (grants FONDEQUIP EQM120039 and FONDECYT 1171496) -CL-ACF,91971,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Antonio Lara -CL-ACF,91971,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -CL-ACF,91971,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,antoniolaraaguilar@gmail.com -CL-ACF,91971,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Universidad Austral de Chile -CL-ACF,91971,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Independencia 641, Valdivia, Chile" -CL-ACF,91970,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Jonathan Barichivich -CL-ACF,91970,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,DataManager -CL-ACF,91970,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,campsidium@gmail.com -CL-ACF,91970,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"Universidad Austral de Chile and LSCE, Paris" -CL-ACF,91981,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Jorge Perez-Quezada -CL-ACF,91981,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Affiliate -CL-ACF,91981,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,jorgepq@uchile.cl -CL-ACF,91981,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Universidad de Chile -CL-ACF,91981,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Avenida Santa Rosa 11315, La Pintana, Santiago, Chile" -CL-ACF,91985,GRP_TOWER_POWER,TOWER_POWER,Solar + generator -CL-ACF,91966,GRP_TOWER_TYPE,TOWER_TYPE,triangle -CL-ACF,91972,GRP_URL,URL,https://www.dendrocronologia.cl/ -CL-ACF,24000858,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/CL-ACF -CL-ACF,91974,GRP_UTC_OFFSET,UTC_OFFSET,-4 -CL-SDF,30252,GRP_CLIM_AVG,MAT,10 -CL-SDF,30252,GRP_CLIM_AVG,MAP,2110 -CL-SDF,30252,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Cfb -CL-SDF,27000686,GRP_COUNTRY,COUNTRY,Chile -CL-SDF,30253,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Forestry -CL-SDF,100826,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -CL-SDF,100826,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -CL-SDF,100826,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20140101 -CL-SDF,100826,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -CL-SDF,100828,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -CL-SDF,100828,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -CL-SDF,100828,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20140101 -CL-SDF,100828,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -CL-SDF,23000686,GRP_HEADER,SITE_NAME,Senda Darwin Forest -CL-SDF,30319,GRP_IGBP,IGBP,EBF -CL-SDF,30319,GRP_IGBP,IGBP_COMMENT,Ours is a mixed forest but not in the sense of deciduous vs evergreen but in the sense of broadleaf vs conifer trees. They are all evergreen species. -CL-SDF,30260,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -CL-SDF,30260,GRP_LAND_OWNERSHIP,LAND_OWNER,Fundación Senda Darwin -CL-SDF,30261,GRP_LOCATION,LOCATION_LAT,-41.8830 -CL-SDF,30261,GRP_LOCATION,LOCATION_LONG,-73.6760 -CL-SDF,30261,GRP_LOCATION,LOCATION_ELEV,50 -CL-SDF,30262,GRP_NETWORK,NETWORK,AmeriFlux -CL-SDF,1700001983,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Perez-Quezada, J. F., Brito, C. E., Cabezas, J., Galleguillos, M., Fuentes, J. P., Bown, H. E., Franck, N. (2016) How Many Measurements Are Needed To Estimate Accurate Daily And Annual Soil Respiration Fluxes? Analysis Using Data From A Temperate Rainforest, Biogeosciences, 13(24), 6599-6609" -CL-SDF,1700001983,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.5194/BG-13-6599-2016 -CL-SDF,1700001983,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CL-SDF,1700006288,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Perez-Quezada, J. F., Celis-Diez, J. L., Brito, C. E., Gaxiola, A., Nuñez-Avila, M., Pugnaire, F. I., Armesto, J. J. (2018) Carbon Fluxes From A Temperate Rainforest Site In Southern South America Reveal A Very Sensitive Sink, Ecosphere, 9(4), e02193" -CL-SDF,1700006288,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/ECS2.2193 -CL-SDF,1700006288,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CL-SDF,1700004773,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Pérez-Quezada, J., Brito, C.E., Cabezas, J., Galleguillos, M., Fuentes, J.P., Bown, H., Franck, N. (2016) How many measurements are needed to estimate accurate daily and annual soil respiration fluxes? Analysis using data from a temperate rainforest, Biogeosciences, 13(), 6599-6609" -CL-SDF,1700004773,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.5194/BG-13-6599-2016 -CL-SDF,1700004773,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CL-SDF,1700006330,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Pérez-Quezada, J., Brito, C.E., Cabezas, J., Galleguillos, M., Fuentes, J.P., Bown, H., Franck, N. (2016) How many measurements are needed to estimate accurate daily and annual soil respiration fluxes? Analysis using data from a temperate rainforest, Biogeosciences, 13(24), 6599-6609" -CL-SDF,1700006330,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.5194/BG-13-6599-2016 -CL-SDF,1700006330,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CL-SDF,30265,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,Greenhouse gas balance -CL-SDF,30266,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"Avenida Santa Rosa 11315, La Pintana, Santiago, Chile" -CL-SDF,30267,GRP_SITE_CHAR,TERRAIN,Flat -CL-SDF,30267,GRP_SITE_CHAR,ASPECT,FLAT -CL-SDF,30267,GRP_SITE_CHAR,WIND_DIRECTION,NW -CL-SDF,30267,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,1000 -CL-SDF,30267,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,0 -CL-SDF,30268,GRP_SITE_DESC,SITE_DESC,"Located at the Senda Darwin Biological Station, in a old-growth rainforest. Locally named as Nordpatagonian type of forest. The station is 15 km east of Ancud, in the Chiloé Island, close to the Huicha river." -CL-SDF,100829,GRP_SITE_FUNDING,SITE_FUNDING,"National Commission for Scientific & Technological Research of Chile (grants FONDEQUIP AIC-37, FONDECYT 1130935, FONDECYT 1171239, FONDECYT 1211652)" -CL-SDF,30270,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Jorge Perez-Quezada -CL-SDF,30270,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -CL-SDF,30270,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,jorgepq@uchile.cl -CL-SDF,30270,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Chile -CL-SDF,30270,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Avenida Santa Rosa 11315, La Pintana, Santiago, Chile" -CL-SDF,30271,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Juan J. Armesto -CL-SDF,30271,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -CL-SDF,30271,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,jarmesto@bio.puc.cl -CL-SDF,30271,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Pontifical Catholic University of Chile -CL-SDF,100823,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,David Trejo -CL-SDF,100823,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,DataManager -CL-SDF,100823,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,david.trejo@uchile.cl -CL-SDF,100823,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Chile -CL-SDF,100823,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Judea 1593, Maipú, Santiago" -CL-SDF,30274,GRP_TOWER_POWER,TOWER_POWER,Direct power -CL-SDF,30272,GRP_TOWER_TYPE,TOWER_TYPE,triangle -CL-SDF,24000686,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/CL-SDF -CL-SDF,30273,GRP_UTC_OFFSET,UTC_OFFSET,-4 -CL-SDP,30229,GRP_CLIM_AVG,MAT,10 -CL-SDP,30229,GRP_CLIM_AVG,MAP,2110 -CL-SDP,30229,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Cfb -CL-SDP,27000687,GRP_COUNTRY,COUNTRY,Chile -CL-SDP,30231,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Agriculture -CL-SDP,30230,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Grazing -CL-SDP,88076,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -CL-SDP,88076,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -CL-SDP,88076,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20130801 -CL-SDP,88076,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -CL-SDP,88086,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -CL-SDP,88086,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -CL-SDP,88086,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20130801 -CL-SDP,88086,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -CL-SDP,30236,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Chambers -CL-SDP,30236,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -CL-SDP,30236,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20140426 -CL-SDP,30236,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Periodic operation -CL-SDP,30234,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Chambers -CL-SDP,30234,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CH4 -CL-SDP,30234,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20140915 -CL-SDP,30234,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Periodic operation -CL-SDP,30235,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Chambers -CL-SDP,30235,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,N2O -CL-SDP,30235,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20140915 -CL-SDP,30235,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Periodic operation -CL-SDP,23000687,GRP_HEADER,SITE_NAME,Senda Darwin Peatland -CL-SDP,30237,GRP_IGBP,IGBP,WET -CL-SDP,30238,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -CL-SDP,30238,GRP_LAND_OWNERSHIP,LAND_OWNER,Fundación Senda Darwin -CL-SDP,30239,GRP_LOCATION,LOCATION_LAT,-41.8790 -CL-SDP,30239,GRP_LOCATION,LOCATION_LONG,-73.6660 -CL-SDP,30239,GRP_LOCATION,LOCATION_ELEV,50 -CL-SDP,30240,GRP_NETWORK,NETWORK,AmeriFlux -CL-SDP,1700000027,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Cabezas, J., Galleguillos, M., Valdés, A., Fuentes, J. P., Pérez, C., Perez-Quezada, J. F. (2015) Evaluation Of Impacts Of Management In An Anthropogenic Peatland Using Field And Remote Sensing Data, Ecosphere, 6(12), art282" -CL-SDP,1700000027,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1890/ES15-00232.1 -CL-SDP,1700000027,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CL-SDP,1700002172,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Cabezas, J., Galleguillos, M., Valdés, A., Fuentes, J.P., Pérez, C., Pérez-Quezada, J. (2015) Evaluation of impacts of management in an anthropogenic peatland using field and remote sensing data, Ecosphere, 6(12), 1-24" -CL-SDP,1700002172,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1890/ES15-00232.1 -CL-SDP,1700002172,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CL-SDP,30242,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,Greenhouse gas balance -CL-SDP,30243,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"Avenida Santa Rosa 11315, La Pintana, Santiago, Chile" -CL-SDP,30244,GRP_SITE_CHAR,TERRAIN,Flat -CL-SDP,30244,GRP_SITE_CHAR,ASPECT,FLAT -CL-SDP,30244,GRP_SITE_CHAR,WIND_DIRECTION,NW -CL-SDP,30244,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,1000 -CL-SDP,30244,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,0 -CL-SDP,30245,GRP_SITE_DESC,SITE_DESC,"Located at the Senda Darwin Biological Station, in a old-growth rainforest. Locally named ""pomponal"" from the common name of Sphagnum, is an anthropogenic peatland, formed after the forest is cut or a forest fire. The station is 15 km east of Ancud, in the Chiloé Island, close to the Huicha river." -CL-SDP,88083,GRP_SITE_FUNDING,SITE_FUNDING,"National Commission for Scientific & Technological Research of Chile (grants FONDEQUIP AIC-37, FONDECYT 1130935, FONDECYT 1171239)" -CL-SDP,30248,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Jorge Perez-Quezada -CL-SDP,30248,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -CL-SDP,30248,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,jorgepq@uchile.cl -CL-SDP,30248,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Chile -CL-SDP,30248,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Avenida Santa Rosa 11315, La Pintana, Santiago, Chile" -CL-SDP,30247,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Juan J. Armesto -CL-SDP,30247,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -CL-SDP,30247,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,jarmesto@bio.puc.cl -CL-SDP,30247,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Pontifical Catholic University of Chile -CL-SDP,99170,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,David Trejo -CL-SDP,99170,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,DataManager -CL-SDP,99170,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,david.trejo@uchile.cl -CL-SDP,99170,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Universidad de Chile -CL-SDP,99170,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Judea 1593, Maipú, Santiago, Chile" -CL-SDP,30251,GRP_TOWER_POWER,TOWER_POWER,Direct power -CL-SDP,30249,GRP_TOWER_TYPE,TOWER_TYPE,tripod -CL-SDP,24000687,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/CL-SDP -CL-SDP,30250,GRP_UTC_OFFSET,UTC_OFFSET,-4 -CR-SoC,12526,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,"This research was supported by the Office of Science (BER), U.S. Department of Energy." -CR-SoC,86939,GRP_CLIM_AVG,MAT,23.1 -CR-SoC,86939,GRP_CLIM_AVG,MAP,4200 -CR-SoC,86939,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Af -CR-SoC,27000530,GRP_COUNTRY,COUNTRY,Costa Rica -CR-SoC,98434,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -CR-SoC,98434,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Anthony T. Cahill -CR-SoC,98434,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -CR-SoC,98434,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Texas A&M University -CR-SoC,98451,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -CR-SoC,98451,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Georgianne W. Moore -CR-SoC,98451,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -CR-SoC,98451,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0001-5190-5983 -CR-SoC,98451,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Texas A&M University -CR-SoC,98448,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -CR-SoC,98448,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Gretchen R. Miller -CR-SoC,98448,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -CR-SoC,98448,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0002-1108-0654 -CR-SoC,98448,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,gmiller@tamu.edu -CR-SoC,98448,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Texas A&M University -CR-SoC,98435,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -CR-SoC,98435,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Jaeyoung Song -CR-SoC,98435,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -CR-SoC,98435,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0002-9554-9252 -CR-SoC,98435,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Texas A&M University -CR-SoC,98435,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,2014 -CR-SoC,98435,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_END,2020 -CR-SoC,98433,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,DOE BER -CR-SoC,98433,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -CR-SoC,12528,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Forestry -CR-SoC,98429,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -CR-SoC,98429,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -CR-SoC,98429,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20140627 -CR-SoC,98429,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,2019 -CR-SoC,98429,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Intermittent -CR-SoC,98429,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,Data quality issues present due to hillslope -CR-SoC,98438,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -CR-SoC,98438,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -CR-SoC,98438,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20140627 -CR-SoC,98438,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,2019 -CR-SoC,98438,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Intermittent -CR-SoC,98438,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,Data quality issues present due to hillslope -CR-SoC,23000530,GRP_HEADER,SITE_NAME,Soltis Center -CR-SoC,12530,GRP_IGBP,IGBP,EBF -CR-SoC,12530,GRP_IGBP,IGBP_DATE_START,20140627 -CR-SoC,12531,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -CR-SoC,12532,GRP_LOCATION,LOCATION_LAT,10.3827 -CR-SoC,12532,GRP_LOCATION,LOCATION_LONG,-84.6210 -CR-SoC,12532,GRP_LOCATION,LOCATION_ELEV,538 -CR-SoC,12532,GRP_LOCATION,LOCATION_DATE_START,20140627 -CR-SoC,12533,GRP_NETWORK,NETWORK,AmeriFlux -CR-SoC,86937,GRP_NETWORK,NETWORK,Phenocam -CR-SoC,1700004026,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Aparecido, L. M., Miller, G. R., Cahill, A. T., Moore, G. W. (2016) Comparison Of Tree Transpiration Under Wet And Dry Canopy Conditions In A Costa Rican Premontane Tropical Forest, Hydrological Processes, 30(26), 5000-5011" -CR-SoC,1700004026,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/HYP.10960 -CR-SoC,1700004026,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CR-SoC,1700003654,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Aparecido, L. M., Miller, G. R., Cahill, A. T., Moore, G. W. (2017) Leaf Surface Traits And Water Storage Retention Affect Photosynthetic Responses To Leaf Surface Wetness Among Wet Tropical Forest And Semiarid Savanna Plants, Tree Physiology, 37(10), 1285-1300" -CR-SoC,1700003654,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1093/TREEPHYS/TPX092 -CR-SoC,1700003654,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Primary_Citation -CR-SoC,1700001758,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Flores III, M. R., Aparecido, L. M., Miller, G. R., Moore, G. W. (2021) Assessing Forest Level Response To The Death Of A Dominant Tree Within A Premontane Tropical Rainforest, Forests, 12(8), 1041" -CR-SoC,1700001758,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.3390/F12081041 -CR-SoC,1700001758,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CR-SoC,1700001491,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Grossiord, C., Christoffersen, B., Alonso-Rodríguez, A. M., Anderson-Teixeira, K., Asbjornsen, H., Aparecido, L. M., Carter Berry, Z., Baraloto, C., Bonal, D., Borrego, I., Burban, B., Chambers, J. Q., Christianson, D. S., Detto, M., Faybishenko, B., Fontes, C. G., Fortunel, C., Gimenez, B. O., Jardine, K. J., Kueppers, L., Miller, G. R., Moore, G. W., Negron-Juarez, R., Stahl, C., Swenson, N. G., Trotsiuk, V., Varadharajan, C., Warren, J. M., Wolfe, B. T., Wei, L., Wood, T. E., Xu, C., McDowell, N. G. (2019) Precipitation Mediates Sap Flux Sensitivity To Evaporative Demand In The Neotropics, Oecologia, 191(3), 519-530" -CR-SoC,1700001491,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1007/S00442-019-04513-X -CR-SoC,1700001491,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CR-SoC,1700005871,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Moore, G. W., Orozco, G., Aparecido, L. M., Miller, G. R. (2018) Upscaling Transpiration In Diverse Forests: Insights From A Tropical Premontane Site, Ecohydrology, 11(3), e1920" -CR-SoC,1700005871,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/ECO.1920 -CR-SoC,1700005871,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Primary_Citation -CR-SoC,1700008580,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Song, J., Miller, G. R., Cahill, A. T., Aparecido, L. M., Moore, G. W. (2021) Modeling Profiles Of Micrometeorological Variables In A Tropical Premontane Rainforest Using Multi‐Layered Clm (Clm‐Ml), Journal Of Advances In Modeling Earth Systems, 13(5), 1285-1300" -CR-SoC,1700008580,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2020MS002259 -CR-SoC,1700008580,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CR-SoC,1700003858,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Song, J., Miller, G. R., Cahill, A. T., Aparecido, L. M., Moore, G. W. (2021) Modeling Profiles Of Micrometeorological Variables In A Tropical Premontane Rainforest Using Multi‐Layered Clm (Clm‐Ml), Journal Of Advances In Modeling Earth Systems, 13(5), 519-530" -CR-SoC,1700003858,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2020MS002259 -CR-SoC,1700003858,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -CR-SoC,98452,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"Transpiration, MoDex approach, UAS for micrometeorology" -CR-SoC,12534,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"The Soltis Center for Research and Education in Costa Rica -Texas A&M University -San Isidro de Peñas Blancas -Apdo 80-4417 Fortuna -San Carlos, Costa Rica" -CR-SoC,12535,GRP_SITE_CHAR,TERRAIN,Strong Slope (>10%) -CR-SoC,12535,GRP_SITE_CHAR,ASPECT,ESE -CR-SoC,12535,GRP_SITE_CHAR,WIND_DIRECTION,N -CR-SoC,12535,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,2000 -CR-SoC,12535,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,0 -CR-SoC,12536,GRP_SITE_DESC,SITE_DESC,"The Texas A&M Soltis Center for Research and Education is located in San Juan de Peñas Blancas, San Ramón, Costa Rica. In 2009, Charles W. ""Bill"" and Wanda Soltis donated a new facility to the university and granted it a long-term lease on the adjacent 250 acres of land. The site hosts both primary and secondary growth rainforest, the later of which was selectively logged between the 1950's and the 1990's. It is best classified as a lower montane forest, located in the transitional area between the upper and lower montane cloud forests and the lowland rainforests. Temperatures average 23°C with 4200 mm/yr of rainfall; a short drier period typically occurs between January and April. Estimates suggest that the site hosts more than 2000 species of vascular plants, with dominant vegetation types including plants in the Sapotaceae, Moracea, and Malvaceae families." -CR-SoC,12537,GRP_SITE_FUNDING,SITE_FUNDING,"Department of Energy, Earth Systems Modeling Program; National Science Foundation, Research Experience for Undergraduates" -CR-SoC,12538,GRP_STATE,STATE,Alajuela -CR-SoC,12539,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Gretchen Miller -CR-SoC,12539,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -CR-SoC,12539,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,gmiller@civil.tamu.edu -CR-SoC,12539,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Texas A&M University -CR-SoC,12539,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"3136 TAMU, College Station, TX 77843-3136" -CR-SoC,12545,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Georgianne Moore -CR-SoC,12545,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,AncContact -CR-SoC,12545,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,gwmoore@tamu.edu -CR-SoC,12545,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Texas A&M University -CR-SoC,12544,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Tony Cahill -CR-SoC,12544,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,AncContact -CR-SoC,12544,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,tcahill@civil.tamu.edu -CR-SoC,12544,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Texas A&M University -CR-SoC,29867,GRP_TOWER_POWER,TOWER_POWER,Direct power -CR-SoC,12540,GRP_TOWER_TYPE,TOWER_TYPE,walk-up -CR-SoC,86938,GRP_URL,URL,http://soltiscentercostarica.tamu.edu/ -CR-SoC,24000530,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/CR-SoC -CR-SoC,12542,GRP_UTC_OFFSET,UTC_OFFSET,-6 -CR-SoC,12542,GRP_UTC_OFFSET,UTC_OFFSET_DATE_START,20140627 -MX-Aog,93633,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,We thank CONACyT México project CB-2013-01:221014 for orginal funding for tower installation and the program PROFAPI-ITSON for additional funding for site maintainance -MX-Aog,93638,GRP_CLIM_AVG,MAT,24.2 -MX-Aog,93638,GRP_CLIM_AVG,MAP,732 -MX-Aog,93638,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Bsh -MX-Aog,27001165,GRP_COUNTRY,COUNTRY,Mexico -MX-Aog,95034,GRP_DOI,DOI,10.17190/AMF/1756414 -MX-Aog,95034,GRP_DOI,DOI_CITATION,"Enrico A. Yepez (2020), AmeriFlux BASE MX-Aog Alamos Old-Growth tropical dry forest, Ver. 1-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1756414" -MX-Aog,95034,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -MX-Aog,94940,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -MX-Aog,94940,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Enrico A. Yepez -MX-Aog,94940,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -MX-Aog,94940,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,enrico.yepez@itson.edu.mx -MX-Aog,94940,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Instituto Tecnologico de Sonora -MX-Aog,94946,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Instituto Tecnologico de Sonora -MX-Aog,94946,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -MX-Aog,94942,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,CONACyT -MX-Aog,94942,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -MX-Aog,93639,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Grazing -MX-Aog,93641,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -MX-Aog,93641,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -MX-Aog,93641,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20160318 -MX-Aog,93641,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20181231 -MX-Aog,93641,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -MX-Aog,93653,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -MX-Aog,93653,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -MX-Aog,93653,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20160318 -MX-Aog,93653,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20181231 -MX-Aog,93653,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -MX-Aog,93650,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -MX-Aog,93650,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -MX-Aog,93650,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20160318 -MX-Aog,93650,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20181231 -MX-Aog,93650,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -MX-Aog,23001165,GRP_HEADER,SITE_NAME,Alamos Old-Growth tropical dry forest -MX-Aog,93637,GRP_IGBP,IGBP,DBF -MX-Aog,93637,GRP_IGBP,IGBP_COMMENT,"This forest is dominated by leguminous trees and very litte boradleaf are actually species are present, tree cover is higher than woody savannas" -MX-Aog,93643,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -MX-Aog,93643,GRP_LAND_OWNERSHIP,LAND_OWNER,Nature and Culture International -MX-Aog,93634,GRP_LOCATION,LOCATION_LAT,26.9968 -MX-Aog,93634,GRP_LOCATION,LOCATION_LONG,-108.7892 -MX-Aog,93634,GRP_LOCATION,LOCATION_ELEV,367.284 -MX-Aog,93634,GRP_LOCATION,LOCATION_COMMENT,"Within the national protected area: ""Sierra de Alamos-Rio Cuchujaqui""" -MX-Aog,93640,GRP_NETWORK,NETWORK,AmeriFlux -MX-Aog,93642,GRP_NETWORK,NETWORK,MexFlux -MX-Aog,1700002880,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Rojas‐Robles, N. E., Garatuza‐Payán, J., Álvarez‐Yépiz, J. C., Sánchez‐Mejía, Z. M., Vargas, R., Yépez, E. A. (2020) Environmental Controls On Carbon And Water Fluxes In An Old‐Growth Tropical Dry Forest, Journal Of Geophysical Research: Biogeosciences, 125(8), " -MX-Aog,1700002880,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2020JG005666 -MX-Aog,1700002880,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -MX-Aog,93645,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"Biogeosciences, ecohydrology, functional plant ecology" -MX-Aog,93649,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"5 de Febrero 818 SUR, Ciudad Obregon, Sonora, Mexico. C.P. 85000" -MX-Aog,93644,GRP_SITE_CHAR,TERRAIN,"Medium Slope (>2 %, <5%)" -MX-Aog,93644,GRP_SITE_CHAR,ASPECT,SSW -MX-Aog,93644,GRP_SITE_CHAR,WIND_DIRECTION,WSW -MX-Aog,93644,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,300 -MX-Aog,93644,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,0 -MX-Aog,93646,GRP_SITE_DESC,SITE_DESC,"This tower is located at a patch of remnant old growth tropical dry forest where the dominant vegetation are leguminous trees and a notorious presence of the genus Brusera. The site is at about 18 km from the municipality of Alamos Sonora Mexico within a private ranch managed by the NGO Nature Culture International. The area is also within a federally protected land named “Area de Proteccion de Flora y Fauna Sierra de Alamos Rio-Cuchijaqui"" in the catalog of the “Comision Nacional de Areas Naturales Protegidas (CONANP-Mexico)”. The preserved ranch is surrounded by a mosaic of forest patches with different successional stages of tropical dry forest, and some places that are used for local agriculture and livestock. This ecosystem lies in a highly seasonal region under the influence of the North American Monsoon that brings about 70% of the rains from July to September." -MX-Aog,93654,GRP_SITE_FUNDING,SITE_FUNDING,CONACyT -MX-Aog,93651,GRP_STATE,STATE,Sonora -MX-Aog,93647,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Enrico A. Yepez -MX-Aog,93647,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -MX-Aog,93647,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,enrico.yepez@itson.edu.mx -MX-Aog,93647,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Instituto Tecnologico de Sonora -MX-Aog,93647,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"5 de Febrero 818 SUR, Ciudad Obregon, Sonora, Mexico. C.P. 85000" -MX-Aog,93635,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Nidia E. Rojas Robles -MX-Aog,93635,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -MX-Aog,93635,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,nerojasrobles@gmail.com -MX-Aog,93635,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Instituto Tecnologico de Sonora -MX-Aog,93635,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"5 de Febrero 818 SUR, Ciudad Obregon, Sonora, Mexico. C.P. 85000" -MX-Aog,93648,GRP_TOWER_POWER,TOWER_POWER,Solar panels -MX-Aog,93652,GRP_TOWER_TYPE,TOWER_TYPE,triangle -MX-Aog,24001165,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/MX-Aog -MX-Aog,93636,GRP_UTC_OFFSET,UTC_OFFSET,-6 -MX-Aog,93636,GRP_UTC_OFFSET,UTC_OFFSET_COMMENT,The state of Sonora Mexico does not observe summer day-light saving -MX-PMm,83436,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,CONACyT is acknowledged for providing all funds (INFR-2016-01 N° 269269 to SAB) for the infrastructure related to flux measurements. El Colegio de la Frontera Sur is acknowledged for providing funds for site operation and maintenance. -MX-PMm,83418,GRP_CLIM_AVG,MAT,26.2 -MX-PMm,83418,GRP_CLIM_AVG,MAP,1222 -MX-PMm,83418,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Aw -MX-PMm,27000980,GRP_COUNTRY,COUNTRY,Mexico -MX-PMm,95061,GRP_DOI,DOI,10.17190/AMF/1756415 -MX-PMm,95061,GRP_DOI,DOI_CITATION,"Ma. Susana Alvarado-Barrientos (2021), AmeriFlux BASE MX-PMm Puerto Morelos mangrove, Ver. 2-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1756415" -MX-PMm,95061,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -MX-PMm,91840,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -MX-PMm,91840,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Ma. Susana Alvarado-Barrientos -MX-PMm,91840,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -MX-PMm,91840,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,1 -MX-PMm,91840,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0003-0098-0806 -MX-PMm,91840,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,susana.alvarado@gmail.com -MX-PMm,91840,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Instituto de Ecología A.C. -MX-PMm,91840,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,20170613 -MX-PMm,91840,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_END,20191130 -MX-PMm,91851,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,CONACYT -MX-PMm,91851,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -MX-PMm,98523,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -MX-PMm,98523,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -MX-PMm,98523,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20170613 -MX-PMm,98523,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20181130 -MX-PMm,98523,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Periodic operation -MX-PMm,98521,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -MX-PMm,98521,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -MX-PMm,98521,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20170613 -MX-PMm,98521,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20181130 -MX-PMm,98521,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Periodic operation -MX-PMm,98526,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -MX-PMm,98526,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -MX-PMm,98526,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20170613 -MX-PMm,98526,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20181130 -MX-PMm,98526,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Periodic operation -MX-PMm,23000980,GRP_HEADER,SITE_NAME,Puerto Morelos mangrove -MX-PMm,96699,GRP_IGBP,IGBP,WET -MX-PMm,96699,GRP_IGBP,IGBP_COMMENT,The surface within the flux tower footprint corresponds to a basin mangrove sporadially flooded. Beyond the footprint (upwind) is a large complex of coastal wetlands with patches that are permanently flooded. The vegetation type is endangared by coastal squeeze due to extensive urban development fueled by the tourism industry in the area (Mayan Riviera). -MX-PMm,83415,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -MX-PMm,83415,GRP_LAND_OWNERSHIP,LAND_OWNER,El Colegio de la Frontera Sur is a public research institute that holds a commodatum agreement with the local state government for the management of the property as a botanical garden and protected area. -MX-PMm,83427,GRP_LOCATION,LOCATION_LAT,20.8462 -MX-PMm,83427,GRP_LOCATION,LOCATION_LONG,-86.8992 -MX-PMm,83427,GRP_LOCATION,LOCATION_ELEV,10 -MX-PMm,83427,GRP_LOCATION,LOCATION_DATE_START,201706131400 -MX-PMm,83427,GRP_LOCATION,LOCATION_COMMENT,"Due to local environmental regulations that limit construction within a protected mangrove area, the tower is 20 m away from the adjacent tropical forest. Thus, data at times when wind direction comes from the area covered with forest (taller vegetation than the mangrove), is filtered out." -MX-PMm,83431,GRP_NETWORK,NETWORK,AmeriFlux -MX-PMm,83416,GRP_NETWORK,NETWORK,MexFlux -MX-PMm,1700007575,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Alvarado‐Barrientos, M. S., López‐Adame, H., Lazcano‐Hernández, H. E., Arellano‐Verdejo, J., Hernández‐Arana, H. A. (2020) Ecosystem‐Atmosphere Exchange Of CO2, Water And Energy In A Basin Mangrove Of The Northeastern Coast Of The Yucatan Peninsula, Journal Of Geophysical Research: Biogeosciences, 125(), " -MX-PMm,1700007575,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2020JG005811 -MX-PMm,1700007575,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -MX-PMm,1700008013,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Alvarado‐Barrientos, M. S., López‐Adame, H., Lazcano‐Hernández, H. E., Arellano‐Verdejo, J., Hernández‐Arana, H. A. (2020) Ecosystem‐Atmosphere Exchange Of CO2, Water And Energy In A Basin Mangrove Of The Northeastern Coast Of The Yucatan Peninsula, Journal Of Geophysical Research: Biogeosciences, 125(2), e2020JG005811" -MX-PMm,1700008013,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2020JG005811 -MX-PMm,1700008013,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -MX-PMm,1700008805,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Alvarado‐Barrientos, M. S., López‐Adame, H., Lazcano‐Hernández, H. E., Arellano‐Verdejo, J., Hernández‐Arana, H. A. (2021) Ecosystem‐Atmosphere Exchange Of CO2, Water, And Energy In A Basin Mangrove Of The Northeastern Coast Of The Yucatan Peninsula, Journal Of Geophysical Research: Biogeosciences, 126(2), e2020JG005811" -MX-PMm,1700008805,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2020JG005811 -MX-PMm,1700008805,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Primary_Citation -MX-PMm,83435,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"Mangrove energy, water and carbon fluxes, environmental controls on fluxes, seasonality of fluxes as related to seasonal flooding, regeneration of mangrove after hurricane and effects on fluxes, scaling measured fluxes to cover larger spatial area, modeling of effects of land use change (coastal development and hydrological disruptions) on fluxes" -MX-PMm,83432,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"Carretera Federal Chetumal-Cancún km 320, Pescadores, Puerto Morelos, CP 77580, Quintana Roo, Mexico" -MX-PMm,83434,GRP_SITE_CHAR,TERRAIN,Flat -MX-PMm,83434,GRP_SITE_CHAR,ASPECT,FLAT -MX-PMm,83434,GRP_SITE_CHAR,WIND_DIRECTION,E -MX-PMm,83434,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,200 -MX-PMm,83434,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,0 -MX-PMm,98931,GRP_SITE_DESC,SITE_DESC,"The tower was located at the “Dr. Alfredo Barrera Marín” Botanical Garden. The surface monitored is covered with basin mangrove (sporadically flooded wetland) that grows in a fringe parallel to the northeastern coast (ca. 1 km) of the Yucatan Peninsula. The dominant species are Rhizophora mangle and Conocarpus erectus, which grow intertwined and relatively stunted (max tree height is 5m). Under the influence of trade winds and frequent stroms. The vegetation is regenerating after complete defoliation due to hurricane Wilma (cat. 4) passing in October 2005. The site is sporadically flooded by rainfall soil saturation excess; there are no marine surface water inputs but ground water level fluctuations show tidal signals. The terrain of the monitored surface is flat, while the area downwind of the tower presents a slope which corresponds to an ancient coast line. There is extensive urban development in the coastal dune along the coast mainly for tourism use (Mayan Riviera)." -MX-PMm,83422,GRP_SITE_FUNDING,SITE_FUNDING,"CONACyT, El Colegio de la Frontera Sur" -MX-PMm,83429,GRP_STATE,STATE,Quintana Roo -MX-PMm,91828,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Susana Alvarado-Barrientos -MX-PMm,91828,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -MX-PMm,91828,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,susana.alvarado@gmail.com -MX-PMm,91828,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Instituto de Ecología A.C. -MX-PMm,91828,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Carretera ant. a Coatepec 351, El Haya, Xalapa CP91073, Veracruz, Mexico" -MX-PMm,83437,GRP_TOWER_POWER,TOWER_POWER,Solar panels -MX-PMm,83430,GRP_TOWER_TYPE,TOWER_TYPE,triangle -MX-PMm,24000980,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/MX-PMm -MX-PMm,83426,GRP_UTC_OFFSET,UTC_OFFSET,-5 -MX-PMm,83426,GRP_UTC_OFFSET,UTC_OFFSET_COMMENT,Daylight saving time is not observed in Quintana Roo since 2014 -MX-Tes,93783,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,We thanks the Consejo Nacional de Ciencia y Tecnología (CONACYT) in Mexico and PROFAPI-ITSON -MX-Tes,93766,GRP_CLIM_AVG,MAT,24.3 -MX-Tes,93766,GRP_CLIM_AVG,MAP,647 -MX-Tes,93766,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Bsh -MX-Tes,27000921,GRP_COUNTRY,COUNTRY,Mexico -MX-Tes,95209,GRP_DOI,DOI,10.17190/AMF/1767832 -MX-Tes,95209,GRP_DOI,DOI_CITATION,"Enrico A. Yepez, Jaime Garatuza (2021), AmeriFlux BASE MX-Tes Tesopaco, secondary tropical dry forest, Ver. 2-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1767832" -MX-Tes,95209,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -MX-Tes,95189,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -MX-Tes,95189,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Enrico A. Yepez -MX-Tes,95189,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -MX-Tes,95189,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,enrico.yepez@itson.edu.mx -MX-Tes,95189,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Instituto Tecnologico de Sonora -MX-Tes,95160,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -MX-Tes,95160,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Jaime Garatuza -MX-Tes,95160,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -MX-Tes,95160,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,garatuza@itson.edu.mx -MX-Tes,95160,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Instituto Tecnologico de Sonora -MX-Tes,95181,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Instituto Tecnologico de Sonora -MX-Tes,95181,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -MX-Tes,95192,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,CONACYT-Mexico -MX-Tes,95192,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -MX-Tes,93764,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Grazing -MX-Tes,93773,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -MX-Tes,93773,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -MX-Tes,93773,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20040709 -MX-Tes,93773,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20081231 -MX-Tes,93773,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -MX-Tes,93771,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -MX-Tes,93771,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -MX-Tes,93771,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20040709 -MX-Tes,93771,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20081231 -MX-Tes,93771,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -MX-Tes,93769,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -MX-Tes,93769,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -MX-Tes,93769,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20040709 -MX-Tes,93769,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20081231 -MX-Tes,93769,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -MX-Tes,23000921,GRP_HEADER,SITE_NAME,"Tesopaco, secondary tropical dry forest" -MX-Tes,93763,GRP_IGBP,IGBP,DBF -MX-Tes,93763,GRP_IGBP,IGBP_COMMENT,The site is dominated by mycrophyllous leguminous trees species -MX-Tes,93768,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -MX-Tes,31713,GRP_LOCATION,LOCATION_LAT,27.8400 -MX-Tes,31713,GRP_LOCATION,LOCATION_LONG,-109.3000 -MX-Tes,93761,GRP_LOCATION,LOCATION_LAT,27.8446 -MX-Tes,93761,GRP_LOCATION,LOCATION_LONG,-109.2977 -MX-Tes,93761,GRP_LOCATION,LOCATION_ELEV,460 -MX-Tes,93761,GRP_LOCATION,LOCATION_DATE_START,20040709 -MX-Tes,93776,GRP_NETWORK,NETWORK,AmeriFlux -MX-Tes,93778,GRP_NETWORK,NETWORK,MexFlux -MX-Tes,1700001551,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Perez-Ruiz, E. R., Garatuza-Payan, J., Watts, C. J., Rodriguez, J. C., Yepez, E. A., Scott, R. L. (2010) Carbon Dioxide And Water Vapour Exchange In A Tropical Dry Forest As Influenced By The North American Monsoon System (Nams), Journal Of Arid Environments, 74(5), 556-563" -MX-Tes,1700001551,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.JARIDENV.2009.09.029 -MX-Tes,1700001551,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -MX-Tes,1700006522,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Verduzco, V. S., Garatuza-Payán, J., Yépez, E. A., Watts, C. J., Rodríguez, J. C., Robles-Morua, A., Vivoni, E. R. (2015) Variations Of Net Ecosystem Production Due To Seasonal Precipitation Differences In A Tropical Dry Forest Of Northwest Mexico, Journal Of Geophysical Research: Biogeosciences, 120(10), 2081-2094" -MX-Tes,1700006522,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/2015JG003119 -MX-Tes,1700006522,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -MX-Tes,93780,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"Biogeosciences, ecohydrology, functional plant ecology" -MX-Tes,93779,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"5 de Febrero 818 Sur, Col. Centro, Ciudad Obregon, Sonora, Mexico 85000" -MX-Tes,93772,GRP_SITE_CHAR,TERRAIN,Flat -MX-Tes,93772,GRP_SITE_CHAR,ASPECT,NW -MX-Tes,93772,GRP_SITE_CHAR,WIND_DIRECTION,SSW -MX-Tes,93772,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,1400 -MX-Tes,93772,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,0 -MX-Tes,93767,GRP_SITE_DESC,SITE_DESC,"This tower was located in the ""Ejido la Estrella"" where the eddy covariance tower is located 7.5 km east of the town Rosario de Tesopaco, in southeastern Sonora, Mexico. The tower was positioned in the center of a homogeneous flat terrain at the foothills of the Madre Occidental. This ecosystem lies in a highly seasonal region under the influence of the North American Monsoon that brings about 70% of the rains from July to September. The site is dominated by leguminous trees. Some of the dominant species are Lysiloma divaricatum, Ipomoea arborescens, Acacia cochliacantha, Haematoxylum brasiletto, and Celtis reticulata. The mean basal area at the study site is 14.83 ± 3.3m2 ha-1, and the aboveground biomass is estimated to be 43.20±9.5Mgha-1. These values and the high counts of Acacia cochliacantha indicate that the area is a secondary forest with significant management activities in the past." -MX-Tes,93777,GRP_SITE_FUNDING,SITE_FUNDING,CONACYT-Mexico -MX-Tes,93762,GRP_STATE,STATE,Sonora -MX-Tes,93774,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Enrico A. Yepez -MX-Tes,93774,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -MX-Tes,93774,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,enrico.yepez@itson.edu.mx -MX-Tes,93774,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Instituto Tecnologico de Sonora -MX-Tes,93781,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Jaime Garatuza -MX-Tes,93781,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -MX-Tes,93781,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,garatuza@itson.edu.mx -MX-Tes,93781,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Instituto Tecnologico de Sonora -MX-Tes,93781,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"5 de Febrero 818 Sur, Col. Centro, Ciudad Obregon, Sonora, Mexico" -MX-Tes,93770,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Miguel Agustin Rivera -MX-Tes,93770,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Technician -MX-Tes,93770,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,migel.rivera@itson.edu.mx -MX-Tes,93770,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Instituto Tecnologico de Sonora -MX-Tes,93782,GRP_TOWER_POWER,TOWER_POWER,Solar panels -MX-Tes,93775,GRP_TOWER_TYPE,TOWER_TYPE,walk-up -MX-Tes,24000921,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/MX-Tes -MX-Tes,93765,GRP_UTC_OFFSET,UTC_OFFSET,-6 -MX-Tes,93765,GRP_UTC_OFFSET,UTC_OFFSET_COMMENT,The state of Sonora Mexico does not observe summer day-light saving -PE-QFR,86032,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Af -PE-QFR,27001043,GRP_COUNTRY,COUNTRY,Peru -PE-QFR,94285,GRP_DOI,DOI,10.17190/AMF/1671889 -PE-QFR,94285,GRP_DOI,DOI_CITATION,"Tyler Roman, Timothy Griffis, Randy Kolka, Craig Wayson, Erik Lilleskov, Dennis del Castillo Torres, Lizardo Fachin Malaverri, Jhon Ever Rengifo Marin (2021), AmeriFlux BASE PE-QFR Quistococha Forest Reserve, Ver. 2-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1671889" -PE-QFR,94285,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -PE-QFR,98672,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -PE-QFR,98672,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Tyler Roman -PE-QFR,98672,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -PE-QFR,98672,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,1 -PE-QFR,98672,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0002-1670-7348 -PE-QFR,98672,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,troman.usfs@gmail.com -PE-QFR,98672,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,USDA-Forest Service-International Programs -PE-QFR,98680,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -PE-QFR,98680,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Timothy Griffis -PE-QFR,98680,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -PE-QFR,98680,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,2 -PE-QFR,98680,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0002-2111-5144 -PE-QFR,98680,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,tgriffis@umn.edu -PE-QFR,98680,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of Minnesota -PE-QFR,98682,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -PE-QFR,98682,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Randy Kolka -PE-QFR,98682,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -PE-QFR,98682,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,3 -PE-QFR,98682,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0002-6419-8218 -PE-QFR,98682,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,USDA-Forest Service-Northern Research Station -PE-QFR,98676,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -PE-QFR,98676,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Craig Wayson -PE-QFR,98676,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -PE-QFR,98676,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,4 -PE-QFR,98676,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,USDA-Forest Service-International Programs -PE-QFR,98681,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -PE-QFR,98681,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Erik Lilleskov -PE-QFR,98681,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -PE-QFR,98681,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,5 -PE-QFR,98681,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0002-9208-1631 -PE-QFR,98681,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,USDA-Forest Service-Northern Research Station -PE-QFR,98673,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -PE-QFR,98673,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Dennis del Castillo Torres -PE-QFR,98673,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -PE-QFR,98673,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,6 -PE-QFR,98673,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0003-0852-5197 -PE-QFR,98673,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Institute of Investigations of Amazonian Peru -PE-QFR,98678,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -PE-QFR,98678,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Lizardo Fachin Malaverri -PE-QFR,98678,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -PE-QFR,98678,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,7 -PE-QFR,98678,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0002-2863-7279 -PE-QFR,98678,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Institute of Investigations of Amazonian Peru -PE-QFR,98679,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -PE-QFR,98679,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Jhon Ever Rengifo Marin -PE-QFR,98679,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -PE-QFR,98679,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,8 -PE-QFR,98679,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0001-7572-1855 -PE-QFR,98679,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Institute of Investigations of Amazonian Peru -PE-QFR,94266,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,University of Minnesota -PE-QFR,94266,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -PE-QFR,98674,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,USDA-Forest Service-International Programs -PE-QFR,98674,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -PE-QFR,86026,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Undisturbed -PE-QFR,91309,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -PE-QFR,91309,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -PE-QFR,91309,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201801010000 -PE-QFR,91309,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -PE-QFR,91300,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -PE-QFR,91300,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -PE-QFR,91300,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201801010000 -PE-QFR,91300,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -PE-QFR,91411,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -PE-QFR,91411,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CH4 -PE-QFR,91411,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201902271200 -PE-QFR,91411,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -PE-QFR,23001043,GRP_HEADER,SITE_NAME,Quistococha Forest Reserve -PE-QFR,86040,GRP_IGBP,IGBP,WET -PE-QFR,86027,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -PE-QFR,86023,GRP_LOCATION,LOCATION_LAT,-3.8344 -PE-QFR,86023,GRP_LOCATION,LOCATION_LONG,-73.3190 -PE-QFR,86023,GRP_LOCATION,LOCATION_ELEV,104 -PE-QFR,86021,GRP_NETWORK,NETWORK,AmeriFlux -PE-QFR,1700000060,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Griffis, T., Roman, D., Wood, J., Deventer, J., Fachin, L., Rengifo, J., Del Castillo, D., Lilleskov, E., Kolka, R., Chimner, R., del Aguila-Pasquel, J., Wayson, C., Hergoualc'h, K., Baker, J., Cadillo-Quiroz, H., Ricciuto, D. (2020) Hydrometeorological Sensitivities Of Net Ecosystem Carbon Dioxide And Methane Exchange Of An Amazonian Palm Swamp Peatland, Agricultural And Forest Meteorology, 295(), 108167" -PE-QFR,1700000060,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2020.108167 -PE-QFR,1700000060,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -PE-QFR,86029,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"1831 E. Hwy 169 Grand Rapids, MN 55744" -PE-QFR,86024,GRP_SITE_CHAR,TERRAIN,Flat -PE-QFR,86024,GRP_SITE_CHAR,ASPECT,FLAT -PE-QFR,86024,GRP_SITE_CHAR,WIND_DIRECTION,S -PE-QFR,86024,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,0 -PE-QFR,86036,GRP_SITE_DESC,SITE_DESC,"The study site is located at Quistococha on the outskirts of Iquitos, Loreto region, Peru. Quistococha is a natural protected forest reserve and an official scientific research area for IIAP. The EC flux tower (45 m tall) is located at 73o 19’ 08.1’’ W; 3o 50’ 03.9’’ S within a pristine palm swamp peatland that is within the reserve. The major vegetation type is Mauritia flexuosa (moriche palm, or aguaje in Spanish, reaching 35 m height)." -PE-QFR,86028,GRP_STATE,STATE,Loreto -PE-QFR,86022,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Timothy Griffis -PE-QFR,86022,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -PE-QFR,86022,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,tgriffis@umn.edu -PE-QFR,86022,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Minnesota -PE-QFR,86022,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"S331 Soil Science Building, 1529 Gortner Ave. St. Paul, MN 55108" -PE-QFR,97708,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Tyler Roman -PE-QFR,97708,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -PE-QFR,97708,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,troman.usfs@gmail.com -PE-QFR,97708,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,USDA- Forest Service -PE-QFR,86038,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Lizardo Fachin Malaverri -PE-QFR,86038,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Technician -PE-QFR,86038,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,lfachin@iiap.gob.pe -PE-QFR,86038,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Instituto de Investigaciones de la Amazonia Peruana -PE-QFR,86030,GRP_TOWER_POWER,TOWER_POWER,Solar panels -PE-QFR,86025,GRP_TOWER_TYPE,TOWER_TYPE,triangle -PE-QFR,24001043,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/PE-QFR -PE-QFR,86034,GRP_UTC_OFFSET,UTC_OFFSET,-5 -PR-xGU,85629,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,The National Ecological Observatory Network is a project solely funded by the National Science Foundation and managed under cooperative agreement by Battelle. -PR-xGU,85614,GRP_CLIM_AVG,MAT,25 -PR-xGU,85614,GRP_CLIM_AVG,MAP,1168 -PR-xGU,85614,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Am -PR-xGU,27001030,GRP_COUNTRY,COUNTRY,Puerto Rico -PR-xGU,95626,GRP_DOI,DOI,10.17190/AMF/1773393 -PR-xGU,95626,GRP_DOI,DOI_CITATION,"NEON (National Ecological Observatory Network) (2022), AmeriFlux BASE PR-xGU NEON Guanica Forest (GUAN), Ver. 3-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1773393" -PR-xGU,95626,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -PR-xGU,96149,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -PR-xGU,96149,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,NEON (National Ecological Observatory Network) -PR-xGU,96149,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -PR-xGU,96149,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,neon-ameriflux@battelleecology.org -PR-xGU,96149,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"NEON Program, Battelle" -PR-xGU,96149,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,20160101 -PR-xGU,96195,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,National Ecological Observatory Network -PR-xGU,96195,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -PR-xGU,95601,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,National Science Foundation (NSF) -PR-xGU,95601,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -PR-xGU,85631,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Storm or wind -PR-xGU,85618,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -PR-xGU,85618,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -PR-xGU,85618,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20180711 -PR-xGU,85618,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -PR-xGU,85630,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -PR-xGU,85630,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -PR-xGU,85630,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20180711 -PR-xGU,85630,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -PR-xGU,85620,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Other -PR-xGU,85620,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,Isotopes -PR-xGU,85620,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20180711 -PR-xGU,85620,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -PR-xGU,23001030,GRP_HEADER,SITE_NAME,NEON Guanica Forest (GUAN) -PR-xGU,85613,GRP_IGBP,IGBP,EBF -PR-xGU,85622,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -PR-xGU,85622,GRP_LAND_OWNERSHIP,LAND_OWNER,"State Forest, Dept. of Natural and Environmental Resources, Commonwealth of Puerto Rico" -PR-xGU,85625,GRP_LOCATION,LOCATION_LAT,17.9696 -PR-xGU,85625,GRP_LOCATION,LOCATION_LONG,-66.8687 -PR-xGU,85625,GRP_LOCATION,LOCATION_ELEV,143 -PR-xGU,85628,GRP_NETWORK,NETWORK,AmeriFlux -PR-xGU,85632,GRP_NETWORK,NETWORK,NEON -PR-xGU,87080,GRP_NETWORK,NETWORK,Phenocam -PR-xGU,1700006312,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Metzger, S., Ayres, E., Durden, D., Florian, C., Lee, R., Lunch, C., Luo, H., Pingintha-Durden, N., Roberti, J. A., SanClements, M., Sturtevant, C., Xu, K., Zulueta, R. C. (2019) From NEON field sites to data portal: a community resource for surface–atmosphere research comes online, Bulletin Of The American Meteorological Society, 100(11), 2305-2325" -PR-xGU,1700006312,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1175/BAMS-D-17-0307.1 -PR-xGU,1700006312,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -PR-xGU,85619,GRP_SITE_CHAR,WIND_DIRECTION,S -PR-xGU,85633,GRP_SITE_DESC,SITE_DESC,"The Guanica Forest (GUAN) site is located on the southwest corner of the main island of Puerto Rico in a protected forest with primary phenological species of Gymnanthes lucida, Pisonia albida, and Bursera simaruba. The mean canopy height is approximately 10 m." -PR-xGU,85621,GRP_SITE_FUNDING,SITE_FUNDING,National Science Foundation (NSF) -PR-xGU,95922,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,National Ecological Observatory Network -PR-xGU,95922,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -PR-xGU,95922,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,neon-ameriflux@battelleecology.org -PR-xGU,95922,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -PR-xGU,95922,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -PR-xGU,95921,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,David Durden -PR-xGU,95921,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -PR-xGU,95921,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,ddurden@battelleecology.org -PR-xGU,95921,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -PR-xGU,95921,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -PR-xGU,95923,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Stefan Metzger -PR-xGU,95923,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -PR-xGU,95923,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,smetzger@battelleecology.org -PR-xGU,95923,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -PR-xGU,95923,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -PR-xGU,95919,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Christopher Florian -PR-xGU,95919,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,BADMContact -PR-xGU,95919,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,cflorian@battelleecology.org -PR-xGU,95919,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -PR-xGU,95919,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -PR-xGU,95920,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Cove Sturtevant -PR-xGU,95920,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,DataManager -PR-xGU,95920,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,csturtevant@battelleecology.org -PR-xGU,95920,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -PR-xGU,95920,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -PR-xGU,85617,GRP_TOWER_POWER,TOWER_POWER,Direct power -PR-xGU,85627,GRP_TOWER_TYPE,TOWER_TYPE,walk-up -PR-xGU,85615,GRP_URL,URL,https://www.neonscience.org/field-sites/field-sites-map/GUAN -PR-xGU,24001030,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/PR-xGU -PR-xGU,85624,GRP_UTC_OFFSET,UTC_OFFSET,-4 -PR-xGU,85624,GRP_UTC_OFFSET,UTC_OFFSET_COMMENT,"Atlantic Standard Time (AST), please note that timestamps are converted to local standard time upon submission to AmeriFlux. Data retrieved from the NEON Data Portal will be in UTC time." -PR-xLA,85592,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,The National Ecological Observatory Network is a project solely funded by the National Science Foundation and managed under cooperative agreement by Battelle. -PR-xLA,85609,GRP_CLIM_AVG,MAT,25 -PR-xLA,85609,GRP_CLIM_AVG,MAP,1168 -PR-xLA,85609,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Am -PR-xLA,27001029,GRP_COUNTRY,COUNTRY,Puerto Rico -PR-xLA,95629,GRP_DOI,DOI,10.17190/AMF/1773394 -PR-xLA,95629,GRP_DOI,DOI_CITATION,"NEON (National Ecological Observatory Network) (2022), AmeriFlux BASE PR-xLA NEON Lajas Experimental Station (LAJA), Ver. 3-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1773394" -PR-xLA,95629,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -PR-xLA,96150,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -PR-xLA,96150,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,NEON (National Ecological Observatory Network) -PR-xLA,96150,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -PR-xLA,96150,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,neon-ameriflux@battelleecology.org -PR-xLA,96150,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"NEON Program, Battelle" -PR-xLA,96150,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,20160101 -PR-xLA,96196,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,National Ecological Observatory Network -PR-xLA,96196,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -PR-xLA,95600,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,National Science Foundation (NSF) -PR-xLA,95600,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -PR-xLA,85608,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Grazing -PR-xLA,85597,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Storm or wind -PR-xLA,85604,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -PR-xLA,85604,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -PR-xLA,85604,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20180530 -PR-xLA,85604,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -PR-xLA,85599,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -PR-xLA,85599,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -PR-xLA,85599,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20180530 -PR-xLA,85599,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -PR-xLA,23001029,GRP_HEADER,SITE_NAME,NEON Lajas Experimental Station (LAJA) -PR-xLA,85607,GRP_IGBP,IGBP,GRA -PR-xLA,85606,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -PR-xLA,85606,GRP_LAND_OWNERSHIP,LAND_OWNER,University of Puerto Rico -PR-xLA,85605,GRP_LOCATION,LOCATION_LAT,18.0212 -PR-xLA,85605,GRP_LOCATION,LOCATION_LONG,-67.0769 -PR-xLA,85605,GRP_LOCATION,LOCATION_ELEV,24 -PR-xLA,85601,GRP_NETWORK,NETWORK,AmeriFlux -PR-xLA,85596,GRP_NETWORK,NETWORK,NEON -PR-xLA,87081,GRP_NETWORK,NETWORK,Phenocam -PR-xLA,1700002973,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Metzger, S., Ayres, E., Durden, D., Florian, C., Lee, R., Lunch, C., Luo, H., Pingintha-Durden, N., Roberti, J. A., SanClements, M., Sturtevant, C., Xu, K., Zulueta, R. C. (2019) From NEON field sites to data portal: a community resource for surface–atmosphere research comes online, Bulletin Of The American Meteorological Society, 100(11), 2305-2325" -PR-xLA,1700002973,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1175/BAMS-D-17-0307.1 -PR-xLA,1700002973,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -PR-xLA,85593,GRP_SITE_CHAR,WIND_DIRECTION,SSE -PR-xLA,85603,GRP_SITE_DESC,SITE_DESC,The NEON Lajas Experimental Station (LAJA) site is located on the southwest corner of the main island of Puerto Rico in a experimental range. This is a grassland site that is periodically grazed by cattle. -PR-xLA,85598,GRP_SITE_FUNDING,SITE_FUNDING,National Science Foundation (NSF) -PR-xLA,95927,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,National Ecological Observatory Network -PR-xLA,95927,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -PR-xLA,95927,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,neon-ameriflux@battelleecology.org -PR-xLA,95927,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -PR-xLA,95927,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -PR-xLA,95926,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,David Durden -PR-xLA,95926,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -PR-xLA,95926,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,ddurden@battelleecology.org -PR-xLA,95926,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -PR-xLA,95926,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -PR-xLA,95925,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Stefan Metzger -PR-xLA,95925,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -PR-xLA,95925,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,smetzger@battelleecology.org -PR-xLA,95925,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -PR-xLA,95925,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -PR-xLA,95924,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Christopher Florian -PR-xLA,95924,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,BADMContact -PR-xLA,95924,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,cflorian@battelleecology.org -PR-xLA,95924,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -PR-xLA,95924,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -PR-xLA,95928,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Cove Sturtevant -PR-xLA,95928,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,DataManager -PR-xLA,95928,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,csturtevant@battelleecology.org -PR-xLA,95928,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -PR-xLA,95928,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -PR-xLA,85594,GRP_TOWER_POWER,TOWER_POWER,Direct power -PR-xLA,85595,GRP_TOWER_TYPE,TOWER_TYPE,walk-up -PR-xLA,85602,GRP_URL,URL,https://www.neonscience.org/field-sites/field-sites-map/LAJA -PR-xLA,24001029,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/PR-xLA -PR-xLA,85600,GRP_UTC_OFFSET,UTC_OFFSET,-4 -PR-xLA,85600,GRP_UTC_OFFSET,UTC_OFFSET_COMMENT,"Atlantic Standard Time (AST), please note that timestamps are converted to local standard time upon submission to AmeriFlux. Data retrieved from the NEON Data Portal will be in UTC time." -US-A03,85018,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,This site is supported by the U.S. Dept. of Energy's Office of Biological and Environmental Research ARM program. -US-A03,85018,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT_COMMENT,"For more information, please contact Dave Billesbach" -US-A03,85028,GRP_CLIM_AVG,MAT,-11.2 -US-A03,85028,GRP_CLIM_AVG,MAP,115.1 -US-A03,85028,GRP_CLIM_AVG,CLIMATE_KOEPPEN,ET -US-A03,27001006,GRP_COUNTRY,COUNTRY,USA -US-A03,86010,GRP_DOI,DOI,10.17190/AMF/1498752 -US-A03,86010,GRP_DOI,DOI_CITATION,"Dave Billesbach, Ryan Sullivan (2022), AmeriFlux BASE US-A03 ARM-AMF3-Oliktok, Ver. 5-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1498752" -US-A03,86010,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-A03,91899,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-A03,91899,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Dave Billesbach -US-A03,91899,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-A03,91899,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0001-8661-9178 -US-A03,91899,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,dbillesbach1@unl.edu -US-A03,91899,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of Nebraska -US-A03,91899,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,20140716 -US-A03,92246,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-A03,92246,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Ryan Sullivan -US-A03,92246,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-A03,92246,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0002-3500-1842 -US-A03,92246,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,rcsullivan@anl.gov -US-A03,92246,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Argonne National Laboratory -US-A03,85929,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Argonne National Laboratory -US-A03,85929,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-A03,85928,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,U.S. DOE ARM program -US-A03,85928,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-A03,93068,GRP_DOI_RELATED_DATA_DOI,DOI_RELATED_DATA_DOI,http://dx.doi.org/10.5439/1025039 -US-A03,85031,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-A03,85031,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-A03,85031,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20140716 -US-A03,85031,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-A03,85020,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-A03,85020,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-A03,85020,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20140716 -US-A03,85020,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-A03,85015,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-A03,85015,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-A03,85015,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20140716 -US-A03,85015,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-A03,91892,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-A03,91892,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CH4 -US-A03,91892,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20140716 -US-A03,91892,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Growing season operation only -US-A03,23001006,GRP_HEADER,SITE_NAME,ARM-AMF3-Oliktok -US-A03,85019,GRP_IGBP,IGBP,BSV -US-A03,85019,GRP_IGBP,IGBP_COMMENT,Coastal Arctic tundra -US-A03,85034,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-A03,85030,GRP_LOCATION,LOCATION_LAT,70.4953 -US-A03,85030,GRP_LOCATION,LOCATION_LONG,-149.8823 -US-A03,85030,GRP_LOCATION,LOCATION_ELEV,5 -US-A03,85030,GRP_LOCATION,LOCATION_DATE_START,20140716 -US-A03,85024,GRP_NETWORK,NETWORK,AmeriFlux -US-A03,1700005997,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Bao, T., Xu, X., Jia, G., Billesbach, D. P., Sullivan, R. C. (2020) Much Stronger Tundra Methane Emissions During Autumn Freeze Than Spring Thaw, Global Change Biology, (), " -US-A03,1700005997,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/GCB.15421 -US-A03,1700005997,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-A03,1700005415,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Bao, T., Xu, X., Jia, G., Billesbach, D. P., Sullivan, R. C. (2020) Much Stronger Tundra Methane Emissions During Autumn Freeze Than Spring Thaw, Global Change Biology, 301-302(), 108350" -US-A03,1700005415,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/GCB.15421 -US-A03,1700005415,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-A03,1700006963,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(), 108350" -US-A03,1700006963,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -US-A03,1700006963,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-A03,85013,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"Greenhouse Gas fluxes, energy balance and partitioning" -US-A03,85021,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"Sandia/Oliktok LRRS, 1 Airport Road, Deadhorse, AK, 99734" -US-A03,85026,GRP_SITE_CHAR,TERRAIN,Flat -US-A03,85026,GRP_SITE_CHAR,ASPECT,FLAT -US-A03,85026,GRP_SITE_CHAR,WIND_DIRECTION,E -US-A03,85026,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,2000 -US-A03,85017,GRP_SITE_DESC,SITE_DESC,"This site is located at ARM AMF3 site near Point Oliktok, AK" -US-A03,85032,GRP_SITE_FUNDING,SITE_FUNDING,U.S. DOE ARM program -US-A03,85033,GRP_STATE,STATE,AK -US-A03,90965,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Ryan Sullivan -US-A03,90965,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-A03,90965,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,rcsullivan@anl.gov -US-A03,90965,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Argonne National Laboratory -US-A03,85027,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Dave Billesbach -US-A03,85027,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-A03,85027,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,dbillesbach1@unl.edu -US-A03,85027,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Nebraska -US-A03,85027,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"157 L.W. Chase Hall, Univ. of Nebraska, Lincoln, NE, 68583-0726" -US-A03,85022,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Sebastien Biraud -US-A03,85022,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,DataManager -US-A03,85022,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,scbiraud@lbl.gov -US-A03,85022,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Lawrence Berkeley National Laboratory -US-A03,85016,GRP_TOWER_POWER,TOWER_POWER,Direct power -US-A03,85029,GRP_TOWER_TYPE,TOWER_TYPE,tripod -US-A03,24001006,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-A03 -US-A03,85025,GRP_UTC_OFFSET,UTC_OFFSET,-9 -US-A03,85025,GRP_UTC_OFFSET,UTC_OFFSET_COMMENT,Alaska Standard Time is UTC-9 -US-A10,85085,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,This site is supported by the U.S. Dept. of Energy's Office of Biological and Environmental Research ARM program. -US-A10,85085,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT_COMMENT,"For more information, please contact Dave Billesbach" -US-A10,85091,GRP_CLIM_AVG,MAT,-11.2 -US-A10,85091,GRP_CLIM_AVG,MAP,115.1 -US-A10,85091,GRP_CLIM_AVG,CLIMATE_KOEPPEN,ET -US-A10,27001008,GRP_COUNTRY,COUNTRY,USA -US-A10,86011,GRP_DOI,DOI,10.17190/AMF/1498753 -US-A10,86011,GRP_DOI,DOI_CITATION,"Dave Billesbach, Ryan Sullivan (2021), AmeriFlux BASE US-A10 ARM-NSA-Barrow, Ver. 4-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1498753" -US-A10,86011,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-A10,91908,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-A10,91908,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Dave Billesbach -US-A10,91908,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-A10,91908,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0001-8661-9178 -US-A10,91908,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,dbillesbach1@unl.edu -US-A10,91908,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of Nebraska -US-A10,91908,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,20111116 -US-A10,92273,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-A10,92273,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Ryan Sullivan -US-A10,92273,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-A10,92273,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0002-3500-1842 -US-A10,92273,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,rcsullivan@anl.gov -US-A10,92273,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Argonne National Laboratory -US-A10,85931,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Argonne National Laboratory -US-A10,85931,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-A10,85930,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,U.S. DOE ARM program -US-A10,85930,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-A10,93030,GRP_DOI_RELATED_DATA_DOI,DOI_RELATED_DATA_DOI,http://dx.doi.org/10.5439/1025039 -US-A10,85079,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-A10,85079,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-A10,85079,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20120328 -US-A10,85079,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-A10,85092,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-A10,85092,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-A10,85092,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20120328 -US-A10,85092,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-A10,85096,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-A10,85096,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-A10,85096,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20120328 -US-A10,85096,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-A10,91914,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-A10,91914,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CH4 -US-A10,91914,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20120328 -US-A10,91914,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Growing season operation only -US-A10,23001008,GRP_HEADER,SITE_NAME,ARM-NSA-Barrow -US-A10,85090,GRP_IGBP,IGBP,BSV -US-A10,85090,GRP_IGBP,IGBP_COMMENT,Coastal Arctic tundra -US-A10,85083,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-A10,85098,GRP_LOCATION,LOCATION_LAT,71.3242 -US-A10,85098,GRP_LOCATION,LOCATION_LONG,-156.6149 -US-A10,85098,GRP_LOCATION,LOCATION_ELEV,4 -US-A10,85098,GRP_LOCATION,LOCATION_DATE_START,20120328 -US-A10,85082,GRP_NETWORK,NETWORK,AmeriFlux -US-A10,1700002148,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Bao, T., Xu, X., Jia, G., Billesbach, D. P., Sullivan, R. C. (2020) Much Stronger Tundra Methane Emissions During Autumn Freeze Than Spring Thaw, Global Change Biology, (), " -US-A10,1700002148,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/GCB.15421 -US-A10,1700002148,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-A10,1700002703,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Bao, T., Xu, X., Jia, G., Billesbach, D. P., Sullivan, R. C. (2020) Much Stronger Tundra Methane Emissions During Autumn Freeze Than Spring Thaw, Global Change Biology, 301-302(), 108350" -US-A10,1700002703,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/GCB.15421 -US-A10,1700002703,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-A10,1700004017,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(), 108350" -US-A10,1700004017,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -US-A10,1700004017,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-A10,85095,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"Greenhouse Gas fluxes, energy balance and partitioning" -US-A10,85084,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"UIC/ARM, 354 NARL St, Box 310, Barrow, AK, 99723" -US-A10,85087,GRP_SITE_CHAR,TERRAIN,Flat -US-A10,85087,GRP_SITE_CHAR,ASPECT,FLAT -US-A10,85087,GRP_SITE_CHAR,WIND_DIRECTION,E -US-A10,85087,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,2000 -US-A10,85086,GRP_SITE_DESC,SITE_DESC,"This site is located at ARM North Slope of Alaska site near Barrow, AK" -US-A10,85097,GRP_SITE_FUNDING,SITE_FUNDING,U.S. DOE ARM program -US-A10,85094,GRP_STATE,STATE,AK -US-A10,90969,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Ryan Sullivan -US-A10,90969,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-A10,90969,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,rcsullivan@anl.gov -US-A10,90969,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Argonne National Laboratory -US-A10,85089,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Dave Billesbach -US-A10,85089,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-A10,85089,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,dbillesbach1@unl.edu -US-A10,85089,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Nebraska -US-A10,85089,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"157 L.W. Chase Hall, Univ. of Nebraska, Lincoln, NE, 68583-0726" -US-A10,85088,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Sebastien Biraud -US-A10,85088,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,DataManager -US-A10,85088,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,scbiraud@lbl.gov -US-A10,85088,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Lawrence Berkeley National Laboratory -US-A10,85077,GRP_TOWER_POWER,TOWER_POWER,Direct power -US-A10,85078,GRP_TOWER_TYPE,TOWER_TYPE,tripod -US-A10,24001008,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-A10 -US-A10,85080,GRP_UTC_OFFSET,UTC_OFFSET,-9 -US-A10,85080,GRP_UTC_OFFSET,UTC_OFFSET_COMMENT,Alaska Standard Time is UTC-9 -US-A32,30065,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,This site is supported by the U.S. Dept. of Energy's Office of Biological and Environmental Research ARM program. -US-A32,30065,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT_COMMENT,"For more information, please contact Dave Billesbach" -US-A32,30049,GRP_CLIM_AVG,MAT,33.9 -US-A32,30049,GRP_CLIM_AVG,MAP,889 -US-A32,30049,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Cfa -US-A32,27000683,GRP_COUNTRY,COUNTRY,USA -US-A32,81557,GRP_DOI,DOI,10.17190/AMF/1436327 -US-A32,81557,GRP_DOI,DOI_CITATION,"Dave Billesbach, Lara Kueppers, Margaret Torn, Sebastien Biraud (2018), AmeriFlux BASE US-A32 ARM-SGP Medford hay pasture, Ver. 1-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1436327" -US-A32,81557,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-A32,91912,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-A32,91912,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Dave Billesbach -US-A32,91912,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-A32,91912,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0001-8661-9178 -US-A32,91912,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,dbillesbach1@unl.edu -US-A32,91912,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of Nebraska -US-A32,91912,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,20150615 -US-A32,91912,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_END,20170613 -US-A32,81543,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-A32,81543,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Lara Kueppers -US-A32,81543,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-A32,81543,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,lmkueppers@lbl.gov -US-A32,81543,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Lawrence Berkeley National Laboratory -US-A32,81542,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-A32,81542,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Margaret Torn -US-A32,81542,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-A32,81542,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,mstorn@lbl.gov -US-A32,81542,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Lawrence Berkeley National Laboratory -US-A32,81544,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-A32,81544,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Sebastien Biraud -US-A32,81544,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-A32,81544,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,scbiraud@lbl.gov -US-A32,81544,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Lawrence Berkeley National Laboratory -US-A32,81546,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Lawrence Berkeley National Laboratory -US-A32,81546,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-A32,81545,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,U.S. DOE ARM program -US-A32,81545,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-A32,30059,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Agriculture -US-A32,91919,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-A32,91919,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-A32,91919,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20150617 -US-A32,91919,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20170613 -US-A32,91919,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-A32,91907,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-A32,91907,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-A32,91907,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20150617 -US-A32,91907,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20170613 -US-A32,91907,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-A32,91891,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-A32,91891,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-A32,91891,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20150617 -US-A32,91891,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20170613 -US-A32,91891,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-A32,23000683,GRP_HEADER,SITE_NAME,ARM-SGP Medford hay pasture -US-A32,30048,GRP_IGBP,IGBP,GRA -US-A32,30048,GRP_IGBP,IGBP_COMMENT,"Grass pasture, periodically cut for hay" -US-A32,30047,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -US-A32,30055,GRP_LOCATION,LOCATION_LAT,36.8193 -US-A32,30055,GRP_LOCATION,LOCATION_LONG,-97.8198 -US-A32,30055,GRP_LOCATION,LOCATION_ELEV,335 -US-A32,30055,GRP_LOCATION,LOCATION_DATE_START,20150903 -US-A32,30056,GRP_NETWORK,NETWORK,AmeriFlux -US-A32,1700003708,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(), 108350" -US-A32,1700003708,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -US-A32,1700003708,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-A32,30060,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"Greenhouse Gas fluxes, energy balance and partitioning" -US-A32,30069,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"DOE ARM Facility Southern Great Plains Site, 109596 Coal Road, Billings, OK, 74630" -US-A32,30057,GRP_SITE_CHAR,TERRAIN,Flat -US-A32,30057,GRP_SITE_CHAR,ASPECT,FLAT -US-A32,30057,GRP_SITE_CHAR,WIND_DIRECTION,S -US-A32,30057,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,150 -US-A32,30050,GRP_SITE_DESC,SITE_DESC,"This site is located at the ARM SGP Extended Facility E32, 8 km West of Medford, OK" -US-A32,30053,GRP_SITE_FUNDING,SITE_FUNDING,U.S. DOE ARM program -US-A32,30066,GRP_STATE,STATE,OK -US-A32,30063,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Lara Kueppers -US-A32,30063,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-A32,30063,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,lmkueppers@lbl.gov -US-A32,30063,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Lawrence Berkeley National Laboratory -US-A32,30062,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Margaret Torn -US-A32,30062,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-A32,30062,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,mstorn@lbl.gov -US-A32,30062,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Lawrence Berkeley National Laboratory -US-A32,30067,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Sebastien Biraud -US-A32,30067,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-A32,30067,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,scbiraud@lbl.gov -US-A32,30067,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Lawrence Berkeley National Laboratory -US-A32,30051,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Dave Billesbach -US-A32,30051,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-A32,30051,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,dbillesbach1@unl.edu -US-A32,30051,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Nebraska -US-A32,30051,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"157 L.W. Chase Hall, Univ. of Nebraska, Lincoln, NE, 68583-0726" -US-A32,30064,GRP_TOWER_POWER,TOWER_POWER,Direct power -US-A32,30054,GRP_TOWER_TYPE,TOWER_TYPE,tripod -US-A32,24000683,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-A32 -US-A32,30068,GRP_UTC_OFFSET,UTC_OFFSET,-6 -US-A32,30068,GRP_UTC_OFFSET,UTC_OFFSET_COMMENT,Central Standard Time is UTC-6 -US-A39,85073,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,This site is supported by the U.S. Dept. of Energy's Office of Biological and Environmental Research ARM program. -US-A39,85073,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT_COMMENT,"For more information, please contact Dave Billesbach" -US-A39,85076,GRP_CLIM_AVG,MAT,14.95 -US-A39,85076,GRP_CLIM_AVG,MAP,965 -US-A39,85076,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Csa -US-A39,27001007,GRP_COUNTRY,COUNTRY,USA -US-A39,85069,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-A39,85069,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-A39,85069,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20151006 -US-A39,85069,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-A39,85065,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-A39,85065,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-A39,85065,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20151006 -US-A39,85065,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-A39,85061,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-A39,85061,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-A39,85061,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20151006 -US-A39,85061,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-A39,23001007,GRP_HEADER,SITE_NAME,ARM-SGP-Morrison -US-A39,85060,GRP_IGBP,IGBP,CRO -US-A39,85060,GRP_IGBP,IGBP_COMMENT,Cropland and pasture -US-A39,85064,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -US-A39,85070,GRP_LOCATION,LOCATION_LAT,36.3776 -US-A39,85070,GRP_LOCATION,LOCATION_LONG,-96.0690 -US-A39,85070,GRP_LOCATION,LOCATION_ELEV,306 -US-A39,85070,GRP_LOCATION,LOCATION_DATE_START,20151006 -US-A39,85071,GRP_NETWORK,NETWORK,AmeriFlux -US-A39,85068,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"Greenhouse Gas fluxes, energy balance and partitioning" -US-A39,85063,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"DOE-ARM, 109596 Coal Road, Billings, OK 74630" -US-A39,85058,GRP_SITE_CHAR,TERRAIN,Flat -US-A39,85058,GRP_SITE_CHAR,ASPECT,FLAT -US-A39,85058,GRP_SITE_CHAR,WIND_DIRECTION,S -US-A39,85058,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,1000 -US-A39,85072,GRP_SITE_DESC,SITE_DESC,"This site is located at ARM SGP Extended Facility 39 near Morrison, OK" -US-A39,85067,GRP_SITE_FUNDING,SITE_FUNDING,U.S. DOE ARM program -US-A39,85056,GRP_STATE,STATE,OK -US-A39,90968,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Ryan Sullivan -US-A39,90968,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-A39,90968,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,rcsullivan@anl.gov -US-A39,90968,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Argonne National Laboratory -US-A39,85057,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Dave Billesbach -US-A39,85057,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-A39,85057,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,dbillesbach1@unl.edu -US-A39,85057,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Nebraska -US-A39,85057,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"157 L.W. Chase Hall, Univ. of Nebraska, Lincoln, NE, 68583-0726" -US-A39,85062,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Sebastien Biraud -US-A39,85062,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,DataManager -US-A39,85062,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,scbiraud@lbl.gov -US-A39,85062,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Lawrence Berkeley National Laboratory -US-A39,85075,GRP_TOWER_POWER,TOWER_POWER,Direct power -US-A39,85066,GRP_TOWER_TYPE,TOWER_TYPE,tripod -US-A39,24001007,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-A39 -US-A39,85059,GRP_UTC_OFFSET,UTC_OFFSET,-6 -US-A39,85059,GRP_UTC_OFFSET,UTC_OFFSET_COMMENT,Central Standard Time is UTC-6 -US-A74,30071,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,This site is supported by the U.S. Dept. of Energy's Office of Biological and Environmental Research ARM program. -US-A74,30071,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT_COMMENT,"For more information, please contact Dave Billesbach" -US-A74,30092,GRP_CLIM_AVG,MAT,33.9 -US-A74,30092,GRP_CLIM_AVG,MAP,889 -US-A74,30092,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Cfa -US-A74,27000684,GRP_COUNTRY,COUNTRY,USA -US-A74,81567,GRP_DOI,DOI,10.17190/AMF/1436328 -US-A74,81567,GRP_DOI,DOI_CITATION,"Dave Billesbach, Lara Kueppers, Margaret Torn, Sebastien Biraud (2018), AmeriFlux BASE US-A74 ARM SGP milo field, Ver. 1-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1436328" -US-A74,81567,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-A74,91901,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-A74,91901,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Dave Billesbach -US-A74,91901,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-A74,91901,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0001-8661-9178 -US-A74,91901,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,dbillesbach1@unl.edu -US-A74,91901,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of Nebraska -US-A74,91901,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,20160127 -US-A74,91901,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_END,20171020 -US-A74,81549,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-A74,81549,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Lara Kueppers -US-A74,81549,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-A74,81549,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,lmkueppers@lbl.gov -US-A74,81549,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Lawrence Berkeley National Laboratory -US-A74,81548,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-A74,81548,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Margaret Torn -US-A74,81548,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-A74,81548,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,mstorn@lbl.gov -US-A74,81548,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Lawrence Berkeley National Laboratory -US-A74,81547,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-A74,81547,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Sebastien Biraud -US-A74,81547,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-A74,81547,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,scbiraud@lbl.gov -US-A74,81547,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Lawrence Berkeley National Laboratory -US-A74,81551,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Lawrence Berkeley National Laboratory -US-A74,81551,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-A74,81550,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,U.S. DOE ARM program -US-A74,81550,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-A74,30079,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Agriculture -US-A74,91917,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-A74,91917,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-A74,91917,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20160128 -US-A74,91917,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20171020 -US-A74,91917,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-A74,91916,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-A74,91916,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-A74,91916,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20160128 -US-A74,91916,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20171020 -US-A74,91916,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-A74,91918,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-A74,91918,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-A74,91918,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20160128 -US-A74,91918,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20171020 -US-A74,91918,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-A74,23000684,GRP_HEADER,SITE_NAME,ARM SGP milo field -US-A74,30080,GRP_IGBP,IGBP,CRO -US-A74,30080,GRP_IGBP,IGBP_COMMENT,Milo field -US-A74,30074,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -US-A74,30073,GRP_LOCATION,LOCATION_LAT,36.8085 -US-A74,30073,GRP_LOCATION,LOCATION_LONG,-97.5489 -US-A74,30073,GRP_LOCATION,LOCATION_ELEV,337 -US-A74,30073,GRP_LOCATION,LOCATION_DATE_START,20160128 -US-A74,30087,GRP_NETWORK,NETWORK,AmeriFlux -US-A74,1700001683,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(), 108350" -US-A74,1700001683,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -US-A74,1700001683,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-A74,30086,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"Greenhouse Gas fluxes, energy balance and partitioning" -US-A74,30089,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"DOE ARM Facility Southern Great Plains Site, 109596 Coal Road, Billings, OK, 74630" -US-A74,30077,GRP_SITE_CHAR,TERRAIN,Flat -US-A74,30077,GRP_SITE_CHAR,ASPECT,FLAT -US-A74,30077,GRP_SITE_CHAR,WIND_DIRECTION,S -US-A74,30077,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,450 -US-A74,30078,GRP_SITE_DESC,SITE_DESC,"This site is located near the ARM SGP Central Facility at the intersection of Oklahoma highways 11 and 74, 16.5 km East of Medford, OK" -US-A74,30085,GRP_SITE_FUNDING,SITE_FUNDING,U.S. DOE ARM program -US-A74,30076,GRP_STATE,STATE,OK -US-A74,30082,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Lara Kueppers -US-A74,30082,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-A74,30082,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,lmkueppers@lbl.gov -US-A74,30082,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Lawrence Berkeley National Laboratory -US-A74,30072,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Margaret Torn -US-A74,30072,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-A74,30072,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,mstorn@lbl.gov -US-A74,30072,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Lawrence Berkeley National Laboratory -US-A74,30081,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Sebastien Biraud -US-A74,30081,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-A74,30081,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,scbiraud@lbl.gov -US-A74,30081,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Lawrence Berkeley National Laboratory -US-A74,30075,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Dave Billesbach -US-A74,30075,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-A74,30075,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,dbillesbach1@unl.edu -US-A74,30075,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Nebraska -US-A74,30075,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"157 L.W. Chase Hall, Univ. of Nebraska, Lincoln, NE, 68583-0726" -US-A74,30090,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-A74,30084,GRP_TOWER_TYPE,TOWER_TYPE,tripod -US-A74,24000684,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-A74 -US-A74,30083,GRP_UTC_OFFSET,UTC_OFFSET,-6 -US-A74,30083,GRP_UTC_OFFSET,UTC_OFFSET_COMMENT,Central Standard Time is UTC-6 -US-AaG,99049,GRP_CLIM_AVG,MAT,17.4 -US-AaG,99049,GRP_CLIM_AVG,MAP,1410 -US-AaG,99049,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Cfa -US-AaG,27001221,GRP_COUNTRY,COUNTRY,USA -US-AaG,99045,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-AaG,99045,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-AaG,99045,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201606050000 -US-AaG,99045,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,201708160000 -US-AaG,99045,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-AaG,99051,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-AaG,99051,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-AaG,99051,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201606050000 -US-AaG,99051,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,201708160000 -US-AaG,99051,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-AaG,23001221,GRP_HEADER,SITE_NAME,Arkansas Grassland -US-AaG,99046,GRP_IGBP,IGBP,GRA -US-AaG,99046,GRP_IGBP,IGBP_DATE_START,201606050000 -US-AaG,99055,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-AaG,99056,GRP_LOCATION,LOCATION_LAT,33.1105 -US-AaG,99056,GRP_LOCATION,LOCATION_LONG,-91.6282 -US-AaG,99056,GRP_LOCATION,LOCATION_ELEV,33 -US-AaG,99056,GRP_LOCATION,LOCATION_DATE_START,201606050000 -US-AaG,99054,GRP_NETWORK,NETWORK,AmeriFlux -US-AaG,99048,GRP_NETWORK,NETWORK,LTER -US-AaG,99050,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,Biophysical impacts of land cover change -US-AaG,99053,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"702 N. Walnut Grove Avenue, MSB2 Room 316, Bloomington, IN 47405" -US-AaG,99043,GRP_SITE_CHAR,TERRAIN,Flat -US-AaG,99043,GRP_SITE_CHAR,ASPECT,FLAT -US-AaG,99039,GRP_SITE_DESC,SITE_DESC,The site is a grassland situated in the Overflow National Wildlife Refuge. It experiences frequent flooding. -US-AaG,99047,GRP_SITE_FUNDING,SITE_FUNDING,NSF DEB 1552747 -US-AaG,99052,GRP_STATE,STATE,GA -US-AaG,99042,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Kim Novick -US-AaG,99042,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-AaG,99042,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,knovick@indiana.edu -US-AaG,99042,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Indiana University - Bloomington -US-AaG,99038,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Quan Zhang -US-AaG,99038,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-AaG,99038,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,quan.zhang@whu.edu.cn -US-AaG,99038,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Wuhan University -US-AaG,99040,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-AaG,99044,GRP_TOWER_TYPE,TOWER_TYPE,tripod -US-AaG,24001221,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-AaG -US-AaG,99041,GRP_UTC_OFFSET,UTC_OFFSET,-5 -US-AaG,99041,GRP_UTC_OFFSET,UTC_OFFSET_DATE_START,201701010000 -US-Act,81642,GRP_CLIM_AVG,MAT,11.1 -US-Act,81642,GRP_CLIM_AVG,MAP,907 -US-Act,81642,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Cfa -US-Act,27000973,GRP_COUNTRY,COUNTRY,USA -US-Act,98950,GRP_DOI,DOI,10.17190/AMF/1846660 -US-Act,98950,GRP_DOI,DOI_CITATION,"Sarah Waldo (2022), AmeriFlux BASE US-Act Acton Lake Flux Tower Site, Ver. 1-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1846660" -US-Act,98950,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-Act,98932,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Act,98932,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Sarah Waldo -US-Act,98932,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Act,98932,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,waldo.sarah@epa.gov -US-Act,98932,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,US EPA Office of Research and Development -US-Act,98948,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,US EPA Office of Research and Development -US-Act,98948,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-Act,98939,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,USEPA -US-Act,98939,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-Act,99255,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Act,99255,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-Act,99255,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201701131600 -US-Act,99255,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,201910 -US-Act,99255,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Act,99274,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Act,99274,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-Act,99274,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201701131600 -US-Act,99274,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,201910 -US-Act,99274,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Act,99245,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Act,99245,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-Act,99245,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201701131600 -US-Act,99245,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,201910 -US-Act,99245,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Act,99251,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Act,99251,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CH4 -US-Act,99251,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201701251730 -US-Act,99251,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,201910 -US-Act,99251,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Act,23000973,GRP_HEADER,SITE_NAME,Acton Lake Flux Tower Site -US-Act,81650,GRP_IGBP,IGBP,WAT -US-Act,81645,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-Act,81645,GRP_LAND_OWNERSHIP,LAND_OWNER,"Hueston Woods is an Ohio State Park, maintained by the Ohio Division of Natural Resources (DNR). See http://parks.ohiodnr.gov/huestonwoods." -US-Act,81639,GRP_LOCATION,LOCATION_LAT,39.5820 -US-Act,81639,GRP_LOCATION,LOCATION_LONG,-84.7580 -US-Act,81639,GRP_LOCATION,LOCATION_ELEV,263 -US-Act,81639,GRP_LOCATION,LOCATION_DATE_START,201701131600 -US-Act,81634,GRP_LOCATION,LOCATION_LAT,39.5820 -US-Act,81634,GRP_LOCATION,LOCATION_LONG,-84.7550 -US-Act,81634,GRP_LOCATION,LOCATION_ELEV,263 -US-Act,81634,GRP_LOCATION,LOCATION_DATE_START,201805071530 -US-Act,81635,GRP_NETWORK,NETWORK,AmeriFlux -US-Act,1700001182,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Waldo, S., Beaulieu, J. J., Barnett, W., Balz, D. A., Vanni, M. J., Williamson, T., Walker, J. T. (2021) Temporal Trends In Methane Emissions From A Small Eutrophic Reservoir: The Key Role Of A Spring Burst, Biogeosciences, 18(19), 5291-5311" -US-Act,1700001182,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.5194/BG-18-5291-2021 -US-Act,1700001182,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Act,81630,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"Reservoir methane emission behavior and biophysical drivers, reservoir carbon dioxide dynamics" -US-Act,81637,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"26 W Martin Luther King Dr., Cincinnati, OH 45223" -US-Act,81644,GRP_SITE_CHAR,TERRAIN,Flat -US-Act,81644,GRP_SITE_CHAR,ASPECT,FLAT -US-Act,81644,GRP_SITE_CHAR,WIND_DIRECTION,NNE -US-Act,81644,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,290 -US-Act,81644,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,30 -US-Act,81638,GRP_SITE_DESC,SITE_DESC,"This tower is located at Acton Lake, a eutrophic reservoir immediately surrounded by forest but draining an agricultural watershed in Hueston Woods State Park outside of Oxford, OH. The EC instrumentation was originally deployed 25 m from shore on a dock piling. In April of 2018 a lake tower was installed >200 m from the closest shoreline. The EC instrumentation was deployed on this aquatic tower on 7 May 2018." -US-Act,81640,GRP_SITE_FUNDING,SITE_FUNDING,USEPA -US-Act,81629,GRP_STATE,STATE,OH -US-Act,81643,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Sarah Waldo -US-Act,81643,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Act,81643,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,waldo.sarah@epa.gov -US-Act,81643,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,US EPA Office of Research and Development -US-Act,81643,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"26 W Martin Luther King Dr., Cincinnati, OH 45223" -US-Act,81649,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Jake Beaulieu -US-Act,81649,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,AncContact -US-Act,81649,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,beaulieu.jake@epa.gov -US-Act,81649,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,US EPA Office of Research and Development -US-Act,81641,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,John Walker -US-Act,81641,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,AncContact -US-Act,81641,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,walker.johnt@epa.gov -US-Act,81641,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,US EPA Office of Research and Development -US-Act,81633,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-Act,81647,GRP_TOWER_TYPE,TOWER_TYPE,triangle -US-Act,24000973,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-Act -US-Act,81636,GRP_UTC_OFFSET,UTC_OFFSET,-5 -US-Act,81636,GRP_UTC_OFFSET,UTC_OFFSET_DATE_START,201701131600 -US-Akn,27000507,GRP_COUNTRY,COUNTRY,USA -US-Akn,15688,GRP_DOI,DOI,10.17190/AMF/1246141 -US-Akn,15688,GRP_DOI,DOI_CITATION,"Monique Leclerc (2019), AmeriFlux BASE US-Akn Savannah River Site, Ver. 5-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1246141" -US-Akn,15688,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-Akn,32340,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Akn,32340,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Monique Leclerc -US-Akn,32340,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Akn,32340,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,mleclerc@uga.edu -US-Akn,32340,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"University of Georgia, Deptartment of Crop and Soil Science, Lab for Biogeosciences" -US-Akn,32342,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,"University of Georgia, Deptartment of Crop and Soil Science, Lab for Biogeosciences" -US-Akn,32342,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-Akn,32341,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,DOE -US-Akn,32341,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-Akn,97947,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Forestry -US-Akn,97943,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Akn,97943,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-Akn,97943,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201102150000 -US-Akn,97943,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,202107010000 -US-Akn,97943,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Akn,97946,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Akn,97946,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-Akn,97946,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20110215 -US-Akn,97946,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,202107010000 -US-Akn,97946,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Akn,23000507,GRP_HEADER,SITE_NAME,Savannah River Site -US-Akn,22257,GRP_IGBP,IGBP,MF -US-Akn,97944,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -US-Akn,97944,GRP_LAND_OWNERSHIP,LAND_OWNER,Land is owned by the Department of Energy; Access to site is restricted and not open to public. -US-Akn,97939,GRP_LOCATION,LOCATION_LAT,33.3825 -US-Akn,97939,GRP_LOCATION,LOCATION_LONG,-81.5653 -US-Akn,97939,GRP_LOCATION,LOCATION_ELEV,93 -US-Akn,22259,GRP_NETWORK,NETWORK,AmeriFlux -US-Akn,97936,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,Forest Management; Understory Changes; Carbon Sequestration -US-Akn,97938,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"Bldg 773-A Rm A-1009; Savannah River National Laboratory; Aiken, SC 29808" -US-Akn,97950,GRP_SITE_CHAR,TERRAIN,Flat -US-Akn,97950,GRP_SITE_CHAR,ASPECT,S -US-Akn,97950,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,2000 -US-Akn,97950,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,0 -US-Akn,97948,GRP_SITE_DESC,SITE_DESC,The site is characterized by a mix of pine and deciduous hardwood forests with a general canopy height of 25m which was established in the 1950s. Management of the forest around the site is performed by the USFS-Savannah River and consists of prescribed burning of the understory on a 3-4 year cycle. -US-Akn,97942,GRP_SITE_FUNDING,SITE_FUNDING,Savannah River National Laboratory -US-Akn,27193,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION,"Loose sand, sandy soils, clean sand, rounded quartz grains, very small amounts of fines (clays) near the surface decreasing downwards" -US-Akn,27193,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION_TAXONOMY,Other -US-Akn,22263,GRP_STATE,STATE,SC -US-Akn,97937,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Brian Viner -US-Akn,97937,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Akn,97937,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,brian.viner@srnl.doe.gov -US-Akn,97937,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Savannah River National Laboratory -US-Akn,97937,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Bldg 773-A Rm A-1009; Savannah River National Laboratory; Aiken, SC 29808" -US-Akn,97935,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Doug Aubrey -US-Akn,97935,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Affiliate -US-Akn,97935,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,daubrey@srel.uga.edu -US-Akn,97945,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Greg Starr -US-Akn,97945,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Affiliate -US-Akn,97945,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,gstarr@ua.edu -US-Akn,97934,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Monique Leclerc -US-Akn,97934,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Affiliate -US-Akn,97934,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,mleclerc@uga.edu -US-Akn,97934,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"University of Georgia, Deptartment of Crop and Soil Science, Lab for Biogeosciences" -US-Akn,97934,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"0260 Redding Building, 1109 Experiment Street,Griffin, GA 30223" -US-Akn,29861,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-Akn,22267,GRP_TOWER_TYPE,TOWER_TYPE,walk-up -US-Akn,97949,GRP_URL,URL,https://srnl.doe.gov/atg/index.html -US-Akn,24000507,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-Akn -US-Akn,97941,GRP_UTC_OFFSET,UTC_OFFSET,-5 -US-ALQ,83617,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfb -US-ALQ,27000981,GRP_COUNTRY,COUNTRY,USA -US-ALQ,85251,GRP_DOI,DOI,10.17190/AMF/1480323 -US-ALQ,85251,GRP_DOI,DOI_CITATION,"Brent Olson (2022), AmeriFlux BASE US-ALQ Allequash Creek Site, Ver. 9-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1480323" -US-ALQ,85251,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-ALQ,84788,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-ALQ,84788,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Brent Olson -US-ALQ,84788,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-ALQ,84788,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,bwolson@usgs.gov -US-ALQ,84788,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,USGS -US-ALQ,84799,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,USGS -US-ALQ,84799,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-ALQ,84798,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,USGS -US-ALQ,84798,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-ALQ,91372,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-ALQ,91372,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-ALQ,91372,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20150411 -US-ALQ,91372,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-ALQ,91457,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-ALQ,91457,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-ALQ,91457,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20150411 -US-ALQ,91457,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-ALQ,91333,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-ALQ,91333,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-ALQ,91333,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20150411 -US-ALQ,91333,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-ALQ,91415,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-ALQ,91415,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CH4 -US-ALQ,91415,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20181116 -US-ALQ,91415,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-ALQ,23000981,GRP_HEADER,SITE_NAME,Allequash Creek Site -US-ALQ,83476,GRP_IGBP,IGBP,WET -US-ALQ,83472,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-ALQ,83468,GRP_LOCATION,LOCATION_LAT,46.0308 -US-ALQ,83468,GRP_LOCATION,LOCATION_LONG,-89.6067 -US-ALQ,83468,GRP_LOCATION,LOCATION_DATE_START,20170424 -US-ALQ,83475,GRP_NETWORK,NETWORK,AmeriFlux -US-ALQ,1700005553,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Turner, J., Desai, A. R., Thom, J., Wickland, K. P., Olson, B. (2019) Wind Sheltering Impacts On Land-Atmosphere Fluxes Over Fens, Frontiers In Environmental Science, 7(), " -US-ALQ,1700005553,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.3389/FENVS.2019.00179 -US-ALQ,1700005553,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-ALQ,83470,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,Flux data processing -US-ALQ,83465,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"1225 W Dayton St, Madison, WI 53706" -US-ALQ,83479,GRP_SITE_DESC,SITE_DESC,This tower is located near Allequash creek in a wetland. -US-ALQ,95088,GRP_SITE_FUNDING,SITE_FUNDING,"DOE Ameriflux Network Management Project core site funding to ChEAS cluster, NSF DEB-1440297" -US-ALQ,83467,GRP_STATE,STATE,WI -US-ALQ,101448,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Ankur Desai -US-ALQ,101448,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-ALQ,101448,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,desai@aos.wisc.edu -US-ALQ,101448,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,U Wisconsin -US-ALQ,101448,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1225 W Dayton St, Madison, WI 53706" -US-ALQ,101447,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Jonathan Thom -US-ALQ,101447,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-ALQ,101447,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,jthom@ssec.wisc.edu -US-ALQ,101447,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Wisconsin-Madison -US-ALQ,83473,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-ALQ,83477,GRP_TOWER_TYPE,TOWER_TYPE,tripod -US-ALQ,83469,GRP_URL,URL,http://flux.aos.wisc.edu/twiki/bin/view/Main/LabData -US-ALQ,24000981,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-ALQ -US-ALQ,83466,GRP_UTC_OFFSET,UTC_OFFSET,-6 -US-An1,27000508,GRP_COUNTRY,COUNTRY,USA -US-An1,15712,GRP_DOI,DOI,10.17190/AMF/1246142 -US-An1,15712,GRP_DOI,DOI_CITATION,"Adrian Rocha, Gaius Shaver, John Hobbie (2020), AmeriFlux BASE US-An1 Anaktuvuk River Severe Burn, Ver. 2-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1246142" -US-An1,15712,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-An1,32345,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-An1,32345,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Adrian Rocha -US-An1,32345,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-An1,32345,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,arocha1@nd.edu -US-An1,32345,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of Notre Dame -US-An1,32344,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-An1,32344,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Gaius Shaver -US-An1,32344,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-An1,32344,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,gshaver@mbl.edu -US-An1,32344,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Marine Biological Laboratory -US-An1,32343,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-An1,32343,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,John Hobbie -US-An1,32343,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-An1,32343,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,jhobbie@mbl.edu -US-An1,32343,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Marine Biological Laboratory -US-An1,32347,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Marine Biological Laboratory -US-An1,32347,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-An1,32348,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,University of Notre Dame -US-An1,32348,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-An1,32346,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,NSF/NEON -US-An1,32346,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-An1,4978,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-An1,4978,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-An1,4978,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,2008 -US-An1,4978,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-An1,23000508,GRP_HEADER,SITE_NAME,Anaktuvuk River Severe Burn -US-An1,5891,GRP_IGBP,IGBP,OSH -US-An1,6598,GRP_LOCATION,LOCATION_LAT,68.9900 -US-An1,6598,GRP_LOCATION,LOCATION_LONG,-150.2800 -US-An1,6598,GRP_LOCATION,LOCATION_ELEV,600 -US-An1,6598,GRP_LOCATION,LOCATION_COMMENT,From CDIAC Tom Boden database dump -US-An1,10000,GRP_NETWORK,NETWORK,AmeriFlux -US-An1,3309,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"The research approach of the Arctic Long Term Ecological Research (LTER) project is to predict the future ecological characteristics of the site based upon existing knowledge of the controls of ecosystem structure and function as exerted by physical setting and geological factors, climatic factors, biotic factors, and the changes in fluxes of water and materials from land to water. Three towers were deployed along the Anaktuvuk River burn gradient to monitor post fire Net Ecosystem Exchange of CO2 (NEE): Severe Burn, Moderate Burn, and Unburned. The research focus of these stations is to characterize the effects of the Anaktuvuk River fire on climate forcing and vegetation recovery on the north slope of Alaska. This work will investigate fire-induced landscape heterogeneity in the Anaktuvuk River fire scar and its implications to scaling disturbances up to the region." -US-An1,4106,GRP_SITE_CHAR,TERRAIN,"Significant Slope (>5%, <10%)" -US-An1,5844,GRP_SITE_DESC,SITE_DESC,"The Anaktuvuk River fire on the North Slope of Alaska started on July 16, 2007 by lightning. It continued until the end of September when nearby lakes had already frozen over and burned >256,000 acres, creating a mosaic of patches that differed in burn severity. The Anaktuvuk River Severe Burn, Moderate Burn, and Unburned sites are 40 km to the west of the nearest road and were selected in late May 2008 to determine the effects of the fire on carbon, water, and energy exchanges during the growing season. Because the fire had burned through September of the previous year, initial deployment of flux towers occurred prior to any significant vegetative regrowth, and our sampling campaign captured the full growing season in 2008. The Severe Burn site consisted of a large area in which all of the green vegetation were consumed in the fire and some of the organic matter had burnt to the mineral soil in many places. A bear damaged the tower during the last week of August 2008, and it was repaired shortly after." -US-An1,8418,GRP_SITE_FUNDING,SITE_FUNDING,NSF/NEON -US-An1,28815,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION,Absent moss layer (<5%) with mineral soil (10%) -US-An1,28815,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION_TAXONOMY,Other -US-An1,9182,GRP_STATE,STATE,AK -US-An1,30720,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Adrian Rocha -US-An1,30720,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-An1,30720,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,arocha1@nd.edu -US-An1,30720,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Notre Dame -US-An1,30720,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"136 Galvin Life Science Center -University of Notre Dame -Notre Dame, IN 46556" -US-An1,98375,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Gaius Shaver -US-An1,98375,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Affiliate -US-An1,98375,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,gshaver@mbl.edu -US-An1,98375,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Marine Biological Laboratory -US-An1,98375,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"The Ecosystems Center, 7 MBL Street,Woods Hole, MA USA 02543" -US-An1,98356,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,John Hobbie -US-An1,98356,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Affiliate -US-An1,98356,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,jhobbie@mbl.edu -US-An1,98356,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Marine Biological Laboratory -US-An1,98356,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"The Ecosystems Center, 7 MBL Street,Woods Hole, MA USA 02543" -US-An1,24000508,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-An1 -US-An1,33612,GRP_UTC_OFFSET,UTC_OFFSET,-9 -US-An1,33612,GRP_UTC_OFFSET,UTC_OFFSET_COMMENT,Added by AMF data processing team for data QAQC checks. -US-An2,27000509,GRP_COUNTRY,COUNTRY,USA -US-An2,15635,GRP_DOI,DOI,10.17190/AMF/1246143 -US-An2,15635,GRP_DOI,DOI_CITATION,"Adrian Rocha, Gaius Shaver, John Hobbie (2020), AmeriFlux BASE US-An2 Anaktuvuk River Moderate Burn, Ver. 2-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1246143" -US-An2,15635,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-An2,32350,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-An2,32350,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Adrian Rocha -US-An2,32350,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-An2,32350,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,arocha1@nd.edu -US-An2,32350,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of Notre Dame -US-An2,32351,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-An2,32351,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Gaius Shaver -US-An2,32351,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-An2,32351,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,gshaver@mbl.edu -US-An2,32351,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Marine Biological Laboratory -US-An2,32349,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-An2,32349,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,John Hobbie -US-An2,32349,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-An2,32349,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,jhobbie@mbl.edu -US-An2,32349,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Marine Biological Laboratory -US-An2,32353,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Marine Biological Laboratory -US-An2,32353,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-An2,32354,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,University of Notre Dame -US-An2,32354,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-An2,32352,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,NSF/NEON -US-An2,32352,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-An2,8355,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-An2,8355,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-An2,8355,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,2008 -US-An2,8355,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-An2,23000509,GRP_HEADER,SITE_NAME,Anaktuvuk River Moderate Burn -US-An2,5892,GRP_IGBP,IGBP,OSH -US-An2,10003,GRP_LOCATION,LOCATION_LAT,68.9500 -US-An2,10003,GRP_LOCATION,LOCATION_LONG,-150.2100 -US-An2,10003,GRP_LOCATION,LOCATION_ELEV,600 -US-An2,10003,GRP_LOCATION,LOCATION_COMMENT,From CDIAC Tom Boden database dump -US-An2,10001,GRP_NETWORK,NETWORK,AmeriFlux -US-An2,10146,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"The research approach of the Arctic Long Term Ecological Research (LTER) project is to predict the future ecological characteristics of the site based upon existing knowledge of the controls of ecosystem structure and function as exerted by physical setting and geological factors, climatic factors, biotic factors, and the changes in fluxes of water and materials from land to water. Three towers were deployed along the Anaktuvuk River burn gradient to monitor post fire Net Ecosystem Exchange of CO2 (NEE): Severe Burn, Moderate Burn, and Unburned. The research focus of these stations is to characterize the effects of the Anaktuvuk River fire on climate forcing and vegetation recovery on the north slope of Alaska. This work will investigate fire-induced landscape heterogeneity in the Anaktuvuk River fire scar and its implications to scaling disturbances up to the region." -US-An2,1598,GRP_SITE_CHAR,TERRAIN,"Significant Slope (>5%, <10%)" -US-An2,5845,GRP_SITE_DESC,SITE_DESC,"The Anaktuvuk River fire on the North Slope of Alaska started on July 16, 2007 by lightning. It continued until the end of September when nearby lakes had already frozen over and burned >256,000 acres, creating a mosaic of patches that differed in burn severity. The Anaktuvuk River Severe Burn, Moderate Burn, and Unburned sites are 40 km to the west of the nearest road and were selected in late May 2008 to determine the effects of the fire on carbon, water, and energy exchanges during the growing season. Because the fire had burned through September of the previous year, initial deployment of flux towers occurred prior to any significant vegetative regrowth, and our sampling campaign captured the full growing season in 2008. The Moderate Burn site consisted of a large area with small patches of completely and partially burned tundra intermixed across the landscape." -US-An2,5017,GRP_SITE_FUNDING,SITE_FUNDING,NSF/NEON -US-An2,28436,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION,Absent moss layer (<5%) with mineral soil (10%) -US-An2,28436,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION_TAXONOMY,Other -US-An2,5764,GRP_STATE,STATE,AK -US-An2,30721,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Adrian Rocha -US-An2,30721,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-An2,30721,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,arocha1@nd.edu -US-An2,30721,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Notre Dame -US-An2,30721,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"136 Galvin Life Science Center -University of Notre Dame -Notre Dame, IN 46556" -US-An2,98369,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Gaius Shaver -US-An2,98369,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Affiliate -US-An2,98369,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,gshaver@mbl.edu -US-An2,98369,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Marine Biological Laboratory -US-An2,98369,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"The Ecosystems Center, 7 MBL Street,Woods Hole, MA USA 02543" -US-An2,98357,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,John Hobbie -US-An2,98357,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Affiliate -US-An2,98357,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,jhobbie@mbl.edu -US-An2,98357,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Marine Biological Laboratory -US-An2,98357,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"The Ecosystems Center, 7 MBL Street,Woods Hole, MA USA 02543" -US-An2,24000509,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-An2 -US-An2,33613,GRP_UTC_OFFSET,UTC_OFFSET,-9 -US-An2,33613,GRP_UTC_OFFSET,UTC_OFFSET_COMMENT,Added by AMF data processing team for data QAQC checks. -US-An3,27000510,GRP_COUNTRY,COUNTRY,USA -US-An3,15681,GRP_DOI,DOI,10.17190/AMF/1246144 -US-An3,15681,GRP_DOI,DOI_CITATION,"Adrian Rocha, Gaius Shaver, John Hobbie (2020), AmeriFlux BASE US-An3 Anaktuvuk River Unburned, Ver. 2-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1246144" -US-An3,15681,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-An3,32355,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-An3,32355,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Adrian Rocha -US-An3,32355,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-An3,32355,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,arocha1@nd.edu -US-An3,32355,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of Notre Dame -US-An3,32356,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-An3,32356,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Gaius Shaver -US-An3,32356,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-An3,32356,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,gshaver@mbl.edu -US-An3,32356,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Marine Biological Laboratory -US-An3,32357,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-An3,32357,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,John Hobbie -US-An3,32357,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-An3,32357,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,jhobbie@mbl.edu -US-An3,32357,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Marine Biological Laboratory -US-An3,32359,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Marine Biological Laboratory -US-An3,32359,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-An3,32360,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,University of Notre Dame -US-An3,32360,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-An3,32358,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,NSF/NEON -US-An3,32358,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-An3,9245,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-An3,9245,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-An3,9245,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,2008 -US-An3,9245,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-An3,23000510,GRP_HEADER,SITE_NAME,Anaktuvuk River Unburned -US-An3,6722,GRP_IGBP,IGBP,OSH -US-An3,7429,GRP_LOCATION,LOCATION_LAT,68.9300 -US-An3,7429,GRP_LOCATION,LOCATION_LONG,-150.2700 -US-An3,7429,GRP_LOCATION,LOCATION_ELEV,600 -US-An3,7429,GRP_LOCATION,LOCATION_COMMENT,From CDIAC Tom Boden database dump -US-An3,7424,GRP_NETWORK,NETWORK,AmeriFlux -US-An3,3296,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"The research approach of the Arctic Long Term Ecological Research (LTER) project is to predict the future ecological characteristics of the site based upon existing knowledge of the controls of ecosystem structure and function as exerted by physical setting and geological factors, climatic factors, biotic factors, and the changes in fluxes of water and materials from land to water. Three towers were deployed along the Anaktuvuk River burn gradient to monitor post fire Net Ecosystem Exchange of CO2 (NEE): Severe Burn, Moderate Burn, and Unburned. The research focus of these stations is to characterize the effects of the Anaktuvuk River fire on climate forcing and vegetation recovery on the north slope of Alaska. This work will investigate fire-induced landscape heterogeneity in the Anaktuvuk River fire scar and its implications to scaling disturbances up to the region." -US-An3,9293,GRP_SITE_CHAR,TERRAIN,"Significant Slope (>5%, <10%)" -US-An3,10127,GRP_SITE_DESC,SITE_DESC,"The Anaktuvuk River fire on the North Slope of Alaska started on July 16, 2007 by lightning. It continued until the end of September when nearby lakes had already frozen over and burned >256,000 acres, creating a mosaic of patches that differed in burn severity. The Anaktuvuk River Severe Burn, Moderate Burn, and Unburned sites are 40 km to the west of the nearest road and were selected in late May 2008 to determine the effects of the fire on carbon, water, and energy exchanges during the growing season. Because the fire had burned through September of the previous year, initial deployment of flux towers occurred prior to any significant vegetative regrowth, and our sampling campaign captured the full growing season in 2008. The Unburned site was located in a large area of tundra that was unaffected by the fire." -US-An3,9297,GRP_SITE_FUNDING,SITE_FUNDING,NSF/NEON -US-An3,29628,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION,Absent moss layer (<5%) with mineral soil (10%) -US-An3,29628,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION_TAXONOMY,Other -US-An3,6619,GRP_STATE,STATE,AK -US-An3,30722,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Adrian Rocha -US-An3,30722,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-An3,30722,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,arocha1@nd.edu -US-An3,30722,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Notre Dame -US-An3,30722,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"136 Galvin Life Science Center -University of Notre Dame -Notre Dame, IN 46556" -US-An3,98363,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Gaius Shaver -US-An3,98363,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Affiliate -US-An3,98363,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,gshaver@mbl.edu -US-An3,98363,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Marine Biological Laboratory -US-An3,98363,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"The Ecosystems Center, 7 MBL Street,Woods Hole, MA USA 02543" -US-An3,98372,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,John Hobbie -US-An3,98372,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Affiliate -US-An3,98372,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,jhobbie@mbl.edu -US-An3,98372,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Marine Biological Laboratory -US-An3,98372,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"The Ecosystems Center, 7 MBL Street,Woods Hole, MA USA 02543" -US-An3,24000510,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-An3 -US-An3,33614,GRP_UTC_OFFSET,UTC_OFFSET,-9 -US-An3,33614,GRP_UTC_OFFSET,UTC_OFFSET_COMMENT,Added by AMF data processing team for data QAQC checks. -US-AR1,15955,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dsa -US-AR1,27000503,GRP_COUNTRY,COUNTRY,USA -US-AR1,15705,GRP_DOI,DOI,10.17190/AMF/1246137 -US-AR1,15705,GRP_DOI,DOI_CITATION,"Dave Billesbach, James Bradford, Margaret Torn (2019), AmeriFlux BASE US-AR1 ARM USDA UNL OSU Woodward Switchgrass 1, Ver. 3-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1246137" -US-AR1,15705,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-AR1,32321,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-AR1,32321,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Dave Billesbach -US-AR1,32321,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-AR1,32321,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,dbillesbach1@unl.edu -US-AR1,32321,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of Nebraska -US-AR1,32320,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-AR1,32320,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,James Bradford -US-AR1,32320,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-AR1,32320,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,jim.bradford@ars.usda.gov -US-AR1,32320,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,U.S. Department of Agriculture -US-AR1,32322,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-AR1,32322,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Margaret Torn -US-AR1,32322,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-AR1,32322,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,mstorn@lbl.gov -US-AR1,32322,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Lawerence Berkeley National Lab -US-AR1,32325,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Lawerence Berkeley National Lab -US-AR1,32325,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-AR1,32326,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,U.S. Department of Agriculture -US-AR1,32326,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-AR1,32324,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,University of Nebraska -US-AR1,32324,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-AR1,32323,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,DOE/ASR -US-AR1,32323,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-AR1,15956,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Agriculture -US-AR1,92259,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-AR1,92259,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-AR1,92259,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20090430 -US-AR1,92259,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20120802 -US-AR1,92259,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-AR1,92259,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,Flux measurements were interrupted by a tornado in fall 2011. -US-AR1,92280,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-AR1,92280,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-AR1,92280,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20090430 -US-AR1,92280,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20120802 -US-AR1,92280,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-AR1,92237,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-AR1,92237,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-AR1,92237,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20090430 -US-AR1,92237,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20120802 -US-AR1,92237,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-AR1,23000503,GRP_HEADER,SITE_NAME,ARM USDA UNL OSU Woodward Switchgrass 1 -US-AR1,88239,GRP_HEIGHTC,HEIGHTC,0 -US-AR1,88239,GRP_HEIGHTC,HEIGHTC_STATISTIC,Minimum -US-AR1,88239,GRP_HEIGHTC,HEIGHTC_DATE,201004 -US-AR1,88239,GRP_HEIGHTC,HEIGHTC_COMMENT,Planting date -US-AR1,88238,GRP_HEIGHTC,HEIGHTC,0.5 -US-AR1,88238,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-AR1,88238,GRP_HEIGHTC,HEIGHTC_DATE,201105 -US-AR1,88238,GRP_HEIGHTC,HEIGHTC_COMMENT,Peak growth -US-AR1,15958,GRP_IGBP,IGBP,GRA -US-AR1,15958,GRP_IGBP,IGBP_DATE_START,20100408 -US-AR1,15958,GRP_IGBP,IGBP_COMMENT,Planted Switchgrass -US-AR1,15959,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-AR1,15959,GRP_LAND_OWNERSHIP,LAND_OWNER,USDA research station field -US-AR1,15960,GRP_LOCATION,LOCATION_LAT,36.4267 -US-AR1,15960,GRP_LOCATION,LOCATION_LONG,-99.4200 -US-AR1,15960,GRP_LOCATION,LOCATION_ELEV,611 -US-AR1,15960,GRP_LOCATION,LOCATION_COMMENT,From CDIAC Tom Boden database dump -US-AR1,15961,GRP_NETWORK,NETWORK,AmeriFlux -US-AR1,1700003978,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Baldocchi, D., Penuelas, J. (2018) The Physics And Ecology Of Mining Carbon Dioxide From The Atmosphere By Ecosystems, Global Change Biology, (), " -US-AR1,1700003978,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/GCB.14559 -US-AR1,1700003978,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-AR1,1700002805,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Baldocchi, D., Penuelas, J. (2018) The Physics And Ecology Of Mining Carbon Dioxide From The Atmosphere By Ecosystems, Global Change Biology, 301-302(7), 108350" -US-AR1,1700002805,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/GCB.14559 -US-AR1,1700002805,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-AR1,1700003096,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(7), 108350" -US-AR1,1700003096,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -US-AR1,1700003096,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-AR1,1700008655,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Sullivan, R. C., Cook, D. R., Ghate, V. P., Kotamarthi, V. R., Feng, Y. (2019) Improved Spatiotemporal Representativeness And Bias Reduction Of Satellite-Based Evapotranspiration Retrievals Via Use Of In Situ Meteorology And Constrained Canopy Surface Resistance, Journal Of Geophysical Research: Biogeosciences, 124(2), 342-352" -US-AR1,1700008655,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018JG004744 -US-AR1,1700008655,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-AR1,1700008259,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Sullivan, R. C., Kotamarthi, V. R., Feng, Y. (2019) Recovering Evapotranspiration Trends From Biased CMIP5 Simulations And Sensitivity To Changing Climate Over North America, Journal Of Hydrometeorology, 20(8), 1619-1633" -US-AR1,1700008259,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1175/JHM-D-18-0259.1 -US-AR1,1700008259,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-AR1,1700008949,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Zhang, Q., Ficklin, D. L., Manzoni, S., Wang, L., Way, D., Phillips, R. P., Novick, K. A. (2019) Response Of Ecosystem Intrinsic Water Use Efficiency And Gross Primary Productivity To Rising Vapor Pressure Deficit, Environmental Research Letters, 14(7), 074023" -US-AR1,1700008949,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1088/1748-9326/AB2603 -US-AR1,1700008949,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-AR1,15962,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,The research focus of the ARM USDA UNL OSU Woodward Switchgrass 1 site is to investigate the effects of land use conversion from mixed prairie and old world bluestern grass plots to switchgrass (a biofuel crop) production. -US-AR1,15963,GRP_SITE_CHAR,TERRAIN,"Medium Slope (>2 %, <5%)" -US-AR1,15963,GRP_SITE_CHAR,WIND_DIRECTION,S -US-AR1,15963,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,400 -US-AR1,15964,GRP_SITE_DESC,SITE_DESC,"The ARM USDA UNL OSU Woodward Switchgrass 1 tower is located on public land owned by the USDA-ARS Southern Plains Range Research Station in Woodward, Oklahoma. The site is on a former native prairie that is in the process of changing to switchgrass. A second companion site (ARM USDA UNL OSU Woodward Switchgrass 2) is on a former wheat field. In Spring 2009, the former native prairie site was burned, cattle were put on the pasture to graze down emergent grass, and broadleaf herbicide was sprayed. In Summer 2009, the cattle were removed from the pasture, and the site was sprayed with herbicide to kill all grass. In Spring 2010, prior to the planting of switchgrass, final herbicide was sprayed to kill cheat grass and to control broadleaf plants." -US-AR1,15965,GRP_SITE_FUNDING,SITE_FUNDING,DOE/ASR -US-AR1,27819,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION,"Loamy, mixed, Superactive, thermic, Shallow Typic Calciustepts" -US-AR1,27819,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION_TAXONOMY,Other -US-AR1,15966,GRP_STATE,STATE,OK -US-AR1,15967,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Dave Billesbach -US-AR1,15967,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-AR1,15967,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,dbillesbach1@unl.edu -US-AR1,15967,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Nebraska -US-AR1,15967,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Department of Biological Systems Engineering, 25 L.W. Chase Hall,Lincoln, NE USA 68583-0726" -US-AR1,15973,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Margaret Torn -US-AR1,15973,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-AR1,15973,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,mstorn@lbl.gov -US-AR1,15973,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Lawerence Berkeley National Lab -US-AR1,15973,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Earth Sciences Division, Lawrence Berkeley National Lab, 1 Cyclotron Road mail stop 84R0171, Berkeley, CA 94720" -US-AR1,15974,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Chris Zou -US-AR1,15974,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Affiliate -US-AR1,15974,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,chris.zou@okstate.edu -US-AR1,15974,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Oklahoma State University -US-AR1,15974,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Natural Resource Ecology and Management, 562 Ag Hall, 008C Ag Hall,Stillwater, OK USA 74077" -US-AR1,29859,GRP_TOWER_POWER,TOWER_POWER,Direct power -US-AR1,15968,GRP_TOWER_TYPE,TOWER_TYPE,tripod -US-AR1,15969,GRP_URL,URL,http://www.arm.gov/sites/sgp -US-AR1,24000503,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-AR1 -US-AR1,33615,GRP_UTC_OFFSET,UTC_OFFSET,-6 -US-AR1,33615,GRP_UTC_OFFSET,UTC_OFFSET_COMMENT,Added by AMF data processing team for data QAQC checks. -US-AR2,15975,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dsa -US-AR2,27000504,GRP_COUNTRY,COUNTRY,USA -US-AR2,15630,GRP_DOI,DOI,10.17190/AMF/1246138 -US-AR2,15630,GRP_DOI,DOI_CITATION,"Dave Billesbach, James Bradford, Margaret Torn (2019), AmeriFlux BASE US-AR2 ARM USDA UNL OSU Woodward Switchgrass 2, Ver. 3-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1246138" -US-AR2,15630,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-AR2,32328,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-AR2,32328,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Dave Billesbach -US-AR2,32328,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-AR2,32328,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,dbillesbach1@unl.edu -US-AR2,32328,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of Nebraska -US-AR2,32329,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-AR2,32329,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,James Bradford -US-AR2,32329,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-AR2,32329,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,jim.bradford@ars.usda.gov -US-AR2,32329,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,U.S. Department of Agriculture -US-AR2,32327,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-AR2,32327,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Margaret Torn -US-AR2,32327,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-AR2,32327,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,mstorn@lbl.gov -US-AR2,32327,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Lawrence Berkeley National Lab -US-AR2,32333,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Lawrence Berkeley National Lab -US-AR2,32333,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-AR2,32332,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,U.S. Department of Agriculture -US-AR2,32332,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-AR2,32331,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,University of Nebraska -US-AR2,32331,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-AR2,32330,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,DOE/ASR -US-AR2,32330,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-AR2,15976,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Agriculture -US-AR2,15977,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-AR2,15977,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-AR2,15977,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20090430 -US-AR2,15977,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20120802 -US-AR2,15977,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-AR2,15990,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-AR2,15990,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-AR2,15990,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20090430 -US-AR2,15990,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20120802 -US-AR2,15990,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-AR2,15992,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-AR2,15992,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-AR2,15992,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20090430 -US-AR2,15992,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20120802 -US-AR2,15992,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-AR2,23000504,GRP_HEADER,SITE_NAME,ARM USDA UNL OSU Woodward Switchgrass 2 -US-AR2,88364,GRP_HEIGHTC,HEIGHTC,0 -US-AR2,88364,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-AR2,88364,GRP_HEIGHTC,HEIGHTC_DATE,201004 -US-AR2,88364,GRP_HEIGHTC,HEIGHTC_COMMENT,Planting date -US-AR2,88365,GRP_HEIGHTC,HEIGHTC,0.5 -US-AR2,88365,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-AR2,88365,GRP_HEIGHTC,HEIGHTC_DATE,201105 -US-AR2,88365,GRP_HEIGHTC,HEIGHTC_COMMENT,Peak growth -US-AR2,15978,GRP_IGBP,IGBP,GRA -US-AR2,15978,GRP_IGBP,IGBP_DATE_START,20100408 -US-AR2,15978,GRP_IGBP,IGBP_COMMENT,Planted Switchgrass -US-AR2,15979,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-AR2,15979,GRP_LAND_OWNERSHIP,LAND_OWNER,USDA research station field -US-AR2,15980,GRP_LOCATION,LOCATION_LAT,36.6358 -US-AR2,15980,GRP_LOCATION,LOCATION_LONG,-99.5975 -US-AR2,15980,GRP_LOCATION,LOCATION_ELEV,646 -US-AR2,15980,GRP_LOCATION,LOCATION_COMMENT,From CDIAC Tom Boden database dump -US-AR2,15981,GRP_NETWORK,NETWORK,AmeriFlux -US-AR2,1700001872,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Baldocchi, D., Penuelas, J. (2018) The Physics And Ecology Of Mining Carbon Dioxide From The Atmosphere By Ecosystems, Global Change Biology, (), " -US-AR2,1700001872,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/GCB.14559 -US-AR2,1700001872,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-AR2,1700005055,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Baldocchi, D., Penuelas, J. (2018) The Physics And Ecology Of Mining Carbon Dioxide From The Atmosphere By Ecosystems, Global Change Biology, 301-302(7), 108350" -US-AR2,1700005055,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/GCB.14559 -US-AR2,1700005055,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-AR2,1700006531,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(7), 108350" -US-AR2,1700006531,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -US-AR2,1700006531,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-AR2,1700008262,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Sullivan, R. C., Cook, D. R., Ghate, V. P., Kotamarthi, V. R., Feng, Y. (2019) Improved Spatiotemporal Representativeness And Bias Reduction Of Satellite-Based Evapotranspiration Retrievals Via Use Of In Situ Meteorology And Constrained Canopy Surface Resistance, Journal Of Geophysical Research: Biogeosciences, 124(2), 342-352" -US-AR2,1700008262,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018JG004744 -US-AR2,1700008262,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-AR2,1700008901,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Sullivan, R. C., Kotamarthi, V. R., Feng, Y. (2019) Recovering Evapotranspiration Trends From Biased CMIP5 Simulations And Sensitivity To Changing Climate Over North America, Journal Of Hydrometeorology, 20(8), 1619-1633" -US-AR2,1700008901,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1175/JHM-D-18-0259.1 -US-AR2,1700008901,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-AR2,1700002505,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Zhang, Q., Ficklin, D. L., Manzoni, S., Wang, L., Way, D., Phillips, R. P., Novick, K. A. (2019) Response Of Ecosystem Intrinsic Water Use Efficiency And Gross Primary Productivity To Rising Vapor Pressure Deficit, Environmental Research Letters, 14(7), 074023" -US-AR2,1700002505,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1088/1748-9326/AB2603 -US-AR2,1700002505,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-AR2,15982,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,The research focus of the ARM USDA UNL OSU Woodward Switchgrass 2 site is to investigate the effects of land use conversion from winter wheat on marginal sandy soil to switchgrass (a biofuel crop) production. -US-AR2,15983,GRP_SITE_CHAR,TERRAIN,"Medium Slope (>2 %, <5%)" -US-AR2,15983,GRP_SITE_CHAR,WIND_DIRECTION,S -US-AR2,15983,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,400 -US-AR2,15984,GRP_SITE_DESC,SITE_DESC,"The ARM USDA UNL OSU Woodward Switchgrass 2 tower is located on public land owned by the USDA-ARS Southern Plains Range Research Station in Woodward, Oklahoma. The site is on a former wheat field that is in the process of changing to switchgrass. A companion site (ARM USDA UNL OSU Woodward Switchgrass 1) is on a former native prairie. Previous wheat was planted in Fall 2008. In Spring 2009, herbicide was applied to kill the wheat prior to switchgrass planting. Later in the year, the site was sprayed with post-emergence herbicide. In 2010, fertilization occurred before herbicide was sprayed for broadleaf control." -US-AR2,15985,GRP_SITE_FUNDING,SITE_FUNDING,DOE/ASR -US-AR2,29315,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION,"Mixed, thermic Lamellic Ustipsamments" -US-AR2,29315,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION_TAXONOMY,Other -US-AR2,15986,GRP_STATE,STATE,OK -US-AR2,15987,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Dave Billesbach -US-AR2,15987,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-AR2,15987,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,dbillesbach1@unl.edu -US-AR2,15987,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Nebraska -US-AR2,15987,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Department of Biological Systems Engineering, 157 L.W. Chase Hall,Lincoln, NE USA 68583-0726" -US-AR2,15993,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Margaret Torn -US-AR2,15993,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-AR2,15993,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,mstorn@lbl.gov -US-AR2,15993,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Lawrence Berkeley National Lab -US-AR2,15993,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Earth Sciences Division, Lawrence Berkeley National Lab, 1 Cyclotron Road mail stop 84R0171, Berkeley, CA 94720" -US-AR2,15994,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Chris Zou -US-AR2,15994,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Affiliate -US-AR2,15994,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,chris.zou@okstate.edu -US-AR2,15994,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Oklahoma State University -US-AR2,15994,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Natural Resource Ecology and Management, 562 Ag Hall, 008C Ag Hall,Stillwater, OK USA 74077" -US-AR2,29860,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-AR2,15988,GRP_TOWER_TYPE,TOWER_TYPE,tripod -US-AR2,15989,GRP_URL,URL,http://www.arm.gov/sites/sgp -US-AR2,24000504,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-AR2 -US-AR2,33616,GRP_UTC_OFFSET,UTC_OFFSET,-6 -US-AR2,33616,GRP_UTC_OFFSET,UTC_OFFSET_COMMENT,Added by AMF data processing team for data QAQC checks. -US-ARM,22343,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,This research was supported by the Office of Biological and Environmental Research of the US Department of Energy under contract No. DE-AC02-05CH11231 as part of the Atmospheric Radiation Measurement Program (ARM) -US-ARM,25131,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,0.41 -US-ARM,25131,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Total -US-ARM,25131,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-ARM,25131,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-ARM,25131,GRP_AG_BIOMASS_CROP,AG_BIOMASS_APPROACH,total AGB in 10 replicate 1m^2 plots along 400 m transect -US-ARM,25131,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20020530 -US-ARM,23719,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,0.51 -US-ARM,23719,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Total -US-ARM,23719,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-ARM,23719,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-ARM,23719,GRP_AG_BIOMASS_CROP,AG_BIOMASS_APPROACH,total AGB in 10 replicate 1m^2 plots along 400 m transect -US-ARM,23719,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20060530 -US-ARM,23977,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,0.88 -US-ARM,23977,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Total -US-ARM,23977,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-ARM,23977,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-ARM,23977,GRP_AG_BIOMASS_CROP,AG_BIOMASS_APPROACH,total AGB in 10 replicate 1m^2 plots along 400 m transect -US-ARM,23977,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20030530 -US-ARM,23898,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER,0.6 -US-ARM,23898,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_ORGAN,Total -US-ARM,23898,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_PHEN,Mixed/unknown -US-ARM,23898,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_UNIT,kgDM m-2 -US-ARM,23898,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_COMMENT,"0.41/ 0.88 / 0.51 -wheat 2002,2003,2006" -US-ARM,23958,GRP_BIOMASS_CHEM,BIOMASS_C,4.5 -US-ARM,25114,GRP_BIOMASS_CHEM,BIOMASS_C,4.5 -US-ARM,27811,GRP_BIOMASS_CHEM,BIOMASS_N,0.35 -US-ARM,27812,GRP_BIOMASS_CHEM,BIOMASS_N,0.36 -US-ARM,23958,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-ARM,25114,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-ARM,27811,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-ARM,27812,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-ARM,23958,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-ARM,25114,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-ARM,27811,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-ARM,27812,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-ARM,23958,GRP_BIOMASS_CHEM,BIOMASS_SPP,TRAE (NRCS plant code) -US-ARM,25114,GRP_BIOMASS_CHEM,BIOMASS_SPP,TRAE (NRCS plant code) -US-ARM,27811,GRP_BIOMASS_CHEM,BIOMASS_SPP,TRAE (NRCS plant code) -US-ARM,27812,GRP_BIOMASS_CHEM,BIOMASS_SPP,TRAE (NRCS plant code) -US-ARM,23958,GRP_BIOMASS_CHEM,BIOMASS_DATE,20030530 -US-ARM,27812,GRP_BIOMASS_CHEM,BIOMASS_DATE,20030530 -US-ARM,25114,GRP_BIOMASS_CHEM,BIOMASS_DATE,20040529 -US-ARM,27811,GRP_BIOMASS_CHEM,BIOMASS_DATE,20040529 -US-ARM,27811,GRP_BIOMASS_CHEM,BIOMASS_COMMENT,Email from mlfischer@lbl.gov. -US-ARM,27812,GRP_BIOMASS_CHEM,BIOMASS_COMMENT,Email from mlfischer@lbl.gov. -US-ARM,11127,GRP_CLIM_AVG,MAT,14.76 -US-ARM,11127,GRP_CLIM_AVG,MAP,843 -US-ARM,11127,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Cfa -US-ARM,27000331,GRP_COUNTRY,COUNTRY,USA -US-ARM,89327,GRP_DM_AGRICULTURE,DM_AGRICULTURE,Harvest -US-ARM,89327,GRP_DM_AGRICULTURE,DM_DATE,200206 -US-ARM,89327,GRP_DM_AGRICULTURE,DM_COMMENT,"harvest (winter wheat), yield was 34 bu per acre" -US-ARM,89309,GRP_DM_AGRICULTURE,DM_AGRICULTURE,Harvest -US-ARM,89309,GRP_DM_AGRICULTURE,DM_DATE,200306 -US-ARM,89309,GRP_DM_AGRICULTURE,DM_COMMENT,"harvest (winter wheat), yield was 42.4 bu per acre" -US-ARM,89341,GRP_DM_AGRICULTURE,DM_AGRICULTURE,Harvest -US-ARM,89341,GRP_DM_AGRICULTURE,DM_DATE,200406 -US-ARM,89341,GRP_DM_AGRICULTURE,DM_COMMENT,"harvest (winter wheat), yield was 34 bu per acre" -US-ARM,89326,GRP_DM_AGRICULTURE,DM_AGRICULTURE,Harvest -US-ARM,89326,GRP_DM_AGRICULTURE,DM_DATE,20051001 -US-ARM,89326,GRP_DM_AGRICULTURE,DM_COMMENT,"harvest (corn), yield was 26.12 bu per acre" -US-ARM,89319,GRP_DM_AGRICULTURE,DM_AGRICULTURE,Harvest -US-ARM,89319,GRP_DM_AGRICULTURE,DM_DATE,20060621 -US-ARM,89319,GRP_DM_AGRICULTURE,DM_COMMENT,"harvest, yield was 25.75 bu per acre" -US-ARM,89308,GRP_DM_AGRICULTURE,DM_AGRICULTURE,Harvest -US-ARM,89308,GRP_DM_AGRICULTURE,DM_DATE,20061110 -US-ARM,89308,GRP_DM_AGRICULTURE,DM_COMMENT,"harvest (soybean), yield was 5 bu per acre" -US-ARM,89352,GRP_DM_AGRICULTURE,DM_AGRICULTURE,Harvest -US-ARM,89352,GRP_DM_AGRICULTURE,DM_DATE,200707 -US-ARM,89352,GRP_DM_AGRICULTURE,DM_COMMENT,"Partial harvest (wheat), approx 20 bu per acre" -US-ARM,89397,GRP_DM_AGRICULTURE,DM_AGRICULTURE,Other -US-ARM,89397,GRP_DM_AGRICULTURE,DM_DATE,20070830 -US-ARM,89397,GRP_DM_AGRICULTURE,DM_COMMENT,Field swathed -US-ARM,89354,GRP_DM_AGRICULTURE,DM_AGRICULTURE,Other -US-ARM,89354,GRP_DM_AGRICULTURE,DM_DATE,20070906 -US-ARM,89354,GRP_DM_AGRICULTURE,DM_COMMENT,Field round baled (1000 lbs per acre hay yield) -US-ARM,89402,GRP_DM_AGRICULTURE,DM_AGRICULTURE,Harvest -US-ARM,89402,GRP_DM_AGRICULTURE,DM_DATE,20080925 -US-ARM,89402,GRP_DM_AGRICULTURE,DM_COMMENT,"harvest (corn), yield was 32.2 bu per acre" -US-ARM,89379,GRP_DM_AGRICULTURE,DM_AGRICULTURE,Harvest -US-ARM,89379,GRP_DM_AGRICULTURE,DM_DATE,20090618 -US-ARM,89379,GRP_DM_AGRICULTURE,DM_COMMENT,"harvest (wheat), yield was 25.1 bu per acre" -US-ARM,89401,GRP_DM_AGRICULTURE,DM_AGRICULTURE,Harvest -US-ARM,89401,GRP_DM_AGRICULTURE,DM_DATE,20100622 -US-ARM,89401,GRP_DM_AGRICULTURE,DM_COMMENT,"harvest (wheat), yield was 32.3 bu per acre" -US-ARM,89342,GRP_DM_AGRICULTURE,DM_AGRICULTURE,Harvest -US-ARM,89342,GRP_DM_AGRICULTURE,DM_DATE,20110615 -US-ARM,89342,GRP_DM_AGRICULTURE,DM_COMMENT,"harvest (canola), yield was 300 lbs per acre" -US-ARM,89410,GRP_DM_AGRICULTURE,DM_AGRICULTURE,Harvest -US-ARM,89410,GRP_DM_AGRICULTURE,DM_DATE,20120521 -US-ARM,89410,GRP_DM_AGRICULTURE,DM_COMMENT,"harvest (wheat), yield was 44 bu per acre" -US-ARM,89339,GRP_DM_AGRICULTURE,DM_AGRICULTURE,Harvest -US-ARM,89339,GRP_DM_AGRICULTURE,DM_DATE,20130621 -US-ARM,89339,GRP_DM_AGRICULTURE,DM_COMMENT,"harvest (wheat), yield was 43 bu per acre" -US-ARM,89357,GRP_DM_AGRICULTURE,DM_AGRICULTURE,Other -US-ARM,89357,GRP_DM_AGRICULTURE,DM_DATE,20130622 -US-ARM,89357,GRP_DM_AGRICULTURE,DM_COMMENT,wheat stubble windrowed and baled (unknown no. and weight) -US-ARM,89350,GRP_DM_AGRICULTURE,DM_AGRICULTURE,Harvest -US-ARM,89350,GRP_DM_AGRICULTURE,DM_DATE,20140607 -US-ARM,89350,GRP_DM_AGRICULTURE,DM_COMMENT,"harvest (wheat), yield was 7 bu per acre (north half of field)" -US-ARM,89314,GRP_DM_AGRICULTURE,DM_AGRICULTURE,Other -US-ARM,89314,GRP_DM_AGRICULTURE,DM_DATE_START,20140621 -US-ARM,89314,GRP_DM_AGRICULTURE,DM_DATE_END,20150915 -US-ARM,89314,GRP_DM_AGRICULTURE,DM_COMMENT,"Field was divided into three sections and management different, unclear records" -US-ARM,89405,GRP_DM_AGRICULTURE,DM_AGRICULTURE,Other -US-ARM,89405,GRP_DM_AGRICULTURE,DM_DATE,20160525 -US-ARM,89405,GRP_DM_AGRICULTURE,DM_COMMENT,alfalfa layed down -US-ARM,89408,GRP_DM_AGRICULTURE,DM_AGRICULTURE,Other -US-ARM,89408,GRP_DM_AGRICULTURE,DM_DATE,20160528 -US-ARM,89408,GRP_DM_AGRICULTURE,DM_COMMENT,alfalfa baled -US-ARM,89345,GRP_DM_AGRICULTURE,DM_AGRICULTURE,Other -US-ARM,89345,GRP_DM_AGRICULTURE,DM_DATE,20160709 -US-ARM,89345,GRP_DM_AGRICULTURE,DM_COMMENT,alfalfa layed down -US-ARM,89359,GRP_DM_AGRICULTURE,DM_AGRICULTURE,Other -US-ARM,89359,GRP_DM_AGRICULTURE,DM_DATE,20160716 -US-ARM,89359,GRP_DM_AGRICULTURE,DM_COMMENT,alfalfa baled -US-ARM,89347,GRP_DM_AGRICULTURE,DM_AGRICULTURE,Other -US-ARM,89347,GRP_DM_AGRICULTURE,DM_DATE,20160915 -US-ARM,89347,GRP_DM_AGRICULTURE,DM_COMMENT,alfalfa layed down -US-ARM,89346,GRP_DM_AGRICULTURE,DM_AGRICULTURE,Other -US-ARM,89346,GRP_DM_AGRICULTURE,DM_DATE,20160920 -US-ARM,89346,GRP_DM_AGRICULTURE,DM_COMMENT,alfalfa baled -US-ARM,89353,GRP_DM_AGRICULTURE,DM_AGRICULTURE,Other -US-ARM,89353,GRP_DM_AGRICULTURE,DM_DATE,20170506 -US-ARM,89353,GRP_DM_AGRICULTURE,DM_COMMENT,alfalfa layed down -US-ARM,89358,GRP_DM_AGRICULTURE,DM_AGRICULTURE,Other -US-ARM,89358,GRP_DM_AGRICULTURE,DM_DATE,20170507 -US-ARM,89358,GRP_DM_AGRICULTURE,DM_COMMENT,alfalfa swathed -US-ARM,89366,GRP_DM_AGRICULTURE,DM_AGRICULTURE,Other -US-ARM,89366,GRP_DM_AGRICULTURE,DM_DATE,20170508 -US-ARM,89366,GRP_DM_AGRICULTURE,DM_COMMENT,alfalfa baled -US-ARM,89306,GRP_DM_AGRICULTURE,DM_AGRICULTURE,Other -US-ARM,89306,GRP_DM_AGRICULTURE,DM_DATE,20170605 -US-ARM,89306,GRP_DM_AGRICULTURE,DM_COMMENT,alfalfa layed down and swathed -US-ARM,89348,GRP_DM_AGRICULTURE,DM_AGRICULTURE,Other -US-ARM,89348,GRP_DM_AGRICULTURE,DM_DATE,20170606 -US-ARM,89348,GRP_DM_AGRICULTURE,DM_COMMENT,alfalfa raked -US-ARM,89373,GRP_DM_AGRICULTURE,DM_AGRICULTURE,Other -US-ARM,89373,GRP_DM_AGRICULTURE,DM_DATE,20170607 -US-ARM,89373,GRP_DM_AGRICULTURE,DM_COMMENT,alfalfa baled -US-ARM,89386,GRP_DM_AGRICULTURE,DM_AGRICULTURE,Other -US-ARM,89386,GRP_DM_AGRICULTURE,DM_DATE,20170718 -US-ARM,89386,GRP_DM_AGRICULTURE,DM_COMMENT,alfalfa layed down -US-ARM,89392,GRP_DM_AGRICULTURE,DM_AGRICULTURE,Other -US-ARM,89392,GRP_DM_AGRICULTURE,DM_DATE,20170719 -US-ARM,89392,GRP_DM_AGRICULTURE,DM_COMMENT,alfalfa baled -US-ARM,89368,GRP_DM_AGRICULTURE,DM_AGRICULTURE,Other -US-ARM,89368,GRP_DM_AGRICULTURE,DM_DATE,20170912 -US-ARM,89368,GRP_DM_AGRICULTURE,DM_COMMENT,alfalfa layed down -US-ARM,89387,GRP_DM_AGRICULTURE,DM_AGRICULTURE,Other -US-ARM,89387,GRP_DM_AGRICULTURE,DM_DATE,20170920 -US-ARM,89387,GRP_DM_AGRICULTURE,DM_COMMENT,alfalfa swathed and baled -US-ARM,89320,GRP_DM_FERT_M,DM_FERT_M,Other -US-ARM,89320,GRP_DM_FERT_M,DM_DATE,20011002 -US-ARM,89320,GRP_DM_FERT_M,DM_COMMENT,100 lbs per acre (30-30-0) -US-ARM,89360,GRP_DM_FERT_M,DM_FERT_M,Other -US-ARM,89360,GRP_DM_FERT_M,DM_DATE,20020928 -US-ARM,89360,GRP_DM_FERT_M,DM_COMMENT,100 lbs per acre (30-0-0) -US-ARM,89388,GRP_DM_FERT_M,DM_FERT_M,Other -US-ARM,89388,GRP_DM_FERT_M,DM_DATE,20030115 -US-ARM,89388,GRP_DM_FERT_M,DM_COMMENT,70 lbs per acre (46-0-0) -US-ARM,89403,GRP_DM_FERT_M,DM_FERT_M,Other -US-ARM,89403,GRP_DM_FERT_M,DM_DATE,20030215 -US-ARM,89403,GRP_DM_FERT_M,DM_COMMENT,100 lbs per acre (28-0-0) -US-ARM,89349,GRP_DM_FERT_M,DM_FERT_M,Other -US-ARM,89349,GRP_DM_FERT_M,DM_DATE,20030321 -US-ARM,89349,GRP_DM_FERT_M,DM_COMMENT,143 lbs per acre (28-0-0) -US-ARM,89385,GRP_DM_FERT_M,DM_FERT_M,Other -US-ARM,89385,GRP_DM_FERT_M,DM_DATE,20030928 -US-ARM,89385,GRP_DM_FERT_M,DM_COMMENT,130 lbs per acre (30-30-0) -US-ARM,89362,GRP_DM_FERT_M,DM_FERT_M,Other -US-ARM,89362,GRP_DM_FERT_M,DM_DATE,20050331 -US-ARM,89362,GRP_DM_FERT_M,DM_COMMENT,20 lbs per acre N and P -US-ARM,89300,GRP_DM_FERT_M,DM_FERT_M,Other -US-ARM,89300,GRP_DM_FERT_M,DM_DATE,20050405 -US-ARM,89300,GRP_DM_FERT_M,DM_COMMENT,100 lbs per acre N -US-ARM,89377,GRP_DM_FERT_M,DM_FERT_M,Other -US-ARM,89377,GRP_DM_FERT_M,DM_DATE,20051026 -US-ARM,89377,GRP_DM_FERT_M,DM_COMMENT,30 lbs per acre N and P -US-ARM,89371,GRP_DM_FERT_M,DM_FERT_M,Other -US-ARM,89371,GRP_DM_FERT_M,DM_DATE,20060306 -US-ARM,89371,GRP_DM_FERT_M,DM_COMMENT,30 lbs per acre N -US-ARM,89396,GRP_DM_FERT_M,DM_FERT_M,Other -US-ARM,89396,GRP_DM_FERT_M,DM_DATE,20061114 -US-ARM,89396,GRP_DM_FERT_M,DM_COMMENT,60 lbs per acre (30-30-0) -US-ARM,89329,GRP_DM_FERT_M,DM_FERT_M,Other -US-ARM,89329,GRP_DM_FERT_M,DM_DATE,20070306 -US-ARM,89329,GRP_DM_FERT_M,DM_COMMENT,20 gallons per acre of (28-0-0) -US-ARM,89369,GRP_DM_FERT_M,DM_FERT_M,Other -US-ARM,89369,GRP_DM_FERT_M,DM_DATE,20080523 -US-ARM,89369,GRP_DM_FERT_M,DM_COMMENT,"25 gallons per acre of (24-8-0), approx 66 lbs per acre N and 22 lbs per acre P" -US-ARM,89355,GRP_DM_FERT_M,DM_FERT_M,Other -US-ARM,89355,GRP_DM_FERT_M,DM_DATE,20080928 -US-ARM,89355,GRP_DM_FERT_M,DM_COMMENT,27 lbs per acre N and 30 lbs per acre P -US-ARM,89302,GRP_DM_FERT_M,DM_FERT_M,Other -US-ARM,89302,GRP_DM_FERT_M,DM_DATE,20090317 -US-ARM,89302,GRP_DM_FERT_M,DM_COMMENT,"10 gallons per acre of (28-0-0), approx 30 lbs per acre N" -US-ARM,89303,GRP_DM_FERT_M,DM_FERT_M,Other -US-ARM,89303,GRP_DM_FERT_M,DM_DATE,20090409 -US-ARM,89303,GRP_DM_FERT_M,DM_COMMENT,"10 gallons per acre of (28-0-0), approx 30 lbs per acre N" -US-ARM,89344,GRP_DM_FERT_M,DM_FERT_M,Other -US-ARM,89344,GRP_DM_FERT_M,DM_DATE,20090928 -US-ARM,89344,GRP_DM_FERT_M,DM_COMMENT,"100 lbs per acre of NH3, approx 82 lbs per acre N" -US-ARM,89411,GRP_DM_FERT_M,DM_FERT_M,Other -US-ARM,89411,GRP_DM_FERT_M,DM_DATE,20090929 -US-ARM,89411,GRP_DM_FERT_M,DM_COMMENT,85 lbs per acre (18-46-0) -US-ARM,89322,GRP_DM_FERT_M,DM_FERT_M,Other -US-ARM,89322,GRP_DM_FERT_M,DM_DATE,20100126 -US-ARM,89322,GRP_DM_FERT_M,DM_COMMENT,"10 gallons per acre of (28-0-0), approx 30 lbs per acre N" -US-ARM,89315,GRP_DM_FERT_M,DM_FERT_M,Other -US-ARM,89315,GRP_DM_FERT_M,DM_DATE,20100408 -US-ARM,89315,GRP_DM_FERT_M,DM_COMMENT,"5 gallons per acre of (28-0-0), approx 15 lbs per acre N" -US-ARM,89414,GRP_DM_FERT_M,DM_FERT_M,Other -US-ARM,89414,GRP_DM_FERT_M,DM_DATE,20100914 -US-ARM,89414,GRP_DM_FERT_M,DM_COMMENT,"NH3 applied, approx 50 lbs per acre N" -US-ARM,89361,GRP_DM_FERT_M,DM_FERT_M,Other -US-ARM,89361,GRP_DM_FERT_M,DM_DATE,20111021 -US-ARM,89361,GRP_DM_FERT_M,DM_COMMENT,85 lbs per acre (11-52-0) -US-ARM,89304,GRP_DM_FERT_M,DM_FERT_M,Other -US-ARM,89304,GRP_DM_FERT_M,DM_DATE,20120303 -US-ARM,89304,GRP_DM_FERT_M,DM_COMMENT,15 gallons per acre (28-0-0) -US-ARM,89330,GRP_DM_FERT_M,DM_FERT_M,Other -US-ARM,89330,GRP_DM_FERT_M,DM_DATE,20130328 -US-ARM,89330,GRP_DM_FERT_M,DM_COMMENT,20 gallons per acre of (34-0-0) -US-ARM,89372,GRP_DM_FERT_M,DM_FERT_M,Other -US-ARM,89372,GRP_DM_FERT_M,DM_DATE,20130927 -US-ARM,89372,GRP_DM_FERT_M,DM_COMMENT,"NH3 applied, approx 60 lbs per acre N" -US-ARM,89324,GRP_DM_FERT_M,DM_FERT_M,Other -US-ARM,89324,GRP_DM_FERT_M,DM_DATE,20140310 -US-ARM,89324,GRP_DM_FERT_M,DM_COMMENT,"10 gallons per acre of (10-34-0), north half of field" -US-ARM,89391,GRP_DM_FERT_M,DM_FERT_M,Other -US-ARM,89391,GRP_DM_FERT_M,DM_DATE,20160719 -US-ARM,89391,GRP_DM_FERT_M,DM_COMMENT,"Mix of pot ash (150 lbs per acre K), and phosphate (50 lbs per acre P)" -US-ARM,89398,GRP_DM_GRAZE,DM_GRAZE,Cattle -US-ARM,89398,GRP_DM_GRAZE,DM_DATE_START,20130630 -US-ARM,89398,GRP_DM_GRAZE,DM_DATE_END,20130901 -US-ARM,89398,GRP_DM_GRAZE,DM_COMMENT,southern part of field only -US-ARM,89407,GRP_DM_GRAZE,DM_GRAZE,Cattle -US-ARM,89407,GRP_DM_GRAZE,DM_DATE_START,20140101 -US-ARM,89407,GRP_DM_GRAZE,DM_DATE_END,201403 -US-ARM,89407,GRP_DM_GRAZE,DM_COMMENT,southern part of field only -US-ARM,89370,GRP_DM_PESTICIDE,DM_PESTICIDE,Herbicide -US-ARM,89370,GRP_DM_PESTICIDE,DM_DATE,20011028 -US-ARM,89370,GRP_DM_PESTICIDE,DM_COMMENT,"Maverick, a herbicide" -US-ARM,89298,GRP_DM_PESTICIDE,DM_PESTICIDE,Herbicide -US-ARM,89298,GRP_DM_PESTICIDE,DM_DATE,20030321 -US-ARM,89298,GRP_DM_PESTICIDE,DM_COMMENT,"MCPA, broad leaf herbicide" -US-ARM,89301,GRP_DM_PESTICIDE,DM_PESTICIDE,Herbicide -US-ARM,89301,GRP_DM_PESTICIDE,DM_DATE,20050501 -US-ARM,89301,GRP_DM_PESTICIDE,DM_COMMENT,Roundup herbicide -US-ARM,89311,GRP_DM_PESTICIDE,DM_PESTICIDE,Herbicide -US-ARM,89311,GRP_DM_PESTICIDE,DM_DATE,20050612 -US-ARM,89311,GRP_DM_PESTICIDE,DM_COMMENT,Roundup herbicide -US-ARM,89384,GRP_DM_PESTICIDE,DM_PESTICIDE,Herbicide -US-ARM,89384,GRP_DM_PESTICIDE,DM_DATE,20060608 -US-ARM,89384,GRP_DM_PESTICIDE,DM_COMMENT,Roundup herbicide -US-ARM,89376,GRP_DM_PESTICIDE,DM_PESTICIDE,Herbicide -US-ARM,89376,GRP_DM_PESTICIDE,DM_DATE,20060913 -US-ARM,89376,GRP_DM_PESTICIDE,DM_COMMENT,Roundup herbicide -US-ARM,89323,GRP_DM_PESTICIDE,DM_PESTICIDE,Herbicide -US-ARM,89323,GRP_DM_PESTICIDE,DM_DATE,20070306 -US-ARM,89323,GRP_DM_PESTICIDE,DM_COMMENT,Amber herbicide -US-ARM,89332,GRP_DM_PESTICIDE,DM_PESTICIDE,Insecticide -US-ARM,89332,GRP_DM_PESTICIDE,DM_DATE,20070510 -US-ARM,89332,GRP_DM_PESTICIDE,DM_COMMENT,Karate insecticide -US-ARM,89336,GRP_DM_PESTICIDE,DM_PESTICIDE,Herbicide -US-ARM,89336,GRP_DM_PESTICIDE,DM_DATE,20070809 -US-ARM,89336,GRP_DM_PESTICIDE,DM_COMMENT,Roundup herbicide -US-ARM,89363,GRP_DM_PESTICIDE,DM_PESTICIDE,Herbicide -US-ARM,89363,GRP_DM_PESTICIDE,DM_DATE,20080517 -US-ARM,89363,GRP_DM_PESTICIDE,DM_COMMENT,Roundup herbicide (22 oz per acre) -US-ARM,89367,GRP_DM_PESTICIDE,DM_PESTICIDE,Other -US-ARM,89367,GRP_DM_PESTICIDE,DM_DATE,20080708 -US-ARM,89367,GRP_DM_PESTICIDE,DM_COMMENT,Known type or amount -US-ARM,89415,GRP_DM_PESTICIDE,DM_PESTICIDE,Herbicide -US-ARM,89415,GRP_DM_PESTICIDE,DM_DATE,20080723 -US-ARM,89415,GRP_DM_PESTICIDE,DM_COMMENT,Roundup herbicide (22 oz per acre) -US-ARM,89390,GRP_DM_PESTICIDE,DM_PESTICIDE,Other -US-ARM,89390,GRP_DM_PESTICIDE,DM_DATE,20090316 -US-ARM,89390,GRP_DM_PESTICIDE,DM_COMMENT,Herbicide and pesticide (Lorsban) applied -US-ARM,89400,GRP_DM_PESTICIDE,DM_PESTICIDE,Herbicide -US-ARM,89400,GRP_DM_PESTICIDE,DM_DATE,20100408 -US-ARM,89400,GRP_DM_PESTICIDE,DM_COMMENT,24D (4 oz per acre) and Affinity (0.8 oz per acre) applied -US-ARM,89380,GRP_DM_PESTICIDE,DM_PESTICIDE,Herbicide -US-ARM,89380,GRP_DM_PESTICIDE,DM_DATE,20110323 -US-ARM,89380,GRP_DM_PESTICIDE,DM_COMMENT,Roundup (22 oz per acre) and Warrior (2.5 oz per acre) applied -US-ARM,89297,GRP_DM_PESTICIDE,DM_PESTICIDE,Fungicide -US-ARM,89297,GRP_DM_PESTICIDE,DM_DATE,20130416 -US-ARM,89297,GRP_DM_PESTICIDE,DM_COMMENT,Unknown amount or type -US-ARM,89317,GRP_DM_PESTICIDE,DM_PESTICIDE,Herbicide -US-ARM,89317,GRP_DM_PESTICIDE,DM_DATE,20160527 -US-ARM,89317,GRP_DM_PESTICIDE,DM_COMMENT,Roundup herbicide -US-ARM,89356,GRP_DM_PESTICIDE,DM_PESTICIDE,Other -US-ARM,89356,GRP_DM_PESTICIDE,DM_DATE,20160703 -US-ARM,89356,GRP_DM_PESTICIDE,DM_COMMENT,sprayed (unknown type or amount) -US-ARM,89365,GRP_DM_PESTICIDE,DM_PESTICIDE,Insecticide -US-ARM,89365,GRP_DM_PESTICIDE,DM_DATE,20160813 -US-ARM,89365,GRP_DM_PESTICIDE,DM_COMMENT,Grizzly 2 insecticide (70 oz per acre) -US-ARM,89313,GRP_DM_PLANTING,DM_PLANTING,Sowing crop seeds -US-ARM,89313,GRP_DM_PLANTING,DM_DATE,20011002 -US-ARM,89313,GRP_DM_PLANTING,DM_COMMENT,"planted with Jaeger (hard red winter wheat), 90 lbs per acre" -US-ARM,89305,GRP_DM_PLANTING,DM_PLANTING,Sowing crop seeds -US-ARM,89305,GRP_DM_PLANTING,DM_DATE,20020928 -US-ARM,89305,GRP_DM_PLANTING,DM_COMMENT,"planted with Jaeger (hard red winter wheat), 90 lbs per acre" -US-ARM,89337,GRP_DM_PLANTING,DM_PLANTING,Sowing crop seeds -US-ARM,89337,GRP_DM_PLANTING,DM_DATE,20030928 -US-ARM,89337,GRP_DM_PLANTING,DM_COMMENT,"planted with Jaeger (hard red winter wheat), 90 lbs per acre" -US-ARM,89394,GRP_DM_PLANTING,DM_PLANTING,Sowing crop seeds -US-ARM,89394,GRP_DM_PLANTING,DM_DATE,20050331 -US-ARM,89394,GRP_DM_PLANTING,DM_COMMENT,planted with corn (23500 sees per acre) 30 inch spacing -US-ARM,89374,GRP_DM_PLANTING,DM_PLANTING,Sowing crop seeds -US-ARM,89374,GRP_DM_PLANTING,DM_DATE,20051026 -US-ARM,89374,GRP_DM_PLANTING,DM_COMMENT,"planted with Jagalene (winter wheat), 90 lbs per acre" -US-ARM,89340,GRP_DM_PLANTING,DM_PLANTING,Sowing crop seeds -US-ARM,89340,GRP_DM_PLANTING,DM_DATE,20060629 -US-ARM,89340,GRP_DM_PLANTING,DM_COMMENT,"planted with soybean, 123,500 seeds per acre" -US-ARM,89321,GRP_DM_PLANTING,DM_PLANTING,Sowing crop seeds -US-ARM,89321,GRP_DM_PLANTING,DM_DATE,20061114 -US-ARM,89321,GRP_DM_PLANTING,DM_COMMENT,"planted with wheat (Big Max), 100 lbs per acre" -US-ARM,89412,GRP_DM_PLANTING,DM_PLANTING,Sowing crop seeds -US-ARM,89412,GRP_DM_PLANTING,DM_DATE,20080428 -US-ARM,89412,GRP_DM_PLANTING,DM_COMMENT,"planted with corn (GH 113-day), 26,500 seeds per acre" -US-ARM,89318,GRP_DM_PLANTING,DM_PLANTING,Sowing crop seeds -US-ARM,89318,GRP_DM_PLANTING,DM_DATE,20080928 -US-ARM,89318,GRP_DM_PLANTING,DM_COMMENT,"planted with wheat (Fuller), 90 lbs per acre" -US-ARM,89383,GRP_DM_PLANTING,DM_PLANTING,Sowing crop seeds -US-ARM,89383,GRP_DM_PLANTING,DM_DATE,20090929 -US-ARM,89383,GRP_DM_PLANTING,DM_COMMENT,"planted wheat (Fuller), 100 lbs per acre" -US-ARM,89378,GRP_DM_PLANTING,DM_PLANTING,Sowing crop seeds -US-ARM,89378,GRP_DM_PLANTING,DM_DATE,20100928 -US-ARM,89378,GRP_DM_PLANTING,DM_COMMENT,"planted canola, 9.4 lbs per acre" -US-ARM,89351,GRP_DM_PLANTING,DM_PLANTING,Sowing crop seeds -US-ARM,89351,GRP_DM_PLANTING,DM_DATE,20111025 -US-ARM,89351,GRP_DM_PLANTING,DM_COMMENT,"planted wheat (Everest), 80 lbs per acre" -US-ARM,89325,GRP_DM_PLANTING,DM_PLANTING,Sowing crop seeds -US-ARM,89325,GRP_DM_PLANTING,DM_DATE,20120609 -US-ARM,89325,GRP_DM_PLANTING,DM_COMMENT,"planted (cowpeas), 14.7 lbs per acre" -US-ARM,89406,GRP_DM_PLANTING,DM_PLANTING,Sowing crop seeds -US-ARM,89406,GRP_DM_PLANTING,DM_DATE,20121010 -US-ARM,89406,GRP_DM_PLANTING,DM_COMMENT,"planted wheat (Everest), 75 lbs per acre" -US-ARM,89382,GRP_DM_PLANTING,DM_PLANTING,Sowing crop seeds -US-ARM,89382,GRP_DM_PLANTING,DM_DATE,20131025 -US-ARM,89382,GRP_DM_PLANTING,DM_COMMENT,"planted wheat (unknown type), 80 lbs per acre" -US-ARM,89299,GRP_DM_PLANTING,DM_PLANTING,Sowing crop seeds -US-ARM,89299,GRP_DM_PLANTING,DM_DATE,20150915 -US-ARM,89299,GRP_DM_PLANTING,DM_COMMENT,planted alfalfa -US-ARM,89333,GRP_DM_TILL,DM_TILL,Other -US-ARM,89333,GRP_DM_TILL,DM_DATE,20010810 -US-ARM,89333,GRP_DM_TILL,DM_COMMENT,disked (4 inch depth) -US-ARM,89404,GRP_DM_TILL,DM_TILL,Other -US-ARM,89404,GRP_DM_TILL,DM_DATE,20010910 -US-ARM,89404,GRP_DM_TILL,DM_COMMENT,disked (5 inch depth) -US-ARM,89364,GRP_DM_TILL,DM_TILL,Other -US-ARM,89364,GRP_DM_TILL,DM_DATE,20010929 -US-ARM,89364,GRP_DM_TILL,DM_COMMENT,cultivated (4 inch depth) -US-ARM,89375,GRP_DM_TILL,DM_TILL,Other -US-ARM,89375,GRP_DM_TILL,DM_DATE,20011001 -US-ARM,89375,GRP_DM_TILL,DM_COMMENT,harrowed (shallow depth) -US-ARM,89307,GRP_DM_TILL,DM_TILL,Other -US-ARM,89307,GRP_DM_TILL,DM_DATE,20020710 -US-ARM,89307,GRP_DM_TILL,DM_COMMENT,disked (4 inch depth) -US-ARM,89310,GRP_DM_TILL,DM_TILL,Other -US-ARM,89310,GRP_DM_TILL,DM_DATE,20020810 -US-ARM,89310,GRP_DM_TILL,DM_COMMENT,chiseled with 8 inch duck feet on 12 inch spacing -US-ARM,89316,GRP_DM_TILL,DM_TILL,Other -US-ARM,89316,GRP_DM_TILL,DM_DATE,20020910 -US-ARM,89316,GRP_DM_TILL,DM_COMMENT,chiseled to 3 inch on 12 inch spacing -US-ARM,89381,GRP_DM_TILL,DM_TILL,Other -US-ARM,89381,GRP_DM_TILL,DM_DATE,20020925 -US-ARM,89381,GRP_DM_TILL,DM_COMMENT,cultivated w flex harrow (3-4 inch depth) -US-ARM,89331,GRP_DM_TILL,DM_TILL,Other -US-ARM,89331,GRP_DM_TILL,DM_DATE,20030725 -US-ARM,89331,GRP_DM_TILL,DM_COMMENT,disked (3 inch depth) -US-ARM,89413,GRP_DM_TILL,DM_TILL,Other -US-ARM,89413,GRP_DM_TILL,DM_DATE,20030918 -US-ARM,89413,GRP_DM_TILL,DM_COMMENT,disked (4 inch depth) -US-ARM,89389,GRP_DM_TILL,DM_TILL,Other -US-ARM,89389,GRP_DM_TILL,DM_DATE,20030925 -US-ARM,89389,GRP_DM_TILL,DM_COMMENT,harrowed (2-3 inch depth) -US-ARM,89328,GRP_DM_TILL,DM_TILL,Other -US-ARM,89328,GRP_DM_TILL,DM_DATE,20090710 -US-ARM,89328,GRP_DM_TILL,DM_COMMENT,disked -US-ARM,89312,GRP_DM_TILL,DM_TILL,Other -US-ARM,89312,GRP_DM_TILL,DM_DATE,20090825 -US-ARM,89312,GRP_DM_TILL,DM_COMMENT,disked -US-ARM,89395,GRP_DM_TILL,DM_TILL,Other -US-ARM,89395,GRP_DM_TILL,DM_DATE,20090929 -US-ARM,89395,GRP_DM_TILL,DM_COMMENT,harrowed -US-ARM,89399,GRP_DM_TILL,DM_TILL,Other -US-ARM,89399,GRP_DM_TILL,DM_DATE,20100804 -US-ARM,89399,GRP_DM_TILL,DM_COMMENT,disked -US-ARM,89393,GRP_DM_TILL,DM_TILL,Other -US-ARM,89393,GRP_DM_TILL,DM_DATE,20100903 -US-ARM,89393,GRP_DM_TILL,DM_COMMENT,disked -US-ARM,89338,GRP_DM_TILL,DM_TILL,Other -US-ARM,89338,GRP_DM_TILL,DM_DATE,20110629 -US-ARM,89338,GRP_DM_TILL,DM_COMMENT,disked -US-ARM,89409,GRP_DM_TILL,DM_TILL,Other -US-ARM,89409,GRP_DM_TILL,DM_DATE,20110903 -US-ARM,89409,GRP_DM_TILL,DM_COMMENT,chiseled -US-ARM,89343,GRP_DM_TILL,DM_TILL,Other -US-ARM,89343,GRP_DM_TILL,DM_DATE,20111017 -US-ARM,89343,GRP_DM_TILL,DM_COMMENT,cultivated field -US-ARM,89335,GRP_DM_TILL,DM_TILL,Other -US-ARM,89335,GRP_DM_TILL,DM_DATE,20130921 -US-ARM,89335,GRP_DM_TILL,DM_COMMENT,disked -US-ARM,89334,GRP_DM_TILL,DM_TILL,Other -US-ARM,89334,GRP_DM_TILL,DM_DATE,20140621 -US-ARM,89334,GRP_DM_TILL,DM_COMMENT,disked -US-ARM,15755,GRP_DOI,DOI,10.17190/AMF/1246027 -US-ARM,15755,GRP_DOI,DOI_CITATION,"Sebastien Biraud, Marc Fischer, Stephen Chan, Margaret Torn (2021), AmeriFlux BASE US-ARM ARM Southern Great Plains site- Lamont, Ver. 11-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1246027" -US-ARM,15755,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-ARM,88158,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-ARM,88158,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Sebastien Biraud -US-ARM,88158,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-ARM,88158,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,1 -US-ARM,88158,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0001-7697-933X -US-ARM,88158,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,SCBiraud@lbl.gov -US-ARM,88158,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Lawrence Berkeley National Laboratory -US-ARM,88159,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-ARM,88159,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Marc Fischer -US-ARM,88159,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-ARM,88159,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,2 -US-ARM,88159,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,mlfischer@lbl.gov -US-ARM,88159,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Lawrence Berkeley National Laboratory -US-ARM,88159,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,2003 -US-ARM,88159,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_END,2013 -US-ARM,88160,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-ARM,88160,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Stephen Chan -US-ARM,88160,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-ARM,88160,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,2 -US-ARM,88160,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0002-4583-1559 -US-ARM,88160,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,swchan@lbl.gov -US-ARM,88160,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Lawrence Berkeley National Laboratory -US-ARM,88160,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,2015 -US-ARM,88161,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-ARM,88161,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Margaret Torn -US-ARM,88161,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-ARM,88161,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,3 -US-ARM,88161,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0002-8174-0099 -US-ARM,88161,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,mstorn@lbl.gov -US-ARM,88161,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Lawrence Berkeley National Laboratory -US-ARM,31949,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Lawrence Berkeley National Laboratory -US-ARM,31949,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-ARM,31948,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,DOE/ARM -US-ARM,31948,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-ARM,22334,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Agriculture -US-ARM,11129,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-ARM,11129,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-ARM,11129,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20021218 -US-ARM,11129,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-ARM,22345,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-ARM,22345,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-ARM,22345,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20021218 -US-ARM,22345,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-ARM,23000331,GRP_HEADER,SITE_NAME,ARM Southern Great Plains site- Lamont -US-ARM,89261,GRP_HEIGHTC,HEIGHTC,0 -US-ARM,89261,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-ARM,89261,GRP_HEIGHTC,HEIGHTC_DATE,20011002 -US-ARM,89261,GRP_HEIGHTC,HEIGHTC_COMMENT,planted with Jaeger (hard red winter wheat) -US-ARM,89222,GRP_HEIGHTC,HEIGHTC,0.4 -US-ARM,89222,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-ARM,89222,GRP_HEIGHTC,HEIGHTC_DATE,20020615 -US-ARM,89222,GRP_HEIGHTC,HEIGHTC_COMMENT,harvest (winter wheat) -US-ARM,89255,GRP_HEIGHTC,HEIGHTC,0 -US-ARM,89255,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-ARM,89255,GRP_HEIGHTC,HEIGHTC_DATE,20020616 -US-ARM,89255,GRP_HEIGHTC,HEIGHTC_COMMENT,wheat stubble -US-ARM,89254,GRP_HEIGHTC,HEIGHTC,0 -US-ARM,89254,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-ARM,89254,GRP_HEIGHTC,HEIGHTC_DATE,20020928 -US-ARM,89254,GRP_HEIGHTC,HEIGHTC_COMMENT,planted with Jaeger (hard red winter wheat) -US-ARM,89260,GRP_HEIGHTC,HEIGHTC,0.4 -US-ARM,89260,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-ARM,89260,GRP_HEIGHTC,HEIGHTC_DATE,20030725 -US-ARM,89260,GRP_HEIGHTC,HEIGHTC_COMMENT,harvest (winter wheat) -US-ARM,89221,GRP_HEIGHTC,HEIGHTC,0 -US-ARM,89221,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-ARM,89221,GRP_HEIGHTC,HEIGHTC_DATE,20030726 -US-ARM,89221,GRP_HEIGHTC,HEIGHTC_COMMENT,wheat stubble -US-ARM,89253,GRP_HEIGHTC,HEIGHTC,0 -US-ARM,89253,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-ARM,89253,GRP_HEIGHTC,HEIGHTC_DATE,20030928 -US-ARM,89253,GRP_HEIGHTC,HEIGHTC_COMMENT,planted with Jaeger (hard red winter wheat) -US-ARM,89226,GRP_HEIGHTC,HEIGHTC,0.4 -US-ARM,89226,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-ARM,89226,GRP_HEIGHTC,HEIGHTC_DATE,20040519 -US-ARM,89226,GRP_HEIGHTC,HEIGHTC_COMMENT,harvest (winter wheat) -US-ARM,89240,GRP_HEIGHTC,HEIGHTC,0 -US-ARM,89240,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-ARM,89240,GRP_HEIGHTC,HEIGHTC_DATE,20040520 -US-ARM,89240,GRP_HEIGHTC,HEIGHTC_COMMENT,wheat stubble -US-ARM,89247,GRP_HEIGHTC,HEIGHTC,0 -US-ARM,89247,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-ARM,89247,GRP_HEIGHTC,HEIGHTC_DATE,20050331 -US-ARM,89247,GRP_HEIGHTC,HEIGHTC_COMMENT,planted with corn (23500 sees per acre) 30 inch spacing -US-ARM,89223,GRP_HEIGHTC,HEIGHTC,2 -US-ARM,89223,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-ARM,89223,GRP_HEIGHTC,HEIGHTC_DATE,20051001 -US-ARM,89223,GRP_HEIGHTC,HEIGHTC_COMMENT,harvest (corn) -US-ARM,89219,GRP_HEIGHTC,HEIGHTC,0 -US-ARM,89219,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-ARM,89219,GRP_HEIGHTC,HEIGHTC_DATE,20051002 -US-ARM,89219,GRP_HEIGHTC,HEIGHTC_COMMENT,corn stubble -US-ARM,89224,GRP_HEIGHTC,HEIGHTC,0 -US-ARM,89224,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-ARM,89224,GRP_HEIGHTC,HEIGHTC_DATE,20051026 -US-ARM,89224,GRP_HEIGHTC,HEIGHTC_COMMENT,planted with Jagalene (winter wheat) -US-ARM,89262,GRP_HEIGHTC,HEIGHTC,0.4 -US-ARM,89262,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-ARM,89262,GRP_HEIGHTC,HEIGHTC_DATE,20060621 -US-ARM,89262,GRP_HEIGHTC,HEIGHTC_COMMENT,harvest -US-ARM,89251,GRP_HEIGHTC,HEIGHTC,0 -US-ARM,89251,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-ARM,89251,GRP_HEIGHTC,HEIGHTC_DATE,20060622 -US-ARM,89251,GRP_HEIGHTC,HEIGHTC_COMMENT,wheat stubble -US-ARM,89229,GRP_HEIGHTC,HEIGHTC,0 -US-ARM,89229,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-ARM,89229,GRP_HEIGHTC,HEIGHTC_DATE,20060629 -US-ARM,89229,GRP_HEIGHTC,HEIGHTC_COMMENT,planted with soybean -US-ARM,89246,GRP_HEIGHTC,HEIGHTC,0 -US-ARM,89246,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-ARM,89246,GRP_HEIGHTC,HEIGHTC_DATE,20061110 -US-ARM,89246,GRP_HEIGHTC,HEIGHTC_COMMENT,harvest (soybean) -US-ARM,89228,GRP_HEIGHTC,HEIGHTC,0 -US-ARM,89228,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-ARM,89228,GRP_HEIGHTC,HEIGHTC_DATE,20061111 -US-ARM,89228,GRP_HEIGHTC,HEIGHTC_COMMENT,bare ground -US-ARM,89235,GRP_HEIGHTC,HEIGHTC,0 -US-ARM,89235,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-ARM,89235,GRP_HEIGHTC,HEIGHTC_DATE,20061114 -US-ARM,89235,GRP_HEIGHTC,HEIGHTC_COMMENT,planted with wheat (Big Max) -US-ARM,89241,GRP_HEIGHTC,HEIGHTC,0.2 -US-ARM,89241,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-ARM,89241,GRP_HEIGHTC,HEIGHTC_DATE,20070707 -US-ARM,89241,GRP_HEIGHTC,HEIGHTC_COMMENT,Partial harvest (wheat) -US-ARM,89242,GRP_HEIGHTC,HEIGHTC,0 -US-ARM,89242,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-ARM,89242,GRP_HEIGHTC,HEIGHTC_DATE,20070708 -US-ARM,89242,GRP_HEIGHTC,HEIGHTC_COMMENT,wheat stubble -US-ARM,89250,GRP_HEIGHTC,HEIGHTC,0 -US-ARM,89250,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-ARM,89250,GRP_HEIGHTC,HEIGHTC_DATE,20080428 -US-ARM,89250,GRP_HEIGHTC,HEIGHTC_COMMENT,planted with corn (GH 113-day) -US-ARM,89231,GRP_HEIGHTC,HEIGHTC,2 -US-ARM,89231,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-ARM,89231,GRP_HEIGHTC,HEIGHTC_DATE,20080925 -US-ARM,89231,GRP_HEIGHTC,HEIGHTC_COMMENT,harvest (corn) -US-ARM,89225,GRP_HEIGHTC,HEIGHTC,0 -US-ARM,89225,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-ARM,89225,GRP_HEIGHTC,HEIGHTC_DATE,20080928 -US-ARM,89225,GRP_HEIGHTC,HEIGHTC_COMMENT,planted with wheat (Fuller) -US-ARM,89245,GRP_HEIGHTC,HEIGHTC,0.4 -US-ARM,89245,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-ARM,89245,GRP_HEIGHTC,HEIGHTC_DATE,20090618 -US-ARM,89245,GRP_HEIGHTC,HEIGHTC_COMMENT,harvest (wheat) -US-ARM,89239,GRP_HEIGHTC,HEIGHTC,0 -US-ARM,89239,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-ARM,89239,GRP_HEIGHTC,HEIGHTC_DATE,20090619 -US-ARM,89239,GRP_HEIGHTC,HEIGHTC_COMMENT,wheat stubble -US-ARM,89234,GRP_HEIGHTC,HEIGHTC,0 -US-ARM,89234,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-ARM,89234,GRP_HEIGHTC,HEIGHTC_DATE,20090926 -US-ARM,89234,GRP_HEIGHTC,HEIGHTC_COMMENT,corn stubble -US-ARM,89243,GRP_HEIGHTC,HEIGHTC,0 -US-ARM,89243,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-ARM,89243,GRP_HEIGHTC,HEIGHTC_DATE,20090929 -US-ARM,89243,GRP_HEIGHTC,HEIGHTC_COMMENT,planted wheat (Fuller) -US-ARM,89236,GRP_HEIGHTC,HEIGHTC,0.4 -US-ARM,89236,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-ARM,89236,GRP_HEIGHTC,HEIGHTC_DATE,20100622 -US-ARM,89236,GRP_HEIGHTC,HEIGHTC_COMMENT,harvest (wheat) -US-ARM,89248,GRP_HEIGHTC,HEIGHTC,0 -US-ARM,89248,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-ARM,89248,GRP_HEIGHTC,HEIGHTC_DATE,20100623 -US-ARM,89248,GRP_HEIGHTC,HEIGHTC_COMMENT,bare ground -US-ARM,89257,GRP_HEIGHTC,HEIGHTC,0 -US-ARM,89257,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-ARM,89257,GRP_HEIGHTC,HEIGHTC_DATE,20100928 -US-ARM,89257,GRP_HEIGHTC,HEIGHTC_COMMENT,planted canola -US-ARM,89227,GRP_HEIGHTC,HEIGHTC,0.4 -US-ARM,89227,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-ARM,89227,GRP_HEIGHTC,HEIGHTC_DATE,20110615 -US-ARM,89227,GRP_HEIGHTC,HEIGHTC_COMMENT,harvest (canola) -US-ARM,89244,GRP_HEIGHTC,HEIGHTC,0 -US-ARM,89244,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-ARM,89244,GRP_HEIGHTC,HEIGHTC_DATE,20110616 -US-ARM,89244,GRP_HEIGHTC,HEIGHTC_COMMENT,canola stubble -US-ARM,89220,GRP_HEIGHTC,HEIGHTC,0 -US-ARM,89220,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-ARM,89220,GRP_HEIGHTC,HEIGHTC_DATE,20111025 -US-ARM,89220,GRP_HEIGHTC,HEIGHTC_COMMENT,planted wheat (Everest) -US-ARM,89259,GRP_HEIGHTC,HEIGHTC,0.4 -US-ARM,89259,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-ARM,89259,GRP_HEIGHTC,HEIGHTC_DATE,20120521 -US-ARM,89259,GRP_HEIGHTC,HEIGHTC_COMMENT,harvest (wheat) -US-ARM,89249,GRP_HEIGHTC,HEIGHTC,0 -US-ARM,89249,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-ARM,89249,GRP_HEIGHTC,HEIGHTC_DATE,20120522 -US-ARM,89249,GRP_HEIGHTC,HEIGHTC_COMMENT,wheat stubble -US-ARM,89256,GRP_HEIGHTC,HEIGHTC,0 -US-ARM,89256,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-ARM,89256,GRP_HEIGHTC,HEIGHTC_DATE,20120609 -US-ARM,89256,GRP_HEIGHTC,HEIGHTC_COMMENT,planted (cowpeas) -US-ARM,89237,GRP_HEIGHTC,HEIGHTC,0 -US-ARM,89237,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-ARM,89237,GRP_HEIGHTC,HEIGHTC_DATE,20121010 -US-ARM,89237,GRP_HEIGHTC,HEIGHTC_COMMENT,planted wheat (Everest) -US-ARM,89252,GRP_HEIGHTC,HEIGHTC,0.4 -US-ARM,89252,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-ARM,89252,GRP_HEIGHTC,HEIGHTC_DATE,20130621 -US-ARM,89252,GRP_HEIGHTC,HEIGHTC_COMMENT,harvest (wheat) -US-ARM,89230,GRP_HEIGHTC,HEIGHTC,0 -US-ARM,89230,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-ARM,89230,GRP_HEIGHTC,HEIGHTC_DATE,20130622 -US-ARM,89230,GRP_HEIGHTC,HEIGHTC_COMMENT,wheat stubble -US-ARM,89218,GRP_HEIGHTC,HEIGHTC,0 -US-ARM,89218,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-ARM,89218,GRP_HEIGHTC,HEIGHTC_DATE,20131025 -US-ARM,89218,GRP_HEIGHTC,HEIGHTC_COMMENT,planted wheat (unknown type) -US-ARM,89238,GRP_HEIGHTC,HEIGHTC,0.4 -US-ARM,89238,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-ARM,89238,GRP_HEIGHTC,HEIGHTC_DATE,20140607 -US-ARM,89238,GRP_HEIGHTC,HEIGHTC_COMMENT,harvest (wheat) -US-ARM,89258,GRP_HEIGHTC,HEIGHTC,0 -US-ARM,89258,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-ARM,89258,GRP_HEIGHTC,HEIGHTC_DATE,20140608 -US-ARM,89258,GRP_HEIGHTC,HEIGHTC_COMMENT,wheat stubble -US-ARM,89232,GRP_HEIGHTC,HEIGHTC,0 -US-ARM,89232,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-ARM,89232,GRP_HEIGHTC,HEIGHTC_DATE,20150915 -US-ARM,89232,GRP_HEIGHTC,HEIGHTC_COMMENT,planted alfalfa -US-ARM,89233,GRP_HEIGHTC,HEIGHTC,0.4 -US-ARM,89233,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-ARM,89233,GRP_HEIGHTC,HEIGHTC_DATE,20160525 -US-ARM,89233,GRP_HEIGHTC,HEIGHTC_COMMENT,alfalfa layed down -US-ARM,11130,GRP_IGBP,IGBP,CRO -US-ARM,89595,GRP_LAI,LAI,0 -US-ARM,89595,GRP_LAI,LAI_TYPE,PAI -US-ARM,89595,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89595,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89595,GRP_LAI,LAI_STATISTIC,Standard Deviation -US-ARM,89595,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89595,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89595,GRP_LAI,LAI_DATE,20030130 -US-ARM,89595,GRP_LAI,LAI_COMMENT,wheat -US-ARM,89702,GRP_LAI,LAI,0 -US-ARM,89702,GRP_LAI,LAI_TYPE,PAI -US-ARM,89702,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89702,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89702,GRP_LAI,LAI_STATISTIC,Minimum -US-ARM,89702,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89702,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89702,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89702,GRP_LAI,LAI_DATE,20090605 -US-ARM,89702,GRP_LAI,LAI_COMMENT,wheat -US-ARM,89734,GRP_LAI,LAI,0 -US-ARM,89734,GRP_LAI,LAI_TYPE,PAI -US-ARM,89734,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89734,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89734,GRP_LAI,LAI_STATISTIC,Minimum -US-ARM,89734,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89734,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89734,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89734,GRP_LAI,LAI_DATE,20120516 -US-ARM,89734,GRP_LAI,LAI_COMMENT,wheat -US-ARM,89758,GRP_LAI,LAI,0 -US-ARM,89758,GRP_LAI,LAI_TYPE,PAI -US-ARM,89758,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89758,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89758,GRP_LAI,LAI_STATISTIC,Minimum -US-ARM,89758,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89758,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89758,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89758,GRP_LAI,LAI_DATE,20151118 -US-ARM,89758,GRP_LAI,LAI_COMMENT,Alfalfa -US-ARM,89591,GRP_LAI,LAI,0.1 -US-ARM,89591,GRP_LAI,LAI_TYPE,PAI -US-ARM,89591,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89591,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89591,GRP_LAI,LAI_STATISTIC,Standard Deviation -US-ARM,89591,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89591,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89591,GRP_LAI,LAI_DATE,20020502 -US-ARM,89591,GRP_LAI,LAI_COMMENT,wheat -US-ARM,89593,GRP_LAI,LAI,0.1 -US-ARM,89593,GRP_LAI,LAI_TYPE,PAI -US-ARM,89593,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89593,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89593,GRP_LAI,LAI_STATISTIC,Standard Deviation -US-ARM,89593,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89593,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89593,GRP_LAI,LAI_DATE,20020510 -US-ARM,89593,GRP_LAI,LAI_COMMENT,wheat -US-ARM,89597,GRP_LAI,LAI,0.1 -US-ARM,89597,GRP_LAI,LAI_TYPE,PAI -US-ARM,89597,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89597,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89597,GRP_LAI,LAI_STATISTIC,Standard Deviation -US-ARM,89597,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89597,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89597,GRP_LAI,LAI_DATE,20030220 -US-ARM,89597,GRP_LAI,LAI_COMMENT,wheat -US-ARM,89599,GRP_LAI,LAI,0.1 -US-ARM,89599,GRP_LAI,LAI_TYPE,PAI -US-ARM,89599,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89599,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89599,GRP_LAI,LAI_STATISTIC,Standard Deviation -US-ARM,89599,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89599,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89599,GRP_LAI,LAI_DATE,20030313 -US-ARM,89599,GRP_LAI,LAI_COMMENT,wheat -US-ARM,89609,GRP_LAI,LAI,0.1 -US-ARM,89609,GRP_LAI,LAI_TYPE,PAI -US-ARM,89609,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89609,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89609,GRP_LAI,LAI_STATISTIC,Standard Deviation -US-ARM,89609,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89609,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89609,GRP_LAI,LAI_DATE,20040316 -US-ARM,89609,GRP_LAI,LAI_COMMENT,wheat -US-ARM,89613,GRP_LAI,LAI,0.1 -US-ARM,89613,GRP_LAI,LAI_TYPE,PAI -US-ARM,89613,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89613,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89613,GRP_LAI,LAI_STATISTIC,Standard Deviation -US-ARM,89613,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89613,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89613,GRP_LAI,LAI_DATE,20040421 -US-ARM,89613,GRP_LAI,LAI_COMMENT,wheat -US-ARM,89806,GRP_LAI,LAI,0.1 -US-ARM,89806,GRP_LAI,LAI_TYPE,PAI -US-ARM,89806,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89806,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89806,GRP_LAI,LAI_STATISTIC,Minimum -US-ARM,89806,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89806,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89806,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89806,GRP_LAI,LAI_DATE,20160727 -US-ARM,89806,GRP_LAI,LAI_COMMENT,Alfalfa -US-ARM,89589,GRP_LAI,LAI,0.2 -US-ARM,89589,GRP_LAI,LAI_TYPE,PAI -US-ARM,89589,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89589,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89589,GRP_LAI,LAI_STATISTIC,Standard Deviation -US-ARM,89589,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89589,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89589,GRP_LAI,LAI_DATE,20020408 -US-ARM,89589,GRP_LAI,LAI_COMMENT,wheat -US-ARM,89605,GRP_LAI,LAI,0.2 -US-ARM,89605,GRP_LAI,LAI_TYPE,PAI -US-ARM,89605,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89605,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89605,GRP_LAI,LAI_STATISTIC,Standard Deviation -US-ARM,89605,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89605,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89605,GRP_LAI,LAI_DATE,20030507 -US-ARM,89605,GRP_LAI,LAI_COMMENT,wheat -US-ARM,89611,GRP_LAI,LAI,0.2 -US-ARM,89611,GRP_LAI,LAI_TYPE,PAI -US-ARM,89611,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89611,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89611,GRP_LAI,LAI_STATISTIC,Standard Deviation -US-ARM,89611,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89611,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89611,GRP_LAI,LAI_DATE,20040331 -US-ARM,89611,GRP_LAI,LAI_COMMENT,wheat -US-ARM,89614,GRP_LAI,LAI,0.2 -US-ARM,89614,GRP_LAI,LAI_TYPE,PAI -US-ARM,89614,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89614,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89614,GRP_LAI,LAI_STATISTIC,Minimum -US-ARM,89614,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89614,GRP_LAI,LAI_STATISTIC_NUMBER,20 -US-ARM,89614,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89614,GRP_LAI,LAI_DATE,20050525 -US-ARM,89614,GRP_LAI,LAI_COMMENT,corn -US-ARM,89618,GRP_LAI,LAI,0.2 -US-ARM,89618,GRP_LAI,LAI_TYPE,PAI -US-ARM,89618,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89618,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89618,GRP_LAI,LAI_STATISTIC,Minimum -US-ARM,89618,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89618,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89618,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89618,GRP_LAI,LAI_DATE,20050613 -US-ARM,89618,GRP_LAI,LAI_COMMENT,corn -US-ARM,89669,GRP_LAI,LAI,0.2 -US-ARM,89669,GRP_LAI,LAI_TYPE,PAI -US-ARM,89669,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89669,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89669,GRP_LAI,LAI_STATISTIC,Standard Deviation -US-ARM,89669,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89669,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89669,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89669,GRP_LAI,LAI_DATE,20070608 -US-ARM,89669,GRP_LAI,LAI_COMMENT,wheat -US-ARM,89689,GRP_LAI,LAI,0.2 -US-ARM,89689,GRP_LAI,LAI_TYPE,PAI -US-ARM,89689,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89689,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89689,GRP_LAI,LAI_STATISTIC,Standard Deviation -US-ARM,89689,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89689,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89689,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89689,GRP_LAI,LAI_DATE,20090316 -US-ARM,89689,GRP_LAI,LAI_COMMENT,wheat -US-ARM,89738,GRP_LAI,LAI,0.2 -US-ARM,89738,GRP_LAI,LAI_TYPE,PAI -US-ARM,89738,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89738,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89738,GRP_LAI,LAI_STATISTIC,Minimum -US-ARM,89738,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89738,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89738,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89738,GRP_LAI,LAI_DATE,20130422 -US-ARM,89738,GRP_LAI,LAI_COMMENT,wheat -US-ARM,89749,GRP_LAI,LAI,0.2 -US-ARM,89749,GRP_LAI,LAI_TYPE,PAI -US-ARM,89749,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89749,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89749,GRP_LAI,LAI_STATISTIC,Standard Deviation -US-ARM,89749,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89749,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89749,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89749,GRP_LAI,LAI_DATE,20150423 -US-ARM,89749,GRP_LAI,LAI_COMMENT,wheat -US-ARM,89793,GRP_LAI,LAI,0.2 -US-ARM,89793,GRP_LAI,LAI_TYPE,PAI -US-ARM,89793,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89793,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89793,GRP_LAI,LAI_STATISTIC,Standard Deviation -US-ARM,89793,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89793,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89793,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89793,GRP_LAI,LAI_DATE,20160603 -US-ARM,89793,GRP_LAI,LAI_COMMENT,Alfalfa -US-ARM,89805,GRP_LAI,LAI,0.2 -US-ARM,89805,GRP_LAI,LAI_TYPE,PAI -US-ARM,89805,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89805,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89805,GRP_LAI,LAI_STATISTIC,Standard Deviation -US-ARM,89805,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89805,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89805,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89805,GRP_LAI,LAI_DATE,20160712 -US-ARM,89805,GRP_LAI,LAI_COMMENT,Alfalfa -US-ARM,89809,GRP_LAI,LAI,0.2 -US-ARM,89809,GRP_LAI,LAI_TYPE,PAI -US-ARM,89809,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89809,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89809,GRP_LAI,LAI_STATISTIC,Standard Deviation -US-ARM,89809,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89809,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89809,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89809,GRP_LAI,LAI_DATE,20160727 -US-ARM,89809,GRP_LAI,LAI_COMMENT,Alfalfa -US-ARM,89893,GRP_LAI,LAI,0.2 -US-ARM,89893,GRP_LAI,LAI_TYPE,PAI -US-ARM,89893,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89893,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89893,GRP_LAI,LAI_STATISTIC,Standard Deviation -US-ARM,89893,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89893,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89893,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89893,GRP_LAI,LAI_DATE,20180614 -US-ARM,89893,GRP_LAI,LAI_COMMENT,Alfalfa -US-ARM,89905,GRP_LAI,LAI,0.2 -US-ARM,89905,GRP_LAI,LAI_TYPE,PAI -US-ARM,89905,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89905,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89905,GRP_LAI,LAI_STATISTIC,Standard Deviation -US-ARM,89905,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89905,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89905,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89905,GRP_LAI,LAI_DATE,20180827 -US-ARM,89905,GRP_LAI,LAI_COMMENT,Alfalfa -US-ARM,89929,GRP_LAI,LAI,0.2 -US-ARM,89929,GRP_LAI,LAI_TYPE,PAI -US-ARM,89929,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89929,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89929,GRP_LAI,LAI_STATISTIC,Standard Deviation -US-ARM,89929,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89929,GRP_LAI,LAI_STATISTIC_NUMBER,9 -US-ARM,89929,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89929,GRP_LAI,LAI_DATE,20190717 -US-ARM,89929,GRP_LAI,LAI_COMMENT,Alfalfa -US-ARM,89933,GRP_LAI,LAI,0.2 -US-ARM,89933,GRP_LAI,LAI_TYPE,PAI -US-ARM,89933,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89933,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89933,GRP_LAI,LAI_STATISTIC,Standard Deviation -US-ARM,89933,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89933,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89933,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89933,GRP_LAI,LAI_DATE,20190814 -US-ARM,89933,GRP_LAI,LAI_COMMENT,Alfalfa -US-ARM,89594,GRP_LAI,LAI,0.3 -US-ARM,89594,GRP_LAI,LAI_TYPE,PAI -US-ARM,89594,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89594,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89594,GRP_LAI,LAI_STATISTIC,Mean -US-ARM,89594,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89594,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89594,GRP_LAI,LAI_DATE,20030130 -US-ARM,89594,GRP_LAI,LAI_COMMENT,wheat -US-ARM,89601,GRP_LAI,LAI,0.3 -US-ARM,89601,GRP_LAI,LAI_TYPE,PAI -US-ARM,89601,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89601,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89601,GRP_LAI,LAI_STATISTIC,Standard Deviation -US-ARM,89601,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89601,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89601,GRP_LAI,LAI_DATE,20030327 -US-ARM,89601,GRP_LAI,LAI_COMMENT,wheat -US-ARM,89603,GRP_LAI,LAI,0.3 -US-ARM,89603,GRP_LAI,LAI_TYPE,PAI -US-ARM,89603,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89603,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89603,GRP_LAI,LAI_STATISTIC,Standard Deviation -US-ARM,89603,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89603,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89603,GRP_LAI,LAI_DATE,20030423 -US-ARM,89603,GRP_LAI,LAI_COMMENT,wheat -US-ARM,89607,GRP_LAI,LAI,0.3 -US-ARM,89607,GRP_LAI,LAI_TYPE,PAI -US-ARM,89607,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89607,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89607,GRP_LAI,LAI_STATISTIC,Standard Deviation -US-ARM,89607,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89607,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89607,GRP_LAI,LAI_DATE,20030528 -US-ARM,89607,GRP_LAI,LAI_COMMENT,wheat -US-ARM,89621,GRP_LAI,LAI,0.3 -US-ARM,89621,GRP_LAI,LAI_TYPE,PAI -US-ARM,89621,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89621,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89621,GRP_LAI,LAI_STATISTIC,Standard Deviation -US-ARM,89621,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89621,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89621,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89621,GRP_LAI,LAI_DATE,20050613 -US-ARM,89621,GRP_LAI,LAI_COMMENT,corn -US-ARM,89625,GRP_LAI,LAI,0.3 -US-ARM,89625,GRP_LAI,LAI_TYPE,PAI -US-ARM,89625,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89625,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89625,GRP_LAI,LAI_STATISTIC,Standard Deviation -US-ARM,89625,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89625,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89625,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89625,GRP_LAI,LAI_DATE,20050708 -US-ARM,89625,GRP_LAI,LAI_COMMENT,corn -US-ARM,89629,GRP_LAI,LAI,0.3 -US-ARM,89629,GRP_LAI,LAI_TYPE,PAI -US-ARM,89629,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89629,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89629,GRP_LAI,LAI_STATISTIC,Standard Deviation -US-ARM,89629,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89629,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89629,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89629,GRP_LAI,LAI_DATE,20050719 -US-ARM,89629,GRP_LAI,LAI_COMMENT,corn -US-ARM,89633,GRP_LAI,LAI,0.3 -US-ARM,89633,GRP_LAI,LAI_TYPE,PAI -US-ARM,89633,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89633,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89633,GRP_LAI,LAI_STATISTIC,Standard Deviation -US-ARM,89633,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89633,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89633,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89633,GRP_LAI,LAI_DATE,20050913 -US-ARM,89633,GRP_LAI,LAI_COMMENT,corn -US-ARM,89637,GRP_LAI,LAI,0.3 -US-ARM,89637,GRP_LAI,LAI_TYPE,PAI -US-ARM,89637,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89637,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89637,GRP_LAI,LAI_STATISTIC,Standard Deviation -US-ARM,89637,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89637,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89637,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89637,GRP_LAI,LAI_DATE,20060406 -US-ARM,89637,GRP_LAI,LAI_COMMENT,wheat -US-ARM,89693,GRP_LAI,LAI,0.3 -US-ARM,89693,GRP_LAI,LAI_TYPE,PAI -US-ARM,89693,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89693,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89693,GRP_LAI,LAI_STATISTIC,Standard Deviation -US-ARM,89693,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89693,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89693,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89693,GRP_LAI,LAI_DATE,20090401 -US-ARM,89693,GRP_LAI,LAI_COMMENT,wheat -US-ARM,89697,GRP_LAI,LAI,0.3 -US-ARM,89697,GRP_LAI,LAI_TYPE,PAI -US-ARM,89697,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89697,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89697,GRP_LAI,LAI_STATISTIC,Standard Deviation -US-ARM,89697,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89697,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89697,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89697,GRP_LAI,LAI_DATE,20090415 -US-ARM,89697,GRP_LAI,LAI_COMMENT,wheat -US-ARM,89753,GRP_LAI,LAI,0.3 -US-ARM,89753,GRP_LAI,LAI_TYPE,PAI -US-ARM,89753,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89753,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89753,GRP_LAI,LAI_STATISTIC,Standard Deviation -US-ARM,89753,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89753,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89753,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89753,GRP_LAI,LAI_DATE,20150519 -US-ARM,89753,GRP_LAI,LAI_COMMENT,wheat -US-ARM,89766,GRP_LAI,LAI,0.3 -US-ARM,89766,GRP_LAI,LAI_TYPE,PAI -US-ARM,89766,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89766,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89766,GRP_LAI,LAI_STATISTIC,Minimum -US-ARM,89766,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89766,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89766,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89766,GRP_LAI,LAI_DATE,20160402 -US-ARM,89766,GRP_LAI,LAI_COMMENT,Alfalfa -US-ARM,89797,GRP_LAI,LAI,0.3 -US-ARM,89797,GRP_LAI,LAI_TYPE,PAI -US-ARM,89797,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89797,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89797,GRP_LAI,LAI_STATISTIC,Standard Deviation -US-ARM,89797,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89797,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89797,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89797,GRP_LAI,LAI_DATE,20160618 -US-ARM,89797,GRP_LAI,LAI_COMMENT,Alfalfa -US-ARM,89798,GRP_LAI,LAI,0.3 -US-ARM,89798,GRP_LAI,LAI_TYPE,PAI -US-ARM,89798,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89798,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89798,GRP_LAI,LAI_STATISTIC,Minimum -US-ARM,89798,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89798,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89798,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89798,GRP_LAI,LAI_DATE,20160702 -US-ARM,89798,GRP_LAI,LAI_COMMENT,Alfalfa -US-ARM,89808,GRP_LAI,LAI,0.3 -US-ARM,89808,GRP_LAI,LAI_TYPE,PAI -US-ARM,89808,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89808,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89808,GRP_LAI,LAI_STATISTIC,Mean -US-ARM,89808,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89808,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89808,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89808,GRP_LAI,LAI_DATE,20160727 -US-ARM,89808,GRP_LAI,LAI_COMMENT,Alfalfa -US-ARM,89897,GRP_LAI,LAI,0.3 -US-ARM,89897,GRP_LAI,LAI_TYPE,PAI -US-ARM,89897,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89897,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89897,GRP_LAI,LAI_STATISTIC,Standard Deviation -US-ARM,89897,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89897,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89897,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89897,GRP_LAI,LAI_DATE,20180629 -US-ARM,89897,GRP_LAI,LAI_COMMENT,Alfalfa -US-ARM,89898,GRP_LAI,LAI,0.3 -US-ARM,89898,GRP_LAI,LAI_TYPE,PAI -US-ARM,89898,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89898,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89898,GRP_LAI,LAI_STATISTIC,Mean -US-ARM,89898,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89898,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89898,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89898,GRP_LAI,LAI_DATE,20180810 -US-ARM,89898,GRP_LAI,LAI_COMMENT,Alfalfa -US-ARM,89909,GRP_LAI,LAI,0.3 -US-ARM,89909,GRP_LAI,LAI_TYPE,PAI -US-ARM,89909,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89909,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89909,GRP_LAI,LAI_STATISTIC,Standard Deviation -US-ARM,89909,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89909,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89909,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89909,GRP_LAI,LAI_DATE,20180914 -US-ARM,89909,GRP_LAI,LAI_COMMENT,Alfalfa -US-ARM,89616,GRP_LAI,LAI,0.4 -US-ARM,89616,GRP_LAI,LAI_TYPE,PAI -US-ARM,89616,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89616,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89616,GRP_LAI,LAI_STATISTIC,Mean -US-ARM,89616,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89616,GRP_LAI,LAI_STATISTIC_NUMBER,20 -US-ARM,89616,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89616,GRP_LAI,LAI_DATE,20050525 -US-ARM,89616,GRP_LAI,LAI_COMMENT,corn -US-ARM,89617,GRP_LAI,LAI,0.4 -US-ARM,89617,GRP_LAI,LAI_TYPE,PAI -US-ARM,89617,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89617,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89617,GRP_LAI,LAI_STATISTIC,Standard Deviation -US-ARM,89617,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89617,GRP_LAI,LAI_STATISTIC_NUMBER,20 -US-ARM,89617,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89617,GRP_LAI,LAI_DATE,20050525 -US-ARM,89617,GRP_LAI,LAI_COMMENT,corn -US-ARM,89630,GRP_LAI,LAI,0.4 -US-ARM,89630,GRP_LAI,LAI_TYPE,PAI -US-ARM,89630,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89630,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89630,GRP_LAI,LAI_STATISTIC,Minimum -US-ARM,89630,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89630,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89630,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89630,GRP_LAI,LAI_DATE,20050913 -US-ARM,89630,GRP_LAI,LAI_COMMENT,corn -US-ARM,89641,GRP_LAI,LAI,0.4 -US-ARM,89641,GRP_LAI,LAI_TYPE,PAI -US-ARM,89641,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89641,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89641,GRP_LAI,LAI_STATISTIC,Standard Deviation -US-ARM,89641,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89641,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89641,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89641,GRP_LAI,LAI_DATE,20060427 -US-ARM,89641,GRP_LAI,LAI_COMMENT,wheat -US-ARM,89681,GRP_LAI,LAI,0.4 -US-ARM,89681,GRP_LAI,LAI_TYPE,PAI -US-ARM,89681,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89681,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89681,GRP_LAI,LAI_STATISTIC,Standard Deviation -US-ARM,89681,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89681,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89681,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89681,GRP_LAI,LAI_DATE,20080716 -US-ARM,89681,GRP_LAI,LAI_COMMENT,corn -US-ARM,89717,GRP_LAI,LAI,0.4 -US-ARM,89717,GRP_LAI,LAI_TYPE,PAI -US-ARM,89717,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89717,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89717,GRP_LAI,LAI_STATISTIC,Standard Deviation -US-ARM,89717,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89717,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89717,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89717,GRP_LAI,LAI_DATE,20100427 -US-ARM,89717,GRP_LAI,LAI_COMMENT,wheat -US-ARM,89722,GRP_LAI,LAI,0.4 -US-ARM,89722,GRP_LAI,LAI_TYPE,PAI -US-ARM,89722,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89722,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89722,GRP_LAI,LAI_STATISTIC,Minimum -US-ARM,89722,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89722,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89722,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89722,GRP_LAI,LAI_DATE,20120301 -US-ARM,89722,GRP_LAI,LAI_COMMENT,wheat -US-ARM,89765,GRP_LAI,LAI,0.4 -US-ARM,89765,GRP_LAI,LAI_TYPE,PAI -US-ARM,89765,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89765,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89765,GRP_LAI,LAI_STATISTIC,Standard Deviation -US-ARM,89765,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89765,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89765,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89765,GRP_LAI,LAI_DATE,20160317 -US-ARM,89765,GRP_LAI,LAI_COMMENT,Alfalfa -US-ARM,89770,GRP_LAI,LAI,0.4 -US-ARM,89770,GRP_LAI,LAI_TYPE,PAI -US-ARM,89770,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89770,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89770,GRP_LAI,LAI_STATISTIC,Minimum -US-ARM,89770,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89770,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89770,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89770,GRP_LAI,LAI_DATE,20160413 -US-ARM,89770,GRP_LAI,LAI_COMMENT,Alfalfa -US-ARM,89801,GRP_LAI,LAI,0.4 -US-ARM,89801,GRP_LAI,LAI_TYPE,PAI -US-ARM,89801,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89801,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89801,GRP_LAI,LAI_STATISTIC,Standard Deviation -US-ARM,89801,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89801,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89801,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89801,GRP_LAI,LAI_DATE,20160702 -US-ARM,89801,GRP_LAI,LAI_COMMENT,Alfalfa -US-ARM,89810,GRP_LAI,LAI,0.4 -US-ARM,89810,GRP_LAI,LAI_TYPE,PAI -US-ARM,89810,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89810,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89810,GRP_LAI,LAI_STATISTIC,Minimum -US-ARM,89810,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89810,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89810,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89810,GRP_LAI,LAI_DATE,20160812 -US-ARM,89810,GRP_LAI,LAI_COMMENT,Alfalfa -US-ARM,89814,GRP_LAI,LAI,0.4 -US-ARM,89814,GRP_LAI,LAI_TYPE,PAI -US-ARM,89814,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89814,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89814,GRP_LAI,LAI_STATISTIC,Minimum -US-ARM,89814,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89814,GRP_LAI,LAI_STATISTIC_NUMBER,8 -US-ARM,89814,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89814,GRP_LAI,LAI_DATE,20160827 -US-ARM,89814,GRP_LAI,LAI_COMMENT,Alfalfa -US-ARM,89817,GRP_LAI,LAI,0.4 -US-ARM,89817,GRP_LAI,LAI_TYPE,PAI -US-ARM,89817,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89817,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89817,GRP_LAI,LAI_STATISTIC,Standard Deviation -US-ARM,89817,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89817,GRP_LAI,LAI_STATISTIC_NUMBER,8 -US-ARM,89817,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89817,GRP_LAI,LAI_DATE,20160827 -US-ARM,89817,GRP_LAI,LAI_COMMENT,Alfalfa -US-ARM,89865,GRP_LAI,LAI,0.4 -US-ARM,89865,GRP_LAI,LAI_TYPE,PAI -US-ARM,89865,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89865,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89865,GRP_LAI,LAI_STATISTIC,Standard Deviation -US-ARM,89865,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89865,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89865,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89865,GRP_LAI,LAI_DATE,20170707 -US-ARM,89865,GRP_LAI,LAI_COMMENT,Alfalfa -US-ARM,89873,GRP_LAI,LAI,0.4 -US-ARM,89873,GRP_LAI,LAI_TYPE,PAI -US-ARM,89873,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89873,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89873,GRP_LAI,LAI_STATISTIC,Standard Deviation -US-ARM,89873,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89873,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89873,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89873,GRP_LAI,LAI_DATE,20170830 -US-ARM,89873,GRP_LAI,LAI_COMMENT,Alfalfa -US-ARM,89881,GRP_LAI,LAI,0.4 -US-ARM,89881,GRP_LAI,LAI_TYPE,PAI -US-ARM,89881,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89881,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89881,GRP_LAI,LAI_STATISTIC,Standard Deviation -US-ARM,89881,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89881,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89881,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89881,GRP_LAI,LAI_DATE,20180419 -US-ARM,89881,GRP_LAI,LAI_COMMENT,Alfalfa -US-ARM,89885,GRP_LAI,LAI,0.4 -US-ARM,89885,GRP_LAI,LAI_TYPE,PAI -US-ARM,89885,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89885,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89885,GRP_LAI,LAI_STATISTIC,Standard Deviation -US-ARM,89885,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89885,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89885,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89885,GRP_LAI,LAI_DATE,20180504 -US-ARM,89885,GRP_LAI,LAI_COMMENT,Alfalfa -US-ARM,89889,GRP_LAI,LAI,0.4 -US-ARM,89889,GRP_LAI,LAI_TYPE,PAI -US-ARM,89889,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89889,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89889,GRP_LAI,LAI_STATISTIC,Standard Deviation -US-ARM,89889,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89889,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89889,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89889,GRP_LAI,LAI_DATE,20180516 -US-ARM,89889,GRP_LAI,LAI_COMMENT,Alfalfa -US-ARM,89901,GRP_LAI,LAI,0.4 -US-ARM,89901,GRP_LAI,LAI_TYPE,PAI -US-ARM,89901,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89901,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89901,GRP_LAI,LAI_STATISTIC,Standard Deviation -US-ARM,89901,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89901,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89901,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89901,GRP_LAI,LAI_DATE,20180810 -US-ARM,89901,GRP_LAI,LAI_COMMENT,Alfalfa -US-ARM,89917,GRP_LAI,LAI,0.4 -US-ARM,89917,GRP_LAI,LAI_TYPE,PAI -US-ARM,89917,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89917,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89917,GRP_LAI,LAI_STATISTIC,Standard Deviation -US-ARM,89917,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89917,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89917,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89917,GRP_LAI,LAI_DATE,20190405 -US-ARM,89917,GRP_LAI,LAI_COMMENT,Alfalfa -US-ARM,89921,GRP_LAI,LAI,0.4 -US-ARM,89921,GRP_LAI,LAI_TYPE,PAI -US-ARM,89921,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89921,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89921,GRP_LAI,LAI_STATISTIC,Standard Deviation -US-ARM,89921,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89921,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89921,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89921,GRP_LAI,LAI_DATE,20190515 -US-ARM,89921,GRP_LAI,LAI_COMMENT,Alfalfa -US-ARM,89645,GRP_LAI,LAI,0.5 -US-ARM,89645,GRP_LAI,LAI_TYPE,PAI -US-ARM,89645,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89645,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89645,GRP_LAI,LAI_STATISTIC,Standard Deviation -US-ARM,89645,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89645,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89645,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89645,GRP_LAI,LAI_DATE,20060516 -US-ARM,89645,GRP_LAI,LAI_COMMENT,wheat -US-ARM,89649,GRP_LAI,LAI,0.5 -US-ARM,89649,GRP_LAI,LAI_TYPE,PAI -US-ARM,89649,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89649,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89649,GRP_LAI,LAI_STATISTIC,Standard Deviation -US-ARM,89649,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89649,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89649,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89649,GRP_LAI,LAI_DATE,20060606 -US-ARM,89649,GRP_LAI,LAI_COMMENT,wheat -US-ARM,89665,GRP_LAI,LAI,0.5 -US-ARM,89665,GRP_LAI,LAI_TYPE,PAI -US-ARM,89665,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89665,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89665,GRP_LAI,LAI_STATISTIC,Standard Deviation -US-ARM,89665,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89665,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89665,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89665,GRP_LAI,LAI_DATE,20070514 -US-ARM,89665,GRP_LAI,LAI_COMMENT,wheat -US-ARM,89670,GRP_LAI,LAI,0.5 -US-ARM,89670,GRP_LAI,LAI_TYPE,PAI -US-ARM,89670,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89670,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89670,GRP_LAI,LAI_STATISTIC,Minimum -US-ARM,89670,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89670,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89670,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89670,GRP_LAI,LAI_DATE,20080612 -US-ARM,89670,GRP_LAI,LAI_COMMENT,corn -US-ARM,89673,GRP_LAI,LAI,0.5 -US-ARM,89673,GRP_LAI,LAI_TYPE,PAI -US-ARM,89673,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89673,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89673,GRP_LAI,LAI_STATISTIC,Standard Deviation -US-ARM,89673,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89673,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89673,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89673,GRP_LAI,LAI_DATE,20080612 -US-ARM,89673,GRP_LAI,LAI_COMMENT,corn -US-ARM,89685,GRP_LAI,LAI,0.5 -US-ARM,89685,GRP_LAI,LAI_TYPE,PAI -US-ARM,89685,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89685,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89685,GRP_LAI,LAI_STATISTIC,Standard Deviation -US-ARM,89685,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89685,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89685,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89685,GRP_LAI,LAI_DATE,20080806 -US-ARM,89685,GRP_LAI,LAI_COMMENT,corn -US-ARM,89701,GRP_LAI,LAI,0.5 -US-ARM,89701,GRP_LAI,LAI_TYPE,PAI -US-ARM,89701,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89701,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89701,GRP_LAI,LAI_STATISTIC,Standard Deviation -US-ARM,89701,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89701,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89701,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89701,GRP_LAI,LAI_DATE,20090507 -US-ARM,89701,GRP_LAI,LAI_COMMENT,wheat -US-ARM,89725,GRP_LAI,LAI,0.5 -US-ARM,89725,GRP_LAI,LAI_TYPE,PAI -US-ARM,89725,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89725,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89725,GRP_LAI,LAI_STATISTIC,Standard Deviation -US-ARM,89725,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89725,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89725,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89725,GRP_LAI,LAI_DATE,20120301 -US-ARM,89725,GRP_LAI,LAI_COMMENT,wheat -US-ARM,89757,GRP_LAI,LAI,0.5 -US-ARM,89757,GRP_LAI,LAI_TYPE,PAI -US-ARM,89757,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89757,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89757,GRP_LAI,LAI_STATISTIC,Standard Deviation -US-ARM,89757,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89757,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89757,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89757,GRP_LAI,LAI_DATE,20150611 -US-ARM,89757,GRP_LAI,LAI_COMMENT,wheat -US-ARM,89760,GRP_LAI,LAI,0.5 -US-ARM,89760,GRP_LAI,LAI_TYPE,PAI -US-ARM,89760,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89760,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89760,GRP_LAI,LAI_STATISTIC,Mean -US-ARM,89760,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89760,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89760,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89760,GRP_LAI,LAI_DATE,20151118 -US-ARM,89760,GRP_LAI,LAI_COMMENT,Alfalfa -US-ARM,89769,GRP_LAI,LAI,0.5 -US-ARM,89769,GRP_LAI,LAI_TYPE,PAI -US-ARM,89769,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89769,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89769,GRP_LAI,LAI_STATISTIC,Standard Deviation -US-ARM,89769,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89769,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89769,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89769,GRP_LAI,LAI_DATE,20160402 -US-ARM,89769,GRP_LAI,LAI_COMMENT,Alfalfa -US-ARM,89773,GRP_LAI,LAI,0.5 -US-ARM,89773,GRP_LAI,LAI_TYPE,PAI -US-ARM,89773,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89773,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89773,GRP_LAI,LAI_STATISTIC,Standard Deviation -US-ARM,89773,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89773,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89773,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89773,GRP_LAI,LAI_DATE,20160413 -US-ARM,89773,GRP_LAI,LAI_COMMENT,Alfalfa -US-ARM,89790,GRP_LAI,LAI,0.5 -US-ARM,89790,GRP_LAI,LAI_TYPE,PAI -US-ARM,89790,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89790,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89790,GRP_LAI,LAI_STATISTIC,Minimum -US-ARM,89790,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89790,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89790,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89790,GRP_LAI,LAI_DATE,20160603 -US-ARM,89790,GRP_LAI,LAI_COMMENT,Alfalfa -US-ARM,89825,GRP_LAI,LAI,0.5 -US-ARM,89825,GRP_LAI,LAI_TYPE,PAI -US-ARM,89825,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89825,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89825,GRP_LAI,LAI_STATISTIC,Standard Deviation -US-ARM,89825,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89825,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89825,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89825,GRP_LAI,LAI_DATE,20161012 -US-ARM,89825,GRP_LAI,LAI_COMMENT,Alfalfa -US-ARM,89837,GRP_LAI,LAI,0.5 -US-ARM,89837,GRP_LAI,LAI_TYPE,PAI -US-ARM,89837,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89837,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89837,GRP_LAI,LAI_STATISTIC,Standard Deviation -US-ARM,89837,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89837,GRP_LAI,LAI_STATISTIC_NUMBER,8 -US-ARM,89837,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89837,GRP_LAI,LAI_DATE,20161119 -US-ARM,89837,GRP_LAI,LAI_COMMENT,Alfalfa -US-ARM,89841,GRP_LAI,LAI,0.5 -US-ARM,89841,GRP_LAI,LAI_TYPE,PAI -US-ARM,89841,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89841,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89841,GRP_LAI,LAI_STATISTIC,Standard Deviation -US-ARM,89841,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89841,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89841,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89841,GRP_LAI,LAI_DATE,20170317 -US-ARM,89841,GRP_LAI,LAI_COMMENT,Alfalfa -US-ARM,89853,GRP_LAI,LAI,0.5 -US-ARM,89853,GRP_LAI,LAI_TYPE,PAI -US-ARM,89853,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89853,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89853,GRP_LAI,LAI_STATISTIC,Standard Deviation -US-ARM,89853,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89853,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89853,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89853,GRP_LAI,LAI_DATE,20170502 -US-ARM,89853,GRP_LAI,LAI_COMMENT,Alfalfa -US-ARM,89857,GRP_LAI,LAI,0.5 -US-ARM,89857,GRP_LAI,LAI_TYPE,PAI -US-ARM,89857,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89857,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89857,GRP_LAI,LAI_STATISTIC,Standard Deviation -US-ARM,89857,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89857,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89857,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89857,GRP_LAI,LAI_DATE,20170509 -US-ARM,89857,GRP_LAI,LAI_COMMENT,Alfalfa -US-ARM,89861,GRP_LAI,LAI,0.5 -US-ARM,89861,GRP_LAI,LAI_TYPE,PAI -US-ARM,89861,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89861,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89861,GRP_LAI,LAI_STATISTIC,Standard Deviation -US-ARM,89861,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89861,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89861,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89861,GRP_LAI,LAI_DATE,20170601 -US-ARM,89861,GRP_LAI,LAI_COMMENT,Alfalfa -US-ARM,89869,GRP_LAI,LAI,0.5 -US-ARM,89869,GRP_LAI,LAI_TYPE,PAI -US-ARM,89869,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89869,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89869,GRP_LAI,LAI_STATISTIC,Standard Deviation -US-ARM,89869,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89869,GRP_LAI,LAI_STATISTIC_NUMBER,9 -US-ARM,89869,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89869,GRP_LAI,LAI_DATE,20170718 -US-ARM,89869,GRP_LAI,LAI_COMMENT,Alfalfa -US-ARM,89902,GRP_LAI,LAI,0.5 -US-ARM,89902,GRP_LAI,LAI_TYPE,PAI -US-ARM,89902,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89902,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89902,GRP_LAI,LAI_STATISTIC,Mean -US-ARM,89902,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89902,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89902,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89902,GRP_LAI,LAI_DATE,20180827 -US-ARM,89902,GRP_LAI,LAI_COMMENT,Alfalfa -US-ARM,89913,GRP_LAI,LAI,0.5 -US-ARM,89913,GRP_LAI,LAI_TYPE,PAI -US-ARM,89913,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89913,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89913,GRP_LAI,LAI_STATISTIC,Standard Deviation -US-ARM,89913,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89913,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89913,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89913,GRP_LAI,LAI_DATE,20180928 -US-ARM,89913,GRP_LAI,LAI_COMMENT,Alfalfa -US-ARM,89925,GRP_LAI,LAI,0.5 -US-ARM,89925,GRP_LAI,LAI_TYPE,PAI -US-ARM,89925,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89925,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89925,GRP_LAI,LAI_STATISTIC,Standard Deviation -US-ARM,89925,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89925,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89925,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89925,GRP_LAI,LAI_DATE,20190613 -US-ARM,89925,GRP_LAI,LAI_COMMENT,Alfalfa -US-ARM,89596,GRP_LAI,LAI,0.6 -US-ARM,89596,GRP_LAI,LAI_TYPE,PAI -US-ARM,89596,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89596,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89596,GRP_LAI,LAI_STATISTIC,Mean -US-ARM,89596,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89596,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89596,GRP_LAI,LAI_DATE,20030220 -US-ARM,89596,GRP_LAI,LAI_COMMENT,wheat -US-ARM,89615,GRP_LAI,LAI,0.6 -US-ARM,89615,GRP_LAI,LAI_TYPE,PAI -US-ARM,89615,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89615,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89615,GRP_LAI,LAI_STATISTIC,Maximum -US-ARM,89615,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89615,GRP_LAI,LAI_STATISTIC_NUMBER,20 -US-ARM,89615,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89615,GRP_LAI,LAI_DATE,20050525 -US-ARM,89615,GRP_LAI,LAI_COMMENT,corn -US-ARM,89620,GRP_LAI,LAI,0.6 -US-ARM,89620,GRP_LAI,LAI_TYPE,PAI -US-ARM,89620,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89620,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89620,GRP_LAI,LAI_STATISTIC,Mean -US-ARM,89620,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89620,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89620,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89620,GRP_LAI,LAI_DATE,20050613 -US-ARM,89620,GRP_LAI,LAI_COMMENT,corn -US-ARM,89661,GRP_LAI,LAI,0.6 -US-ARM,89661,GRP_LAI,LAI_TYPE,PAI -US-ARM,89661,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89661,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89661,GRP_LAI,LAI_STATISTIC,Standard Deviation -US-ARM,89661,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89661,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89661,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89661,GRP_LAI,LAI_DATE,20070427 -US-ARM,89661,GRP_LAI,LAI_COMMENT,wheat -US-ARM,89705,GRP_LAI,LAI,0.6 -US-ARM,89705,GRP_LAI,LAI_TYPE,PAI -US-ARM,89705,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89705,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89705,GRP_LAI,LAI_STATISTIC,Standard Deviation -US-ARM,89705,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89705,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89705,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89705,GRP_LAI,LAI_DATE,20090605 -US-ARM,89705,GRP_LAI,LAI_COMMENT,wheat -US-ARM,89709,GRP_LAI,LAI,0.6 -US-ARM,89709,GRP_LAI,LAI_TYPE,PAI -US-ARM,89709,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89709,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89709,GRP_LAI,LAI_STATISTIC,Standard Deviation -US-ARM,89709,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89709,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89709,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89709,GRP_LAI,LAI_DATE,20100316 -US-ARM,89709,GRP_LAI,LAI_COMMENT,wheat -US-ARM,89721,GRP_LAI,LAI,0.6 -US-ARM,89721,GRP_LAI,LAI_TYPE,PAI -US-ARM,89721,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89721,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89721,GRP_LAI,LAI_STATISTIC,Standard Deviation -US-ARM,89721,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89721,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89721,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89721,GRP_LAI,LAI_DATE,20100511 -US-ARM,89721,GRP_LAI,LAI_COMMENT,wheat -US-ARM,89761,GRP_LAI,LAI,0.6 -US-ARM,89761,GRP_LAI,LAI_TYPE,PAI -US-ARM,89761,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89761,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89761,GRP_LAI,LAI_STATISTIC,Standard Deviation -US-ARM,89761,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89761,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89761,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89761,GRP_LAI,LAI_DATE,20151118 -US-ARM,89761,GRP_LAI,LAI_COMMENT,Alfalfa -US-ARM,89762,GRP_LAI,LAI,0.6 -US-ARM,89762,GRP_LAI,LAI_TYPE,PAI -US-ARM,89762,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89762,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89762,GRP_LAI,LAI_STATISTIC,Minimum -US-ARM,89762,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89762,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89762,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89762,GRP_LAI,LAI_DATE,20160317 -US-ARM,89762,GRP_LAI,LAI_COMMENT,Alfalfa -US-ARM,89802,GRP_LAI,LAI,0.6 -US-ARM,89802,GRP_LAI,LAI_TYPE,PAI -US-ARM,89802,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89802,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89802,GRP_LAI,LAI_STATISTIC,Minimum -US-ARM,89802,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89802,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89802,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89802,GRP_LAI,LAI_DATE,20160712 -US-ARM,89802,GRP_LAI,LAI_COMMENT,Alfalfa -US-ARM,89818,GRP_LAI,LAI,0.6 -US-ARM,89818,GRP_LAI,LAI_TYPE,PAI -US-ARM,89818,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89818,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89818,GRP_LAI,LAI_STATISTIC,Minimum -US-ARM,89818,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89818,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89818,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89818,GRP_LAI,LAI_DATE,20160909 -US-ARM,89818,GRP_LAI,LAI_COMMENT,Alfalfa -US-ARM,89833,GRP_LAI,LAI,0.6 -US-ARM,89833,GRP_LAI,LAI_TYPE,PAI -US-ARM,89833,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89833,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89833,GRP_LAI,LAI_STATISTIC,Standard Deviation -US-ARM,89833,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89833,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89833,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89833,GRP_LAI,LAI_DATE,20161105 -US-ARM,89833,GRP_LAI,LAI_COMMENT,Alfalfa -US-ARM,89834,GRP_LAI,LAI,0.6 -US-ARM,89834,GRP_LAI,LAI_TYPE,PAI -US-ARM,89834,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89834,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89834,GRP_LAI,LAI_STATISTIC,Minimum -US-ARM,89834,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89834,GRP_LAI,LAI_STATISTIC_NUMBER,8 -US-ARM,89834,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89834,GRP_LAI,LAI_DATE,20161119 -US-ARM,89834,GRP_LAI,LAI_COMMENT,Alfalfa -US-ARM,89849,GRP_LAI,LAI,0.6 -US-ARM,89849,GRP_LAI,LAI_TYPE,PAI -US-ARM,89849,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89849,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89849,GRP_LAI,LAI_STATISTIC,Standard Deviation -US-ARM,89849,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89849,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89849,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89849,GRP_LAI,LAI_DATE,20170410 -US-ARM,89849,GRP_LAI,LAI_COMMENT,Alfalfa -US-ARM,89926,GRP_LAI,LAI,0.6 -US-ARM,89926,GRP_LAI,LAI_TYPE,PAI -US-ARM,89926,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89926,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89926,GRP_LAI,LAI_STATISTIC,Mean -US-ARM,89926,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89926,GRP_LAI,LAI_STATISTIC_NUMBER,9 -US-ARM,89926,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89926,GRP_LAI,LAI_DATE,20190717 -US-ARM,89926,GRP_LAI,LAI_COMMENT,Alfalfa -US-ARM,89632,GRP_LAI,LAI,0.7 -US-ARM,89632,GRP_LAI,LAI_TYPE,PAI -US-ARM,89632,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89632,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89632,GRP_LAI,LAI_STATISTIC,Mean -US-ARM,89632,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89632,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89632,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89632,GRP_LAI,LAI_DATE,20050913 -US-ARM,89632,GRP_LAI,LAI_COMMENT,corn -US-ARM,89657,GRP_LAI,LAI,0.7 -US-ARM,89657,GRP_LAI,LAI_TYPE,PAI -US-ARM,89657,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89657,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89657,GRP_LAI,LAI_STATISTIC,Standard Deviation -US-ARM,89657,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89657,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89657,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89657,GRP_LAI,LAI_DATE,20070416 -US-ARM,89657,GRP_LAI,LAI_COMMENT,wheat -US-ARM,89686,GRP_LAI,LAI,0.7 -US-ARM,89686,GRP_LAI,LAI_TYPE,PAI -US-ARM,89686,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89686,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89686,GRP_LAI,LAI_STATISTIC,Minimum -US-ARM,89686,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89686,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89686,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89686,GRP_LAI,LAI_DATE,20090316 -US-ARM,89686,GRP_LAI,LAI_COMMENT,wheat -US-ARM,89733,GRP_LAI,LAI,0.7 -US-ARM,89733,GRP_LAI,LAI_TYPE,PAI -US-ARM,89733,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89733,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89733,GRP_LAI,LAI_STATISTIC,Standard Deviation -US-ARM,89733,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89733,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89733,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89733,GRP_LAI,LAI_DATE,20120405 -US-ARM,89733,GRP_LAI,LAI_COMMENT,wheat -US-ARM,89741,GRP_LAI,LAI,0.7 -US-ARM,89741,GRP_LAI,LAI_TYPE,PAI -US-ARM,89741,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89741,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89741,GRP_LAI,LAI_STATISTIC,Standard Deviation -US-ARM,89741,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89741,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89741,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89741,GRP_LAI,LAI_DATE,20130422 -US-ARM,89741,GRP_LAI,LAI_COMMENT,wheat -US-ARM,89746,GRP_LAI,LAI,0.7 -US-ARM,89746,GRP_LAI,LAI_TYPE,PAI -US-ARM,89746,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89746,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89746,GRP_LAI,LAI_STATISTIC,Minimum -US-ARM,89746,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89746,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89746,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89746,GRP_LAI,LAI_DATE,20150423 -US-ARM,89746,GRP_LAI,LAI_COMMENT,wheat -US-ARM,89781,GRP_LAI,LAI,0.7 -US-ARM,89781,GRP_LAI,LAI_TYPE,PAI -US-ARM,89781,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89781,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89781,GRP_LAI,LAI_STATISTIC,Standard Deviation -US-ARM,89781,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89781,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89781,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89781,GRP_LAI,LAI_DATE,20160511 -US-ARM,89781,GRP_LAI,LAI_COMMENT,Alfalfa -US-ARM,89807,GRP_LAI,LAI,0.7 -US-ARM,89807,GRP_LAI,LAI_TYPE,PAI -US-ARM,89807,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89807,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89807,GRP_LAI,LAI_STATISTIC,Maximum -US-ARM,89807,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89807,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89807,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89807,GRP_LAI,LAI_DATE,20160727 -US-ARM,89807,GRP_LAI,LAI_COMMENT,Alfalfa -US-ARM,89821,GRP_LAI,LAI,0.7 -US-ARM,89821,GRP_LAI,LAI_TYPE,PAI -US-ARM,89821,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89821,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89821,GRP_LAI,LAI_STATISTIC,Standard Deviation -US-ARM,89821,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89821,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89821,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89821,GRP_LAI,LAI_DATE,20160909 -US-ARM,89821,GRP_LAI,LAI_COMMENT,Alfalfa -US-ARM,89845,GRP_LAI,LAI,0.7 -US-ARM,89845,GRP_LAI,LAI_TYPE,PAI -US-ARM,89845,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89845,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89845,GRP_LAI,LAI_STATISTIC,Standard Deviation -US-ARM,89845,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89845,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89845,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89845,GRP_LAI,LAI_DATE,20170406 -US-ARM,89845,GRP_LAI,LAI_COMMENT,Alfalfa -US-ARM,89626,GRP_LAI,LAI,0.8 -US-ARM,89626,GRP_LAI,LAI_TYPE,PAI -US-ARM,89626,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89626,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89626,GRP_LAI,LAI_STATISTIC,Minimum -US-ARM,89626,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89626,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89626,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89626,GRP_LAI,LAI_DATE,20050719 -US-ARM,89626,GRP_LAI,LAI_COMMENT,corn -US-ARM,89653,GRP_LAI,LAI,0.8 -US-ARM,89653,GRP_LAI,LAI_TYPE,PAI -US-ARM,89653,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89653,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89653,GRP_LAI,LAI_STATISTIC,Standard Deviation -US-ARM,89653,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89653,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89653,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89653,GRP_LAI,LAI_DATE,20070328 -US-ARM,89653,GRP_LAI,LAI_COMMENT,wheat -US-ARM,89677,GRP_LAI,LAI,0.8 -US-ARM,89677,GRP_LAI,LAI_TYPE,PAI -US-ARM,89677,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89677,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89677,GRP_LAI,LAI_STATISTIC,Standard Deviation -US-ARM,89677,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89677,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89677,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89677,GRP_LAI,LAI_DATE,20080630 -US-ARM,89677,GRP_LAI,LAI_COMMENT,corn -US-ARM,89724,GRP_LAI,LAI,0.8 -US-ARM,89724,GRP_LAI,LAI_TYPE,PAI -US-ARM,89724,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89724,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89724,GRP_LAI,LAI_STATISTIC,Mean -US-ARM,89724,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89724,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89724,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89724,GRP_LAI,LAI_DATE,20120301 -US-ARM,89724,GRP_LAI,LAI_COMMENT,wheat -US-ARM,89729,GRP_LAI,LAI,0.8 -US-ARM,89729,GRP_LAI,LAI_TYPE,PAI -US-ARM,89729,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89729,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89729,GRP_LAI,LAI_STATISTIC,Standard Deviation -US-ARM,89729,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89729,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89729,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89729,GRP_LAI,LAI_DATE,20120313 -US-ARM,89729,GRP_LAI,LAI_COMMENT,wheat -US-ARM,89745,GRP_LAI,LAI,0.8 -US-ARM,89745,GRP_LAI,LAI_TYPE,PAI -US-ARM,89745,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89745,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89745,GRP_LAI,LAI_STATISTIC,Standard Deviation -US-ARM,89745,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89745,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89745,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89745,GRP_LAI,LAI_DATE,20130613 -US-ARM,89745,GRP_LAI,LAI_COMMENT,wheat -US-ARM,89768,GRP_LAI,LAI,0.8 -US-ARM,89768,GRP_LAI,LAI_TYPE,PAI -US-ARM,89768,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89768,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89768,GRP_LAI,LAI_STATISTIC,Mean -US-ARM,89768,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89768,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89768,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89768,GRP_LAI,LAI_DATE,20160402 -US-ARM,89768,GRP_LAI,LAI_COMMENT,Alfalfa -US-ARM,89777,GRP_LAI,LAI,0.8 -US-ARM,89777,GRP_LAI,LAI_TYPE,PAI -US-ARM,89777,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89777,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89777,GRP_LAI,LAI_STATISTIC,Standard Deviation -US-ARM,89777,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89777,GRP_LAI,LAI_STATISTIC_NUMBER,9 -US-ARM,89777,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89777,GRP_LAI,LAI_DATE,20160427 -US-ARM,89777,GRP_LAI,LAI_COMMENT,Alfalfa -US-ARM,89778,GRP_LAI,LAI,0.8 -US-ARM,89778,GRP_LAI,LAI_TYPE,PAI -US-ARM,89778,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89778,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89778,GRP_LAI,LAI_STATISTIC,Minimum -US-ARM,89778,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89778,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89778,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89778,GRP_LAI,LAI_DATE,20160511 -US-ARM,89778,GRP_LAI,LAI_COMMENT,Alfalfa -US-ARM,89794,GRP_LAI,LAI,0.8 -US-ARM,89794,GRP_LAI,LAI_TYPE,PAI -US-ARM,89794,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89794,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89794,GRP_LAI,LAI_STATISTIC,Minimum -US-ARM,89794,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89794,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89794,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89794,GRP_LAI,LAI_DATE,20160618 -US-ARM,89794,GRP_LAI,LAI_COMMENT,Alfalfa -US-ARM,89804,GRP_LAI,LAI,0.8 -US-ARM,89804,GRP_LAI,LAI_TYPE,PAI -US-ARM,89804,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89804,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89804,GRP_LAI,LAI_STATISTIC,Mean -US-ARM,89804,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89804,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89804,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89804,GRP_LAI,LAI_DATE,20160712 -US-ARM,89804,GRP_LAI,LAI_COMMENT,Alfalfa -US-ARM,89829,GRP_LAI,LAI,0.8 -US-ARM,89829,GRP_LAI,LAI_TYPE,PAI -US-ARM,89829,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89829,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89829,GRP_LAI,LAI_STATISTIC,Standard Deviation -US-ARM,89829,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89829,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89829,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89829,GRP_LAI,LAI_DATE,20161021 -US-ARM,89829,GRP_LAI,LAI_COMMENT,Alfalfa -US-ARM,89878,GRP_LAI,LAI,0.8 -US-ARM,89878,GRP_LAI,LAI_TYPE,PAI -US-ARM,89878,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89878,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89878,GRP_LAI,LAI_STATISTIC,Mean -US-ARM,89878,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89878,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89878,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89878,GRP_LAI,LAI_DATE,20180419 -US-ARM,89878,GRP_LAI,LAI_COMMENT,Alfalfa -US-ARM,89900,GRP_LAI,LAI,0.8 -US-ARM,89900,GRP_LAI,LAI_TYPE,PAI -US-ARM,89900,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89900,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89900,GRP_LAI,LAI_STATISTIC,Minimum -US-ARM,89900,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89900,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89900,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89900,GRP_LAI,LAI_DATE,20180810 -US-ARM,89900,GRP_LAI,LAI_COMMENT,Alfalfa -US-ARM,89928,GRP_LAI,LAI,0.8 -US-ARM,89928,GRP_LAI,LAI_TYPE,PAI -US-ARM,89928,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89928,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89928,GRP_LAI,LAI_STATISTIC,Minimum -US-ARM,89928,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89928,GRP_LAI,LAI_STATISTIC_NUMBER,9 -US-ARM,89928,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89928,GRP_LAI,LAI_DATE,20190717 -US-ARM,89928,GRP_LAI,LAI_COMMENT,Alfalfa -US-ARM,89608,GRP_LAI,LAI,0.9 -US-ARM,89608,GRP_LAI,LAI_TYPE,PAI -US-ARM,89608,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89608,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89608,GRP_LAI,LAI_STATISTIC,Mean -US-ARM,89608,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89608,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89608,GRP_LAI,LAI_DATE,20040316 -US-ARM,89608,GRP_LAI,LAI_COMMENT,wheat -US-ARM,89622,GRP_LAI,LAI,0.9 -US-ARM,89622,GRP_LAI,LAI_TYPE,PAI -US-ARM,89622,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89622,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89622,GRP_LAI,LAI_STATISTIC,Minimum -US-ARM,89622,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89622,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89622,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89622,GRP_LAI,LAI_DATE,20050708 -US-ARM,89622,GRP_LAI,LAI_COMMENT,corn -US-ARM,89706,GRP_LAI,LAI,0.9 -US-ARM,89706,GRP_LAI,LAI_TYPE,PAI -US-ARM,89706,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89706,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89706,GRP_LAI,LAI_STATISTIC,Minimum -US-ARM,89706,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89706,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89706,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89706,GRP_LAI,LAI_DATE,20100316 -US-ARM,89706,GRP_LAI,LAI_COMMENT,wheat -US-ARM,89713,GRP_LAI,LAI,0.9 -US-ARM,89713,GRP_LAI,LAI_TYPE,PAI -US-ARM,89713,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89713,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89713,GRP_LAI,LAI_STATISTIC,Standard Deviation -US-ARM,89713,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89713,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89713,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89713,GRP_LAI,LAI_DATE,20100412 -US-ARM,89713,GRP_LAI,LAI_COMMENT,wheat -US-ARM,89737,GRP_LAI,LAI,0.9 -US-ARM,89737,GRP_LAI,LAI_TYPE,PAI -US-ARM,89737,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89737,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89737,GRP_LAI,LAI_STATISTIC,Standard Deviation -US-ARM,89737,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89737,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89737,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89737,GRP_LAI,LAI_DATE,20120516 -US-ARM,89737,GRP_LAI,LAI_COMMENT,wheat -US-ARM,89785,GRP_LAI,LAI,0.9 -US-ARM,89785,GRP_LAI,LAI_TYPE,PAI -US-ARM,89785,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89785,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89785,GRP_LAI,LAI_STATISTIC,Standard Deviation -US-ARM,89785,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89785,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89785,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89785,GRP_LAI,LAI_DATE,20160521 -US-ARM,89785,GRP_LAI,LAI_COMMENT,Alfalfa -US-ARM,89789,GRP_LAI,LAI,0.9 -US-ARM,89789,GRP_LAI,LAI_TYPE,PAI -US-ARM,89789,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89789,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89789,GRP_LAI,LAI_STATISTIC,Standard Deviation -US-ARM,89789,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89789,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89789,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89789,GRP_LAI,LAI_DATE,20160525 -US-ARM,89789,GRP_LAI,LAI_COMMENT,Alfalfa -US-ARM,89813,GRP_LAI,LAI,0.9 -US-ARM,89813,GRP_LAI,LAI_TYPE,PAI -US-ARM,89813,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89813,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89813,GRP_LAI,LAI_STATISTIC,Standard Deviation -US-ARM,89813,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89813,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89813,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89813,GRP_LAI,LAI_DATE,20160812 -US-ARM,89813,GRP_LAI,LAI_COMMENT,Alfalfa -US-ARM,89816,GRP_LAI,LAI,0.9 -US-ARM,89816,GRP_LAI,LAI_TYPE,PAI -US-ARM,89816,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89816,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89816,GRP_LAI,LAI_STATISTIC,Mean -US-ARM,89816,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89816,GRP_LAI,LAI_STATISTIC_NUMBER,8 -US-ARM,89816,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89816,GRP_LAI,LAI_DATE,20160827 -US-ARM,89816,GRP_LAI,LAI_COMMENT,Alfalfa -US-ARM,89874,GRP_LAI,LAI,0.9 -US-ARM,89874,GRP_LAI,LAI_TYPE,PAI -US-ARM,89874,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89874,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89874,GRP_LAI,LAI_STATISTIC,Minimum -US-ARM,89874,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89874,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89874,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89874,GRP_LAI,LAI_DATE,20171023 -US-ARM,89874,GRP_LAI,LAI_COMMENT,Alfalfa -US-ARM,89890,GRP_LAI,LAI,0.9 -US-ARM,89890,GRP_LAI,LAI_TYPE,PAI -US-ARM,89890,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89890,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89890,GRP_LAI,LAI_STATISTIC,Mean -US-ARM,89890,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89890,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89890,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89890,GRP_LAI,LAI_DATE,20180614 -US-ARM,89890,GRP_LAI,LAI_COMMENT,Alfalfa -US-ARM,89904,GRP_LAI,LAI,0.9 -US-ARM,89904,GRP_LAI,LAI_TYPE,PAI -US-ARM,89904,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89904,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89904,GRP_LAI,LAI_STATISTIC,Minimum -US-ARM,89904,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89904,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89904,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89904,GRP_LAI,LAI_DATE,20180827 -US-ARM,89904,GRP_LAI,LAI_COMMENT,Alfalfa -US-ARM,89672,GRP_LAI,LAI,1 -US-ARM,89672,GRP_LAI,LAI_TYPE,PAI -US-ARM,89672,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89672,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89672,GRP_LAI,LAI_STATISTIC,Mean -US-ARM,89672,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89672,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89672,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89672,GRP_LAI,LAI_DATE,20080612 -US-ARM,89672,GRP_LAI,LAI_COMMENT,corn -US-ARM,89688,GRP_LAI,LAI,1 -US-ARM,89688,GRP_LAI,LAI_TYPE,PAI -US-ARM,89688,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89688,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89688,GRP_LAI,LAI_STATISTIC,Mean -US-ARM,89688,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89688,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89688,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89688,GRP_LAI,LAI_DATE,20090316 -US-ARM,89688,GRP_LAI,LAI_COMMENT,wheat -US-ARM,89748,GRP_LAI,LAI,1 -US-ARM,89748,GRP_LAI,LAI_TYPE,PAI -US-ARM,89748,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89748,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89748,GRP_LAI,LAI_STATISTIC,Mean -US-ARM,89748,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89748,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89748,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89748,GRP_LAI,LAI_DATE,20150423 -US-ARM,89748,GRP_LAI,LAI_COMMENT,wheat -US-ARM,89772,GRP_LAI,LAI,1 -US-ARM,89772,GRP_LAI,LAI_TYPE,PAI -US-ARM,89772,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89772,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89772,GRP_LAI,LAI_STATISTIC,Mean -US-ARM,89772,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89772,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89772,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89772,GRP_LAI,LAI_DATE,20160413 -US-ARM,89772,GRP_LAI,LAI_COMMENT,Alfalfa -US-ARM,89792,GRP_LAI,LAI,1 -US-ARM,89792,GRP_LAI,LAI_TYPE,PAI -US-ARM,89792,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89792,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89792,GRP_LAI,LAI_STATISTIC,Mean -US-ARM,89792,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89792,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89792,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89792,GRP_LAI,LAI_DATE,20160603 -US-ARM,89792,GRP_LAI,LAI_COMMENT,Alfalfa -US-ARM,89800,GRP_LAI,LAI,1 -US-ARM,89800,GRP_LAI,LAI_TYPE,PAI -US-ARM,89800,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89800,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89800,GRP_LAI,LAI_STATISTIC,Mean -US-ARM,89800,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89800,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89800,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89800,GRP_LAI,LAI_DATE,20160702 -US-ARM,89800,GRP_LAI,LAI_COMMENT,Alfalfa -US-ARM,89830,GRP_LAI,LAI,1 -US-ARM,89830,GRP_LAI,LAI_TYPE,PAI -US-ARM,89830,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89830,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89830,GRP_LAI,LAI_STATISTIC,Minimum -US-ARM,89830,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89830,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89830,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89830,GRP_LAI,LAI_DATE,20161105 -US-ARM,89830,GRP_LAI,LAI_COMMENT,Alfalfa -US-ARM,89870,GRP_LAI,LAI,1 -US-ARM,89870,GRP_LAI,LAI_TYPE,PAI -US-ARM,89870,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89870,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89870,GRP_LAI,LAI_STATISTIC,Minimum -US-ARM,89870,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89870,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89870,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89870,GRP_LAI,LAI_DATE,20170830 -US-ARM,89870,GRP_LAI,LAI_COMMENT,Alfalfa -US-ARM,89877,GRP_LAI,LAI,1 -US-ARM,89877,GRP_LAI,LAI_TYPE,PAI -US-ARM,89877,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89877,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89877,GRP_LAI,LAI_STATISTIC,Standard Deviation -US-ARM,89877,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89877,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89877,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89877,GRP_LAI,LAI_DATE,20171023 -US-ARM,89877,GRP_LAI,LAI_COMMENT,Alfalfa -US-ARM,89894,GRP_LAI,LAI,1 -US-ARM,89894,GRP_LAI,LAI_TYPE,PAI -US-ARM,89894,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89894,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89894,GRP_LAI,LAI_STATISTIC,Mean -US-ARM,89894,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89894,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89894,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89894,GRP_LAI,LAI_DATE,20180629 -US-ARM,89894,GRP_LAI,LAI_COMMENT,Alfalfa -US-ARM,89930,GRP_LAI,LAI,1 -US-ARM,89930,GRP_LAI,LAI_TYPE,PAI -US-ARM,89930,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89930,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89930,GRP_LAI,LAI_STATISTIC,Mean -US-ARM,89930,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89930,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89930,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89930,GRP_LAI,LAI_DATE,20190814 -US-ARM,89930,GRP_LAI,LAI_COMMENT,Alfalfa -US-ARM,89598,GRP_LAI,LAI,1.1 -US-ARM,89598,GRP_LAI,LAI_TYPE,PAI -US-ARM,89598,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89598,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89598,GRP_LAI,LAI_STATISTIC,Mean -US-ARM,89598,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89598,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89598,GRP_LAI,LAI_DATE,20030313 -US-ARM,89598,GRP_LAI,LAI_COMMENT,wheat -US-ARM,89638,GRP_LAI,LAI,1.1 -US-ARM,89638,GRP_LAI,LAI_TYPE,PAI -US-ARM,89638,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89638,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89638,GRP_LAI,LAI_STATISTIC,Minimum -US-ARM,89638,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89638,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89638,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89638,GRP_LAI,LAI_DATE,20060427 -US-ARM,89638,GRP_LAI,LAI_COMMENT,wheat -US-ARM,89764,GRP_LAI,LAI,1.1 -US-ARM,89764,GRP_LAI,LAI_TYPE,PAI -US-ARM,89764,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89764,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89764,GRP_LAI,LAI_STATISTIC,Mean -US-ARM,89764,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89764,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89764,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89764,GRP_LAI,LAI_DATE,20160317 -US-ARM,89764,GRP_LAI,LAI_COMMENT,Alfalfa -US-ARM,89774,GRP_LAI,LAI,1.1 -US-ARM,89774,GRP_LAI,LAI_TYPE,PAI -US-ARM,89774,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89774,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89774,GRP_LAI,LAI_STATISTIC,Minimum -US-ARM,89774,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89774,GRP_LAI,LAI_STATISTIC_NUMBER,9 -US-ARM,89774,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89774,GRP_LAI,LAI_DATE,20160427 -US-ARM,89774,GRP_LAI,LAI_COMMENT,Alfalfa -US-ARM,89782,GRP_LAI,LAI,1.1 -US-ARM,89782,GRP_LAI,LAI_TYPE,PAI -US-ARM,89782,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89782,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89782,GRP_LAI,LAI_STATISTIC,Minimum -US-ARM,89782,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89782,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89782,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89782,GRP_LAI,LAI_DATE,20160521 -US-ARM,89782,GRP_LAI,LAI_COMMENT,Alfalfa -US-ARM,89910,GRP_LAI,LAI,1.1 -US-ARM,89910,GRP_LAI,LAI_TYPE,PAI -US-ARM,89910,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89910,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89910,GRP_LAI,LAI_STATISTIC,Mean -US-ARM,89910,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89910,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89910,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89910,GRP_LAI,LAI_DATE,20180928 -US-ARM,89910,GRP_LAI,LAI_COMMENT,Alfalfa -US-ARM,89619,GRP_LAI,LAI,1.2 -US-ARM,89619,GRP_LAI,LAI_TYPE,PAI -US-ARM,89619,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89619,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89619,GRP_LAI,LAI_STATISTIC,Maximum -US-ARM,89619,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89619,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89619,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89619,GRP_LAI,LAI_DATE,20050613 -US-ARM,89619,GRP_LAI,LAI_COMMENT,corn -US-ARM,89642,GRP_LAI,LAI,1.2 -US-ARM,89642,GRP_LAI,LAI_TYPE,PAI -US-ARM,89642,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89642,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89642,GRP_LAI,LAI_STATISTIC,Minimum -US-ARM,89642,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89642,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89642,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89642,GRP_LAI,LAI_DATE,20060516 -US-ARM,89642,GRP_LAI,LAI_COMMENT,wheat -US-ARM,89690,GRP_LAI,LAI,1.2 -US-ARM,89690,GRP_LAI,LAI_TYPE,PAI -US-ARM,89690,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89690,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89690,GRP_LAI,LAI_STATISTIC,Minimum -US-ARM,89690,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89690,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89690,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89690,GRP_LAI,LAI_DATE,20090401 -US-ARM,89690,GRP_LAI,LAI_COMMENT,wheat -US-ARM,89694,GRP_LAI,LAI,1.2 -US-ARM,89694,GRP_LAI,LAI_TYPE,PAI -US-ARM,89694,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89694,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89694,GRP_LAI,LAI_STATISTIC,Minimum -US-ARM,89694,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89694,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89694,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89694,GRP_LAI,LAI_DATE,20090415 -US-ARM,89694,GRP_LAI,LAI_COMMENT,wheat -US-ARM,89742,GRP_LAI,LAI,1.2 -US-ARM,89742,GRP_LAI,LAI_TYPE,PAI -US-ARM,89742,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89742,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89742,GRP_LAI,LAI_STATISTIC,Minimum -US-ARM,89742,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89742,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89742,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89742,GRP_LAI,LAI_DATE,20130613 -US-ARM,89742,GRP_LAI,LAI_COMMENT,wheat -US-ARM,89796,GRP_LAI,LAI,1.2 -US-ARM,89796,GRP_LAI,LAI_TYPE,PAI -US-ARM,89796,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89796,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89796,GRP_LAI,LAI_STATISTIC,Mean -US-ARM,89796,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89796,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89796,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89796,GRP_LAI,LAI_DATE,20160618 -US-ARM,89796,GRP_LAI,LAI_COMMENT,Alfalfa -US-ARM,89812,GRP_LAI,LAI,1.2 -US-ARM,89812,GRP_LAI,LAI_TYPE,PAI -US-ARM,89812,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89812,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89812,GRP_LAI,LAI_STATISTIC,Mean -US-ARM,89812,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89812,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89812,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89812,GRP_LAI,LAI_DATE,20160812 -US-ARM,89812,GRP_LAI,LAI_COMMENT,Alfalfa -US-ARM,89822,GRP_LAI,LAI,1.2 -US-ARM,89822,GRP_LAI,LAI_TYPE,PAI -US-ARM,89822,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89822,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89822,GRP_LAI,LAI_STATISTIC,Minimum -US-ARM,89822,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89822,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89822,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89822,GRP_LAI,LAI_DATE,20161012 -US-ARM,89822,GRP_LAI,LAI_COMMENT,Alfalfa -US-ARM,89862,GRP_LAI,LAI,1.2 -US-ARM,89862,GRP_LAI,LAI_TYPE,PAI -US-ARM,89862,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89862,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89862,GRP_LAI,LAI_STATISTIC,Minimum -US-ARM,89862,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89862,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89862,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89862,GRP_LAI,LAI_DATE,20170707 -US-ARM,89862,GRP_LAI,LAI_COMMENT,Alfalfa -US-ARM,89892,GRP_LAI,LAI,1.2 -US-ARM,89892,GRP_LAI,LAI_TYPE,PAI -US-ARM,89892,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89892,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89892,GRP_LAI,LAI_STATISTIC,Minimum -US-ARM,89892,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89892,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89892,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89892,GRP_LAI,LAI_DATE,20180614 -US-ARM,89892,GRP_LAI,LAI_COMMENT,Alfalfa -US-ARM,89927,GRP_LAI,LAI,1.2 -US-ARM,89927,GRP_LAI,LAI_TYPE,PAI -US-ARM,89927,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89927,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89927,GRP_LAI,LAI_STATISTIC,Maximum -US-ARM,89927,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89927,GRP_LAI,LAI_STATISTIC_NUMBER,9 -US-ARM,89927,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89927,GRP_LAI,LAI_DATE,20190717 -US-ARM,89927,GRP_LAI,LAI_COMMENT,Alfalfa -US-ARM,89932,GRP_LAI,LAI,1.2 -US-ARM,89932,GRP_LAI,LAI_TYPE,PAI -US-ARM,89932,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89932,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89932,GRP_LAI,LAI_STATISTIC,Minimum -US-ARM,89932,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89932,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89932,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89932,GRP_LAI,LAI_DATE,20190814 -US-ARM,89932,GRP_LAI,LAI_COMMENT,Alfalfa -US-ARM,89628,GRP_LAI,LAI,1.3 -US-ARM,89628,GRP_LAI,LAI_TYPE,PAI -US-ARM,89628,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89628,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89628,GRP_LAI,LAI_STATISTIC,Mean -US-ARM,89628,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89628,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89628,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89628,GRP_LAI,LAI_DATE,20050719 -US-ARM,89628,GRP_LAI,LAI_COMMENT,corn -US-ARM,89634,GRP_LAI,LAI,1.3 -US-ARM,89634,GRP_LAI,LAI_TYPE,PAI -US-ARM,89634,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89634,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89634,GRP_LAI,LAI_STATISTIC,Minimum -US-ARM,89634,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89634,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89634,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89634,GRP_LAI,LAI_DATE,20060406 -US-ARM,89634,GRP_LAI,LAI_COMMENT,wheat -US-ARM,89682,GRP_LAI,LAI,1.3 -US-ARM,89682,GRP_LAI,LAI_TYPE,PAI -US-ARM,89682,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89682,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89682,GRP_LAI,LAI_STATISTIC,Minimum -US-ARM,89682,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89682,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89682,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89682,GRP_LAI,LAI_DATE,20080806 -US-ARM,89682,GRP_LAI,LAI_COMMENT,corn -US-ARM,89726,GRP_LAI,LAI,1.3 -US-ARM,89726,GRP_LAI,LAI_TYPE,PAI -US-ARM,89726,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89726,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89726,GRP_LAI,LAI_STATISTIC,Minimum -US-ARM,89726,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89726,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89726,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89726,GRP_LAI,LAI_DATE,20120313 -US-ARM,89726,GRP_LAI,LAI_COMMENT,wheat -US-ARM,89786,GRP_LAI,LAI,1.3 -US-ARM,89786,GRP_LAI,LAI_TYPE,PAI -US-ARM,89786,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89786,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89786,GRP_LAI,LAI_STATISTIC,Minimum -US-ARM,89786,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89786,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89786,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89786,GRP_LAI,LAI_DATE,20160525 -US-ARM,89786,GRP_LAI,LAI_COMMENT,Alfalfa -US-ARM,89791,GRP_LAI,LAI,1.3 -US-ARM,89791,GRP_LAI,LAI_TYPE,PAI -US-ARM,89791,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89791,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89791,GRP_LAI,LAI_STATISTIC,Maximum -US-ARM,89791,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89791,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89791,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89791,GRP_LAI,LAI_DATE,20160603 -US-ARM,89791,GRP_LAI,LAI_COMMENT,Alfalfa -US-ARM,89803,GRP_LAI,LAI,1.3 -US-ARM,89803,GRP_LAI,LAI_TYPE,PAI -US-ARM,89803,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89803,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89803,GRP_LAI,LAI_STATISTIC,Maximum -US-ARM,89803,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89803,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89803,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89803,GRP_LAI,LAI_DATE,20160712 -US-ARM,89803,GRP_LAI,LAI_COMMENT,Alfalfa -US-ARM,89826,GRP_LAI,LAI,1.3 -US-ARM,89826,GRP_LAI,LAI_TYPE,PAI -US-ARM,89826,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89826,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89826,GRP_LAI,LAI_STATISTIC,Minimum -US-ARM,89826,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89826,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89826,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89826,GRP_LAI,LAI_DATE,20161021 -US-ARM,89826,GRP_LAI,LAI_COMMENT,Alfalfa -US-ARM,89836,GRP_LAI,LAI,1.3 -US-ARM,89836,GRP_LAI,LAI_TYPE,PAI -US-ARM,89836,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89836,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89836,GRP_LAI,LAI_STATISTIC,Mean -US-ARM,89836,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89836,GRP_LAI,LAI_STATISTIC_NUMBER,8 -US-ARM,89836,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89836,GRP_LAI,LAI_DATE,20161119 -US-ARM,89836,GRP_LAI,LAI_COMMENT,Alfalfa -US-ARM,89858,GRP_LAI,LAI,1.3 -US-ARM,89858,GRP_LAI,LAI_TYPE,PAI -US-ARM,89858,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89858,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89858,GRP_LAI,LAI_STATISTIC,Minimum -US-ARM,89858,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89858,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89858,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89858,GRP_LAI,LAI_DATE,20170601 -US-ARM,89858,GRP_LAI,LAI_COMMENT,Alfalfa -US-ARM,89866,GRP_LAI,LAI,1.3 -US-ARM,89866,GRP_LAI,LAI_TYPE,PAI -US-ARM,89866,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89866,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89866,GRP_LAI,LAI_STATISTIC,Minimum -US-ARM,89866,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89866,GRP_LAI,LAI_STATISTIC_NUMBER,9 -US-ARM,89866,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89866,GRP_LAI,LAI_DATE,20170718 -US-ARM,89866,GRP_LAI,LAI_COMMENT,Alfalfa -US-ARM,89903,GRP_LAI,LAI,1.3 -US-ARM,89903,GRP_LAI,LAI_TYPE,PAI -US-ARM,89903,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89903,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89903,GRP_LAI,LAI_STATISTIC,Maximum -US-ARM,89903,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89903,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89903,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89903,GRP_LAI,LAI_DATE,20180827 -US-ARM,89903,GRP_LAI,LAI_COMMENT,Alfalfa -US-ARM,89624,GRP_LAI,LAI,1.4 -US-ARM,89624,GRP_LAI,LAI_TYPE,PAI -US-ARM,89624,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89624,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89624,GRP_LAI,LAI_STATISTIC,Mean -US-ARM,89624,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89624,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89624,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89624,GRP_LAI,LAI_DATE,20050708 -US-ARM,89624,GRP_LAI,LAI_COMMENT,corn -US-ARM,89646,GRP_LAI,LAI,1.4 -US-ARM,89646,GRP_LAI,LAI_TYPE,PAI -US-ARM,89646,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89646,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89646,GRP_LAI,LAI_STATISTIC,Minimum -US-ARM,89646,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89646,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89646,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89646,GRP_LAI,LAI_DATE,20060606 -US-ARM,89646,GRP_LAI,LAI_COMMENT,wheat -US-ARM,89687,GRP_LAI,LAI,1.4 -US-ARM,89687,GRP_LAI,LAI_TYPE,PAI -US-ARM,89687,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89687,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89687,GRP_LAI,LAI_STATISTIC,Maximum -US-ARM,89687,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89687,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89687,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89687,GRP_LAI,LAI_DATE,20090316 -US-ARM,89687,GRP_LAI,LAI_COMMENT,wheat -US-ARM,89815,GRP_LAI,LAI,1.4 -US-ARM,89815,GRP_LAI,LAI_TYPE,PAI -US-ARM,89815,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89815,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89815,GRP_LAI,LAI_STATISTIC,Maximum -US-ARM,89815,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89815,GRP_LAI,LAI_STATISTIC_NUMBER,8 -US-ARM,89815,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89815,GRP_LAI,LAI_DATE,20160827 -US-ARM,89815,GRP_LAI,LAI_COMMENT,Alfalfa -US-ARM,89880,GRP_LAI,LAI,1.4 -US-ARM,89880,GRP_LAI,LAI_TYPE,PAI -US-ARM,89880,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89880,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89880,GRP_LAI,LAI_STATISTIC,Minimum -US-ARM,89880,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89880,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89880,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89880,GRP_LAI,LAI_DATE,20180419 -US-ARM,89880,GRP_LAI,LAI_COMMENT,Alfalfa -US-ARM,89886,GRP_LAI,LAI,1.4 -US-ARM,89886,GRP_LAI,LAI_TYPE,PAI -US-ARM,89886,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89886,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89886,GRP_LAI,LAI_STATISTIC,Mean -US-ARM,89886,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89886,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89886,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89886,GRP_LAI,LAI_DATE,20180516 -US-ARM,89886,GRP_LAI,LAI_COMMENT,Alfalfa -US-ARM,89590,GRP_LAI,LAI,1.5 -US-ARM,89590,GRP_LAI,LAI_TYPE,PAI -US-ARM,89590,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89590,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89590,GRP_LAI,LAI_STATISTIC,Mean -US-ARM,89590,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89590,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89590,GRP_LAI,LAI_DATE,20020502 -US-ARM,89590,GRP_LAI,LAI_COMMENT,wheat -US-ARM,89592,GRP_LAI,LAI,1.5 -US-ARM,89592,GRP_LAI,LAI_TYPE,PAI -US-ARM,89592,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89592,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89592,GRP_LAI,LAI_STATISTIC,Mean -US-ARM,89592,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89592,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89592,GRP_LAI,LAI_DATE,20020510 -US-ARM,89592,GRP_LAI,LAI_COMMENT,wheat -US-ARM,89610,GRP_LAI,LAI,1.5 -US-ARM,89610,GRP_LAI,LAI_TYPE,PAI -US-ARM,89610,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89610,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89610,GRP_LAI,LAI_STATISTIC,Mean -US-ARM,89610,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89610,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89610,GRP_LAI,LAI_DATE,20040331 -US-ARM,89610,GRP_LAI,LAI_COMMENT,wheat -US-ARM,89631,GRP_LAI,LAI,1.5 -US-ARM,89631,GRP_LAI,LAI_TYPE,PAI -US-ARM,89631,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89631,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89631,GRP_LAI,LAI_STATISTIC,Maximum -US-ARM,89631,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89631,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89631,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89631,GRP_LAI,LAI_DATE,20050913 -US-ARM,89631,GRP_LAI,LAI_COMMENT,corn -US-ARM,89640,GRP_LAI,LAI,1.5 -US-ARM,89640,GRP_LAI,LAI_TYPE,PAI -US-ARM,89640,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89640,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89640,GRP_LAI,LAI_STATISTIC,Mean -US-ARM,89640,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89640,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89640,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89640,GRP_LAI,LAI_DATE,20060427 -US-ARM,89640,GRP_LAI,LAI_COMMENT,wheat -US-ARM,89674,GRP_LAI,LAI,1.5 -US-ARM,89674,GRP_LAI,LAI_TYPE,PAI -US-ARM,89674,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89674,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89674,GRP_LAI,LAI_STATISTIC,Minimum -US-ARM,89674,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89674,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89674,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89674,GRP_LAI,LAI_DATE,20080630 -US-ARM,89674,GRP_LAI,LAI_COMMENT,corn -US-ARM,89692,GRP_LAI,LAI,1.5 -US-ARM,89692,GRP_LAI,LAI_TYPE,PAI -US-ARM,89692,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89692,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89692,GRP_LAI,LAI_STATISTIC,Mean -US-ARM,89692,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89692,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89692,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89692,GRP_LAI,LAI_DATE,20090401 -US-ARM,89692,GRP_LAI,LAI_COMMENT,wheat -US-ARM,89740,GRP_LAI,LAI,1.5 -US-ARM,89740,GRP_LAI,LAI_TYPE,PAI -US-ARM,89740,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89740,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89740,GRP_LAI,LAI_STATISTIC,Mean -US-ARM,89740,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89740,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89740,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89740,GRP_LAI,LAI_DATE,20130422 -US-ARM,89740,GRP_LAI,LAI_COMMENT,wheat -US-ARM,89747,GRP_LAI,LAI,1.5 -US-ARM,89747,GRP_LAI,LAI_TYPE,PAI -US-ARM,89747,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89747,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89747,GRP_LAI,LAI_STATISTIC,Maximum -US-ARM,89747,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89747,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89747,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89747,GRP_LAI,LAI_DATE,20150423 -US-ARM,89747,GRP_LAI,LAI_COMMENT,wheat -US-ARM,89820,GRP_LAI,LAI,1.5 -US-ARM,89820,GRP_LAI,LAI_TYPE,PAI -US-ARM,89820,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89820,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89820,GRP_LAI,LAI_STATISTIC,Mean -US-ARM,89820,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89820,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89820,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89820,GRP_LAI,LAI_DATE,20160909 -US-ARM,89820,GRP_LAI,LAI_COMMENT,Alfalfa -US-ARM,89872,GRP_LAI,LAI,1.5 -US-ARM,89872,GRP_LAI,LAI_TYPE,PAI -US-ARM,89872,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89872,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89872,GRP_LAI,LAI_STATISTIC,Mean -US-ARM,89872,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89872,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89872,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89872,GRP_LAI,LAI_DATE,20170830 -US-ARM,89872,GRP_LAI,LAI_COMMENT,Alfalfa -US-ARM,89899,GRP_LAI,LAI,1.5 -US-ARM,89899,GRP_LAI,LAI_TYPE,PAI -US-ARM,89899,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89899,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89899,GRP_LAI,LAI_STATISTIC,Maximum -US-ARM,89899,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89899,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89899,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89899,GRP_LAI,LAI_DATE,20180810 -US-ARM,89899,GRP_LAI,LAI_COMMENT,Alfalfa -US-ARM,89906,GRP_LAI,LAI,1.5 -US-ARM,89906,GRP_LAI,LAI_TYPE,PAI -US-ARM,89906,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89906,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89906,GRP_LAI,LAI_STATISTIC,Mean -US-ARM,89906,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89906,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89906,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89906,GRP_LAI,LAI_DATE,20180914 -US-ARM,89906,GRP_LAI,LAI_COMMENT,Alfalfa -US-ARM,89922,GRP_LAI,LAI,1.5 -US-ARM,89922,GRP_LAI,LAI_TYPE,PAI -US-ARM,89922,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89922,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89922,GRP_LAI,LAI_STATISTIC,Mean -US-ARM,89922,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89922,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89922,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89922,GRP_LAI,LAI_DATE,20190613 -US-ARM,89922,GRP_LAI,LAI_COMMENT,Alfalfa -US-ARM,89612,GRP_LAI,LAI,1.6 -US-ARM,89612,GRP_LAI,LAI_TYPE,PAI -US-ARM,89612,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89612,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89612,GRP_LAI,LAI_STATISTIC,Mean -US-ARM,89612,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89612,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89612,GRP_LAI,LAI_DATE,20040421 -US-ARM,89612,GRP_LAI,LAI_COMMENT,wheat -US-ARM,89666,GRP_LAI,LAI,1.6 -US-ARM,89666,GRP_LAI,LAI_TYPE,PAI -US-ARM,89666,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89666,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89666,GRP_LAI,LAI_STATISTIC,Minimum -US-ARM,89666,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89666,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89666,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89666,GRP_LAI,LAI_DATE,20070608 -US-ARM,89666,GRP_LAI,LAI_COMMENT,wheat -US-ARM,89696,GRP_LAI,LAI,1.6 -US-ARM,89696,GRP_LAI,LAI_TYPE,PAI -US-ARM,89696,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89696,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89696,GRP_LAI,LAI_STATISTIC,Mean -US-ARM,89696,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89696,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89696,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89696,GRP_LAI,LAI_DATE,20090415 -US-ARM,89696,GRP_LAI,LAI_COMMENT,wheat -US-ARM,89704,GRP_LAI,LAI,1.6 -US-ARM,89704,GRP_LAI,LAI_TYPE,PAI -US-ARM,89704,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89704,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89704,GRP_LAI,LAI_STATISTIC,Mean -US-ARM,89704,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89704,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89704,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89704,GRP_LAI,LAI_DATE,20090605 -US-ARM,89704,GRP_LAI,LAI_COMMENT,wheat -US-ARM,89750,GRP_LAI,LAI,1.6 -US-ARM,89750,GRP_LAI,LAI_TYPE,PAI -US-ARM,89750,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89750,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89750,GRP_LAI,LAI_STATISTIC,Minimum -US-ARM,89750,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89750,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89750,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89750,GRP_LAI,LAI_DATE,20150519 -US-ARM,89750,GRP_LAI,LAI_COMMENT,wheat -US-ARM,89795,GRP_LAI,LAI,1.6 -US-ARM,89795,GRP_LAI,LAI_TYPE,PAI -US-ARM,89795,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89795,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89795,GRP_LAI,LAI_STATISTIC,Maximum -US-ARM,89795,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89795,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89795,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89795,GRP_LAI,LAI_DATE,20160618 -US-ARM,89795,GRP_LAI,LAI_COMMENT,Alfalfa -US-ARM,89799,GRP_LAI,LAI,1.6 -US-ARM,89799,GRP_LAI,LAI_TYPE,PAI -US-ARM,89799,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89799,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89799,GRP_LAI,LAI_STATISTIC,Maximum -US-ARM,89799,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89799,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89799,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89799,GRP_LAI,LAI_DATE,20160702 -US-ARM,89799,GRP_LAI,LAI_COMMENT,Alfalfa -US-ARM,89838,GRP_LAI,LAI,1.6 -US-ARM,89838,GRP_LAI,LAI_TYPE,PAI -US-ARM,89838,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89838,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89838,GRP_LAI,LAI_STATISTIC,Minimum -US-ARM,89838,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89838,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89838,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89838,GRP_LAI,LAI_DATE,20170317 -US-ARM,89838,GRP_LAI,LAI_COMMENT,Alfalfa -US-ARM,89891,GRP_LAI,LAI,1.6 -US-ARM,89891,GRP_LAI,LAI_TYPE,PAI -US-ARM,89891,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89891,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89891,GRP_LAI,LAI_STATISTIC,Maximum -US-ARM,89891,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89891,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89891,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89891,GRP_LAI,LAI_DATE,20180614 -US-ARM,89891,GRP_LAI,LAI_COMMENT,Alfalfa -US-ARM,89896,GRP_LAI,LAI,1.6 -US-ARM,89896,GRP_LAI,LAI_TYPE,PAI -US-ARM,89896,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89896,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89896,GRP_LAI,LAI_STATISTIC,Minimum -US-ARM,89896,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89896,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89896,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89896,GRP_LAI,LAI_DATE,20180629 -US-ARM,89896,GRP_LAI,LAI_COMMENT,Alfalfa -US-ARM,89912,GRP_LAI,LAI,1.6 -US-ARM,89912,GRP_LAI,LAI_TYPE,PAI -US-ARM,89912,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89912,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89912,GRP_LAI,LAI_STATISTIC,Minimum -US-ARM,89912,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89912,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89912,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89912,GRP_LAI,LAI_DATE,20180928 -US-ARM,89912,GRP_LAI,LAI_COMMENT,Alfalfa -US-ARM,89600,GRP_LAI,LAI,1.7 -US-ARM,89600,GRP_LAI,LAI_TYPE,PAI -US-ARM,89600,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89600,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89600,GRP_LAI,LAI_STATISTIC,Mean -US-ARM,89600,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89600,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89600,GRP_LAI,LAI_DATE,20030327 -US-ARM,89600,GRP_LAI,LAI_COMMENT,wheat -US-ARM,89636,GRP_LAI,LAI,1.7 -US-ARM,89636,GRP_LAI,LAI_TYPE,PAI -US-ARM,89636,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89636,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89636,GRP_LAI,LAI_STATISTIC,Mean -US-ARM,89636,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89636,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89636,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89636,GRP_LAI,LAI_DATE,20060406 -US-ARM,89636,GRP_LAI,LAI_COMMENT,wheat -US-ARM,89698,GRP_LAI,LAI,1.7 -US-ARM,89698,GRP_LAI,LAI_TYPE,PAI -US-ARM,89698,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89698,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89698,GRP_LAI,LAI_STATISTIC,Minimum -US-ARM,89698,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89698,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89698,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89698,GRP_LAI,LAI_DATE,20090507 -US-ARM,89698,GRP_LAI,LAI_COMMENT,wheat -US-ARM,89708,GRP_LAI,LAI,1.7 -US-ARM,89708,GRP_LAI,LAI_TYPE,PAI -US-ARM,89708,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89708,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89708,GRP_LAI,LAI_STATISTIC,Mean -US-ARM,89708,GRP_LAI,LAI_STATISTIC_TYPE,Spatial 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-US-ARM,89851,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89851,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89851,GRP_LAI,LAI_DATE,20170502 -US-ARM,89851,GRP_LAI,LAI_COMMENT,Alfalfa -US-ARM,89655,GRP_LAI,LAI,5.1 -US-ARM,89655,GRP_LAI,LAI_TYPE,PAI -US-ARM,89655,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89655,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89655,GRP_LAI,LAI_STATISTIC,Maximum -US-ARM,89655,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89655,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89655,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89655,GRP_LAI,LAI_DATE,20070416 -US-ARM,89655,GRP_LAI,LAI_COMMENT,wheat -US-ARM,89715,GRP_LAI,LAI,5.1 -US-ARM,89715,GRP_LAI,LAI_TYPE,PAI -US-ARM,89715,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89715,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89715,GRP_LAI,LAI_STATISTIC,Maximum -US-ARM,89715,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89715,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89715,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89715,GRP_LAI,LAI_DATE,20100427 -US-ARM,89715,GRP_LAI,LAI_COMMENT,wheat -US-ARM,89659,GRP_LAI,LAI,5.3 -US-ARM,89659,GRP_LAI,LAI_TYPE,PAI -US-ARM,89659,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89659,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89659,GRP_LAI,LAI_STATISTIC,Maximum -US-ARM,89659,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89659,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89659,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89659,GRP_LAI,LAI_DATE,20070427 -US-ARM,89659,GRP_LAI,LAI_COMMENT,wheat -US-ARM,89731,GRP_LAI,LAI,5.7 -US-ARM,89731,GRP_LAI,LAI_TYPE,PAI -US-ARM,89731,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89731,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89731,GRP_LAI,LAI_STATISTIC,Maximum -US-ARM,89731,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89731,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89731,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89731,GRP_LAI,LAI_DATE,20120405 -US-ARM,89731,GRP_LAI,LAI_COMMENT,wheat -US-ARM,89711,GRP_LAI,LAI,5.9 -US-ARM,89711,GRP_LAI,LAI_TYPE,PAI -US-ARM,89711,GRP_LAI,LAI_CANOPY_TYPE,Total -US-ARM,89711,GRP_LAI,LAI_VEGTYPE,Crop -US-ARM,89711,GRP_LAI,LAI_STATISTIC,Maximum -US-ARM,89711,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-ARM,89711,GRP_LAI,LAI_STATISTIC_NUMBER,10 -US-ARM,89711,GRP_LAI,LAI_METHOD,LAI_2000 -US-ARM,89711,GRP_LAI,LAI_DATE,20100412 -US-ARM,89711,GRP_LAI,LAI_COMMENT,wheat -US-ARM,11131,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -US-ARM,22344,GRP_LOCATION,LOCATION_LAT,36.6058 -US-ARM,22344,GRP_LOCATION,LOCATION_LONG,-97.4888 -US-ARM,22344,GRP_LOCATION,LOCATION_ELEV,314 -US-ARM,22344,GRP_LOCATION,LOCATION_DATE_START,20021218 -US-ARM,23900,GRP_NEP,NEP,600 -US-ARM,23900,GRP_NEP,NEP_COMMENT,"0.41/ 0.88 / 0.51 -wheat 2002,2003,2006" -US-ARM,11133,GRP_NETWORK,NETWORK,AmeriFlux -US-ARM,22333,GRP_NETWORK,NETWORK,Phenocam -US-ARM,1700006339,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Bagley, J. E., Kueppers, L. M., Billesbach, D. P., Williams, I. N., Biraud, S. C., Torn, M. S. (2017) The Influence Of Land Cover On Surface Energy Partitioning And Evaporative Fraction Regimes In The U.S. Southern Great Plains, Journal Of Geophysical Research: Atmospheres, 122(11), 5793-5807" -US-ARM,1700006339,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/2017JD026740 -US-ARM,1700006339,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-ARM,1700008565,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Baker, I. T., Sellers, P. J., Denning, A. S., Medina, I., Kraus, P., Haynes, K. D., Biraud, S. C. (2017) Closing The Scale Gap Between Land Surface Parameterizations And Gcms With A New Scheme, Sib3-Bins, Journal Of Advances In Modeling Earth Systems, 9(1), 691-711" -US-ARM,1700008565,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/2016MS000764 -US-ARM,1700008565,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-ARM,1700007827,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Baldocchi, D., Penuelas, J. (2018) The Physics And Ecology Of Mining Carbon Dioxide From The Atmosphere By Ecosystems, Global Change Biology, 122(11), 5793-5807" -US-ARM,1700007827,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/GCB.14559 -US-ARM,1700007827,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-ARM,1700005691,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Barr, A., Richardson, A., Hollinger, D., Papale, D., Arain, M., Black, T., Bohrer, G., Dragoni, D., Fischer, M., Gu, L., Law, B., Margolis, H., McCaughey, J., Munger, J., Oechel, W., Schaeffer, K. (2013) Use Of Change-Point Detection For Friction–Velocity Threshold Evaluation In Eddy-Covariance Studies, Agricultural And Forest Meteorology, 171-172(7), 31-45" -US-ARM,1700005691,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2012.11.023 -US-ARM,1700005691,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-ARM,1700000675,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(6), 108350" -US-ARM,1700000675,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -US-ARM,1700000675,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-ARM,1700007242,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Dennis Baldocchi, Cove Sturtevant (2015) Does day and night sampling reduce spurious correlation between canopy photosynthesis and ecosystem respiration?, Agricultural and Forest Meteorology, 207(), 117-126" -US-ARM,1700007242,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2015.03.010 -US-ARM,1700007242,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-ARM,1700004974,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Fischer, M. L., Billesbach, D. P., Berry, J. A., Riley, W. J., Torn, M. S. (2007) Spatiotemporal Variations In Growing Season Exchanges Of Co2, H2o, And Sensible Heat In Agricultural Fields Of The Southern Great Plains, Earth Interactions, 11(17), 1-21" -US-ARM,1700004974,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1175/EI231.1 -US-ARM,1700004974,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Primary_Citation -US-ARM,1700002856,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Lu, Y., Williams, I. N., Bagley, J. E., Torn, M. S., Kueppers, L. M. (2017) Representing Winter Wheat In The Community Land Model (Version 4.5), Geoscientific Model Development, 10(5), 1873-1888" -US-ARM,1700002856,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.5194/GMD-10-1873-2017 -US-ARM,1700002856,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-ARM,1700001134,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Matheny, A. M., Bohrer, G., Stoy, P. C., Baker, I. T., Black, A. T., Desai, A. R., Dietze, M. C., Gough, C. M., Ivanov, V. Y., Jassal, R. S., Novick, K. A., Schäfer, K. V., Verbeeck, H. (2014) Characterizing The Diurnal Patterns of Errors in The Prediction of Evapotranspiration by Several Land-Surface Models: An Nacp Analysis, Journal Of Geophysical Research: Biogeosciences, 119(7), 1458-1473" -US-ARM,1700001134,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/2014JG002623 -US-ARM,1700001134,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-ARM,1700002571,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"McCombs, A. G., Hiscox, A. L., Wang, C., Desai, A. R., Suyker, A. E., Biraud, S. C. (2018) Carbon Flux Phenology From The Sky: Evaluation For Maize And Soybean, Journal Of Atmospheric And Oceanic Technology, 35(4), 877-892" -US-ARM,1700002571,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1175/JTECH-D-17-0004.1 -US-ARM,1700002571,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-ARM,1700000480,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Novick, K. A., Ficklin, D. L., Stoy, P. C., Williams, C. A., Bohrer, G., Oishi, A., Papuga, S. A., Blanken, P. D., Noormets, A., Sulman, B. N., Scott, R. L., Wang, L., Phillips, R. P. (2016) The Increasing Importance Of Atmospheric Demand For Ecosystem Water And Carbon Fluxes, Nature Climate Change, 6(11), 1023-1027" -US-ARM,1700000480,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1038/NCLIMATE3114 -US-ARM,1700000480,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-ARM,1700005298,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Novick, K. A., Konings, A. G., Gentine, P. (2019) Beyond Soil Water Potential: An Expanded View On Isohydricity Including Land–Atmosphere Interactions And Phenology, Plant, Cell & Environment, 42(6), 1802-1815" -US-ARM,1700005298,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/PCE.13517 -US-ARM,1700005298,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-ARM,1700002982,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Raczka, B., Biraud, S. C., Ehleringer, J. R., Lai, C., Miller, J. B., Pataki, D. E., Saleska, S. R., Torn, M. S., Vaughn, B. H., Wehr, R., Bowling, D. R. (2017) Does Vapor Pressure Deficit Drive The Seasonality Of δ13C Of The Net Land-Atmosphere Co2 Exchange Across The United States?, Journal Of Geophysical Research: Biogeosciences, 122(8), 1969-1987" -US-ARM,1700002982,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/2017JG003795 -US-ARM,1700002982,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-ARM,1700008799,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Raz-Yaseef, N., Billesbach, D. P., Fischer, M. L., Biraud, S. C., Gunter, S. A., Bradford, J. A., Torn, M. S. (2015) Vulnerability Of Crops And Native Grasses To Summer Drying In The U.S. Southern Great Plains, Agriculture, Ecosystems & Environment, 213(), 209-218" -US-ARM,1700008799,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGEE.2015.07.021 -US-ARM,1700008799,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Primary_Citation -US-ARM,1700005937,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Riley, W. J., Biraud, S. C., Torn, M. S., Fischer, M. L., Billesbach, D. P., Berry, J. A. (2009) Regional Co2and Latent Heat Surface Fluxes In The Southern Great Plains: Measurements, Modeling, And Scaling, Journal Of Geophysical Research, 114(G4), 181-195" -US-ARM,1700005937,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2009JG001003 -US-ARM,1700005937,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-ARM,1700004023,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Still, C. J., Riley, W. J., Biraud, S. C., Noone, D. C., Buenning, N. H., Randerson, J. T., Torn, M. S., Welker, J., White, J. W., Vachon, R., Farquhar, G. D., Berry, J. A. (2009) Influence Of Clouds And Diffuse Radiation On Ecosystem-Atmosphere Co2and Co18o Exchanges, Journal Of Geophysical Research, 114(G1), 181-195" -US-ARM,1700004023,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2007JG000675 -US-ARM,1700004023,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-ARM,1700007710,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Sullivan, R. C., Cook, D. R., Ghate, V. P., Kotamarthi, V. R., Feng, Y. (2019) Improved Spatiotemporal Representativeness And Bias Reduction Of Satellite-Based Evapotranspiration Retrievals Via Use Of In Situ Meteorology And Constrained Canopy Surface Resistance, Journal Of Geophysical Research: Biogeosciences, 124(2), 342-352" -US-ARM,1700007710,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018JG004744 -US-ARM,1700007710,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-ARM,1700000990,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Sullivan, R. C., Kotamarthi, V. R., Feng, Y. (2019) Recovering Evapotranspiration Trends From Biased CMIP5 Simulations And Sensitivity To Changing Climate Over North America, Journal Of Hydrometeorology, 20(8), 1619-1633" -US-ARM,1700000990,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1175/JHM-D-18-0259.1 -US-ARM,1700000990,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-ARM,1700000054,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Toomey, M., Friedl, M. A., Frolking, S., Hufkens, K., Klosterman, S., Sonnentag, O., Baldocchi, D. D., Bernacchi, C. J., Biraud, S. C., Bohrer, G., Brzostek, E., Burns, S. P., Coursolle, C., Hollinger, D. Y., Margolis, H. A., McCaughey, H., Monson, R. K., Munger, J. W., Pallardy, S., Phillips, R. P., Torn, M. S., Wharton, S., Zeri, M., Richardson, A. D. (2015) Greenness Indices From Digital Cameras Predict The Timing And Seasonal Dynamics Of Canopy-Scale Photosynthesis, Ecological Applications, 25(1), 99-115" -US-ARM,1700000054,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1890/14-0005.1 -US-ARM,1700000054,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-ARM,1700000309,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Torn, M. S., Biraud, S. C., Still, C. J., Riley, W. J., Berry, J. A. (2011) Seasonal And Interannual Variability In 13c Composition Of Ecosystem Carbon Fluxes In The U.S. Southern Great Plains, Tellus B: Chemical And Physical Meteorology, 63(2), 181-195" -US-ARM,1700000309,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/J.1600-0889.2010.00519.X -US-ARM,1700000309,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-ARM,1700006846,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Wharton, S., Simpson, M., Osuna, J., Newman, J., Biraud, S. (2014) Role Of Surface Energy Exchange For Simulating Wind Turbine Inflow: A Case Study In The Southern Great Plains, Usa, Atmosphere, 6(1), 21-49" -US-ARM,1700006846,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.3390/ATMOS6010021 -US-ARM,1700006846,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-ARM,1700007479,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Williams, I. N., Lu, Y., Kueppers, L. M., Riley, W. J., Biraud, S. C., Bagley, J. E., Torn, M. S. (2016) Land-Atmosphere Coupling And Climate Prediction Over The U.S. Southern Great Plains, Journal Of Geophysical Research: Atmospheres, 121(20), 12,125-12,144" -US-ARM,1700007479,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/2016JD025223 -US-ARM,1700007479,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-ARM,1700009033,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Williams, I. N., Riley, W. J., Kueppers, L. M., Biraud, S. C., Torn, M. S. (2016) Separating The Effects Of Phenology And Diffuse Radiation On Gross Primary Productivity In Winter Wheat, Journal Of Geophysical Research: Biogeosciences, 121(7), 1903-1915" -US-ARM,1700009033,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/2015JG003317 -US-ARM,1700009033,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-ARM,1700002241,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Williams, I. N., Riley, W. J., Torn, M. S., Biraud, S. C., Fischer, M. L. (2014) Biases In Regional Carbon Budgets From Covariation Of Surface Fluxes And Weather In Transport Model Inversions, Atmospheric Chemistry And Physics, 14(3), 1571-1585" -US-ARM,1700002241,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.5194/ACP-14-1571-2014 -US-ARM,1700002241,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-ARM,1700006831,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Zhang, Q., Ficklin, D. L., Manzoni, S., Wang, L., Way, D., Phillips, R. P., Novick, K. A. (2019) Response Of Ecosystem Intrinsic Water Use Efficiency And Gross Primary Productivity To Rising Vapor Pressure Deficit, Environmental Research Letters, 14(7), 074023" -US-ARM,1700006831,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1088/1748-9326/AB2603 -US-ARM,1700006831,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-ARM,29689,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,The research focus of the ARM SGP Main site is carbon dioxide and water dynamics at a regional scale; influence of the land surface on carbon dioxide in the boundary layer; and land-atmosphere interactions for example involving convection. -US-ARM,22347,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"George Sawyer -ARM SGP 309600 -Billings, OK 74630-2045" -US-ARM,22338,GRP_SITE_CHAR,TERRAIN,"Medium Slope (>2 %, <5%)" -US-ARM,22338,GRP_SITE_CHAR,WIND_DIRECTION,S -US-ARM,22338,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,370 -US-ARM,22338,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,7 -US-ARM,29687,GRP_SITE_DESC,SITE_DESC,"Central facility tower crop field (winter wheat, corn, soy, alfalfa). The site also has continuous measurements of precise mixing ratios of CO2, CH4, CO, N2O, and isotopic ratio of 13CO2. In addition to 4 m system, there are sonic anemometers at 25 m and 60 m." -US-ARM,22339,GRP_SITE_FUNDING,SITE_FUNDING,DOE/ARM -US-ARM,24464,GRP_SOIL_CHEM,SOIL_CHEM_C_ORG,1500 -US-ARM,23828,GRP_SOIL_CHEM,SOIL_CHEM_BD,1.0 -US-ARM,24464,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,0 -US-ARM,23828,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,5 -US-ARM,23828,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,25 -US-ARM,24464,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,25 -US-ARM,23828,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,Total -US-ARM,24464,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,Total -US-ARM,23828,GRP_SOIL_CHEM,SOIL_CHEM_DATE,20020331 -US-ARM,24464,GRP_SOIL_CHEM,SOIL_CHEM_DATE,20020331 -US-ARM,29314,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION,"Renfrow-silty clay loam, fine mixed thermic Udertic Paleustolls" -US-ARM,29314,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION_TAXONOMY,Other -US-ARM,24493,GRP_SOIL_DEPTH,SOIL_DEPTH,25 -US-ARM,24493,GRP_SOIL_DEPTH,SOIL_DEPTH_DATE,2007 -US-ARM,24586,GRP_SOIL_TEX,SOIL_TEX_SAND,27.98 -US-ARM,24586,GRP_SOIL_TEX,SOIL_TEX_SILT,28.92 -US-ARM,24586,GRP_SOIL_TEX,SOIL_TEX_CLAY,43.10 -US-ARM,24241,GRP_SOIL_TEX,SOIL_TEX_WATER_HOLD_CAP,114 -US-ARM,24241,GRP_SOIL_TEX,SOIL_TEX_PROFILE_MIN,0 -US-ARM,24241,GRP_SOIL_TEX,SOIL_TEX_PROFILE_MAX,25 -US-ARM,24241,GRP_SOIL_TEX,SOIL_TEX_HORIZON,Total -US-ARM,24586,GRP_SOIL_TEX,SOIL_TEX_HORIZON,Total -US-ARM,24241,GRP_SOIL_TEX,SOIL_TEX_DATE,2007 -US-ARM,24586,GRP_SOIL_TEX,SOIL_TEX_DATE,2007 -US-ARM,24179,GRP_SPP_O,SPP_O,"wheat (2002,2003,2004,2006); corn ( 2005) soybeans (in 2006 soybeans were planted after wheat, rather than fallow)" -US-ARM,25371,GRP_SPP_U,SPP_U,GLYCI (NRCS plant code) -US-ARM,23982,GRP_SPP_U,SPP_U,TRAE (NRCS plant code) -US-ARM,24626,GRP_SPP_U,SPP_U,TRAE (NRCS plant code) -US-ARM,24627,GRP_SPP_U,SPP_U,TRAE (NRCS plant code) -US-ARM,25133,GRP_SPP_U,SPP_U,TRAE (NRCS plant code) -US-ARM,24240,GRP_SPP_U,SPP_U,ZEMA (NRCS plant code) -US-ARM,23982,GRP_SPP_U,SPP_U_PERC,100 -US-ARM,24240,GRP_SPP_U,SPP_U_PERC,100 -US-ARM,24626,GRP_SPP_U,SPP_U_PERC,100 -US-ARM,24627,GRP_SPP_U,SPP_U_PERC,100 -US-ARM,25133,GRP_SPP_U,SPP_U_PERC,100 -US-ARM,25371,GRP_SPP_U,SPP_U_PERC,100 -US-ARM,23982,GRP_SPP_U,SPP_DATE,2002 -US-ARM,25133,GRP_SPP_U,SPP_DATE,2003 -US-ARM,24626,GRP_SPP_U,SPP_DATE,2004 -US-ARM,24240,GRP_SPP_U,SPP_DATE,2005 -US-ARM,24627,GRP_SPP_U,SPP_DATE,2006 -US-ARM,25371,GRP_SPP_U,SPP_DATE,20061101 -US-ARM,11140,GRP_STATE,STATE,OK -US-ARM,22335,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Sebastien Biraud -US-ARM,22335,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-ARM,22335,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,SCBiraud@lbl.gov -US-ARM,22335,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Lawrence Berkeley National Laboratory -US-ARM,22335,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,One Cyclotron Road Berkeley CA 94720 -US-ARM,29688,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Margaret Torn -US-ARM,29688,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,AncContact -US-ARM,29688,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,mstorn@lbl.gov -US-ARM,29688,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Lawrence Berkeley National Laboratory -US-ARM,29688,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,One Cyclotron Road Berkeley CA 94720 -US-ARM,30892,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Stephen Chan -US-ARM,30892,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,AncContact -US-ARM,30892,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,SWChan@lbl.gov -US-ARM,30892,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Lawrence Berkeley National Laboratory -US-ARM,30892,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,One Cyclotron Road Berkeley CA 94720 -US-ARM,29803,GRP_TOWER_POWER,TOWER_POWER,Direct power -US-ARM,22337,GRP_TOWER_TYPE,TOWER_TYPE,tripod -US-ARM,11142,GRP_URL,URL,http://www.arm.gov/sites/sgp -US-ARM,24000331,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-ARM -US-ARM,11143,GRP_UTC_OFFSET,UTC_OFFSET,-6 -US-ASH,86816,GRP_CLIM_AVG,MAT,18.1 -US-ASH,86816,GRP_CLIM_AVG,MAP,210 -US-ASH,86816,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Bwk -US-ASH,27001069,GRP_COUNTRY,COUNTRY,USA -US-ASH,92865,GRP_DOI,DOI,10.17190/AMF/1634880 -US-ASH,92865,GRP_DOI,DOI_CITATION,"Ray G. Anderson (2020), AmeriFlux BASE US-ASH USSL San Joaquin Valley Almond High Salinity, Ver. 1-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1634880" -US-ASH,92865,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-ASH,92838,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-ASH,92838,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Ray G. Anderson -US-ASH,92838,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-ASH,92838,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,ray.anderson@usda.gov -US-ASH,92838,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"USDA-Agricultural Research Service, US Salinity Laboratory" -US-ASH,92855,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,"USDA-Agricultural Research Service, US Salinity Laboratory" -US-ASH,92855,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-ASH,92845,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,USDA ARS Office of National Programs (NP 211) -US-ASH,92845,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-ASH,86815,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Agriculture -US-ASH,86829,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-ASH,86829,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-ASH,86829,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201610121730 -US-ASH,86829,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-ASH,86829,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,Will be operational through end of 2019 growing season -US-ASH,86825,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-ASH,86825,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-ASH,86825,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201610121730 -US-ASH,86825,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-ASH,86825,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,Will be operational through end of 2019 growing season -US-ASH,86819,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-ASH,86819,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-ASH,86819,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201610121730 -US-ASH,86819,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-ASH,86819,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,Will be operational through end of 2019 growing season -US-ASH,23001069,GRP_HEADER,SITE_NAME,USSL San Joaquin Valley Almond High Salinity -US-ASH,86827,GRP_IGBP,IGBP,DBF -US-ASH,86827,GRP_IGBP,IGBP_DATE_START,199802010000 -US-ASH,86827,GRP_IGBP,IGBP_COMMENT,almond orchard -US-ASH,86813,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -US-ASH,86813,GRP_LAND_OWNERSHIP,LAND_OWNER,Not public at this time -US-ASH,86820,GRP_LOCATION,LOCATION_LAT,36.1697 -US-ASH,86820,GRP_LOCATION,LOCATION_LONG,-120.2010 -US-ASH,86820,GRP_LOCATION,LOCATION_ELEV,147 -US-ASH,86820,GRP_LOCATION,LOCATION_DATE_START,201610121730 -US-ASH,86820,GRP_LOCATION,LOCATION_COMMENT,93 ha orchard in trapezoidal shape -US-ASH,86828,GRP_NETWORK,NETWORK,AmeriFlux -US-ASH,86826,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,Soil and water salinity impact on crop productivity and water use -US-ASH,86822,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"George E. Brown Jr. Salinity Laboratory Building, 450 W. Big Springs Rd., Riverside, CA 92507-4617USA" -US-ASH,86818,GRP_SITE_CHAR,TERRAIN,Flat -US-ASH,86818,GRP_SITE_CHAR,ASPECT,NW -US-ASH,86818,GRP_SITE_CHAR,WIND_DIRECTION,NW -US-ASH,86818,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,600 -US-ASH,86818,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,0 -US-ASH,86823,GRP_SITE_FUNDING,SITE_FUNDING,USDA ARS Office of National Programs (NP 211) -US-ASH,86821,GRP_STATE,STATE,CA -US-ASH,86814,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Ray G. Anderson -US-ASH,86814,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-ASH,86814,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,ray.anderson@usda.gov -US-ASH,86814,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"USDA-Agricultural Research Service, US Salinity Laboratory" -US-ASH,86814,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"George E. Brown Jr. Salinity Laboratory Building, 450 W. Big Springs Rd., Riverside, CA 92507-4617 USA" -US-ASH,86817,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-ASH,86812,GRP_TOWER_TYPE,TOWER_TYPE,walk-up -US-ASH,24001069,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-ASH -US-ASH,86824,GRP_UTC_OFFSET,UTC_OFFSET,-7 -US-ASH,86824,GRP_UTC_OFFSET,UTC_OFFSET_DATE_START,201610121730 -US-ASH,86824,GRP_UTC_OFFSET,UTC_OFFSET_COMMENT,Dataloggers kept in Pacific Daylight Time (GMT-7) year round -US-ASL,86757,GRP_CLIM_AVG,MAT,16.7 -US-ASL,86757,GRP_CLIM_AVG,MAP,311 -US-ASL,86757,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Bwk -US-ASL,27001067,GRP_COUNTRY,COUNTRY,USA -US-ASL,91684,GRP_DOI,DOI,10.17190/AMF/1617706 -US-ASL,91684,GRP_DOI,DOI_CITATION,"Ray G. Anderson (2020), AmeriFlux BASE US-ASL USSL San Joaquin Valley Almond Low Salinity, Ver. 1-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1617706" -US-ASL,91684,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-ASL,91589,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-ASL,91589,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Ray G. Anderson -US-ASL,91589,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-ASL,91589,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,ray.anderson@usda.gov -US-ASL,91589,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"USDA-Agricultural Research Service, US Salinity Laboratory" -US-ASL,91653,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,"USDA-Agricultural Research Service, US Salinity Laboratory" -US-ASL,91653,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-ASL,91637,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,USDA ARS Office of National Programs (NP 211) -US-ASL,91637,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-ASL,86758,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Agriculture -US-ASL,86764,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-ASL,86764,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-ASL,86764,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201610041230 -US-ASL,86764,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-ASL,86764,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,Will be operational through end of 2019 growing season -US-ASL,86755,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-ASL,86755,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-ASL,86755,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201610041230 -US-ASL,86755,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-ASL,86755,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,Will be operational through end of 2019 growing season -US-ASL,86772,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-ASL,86772,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-ASL,86772,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201610041230 -US-ASL,86772,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-ASL,86772,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,Will be operational through end of 2019 growing season -US-ASL,23001067,GRP_HEADER,SITE_NAME,USSL San Joaquin Valley Almond Low Salinity -US-ASL,86766,GRP_IGBP,IGBP,DBF -US-ASL,86766,GRP_IGBP,IGBP_DATE_START,201002010000 -US-ASL,86766,GRP_IGBP,IGBP_COMMENT,almond orchard -US-ASL,86767,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -US-ASL,86767,GRP_LAND_OWNERSHIP,LAND_OWNER,Not public at this time -US-ASL,86760,GRP_LOCATION,LOCATION_LAT,36.9466 -US-ASL,86760,GRP_LOCATION,LOCATION_LONG,-120.1024 -US-ASL,86760,GRP_LOCATION,LOCATION_ELEV,78 -US-ASL,86760,GRP_LOCATION,LOCATION_DATE_START,201610041230 -US-ASL,86760,GRP_LOCATION,LOCATION_COMMENT,16.2 ha orchard -US-ASL,86763,GRP_NETWORK,NETWORK,AmeriFlux -US-ASL,86759,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,Soil and water salinity impact on crop productivity and water use -US-ASL,86773,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"George E. Brown Jr. Salinity Laboratory Building, 450 W. Big Springs Rd., Riverside, CA 92507-4617USA" -US-ASL,86765,GRP_SITE_CHAR,TERRAIN,Flat -US-ASL,86765,GRP_SITE_CHAR,ASPECT,NW -US-ASL,86765,GRP_SITE_CHAR,WIND_DIRECTION,NW -US-ASL,86765,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,300 -US-ASL,86765,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,0 -US-ASL,86762,GRP_SITE_DESC,SITE_DESC,almond orchard in San Joaquin Valley. Lowest salinity almond orchard in network -US-ASL,86756,GRP_SITE_FUNDING,SITE_FUNDING,USDA ARS Office of National Programs (NP 211) -US-ASL,86770,GRP_STATE,STATE,CA -US-ASL,86761,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Ray G. Anderson -US-ASL,86761,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-ASL,86761,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,ray.anderson@usda.gov -US-ASL,86761,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"USDA-Agricultural Research Service, US Salinity Laboratory" -US-ASL,86761,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"George E. Brown Jr. Salinity Laboratory Building, 450 W. Big Springs Rd., Riverside, CA 92507-4617 USA" -US-ASL,86771,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-ASL,86769,GRP_TOWER_TYPE,TOWER_TYPE,walk-up -US-ASL,24001067,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-ASL -US-ASL,86768,GRP_UTC_OFFSET,UTC_OFFSET,-7 -US-ASL,86768,GRP_UTC_OFFSET,UTC_OFFSET_DATE_START,201610041230 -US-ASL,86768,GRP_UTC_OFFSET,UTC_OFFSET_COMMENT,Dataloggers kept in Pacific Daylight Time (GMT-7) year round -US-ASM,86745,GRP_CLIM_AVG,MAT,18.1 -US-ASM,86745,GRP_CLIM_AVG,MAP,210 -US-ASM,86745,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Bwk -US-ASM,27001068,GRP_COUNTRY,COUNTRY,USA -US-ASM,91707,GRP_DOI,DOI,10.17190/AMF/1617709 -US-ASM,91707,GRP_DOI,DOI_CITATION,"Ray G. Anderson (2020), AmeriFlux BASE US-ASM USSL San Joaquin Valley Almond Medium Salinity, Ver. 1-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1617709" -US-ASM,91707,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-ASM,91590,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-ASM,91590,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Ray G. Anderson -US-ASM,91590,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-ASM,91590,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,ray.anderson@usda.gov -US-ASM,91590,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"USDA-Agricultural Research Service, US Salinity Laboratory" -US-ASM,91659,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,"USDA-Agricultural Research Service, US Salinity Laboratory" -US-ASM,91659,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-ASM,91631,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,USDA ARS Office of National Programs (NP 211) -US-ASM,91631,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-ASM,86738,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Agriculture -US-ASM,86740,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-ASM,86740,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-ASM,86740,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201609271730 -US-ASM,86740,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-ASM,86740,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,Will be operational through end of 2019 growing season -US-ASM,86739,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-ASM,86739,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-ASM,86739,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201609271730 -US-ASM,86739,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-ASM,86739,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,Will be operational through end of 2019 growing season -US-ASM,86746,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-ASM,86746,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-ASM,86746,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201609271730 -US-ASM,86746,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-ASM,86746,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,Will be operational through end of 2019 growing season -US-ASM,23001068,GRP_HEADER,SITE_NAME,USSL San Joaquin Valley Almond Medium Salinity -US-ASM,86736,GRP_IGBP,IGBP,DBF -US-ASM,86736,GRP_IGBP,IGBP_DATE_START,200602010000 -US-ASM,86736,GRP_IGBP,IGBP_COMMENT,almond orchard -US-ASM,86748,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -US-ASM,86748,GRP_LAND_OWNERSHIP,LAND_OWNER,Not public at this time -US-ASM,86749,GRP_LOCATION,LOCATION_LAT,36.1777 -US-ASM,86749,GRP_LOCATION,LOCATION_LONG,-120.2026 -US-ASM,86749,GRP_LOCATION,LOCATION_ELEV,147 -US-ASM,86749,GRP_LOCATION,LOCATION_DATE_START,201609271730 -US-ASM,86749,GRP_LOCATION,LOCATION_COMMENT,40.5 ha orchard -US-ASM,86743,GRP_NETWORK,NETWORK,AmeriFlux -US-ASM,86750,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,Soil and water salinity impact on crop productivity and water use -US-ASM,86747,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"George E. Brown Jr. Salinity Laboratory Building, 450 W. Big Springs Rd., Riverside, CA 92507-4617USA" -US-ASM,86751,GRP_SITE_CHAR,TERRAIN,Flat -US-ASM,86751,GRP_SITE_CHAR,ASPECT,NW -US-ASM,86751,GRP_SITE_CHAR,WIND_DIRECTION,NW -US-ASM,86751,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,450 -US-ASM,86751,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,0 -US-ASM,86742,GRP_SITE_DESC,SITE_DESC,almond orchard in San Joaquin Valley. Different water source and water quality than adjacent site US-SAH -US-ASM,86744,GRP_SITE_FUNDING,SITE_FUNDING,USDA ARS Office of National Programs (NP 211) -US-ASM,86753,GRP_STATE,STATE,CA -US-ASM,86754,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Ray G. Anderson -US-ASM,86754,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-ASM,86754,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,ray.anderson@usda.gov -US-ASM,86754,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"USDA-Agricultural Research Service, US Salinity Laboratory" -US-ASM,86754,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"George E. Brown Jr. Salinity Laboratory Building, 450 W. Big Springs Rd., Riverside, CA 92507-4617 USA" -US-ASM,86737,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-ASM,86741,GRP_TOWER_TYPE,TOWER_TYPE,walk-up -US-ASM,24001068,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-ASM -US-ASM,86752,GRP_UTC_OFFSET,UTC_OFFSET,-7 -US-ASM,86752,GRP_UTC_OFFSET,UTC_OFFSET_DATE_START,201609271730 -US-ASM,86752,GRP_UTC_OFFSET,UTC_OFFSET_COMMENT,Dataloggers kept in Pacific Daylight Time (GMT-7) year round -US-Bar,95074,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,Research at the Bartlett Experimental Forest tower is supported by the USDA Forest Service's Northern Research Station and the National Science Foundation (grant DEB-1114804). -US-Bar,24793,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER,10.73 -US-Bar,24793,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_ORGAN,Total -US-Bar,24793,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_PHEN,Mixed/unknown -US-Bar,24793,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_UNIT,kgDM m-2 -US-Bar,24793,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_COMMENT,10730 g m-2 -US-Bar,24497,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,10600 -US-Bar,24497,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Wood -US-Bar,24497,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-Bar,24497,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-Bar,24497,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,"C.M. Hoover (Ed.). 2008. Field measurements for forest carbon monitoring: A landscape-scale approach. Springer, New York (in press)." -US-Bar,24497,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,20040530 -US-Bar,24497,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,12 FIA plots surrounding tower -US-Bar,24091,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,150 -US-Bar,24091,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Foliage -US-Bar,24091,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-Bar,24091,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-Bar,24091,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,20040530 -US-Bar,24091,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,12 FIA plots surrounding tower -US-Bar,25003,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS,110 -US-Bar,25003,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_UNIT,gC m-2 -US-Bar,25003,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_DATE,2004 -US-Bar,25003,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_COMMENT,leaf litter (annual) -US-Bar,24246,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS,25 -US-Bar,24246,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_UNIT,gC m-2 -US-Bar,24246,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_DATE,2004 -US-Bar,24246,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_COMMENT,large branches (annual) -US-Bar,24245,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS,40 -US-Bar,24245,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_UNIT,gC m-2 -US-Bar,24245,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_DATE,2004 -US-Bar,24245,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_COMMENT,other (annual) -US-Bar,24092,GRP_AG_PROD_TREE,AG_PROD_TREE,120 -US-Bar,24092,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Wood -US-Bar,24092,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-Bar,24092,GRP_AG_PROD_TREE,AG_PROD_APPROACH,"C.M. Hoover (Ed.). 2008. Field measurements for forest carbon monitoring: A landscape-scale approach. Springer, New York (in press)." -US-Bar,24092,GRP_AG_PROD_TREE,AG_PROD_DATE_START,2006 -US-Bar,24248,GRP_AG_PROD_TREE,AG_PROD_TREE,120 -US-Bar,24248,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Wood -US-Bar,24248,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-Bar,24248,GRP_AG_PROD_TREE,AG_PROD_APPROACH,"C.M. Hoover (Ed.). 2008. Field measurements for forest carbon monitoring: A landscape-scale approach. Springer, New York (in press)." -US-Bar,24248,GRP_AG_PROD_TREE,AG_PROD_DATE_START,2004 -US-Bar,25135,GRP_AG_PROD_TREE,AG_PROD_TREE,120 -US-Bar,25135,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Wood -US-Bar,25135,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-Bar,25135,GRP_AG_PROD_TREE,AG_PROD_APPROACH,"C.M. Hoover (Ed.). 2008. Field measurements for forest carbon monitoring: A landscape-scale approach. Springer, New York (in press)." -US-Bar,25135,GRP_AG_PROD_TREE,AG_PROD_DATE_START,2005 -US-Bar,24247,GRP_AG_PROD_TREE,AG_PROD_TREE,150 -US-Bar,24247,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Foliage -US-Bar,24247,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-Bar,24247,GRP_AG_PROD_TREE,AG_PROD_DATE_START,2004 -US-Bar,24635,GRP_AG_PROD_TREE,AG_PROD_TREE,150 -US-Bar,24635,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Foliage -US-Bar,24635,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-Bar,24635,GRP_AG_PROD_TREE,AG_PROD_DATE_START,2005 -US-Bar,24636,GRP_AG_PROD_TREE,AG_PROD_TREE,150 -US-Bar,24636,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Foliage -US-Bar,24636,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-Bar,24636,GRP_AG_PROD_TREE,AG_PROD_DATE_START,2006 -US-Bar,28779,GRP_BIOMASS_CHEM,BIOMASS_N,0.091 -US-Bar,28780,GRP_BIOMASS_CHEM,BIOMASS_N,0.143 -US-Bar,27181,GRP_BIOMASS_CHEM,BIOMASS_N,0.155 -US-Bar,27727,GRP_BIOMASS_CHEM,BIOMASS_N,0.172 -US-Bar,28778,GRP_BIOMASS_CHEM,BIOMASS_N,0.208 -US-Bar,28777,GRP_BIOMASS_CHEM,BIOMASS_N,0.21 -US-Bar,28808,GRP_BIOMASS_CHEM,BIOMASS_N,0.211 -US-Bar,27182,GRP_BIOMASS_CHEM,BIOMASS_N,0.219 -US-Bar,29416,GRP_BIOMASS_CHEM,BIOMASS_N,0.222 -US-Bar,28428,GRP_BIOMASS_CHEM,BIOMASS_N,0.255 -US-Bar,27181,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-Bar,27182,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-Bar,27727,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-Bar,28428,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-Bar,28777,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-Bar,28778,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-Bar,28779,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-Bar,28780,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-Bar,28808,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-Bar,29416,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-Bar,27181,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-Bar,27182,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-Bar,27727,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-Bar,28428,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-Bar,28777,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-Bar,28778,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-Bar,28779,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-Bar,28780,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-Bar,28808,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-Bar,29416,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-Bar,28808,GRP_BIOMASS_CHEM,BIOMASS_SPP,ACPE (NRCS plant code) -US-Bar,27727,GRP_BIOMASS_CHEM,BIOMASS_SPP,ACRU (NRCS plant code) -US-Bar,27181,GRP_BIOMASS_CHEM,BIOMASS_SPP,ACSA3 (NRCS plant code) -US-Bar,29416,GRP_BIOMASS_CHEM,BIOMASS_SPP,BEAL2 (NRCS plant code) -US-Bar,27182,GRP_BIOMASS_CHEM,BIOMASS_SPP,BEPA (NRCS plant code) -US-Bar,28777,GRP_BIOMASS_CHEM,BIOMASS_SPP,FAGR (NRCS plant code) -US-Bar,28778,GRP_BIOMASS_CHEM,BIOMASS_SPP,FRAM2 (NRCS plant code) -US-Bar,28779,GRP_BIOMASS_CHEM,BIOMASS_SPP,PIRU (NRCS plant code) -US-Bar,28780,GRP_BIOMASS_CHEM,BIOMASS_SPP,PIST (NRCS plant code) -US-Bar,28428,GRP_BIOMASS_CHEM,BIOMASS_SPP,POGR4 (NRCS plant code) -US-Bar,27181,GRP_BIOMASS_CHEM,BIOMASS_DATE,20040728 -US-Bar,27182,GRP_BIOMASS_CHEM,BIOMASS_DATE,20040728 -US-Bar,27727,GRP_BIOMASS_CHEM,BIOMASS_DATE,20040728 -US-Bar,28428,GRP_BIOMASS_CHEM,BIOMASS_DATE,20040728 -US-Bar,28777,GRP_BIOMASS_CHEM,BIOMASS_DATE,20040728 -US-Bar,28778,GRP_BIOMASS_CHEM,BIOMASS_DATE,20040728 -US-Bar,28779,GRP_BIOMASS_CHEM,BIOMASS_DATE,20040728 -US-Bar,28780,GRP_BIOMASS_CHEM,BIOMASS_DATE,20040728 -US-Bar,28808,GRP_BIOMASS_CHEM,BIOMASS_DATE,20040728 -US-Bar,29416,GRP_BIOMASS_CHEM,BIOMASS_DATE,20040728 -US-Bar,27181,GRP_BIOMASS_CHEM,BIOMASS_COMMENT,"Canopy average foliar N: 1.73% (2004), 1.58% (2005)" -US-Bar,27182,GRP_BIOMASS_CHEM,BIOMASS_COMMENT,"Canopy average foliar N: 1.73% (2004), 1.58% (2005)" -US-Bar,27727,GRP_BIOMASS_CHEM,BIOMASS_COMMENT,"Canopy average foliar N: 1.73% (2004), 1.58% (2005)" -US-Bar,28428,GRP_BIOMASS_CHEM,BIOMASS_COMMENT,"Canopy average foliar N: 1.73% (2004), 1.58% (2005)" -US-Bar,28777,GRP_BIOMASS_CHEM,BIOMASS_COMMENT,"Canopy average foliar N: 1.73% (2004), 1.58% (2005)" -US-Bar,28778,GRP_BIOMASS_CHEM,BIOMASS_COMMENT,"Canopy average foliar N: 1.73% (2004), 1.58% (2005)" -US-Bar,28779,GRP_BIOMASS_CHEM,BIOMASS_COMMENT,"Canopy average foliar N: 1.73% (2004), 1.58% (2005)" -US-Bar,28780,GRP_BIOMASS_CHEM,BIOMASS_COMMENT,"Canopy average foliar N: 1.73% (2004), 1.58% (2005)" -US-Bar,28808,GRP_BIOMASS_CHEM,BIOMASS_COMMENT,"Canopy average foliar N: 1.73% (2004), 1.58% (2005)" -US-Bar,29416,GRP_BIOMASS_CHEM,BIOMASS_COMMENT,"Canopy average foliar N: 1.73% (2004), 1.58% (2005)" -US-Bar,839,GRP_CLIM_AVG,MAT,5.61 -US-Bar,839,GRP_CLIM_AVG,MAP,1245.77 -US-Bar,839,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfb -US-Bar,27000334,GRP_COUNTRY,COUNTRY,USA -US-Bar,6902,GRP_DM_FORESTRY,DM_FORESTRY,Clearcutting -US-Bar,6902,GRP_DM_FORESTRY,DM_COMMENT,"There has historically been a program of silvicultural research at Bartlett Experimental Forest. Within the tower footprint, recent disturbances have been minimal, and are generally restricted to small patch cuts. The footprint is mostly undisturbed in the last 60-80 y. The oldest trees in the tower footprint (median age of 3 oldest trees in each of 12 FIA-style plots) are typically about 120 y." -US-Bar,15639,GRP_DOI,DOI,10.17190/AMF/1246030 -US-Bar,15639,GRP_DOI,DOI_CITATION,"Andrew Richardson, David Hollinger (2019), AmeriFlux BASE US-Bar Bartlett Experimental Forest, Ver. 5-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1246030" -US-Bar,15639,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-Bar,95083,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Bar,95083,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Andrew Richardson -US-Bar,95083,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Bar,95083,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,1 -US-Bar,95083,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,Andrew.richardson@nau.edu -US-Bar,95083,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Northern Arizona University -US-Bar,95075,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Bar,95075,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,David Hollinger -US-Bar,95075,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Bar,95075,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,2 -US-Bar,95075,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,david.hollinger@usda.gov -US-Bar,95075,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,USDA Forest Service -US-Bar,95085,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Northern Arizona University -US-Bar,95085,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-Bar,31958,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,USDA/Forest Service -US-Bar,31958,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-Bar,3360,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Forestry -US-Bar,6350,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Bar,6350,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-Bar,6350,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,2004 -US-Bar,6350,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Bar,91460,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Bar,91460,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-Bar,91460,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,2004 -US-Bar,91460,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Bar,91460,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,FLUX_MEASUREMENTS_COMMENT -US-Bar,91314,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Bar,91314,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-Bar,91314,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,2004 -US-Bar,91314,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Bar,91314,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,FLUX_MEASUREMENTS_COMMENT -US-Bar,23000334,GRP_HEADER,SITE_NAME,Bartlett Experimental Forest -US-Bar,23851,GRP_HEIGHTC,HEIGHTC,19 -US-Bar,23851,GRP_HEIGHTC,HEIGHTC_DATE,20040505 -US-Bar,23851,GRP_HEIGHTC,HEIGHTC_COMMENT,12 FIA plots surrounding tower -US-Bar,1821,GRP_IGBP,IGBP,DBF -US-Bar,1821,GRP_IGBP,IGBP_COMMENT,<10% total ENF -US-Bar,24631,GRP_LAI,LAI_TYPE,LAI -US-Bar,24632,GRP_LAI,LAI_TYPE,LAI -US-Bar,24631,GRP_LAI,LAI_CLUMP,1 -US-Bar,24632,GRP_LAI,LAI_CLUMP,1 -US-Bar,24631,GRP_LAI,LAI_METHOD,LAI_2000 -US-Bar,24632,GRP_LAI,LAI_METHOD,LAI_2000 -US-Bar,24631,GRP_LAI,LAI_DATE,20040729 -US-Bar,24632,GRP_LAI,LAI_DATE,20070729 -US-Bar,24632,GRP_LAI,LAI_COMMENT,4.6 ± 0.1; measured at centerpoint of 12 FIA plots around tower (4 subplots on each plot; each surveyed separately) -US-Bar,24631,GRP_LAI,LAI_COMMENT,4.7 ± 0.2 (mean ± 1 SE); measured at centerpoint of 12 FIA plots around tower (4 subplots on each plot; each surveyed separately) -US-Bar,24632,GRP_LAI,LAI_TOT,4.6 -US-Bar,24631,GRP_LAI,LAI_TOT,4.7 -US-Bar,1820,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-Bar,1820,GRP_LAND_OWNERSHIP,LAND_OWNER,USDA FOREST SERVICE -US-Bar,26902,GRP_LMA,LMA,173.67 -US-Bar,26902,GRP_LMA,LMA_SPP,PIST (NRCS plant code) -US-Bar,26902,GRP_LMA,LMA_DATE,20040728 -US-Bar,27595,GRP_LMA,LMA,304.67 -US-Bar,27595,GRP_LMA,LMA_SPP,PIRU (NRCS plant code) -US-Bar,27595,GRP_LMA,LMA_DATE,20040728 -US-Bar,28578,GRP_LMA,LMA,43.97 -US-Bar,28578,GRP_LMA,LMA_SPP,ACPE (NRCS plant code) -US-Bar,28578,GRP_LMA,LMA_DATE,20040728 -US-Bar,29514,GRP_LMA,LMA,61.0799999999999 -US-Bar,29514,GRP_LMA,LMA_SPP,FAGR (NRCS plant code) -US-Bar,29514,GRP_LMA,LMA_DATE,20040728 -US-Bar,28318,GRP_LMA,LMA,61.32 -US-Bar,28318,GRP_LMA,LMA_SPP,FRAM2 (NRCS plant code) -US-Bar,28318,GRP_LMA,LMA_DATE,20040728 -US-Bar,27967,GRP_LMA,LMA,62.58 -US-Bar,27967,GRP_LMA,LMA_SPP,ACRU (NRCS plant code) -US-Bar,27967,GRP_LMA,LMA_DATE,20040728 -US-Bar,26755,GRP_LMA,LMA,65.61 -US-Bar,26755,GRP_LMA,LMA_SPP,POGR4 (NRCS plant code) -US-Bar,26755,GRP_LMA,LMA_DATE,20040728 -US-Bar,27350,GRP_LMA,LMA,66.33 -US-Bar,27350,GRP_LMA,LMA_SPP,BEAL2 (NRCS plant code) -US-Bar,27350,GRP_LMA,LMA_DATE,20040728 -US-Bar,28579,GRP_LMA,LMA,66.33 -US-Bar,28579,GRP_LMA,LMA_SPP,ACSA3 (NRCS plant code) -US-Bar,28579,GRP_LMA,LMA_DATE,20040728 -US-Bar,28317,GRP_LMA,LMA,74.4 -US-Bar,28317,GRP_LMA,LMA_SPP,BEPA (NRCS plant code) -US-Bar,28317,GRP_LMA,LMA_DATE,20040728 -US-Bar,4297,GRP_LOCATION,LOCATION_LAT,44.0646 -US-Bar,4297,GRP_LOCATION,LOCATION_LONG,-71.2881 -US-Bar,4297,GRP_LOCATION,LOCATION_ELEV,272 -US-Bar,4297,GRP_LOCATION,LOCATION_COMMENT,"... Bartlett Experimental Forest. ...The correct location is 44 deg 3' 52.702794"" N [NOT 43 deg as I had earlier specified] 71 deg 17' 17.0766744"" W" -US-Bar,23643,GRP_N_DEP,N_DEP_WET,0.65 -US-Bar,24150,GRP_NEP,NEP,383 -US-Bar,24150,GRP_NEP,NEP_COMMENT,383 g m-2 yr-1 -US-Bar,5541,GRP_NETWORK,NETWORK,AmeriFlux -US-Bar,86949,GRP_NETWORK,NETWORK,Phenocam -US-Bar,24093,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,BudBreak -US-Bar,24093,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,(All) -US-Bar,24093,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20060509 -US-Bar,24093,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,"average across canopy; date is 50% canopy development, derived from fAPAR measurements (available on request)" -US-Bar,24353,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,BudBreak -US-Bar,24353,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,(All) -US-Bar,24353,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20050519 -US-Bar,24353,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,"average across canopy; date is 50% canopy development, derived from fAPAR measurements (available on request)" -US-Bar,24498,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,BudBreak -US-Bar,24498,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,(All) -US-Bar,24498,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20070512 -US-Bar,24498,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,"average across canopy; date is 50% canopy development, derived from fAPAR measurements (available on request)" -US-Bar,25004,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,BudBreak -US-Bar,25004,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,(All) -US-Bar,25004,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20040509 -US-Bar,25004,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,"average across canopy; date is 50% canopy development, derived from fAPAR measurements (available on request)" -US-Bar,23852,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,Total leaf-off -US-Bar,23852,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,(All) -US-Bar,23852,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20061016 -US-Bar,23852,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,"average across canopy; date is 50% canopy abscission, derived from fAPAR measurements (available on request)" -US-Bar,23984,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,Total leaf-off -US-Bar,23984,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,(All) -US-Bar,23984,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20041026 -US-Bar,23984,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,"average across canopy; date is 50% canopy abscission, derived from fAPAR measurements (available on request)" -US-Bar,24753,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,Total leaf-off -US-Bar,24753,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,(All) -US-Bar,24753,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20051101 -US-Bar,24753,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,"average across canopy; date is 50% canopy abscission, derived from fAPAR measurements (available on request)" -US-Bar,1700003840,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(11), 108350" -US-Bar,1700003840,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -US-Bar,1700003840,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Bar,1700008928,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Fer, I. and Kelly, R. and Moorcroft, P. R. and Richardson, A. D. and Cowdery, E. M. and Dietze, M. C. (2018) Linking Big Models To Big Data: Efficient Ecosystem Model Calibration Through Bayesian Model Emulation, Biogeosciences, 15(19), 5801-5830" -US-Bar,1700008928,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.5194/BG-15-5801-2018 -US-Bar,1700008928,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Bar,1700005976,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Guerrieri, R., Belmecheri, S., Ollinger, S. V., Asbjornsen, H., Jennings, K., Xiao, J., Stocker, B. D., Martin, M., Hollinger, D. Y., Bracho-Garrillo, R., Clark, K., Dore, S., Kolb, T., Munger, J. W., Novick, K., Richardson, A. D. (2019) Disentangling The Role Of Photosynthesis And Stomatal Conductance On Rising Forest Water-Use Efficiency, Proceedings Of The National Academy Of Sciences, 116(34), 16909-16914" -US-Bar,1700005976,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1073/PNAS.1905912116 -US-Bar,1700005976,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Bar,1700004461,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Helliker, B. R., Song, X., Goulden, M. L., Clark, K., Bolstad, P., Munger, J. W., Chen, J., Noormets, A., Hollinger, D., Wofsy, S., Martin, T., Baldocchi, D., Euskirchenn, E., Desai, A., Burns, S. P. (2018) Assessing The Interplay Between Canopy Energy Balance And Photosynthesis With Cellulose δ18o: Large-Scale Patterns And Independent Ground-Truthing, Oecologia, 133(3), 333-345" -US-Bar,1700004461,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1007/S00442-018-4198-Z -US-Bar,1700004461,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Bar,1700001305,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Jenkins, J., Richardson, A., Braswell, B., Ollinger, S., Hollinger, D., Smith, M. (2007) Refining Light-Use Efficiency Calculations For A Deciduous Forest Canopy Using Simultaneous Tower-Based Carbon Flux And Radiometric Measurements, Agricultural And Forest Meteorology, 143(1-2), 64-79" -US-Bar,1700001305,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2006.11.008 -US-Bar,1700001305,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Primary_Citation -US-Bar,1700006333,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Keenan, T. F., Hollinger, D. Y., Bohrer, G., Dragoni, D., Munger, J. W., Schmid, H. P., Richardson, A. D. (2013) Increase In Forest Water-Use Efficiency As Atmospheric Carbon Dioxide Concentrations Rise, Nature, 499(7458), 324-327" -US-Bar,1700006333,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1038/NATURE12291 -US-Bar,1700006333,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Bar,1700008451,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"McFarlane, K. J., Torn, M. S., Hanson, P. J., Porras, R. C., Swanston, C. W., Callaham, M. A., Guilderson, T. P. (2013) Comparison Of Soil Organic Matter Dynamics At Five Temperate Deciduous Forests With Physical Fractionation And Radiocarbon Measurements, Biogeochemistry, 112(1-3), 457-476" -US-Bar,1700008451,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1007/S10533-012-9740-1 -US-Bar,1700008451,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Bar,1700008436,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Novick, K. A., Ficklin, D. L., Stoy, P. C., Williams, C. A., Bohrer, G., Oishi, A., Papuga, S. A., Blanken, P. D., Noormets, A., Sulman, B. N., Scott, R. L., Wang, L., Phillips, R. P. (2016) The Increasing Importance Of Atmospheric Demand For Ecosystem Water And Carbon Fluxes, Nature Climate Change, 6(11), 1023-1027" -US-Bar,1700008436,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1038/NCLIMATE3114 -US-Bar,1700008436,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Bar,1700000123,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Ollinger, S. V., Smith, M. (2005) Net Primary Production And Canopy Nitrogen In A Temperate Forest Landscape: An Analysis Using Imaging Spectroscopy, Modeling And Field Data, Ecosystems, 8(7), 760-778" -US-Bar,1700000123,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1007/S10021-005-0079-5 -US-Bar,1700000123,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Bar,1700008250,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Ouimette, A. P., Ollinger, S. V., Richardson, A. D., Hollinger, D. Y., Keenan, T. F., Lepine, L. C., Vadeboncoeur, M. A. (2018) Carbon Fluxes And Interannual Drivers In A Temperate Forest Ecosystem Assessed Through Comparison Of Top-Down And Bottom-Up Approaches, Agricultural And Forest Meteorology, 256-257(11), 420-430" -US-Bar,1700008250,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2018.03.017 -US-Bar,1700008250,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Primary_Citation -US-Bar,1700007953,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Porras, R. C., Hicks Pries, C. E., McFarlane, K. J., Hanson, P. J., Torn, M. S. (2017) Association With Pedogenic Iron And Aluminum: Effects On Soil Organic Carbon Storage And Stability In Four Temperate Forest Soils, Biogeochemistry, 133(3), 333-345" -US-Bar,1700007953,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1007/S10533-017-0337-6 -US-Bar,1700007953,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Bar,1700005988,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Richardson, A. D., Jenkins, J. P., Braswell, B. H., Hollinger, D. Y., Ollinger, S. V., Smith, M. (2007) Use Of Digital Webcam Images To Track Spring Green-Up In A Deciduous Broadleaf Forest, Oecologia, 152(2), 323-334" -US-Bar,1700005988,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1007/S00442-006-0657-Z -US-Bar,1700005988,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Bar,1700002268,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Smith, M., Ollinger, S. V., Martin, M. E., Aber, J. D., Hallett, R. A., Goodale, C. L. (2002) Direct Estimation Of Aboveground Forest Productivity Through Hyperspectral Remote Sensing Of Canopy Nitrogen, Ecological Applications, 12(5), 1286-1302" -US-Bar,1700002268,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.2307/3099972 -US-Bar,1700002268,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Bar,1700006951,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Toomey, M., Friedl, M. A., Frolking, S., Hufkens, K., Klosterman, S., Sonnentag, O., Baldocchi, D. D., Bernacchi, C. J., Biraud, S. C., Bohrer, G., Brzostek, E., Burns, S. P., Coursolle, C., Hollinger, D. Y., Margolis, H. A., McCaughey, H., Monson, R. K., Munger, J. W., Pallardy, S., Phillips, R. P., Torn, M. S., Wharton, S., Zeri, M., Richardson, A. D. (2015) Greenness Indices From Digital Cameras Predict The Timing And Seasonal Dynamics Of Canopy-Scale Photosynthesis, Ecological Applications, 25(1), 99-115" -US-Bar,1700006951,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1890/14-0005.1 -US-Bar,1700006951,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Bar,1700005448,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Wolf, S., Keenan, T.F., Fisher, J.B., Baldocchi, D.D., Desai, A.R., Richardson, A.D., Scott, R.L., Law, B.E., Litvak, M.E., Brunsell, N.A., Peters, W., van der Laan-Luijkx, I.T. (2016) Warm spring reduced carbon cycle impact of the 2012 US summer drought, Proceedings of the National Academy of Sciences, 113(21), 5880-5885" -US-Bar,1700005448,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1073/PNAS.1519620113 -US-Bar,1700005448,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Bar,1700007965,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Xu, B., Arain, M. A., Black, T. A., Law, B. E., Pastorello, G. Z., Chu, H. (2020) Seasonal Variability Of Forest Sensitivity To Heat And Drought Stresses: A Synthesis Based On Carbon Fluxes From North American Forest Ecosystems, Global Change Biology, 26(2), 901-918" -US-Bar,1700007965,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/GCB.14843 -US-Bar,1700007965,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Bar,1700000105,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Zscheischler, J., Fatichi, S., Wolf, S., Blanken, P., Bohrer, G., Clark, K., Desai, A., Hollinger, D., Keenan, T., Novick, K.A., Seneviratne, S.I. (2016) Short-term favorable weather conditions are an important control of interannual variability in carbon and water fluxes, Journal of Geophysical Research - Biogeosciences, 121(8), 2186-2198" -US-Bar,1700000105,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/2016JG003503 -US-Bar,1700000105,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Bar,24352,GRP_ROOT_BIOMASS,ROOT_BIOMASS_CRS,1100 -US-Bar,24352,GRP_ROOT_BIOMASS,ROOT_BIOMASS_FINE,900 -US-Bar,24352,GRP_ROOT_BIOMASS,ROOT_BIOMASS_TOT,2000 -US-Bar,24352,GRP_ROOT_BIOMASS,ROOT_BIOMASS_UNIT,gC m-2 -US-Bar,24352,GRP_ROOT_BIOMASS,ROOT_BIOMASS_COMMENT,"See: Ruth D. Yanai, Byung B. Park, and Steven P. Hamburg. 2006. The vertical and horizontal distribution of roots in northern hardwood stands of varying age. Can. J. For. Res. 36: 450-459. and Byung B. Park, Ruth D. Yanai, Matthew A. Vadeboncoeur, and Steven P. Hamburg. 2007. Estimating root biomass in rocky soils using pits, cores, and allometric equations. Soil Science Society of America Journal." -US-Bar,24496,GRP_SA,SA,99 -US-Bar,24496,GRP_SA,SA_DATE,2006 -US-Bar,24496,GRP_SA,SA_COMMENT,based on aging of cores extracted from trees in 12 FIA-style plots -US-Bar,24886,GRP_SA,SA_DATE,2006 -US-Bar,24886,GRP_SA,SA_MAX,130 -US-Bar,4336,GRP_SITE_DESC,SITE_DESC,"The Bartlett Experimental Forest (448170 N, 71830 W) is located within the White Mountains National Forest in north-central New Hampshire, USA. The 1050 ha forest extends across an elevational range from 200 to 900 m a.s.l. It was established in 1931 and is managed by the USDA Forest Service Northeastern Research Station in Durham, NH. The climate is humid continental with short, cool summers (mean July temperature, 19.8C) and long, cold winters (mean January temperature, 9.8C). Annual precipitation averages 130 cm and is distributed evenly throughout the year. Soils are developed from glacial till and are predominantly shallow, well-drained spodosols. At lowto mid-elevation, vegetation is dominated by northern hardwoods (American beech, Fagus grandifolia; sugar maple, Acer saccharum; yellow birch, Betula alleghaniensis; with some red maple, Acer rubrum and paper birch, Betula papyrifera). Conifers (eastern hemlock, Tsuga canadensis; eastern white pine, Pinus strobus; red spruce, Picea rubens) are occasionally found intermixed with the more abundant deciduous species but are generally confined to the highest (red spruce) and lowest (hemlock and pine) elevations. In 2003, the site was adopted as a NASA North American Carbon Program (NACP) Tier-2 field research and validation site. A 26.5 m high tower was installed in a low-elevation northern hardwood stand in November, 2003, for the purpose of making eddy covariance measurements of the forest–atmosphere exchange of CO2, H2O and radiant energy. Continuous flux and meteorological measurements began in January, 2004, and are ongoing. Average canopy height in the vicinity of the tower is approximately 20–22 m. In the tower footprint, the forest is predominantly classified into red maple, sugar maple, and American beech forest types. Leaf area index in the vicinity of the tower is 3.6 as measured by seasonal litterfall collection, and 4.5 as measured by the optically based Li-Cor LAI-2000 instrument. Further site information: http://www.fs.fed.us/ne/durham/4155/bartlett.htm" -US-Bar,6703,GRP_SITE_FUNDING,SITE_FUNDING,USDA/Forest Service -US-Bar,24634,GRP_SNAG_MASS,SNAG_MASS,1350 -US-Bar,24634,GRP_SNAG_MASS,SNAG_MASS_UNIT,gC m-2 -US-Bar,24634,GRP_SNAG_MASS,SNAG_MASS_DATE,20040430 -US-Bar,24754,GRP_SOIL_CHEM,SOIL_CHEM_C_ORG,11 -US-Bar,24094,GRP_SOIL_CHEM,SOIL_CHEM_C_ORG,18 -US-Bar,23725,GRP_SOIL_CHEM,SOIL_CHEM_C_ORG,5 -US-Bar,24754,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,0 -US-Bar,23725,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,10 -US-Bar,24754,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,10 -US-Bar,23725,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,30 -US-Bar,23725,GRP_SOIL_CHEM,SOIL_CHEM_DATE,20040729 -US-Bar,24094,GRP_SOIL_CHEM,SOIL_CHEM_DATE,20040729 -US-Bar,24754,GRP_SOIL_CHEM,SOIL_CHEM_DATE,20040729 -US-Bar,24094,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,Forest floor -US-Bar,23725,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,mineral -US-Bar,24754,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,mineral soil -US-Bar,29624,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION,Spodosol -US-Bar,29624,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION_TAXONOMY,Other -US-Bar,23779,GRP_SOIL_DEPTH,SOIL_DEPTH,100 -US-Bar,23779,GRP_SOIL_DEPTH,SOIL_DEPTH_COMMENT," -<1m" -US-Bar,24545,GRP_SOIL_DEPTH,SOIL_DEPTH,7 -US-Bar,23724,GRP_SOIL_TEX,SOIL_TEX_SAND,74 -US-Bar,23724,GRP_SOIL_TEX,SOIL_TEX_SILT,23 -US-Bar,23724,GRP_SOIL_TEX,SOIL_TEX_CLAY,4 -US-Bar,23724,GRP_SOIL_TEX,SOIL_TEX_COMMENT,"data from Bartlett Experimental Forest, but not within tower footprint. Texture is for shallow-C layer material." -US-Bar,27966,GRP_SPP_O,SPP_O,ACRU (NRCS plant code) -US-Bar,29513,GRP_SPP_O,SPP_O,BEAL2 (NRCS plant code) -US-Bar,27051,GRP_SPP_O,SPP_O,BEPA (NRCS plant code) -US-Bar,27349,GRP_SPP_O,SPP_O,FAGR (NRCS plant code) -US-Bar,27052,GRP_SPP_O,SPP_O,POGR4 (NRCS plant code) -US-Bar,28577,GRP_SPP_O,SPP_O,TSCA (NRCS plant code) -US-Bar,28577,GRP_SPP_O,SPP_O_PERC,17 -US-Bar,27349,GRP_SPP_O,SPP_O_PERC,2 -US-Bar,27966,GRP_SPP_O,SPP_O_PERC,28 -US-Bar,29513,GRP_SPP_O,SPP_O_PERC,5 -US-Bar,27051,GRP_SPP_O,SPP_O_PERC,9 -US-Bar,27051,GRP_SPP_O,SPP_APPROACH,"C.M. Hoover (Ed.). 2008. Field measurements for forest carbon monitoring: A landscape-scale approach. Springer, New York (in press)." -US-Bar,27052,GRP_SPP_O,SPP_APPROACH,"C.M. Hoover (Ed.). 2008. Field measurements for forest carbon monitoring: A landscape-scale approach. Springer, New York (in press)." -US-Bar,27349,GRP_SPP_O,SPP_APPROACH,"C.M. Hoover (Ed.). 2008. Field measurements for forest carbon monitoring: A landscape-scale approach. Springer, New York (in press)." -US-Bar,27966,GRP_SPP_O,SPP_APPROACH,"C.M. Hoover (Ed.). 2008. Field measurements for forest carbon monitoring: A landscape-scale approach. Springer, New York (in press)." -US-Bar,28577,GRP_SPP_O,SPP_APPROACH,"C.M. Hoover (Ed.). 2008. Field measurements for forest carbon monitoring: A landscape-scale approach. Springer, New York (in press)." -US-Bar,29513,GRP_SPP_O,SPP_APPROACH,"C.M. Hoover (Ed.). 2008. Field measurements for forest carbon monitoring: A landscape-scale approach. Springer, New York (in press)." -US-Bar,27051,GRP_SPP_O,SPP_COMMENT,based on 12 FIA-style plots arrayed around the tower -US-Bar,27052,GRP_SPP_O,SPP_COMMENT,based on 12 FIA-style plots arrayed around the tower -US-Bar,27349,GRP_SPP_O,SPP_COMMENT,based on 12 FIA-style plots arrayed around the tower -US-Bar,27966,GRP_SPP_O,SPP_COMMENT,based on 12 FIA-style plots arrayed around the tower -US-Bar,28577,GRP_SPP_O,SPP_COMMENT,based on 12 FIA-style plots arrayed around the tower -US-Bar,29513,GRP_SPP_O,SPP_COMMENT,based on 12 FIA-style plots arrayed around the tower -US-Bar,28563,GRP_SPP_U,SPP_U,VIAL3 (NRCS plant code) -US-Bar,28563,GRP_SPP_U,SPP_COMMENT,not formally surveyed; based on 12 FIA-style plots arrayed around the tower -US-Bar,10008,GRP_STATE,STATE,NH -US-Bar,81662,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Andrew Richardson -US-Bar,81662,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Bar,81662,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,Andrew.Richardson@nau.edu -US-Bar,81662,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Northern Arizona University -US-Bar,81662,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"PO Box 5693 -Flagstaff, AZ 86011 - -School of Informatics, Computing, and Cyber Systems -Building 90 Room 321 -1295 S. Knoles Drive -Flagstaff, AZ 86011" -US-Bar,3252,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Trevor Keenan -US-Bar,3252,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,AncContact -US-Bar,3252,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,keenan_trevor@yahoo.ie -US-Bar,3252,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION, -US-Bar,22348,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,David Hollinger -US-Bar,22348,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-Bar,22348,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,davidh@unh.edu -US-Bar,22348,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,USDA Forest Service -US-Bar,22348,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Northeastern Forest Exp. Station, 271 Mast Rd, Durham, NH USA 03824" -US-Bar,81663,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Jim Le Moine -US-Bar,81663,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Technician -US-Bar,81663,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,jim.le.moine@nau.edu -US-Bar,81663,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Northern Arizona University -US-Bar,81663,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Science Lab Facility Bldg. 17, Room 201 -600 S. Knoles Dr -Flagstaff, AZ 86011" -US-Bar,91312,GRP_TOWER_POWER,TOWER_POWER,Direct power -US-Bar,91335,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-Bar,91413,GRP_TOWER_TYPE,TOWER_TYPE,triangle -US-Bar,4325,GRP_URL,URL,http://www.fs.fed.us/ne/durham/4155/bartlett.htm -US-Bar,24000334,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-Bar -US-Bar,1073,GRP_UTC_OFFSET,UTC_OFFSET,-5 -US-Bar,24633,GRP_WD_BIOMASS,WD_BIOMASS_CRS,900 -US-Bar,24633,GRP_WD_BIOMASS,WD_BIOMASS_UNIT,gC m-2 -US-Bar,24633,GRP_WD_BIOMASS,WD_BIOMASS_DATE,20040729 -US-Bar,24633,GRP_WD_BIOMASS,WD_BIOMASS_COMMENT,Line intersect sampling -US-BCM,87305,GRP_CLIM_AVG,MAT,22.6 -US-BCM,87305,GRP_CLIM_AVG,MAP,1142 -US-BCM,87305,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Cwa -US-BCM,27001082,GRP_COUNTRY,COUNTRY,USA -US-BCM,87303,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Fire -US-BCM,87310,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Hydrologic event -US-BCM,87292,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-BCM,87292,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-BCM,87292,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20091211 -US-BCM,87292,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20141114 -US-BCM,87292,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-BCM,87295,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-BCM,87295,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-BCM,87295,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20091211 -US-BCM,87295,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20141114 -US-BCM,87295,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-BCM,87296,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-BCM,87296,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-BCM,87296,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20091211 -US-BCM,87296,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20141114 -US-BCM,87296,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-BCM,87308,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-BCM,87308,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CH4 -US-BCM,87308,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20110406 -US-BCM,87308,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20141114 -US-BCM,87308,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-BCM,23001082,GRP_HEADER,SITE_NAME,Blue Cypress Marsh -US-BCM,87309,GRP_IGBP,IGBP,WET -US-BCM,87309,GRP_IGBP,IGBP_COMMENT,Sawgrass marsh -US-BCM,87307,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -US-BCM,87307,GRP_LAND_OWNERSHIP,LAND_OWNER,St. Johns Water Management District -US-BCM,87312,GRP_LOCATION,LOCATION_LAT,27.6953 -US-BCM,87312,GRP_LOCATION,LOCATION_LONG,-80.7114 -US-BCM,87312,GRP_LOCATION,LOCATION_ELEV,23 -US-BCM,87312,GRP_LOCATION,LOCATION_DATE_START,20100101 -US-BCM,87301,GRP_NETWORK,NETWORK,AmeriFlux -US-BCM,87299,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"Carbon, methane, water and heat fluxes in a Florida peat marsh." -US-BCM,87306,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"School of Forest Resources & Conservation, University of Florida, Gainesville, FL, 32611." -US-BCM,87311,GRP_SITE_CHAR,TERRAIN,Flat -US-BCM,87311,GRP_SITE_CHAR,ASPECT,FLAT -US-BCM,87311,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,800 -US-BCM,87311,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,0 -US-BCM,87294,GRP_SITE_DESC,SITE_DESC,The area was set aside for water conservation and management as part of the Upper St. Johns River restoration project -US-BCM,87302,GRP_SITE_FUNDING,SITE_FUNDING,"The USGS, St Johns Water management District collaborated on a carbon dynamics project funded by DOE" -US-BCM,87300,GRP_STATE,STATE,FL -US-BCM,87304,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Charless Ross Hinkle -US-BCM,87304,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-BCM,87304,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,rhinkle@ucf.edu -US-BCM,87304,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Central Florida -US-BCM,87304,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Department of Biology, 4110 Libra Drive , Orlando FL, 32816" -US-BCM,87297,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Rosvel Bracho -US-BCM,87297,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-BCM,87297,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,rbracho@ufl.edu -US-BCM,87297,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Florida -US-BCM,87297,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"School of Forest Resources & Conservation, University of Florida, Gainesville, FL, 32611." -US-BCM,87298,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-BCM,87293,GRP_TOWER_TYPE,TOWER_TYPE,other -US-BCM,24001082,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-BCM -US-BCM,87884,GRP_UTC_OFFSET,UTC_OFFSET,-5 -US-Bd4,92696,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Cfa -US-Bd4,27001155,GRP_COUNTRY,COUNTRY,USA -US-Bd4,92707,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Agriculture -US-Bd4,92701,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Bd4,92701,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-Bd4,92701,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20200528 -US-Bd4,92701,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Bd4,92712,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Bd4,92712,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CH4 -US-Bd4,92712,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20200528 -US-Bd4,92712,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Bd4,92704,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Bd4,92704,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-Bd4,92704,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20200528 -US-Bd4,92704,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Bd4,23001155,GRP_HEADER,SITE_NAME,Burdette Farm Rice Field - 4N -US-Bd4,92703,GRP_IGBP,IGBP,CRO -US-Bd4,92703,GRP_IGBP,IGBP_COMMENT,rice-soybean-rice annual rotation -US-Bd4,92709,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -US-Bd4,92699,GRP_LOCATION,LOCATION_LAT,35.8139 -US-Bd4,92699,GRP_LOCATION,LOCATION_LONG,-89.9862 -US-Bd4,92699,GRP_LOCATION,LOCATION_ELEV,70 -US-Bd4,92699,GRP_LOCATION,LOCATION_DATE_START,20200528 -US-Bd4,92702,GRP_NETWORK,NETWORK,AmeriFlux -US-Bd4,92693,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"Agriculture, irrigation management, water balance, carbon balance" -US-Bd4,92700,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"504 UNIVERSITY LOOP EAST, Jonesboro AR 72401" -US-Bd4,92708,GRP_SITE_CHAR,TERRAIN,Flat -US-Bd4,92708,GRP_SITE_CHAR,ASPECT,S -US-Bd4,92708,GRP_SITE_CHAR,WIND_DIRECTION,SSW -US-Bd4,92706,GRP_SITE_DESC,SITE_DESC,Row rice with winter cover crop -US-Bd4,92711,GRP_SITE_FUNDING,SITE_FUNDING,"USDA, Arkansas State University, University of Arkansas" -US-Bd4,92705,GRP_STATE,STATE,AR -US-Bd4,92697,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Michele L. Reba -US-Bd4,92697,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Bd4,92697,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,Michele.Reba@usda.gov -US-Bd4,92697,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"USDA, ARS, DELTA WATER MANAGEMENT RESEARCH UNIT" -US-Bd4,92697,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"504 UNIVERSITY LOOP EAST, Jonesboro AR 72401" -US-Bd4,92698,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Benjamin R.K. Runkle -US-Bd4,92698,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,AncContact -US-Bd4,92698,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,brrunkle@uark.edu -US-Bd4,92698,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Arkansas -US-Bd4,92698,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1 University of Arkansas, Engineering Hall 231, Fayetteville, AR 72701" -US-Bd4,92694,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-Bd4,92695,GRP_TOWER_TYPE,TOWER_TYPE,tripod -US-Bd4,24001155,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-Bd4 -US-Bd4,92710,GRP_UTC_OFFSET,UTC_OFFSET,-6 -US-Bd5,92723,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Cfa -US-Bd5,27001156,GRP_COUNTRY,COUNTRY,USA -US-Bd5,92720,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Agriculture -US-Bd5,92732,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Bd5,92732,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-Bd5,92732,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20200528 -US-Bd5,92732,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Bd5,92713,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Bd5,92713,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CH4 -US-Bd5,92713,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20200528 -US-Bd5,92713,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Bd5,92715,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Bd5,92715,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-Bd5,92715,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20200528 -US-Bd5,92715,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Bd5,23001156,GRP_HEADER,SITE_NAME,Burdette Farm Rice Field - Seagraves South -US-Bd5,92717,GRP_IGBP,IGBP,CRO -US-Bd5,92717,GRP_IGBP,IGBP_COMMENT,rice-soybean-rice annual rotation -US-Bd5,92714,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -US-Bd5,92722,GRP_LOCATION,LOCATION_LAT,35.8105 -US-Bd5,92722,GRP_LOCATION,LOCATION_LONG,-90.0194 -US-Bd5,92722,GRP_LOCATION,LOCATION_ELEV,70 -US-Bd5,92722,GRP_LOCATION,LOCATION_DATE_START,20200528 -US-Bd5,92719,GRP_NETWORK,NETWORK,AmeriFlux -US-Bd5,92730,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"Agriculture, carbon balance, water balance" -US-Bd5,92727,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"504 UNIVERSITY LOOP EAST, Jonesboro AR 72401" -US-Bd5,92721,GRP_SITE_CHAR,TERRAIN,Flat -US-Bd5,92721,GRP_SITE_CHAR,ASPECT,S -US-Bd5,92721,GRP_SITE_CHAR,WIND_DIRECTION,SSW -US-Bd5,92731,GRP_SITE_DESC,SITE_DESC,Row rice without winter cover crop -US-Bd5,92728,GRP_SITE_FUNDING,SITE_FUNDING,"USDA, Arkansas State University, University of Arkansas" -US-Bd5,92725,GRP_STATE,STATE,AR -US-Bd5,92724,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Michele L. Reba -US-Bd5,92724,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Bd5,92724,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,Michele.Reba@usda.gov -US-Bd5,92724,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"USDA, ARS, DELTA WATER MANAGEMENT RESEARCH UNIT" -US-Bd5,92724,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"504 UNIVERSITY LOOP EAST, Jonesboro AR 72401" -US-Bd5,92716,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Benjamin R.K. Runkle -US-Bd5,92716,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,AncContact -US-Bd5,92716,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,brrunkle@uark.edu -US-Bd5,92716,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Arkansas -US-Bd5,92716,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1 University of Arkansas, Engineering Hall 231, Fayetteville, AR 72701" -US-Bd5,92726,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-Bd5,92729,GRP_TOWER_TYPE,TOWER_TYPE,tripod -US-Bd5,24001156,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-Bd5 -US-Bd5,92718,GRP_UTC_OFFSET,UTC_OFFSET,-6 -US-Bd6,92740,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Cfa -US-Bd6,27001157,GRP_COUNTRY,COUNTRY,USA -US-Bd6,92733,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Agriculture -US-Bd6,92750,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Bd6,92750,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-Bd6,92750,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20200528 -US-Bd6,92750,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Bd6,92744,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Bd6,92744,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CH4 -US-Bd6,92744,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20200528 -US-Bd6,92744,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Bd6,92734,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Bd6,92734,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-Bd6,92734,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20200528 -US-Bd6,92734,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Bd6,23001157,GRP_HEADER,SITE_NAME,Burdette Farm Rice - Seagraves North -US-Bd6,92739,GRP_IGBP,IGBP,CRO -US-Bd6,92739,GRP_IGBP,IGBP_COMMENT,rice-soybean-rice annual rotation -US-Bd6,92741,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -US-Bd6,92752,GRP_LOCATION,LOCATION_LAT,35.8140 -US-Bd6,92752,GRP_LOCATION,LOCATION_LONG,-90.0194 -US-Bd6,92752,GRP_LOCATION,LOCATION_ELEV,70 -US-Bd6,92752,GRP_LOCATION,LOCATION_DATE_START,20200528 -US-Bd6,92735,GRP_NETWORK,NETWORK,AmeriFlux -US-Bd6,92737,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"Agriculture, carbon balance, water balance" -US-Bd6,92747,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"504 UNIVERSITY LOOP EAST, Jonesboro AR 72401" -US-Bd6,92742,GRP_SITE_CHAR,TERRAIN,Flat -US-Bd6,92742,GRP_SITE_CHAR,ASPECT,S -US-Bd6,92742,GRP_SITE_CHAR,WIND_DIRECTION,SSW -US-Bd6,92748,GRP_SITE_DESC,SITE_DESC,"Conventional irrigation with Multiple Inlet Rice Irrigation (MIRI), control for row rice sites" -US-Bd6,92749,GRP_SITE_FUNDING,SITE_FUNDING,"USDA, Arkansas State University, University of Arkansas" -US-Bd6,92736,GRP_STATE,STATE,AR -US-Bd6,92738,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Michele L. Reba -US-Bd6,92738,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Bd6,92738,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,Michele.Reba@usda.gov -US-Bd6,92738,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"USDA, ARS, DELTA WATER MANAGEMENT RESEARCH UNIT" -US-Bd6,92738,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"504 UNIVERSITY LOOP EAST, Jonesboro AR 72401" -US-Bd6,92743,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Benjamin R.K. Runkle -US-Bd6,92743,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,AncContact -US-Bd6,92743,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,brrunkle@uark.edu -US-Bd6,92743,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Arkansas -US-Bd6,92743,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1 University of Arkansas, Engineering Hall 231, Fayetteville, AR 72701" -US-Bd6,92751,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-Bd6,92745,GRP_TOWER_TYPE,TOWER_TYPE,tripod -US-Bd6,24001157,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-Bd6 -US-Bd6,92746,GRP_UTC_OFFSET,UTC_OFFSET,-6 -US-BdA,13309,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Cfa -US-BdA,27000553,GRP_COUNTRY,COUNTRY,USA -US-BdA,13310,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-BdA,13310,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-BdA,13310,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Planned -US-BdA,13310,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,"Intermittent only for brief farm operations (e.g., burning, planting)" -US-BdA,13326,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-BdA,13326,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CH4 -US-BdA,13326,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Planned -US-BdA,13326,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,"Intermittent only for brief farm operations (e.g., burning, planting)" -US-BdA,13324,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-BdA,13324,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-BdA,13324,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Planned -US-BdA,13324,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,"Intermittent only for brief farm operations (e.g., burning, planting)" -US-BdA,23000553,GRP_HEADER,SITE_NAME,Burdette Farm Rice Field - AWD -US-BdA,13311,GRP_IGBP,IGBP,CRO -US-BdA,13312,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -US-BdA,13313,GRP_LOCATION,LOCATION_LAT,35.8089 -US-BdA,13313,GRP_LOCATION,LOCATION_LONG,-90.0327 -US-BdA,13314,GRP_NETWORK,NETWORK,AmeriFlux -US-BdA,86950,GRP_NETWORK,NETWORK,Phenocam -US-BdA,1700006927,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Benjamin R. K. Runkle, James R. Rigbyb, Michele L. Rebac, Saseendran S. Anapallid, Joydeep Bhattacharjeee, Ken W. Kraussf, Lu Liangg, Martin A. Locke, Kimberly A. Novick, Ruixiu Suid, Kosana Suvočareva and Paul M. White (2017) Delta-Flux: An Eddy Covariance Network for a Climate-Smart Lower Mississippi Basin, Agricultural & Environmental Letters, 2(1), 170003 - 170003" -US-BdA,1700006927,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.2134/AEL2017.01.0003 -US-BdA,1700006927,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-BdA,13315,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"Agriculture, carbon balance, water balance" -US-BdA,13316,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"504 UNIVERSITY LOOP EAST, Jonesboro AR 72401" -US-BdA,13317,GRP_SITE_CHAR,TERRAIN,Flat -US-BdA,13317,GRP_SITE_CHAR,ASPECT,FLAT -US-BdA,13317,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,350 -US-BdA,13318,GRP_SITE_DESC,SITE_DESC,Alternate wetting and drying irrigation method on a rice field under annual rice-soybean rotation -US-BdA,13319,GRP_SITE_FUNDING,SITE_FUNDING,"USDA, Arkansas State University, University of Arkansas" -US-BdA,13320,GRP_STATE,STATE,AR -US-BdA,13321,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Michele L. Reba -US-BdA,13321,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-BdA,13321,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,michele.reba@ars.usda.gov -US-BdA,13321,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"USDA, ARS, DELTA WATER MANAGEMENT RESEARCH UNIT" -US-BdA,13321,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"504 UNIVERSITY LOOP EAST, Jonesboro AR 72401" -US-BdA,13325,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Benjamin R. K. Runkle -US-BdA,13325,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,AncContact -US-BdA,13325,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,brrunkle@uark.edu -US-BdA,13325,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Arkansas -US-BdA,13325,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1 University of Arkansas, Engineering Hall 231, Fayetteville AR 72701" -US-BdA,29887,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-BdA,13322,GRP_TOWER_TYPE,TOWER_TYPE,tripod -US-BdA,24000553,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-BdA -US-BdA,13323,GRP_UTC_OFFSET,UTC_OFFSET,-6 -US-BdC,13327,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Cfa -US-BdC,27000552,GRP_COUNTRY,COUNTRY,USA -US-BdC,13328,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-BdC,13328,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-BdC,13328,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Planned -US-BdC,13328,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,"Intermittent only for brief farm operations (e.g., burning, planting)" -US-BdC,13344,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-BdC,13344,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CH4 -US-BdC,13344,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Planned -US-BdC,13344,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,"Intermittent only for brief farm operations (e.g., burning, planting)" -US-BdC,13342,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-BdC,13342,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-BdC,13342,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Planned -US-BdC,13342,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,"Intermittent only for brief farm operations (e.g., burning, planting)" -US-BdC,23000552,GRP_HEADER,SITE_NAME,Burdette Farm Rice Field - conventional -US-BdC,13329,GRP_IGBP,IGBP,CRO -US-BdC,13330,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -US-BdC,13331,GRP_LOCATION,LOCATION_LAT,35.8089 -US-BdC,13331,GRP_LOCATION,LOCATION_LONG,-90.0284 -US-BdC,13332,GRP_NETWORK,NETWORK,AmeriFlux -US-BdC,86951,GRP_NETWORK,NETWORK,Phenocam -US-BdC,1700004893,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Benjamin R. K. Runkle, James R. Rigbyb, Michele L. Rebac, Saseendran S. Anapallid, Joydeep Bhattacharjeee, Ken W. Kraussf, Lu Liangg, Martin A. Locke, Kimberly A. Novick, Ruixiu Suid, Kosana Suvočareva and Paul M. White (2017) Delta-Flux: An Eddy Covariance Network for a Climate-Smart Lower Mississippi Basin, Agricultural & Environmental Letters, 2(1), 170003 - 170003" -US-BdC,1700004893,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.2134/AEL2017.01.0003 -US-BdC,1700004893,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-BdC,13333,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"Agriculture, carbon balance, water balance" -US-BdC,13334,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"504 UNIVERSITY LOOP EAST, Jonesboro AR 72401" -US-BdC,13335,GRP_SITE_CHAR,TERRAIN,Flat -US-BdC,13335,GRP_SITE_CHAR,ASPECT,FLAT -US-BdC,13335,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,350 -US-BdC,13336,GRP_SITE_DESC,SITE_DESC,Conventional flood irrigation method on a rice field under annual rice-soybean rotation -US-BdC,13337,GRP_SITE_FUNDING,SITE_FUNDING,"USDA, Arkansas State University, University of Arkansas" -US-BdC,13338,GRP_STATE,STATE,AR -US-BdC,13339,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Michele L. Reba -US-BdC,13339,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-BdC,13339,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,michele.reba@ars.usda.gov -US-BdC,13339,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"USDA, ARS, DELTA WATER MANAGEMENT RESEARCH UNIT" -US-BdC,13339,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"504 UNIVERSITY LOOP EAST, Jonesboro AR 72401" -US-BdC,13343,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Benjamin R. K. Runkle -US-BdC,13343,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,AncContact -US-BdC,13343,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,brrunkle@uark.edu -US-BdC,13343,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Arkansas -US-BdC,13343,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1 University of Arkansas, Engineering Hall 231, Fayetteville AR 72701" -US-BdC,29886,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-BdC,13340,GRP_TOWER_TYPE,TOWER_TYPE,tripod -US-BdC,24000552,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-BdC -US-BdC,13341,GRP_UTC_OFFSET,UTC_OFFSET,-6 -US-Bi1,30358,GRP_CLIM_AVG,MAT,16 -US-Bi1,30358,GRP_CLIM_AVG,MAP,338 -US-Bi1,30358,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Csa -US-Bi1,27000690,GRP_COUNTRY,COUNTRY,USA -US-Bi1,85252,GRP_DOI,DOI,10.17190/AMF/1480317 -US-Bi1,85252,GRP_DOI,DOI_CITATION,"Camilo Rey-Sanchez, Carlos Tianxin Wang, Daphne Szutu, Robert Shortt, Samuel D. Chamberlain, Joseph Verfaillie, Dennis Baldocchi (2022), AmeriFlux BASE US-Bi1 Bouldin Island Alfalfa, Ver. 8-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1480317" -US-Bi1,85252,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-Bi1,98374,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Bi1,98374,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Camilo Rey-Sanchez -US-Bi1,98374,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Bi1,98374,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,1 -US-Bi1,98374,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0003-4762-9001 -US-Bi1,98374,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,rey.1@berkeley.edu -US-Bi1,98374,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of California-Berkeley -US-Bi1,98374,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,201902 -US-Bi1,98374,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_END,202108 -US-Bi1,98361,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Bi1,98361,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Carlos Tianxin Wang -US-Bi1,98361,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Bi1,98361,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,1 -US-Bi1,98361,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0002-2709-9122 -US-Bi1,98361,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,cawang@berkeley.edu -US-Bi1,98361,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"University of California, Berkeley" -US-Bi1,98361,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,20210101 -US-Bi1,94100,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Bi1,94100,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Daphne Szutu -US-Bi1,94100,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Bi1,94100,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,2 -US-Bi1,94100,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0001-7698-0461 -US-Bi1,94100,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,daphneszutu@berkeley.edu -US-Bi1,94100,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"University of California, Berkeley" -US-Bi1,94100,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,201612 -US-Bi1,98367,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Bi1,98367,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Robert Shortt -US-Bi1,98367,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Bi1,98367,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,3 -US-Bi1,98367,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0001-5690-4656 -US-Bi1,98367,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,robert_shortt@berkeley.edu -US-Bi1,98367,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of California-Berkeley -US-Bi1,98367,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,20190101 -US-Bi1,98367,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_END,20201231 -US-Bi1,98360,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Bi1,98360,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Samuel D. Chamberlain -US-Bi1,98360,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Bi1,98360,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,4 -US-Bi1,98360,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0002-5570-764X -US-Bi1,98360,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,sam.d.chamberlain@gmail.com -US-Bi1,98360,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"University of California, Berkeley" -US-Bi1,98360,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,20160812 -US-Bi1,98360,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_END,20171026 -US-Bi1,94093,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Bi1,94093,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Joseph Verfaillie -US-Bi1,94093,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Bi1,94093,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,5 -US-Bi1,94093,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0002-7009-8942 -US-Bi1,94093,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,jverfail@berkeley.edu -US-Bi1,94093,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"University of California, Berkeley" -US-Bi1,94093,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,20160812 -US-Bi1,94042,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Bi1,94042,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Dennis Baldocchi -US-Bi1,94042,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Bi1,94042,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,6 -US-Bi1,94042,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0003-3496-4919 -US-Bi1,94042,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,Baldocchi@berkeley.edu -US-Bi1,94042,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"University of California, Berkeley" -US-Bi1,94042,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,20160812 -US-Bi1,84794,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,"University of California, Berkeley" -US-Bi1,84794,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-Bi1,84793,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,CA Dept Water Resources/CA Dept Fish and Wildlife -US-Bi1,84793,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-Bi1,30371,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Agriculture -US-Bi1,30366,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Bi1,30366,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-Bi1,30366,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201608111600 -US-Bi1,30366,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Bi1,30370,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Bi1,30370,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CH4 -US-Bi1,30370,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201608111600 -US-Bi1,30370,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Bi1,30367,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Bi1,30367,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-Bi1,30367,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201608111600 -US-Bi1,30367,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Bi1,91296,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Chambers -US-Bi1,91296,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-Bi1,91296,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20180712 -US-Bi1,91296,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Bi1,91296,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,Single forced diffusion chamber measuring soil co2 flux -US-Bi1,23000690,GRP_HEADER,SITE_NAME,Bouldin Island Alfalfa -US-Bi1,94521,GRP_HEIGHTC,HEIGHTC,0.064 -US-Bi1,94521,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Bi1,94521,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi1,94521,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Bi1,94521,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi1,94521,GRP_HEIGHTC,HEIGHTC_DATE,20170315 -US-Bi1,94547,GRP_HEIGHTC,HEIGHTC,0.244 -US-Bi1,94547,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Bi1,94547,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi1,94547,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Bi1,94547,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi1,94547,GRP_HEIGHTC,HEIGHTC_DATE,20170315 -US-Bi1,94512,GRP_HEIGHTC,HEIGHTC,0.025 -US-Bi1,94512,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Bi1,94512,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi1,94512,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Bi1,94512,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi1,94512,GRP_HEIGHTC,HEIGHTC_DATE,20170329 -US-Bi1,94513,GRP_HEIGHTC,HEIGHTC,0.394 -US-Bi1,94513,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Bi1,94513,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi1,94513,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Bi1,94513,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi1,94513,GRP_HEIGHTC,HEIGHTC_DATE,20170329 -US-Bi1,94544,GRP_HEIGHTC,HEIGHTC,0.53 -US-Bi1,94544,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Bi1,94544,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi1,94544,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Bi1,94544,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi1,94544,GRP_HEIGHTC,HEIGHTC_DATE,20170411 -US-Bi1,94579,GRP_HEIGHTC,HEIGHTC,0.069 -US-Bi1,94579,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Bi1,94579,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi1,94579,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Bi1,94579,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi1,94579,GRP_HEIGHTC,HEIGHTC_DATE,20170411 -US-Bi1,94508,GRP_HEIGHTC,HEIGHTC,0.161 -US-Bi1,94508,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Bi1,94508,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi1,94508,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Bi1,94508,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi1,94508,GRP_HEIGHTC,HEIGHTC_DATE,20170510 -US-Bi1,94569,GRP_HEIGHTC,HEIGHTC,0.026 -US-Bi1,94569,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Bi1,94569,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi1,94569,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Bi1,94569,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi1,94569,GRP_HEIGHTC,HEIGHTC_DATE,20170510 -US-Bi1,94501,GRP_HEIGHTC,HEIGHTC,0.083 -US-Bi1,94501,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Bi1,94501,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi1,94501,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,12 -US-Bi1,94501,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi1,94501,GRP_HEIGHTC,HEIGHTC_DATE,20170525 -US-Bi1,94552,GRP_HEIGHTC,HEIGHTC,0.679 -US-Bi1,94552,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Bi1,94552,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi1,94552,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,12 -US-Bi1,94552,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi1,94552,GRP_HEIGHTC,HEIGHTC_DATE,20170525 -US-Bi1,94533,GRP_HEIGHTC,HEIGHTC,0.378 -US-Bi1,94533,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Bi1,94533,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi1,94533,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Bi1,94533,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi1,94533,GRP_HEIGHTC,HEIGHTC_DATE,20170712 -US-Bi1,94580,GRP_HEIGHTC,HEIGHTC,0.051 -US-Bi1,94580,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Bi1,94580,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi1,94580,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Bi1,94580,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi1,94580,GRP_HEIGHTC,HEIGHTC_DATE,20170712 -US-Bi1,94476,GRP_HEIGHTC,HEIGHTC,0.282 -US-Bi1,94476,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Bi1,94476,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi1,94476,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Bi1,94476,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi1,94476,GRP_HEIGHTC,HEIGHTC_DATE,20170809 -US-Bi1,94566,GRP_HEIGHTC,HEIGHTC,0.083 -US-Bi1,94566,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Bi1,94566,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi1,94566,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Bi1,94566,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi1,94566,GRP_HEIGHTC,HEIGHTC_DATE,20170809 -US-Bi1,94522,GRP_HEIGHTC,HEIGHTC,0.072 -US-Bi1,94522,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Bi1,94522,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi1,94522,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Bi1,94522,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi1,94522,GRP_HEIGHTC,HEIGHTC_DATE,20170823 -US-Bi1,94581,GRP_HEIGHTC,HEIGHTC,0.417 -US-Bi1,94581,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Bi1,94581,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi1,94581,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Bi1,94581,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi1,94581,GRP_HEIGHTC,HEIGHTC_DATE,20170823 -US-Bi1,94543,GRP_HEIGHTC,HEIGHTC,0.097 -US-Bi1,94543,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Bi1,94543,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi1,94543,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Bi1,94543,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi1,94543,GRP_HEIGHTC,HEIGHTC_DATE,20170906 -US-Bi1,94557,GRP_HEIGHTC,HEIGHTC,0.025 -US-Bi1,94557,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Bi1,94557,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi1,94557,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Bi1,94557,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi1,94557,GRP_HEIGHTC,HEIGHTC_DATE,20170906 -US-Bi1,94483,GRP_HEIGHTC,HEIGHTC,0.055 -US-Bi1,94483,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Bi1,94483,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi1,94483,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Bi1,94483,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi1,94483,GRP_HEIGHTC,HEIGHTC_DATE,20170919 -US-Bi1,94529,GRP_HEIGHTC,HEIGHTC,0.302 -US-Bi1,94529,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Bi1,94529,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi1,94529,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Bi1,94529,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi1,94529,GRP_HEIGHTC,HEIGHTC_DATE,20170919 -US-Bi1,94536,GRP_HEIGHTC,HEIGHTC,0.044 -US-Bi1,94536,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Bi1,94536,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi1,94536,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,23 -US-Bi1,94536,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi1,94536,GRP_HEIGHTC,HEIGHTC_DATE,20171019 -US-Bi1,94578,GRP_HEIGHTC,HEIGHTC,0.143 -US-Bi1,94578,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Bi1,94578,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi1,94578,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,23 -US-Bi1,94578,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi1,94578,GRP_HEIGHTC,HEIGHTC_DATE,20171019 -US-Bi1,94531,GRP_HEIGHTC,HEIGHTC,0.062 -US-Bi1,94531,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Bi1,94531,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi1,94531,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Bi1,94531,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi1,94531,GRP_HEIGHTC,HEIGHTC_DATE,20171026 -US-Bi1,94577,GRP_HEIGHTC,HEIGHTC,0.192 -US-Bi1,94577,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Bi1,94577,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi1,94577,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Bi1,94577,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi1,94577,GRP_HEIGHTC,HEIGHTC_DATE,20171026 -US-Bi1,94555,GRP_HEIGHTC,HEIGHTC,0.329 -US-Bi1,94555,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Bi1,94555,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi1,94555,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Bi1,94555,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi1,94555,GRP_HEIGHTC,HEIGHTC_DATE,20171110 -US-Bi1,94564,GRP_HEIGHTC,HEIGHTC,0.072 -US-Bi1,94564,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Bi1,94564,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi1,94564,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Bi1,94564,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi1,94564,GRP_HEIGHTC,HEIGHTC_DATE,20171110 -US-Bi1,94487,GRP_HEIGHTC,HEIGHTC,0.322 -US-Bi1,94487,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Bi1,94487,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi1,94487,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Bi1,94487,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi1,94487,GRP_HEIGHTC,HEIGHTC_DATE,20171130 -US-Bi1,94568,GRP_HEIGHTC,HEIGHTC,0.068 -US-Bi1,94568,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Bi1,94568,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi1,94568,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Bi1,94568,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi1,94568,GRP_HEIGHTC,HEIGHTC_DATE,20171130 -US-Bi1,94516,GRP_HEIGHTC,HEIGHTC,0.288 -US-Bi1,94516,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Bi1,94516,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi1,94516,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Bi1,94516,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi1,94516,GRP_HEIGHTC,HEIGHTC_DATE,20171219 -US-Bi1,94516,GRP_HEIGHTC,HEIGHTC_COMMENT,"Uneven canopy height, tops frost burned" -US-Bi1,94526,GRP_HEIGHTC,HEIGHTC,0.07 -US-Bi1,94526,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Bi1,94526,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi1,94526,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Bi1,94526,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi1,94526,GRP_HEIGHTC,HEIGHTC_DATE,20171219 -US-Bi1,94526,GRP_HEIGHTC,HEIGHTC_COMMENT,"Uneven canopy height, tops frost burned" -US-Bi1,94479,GRP_HEIGHTC,HEIGHTC,0.344 -US-Bi1,94479,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Bi1,94479,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi1,94479,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,16 -US-Bi1,94479,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi1,94479,GRP_HEIGHTC,HEIGHTC_DATE,20180104 -US-Bi1,94479,GRP_HEIGHTC,HEIGHTC_COMMENT,Tall and yellowing at tips -US-Bi1,94492,GRP_HEIGHTC,HEIGHTC,0.133 -US-Bi1,94492,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Bi1,94492,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi1,94492,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,16 -US-Bi1,94492,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi1,94492,GRP_HEIGHTC,HEIGHTC_DATE,20180104 -US-Bi1,94492,GRP_HEIGHTC,HEIGHTC_COMMENT,Tall and yellowing at tips -US-Bi1,94538,GRP_HEIGHTC,HEIGHTC,0.228 -US-Bi1,94538,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Bi1,94538,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi1,94538,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,18 -US-Bi1,94538,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi1,94538,GRP_HEIGHTC,HEIGHTC_DATE,20180116 -US-Bi1,94540,GRP_HEIGHTC,HEIGHTC,0.051 -US-Bi1,94540,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Bi1,94540,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi1,94540,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,18 -US-Bi1,94540,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi1,94540,GRP_HEIGHTC,HEIGHTC_DATE,20180116 -US-Bi1,94528,GRP_HEIGHTC,HEIGHTC,0.107 -US-Bi1,94528,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Bi1,94528,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi1,94528,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Bi1,94528,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi1,94528,GRP_HEIGHTC,HEIGHTC_DATE,20180213 -US-Bi1,94542,GRP_HEIGHTC,HEIGHTC,0.017 -US-Bi1,94542,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Bi1,94542,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi1,94542,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Bi1,94542,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi1,94542,GRP_HEIGHTC,HEIGHTC_DATE,20180213 -US-Bi1,94509,GRP_HEIGHTC,HEIGHTC,0.051 -US-Bi1,94509,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Bi1,94509,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi1,94509,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Bi1,94509,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi1,94509,GRP_HEIGHTC,HEIGHTC_DATE,20180319 -US-Bi1,94549,GRP_HEIGHTC,HEIGHTC,0.228 -US-Bi1,94549,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Bi1,94549,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi1,94549,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Bi1,94549,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi1,94549,GRP_HEIGHTC,HEIGHTC_DATE,20180319 -US-Bi1,94498,GRP_HEIGHTC,HEIGHTC,0.048 -US-Bi1,94498,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Bi1,94498,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi1,94498,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Bi1,94498,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi1,94498,GRP_HEIGHTC,HEIGHTC_DATE,20180419 -US-Bi1,94499,GRP_HEIGHTC,HEIGHTC,0.312 -US-Bi1,94499,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Bi1,94499,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi1,94499,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Bi1,94499,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi1,94499,GRP_HEIGHTC,HEIGHTC_DATE,20180419 -US-Bi1,94541,GRP_HEIGHTC,HEIGHTC,0.027 -US-Bi1,94541,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Bi1,94541,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi1,94541,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,19 -US-Bi1,94541,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi1,94541,GRP_HEIGHTC,HEIGHTC_DATE,20180503 -US-Bi1,94553,GRP_HEIGHTC,HEIGHTC,0.109 -US-Bi1,94553,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Bi1,94553,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi1,94553,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,19 -US-Bi1,94553,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi1,94553,GRP_HEIGHTC,HEIGHTC_DATE,20180503 -US-Bi1,94494,GRP_HEIGHTC,HEIGHTC,0.05 -US-Bi1,94494,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Bi1,94494,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi1,94494,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Bi1,94494,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi1,94494,GRP_HEIGHTC,HEIGHTC_DATE,20180516 -US-Bi1,94570,GRP_HEIGHTC,HEIGHTC,0.338 -US-Bi1,94570,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Bi1,94570,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi1,94570,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Bi1,94570,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi1,94570,GRP_HEIGHTC,HEIGHTC_DATE,20180516 -US-Bi1,94472,GRP_HEIGHTC,HEIGHTC,0.091 -US-Bi1,94472,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Bi1,94472,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi1,94472,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Bi1,94472,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi1,94472,GRP_HEIGHTC,HEIGHTC_DATE,20180531 -US-Bi1,94472,GRP_HEIGHTC,HEIGHTC_COMMENT,AV -US-Bi1,94518,GRP_HEIGHTC,HEIGHTC,0.037 -US-Bi1,94518,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Bi1,94518,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi1,94518,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Bi1,94518,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi1,94518,GRP_HEIGHTC,HEIGHTC_DATE,20180531 -US-Bi1,94518,GRP_HEIGHTC,HEIGHTC_COMMENT,AV -US-Bi1,94486,GRP_HEIGHTC,HEIGHTC,0.066 -US-Bi1,94486,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Bi1,94486,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi1,94486,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,19 -US-Bi1,94486,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi1,94486,GRP_HEIGHTC,HEIGHTC_DATE,20180614 -US-Bi1,94539,GRP_HEIGHTC,HEIGHTC,0.344 -US-Bi1,94539,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Bi1,94539,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi1,94539,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,19 -US-Bi1,94539,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi1,94539,GRP_HEIGHTC,HEIGHTC_DATE,20180614 -US-Bi1,94505,GRP_HEIGHTC,HEIGHTC,0.095 -US-Bi1,94505,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Bi1,94505,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi1,94505,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Bi1,94505,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi1,94505,GRP_HEIGHTC,HEIGHTC_DATE,20180712 -US-Bi1,94505,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured by Katrina and Kuno -US-Bi1,94514,GRP_HEIGHTC,HEIGHTC,0.32 -US-Bi1,94514,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Bi1,94514,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi1,94514,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Bi1,94514,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi1,94514,GRP_HEIGHTC,HEIGHTC_DATE,20180712 -US-Bi1,94514,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured by Katrina and Kuno -US-Bi1,94530,GRP_HEIGHTC,HEIGHTC,0.055 -US-Bi1,94530,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Bi1,94530,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi1,94530,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,21 -US-Bi1,94530,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi1,94530,GRP_HEIGHTC,HEIGHTC_DATE,20180726 -US-Bi1,94530,GRP_HEIGHTC,HEIGHTC_COMMENT,"Flowering, full cover, measured by DB" -US-Bi1,94582,GRP_HEIGHTC,HEIGHTC,0.644 -US-Bi1,94582,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Bi1,94582,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi1,94582,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,21 -US-Bi1,94582,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi1,94582,GRP_HEIGHTC,HEIGHTC_DATE,20180726 -US-Bi1,94582,GRP_HEIGHTC,HEIGHTC_COMMENT,"Flowering, full cover, measured by DB" -US-Bi1,94562,GRP_HEIGHTC,HEIGHTC,0.577 -US-Bi1,94562,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Bi1,94562,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi1,94562,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Bi1,94562,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi1,94562,GRP_HEIGHTC,HEIGHTC_DATE,20180823 -US-Bi1,94562,GRP_HEIGHTC,HEIGHTC_COMMENT,"Alfalfa starting to flower, measured by Kuno" -US-Bi1,94563,GRP_HEIGHTC,HEIGHTC,0.113 -US-Bi1,94563,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Bi1,94563,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi1,94563,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Bi1,94563,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi1,94563,GRP_HEIGHTC,HEIGHTC_DATE,20180823 -US-Bi1,94563,GRP_HEIGHTC,HEIGHTC_COMMENT,"Alfalfa starting to flower, measured by Kuno" -US-Bi1,94471,GRP_HEIGHTC,HEIGHTC,0.062 -US-Bi1,94471,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Bi1,94471,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi1,94471,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Bi1,94471,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi1,94471,GRP_HEIGHTC,HEIGHTC_DATE,20180905 -US-Bi1,94471,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured by SC -US-Bi1,94495,GRP_HEIGHTC,HEIGHTC,0.84 -US-Bi1,94495,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Bi1,94495,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi1,94495,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Bi1,94495,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi1,94495,GRP_HEIGHTC,HEIGHTC_DATE,20180905 -US-Bi1,94495,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured by SC -US-Bi1,94485,GRP_HEIGHTC,HEIGHTC,0.383 -US-Bi1,94485,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Bi1,94485,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi1,94485,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Bi1,94485,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi1,94485,GRP_HEIGHTC,HEIGHTC_DATE,20181004 -US-Bi1,94546,GRP_HEIGHTC,HEIGHTC,0.058 -US-Bi1,94546,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Bi1,94546,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi1,94546,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Bi1,94546,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi1,94546,GRP_HEIGHTC,HEIGHTC_DATE,20181004 -US-Bi1,94515,GRP_HEIGHTC,HEIGHTC,0.481 -US-Bi1,94515,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Bi1,94515,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi1,94515,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Bi1,94515,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi1,94515,GRP_HEIGHTC,HEIGHTC_DATE,20181018 -US-Bi1,94527,GRP_HEIGHTC,HEIGHTC,0.07 -US-Bi1,94527,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Bi1,94527,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi1,94527,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Bi1,94527,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi1,94527,GRP_HEIGHTC,HEIGHTC_DATE,20181018 -US-Bi1,94520,GRP_HEIGHTC,HEIGHTC,0.117 -US-Bi1,94520,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Bi1,94520,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi1,94520,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Bi1,94520,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi1,94520,GRP_HEIGHTC,HEIGHTC_DATE,20181101 -US-Bi1,94520,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured by KK -US-Bi1,94537,GRP_HEIGHTC,HEIGHTC,0.032 -US-Bi1,94537,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Bi1,94537,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi1,94537,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Bi1,94537,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi1,94537,GRP_HEIGHTC,HEIGHTC_DATE,20181101 -US-Bi1,94537,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured by KK -US-Bi1,94551,GRP_HEIGHTC,HEIGHTC,0.202 -US-Bi1,94551,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Bi1,94551,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi1,94551,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Bi1,94551,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi1,94551,GRP_HEIGHTC,HEIGHTC_DATE,20181128 -US-Bi1,94551,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured by KH -US-Bi1,94554,GRP_HEIGHTC,HEIGHTC,0.055 -US-Bi1,94554,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Bi1,94554,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi1,94554,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Bi1,94554,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi1,94554,GRP_HEIGHTC,HEIGHTC_DATE,20181128 -US-Bi1,94554,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured by KH -US-Bi1,94491,GRP_HEIGHTC,HEIGHTC,0.054 -US-Bi1,94491,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Bi1,94491,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi1,94491,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Bi1,94491,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi1,94491,GRP_HEIGHTC,HEIGHTC_DATE,20181218 -US-Bi1,94491,GRP_HEIGHTC,HEIGHTC_COMMENT,Daphne measured veg height. -US-Bi1,94576,GRP_HEIGHTC,HEIGHTC,0.223 -US-Bi1,94576,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Bi1,94576,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi1,94576,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Bi1,94576,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi1,94576,GRP_HEIGHTC,HEIGHTC_DATE,20181218 -US-Bi1,94576,GRP_HEIGHTC,HEIGHTC_COMMENT,Daphne measured veg height. -US-Bi1,94473,GRP_HEIGHTC,HEIGHTC,0.3 -US-Bi1,94473,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Bi1,94473,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi1,94473,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Bi1,94473,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi1,94473,GRP_HEIGHTC,HEIGHTC_DATE,20190118 -US-Bi1,94473,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured by CRS -US-Bi1,94484,GRP_HEIGHTC,HEIGHTC,0.049 -US-Bi1,94484,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Bi1,94484,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi1,94484,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Bi1,94484,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi1,94484,GRP_HEIGHTC,HEIGHTC_DATE,20190118 -US-Bi1,94484,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured by CRS -US-Bi1,94490,GRP_HEIGHTC,HEIGHTC,0.13 -US-Bi1,94490,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Bi1,94490,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi1,94490,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Bi1,94490,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi1,94490,GRP_HEIGHTC,HEIGHTC_DATE,20190228 -US-Bi1,94490,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured by CRS -US-Bi1,94511,GRP_HEIGHTC,HEIGHTC,0.037 -US-Bi1,94511,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Bi1,94511,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi1,94511,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Bi1,94511,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi1,94511,GRP_HEIGHTC,HEIGHTC_DATE,20190228 -US-Bi1,94511,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured by CRS -US-Bi1,94478,GRP_HEIGHTC,HEIGHTC,0.034 -US-Bi1,94478,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Bi1,94478,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi1,94478,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Bi1,94478,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi1,94478,GRP_HEIGHTC,HEIGHTC_DATE,20190314 -US-Bi1,94478,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured by Alex -US-Bi1,94502,GRP_HEIGHTC,HEIGHTC,0.091 -US-Bi1,94502,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Bi1,94502,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi1,94502,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Bi1,94502,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi1,94502,GRP_HEIGHTC,HEIGHTC_DATE,20190314 -US-Bi1,94502,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured by Alex -US-Bi1,94550,GRP_HEIGHTC,HEIGHTC,0.06 -US-Bi1,94550,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Bi1,94550,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi1,94550,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Bi1,94550,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi1,94550,GRP_HEIGHTC,HEIGHTC_DATE,20190403 -US-Bi1,94550,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured by CRS -US-Bi1,94567,GRP_HEIGHTC,HEIGHTC,0.381 -US-Bi1,94567,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Bi1,94567,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi1,94567,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Bi1,94567,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi1,94567,GRP_HEIGHTC,HEIGHTC_DATE,20190403 -US-Bi1,94567,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured by CRS -US-Bi1,94497,GRP_HEIGHTC,HEIGHTC,0.042 -US-Bi1,94497,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Bi1,94497,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi1,94497,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Bi1,94497,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi1,94497,GRP_HEIGHTC,HEIGHTC_DATE,20190418 -US-Bi1,94497,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured by JL -US-Bi1,94561,GRP_HEIGHTC,HEIGHTC,0.395 -US-Bi1,94561,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Bi1,94561,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi1,94561,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Bi1,94561,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi1,94561,GRP_HEIGHTC,HEIGHTC_DATE,20190418 -US-Bi1,94561,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured by JL -US-Bi1,94475,GRP_HEIGHTC,HEIGHTC,0.316 -US-Bi1,94475,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Bi1,94475,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi1,94475,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,10 -US-Bi1,94475,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi1,94475,GRP_HEIGHTC,HEIGHTC_DATE,20190620 -US-Bi1,94475,GRP_HEIGHTC,HEIGHTC_COMMENT,"Measured in NW Transect from Tower, ~5m between measurements" -US-Bi1,94524,GRP_HEIGHTC,HEIGHTC,0.066 -US-Bi1,94524,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Bi1,94524,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi1,94524,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,10 -US-Bi1,94524,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi1,94524,GRP_HEIGHTC,HEIGHTC_DATE,20190620 -US-Bi1,94524,GRP_HEIGHTC,HEIGHTC_COMMENT,"Measured in NW Transect from Tower, ~5m between measurements" -US-Bi1,94481,GRP_HEIGHTC,HEIGHTC,0.341 -US-Bi1,94481,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Bi1,94481,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi1,94481,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,10 -US-Bi1,94481,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi1,94481,GRP_HEIGHTC,HEIGHTC_DATE,20190807 -US-Bi1,94510,GRP_HEIGHTC,HEIGHTC,0.045 -US-Bi1,94510,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Bi1,94510,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi1,94510,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,10 -US-Bi1,94510,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi1,94510,GRP_HEIGHTC,HEIGHTC_DATE,20190807 -US-Bi1,94480,GRP_HEIGHTC,HEIGHTC,0.076 -US-Bi1,94480,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Bi1,94480,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi1,94480,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Bi1,94480,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi1,94480,GRP_HEIGHTC,HEIGHTC_DATE,20190904 -US-Bi1,94480,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured by Alex -US-Bi1,94545,GRP_HEIGHTC,HEIGHTC,0.449 -US-Bi1,94545,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Bi1,94545,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi1,94545,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Bi1,94545,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi1,94545,GRP_HEIGHTC,HEIGHTC_DATE,20190904 -US-Bi1,94545,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured by Alex -US-Bi1,94507,GRP_HEIGHTC,HEIGHTC,0.699 -US-Bi1,94507,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Bi1,94507,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi1,94507,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,12 -US-Bi1,94507,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi1,94507,GRP_HEIGHTC,HEIGHTC_DATE,20190917 -US-Bi1,94507,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured by DS -US-Bi1,94548,GRP_HEIGHTC,HEIGHTC,0.071 -US-Bi1,94548,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Bi1,94548,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi1,94548,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,12 -US-Bi1,94548,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi1,94548,GRP_HEIGHTC,HEIGHTC_DATE,20190917 -US-Bi1,94548,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured by DS -US-Bi1,94489,GRP_HEIGHTC,HEIGHTC,0.034 -US-Bi1,94489,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Bi1,94489,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi1,94489,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Bi1,94489,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi1,94489,GRP_HEIGHTC,HEIGHTC_DATE,20191002 -US-Bi1,94489,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured by AAO -US-Bi1,94558,GRP_HEIGHTC,HEIGHTC,0.232 -US-Bi1,94558,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Bi1,94558,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi1,94558,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Bi1,94558,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi1,94558,GRP_HEIGHTC,HEIGHTC_DATE,20191002 -US-Bi1,94558,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured by AAO -US-Bi1,94474,GRP_HEIGHTC,HEIGHTC,0.086 -US-Bi1,94474,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Bi1,94474,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi1,94474,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Bi1,94474,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi1,94474,GRP_HEIGHTC,HEIGHTC_DATE,20191017 -US-Bi1,94474,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured by DS -US-Bi1,94575,GRP_HEIGHTC,HEIGHTC,0.401 -US-Bi1,94575,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Bi1,94575,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi1,94575,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Bi1,94575,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi1,94575,GRP_HEIGHTC,HEIGHTC_DATE,20191017 -US-Bi1,94575,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured by DS -US-Bi1,94534,GRP_HEIGHTC,HEIGHTC,0.074 -US-Bi1,94534,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Bi1,94534,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi1,94534,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,10 -US-Bi1,94534,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi1,94534,GRP_HEIGHTC,HEIGHTC_DATE,20191031 -US-Bi1,94534,GRP_HEIGHTC,HEIGHTC_COMMENT,Bales still on the field -US-Bi1,94559,GRP_HEIGHTC,HEIGHTC,0.03 -US-Bi1,94559,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Bi1,94559,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi1,94559,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,10 -US-Bi1,94559,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi1,94559,GRP_HEIGHTC,HEIGHTC_DATE,20191031 -US-Bi1,94559,GRP_HEIGHTC,HEIGHTC_COMMENT,Bales still on the field -US-Bi1,94482,GRP_HEIGHTC,HEIGHTC,0.061 -US-Bi1,94482,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Bi1,94482,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi1,94482,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Bi1,94482,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi1,94482,GRP_HEIGHTC,HEIGHTC_DATE,20191114 -US-Bi1,94504,GRP_HEIGHTC,HEIGHTC,0.184 -US-Bi1,94504,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Bi1,94504,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi1,94504,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Bi1,94504,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi1,94504,GRP_HEIGHTC,HEIGHTC_DATE,20191114 -US-Bi1,94496,GRP_HEIGHTC,HEIGHTC,0.319 -US-Bi1,94496,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Bi1,94496,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi1,94496,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,16 -US-Bi1,94496,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi1,94496,GRP_HEIGHTC,HEIGHTC_DATE,20191217 -US-Bi1,94500,GRP_HEIGHTC,HEIGHTC,0.055 -US-Bi1,94500,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Bi1,94500,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi1,94500,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,16 -US-Bi1,94500,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi1,94500,GRP_HEIGHTC,HEIGHTC_DATE,20191217 -US-Bi1,94477,GRP_HEIGHTC,HEIGHTC,0.056 -US-Bi1,94477,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Bi1,94477,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi1,94477,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Bi1,94477,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi1,94477,GRP_HEIGHTC,HEIGHTC_DATE,20200107 -US-Bi1,94574,GRP_HEIGHTC,HEIGHTC,0.391 -US-Bi1,94574,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Bi1,94574,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi1,94574,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Bi1,94574,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi1,94574,GRP_HEIGHTC,HEIGHTC_DATE,20200107 -US-Bi1,94506,GRP_HEIGHTC,HEIGHTC,0.335 -US-Bi1,94506,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Bi1,94506,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi1,94506,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Bi1,94506,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi1,94506,GRP_HEIGHTC,HEIGHTC_DATE,20200123 -US-Bi1,94506,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured with water level tape instead of measuring tape -US-Bi1,94560,GRP_HEIGHTC,HEIGHTC,0.063 -US-Bi1,94560,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Bi1,94560,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi1,94560,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Bi1,94560,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi1,94560,GRP_HEIGHTC,HEIGHTC_DATE,20200123 -US-Bi1,94560,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured with water level tape instead of measuring tape -US-Bi1,94532,GRP_HEIGHTC,HEIGHTC,0.331 -US-Bi1,94532,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Bi1,94532,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi1,94532,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Bi1,94532,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi1,94532,GRP_HEIGHTC,HEIGHTC_DATE,20200306 -US-Bi1,94573,GRP_HEIGHTC,HEIGHTC,0.056 -US-Bi1,94573,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Bi1,94573,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi1,94573,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Bi1,94573,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi1,94573,GRP_HEIGHTC,HEIGHTC_DATE,20200306 -US-Bi1,94503,GRP_HEIGHTC,HEIGHTC,0.082 -US-Bi1,94503,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Bi1,94503,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi1,94503,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Bi1,94503,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi1,94503,GRP_HEIGHTC,HEIGHTC_DATE,20200403 -US-Bi1,94535,GRP_HEIGHTC,HEIGHTC,0.607 -US-Bi1,94535,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Bi1,94535,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi1,94535,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Bi1,94535,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi1,94535,GRP_HEIGHTC,HEIGHTC_DATE,20200403 -US-Bi1,94493,GRP_HEIGHTC,HEIGHTC,0.106 -US-Bi1,94493,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Bi1,94493,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi1,94493,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,10 -US-Bi1,94493,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi1,94493,GRP_HEIGHTC,HEIGHTC_DATE,20200417 -US-Bi1,94517,GRP_HEIGHTC,HEIGHTC,0.773 -US-Bi1,94517,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Bi1,94517,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi1,94517,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,10 -US-Bi1,94517,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi1,94517,GRP_HEIGHTC,HEIGHTC_DATE,20200417 -US-Bi1,94523,GRP_HEIGHTC,HEIGHTC,0.072 -US-Bi1,94523,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Bi1,94523,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi1,94523,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Bi1,94523,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi1,94523,GRP_HEIGHTC,HEIGHTC_DATE,20200519 -US-Bi1,94556,GRP_HEIGHTC,HEIGHTC,0.463 -US-Bi1,94556,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Bi1,94556,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi1,94556,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Bi1,94556,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi1,94556,GRP_HEIGHTC,HEIGHTC_DATE,20200519 -US-Bi1,94488,GRP_HEIGHTC,HEIGHTC,0.078 -US-Bi1,94488,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Bi1,94488,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi1,94488,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,10 -US-Bi1,94488,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi1,94488,GRP_HEIGHTC,HEIGHTC_DATE,20200609 -US-Bi1,94488,GRP_HEIGHTC,HEIGHTC_COMMENT,"Mowed five days ago, baling today" -US-Bi1,94519,GRP_HEIGHTC,HEIGHTC,0.029 -US-Bi1,94519,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Bi1,94519,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi1,94519,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,10 -US-Bi1,94519,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi1,94519,GRP_HEIGHTC,HEIGHTC_DATE,20200609 -US-Bi1,94519,GRP_HEIGHTC,HEIGHTC_COMMENT,"Mowed five days ago, baling today" -US-Bi1,94571,GRP_HEIGHTC,HEIGHTC,0.073 -US-Bi1,94571,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Bi1,94571,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi1,94571,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Bi1,94571,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi1,94571,GRP_HEIGHTC,HEIGHTC_DATE,20200701 -US-Bi1,94572,GRP_HEIGHTC,HEIGHTC,0.53 -US-Bi1,94572,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Bi1,94572,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi1,94572,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Bi1,94572,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi1,94572,GRP_HEIGHTC,HEIGHTC_DATE,20200701 -US-Bi1,94525,GRP_HEIGHTC,HEIGHTC,0.08 -US-Bi1,94525,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Bi1,94525,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi1,94525,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,8 -US-Bi1,94525,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi1,94525,GRP_HEIGHTC,HEIGHTC_DATE,20201005 -US-Bi1,94565,GRP_HEIGHTC,HEIGHTC,0.565 -US-Bi1,94565,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Bi1,94565,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi1,94565,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,8 -US-Bi1,94565,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi1,94565,GRP_HEIGHTC,HEIGHTC_DATE,20201005 -US-Bi1,30365,GRP_IGBP,IGBP,CRO -US-Bi1,30365,GRP_IGBP,IGBP_DATE_START,201608111800 -US-Bi1,92452,GRP_LAI,LAI,0.044 -US-Bi1,92452,GRP_LAI,LAI_TYPE,PAI -US-Bi1,92452,GRP_LAI,LAI_CANOPY_TYPE,Total -US-Bi1,92452,GRP_LAI,LAI_STATISTIC,Standard Deviation -US-Bi1,92452,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-Bi1,92452,GRP_LAI,LAI_STATISTIC_NUMBER,3 -US-Bi1,92452,GRP_LAI,LAI_METHOD,Direct -US-Bi1,92452,GRP_LAI,LAI_APPROACH,"1600cm2 Clip plot, PAI scanned with LI-3100, oven dried" -US-Bi1,92452,GRP_LAI,LAI_DATE,20170906 -US-Bi1,92452,GRP_LAI,LAI_COMMENT,Sample STDEV -US-Bi1,92476,GRP_LAI,LAI,0.054 -US-Bi1,92476,GRP_LAI,LAI_TYPE,PAI -US-Bi1,92476,GRP_LAI,LAI_CANOPY_TYPE,Total -US-Bi1,92476,GRP_LAI,LAI_STATISTIC,Standard Deviation -US-Bi1,92476,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-Bi1,92476,GRP_LAI,LAI_STATISTIC_NUMBER,5 -US-Bi1,92476,GRP_LAI,LAI_METHOD,Direct -US-Bi1,92476,GRP_LAI,LAI_APPROACH,"1600cm2 Clip plot, PAI scanned with LI-3100, oven dried" -US-Bi1,92476,GRP_LAI,LAI_DATE,20180503 -US-Bi1,92476,GRP_LAI,LAI_COMMENT,Sample STDEV -US-Bi1,92449,GRP_LAI,LAI,0.067 -US-Bi1,92449,GRP_LAI,LAI_TYPE,PAI -US-Bi1,92449,GRP_LAI,LAI_CANOPY_TYPE,Total -US-Bi1,92449,GRP_LAI,LAI_STATISTIC,Standard Deviation -US-Bi1,92449,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-Bi1,92449,GRP_LAI,LAI_STATISTIC_NUMBER,5 -US-Bi1,92449,GRP_LAI,LAI_METHOD,Direct -US-Bi1,92449,GRP_LAI,LAI_APPROACH,"1600cm2 Clip plot, PAI scanned with LI-3100, oven dried" -US-Bi1,92449,GRP_LAI,LAI_DATE,20180531 -US-Bi1,92449,GRP_LAI,LAI_COMMENT,Sample STDEV -US-Bi1,92470,GRP_LAI,LAI,0.08 -US-Bi1,92470,GRP_LAI,LAI_TYPE,PAI -US-Bi1,92470,GRP_LAI,LAI_CANOPY_TYPE,Total -US-Bi1,92470,GRP_LAI,LAI_STATISTIC,Standard Deviation -US-Bi1,92470,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-Bi1,92470,GRP_LAI,LAI_STATISTIC_NUMBER,5 -US-Bi1,92470,GRP_LAI,LAI_METHOD,Direct -US-Bi1,92470,GRP_LAI,LAI_APPROACH,"1600cm2 Clip plot, PAI scanned with LI-3100, oven dried" -US-Bi1,92470,GRP_LAI,LAI_DATE,20200519 -US-Bi1,92470,GRP_LAI,LAI_COMMENT,Sample STDEV -US-Bi1,92441,GRP_LAI,LAI,0.081 -US-Bi1,92441,GRP_LAI,LAI_TYPE,PAI -US-Bi1,92441,GRP_LAI,LAI_CANOPY_TYPE,Total -US-Bi1,92441,GRP_LAI,LAI_STATISTIC,Standard Deviation -US-Bi1,92441,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-Bi1,92441,GRP_LAI,LAI_STATISTIC_NUMBER,5 -US-Bi1,92441,GRP_LAI,LAI_METHOD,Direct -US-Bi1,92441,GRP_LAI,LAI_APPROACH,"1600cm2 Clip plot, PAI scanned with LI-3100, oven dried" -US-Bi1,92441,GRP_LAI,LAI_DATE,20180213 -US-Bi1,92441,GRP_LAI,LAI_COMMENT,Sample STDEV -US-Bi1,92436,GRP_LAI,LAI,0.102 -US-Bi1,92436,GRP_LAI,LAI_TYPE,PAI -US-Bi1,92436,GRP_LAI,LAI_CANOPY_TYPE,Total -US-Bi1,92436,GRP_LAI,LAI_STATISTIC,Standard Deviation -US-Bi1,92436,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-Bi1,92436,GRP_LAI,LAI_STATISTIC_NUMBER,5 -US-Bi1,92436,GRP_LAI,LAI_METHOD,Direct -US-Bi1,92436,GRP_LAI,LAI_APPROACH,"1600cm2 Clip plot, PAI scanned with LI-3100, oven dried" -US-Bi1,92436,GRP_LAI,LAI_DATE,20180726 -US-Bi1,92436,GRP_LAI,LAI_COMMENT,Sample STDEV -US-Bi1,92469,GRP_LAI,LAI,0.107 -US-Bi1,92469,GRP_LAI,LAI_TYPE,PAI -US-Bi1,92469,GRP_LAI,LAI_CANOPY_TYPE,Total -US-Bi1,92469,GRP_LAI,LAI_STATISTIC,Mean -US-Bi1,92469,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-Bi1,92469,GRP_LAI,LAI_STATISTIC_NUMBER,5 -US-Bi1,92469,GRP_LAI,LAI_METHOD,Direct -US-Bi1,92469,GRP_LAI,LAI_APPROACH,"1600cm2 Clip plot, PAI scanned with LI-3100, oven dried" -US-Bi1,92469,GRP_LAI,LAI_DATE,20180531 -US-Bi1,92478,GRP_LAI,LAI,0.108 -US-Bi1,92478,GRP_LAI,LAI_TYPE,PAI -US-Bi1,92478,GRP_LAI,LAI_CANOPY_TYPE,Total -US-Bi1,92478,GRP_LAI,LAI_STATISTIC,Standard Deviation -US-Bi1,92478,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-Bi1,92478,GRP_LAI,LAI_STATISTIC_NUMBER,5 -US-Bi1,92478,GRP_LAI,LAI_METHOD,Direct -US-Bi1,92478,GRP_LAI,LAI_APPROACH,"1600cm2 Clip plot, PAI scanned with LI-3100, oven dried" -US-Bi1,92478,GRP_LAI,LAI_DATE,20170809 -US-Bi1,92478,GRP_LAI,LAI_COMMENT,Sample STDEV -US-Bi1,92454,GRP_LAI,LAI,0.109 -US-Bi1,92454,GRP_LAI,LAI_TYPE,PAI -US-Bi1,92454,GRP_LAI,LAI_CANOPY_TYPE,Total -US-Bi1,92454,GRP_LAI,LAI_STATISTIC,Standard Deviation -US-Bi1,92454,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-Bi1,92454,GRP_LAI,LAI_STATISTIC_NUMBER,5 -US-Bi1,92454,GRP_LAI,LAI_METHOD,Direct -US-Bi1,92454,GRP_LAI,LAI_APPROACH,"1600cm2 Clip plot, PAI scanned with LI-3100, oven dried" -US-Bi1,92454,GRP_LAI,LAI_DATE,20180419 -US-Bi1,92454,GRP_LAI,LAI_COMMENT,Sample STDEV -US-Bi1,92434,GRP_LAI,LAI,0.136 -US-Bi1,92434,GRP_LAI,LAI_TYPE,PAI -US-Bi1,92434,GRP_LAI,LAI_CANOPY_TYPE,Total -US-Bi1,92434,GRP_LAI,LAI_STATISTIC,Standard Deviation -US-Bi1,92434,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-Bi1,92434,GRP_LAI,LAI_STATISTIC_NUMBER,5 -US-Bi1,92434,GRP_LAI,LAI_METHOD,Direct -US-Bi1,92434,GRP_LAI,LAI_APPROACH,"1600cm2 Clip plot, PAI scanned with LI-3100, oven dried" -US-Bi1,92434,GRP_LAI,LAI_DATE,20170919 -US-Bi1,92434,GRP_LAI,LAI_COMMENT,Sample STDEV -US-Bi1,92463,GRP_LAI,LAI,0.136 -US-Bi1,92463,GRP_LAI,LAI_TYPE,PAI -US-Bi1,92463,GRP_LAI,LAI_CANOPY_TYPE,Total -US-Bi1,92463,GRP_LAI,LAI_STATISTIC,Standard Deviation -US-Bi1,92463,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-Bi1,92463,GRP_LAI,LAI_STATISTIC_NUMBER,3 -US-Bi1,92463,GRP_LAI,LAI_METHOD,Direct -US-Bi1,92463,GRP_LAI,LAI_APPROACH,"1600cm2 Clip plot, PAI scanned with LI-3100, oven dried" -US-Bi1,92463,GRP_LAI,LAI_DATE,20171019 -US-Bi1,92463,GRP_LAI,LAI_COMMENT,Sample STDEV -US-Bi1,92427,GRP_LAI,LAI,0.155 -US-Bi1,92427,GRP_LAI,LAI_TYPE,PAI -US-Bi1,92427,GRP_LAI,LAI_CANOPY_TYPE,Total -US-Bi1,92427,GRP_LAI,LAI_STATISTIC,Standard Deviation -US-Bi1,92427,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-Bi1,92427,GRP_LAI,LAI_STATISTIC_NUMBER,5 -US-Bi1,92427,GRP_LAI,LAI_METHOD,Direct -US-Bi1,92427,GRP_LAI,LAI_APPROACH,"1600cm2 Clip plot, PAI scanned with LI-3100, oven dried" -US-Bi1,92427,GRP_LAI,LAI_DATE,20170823 -US-Bi1,92427,GRP_LAI,LAI_COMMENT,Sample STDEV -US-Bi1,92438,GRP_LAI,LAI,0.158 -US-Bi1,92438,GRP_LAI,LAI_TYPE,PAI -US-Bi1,92438,GRP_LAI,LAI_CANOPY_TYPE,Total -US-Bi1,92438,GRP_LAI,LAI_STATISTIC,Standard Deviation -US-Bi1,92438,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-Bi1,92438,GRP_LAI,LAI_STATISTIC_NUMBER,5 -US-Bi1,92438,GRP_LAI,LAI_METHOD,Direct -US-Bi1,92438,GRP_LAI,LAI_APPROACH,"1600cm2 Clip plot, PAI scanned with LI-3100, oven dried" -US-Bi1,92438,GRP_LAI,LAI_DATE,20170411 -US-Bi1,92438,GRP_LAI,LAI_COMMENT,Sample STDEV -US-Bi1,92465,GRP_LAI,LAI,0.159 -US-Bi1,92465,GRP_LAI,LAI_TYPE,PAI -US-Bi1,92465,GRP_LAI,LAI_CANOPY_TYPE,Total -US-Bi1,92465,GRP_LAI,LAI_STATISTIC,Standard Deviation -US-Bi1,92465,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-Bi1,92465,GRP_LAI,LAI_STATISTIC_NUMBER,5 -US-Bi1,92465,GRP_LAI,LAI_METHOD,Direct -US-Bi1,92465,GRP_LAI,LAI_APPROACH,"1600cm2 Clip plot, PAI scanned with LI-3100, oven dried" -US-Bi1,92465,GRP_LAI,LAI_DATE,20170315 -US-Bi1,92465,GRP_LAI,LAI_COMMENT,Sample STDEV -US-Bi1,92433,GRP_LAI,LAI,0.16 -US-Bi1,92433,GRP_LAI,LAI_TYPE,PAI -US-Bi1,92433,GRP_LAI,LAI_CANOPY_TYPE,Total -US-Bi1,92433,GRP_LAI,LAI_STATISTIC,Mean -US-Bi1,92433,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-Bi1,92433,GRP_LAI,LAI_STATISTIC_NUMBER,5 -US-Bi1,92433,GRP_LAI,LAI_METHOD,Direct -US-Bi1,92433,GRP_LAI,LAI_APPROACH,"1600cm2 Clip plot, PAI scanned with LI-3100, oven dried" -US-Bi1,92433,GRP_LAI,LAI_DATE,20180503 -US-Bi1,92431,GRP_LAI,LAI,0.169 -US-Bi1,92431,GRP_LAI,LAI_TYPE,PAI -US-Bi1,92431,GRP_LAI,LAI_CANOPY_TYPE,Total -US-Bi1,92431,GRP_LAI,LAI_STATISTIC,Mean -US-Bi1,92431,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-Bi1,92431,GRP_LAI,LAI_STATISTIC_NUMBER,3 -US-Bi1,92431,GRP_LAI,LAI_METHOD,Direct -US-Bi1,92431,GRP_LAI,LAI_APPROACH,"1600cm2 Clip plot, PAI scanned with LI-3100, oven dried" -US-Bi1,92431,GRP_LAI,LAI_DATE,20170906 -US-Bi1,92429,GRP_LAI,LAI,0.182 -US-Bi1,92429,GRP_LAI,LAI_TYPE,PAI -US-Bi1,92429,GRP_LAI,LAI_CANOPY_TYPE,Total -US-Bi1,92429,GRP_LAI,LAI_STATISTIC,Standard Deviation -US-Bi1,92429,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-Bi1,92429,GRP_LAI,LAI_STATISTIC_NUMBER,5 -US-Bi1,92429,GRP_LAI,LAI_METHOD,Direct -US-Bi1,92429,GRP_LAI,LAI_APPROACH,"1600cm2 Clip plot, PAI scanned with LI-3100, oven dried" -US-Bi1,92429,GRP_LAI,LAI_DATE,20170712 -US-Bi1,92429,GRP_LAI,LAI_COMMENT,Sample STDEV -US-Bi1,92445,GRP_LAI,LAI,0.186 -US-Bi1,92445,GRP_LAI,LAI_TYPE,PAI -US-Bi1,92445,GRP_LAI,LAI_CANOPY_TYPE,Total -US-Bi1,92445,GRP_LAI,LAI_STATISTIC,Standard Deviation -US-Bi1,92445,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-Bi1,92445,GRP_LAI,LAI_STATISTIC_NUMBER,5 -US-Bi1,92445,GRP_LAI,LAI_METHOD,Direct -US-Bi1,92445,GRP_LAI,LAI_APPROACH,"1849cm2 Clip plot, PAI scanned with LI-3100, oven dried" -US-Bi1,92445,GRP_LAI,LAI_DATE,20190403 -US-Bi1,92445,GRP_LAI,LAI_COMMENT,Sample STDEV -US-Bi1,92466,GRP_LAI,LAI,0.213 -US-Bi1,92466,GRP_LAI,LAI_TYPE,PAI -US-Bi1,92466,GRP_LAI,LAI_CANOPY_TYPE,Total -US-Bi1,92466,GRP_LAI,LAI_STATISTIC,Mean -US-Bi1,92466,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-Bi1,92466,GRP_LAI,LAI_STATISTIC_NUMBER,3 -US-Bi1,92466,GRP_LAI,LAI_METHOD,Direct -US-Bi1,92466,GRP_LAI,LAI_APPROACH,"1600cm2 Clip plot, PAI scanned with LI-3100, oven dried" -US-Bi1,92466,GRP_LAI,LAI_DATE,20171019 -US-Bi1,92468,GRP_LAI,LAI,0.229 -US-Bi1,92468,GRP_LAI,LAI_TYPE,PAI -US-Bi1,92468,GRP_LAI,LAI_CANOPY_TYPE,Total -US-Bi1,92468,GRP_LAI,LAI_STATISTIC,Standard Deviation -US-Bi1,92468,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-Bi1,92468,GRP_LAI,LAI_STATISTIC_NUMBER,3 -US-Bi1,92468,GRP_LAI,LAI_METHOD,Direct -US-Bi1,92468,GRP_LAI,LAI_APPROACH,"1600cm2 Clip plot, PAI scanned with LI-3100, oven dried" -US-Bi1,92468,GRP_LAI,LAI_DATE,20190711 -US-Bi1,92468,GRP_LAI,LAI_COMMENT,Sample STDEV -US-Bi1,92473,GRP_LAI,LAI,0.248 -US-Bi1,92473,GRP_LAI,LAI_TYPE,PAI -US-Bi1,92473,GRP_LAI,LAI_CANOPY_TYPE,Total -US-Bi1,92473,GRP_LAI,LAI_STATISTIC,Standard Deviation -US-Bi1,92473,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-Bi1,92473,GRP_LAI,LAI_STATISTIC_NUMBER,5 -US-Bi1,92473,GRP_LAI,LAI_METHOD,Direct -US-Bi1,92473,GRP_LAI,LAI_APPROACH,"1600cm2 Clip plot, PAI scanned with LI-3100, oven dried" -US-Bi1,92473,GRP_LAI,LAI_DATE,20180319 -US-Bi1,92473,GRP_LAI,LAI_COMMENT,Sample STDEV -US-Bi1,92432,GRP_LAI,LAI,0.255 -US-Bi1,92432,GRP_LAI,LAI_TYPE,PAI -US-Bi1,92432,GRP_LAI,LAI_CANOPY_TYPE,Total -US-Bi1,92432,GRP_LAI,LAI_STATISTIC,Standard Deviation -US-Bi1,92432,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-Bi1,92432,GRP_LAI,LAI_STATISTIC_NUMBER,4 -US-Bi1,92432,GRP_LAI,LAI_METHOD,Direct -US-Bi1,92432,GRP_LAI,LAI_APPROACH,"1600cm2 Clip plot, PAI scanned with LI-3100, oven dried" -US-Bi1,92432,GRP_LAI,LAI_DATE,20180614 -US-Bi1,92432,GRP_LAI,LAI_COMMENT,Sample STDEV -US-Bi1,92446,GRP_LAI,LAI,0.282 -US-Bi1,92446,GRP_LAI,LAI_TYPE,PAI -US-Bi1,92446,GRP_LAI,LAI_CANOPY_TYPE,Total -US-Bi1,92446,GRP_LAI,LAI_STATISTIC,Standard Deviation -US-Bi1,92446,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-Bi1,92446,GRP_LAI,LAI_STATISTIC_NUMBER,5 -US-Bi1,92446,GRP_LAI,LAI_METHOD,Direct -US-Bi1,92446,GRP_LAI,LAI_APPROACH,"1600cm2 Clip plot, PAI scanned with LI-3100, oven dried" -US-Bi1,92446,GRP_LAI,LAI_DATE,20170510 -US-Bi1,92446,GRP_LAI,LAI_COMMENT,Sample STDEV -US-Bi1,92464,GRP_LAI,LAI,0.345 -US-Bi1,92464,GRP_LAI,LAI_TYPE,PAI -US-Bi1,92464,GRP_LAI,LAI_CANOPY_TYPE,Total -US-Bi1,92464,GRP_LAI,LAI_STATISTIC,Standard Deviation -US-Bi1,92464,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-Bi1,92464,GRP_LAI,LAI_STATISTIC_NUMBER,5 -US-Bi1,92464,GRP_LAI,LAI_METHOD,Direct -US-Bi1,92464,GRP_LAI,LAI_APPROACH,"1600cm2 Clip plot, PAI scanned with LI-3100, oven dried" -US-Bi1,92464,GRP_LAI,LAI_DATE,20171130 -US-Bi1,92464,GRP_LAI,LAI_COMMENT,Sample STDEV -US-Bi1,92443,GRP_LAI,LAI,0.369 -US-Bi1,92443,GRP_LAI,LAI_TYPE,PAI -US-Bi1,92443,GRP_LAI,LAI_CANOPY_TYPE,Total -US-Bi1,92443,GRP_LAI,LAI_STATISTIC,Mean -US-Bi1,92443,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-Bi1,92443,GRP_LAI,LAI_STATISTIC_NUMBER,5 -US-Bi1,92443,GRP_LAI,LAI_METHOD,Direct -US-Bi1,92443,GRP_LAI,LAI_APPROACH,"1600cm2 Clip plot, PAI scanned with LI-3100, oven dried" -US-Bi1,92443,GRP_LAI,LAI_DATE,20180213 -US-Bi1,92459,GRP_LAI,LAI,0.374 -US-Bi1,92459,GRP_LAI,LAI_TYPE,PAI -US-Bi1,92459,GRP_LAI,LAI_CANOPY_TYPE,Total -US-Bi1,92459,GRP_LAI,LAI_STATISTIC,Mean -US-Bi1,92459,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-Bi1,92459,GRP_LAI,LAI_STATISTIC_NUMBER,5 -US-Bi1,92459,GRP_LAI,LAI_METHOD,Direct -US-Bi1,92459,GRP_LAI,LAI_APPROACH,"1600cm2 Clip plot, PAI scanned with LI-3100, oven dried" -US-Bi1,92459,GRP_LAI,LAI_DATE,20170919 -US-Bi1,92471,GRP_LAI,LAI,0.399 -US-Bi1,92471,GRP_LAI,LAI_TYPE,PAI -US-Bi1,92471,GRP_LAI,LAI_CANOPY_TYPE,Total -US-Bi1,92471,GRP_LAI,LAI_STATISTIC,Mean -US-Bi1,92471,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-Bi1,92471,GRP_LAI,LAI_STATISTIC_NUMBER,5 -US-Bi1,92471,GRP_LAI,LAI_METHOD,Direct -US-Bi1,92471,GRP_LAI,LAI_APPROACH,"1600cm2 Clip plot, PAI scanned with LI-3100, oven dried" -US-Bi1,92471,GRP_LAI,LAI_DATE,20170809 -US-Bi1,92458,GRP_LAI,LAI,0.41 -US-Bi1,92458,GRP_LAI,LAI_TYPE,PAI -US-Bi1,92458,GRP_LAI,LAI_CANOPY_TYPE,Total -US-Bi1,92458,GRP_LAI,LAI_STATISTIC,Standard Deviation -US-Bi1,92458,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-Bi1,92458,GRP_LAI,LAI_STATISTIC_NUMBER,5 -US-Bi1,92458,GRP_LAI,LAI_METHOD,Direct -US-Bi1,92458,GRP_LAI,LAI_APPROACH,"1600cm2 Clip plot, PAI scanned with LI-3100, oven dried" -US-Bi1,92458,GRP_LAI,LAI_DATE,20170329 -US-Bi1,92458,GRP_LAI,LAI_COMMENT,Sample STDEV -US-Bi1,92460,GRP_LAI,LAI,0.437 -US-Bi1,92460,GRP_LAI,LAI_TYPE,PAI -US-Bi1,92460,GRP_LAI,LAI_CANOPY_TYPE,Total -US-Bi1,92460,GRP_LAI,LAI_STATISTIC,Standard Deviation -US-Bi1,92460,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-Bi1,92460,GRP_LAI,LAI_STATISTIC_NUMBER,5 -US-Bi1,92460,GRP_LAI,LAI_METHOD,Direct -US-Bi1,92460,GRP_LAI,LAI_APPROACH,"1600cm2 Clip plot, PAI scanned with LI-3100, oven dried" -US-Bi1,92460,GRP_LAI,LAI_DATE,20181018 -US-Bi1,92460,GRP_LAI,LAI_COMMENT,Sample STDEV -US-Bi1,92440,GRP_LAI,LAI,0.439 -US-Bi1,92440,GRP_LAI,LAI_TYPE,PAI -US-Bi1,92440,GRP_LAI,LAI_CANOPY_TYPE,Total -US-Bi1,92440,GRP_LAI,LAI_STATISTIC,Mean -US-Bi1,92440,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-Bi1,92440,GRP_LAI,LAI_STATISTIC_NUMBER,5 -US-Bi1,92440,GRP_LAI,LAI_METHOD,Direct -US-Bi1,92440,GRP_LAI,LAI_APPROACH,"1600cm2 Clip plot, PAI scanned with LI-3100, oven dried" -US-Bi1,92440,GRP_LAI,LAI_DATE,20170712 -US-Bi1,92448,GRP_LAI,LAI,0.452 -US-Bi1,92448,GRP_LAI,LAI_TYPE,PAI -US-Bi1,92448,GRP_LAI,LAI_CANOPY_TYPE,Total -US-Bi1,92448,GRP_LAI,LAI_STATISTIC,Standard Deviation -US-Bi1,92448,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-Bi1,92448,GRP_LAI,LAI_STATISTIC_NUMBER,5 -US-Bi1,92448,GRP_LAI,LAI_METHOD,Direct -US-Bi1,92448,GRP_LAI,LAI_APPROACH,"1600cm2 Clip plot, PAI scanned with LI-3100, oven dried" -US-Bi1,92448,GRP_LAI,LAI_DATE,20180823 -US-Bi1,92448,GRP_LAI,LAI_COMMENT,Sample STDEV -US-Bi1,92442,GRP_LAI,LAI,0.512 -US-Bi1,92442,GRP_LAI,LAI_TYPE,PAI -US-Bi1,92442,GRP_LAI,LAI_CANOPY_TYPE,Total -US-Bi1,92442,GRP_LAI,LAI_STATISTIC,Standard Deviation -US-Bi1,92442,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-Bi1,92442,GRP_LAI,LAI_STATISTIC_NUMBER,5 -US-Bi1,92442,GRP_LAI,LAI_METHOD,Direct -US-Bi1,92442,GRP_LAI,LAI_APPROACH,"1600cm2 Clip plot, PAI scanned with LI-3100, oven dried" -US-Bi1,92442,GRP_LAI,LAI_DATE,20191017 -US-Bi1,92442,GRP_LAI,LAI_COMMENT,Sample STDEV -US-Bi1,92447,GRP_LAI,LAI,0.529 -US-Bi1,92447,GRP_LAI,LAI_TYPE,PAI -US-Bi1,92447,GRP_LAI,LAI_CANOPY_TYPE,Total -US-Bi1,92447,GRP_LAI,LAI_STATISTIC,Mean -US-Bi1,92447,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-Bi1,92447,GRP_LAI,LAI_STATISTIC_NUMBER,5 -US-Bi1,92447,GRP_LAI,LAI_METHOD,Direct -US-Bi1,92447,GRP_LAI,LAI_APPROACH,"1600cm2 Clip plot, PAI scanned with LI-3100, oven dried" -US-Bi1,92447,GRP_LAI,LAI_DATE,20170823 -US-Bi1,92437,GRP_LAI,LAI,0.599 -US-Bi1,92437,GRP_LAI,LAI_TYPE,PAI -US-Bi1,92437,GRP_LAI,LAI_CANOPY_TYPE,Total -US-Bi1,92437,GRP_LAI,LAI_STATISTIC,Standard Deviation -US-Bi1,92437,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-Bi1,92437,GRP_LAI,LAI_STATISTIC_NUMBER,3 -US-Bi1,92437,GRP_LAI,LAI_METHOD,Direct -US-Bi1,92437,GRP_LAI,LAI_APPROACH,"1600cm2 Clip plot, PAI scanned with LI-3100, oven dried" -US-Bi1,92437,GRP_LAI,LAI_DATE,20171219 -US-Bi1,92437,GRP_LAI,LAI_COMMENT,Sample STDEV -US-Bi1,92467,GRP_LAI,LAI,0.619 -US-Bi1,92467,GRP_LAI,LAI_TYPE,PAI -US-Bi1,92467,GRP_LAI,LAI_CANOPY_TYPE,Total -US-Bi1,92467,GRP_LAI,LAI_STATISTIC,Standard Deviation -US-Bi1,92467,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-Bi1,92467,GRP_LAI,LAI_STATISTIC_NUMBER,5 -US-Bi1,92467,GRP_LAI,LAI_METHOD,Direct -US-Bi1,92467,GRP_LAI,LAI_APPROACH,"2500cm2 Clip plot, PAI scanned with LI-3100, oven dried" -US-Bi1,92467,GRP_LAI,LAI_DATE,20190523 -US-Bi1,92467,GRP_LAI,LAI_COMMENT,Sample STDEV -US-Bi1,92435,GRP_LAI,LAI,0.736 -US-Bi1,92435,GRP_LAI,LAI_TYPE,PAI -US-Bi1,92435,GRP_LAI,LAI_CANOPY_TYPE,Total -US-Bi1,92435,GRP_LAI,LAI_STATISTIC,Mean -US-Bi1,92435,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-Bi1,92435,GRP_LAI,LAI_STATISTIC_NUMBER,5 -US-Bi1,92435,GRP_LAI,LAI_METHOD,Direct -US-Bi1,92435,GRP_LAI,LAI_APPROACH,"1600cm2 Clip plot, PAI scanned with LI-3100, oven dried" -US-Bi1,92435,GRP_LAI,LAI_DATE,20180419 -US-Bi1,92439,GRP_LAI,LAI,0.744 -US-Bi1,92439,GRP_LAI,LAI_TYPE,PAI -US-Bi1,92439,GRP_LAI,LAI_CANOPY_TYPE,Total -US-Bi1,92439,GRP_LAI,LAI_STATISTIC,Mean -US-Bi1,92439,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-Bi1,92439,GRP_LAI,LAI_STATISTIC_NUMBER,4 -US-Bi1,92439,GRP_LAI,LAI_METHOD,Direct -US-Bi1,92439,GRP_LAI,LAI_APPROACH,"1600cm2 Clip plot, PAI scanned with LI-3100, oven dried" -US-Bi1,92439,GRP_LAI,LAI_DATE,20180614 -US-Bi1,92430,GRP_LAI,LAI,0.861 -US-Bi1,92430,GRP_LAI,LAI_TYPE,PAI -US-Bi1,92430,GRP_LAI,LAI_CANOPY_TYPE,Total -US-Bi1,92430,GRP_LAI,LAI_STATISTIC,Standard Deviation -US-Bi1,92430,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-Bi1,92430,GRP_LAI,LAI_STATISTIC_NUMBER,5 -US-Bi1,92430,GRP_LAI,LAI_METHOD,Direct -US-Bi1,92430,GRP_LAI,LAI_APPROACH,"1600cm2 Clip plot, PAI scanned with LI-3100, oven dried" -US-Bi1,92430,GRP_LAI,LAI_DATE,20190604 -US-Bi1,92430,GRP_LAI,LAI_COMMENT,Sample STDEV -US-Bi1,92450,GRP_LAI,LAI,0.875 -US-Bi1,92450,GRP_LAI,LAI_TYPE,PAI -US-Bi1,92450,GRP_LAI,LAI_CANOPY_TYPE,Total -US-Bi1,92450,GRP_LAI,LAI_STATISTIC,Mean -US-Bi1,92450,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-Bi1,92450,GRP_LAI,LAI_STATISTIC_NUMBER,5 -US-Bi1,92450,GRP_LAI,LAI_METHOD,Direct -US-Bi1,92450,GRP_LAI,LAI_APPROACH,"1600cm2 Clip plot, PAI scanned with LI-3100, oven dried" -US-Bi1,92450,GRP_LAI,LAI_DATE,20200519 -US-Bi1,92450,GRP_LAI,LAI_COMMENT,"Some alfalfa were flowering, changed LI-3100 bulb before these samples" -US-Bi1,92456,GRP_LAI,LAI,0.902 -US-Bi1,92456,GRP_LAI,LAI_TYPE,PAI -US-Bi1,92456,GRP_LAI,LAI_CANOPY_TYPE,Total -US-Bi1,92456,GRP_LAI,LAI_STATISTIC,Mean -US-Bi1,92456,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-Bi1,92456,GRP_LAI,LAI_STATISTIC_NUMBER,5 -US-Bi1,92456,GRP_LAI,LAI_METHOD,Direct -US-Bi1,92456,GRP_LAI,LAI_APPROACH,"1600cm2 Clip plot, PAI scanned with LI-3100, oven dried" -US-Bi1,92456,GRP_LAI,LAI_DATE,20180319 -US-Bi1,92480,GRP_LAI,LAI,0.982 -US-Bi1,92480,GRP_LAI,LAI_TYPE,PAI -US-Bi1,92480,GRP_LAI,LAI_CANOPY_TYPE,Total -US-Bi1,92480,GRP_LAI,LAI_STATISTIC,Mean -US-Bi1,92480,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-Bi1,92480,GRP_LAI,LAI_STATISTIC_NUMBER,5 -US-Bi1,92480,GRP_LAI,LAI_METHOD,Direct -US-Bi1,92480,GRP_LAI,LAI_APPROACH,"1600cm2 Clip plot, PAI scanned with LI-3100, oven dried" -US-Bi1,92480,GRP_LAI,LAI_DATE,20171130 -US-Bi1,92479,GRP_LAI,LAI,1.034 -US-Bi1,92479,GRP_LAI,LAI_TYPE,PAI -US-Bi1,92479,GRP_LAI,LAI_CANOPY_TYPE,Total -US-Bi1,92479,GRP_LAI,LAI_STATISTIC,Mean -US-Bi1,92479,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-Bi1,92479,GRP_LAI,LAI_STATISTIC_NUMBER,5 -US-Bi1,92479,GRP_LAI,LAI_METHOD,Direct -US-Bi1,92479,GRP_LAI,LAI_APPROACH,"1600cm2 Clip plot, PAI scanned with LI-3100, oven dried" -US-Bi1,92479,GRP_LAI,LAI_DATE,20180726 -US-Bi1,92455,GRP_LAI,LAI,1.123 -US-Bi1,92455,GRP_LAI,LAI_TYPE,PAI -US-Bi1,92455,GRP_LAI,LAI_CANOPY_TYPE,Total -US-Bi1,92455,GRP_LAI,LAI_STATISTIC,Mean -US-Bi1,92455,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-Bi1,92455,GRP_LAI,LAI_STATISTIC_NUMBER,5 -US-Bi1,92455,GRP_LAI,LAI_METHOD,Direct -US-Bi1,92455,GRP_LAI,LAI_APPROACH,"1849cm2 Clip plot, PAI scanned with LI-3100, oven dried" -US-Bi1,92455,GRP_LAI,LAI_DATE,20190403 -US-Bi1,92474,GRP_LAI,LAI,1.257 -US-Bi1,92474,GRP_LAI,LAI_TYPE,PAI -US-Bi1,92474,GRP_LAI,LAI_CANOPY_TYPE,Total -US-Bi1,92474,GRP_LAI,LAI_STATISTIC,Mean -US-Bi1,92474,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-Bi1,92474,GRP_LAI,LAI_STATISTIC_NUMBER,3 -US-Bi1,92474,GRP_LAI,LAI_METHOD,Direct -US-Bi1,92474,GRP_LAI,LAI_APPROACH,"1600cm2 Clip plot, PAI scanned with LI-3100, oven dried" -US-Bi1,92474,GRP_LAI,LAI_DATE,20171219 -US-Bi1,92462,GRP_LAI,LAI,1.328 -US-Bi1,92462,GRP_LAI,LAI_TYPE,PAI -US-Bi1,92462,GRP_LAI,LAI_CANOPY_TYPE,Total -US-Bi1,92462,GRP_LAI,LAI_STATISTIC,Mean -US-Bi1,92462,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-Bi1,92462,GRP_LAI,LAI_STATISTIC_NUMBER,5 -US-Bi1,92462,GRP_LAI,LAI_METHOD,Direct -US-Bi1,92462,GRP_LAI,LAI_APPROACH,"1600cm2 Clip plot, PAI scanned with LI-3100, oven dried" -US-Bi1,92462,GRP_LAI,LAI_DATE,20170315 -US-Bi1,92472,GRP_LAI,LAI,1.443 -US-Bi1,92472,GRP_LAI,LAI_TYPE,PAI -US-Bi1,92472,GRP_LAI,LAI_CANOPY_TYPE,Total -US-Bi1,92472,GRP_LAI,LAI_STATISTIC,Mean -US-Bi1,92472,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-Bi1,92472,GRP_LAI,LAI_STATISTIC_NUMBER,5 -US-Bi1,92472,GRP_LAI,LAI_METHOD,Direct -US-Bi1,92472,GRP_LAI,LAI_APPROACH,"1600cm2 Clip plot, PAI scanned with LI-3100, oven dried" -US-Bi1,92472,GRP_LAI,LAI_DATE,20180823 -US-Bi1,92444,GRP_LAI,LAI,1.509 -US-Bi1,92444,GRP_LAI,LAI_TYPE,PAI -US-Bi1,92444,GRP_LAI,LAI_CANOPY_TYPE,Total -US-Bi1,92444,GRP_LAI,LAI_STATISTIC,Mean -US-Bi1,92444,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-Bi1,92444,GRP_LAI,LAI_STATISTIC_NUMBER,5 -US-Bi1,92444,GRP_LAI,LAI_METHOD,Direct -US-Bi1,92444,GRP_LAI,LAI_APPROACH,"1600cm2 Clip plot, PAI scanned with LI-3100, oven dried" -US-Bi1,92444,GRP_LAI,LAI_DATE,20170510 -US-Bi1,92428,GRP_LAI,LAI,1.805 -US-Bi1,92428,GRP_LAI,LAI_TYPE,PAI -US-Bi1,92428,GRP_LAI,LAI_CANOPY_TYPE,Total -US-Bi1,92428,GRP_LAI,LAI_STATISTIC,Mean -US-Bi1,92428,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-Bi1,92428,GRP_LAI,LAI_STATISTIC_NUMBER,5 -US-Bi1,92428,GRP_LAI,LAI_METHOD,Direct -US-Bi1,92428,GRP_LAI,LAI_APPROACH,"2500cm2 Clip plot, PAI scanned with LI-3100, oven dried" -US-Bi1,92428,GRP_LAI,LAI_DATE,20190523 -US-Bi1,92461,GRP_LAI,LAI,1.884 -US-Bi1,92461,GRP_LAI,LAI_TYPE,PAI -US-Bi1,92461,GRP_LAI,LAI_CANOPY_TYPE,Total -US-Bi1,92461,GRP_LAI,LAI_STATISTIC,Mean -US-Bi1,92461,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-Bi1,92461,GRP_LAI,LAI_STATISTIC_NUMBER,5 -US-Bi1,92461,GRP_LAI,LAI_METHOD,Direct -US-Bi1,92461,GRP_LAI,LAI_APPROACH,"1600cm2 Clip plot, PAI scanned with LI-3100, oven dried" -US-Bi1,92461,GRP_LAI,LAI_DATE,20191017 -US-Bi1,92457,GRP_LAI,LAI,1.904 -US-Bi1,92457,GRP_LAI,LAI_TYPE,PAI -US-Bi1,92457,GRP_LAI,LAI_CANOPY_TYPE,Total -US-Bi1,92457,GRP_LAI,LAI_STATISTIC,Mean -US-Bi1,92457,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-Bi1,92457,GRP_LAI,LAI_STATISTIC_NUMBER,3 -US-Bi1,92457,GRP_LAI,LAI_METHOD,Direct -US-Bi1,92457,GRP_LAI,LAI_APPROACH,"1600cm2 Clip plot, PAI scanned with LI-3100, oven dried" -US-Bi1,92457,GRP_LAI,LAI_DATE,20190711 -US-Bi1,92477,GRP_LAI,LAI,1.967 -US-Bi1,92477,GRP_LAI,LAI_TYPE,PAI -US-Bi1,92477,GRP_LAI,LAI_CANOPY_TYPE,Total -US-Bi1,92477,GRP_LAI,LAI_STATISTIC,Mean -US-Bi1,92477,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-Bi1,92477,GRP_LAI,LAI_STATISTIC_NUMBER,5 -US-Bi1,92477,GRP_LAI,LAI_METHOD,Direct -US-Bi1,92477,GRP_LAI,LAI_APPROACH,"1600cm2 Clip plot, PAI scanned with LI-3100, oven dried" -US-Bi1,92477,GRP_LAI,LAI_DATE,20181018 -US-Bi1,92451,GRP_LAI,LAI,2.002 -US-Bi1,92451,GRP_LAI,LAI_TYPE,PAI -US-Bi1,92451,GRP_LAI,LAI_CANOPY_TYPE,Total -US-Bi1,92451,GRP_LAI,LAI_STATISTIC,Mean -US-Bi1,92451,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-Bi1,92451,GRP_LAI,LAI_STATISTIC_NUMBER,5 -US-Bi1,92451,GRP_LAI,LAI_METHOD,Direct -US-Bi1,92451,GRP_LAI,LAI_APPROACH,"1600cm2 Clip plot, PAI scanned with LI-3100, oven dried" -US-Bi1,92451,GRP_LAI,LAI_DATE,20170329 -US-Bi1,92453,GRP_LAI,LAI,2.321 -US-Bi1,92453,GRP_LAI,LAI_TYPE,PAI -US-Bi1,92453,GRP_LAI,LAI_CANOPY_TYPE,Total -US-Bi1,92453,GRP_LAI,LAI_STATISTIC,Mean -US-Bi1,92453,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-Bi1,92453,GRP_LAI,LAI_STATISTIC_NUMBER,5 -US-Bi1,92453,GRP_LAI,LAI_METHOD,Direct -US-Bi1,92453,GRP_LAI,LAI_APPROACH,"1600cm2 Clip plot, PAI scanned with LI-3100, oven dried" -US-Bi1,92453,GRP_LAI,LAI_DATE,20170411 -US-Bi1,92475,GRP_LAI,LAI,3.596 -US-Bi1,92475,GRP_LAI,LAI_TYPE,PAI -US-Bi1,92475,GRP_LAI,LAI_CANOPY_TYPE,Total -US-Bi1,92475,GRP_LAI,LAI_STATISTIC,Mean -US-Bi1,92475,GRP_LAI,LAI_STATISTIC_TYPE,Spatial -US-Bi1,92475,GRP_LAI,LAI_STATISTIC_NUMBER,5 -US-Bi1,92475,GRP_LAI,LAI_METHOD,Direct -US-Bi1,92475,GRP_LAI,LAI_APPROACH,"1600cm2 Clip plot, PAI scanned with LI-3100, oven dried" -US-Bi1,92475,GRP_LAI,LAI_DATE,20190604 -US-Bi1,30363,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -US-Bi1,30363,GRP_LAND_OWNERSHIP,LAND_OWNER,Los Angeles Metropolitan Water District -US-Bi1,86634,GRP_LOCATION,LOCATION_LAT,38.0992 -US-Bi1,86634,GRP_LOCATION,LOCATION_LONG,-121.4993 -US-Bi1,86634,GRP_LOCATION,LOCATION_ELEV,-2.7 -US-Bi1,86634,GRP_LOCATION,LOCATION_DATE_START,201608111800 -US-Bi1,30373,GRP_NETWORK,NETWORK,AmeriFlux -US-Bi1,86952,GRP_NETWORK,NETWORK,Phenocam -US-Bi1,1700005358,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Baldocchi, D. D., Ryu, Y., Dechant, B., Eichelmann, E., Hemes, K., Ma, S., Sanchez, C. R., Shortt, R., Szutu, D., Valach, A., Verfaillie, J., Badgley, G., Zeng, Y., Berry, J. A. (2020) Outgoing Near‐Infrared Radiation From Vegetation Scales With Canopy Photosynthesis Across A Spectrum Of Function, Structure, Physiological Capacity, And Weather, Journal Of Geophysical Research: Biogeosciences, 125(7), 108350" -US-Bi1,1700005358,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2019JG005534 -US-Bi1,1700005358,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Bi1,1700001980,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Baldocchi, D. D., Ryu, Y., Dechant, B., Eichelmann, E., Hemes, K., Ma, S., Sanchez, C. R., Shortt, R., Szutu, D., Valach, A., Verfaillie, J., Badgley, G., Zeng, Y., Berry, J. A. (2020) Outgoing Near‐Infrared Radiation From Vegetation Scales With Canopy Photosynthesis Across A Spectrum Of Function, Structure, Physiological Capacity, And Weather, Journal Of Geophysical Research: Biogeosciences, 125(7), 202-214" -US-Bi1,1700001980,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2019JG005534 -US-Bi1,1700001980,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Bi1,1700007860,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(), 108350" -US-Bi1,1700007860,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -US-Bi1,1700007860,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Bi1,1700005352,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Hemes, K. S., Chamberlain, S. D., Eichelmann, E., Anthony, T., Valach, A., Kasak, K., Szutu, D., Verfaillie, J., Silver, W. L., Baldocchi, D. D. (2019) Assessing The Carbon And Climate Benefit Of Restoring Degraded Agricultural Peat Soils To Managed Wetlands, Agricultural And Forest Meteorology, 268(), 202-214" -US-Bi1,1700005352,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2019.01.017 -US-Bi1,1700005352,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Primary_Citation -US-Bi1,1700007158,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Hemes, K. S., Chamberlain, S. D., Eichelmann, E., Anthony, T., Valach, A., Kasak, K., Szutu, D., Verfaillie, J., Silver, W. L., Baldocchi, D. D. (2019) Assessing The Carbon And Climate Benefit Of Restoring Degraded Agricultural Peat Soils To Managed Wetlands, Agricultural And Forest Meteorology, 268(7), 202-214" -US-Bi1,1700007158,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2019.01.017 -US-Bi1,1700007158,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Primary_Citation -US-Bi1,1700005508,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Hemes, K. S., Verfaillie, J., Baldocchi, D. D. (2020) Wildfire‐Smoke Aerosols Lead To Increased Light Use Efficiency Among Agricultural And Restored Wetland Land Uses In California'S Central Valley, Journal Of Geophysical Research: Biogeosciences, 268(), 202-214" -US-Bi1,1700005508,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2019JG005380 -US-Bi1,1700005508,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Bi1,1700001185,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Hemes, K. S., Verfaillie, J., Baldocchi, D. D. (2020) Wildfire‐Smoke Aerosols Lead To Increased Light Use Efficiency Among Agricultural And Restored Wetland Land Uses In California'S Central Valley, Journal Of Geophysical Research: Biogeosciences, 268(7), 202-214" -US-Bi1,1700001185,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2019JG005380 -US-Bi1,1700001185,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Bi1,1700001977,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Rey‐Sanchez, C., Wharton, S., Vilà‐Guerau de Arellano, J., Paw U, K. T., Hemes, K. S., Fuentes, J. D., Osuna, J., Szutu, D., Ribeiro, J. V., Verfaillie, J., Baldocchi, D. (2021) Evaluation Of Atmospheric Boundary Layer Height From Wind Profiling Radar And Slab Models And Its Responses To Seasonality Of Land Cover, Subsidence, And Advection, Journal Of Geophysical Research: Atmospheres, 126(7), 108350" -US-Bi1,1700001977,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2020JD033775 -US-Bi1,1700001977,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Bi1,1700003750,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Rey‐Sanchez, C., Wharton, S., Vilà‐Guerau de Arellano, J., Paw U, K. T., Hemes, K. S., Fuentes, J. D., Osuna, J., Szutu, D., Ribeiro, J. V., Verfaillie, J., Baldocchi, D. (2021) Evaluation Of Atmospheric Boundary Layer Height From Wind Profiling Radar And Slab Models And Its Responses To Seasonality Of Land Cover, Subsidence, And Advection, Journal Of Geophysical Research: Atmospheres, 126(7), 202-214" -US-Bi1,1700003750,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2020JD033775 -US-Bi1,1700003750,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Bi1,30362,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,soil subsidence and greenhouse gas budgets -US-Bi1,30372,GRP_SITE_CHAR,TERRAIN,Flat -US-Bi1,30372,GRP_SITE_CHAR,ASPECT,FLAT -US-Bi1,30372,GRP_SITE_CHAR,WIND_DIRECTION,W -US-Bi1,30372,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,1000 -US-Bi1,30372,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,0 -US-Bi1,97350,GRP_SITE_DESC,SITE_DESC,An agricultural field in the San Joaquin Sacramento Delta. The field is a mix of organic peat and sediments and minerals from old river channels -US-Bi1,30355,GRP_SITE_FUNDING,SITE_FUNDING,CA Dept Water Resources/CA Dept Fish and Wildlife -US-Bi1,30360,GRP_STATE,STATE,CA -US-Bi1,30369,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Dennis Baldocchi -US-Bi1,30369,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Bi1,30369,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,Baldocchi@berkeley.edu -US-Bi1,30369,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"University of California, Berkeley" -US-Bi1,30369,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Department of Environmental Science, Policy and Management, 130 Mulford Hall, Berkeley, CA USA 94720-3110" -US-Bi1,98920,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Tianxin 'Carlos' Wang -US-Bi1,98920,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-Bi1,98920,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,cawang@berkeley.edu -US-Bi1,98920,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"University of California, Berkeley" -US-Bi1,98920,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"130 Mulford Hall, Berkeley, CA" -US-Bi1,81382,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Daphne Szutu -US-Bi1,81382,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Technician -US-Bi1,81382,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,daphneszutu@berkeley.edu -US-Bi1,81382,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"University of California, Berkeley" -US-Bi1,81382,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"130 Mulford Hall, Berkeley, CA" -US-Bi1,30357,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Joe Verfaillie -US-Bi1,30357,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Technician -US-Bi1,30357,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,jverfail@berkeley.edu -US-Bi1,30357,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"University of California, Berkeley" -US-Bi1,30357,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"130 Mulford Hall, Berkeley, CA" -US-Bi1,30356,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-Bi1,30359,GRP_TOWER_TYPE,TOWER_TYPE,walk-up -US-Bi1,30361,GRP_URL,URL,https://nature.berkeley.edu/biometlab/sites.php?site=US-Bi1 -US-Bi1,24000690,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-Bi1 -US-Bi1,84726,GRP_UTC_OFFSET,UTC_OFFSET,-8 -US-Bi2,31259,GRP_CLIM_AVG,MAT,16 -US-Bi2,31259,GRP_CLIM_AVG,MAP,338 -US-Bi2,31259,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Csa -US-Bi2,27000721,GRP_COUNTRY,COUNTRY,USA -US-Bi2,79480,GRP_DOI,DOI,10.17190/AMF/1419513 -US-Bi2,79480,GRP_DOI,DOI_CITATION,"Camilo Rey-Sanchez, Carlos Tianxin Wang, Daphne Szutu, Kyle Hemes, Joseph Verfaillie, Dennis Baldocchi (2022), AmeriFlux BASE US-Bi2 Bouldin Island corn, Ver. 13-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1419513" -US-Bi2,79480,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-Bi2,98365,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Bi2,98365,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Camilo Rey-Sanchez -US-Bi2,98365,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Bi2,98365,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,1 -US-Bi2,98365,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0003-4762-9001 -US-Bi2,98365,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,rey.1@berkeley.edu -US-Bi2,98365,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"University of California, Berkeley" -US-Bi2,98365,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,20190619 -US-Bi2,98365,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_END,20210621 -US-Bi2,98366,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Bi2,98366,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Carlos Tianxin Wang -US-Bi2,98366,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Bi2,98366,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,1 -US-Bi2,98366,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0002-2709-9122 -US-Bi2,98366,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,cawang@berkeley.edu -US-Bi2,98366,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"University of California, Berkeley" -US-Bi2,98366,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,20210622 -US-Bi2,94037,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Bi2,94037,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Daphne Szutu -US-Bi2,94037,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Bi2,94037,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,2 -US-Bi2,94037,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0001-7698-0461 -US-Bi2,94037,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,daphneszutu@berkeley.edu -US-Bi2,94037,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"University of California, Berkeley" -US-Bi2,94037,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,20170426 -US-Bi2,98371,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Bi2,98371,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Kyle Hemes -US-Bi2,98371,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Bi2,98371,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,3 -US-Bi2,98371,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0001-5090-1083 -US-Bi2,98371,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,hemesphere@gmail.com -US-Bi2,98371,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"University of California, Berkeley" -US-Bi2,98371,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,20170426 -US-Bi2,98371,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_END,20190618 -US-Bi2,94103,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Bi2,94103,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Joseph Verfaillie -US-Bi2,94103,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Bi2,94103,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,4 -US-Bi2,94103,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0002-7009-8942 -US-Bi2,94103,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,jverfail@berkeley.edu -US-Bi2,94103,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"University of California, Berkeley" -US-Bi2,94103,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,20170426 -US-Bi2,94017,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Bi2,94017,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Dennis Baldocchi -US-Bi2,94017,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Bi2,94017,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,5 -US-Bi2,94017,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0003-3496-4919 -US-Bi2,94017,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,baldocchi@berkeley.edu -US-Bi2,94017,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"University of California, Berkeley" -US-Bi2,94017,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,20170426 -US-Bi2,79467,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,"University of California, Berkeley" -US-Bi2,79467,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-Bi2,79466,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,CA Dept Water Resources/CA Dept Fish and Wildlife -US-Bi2,79466,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-Bi2,31249,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Agriculture -US-Bi2,31261,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Bi2,31261,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-Bi2,31261,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201704261500 -US-Bi2,31261,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Bi2,31261,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,"co2, H2O, sensible heat, momentum" -US-Bi2,31257,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Bi2,31257,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CH4 -US-Bi2,31257,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201704261500 -US-Bi2,31257,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Bi2,31258,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Bi2,31258,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-Bi2,31258,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201704261500 -US-Bi2,31258,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Bi2,23000721,GRP_HEADER,SITE_NAME,Bouldin Island corn -US-Bi2,94624,GRP_HEIGHTC,HEIGHTC,0.079 -US-Bi2,94624,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Bi2,94624,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi2,94624,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Bi2,94624,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi2,94624,GRP_HEIGHTC,HEIGHTC_DATE,20170623 -US-Bi2,94635,GRP_HEIGHTC,HEIGHTC,0.28 -US-Bi2,94635,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Bi2,94635,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi2,94635,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Bi2,94635,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi2,94635,GRP_HEIGHTC,HEIGHTC_DATE,20170623 -US-Bi2,94594,GRP_HEIGHTC,HEIGHTC,1.393 -US-Bi2,94594,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Bi2,94594,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi2,94594,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Bi2,94594,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi2,94594,GRP_HEIGHTC,HEIGHTC_DATE,20170712 -US-Bi2,94630,GRP_HEIGHTC,HEIGHTC,0.186 -US-Bi2,94630,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Bi2,94630,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi2,94630,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Bi2,94630,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi2,94630,GRP_HEIGHTC,HEIGHTC_DATE,20170712 -US-Bi2,94587,GRP_HEIGHTC,HEIGHTC,2.123 -US-Bi2,94587,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Bi2,94587,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi2,94587,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,34 -US-Bi2,94587,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi2,94587,GRP_HEIGHTC,HEIGHTC_DATE,20170726 -US-Bi2,94587,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured by DB and KH -US-Bi2,94592,GRP_HEIGHTC,HEIGHTC,0.334 -US-Bi2,94592,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Bi2,94592,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi2,94592,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,34 -US-Bi2,94592,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi2,94592,GRP_HEIGHTC,HEIGHTC_DATE,20170726 -US-Bi2,94592,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured by DB and KH -US-Bi2,94583,GRP_HEIGHTC,HEIGHTC,3.141 -US-Bi2,94583,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Bi2,94583,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi2,94583,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,25 -US-Bi2,94583,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi2,94583,GRP_HEIGHTC,HEIGHTC_DATE,20170809 -US-Bi2,94610,GRP_HEIGHTC,HEIGHTC,0.132 -US-Bi2,94610,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Bi2,94610,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi2,94610,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,25 -US-Bi2,94610,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi2,94610,GRP_HEIGHTC,HEIGHTC_DATE,20170809 -US-Bi2,94611,GRP_HEIGHTC,HEIGHTC,3.035 -US-Bi2,94611,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Bi2,94611,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi2,94611,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,26 -US-Bi2,94611,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi2,94611,GRP_HEIGHTC,HEIGHTC_DATE,20170823 -US-Bi2,94619,GRP_HEIGHTC,HEIGHTC,0.251 -US-Bi2,94619,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Bi2,94619,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi2,94619,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,26 -US-Bi2,94619,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi2,94619,GRP_HEIGHTC,HEIGHTC_DATE,20170823 -US-Bi2,94589,GRP_HEIGHTC,HEIGHTC,3.15 -US-Bi2,94589,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Bi2,94589,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi2,94589,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,3 -US-Bi2,94589,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi2,94589,GRP_HEIGHTC,HEIGHTC_DATE,20170906 -US-Bi2,94621,GRP_HEIGHTC,HEIGHTC,0.131 -US-Bi2,94621,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Bi2,94621,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi2,94621,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,3 -US-Bi2,94621,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi2,94621,GRP_HEIGHTC,HEIGHTC_DATE,20170906 -US-Bi2,94607,GRP_HEIGHTC,HEIGHTC,2.903 -US-Bi2,94607,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Bi2,94607,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi2,94607,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,15 -US-Bi2,94607,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi2,94607,GRP_HEIGHTC,HEIGHTC_DATE,20170919 -US-Bi2,94617,GRP_HEIGHTC,HEIGHTC,0.143 -US-Bi2,94617,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Bi2,94617,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi2,94617,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,15 -US-Bi2,94617,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi2,94617,GRP_HEIGHTC,HEIGHTC_DATE,20170919 -US-Bi2,94599,GRP_HEIGHTC,HEIGHTC,0.046 -US-Bi2,94599,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Bi2,94599,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi2,94599,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,21 -US-Bi2,94599,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi2,94599,GRP_HEIGHTC,HEIGHTC_DATE,20180614 -US-Bi2,94631,GRP_HEIGHTC,HEIGHTC,0.209 -US-Bi2,94631,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Bi2,94631,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi2,94631,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,21 -US-Bi2,94631,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi2,94631,GRP_HEIGHTC,HEIGHTC_DATE,20180614 -US-Bi2,94595,GRP_HEIGHTC,HEIGHTC,0.156 -US-Bi2,94595,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Bi2,94595,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi2,94595,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Bi2,94595,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi2,94595,GRP_HEIGHTC,HEIGHTC_DATE,20180712 -US-Bi2,94603,GRP_HEIGHTC,HEIGHTC,1.67 -US-Bi2,94603,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Bi2,94603,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi2,94603,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Bi2,94603,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi2,94603,GRP_HEIGHTC,HEIGHTC_DATE,20180712 -US-Bi2,94586,GRP_HEIGHTC,HEIGHTC,2.009 -US-Bi2,94586,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Bi2,94586,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi2,94586,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,10 -US-Bi2,94586,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi2,94586,GRP_HEIGHTC,HEIGHTC_DATE,20180726 -US-Bi2,94629,GRP_HEIGHTC,HEIGHTC,0.097 -US-Bi2,94629,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Bi2,94629,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi2,94629,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,10 -US-Bi2,94629,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi2,94629,GRP_HEIGHTC,HEIGHTC_DATE,20180726 -US-Bi2,94618,GRP_HEIGHTC,HEIGHTC,2.657 -US-Bi2,94618,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Bi2,94618,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi2,94618,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,15 -US-Bi2,94618,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi2,94618,GRP_HEIGHTC,HEIGHTC_DATE,20180807 -US-Bi2,94618,GRP_HEIGHTC,HEIGHTC_COMMENT,Corn is Tasseling. Measured by R.S. -US-Bi2,94627,GRP_HEIGHTC,HEIGHTC,0.172 -US-Bi2,94627,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Bi2,94627,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi2,94627,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,15 -US-Bi2,94627,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi2,94627,GRP_HEIGHTC,HEIGHTC_DATE,20180807 -US-Bi2,94627,GRP_HEIGHTC,HEIGHTC_COMMENT,Corn is Tasseling. Measured by R.S. -US-Bi2,94604,GRP_HEIGHTC,HEIGHTC,2.622 -US-Bi2,94604,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Bi2,94604,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi2,94604,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,10 -US-Bi2,94604,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi2,94604,GRP_HEIGHTC,HEIGHTC_DATE,20180823 -US-Bi2,94604,GRP_HEIGHTC,HEIGHTC_COMMENT,measured by Kuno -US-Bi2,94613,GRP_HEIGHTC,HEIGHTC,0.152 -US-Bi2,94613,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Bi2,94613,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi2,94613,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,10 -US-Bi2,94613,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi2,94613,GRP_HEIGHTC,HEIGHTC_DATE,20180823 -US-Bi2,94613,GRP_HEIGHTC,HEIGHTC_COMMENT,measured by Kuno -US-Bi2,94608,GRP_HEIGHTC,HEIGHTC,0.086 -US-Bi2,94608,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Bi2,94608,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi2,94608,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,10 -US-Bi2,94608,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi2,94608,GRP_HEIGHTC,HEIGHTC_DATE,20180905 -US-Bi2,94608,GRP_HEIGHTC,HEIGHTC_COMMENT,measured by SC -US-Bi2,94614,GRP_HEIGHTC,HEIGHTC,2.578 -US-Bi2,94614,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Bi2,94614,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi2,94614,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,10 -US-Bi2,94614,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi2,94614,GRP_HEIGHTC,HEIGHTC_DATE,20180905 -US-Bi2,94614,GRP_HEIGHTC,HEIGHTC_COMMENT,measured by SC -US-Bi2,94616,GRP_HEIGHTC,HEIGHTC,0.116 -US-Bi2,94616,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Bi2,94616,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi2,94616,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,10 -US-Bi2,94616,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi2,94616,GRP_HEIGHTC,HEIGHTC_DATE,20190620 -US-Bi2,94616,GRP_HEIGHTC,HEIGHTC_COMMENT,Measurements taken in NE transect across footprint. ~5m between measurements. -US-Bi2,94632,GRP_HEIGHTC,HEIGHTC,0.432 -US-Bi2,94632,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Bi2,94632,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi2,94632,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,10 -US-Bi2,94632,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi2,94632,GRP_HEIGHTC,HEIGHTC_DATE,20190620 -US-Bi2,94632,GRP_HEIGHTC,HEIGHTC_COMMENT,Measurements taken in NE transect across footprint. ~5m between measurements. -US-Bi2,94598,GRP_HEIGHTC,HEIGHTC,1.65 -US-Bi2,94598,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Bi2,94598,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi2,94598,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,5 -US-Bi2,94598,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi2,94598,GRP_HEIGHTC,HEIGHTC_DATE,20190711 -US-Bi2,94600,GRP_HEIGHTC,HEIGHTC,0.137 -US-Bi2,94600,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Bi2,94600,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi2,94600,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,5 -US-Bi2,94600,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi2,94600,GRP_HEIGHTC,HEIGHTC_DATE,20190711 -US-Bi2,94625,GRP_HEIGHTC,HEIGHTC,2.543 -US-Bi2,94625,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Bi2,94625,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi2,94625,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,10 -US-Bi2,94625,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi2,94625,GRP_HEIGHTC,HEIGHTC_DATE,20190726 -US-Bi2,94625,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured by DS -US-Bi2,94634,GRP_HEIGHTC,HEIGHTC,0.093 -US-Bi2,94634,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Bi2,94634,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi2,94634,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,10 -US-Bi2,94634,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi2,94634,GRP_HEIGHTC,HEIGHTC_DATE,20190726 -US-Bi2,94634,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured by DS -US-Bi2,94585,GRP_HEIGHTC,HEIGHTC,0.228 -US-Bi2,94585,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Bi2,94585,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi2,94585,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,10 -US-Bi2,94585,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi2,94585,GRP_HEIGHTC,HEIGHTC_DATE,20190807 -US-Bi2,94585,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured by RS -US-Bi2,94606,GRP_HEIGHTC,HEIGHTC,2.776 -US-Bi2,94606,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Bi2,94606,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi2,94606,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,10 -US-Bi2,94606,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi2,94606,GRP_HEIGHTC,HEIGHTC_DATE,20190807 -US-Bi2,94606,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured by RS -US-Bi2,94584,GRP_HEIGHTC,HEIGHTC,2.809 -US-Bi2,94584,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Bi2,94584,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi2,94584,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,8 -US-Bi2,94584,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi2,94584,GRP_HEIGHTC,HEIGHTC_DATE,20190821 -US-Bi2,94584,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured by DS -US-Bi2,94636,GRP_HEIGHTC,HEIGHTC,0.091 -US-Bi2,94636,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Bi2,94636,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi2,94636,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,8 -US-Bi2,94636,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi2,94636,GRP_HEIGHTC,HEIGHTC_DATE,20190821 -US-Bi2,94636,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured by DS -US-Bi2,94601,GRP_HEIGHTC,HEIGHTC,3.041 -US-Bi2,94601,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Bi2,94601,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi2,94601,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,13 -US-Bi2,94601,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi2,94601,GRP_HEIGHTC,HEIGHTC_DATE,20190911 -US-Bi2,94601,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured by DS -US-Bi2,94602,GRP_HEIGHTC,HEIGHTC,3.095 -US-Bi2,94602,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Bi2,94602,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi2,94602,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,13 -US-Bi2,94602,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi2,94602,GRP_HEIGHTC,HEIGHTC_DATE,20190911 -US-Bi2,94602,GRP_HEIGHTC,HEIGHTC_COMMENT,Heights measured on the day of corn biomass harvesting -US-Bi2,94605,GRP_HEIGHTC,HEIGHTC,0.201 -US-Bi2,94605,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Bi2,94605,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi2,94605,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,13 -US-Bi2,94605,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi2,94605,GRP_HEIGHTC,HEIGHTC_DATE,20190911 -US-Bi2,94605,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured by DS -US-Bi2,94628,GRP_HEIGHTC,HEIGHTC,0.26 -US-Bi2,94628,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Bi2,94628,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi2,94628,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,13 -US-Bi2,94628,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi2,94628,GRP_HEIGHTC,HEIGHTC_DATE,20190911 -US-Bi2,94628,GRP_HEIGHTC,HEIGHTC_COMMENT,Heights measured on the day of corn biomass harvesting -US-Bi2,94597,GRP_HEIGHTC,HEIGHTC,0.324 -US-Bi2,94597,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Bi2,94597,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi2,94597,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,10 -US-Bi2,94597,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi2,94597,GRP_HEIGHTC,HEIGHTC_DATE,20200529 -US-Bi2,94597,GRP_HEIGHTC,HEIGHTC_COMMENT,Very windy plants bending in the wind -US-Bi2,94622,GRP_HEIGHTC,HEIGHTC,0.084 -US-Bi2,94622,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Bi2,94622,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi2,94622,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,10 -US-Bi2,94622,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi2,94622,GRP_HEIGHTC,HEIGHTC_DATE,20200529 -US-Bi2,94622,GRP_HEIGHTC,HEIGHTC_COMMENT,Very windy plants bending in the wind -US-Bi2,94588,GRP_HEIGHTC,HEIGHTC,0.065 -US-Bi2,94588,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Bi2,94588,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi2,94588,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,12 -US-Bi2,94588,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi2,94588,GRP_HEIGHTC,HEIGHTC_DATE,20200609 -US-Bi2,94588,GRP_HEIGHTC,HEIGHTC_COMMENT,Furrowed today soil piled around base of plants -US-Bi2,94612,GRP_HEIGHTC,HEIGHTC,0.86 -US-Bi2,94612,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Bi2,94612,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi2,94612,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,12 -US-Bi2,94612,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi2,94612,GRP_HEIGHTC,HEIGHTC_DATE,20200609 -US-Bi2,94612,GRP_HEIGHTC,HEIGHTC_COMMENT,Furrowed today soil piled around base of plants -US-Bi2,94593,GRP_HEIGHTC,HEIGHTC,0.087 -US-Bi2,94593,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Bi2,94593,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi2,94593,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,13 -US-Bi2,94593,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi2,94593,GRP_HEIGHTC,HEIGHTC_DATE,20200615 -US-Bi2,94615,GRP_HEIGHTC,HEIGHTC,1.098 -US-Bi2,94615,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Bi2,94615,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi2,94615,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,13 -US-Bi2,94615,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi2,94615,GRP_HEIGHTC,HEIGHTC_DATE,20200615 -US-Bi2,94623,GRP_HEIGHTC,HEIGHTC,0.107 -US-Bi2,94623,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Bi2,94623,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi2,94623,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,12 -US-Bi2,94623,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi2,94623,GRP_HEIGHTC,HEIGHTC_DATE,20200701 -US-Bi2,94633,GRP_HEIGHTC,HEIGHTC,1.998 -US-Bi2,94633,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Bi2,94633,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi2,94633,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,12 -US-Bi2,94633,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi2,94633,GRP_HEIGHTC,HEIGHTC_DATE,20200701 -US-Bi2,94591,GRP_HEIGHTC,HEIGHTC,0.139 -US-Bi2,94591,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Bi2,94591,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi2,94591,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,11 -US-Bi2,94591,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi2,94591,GRP_HEIGHTC,HEIGHTC_DATE,20200708 -US-Bi2,94620,GRP_HEIGHTC,HEIGHTC,2.254 -US-Bi2,94620,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Bi2,94620,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi2,94620,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,11 -US-Bi2,94620,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi2,94620,GRP_HEIGHTC,HEIGHTC_DATE,20200708 -US-Bi2,94609,GRP_HEIGHTC,HEIGHTC,0.159 -US-Bi2,94609,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Bi2,94609,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi2,94609,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,13 -US-Bi2,94609,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi2,94609,GRP_HEIGHTC,HEIGHTC_DATE,20200730 -US-Bi2,94609,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured to top of tassel -US-Bi2,94626,GRP_HEIGHTC,HEIGHTC,2.413 -US-Bi2,94626,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Bi2,94626,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi2,94626,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,13 -US-Bi2,94626,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi2,94626,GRP_HEIGHTC,HEIGHTC_DATE,20200730 -US-Bi2,94626,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured to top of tassel -US-Bi2,94590,GRP_HEIGHTC,HEIGHTC,0.19 -US-Bi2,94590,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Bi2,94590,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi2,94590,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,12 -US-Bi2,94590,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi2,94590,GRP_HEIGHTC,HEIGHTC_DATE,20200901 -US-Bi2,94596,GRP_HEIGHTC,HEIGHTC,2.228 -US-Bi2,94596,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Bi2,94596,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Bi2,94596,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,12 -US-Bi2,94596,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Bi2,94596,GRP_HEIGHTC,HEIGHTC_DATE,20200901 -US-Bi2,31256,GRP_IGBP,IGBP,CRO -US-Bi2,31256,GRP_IGBP,IGBP_DATE_START,20170426 -US-Bi2,31253,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -US-Bi2,31253,GRP_LAND_OWNERSHIP,LAND_OWNER,Los Angeles Metropolitan Water District -US-Bi2,94778,GRP_LOCATION,LOCATION_LAT,38.1091 -US-Bi2,94778,GRP_LOCATION,LOCATION_LONG,-121.5351 -US-Bi2,94778,GRP_LOCATION,LOCATION_ELEV,-5 -US-Bi2,94778,GRP_LOCATION,LOCATION_DATE_START,201704261500 -US-Bi2,94778,GRP_LOCATION,LOCATION_COMMENT,This location varies by about +-3m (mostly east-west) as the tower is moved to and from the field edge for planting and harvest. -US-Bi2,31263,GRP_NETWORK,NETWORK,AmeriFlux -US-Bi2,86953,GRP_NETWORK,NETWORK,Phenocam -US-Bi2,1700001482,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Baldocchi, D. D., Ryu, Y., Dechant, B., Eichelmann, E., Hemes, K., Ma, S., Sanchez, C. R., Shortt, R., Szutu, D., Valach, A., Verfaillie, J., Badgley, G., Zeng, Y., Berry, J. A. (2020) Outgoing Near‐Infrared Radiation From Vegetation Scales With Canopy Photosynthesis Across A Spectrum Of Function, Structure, Physiological Capacity, And Weather, Journal Of Geophysical Research: Biogeosciences, 125(7), 108350" -US-Bi2,1700001482,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2019JG005534 -US-Bi2,1700001482,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Bi2,1700004713,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Baldocchi, D. D., Ryu, Y., Dechant, B., Eichelmann, E., Hemes, K., Ma, S., Sanchez, C. R., Shortt, R., Szutu, D., Valach, A., Verfaillie, J., Badgley, G., Zeng, Y., Berry, J. A. (2020) Outgoing Near‐Infrared Radiation From Vegetation Scales With Canopy Photosynthesis Across A Spectrum Of Function, Structure, Physiological Capacity, And Weather, Journal Of Geophysical Research: Biogeosciences, 125(7), 202-214" -US-Bi2,1700004713,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2019JG005534 -US-Bi2,1700004713,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Bi2,1700004179,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(), 108350" -US-Bi2,1700004179,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -US-Bi2,1700004179,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Bi2,1700000792,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Hemes, K. S., Chamberlain, S. D., Eichelmann, E., Anthony, T., Valach, A., Kasak, K., Szutu, D., Verfaillie, J., Silver, W. L., Baldocchi, D. D. (2019) Assessing The Carbon And Climate Benefit Of Restoring Degraded Agricultural Peat Soils To Managed Wetlands, Agricultural And Forest Meteorology, 268(), 202-214" -US-Bi2,1700000792,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2019.01.017 -US-Bi2,1700000792,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Bi2,1700008478,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Hemes, K. S., Chamberlain, S. D., Eichelmann, E., Anthony, T., Valach, A., Kasak, K., Szutu, D., Verfaillie, J., Silver, W. L., Baldocchi, D. D. (2019) Assessing The Carbon And Climate Benefit Of Restoring Degraded Agricultural Peat Soils To Managed Wetlands, Agricultural And Forest Meteorology, 268(7), 202-214" -US-Bi2,1700008478,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2019.01.017 -US-Bi2,1700008478,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Bi2,1700001659,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Hemes, K. S., Verfaillie, J., Baldocchi, D. D. (2020) Wildfire‐Smoke Aerosols Lead To Increased Light Use Efficiency Among Agricultural And Restored Wetland Land Uses In California'S Central Valley, Journal Of Geophysical Research: Biogeosciences, 268(), 202-214" -US-Bi2,1700001659,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2019JG005380 -US-Bi2,1700001659,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Bi2,1700002682,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Hemes, K. S., Verfaillie, J., Baldocchi, D. D. (2020) Wildfire‐Smoke Aerosols Lead To Increased Light Use Efficiency Among Agricultural And Restored Wetland Land Uses In California'S Central Valley, Journal Of Geophysical Research: Biogeosciences, 268(7), 202-214" -US-Bi2,1700002682,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2019JG005380 -US-Bi2,1700002682,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Bi2,1700005406,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Rey‐Sanchez, C., Wharton, S., Vilà‐Guerau de Arellano, J., Paw U, K. T., Hemes, K. S., Fuentes, J. D., Osuna, J., Szutu, D., Ribeiro, J. V., Verfaillie, J., Baldocchi, D. (2021) Evaluation Of Atmospheric Boundary Layer Height From Wind Profiling Radar And Slab Models And Its Responses To Seasonality Of Land Cover, Subsidence, And Advection, Journal Of Geophysical Research: Atmospheres, 126(7), 108350" -US-Bi2,1700005406,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2020JD033775 -US-Bi2,1700005406,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Bi2,1700005232,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Rey‐Sanchez, C., Wharton, S., Vilà‐Guerau de Arellano, J., Paw U, K. T., Hemes, K. S., Fuentes, J. D., Osuna, J., Szutu, D., Ribeiro, J. V., Verfaillie, J., Baldocchi, D. (2021) Evaluation Of Atmospheric Boundary Layer Height From Wind Profiling Radar And Slab Models And Its Responses To Seasonality Of Land Cover, Subsidence, And Advection, Journal Of Geophysical Research: Atmospheres, 126(7), 202-214" -US-Bi2,1700005232,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2020JD033775 -US-Bi2,1700005232,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Bi2,31265,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,soil subsidence and greenhouse gas budgets -US-Bi2,31250,GRP_SITE_CHAR,TERRAIN,Flat -US-Bi2,31250,GRP_SITE_CHAR,ASPECT,FLAT -US-Bi2,31250,GRP_SITE_CHAR,WIND_DIRECTION,W -US-Bi2,31250,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,1000 -US-Bi2,31250,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,0 -US-Bi2,33512,GRP_SITE_DESC,SITE_DESC,corn is growing on an island in the Sacramento San Joaquin Delta. This site has deep peat that was drained for farming. Over the past 100 years there has been excessive subsidence of the peat in the delta -US-Bi2,31251,GRP_SITE_FUNDING,SITE_FUNDING,CA Dept Water Resources/CA Dept Fish and Wildlife -US-Bi2,31266,GRP_STATE,STATE,CA -US-Bi2,31260,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Dennis Baldocchi -US-Bi2,31260,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Bi2,31260,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,baldocchi@berkeley.edu -US-Bi2,31260,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"University of California, Berkeley" -US-Bi2,31260,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"130 Mulford Hall, Berkeley, CA" -US-Bi2,98916,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Tianxin 'Carlos' Wang -US-Bi2,98916,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-Bi2,98916,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,cawang@berkeley.edu -US-Bi2,98916,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"University of California, Berkeley" -US-Bi2,98916,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"130 Mulford Hall, Berkeley, CA" -US-Bi2,33513,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Daphne Szutu -US-Bi2,33513,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,DataManager -US-Bi2,33513,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,daphneszutu@berkeley.edu -US-Bi2,31262,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Joe Verfaillie -US-Bi2,31262,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Technician -US-Bi2,31262,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,jverfail@berkeley.edu -US-Bi2,31254,GRP_TOWER_POWER,TOWER_POWER,Direct power -US-Bi2,31255,GRP_TOWER_TYPE,TOWER_TYPE,walk-up -US-Bi2,31252,GRP_URL,URL,https://nature.berkeley.edu/biometlab/sites.php?site=US-Bi2 -US-Bi2,24000721,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-Bi2 -US-Bi2,31264,GRP_UTC_OFFSET,UTC_OFFSET,-8 -US-Blo,23664,GRP_BIOMASS_CHEM,BIOMASS_N,0.1407 -US-Blo,23664,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-Blo,23664,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-Blo,23664,GRP_BIOMASS_CHEM,BIOMASS_SPP,(All) -US-Blo,23664,GRP_BIOMASS_CHEM,BIOMASS_COMMENT,see extra data file US-Blo_Ncontent_leaves.xls -US-Blo,14391,GRP_CLIM_AVG,MAT,11.09 -US-Blo,14391,GRP_CLIM_AVG,MAP,1226 -US-Blo,14391,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Csa -US-Blo,27000337,GRP_COUNTRY,COUNTRY,USA -US-Blo,15676,GRP_DOI,DOI,10.17190/AMF/1246032 -US-Blo,15676,GRP_DOI,DOI_CITATION,"Allen Goldstein (2019), AmeriFlux BASE US-Blo Blodgett Forest, Ver. 4-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1246032" -US-Blo,15676,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-Blo,31963,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Blo,31963,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Allen Goldstein -US-Blo,31963,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Blo,31963,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,ahg@berkeley.edu -US-Blo,31963,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"University of California, Berkeley" -US-Blo,31965,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,"University of California, Berkeley" -US-Blo,31965,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-Blo,31964,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,"DOE/NIGEC, EPA, University of California" -US-Blo,31964,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-Blo,14392,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Blo,14392,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-Blo,14392,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,1997 -US-Blo,14392,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,2006 -US-Blo,14392,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Blo,23000337,GRP_HEADER,SITE_NAME,Blodgett Forest -US-Blo,88366,GRP_HEIGHTC,HEIGHTC,2.59 -US-Blo,88366,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Blo,88366,GRP_HEIGHTC,HEIGHTC_DATE,1999 -US-Blo,14393,GRP_IGBP,IGBP,ENF -US-Blo,24951,GRP_LAI,LAI_TYPE,LAI -US-Blo,25080,GRP_LAI,LAI_TYPE,LAI -US-Blo,24951,GRP_LAI,LAI_COMMENT," -projected leaf area for Ponderosa pine + understory -" -US-Blo,25080,GRP_LAI,LAI_COMMENT," -projected leaf area for understory (Ceanothus+Arctostaphylos)" -US-Blo,24951,GRP_LAI,LAI_TOT,4.63 -US-Blo,25080,GRP_LAI,LAI_U,1.68 -US-Blo,23934,GRP_LMA,LMA,117 -US-Blo,23934,GRP_LMA,LMA_SPP,(All) -US-Blo,23934,GRP_LMA,LMA_COMMENT," -average for Pinus; 111 for 2 years old needle, 123 for 1 year old needle, - -262 for Arctostaphylos, 104 for ceanothus" -US-Blo,14394,GRP_LOCATION,LOCATION_LAT,38.8953 -US-Blo,14394,GRP_LOCATION,LOCATION_LONG,-120.6328 -US-Blo,14394,GRP_LOCATION,LOCATION_ELEV,1315 -US-Blo,14395,GRP_NETWORK,NETWORK,AmeriFlux -US-Blo,1700001830,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Baker, B., Guenther, A., Greenberg, J., Goldstein, A., Fall, R. (1999) Canopy Fluxes Of 2-Methyl-3-Buten-2-Ol Over A Ponderosa Pine Forest By Relaxed Eddy Accumulation: Field Data And Model Comparison, Journal Of Geophysical Research: Atmospheres, 104(D21), 26107-26114" -US-Blo,1700001830,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/1999JD900749 -US-Blo,1700001830,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Blo,1700008871,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Baldocchi, D., Penuelas, J. (2018) The Physics And Ecology Of Mining Carbon Dioxide From The Atmosphere By Ecosystems, Global Change Biology, 45(3), 9275–9287" -US-Blo,1700008871,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/GCB.14559 -US-Blo,1700008871,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Blo,1700002871,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Bauer, M. R., Hultman, N. E., Panek, J. A., Goldstein, A. H. (2000) Ozone Deposition To A Ponderosa Pine Plantation In The Sierra Nevada Mountains (CA): A Comparison Of Two Different Climatic Years, Journal Of Geophysical Research: Atmospheres, 105(D17), 22123-22136" -US-Blo,1700002871,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2000JD900168 -US-Blo,1700002871,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Blo,1700003054,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Baldocchi, D. D., Poindexter, C., Abraha, M., Desai, A. R., Bohrer, G., Arain, M. A., Griffis, T., Blanken, P. D., O'Halloran, T. L., Thomas, R. Q., Zhang, Q., Burns, S. P., Frank, J. M., Christian, D., Brown, S., Black, T. A., Gough, C. M., Law, B. E., Lee, X., Chen, J., Reed, D. E., Massman, W. J., Clark, K., Hatfield, J., Prueger, J., Bracho, R., Baker, J. M., Martin, T. A. (2018) Temporal Dynamics Of Aerodynamic Canopy Height Derived From Eddy Covariance Momentum Flux Data Across North American Flux Networks, Geophysical Research Letters, 45(3), 9275–9287" -US-Blo,1700003054,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018GL079306 -US-Blo,1700003054,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Blo,1700004791,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. 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(2006) Seasonal Measurements Of Acetone And Methanol: Abundances And Implications For Atmospheric Budgets, Global Biogeochemical Cycles, 20(1), 1-10" -US-Blo,1700002220,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2005GB002566 -US-Blo,1700002220,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Blo,1700002226,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Schade, G. W., Goldstein, A. H., Gray, D. W., Lerdau, M. T. (2000) Canopy And Leaf Level 2-Methyl-3-Buten-2-Ol Fluxes From A Ponderosa Pine Plantation, Atmospheric Environment, 34(21), 3535-3544" -US-Blo,1700002226,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/S1352-2310(00)00120-5 -US-Blo,1700002226,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Blo,1700006921,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Schade, G. W., Goldstein, A. H., Lamanna, M. S. (1999) Are Monoterpene Emissions Influenced By Humidity?, Geophysical Research Letters, 26(14), 2187-2190" -US-Blo,1700006921,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/1999GL900444 -US-Blo,1700006921,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Blo,1700007359,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Schade,G.W., Goldstein,A.H. (2001) Fluxes of oxygenated volatile organic compounds from a ponderosa pine plantatio, Journal of Geophysical Research-Atmospheres, 106(D3), 3111-3123" -US-Blo,1700007359,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Blo,1700005292,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Sims, D. A., Rahman, A. F., Cordova, V. D., Baldocchi, D. D., Flanagan, L. B., Goldstein, A. H., Hollinger, D. Y., Misson, L., Monson, R. K., Schmid, H. P., Wofsy, S. C., Xu, L. (2005) Midday Values Of Gross CO2 Flux And Light Use Efficiency During Satellite Overpasses Can Be Used To Directly Estimate Eight-Day Mean Flux, Agricultural And Forest Meteorology, 131(1-2), 1-12" -US-Blo,1700005292,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2005.04.006 -US-Blo,1700005292,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Blo,1700002769,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Spaulding, R. S., Schade, G. W., Goldstein, A. H., Charles, M. J. (2003) Characterization Of Secondary Atmospheric Photooxidation Products: Evidence For Biogenic And Anthropogenic Sources, Journal Of Geophysical Research: Atmospheres, 108(D8), n/a-n/a" -US-Blo,1700002769,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2002JD002478 -US-Blo,1700002769,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Blo,1700000591,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Sullivan, R. C., Cook, D. R., Ghate, V. P., Kotamarthi, V. R., Feng, Y. (2019) Improved Spatiotemporal Representativeness And Bias Reduction Of Satellite-Based Evapotranspiration Retrievals Via Use Of In Situ Meteorology And Constrained Canopy Surface Resistance, Journal Of Geophysical Research: Biogeosciences, 124(2), 342-352" -US-Blo,1700000591,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018JG004744 -US-Blo,1700000591,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Blo,1700008499,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Sullivan, R. C., Kotamarthi, V. R., Feng, Y. (2019) Recovering Evapotranspiration Trends From Biased CMIP5 Simulations And Sensitivity To Changing Climate Over North America, Journal Of Hydrometeorology, 20(8), 1619-1633" -US-Blo,1700008499,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1175/JHM-D-18-0259.1 -US-Blo,1700008499,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Blo,1700004257,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Tang, J., Misson, L., Gershenson, A., Cheng, W., Goldstein, A. H. (2005) Continuous Measurements Of Soil Respiration With And Without Roots In A Ponderosa Pine Plantation In The Sierra Nevada Mountains, Agricultural And Forest Meteorology, 132(3-4), 212-227" -US-Blo,1700004257,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2005.07.011 -US-Blo,1700004257,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Blo,1700006651,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Tang, J., Qi, Y., Xu, M., Misson, L., Goldstein, A. H. (2005) Forest Thinning And Soil Respiration In A Ponderosa Pine Plantation In The Sierra Nevada, Tree Physiology, 25(1), 57-66" -US-Blo,1700006651,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1093/TREEPHYS/25.1.57 -US-Blo,1700006651,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Blo,1700001734,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Wilson, K. B., Baldocchi, D. D., Aubinet, M., Berbigier, P., Bernhofer, C., Dolman, H., Falge, E., Field, C., Goldstein, A., Granier, A., Grelle, A., Halldor, T., Hollinger, D., Katul, G., Law, B. E., Lindroth, A., Meyers, T., Moncrieff, J., Monson, R., Oechel, W., Tenhunen, J., Valentini, R., Verma, S., Vesala, T., Wofsy, S. (2002) Energy Partitioning Between Latent And Sensible Heat Flux During The Warm Season At FLUXNET Sites, Water Resources Research, 38(12), 1294-1305" -US-Blo,1700001734,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2001WR000989 -US-Blo,1700001734,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Blo,1700004497,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Wilson, K. B., Baldocchi, D., Falge, E., Aubinet, M., Berbigier, P., Bernhofer, C., Dolman, H., Field, C., Goldstein, A., Granier, A., Hollinger, D., Katul, G., Law, B. E., Meyers, T., Moncrieff, J., Monson, R., Tenhunen, J., Valentini, R., Verma, S., Wofsy, S. (2003) Diurnal Centroid Of Ecosystem Energy And Carbon Fluxes At FLUXNET Sites, Journal Of Geophysical Research: Atmospheres, 108(D21), n/a-n/a" -US-Blo,1700004497,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2001JD001349 -US-Blo,1700004497,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Blo,1700002487,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Wilson, K., Goldstein, A., Falge, E., Aubinet, M., Baldocchi, D., Berbigier, P., Bernhofer, C., Ceulemans, R., Dolman, H., Field, C., Grelle, A., Ibrom, A., Law, B., Kowalski, A., Meyers, T., Moncrieff, J., Monson, R., Oechel, W., Tenhunen, J., Valentini, R., Verma, S. (2002) Energy Balance Closure At FLUXNET Sites, Agricultural And Forest Meteorology, 113(1-4), 223-243" -US-Blo,1700002487,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/S0168-1923(02)00109-0 -US-Blo,1700002487,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Blo,1700003276,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Xu, B., Arain, M. A., Black, T. A., Law, B. E., Pastorello, G. Z., Chu, H. (2020) Seasonal Variability Of Forest Sensitivity To Heat And Drought Stresses: A Synthesis Based On Carbon Fluxes From North American Forest Ecosystems, Global Change Biology, 26(2), 901-918" -US-Blo,1700003276,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/GCB.14843 -US-Blo,1700003276,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Blo,1700007044,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Xu, M., DeBiase, T. A., Qi, Y., Goldstein, A., Liu, Z. (2001) Ecosystem Respiration In A Young Ponderosa Pine Plantation In The Sierra Nevada Mountains, California, Tree Physiology, 21(5), 309-318" -US-Blo,1700007044,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1093/TREEPHYS/21.5.309 -US-Blo,1700007044,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Blo,1700006570,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Zhang, Q., Ficklin, D. L., Manzoni, S., Wang, L., Way, D., Phillips, R. P., Novick, K. A. (2019) Response Of Ecosystem Intrinsic Water Use Efficiency And Gross Primary Productivity To Rising Vapor Pressure Deficit, Environmental Research Letters, 14(7), 074023" -US-Blo,1700006570,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1088/1748-9326/AB2603 -US-Blo,1700006570,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Blo,14397,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,1) Carbon Balance; 2) Ozone deposition; 3) Influence of forest management practices and climate on ozone deposition and carbon balance; 4) Ecosystem modeling and spatial analysis of forest productivity and water balance; 5) Biogenic Hydrocarbon emissions -US-Blo,25079,GRP_SA,SA,17 -US-Blo,25079,GRP_SA,SA_COMMENT," -planted in 1990" -US-Blo,14398,GRP_SITE_DESC,SITE_DESC,"The flux tower site at Blodgett Forest is on a 1200 ha parcel of land owned by Sierra Pacific Industries in the Sierra Nevada range near Georgetown, California. The field site was established in May 1997 with continuous operation since May 1999. The site is situated in a ponderosa pine plantation, mixed-evergreen coniferous forest, located adjacent to Blodgett Forest Research Station. The Mediterranean-type climate of California is characterized by a protracted summer drought, with precipitation occurring mainly from October through May. The infrastructure for the ecosystem scale flux measurements includes a walkup measurement tower, two temperature controlled instrument buildings, and an electrical generation system powered by a diesel generator. Typical wind patterns at the site include upslope flow during the day (from the west) and downslope flow at night (from the east). The plantation is relatively flat, and contains a homogenous mixture of evenly aged ponderosa pine with other trees and shrubs scattered throughout the ecosystem making up less than 30% of the biomass. The daytime fetch for the tower measurements extends approximately 200 m to the southwest of the tower (this region contributes ~90% of the daytime flux), thus remote sensing images to be used for modeling should probably be centered approximately 100 m from the tower at an angle of 225 deg." -US-Blo,14399,GRP_SITE_FUNDING,SITE_FUNDING,"DOE/NIGEC, EPA, University of California" -US-Blo,24433,GRP_SOIL_CHEM,SOIL_CHEM_BD,0.76 -US-Blo,24433,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,0 -US-Blo,24433,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,10 -US-Blo,24433,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,A -US-Blo,28429,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION,"Fine-loamy, mixed, mesic, ultic haploxeralf in the Cohasset series whose parent material was andesitic lahar. Relatively uniform, comprised predominantly of loam or clay-loam. The soil is comprised of 60% sand, 29% loam and 11% clay with a pH of 5.5." -US-Blo,28429,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION_TAXONOMY,Other -US-Blo,23801,GRP_SOIL_DEPTH,SOIL_DEPTH,10 -US-Blo,24299,GRP_SOIL_DEPTH,SOIL_DEPTH,200 -US-Blo,24299,GRP_SOIL_DEPTH,SOIL_DEPTH_COMMENT," -at least 2 m" -US-Blo,24188,GRP_SOIL_TEX,SOIL_TEX_SAND,60 -US-Blo,24188,GRP_SOIL_TEX,SOIL_TEX_SILT,29 -US-Blo,24188,GRP_SOIL_TEX,SOIL_TEX_CLAY,11 -US-Blo,24188,GRP_SOIL_TEX,SOIL_TEX_PROFILE_MIN,0 -US-Blo,24188,GRP_SOIL_TEX,SOIL_TEX_PROFILE_MAX,10 -US-Blo,24188,GRP_SOIL_TEX,SOIL_TEX_HORIZON,A -US-Blo,24186,GRP_SPP_O,SPP_O,Ponderosa pine -US-Blo,14400,GRP_STATE,STATE,CA -US-Blo,14401,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Allen Goldstein -US-Blo,14401,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Blo,14401,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,ahg@berkeley.edu -US-Blo,14401,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"University of California, Berkeley" -US-Blo,14401,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Environmental Science, Policy, & Management, 151 Hilgard Hall,Berkeley, CA USA 94720-3110" -US-Blo,93440,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Silvano Fares -US-Blo,93440,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,AncContact -US-Blo,93440,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,silvano.fares@cnr.it -US-Blo,93440,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Entecra -US-Blo,14402,GRP_URL,URL,http://www.cnr.berkeley.edu/~ahg/tgbl/group.html -US-Blo,24000337,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-Blo -US-Blo,14403,GRP_UTC_OFFSET,UTC_OFFSET,-8 -US-BMM,91059,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,"NSF DEB #1552976, Montana State University College of Agriculture" -US-BMM,91062,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfc -US-BMM,27001122,GRP_COUNTRY,COUNTRY,USA -US-BMM,93745,GRP_DOI,DOI,10.17190/AMF/1660338 -US-BMM,93745,GRP_DOI,DOI_CITATION,"Paul Stoy (2021), AmeriFlux BASE US-BMM Bangtail Mountain Meadow, Ver. 2-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1660338" -US-BMM,93745,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-BMM,93702,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-BMM,93702,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Paul Stoy -US-BMM,93702,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-BMM,93702,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,pcstoy@wisc.edu -US-BMM,93702,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of Wisconsin - Madison -US-BMM,93734,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,University of Wisconsin - Madison -US-BMM,93734,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-BMM,93726,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,"NSF DEB #1552976, Montana State University College of Agriculture" -US-BMM,93726,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-BMM,91063,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-BMM,91063,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-BMM,91063,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201610030000 -US-BMM,91063,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,201908280000 -US-BMM,91063,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Periodic operation -US-BMM,91068,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-BMM,91068,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-BMM,91068,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201610030000 -US-BMM,91068,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,201908280000 -US-BMM,91068,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Periodic operation -US-BMM,91057,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-BMM,91057,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-BMM,91057,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201610030000 -US-BMM,91057,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,201908280000 -US-BMM,91057,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Periodic operation -US-BMM,23001122,GRP_HEADER,SITE_NAME,Bangtail Mountain Meadow -US-BMM,91069,GRP_IGBP,IGBP,GRA -US-BMM,91058,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-BMM,91058,GRP_LAND_OWNERSHIP,LAND_OWNER,United States Forest Service -US-BMM,91054,GRP_LOCATION,LOCATION_LAT,45.7830 -US-BMM,91054,GRP_LOCATION,LOCATION_LONG,-110.7776 -US-BMM,91054,GRP_LOCATION,LOCATION_ELEV,2324 -US-BMM,91054,GRP_LOCATION,LOCATION_DATE_START,201610030000 -US-BMM,91070,GRP_NETWORK,NETWORK,AmeriFlux -US-BMM,91071,GRP_NETWORK,NETWORK,Phenocam -US-BMM,1700006237,GRP_REFERENCE_PAPER,REFERENCE_PAPER," (2015) Long-term decline in grassland productivity driven by increasing dryness, Nature Communications, (), " -US-BMM,1700006237,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1038/NCOMMS8148 -US-BMM,1700006237,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-BMM,91067,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"grassland, phenocam" -US-BMM,91053,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"540 Elm Drive, University of Wisconsin – Madison, Madison, WI 53706" -US-BMM,91064,GRP_SITE_CHAR,TERRAIN,Gentle slope (<2 %) -US-BMM,91064,GRP_SITE_CHAR,ASPECT,S -US-BMM,91064,GRP_SITE_CHAR,WIND_DIRECTION,SW -US-BMM,91064,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,300 -US-BMM,91061,GRP_SITE_DESC,SITE_DESC,montane grassland -US-BMM,91056,GRP_SITE_FUNDING,SITE_FUNDING,"NSF DEB #1552976, Montana State University College of Agriculture" -US-BMM,91055,GRP_STATE,STATE,MT -US-BMM,91060,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Paul Stoy -US-BMM,91060,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-BMM,91060,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,pcstoy@wisc.edu -US-BMM,91060,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Wisconsin - Madison -US-BMM,91060,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"460 Henry Mall, University of Wisconsin – Madison, Madison, WI 53706" -US-BMM,91066,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Jack Brookshire -US-BMM,91066,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,AncContact -US-BMM,91066,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,jbrookshire@montana.edu -US-BMM,91072,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-BMM,91065,GRP_TOWER_TYPE,TOWER_TYPE,tripod -US-BMM,24001122,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-BMM -US-BMM,91052,GRP_UTC_OFFSET,UTC_OFFSET,-7 -US-BMM,91052,GRP_UTC_OFFSET,UTC_OFFSET_DATE_START,201605011900 -US-BMM,91052,GRP_UTC_OFFSET,UTC_OFFSET_COMMENT,The data logger should be in local (Mountain) standard time -US-Bo1,1724,GRP_CLIM_AVG,MAT,11.02 -US-Bo1,1724,GRP_CLIM_AVG,MAP,991.29 -US-Bo1,1724,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfa -US-Bo1,27000341,GRP_COUNTRY,COUNTRY,USA -US-Bo1,15620,GRP_DOI,DOI,10.17190/AMF/1246036 -US-Bo1,15620,GRP_DOI,DOI_CITATION,"Tilden Meyers (2016), AmeriFlux BASE US-Bo1 Bondville, Ver. 2-1, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1246036" -US-Bo1,15620,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-Bo1,31975,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Bo1,31975,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Tilden Meyers -US-Bo1,31975,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Bo1,31975,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,Tilden.Meyers@noaa.gov -US-Bo1,31975,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,NOAA/ARL -US-Bo1,31977,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,NOAA/ARL -US-Bo1,31977,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-Bo1,31976,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,NOAA/GEWEX -US-Bo1,31976,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-Bo1,3782,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Bo1,3782,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-Bo1,3782,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,1996 -US-Bo1,3782,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Bo1,23000341,GRP_HEADER,SITE_NAME,Bondville -US-Bo1,23889,GRP_HEIGHTC,HEIGHTC,3.0 -US-Bo1,9434,GRP_IGBP,IGBP,CRO -US-Bo1,9434,GRP_IGBP,IGBP_COMMENT,http://public.ornl.gov/ameriflux/Site_Info/siteInfo.cfm?KEYID=us.bondville.01 -US-Bo1,23629,GRP_LAI,LAI_TYPE,LAI -US-Bo1,23629,GRP_LAI,LAI_COMMENT,(range 5-5.5) 2000: soybean LAI 5; 1999 Maize: LAI 5.5; Source: http://public.ornl.gov/ameriflux/Site_Info/siteInfo.cfm?KEYID=us.bondville.01 -US-Bo1,23629,GRP_LAI,LAI_TOT,5.25 -US-Bo1,4521,GRP_LOCATION,LOCATION_LAT,40.0062 -US-Bo1,4521,GRP_LOCATION,LOCATION_LONG,-88.2904 -US-Bo1,4521,GRP_LOCATION,LOCATION_ELEV,219 -US-Bo1,6387,GRP_NETWORK,NETWORK,AmeriFlux -US-Bo1,1700002610,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Bernacchi, C. J., Hollinger, S. E., Meyers, T. (2005) The Conversion Of The Corn/Soybean Ecosystem To No-Till Agriculture May Result In A Carbon Sink, Global Change Biology, 11(11), 1867-1872" -US-Bo1,1700002610,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/J.1365-2486.2005.01050.X -US-Bo1,1700002610,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Bo1,1700002712,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(11), 108350" -US-Bo1,1700002712,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -US-Bo1,1700002712,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Bo1,1700004485,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Dennis Baldocchi, Cove Sturtevant (2015) Does day and night sampling reduce spurious correlation between canopy photosynthesis and ecosystem respiration?, Agricultural and Forest Meteorology, 207(1-2), 117-126" -US-Bo1,1700004485,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2015.03.010 -US-Bo1,1700004485,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Bo1,1700007266,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Hollinger, S. E., Bernacchi, C. J., Meyers, T. P. (2005) Carbon Budget Of Mature No-Till Ecosystem In North Central Region Of The United States, Agricultural And Forest Meteorology, 130(1-2), 59-69" -US-Bo1,1700007266,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2005.01.005 -US-Bo1,1700007266,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Bo1,1700008994,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Koloutsou-Vakakis, S., Carrico, C. M., Kus, P., Rood, M. J., Li, Z., Shrestha, R., Ogren, J. A., Chow, J. C., Watson, J. G. (2001) Aerosol Properties At A Midlatitude Northern Hemisphere Continental Site, Journal Of Geophysical Research: Atmospheres, 106(D3), 3019-3032" -US-Bo1,1700008994,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2000JD900126 -US-Bo1,1700008994,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Bo1,1700000663,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Meyers, T. P., Hollinger, S. E. (2004) An Assessment Of Storage Terms In The Surface Energy Balance Of Maize And Soybean, Agricultural And Forest Meteorology, 125(1-2), 105-115" -US-Bo1,1700000663,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2004.03.001 -US-Bo1,1700000663,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Bo1,1700000471,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Novick, K. A., Ficklin, D. L., Stoy, P. C., Williams, C. A., Bohrer, G., Oishi, A., Papuga, S. A., Blanken, P. D., Noormets, A., Sulman, B. N., Scott, R. L., Wang, L., Phillips, R. P. (2016) The Increasing Importance Of Atmospheric Demand For Ecosystem Water And Carbon Fluxes, Nature Climate Change, 6(11), 1023-1027" -US-Bo1,1700000471,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1038/NCLIMATE3114 -US-Bo1,1700000471,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Bo1,1700007287,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Reichstein, M., Falge, E., Baldocchi, D., Papale, D., Aubinet, M., Berbigier, P., Bernhofer, C., Buchmann, N., Gilmanov, T., Granier, A., Grunwald, T., Havrankova, K., Ilvesniemi, H., Janous, D., Knohl, A., Laurila, T., Lohila, A., Loustau, D., Matteucci, G., Meyers, T., Miglietta, F., Ourcival, J., Pumpanen, J., Rambal, S., Rotenberg, E., Sanz, M., Tenhunen, J., Seufert, G., Vaccari, F., Vesala, T., Yakir, D., Valentini, R. (2005) On The Separation Of Net Ecosystem Exchange Into Assimilation And Ecosystem Respiration: Review And Improved Algorithm, Global Change Biology, 11(9), 1424-1439" -US-Bo1,1700007287,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/J.1365-2486.2005.001002.X -US-Bo1,1700007287,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Bo1,1700002388,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Turner, D. P., Gower, S. T., Cohen, W. B., Gregory, M., Maiersperger, T. K. (2002) Effects Of Spatial Variability In Light Use Efficiency On Satellite-Based NPP Monitoring, Remote Sensing Of Environment, 80(3), 397-405" -US-Bo1,1700002388,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/S0034-4257(01)00319-4 -US-Bo1,1700002388,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Bo1,1700002307,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Turner, D. P., Urbanski, S., Bremer, D., Wofsy, S. C., Meyers, T., Gower, S. T., Gregory, M. (2003) A Cross-Biome Comparison Of Daily Light Use Efficiency For Gross Primary Production, Global Change Biology, 9(3), 383-395" -US-Bo1,1700002307,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1046/J.1365-2486.2003.00573.X -US-Bo1,1700002307,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Bo1,10162,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,1) Provide a long-term continuous record of the surface energy balance components for model testing and evaluation. 2) Ammonia and sulfate fluxes in croplands -US-Bo1,4118,GRP_SITE_DESC,SITE_DESC,"Agriculture, continuous no-till since 1986, Annual rotation between corn (C4) and soybeans (C3). The field was planted with corn during 2005 and 2007, with soybeans during 2006 and 2008." -US-Bo1,4108,GRP_SITE_FUNDING,SITE_FUNDING,NOAA/GEWEX -US-Bo1,24810,GRP_SOIL_CHEM,SOIL_CHEM_BD,1.4 -US-Bo1,24811,GRP_SOIL_CHEM,SOIL_CHEM_BD,1.4 -US-Bo1,24810,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,A -US-Bo1,24811,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,B -US-Bo1,24810,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,Meyers et al 2004: Measurements of soil bulk density average ≈1.4Mgm−3. -US-Bo1,24811,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,Meyers et al 2004: Measurements of soil bulk density average ≈1.4Mgm−3. -US-Bo1,27185,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION,Slit loam -US-Bo1,27185,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION_TAXONOMY,Other -US-Bo1,24680,GRP_SPP_O,SPP_O,"Annual rotation between Corn (C4) - 2005, Soybeans (C3) - 2006" -US-Bo1,24680,GRP_SPP_O,SPP_COMMENT,http://public.ornl.gov/ameriflux/Site_Info/siteInfo.cfm?KEYID=us.bondville.01 -US-Bo1,642,GRP_STATE,STATE,IL -US-Bo1,10042,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Tilden Meyers -US-Bo1,10042,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Bo1,10042,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,Tilden.Meyers@noaa.gov -US-Bo1,10042,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,NOAA/ARL -US-Bo1,10042,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Atmospheric Turbulence and Diffusion Division, P.O. Box 2456 456 South Illinois Avenue,Oak Ridge, TN USA 37831-2456" -US-Bo1,85943,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Praveena Krishnan -US-Bo1,85943,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Affiliate -US-Bo1,85943,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,Praveena.Krishnan@noaa.gov -US-Bo1,85943,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,NOAA/ARL/ATDD -US-Bo1,85943,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Atmospheric Turbulence and Diffusion Division, P.O. Box 2456 456 South Illinois Avenue,Oak Ridge, TN USA 37831-2456" -US-Bo1,2474,GRP_URL,URL,http://www.life.illinois.edu/bernacchi/ -US-Bo1,24000341,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-Bo1 -US-Bo1,9598,GRP_UTC_OFFSET,UTC_OFFSET,-6 -US-Bo2,7679,GRP_CLIM_AVG,MAT,11.02 -US-Bo2,7679,GRP_CLIM_AVG,MAP,991.29 -US-Bo2,7679,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfa -US-Bo2,27000342,GRP_COUNTRY,COUNTRY,USA -US-Bo2,15685,GRP_DOI,DOI,10.17190/AMF/1246037 -US-Bo2,15685,GRP_DOI,DOI_CITATION,"Carl Bernacchi (2016), AmeriFlux BASE US-Bo2 Bondville (companion site), Ver. 2-1, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1246037" -US-Bo2,15685,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-Bo2,31978,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Bo2,31978,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Carl Bernacchi -US-Bo2,31978,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Bo2,31978,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,bernacch@uiuc.edu -US-Bo2,31978,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"University of Illinois, Urbana-Champaign" -US-Bo2,31980,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,"University of Illinois, Urbana-Champaign" -US-Bo2,31980,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-Bo2,31979,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,DOE/TCP -US-Bo2,31979,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-Bo2,3328,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Bo2,3328,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-Bo2,3328,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,2004 -US-Bo2,3328,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,2008 -US-Bo2,3328,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Bo2,23000342,GRP_HEADER,SITE_NAME,Bondville (companion site) -US-Bo2,8549,GRP_IGBP,IGBP,CRO -US-Bo2,8549,GRP_IGBP,IGBP_COMMENT,http://public.ornl.gov/ameriflux/Site_Info/siteInfo.cfm?KEYID=us.bondville.02 -US-Bo2,2009,GRP_LOCATION,LOCATION_LAT,40.0090 -US-Bo2,2009,GRP_LOCATION,LOCATION_LONG,-88.2900 -US-Bo2,2009,GRP_LOCATION,LOCATION_ELEV,219 -US-Bo2,2009,GRP_LOCATION,LOCATION_COMMENT,N; ftp://cdiac.ornl.gov/pub/ameriflux/data/Level1/Sites_ByName/Bondville_Companion_Site/BP08_DAT.LABELS -US-Bo2,7216,GRP_NETWORK,NETWORK,AmeriFlux -US-Bo2,1700000894,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Bernacchi, C. J., Hollinger, S. E., Meyers, T. (2005) The Conversion Of The Corn/Soybean Ecosystem To No-Till Agriculture May Result In A Carbon Sink, Global Change Biology, 11(11), 1867-1872" -US-Bo2,1700000894,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/J.1365-2486.2005.01050.X -US-Bo2,1700000894,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Bo2,1700004563,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(1-2), 108350" -US-Bo2,1700004563,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -US-Bo2,1700004563,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Bo2,1700004746,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Hollinger, S. E., Bernacchi, C. J., Meyers, T. P. (2005) Carbon Budget Of Mature No-Till Ecosystem In North Central Region Of The United States, Agricultural And Forest Meteorology, 130(1-2), 59-69" -US-Bo2,1700004746,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2005.01.005 -US-Bo2,1700004746,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Bo2,1700001716,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Meyers, T. P., Hollinger, S. E. (2004) An Assessment Of Storage Terms In The Surface Energy Balance Of Maize And Soybean, Agricultural And Forest Meteorology, 125(1-2), 105-115" -US-Bo2,1700001716,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2004.03.001 -US-Bo2,1700001716,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Bo2,1700000462,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Reichstein, M., Falge, E., Baldocchi, D., Papale, D., Aubinet, M., Berbigier, P., Bernhofer, C., Buchmann, N., Gilmanov, T., Granier, A., Grunwald, T., Havrankova, K., Ilvesniemi, H., Janous, D., Knohl, A., Laurila, T., Lohila, A., Loustau, D., Matteucci, G., Meyers, T., Miglietta, F., Ourcival, J., Pumpanen, J., Rambal, S., Rotenberg, E., Sanz, M., Tenhunen, J., Seufert, G., Vaccari, F., Vesala, T., Yakir, D., Valentini, R. (2005) On The Separation Of Net Ecosystem Exchange Into Assimilation And Ecosystem Respiration: Review And Improved Algorithm, Global Change Biology, 11(9), 1424-1439" -US-Bo2,1700000462,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/J.1365-2486.2005.001002.X -US-Bo2,1700000462,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Bo2,1700007335,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Turner, D. P., Urbanski, S., Bremer, D., Wofsy, S. C., Meyers, T., Gower, S. T., Gregory, M. (2003) A Cross-Biome Comparison Of Daily Light Use Efficiency For Gross Primary Production, Global Change Biology, 9(3), 383-395" -US-Bo2,1700007335,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1046/J.1365-2486.2003.00573.X -US-Bo2,1700007335,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Bo2,6776,GRP_SITE_DESC,SITE_DESC,Located 400m north of Tilden Meyer's site and planted with opposite crop in corn/soybean rotation -US-Bo2,5019,GRP_SITE_FUNDING,SITE_FUNDING,DOE/TCP -US-Bo2,24677,GRP_SOIL_CHEM,SOIL_CHEM_BD,1.4 -US-Bo2,25063,GRP_SOIL_CHEM,SOIL_CHEM_BD,1.4 -US-Bo2,25063,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,A -US-Bo2,24677,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,B -US-Bo2,24677,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,Meyers et al 2004: Measurements of soil bulk density average ≈1.4Mgm−3. -US-Bo2,25063,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,Meyers et al 2004: Measurements of soil bulk density average ≈1.4Mgm−3. -US-Bo2,24022,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION,"Argiudolls ,Haplaquolls" -US-Bo2,24022,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION_TAXONOMY,Other -US-Bo2,24022,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION_COMMENT,"Meyers et al 2004: -The field contains three soil series: Dana (Fine-silty, mixed, mesic, Typic Argiudolls), Flanagan (Fine, montmorillonitic, mesic, -Aquic Argiudolls), and Drummer (Fine-silty, mixed, mesic, Typic Haplaquolls)" -US-Bo2,25070,GRP_SPP_O,SPP_O,"Annual rotation between Corn (C4) - 2004, Soybeans (C3) - 2005" -US-Bo2,25070,GRP_SPP_O,SPP_COMMENT,http://public.ornl.gov/ameriflux/Site_Info/siteInfo.cfm?KEYID=us.bondville.02 -US-Bo2,8297,GRP_STATE,STATE,IL -US-Bo2,2360,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Carl Bernacchi -US-Bo2,2360,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Bo2,2360,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,bernacch@uiuc.edu -US-Bo2,2360,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"University of Illinois, Urbana-Champaign" -US-Bo2,2360,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Department of Plant Biology, 193 ERML-051,Urbana, IL 61801" -US-Bo2,7628,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Steven E. Hollinger -US-Bo2,7628,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Affiliate -US-Bo2,7628,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,hollinger@uiuc.edu -US-Bo2,7628,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Illinois State Water Survey -US-Bo2,7628,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Survey Research Center, 2204 Griffith Drive,Champaign, IL USA 61820" -US-Bo2,8425,GRP_URL,URL,http://www.life.illinois.edu/bernacchi/ -US-Bo2,24000342,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-Bo2 -US-Bo2,7007,GRP_UTC_OFFSET,UTC_OFFSET,-6 -US-BRG,30560,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,"The Bayles Road grassland tower is supported by the Department of Energy via the Ameriflux Management Project administered by Lawrence Berkeley National Lab, and by the National Science Foundation, Division of Environmental Biology (DEB 1552747 )" -US-BRG,30561,GRP_CLIM_AVG,MAT,11.8 -US-BRG,30561,GRP_CLIM_AVG,MAP,1200 -US-BRG,30561,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Cfa -US-BRG,27000697,GRP_COUNTRY,COUNTRY,USA -US-BRG,95035,GRP_DOI,DOI,10.17190/AMF/1756416 -US-BRG,95035,GRP_DOI,DOI_CITATION,"Kimberly Novick (2020), AmeriFlux BASE US-BRG Bayles Road Grassland Tower, Ver. 1-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1756416" -US-BRG,95035,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-BRG,94941,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-BRG,94941,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Kimberly Novick -US-BRG,94941,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-BRG,94941,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,knovick@indiana.edu -US-BRG,94941,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Indiana University -US-BRG,94945,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Indiana University -US-BRG,94945,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-BRG,94944,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,"Ameriflux Management Project, National Science Foundation" -US-BRG,94944,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-BRG,30563,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-BRG,30563,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-BRG,30563,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201608050930 -US-BRG,30563,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-BRG,30562,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-BRG,30562,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-BRG,30562,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201608050930 -US-BRG,30562,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-BRG,23000697,GRP_HEADER,SITE_NAME,Bayles Road Grassland Tower -US-BRG,30564,GRP_IGBP,IGBP,GRA -US-BRG,30564,GRP_IGBP,IGBP_DATE_START,200510010000 -US-BRG,30565,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-BRG,30565,GRP_LAND_OWNERSHIP,LAND_OWNER,Indiana University -US-BRG,30566,GRP_LOCATION,LOCATION_LAT,39.2167 -US-BRG,30566,GRP_LOCATION,LOCATION_LONG,-86.5406 -US-BRG,30566,GRP_LOCATION,LOCATION_ELEV,180 -US-BRG,30566,GRP_LOCATION,LOCATION_DATE_START,201511251000 -US-BRG,30567,GRP_NETWORK,NETWORK,AmeriFlux -US-BRG,1700008520,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Zhang, Q., Barnes, M., Benson, M., Burakowski, E., Oishi, A. C., Ouimette, A., Sanders‐DeMott, R., Stoy, P. C., Wenzel, M., Xiong, L., Yi, K., Novick, K. A. (2020) Reforestation And Surface Cooling In Temperate Zones: Mechanisms And Implications, Global Change Biology, 26(6), 3384-3401" -US-BRG,1700008520,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/GCB.15069 -US-BRG,1700008520,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-BRG,30568,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,Land cover effects of energy balance; CO2 flux dynamics across successional chronosequences -US-BRG,30569,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"Bloomington, IN 47405" -US-BRG,30570,GRP_SITE_CHAR,TERRAIN,Flat -US-BRG,30570,GRP_SITE_CHAR,ASPECT,FLAT -US-BRG,30570,GRP_SITE_CHAR,WIND_DIRECTION,SW -US-BRG,30570,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,80 -US-BRG,30570,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,30 -US-BRG,30571,GRP_SITE_DESC,SITE_DESC,"The Bayles Road grassland tower is situated in an experimental field incorporated within the Indiana University Research and Teaching Preserve. The field was historically covered by bottomland hardwood forest and later maintained for plant genetics studies. Intermixed species of grasses, sedges, and forbs are currently maintained with occasional mowing." -US-BRG,30572,GRP_SITE_FUNDING,SITE_FUNDING,"Ameriflux Management Project, National Science Foundation" -US-BRG,30573,GRP_STATE,STATE,IN -US-BRG,30574,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Kimberly Novick -US-BRG,30574,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-BRG,30574,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,knovick@indiana.edu -US-BRG,30574,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Indiana University -US-BRG,30574,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,702 N Walnut Grove Ave -US-BRG,30576,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Quan Zhang -US-BRG,30576,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,AncContact -US-BRG,30576,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,quazhang@indiana.edu -US-BRG,83444,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Michael Benson -US-BRG,83444,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,DataManager -US-BRG,83444,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,micbenso@iu.edu -US-BRG,83444,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Indiana University Bloomington -US-BRG,30579,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-BRG,30577,GRP_TOWER_TYPE,TOWER_TYPE,triangle -US-BRG,24000697,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-BRG -US-BRG,30578,GRP_UTC_OFFSET,UTC_OFFSET,-5 -US-BRG,30578,GRP_UTC_OFFSET,UTC_OFFSET_COMMENT,"Monroe County utilizes daylight savings time(DST), however the tower clock is not set to observe DST" -US-Bsg,16081,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,Supported by NOAA -US-Bsg,16082,GRP_CLIM_AVG,MAT,7.36 -US-Bsg,16082,GRP_CLIM_AVG,MAP,289 -US-Bsg,16082,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Bsk -US-Bsg,27000669,GRP_COUNTRY,COUNTRY,USA -US-Bsg,98953,GRP_DOI,DOI,10.17190/AMF/1846661 -US-Bsg,98953,GRP_DOI,DOI_CITATION,"Chris Still (2022), AmeriFlux BASE US-Bsg Burns Sagebrush, Ver. 1-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1846661" -US-Bsg,98953,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-Bsg,98936,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Bsg,98936,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Chris Still -US-Bsg,98936,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Bsg,98936,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,chris.still@oregonstate.edu -US-Bsg,98936,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Oregon State University -US-Bsg,98945,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Oregon State University -US-Bsg,98945,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-Bsg,98938,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,NOAA -US-Bsg,98938,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-Bsg,29691,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Grazing -US-Bsg,91416,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Bsg,91416,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-Bsg,91416,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201301 -US-Bsg,91416,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,201805 -US-Bsg,91416,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Bsg,91399,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Bsg,91399,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-Bsg,91399,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201301 -US-Bsg,91399,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,201805 -US-Bsg,91399,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Bsg,23000669,GRP_HEADER,SITE_NAME,Burns Sagebrush -US-Bsg,16084,GRP_IGBP,IGBP,OSH -US-Bsg,16085,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-Bsg,16085,GRP_LAND_OWNERSHIP,LAND_OWNER,USDA-ARS and Oregon State University -US-Bsg,16086,GRP_LOCATION,LOCATION_LAT,43.4712 -US-Bsg,16086,GRP_LOCATION,LOCATION_LONG,-119.6909 -US-Bsg,16086,GRP_LOCATION,LOCATION_ELEV,1398 -US-Bsg,16087,GRP_NETWORK,NETWORK,AmeriFlux -US-Bsg,86954,GRP_NETWORK,NETWORK,Phenocam -US-Bsg,1700006681,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Schmidt, A., Law, B. E., Göckede, M., Hanson, C., Yang, Z., Conley, S. (2016) Bayesian Optimization Of The Community Land Model Simulated Biosphere–Atmosphere Exchange Using CO2 Observations From A Dense Tower Network And Aircraft Campaigns Over Oregon, Earth Interactions, 20(22), 1-35" -US-Bsg,1700006681,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1175/EI-D-16-0011.1 -US-Bsg,1700006681,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Bsg,1700006858,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Schmidt, A., Law, B. E., Göckede, M., Hanson, C., Yang, Z., Conley, S. (2016) Bayesian Optimization Of The Community Land Model Simulated Biosphere–Atmosphere Exchange Using Co2observations From A Dense Tower Network And Aircraft Campaigns Over Oregon, Earth Interactions, 20(22), 1-35" -US-Bsg,1700006858,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1175/EI-D-16-0011.1 -US-Bsg,1700006858,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Bsg,29690,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,Flux patterns in dry shrubland areas of the northwestern Great Basin -US-Bsg,16088,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"321 Richardson Hall, Oregon State University,Corvallis, OR, 97331" -US-Bsg,16089,GRP_SITE_CHAR,TERRAIN,Flat -US-Bsg,16089,GRP_SITE_CHAR,ASPECT,W -US-Bsg,16089,GRP_SITE_CHAR,WIND_DIRECTION,W -US-Bsg,16089,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,1947 -US-Bsg,16089,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,0 -US-Bsg,16090,GRP_SITE_DESC,SITE_DESC,"The site was established in 2012 and is part of a NOAA observation network for high precision measurements of carbon dioxide concentrations. It is located about 60 km southwest of Burns, Oregon in the Oregon High Desert. The vegetation in this area is dominated by sagebrush. The sampling inlets are at the heights of 18.5, 28.5, and 38.5 m. Gas analysis is performed with a Picarro 2302 Cavity Ringdown Spectrometer and a Li-Cor 7200 enclosed path IRGA. The tower is also equipped with a set of meteorological instruments, including an HMP sensor, radiation sensors (incoming and diffuse PAR, Net radiometer), and a CSAT3 sonic anemometer. This site is also part of the PhenoCam network operated by Harvard University and the University of New Hampshire." -US-Bsg,16091,GRP_SITE_FUNDING,SITE_FUNDING,NOAA -US-Bsg,16092,GRP_STATE,STATE,OR -US-Bsg,95077,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Chris Still -US-Bsg,95077,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Bsg,95077,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,chris.still@oregonstate.edu -US-Bsg,95077,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Oregon State University -US-Bsg,95077,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Department of Forest Ecosystems and Society, 321 Richardson Hall,Corvallis, OR USA 97331" -US-Bsg,95081,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Chad Hanson -US-Bsg,95081,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,AncContact -US-Bsg,95081,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,chad.hanson@oregonstate.edu -US-Bsg,95081,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Oregon State University -US-Bsg,95081,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Department of Forest Ecosystems and Society, 321 Richardson Hall,Corvallis, OR USA 97331" -US-Bsg,29921,GRP_TOWER_POWER,TOWER_POWER,Direct power -US-Bsg,16094,GRP_TOWER_TYPE,TOWER_TYPE,triangle -US-Bsg,16095,GRP_URL,URL,http://terraweb.forestry.oregonstate.edu/burns.htm -US-Bsg,24000669,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-Bsg -US-Bsg,97741,GRP_UTC_OFFSET,UTC_OFFSET,-8 -US-BZB,87192,GRP_CLIM_AVG,MAT,-2.4 -US-BZB,87192,GRP_CLIM_AVG,MAP,274 -US-BZB,87192,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfd -US-BZB,27001077,GRP_COUNTRY,COUNTRY,USA -US-BZB,95624,GRP_DOI,DOI,10.17190/AMF/1773401 -US-BZB,95624,GRP_DOI,DOI_CITATION,"Eugenie Euskirchen (2022), AmeriFlux BASE US-BZB Bonanza Creek Thermokarst Bog, Ver. 3-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1773401" -US-BZB,95624,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-BZB,95618,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-BZB,95618,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Eugenie Euskirchen -US-BZB,95618,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-BZB,95618,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,seeuskirchen@alaska.edu -US-BZB,95618,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"University of Alaska Fairbanks, Institute of Arctic Biology" -US-BZB,95619,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,"University of Alaska Fairbanks, Institute of Arctic Biology" -US-BZB,95619,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-BZB,93351,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,National Science Foundation -US-BZB,93351,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-BZB,93348,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,U.S. Geological Survey -US-BZB,93348,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-BZB,87198,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-BZB,87198,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-BZB,87198,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20110101 -US-BZB,87198,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-BZB,87190,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-BZB,87190,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-BZB,87190,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20110101 -US-BZB,87190,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-BZB,87194,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-BZB,87194,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CH4 -US-BZB,87194,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20130420 -US-BZB,87194,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Growing season operation only -US-BZB,23001077,GRP_HEADER,SITE_NAME,Bonanza Creek Thermokarst Bog -US-BZB,87202,GRP_IGBP,IGBP,WET -US-BZB,87202,GRP_IGBP,IGBP_COMMENT,Classified as a bog wetland -US-BZB,87206,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-BZB,87191,GRP_LOCATION,LOCATION_LAT,64.6955 -US-BZB,87191,GRP_LOCATION,LOCATION_LONG,-148.3208 -US-BZB,87191,GRP_LOCATION,LOCATION_ELEV,100 -US-BZB,87200,GRP_NETWORK,NETWORK,AmeriFlux -US-BZB,87205,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"Part of a long-term study to examine carbon, water, and energy fluxes across a gradient of permafrost thaw. Data are already available by request or through the Bonanza Creek LTER database: https://www.lter.uaf.edu/data/" -US-BZB,87197,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"2140 Koyukuk Dr., Box 757000, Fairbanks, AK 99775" -US-BZB,87193,GRP_SITE_CHAR,TERRAIN,Flat -US-BZB,87193,GRP_SITE_CHAR,WIND_DIRECTION,ENE -US-BZB,87193,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,20 -US-BZB,87193,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,180 -US-BZB,87196,GRP_SITE_DESC,SITE_DESC,Intermediate to old age thermokarst collapse scar boreal bog in the Tanana Lowlands of Interior Alaska. Peat soils ~1-m thick. Recharged by precipitation and runoff from the surrounding forested peat plateaus. Primary wind direction in the summer is WSW. -US-BZB,87195,GRP_SITE_FUNDING,SITE_FUNDING,"USGS, NSF" -US-BZB,87201,GRP_STATE,STATE,AK -US-BZB,87203,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Eugenie Euskirchen -US-BZB,87203,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-BZB,87203,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,seeuskirchen@alaska.edu -US-BZB,87203,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"University of Alaska Fairbanks, Institute of Arctic Biology" -US-BZB,87203,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"2140 Koyukuk Dr., Box 757000, Fairbanks, AK 99775" -US-BZB,95241,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Colin Edgar -US-BZB,95241,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-BZB,95241,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,cedgar3@alaska.edu -US-BZB,87188,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-BZB,87189,GRP_TOWER_TYPE,TOWER_TYPE,tripod -US-BZB,24001077,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-BZB -US-BZB,87199,GRP_UTC_OFFSET,UTC_OFFSET,-9 -US-BZB,87199,GRP_UTC_OFFSET,UTC_OFFSET_COMMENT,The -9 offset is for Alaska Standard Time. -US-BZF,87216,GRP_CLIM_AVG,MAT,-2.4 -US-BZF,87216,GRP_CLIM_AVG,MAP,274 -US-BZF,87216,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfd -US-BZF,27001079,GRP_COUNTRY,COUNTRY,USA -US-BZF,95060,GRP_DOI,DOI,10.17190/AMF/1756433 -US-BZF,95060,GRP_DOI,DOI_CITATION,"Eugenie Euskirchen (2022), AmeriFlux BASE US-BZF Bonanza Creek Rich Fen, Ver. 3-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1756433" -US-BZF,95060,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-BZF,94989,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-BZF,94989,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Eugenie Euskirchen -US-BZF,94989,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-BZF,94989,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,seeuskirchen@alaska.edu -US-BZF,94989,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"University of Alaska Fairbanks, Institute of Arctic Biology" -US-BZF,94991,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,"University of Alaska Fairbanks, Institute of Arctic Biology" -US-BZF,94991,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-BZF,93359,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,National Science Foundation -US-BZF,93359,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-BZF,93358,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,U.S. Geological Survey -US-BZF,93358,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-BZF,87222,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-BZF,87222,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-BZF,87222,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20110512 -US-BZF,87222,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-BZF,87214,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-BZF,87214,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-BZF,87214,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20110512 -US-BZF,87214,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-BZF,87219,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-BZF,87219,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CH4 -US-BZF,87219,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20140416 -US-BZF,87219,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Growing season operation only -US-BZF,23001079,GRP_HEADER,SITE_NAME,Bonanza Creek Rich Fen -US-BZF,87224,GRP_IGBP,IGBP,WET -US-BZF,87224,GRP_IGBP,IGBP_COMMENT,Classified as a rich fen -US-BZF,87210,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-BZF,96757,GRP_LOCATION,LOCATION_LAT,64.7013 -US-BZF,96757,GRP_LOCATION,LOCATION_LONG,-148.3121 -US-BZF,96757,GRP_LOCATION,LOCATION_ELEV,95 -US-BZF,96757,GRP_LOCATION,LOCATION_COMMENT,APEX Alpha site -US-BZF,87220,GRP_NETWORK,NETWORK,AmeriFlux -US-BZF,1700006816,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Euskirchen, E. S., Kane, E. S., Edgar, C. W., Turetsky, M. R. (2019) When The Source Of Flooding Matters: Divergent Responses In Carbon Fluxes In An Alaskan Rich Fen To Two Types Of Inundation, Ecosystems, (), " -US-BZF,1700006816,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1007/S10021-019-00460-Z -US-BZF,1700006816,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-BZF,87217,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"Part of a long-term study to examine carbon, water, and energy fluxes across a gradient of permafrost thaw. Data are already available by request or through the Bonanza Creek LTER database: https://www.lter.uaf.edu/data/" -US-BZF,87218,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"2140 Koyukuk Dr., Box 757000, Fairbanks, AK 99775" -US-BZF,87213,GRP_SITE_CHAR,TERRAIN,Flat -US-BZF,87213,GRP_SITE_CHAR,WIND_DIRECTION,ENE -US-BZF,87213,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,20 -US-BZF,87213,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,180 -US-BZF,87223,GRP_SITE_DESC,SITE_DESC,The rich fen is in the boreal peatland lowlands of the Tanana Flats in interior Alaska. Lacks near-surface permafrost even though the surrounding landscape is marked by the presence of permafrost. Peat depth is 1-2m. Primary wind direction in the summer is WSW. -US-BZF,87221,GRP_SITE_FUNDING,SITE_FUNDING,"USGS, NSF" -US-BZF,87225,GRP_STATE,STATE,AK -US-BZF,87211,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Eugenie Euskirchen -US-BZF,87211,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-BZF,87211,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,seeuskirchen@alaska.edu -US-BZF,87211,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"University of Alaska Fairbanks, Institute of Arctic Biology" -US-BZF,87211,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"2140 Koyukuk Dr., Box 757000, Fairbanks, AK 99775" -US-BZF,95243,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Colin Edgar -US-BZF,95243,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-BZF,95243,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,cedgar3@alaska.edu -US-BZF,87208,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-BZF,87215,GRP_TOWER_TYPE,TOWER_TYPE,tripod -US-BZF,24001079,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-BZF -US-BZF,87209,GRP_UTC_OFFSET,UTC_OFFSET,-9 -US-BZF,87209,GRP_UTC_OFFSET,UTC_OFFSET_COMMENT,The -9 offset is for Alaska Standard Time. -US-BZL,87243,GRP_CLIM_AVG,MAT,-2.4 -US-BZL,87243,GRP_CLIM_AVG,MAP,274 -US-BZL,87243,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfd -US-BZL,27001080,GRP_COUNTRY,COUNTRY,USA -US-BZL,87234,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-BZL,87234,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-BZL,87234,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20171118 -US-BZL,87234,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-BZL,87244,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-BZL,87244,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CH4 -US-BZL,87244,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20171118 -US-BZL,87244,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-BZL,87245,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-BZL,87245,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-BZL,87245,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20171118 -US-BZL,87245,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-BZL,23001080,GRP_HEADER,SITE_NAME,Goldstream Valley Thermokarst Lake -US-BZL,87232,GRP_IGBP,IGBP,WET -US-BZL,87232,GRP_IGBP,IGBP_COMMENT,"Thermokarst Lake, with lake margins surrounded by black spruce and shrubs" -US-BZL,87235,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-BZL,87240,GRP_LOCATION,LOCATION_LAT,64.9194 -US-BZL,87240,GRP_LOCATION,LOCATION_LONG,-147.8222 -US-BZL,87240,GRP_LOCATION,LOCATION_ELEV,188 -US-BZL,87236,GRP_NETWORK,NETWORK,AmeriFlux -US-BZL,87241,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,This is part of a study to better understand methane emissions from newly formed thermokarst lakes in Alaska. -US-BZL,87237,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"2140 Koyukuk Dr., Box 757000, Fairbanks, AK 99775" -US-BZL,87238,GRP_SITE_CHAR,TERRAIN,Flat -US-BZL,87238,GRP_SITE_CHAR,WIND_DIRECTION,ENE -US-BZL,87238,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,20 -US-BZL,87238,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,180 -US-BZL,87229,GRP_SITE_DESC,SITE_DESC,"The thermokarst lake is fairly newly formed and is located within the Goldstream Valley in Fairbanks, AK. The lake is informally known as 'Big Trail Lake', and is within a discontinuos permafrost area, although Goldstream Valley itself contains more continuous permafrost and peaty soils." -US-BZL,87227,GRP_SITE_FUNDING,SITE_FUNDING,NASA -US-BZL,87233,GRP_STATE,STATE,AK -US-BZL,87226,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Eugenie Euskirchen -US-BZL,87226,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-BZL,87226,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,seeuskirchen@alaska.edu -US-BZL,87226,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"University of Alaska Fairbanks, Institute of Arctic Biology" -US-BZL,87226,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"2140 Koyukuk Dr., Box 757000, Fairbanks, AK 99775" -US-BZL,87231,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Katey Walter Anthony -US-BZL,87231,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-BZL,87231,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,kmwalteranthony@alaska.edu -US-BZL,87231,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"University of Alsaka Fairbanks, Water and Environmental Research Center" -US-BZL,87231,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1764 Tanana Loop, Ste. 240, ELIF Building" -US-BZL,95240,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Colin Edgar -US-BZL,95240,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-BZL,95240,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,cedgar3@alaska.edu -US-BZL,95240,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"University of Alaska Fairbanks, Institute of Arctic Biology" -US-BZL,87230,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-BZL,87242,GRP_TOWER_TYPE,TOWER_TYPE,tripod -US-BZL,24001080,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-BZL -US-BZL,87228,GRP_UTC_OFFSET,UTC_OFFSET,-9 -US-BZL,87228,GRP_UTC_OFFSET,UTC_OFFSET_COMMENT,The -9 offset is for Alaska Standard Time. -US-BZo,87283,GRP_CLIM_AVG,MAT,-2.4 -US-BZo,87283,GRP_CLIM_AVG,MAP,274 -US-BZo,87283,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfd -US-BZo,27001078,GRP_COUNTRY,COUNTRY,USA -US-BZo,98954,GRP_DOI,DOI,10.17190/AMF/1846662 -US-BZo,98954,GRP_DOI,DOI_CITATION,"Eugenie Euskirchen (2022), AmeriFlux BASE US-BZo Bonanza Creek Old Thermokarst Bog, Ver. 2-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1846662" -US-BZo,98954,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-BZo,98933,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-BZo,98933,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Eugenie Euskirchen -US-BZo,98933,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-BZo,98933,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,seeuskirchen@alaska.edu -US-BZo,98933,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"University of Alaska Fairbanks, Institute of Arctic Biology" -US-BZo,98946,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,"University of Alaska Fairbanks, Institute of Arctic Biology" -US-BZo,98946,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-BZo,98943,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,"USGS, NSF" -US-BZo,98943,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-BZo,87272,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-BZo,87272,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-BZo,87272,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20180506 -US-BZo,87272,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-BZo,87273,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-BZo,87273,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-BZo,87273,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20180506 -US-BZo,87273,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-BZo,87274,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-BZo,87274,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CH4 -US-BZo,87274,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20180506 -US-BZo,87274,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Growing season operation only -US-BZo,23001078,GRP_HEADER,SITE_NAME,Bonanza Creek Old Thermokarst Bog -US-BZo,87280,GRP_IGBP,IGBP,WET -US-BZo,87280,GRP_IGBP,IGBP_COMMENT,Classified as a bog wetland -US-BZo,87281,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-BZo,87279,GRP_LOCATION,LOCATION_LAT,64.6936 -US-BZo,87279,GRP_LOCATION,LOCATION_LONG,-148.3300 -US-BZo,87279,GRP_LOCATION,LOCATION_ELEV,100 -US-BZo,87271,GRP_NETWORK,NETWORK,AmeriFlux -US-BZo,87277,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"Part of a long-term study to examine carbon, water, and energy fluxes across a gradient of permafrost thaw. Data are already available by request or through the Bonanza Creek LTER database: https://www.lter.uaf.edu/data/" -US-BZo,87270,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"2140 Koyukuk Dr., Box 757000, Fairbanks, AK 99775" -US-BZo,87284,GRP_SITE_CHAR,TERRAIN,Flat -US-BZo,87284,GRP_SITE_CHAR,WIND_DIRECTION,ENE -US-BZo,87284,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,20 -US-BZo,87284,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,180 -US-BZo,87276,GRP_SITE_DESC,SITE_DESC,Old thermokarst collapse scar boreal bog (several hundred years old) in the Tanana Lowlands of Interior Alaska. Peat soils ~1-m thick. Recharged by precipitation and runoff from the surrounding forested peat plateaus. Primary wind direction in the summer is WSW. -US-BZo,87278,GRP_SITE_FUNDING,SITE_FUNDING,"USGS, NSF" -US-BZo,87275,GRP_STATE,STATE,AK -US-BZo,87268,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Eugenie Euskirchen -US-BZo,87268,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-BZo,87268,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,seeuskirchen@alaska.edu -US-BZo,87268,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"University of Alaska Fairbanks, Institute of Arctic Biology" -US-BZo,87268,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"2140 Koyukuk Dr., Box 757000, Fairbanks, AK 99775" -US-BZo,95245,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Colin Edgar -US-BZo,95245,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-BZo,95245,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,cedgar3@alaska.edu -US-BZo,87286,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-BZo,87285,GRP_TOWER_TYPE,TOWER_TYPE,tripod -US-BZo,24001078,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-BZo -US-BZo,87282,GRP_UTC_OFFSET,UTC_OFFSET,-9 -US-BZo,87282,GRP_UTC_OFFSET,UTC_OFFSET_COMMENT,The -9 offset is for Alaska Standard Time. -US-BZS,87184,GRP_CLIM_AVG,MAT,-2.4 -US-BZS,87184,GRP_CLIM_AVG,MAP,274 -US-BZS,87184,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfd -US-BZS,27001076,GRP_COUNTRY,COUNTRY,USA -US-BZS,95025,GRP_DOI,DOI,10.17190/AMF/1756434 -US-BZS,95025,GRP_DOI,DOI_CITATION,"Eugenie Euskirchen (2022), AmeriFlux BASE US-BZS Bonanza Creek Black Spruce, Ver. 3-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1756434" -US-BZS,95025,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-BZS,94988,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-BZS,94988,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Eugenie Euskirchen -US-BZS,94988,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-BZS,94988,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,seeuskirchen@alaska.edu -US-BZS,94988,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"University of Alaska Fairbanks, Institute of Arctic Biology" -US-BZS,94990,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,"University of Alaska Fairbanks, Institute of Arctic Biology" -US-BZS,94990,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-BZS,93354,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,National Science Foundation -US-BZS,93354,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-BZS,93353,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,U.S. Geological Survey -US-BZS,93353,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-BZS,87173,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-BZS,87173,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-BZS,87173,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20100615 -US-BZS,87173,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-BZS,87174,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-BZS,87174,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-BZS,87174,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20100615 -US-BZS,87174,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-BZS,87175,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-BZS,87175,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CH4 -US-BZS,87175,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20150407 -US-BZS,87175,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20171103 -US-BZS,87175,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Growing season operation only -US-BZS,87175,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,CH4 sensor moved to another site in 2018 -US-BZS,23001076,GRP_HEADER,SITE_NAME,Bonanza Creek Black Spruce -US-BZS,87181,GRP_IGBP,IGBP,ENF -US-BZS,87181,GRP_IGBP,IGBP_COMMENT,Black spruce -US-BZS,87182,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-BZS,87180,GRP_LOCATION,LOCATION_LAT,64.6963 -US-BZS,87180,GRP_LOCATION,LOCATION_LONG,-148.3235 -US-BZS,87180,GRP_LOCATION,LOCATION_ELEV,100 -US-BZS,87172,GRP_NETWORK,NETWORK,AmeriFlux -US-BZS,87178,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"Part of a long-term study to examine carbon, water, and energy fluxes across a gradient of permafrost thaw. Data are already available by request or through the Bonanza Creek LTER database: https://www.lter.uaf.edu/data/" -US-BZS,87171,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"2140 Koyukuk Dr., Box 757000, Fairbanks, AK 99775" -US-BZS,87185,GRP_SITE_CHAR,TERRAIN,Flat -US-BZS,87185,GRP_SITE_CHAR,WIND_DIRECTION,ENE -US-BZS,87185,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,30 -US-BZS,87185,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,180 -US-BZS,87177,GRP_SITE_DESC,SITE_DESC,"Mature black spruce boreal forest with cold, permafrost soils on a peat plateau. In the Tanana lowlands in interior Alaska. Primary wind direction in the summer is WSW." -US-BZS,87179,GRP_SITE_FUNDING,SITE_FUNDING,"USGS, NSF" -US-BZS,87176,GRP_STATE,STATE,AK -US-BZS,87169,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Eugenie Euskirchen -US-BZS,87169,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-BZS,87169,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,seeuskirchen@alaska.edu -US-BZS,87169,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"University of Alaska Fairbanks, Institute of Arctic Biology" -US-BZS,87169,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"2140 Koyukuk Dr., Box 757000, Fairbanks, AK 99775" -US-BZS,95244,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Colin Edgar -US-BZS,95244,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-BZS,95244,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,cedgar3@alaska.edu -US-BZS,87187,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-BZS,87186,GRP_TOWER_TYPE,TOWER_TYPE,triangle -US-BZS,24001076,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-BZS -US-BZS,87183,GRP_UTC_OFFSET,UTC_OFFSET,-9 -US-BZS,87183,GRP_UTC_OFFSET,UTC_OFFSET_COMMENT,The -9 offset is for Alaska Standard Time. -US-CC1,98563,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,We acknowledge support from the Wisconsin Potato and Vegetable Growers Association and the University of Wisconsin - Madison -US-CC1,98560,GRP_CLIM_AVG,MAT,7.5 -US-CC1,98560,GRP_CLIM_AVG,MAP,906.5 -US-CC1,98560,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfb -US-CC1,27001207,GRP_COUNTRY,COUNTRY,USA -US-CC1,99514,GRP_DOI,DOI,10.17190/AMF/1865475 -US-CC1,99514,GRP_DOI,DOI_CITATION,"Paul Stoy (2022), AmeriFlux BASE US-CC1 Coloma Corn 1, Ver. 1-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1865475" -US-CC1,99514,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-CC1,99481,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-CC1,99481,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Paul Stoy -US-CC1,99481,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-CC1,99481,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,pcstoy@wisc.edu -US-CC1,99481,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of Wisconsin -US-CC1,99502,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,University of Wisconsin -US-CC1,99502,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-CC1,99497,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Wisconsin Potato and Vegetable Growers Association -US-CC1,99497,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-CC1,98561,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-CC1,98561,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-CC1,98561,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,202106241500 -US-CC1,98561,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,202110121100 -US-CC1,98561,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Periodic operation -US-CC1,98569,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-CC1,98569,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-CC1,98569,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,202106241500 -US-CC1,98569,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,202110121100 -US-CC1,98569,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Periodic operation -US-CC1,98566,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-CC1,98566,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-CC1,98566,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,202106241500 -US-CC1,98566,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,202110121100 -US-CC1,98566,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Periodic operation -US-CC1,23001207,GRP_HEADER,SITE_NAME,Coloma Corn 1 -US-CC1,98573,GRP_IGBP,IGBP,CRO -US-CC1,98573,GRP_IGBP,IGBP_COMMENT,Corn -US-CC1,98614,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -US-CC1,98562,GRP_LOCATION,LOCATION_LAT,44.0732 -US-CC1,98562,GRP_LOCATION,LOCATION_LONG,-89.6787 -US-CC1,98562,GRP_LOCATION,LOCATION_ELEV,314 -US-CC1,98562,GRP_LOCATION,LOCATION_DATE_START,202106241500 -US-CC1,98572,GRP_NETWORK,NETWORK,AmeriFlux -US-CC1,98556,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"carbon dioxide flux, evapotranspiration" -US-CC1,98571,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"540 Elm Drive, University of Wisconsin – Madison, Madison, WI 53706" -US-CC1,98574,GRP_SITE_CHAR,TERRAIN,Flat -US-CC1,98574,GRP_SITE_CHAR,ASPECT,FLAT -US-CC1,98574,GRP_SITE_CHAR,WIND_DIRECTION,SW -US-CC1,98574,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,100 -US-CC1,98555,GRP_SITE_DESC,SITE_DESC,The site is a corn (Zea mays) field on sandy soil -US-CC1,98564,GRP_SITE_FUNDING,SITE_FUNDING,Wisconsin Potato and Vegetable Growers Association -US-CC1,98565,GRP_STATE,STATE,WI -US-CC1,98558,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Paul Stoy -US-CC1,98558,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-CC1,98558,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,pcstoy@wisc.edu -US-CC1,98558,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Wisconsin -US-CC1,98558,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"460 Henry Mall, University of Wisconsin – Madison, Madison, WI 53706" -US-CC1,98559,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Sharifa Brevert -US-CC1,98559,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,AncContact -US-CC1,98559,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,brevert@wisc.edu -US-CC1,98559,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Wisconsin -US-CC1,98557,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-CC1,98568,GRP_TOWER_TYPE,TOWER_TYPE,tripod -US-CC1,24001207,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-CC1 -US-CC1,98570,GRP_UTC_OFFSET,UTC_OFFSET,-6 -US-CC1,98570,GRP_UTC_OFFSET,UTC_OFFSET_DATE_START,202106241500 -US-CC2,98582,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,We acknowledge support from the Wisconsin Potato and Vegetable Growers Association and the University of Wisconsin - Madison -US-CC2,98578,GRP_CLIM_AVG,MAT,7.5 -US-CC2,98578,GRP_CLIM_AVG,MAP,906.5 -US-CC2,98578,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfb -US-CC2,27001208,GRP_COUNTRY,COUNTRY,USA -US-CC2,99512,GRP_DOI,DOI,10.17190/AMF/1865476 -US-CC2,99512,GRP_DOI,DOI_CITATION,"Paul Stoy (2022), AmeriFlux BASE US-CC2 Coloma Corn 2, Ver. 1-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1865476" -US-CC2,99512,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-CC2,99486,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-CC2,99486,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Paul Stoy -US-CC2,99486,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-CC2,99486,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,pcstoy@wisc.edu -US-CC2,99486,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of Wisconsin -US-CC2,99500,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,University of Wisconsin -US-CC2,99500,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-CC2,99498,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Wisconsin Potato and Vegetable Growers Association -US-CC2,99498,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-CC2,98575,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-CC2,98575,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-CC2,98575,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,202107051500 -US-CC2,98575,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,202110120900 -US-CC2,98575,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Periodic operation -US-CC2,98585,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-CC2,98585,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-CC2,98585,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,202107051500 -US-CC2,98585,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,202110120900 -US-CC2,98585,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Periodic operation -US-CC2,98577,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-CC2,98577,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-CC2,98577,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,202107051500 -US-CC2,98577,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,202110120900 -US-CC2,98577,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Periodic operation -US-CC2,23001208,GRP_HEADER,SITE_NAME,Coloma Corn 2 -US-CC2,98584,GRP_IGBP,IGBP,CRO -US-CC2,98584,GRP_IGBP,IGBP_COMMENT,Corn -US-CC2,98615,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -US-CC2,98594,GRP_LOCATION,LOCATION_LAT,44.1039 -US-CC2,98594,GRP_LOCATION,LOCATION_LONG,-89.6196 -US-CC2,98594,GRP_LOCATION,LOCATION_ELEV,320 -US-CC2,98594,GRP_LOCATION,LOCATION_DATE_START,202107051500 -US-CC2,98595,GRP_NETWORK,NETWORK,AmeriFlux -US-CC2,98576,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"carbon dioxide flux, evapotranspiration" -US-CC2,98590,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"540 Elm Drive, University of Wisconsin – Madison, Madison, WI 53706" -US-CC2,98581,GRP_SITE_CHAR,TERRAIN,Flat -US-CC2,98581,GRP_SITE_CHAR,ASPECT,FLAT -US-CC2,98581,GRP_SITE_CHAR,WIND_DIRECTION,SW -US-CC2,98581,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,40 -US-CC2,98591,GRP_SITE_DESC,SITE_DESC,The site is a corn (Zea mays) field on sandy soil -US-CC2,98586,GRP_SITE_FUNDING,SITE_FUNDING,Wisconsin Potato and Vegetable Growers Association -US-CC2,98592,GRP_STATE,STATE,WI -US-CC2,98587,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Paul Stoy -US-CC2,98587,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-CC2,98587,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,pcstoy@wisc.edu -US-CC2,98587,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Wisconsin -US-CC2,98587,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"460 Henry Mall, University of Wisconsin – Madison, Madison, WI 53706" -US-CC2,98588,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Anam Khan -US-CC2,98588,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,AncContact -US-CC2,98588,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,amkhan7@wisc.edu -US-CC2,98588,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Wisconsin -US-CC2,98589,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Sharifa Brevert -US-CC2,98589,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,AncContact -US-CC2,98589,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,brevert@wisc.edu -US-CC2,98589,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Wisconsin -US-CC2,98580,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-CC2,98583,GRP_TOWER_TYPE,TOWER_TYPE,tripod -US-CC2,24001208,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-CC2 -US-CC2,98579,GRP_UTC_OFFSET,UTC_OFFSET,-6 -US-CC2,98579,GRP_UTC_OFFSET,UTC_OFFSET_DATE_START,202106241500 -US-CdM,86841,GRP_CLIM_AVG,MAT,11.3 -US-CdM,86841,GRP_CLIM_AVG,MAP,348 -US-CdM,86841,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Bsk -US-CdM,27001072,GRP_COUNTRY,COUNTRY,USA -US-CdM,99511,GRP_DOI,DOI,10.17190/AMF/1865477 -US-CdM,99511,GRP_DOI,DOI_CITATION,"David Bowling, Steve Kannenberg, William Anderegg (2022), AmeriFlux BASE US-CdM Cedar Mesa, Ver. 1-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1865477" -US-CdM,99511,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-CdM,99478,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-CdM,99478,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,David Bowling -US-CdM,99478,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-CdM,99478,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,david.bowling@utah.edu -US-CdM,99478,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of Utah -US-CdM,99484,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-CdM,99484,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Steve Kannenberg -US-CdM,99484,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-CdM,99484,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,s.kannenberg@utah.edu -US-CdM,99484,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of Utah -US-CdM,99483,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-CdM,99483,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,William Anderegg -US-CdM,99483,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-CdM,99483,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,anderegg@utah.edu -US-CdM,99483,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of Utah -US-CdM,99501,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,University of Utah -US-CdM,99501,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-CdM,99495,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,"Ameriflux Management Project, U.S. Forest Service Evaluation Monitoring program" -US-CdM,99495,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-CdM,86847,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Drought -US-CdM,86832,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Grazing -US-CdM,86848,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-CdM,86848,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-CdM,86848,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201906120000 -US-CdM,86848,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-CdM,86831,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-CdM,86831,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-CdM,86831,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201906120000 -US-CdM,86831,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-CdM,86835,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-CdM,86835,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-CdM,86835,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201906120000 -US-CdM,86835,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-CdM,23001072,GRP_HEADER,SITE_NAME,Cedar Mesa -US-CdM,86833,GRP_IGBP,IGBP,WSA -US-CdM,86833,GRP_IGBP,IGBP_DATE_START,20190510 -US-CdM,86839,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-CdM,86839,GRP_LAND_OWNERSHIP,LAND_OWNER,State of Utah -US-CdM,86842,GRP_LOCATION,LOCATION_LAT,37.5241 -US-CdM,86842,GRP_LOCATION,LOCATION_LONG,-109.7471 -US-CdM,86842,GRP_LOCATION,LOCATION_ELEV,1860 -US-CdM,86842,GRP_LOCATION,LOCATION_DATE_START,20190510 -US-CdM,86850,GRP_NETWORK,NETWORK,AmeriFlux -US-CdM,86836,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"Pairing ecosystem fluxes with ecophysiological measurements, C and H2O fluxes, ecosystem recovery from drought" -US-CdM,86843,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"257 S 1400 E, Salt Lake City UT 84112" -US-CdM,86845,GRP_SITE_CHAR,TERRAIN,Flat -US-CdM,86845,GRP_SITE_CHAR,ASPECT,FLAT -US-CdM,86845,GRP_SITE_CHAR,WIND_DIRECTION,W -US-CdM,86845,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,4667 -US-CdM,94755,GRP_SITE_DESC,SITE_DESC,"This site is an Ameriflux rapid response system (installed May 2019) located on Cedar Mesa in the middle of Bear's Ears National Monument. In 2018, this pinyon-juniper woodland experienced a very severe drought, resulting in widespread mortality of Utah juniper (Juniperus osteosperma). The land is occasionally grazed for a few months in the spring." -US-CdM,86838,GRP_SITE_FUNDING,SITE_FUNDING,"Ameriflux Management Project, U.S. Forest Service Evaluation Monitoring program" -US-CdM,86830,GRP_STATE,STATE,UT -US-CdM,94877,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,David Bowling -US-CdM,94877,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-CdM,94877,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,david.bowling@utah.edu -US-CdM,94877,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Utah -US-CdM,94751,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Steve Kannenberg -US-CdM,94751,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-CdM,94751,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,s.kannenberg@utah.edu -US-CdM,94751,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Utah -US-CdM,86844,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,William Anderegg -US-CdM,86844,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-CdM,86844,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,anderegg@utah.edu -US-CdM,86844,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Utah -US-CdM,86834,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-CdM,24001072,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-CdM -US-CdM,86837,GRP_UTC_OFFSET,UTC_OFFSET,-6 -US-CdM,86837,GRP_UTC_OFFSET,UTC_OFFSET_DATE_START,20190510 -US-Ced,12657,GRP_CLIM_AVG,MAT,11.04 -US-Ced,12657,GRP_CLIM_AVG,MAP,1138 -US-Ced,12657,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Cfa -US-Ced,27000349,GRP_COUNTRY,COUNTRY,USA -US-Ced,15758,GRP_DOI,DOI,10.17190/AMF/1246043 -US-Ced,15758,GRP_DOI,DOI_CITATION,"Ken Clark (2016), AmeriFlux BASE US-Ced Cedar Bridge, Ver. 7-1, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1246043" -US-Ced,15758,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-Ced,32001,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Ced,32001,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Ken Clark -US-Ced,32001,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Ced,32001,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,kennethclark@fs.fed.us -US-Ced,32001,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,USDA Forest Service -US-Ced,32003,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,USDA Forest Service -US-Ced,32003,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-Ced,32002,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,USDA/Forest Service -US-Ced,32002,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-Ced,12674,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Fire -US-Ced,12658,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Pests and disease -US-Ced,12659,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Ced,12659,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-Ced,12659,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20050701 -US-Ced,12659,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Ced,12659,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,"Closed path system using a LI-7000 with a short inlet tube, resulting in a lag time of approx. 2.5 seconds." -US-Ced,12675,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Ced,12675,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-Ced,12675,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20050701 -US-Ced,12675,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Ced,12677,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Ced,12677,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-Ced,12677,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20050701 -US-Ced,12677,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Ced,23000349,GRP_HEADER,SITE_NAME,Cedar Bridge -US-Ced,12660,GRP_IGBP,IGBP,CSH -US-Ced,12661,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-Ced,12661,GRP_LAND_OWNERSHIP,LAND_OWNER,"Greenwood Wildlife Management Area, State of New Jersey" -US-Ced,12662,GRP_LOCATION,LOCATION_LAT,39.8379 -US-Ced,12662,GRP_LOCATION,LOCATION_LONG,-74.3791 -US-Ced,12662,GRP_LOCATION,LOCATION_ELEV,58 -US-Ced,12662,GRP_LOCATION,LOCATION_COMMENT,"Annual tree census data, annual clip plots for understory vegetation, approx. monthly litterfall collection, forest floor sampling in 2003, 2006, 2008, 2012, 2013. Extensive soil sampling in 2012." -US-Ced,12663,GRP_NETWORK,NETWORK,AmeriFlux -US-Ced,1700002961,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Baldocchi, D. D., Poindexter, C., Abraha, M., Desai, A. R., Bohrer, G., Arain, M. A., Griffis, T., Blanken, P. D., O'Halloran, T. L., Thomas, R. Q., Zhang, Q., Burns, S. P., Frank, J. M., Christian, D., Brown, S., Black, T. A., Gough, C. M., Law, B. E., Lee, X., Chen, J., Reed, D. E., Massman, W. J., Clark, K., Hatfield, J., Prueger, J., Bracho, R., Baker, J. M., Martin, T. A. (2018) Temporal Dynamics Of Aerodynamic Canopy Height Derived From Eddy Covariance Momentum Flux Data Across North American Flux Networks, Geophysical Research Letters, 45(3), 9275–9287" -US-Ced,1700002961,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018GL079306 -US-Ced,1700002961,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ced,1700005934,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(3), 108350" -US-Ced,1700005934,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -US-Ced,1700005934,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ced,1700005175,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Clark, K. L., Heilman, W. E., Skowronski, N. S., Gallagher, M. R., Mueller, E., Hadden, R. M., Simeoni, A. (2020) Fire Behavior, Fuel Consumption, And Turbulence And Energy Exchange During Prescribed Fires In Pitch Pine Forests, Atmosphere, 11(3), 25" -US-Ced,1700005175,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.3390/ATMOS11030242 -US-Ced,1700005175,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ced,1700006183,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Clark, K. L., Skowronski, N., Gallagher, M., Renninger, H., Schäfer, K. (2012) Effects Of Invasive Insects And Fire On Forest Energy Exchange And Evapotranspiration In The New Jersey Pinelands, Agricultural And Forest Meteorology, 166-167(1), 50-61" -US-Ced,1700006183,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2012.07.007 -US-Ced,1700006183,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ced,1700008475,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Clark, K. L., Skowronski, N., Hom, J. (2010) Invasive Insects Impact Forest Carbon Dynamics, Global Change Biology, 16(1), 88-101" -US-Ced,1700008475,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/J.1365-2486.2009.01983.X -US-Ced,1700008475,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ced,1700007248,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Clark, K. L., Skowronski, N., Renninger, H., Scheller, R. (2014) Climate Change And Fire Management In The Mid-Atlantic Region, Forest Ecology And Management, 327(2), 306-315" -US-Ced,1700007248,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.FORECO.2013.09.049 -US-Ced,1700007248,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ced,1700008334,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Clark, K., Renninger, H., Skowronski, N., Gallagher, M., Schäfer, K. (2018) Decadal-Scale Reduction In Forest Net Ecosystem Production Following Insect Defoliation Contrasts With Short-Term Impacts Of Prescribed Fires, Forests, 9(3), 145" -US-Ced,1700008334,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.3390/F9030145 -US-Ced,1700008334,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ced,1700007308,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Hannun, R. A., Wolfe, G. M., Kawa, S. R., Hanisco, T. F., Newman, P. A., Alfieri, J. G., Barrick, J., Clark, K. L., DiGangi, J. P., Diskin, G. S., King, J., Kustas, W. P., Mitra, B., Noormets, A., Nowak, J. B., Thornhill, K. L., Vargas, R. (2020) Spatial Heterogeneity In Co2, Ch4, And Energy Fluxes: Insights From Airborne Eddy Covariance Measurements Over The Mid-Atlantic Region, Environmental Research Letters, 15(3), 035008" -US-Ced,1700007308,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1088/1748-9326/AB7391 -US-Ced,1700007308,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ced,1700000261,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Skowronski, N. S., Clark, K. L., Duveneck, M., Hom, J. (2011) Three-Dimensional Canopy Fuel Loading Predicted Using Upward And Downward Sensing LiDAR Systems, Remote Sensing Of Environment, 115(2), 703-714" -US-Ced,1700000261,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.RSE.2010.10.012 -US-Ced,1700000261,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ced,1700000741,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"SKOWRONSKI, N., CLARK, K., NELSON, R., HOM, J., PATTERSON, M. (2007) Remotely Sensed Measurements Of Forest Structure And Fuel Loads In The Pinelands Of New Jersey, Remote Sensing Of Environment, 108(2), 123-129" -US-Ced,1700000741,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.RSE.2006.09.032 -US-Ced,1700000741,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ced,1700003669,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Wolf, S., Keenan, T.F., Fisher, J.B., Baldocchi, D.D., Desai, A.R., Richardson, A.D., Scott, R.L., Law, B.E., Litvak, M.E., Brunsell, N.A., Peters, W., van der Laan-Luijkx, I.T. (2016) Warm spring reduced carbon cycle impact of the 2012 US summer drought, Proceedings of the National Academy of Sciences, 113(21), 5880-5885" -US-Ced,1700003669,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1073/PNAS.1519620113 -US-Ced,1700003669,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ced,1700003720,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Zscheischler, J., Fatichi, S., Wolf, S., Blanken, P., Bohrer, G., Clark, K., Desai, A., Hollinger, D., Keenan, T., Novick, K.A., Seneviratne, S.I. (2016) Short-term favorable weather conditions are an important control of interannual variability in carbon and water fluxes, Journal of Geophysical Research - Biogeosciences, 121(8), 2186-2198" -US-Ced,1700003720,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/2016JG003503 -US-Ced,1700003720,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ced,12665,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"1) Impact of fire management activities on stand carbon dynamics, 2) Flux measurements and smoke emissions during prescribed burns, 3) Comparision of biometric, remotely sensed (LiDAR), and flux-based measurements of stand carbon dynamics." -US-Ced,12666,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"501 Four Mile Road, New Lisbon, NJ USA 08064" -US-Ced,12667,GRP_SITE_CHAR,TERRAIN,Flat -US-Ced,12667,GRP_SITE_CHAR,ASPECT,FLAT -US-Ced,12667,GRP_SITE_CHAR,WIND_DIRECTION,WNW -US-Ced,12667,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,20 -US-Ced,12668,GRP_SITE_DESC,SITE_DESC,"Wildfires and prescribed fires are a common occurrence in the NJ Pinelands. Prior to a 1995 nonstand replacing wildfire, the stand was last burned in the very large wildfire in 1963. Plow lines were installed for fire control in December of 2007, followed by a prescribed burns in 2008 and 2013, conducted by the New Jersey Forest Fire Service. Pine looper defoliated the stand in 1998, and Gypsy moth defoliated the understory and deciduos oaks in 2007. Pitch Pines are largely unaffected by defoliation by Gypsy moth." -US-Ced,12669,GRP_SITE_FUNDING,SITE_FUNDING,USDA/Forest Service -US-Ced,29625,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION,"Podzol, underlain by late Miocene fluvial sediments of the Kirkwood formation, and overlain with Cohansey sandy soil with low nutrient and cation exchange capacity" -US-Ced,29625,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION_TAXONOMY,Other -US-Ced,12670,GRP_STATE,STATE,NJ -US-Ced,12671,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Ken Clark -US-Ced,12671,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Ced,12671,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,kennethclark@fs.fed.us -US-Ced,12671,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,USDA Forest Service -US-Ced,12671,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Silas Little Experimental Forest, P.O. Box 232,New Lisbon, NJ USA 08064" -US-Ced,29806,GRP_TOWER_POWER,TOWER_POWER,Direct power -US-Ced,12672,GRP_TOWER_TYPE,TOWER_TYPE,triangle -US-Ced,12673,GRP_URL,URL,http://www.fs.fed.us/ne/global -US-Ced,24000349,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-Ced -US-Ced,33621,GRP_UTC_OFFSET,UTC_OFFSET,-5 -US-Ced,33621,GRP_UTC_OFFSET,UTC_OFFSET_COMMENT,Added by AMF data processing team for data QAQC checks. -US-CF1,84800,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,The USDA-ARS supported Cook Agronomy Farm Long-Term Agro-ecosystem Research site provided data for this work. -US-CF1,84801,GRP_CLIM_AVG,MAT,9 -US-CF1,84801,GRP_CLIM_AVG,MAP,550 -US-CF1,84801,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dsb -US-CF1,27000995,GRP_COUNTRY,COUNTRY,USA -US-CF1,87133,GRP_DOI,DOI,10.17190/AMF/1543382 -US-CF1,87133,GRP_DOI,DOI_CITATION,"Dave Huggins (2022), AmeriFlux BASE US-CF1 CAF-LTAR Cook East, Ver. 3-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1543382" -US-CF1,87133,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-CF1,86616,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-CF1,86616,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Dave Huggins -US-CF1,86616,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-CF1,86616,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,David.Huggins@ars.usda.gov -US-CF1,86616,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,USDA ARS -US-CF1,86627,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,USDA ARS -US-CF1,86627,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-CF1,86626,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,USDA ARS -US-CF1,86626,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-CF1,84802,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Agriculture -US-CF1,84803,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-CF1,84803,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-CF1,84803,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20170511 -US-CF1,84803,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-CF1,84804,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-CF1,84804,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-CF1,84804,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20170511 -US-CF1,84804,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-CF1,23000995,GRP_HEADER,SITE_NAME,CAF-LTAR Cook East -US-CF1,84805,GRP_IGBP,IGBP,CRO -US-CF1,84805,GRP_IGBP,IGBP_COMMENT,"Dryland cropping system, predominantly winter wheat, spring cereals (barley and wheat), and pulse crops (dry pea, lentil and chickpea)" -US-CF1,84806,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-CF1,84806,GRP_LAND_OWNERSHIP,LAND_OWNER,Washington State University -US-CF1,84807,GRP_LOCATION,LOCATION_LAT,46.7815 -US-CF1,84807,GRP_LOCATION,LOCATION_LONG,-117.0821 -US-CF1,84807,GRP_LOCATION,LOCATION_ELEV,794 -US-CF1,84807,GRP_LOCATION,LOCATION_DATE_START,20170511 -US-CF1,84808,GRP_NETWORK,NETWORK,AmeriFlux -US-CF1,96707,GRP_NETWORK,NETWORK,LTAR -US-CF1,86955,GRP_NETWORK,NETWORK,Phenocam -US-CF1,1700008001,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(), 108350" -US-CF1,1700008001,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -US-CF1,1700008001,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-CF1,84809,GRP_SITE_CHAR,TERRAIN,Undulated/Variable -US-CF1,84809,GRP_SITE_CHAR,ASPECT,S -US-CF1,84809,GRP_SITE_CHAR,WIND_DIRECTION,W -US-CF1,84809,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,300 -US-CF1,84810,GRP_SITE_FUNDING,SITE_FUNDING,USDA ARS -US-CF1,84811,GRP_STATE,STATE,WA -US-CF1,98919,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Claire Phillips -US-CF1,98919,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-CF1,98919,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,claire.phillips@usda.gov -US-CF1,98919,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,USDA ARS -US-CF1,96701,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Dave Huggins -US-CF1,96701,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-CF1,96701,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,David.Huggins@usda.gov -US-CF1,96701,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,USDA ARS -US-CF1,87993,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Eric Russell -US-CF1,87993,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-CF1,87993,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,eric.s.russell@wsu.edu -US-CF1,87993,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Washington State University -US-CF1,96706,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Ian Leslie -US-CF1,96706,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,BADMContact -US-CF1,96706,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,ian.leslie@usda.gov -US-CF1,96706,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,USDA ARS NSAR -US-CF1,96673,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Bryan Carlson -US-CF1,96673,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,DataManager -US-CF1,96673,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,bryan.carlson@usda.gov -US-CF1,96673,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,USDA ARS -US-CF1,96742,GRP_TOWER_POWER,TOWER_POWER,Direct power -US-CF1,84817,GRP_TOWER_TYPE,TOWER_TYPE,triangle -US-CF1,84818,GRP_URL,URL,http://www.cafltar.org/ -US-CF1,24000995,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-CF1 -US-CF1,84819,GRP_UTC_OFFSET,UTC_OFFSET,-8 -US-CF1,84819,GRP_UTC_OFFSET,UTC_OFFSET_DATE_START,20170511 -US-CF1,84819,GRP_UTC_OFFSET,UTC_OFFSET_COMMENT,Pacific Standard Time -US-CF2,84820,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,The USDA-ARS supported Cook Agronomy Farm Long-Term Agro-ecosystem Research site provided data for this work. -US-CF2,84821,GRP_CLIM_AVG,MAT,9 -US-CF2,84821,GRP_CLIM_AVG,MAP,550 -US-CF2,84821,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dsb -US-CF2,27000996,GRP_COUNTRY,COUNTRY,USA -US-CF2,87131,GRP_DOI,DOI,10.17190/AMF/1543383 -US-CF2,87131,GRP_DOI,DOI_CITATION,"Dave Huggins (2021), AmeriFlux BASE US-CF2 CAF-LTAR Cook West, Ver. 2-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1543383" -US-CF2,87131,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-CF2,86617,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-CF2,86617,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Dave Huggins -US-CF2,86617,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-CF2,86617,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,David.Huggins@ars.usda.gov -US-CF2,86617,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,USDA ARS -US-CF2,86629,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,USDA ARS -US-CF2,86629,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-CF2,86628,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,USDA ARS -US-CF2,86628,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-CF2,84822,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Agriculture -US-CF2,84824,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-CF2,84824,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-CF2,84824,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20170512 -US-CF2,84824,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-CF2,84823,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-CF2,84823,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-CF2,84823,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20170512 -US-CF2,84823,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-CF2,23000996,GRP_HEADER,SITE_NAME,CAF-LTAR Cook West -US-CF2,84825,GRP_IGBP,IGBP,CRO -US-CF2,84825,GRP_IGBP,IGBP_COMMENT,"Dryland cropping system, predominantly winter wheat, spring cereals (barley and wheat), and pulse crops (dry pea, lentil and chickpea)" -US-CF2,84826,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-CF2,84826,GRP_LAND_OWNERSHIP,LAND_OWNER,Washington State University -US-CF2,84827,GRP_LOCATION,LOCATION_LAT,46.7840 -US-CF2,84827,GRP_LOCATION,LOCATION_LONG,-117.0908 -US-CF2,84827,GRP_LOCATION,LOCATION_ELEV,807 -US-CF2,84827,GRP_LOCATION,LOCATION_DATE_START,20170512 -US-CF2,84828,GRP_NETWORK,NETWORK,AmeriFlux -US-CF2,86956,GRP_NETWORK,NETWORK,Phenocam -US-CF2,1700002778,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(), 108350" -US-CF2,1700002778,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -US-CF2,1700002778,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-CF2,84829,GRP_SITE_CHAR,TERRAIN,Undulated/Variable -US-CF2,84829,GRP_SITE_CHAR,ASPECT,S -US-CF2,84829,GRP_SITE_CHAR,WIND_DIRECTION,W -US-CF2,84829,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,200 -US-CF2,84830,GRP_SITE_FUNDING,SITE_FUNDING,USDA ARS -US-CF2,84831,GRP_STATE,STATE,WA -US-CF2,98911,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Claire Phillips -US-CF2,98911,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-CF2,98911,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,claire.phillips@usda.gov -US-CF2,98911,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,USDA ARS -US-CF2,84834,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Dave Huggins -US-CF2,84834,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-CF2,84834,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,David.Huggins@ars.usda.gov -US-CF2,84834,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,USDA ARS -US-CF2,87995,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Eric Russell -US-CF2,87995,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-CF2,87995,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,eric.s.russell@wsu.edu -US-CF2,87995,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Washington State University -US-CF2,84835,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Ian Leslie -US-CF2,84835,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,BADMContact -US-CF2,84835,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,ian.leslie@ars.usda.gov -US-CF2,84835,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,USDA ARS -US-CF2,84833,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Bryan Carlson -US-CF2,84833,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,DataManager -US-CF2,84833,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,bryan.carlson@ars.usda.gov -US-CF2,84833,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,USDA ARS -US-CF2,84836,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-CF2,84837,GRP_TOWER_TYPE,TOWER_TYPE,triangle -US-CF2,84838,GRP_URL,URL,http://www.cafltar.org/ -US-CF2,24000996,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-CF2 -US-CF2,84839,GRP_UTC_OFFSET,UTC_OFFSET,-8 -US-CF2,84839,GRP_UTC_OFFSET,UTC_OFFSET_DATE_START,20170512 -US-CF2,84839,GRP_UTC_OFFSET,UTC_OFFSET_COMMENT,Pacific Standard Time -US-CF3,84840,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,The USDA-ARS supported Cook Agronomy Farm Long-Term Agro-ecosystem Research site provided data for this work. -US-CF3,84841,GRP_CLIM_AVG,MAT,9 -US-CF3,84841,GRP_CLIM_AVG,MAP,550 -US-CF3,84841,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dsb -US-CF3,27000998,GRP_COUNTRY,COUNTRY,USA -US-CF3,87127,GRP_DOI,DOI,10.17190/AMF/1543385 -US-CF3,87127,GRP_DOI,DOI_CITATION,"Dave Huggins (2022), AmeriFlux BASE US-CF3 CAF-LTAR Boyd North, Ver. 3-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1543385" -US-CF3,87127,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-CF3,86619,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-CF3,86619,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Dave Huggins -US-CF3,86619,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-CF3,86619,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,David.Huggins@ars.usda.gov -US-CF3,86619,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,USDA ARS -US-CF3,86633,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,USDA ARS -US-CF3,86633,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-CF3,86632,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,USDA ARS -US-CF3,86632,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-CF3,84842,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Agriculture -US-CF3,84843,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-CF3,84843,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-CF3,84843,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20170602 -US-CF3,84843,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-CF3,84844,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-CF3,84844,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-CF3,84844,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20170602 -US-CF3,84844,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-CF3,23000998,GRP_HEADER,SITE_NAME,CAF-LTAR Boyd North -US-CF3,84845,GRP_IGBP,IGBP,CRO -US-CF3,84845,GRP_IGBP,IGBP_COMMENT,"Annual dryland cropping system, predominantly winter wheat, spring cereals (barley and wheat), and pulse crops (dry pea, lentil and chickpea)." -US-CF3,84846,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-CF3,84846,GRP_LAND_OWNERSHIP,LAND_OWNER,Washington State University -US-CF3,84847,GRP_LOCATION,LOCATION_LAT,46.7551 -US-CF3,84847,GRP_LOCATION,LOCATION_LONG,-117.1261 -US-CF3,84847,GRP_LOCATION,LOCATION_ELEV,795 -US-CF3,84847,GRP_LOCATION,LOCATION_DATE_START,20170602 -US-CF3,84848,GRP_NETWORK,NETWORK,AmeriFlux -US-CF3,86957,GRP_NETWORK,NETWORK,Phenocam -US-CF3,1700003006,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(), 108350" -US-CF3,1700003006,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -US-CF3,1700003006,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-CF3,84849,GRP_SITE_CHAR,TERRAIN,Undulated/Variable -US-CF3,84849,GRP_SITE_CHAR,ASPECT,S -US-CF3,84849,GRP_SITE_CHAR,WIND_DIRECTION,W -US-CF3,84849,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,350 -US-CF3,84850,GRP_SITE_FUNDING,SITE_FUNDING,USDA ARS -US-CF3,84851,GRP_STATE,STATE,WA -US-CF3,98914,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Claire Phillips -US-CF3,98914,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-CF3,98914,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,claire.phillips@usda.gov -US-CF3,98914,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,USDA ARS -US-CF3,84852,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Dave Huggins -US-CF3,84852,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-CF3,84852,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,David.Huggins@ars.usda.gov -US-CF3,84852,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,USDA ARS -US-CF3,87990,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Eric Russell -US-CF3,87990,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-CF3,87990,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,eric.s.russell@wsu.edu -US-CF3,87990,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Washington State University -US-CF3,84853,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Ian Leslie -US-CF3,84853,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,BADMContact -US-CF3,84853,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,ian.leslie@ars.usda.gov -US-CF3,84853,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,USDA ARS -US-CF3,84855,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Bryan Carlson -US-CF3,84855,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,DataManager -US-CF3,84855,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,bryan.carlson@ars.usda.gov -US-CF3,84855,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,USDA ARS -US-CF3,84856,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-CF3,84857,GRP_TOWER_TYPE,TOWER_TYPE,triangle -US-CF3,84858,GRP_URL,URL,http://www.cafltar.org/ -US-CF3,24000998,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-CF3 -US-CF3,84859,GRP_UTC_OFFSET,UTC_OFFSET,-8 -US-CF3,84859,GRP_UTC_OFFSET,UTC_OFFSET_DATE_START,20170602 -US-CF3,84859,GRP_UTC_OFFSET,UTC_OFFSET_COMMENT,Pacific Standard Time -US-CF4,84860,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,The USDA-ARS supported Cook Agronomy Farm Long-Term Agro-ecosystem Research site provided data for this work. -US-CF4,84861,GRP_CLIM_AVG,MAT,9 -US-CF4,84861,GRP_CLIM_AVG,MAP,550 -US-CF4,84861,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dsb -US-CF4,27000997,GRP_COUNTRY,COUNTRY,USA -US-CF4,87124,GRP_DOI,DOI,10.17190/AMF/1543384 -US-CF4,87124,GRP_DOI,DOI_CITATION,"Dave Huggins (2022), AmeriFlux BASE US-CF4 CAF-LTAR Boyd South, Ver. 3-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1543384" -US-CF4,87124,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-CF4,86618,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-CF4,86618,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Dave Huggins -US-CF4,86618,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-CF4,86618,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,David.Huggins@ars.usda.gov -US-CF4,86618,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,USDA ARS -US-CF4,86631,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,USDA ARS -US-CF4,86631,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-CF4,86630,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,USDA ARS -US-CF4,86630,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-CF4,84862,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Agriculture -US-CF4,84863,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-CF4,84863,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-CF4,84863,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20170602 -US-CF4,84863,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-CF4,84864,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-CF4,84864,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-CF4,84864,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20170602 -US-CF4,84864,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-CF4,23000997,GRP_HEADER,SITE_NAME,CAF-LTAR Boyd South -US-CF4,84865,GRP_IGBP,IGBP,CRO -US-CF4,84865,GRP_IGBP,IGBP_COMMENT,"Dryland cropping system, predominantly winter wheat, spring cereals (barley and wheat), and pulse crops (dry pea, lentil and chickpea)" -US-CF4,84866,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-CF4,84866,GRP_LAND_OWNERSHIP,LAND_OWNER,Washington State University -US-CF4,84867,GRP_LOCATION,LOCATION_LAT,46.7518 -US-CF4,84867,GRP_LOCATION,LOCATION_LONG,-117.1285 -US-CF4,84867,GRP_LOCATION,LOCATION_ELEV,795 -US-CF4,84867,GRP_LOCATION,LOCATION_DATE_START,20170602 -US-CF4,84868,GRP_NETWORK,NETWORK,AmeriFlux -US-CF4,86958,GRP_NETWORK,NETWORK,Phenocam -US-CF4,1700008388,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(), 108350" -US-CF4,1700008388,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -US-CF4,1700008388,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-CF4,84869,GRP_SITE_CHAR,TERRAIN,Undulated/Variable -US-CF4,84869,GRP_SITE_CHAR,ASPECT,S -US-CF4,84869,GRP_SITE_CHAR,WIND_DIRECTION,W -US-CF4,84869,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,175 -US-CF4,84870,GRP_SITE_FUNDING,SITE_FUNDING,USDA ARS -US-CF4,84871,GRP_STATE,STATE,WA -US-CF4,98917,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Claire Phillips -US-CF4,98917,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-CF4,98917,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,claire.phillips@usda.gov -US-CF4,98917,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,USDA ARS -US-CF4,84872,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Dave Huggins -US-CF4,84872,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-CF4,84872,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,David.Huggins@ars.usda.gov -US-CF4,84872,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,USDA ARS -US-CF4,87992,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Eric Russell -US-CF4,87992,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-CF4,87992,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,eric.s.russell@wsu.edu -US-CF4,87992,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Washington State University -US-CF4,84875,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Ian Leslie -US-CF4,84875,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,BADMContact -US-CF4,84875,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,ian.leslie@ars.usda.gov -US-CF4,84875,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,USDA ARS -US-CF4,84874,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Bryan Carlson -US-CF4,84874,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,DataManager -US-CF4,84874,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,bryan.carlson@ars.usda.gov -US-CF4,84874,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,USDA ARS -US-CF4,84876,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-CF4,84877,GRP_TOWER_TYPE,TOWER_TYPE,triangle -US-CF4,84878,GRP_URL,URL,http://www.cafltar.org/ -US-CF4,24000997,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-CF4 -US-CF4,84879,GRP_UTC_OFFSET,UTC_OFFSET,-8 -US-CF4,84879,GRP_UTC_OFFSET,UTC_OFFSET_DATE_START,20170602 -US-CF4,84879,GRP_UTC_OFFSET,UTC_OFFSET_COMMENT,Pacific Standard Time -US-CGG,93017,GRP_CLIM_AVG,MAT,16 -US-CGG,93017,GRP_CLIM_AVG,MAP,419 -US-CGG,93017,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Csa -US-CGG,27001161,GRP_COUNTRY,COUNTRY,USA -US-CGG,93006,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Fire -US-CGG,93000,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Chambers -US-CGG,93000,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-CGG,93000,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201906141700 -US-CGG,93000,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-CGG,93012,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-CGG,93012,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-CGG,93012,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201906141700 -US-CGG,93012,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-CGG,23001161,GRP_HEADER,SITE_NAME,Concord Grazed Grassland -US-CGG,92999,GRP_IGBP,IGBP,GRA -US-CGG,92999,GRP_IGBP,IGBP_COMMENT,"The site is dominated by annual cool season grasses. Additionally From ~July-November Stinkwork, and annual invasive dominates the site." -US-CGG,93015,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-CGG,93015,GRP_LAND_OWNERSHIP,LAND_OWNER,Cal State East Bay -US-CGG,93005,GRP_LOCATION,LOCATION_LAT,37.9380 -US-CGG,93005,GRP_LOCATION,LOCATION_LONG,-121.9761 -US-CGG,93005,GRP_LOCATION,LOCATION_ELEV,119.5 -US-CGG,93005,GRP_LOCATION,LOCATION_DATE_START,201906141700 -US-CGG,93003,GRP_NETWORK,NETWORK,AmeriFlux -US-CGG,93016,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"Processing collected flux data, Instrument QA. In the Fall of 2020 compost will be applied to a portion of the tower's footprint, so that the tower can monitor the longterm effect of compost to a grazed grasslands' GHG and water budgets. Compost will be applied at a rate of 6.35 Mg/acre (wet weight)." -US-CGG,93004,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"25800 Carlos Bee Blvd. Hayward, CA 94542" -US-CGG,93007,GRP_SITE_CHAR,TERRAIN,Valley -US-CGG,93007,GRP_SITE_CHAR,ASPECT,FLAT -US-CGG,93007,GRP_SITE_CHAR,WIND_DIRECTION,SW -US-CGG,93007,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,500 -US-CGG,93007,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,0 -US-CGG,93018,GRP_SITE_DESC,SITE_DESC,"This tower located on a grazed grassland in Concord, CA. The land is owned by Cal State East Bay and leased to a local rancher. Approximately 60 head of cattle graze the site from December to April.The site is dominated by annual cool season grasses. The soil on the site is described as Altamont Clay." -US-CGG,93009,GRP_SITE_FUNDING,SITE_FUNDING,"California Strategic Growth Council/ -Cal State East Bay (CSUEB)" -US-CGG,93010,GRP_STATE,STATE,CA -US-CGG,93011,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Patty Oikawa -US-CGG,93011,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-CGG,93011,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,Patty.oikawa@csueastbay.edu -US-CGG,93011,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"California State University, East Bay" -US-CGG,93011,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"25800 Carlos Bee Blvd. Hayward, CA 94542" -US-CGG,93498,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Tommy Fenster -US-CGG,93498,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Affiliate -US-CGG,93498,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,tfenster@horizon.csueastbay.edu -US-CGG,93498,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"California State University, East Bay and Lawrence Berkeley National Laboratory (affiliated)" -US-CGG,93498,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"25800 Carlos Bee Blvd. Hayward, CA 94542" -US-CGG,93002,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-CGG,93001,GRP_TOWER_TYPE,TOWER_TYPE,walk-up -US-CGG,93008,GRP_URL,URL,https://pattyoikawa.weebly.com/ -US-CGG,24001161,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-CGG -US-CGG,93013,GRP_UTC_OFFSET,UTC_OFFSET,-8 -US-CGG,93013,GRP_UTC_OFFSET,UTC_OFFSET_DATE_START,201906141700 -US-CMW,92805,GRP_CLIM_AVG,MAT,17 -US-CMW,92805,GRP_CLIM_AVG,MAP,288 -US-CMW,92805,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Bsh -US-CMW,27001158,GRP_COUNTRY,COUNTRY,USA -US-CMW,93748,GRP_DOI,DOI,10.17190/AMF/1660339 -US-CMW,93748,GRP_DOI,DOI_CITATION,"Russell Scott (2022), AmeriFlux BASE US-CMW Charleston Mesquite Woodland, Ver. 2-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1660339" -US-CMW,93748,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-CMW,93715,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-CMW,93715,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Russell Scott -US-CMW,93715,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-CMW,93715,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,russ.scott@ars.usda.gov -US-CMW,93715,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,USDA-ARS -US-CMW,93741,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,USDA-ARS -US-CMW,93741,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-CMW,93725,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,"USDA, NSF" -US-CMW,93725,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-CMW,92814,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-CMW,92814,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-CMW,92814,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,200101010030 -US-CMW,92814,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-CMW,92814,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,For eddy covariance measurements only March through December measurements for 2001 and 2002. Continuous operations beginning in 2003. -US-CMW,92807,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-CMW,92807,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-CMW,92807,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,200101010030 -US-CMW,92807,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-CMW,23001158,GRP_HEADER,SITE_NAME,Charleston Mesquite Woodland -US-CMW,92806,GRP_IGBP,IGBP,DBF -US-CMW,92806,GRP_IGBP,IGBP_COMMENT,Site is a mesquite woodland with tall 7-10 m velvet mesquite that lose their leaves annually -US-CMW,92813,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-CMW,92813,GRP_LAND_OWNERSHIP,LAND_OWNER,Bureau of Land Management -US-CMW,92811,GRP_LOCATION,LOCATION_LAT,31.6637 -US-CMW,92811,GRP_LOCATION,LOCATION_LONG,-110.1777 -US-CMW,92811,GRP_LOCATION,LOCATION_ELEV,1199 -US-CMW,92803,GRP_NETWORK,NETWORK,AmeriFlux -US-CMW,1700005178,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Scott, R. L., Edwards, E. A., Shuttleworth, W., Huxman, T. E., Watts, C., Goodrich, D. C. (2004) Interannual And Seasonal Variation In Fluxes Of Water And Carbon Dioxide From A Riparian Woodland Ecosystem, Agricultural And Forest Meteorology, 122(1-2), 65-84" -US-CMW,1700005178,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2003.09.001 -US-CMW,1700005178,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-CMW,1700005610,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Scott, R. L., Huxman, T. E., Barron-Gafford, G. A., Darrel Jenerette, G., Young, J. M., Hamerlynck, E. P. (2014) When Vegetation Change Alters Ecosystem Water Availability, Global Change Biology, 20(7), 2198-2210" -US-CMW,1700005610,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/GCB.12511 -US-CMW,1700005610,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Primary_Citation -US-CMW,1700005796,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Scott, R. L., Huxman, T. E., Barron-Gafford, G. A., Darrel Jenerette, G., Young, J. M., Hamerlynck, E. P. (2014) When Vegetation Change Alters Ecosystem Water Availability, Global Change Biology, 20(7), 2198-2210" -US-CMW,1700005796,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/GCB.12511 -US-CMW,1700005796,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-CMW,1700006150,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"SCOTT, R. L., HUXMAN, T. E., WILLIAMS, D. G., GOODRICH, D. C. (2006) Ecohydrological Impacts Of Woody-Plant Encroachment: Seasonal Patterns Of Water And Carbon Dioxide Exchange Within A Semiarid Riparian Environment, Global Change Biology, 12(2), 311-324" -US-CMW,1700006150,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/J.1365-2486.2005.01093.X -US-CMW,1700006150,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-CMW,1700000219,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Scott, R., Cable, W., Huxman, T., Nagler, P., Hernandez, M., Goodrich, D. (2008) Multiyear Riparian Evapotranspiration And Groundwater Use For A Semiarid Watershed, Journal Of Arid Environments, 72(7), 1232-1246" -US-CMW,1700000219,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.JARIDENV.2008.01.001 -US-CMW,1700000219,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-CMW,1700005496,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Yepez, E. A., Scott, R. L., Cable, W. L., Williams, D. G. (2007) Intraseasonal Variation In Water And Carbon Dioxide Flux Components In A Semiarid Riparian Woodland, Ecosystems, 10(7), 1100-1115" -US-CMW,1700005496,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1007/S10021-007-9079-Y -US-CMW,1700005496,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-CMW,92804,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"riparian vegetation water use and carbon uptake, groundwater dependent ecosystem functioning, evapotranspiration partitioning, hydraulic redistribution" -US-CMW,92819,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"2000 E. Allen Rd. Tucson, AZ USA 85719" -US-CMW,92812,GRP_SITE_CHAR,TERRAIN,Valley -US-CMW,92812,GRP_SITE_CHAR,ASPECT,FLAT -US-CMW,92812,GRP_SITE_CHAR,WIND_DIRECTION,SSE -US-CMW,92812,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,200 -US-CMW,92812,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,0 -US-CMW,92818,GRP_SITE_DESC,SITE_DESC,Site is a riparian mesquite woodland located along an old alluvial terrace along the banks of the San Pedro River in southeastern Arizona. Site climate is semiarid with monsoonal (Jul-Sep) rainfall. The mesquite trees access groundwater from an alluvial aquifer recharged elsewhere. Site water balance is not closed and ET greatly exceeds precipitation. The understory grasses and forbs are rainfall dependent. This groundwater-dependent ecosystem is far more ebulliant and productive than the upland vegetation around it (shrublands and grasslands). -US-CMW,92815,GRP_SITE_FUNDING,SITE_FUNDING,"USDA, NSF" -US-CMW,92809,GRP_STATE,STATE,AZ -US-CMW,92810,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Russell Scott -US-CMW,92810,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-CMW,92810,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,russ.scott@ars.usda.gov -US-CMW,92810,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,USDA-ARS -US-CMW,96261,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Ross Bryant -US-CMW,96261,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Technician -US-CMW,96261,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,ross.bryant@usda.gov -US-CMW,96261,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,USDA -US-CMW,96261,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"ARS-SWRC -2000 East Allen Rd -Tucson, AZ 85719" -US-CMW,92808,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-CMW,92817,GRP_TOWER_TYPE,TOWER_TYPE,walk-up -US-CMW,24001158,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-CMW -US-CMW,92816,GRP_UTC_OFFSET,UTC_OFFSET,-7 -US-CMW,92816,GRP_UTC_OFFSET,UTC_OFFSET_DATE_START,200103210000 -US-CMW,92816,GRP_UTC_OFFSET,UTC_OFFSET_COMMENT,AZ has no daylight saving time. We are always -7 UTC -US-Cop,27000494,GRP_COUNTRY,COUNTRY,USA -US-Cop,15663,GRP_DOI,DOI,10.17190/AMF/1246129 -US-Cop,15663,GRP_DOI,DOI_CITATION,"David Bowling (2019), AmeriFlux BASE US-Cop Corral Pocket, Ver. 2-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1246129" -US-Cop,15663,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-Cop,32283,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Cop,32283,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,David Bowling -US-Cop,32283,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Cop,32283,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,david.bowling@utah.edu -US-Cop,32283,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of Utah -US-Cop,32285,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,University of Utah -US-Cop,32285,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-Cop,32284,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,University of Utah and USGS -US-Cop,32284,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-Cop,2399,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Cop,2399,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-Cop,2399,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,2001 -US-Cop,2399,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,2007 -US-Cop,2399,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Cop,23000494,GRP_HEADER,SITE_NAME,Corral Pocket -US-Cop,88368,GRP_HEIGHTC,HEIGHTC,0.5 -US-Cop,88368,GRP_HEIGHTC,HEIGHTC_STATISTIC,Expert estimate -US-Cop,88368,GRP_HEIGHTC,HEIGHTC_DATE,2003 -US-Cop,7579,GRP_IGBP,IGBP,GRA -US-Cop,5746,GRP_LOCATION,LOCATION_LAT,38.0900 -US-Cop,5746,GRP_LOCATION,LOCATION_LONG,-109.3900 -US-Cop,5746,GRP_LOCATION,LOCATION_ELEV,1520 -US-Cop,5746,GRP_LOCATION,LOCATION_COMMENT,From CDIAC Tom Boden database dump -US-Cop,630,GRP_NETWORK,NETWORK,AmeriFlux -US-Cop,1700005775,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(8), 108350" -US-Cop,1700005775,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -US-Cop,1700005775,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Cop,1700005049,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Sullivan, R. C., Cook, D. R., Ghate, V. P., Kotamarthi, V. R., Feng, Y. (2019) Improved Spatiotemporal Representativeness And Bias Reduction Of Satellite-Based Evapotranspiration Retrievals Via Use Of In Situ Meteorology And Constrained Canopy Surface Resistance, Journal Of Geophysical Research: Biogeosciences, 124(2), 342-352" -US-Cop,1700005049,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018JG004744 -US-Cop,1700005049,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Cop,1700006255,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Sullivan, R. C., Kotamarthi, V. R., Feng, Y. (2019) Recovering Evapotranspiration Trends From Biased CMIP5 Simulations And Sensitivity To Changing Climate Over North America, Journal Of Hydrometeorology, 20(8), 1619-1633" -US-Cop,1700006255,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1175/JHM-D-18-0259.1 -US-Cop,1700006255,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Cop,6726,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"The research and science objectives of the Corral Pocket site are as follows: 1) Investigate the response of carbon, water, and energy fluxes in a semi-arid cold desert to multi-year drought conditions; 2) Quantify the sensitivity of the Colorado Plateau to climate change; 3) Investigate the impacts and land use of on the southwestern United States." -US-Cop,758,GRP_SITE_DESC,SITE_DESC,"The Corral Pocket site is located in a semi-arid grassland in southeastern Utah, just east of Canyonlands National park. For the greater part of the year, 38-80% of the ground is essentially bare. Vegetation is primarily native perennial C3/C4 grasses with annual ground converge ranging from 8-35%. Leaving the remaining 0-15% coverage to interspersed annual grasses, the remaining 0-15% coverage is occupied by annual grasses. 6-8 weeks during the late fall or winter, Livestock grazing is responsible for the majority of aboveground vegetation loss and subsequent high variability of ground coverage." -US-Cop,7552,GRP_SITE_FUNDING,SITE_FUNDING,University of Utah and USGS -US-Cop,28094,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION,"Young, alkaline, well-drained fine sandy loams with weak or little horizonation" -US-Cop,28094,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION_TAXONOMY,Other -US-Cop,4916,GRP_STATE,STATE,UT -US-Cop,3240,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,David Bowling -US-Cop,3240,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Cop,3240,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,david.bowling@utah.edu -US-Cop,3240,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Utah -US-Cop,3240,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Department of Biology, 257 S. 1400 E.,Salt Lake City, UT USA 84112-0840" -US-Cop,7570,GRP_URL,URL,http://esp.cr.usgs.gov/info/sw/clim-met/corral.html -US-Cop,24000494,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-Cop -US-Cop,33623,GRP_UTC_OFFSET,UTC_OFFSET,-7 -US-Cop,33623,GRP_UTC_OFFSET,UTC_OFFSET_COMMENT,Added by AMF data processing team for data QAQC checks. -US-CPk,10211,GRP_CLIM_AVG,MAT,6.1 -US-CPk,10211,GRP_CLIM_AVG,MAP,545 -US-CPk,10211,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfc -US-CPk,27000521,GRP_COUNTRY,COUNTRY,USA -US-CPk,15664,GRP_DOI,DOI,10.17190/AMF/1246150 -US-CPk,15664,GRP_DOI,DOI_CITATION,"Brent Ewers, Mario Bretfeld, Elise Pendall (2016), AmeriFlux BASE US-CPk Chimney Park, Ver. 2-1, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1246150" -US-CPk,15664,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-CPk,92275,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-CPk,92275,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Brent Ewers -US-CPk,92275,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-CPk,92275,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,1 -US-CPk,92275,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,BEEwers@uwyo.edu -US-CPk,92275,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of Wyoming -US-CPk,92267,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-CPk,92267,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Mario Bretfeld -US-CPk,92267,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-CPk,92267,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,2 -US-CPk,92267,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0002-3875-9042 -US-CPk,92267,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,mbretfel@kennesaw.edu -US-CPk,92267,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Kennesaw State University -US-CPk,92267,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,20180601 -US-CPk,32379,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-CPk,32379,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Elise Pendall -US-CPk,32379,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-CPk,32379,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,e.pendall@westernsydney.edu.au -US-CPk,32379,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of Wyoming -US-CPk,32382,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,University of Wyoming -US-CPk,32382,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-CPk,32381,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,"NSF Hydrologic Science, UW Ag Experiment Station, McIntire-Stennis, Wyoming water development commission, USGS" -US-CPk,32381,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-CPk,10212,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-CPk,10212,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-CPk,10212,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,2009 -US-CPk,10212,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-CPk,10225,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-CPk,10225,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-CPk,10225,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,2009 -US-CPk,10225,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-CPk,23000521,GRP_HEADER,SITE_NAME,Chimney Park -US-CPk,10213,GRP_IGBP,IGBP,ENF -US-CPk,10213,GRP_IGBP,IGBP_DATE_START,20090101 -US-CPk,10213,GRP_IGBP,IGBP_COMMENT,Tree mortality from Bark Beetles is high at the site (45-80% depending on year) -US-CPk,10214,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-CPk,10214,GRP_LAND_OWNERSHIP,LAND_OWNER,USFS -US-CPk,10215,GRP_LOCATION,LOCATION_LAT,41.0680 -US-CPk,10215,GRP_LOCATION,LOCATION_LONG,-106.1187 -US-CPk,10215,GRP_LOCATION,LOCATION_ELEV,2750 -US-CPk,10215,GRP_LOCATION,LOCATION_DATE_START,20090101 -US-CPk,10216,GRP_NETWORK,NETWORK,AmeriFlux -US-CPk,1700002154,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Baldocchi, D. D., Poindexter, C., Abraha, M., Desai, A. R., Bohrer, G., Arain, M. A., Griffis, T., Blanken, P. D., O'Halloran, T. L., Thomas, R. Q., Zhang, Q., Burns, S. P., Frank, J. M., Christian, D., Brown, S., Black, T. A., Gough, C. M., Law, B. E., Lee, X., Chen, J., Reed, D. E., Massman, W. J., Clark, K., Hatfield, J., Prueger, J., Bracho, R., Baker, J. M., Martin, T. A. (2018) Temporal Dynamics Of Aerodynamic Canopy Height Derived From Eddy Covariance Momentum Flux Data Across North American Flux Networks, Geophysical Research Letters, 45(1-2), 9275–9287" -US-CPk,1700002154,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018GL079306 -US-CPk,1700002154,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-CPk,1700006123,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(1-2), 108350" -US-CPk,1700006123,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -US-CPk,1700006123,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-CPk,1700001209,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"E Reed, D., Ewers, B. E., Pendall, E. (2014) Impact Of Mountain Pine Beetle Induced Mortality On Forest Carbon And Water Fluxes, Environmental Research Letters, 9(10), 105004" -US-CPk,1700001209,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1088/1748-9326/9/10/105004 -US-CPk,1700001209,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-CPk,1700008355,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Reed, D. E., Ewers, B. E., Pendall, E., Frank, J., Kelly, R. (2018) Bark Beetle-Induced Tree Mortality Alters Stand Energy Budgets Due To Water Budget Changes, Theoretical And Applied Climatology, 131(1-2), 153-165" -US-CPk,1700008355,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1007/S00704-016-1965-9 -US-CPk,1700008355,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-CPk,86477,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"Ecosystem Effects of Mountain Pine Bark Beetle. -Interactive Effects of Fire following Bark Beetle Mortality." -US-CPk,10218,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"1000 E. University Avenue -University of Wyoming -Laramie, WY 82071 USA" -US-CPk,10219,GRP_SITE_CHAR,TERRAIN,Gentle slope (<2 %) -US-CPk,10219,GRP_SITE_CHAR,ASPECT,W -US-CPk,10219,GRP_SITE_CHAR,WIND_DIRECTION,W -US-CPk,10219,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,875 -US-CPk,10219,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,180 -US-CPk,86478,GRP_SITE_DESC,SITE_DESC,"High elevation, primarily lodge-pole pine forest with high amounts of Mountain Pine Bark Beetle mortality. Site burned in June/July 2018, characterized by a highly heterogeneous fire behavior that resulted in unburned, understory-only, as well as severely-burned patches within meters of the tower structure." -US-CPk,86479,GRP_SITE_FUNDING,SITE_FUNDING,"NSF Hydrologic Science, NSF Ecosystems, UW Ag Experiment Station, McIntire-Stennis, Wyoming water development commission, USGS" -US-CPk,10222,GRP_STATE,STATE,WY -US-CPk,10223,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Brent Ewers -US-CPk,10223,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-CPk,10223,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,BEEwers@uwyo.edu -US-CPk,10223,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Wyoming -US-CPk,85171,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Mario Bretfeld -US-CPk,85171,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-CPk,85171,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,mbretfel@uwyo.edu -US-CPk,85171,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Wyoming -US-CPk,10227,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,David Reed -US-CPk,10227,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-CPk,10227,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,david.edwin.reed@gmail.com -US-CPk,10227,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Wyoming -US-CPk,24000521,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-CPk -US-CPk,10224,GRP_UTC_OFFSET,UTC_OFFSET,-7 -US-CPk,10224,GRP_UTC_OFFSET,UTC_OFFSET_DATE_START,20090101 -US-CRT,12764,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,Supported by NOAA (NA10OAR4170224) & NSF (NSF1034791) -US-CRT,12764,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT_COMMENT,Acknowledgement Walter Berger for fully support -US-CRT,12765,GRP_CLIM_AVG,MAT,10.1 -US-CRT,12765,GRP_CLIM_AVG,MAP,849 -US-CRT,12765,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfa -US-CRT,27000537,GRP_COUNTRY,COUNTRY,USA -US-CRT,15683,GRP_DOI,DOI,10.17190/AMF/1246156 -US-CRT,15683,GRP_DOI,DOI_CITATION,"Jiquan Chen, Housen Chu (2021), AmeriFlux BASE US-CRT Curtice Walter-Berger cropland, Ver. 5-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1246156" -US-CRT,15683,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-CRT,88075,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-CRT,88075,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Jiquan Chen -US-CRT,88075,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-CRT,88075,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,1 -US-CRT,88075,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,jqchen@msu.edu -US-CRT,88075,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of Toledo / Michigan State University -US-CRT,88074,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-CRT,88074,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Housen Chu -US-CRT,88074,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-CRT,88074,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,2 -US-CRT,88074,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0002-8131-4938 -US-CRT,88074,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,chu.housen@gmail.com -US-CRT,88074,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Lawrence Berkeley Lab -US-CRT,32409,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,University of Toledo / Michigan State University -US-CRT,32409,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-CRT,32408,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,NOAA & NSF -US-CRT,32408,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-CRT,12766,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Agriculture -US-CRT,12785,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Storm or wind -US-CRT,12781,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Temperature extreme -US-CRT,12767,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-CRT,12767,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-CRT,12767,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20110101 -US-CRT,12767,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20131231 -US-CRT,12767,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-CRT,12786,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-CRT,12786,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-CRT,12786,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20110101 -US-CRT,12786,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20131231 -US-CRT,12786,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-CRT,12782,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-CRT,12782,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-CRT,12782,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20110101 -US-CRT,12782,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20131231 -US-CRT,12782,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-CRT,12787,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-CRT,12787,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CH4 -US-CRT,12787,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20110511 -US-CRT,12787,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20120520 -US-CRT,12787,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-CRT,23000537,GRP_HEADER,SITE_NAME,Curtice Walter-Berger cropland -US-CRT,88232,GRP_HEIGHTC,HEIGHTC,0 -US-CRT,88232,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-CRT,88232,GRP_HEIGHTC,HEIGHTC_DATE,20110611 -US-CRT,88222,GRP_HEIGHTC,HEIGHTC,0.075 -US-CRT,88222,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-CRT,88222,GRP_HEIGHTC,HEIGHTC_DATE,20110617 -US-CRT,88207,GRP_HEIGHTC,HEIGHTC,0.15 -US-CRT,88207,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-CRT,88207,GRP_HEIGHTC,HEIGHTC_DATE,20110705 -US-CRT,88212,GRP_HEIGHTC,HEIGHTC,0.45 -US-CRT,88212,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-CRT,88212,GRP_HEIGHTC,HEIGHTC_DATE,20110726 -US-CRT,88218,GRP_HEIGHTC,HEIGHTC,0.675 -US-CRT,88218,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-CRT,88218,GRP_HEIGHTC,HEIGHTC_DATE,20110810 -US-CRT,88213,GRP_HEIGHTC,HEIGHTC,0.975 -US-CRT,88213,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-CRT,88213,GRP_HEIGHTC,HEIGHTC_DATE,20110819 -US-CRT,88227,GRP_HEIGHTC,HEIGHTC,1.125 -US-CRT,88227,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-CRT,88227,GRP_HEIGHTC,HEIGHTC_DATE,20111007 -US-CRT,88209,GRP_HEIGHTC,HEIGHTC,0 -US-CRT,88209,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-CRT,88209,GRP_HEIGHTC,HEIGHTC_DATE,20111024 -US-CRT,88214,GRP_HEIGHTC,HEIGHTC,0 -US-CRT,88214,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-CRT,88214,GRP_HEIGHTC,HEIGHTC_DATE,20120520 -US-CRT,88225,GRP_HEIGHTC,HEIGHTC,0.225 -US-CRT,88225,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-CRT,88225,GRP_HEIGHTC,HEIGHTC_DATE,20120612 -US-CRT,88204,GRP_HEIGHTC,HEIGHTC,0.375 -US-CRT,88204,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-CRT,88204,GRP_HEIGHTC,HEIGHTC_DATE,20120627 -US-CRT,88230,GRP_HEIGHTC,HEIGHTC,0.525 -US-CRT,88230,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-CRT,88230,GRP_HEIGHTC,HEIGHTC_DATE,20120720 -US-CRT,88215,GRP_HEIGHTC,HEIGHTC,0.975 -US-CRT,88215,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-CRT,88215,GRP_HEIGHTC,HEIGHTC_DATE,20120820 -US-CRT,88220,GRP_HEIGHTC,HEIGHTC,1.125 -US-CRT,88220,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-CRT,88220,GRP_HEIGHTC,HEIGHTC_DATE,20120912 -US-CRT,88203,GRP_HEIGHTC,HEIGHTC,1.125 -US-CRT,88203,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-CRT,88203,GRP_HEIGHTC,HEIGHTC_DATE,20120928 -US-CRT,88208,GRP_HEIGHTC,HEIGHTC,0 -US-CRT,88208,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-CRT,88208,GRP_HEIGHTC,HEIGHTC_DATE,20121001 -US-CRT,88205,GRP_HEIGHTC,HEIGHTC,0 -US-CRT,88205,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-CRT,88205,GRP_HEIGHTC,HEIGHTC_DATE,20121002 -US-CRT,88233,GRP_HEIGHTC,HEIGHTC,0.06 -US-CRT,88233,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-CRT,88233,GRP_HEIGHTC,HEIGHTC_DATE,20121022 -US-CRT,88202,GRP_HEIGHTC,HEIGHTC,0.12 -US-CRT,88202,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-CRT,88202,GRP_HEIGHTC,HEIGHTC_DATE,20121121 -US-CRT,88216,GRP_HEIGHTC,HEIGHTC,0.18 -US-CRT,88216,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-CRT,88216,GRP_HEIGHTC,HEIGHTC_DATE,20121214 -US-CRT,88217,GRP_HEIGHTC,HEIGHTC,0.18 -US-CRT,88217,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-CRT,88217,GRP_HEIGHTC,HEIGHTC_DATE,20130104 -US-CRT,88231,GRP_HEIGHTC,HEIGHTC,0.18 -US-CRT,88231,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-CRT,88231,GRP_HEIGHTC,HEIGHTC_DATE,20130124 -US-CRT,88223,GRP_HEIGHTC,HEIGHTC,0.18 -US-CRT,88223,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-CRT,88223,GRP_HEIGHTC,HEIGHTC_DATE,20130212 -US-CRT,88224,GRP_HEIGHTC,HEIGHTC,0.18 -US-CRT,88224,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-CRT,88224,GRP_HEIGHTC,HEIGHTC_DATE,20130319 -US-CRT,88221,GRP_HEIGHTC,HEIGHTC,0.3 -US-CRT,88221,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-CRT,88221,GRP_HEIGHTC,HEIGHTC_DATE,20130422 -US-CRT,88206,GRP_HEIGHTC,HEIGHTC,0.52 -US-CRT,88206,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-CRT,88206,GRP_HEIGHTC,HEIGHTC_DATE,20130515 -US-CRT,88219,GRP_HEIGHTC,HEIGHTC,0.72 -US-CRT,88219,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-CRT,88219,GRP_HEIGHTC,HEIGHTC_DATE,20130605 -US-CRT,88226,GRP_HEIGHTC,HEIGHTC,1 -US-CRT,88226,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-CRT,88226,GRP_HEIGHTC,HEIGHTC_DATE,20130620 -US-CRT,88210,GRP_HEIGHTC,HEIGHTC,1.14 -US-CRT,88210,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-CRT,88210,GRP_HEIGHTC,HEIGHTC_DATE,20130703 -US-CRT,88211,GRP_HEIGHTC,HEIGHTC,0.35 -US-CRT,88211,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-CRT,88211,GRP_HEIGHTC,HEIGHTC_DATE,20130716 -US-CRT,88229,GRP_HEIGHTC,HEIGHTC,0.35 -US-CRT,88229,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-CRT,88229,GRP_HEIGHTC,HEIGHTC_DATE,20130725 -US-CRT,88228,GRP_HEIGHTC,HEIGHTC,0.3 -US-CRT,88228,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-CRT,88228,GRP_HEIGHTC,HEIGHTC_DATE,20130816 -US-CRT,12768,GRP_IGBP,IGBP,CRO -US-CRT,12769,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -US-CRT,12769,GRP_LAND_OWNERSHIP,LAND_OWNER,Walter Berger -US-CRT,12770,GRP_LOCATION,LOCATION_LAT,41.6285 -US-CRT,12770,GRP_LOCATION,LOCATION_LONG,-83.3471 -US-CRT,12770,GRP_LOCATION,LOCATION_ELEV,180 -US-CRT,12770,GRP_LOCATION,LOCATION_DATE_START,20100920 -US-CRT,12770,GRP_LOCATION,LOCATION_COMMENT,"The tower was constructed in August and continuous measurement began in September, 2010." -US-CRT,12771,GRP_NETWORK,NETWORK,AmeriFlux -US-CRT,86960,GRP_NETWORK,NETWORK,Phenocam -US-CRT,1700002640,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Baldocchi, D. D., Poindexter, C., Abraha, M., Desai, A. R., Bohrer, G., Arain, M. A., Griffis, T., Blanken, P. D., O'Halloran, T. L., Thomas, R. Q., Zhang, Q., Burns, S. P., Frank, J. M., Christian, D., Brown, S., Black, T. A., Gough, C. M., Law, B. E., Lee, X., Chen, J., Reed, D. E., Massman, W. J., Clark, K., Hatfield, J., Prueger, J., Bracho, R., Baker, J. M., Martin, T. A. (2018) Temporal Dynamics Of Aerodynamic Canopy Height Derived From Eddy Covariance Momentum Flux Data Across North American Flux Networks, Geophysical Research Letters, 45(5), 9275–9287" -US-CRT,1700002640,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018GL079306 -US-CRT,1700002640,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-CRT,1700006192,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Chen, J., Gottgens, J. F., Desai, A. R., Ouyang, Z., Qian, S. S. (2016) Response And Biophysical Regulation Of Carbon Dioxide Fluxes To Climate Variability And Anomaly In Contrasting Ecosystems In Northwestern Ohio, Usa, Agricultural And Forest Meteorology, 220(5), 50-68" -US-CRT,1700006192,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2016.01.008 -US-CRT,1700006192,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-CRT,1700005154,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Chen, J., Gottgens, J. F., Ouyang, Z., John, R., Czajkowski, K., Becker, R. (2014) Net Ecosystem Methane And Carbon Dioxide Exchanges In A Lake Erie Coastal Marsh And A Nearby Cropland, Journal Of Geophysical Research: Biogeosciences, 119(5), 722-740" -US-CRT,1700005154,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/2013JG002520 -US-CRT,1700005154,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Primary_Citation -US-CRT,1700004503,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(5), 108350" -US-CRT,1700004503,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -US-CRT,1700004503,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-CRT,1700000582,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Lu, Y., Williams, I. N., Bagley, J. E., Torn, M. S., Kueppers, L. M. (2017) Representing Winter Wheat In The Community Land Model (Version 4.5), Geoscientific Model Development, 10(5), 1873-1888" -US-CRT,1700000582,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.5194/GMD-10-1873-2017 -US-CRT,1700000582,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-CRT,12783,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"202 Manly Miles Bldg. 1405 South Harrison Road Michigan State University, East Lansing, MI 48823" -US-CRT,12773,GRP_SITE_CHAR,TERRAIN,Flat -US-CRT,12773,GRP_SITE_CHAR,ASPECT,FLAT -US-CRT,12773,GRP_SITE_CHAR,WIND_DIRECTION,WNW -US-CRT,12773,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,300 -US-CRT,12773,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,60 -US-CRT,12774,GRP_SITE_DESC,SITE_DESC,"The conventional cropland site is rain fed and no irrigation is applied. As it is located in a part of the historic Great Black Swamp, drainage tiles are deployed around 0.5–1.0 m beneath the ground surface in order to draw down the water level. The soil is classified as silty clay and silty clay loam. The cultivation practices include minimum tillage and both insect and weed control.  During the study period, the cropland was planted with soybean and winter wheat." -US-CRT,12775,GRP_SITE_FUNDING,SITE_FUNDING,NOAA & NSF -US-CRT,12776,GRP_STATE,STATE,OH -US-CRT,12784,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Jiquan Chen -US-CRT,12784,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-CRT,12784,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,jqchen@msu.edu -US-CRT,12784,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Toledo / Michigan State University -US-CRT,12784,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"202 Manly Miles Bldg. 1405 South Harrison Road Michigan State University, East Lansing, MI 48823" -US-CRT,95536,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Housen Chu -US-CRT,95536,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-CRT,95536,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,chu.housen@gmail.com -US-CRT,95536,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Lawrence Berkeley National Lab -US-CRT,29871,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-CRT,12778,GRP_TOWER_TYPE,TOWER_TYPE,triangle -US-CRT,12779,GRP_URL,URL,http://lees.geo.msu.edu/index.html -US-CRT,24000537,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-CRT -US-CRT,12780,GRP_UTC_OFFSET,UTC_OFFSET,-5 -US-CS1,83394,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,This work was funded by an award to UW-Madison from WPVGA and the Wisconsin DNR -US-CS1,83379,GRP_CLIM_AVG,MAT,7 -US-CS1,83379,GRP_CLIM_AVG,MAP,830 -US-CS1,83379,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfa -US-CS1,27000979,GRP_COUNTRY,COUNTRY,USA -US-CS1,91694,GRP_DOI,DOI,10.17190/AMF/1617710 -US-CS1,91694,GRP_DOI,DOI_CITATION,"Ankur Desai (2021), AmeriFlux BASE US-CS1 Central Sands Irrigated Agricultural Field, Ver. 2-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1617710" -US-CS1,91694,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-CS1,91552,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-CS1,91552,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Ankur Desai -US-CS1,91552,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-CS1,91552,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,desai@aos.wisc.edu -US-CS1,91552,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of Wisconsin-Madison -US-CS1,91670,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,University of Wisconsin-Madison -US-CS1,91670,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-CS1,91630,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,"Wisconsin Potato and Vegetable Growers Association, Wisconsin Department of Natural Resources" -US-CS1,91630,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-CS1,83392,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Agriculture -US-CS1,91379,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-CS1,91379,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-CS1,91379,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20180629 -US-CS1,91379,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20190529 -US-CS1,91379,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-CS1,91429,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-CS1,91429,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-CS1,91429,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20180629 -US-CS1,91429,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20190529 -US-CS1,91429,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-CS1,91385,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-CS1,91385,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-CS1,91385,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20180629 -US-CS1,91385,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20190529 -US-CS1,91385,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-CS1,23000979,GRP_HEADER,SITE_NAME,Central Sands Irrigated Agricultural Field -US-CS1,83396,GRP_IGBP,IGBP,CRO -US-CS1,83396,GRP_IGBP,IGBP_COMMENT,"2018 is Potatoes, 3-yr rotation" -US-CS1,83386,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -US-CS1,83386,GRP_LAND_OWNERSHIP,LAND_OWNER,Heartland Farms -US-CS1,83383,GRP_LOCATION,LOCATION_LAT,44.1031 -US-CS1,83383,GRP_LOCATION,LOCATION_LONG,-89.5379 -US-CS1,83383,GRP_LOCATION,LOCATION_ELEV,328 -US-CS1,83383,GRP_LOCATION,LOCATION_DATE_START,201806291800 -US-CS1,83383,GRP_LOCATION,LOCATION_COMMENT,Approximation based on Google maps. GPS coords forthcoming -US-CS1,83397,GRP_NETWORK,NETWORK,AmeriFlux -US-CS1,83388,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"Evapotranspiration, irrigation, groundwater recharge" -US-CS1,83378,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"1225 W Dayton St, Madison, WI 53706 USA" -US-CS1,83389,GRP_SITE_CHAR,TERRAIN,Flat -US-CS1,83389,GRP_SITE_CHAR,ASPECT,FLAT -US-CS1,83389,GRP_SITE_CHAR,WIND_DIRECTION,W -US-CS1,83389,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,300 -US-CS1,83385,GRP_SITE_DESC,SITE_DESC,Heartland Farms Center-Pivot Irrigated Potato Field -US-CS1,83382,GRP_SITE_FUNDING,SITE_FUNDING,"Wisconsin Potato and Vegetable Growers Association, Wisconsin Department of Natural Resources" -US-CS1,83399,GRP_STATE,STATE,WI -US-CS1,83391,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Ankur Desai -US-CS1,83391,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-CS1,83391,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,desai@aos.wisc.edu -US-CS1,83391,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Wisconsin-Madison -US-CS1,83384,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Jonathan Thom -US-CS1,83384,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-CS1,83384,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,jonathan.thom@ssec.wisc.edu -US-CS1,83384,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Wisconsin-Madison -US-CS1,83393,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-CS1,83380,GRP_TOWER_TYPE,TOWER_TYPE,triangle -US-CS1,83398,GRP_URL,URL,http://flux.aos.wisc.edu/twiki/bin/view/Main/ChEASData -US-CS1,24000979,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-CS1 -US-CS1,89940,GRP_UTC_OFFSET,UTC_OFFSET,-6 -US-CS2,87369,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,This work was funded by an award to UW-Madison from WPVGA and the Wisconsin DNR -US-CS2,87373,GRP_CLIM_AVG,MAT,7 -US-CS2,87373,GRP_CLIM_AVG,MAP,830 -US-CS2,87373,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfa -US-CS2,27001084,GRP_COUNTRY,COUNTRY,USA -US-CS2,91693,GRP_DOI,DOI,10.17190/AMF/1617711 -US-CS2,91693,GRP_DOI,DOI_CITATION,"Ankur Desai (2022), AmeriFlux BASE US-CS2 Tri county school Pine Forest, Ver. 4-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1617711" -US-CS2,91693,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-CS2,91596,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-CS2,91596,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Ankur Desai -US-CS2,91596,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-CS2,91596,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,desai@aos.wisc.edu -US-CS2,91596,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of Wisconsin-Madison -US-CS2,91650,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,University of Wisconsin-Madison -US-CS2,91650,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-CS2,91633,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Wisconsin Department of Natural Resources -US-CS2,91633,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-CS2,87363,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-CS2,87363,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-CS2,87363,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20181013 -US-CS2,87363,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-CS2,87356,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-CS2,87356,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-CS2,87356,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20181013 -US-CS2,87356,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-CS2,87353,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-CS2,87353,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-CS2,87353,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20181013 -US-CS2,87353,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-CS2,23001084,GRP_HEADER,SITE_NAME,Tri county school Pine Forest -US-CS2,87361,GRP_IGBP,IGBP,ENF -US-CS2,87361,GRP_IGBP,IGBP_COMMENT,"Red Pine, White Pine" -US-CS2,87358,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -US-CS2,87358,GRP_LAND_OWNERSHIP,LAND_OWNER,Tri county school Forest -US-CS2,87368,GRP_LOCATION,LOCATION_LAT,44.1467 -US-CS2,87368,GRP_LOCATION,LOCATION_LONG,-89.5002 -US-CS2,87368,GRP_LOCATION,LOCATION_ELEV,328 -US-CS2,87368,GRP_LOCATION,LOCATION_DATE_START,201806291800 -US-CS2,87368,GRP_LOCATION,LOCATION_COMMENT,Approximation based on Google maps. GPS coords forthcoming -US-CS2,87372,GRP_NETWORK,NETWORK,AmeriFlux -US-CS2,87364,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"Evapotranspiration, irrigation, groundwater recharge" -US-CS2,87365,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"1225 W Dayton St, Madison, WI 53706 USA" -US-CS2,87370,GRP_SITE_CHAR,TERRAIN,Flat -US-CS2,87370,GRP_SITE_CHAR,ASPECT,FLAT -US-CS2,87370,GRP_SITE_CHAR,WIND_DIRECTION,W -US-CS2,87370,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,300 -US-CS2,87359,GRP_SITE_DESC,SITE_DESC,Tri county school Forest -US-CS2,87360,GRP_SITE_FUNDING,SITE_FUNDING,Wisconsin Department of Natural Resources -US-CS2,87362,GRP_STATE,STATE,WI -US-CS2,87354,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Ankur Desai -US-CS2,87354,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-CS2,87354,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,desai@aos.wisc.edu -US-CS2,87354,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Wisconsin-Madison -US-CS2,87367,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Jonathan Thom -US-CS2,87367,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-CS2,87367,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,jonathan.thom@ssec.wisc.edu -US-CS2,87367,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Wisconsin-Madison -US-CS2,89937,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Ammara Talib -US-CS2,89937,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,DataManager -US-CS2,89937,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,talib@wisc.edu -US-CS2,89937,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Wisconsin-Madison -US-CS2,87371,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-CS2,87366,GRP_TOWER_TYPE,TOWER_TYPE,triangle -US-CS2,87355,GRP_URL,URL,https://flux.aos.wisc.edu/fluxdata -US-CS2,24001084,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-CS2 -US-CS2,89939,GRP_UTC_OFFSET,UTC_OFFSET,-6 -US-CS3,87384,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,This work was funded by an award to UW-Madison from WPVGA and the Wisconsin DNR -US-CS3,87376,GRP_CLIM_AVG,MAT,7 -US-CS3,87376,GRP_CLIM_AVG,MAP,830 -US-CS3,87376,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfa -US-CS3,27001085,GRP_COUNTRY,COUNTRY,USA -US-CS3,91710,GRP_DOI,DOI,10.17190/AMF/1617713 -US-CS3,91710,GRP_DOI,DOI_CITATION,"Ankur Desai (2021), AmeriFlux BASE US-CS3 Central Sands Irrigated Agricultural Field, Ver. 3-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1617713" -US-CS3,91710,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-CS3,91597,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-CS3,91597,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Ankur Desai -US-CS3,91597,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-CS3,91597,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,desai@aos.wisc.edu -US-CS3,91597,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of Wisconsin-Madison -US-CS3,91665,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,University of Wisconsin-Madison -US-CS3,91665,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-CS3,91616,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Wisconsin Department of Natural Resources -US-CS3,91616,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-CS3,87374,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Agriculture -US-CS3,91359,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-CS3,91359,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-CS3,91359,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20190530 -US-CS3,91359,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-CS3,91424,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-CS3,91424,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-CS3,91424,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20190530 -US-CS3,91424,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-CS3,91421,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-CS3,91421,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-CS3,91421,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20190530 -US-CS3,91421,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-CS3,23001085,GRP_HEADER,SITE_NAME,Central Sands Irrigated Agricultural Field -US-CS3,87377,GRP_IGBP,IGBP,CRO -US-CS3,87377,GRP_IGBP,IGBP_COMMENT,"2018 is Potatoes, 3-yr rotation" -US-CS3,87380,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -US-CS3,87380,GRP_LAND_OWNERSHIP,LAND_OWNER,Heartland Farms -US-CS3,87378,GRP_LOCATION,LOCATION_LAT,44.1394 -US-CS3,87378,GRP_LOCATION,LOCATION_LONG,-89.5727 -US-CS3,87378,GRP_LOCATION,LOCATION_ELEV,328 -US-CS3,87378,GRP_LOCATION,LOCATION_DATE_START,20190503 -US-CS3,87378,GRP_LOCATION,LOCATION_COMMENT,Approximation based on Google maps. GPS coords forthcoming -US-CS3,87387,GRP_NETWORK,NETWORK,AmeriFlux -US-CS3,87390,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"Evapotranspiration, irrigation, groundwater recharge" -US-CS3,87388,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"1225 W Dayton St, Madison, WI 53706 USA" -US-CS3,87386,GRP_SITE_CHAR,TERRAIN,Flat -US-CS3,87386,GRP_SITE_CHAR,ASPECT,FLAT -US-CS3,87386,GRP_SITE_CHAR,WIND_DIRECTION,W -US-CS3,87386,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,300 -US-CS3,87394,GRP_SITE_DESC,SITE_DESC,Heartland Farms Center-Pivot Irrigated Potato Field -US-CS3,87393,GRP_SITE_FUNDING,SITE_FUNDING,Wisconsin Department of Natural Resources -US-CS3,87389,GRP_STATE,STATE,WI -US-CS3,87395,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Ankur Desai -US-CS3,87395,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-CS3,87395,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,desai@aos.wisc.edu -US-CS3,87395,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Wisconsin-Madison -US-CS3,87392,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Jonathan Thom -US-CS3,87392,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-CS3,87392,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,jonathan.thom@ssec.wisc.edu -US-CS3,87392,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Wisconsin-Madison -US-CS3,87375,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-CS3,87385,GRP_TOWER_TYPE,TOWER_TYPE,triangle -US-CS3,87383,GRP_URL,URL,https://flux.aos.wisc.edu/fluxdata -US-CS3,24001085,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-CS3 -US-CS3,89938,GRP_UTC_OFFSET,UTC_OFFSET,-6 -US-CS4,94903,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,This work was funded by an award to UW-Madison from WPVGA and the Wisconsin DNR -US-CS4,94901,GRP_CLIM_AVG,MAT,7 -US-CS4,94901,GRP_CLIM_AVG,MAP,830 -US-CS4,94901,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfa -US-CS4,27001173,GRP_COUNTRY,COUNTRY,USA -US-CS4,95045,GRP_DOI,DOI,10.17190/AMF/1756417 -US-CS4,95045,GRP_DOI,DOI_CITATION,"Ankur Desai (2022), AmeriFlux BASE US-CS4 Central Sands Irrigated Agricultural Field, Ver. 3-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1756417" -US-CS4,95045,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-CS4,94939,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-CS4,94939,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Ankur Desai -US-CS4,94939,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-CS4,94939,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,desai@aos.wisc.edu -US-CS4,94939,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of Wisconsin-Madison -US-CS4,94947,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,University of Wisconsin-Madison -US-CS4,94947,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-CS4,94943,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Wisconsin Department of Natural Resources -US-CS4,94943,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-CS4,94918,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Agriculture -US-CS4,94915,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-CS4,94915,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-CS4,94915,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,202005060000 -US-CS4,94915,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,202012011800 -US-CS4,94915,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-CS4,94902,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-CS4,94902,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-CS4,94902,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,202005060000 -US-CS4,94902,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,202012011800 -US-CS4,94902,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-CS4,94914,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-CS4,94914,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-CS4,94914,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,202005060000 -US-CS4,94914,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,202012011800 -US-CS4,94914,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-CS4,23001173,GRP_HEADER,SITE_NAME,Central Sands Irrigated Agricultural Field -US-CS4,94907,GRP_IGBP,IGBP,CRO -US-CS4,94907,GRP_IGBP,IGBP_COMMENT,"2020 is Potatoes, 3-yr rotation" -US-CS4,94911,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -US-CS4,94911,GRP_LAND_OWNERSHIP,LAND_OWNER,Heartland Farms -US-CS4,94913,GRP_LOCATION,LOCATION_LAT,44.1597 -US-CS4,94913,GRP_LOCATION,LOCATION_LONG,-89.5475 -US-CS4,94913,GRP_LOCATION,LOCATION_ELEV,328 -US-CS4,94913,GRP_LOCATION,LOCATION_DATE_START,202005060000 -US-CS4,94913,GRP_LOCATION,LOCATION_COMMENT,Approximation based on Google maps. GPS coords forthcoming -US-CS4,94910,GRP_NETWORK,NETWORK,AmeriFlux -US-CS4,94912,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"Evapotranspiration, irrigation, groundwater recharge" -US-CS4,94917,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"1225 W Dayton St, Madison, WI 53706 USA" -US-CS4,94898,GRP_SITE_CHAR,TERRAIN,Flat -US-CS4,94898,GRP_SITE_CHAR,ASPECT,FLAT -US-CS4,94898,GRP_SITE_CHAR,WIND_DIRECTION,W -US-CS4,94898,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,300 -US-CS4,94916,GRP_SITE_DESC,SITE_DESC,Heartland Farms Center-Pivot Irrigated Potato Field -US-CS4,94919,GRP_SITE_FUNDING,SITE_FUNDING,Wisconsin Department of Natural Resources -US-CS4,94905,GRP_STATE,STATE,WI -US-CS4,94909,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Ankur Desai -US-CS4,94909,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-CS4,94909,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,desai@aos.wisc.edu -US-CS4,94909,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Wisconsin-Madison -US-CS4,94900,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Jonathan Thom -US-CS4,94900,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-CS4,94900,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,jonathan.thom@ssec.wisc.edu -US-CS4,94900,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Wisconsin-Madison -US-CS4,94906,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-CS4,94904,GRP_TOWER_TYPE,TOWER_TYPE,triangle -US-CS4,94899,GRP_URL,URL,https://flux.aos.wisc.edu/fluxdata -US-CS4,24001173,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-CS4 -US-CS4,94908,GRP_UTC_OFFSET,UTC_OFFSET,-6 -US-CS5,97584,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,This work was funded by an award to UW-Madison from WPVGA and the Wisconsin DNR -US-CS5,97581,GRP_CLIM_AVG,MAT,7 -US-CS5,97581,GRP_CLIM_AVG,MAP,830 -US-CS5,97581,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfa -US-CS5,27001200,GRP_COUNTRY,COUNTRY,USA -US-CS5,98951,GRP_DOI,DOI,10.17190/AMF/1846663 -US-CS5,98951,GRP_DOI,DOI_CITATION,"Ankur Desai (2022), AmeriFlux BASE US-CS5 Central Sands Irrigated Agricultural Field, Ver. 1-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1846663" -US-CS5,98951,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-CS5,98937,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-CS5,98937,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Ankur Desai -US-CS5,98937,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-CS5,98937,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,desai@aos.wisc.edu -US-CS5,98937,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of Wisconsin-Madison -US-CS5,98947,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,University of Wisconsin-Madison -US-CS5,98947,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-CS5,98942,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,"Wisconsin Potato and Vegetable Growers Association, Wisconsin Department of Natural Resources" -US-CS5,98942,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-CS5,97583,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Agriculture -US-CS5,97578,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-CS5,97578,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-CS5,97578,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20210505 -US-CS5,97578,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-CS5,97587,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-CS5,97587,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-CS5,97587,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20210505 -US-CS5,97587,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-CS5,97594,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-CS5,97594,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-CS5,97594,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20210505 -US-CS5,97594,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-CS5,23001200,GRP_HEADER,SITE_NAME,Central Sands Irrigated Agricultural Field -US-CS5,97589,GRP_IGBP,IGBP,CRO -US-CS5,97589,GRP_IGBP,IGBP_COMMENT,"2021 is Potatoes, 3-yr rotation" -US-CS5,97579,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -US-CS5,97579,GRP_LAND_OWNERSHIP,LAND_OWNER,Heartland Farms -US-CS5,97585,GRP_LOCATION,LOCATION_LAT,44.1095 -US-CS5,97585,GRP_LOCATION,LOCATION_LONG,-89.5377 -US-CS5,97585,GRP_LOCATION,LOCATION_ELEV,328 -US-CS5,97585,GRP_LOCATION,LOCATION_DATE_START,202105050000 -US-CS5,97585,GRP_LOCATION,LOCATION_COMMENT,Approximation based on Google maps. GPS coords forthcoming -US-CS5,97593,GRP_NETWORK,NETWORK,AmeriFlux -US-CS5,97591,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"Evapotranspiration, irrigation, groundwater recharge" -US-CS5,97590,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"1225 W Dayton St, Madison, WI 53706 USA" -US-CS5,97597,GRP_SITE_CHAR,TERRAIN,Flat -US-CS5,97597,GRP_SITE_CHAR,ASPECT,FLAT -US-CS5,97597,GRP_SITE_CHAR,WIND_DIRECTION,W -US-CS5,97597,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,300 -US-CS5,97588,GRP_SITE_DESC,SITE_DESC,Heartland Farms Center-Pivot Irrigated Potato Field -US-CS5,97596,GRP_SITE_FUNDING,SITE_FUNDING,"Wisconsin Potato and Vegetable Growers Association, Wisconsin Department of Natural Resources" -US-CS5,97598,GRP_STATE,STATE,WI -US-CS5,97582,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Ankur Desai -US-CS5,97582,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-CS5,97582,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,desai@aos.wisc.edu -US-CS5,97582,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Wisconsin-Madison -US-CS5,97599,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Jonathan Thom -US-CS5,97599,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-CS5,97599,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,jonathan.thom@ssec.wisc.edu -US-CS5,97599,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Wisconsin-Madison -US-CS5,97595,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-CS5,97580,GRP_TOWER_TYPE,TOWER_TYPE,triangle -US-CS5,97586,GRP_URL,URL,https://flux.aos.wisc.edu/fluxdata -US-CS5,24001200,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-CS5 -US-CS5,97592,GRP_UTC_OFFSET,UTC_OFFSET,-6 -US-CwG,99029,GRP_CLIM_AVG,MAT,12.9 -US-CwG,99029,GRP_CLIM_AVG,MAP,1495 -US-CwG,99029,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfb -US-CwG,27001220,GRP_COUNTRY,COUNTRY,USA -US-CwG,99035,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Grazing -US-CwG,99022,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-CwG,99022,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-CwG,99022,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201701010000 -US-CwG,99022,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,201807300000 -US-CwG,99022,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-CwG,99025,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-CwG,99025,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-CwG,99025,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201701010000 -US-CwG,99025,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,201807300000 -US-CwG,99025,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-CwG,23001220,GRP_HEADER,SITE_NAME,Coweeta Grassland -US-CwG,99023,GRP_IGBP,IGBP,GRA -US-CwG,99023,GRP_IGBP,IGBP_DATE_START,201701010000 -US-CwG,99033,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -US-CwG,99020,GRP_LOCATION,LOCATION_LAT,34.9682 -US-CwG,99020,GRP_LOCATION,LOCATION_LONG,-83.3951 -US-CwG,99020,GRP_LOCATION,LOCATION_ELEV,657 -US-CwG,99020,GRP_LOCATION,LOCATION_DATE_START,201701010000 -US-CwG,99024,GRP_NETWORK,NETWORK,AmeriFlux -US-CwG,99028,GRP_NETWORK,NETWORK,LTER -US-CwG,99032,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,Biophysical impacts of land cover change -US-CwG,99037,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"702 N. Walnut Grove Avenue, MSB2 Room 316, Bloomington, IN 47405" -US-CwG,99021,GRP_SITE_CHAR,TERRAIN,Undulated/Variable -US-CwG,99021,GRP_SITE_CHAR,ASPECT,FLAT -US-CwG,99026,GRP_SITE_DESC,SITE_DESC,"The site is a managed pasture located on the grounds of the Rabun Gap - Nacoochee School in North Georgia, about 10 miles south of the Coweeta Hydrologic Lab in southwestern North Carolina." -US-CwG,99027,GRP_SITE_FUNDING,SITE_FUNDING,NSF DEB 1552747 -US-CwG,99036,GRP_STATE,STATE,GA -US-CwG,99034,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Kim Novick -US-CwG,99034,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-CwG,99034,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,knovick@indiana.edu -US-CwG,99034,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Indiana University - Bloomington -US-CwG,99031,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Quan Zhang -US-CwG,99031,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-CwG,99031,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,quan.zhang@whu.edu.cn -US-CwG,99031,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Wuhan University -US-CwG,99030,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-CwG,99019,GRP_TOWER_TYPE,TOWER_TYPE,tripod -US-CwG,24001220,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-CwG -US-CwG,99018,GRP_UTC_OFFSET,UTC_OFFSET,-5 -US-CwG,99018,GRP_UTC_OFFSET,UTC_OFFSET_DATE_START,201701010000 -US-DCS,90707,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,USGS Priority Ecosystem Science Everglades Program -US-DCS,90707,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT_COMMENT,Tower construction funded by South Florida Water Management District -US-DCS,90705,GRP_CLIM_AVG,MAT,23.1 -US-DCS,90705,GRP_CLIM_AVG,MAP,1312 -US-DCS,90705,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Cwa -US-DCS,27001116,GRP_COUNTRY,COUNTRY,USA -US-DCS,90723,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Hydrologic event -US-DCS,90717,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Storm or wind -US-DCS,90720,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-DCS,90720,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-DCS,90720,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20121203 -US-DCS,90720,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,201412080000 -US-DCS,90720,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-DCS,90706,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-DCS,90706,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CH4 -US-DCS,90706,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20121203 -US-DCS,90706,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,201412080000 -US-DCS,90706,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-DCS,90718,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-DCS,90718,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-DCS,90718,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20121203 -US-DCS,90718,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,201412080000 -US-DCS,90718,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-DCS,90708,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-DCS,90708,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,Other -US-DCS,90708,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20121203 -US-DCS,90708,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,201412080000 -US-DCS,90708,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-DCS,90708,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,Measured for LE -US-DCS,23001116,GRP_HEADER,SITE_NAME,Dwarf Cypress Swamp -US-DCS,90711,GRP_IGBP,IGBP,WET -US-DCS,90719,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-DCS,90719,GRP_LAND_OWNERSHIP,LAND_OWNER,National Preserve -US-DCS,90712,GRP_LOCATION,LOCATION_LAT,25.7626 -US-DCS,90712,GRP_LOCATION,LOCATION_LONG,-80.9078 -US-DCS,90712,GRP_LOCATION,LOCATION_ELEV,2.05 -US-DCS,90712,GRP_LOCATION,LOCATION_DATE_START,20121203 -US-DCS,90712,GRP_LOCATION,LOCATION_COMMENT,Located in Big Cypress National Preserve -US-DCS,90714,GRP_NETWORK,NETWORK,AmeriFlux -US-DCS,90715,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,Carbon and water fluxes -US-DCS,90725,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"3321 College Ave, Davie FL 33314" -US-DCS,90726,GRP_SITE_CHAR,TERRAIN,Flat -US-DCS,90726,GRP_SITE_CHAR,ASPECT,S -US-DCS,90726,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,0 -US-DCS,90709,GRP_SITE_DESC,SITE_DESC,Dwarf Cypress -US-DCS,90710,GRP_SITE_FUNDING,SITE_FUNDING,USGS Priority Ecosystem Science Everglades Program -US-DCS,90713,GRP_STATE,STATE,FL -US-DCS,90754,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Andre Daniels -US-DCS,90754,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-DCS,90754,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,andre_daniels@usgs.gov -US-DCS,90754,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,USGS -US-DCS,90722,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,W. Barclay Shoemaker -US-DCS,90722,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-DCS,90722,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,bshoemak@usgs.gov -US-DCS,90722,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,USGS -US-DCS,90722,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"3321 College Ave, Davie FL 33314" -US-DCS,93494,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Rosvel Bracho-Garrillo -US-DCS,93494,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,DataManager -US-DCS,93494,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,rbracho@ufl.edu -US-DCS,93494,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Florida -US-DCS,90716,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-DCS,90721,GRP_TOWER_TYPE,TOWER_TYPE,triangle -US-DCS,90724,GRP_URL,URL,https://sites.google.com/site/floridaetwiki/home -US-DCS,24001116,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-DCS -US-DCS,90728,GRP_UTC_OFFSET,UTC_OFFSET,-5 -US-DCS,90728,GRP_UTC_OFFSET,UTC_OFFSET_DATE_START,20200113 -US-DCS,90728,GRP_UTC_OFFSET,UTC_OFFSET_COMMENT,Eatern Standard Time Zone -US-DFC,91762,GRP_CLIM_AVG,MAT,7.65 -US-DFC,91762,GRP_CLIM_AVG,MAP,787 -US-DFC,91762,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfb -US-DFC,27001135,GRP_COUNTRY,COUNTRY,USA -US-DFC,93747,GRP_DOI,DOI,10.17190/AMF/1660340 -US-DFC,93747,GRP_DOI,DOI_CITATION,"Alison Duff, Ankur Desai (2020), AmeriFlux BASE US-DFC US Dairy Forage Research Center, Prairie du Sac, Ver. 1-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1660340" -US-DFC,93747,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-DFC,93701,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-DFC,93701,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Alison Duff -US-DFC,93701,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-DFC,93701,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,alison.duff@usda.gov -US-DFC,93701,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,US Dairy Forage Research Center -US-DFC,93716,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-DFC,93716,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Ankur Desai -US-DFC,93716,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-DFC,93716,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,desai@aos.wisc.edu -US-DFC,93716,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of Wisconsin Madison -US-DFC,93739,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,University of Wisconsin Madison -US-DFC,93739,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-DFC,93738,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,US Dairy Forage Research Center -US-DFC,93738,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-DFC,93721,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,US Department of Agriculture -US-DFC,93721,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-DFC,91754,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Agriculture -US-DFC,91764,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-DFC,91764,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-DFC,91764,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201804041600 -US-DFC,91764,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-DFC,91772,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-DFC,91772,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CH4 -US-DFC,91772,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201804041600 -US-DFC,91772,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-DFC,91753,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-DFC,91753,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-DFC,91753,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201804041600 -US-DFC,91753,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-DFC,23001135,GRP_HEADER,SITE_NAME,"US Dairy Forage Research Center, Prairie du Sac" -US-DFC,91761,GRP_IGBP,IGBP,CRO -US-DFC,91761,GRP_IGBP,IGBP_DATE_START,1980 -US-DFC,92294,GRP_INST,INST_MODEL,SOIL_H-Plate -US-DFC,92294,GRP_INST,INST_SN,13546 -US-DFC,92294,GRP_INST,INST_DATE,201804041600 -US-DFC,92294,GRP_INST,INST_DATE_UNC,0 -US-DFC,92295,GRP_INST,INST_MODEL,SOIL_H-Plate -US-DFC,92295,GRP_INST,INST_SN,13547 -US-DFC,92295,GRP_INST,INST_DATE,201804041600 -US-DFC,92295,GRP_INST,INST_DATE_UNC,0 -US-DFC,92303,GRP_INST,INST_MODEL,SOIL_H-Plate -US-DFC,92303,GRP_INST,INST_SN,13548 -US-DFC,92303,GRP_INST,INST_DATE,201804041600 -US-DFC,92303,GRP_INST,INST_DATE_UNC,0 -US-DFC,92302,GRP_INST,INST_MODEL,RAD-Pyrrad-SW+LW -US-DFC,92302,GRP_INST,INST_SN,150754 -US-DFC,92302,GRP_INST,INST_DATE,201804041600 -US-DFC,92302,GRP_INST,INST_DATE_UNC,0 -US-DFC,92305,GRP_INST,INST_MODEL,SA-Gill Windmaster -US-DFC,92305,GRP_INST,INST_SN,171301 -US-DFC,92305,GRP_INST,INST_DATE,201804041600 -US-DFC,92305,GRP_INST,INST_DATE_UNC,0 -US-DFC,92305,GRP_INST,INST_FIRMWARE,2329-701-01 -US-DFC,92305,GRP_INST,INST_SAMPLING_INT,0.1 -US-DFC,92305,GRP_INST,INST_AVERAGING_INT,0.1 -US-DFC,92305,GRP_INST,INST_SA_OFFSET_NORTH,270 -US-DFC,92305,GRP_INST,INST_SA_WIND_FORMAT,"U, V, W" -US-DFC,92305,GRP_INST,INST_SA_GILL_ALIGN,Spar -US-DFC,92297,GRP_INST,INST_MODEL,SWC-Other -US-DFC,92297,GRP_INST,INST_SN,240932 -US-DFC,92297,GRP_INST,INST_DATE,201804041600 -US-DFC,92297,GRP_INST,INST_DATE_UNC,0 -US-DFC,92296,GRP_INST,INST_MODEL,SWC-Other -US-DFC,92296,GRP_INST,INST_SN,240933 -US-DFC,92296,GRP_INST,INST_DATE,201804041600 -US-DFC,92296,GRP_INST,INST_DATE_UNC,0 -US-DFC,92300,GRP_INST,INST_MODEL,SWC-Other -US-DFC,92300,GRP_INST,INST_SN,240934 -US-DFC,92300,GRP_INST,INST_DATE,201804041600 -US-DFC,92300,GRP_INST,INST_DATE_UNC,0 -US-DFC,92306,GRP_INST,INST_MODEL,RAIN-TipBucGauge -US-DFC,92306,GRP_INST,INST_SN,68831-416 -US-DFC,92306,GRP_INST,INST_DATE,201804041600 -US-DFC,92306,GRP_INST,INST_DATE_UNC,0 -US-DFC,92298,GRP_INST,INST_MODEL,GA_OP-LI-COR LI-7500A -US-DFC,92298,GRP_INST,INST_SN,75H-2987 -US-DFC,92298,GRP_INST,INST_DATE,201804041600 -US-DFC,92298,GRP_INST,INST_DATE_UNC,0 -US-DFC,92298,GRP_INST,INST_FIRMWARE,8.7.5 -US-DFC,92298,GRP_INST,INST_SAMPLING_INT,0.1 -US-DFC,92298,GRP_INST,INST_AVERAGING_INT,0.1 -US-DFC,92298,GRP_INST,INST_SA_OFFSET_NORTH,270 -US-DFC,92299,GRP_INST,INST_MODEL,RH-Other -US-DFC,92299,GRP_INST,INST_SN,m0950043 -US-DFC,92299,GRP_INST,INST_DATE,201804041600 -US-DFC,92299,GRP_INST,INST_DATE_UNC,0 -US-DFC,92299,GRP_INST,INST_SHIELDING,Radiation -US-DFC,92307,GRP_INST,INST_MODEL,RAD-PAR Quantum -US-DFC,92307,GRP_INST,INST_SN,PY 104433 -US-DFC,92307,GRP_INST,INST_DATE,201804041600 -US-DFC,92307,GRP_INST,INST_DATE_UNC,0 -US-DFC,92308,GRP_INST,INST_MODEL,GA_OP-LI-COR LI-7700 -US-DFC,92308,GRP_INST,INST_SN,TG1-0497 -US-DFC,92308,GRP_INST,INST_DATE,201804041600 -US-DFC,92308,GRP_INST,INST_DATE_UNC,0 -US-DFC,92308,GRP_INST,INST_FIRMWARE,1.0.23 -US-DFC,92308,GRP_INST,INST_SAMPLING_INT,0.1 -US-DFC,92308,GRP_INST,INST_AVERAGING_INT,0.1 -US-DFC,92308,GRP_INST,INST_SA_OFFSET_NORTH,270 -US-DFC,92301,GRP_INSTPAIR,INSTPAIR_MODEL_1,GA_OP-LI-COR LI-7500A -US-DFC,92301,GRP_INSTPAIR,INSTPAIR_SN_1,75H-2987 -US-DFC,92301,GRP_INSTPAIR,INSTPAIR_MODEL_2,SA-Gill Windmaster -US-DFC,92301,GRP_INSTPAIR,INSTPAIR_SN_2,171301 -US-DFC,92301,GRP_INSTPAIR,INSTPAIR_DATE,201804041600 -US-DFC,92301,GRP_INSTPAIR,INSTPAIR_DATE_UNC,0 -US-DFC,92301,GRP_INSTPAIR,INSTPAIR_COMMENT,Paired with Gill Windmaster -US-DFC,92301,GRP_INSTPAIR,INSTPAIR_HEIGHT_SEP,-1 -US-DFC,92301,GRP_INSTPAIR,INSTPAIR_EASTWARD_SEP,0 -US-DFC,92301,GRP_INSTPAIR,INSTPAIR_NORTHWARD_SEP,19 -US-DFC,92304,GRP_INSTPAIR,INSTPAIR_MODEL_1,GA_OP-LI-COR LI-7700 -US-DFC,92304,GRP_INSTPAIR,INSTPAIR_SN_1,TG1-0497 -US-DFC,92304,GRP_INSTPAIR,INSTPAIR_MODEL_2,SA-Gill Windmaster -US-DFC,92304,GRP_INSTPAIR,INSTPAIR_SN_2,171301 -US-DFC,92304,GRP_INSTPAIR,INSTPAIR_DATE,201804041600 -US-DFC,92304,GRP_INSTPAIR,INSTPAIR_DATE_UNC,0 -US-DFC,92304,GRP_INSTPAIR,INSTPAIR_COMMENT,Paired with Gill Windmaster -US-DFC,92304,GRP_INSTPAIR,INSTPAIR_HEIGHT_SEP,-16 -US-DFC,92304,GRP_INSTPAIR,INSTPAIR_EASTWARD_SEP,0 -US-DFC,92304,GRP_INSTPAIR,INSTPAIR_NORTHWARD_SEP,-22 -US-DFC,91759,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -US-DFC,91759,GRP_LAND_OWNERSHIP,LAND_OWNER,US Department of Agriculture -US-DFC,91756,GRP_LOCATION,LOCATION_LAT,43.3448 -US-DFC,91756,GRP_LOCATION,LOCATION_LONG,-89.7117 -US-DFC,91756,GRP_LOCATION,LOCATION_ELEV,264.9 -US-DFC,91756,GRP_LOCATION,LOCATION_DATE_START,1980 -US-DFC,91769,GRP_NETWORK,NETWORK,AmeriFlux -US-DFC,91767,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,Greenhouse gas emissions and carbon sequestration of an integrated crop-dairy farm -US-DFC,91770,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"S8822 Sunset Dr, Prairie Du Sac, WI 53578" -US-DFC,91773,GRP_SITE_CHAR,TERRAIN,Undulated/Variable -US-DFC,91773,GRP_SITE_CHAR,ASPECT,WSW -US-DFC,91773,GRP_SITE_CHAR,WIND_DIRECTION,SW -US-DFC,91773,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,200 -US-DFC,91773,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,100 -US-DFC,91758,GRP_SITE_DESC,SITE_DESC,"Former US ammunition plant converted to dairy farm in 1980 with annual and perennial croplands mostly comprised of alfalfa, corn, soybean and wheat, with natural vegetation (forest, grass and shrubland), as well as pastures and and hedgerows surrounding the fields. During spring and summer months, dry cows and heifer graze on pastures." -US-DFC,91757,GRP_SITE_FUNDING,SITE_FUNDING,US Department of Agriculture -US-DFC,91765,GRP_STATE,STATE,WI -US-DFC,91768,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Alison Duff -US-DFC,91768,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-DFC,91768,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,alison.duff@usda.gov -US-DFC,91768,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,US Dairy Forage Research Center -US-DFC,91763,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Ankur Desai -US-DFC,91763,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-DFC,91763,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,desai@aos.wisc.edu -US-DFC,91763,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Wisconsin Madison -US-DFC,91766,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Susanne Wiesner -US-DFC,91766,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,DataManager -US-DFC,91766,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,swiesner2@wisc.edu -US-DFC,91766,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Wisconsin Madison -US-DFC,91755,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Jonathan Thom -US-DFC,91755,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Technician -US-DFC,91755,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,jthom@ssec.wisc.edu -US-DFC,91755,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Wisconsin Madison -US-DFC,91752,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Kris Niemann -US-DFC,91752,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Technician -US-DFC,91752,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,kris.niemann@usda.gov -US-DFC,91752,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,US Dairy Forage Research Center -US-DFC,91760,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-DFC,91751,GRP_TOWER_TYPE,TOWER_TYPE,triangle -US-DFC,24001135,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-DFC -US-DFC,91771,GRP_UTC_OFFSET,UTC_OFFSET,-6 -US-DFK,87346,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,We thank Patagonia Provisions for funding for this project -US-DFK,87348,GRP_CLIM_AVG,MAT,7.65 -US-DFK,87348,GRP_CLIM_AVG,MAP,787 -US-DFK,87348,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfb -US-DFK,27001083,GRP_COUNTRY,COUNTRY,USA -US-DFK,88006,GRP_DM_AGRICULTURE,DM_AGRICULTURE,Harvest -US-DFK,88006,GRP_DM_AGRICULTURE,DM_SURF,80 -US-DFK,88006,GRP_DM_AGRICULTURE,DM_SURF_MEAS_UNC,10 -US-DFK,88006,GRP_DM_AGRICULTURE,DM_DATE,201908231300 -US-DFK,88006,GRP_DM_AGRICULTURE,DM_DATE_UNC,0 -US-DFK,88006,GRP_DM_AGRICULTURE,DM_COMMENT,Kernza grain was harvest in ~80% of the field -US-DFK,98495,GRP_DOI,DOI,10.17190/AMF/1825937 -US-DFK,98495,GRP_DOI,DOI_CITATION,"Alison Duff, Ankur Desai, Valentin Picasso Risso (2021), AmeriFlux BASE US-DFK Dairy Forage Research Center - Kernza, Ver. 1-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1825937" -US-DFK,98495,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-DFK,98478,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-DFK,98478,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Alison Duff -US-DFK,98478,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-DFK,98478,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,alison.duff@usda.gov -US-DFK,98478,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,US Dairy Forage Research Center -US-DFK,98477,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-DFK,98477,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Ankur Desai -US-DFK,98477,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-DFK,98477,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,desai@aos.wisc.edu -US-DFK,98477,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of Wisconsin Madison -US-DFK,98479,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-DFK,98479,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Valentin Picasso Risso -US-DFK,98479,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-DFK,98479,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,picassorisso@wisc.edu -US-DFK,98479,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of Wisconsin Madison -US-DFK,98489,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,University of Wisconsin Madison -US-DFK,98489,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-DFK,98486,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,US Dairy Forage Research Center -US-DFK,98486,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-DFK,98481,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,"Patagonia provisions, US Department of Agriculture" -US-DFK,98481,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-DFK,87350,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Agriculture -US-DFK,87337,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-DFK,87337,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-DFK,87337,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201812141315 -US-DFK,87337,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-DFK,87338,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-DFK,87338,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-DFK,87338,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201812141315 -US-DFK,87338,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-DFK,23001083,GRP_HEADER,SITE_NAME,Dairy Forage Research Center - Kernza -US-DFK,87344,GRP_IGBP,IGBP,CRO -US-DFK,87344,GRP_IGBP,IGBP_DATE_START,1980 -US-DFK,92318,GRP_INST,INST_MODEL,SOIL_H-Plate_AUTO -US-DFK,92318,GRP_INST,INST_SN,21266-2-1 -US-DFK,92318,GRP_INST,INST_DATE,202005071000 -US-DFK,92318,GRP_INST,INST_DATE_UNC,0 -US-DFK,92318,GRP_INST,INST_COMMENT,Hukseflux Soil Heat flux plate HFP01-L50- PT (16 cm) -US-DFK,92318,GRP_INST,INST_SAMPLING_INT,5 -US-DFK,92318,GRP_INST,INST_AVERAGING_INT,5 -US-DFK,92318,GRP_INST,INST_HEAT,Unheated -US-DFK,92318,GRP_INST,INST_ASPIRATION,None -US-DFK,92318,GRP_INST,INST_SA_OFFSET_NORTH,0 -US-DFK,92311,GRP_INST,INST_MODEL,SOIL_H-Plate_AUTO -US-DFK,92311,GRP_INST,INST_SN,21266-2-2 -US-DFK,92311,GRP_INST,INST_DATE,202005071000 -US-DFK,92311,GRP_INST,INST_DATE_UNC,0 -US-DFK,92311,GRP_INST,INST_COMMENT,Hukseflux Soil Heat flux plate HFP01-L50- PT (16 cm) -US-DFK,92311,GRP_INST,INST_SAMPLING_INT,5 -US-DFK,92311,GRP_INST,INST_AVERAGING_INT,5 -US-DFK,92311,GRP_INST,INST_HEAT,Unheated -US-DFK,92311,GRP_INST,INST_ASPIRATION,None -US-DFK,92311,GRP_INST,INST_SA_OFFSET_NORTH,0 -US-DFK,92319,GRP_INST,INST_MODEL,SOIL_H-Plate_AUTO -US-DFK,92319,GRP_INST,INST_SN,21266-2-3 -US-DFK,92319,GRP_INST,INST_DATE,202005071000 -US-DFK,92319,GRP_INST,INST_DATE_UNC,0 -US-DFK,92319,GRP_INST,INST_COMMENT,Hukseflux Soil Heat flux plate HFP01-L50- PT (16 cm) -US-DFK,92319,GRP_INST,INST_SAMPLING_INT,5 -US-DFK,92319,GRP_INST,INST_AVERAGING_INT,5 -US-DFK,92319,GRP_INST,INST_HEAT,Unheated -US-DFK,92319,GRP_INST,INST_ASPIRATION,None -US-DFK,92319,GRP_INST,INST_SA_OFFSET_NORTH,180 -US-DFK,92315,GRP_INST,INST_MODEL,SOIL_H-Plate_AUTO -US-DFK,92315,GRP_INST,INST_SN,21266-2-4 -US-DFK,92315,GRP_INST,INST_DATE,202005071000 -US-DFK,92315,GRP_INST,INST_DATE_UNC,0 -US-DFK,92315,GRP_INST,INST_COMMENT,Hukseflux Soil Heat flux plate HFP01-PT (16 cm) -US-DFK,92315,GRP_INST,INST_SAMPLING_INT,5 -US-DFK,92315,GRP_INST,INST_AVERAGING_INT,5 -US-DFK,92315,GRP_INST,INST_HEAT,Unheated -US-DFK,92315,GRP_INST,INST_ASPIRATION,None -US-DFK,92315,GRP_INST,INST_SA_OFFSET_NORTH,180 -US-DFK,88069,GRP_INST,INST_MODEL,LEAF_WET-FrequencyDomain -US-DFK,88069,GRP_INST,INST_SN,22121-66 -US-DFK,88069,GRP_INST,INST_DATE,201812141300 -US-DFK,88069,GRP_INST,INST_DATE_UNC,0 -US-DFK,88069,GRP_INST,INST_COMMENT,Decagon LWS-L15-PT -US-DFK,88069,GRP_INST,INST_SAMPLING_INT,5 -US-DFK,88069,GRP_INST,INST_AVERAGING_INT,5 -US-DFK,88069,GRP_INST,INST_HEAT,Unheated -US-DFK,88069,GRP_INST,INST_SHIELDING,None -US-DFK,88069,GRP_INST,INST_ASPIRATION,None -US-DFK,88069,GRP_INST,INST_SA_OFFSET_NORTH,180 -US-DFK,88072,GRP_INST,INST_MODEL,RH-Other -US-DFK,88072,GRP_INST,INST_SN,22280-3 -US-DFK,88072,GRP_INST,INST_DATE,201812141300 -US-DFK,88072,GRP_INST,INST_DATE_UNC,0 -US-DFK,88072,GRP_INST,INST_COMMENT,Vaisala Temperature/RH -US-DFK,88072,GRP_INST,INST_SAMPLING_INT,5 -US-DFK,88072,GRP_INST,INST_AVERAGING_INT,5 -US-DFK,88072,GRP_INST,INST_HEAT,Unheated -US-DFK,88072,GRP_INST,INST_SHIELDING,Radiation -US-DFK,88072,GRP_INST,INST_ASPIRATION,None -US-DFK,88072,GRP_INST,INST_SA_OFFSET_NORTH,90 -US-DFK,92317,GRP_INST,INST_MODEL,SWC-Other -US-DFK,92317,GRP_INST,INST_SN,25471-243-1 -US-DFK,92317,GRP_INST,INST_DATE,202005121000 -US-DFK,92317,GRP_INST,INST_DATE_UNC,0 -US-DFK,92317,GRP_INST,INST_COMMENT,CS655 Water Content Reflectometer Plus (8 cm) -US-DFK,92317,GRP_INST,INST_SAMPLING_INT,5 -US-DFK,92317,GRP_INST,INST_AVERAGING_INT,5 -US-DFK,92317,GRP_INST,INST_HEAT,Unheated -US-DFK,92317,GRP_INST,INST_ASPIRATION,None -US-DFK,92317,GRP_INST,INST_SA_OFFSET_NORTH,0 -US-DFK,92320,GRP_INST,INST_MODEL,SWC-Other -US-DFK,92320,GRP_INST,INST_SN,25471-243-2 -US-DFK,92320,GRP_INST,INST_DATE,202005121000 -US-DFK,92320,GRP_INST,INST_DATE_UNC,0 -US-DFK,92320,GRP_INST,INST_COMMENT,CS655 Water Content Reflectometer Plus (8 cm) -US-DFK,92320,GRP_INST,INST_SAMPLING_INT,5 -US-DFK,92320,GRP_INST,INST_AVERAGING_INT,5 -US-DFK,92320,GRP_INST,INST_HEAT,Unheated -US-DFK,92320,GRP_INST,INST_ASPIRATION,None -US-DFK,92320,GRP_INST,INST_SA_OFFSET_NORTH,180 -US-DFK,88073,GRP_INST,INST_MODEL,RAD-Pyrrad-SW+LW -US-DFK,88073,GRP_INST,INST_SN,26003-15 -US-DFK,88073,GRP_INST,INST_DATE,201812141300 -US-DFK,88073,GRP_INST,INST_DATE_UNC,0 -US-DFK,88073,GRP_INST,INST_COMMENT,Kipp & Zonen 4-Component -US-DFK,88073,GRP_INST,INST_SAMPLING_INT,5 -US-DFK,88073,GRP_INST,INST_AVERAGING_INT,5 -US-DFK,88073,GRP_INST,INST_HEAT,Heated -US-DFK,88073,GRP_INST,INST_SHIELDING,None -US-DFK,88073,GRP_INST,INST_ASPIRATION,None -US-DFK,88073,GRP_INST,INST_SA_OFFSET_NORTH,180 -US-DFK,88071,GRP_INST,INST_MODEL,GA_OP_SA-Campbell IRGASON -US-DFK,88071,GRP_INST,INST_SN,27350-1 -US-DFK,88071,GRP_INST,INST_DATE,201812141300 -US-DFK,88071,GRP_INST,INST_DATE_UNC,0 -US-DFK,88071,GRP_INST,INST_FIRMWARE,v1.03.01 -US-DFK,88071,GRP_INST,INST_SAMPLING_INT,0.1 -US-DFK,88071,GRP_INST,INST_AVERAGING_INT,0.1 -US-DFK,88071,GRP_INST,INST_HEAT,Unheated -US-DFK,88071,GRP_INST,INST_SHIELDING,None -US-DFK,88071,GRP_INST,INST_ASPIRATION,None -US-DFK,88071,GRP_INST,INST_SA_OFFSET_NORTH,306 -US-DFK,88071,GRP_INST,INST_SA_WIND_FORMAT,"U, V, W" -US-DFK,88070,GRP_INST,INST_MODEL,RAD-PAR Quantum -US-DFK,88070,GRP_INST,INST_SN,31982-61 -US-DFK,88070,GRP_INST,INST_DATE,201812141300 -US-DFK,88070,GRP_INST,INST_DATE_UNC,0 -US-DFK,88070,GRP_INST,INST_COMMENT,LI-COR -US-DFK,88070,GRP_INST,INST_SAMPLING_INT,5 -US-DFK,88070,GRP_INST,INST_AVERAGING_INT,5 -US-DFK,88070,GRP_INST,INST_HEAT,Unheated -US-DFK,88070,GRP_INST,INST_SHIELDING,None -US-DFK,88070,GRP_INST,INST_ASPIRATION,None -US-DFK,88070,GRP_INST,INST_SA_OFFSET_NORTH,180 -US-DFK,92309,GRP_INST,INST_MODEL,TEMP-Other -US-DFK,92309,GRP_INST,INST_SN,8731-4-1 -US-DFK,92309,GRP_INST,INST_DATE,202005071000 -US-DFK,92309,GRP_INST,INST_DATE_UNC,0 -US-DFK,92309,GRP_INST,INST_COMMENT,"Averaging Soil TC Probe TCAV (0.5, 5.5, 10.5, 15.5 cm)" -US-DFK,92309,GRP_INST,INST_SAMPLING_INT,5 -US-DFK,92309,GRP_INST,INST_AVERAGING_INT,5 -US-DFK,92309,GRP_INST,INST_HEAT,Unheated -US-DFK,92309,GRP_INST,INST_ASPIRATION,None -US-DFK,92309,GRP_INST,INST_SA_OFFSET_NORTH,0 -US-DFK,92312,GRP_INST,INST_MODEL,TEMP-Other -US-DFK,92312,GRP_INST,INST_SN,8731-4-2 -US-DFK,92312,GRP_INST,INST_DATE,202005071000 -US-DFK,92312,GRP_INST,INST_DATE_UNC,0 -US-DFK,92312,GRP_INST,INST_COMMENT,"Averaging Soil TC Probe TCAV (0.5, 5.5, 10.5, 15.5 cm)" -US-DFK,92312,GRP_INST,INST_SAMPLING_INT,5 -US-DFK,92312,GRP_INST,INST_AVERAGING_INT,5 -US-DFK,92312,GRP_INST,INST_HEAT,Unheated -US-DFK,92312,GRP_INST,INST_ASPIRATION,None -US-DFK,92312,GRP_INST,INST_SA_OFFSET_NORTH,180 -US-DFK,87345,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -US-DFK,87345,GRP_LAND_OWNERSHIP,LAND_OWNER,US Department of Agriculture -US-DFK,87343,GRP_LOCATION,LOCATION_LAT,43.3453 -US-DFK,87343,GRP_LOCATION,LOCATION_LONG,-89.7154 -US-DFK,87343,GRP_LOCATION,LOCATION_ELEV,210 -US-DFK,87343,GRP_LOCATION,LOCATION_DATE_START,1980 -US-DFK,87336,GRP_NETWORK,NETWORK,AmeriFlux -US-DFK,87341,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,This tower is located in an intermediate wheatgrass cropfield to measure carbon and energy exchanges relative to annual counterparts -US-DFK,87335,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"Room 1549 Atmospheric and Oceanic Sciences building, 1225 W Dayton Street -Madison, WI 53706 USA" -US-DFK,87349,GRP_SITE_CHAR,TERRAIN,Gentle slope (<2 %) -US-DFK,87349,GRP_SITE_CHAR,ASPECT,WSW -US-DFK,87349,GRP_SITE_CHAR,WIND_DIRECTION,SW -US-DFK,87349,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,200 -US-DFK,87349,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,100 -US-DFK,87340,GRP_SITE_DESC,SITE_DESC,alfalfa field prior to intermediate wheatgrass planting -US-DFK,87342,GRP_SITE_FUNDING,SITE_FUNDING,"Patagonia provisions, US Department of Agriculture" -US-DFK,87339,GRP_STATE,STATE,WI -US-DFK,87333,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Alison Duff -US-DFK,87333,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-DFK,87333,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,alison.duff@usda.gov -US-DFK,87333,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,US Dairy Forage Research Center -US-DFK,87332,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Ankur Desai -US-DFK,87332,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-DFK,87332,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,desai@aos.wisc.edu -US-DFK,87332,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Wisconsin Madison -US-DFK,87330,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Valentin Picasso Risso -US-DFK,87330,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-DFK,87330,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,picassorisso@wisc.edu -US-DFK,87330,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Wisconsin Madison -US-DFK,91903,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Susanne Wiesner -US-DFK,91903,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,DataManager -US-DFK,91903,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,swiesner2@wisc.edu -US-DFK,91903,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Wisconsin Madison -US-DFK,87334,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Jonathan Thom -US-DFK,87334,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Technician -US-DFK,87334,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,jthom@ssec.wisc.edu -US-DFK,87334,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Wisconsin Madison -US-DFK,87352,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-DFK,87351,GRP_TOWER_TYPE,TOWER_TYPE,tripod -US-DFK,24001083,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-DFK -US-DFK,87347,GRP_UTC_OFFSET,UTC_OFFSET,-6 -US-Dia,11502,GRP_CLIM_AVG,MAT,15.6 -US-Dia,11502,GRP_CLIM_AVG,MAP,265 -US-Dia,11502,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Csa -US-Dia,27000512,GRP_COUNTRY,COUNTRY,USA -US-Dia,15724,GRP_DOI,DOI,10.17190/AMF/1246146 -US-Dia,15724,GRP_DOI,DOI_CITATION,"Sonia Wharton (2016), AmeriFlux BASE US-Dia Diablo, Ver. 1-1, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1246146" -US-Dia,15724,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-Dia,32364,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Dia,32364,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Sonia Wharton -US-Dia,32364,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Dia,32364,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,wharton4@llnl.gov -US-Dia,32364,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Lawrence Livermore National Laboratory -US-Dia,32366,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Lawrence Livermore National Laboratory -US-Dia,32366,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-Dia,32365,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,DOE -US-Dia,32365,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-Dia,30450,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Dia,30450,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-Dia,30450,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20101014 -US-Dia,30450,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20150923 -US-Dia,30450,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Dia,23000512,GRP_HEADER,SITE_NAME,Diablo -US-Dia,11504,GRP_IGBP,IGBP,GRA -US-Dia,11505,GRP_LOCATION,LOCATION_LAT,37.6773 -US-Dia,11505,GRP_LOCATION,LOCATION_LONG,-121.5296 -US-Dia,11505,GRP_LOCATION,LOCATION_ELEV,323 -US-Dia,11505,GRP_LOCATION,LOCATION_COMMENT,From CDIAC Tom Boden database dump -US-Dia,11506,GRP_NETWORK,NETWORK,AmeriFlux -US-Dia,1700006654,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(5), 108350" -US-Dia,1700006654,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -US-Dia,1700006654,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Dia,1700002196,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"DuBois, S., Desai, A. R., Singh, A., Serbin, S. P., Goulden, M. L., Baldocchi, D. D., Ma, S., Oechel, W. C., Wharton, S., Kruger, E. L., Townsend, P. A. (2018) Using Imaging Spectroscopy To Detect Variation In Terrestrial Ecosystem Productivity Across A Water-Stressed Landscape, Ecological Applications, 28(5), 1313-1324" -US-Dia,1700002196,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/EAP.1733 -US-Dia,1700002196,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Dia,1700006627,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"DuBois, S., Desai, A. R., Singh, A., Serbin, S. P., Goulden, M. L., Baldocchi, D. D., Ma, S., Oechel, W. C., Wharton, S., Kruger, E. L., Townsend, P. A. (2018) Using Imaging Spectroscopy To Detect Variation In Terrestrial Ecosystem Productivity Across A Water-Stressed Landscape, Ecological Applications, 28(5), 1313-1324" -US-Dia,1700006627,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/EAP.1733 -US-Dia,1700006627,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Primary_Citation -US-Dia,30449,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"Drought-effects on carbon fluxes, effects of variable winter precipitation on carbon fluxes, flows in moderate complex terrain, katabatic flows, sea-breeze" -US-Dia,11507,GRP_SITE_CHAR,TERRAIN,Undulated/Variable -US-Dia,11507,GRP_SITE_CHAR,ASPECT,SSW -US-Dia,11507,GRP_SITE_CHAR,WIND_DIRECTION,SSW -US-Dia,11507,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,0 -US-Dia,11508,GRP_SITE_DESC,SITE_DESC,The site is on land owned by Lawrence Livermore National Laboratory (Site 300) and has no grazing or management history since the 1950's except for summer-time burning of selected acres for fire management (not included in the tower footprint). -US-Dia,11509,GRP_SITE_FUNDING,SITE_FUNDING,DOE -US-Dia,11510,GRP_STATE,STATE,CA -US-Dia,11511,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Sonia Wharton -US-Dia,11511,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Dia,11511,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,wharton4@llnl.gov -US-Dia,11511,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Lawrence Livermore National Laboratory -US-Dia,11511,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Atmospheric, Earth and Energy Division, PO Box 808, L-103,Livermore, CA 94551" -US-Dia,29863,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-Dia,11512,GRP_TOWER_TYPE,TOWER_TYPE,tripod -US-Dia,24000512,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-Dia -US-Dia,11513,GRP_UTC_OFFSET,UTC_OFFSET,-8 -US-Dia,11513,GRP_UTC_OFFSET,UTC_OFFSET_COMMENT,Timestamp is Pacific Standard Time -US-Dix,2575,GRP_CLIM_AVG,MAT,11.07 -US-Dix,2575,GRP_CLIM_AVG,MAP,1126.63 -US-Dix,2575,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Cfa -US-Dix,27000356,GRP_COUNTRY,COUNTRY,USA -US-Dix,15629,GRP_DOI,DOI,10.17190/AMF/1246045 -US-Dix,15629,GRP_DOI,DOI_CITATION,"Ken Clark (2016), AmeriFlux BASE US-Dix Fort Dix, Ver. 2-1, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1246045" -US-Dix,15629,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-Dix,32007,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Dix,32007,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Ken Clark -US-Dix,32007,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Dix,32007,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,kennethclark@fs.fed.us -US-Dix,32007,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,USDA Forest Service -US-Dix,32009,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,USDA Forest Service -US-Dix,32009,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-Dix,32008,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,USDA/Forest Service -US-Dix,32008,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-Dix,10163,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Dix,10163,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-Dix,10163,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,2005 -US-Dix,10163,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,2008 -US-Dix,10163,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Dix,23000356,GRP_HEADER,SITE_NAME,Fort Dix -US-Dix,9318,GRP_IGBP,IGBP,MF -US-Dix,7507,GRP_LOCATION,LOCATION_LAT,39.9712 -US-Dix,7507,GRP_LOCATION,LOCATION_LONG,-74.4346 -US-Dix,7507,GRP_LOCATION,LOCATION_ELEV,48 -US-Dix,7218,GRP_NETWORK,NETWORK,AmeriFlux -US-Dix,1700006465,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Baldocchi, D. D., Poindexter, C., Abraha, M., Desai, A. R., Bohrer, G., Arain, M. A., Griffis, T., Blanken, P. D., O'Halloran, T. L., Thomas, R. Q., Zhang, Q., Burns, S. P., Frank, J. M., Christian, D., Brown, S., Black, T. A., Gough, C. M., Law, B. E., Lee, X., Chen, J., Reed, D. E., Massman, W. J., Clark, K., Hatfield, J., Prueger, J., Bracho, R., Baker, J. M., Martin, T. A. (2018) Temporal Dynamics Of Aerodynamic Canopy Height Derived From Eddy Covariance Momentum Flux Data Across North American Flux Networks, Geophysical Research Letters, 45(), 9275–9287" -US-Dix,1700006465,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018GL079306 -US-Dix,1700006465,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Dix,1700002403,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(3), 108350" -US-Dix,1700002403,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -US-Dix,1700002403,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Dix,1700003114,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Clark, K. L., Heilman, W. E., Skowronski, N. S., Gallagher, M. R., Mueller, E., Hadden, R. M., Simeoni, A. (2020) Fire Behavior, Fuel Consumption, And Turbulence And Energy Exchange During Prescribed Fires In Pitch Pine Forests, Atmosphere, 11(3), 25" -US-Dix,1700003114,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.3390/ATMOS11030242 -US-Dix,1700003114,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Dix,5037,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"The research and science objectives of the Fort Dix site are as follows: 1) Characterize net ecosystem productivity (NEP) in oak- and pine-dominated forests that were defoliated by Gypsy moth (Lymantria dispar L.) in the New Jersey Pine Barrens; 2) Investigate the impacts of transient disturbance due to Gypsy moth (Lymantria dispar L.) defoliation; 3) Quantify the extent Gypsy moth defoliation alter patterns of net CO2 exchange at stand and landscape scales; 4) Determine the extent differences in annual productivity in deciduous vs. conifer dominated stands account for the observed patterns of aboveground biomass distribution in these nutrient limited forests; 5) Characterize forest structure and ladder fuels in the New Jersey Pinelands using LIDAR measurements, intensive biometric measurements, and Forest Inventory and Analysis (FIA) data. (Clark et al., 2009a, Skowronski et al., 2007)" -US-Dix,8401,GRP_SITE_DESC,SITE_DESC,"The Fort Dix site is located in the upland forests of the New Jersey Pine Barrens, the largest continuous forested landscape on the Northeastern coastal plain. Upland forests occupy 62% of the 1.1 million acre Pine Barrens and can be divided into three dominant stand types, Oak/Pine (19.1%), Pine/Oak (13.1%), and Pitch Pine/Scrub oak (14.3%). The majority of mature upland forests are the product of regeneration following late 19th century logging and charcoaling activities. Gypsy moths first appeared in the Pine Barrens of New Jersey in 1966. Since the time of arrival, the upland forest stands have undergone several episodes of defoliation, the most significant occurred in 1972, 1981, and 1990. In recent years, the overstory oaks and understory oaks and shrubs of the Fort Dix stand, underwent two periods of defoliation by Gypsy moth, in 2006 and 2007. During these two years, maximum leaf area reached only 70% of the 2005 summer maximum." -US-Dix,5867,GRP_SITE_FUNDING,SITE_FUNDING,USDA/Forest Service -US-Dix,28939,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION,"Podzol, underlain by late Miocene fluvial sediments of the Kirkwood formation, and overlain with Cohansey sandy soil with low nutrient and cation exchange capacity" -US-Dix,28939,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION_TAXONOMY,Other -US-Dix,1490,GRP_STATE,STATE,NJ -US-Dix,2363,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Ken Clark -US-Dix,2363,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Dix,2363,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,kennethclark@fs.fed.us -US-Dix,2363,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,USDA Forest Service -US-Dix,2363,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Silas Little Experimental Forest, P.O. Box 232,New Lisbon, NJ USA 08064" -US-Dix,136,GRP_URL,URL,http://www.fs.fed.us/ne/global/ -US-Dix,24000356,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-Dix -US-Dix,33625,GRP_UTC_OFFSET,UTC_OFFSET,-5 -US-Dix,33625,GRP_UTC_OFFSET,UTC_OFFSET_COMMENT,Added by AMF data processing team for data QAQC checks. -US-Dk1,27969,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,100 -US-Dk1,27969,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Total -US-Dk1,27969,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Dk1,27969,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Dk1,27969,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20010628 -US-Dk1,27969,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,There are no trees and an insignificant number of shrubs in this field. It is mowed annually for hay; biomass was estimated by counting bales and multiplying by measured mass/bale -US-Dk1,27970,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,100 -US-Dk1,27970,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Total -US-Dk1,27970,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Dk1,27970,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Dk1,27970,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20020602 -US-Dk1,27970,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,There are no trees and an insignificant number of shrubs in this field. It is mowed annually for hay; biomass was estimated by counting bales and multiplying by measured mass/bale -US-Dk1,29517,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,100 -US-Dk1,29517,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Total -US-Dk1,29517,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Dk1,29517,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Dk1,29517,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20050901 -US-Dk1,29517,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,There are no trees and an insignificant number of shrubs in this field. It is mowed annually for hay; biomass was estimated by counting bales and multiplying by measured mass/bale -US-Dk1,28320,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,200 -US-Dk1,28320,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Total -US-Dk1,28320,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Dk1,28320,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Dk1,28320,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20040518 -US-Dk1,28320,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,There are no trees and an insignificant number of shrubs in this field. It is mowed annually for hay; biomass was estimated by counting bales and multiplying by measured mass/bale -US-Dk1,29516,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,400 -US-Dk1,29516,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Total -US-Dk1,29516,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Dk1,29516,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Dk1,29516,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20030725 -US-Dk1,29516,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,There are no trees and an insignificant number of shrubs in this field. It is mowed annually for hay; biomass was estimated by counting bales and multiplying by measured mass/bale -US-Dk1,1712,GRP_CLIM_AVG,MAT,14.36 -US-Dk1,1712,GRP_CLIM_AVG,MAP,1169.75 -US-Dk1,1712,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Cfa -US-Dk1,27000357,GRP_COUNTRY,COUNTRY,USA -US-Dk1,1988,GRP_DM_AGRICULTURE,DM_AGRICULTURE,Harvest -US-Dk1,1988,GRP_DM_AGRICULTURE,DM_DATE,20010602 -US-Dk1,1988,GRP_DM_AGRICULTURE,DM_COMMENT,"Harvesting for hay; See Table 2 in: Stoy PC, G.G. Katul, M.B.S. Siqueira, J.Y. Juang, K.A. Novick, H.R. McCarthy, A.C. Oishi, R. Oren, 2008, Role of vegetation in determining carbon sequestration along ecological succession in the southeastern United States, Global Change Biology , 14 (6), 1409-1427" -US-Dk1,2829,GRP_DM_AGRICULTURE,DM_AGRICULTURE,Harvest -US-Dk1,2829,GRP_DM_AGRICULTURE,DM_DATE,20010628 -US-Dk1,2829,GRP_DM_AGRICULTURE,DM_COMMENT,"Harvesting for hay; See Table 2 in: Stoy PC, G.G. Katul, M.B.S. Siqueira, J.Y. Juang, K.A. Novick, H.R. McCarthy, A.C. Oishi, R. Oren, 2008, Role of vegetation in determining carbon sequestration along ecological succession in the southeastern United States, Global Change Biology , 14 (6), 1409-1427" -US-Dk1,307,GRP_DM_AGRICULTURE,DM_AGRICULTURE,Harvest -US-Dk1,307,GRP_DM_AGRICULTURE,DM_DATE,20030725 -US-Dk1,307,GRP_DM_AGRICULTURE,DM_COMMENT,"Harvesting for hay; See Table 2 in: Stoy PC, G.G. Katul, M.B.S. Siqueira, J.Y. Juang, K.A. Novick, H.R. McCarthy, A.C. Oishi, R. Oren, 2008, Role of vegetation in determining carbon sequestration along ecological succession in the southeastern United States, Global Change Biology , 14 (6), 1409-1427" -US-Dk1,2830,GRP_DM_AGRICULTURE,DM_AGRICULTURE,Harvest -US-Dk1,2830,GRP_DM_AGRICULTURE,DM_DATE,20040519 -US-Dk1,2830,GRP_DM_AGRICULTURE,DM_COMMENT,"Harvesting for hay; See Table 2 in: Stoy PC, G.G. Katul, M.B.S. Siqueira, J.Y. Juang, K.A. Novick, H.R. McCarthy, A.C. Oishi, R. Oren, 2008, Role of vegetation in determining carbon sequestration along ecological succession in the southeastern United States, Global Change Biology , 14 (6), 1409-1427" -US-Dk1,5382,GRP_DM_AGRICULTURE,DM_AGRICULTURE,Harvest -US-Dk1,5382,GRP_DM_AGRICULTURE,DM_DATE,20050901 -US-Dk1,5382,GRP_DM_AGRICULTURE,DM_COMMENT,"Harvesting for hay; See Table 2 in: Stoy PC, G.G. Katul, M.B.S. Siqueira, J.Y. Juang, K.A. Novick, H.R. McCarthy, A.C. Oishi, R. Oren, 2008, Role of vegetation in determining carbon sequestration along ecological succession in the southeastern United States, Global Change Biology , 14 (6), 1409-1427" -US-Dk1,1136,GRP_DM_AGRICULTURE,DM_AGRICULTURE,Harvest -US-Dk1,1136,GRP_DM_AGRICULTURE,DM_DATE,20060515 -US-Dk1,1136,GRP_DM_AGRICULTURE,DM_COMMENT,"Harvesting for hay; See Table 2 in: Stoy PC, G.G. Katul, M.B.S. Siqueira, J.Y. Juang, K.A. Novick, H.R. McCarthy, A.C. Oishi, R. Oren, 2008, Role of vegetation in determining carbon sequestration along ecological succession in the southeastern United States, Global Change Biology , 14 (6), 1409-1427" -US-Dk1,6241,GRP_DM_AGRICULTURE,DM_AGRICULTURE,Harvest -US-Dk1,6241,GRP_DM_AGRICULTURE,DM_DATE,20060925 -US-Dk1,6241,GRP_DM_AGRICULTURE,DM_COMMENT,"Harvesting for hay; See Table 2 in: Stoy PC, G.G. Katul, M.B.S. Siqueira, J.Y. Juang, K.A. Novick, H.R. McCarthy, A.C. Oishi, R. Oren, 2008, Role of vegetation in determining carbon sequestration along ecological succession in the southeastern United States, Global Change Biology , 14 (6), 1409-1427" -US-Dk1,8794,GRP_DM_AGRICULTURE,DM_AGRICULTURE,Harvest -US-Dk1,8794,GRP_DM_AGRICULTURE,DM_DATE,20070525 -US-Dk1,8794,GRP_DM_AGRICULTURE,DM_COMMENT,"Harvesting for hay; See Table 2 in: Stoy PC, G.G. Katul, M.B.S. Siqueira, J.Y. Juang, K.A. Novick, H.R. McCarthy, A.C. Oishi, R. Oren, 2008, Role of vegetation in determining carbon sequestration along ecological succession in the southeastern United States, Global Change Biology , 14 (6), 1409-1427" -US-Dk1,15670,GRP_DOI,DOI,10.17190/AMF/1246046 -US-Dk1,15670,GRP_DOI,DOI_CITATION,"Chris Oishi, Kim Novick, Paul Stoy (2018), AmeriFlux BASE US-Dk1 Duke Forest-open field, Ver. 4-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1246046" -US-Dk1,15670,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-Dk1,32010,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Dk1,32010,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Chris Oishi -US-Dk1,32010,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Dk1,32010,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,christopher.oishi@gmail.com -US-Dk1,32010,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,USDA Forest Service -US-Dk1,32011,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Dk1,32011,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Kim Novick -US-Dk1,32011,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Dk1,32011,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,knovick@indiana.edu -US-Dk1,32011,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Indiana University -US-Dk1,32012,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Dk1,32012,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Paul Stoy -US-Dk1,32012,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Dk1,32012,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,paul.stoy@montana.edu -US-Dk1,32012,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Montana State University -US-Dk1,32014,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Indiana University -US-Dk1,32014,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-Dk1,32015,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Montana State University -US-Dk1,32015,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-Dk1,32016,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,USDA Forest Service -US-Dk1,32016,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-Dk1,32013,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,DOE/TCP -US-Dk1,32013,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-Dk1,3365,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Agriculture -US-Dk1,79233,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Dk1,79233,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-Dk1,79233,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,2001 -US-Dk1,79233,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,2008 -US-Dk1,79233,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Dk1,23000357,GRP_HEADER,SITE_NAME,Duke Forest-open field -US-Dk1,29166,GRP_HEIGHTC,HEIGHTC,0.55 -US-Dk1,29166,GRP_HEIGHTC,HEIGHTC_COMMENT,(range 0.1-1) variable; Dependent on phenology and date of mow. -US-Dk1,1133,GRP_IGBP,IGBP,GRA -US-Dk1,6234,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -US-Dk1,6234,GRP_LAND_OWNERSHIP,LAND_OWNER,Duke Forest -US-Dk1,29518,GRP_LMA,LMA,100.85 -US-Dk1,29518,GRP_LMA,LMA_SPP,(All) -US-Dk1,29518,GRP_LMA,LMA_COMMENT,"SLA is a composite of all species present in the sample, giving rise to its variability. Area measured on light table (Decagon) and wieghts measured on microbalance. Mass measurements converted to mass C by assuming 50% carbon content" -US-Dk1,28582,GRP_LMA,LMA,26.38 -US-Dk1,28582,GRP_LMA,LMA_SPP,(All) -US-Dk1,28582,GRP_LMA,LMA_COMMENT,"SLA is a composite of all species present in the sample, giving rise to its variability. Area measured on light table (Decagon) and wieghts measured on microbalance. Mass measurements converted to mass C by assuming 50% carbon content" -US-Dk1,29519,GRP_LMA,LMA,48.36 -US-Dk1,29519,GRP_LMA,LMA_SPP,(All) -US-Dk1,29519,GRP_LMA,LMA_COMMENT,"SLA is a composite of all species present in the sample, giving rise to its variability. Area measured on light table (Decagon) and wieghts measured on microbalance. Mass measurements converted to mass C by assuming 50% carbon content" -US-Dk1,27598,GRP_LMA,LMA,59.88 -US-Dk1,27598,GRP_LMA,LMA_SPP,(All) -US-Dk1,27598,GRP_LMA,LMA_COMMENT,"SLA is a composite of all species present in the sample, giving rise to its variability. Area measured on light table (Decagon) and wieghts measured on microbalance. Mass measurements converted to mass C by assuming 50% carbon content" -US-Dk1,27971,GRP_LMA,LMA,62.47 -US-Dk1,27971,GRP_LMA,LMA_SPP,(All) -US-Dk1,27971,GRP_LMA,LMA_COMMENT,"SLA is a composite of all species present in the sample, giving rise to its variability. Area measured on light table (Decagon) and wieghts measured on microbalance. Mass measurements converted to mass C by assuming 50% carbon content" -US-Dk1,29050,GRP_LMA,LMA,63.38 -US-Dk1,29050,GRP_LMA,LMA_SPP,(All) -US-Dk1,29050,GRP_LMA,LMA_COMMENT,"SLA is a composite of all species present in the sample, giving rise to its variability. Area measured on light table (Decagon) and wieghts measured on microbalance. Mass measurements converted to mass C by assuming 50% carbon content" -US-Dk1,29051,GRP_LMA,LMA,73.08 -US-Dk1,29051,GRP_LMA,LMA_SPP,(All) -US-Dk1,29051,GRP_LMA,LMA_COMMENT,"SLA is a composite of all species present in the sample, giving rise to its variability. Area measured on light table (Decagon) and wieghts measured on microbalance. Mass measurements converted to mass C by assuming 50% carbon content" -US-Dk1,27056,GRP_LMA,LMA,76.82 -US-Dk1,27056,GRP_LMA,LMA_SPP,(All) -US-Dk1,27056,GRP_LMA,LMA_COMMENT,"SLA is a composite of all species present in the sample, giving rise to its variability. Area measured on light table (Decagon) and wieghts measured on microbalance. Mass measurements converted to mass C by assuming 50% carbon content" -US-Dk1,26905,GRP_LMA,LMA,79.78 -US-Dk1,26905,GRP_LMA,LMA_SPP,(All) -US-Dk1,26905,GRP_LMA,LMA_COMMENT,"SLA is a composite of all species present in the sample, giving rise to its variability. Area measured on light table (Decagon) and wieghts measured on microbalance. Mass measurements converted to mass C by assuming 50% carbon content" -US-Dk1,29049,GRP_LMA,LMA,82.63 -US-Dk1,29049,GRP_LMA,LMA_SPP,(All) -US-Dk1,29049,GRP_LMA,LMA_COMMENT,"SLA is a composite of all species present in the sample, giving rise to its variability. Area measured on light table (Decagon) and wieghts measured on microbalance. Mass measurements converted to mass C by assuming 50% carbon content" -US-Dk1,6039,GRP_LOCATION,LOCATION_LAT,35.9712 -US-Dk1,6039,GRP_LOCATION,LOCATION_LONG,-79.0934 -US-Dk1,6039,GRP_LOCATION,LOCATION_ELEV,168 -US-Dk1,3813,GRP_NETWORK,NETWORK,AmeriFlux -US-Dk1,1700005787,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Bond-Lamberty, B., Wang, C., Gower, S. T. (2004) A Global Relationship Between The Heterotrophic And Autotrophic Components Of Soil Respiration?, Global Change Biology, 10(10), 1756-1766" -US-Dk1,1700005787,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/J.1365-2486.2004.00816.X -US-Dk1,1700005787,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Dk1,1700001005,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(11), 108350" -US-Dk1,1700001005,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -US-Dk1,1700001005,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Dk1,1700007650,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Ellsworth, D. S., Reich, P. B., Naumburg, E. S., Koch, G. W., Kubiske, M. E., Smith, S. D. (2004) Photosynthesis, Carboxylation And Leaf Nitrogen Responses Of 16 Species To Elevated pCO2 Across Four Free-Air CO2 Enrichment Experiments In Forest, Grassland And Desert, Global Change Biology, 10(12), 2121-2138" -US-Dk1,1700007650,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/J.1365-2486.2004.00867.X -US-Dk1,1700007650,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Dk1,1700002685,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Katul, G., Leuning, R., Oren, R. (2003) Relationship Between Plant Hydraulic And Biochemical Properties Derived From A Steady-State Coupled Water And Carbon Transport Model, Plant, Cell And Environment, 26(3), 339-350" -US-Dk1,1700002685,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1046/J.1365-3040.2003.00965.X -US-Dk1,1700002685,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Dk1,1700001203,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Novick, K. A., Ficklin, D. L., Stoy, P. C., Williams, C. A., Bohrer, G., Oishi, A., Papuga, S. A., Blanken, P. D., Noormets, A., Sulman, B. N., Scott, R. L., Wang, L., Phillips, R. P. (2016) The Increasing Importance Of Atmospheric Demand For Ecosystem Water And Carbon Fluxes, Nature Climate Change, 6(11), 1023-1027" -US-Dk1,1700001203,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1038/NCLIMATE3114 -US-Dk1,1700001203,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Dk1,1700006735,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Oren, R., Hsieh, C., Stoy, P., Albertson, J., Mccarthy, H. R., Harrell, P., Katul, G. G. (2006) Estimating The Uncertainty In Annual Net Ecosystem Carbon Exchange: Spatial Variation In Turbulent Fluxes And Sampling Errors In Eddy-Covariance Measurements, Global Change Biology, 12(5), 883-896" -US-Dk1,1700006735,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/J.1365-2486.2006.01131.X -US-Dk1,1700006735,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Dk1,1700002109,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Zhang, Q., Barnes, M., Benson, M., Burakowski, E., Oishi, A. C., Ouimette, A., Sanders‐DeMott, R., Stoy, P. C., Wenzel, M., Xiong, L., Yi, K., Novick, K. A. (2020) Reforestation And Surface Cooling In Temperate Zones: Mechanisms And Implications, Global Change Biology, 26(6), 3384-3401" -US-Dk1,1700002109,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/GCB.15069 -US-Dk1,1700002109,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Dk1,7536,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"The research and science objectives of the Duke Forest Open Field site are as follows: 1) Examine ecological roles of vegetation and climate in controlling long-term carbon exchange; 2) Determine the contribution of vegetation from that of climate and soils on controlling ET at three adjacent SE Piedmont ecosystems, namely the three Duke Forest Sites, US-Dk1, US-Dk2, and US-Dk3; 3) Assess the magnitude and direction of NEE and its components, carbon assimilation and respiration, in a southeastern United States warm-temperate grassland ecosystem, and to assess NEE and ET responses to episodic droughts and harvests. (Stoy et al., 2008, Stoy et al., 2006, Novick et al., 2004)" -US-Dk1,29048,GRP_SA,SA_COMMENT,The site is harvested at least once per year. The age distribution of the root system is unknown. -US-Dk1,29048,GRP_SA,SA_MAX,1 -US-Dk1,29515,GRP_SA,SA,1 -US-Dk1,29515,GRP_SA,SA_COMMENT,"See http://face.env.duke.edu/sitehistory.cfm. Johnston tract, purchased May 26, 1944. Northern area partially burned in 1951, apparent wildfire. Eastern portion clear-cut 1963-64. Western section thinned 1964-65. Central portion cleared in 1978/79. Outer perimeter of field cleared in 1980. Prescribe-burned 1989 and 1991. Mowed at least once per year since 1992" -US-Dk1,5852,GRP_SITE_CHAR,TERRAIN,Gentle slope (<2 %) -US-Dk1,7949,GRP_SITE_DESC,SITE_DESC,"The Duke Forest grass field is approximately 480×305 m, dominated by the C3 grass Festuca arundinacea Shreb. (tall fescue) includes minor components of C3 herbs and the C4 grass Schizachyrium scoparium (Michx.) Nash, not considered here. The site was burned in 1979 and is mowed annually during the summer for hay according to local practices. Lai, C.T. and G.G. Katul, 2000, ""The dynamic role of root-water uptake in coupling potential to actual transpiration"" , Advances in Water Resources, 23, 427-439; Novick , K.A., P. C. Stoy, G. G. Katul, D. S. Ellsworth, M. B. S. Siqueira, J. Juang, R. Oren, 2004, Carbon dioxide and water vapor exchange in a warm temperate grassland, Oecologia, 138, 259-274; Stoy PC, Katul GG, Siqueira MBS, Juang J-Y, McCarthy HR, Oishi AC, Uebelherr JM, Kim H-S, Oren R (2006). Separating the effects of climate and vegetation on evapotranspiration along a successional chronosequence in the southeastern U.S. Global Change Biology 12:2115-2135" -US-Dk1,10141,GRP_SITE_FUNDING,SITE_FUNDING,DOE/TCP -US-Dk1,28092,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION,"Enon Series, low-fertility, acidic Hapludalf. An imprevious clay pan is located beneath all soils at a depth of 0.30 m." -US-Dk1,28092,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION_TAXONOMY,Other -US-Dk1,27059,GRP_SOIL_DEPTH,SOIL_DEPTH,3000 -US-Dk1,27059,GRP_SOIL_DEPTH,SOIL_DEPTH_COMMENT,A clay-pan underlies the entire Blackwood division of the Duke forest at 30 cm. -US-Dk1,27058,GRP_SOIL_TEX,SOIL_TEX_SAND,25.5 -US-Dk1,26756,GRP_SOIL_TEX,SOIL_TEX_SAND,35.5 -US-Dk1,26757,GRP_SOIL_TEX,SOIL_TEX_SAND,44 -US-Dk1,28584,GRP_SOIL_TEX,SOIL_TEX_SAND,47.6 -US-Dk1,28583,GRP_SOIL_TEX,SOIL_TEX_SAND,48.4 -US-Dk1,27352,GRP_SOIL_TEX,SOIL_TEX_SAND,50.3 -US-Dk1,26906,GRP_SOIL_TEX,SOIL_TEX_SAND,55.1 -US-Dk1,28819,GRP_SOIL_TEX,SOIL_TEX_SAND,61 -US-Dk1,27060,GRP_SOIL_TEX,SOIL_TEX_SAND,63.8 -US-Dk1,27599,GRP_SOIL_TEX,SOIL_TEX_SAND,67.4 -US-Dk1,29168,GRP_SOIL_TEX,SOIL_TEX_SAND,68.9 -US-Dk1,26758,GRP_SOIL_TEX,SOIL_TEX_SILT,26.6 -US-Dk1,26759,GRP_SOIL_TEX,SOIL_TEX_SILT,27.2 -US-Dk1,26908,GRP_SOIL_TEX,SOIL_TEX_SILT,27.5 -US-Dk1,26907,GRP_SOIL_TEX,SOIL_TEX_SILT,29.4 -US-Dk1,26906,GRP_SOIL_TEX,SOIL_TEX_SILT,32.3 -US-Dk1,26757,GRP_SOIL_TEX,SOIL_TEX_SILT,37.6 -US-Dk1,28584,GRP_SOIL_TEX,SOIL_TEX_SILT,38.5 -US-Dk1,26756,GRP_SOIL_TEX,SOIL_TEX_SILT,40.1 -US-Dk1,27352,GRP_SOIL_TEX,SOIL_TEX_SILT,40.1 -US-Dk1,27058,GRP_SOIL_TEX,SOIL_TEX_SILT,40.3 -US-Dk1,28583,GRP_SOIL_TEX,SOIL_TEX_SILT,43.3 -US-Dk1,26906,GRP_SOIL_TEX,SOIL_TEX_CLAY,12.6 -US-Dk1,28584,GRP_SOIL_TEX,SOIL_TEX_CLAY,14.2 -US-Dk1,26757,GRP_SOIL_TEX,SOIL_TEX_CLAY,18.4 -US-Dk1,26756,GRP_SOIL_TEX,SOIL_TEX_CLAY,24.4 -US-Dk1,27058,GRP_SOIL_TEX,SOIL_TEX_CLAY,34.2 -US-Dk1,29522,GRP_SOIL_TEX,SOIL_TEX_CLAY,4 -US-Dk1,26909,GRP_SOIL_TEX,SOIL_TEX_CLAY,6 -US-Dk1,28583,GRP_SOIL_TEX,SOIL_TEX_CLAY,8.6 -US-Dk1,28820,GRP_SOIL_TEX,SOIL_TEX_CLAY,8.7 -US-Dk1,26760,GRP_SOIL_TEX,SOIL_TEX_CLAY,9.6 -US-Dk1,27352,GRP_SOIL_TEX,SOIL_TEX_CLAY,9.6 -US-Dk1,28321,GRP_SOIL_TEX,SOIL_TEX_WATER_HOLD_CAP,0.52 -US-Dk1,28321,GRP_SOIL_TEX,SOIL_TEX_PROFILE_MIN,0 -US-Dk1,28321,GRP_SOIL_TEX,SOIL_TEX_PROFILE_MAX,30 -US-Dk1,28583,GRP_SOIL_TEX,SOIL_TEX_HORIZON,A -US-Dk1,27352,GRP_SOIL_TEX,SOIL_TEX_HORIZON,AE -US-Dk1,26756,GRP_SOIL_TEX,SOIL_TEX_HORIZON,B -US-Dk1,26757,GRP_SOIL_TEX,SOIL_TEX_HORIZON,BC -US-Dk1,28584,GRP_SOIL_TEX,SOIL_TEX_HORIZON,BE -US-Dk1,27058,GRP_SOIL_TEX,SOIL_TEX_HORIZON,Bt -US-Dk1,26758,GRP_SOIL_TEX,SOIL_TEX_HORIZON,C -US-Dk1,26759,GRP_SOIL_TEX,SOIL_TEX_HORIZON,C -US-Dk1,26760,GRP_SOIL_TEX,SOIL_TEX_HORIZON,C -US-Dk1,26907,GRP_SOIL_TEX,SOIL_TEX_HORIZON,C -US-Dk1,26908,GRP_SOIL_TEX,SOIL_TEX_HORIZON,C -US-Dk1,26909,GRP_SOIL_TEX,SOIL_TEX_HORIZON,C -US-Dk1,27060,GRP_SOIL_TEX,SOIL_TEX_HORIZON,C -US-Dk1,27599,GRP_SOIL_TEX,SOIL_TEX_HORIZON,C -US-Dk1,28819,GRP_SOIL_TEX,SOIL_TEX_HORIZON,C -US-Dk1,28820,GRP_SOIL_TEX,SOIL_TEX_HORIZON,C -US-Dk1,29168,GRP_SOIL_TEX,SOIL_TEX_HORIZON,C -US-Dk1,29522,GRP_SOIL_TEX,SOIL_TEX_HORIZON,C -US-Dk1,26906,GRP_SOIL_TEX,SOIL_TEX_HORIZON,CB -US-Dk1,26756,GRP_SOIL_TEX,SOIL_TEX_COMMENT,"Oh, N.H. and D.D. Richter. Elemental translocation and loss from three highly weathered soil-bedrock profiles in the southeastern United States. Geoderma 126 (5-25)" -US-Dk1,26757,GRP_SOIL_TEX,SOIL_TEX_COMMENT,"Oh, N.H. and D.D. Richter. Elemental translocation and loss from three highly weathered soil-bedrock profiles in the southeastern United States. Geoderma 126 (5-25)" -US-Dk1,26758,GRP_SOIL_TEX,SOIL_TEX_COMMENT,"Oh, N.H. and D.D. Richter. Elemental translocation and loss from three highly weathered soil-bedrock profiles in the southeastern United States. Geoderma 126 (5-25)" -US-Dk1,26759,GRP_SOIL_TEX,SOIL_TEX_COMMENT,"Oh, N.H. and D.D. Richter. Elemental translocation and loss from three highly weathered soil-bedrock profiles in the southeastern United States. Geoderma 126 (5-25)" -US-Dk1,26760,GRP_SOIL_TEX,SOIL_TEX_COMMENT,"Oh, N.H. and D.D. Richter. Elemental translocation and loss from three highly weathered soil-bedrock profiles in the southeastern United States. Geoderma 126 (5-25)" -US-Dk1,26906,GRP_SOIL_TEX,SOIL_TEX_COMMENT,"Oh, N.H. and D.D. Richter. Elemental translocation and loss from three highly weathered soil-bedrock profiles in the southeastern United States. Geoderma 126 (5-25)" -US-Dk1,26907,GRP_SOIL_TEX,SOIL_TEX_COMMENT,"Oh, N.H. and D.D. Richter. Elemental translocation and loss from three highly weathered soil-bedrock profiles in the southeastern United States. Geoderma 126 (5-25)" -US-Dk1,26908,GRP_SOIL_TEX,SOIL_TEX_COMMENT,"Oh, N.H. and D.D. Richter. Elemental translocation and loss from three highly weathered soil-bedrock profiles in the southeastern United States. Geoderma 126 (5-25)" -US-Dk1,26909,GRP_SOIL_TEX,SOIL_TEX_COMMENT,"Oh, N.H. and D.D. Richter. Elemental translocation and loss from three highly weathered soil-bedrock profiles in the southeastern United States. Geoderma 126 (5-25)" -US-Dk1,27058,GRP_SOIL_TEX,SOIL_TEX_COMMENT,"Oh, N.H. and D.D. Richter. Elemental translocation and loss from three highly weathered soil-bedrock profiles in the southeastern United States. Geoderma 126 (5-25)" -US-Dk1,27060,GRP_SOIL_TEX,SOIL_TEX_COMMENT,"Oh, N.H. and D.D. Richter. Elemental translocation and loss from three highly weathered soil-bedrock profiles in the southeastern United States. Geoderma 126 (5-25)" -US-Dk1,27352,GRP_SOIL_TEX,SOIL_TEX_COMMENT,"Oh, N.H. and D.D. Richter. Elemental translocation and loss from three highly weathered soil-bedrock profiles in the southeastern United States. Geoderma 126 (5-25)" -US-Dk1,27599,GRP_SOIL_TEX,SOIL_TEX_COMMENT,"Oh, N.H. and D.D. Richter. Elemental translocation and loss from three highly weathered soil-bedrock profiles in the southeastern United States. Geoderma 126 (5-25)" -US-Dk1,28583,GRP_SOIL_TEX,SOIL_TEX_COMMENT,"Oh, N.H. and D.D. Richter. Elemental translocation and loss from three highly weathered soil-bedrock profiles in the southeastern United States. Geoderma 126 (5-25)" -US-Dk1,28584,GRP_SOIL_TEX,SOIL_TEX_COMMENT,"Oh, N.H. and D.D. Richter. Elemental translocation and loss from three highly weathered soil-bedrock profiles in the southeastern United States. Geoderma 126 (5-25)" -US-Dk1,28819,GRP_SOIL_TEX,SOIL_TEX_COMMENT,"Oh, N.H. and D.D. Richter. Elemental translocation and loss from three highly weathered soil-bedrock profiles in the southeastern United States. Geoderma 126 (5-25)" -US-Dk1,28820,GRP_SOIL_TEX,SOIL_TEX_COMMENT,"Oh, N.H. and D.D. Richter. Elemental translocation and loss from three highly weathered soil-bedrock profiles in the southeastern United States. Geoderma 126 (5-25)" -US-Dk1,29168,GRP_SOIL_TEX,SOIL_TEX_COMMENT,"Oh, N.H. and D.D. Richter. Elemental translocation and loss from three highly weathered soil-bedrock profiles in the southeastern United States. Geoderma 126 (5-25)" -US-Dk1,29522,GRP_SOIL_TEX,SOIL_TEX_COMMENT,"Oh, N.H. and D.D. Richter. Elemental translocation and loss from three highly weathered soil-bedrock profiles in the southeastern United States. Geoderma 126 (5-25)" -US-Dk1,29165,GRP_SPP_O,SPP_O,SCPH (NRCS plant code) -US-Dk1,29165,GRP_SPP_O,SPP_COMMENT,"SCPH (FEAR3); variable; Festuca arundinacea Shreb. (tall fescue, i.e. Schedonorus phoenix [Scop.]) with mix of C3/C4 grasses and forbs. Composition variable depending on season, time since mow, and drought." -US-Dk1,5754,GRP_STATE,STATE,NC -US-Dk1,12682,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Chris Oishi -US-Dk1,12682,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Dk1,12682,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,christopher.oishi@gmail.com -US-Dk1,12682,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,USDA Forest Service -US-Dk1,12681,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Kim Novick -US-Dk1,12681,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Dk1,12681,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,knovick@indiana.edu -US-Dk1,12681,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Indiana University -US-Dk1,12683,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Paul Stoy -US-Dk1,12683,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Dk1,12683,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,paul.stoy@montana.edu -US-Dk1,12683,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Montana State University -US-Dk1,79232,GRP_TOWER_TYPE,TOWER_TYPE,walk-up -US-Dk1,5883,GRP_URL,URL,http://www.nicholas.duke.edu/other/AMERIFLUX/amerflux.html -US-Dk1,24000357,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-Dk1 -US-Dk1,33626,GRP_UTC_OFFSET,UTC_OFFSET,-5 -US-Dk1,33626,GRP_UTC_OFFSET,UTC_OFFSET_COMMENT,Added by AMF data processing team for data QAQC checks. -US-Dk2,24270,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,0 -US-Dk2,24270,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Fruits -US-Dk2,24270,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Dk2,24270,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Dk2,24270,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20021007 -US-Dk2,24270,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,Estimated based on allometric equations for DBH (Clark et al. 2006) -US-Dk2,25545,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,0 -US-Dk2,25545,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Total -US-Dk2,25545,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Dk2,25545,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Dk2,25545,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20021007 -US-Dk2,25545,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,Estimated based on allometric equations for DBH (Clark et al. 2006) -US-Dk2,26050,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,0 -US-Dk2,26050,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Dk2,26050,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Dk2,26050,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Dk2,26050,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20021007 -US-Dk2,26050,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,Estimated based on allometric equations for DBH (Clark et al. 2006) -US-Dk2,23874,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB,0 -US-Dk2,23874,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_ORGAN,Wood -US-Dk2,23874,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_PHEN,Mixed/unknown -US-Dk2,23874,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_UNIT,gC m-2 -US-Dk2,23874,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_DATE,20021007 -US-Dk2,23874,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_COMMENT,Estimated based on allometric equations for DBH (Clark et al. 2006) -US-Dk2,23875,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB,0 -US-Dk2,23875,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_ORGAN,Total -US-Dk2,23875,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_PHEN,Mixed/unknown -US-Dk2,23875,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_UNIT,gC m-2 -US-Dk2,23875,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_DATE,20021007 -US-Dk2,23875,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_COMMENT,Estimated based on allometric equations for DBH (Clark et al. 2006) -US-Dk2,25025,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB,0 -US-Dk2,25025,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_ORGAN,Foliage -US-Dk2,25025,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_PHEN,Mixed/unknown -US-Dk2,25025,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_UNIT,gC m-2 -US-Dk2,25025,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_DATE,20021007 -US-Dk2,25025,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_COMMENT,Estimated based on allometric equations for DBH (Clark et al. 2006) -US-Dk2,24114,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,0 -US-Dk2,24114,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Total -US-Dk2,24114,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-Dk2,24114,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-Dk2,24114,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,20021007 -US-Dk2,24114,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,Estimated based on allometric equations for DBH (Clark et al. 2006) -US-Dk2,25156,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,18000 -US-Dk2,25156,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Wood -US-Dk2,25156,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-Dk2,25156,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-Dk2,25156,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,20021007 -US-Dk2,25156,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,Estimated based on allometric equations for DBH (Clark et al. 2006) -US-Dk2,24118,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS,480 -US-Dk2,24118,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_UNIT,gC m-2 -US-Dk2,24118,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_DATE,2005 -US-Dk2,24118,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_COMMENT,"Measured with litter baskets, annual sum of dry weight (not C)" -US-Dk2,25026,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS,480 -US-Dk2,25026,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_UNIT,gC m-2 -US-Dk2,25026,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_DATE,2002 -US-Dk2,25026,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_COMMENT,"Measured with litter baskets, annual sum of dry weight (not C)" -US-Dk2,25027,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS,480 -US-Dk2,25027,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_UNIT,gC m-2 -US-Dk2,25027,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_DATE,2003 -US-Dk2,25027,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_COMMENT,"Measured with litter baskets, annual sum of dry weight (not C)" -US-Dk2,25546,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS,480 -US-Dk2,25546,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_UNIT,gC m-2 -US-Dk2,25546,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_DATE,2004 -US-Dk2,25546,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_COMMENT,"Measured with litter baskets, annual sum of dry weight (not C)" -US-Dk2,25159,GRP_AG_PROD_TREE,AG_PROD_TREE,0 -US-Dk2,25159,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Total -US-Dk2,25159,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-Dk2,2576,GRP_CLIM_AVG,MAT,14.36 -US-Dk2,2576,GRP_CLIM_AVG,MAP,1168.69 -US-Dk2,2576,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Cfa -US-Dk2,27000358,GRP_COUNTRY,COUNTRY,USA -US-Dk2,298,GRP_DM_GENERAL,DM_GENERAL,Other -US-Dk2,298,GRP_DM_GENERAL,DM_COMMENT,"No known anthropogenic disturbance has occurred in this forest within 250 m of the tower. There was a private land (non-Duke Forest) clearcut in late Nov. 2002 as discussed in Stoy et al. (2006) AFM. The Dec. 2002 ice storm had minor impacts on the canopy (a few large branches fell), minor compared to Duke Pine, which sustained heavy canoy damage (McCarthy HR, Oren R, Kim HS, Johnsen KH, Maier C, Pritchard SG, Davis MA (2006) Interaction of ice storme and management practices on current carbon sequestration in forests with potential mitigation under future CO2 atmosphere. Journal of Geophysical Research 111 D151037)." -US-Dk2,15637,GRP_DOI,DOI,10.17190/AMF/1246047 -US-Dk2,15637,GRP_DOI,DOI_CITATION,"Chris Oishi, Kim Novick, Paul Stoy (2018), AmeriFlux BASE US-Dk2 Duke Forest-hardwoods, Ver. 4-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1246047" -US-Dk2,15637,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-Dk2,32017,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Dk2,32017,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Chris Oishi -US-Dk2,32017,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Dk2,32017,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,christopher.oishi@gmail.com -US-Dk2,32017,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,USDA Forest Service -US-Dk2,32019,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Dk2,32019,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Kim Novick -US-Dk2,32019,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Dk2,32019,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,knovick@indiana.edu -US-Dk2,32019,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Indiana University -US-Dk2,32018,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Dk2,32018,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Paul Stoy -US-Dk2,32018,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Dk2,32018,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,paul.stoy@montana.edu -US-Dk2,32018,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Montana State University -US-Dk2,32022,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Indiana University -US-Dk2,32022,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-Dk2,32021,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Montana State University -US-Dk2,32021,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-Dk2,32023,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,USDA Forest Service -US-Dk2,32023,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-Dk2,32020,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,DOE/NIGEC -US-Dk2,32020,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-Dk2,79234,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Dk2,79234,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-Dk2,79234,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,2001 -US-Dk2,79234,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,2008 -US-Dk2,79234,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Dk2,23000358,GRP_HEADER,SITE_NAME,Duke Forest-hardwoods -US-Dk2,24519,GRP_HEIGHTC,HEIGHTC,25 -US-Dk2,24519,GRP_HEIGHTC,HEIGHTC_DATE,2006 -US-Dk2,24519,GRP_HEIGHTC,HEIGHTC_COMMENT,Determined by assessing the height of trees growing near the tower -US-Dk2,4465,GRP_IGBP,IGBP,DBF -US-Dk2,4465,GRP_IGBP,IGBP_COMMENT,"There is a transition to MF toward the FACE site (Duke Pine forest). For the purposes of research, the area around the tower should be considered DBF." -US-Dk2,24520,GRP_LAI,LAI_TYPE,LAI -US-Dk2,24520,GRP_LAI,LAI_METHOD,LAI_2000 -US-Dk2,24520,GRP_LAI,LAI_DATE,2006 -US-Dk2,24520,GRP_LAI,LAI_COMMENT,"(maximum) LAI_2000 scaled with literfall mesurements; Oishi AC, Oren R, Stoy PC (2008) Estimating components of forest evapotranspiration: A footprint approach for scaling sap flux measurements. Agricultural and Forest Meteorology 148: 1719:1732" -US-Dk2,24520,GRP_LAI,LAI_TOT,7.03 -US-Dk2,24004,GRP_LMA,LMA,62 -US-Dk2,24004,GRP_LMA,LMA_SPP,LITU (NRCS plant code) -US-Dk2,24004,GRP_LMA,LMA_DATE,2006 -US-Dk2,24004,GRP_LMA,LMA_COMMENT,"Oishi, A.C., Oren, R. and Stoy, P., 2008. Estimating components of forest evapotranspiration: A footprint approach for scaling sap flux measurements Agricultural and Forest Meteorology, In Revision, In Revision." -US-Dk2,24119,GRP_LMA,LMA,62 -US-Dk2,24119,GRP_LMA,LMA_SPP,QUPH (NRCS plant code) -US-Dk2,24119,GRP_LMA,LMA_DATE,2006 -US-Dk2,24119,GRP_LMA,LMA_COMMENT,"Oishi, A.C., Oren, R. and Stoy, P., 2008. Estimating components of forest evapotranspiration: A footprint approach for scaling sap flux measurements Agricultural and Forest Meteorology, In Revision, In Revision." -US-Dk2,25160,GRP_LMA,LMA,73 -US-Dk2,25160,GRP_LMA,LMA_SPP,(All) -US-Dk2,25160,GRP_LMA,LMA_DATE,2006 -US-Dk2,25160,GRP_LMA,LMA_COMMENT,"Oishi, A.C., Oren, R. and Stoy, P., 2008. Estimating components of forest evapotranspiration: A footprint approach for scaling sap flux measurements Agricultural and Forest Meteorology, In Revision, In Revision." -US-Dk2,25031,GRP_LMA,LMA,76 -US-Dk2,25031,GRP_LMA,LMA_SPP,CAAL27 (NRCS plant code) -US-Dk2,25031,GRP_LMA,LMA_DATE,2006 -US-Dk2,25031,GRP_LMA,LMA_COMMENT,"Oishi, A.C., Oren, R. and Stoy, P., 2008. Estimating components of forest evapotranspiration: A footprint approach for scaling sap flux measurements Agricultural and Forest Meteorology, In Revision, In Revision." -US-Dk2,26052,GRP_LMA,LMA,78 -US-Dk2,26052,GRP_LMA,LMA_SPP,QUMI (NRCS plant code) -US-Dk2,26052,GRP_LMA,LMA_DATE,2006 -US-Dk2,26052,GRP_LMA,LMA_COMMENT,"Oishi, A.C., Oren, R. and Stoy, P., 2008. Estimating components of forest evapotranspiration: A footprint approach for scaling sap flux measurements Agricultural and Forest Meteorology, In Revision, In Revision." -US-Dk2,25550,GRP_LMA,LMA,89 -US-Dk2,25550,GRP_LMA,LMA_SPP,QUAL (NRCS plant code) -US-Dk2,25550,GRP_LMA,LMA_DATE,2006 -US-Dk2,25550,GRP_LMA,LMA_COMMENT,"Oishi, A.C., Oren, R. and Stoy, P., 2008. Estimating components of forest evapotranspiration: A footprint approach for scaling sap flux measurements Agricultural and Forest Meteorology, In Revision, In Revision." -US-Dk2,26051,GRP_LMA,LMA,98 -US-Dk2,26051,GRP_LMA,LMA_SPP,LIST2 (NRCS plant code) -US-Dk2,26051,GRP_LMA,LMA_DATE,2006 -US-Dk2,26051,GRP_LMA,LMA_COMMENT,"Oishi, A.C., Oren, R. and Stoy, P., 2008. Estimating components of forest evapotranspiration: A footprint approach for scaling sap flux measurements Agricultural and Forest Meteorology, In Revision, In Revision." -US-Dk2,6680,GRP_LOCATION,LOCATION_LAT,35.9736 -US-Dk2,6680,GRP_LOCATION,LOCATION_LONG,-79.1004 -US-Dk2,6680,GRP_LOCATION,LOCATION_ELEV,168 -US-Dk2,9813,GRP_NETWORK,NETWORK,AmeriFlux -US-Dk2,86962,GRP_NETWORK,NETWORK,Phenocam -US-Dk2,1700004104,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Bond-Lamberty, B., Wang, C., Gower, S. T. (2004) A Global Relationship Between The Heterotrophic And Autotrophic Components Of Soil Respiration?, Global Change Biology, 10(10), 1756-1766" -US-Dk2,1700004104,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/J.1365-2486.2004.00816.X -US-Dk2,1700004104,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Dk2,1700005493,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Butnor, J. R., Johnsen, K. H., Maier, C. A. (2005) Soil Properties Differently Influence Estimates Of Soil CO2 Efflux From Three Chamber-Based Measurement Systems, Biogeochemistry, 73(1), 283-301" -US-Dk2,1700005493,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1007/S10533-004-4022-1 -US-Dk2,1700005493,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Dk2,1700002034,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Baldocchi, D. D., Poindexter, C., Abraha, M., Desai, A. R., Bohrer, G., Arain, M. A., Griffis, T., Blanken, P. D., O'Halloran, T. L., Thomas, R. Q., Zhang, Q., Burns, S. P., Frank, J. M., Christian, D., Brown, S., Black, T. A., Gough, C. M., Law, B. E., Lee, X., Chen, J., Reed, D. E., Massman, W. J., Clark, K., Hatfield, J., Prueger, J., Bracho, R., Baker, J. M., Martin, T. A. (2018) Temporal Dynamics Of Aerodynamic Canopy Height Derived From Eddy Covariance Momentum Flux Data Across North American Flux Networks, Geophysical Research Letters, 45(11), 9275–9287" -US-Dk2,1700002034,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018GL079306 -US-Dk2,1700002034,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Dk2,1700007554,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Baldocchi, D. D., Poindexter, C., Abraha, M., Desai, A. R., Bohrer, G., Arain, M. A., Griffis, T., Blanken, P. D., O'Halloran, T. L., Thomas, R. Q., Zhang, Q., Burns, S. P., Frank, J. M., Christian, D., Brown, S., Black, T. A., Gough, C. M., Law, B. E., Lee, X., Chen, J., Reed, D. E., Massman, W. J., Clark, K., Hatfield, J., Prueger, J., Bracho, R., Baker, J. M., Martin, T. A. (2018) Temporal Dynamics Of Aerodynamic Canopy Height Derived From Eddy Covariance Momentum Flux Data Across North American Flux Networks, Geophysical Research Letters, 45(6), 9275–9287" -US-Dk2,1700007554,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018GL079306 -US-Dk2,1700007554,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Dk2,1700002205,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(11), 108350" -US-Dk2,1700002205,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -US-Dk2,1700002205,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Dk2,1700007482,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Domec, J.C., Ward, E.J., Oishi, A.C., Palmroth, S., Radecki, A., Bell, D.M., Miao, G., Gavazzi, M., Johnson, D.M., King, J.S., McNulty, S.G., Oren, R., Sun, G., Noormets, A. (2015) Conversion of natural forests to managed forest plantations impacts tree response to climatic variable and affects negatively tree resistance to prolonged droughts, Forest Ecology and Management, 355(), 58-71" -US-Dk2,1700007482,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Dk2,1700008508,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Ellsworth, D. S., Reich, P. B., Naumburg, E. S., Koch, G. W., Kubiske, M. E., Smith, S. D. (2004) Photosynthesis, Carboxylation And Leaf Nitrogen Responses Of 16 Species To Elevated pCO2 Across Four Free-Air CO2 Enrichment Experiments In Forest, Grassland And Desert, Global Change Biology, 10(12), 2121-2138" -US-Dk2,1700008508,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/J.1365-2486.2004.00867.X -US-Dk2,1700008508,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Dk2,1700005094,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Guerrieri, R., Belmecheri, S., Ollinger, S. V., Asbjornsen, H., Jennings, K., Xiao, J., Stocker, B. D., Martin, M., Hollinger, D. Y., Bracho-Garrillo, R., Clark, K., Dore, S., Kolb, T., Munger, J. W., Novick, K., Richardson, A. D. (2019) Disentangling The Role Of Photosynthesis And Stomatal Conductance On Rising Forest Water-Use Efficiency, Proceedings Of The National Academy Of Sciences, 116(34), 16909-16914" -US-Dk2,1700005094,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1073/PNAS.1905912116 -US-Dk2,1700005094,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Dk2,1700002709,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Juang, J., Porporato, A., Stoy, P. C., Siqueira, M. S., Oishi, A. C., Detto, M., Kim, H., Katul, G. G. (2007) Hydrologic And Atmospheric Controls On Initiation Of Convective Precipitation Events, Water Resources Research, 43(3), n/a-n/a" -US-Dk2,1700002709,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2006WR004954 -US-Dk2,1700002709,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Dk2,1700004032,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Katul, G., Leuning, R., Oren, R. (2003) Relationship Between Plant Hydraulic And Biochemical Properties Derived From A Steady-State Coupled Water And Carbon Transport Model, Plant, Cell And Environment, 26(3), 339-350" -US-Dk2,1700004032,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1046/J.1365-3040.2003.00965.X -US-Dk2,1700004032,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Dk2,1700008889,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Novick, K. A., Ficklin, D. L., Stoy, P. C., Williams, C. A., Bohrer, G., Oishi, A., Papuga, S. A., Blanken, P. D., Noormets, A., Sulman, B. N., Scott, R. L., Wang, L., Phillips, R. P. (2016) The Increasing Importance Of Atmospheric Demand For Ecosystem Water And Carbon Fluxes, Nature Climate Change, 6(11), 1023-1027" -US-Dk2,1700008889,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1038/NCLIMATE3114 -US-Dk2,1700008889,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Dk2,1700006474,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Novick, K., Oren, R., Stoy, P., Siqueira, M., Katul, G. (2009) Nocturnal Evapotranspiration In Eddy-Covariance Records From Three Co-Located Ecosystems In The Southeastern U.S.: Implications For Annual Fluxes, Agricultural And Forest Meteorology, 149(9), 1491-1504" -US-Dk2,1700006474,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2009.04.005 -US-Dk2,1700006474,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Dk2,1700005082,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Oishi, A. C., Oren, R., Stoy, P. C. (2008) Estimating Components Of Forest Evapotranspiration: A Footprint Approach For Scaling Sap Flux Measurements, Agricultural And Forest Meteorology, 148(11), 1719-1732" -US-Dk2,1700005082,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2008.06.013 -US-Dk2,1700005082,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Dk2,1700002580,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Oren, R., Hsieh, C., Stoy, P., Albertson, J., Mccarthy, H. R., Harrell, P., Katul, G. G. (2006) Estimating The Uncertainty In Annual Net Ecosystem Carbon Exchange: Spatial Variation In Turbulent Fluxes And Sampling Errors In Eddy-Covariance Measurements, Global Change Biology, 12(5), 883-896" -US-Dk2,1700002580,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/J.1365-2486.2006.01131.X -US-Dk2,1700002580,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Dk2,1700000930,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Pataki, D., Oren, R. (2003) Species Differences In Stomatal Control Of Water Loss At The Canopy Scale In A Mature Bottomland Deciduous Forest, Advances In Water Resources, 26(12), 1267-1278" -US-Dk2,1700000930,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.ADVWATRES.2003.08.001 -US-Dk2,1700000930,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Dk2,1700009042,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Siqueira, M. B., Katul, G. G., Sampson, D. A., Stoy, P. C., Juang, J., Mccarthy, H. R., Oren, R. (2006) Multiscale Model Intercomparisons Of CO2 And H2O Exchange Rates In A Maturing Southeastern US Pine Forest, Global Change Biology, 12(7), 1189-1207" -US-Dk2,1700009042,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/J.1365-2486.2006.01158.X -US-Dk2,1700009042,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Dk2,1700005853,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Zhang, Q., Barnes, M., Benson, M., Burakowski, E., Oishi, A. C., Ouimette, A., Sanders‐DeMott, R., Stoy, P. C., Wenzel, M., Xiong, L., Yi, K., Novick, K. A. (2020) Reforestation And Surface Cooling In Temperate Zones: Mechanisms And Implications, Global Change Biology, 26(6), 3384-3401" -US-Dk2,1700005853,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/GCB.15069 -US-Dk2,1700005853,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Dk2,1700008943,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Zhang, Q., Phillips, R. P., Manzoni, S., Scott, R. L., Oishi, A. C., Finzi, A., Daly, E., Vargas, R., Novick, K. A. (2018) Changes In Photosynthesis And Soil Moisture Drive The Seasonal Soil Respiration-Temperature Hysteresis Relationship, Agricultural And Forest Meteorology, 259(11), 184-195" -US-Dk2,1700008943,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2018.05.005 -US-Dk2,1700008943,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Dk2,1700003174,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Zhang, Q., Phillips, R. P., Manzoni, S., Scott, R. L., Oishi, A. C., Finzi, A., Daly, E., Vargas, R., Novick, K. A. (2018) Changes In Photosynthesis And Soil Moisture Drive The Seasonal Soil Respiration-Temperature Hysteresis Relationship, Agricultural And Forest Meteorology, 259(6), 184-195" -US-Dk2,1700003174,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2018.05.005 -US-Dk2,1700003174,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Dk2,4094,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"The research objectives of the Duke Forest Hardwoods site are as follows: 1) Examine ecological roles of vegetation and climate in controlling long-term carbon exchange; 2) Determine the contribution of vegetation from that of climate and soils on controlling ET at three adjacent SE Piedmont ecosystems, namely the three Duke Forest Sites, US-Dk1, US-Dk2, and US-Dk3; 3) Quantify seasonal and annual forest floor CO2 efflux in a mature oak-hickory forest type, and to separate the effect of forest type from that of climate or soil on the magnitude and dynamics of forest floor CO2 efflux. (Stoy et al., 2008, Stoy et al., 2006, Palmroth et al., 2005)" -US-Dk2,24908,GRP_ROOT_BIOMASS,ROOT_BIOMASS_CRS,2900 -US-Dk2,24908,GRP_ROOT_BIOMASS,ROOT_BIOMASS_UNIT,gC m-2 -US-Dk2,24908,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MIN,0 -US-Dk2,24908,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MAX,40 -US-Dk2,24908,GRP_ROOT_BIOMASS,ROOT_BIOMASS_DATE,2004 -US-Dk2,26053,GRP_ROOT_CHEM,ROOT_C,4.38 -US-Dk2,26053,GRP_ROOT_CHEM,ROOT_N,3.52 -US-Dk2,26053,GRP_ROOT_CHEM,ROOT_SPP,(Unknown) -US-Dk2,26053,GRP_ROOT_CHEM,ROOT_DATE,2004 -US-Dk2,26053,GRP_ROOT_CHEM,ROOT_COMMENT,"Sumer; Unpublished data, K. Johnsen et al." -US-Dk2,25024,GRP_SA,SA,90 -US-Dk2,25024,GRP_SA,SA_DATE,2006 -US-Dk2,25155,GRP_SA,SA_DATE,2006 -US-Dk2,25155,GRP_SA,SA_COMMENT,(range 80-100) The stand is of uniform age -US-Dk2,25155,GRP_SA,SA_MAX,90 -US-Dk2,5851,GRP_SITE_CHAR,TERRAIN,Gentle slope (<2 %) -US-Dk2,2788,GRP_SITE_DESC,SITE_DESC,private land adjacent to the Duke Forest in November 2002 -US-Dk2,5868,GRP_SITE_FUNDING,SITE_FUNDING,DOE/NIGEC -US-Dk2,25549,GRP_SNAG_MASS,SNAG_MASS,0 -US-Dk2,25549,GRP_SNAG_MASS,SNAG_MASS_UNIT,gC m-2 -US-Dk2,24435,GRP_SOIL_CHEM,SOIL_CHEM_C_ORG,17.9 -US-Dk2,23918,GRP_SOIL_CHEM,SOIL_CHEM_PH_SALT,4.975 -US-Dk2,24554,GRP_SOIL_CHEM,SOIL_CHEM_PH_H2O,5.9 -US-Dk2,24419,GRP_SOIL_CHEM,SOIL_CHEM_PH_H2O,6.04 -US-Dk2,24941,GRP_SOIL_CHEM,SOIL_CHEM_BD,1.22 -US-Dk2,23660,GRP_SOIL_CHEM,SOIL_CHEM_BD,1.46 -US-Dk2,23660,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,0 -US-Dk2,23918,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,0 -US-Dk2,24419,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,0 -US-Dk2,24435,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,0 -US-Dk2,24554,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,0 -US-Dk2,24941,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,0 -US-Dk2,23918,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,20.32 -US-Dk2,24419,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,20.32 -US-Dk2,24435,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,20.32 -US-Dk2,24941,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,20.32 -US-Dk2,23660,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,92 -US-Dk2,24554,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,92 -US-Dk2,23918,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,A -US-Dk2,24419,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,A -US-Dk2,24435,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,A -US-Dk2,24941,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,A -US-Dk2,23660,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,B -US-Dk2,24554,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,B -US-Dk2,23660,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,"/Bulk density -BE/1.43 -Bt/1.38 -Bt/1.54 -B/1.49 -D.D. Richter / Geoderma 126 (2005) 5–25 description ENON Series; BE/0.48 -Bt/0.8 -Bt/1.15 -B/1.4 -D.D. Richter / Geoderma 126 (2005) 5–25 description ENON Series" -US-Dk2,24554,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,"/pHw -BE/5.75 -Bt/5.83 -Bt/6.26 -B/5.82 -D.D. Richter / Geoderma 126 (2005) 5–25 description ENON Series; BE/0.48 -Bt/0.8 -Bt/1.15 -B/1.4 -D.D. Richter / Geoderma 126 (2005) 5–25 description ENON Series" -US-Dk2,24941,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,"A 1.15; E 1.29 N.-H. Oh, D.D. Richter / Geoderma 126 (2005) 5–25 description ENON Series; A--0 to 3 inches; dark grayish brown (10YR 4/2) fine sandy loam; ...strongly acid; clear smooth boundary. (2 to 9 inches thick) -E--3 to 8 inches; yellowish brown (10YR 5/4) fine sandy loam; ...moderately acid; clear wavy boundary. (0 to 7 inches thick) -source: description ENON Series" -US-Dk2,24435,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,"A 2.48; E 1.10; (%C) N.-H. Oh, D.D. Richter / Geoderma 126 (2005) 5–25 description ENON Series; A--0 to 3 inches; dark grayish brown (10YR 4/2) fine sandy loam; ...strongly acid; clear smooth boundary. (2 to 9 inches thick) -E--3 to 8 inches; yellowish brown (10YR 5/4) fine sandy loam; ...moderately acid; clear wavy boundary. (0 to 7 inches thick) -source: description ENON Series" -US-Dk2,23918,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,"A 4.85; E 5.10 N.-H. Oh, D.D. Richter / Geoderma 126 (2005) 5–25 description ENON Series; A--0 to 3 inches; dark grayish brown (10YR 4/2) fine sandy loam; ...strongly acid; clear smooth boundary. (2 to 9 inches thick) -E--3 to 8 inches; yellowish brown (10YR 5/4) fine sandy loam; ...moderately acid; clear wavy boundary. (0 to 7 inches thick) -source: description ENON Series" -US-Dk2,24419,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,"A 5.85; E 6.23 N.-H. Oh, D.D. Richter / Geoderma 126 (2005) 5–25 description ENON Series; A--0 to 3 inches; dark grayish brown (10YR 4/2) fine sandy loam; ...strongly acid; clear smooth boundary. (2 to 9 inches thick) -E--3 to 8 inches; yellowish brown (10YR 5/4) fine sandy loam; ...moderately acid; clear wavy boundary. (0 to 7 inches thick) -source: description ENON Series" -US-Dk2,29423,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION,"Enron silt loam transitioning to Iredell gravely loam to the southwest, an imprevious clay pan is located beneath all soils at a depth of 0.30 m" -US-Dk2,29423,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION_TAXONOMY,Other -US-Dk2,24375,GRP_SOIL_DEPTH,SOIL_DEPTH,3000 -US-Dk2,24375,GRP_SOIL_DEPTH,SOIL_DEPTH_COMMENT,A clay-pan underlies the entire Blackwood division of the Duke forest at 30 cm. -US-Dk2,24376,GRP_SOIL_TEX,SOIL_TEX_WATER_HOLD_CAP,0.52 -US-Dk2,24376,GRP_SOIL_TEX,SOIL_TEX_PROFILE_MIN,0 -US-Dk2,24376,GRP_SOIL_TEX,SOIL_TEX_PROFILE_MAX,30 -US-Dk2,25157,GRP_SPP_O,SPP_O,ACRU (NRCS plant code) -US-Dk2,24269,GRP_SPP_O,SPP_O,CAAL27 (NRCS plant code) -US-Dk2,26049,GRP_SPP_O,SPP_O,CAGL8 (NRCS plant code) -US-Dk2,24373,GRP_SPP_O,SPP_O,LIST2 (NRCS plant code) -US-Dk2,24906,GRP_SPP_O,SPP_O,LITU (NRCS plant code) -US-Dk2,24115,GRP_SPP_O,SPP_O,PITA (NRCS plant code) -US-Dk2,23737,GRP_SPP_O,SPP_O,QUAL (NRCS plant code) -US-Dk2,24907,GRP_SPP_O,SPP_O,QUMI (NRCS plant code) -US-Dk2,25158,GRP_SPP_O,SPP_O,QUPH (NRCS plant code) -US-Dk2,24115,GRP_SPP_O,SPP_O_PERC,1 -US-Dk2,24373,GRP_SPP_O,SPP_O_PERC,15 -US-Dk2,24906,GRP_SPP_O,SPP_O_PERC,21 -US-Dk2,25157,GRP_SPP_O,SPP_O_PERC,4 -US-Dk2,24269,GRP_SPP_O,SPP_O_PERC,46 -US-Dk2,23737,GRP_SPP_O,SPP_O_PERC,5 -US-Dk2,26049,GRP_SPP_O,SPP_O_PERC,9 -US-Dk2,23737,GRP_SPP_O,SPP_DATE,1997 -US-Dk2,24115,GRP_SPP_O,SPP_DATE,1997 -US-Dk2,24269,GRP_SPP_O,SPP_DATE,1997 -US-Dk2,24373,GRP_SPP_O,SPP_DATE,1997 -US-Dk2,24906,GRP_SPP_O,SPP_DATE,1997 -US-Dk2,24907,GRP_SPP_O,SPP_DATE,1997 -US-Dk2,25157,GRP_SPP_O,SPP_DATE,1997 -US-Dk2,25158,GRP_SPP_O,SPP_DATE,1997 -US-Dk2,26049,GRP_SPP_O,SPP_DATE,1997 -US-Dk2,25158,GRP_SPP_O,SPP_COMMENT,"spatially variable, more prevalent in wet subplot; Species composition spatially variable with respect to relatively wet and dry plots. For basal and sapwood area, see Oishi AC, Oren R, Stoy PC (2008) Estimating components of forest evapotranspiration: A footprint approach for scaling sap flux measurements. Measurements above come from: Pataki, D.E. and Oren, R., 2003. Species differences in stomatal control of water loss at the canopy scale in a mature bottomland deciduous forest. Advances in Water Resources, 26(12): 1267-1278." -US-Dk2,24907,GRP_SPP_O,SPP_COMMENT,"spatially variable;Species composition spatially variable with respect to relatively wet and dry plots. For basal and sapwood area, see Oishi AC, Oren R, Stoy PC (2008) Estimating components of forest evapotranspiration: A footprint approach for scaling sap flux measurements. Measurements above come from: Pataki, D.E. and Oren, R., 2003. Species differences in stomatal control of water loss at the canopy scale in a mature bottomland deciduous forest. Advances in Water Resources, 26(12): 1267-1278." -US-Dk2,23737,GRP_SPP_O,SPP_COMMENT,"Species composition spatially variable with respect to relatively wet and dry plots. For basal and sapwood area, see Oishi AC, Oren R, Stoy PC (2008) Estimating components of forest evapotranspiration: A footprint approach for scaling sap flux measurements. Measurements above come from: Pataki, D.E. and Oren, R., 2003. Species differences in stomatal control of water loss at the canopy scale in a mature bottomland deciduous forest. Advances in Water Resources, 26(12): 1267-1278." -US-Dk2,24115,GRP_SPP_O,SPP_COMMENT,"Species composition spatially variable with respect to relatively wet and dry plots. For basal and sapwood area, see Oishi AC, Oren R, Stoy PC (2008) Estimating components of forest evapotranspiration: A footprint approach for scaling sap flux measurements. Measurements above come from: Pataki, D.E. and Oren, R., 2003. Species differences in stomatal control of water loss at the canopy scale in a mature bottomland deciduous forest. Advances in Water Resources, 26(12): 1267-1278." -US-Dk2,24269,GRP_SPP_O,SPP_COMMENT,"Species composition spatially variable with respect to relatively wet and dry plots. For basal and sapwood area, see Oishi AC, Oren R, Stoy PC (2008) Estimating components of forest evapotranspiration: A footprint approach for scaling sap flux measurements. Measurements above come from: Pataki, D.E. and Oren, R., 2003. Species differences in stomatal control of water loss at the canopy scale in a mature bottomland deciduous forest. Advances in Water Resources, 26(12): 1267-1278." -US-Dk2,24373,GRP_SPP_O,SPP_COMMENT,"Species composition spatially variable with respect to relatively wet and dry plots. For basal and sapwood area, see Oishi AC, Oren R, Stoy PC (2008) Estimating components of forest evapotranspiration: A footprint approach for scaling sap flux measurements. Measurements above come from: Pataki, D.E. and Oren, R., 2003. Species differences in stomatal control of water loss at the canopy scale in a mature bottomland deciduous forest. Advances in Water Resources, 26(12): 1267-1278." -US-Dk2,24906,GRP_SPP_O,SPP_COMMENT,"Species composition spatially variable with respect to relatively wet and dry plots. For basal and sapwood area, see Oishi AC, Oren R, Stoy PC (2008) Estimating components of forest evapotranspiration: A footprint approach for scaling sap flux measurements. Measurements above come from: Pataki, D.E. and Oren, R., 2003. Species differences in stomatal control of water loss at the canopy scale in a mature bottomland deciduous forest. Advances in Water Resources, 26(12): 1267-1278." -US-Dk2,25157,GRP_SPP_O,SPP_COMMENT,"Species composition spatially variable with respect to relatively wet and dry plots. For basal and sapwood area, see Oishi AC, Oren R, Stoy PC (2008) Estimating components of forest evapotranspiration: A footprint approach for scaling sap flux measurements. Measurements above come from: Pataki, D.E. and Oren, R., 2003. Species differences in stomatal control of water loss at the canopy scale in a mature bottomland deciduous forest. Advances in Water Resources, 26(12): 1267-1278." -US-Dk2,26049,GRP_SPP_O,SPP_COMMENT,"Species composition spatially variable with respect to relatively wet and dry plots. For basal and sapwood area, see Oishi AC, Oren R, Stoy PC (2008) Estimating components of forest evapotranspiration: A footprint approach for scaling sap flux measurements. Measurements above come from: Pataki, D.E. and Oren, R., 2003. Species differences in stomatal control of water loss at the canopy scale in a mature bottomland deciduous forest. Advances in Water Resources, 26(12): 1267-1278." -US-Dk2,24116,GRP_SPP_U,SPP_U,CACA18 (NRCS plant code) -US-Dk2,23876,GRP_SPP_U,SPP_U,CECA4 (NRCS plant code) -US-Dk2,24775,GRP_SPP_U,SPP_U,COFL2 (NRCS plant code) -US-Dk2,23877,GRP_SPP_U,SPP_U,JUVI (NRCS plant code) -US-Dk2,24374,GRP_SPP_U,SPP_U,OSVI (NRCS plant code) -US-Dk2,24117,GRP_SPP_U,SPP_U,ULAL (NRCS plant code) -US-Dk2,23876,GRP_SPP_U,SPP_DATE,1997 -US-Dk2,23877,GRP_SPP_U,SPP_DATE,1997 -US-Dk2,24116,GRP_SPP_U,SPP_DATE,1997 -US-Dk2,24117,GRP_SPP_U,SPP_DATE,1997 -US-Dk2,24374,GRP_SPP_U,SPP_DATE,1997 -US-Dk2,24775,GRP_SPP_U,SPP_DATE,1997 -US-Dk2,23876,GRP_SPP_U,SPP_COMMENT,"Species composition spatially variable with respect to relatively wet and dry plots. For basal and sapwood area, see Oishi AC, Oren R, Stoy PC (2008) Estimating components of forest evapotranspiration: A footprint approach for scaling sap flux measurements. Measurements above come from: Pataki, D.E. and Oren, R., 2003. Species differences in stomatal control of water loss at the canopy scale in a mature bottomland deciduous forest. Advances in Water Resources, 26(12): 1267-1278." -US-Dk2,23877,GRP_SPP_U,SPP_COMMENT,"Species composition spatially variable with respect to relatively wet and dry plots. For basal and sapwood area, see Oishi AC, Oren R, Stoy PC (2008) Estimating components of forest evapotranspiration: A footprint approach for scaling sap flux measurements. Measurements above come from: Pataki, D.E. and Oren, R., 2003. Species differences in stomatal control of water loss at the canopy scale in a mature bottomland deciduous forest. Advances in Water Resources, 26(12): 1267-1278." -US-Dk2,24116,GRP_SPP_U,SPP_COMMENT,"Species composition spatially variable with respect to relatively wet and dry plots. For basal and sapwood area, see Oishi AC, Oren R, Stoy PC (2008) Estimating components of forest evapotranspiration: A footprint approach for scaling sap flux measurements. Measurements above come from: Pataki, D.E. and Oren, R., 2003. Species differences in stomatal control of water loss at the canopy scale in a mature bottomland deciduous forest. Advances in Water Resources, 26(12): 1267-1278." -US-Dk2,24117,GRP_SPP_U,SPP_COMMENT,"Species composition spatially variable with respect to relatively wet and dry plots. For basal and sapwood area, see Oishi AC, Oren R, Stoy PC (2008) Estimating components of forest evapotranspiration: A footprint approach for scaling sap flux measurements. Measurements above come from: Pataki, D.E. and Oren, R., 2003. Species differences in stomatal control of water loss at the canopy scale in a mature bottomland deciduous forest. Advances in Water Resources, 26(12): 1267-1278." -US-Dk2,24374,GRP_SPP_U,SPP_COMMENT,"Species composition spatially variable with respect to relatively wet and dry plots. For basal and sapwood area, see Oishi AC, Oren R, Stoy PC (2008) Estimating components of forest evapotranspiration: A footprint approach for scaling sap flux measurements. Measurements above come from: Pataki, D.E. and Oren, R., 2003. Species differences in stomatal control of water loss at the canopy scale in a mature bottomland deciduous forest. Advances in Water Resources, 26(12): 1267-1278." -US-Dk2,24775,GRP_SPP_U,SPP_COMMENT,"Species composition spatially variable with respect to relatively wet and dry plots. For basal and sapwood area, see Oishi AC, Oren R, Stoy PC (2008) Estimating components of forest evapotranspiration: A footprint approach for scaling sap flux measurements. Measurements above come from: Pataki, D.E. and Oren, R., 2003. Species differences in stomatal control of water loss at the canopy scale in a mature bottomland deciduous forest. Advances in Water Resources, 26(12): 1267-1278." -US-Dk2,1491,GRP_STATE,STATE,NC -US-Dk2,25030,GRP_STUMP_MASS,STUMP_MASS,0 -US-Dk2,25030,GRP_STUMP_MASS,STUMP_MASS_UNIT,gC m-2 -US-Dk2,86920,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,A. Christopher Oishi -US-Dk2,86920,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Dk2,86920,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,acoishi@fs.fed.us -US-Dk2,86920,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,USDA Forest Service -US-Dk2,12684,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Kim Novick -US-Dk2,12684,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Dk2,12684,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,knovick@indiana.edu -US-Dk2,12684,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Indiana University -US-Dk2,12685,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Paul Stoy -US-Dk2,12685,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Dk2,12685,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,paul.stoy@montana.edu -US-Dk2,12685,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Montana State University -US-Dk2,6719,GRP_URL,URL,http://www.nicholas.duke.edu/other/AMERIFLUX/amerflux.html -US-Dk2,24000358,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-Dk2 -US-Dk2,33627,GRP_UTC_OFFSET,UTC_OFFSET,-5 -US-Dk2,33627,GRP_UTC_OFFSET,UTC_OFFSET_COMMENT,Added by AMF data processing team for data QAQC checks. -US-Dk2,24521,GRP_WD_BIOMASS,WD_BIOMASS_CRS,500 -US-Dk2,25028,GRP_WD_BIOMASS,WD_BIOMASS_CRS,500 -US-Dk2,25029,GRP_WD_BIOMASS,WD_BIOMASS_CRS,500 -US-Dk2,25547,GRP_WD_BIOMASS,WD_BIOMASS_CRS,500 -US-Dk2,25548,GRP_WD_BIOMASS,WD_BIOMASS_FINE,0 -US-Dk2,24521,GRP_WD_BIOMASS,WD_BIOMASS_UNIT,gC m-2 -US-Dk2,25028,GRP_WD_BIOMASS,WD_BIOMASS_UNIT,gC m-2 -US-Dk2,25029,GRP_WD_BIOMASS,WD_BIOMASS_UNIT,gC m-2 -US-Dk2,25547,GRP_WD_BIOMASS,WD_BIOMASS_UNIT,gC m-2 -US-Dk2,25548,GRP_WD_BIOMASS,WD_BIOMASS_UNIT,gC m-2 -US-Dk2,24521,GRP_WD_BIOMASS,WD_BIOMASS_DATE,2002 -US-Dk2,25028,GRP_WD_BIOMASS,WD_BIOMASS_DATE,2003 -US-Dk2,25547,GRP_WD_BIOMASS,WD_BIOMASS_DATE,2004 -US-Dk2,25029,GRP_WD_BIOMASS,WD_BIOMASS_DATE,2005 -US-Dk2,24521,GRP_WD_BIOMASS,WD_BIOMASS_COMMENT,"Total annual dry weight, collected in litter baskets (not C only)" -US-Dk2,25028,GRP_WD_BIOMASS,WD_BIOMASS_COMMENT,"Total annual dry weight, collected in litter baskets (not C only)" -US-Dk2,25029,GRP_WD_BIOMASS,WD_BIOMASS_COMMENT,"Total annual dry weight, collected in litter baskets (not C only)" -US-Dk2,25547,GRP_WD_BIOMASS,WD_BIOMASS_COMMENT,"Total annual dry weight, collected in litter baskets (not C only)" -US-Dk3,28948,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,350 -US-Dk3,28948,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Foliage -US-Dk3,28948,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-Dk3,28948,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-Dk3,28948,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2003 -US-Dk3,28948,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,"References: (1) McCarthy, H.R. 2007 ( Long-term effects of elevated CO2, soil nutrition, water availability and disturbance on carbon relations in a loblolly pine forest. PhD Dissertation. Nicholas School of the Environment, Duke University. (2) McCarthy HR, Oren R, Kim H-K et al. (2006) Interaction of ice storms and management practices on current carbon sequestration in forests with potential mitigation under future CO2 atmosphere. Journal of Geophysical Research - Atmospheres, 111, D15103; (3) Naidu SL, DeLucia EH, Thomas RB (1998) Contrasting patterns of biomass allocation in dominant and suppressed loblolly pine. Canadian Journal of Forest Research, 28, 1116-1124; (4) Oren R, Ellsworth DS, Johnsen KH et al. (2001) Soil fertility limits carbon sequestration by forest ecosystems in a CO2 - enriched atmosphere. Nature, 411, 469-472." -US-Dk3,28453,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,375 -US-Dk3,28453,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Foliage -US-Dk3,28453,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-Dk3,28453,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-Dk3,28453,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2005 -US-Dk3,28453,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,"References: (1) McCarthy, H.R. 2007 ( Long-term effects of elevated CO2, soil nutrition, water availability and disturbance on carbon relations in a loblolly pine forest. PhD Dissertation. Nicholas School of the Environment, Duke University. (2) McCarthy HR, Oren R, Kim H-K et al. (2006) Interaction of ice storms and management practices on current carbon sequestration in forests with potential mitigation under future CO2 atmosphere. Journal of Geophysical Research - Atmospheres, 111, D15103; (3) Naidu SL, DeLucia EH, Thomas RB (1998) Contrasting patterns of biomass allocation in dominant and suppressed loblolly pine. Canadian Journal of Forest Research, 28, 1116-1124; (4) Oren R, Ellsworth DS, Johnsen KH et al. (2001) Soil fertility limits carbon sequestration by forest ecosystems in a CO2 - enriched atmosphere. Nature, 411, 469-472." -US-Dk3,27502,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,378 -US-Dk3,27502,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Foliage -US-Dk3,27502,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-Dk3,27502,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-Dk3,27502,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2002 -US-Dk3,27502,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,"References: (1) McCarthy, H.R. 2007 ( Long-term effects of elevated CO2, soil nutrition, water availability and disturbance on carbon relations in a loblolly pine forest. PhD Dissertation. Nicholas School of the Environment, Duke University. (2) McCarthy HR, Oren R, Kim H-K et al. (2006) Interaction of ice storms and management practices on current carbon sequestration in forests with potential mitigation under future CO2 atmosphere. Journal of Geophysical Research - Atmospheres, 111, D15103; (3) Naidu SL, DeLucia EH, Thomas RB (1998) Contrasting patterns of biomass allocation in dominant and suppressed loblolly pine. Canadian Journal of Forest Research, 28, 1116-1124; (4) Oren R, Ellsworth DS, Johnsen KH et al. (2001) Soil fertility limits carbon sequestration by forest ecosystems in a CO2 - enriched atmosphere. Nature, 411, 469-472." -US-Dk3,28447,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,398 -US-Dk3,28447,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Foliage -US-Dk3,28447,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-Dk3,28447,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-Dk3,28447,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2004 -US-Dk3,28447,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,"References: (1) McCarthy, H.R. 2007 ( Long-term effects of elevated CO2, soil nutrition, water availability and disturbance on carbon relations in a loblolly pine forest. PhD Dissertation. Nicholas School of the Environment, Duke University. (2) McCarthy HR, Oren R, Kim H-K et al. (2006) Interaction of ice storms and management practices on current carbon sequestration in forests with potential mitigation under future CO2 atmosphere. Journal of Geophysical Research - Atmospheres, 111, D15103; (3) Naidu SL, DeLucia EH, Thomas RB (1998) Contrasting patterns of biomass allocation in dominant and suppressed loblolly pine. Canadian Journal of Forest Research, 28, 1116-1124; (4) Oren R, Ellsworth DS, Johnsen KH et al. (2001) Soil fertility limits carbon sequestration by forest ecosystems in a CO2 - enriched atmosphere. Nature, 411, 469-472." -US-Dk3,28451,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,408 -US-Dk3,28451,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Foliage -US-Dk3,28451,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-Dk3,28451,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-Dk3,28451,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2001 -US-Dk3,28451,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,"References: (1) McCarthy, H.R. 2007 ( Long-term effects of elevated CO2, soil nutrition, water availability and disturbance on carbon relations in a loblolly pine forest. PhD Dissertation. Nicholas School of the Environment, Duke University. (2) McCarthy HR, Oren R, Kim H-K et al. (2006) Interaction of ice storms and management practices on current carbon sequestration in forests with potential mitigation under future CO2 atmosphere. Journal of Geophysical Research - Atmospheres, 111, D15103; (3) Naidu SL, DeLucia EH, Thomas RB (1998) Contrasting patterns of biomass allocation in dominant and suppressed loblolly pine. Canadian Journal of Forest Research, 28, 1116-1124; (4) Oren R, Ellsworth DS, Johnsen KH et al. (2001) Soil fertility limits carbon sequestration by forest ecosystems in a CO2 - enriched atmosphere. Nature, 411, 469-472." -US-Dk3,25410,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,7345 -US-Dk3,25410,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Wood -US-Dk3,25410,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-Dk3,25410,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-Dk3,25410,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2001 -US-Dk3,25410,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,"References: (1) McCarthy, H.R. 2007 ( Long-term effects of elevated CO2, soil nutrition, water availability and disturbance on carbon relations in a loblolly pine forest. PhD Dissertation. Nicholas School of the Environment, Duke University. (2) McCarthy HR, Oren R, Kim H-K et al. (2006) Interaction of ice storms and management practices on current carbon sequestration in forests with potential mitigation under future CO2 atmosphere. Journal of Geophysical Research - Atmospheres, 111, D15103; (3) Naidu SL, DeLucia EH, Thomas RB (1998) Contrasting patterns of biomass allocation in dominant and suppressed loblolly pine. Canadian Journal of Forest Research, 28, 1116-1124; (4) Oren R, Ellsworth DS, Johnsen KH et al. (2001) Soil fertility limits carbon sequestration by forest ecosystems in a CO2 - enriched atmosphere. Nature, 411, 469-472." -US-Dk3,25539,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,7664 -US-Dk3,25539,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Wood -US-Dk3,25539,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-Dk3,25539,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-Dk3,25539,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2002 -US-Dk3,25539,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,"References: (1) McCarthy, H.R. 2007 ( Long-term effects of elevated CO2, soil nutrition, water availability and disturbance on carbon relations in a loblolly pine forest. PhD Dissertation. Nicholas School of the Environment, Duke University. (2) McCarthy HR, Oren R, Kim H-K et al. (2006) Interaction of ice storms and management practices on current carbon sequestration in forests with potential mitigation under future CO2 atmosphere. Journal of Geophysical Research - Atmospheres, 111, D15103; (3) Naidu SL, DeLucia EH, Thomas RB (1998) Contrasting patterns of biomass allocation in dominant and suppressed loblolly pine. Canadian Journal of Forest Research, 28, 1116-1124; (4) Oren R, Ellsworth DS, Johnsen KH et al. (2001) Soil fertility limits carbon sequestration by forest ecosystems in a CO2 - enriched atmosphere. Nature, 411, 469-472." -US-Dk3,28222,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,7754 -US-Dk3,28222,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Total -US-Dk3,28222,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-Dk3,28222,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-Dk3,28222,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2001 -US-Dk3,28222,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,"References: (1) McCarthy, H.R. 2007 ( Long-term effects of elevated CO2, soil nutrition, water availability and disturbance on carbon relations in a loblolly pine forest. PhD Dissertation. Nicholas School of the Environment, Duke University. (2) McCarthy HR, Oren R, Kim H-K et al. (2006) Interaction of ice storms and management practices on current carbon sequestration in forests with potential mitigation under future CO2 atmosphere. Journal of Geophysical Research - Atmospheres, 111, D15103; (3) Naidu SL, DeLucia EH, Thomas RB (1998) Contrasting patterns of biomass allocation in dominant and suppressed loblolly pine. Canadian Journal of Forest Research, 28, 1116-1124; (4) Oren R, Ellsworth DS, Johnsen KH et al. (2001) Soil fertility limits carbon sequestration by forest ecosystems in a CO2 - enriched atmosphere. Nature, 411, 469-472." -US-Dk3,27501,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,7821 -US-Dk3,27501,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Wood -US-Dk3,27501,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-Dk3,27501,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-Dk3,27501,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2003 -US-Dk3,27501,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,"References: (1) McCarthy, H.R. 2007 ( Long-term effects of elevated CO2, soil nutrition, water availability and disturbance on carbon relations in a loblolly pine forest. PhD Dissertation. Nicholas School of the Environment, Duke University. (2) McCarthy HR, Oren R, Kim H-K et al. (2006) Interaction of ice storms and management practices on current carbon sequestration in forests with potential mitigation under future CO2 atmosphere. Journal of Geophysical Research - Atmospheres, 111, D15103; (3) Naidu SL, DeLucia EH, Thomas RB (1998) Contrasting patterns of biomass allocation in dominant and suppressed loblolly pine. Canadian Journal of Forest Research, 28, 1116-1124; (4) Oren R, Ellsworth DS, Johnsen KH et al. (2001) Soil fertility limits carbon sequestration by forest ecosystems in a CO2 - enriched atmosphere. Nature, 411, 469-472." -US-Dk3,25915,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,8042 -US-Dk3,25915,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Total -US-Dk3,25915,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-Dk3,25915,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-Dk3,25915,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2002 -US-Dk3,25915,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,"References: (1) McCarthy, H.R. 2007 ( Long-term effects of elevated CO2, soil nutrition, water availability and disturbance on carbon relations in a loblolly pine forest. PhD Dissertation. Nicholas School of the Environment, Duke University. (2) McCarthy HR, Oren R, Kim H-K et al. (2006) Interaction of ice storms and management practices on current carbon sequestration in forests with potential mitigation under future CO2 atmosphere. Journal of Geophysical Research - Atmospheres, 111, D15103; (3) Naidu SL, DeLucia EH, Thomas RB (1998) Contrasting patterns of biomass allocation in dominant and suppressed loblolly pine. Canadian Journal of Forest Research, 28, 1116-1124; (4) Oren R, Ellsworth DS, Johnsen KH et al. (2001) Soil fertility limits carbon sequestration by forest ecosystems in a CO2 - enriched atmosphere. Nature, 411, 469-472." -US-Dk3,28108,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,8171 -US-Dk3,28108,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Total -US-Dk3,28108,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-Dk3,28108,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-Dk3,28108,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2003 -US-Dk3,28108,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,"References: (1) McCarthy, H.R. 2007 ( Long-term effects of elevated CO2, soil nutrition, water availability and disturbance on carbon relations in a loblolly pine forest. PhD Dissertation. Nicholas School of the Environment, Duke University. (2) McCarthy HR, Oren R, Kim H-K et al. (2006) Interaction of ice storms and management practices on current carbon sequestration in forests with potential mitigation under future CO2 atmosphere. Journal of Geophysical Research - Atmospheres, 111, D15103; (3) Naidu SL, DeLucia EH, Thomas RB (1998) Contrasting patterns of biomass allocation in dominant and suppressed loblolly pine. Canadian Journal of Forest Research, 28, 1116-1124; (4) Oren R, Ellsworth DS, Johnsen KH et al. (2001) Soil fertility limits carbon sequestration by forest ecosystems in a CO2 - enriched atmosphere. Nature, 411, 469-472." -US-Dk3,25540,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,8464 -US-Dk3,25540,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Wood -US-Dk3,25540,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-Dk3,25540,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-Dk3,25540,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2004 -US-Dk3,25540,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,"References: (1) McCarthy, H.R. 2007 ( Long-term effects of elevated CO2, soil nutrition, water availability and disturbance on carbon relations in a loblolly pine forest. PhD Dissertation. Nicholas School of the Environment, Duke University. (2) McCarthy HR, Oren R, Kim H-K et al. (2006) Interaction of ice storms and management practices on current carbon sequestration in forests with potential mitigation under future CO2 atmosphere. Journal of Geophysical Research - Atmospheres, 111, D15103; (3) Naidu SL, DeLucia EH, Thomas RB (1998) Contrasting patterns of biomass allocation in dominant and suppressed loblolly pine. Canadian Journal of Forest Research, 28, 1116-1124; (4) Oren R, Ellsworth DS, Johnsen KH et al. (2001) Soil fertility limits carbon sequestration by forest ecosystems in a CO2 - enriched atmosphere. Nature, 411, 469-472." -US-Dk3,28109,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,8859 -US-Dk3,28109,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Total -US-Dk3,28109,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-Dk3,28109,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-Dk3,28109,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2004 -US-Dk3,28109,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,"References: (1) McCarthy, H.R. 2007 ( Long-term effects of elevated CO2, soil nutrition, water availability and disturbance on carbon relations in a loblolly pine forest. PhD Dissertation. Nicholas School of the Environment, Duke University. (2) McCarthy HR, Oren R, Kim H-K et al. (2006) Interaction of ice storms and management practices on current carbon sequestration in forests with potential mitigation under future CO2 atmosphere. Journal of Geophysical Research - Atmospheres, 111, D15103; (3) Naidu SL, DeLucia EH, Thomas RB (1998) Contrasting patterns of biomass allocation in dominant and suppressed loblolly pine. Canadian Journal of Forest Research, 28, 1116-1124; (4) Oren R, Ellsworth DS, Johnsen KH et al. (2001) Soil fertility limits carbon sequestration by forest ecosystems in a CO2 - enriched atmosphere. Nature, 411, 469-472." -US-Dk3,27503,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,9123 -US-Dk3,27503,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Wood -US-Dk3,27503,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-Dk3,27503,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-Dk3,27503,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2005 -US-Dk3,27503,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,"References: (1) McCarthy, H.R. 2007 ( Long-term effects of elevated CO2, soil nutrition, water availability and disturbance on carbon relations in a loblolly pine forest. PhD Dissertation. Nicholas School of the Environment, Duke University. (2) McCarthy HR, Oren R, Kim H-K et al. (2006) Interaction of ice storms and management practices on current carbon sequestration in forests with potential mitigation under future CO2 atmosphere. Journal of Geophysical Research - Atmospheres, 111, D15103; (3) Naidu SL, DeLucia EH, Thomas RB (1998) Contrasting patterns of biomass allocation in dominant and suppressed loblolly pine. Canadian Journal of Forest Research, 28, 1116-1124; (4) Oren R, Ellsworth DS, Johnsen KH et al. (2001) Soil fertility limits carbon sequestration by forest ecosystems in a CO2 - enriched atmosphere. Nature, 411, 469-472." -US-Dk3,28221,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,9498 -US-Dk3,28221,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Total -US-Dk3,28221,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-Dk3,28221,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-Dk3,28221,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2005 -US-Dk3,28221,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,"References: (1) McCarthy, H.R. 2007 ( Long-term effects of elevated CO2, soil nutrition, water availability and disturbance on carbon relations in a loblolly pine forest. PhD Dissertation. Nicholas School of the Environment, Duke University. (2) McCarthy HR, Oren R, Kim H-K et al. (2006) Interaction of ice storms and management practices on current carbon sequestration in forests with potential mitigation under future CO2 atmosphere. Journal of Geophysical Research - Atmospheres, 111, D15103; (3) Naidu SL, DeLucia EH, Thomas RB (1998) Contrasting patterns of biomass allocation in dominant and suppressed loblolly pine. Canadian Journal of Forest Research, 28, 1116-1124; (4) Oren R, Ellsworth DS, Johnsen KH et al. (2001) Soil fertility limits carbon sequestration by forest ecosystems in a CO2 - enriched atmosphere. Nature, 411, 469-472." -US-Dk3,27850,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS,200 -US-Dk3,27850,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_UNIT,gC m-2 -US-Dk3,27850,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_DATE,2001 -US-Dk3,27850,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_COMMENT,"Reference: Lichter J, Barron S, Finzi A, Irving K, Roberts M, Stemmler E and W Schlesinger. 2005. Soil carbon sequestration and turnover in a pine forest after six years of atmospheric CO2 enrichment. Ecology 86(7):1835-1847" -US-Dk3,25912,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS,226 -US-Dk3,25912,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_UNIT,gC m-2 -US-Dk3,25912,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_DATE,2002 -US-Dk3,25912,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_COMMENT,"Reference: Lichter J, Barron S, Finzi A, Irving K, Roberts M, Stemmler E and W Schlesinger. 2005. Soil carbon sequestration and turnover in a pine forest after six years of atmospheric CO2 enrichment. Ecology 86(7):1835-1847" -US-Dk3,28946,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS,226 -US-Dk3,28946,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_UNIT,gC m-2 -US-Dk3,28946,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_DATE,2004 -US-Dk3,28946,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_COMMENT,"Reference: Lichter J, Barron S, Finzi A, Irving K, Roberts M, Stemmler E and W Schlesinger. 2005. Soil carbon sequestration and turnover in a pine forest after six years of atmospheric CO2 enrichment. Ecology 86(7):1835-1847" -US-Dk3,28949,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS,234 -US-Dk3,28949,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_UNIT,gC m-2 -US-Dk3,28949,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_DATE,2003 -US-Dk3,28949,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_COMMENT,"Reference: Lichter J, Barron S, Finzi A, Irving K, Roberts M, Stemmler E and W Schlesinger. 2005. Soil carbon sequestration and turnover in a pine forest after six years of atmospheric CO2 enrichment. Ecology 86(7):1835-1847" -US-Dk3,28146,GRP_AG_LIT_CHEM,AG_LIT_C,3.407 -US-Dk3,28144,GRP_AG_LIT_CHEM,AG_LIT_C,3.805 -US-Dk3,28145,GRP_AG_LIT_CHEM,AG_LIT_C,4.107 -US-Dk3,27537,GRP_AG_LIT_CHEM,AG_LIT_C,4.192 -US-Dk3,28145,GRP_AG_LIT_CHEM,AG_LIT_N,0.084 -US-Dk3,28144,GRP_AG_LIT_CHEM,AG_LIT_N,0.086 -US-Dk3,28146,GRP_AG_LIT_CHEM,AG_LIT_N,0.086 -US-Dk3,27537,GRP_AG_LIT_CHEM,AG_LIT_N,0.096 -US-Dk3,27537,GRP_AG_LIT_CHEM,AG_LIT_DATE,1996 -US-Dk3,28144,GRP_AG_LIT_CHEM,AG_LIT_DATE,1999 -US-Dk3,28145,GRP_AG_LIT_CHEM,AG_LIT_DATE,2002 -US-Dk3,28146,GRP_AG_LIT_CHEM,AG_LIT_DATE,2005 -US-Dk3,27537,GRP_AG_LIT_CHEM,AG_LIT_COMMENT,Data from http://face.env.duke.edu/face.cfm -US-Dk3,28144,GRP_AG_LIT_CHEM,AG_LIT_COMMENT,Data from http://face.env.duke.edu/face.cfm -US-Dk3,28145,GRP_AG_LIT_CHEM,AG_LIT_COMMENT,Data from http://face.env.duke.edu/face.cfm -US-Dk3,28146,GRP_AG_LIT_CHEM,AG_LIT_COMMENT,Data from http://face.env.duke.edu/face.cfm -US-Dk3,28985,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT,200 -US-Dk3,28484,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT,228 -US-Dk3,26830,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT,234 -US-Dk3,29448,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT,247 -US-Dk3,26830,GRP_AG_LIT_PROD,AG_LIT_PROD_UNIT,gC m-2 -US-Dk3,28484,GRP_AG_LIT_PROD,AG_LIT_PROD_UNIT,gC m-2 -US-Dk3,28985,GRP_AG_LIT_PROD,AG_LIT_PROD_UNIT,gC m-2 -US-Dk3,29448,GRP_AG_LIT_PROD,AG_LIT_PROD_UNIT,gC m-2 -US-Dk3,28985,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_START,2001 -US-Dk3,29448,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_START,2002 -US-Dk3,26830,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_START,2003 -US-Dk3,28484,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_START,2004 -US-Dk3,28253,GRP_AG_PROD_TREE,AG_PROD_TREE,1122 -US-Dk3,28253,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Wood -US-Dk3,28253,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-Dk3,28253,GRP_AG_PROD_TREE,AG_PROD_DATE_START,2005 -US-Dk3,28253,GRP_AG_PROD_TREE,AG_PROD_COMMENT,"References: (1) McCarthy, H.R. 2007 ( Long-term effects of elevated CO2, soil nutrition, water availability and disturbance on carbon relations in a loblolly pine forest. PhD Dissertation. Nicholas School of the Environment, Duke University. (2) McCarthy HR, Oren R, Kim H-K et al. (2006) Interaction of ice storms and management practices on current carbon sequestration in forests with potential mitigation under future CO2 atmosphere. Journal of Geophysical Research - Atmospheres, 111, D15103; (3) Naidu SL, DeLucia EH, Thomas RB (1998) Contrasting patterns of biomass allocation in dominant and suppressed loblolly pine. Canadian Journal of Forest Research, 28, 1116-1124; (4) Oren R, Ellsworth DS, Johnsen KH et al. (2001) Soil fertility limits carbon sequestration by forest ecosystems in a CO2 - enriched atmosphere. Nature, 411, 469-472." -US-Dk3,26936,GRP_AG_PROD_TREE,AG_PROD_TREE,1308 -US-Dk3,26936,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Wood -US-Dk3,26936,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-Dk3,26936,GRP_AG_PROD_TREE,AG_PROD_DATE_START,2003 -US-Dk3,26936,GRP_AG_PROD_TREE,AG_PROD_COMMENT,"References: (1) McCarthy, H.R. 2007 ( Long-term effects of elevated CO2, soil nutrition, water availability and disturbance on carbon relations in a loblolly pine forest. PhD Dissertation. Nicholas School of the Environment, Duke University. (2) McCarthy HR, Oren R, Kim H-K et al. (2006) Interaction of ice storms and management practices on current carbon sequestration in forests with potential mitigation under future CO2 atmosphere. Journal of Geophysical Research - Atmospheres, 111, D15103; (3) Naidu SL, DeLucia EH, Thomas RB (1998) Contrasting patterns of biomass allocation in dominant and suppressed loblolly pine. Canadian Journal of Forest Research, 28, 1116-1124; (4) Oren R, Ellsworth DS, Johnsen KH et al. (2001) Soil fertility limits carbon sequestration by forest ecosystems in a CO2 - enriched atmosphere. Nature, 411, 469-472." -US-Dk3,25412,GRP_AG_PROD_TREE,AG_PROD_TREE,1396 -US-Dk3,25412,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Wood -US-Dk3,25412,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-Dk3,25412,GRP_AG_PROD_TREE,AG_PROD_DATE_START,2004 -US-Dk3,25412,GRP_AG_PROD_TREE,AG_PROD_COMMENT,"References: (1) McCarthy, H.R. 2007 ( Long-term effects of elevated CO2, soil nutrition, water availability and disturbance on carbon relations in a loblolly pine forest. PhD Dissertation. Nicholas School of the Environment, Duke University. (2) McCarthy HR, Oren R, Kim H-K et al. (2006) Interaction of ice storms and management practices on current carbon sequestration in forests with potential mitigation under future CO2 atmosphere. Journal of Geophysical Research - Atmospheres, 111, D15103; (3) Naidu SL, DeLucia EH, Thomas RB (1998) Contrasting patterns of biomass allocation in dominant and suppressed loblolly pine. Canadian Journal of Forest Research, 28, 1116-1124; (4) Oren R, Ellsworth DS, Johnsen KH et al. (2001) Soil fertility limits carbon sequestration by forest ecosystems in a CO2 - enriched atmosphere. Nature, 411, 469-472." -US-Dk3,25917,GRP_AG_PROD_TREE,AG_PROD_TREE,1444 -US-Dk3,25917,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Wood -US-Dk3,25917,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-Dk3,25917,GRP_AG_PROD_TREE,AG_PROD_DATE_START,2001 -US-Dk3,25917,GRP_AG_PROD_TREE,AG_PROD_COMMENT,"References: (1) McCarthy, H.R. 2007 ( Long-term effects of elevated CO2, soil nutrition, water availability and disturbance on carbon relations in a loblolly pine forest. PhD Dissertation. Nicholas School of the Environment, Duke University. (2) McCarthy HR, Oren R, Kim H-K et al. (2006) Interaction of ice storms and management practices on current carbon sequestration in forests with potential mitigation under future CO2 atmosphere. Journal of Geophysical Research - Atmospheres, 111, D15103; (3) Naidu SL, DeLucia EH, Thomas RB (1998) Contrasting patterns of biomass allocation in dominant and suppressed loblolly pine. Canadian Journal of Forest Research, 28, 1116-1124; (4) Oren R, Ellsworth DS, Johnsen KH et al. (2001) Soil fertility limits carbon sequestration by forest ecosystems in a CO2 - enriched atmosphere. Nature, 411, 469-472." -US-Dk3,25542,GRP_AG_PROD_TREE,AG_PROD_TREE,220 -US-Dk3,25542,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Foliage -US-Dk3,25542,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-Dk3,25542,GRP_AG_PROD_TREE,AG_PROD_DATE_START,2002 -US-Dk3,25542,GRP_AG_PROD_TREE,AG_PROD_COMMENT,"References: (1) McCarthy, H.R. 2007 ( Long-term effects of elevated CO2, soil nutrition, water availability and disturbance on carbon relations in a loblolly pine forest. PhD Dissertation. Nicholas School of the Environment, Duke University. (2) McCarthy HR, Oren R, Kim H-K et al. (2006) Interaction of ice storms and management practices on current carbon sequestration in forests with potential mitigation under future CO2 atmosphere. Journal of Geophysical Research - Atmospheres, 111, D15103; (3) Naidu SL, DeLucia EH, Thomas RB (1998) Contrasting patterns of biomass allocation in dominant and suppressed loblolly pine. Canadian Journal of Forest Research, 28, 1116-1124; (4) Oren R, Ellsworth DS, Johnsen KH et al. (2001) Soil fertility limits carbon sequestration by forest ecosystems in a CO2 - enriched atmosphere. Nature, 411, 469-472." -US-Dk3,28454,GRP_AG_PROD_TREE,AG_PROD_TREE,226 -US-Dk3,28454,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Foliage -US-Dk3,28454,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-Dk3,28454,GRP_AG_PROD_TREE,AG_PROD_DATE_START,2003 -US-Dk3,28454,GRP_AG_PROD_TREE,AG_PROD_COMMENT,"References: (1) McCarthy, H.R. 2007 ( Long-term effects of elevated CO2, soil nutrition, water availability and disturbance on carbon relations in a loblolly pine forest. PhD Dissertation. Nicholas School of the Environment, Duke University. (2) McCarthy HR, Oren R, Kim H-K et al. (2006) Interaction of ice storms and management practices on current carbon sequestration in forests with potential mitigation under future CO2 atmosphere. Journal of Geophysical Research - Atmospheres, 111, D15103; (3) Naidu SL, DeLucia EH, Thomas RB (1998) Contrasting patterns of biomass allocation in dominant and suppressed loblolly pine. Canadian Journal of Forest Research, 28, 1116-1124; (4) Oren R, Ellsworth DS, Johnsen KH et al. (2001) Soil fertility limits carbon sequestration by forest ecosystems in a CO2 - enriched atmosphere. Nature, 411, 469-472." -US-Dk3,27856,GRP_AG_PROD_TREE,AG_PROD_TREE,243 -US-Dk3,27856,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Foliage -US-Dk3,27856,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-Dk3,27856,GRP_AG_PROD_TREE,AG_PROD_DATE_START,2005 -US-Dk3,27856,GRP_AG_PROD_TREE,AG_PROD_COMMENT,"References: (1) McCarthy, H.R. 2007 ( Long-term effects of elevated CO2, soil nutrition, water availability and disturbance on carbon relations in a loblolly pine forest. PhD Dissertation. Nicholas School of the Environment, Duke University. (2) McCarthy HR, Oren R, Kim H-K et al. (2006) Interaction of ice storms and management practices on current carbon sequestration in forests with potential mitigation under future CO2 atmosphere. Journal of Geophysical Research - Atmospheres, 111, D15103; (3) Naidu SL, DeLucia EH, Thomas RB (1998) Contrasting patterns of biomass allocation in dominant and suppressed loblolly pine. Canadian Journal of Forest Research, 28, 1116-1124; (4) Oren R, Ellsworth DS, Johnsen KH et al. (2001) Soil fertility limits carbon sequestration by forest ecosystems in a CO2 - enriched atmosphere. Nature, 411, 469-472." -US-Dk3,28110,GRP_AG_PROD_TREE,AG_PROD_TREE,262 -US-Dk3,28110,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Foliage -US-Dk3,28110,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-Dk3,28110,GRP_AG_PROD_TREE,AG_PROD_DATE_START,2001 -US-Dk3,28110,GRP_AG_PROD_TREE,AG_PROD_COMMENT,"References: (1) McCarthy, H.R. 2007 ( Long-term effects of elevated CO2, soil nutrition, water availability and disturbance on carbon relations in a loblolly pine forest. PhD Dissertation. Nicholas School of the Environment, Duke University. (2) McCarthy HR, Oren R, Kim H-K et al. (2006) Interaction of ice storms and management practices on current carbon sequestration in forests with potential mitigation under future CO2 atmosphere. Journal of Geophysical Research - Atmospheres, 111, D15103; (3) Naidu SL, DeLucia EH, Thomas RB (1998) Contrasting patterns of biomass allocation in dominant and suppressed loblolly pine. Canadian Journal of Forest Research, 28, 1116-1124; (4) Oren R, Ellsworth DS, Johnsen KH et al. (2001) Soil fertility limits carbon sequestration by forest ecosystems in a CO2 - enriched atmosphere. Nature, 411, 469-472." -US-Dk3,26034,GRP_AG_PROD_TREE,AG_PROD_TREE,273 -US-Dk3,26034,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Foliage -US-Dk3,26034,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-Dk3,26034,GRP_AG_PROD_TREE,AG_PROD_DATE_START,2004 -US-Dk3,26034,GRP_AG_PROD_TREE,AG_PROD_COMMENT,"References: (1) McCarthy, H.R. 2007 ( Long-term effects of elevated CO2, soil nutrition, water availability and disturbance on carbon relations in a loblolly pine forest. PhD Dissertation. Nicholas School of the Environment, Duke University. (2) McCarthy HR, Oren R, Kim H-K et al. (2006) Interaction of ice storms and management practices on current carbon sequestration in forests with potential mitigation under future CO2 atmosphere. Journal of Geophysical Research - Atmospheres, 111, D15103; (3) Naidu SL, DeLucia EH, Thomas RB (1998) Contrasting patterns of biomass allocation in dominant and suppressed loblolly pine. Canadian Journal of Forest Research, 28, 1116-1124; (4) Oren R, Ellsworth DS, Johnsen KH et al. (2001) Soil fertility limits carbon sequestration by forest ecosystems in a CO2 - enriched atmosphere. Nature, 411, 469-472." -US-Dk3,25920,GRP_AG_PROD_TREE,AG_PROD_TREE,706 -US-Dk3,25920,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Wood -US-Dk3,25920,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-Dk3,25920,GRP_AG_PROD_TREE,AG_PROD_DATE_START,2002 -US-Dk3,25920,GRP_AG_PROD_TREE,AG_PROD_COMMENT,"References: (1) McCarthy, H.R. 2007 ( Long-term effects of elevated CO2, soil nutrition, water availability and disturbance on carbon relations in a loblolly pine forest. PhD Dissertation. Nicholas School of the Environment, Duke University. (2) McCarthy HR, Oren R, Kim H-K et al. (2006) Interaction of ice storms and management practices on current carbon sequestration in forests with potential mitigation under future CO2 atmosphere. Journal of Geophysical Research - Atmospheres, 111, D15103; (3) Naidu SL, DeLucia EH, Thomas RB (1998) Contrasting patterns of biomass allocation in dominant and suppressed loblolly pine. Canadian Journal of Forest Research, 28, 1116-1124; (4) Oren R, Ellsworth DS, Johnsen KH et al. (2001) Soil fertility limits carbon sequestration by forest ecosystems in a CO2 - enriched atmosphere. Nature, 411, 469-472." -US-Dk3,27891,GRP_BIOMASS_CHEM,BIOMASS_C,4.8 -US-Dk3,27255,GRP_BIOMASS_CHEM,BIOMASS_N,0.0141 -US-Dk3,27536,GRP_BIOMASS_CHEM,BIOMASS_N,0.0143 -US-Dk3,27256,GRP_BIOMASS_CHEM,BIOMASS_N,0.0148 -US-Dk3,28986,GRP_BIOMASS_CHEM,BIOMASS_N,0.0148 -US-Dk3,28143,GRP_BIOMASS_CHEM,BIOMASS_N,0.0159 -US-Dk3,28256,GRP_BIOMASS_CHEM,BIOMASS_N,0.098 -US-Dk3,28485,GRP_BIOMASS_CHEM,BIOMASS_N,0.099 -US-Dk3,26668,GRP_BIOMASS_CHEM,BIOMASS_N,0.1 -US-Dk3,27535,GRP_BIOMASS_CHEM,BIOMASS_N,0.103 -US-Dk3,28776,GRP_BIOMASS_CHEM,BIOMASS_N,0.106 -US-Dk3,26668,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-Dk3,27255,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-Dk3,27256,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-Dk3,27535,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-Dk3,27536,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-Dk3,27891,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-Dk3,28143,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-Dk3,28256,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-Dk3,28485,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-Dk3,28776,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-Dk3,28986,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-Dk3,26668,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-Dk3,27255,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-Dk3,27256,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-Dk3,27535,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-Dk3,27536,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-Dk3,27891,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-Dk3,28143,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-Dk3,28256,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-Dk3,28485,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-Dk3,28776,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-Dk3,28986,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-Dk3,26668,GRP_BIOMASS_CHEM,BIOMASS_SPP,PITA (NRCS plant code) -US-Dk3,27255,GRP_BIOMASS_CHEM,BIOMASS_SPP,PITA (NRCS plant code) -US-Dk3,27256,GRP_BIOMASS_CHEM,BIOMASS_SPP,PITA (NRCS plant code) -US-Dk3,27535,GRP_BIOMASS_CHEM,BIOMASS_SPP,PITA (NRCS plant code) -US-Dk3,27536,GRP_BIOMASS_CHEM,BIOMASS_SPP,PITA (NRCS plant code) -US-Dk3,27891,GRP_BIOMASS_CHEM,BIOMASS_SPP,PITA (NRCS plant code) -US-Dk3,28143,GRP_BIOMASS_CHEM,BIOMASS_SPP,PITA (NRCS plant code) -US-Dk3,28256,GRP_BIOMASS_CHEM,BIOMASS_SPP,PITA (NRCS plant code) -US-Dk3,28485,GRP_BIOMASS_CHEM,BIOMASS_SPP,PITA (NRCS plant code) -US-Dk3,28776,GRP_BIOMASS_CHEM,BIOMASS_SPP,PITA (NRCS plant code) -US-Dk3,28986,GRP_BIOMASS_CHEM,BIOMASS_SPP,PITA (NRCS plant code) -US-Dk3,26668,GRP_BIOMASS_CHEM,BIOMASS_DATE,2001 -US-Dk3,28986,GRP_BIOMASS_CHEM,BIOMASS_DATE,2001 -US-Dk3,27536,GRP_BIOMASS_CHEM,BIOMASS_DATE,2002 -US-Dk3,28485,GRP_BIOMASS_CHEM,BIOMASS_DATE,2002 -US-Dk3,27255,GRP_BIOMASS_CHEM,BIOMASS_DATE,2003 -US-Dk3,28776,GRP_BIOMASS_CHEM,BIOMASS_DATE,2003 -US-Dk3,28143,GRP_BIOMASS_CHEM,BIOMASS_DATE,2004 -US-Dk3,28256,GRP_BIOMASS_CHEM,BIOMASS_DATE,2004 -US-Dk3,27256,GRP_BIOMASS_CHEM,BIOMASS_DATE,2005 -US-Dk3,27535,GRP_BIOMASS_CHEM,BIOMASS_DATE,2005 -US-Dk3,26668,GRP_BIOMASS_CHEM,BIOMASS_COMMENT,Data from http://face.env.duke.edu/face.cfm -US-Dk3,27255,GRP_BIOMASS_CHEM,BIOMASS_COMMENT,Data from http://face.env.duke.edu/face.cfm -US-Dk3,27256,GRP_BIOMASS_CHEM,BIOMASS_COMMENT,Data from http://face.env.duke.edu/face.cfm -US-Dk3,27535,GRP_BIOMASS_CHEM,BIOMASS_COMMENT,Data from http://face.env.duke.edu/face.cfm -US-Dk3,27536,GRP_BIOMASS_CHEM,BIOMASS_COMMENT,Data from http://face.env.duke.edu/face.cfm -US-Dk3,28143,GRP_BIOMASS_CHEM,BIOMASS_COMMENT,Data from http://face.env.duke.edu/face.cfm -US-Dk3,28256,GRP_BIOMASS_CHEM,BIOMASS_COMMENT,Data from http://face.env.duke.edu/face.cfm -US-Dk3,28485,GRP_BIOMASS_CHEM,BIOMASS_COMMENT,Data from http://face.env.duke.edu/face.cfm -US-Dk3,28776,GRP_BIOMASS_CHEM,BIOMASS_COMMENT,Data from http://face.env.duke.edu/face.cfm -US-Dk3,28986,GRP_BIOMASS_CHEM,BIOMASS_COMMENT,Data from http://face.env.duke.edu/face.cfm -US-Dk3,27891,GRP_BIOMASS_CHEM,BIOMASS_COMMENT,"Oren R, Ellsworth DS, Johnsen KH et al. (2001) Soil fertility limits carbon sequestration by forest ecosystems in a CO2 - enriched atmosphere. Nature, 411, 469-472" -US-Dk3,5125,GRP_CLIM_AVG,MAT,14.36 -US-Dk3,5125,GRP_CLIM_AVG,MAP,1169.69 -US-Dk3,5125,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Cfa -US-Dk3,27000359,GRP_COUNTRY,COUNTRY,USA -US-Dk3,1125,GRP_DM_EXT_WEATHER,DM_EXT_WEATHER,Storm -US-Dk3,1125,GRP_DM_EXT_WEATHER,DM_COMMENT,"McCarthy HR, Oren R, Kim HS, Johnsen KH, Maier C, Pritchard SG, Davis MA (2006) Interaction of ice storme and management practices on current carbon sequestration in forests with potential mitigation under future CO2 atmosphere. Journal of Geophysical Research 111 D15103" -US-Dk3,8787,GRP_DM_FERT_M,DM_FERT_M,Other -US-Dk3,8787,GRP_DM_FERT_M,DM_COMMENT,"FACE rings were partitioned using an impervious rubber barrier set from soil level to 75 cm belowground in winter 2004-2005. One half of each ring was fertilized the following and subsequent growing seasons. The treatments comprised a very small area (ca. 2000 m2, 1%) of the total stand (ca 200000 m2)." -US-Dk3,7946,GRP_DM_PLANTING,DM_PLANTING,Planting live trees -US-Dk3,7946,GRP_DM_PLANTING,DM_DATE,1983 -US-Dk3,7946,GRP_DM_PLANTING,DM_COMMENT,"The site was clear cut and burned, and Pinus Taeda L. seedlings were planted" -US-Dk3,15641,GRP_DOI,DOI,10.17190/AMF/1246048 -US-Dk3,15641,GRP_DOI,DOI_CITATION,"Chris Oishi, Kim Novick, Paul Stoy (2018), AmeriFlux BASE US-Dk3 Duke Forest - loblolly pine, Ver. 4-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1246048" -US-Dk3,15641,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-Dk3,32026,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Dk3,32026,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Chris Oishi -US-Dk3,32026,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Dk3,32026,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,christopher.oishi@gmail.com -US-Dk3,32026,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,USDA Forest Service -US-Dk3,32025,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Dk3,32025,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Kim Novick -US-Dk3,32025,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Dk3,32025,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,knovick@indiana.edu -US-Dk3,32025,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Indiana University -US-Dk3,32024,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Dk3,32024,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Paul Stoy -US-Dk3,32024,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Dk3,32024,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,paul.stoy@montana.edu -US-Dk3,32024,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Montana State University -US-Dk3,32028,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Indiana University -US-Dk3,32028,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-Dk3,32029,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Montana State University -US-Dk3,32029,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-Dk3,32030,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,USDA Forest Service -US-Dk3,32030,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-Dk3,32027,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,DOE/TCP -US-Dk3,32027,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-Dk3,10200,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Forestry -US-Dk3,5082,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Storm or wind -US-Dk3,1630,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Dk3,1630,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-Dk3,1630,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,2001 -US-Dk3,1630,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,2008 -US-Dk3,1630,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Dk3,23000359,GRP_HEADER,SITE_NAME,Duke Forest - loblolly pine -US-Dk3,28132,GRP_HEIGHTC,HEIGHTC,16 -US-Dk3,28132,GRP_HEIGHTC,HEIGHTC_DATE,2001 -US-Dk3,27249,GRP_HEIGHTC,HEIGHTC,18 -US-Dk3,27249,GRP_HEIGHTC,HEIGHTC_DATE,2004 -US-Dk3,25538,GRP_HEIGHTC,HEIGHTC,19 -US-Dk3,25538,GRP_HEIGHTC,HEIGHTC_DATE,2006 -US-Dk3,7942,GRP_IGBP,IGBP,ENF -US-Dk3,7942,GRP_IGBP,IGBP_COMMENT,"In early 2002, pines made up 90% of the basal area in this site. The predominantly hardwood midstory has been expanding since site establishment." -US-Dk3,26832,GRP_LAI,LAI_TYPE,LAI -US-Dk3,27539,GRP_LAI,LAI_TYPE,LAI -US-Dk3,28259,GRP_LAI,LAI_TYPE,LAI -US-Dk3,28488,GRP_LAI,LAI_TYPE,LAI -US-Dk3,28489,GRP_LAI,LAI_TYPE,LAI -US-Dk3,28490,GRP_LAI,LAI_TYPE,LAI -US-Dk3,28947,GRP_LAI,LAI_TYPE,LAI -US-Dk3,29092,GRP_LAI,LAI_TYPE,LAI -US-Dk3,28947,GRP_LAI,LAI_DATE,2002 -US-Dk3,28259,GRP_LAI,LAI_DATE,20020701 -US-Dk3,29092,GRP_LAI,LAI_DATE,2003 -US-Dk3,26832,GRP_LAI,LAI_DATE,20030701 -US-Dk3,28488,GRP_LAI,LAI_DATE,2004 -US-Dk3,28489,GRP_LAI,LAI_DATE,20040701 -US-Dk3,28490,GRP_LAI,LAI_DATE,2005 -US-Dk3,27539,GRP_LAI,LAI_DATE,20050701 -US-Dk3,26832,GRP_LAI,LAI_COMMENT,"(Multiple techniques assimilated to determine LAI); These are extracted values from an interpoloated time series. The time series is available upon requestion. See McCarthy HR, Oren R, Finzi AC, Ellsworth DS, Kim H-S, Johnsen KH, Millar B (2007) Temporal dynamics and spatial variability in the enhancement of canopy leaf area under elevated atmospheric CO2. Global Change Biology 13(12): 2479-2497 for details on measurement technique." -US-Dk3,27539,GRP_LAI,LAI_COMMENT,"(Multiple techniques assimilated to determine LAI); These are extracted values from an interpoloated time series. The time series is available upon requestion. See McCarthy HR, Oren R, Finzi AC, Ellsworth DS, Kim H-S, Johnsen KH, Millar B (2007) Temporal dynamics and spatial variability in the enhancement of canopy leaf area under elevated atmospheric CO2. Global Change Biology 13(12): 2479-2497 for details on measurement technique." -US-Dk3,28259,GRP_LAI,LAI_COMMENT,"(Multiple techniques assimilated to determine LAI); These are extracted values from an interpoloated time series. The time series is available upon requestion. See McCarthy HR, Oren R, Finzi AC, Ellsworth DS, Kim H-S, Johnsen KH, Millar B (2007) Temporal dynamics and spatial variability in the enhancement of canopy leaf area under elevated atmospheric CO2. Global Change Biology 13(12): 2479-2497 for details on measurement technique." -US-Dk3,28488,GRP_LAI,LAI_COMMENT,"(Multiple techniques assimilated to determine LAI); These are extracted values from an interpoloated time series. The time series is available upon requestion. See McCarthy HR, Oren R, Finzi AC, Ellsworth DS, Kim H-S, Johnsen KH, Millar B (2007) Temporal dynamics and spatial variability in the enhancement of canopy leaf area under elevated atmospheric CO2. Global Change Biology 13(12): 2479-2497 for details on measurement technique." -US-Dk3,28489,GRP_LAI,LAI_COMMENT,"(Multiple techniques assimilated to determine LAI); These are extracted values from an interpoloated time series. The time series is available upon requestion. See McCarthy HR, Oren R, Finzi AC, Ellsworth DS, Kim H-S, Johnsen KH, Millar B (2007) Temporal dynamics and spatial variability in the enhancement of canopy leaf area under elevated atmospheric CO2. Global Change Biology 13(12): 2479-2497 for details on measurement technique." -US-Dk3,28490,GRP_LAI,LAI_COMMENT,"(Multiple techniques assimilated to determine LAI); These are extracted values from an interpoloated time series. The time series is available upon requestion. See McCarthy HR, Oren R, Finzi AC, Ellsworth DS, Kim H-S, Johnsen KH, Millar B (2007) Temporal dynamics and spatial variability in the enhancement of canopy leaf area under elevated atmospheric CO2. Global Change Biology 13(12): 2479-2497 for details on measurement technique." -US-Dk3,28947,GRP_LAI,LAI_COMMENT,"(Multiple techniques assimilated to determine LAI); These are extracted values from an interpoloated time series. The time series is available upon requestion. See McCarthy HR, Oren R, Finzi AC, Ellsworth DS, Kim H-S, Johnsen KH, Millar B (2007) Temporal dynamics and spatial variability in the enhancement of canopy leaf area under elevated atmospheric CO2. Global Change Biology 13(12): 2479-2497 for details on measurement technique." -US-Dk3,29092,GRP_LAI,LAI_COMMENT,"(Multiple techniques assimilated to determine LAI); These are extracted values from an interpoloated time series. The time series is available upon requestion. See McCarthy HR, Oren R, Finzi AC, Ellsworth DS, Kim H-S, Johnsen KH, Millar B (2007) Temporal dynamics and spatial variability in the enhancement of canopy leaf area under elevated atmospheric CO2. Global Change Biology 13(12): 2479-2497 for details on measurement technique." -US-Dk3,28490,GRP_LAI,LAI_TOT,1.6 -US-Dk3,29092,GRP_LAI,LAI_TOT,1.63 -US-Dk3,28488,GRP_LAI,LAI_TOT,1.89 -US-Dk3,28947,GRP_LAI,LAI_TOT,1.91 -US-Dk3,28489,GRP_LAI,LAI_TOT,4.09 -US-Dk3,26832,GRP_LAI,LAI_TOT,4.11 -US-Dk3,27539,GRP_LAI,LAI_TOT,4.22 -US-Dk3,28259,GRP_LAI,LAI_TOT,4.57 -US-Dk3,2820,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -US-Dk3,2820,GRP_LAND_OWNERSHIP,LAND_OWNER,Duke Forest -US-Dk3,29088,GRP_LMA,LMA,131.9 -US-Dk3,29088,GRP_LMA,LMA_SPP,(All) -US-Dk3,29088,GRP_LMA,LMA_DATE,2002 -US-Dk3,29088,GRP_LMA,LMA_COMMENT,Data from http://face.env.duke.edu/face.cfm -US-Dk3,28254,GRP_LMA,LMA,135.4 -US-Dk3,28254,GRP_LMA,LMA_SPP,(All) -US-Dk3,28254,GRP_LMA,LMA_DATE,2001 -US-Dk3,28254,GRP_LMA,LMA_COMMENT,Data from http://face.env.duke.edu/face.cfm -US-Dk3,27890,GRP_LMA,LMA,140.2 -US-Dk3,27890,GRP_LMA,LMA_SPP,(All) -US-Dk3,27890,GRP_LMA,LMA_DATE,2005 -US-Dk3,27890,GRP_LMA,LMA_COMMENT,Data from http://face.env.duke.edu/face.cfm -US-Dk3,27254,GRP_LMA,LMA,143.1 -US-Dk3,27254,GRP_LMA,LMA_SPP,(All) -US-Dk3,27254,GRP_LMA,LMA_DATE,2004 -US-Dk3,27254,GRP_LMA,LMA_COMMENT,Data from http://face.env.duke.edu/face.cfm -US-Dk3,28255,GRP_LMA,LMA,170.7 -US-Dk3,28255,GRP_LMA,LMA_SPP,(All) -US-Dk3,28255,GRP_LMA,LMA_DATE,2003 -US-Dk3,28255,GRP_LMA,LMA_COMMENT,Data from http://face.env.duke.edu/face.cfm -US-Dk3,9262,GRP_LOCATION,LOCATION_LAT,35.9782 -US-Dk3,9262,GRP_LOCATION,LOCATION_LONG,-79.0942 -US-Dk3,9262,GRP_LOCATION,LOCATION_ELEV,163 -US-Dk3,9262,GRP_LOCATION,LOCATION_COMMENT,Central towere located in Ring 1 of FACE experiment -US-Dk3,434,GRP_NETWORK,NETWORK,AmeriFlux -US-Dk3,1700005373,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Albertson, J. D., Katul, G. G., Wiberg, P. (2001) Relative Importance Of Local And Regional Controls On Coupled Water, Carbon, And Energy Fluxes, Advances In Water Resources, 24(9-10), 1103-1118" -US-Dk3,1700005373,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/S0309-1708(01)00042-2 -US-Dk3,1700005373,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Dk3,1700003909,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Arain, M. A., Restrepo-Coupe, N. (2005) Net Ecosystem Production In A Temperate Pine Plantation In Southeastern Canada, Agricultural And Forest Meteorology, 128(3-4), 223-241" -US-Dk3,1700003909,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2004.10.003 -US-Dk3,1700003909,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Dk3,1700005316,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Barr, A., Richardson, A., Hollinger, D., Papale, D., Arain, M., Black, T., Bohrer, G., Dragoni, D., Fischer, M., Gu, L., Law, B., Margolis, H., McCaughey, J., Munger, J., Oechel, W., Schaeffer, K. (2013) Use Of Change-Point Detection For Friction–Velocity Threshold Evaluation In Eddy-Covariance Studies, Agricultural And Forest Meteorology, 171-172(7), 31-45" -US-Dk3,1700005316,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2012.11.023 -US-Dk3,1700005316,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Dk3,1700007107,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Bond-Lamberty, B., Wang, C., Gower, S. T. (2004) A Global Relationship Between The Heterotrophic And Autotrophic Components Of Soil Respiration?, Global Change Biology, 10(10), 1756-1766" -US-Dk3,1700007107,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/J.1365-2486.2004.00816.X -US-Dk3,1700007107,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Dk3,1700004059,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Butnor, J. R., Johnsen, K. H., Maier, C. A. 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(2014) Characterizing The Diurnal Patterns of Errors in The Prediction of Evapotranspiration by Several Land-Surface Models: An Nacp Analysis, Journal Of Geophysical Research: Biogeosciences, 119(7), 1458-1473" -US-Dk3,1700006045,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/2014JG002623 -US-Dk3,1700006045,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Dk3,1700003105,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"McCarthy, H. R., Oren, R., Finzi, A. C., Ellsworth, D. S., Kim, H., Johnsen, K. H., Millar, B. (2007) Temporal Dynamics And Spatial Variability In The Enhancement Of Canopy Leaf Area Under Elevated Atmospheric CO2, Global Change Biology, 13(12), 2479-2497" -US-Dk3,1700003105,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/J.1365-2486.2007.01455.X -US-Dk3,1700003105,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Dk3,1700007680,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"McCarthy, H. R., Oren, R., Finzi, A. C., Johnsen, K. H. (2006) Canopy Leaf Area Constrains [Co2]-Induced Enhancement Of Productivity And Partitioning Among Aboveground Carbon Pools, Proceedings Of The National Academy Of Sciences, 103(51), 19356-19361" -US-Dk3,1700007680,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1073/PNAS.0609448103 -US-Dk3,1700007680,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Dk3,1700002124,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Nathan, R., Katul, G. G. (2005) Foliage Shedding In Deciduous Forests Lifts Up Long-Distance Seed Dispersal By Wind, Proceedings Of The National Academy Of Sciences, 102(23), 8251-8256" -US-Dk3,1700002124,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1073/PNAS.0503048102 -US-Dk3,1700002124,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Dk3,1700000492,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Naumburg, E., Ellsworth, D. S. (2002) Short-Term Light And Leaf Photosynthetic Dynamics Affect Estimates Of Daily Understory Photosynthesis In Four Tree Species, Tree Physiology, 22(6), 393-401" -US-Dk3,1700000492,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1093/TREEPHYS/22.6.393 -US-Dk3,1700000492,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Dk3,1700005946,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Novick, K. A., Ficklin, D. L., Stoy, P. C., Williams, C. A., Bohrer, G., Oishi, A., Papuga, S. A., Blanken, P. D., Noormets, A., Sulman, B. N., Scott, R. L., Wang, L., Phillips, R. P. (2016) The Increasing Importance Of Atmospheric Demand For Ecosystem Water And Carbon Fluxes, Nature Climate Change, 6(11), 1023-1027" -US-Dk3,1700005946,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1038/NCLIMATE3114 -US-Dk3,1700005946,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Dk3,1700002073,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Novick, K., Oren, R., Stoy, P., Siqueira, M., Katul, G. (2009) Nocturnal Evapotranspiration In Eddy-Covariance Records From Three Co-Located Ecosystems In The Southeastern U.S.: Implications For Annual Fluxes, Agricultural And Forest Meteorology, 149(9), 1491-1504" -US-Dk3,1700002073,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2009.04.005 -US-Dk3,1700002073,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Dk3,1700002832,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Oishi, A. C., Oren, R., Stoy, P. C. (2008) Estimating Components Of Forest Evapotranspiration: A Footprint Approach For Scaling Sap Flux Measurements, Agricultural And Forest Meteorology, 148(11), 1719-1732" -US-Dk3,1700002832,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2008.06.013 -US-Dk3,1700002832,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Dk3,1700002787,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Oren, R., Hsieh, C., Stoy, P., Albertson, J., Mccarthy, H. R., Harrell, P., Katul, G. G. (2006) Estimating The Uncertainty In Annual Net Ecosystem Carbon Exchange: Spatial Variation In Turbulent Fluxes And Sampling Errors In Eddy-Covariance Measurements, Global Change Biology, 12(5), 883-896" -US-Dk3,1700002787,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/J.1365-2486.2006.01131.X -US-Dk3,1700002787,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Dk3,1700006378,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Oren, R., Pataki, D. E. (2001) Transpiration In Response To Variation In Microclimate And Soil Moisture In Southeastern Deciduous Forests, Oecologia, 127(4), 549-559" -US-Dk3,1700006378,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1007/S004420000622 -US-Dk3,1700006378,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Dk3,1700005475,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Palmroth, S., Maier, C. A., McCarthy, H. R., Oishi, A. C., Kim, H., Johnsen, K., Katul, G. G., Oren, R. (2005) Contrasting Responses To Drought Of Forest Floor CO2 Efflux In A Loblolly Pine Plantation And A Nearby Oak-Hickory Forest, Global Change Biology, 11(3), 421-434" -US-Dk3,1700005475,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/J.1365-2486.2005.00915.X -US-Dk3,1700005475,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Dk3,1700002547,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Richardson, A. D., Hollinger, D. Y., Burba, G. G., Davis, K. J., Flanagan, L. B., Katul, G. G., William Munger, J., Ricciuto, D. M., Stoy, P. C., Suyker, A. E., Verma, S. B., Wofsy, S. C. (2006) A Multi-Site Analysis Of Random Error In Tower-Based Measurements Of Carbon And Energy Fluxes, Agricultural And Forest Meteorology, 136(1-2), 1-18" -US-Dk3,1700002547,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2006.01.007 -US-Dk3,1700002547,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Dk3,1700004176,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Schafer, K. V., Oren, R., Ellsworth, D. S., Lai, C., Herrick, J. D., Finzi, A. C., Richter, D. D., Katul, G. G. (2003) Exposure To An Enriched CO2 Atmosphere Alters Carbon Assimilation And Allocation In A Pine Forest Ecosystem, Global Change Biology, 9(10), 1378-1400" -US-Dk3,1700004176,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1046/J.1365-2486.2003.00662.X -US-Dk3,1700004176,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Dk3,1700008106,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Schafer, K. V., Oren, R., Lai, C., Katul, G. G. (2002) Hydrologic Balance In An Intact Temperate Forest Ecosystem Under Ambient And Elevated Atmospheric CO2 Concentration, Global Change Biology, 8(9), 895-911" -US-Dk3,1700008106,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1046/J.1365-2486.2002.00513.X -US-Dk3,1700008106,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Dk3,1700004224,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Siqueira, M. B., Katul, G. G., Sampson, D. A., Stoy, P. C., Juang, J., Mccarthy, H. R., Oren, R. (2006) Multiscale Model Intercomparisons Of CO2 And H2O Exchange Rates In A Maturing Southeastern US Pine Forest, Global Change Biology, 12(7), 1189-1207" -US-Dk3,1700004224,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/J.1365-2486.2006.01158.X -US-Dk3,1700004224,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Dk3,1700007578,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Stoy, P. C., Katul, G. G., Siqueira, M. B., Juang, J., Novick, K. A., Mccarthy, H. R., Christopher Oishi, A., Uebelherr, J. M., Kim, H., Oren, R. (2006) Separating The Effects Of Climate And Vegetation On Evapotranspiration Along A Successional Chronosequence In The Southeastern US, Global Change Biology, 12(11), 2115-2135" -US-Dk3,1700007578,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/J.1365-2486.2006.01244.X -US-Dk3,1700007578,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Dk3,1700007386,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Stoy, P. C., Katul, G. G., Siqueira, M. B., Juang, J., Novick, K. A., Mccarthy, H. R., Oishi, A. C., Oren, R. (2008) Role Of Vegetation In Determining Carbon Sequestration Along Ecological Succession In The Southeastern United States, Global Change Biology, 14(6), 1409-1427" -US-Dk3,1700007386,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/J.1365-2486.2008.01587.X -US-Dk3,1700007386,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Dk3,1700003630,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Stoy, P. C., Katul, G. G., Siqueira, M. B., Juang, J., Novick, K. A., Uebelherr, J. M., Oren, R. (2006) An Evaluation Of Models For Partitioning Eddy Covariance-Measured Net Ecosystem Exchange Into Photosynthesis And Respiration, Agricultural And Forest Meteorology, 141(1), 2-18" -US-Dk3,1700003630,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2006.09.001 -US-Dk3,1700003630,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Dk3,1700007092,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Suwa, M., Katul, G. G., Oren, R., Andrews, J., Pippen, J., Mace, A., Schlesinger, W. H. (2004) Impact Of Elevated Atmospheric CO2 on Forest Floor Respiration In A Temperate Pine Forest, Global Biogeochemical Cycles, 18(2), n/a-n/a" -US-Dk3,1700007092,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2003GB002182 -US-Dk3,1700007092,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Dk3,1700006438,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Wesson, K. H., Katul, G., Lai, C. (2001) Sensible Heat Flux Estimation By Flux Variance And Half-Order Time Derivative Methods, Water Resources Research, 37(9), 2333-2343" -US-Dk3,1700006438,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2001WR900021 -US-Dk3,1700006438,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Dk3,1700006852,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Zhang, Q., Barnes, M., Benson, M., Burakowski, E., Oishi, A. C., Ouimette, A., Sanders‐DeMott, R., Stoy, P. C., Wenzel, M., Xiong, L., Yi, K., Novick, K. A. (2020) Reforestation And Surface Cooling In Temperate Zones: Mechanisms And Implications, Global Change Biology, 26(6), 3384-3401" -US-Dk3,1700006852,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/GCB.15069 -US-Dk3,1700006852,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Dk3,1700008193,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Zhang, Q., Phillips, R. P., Manzoni, S., Scott, R. L., Oishi, A. C., Finzi, A., Daly, E., Vargas, R., Novick, K. A. (2018) Changes In Photosynthesis And Soil Moisture Drive The Seasonal Soil Respiration-Temperature Hysteresis Relationship, Agricultural And Forest Meteorology, 259(5), 184-195" -US-Dk3,1700008193,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2018.05.005 -US-Dk3,1700008193,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Dk3,1700008583,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Zhang, Q., Phillips, R. P., Manzoni, S., Scott, R. L., Oishi, A. C., Finzi, A., Daly, E., Vargas, R., Novick, K. A. (2018) Changes In Photosynthesis And Soil Moisture Drive The Seasonal Soil Respiration-Temperature Hysteresis Relationship, Agricultural And Forest Meteorology, 259(6), 184-195" -US-Dk3,1700008583,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2018.05.005 -US-Dk3,1700008583,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Dk3,6686,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"The research and science objectives of the Duke Forest Loblolly Pine site are as follows: 1) Examine ecological roles of vegetation and climate in controlling long-term carbon exchange; 2) Determine the contribution of vegetation from that of climate and soils on controlling ET at three adjacent SE Piedmont ecosystems, namely the three Duke Forest Sites, US-Dk1, US-Dk2, and US-Dk3; 3) Quantify soil carbon pools, inputs, turnover, and long-term storage to better understand the capacity of forest soils for carbon sequestration; 4) Quantify seasonal and annual forest floor CO2 efflux in a loblolly pine plantation forest type, and to separate the effect of forest type from that of climate or soil on the magnitude and dynamics of forest floor CO2 efflux. (Stoy et al., 2008, Stoy et al., 2006, Lichter et al., 2005, Palmroth et al., 2005)" -US-Dk3,28220,GRP_ROOT_BIOMASS,ROOT_BIOMASS_FINE,135 -US-Dk3,27218,GRP_ROOT_BIOMASS,ROOT_BIOMASS_FINE,144 -US-Dk3,26032,GRP_ROOT_BIOMASS,ROOT_BIOMASS_FINE,156 -US-Dk3,25279,GRP_ROOT_BIOMASS,ROOT_BIOMASS_FINE,159 -US-Dk3,28450,GRP_ROOT_BIOMASS,ROOT_BIOMASS_FINE,172 -US-Dk3,25279,GRP_ROOT_BIOMASS,ROOT_BIOMASS_UNIT,gC m-2 -US-Dk3,26032,GRP_ROOT_BIOMASS,ROOT_BIOMASS_UNIT,gC m-2 -US-Dk3,27218,GRP_ROOT_BIOMASS,ROOT_BIOMASS_UNIT,gC m-2 -US-Dk3,28220,GRP_ROOT_BIOMASS,ROOT_BIOMASS_UNIT,gC m-2 -US-Dk3,28450,GRP_ROOT_BIOMASS,ROOT_BIOMASS_UNIT,gC m-2 -US-Dk3,25279,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MIN,0 -US-Dk3,26032,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MIN,0 -US-Dk3,27218,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MIN,0 -US-Dk3,28220,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MIN,0 -US-Dk3,28450,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MIN,0 -US-Dk3,25279,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MAX,30 -US-Dk3,26032,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MAX,30 -US-Dk3,27218,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MAX,30 -US-Dk3,28220,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MAX,30 -US-Dk3,28450,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MAX,30 -US-Dk3,28220,GRP_ROOT_BIOMASS,ROOT_BIOMASS_DATE,2001 -US-Dk3,27218,GRP_ROOT_BIOMASS,ROOT_BIOMASS_DATE,2002 -US-Dk3,26032,GRP_ROOT_BIOMASS,ROOT_BIOMASS_DATE,2003 -US-Dk3,25279,GRP_ROOT_BIOMASS,ROOT_BIOMASS_DATE,2004 -US-Dk3,28450,GRP_ROOT_BIOMASS,ROOT_BIOMASS_DATE,2005 -US-Dk3,25279,GRP_ROOT_BIOMASS,ROOT_BIOMASS_COMMENT,"35 cm (rooting depth ca. 30 cm, Oren et al., 1998; (1) McCarthy, H.R. 2007 ( Long-term effects of elevated CO2, soil nutrition, water availability and disturbance on carbon relations in a loblolly pine forest. PhD Dissertation. Nicholas School of the Environment, Duke University." -US-Dk3,26032,GRP_ROOT_BIOMASS,ROOT_BIOMASS_COMMENT,"35 cm (rooting depth ca. 30 cm, Oren et al., 1998; (1) McCarthy, H.R. 2007 ( Long-term effects of elevated CO2, soil nutrition, water availability and disturbance on carbon relations in a loblolly pine forest. PhD Dissertation. Nicholas School of the Environment, Duke University." -US-Dk3,27218,GRP_ROOT_BIOMASS,ROOT_BIOMASS_COMMENT,"35 cm (rooting depth ca. 30 cm, Oren et al., 1998; (1) McCarthy, H.R. 2007 ( Long-term effects of elevated CO2, soil nutrition, water availability and disturbance on carbon relations in a loblolly pine forest. PhD Dissertation. Nicholas School of the Environment, Duke University." -US-Dk3,28220,GRP_ROOT_BIOMASS,ROOT_BIOMASS_COMMENT,"35 cm (rooting depth ca. 30 cm, Oren et al., 1998; (1) McCarthy, H.R. 2007 ( Long-term effects of elevated CO2, soil nutrition, water availability and disturbance on carbon relations in a loblolly pine forest. PhD Dissertation. Nicholas School of the Environment, Duke University." -US-Dk3,28450,GRP_ROOT_BIOMASS,ROOT_BIOMASS_COMMENT,"35 cm (rooting depth ca. 30 cm, Oren et al., 1998; (1) McCarthy, H.R. 2007 ( Long-term effects of elevated CO2, soil nutrition, water availability and disturbance on carbon relations in a loblolly pine forest. PhD Dissertation. Nicholas School of the Environment, Duke University." -US-Dk3,26969,GRP_ROOT_CHEM,ROOT_C,4.3 -US-Dk3,27257,GRP_ROOT_CHEM,ROOT_C,4.3 -US-Dk3,29089,GRP_ROOT_CHEM,ROOT_C,4.3 -US-Dk3,27206,GRP_ROOT_CHEM,ROOT_N,0.069 -US-Dk3,26967,GRP_ROOT_CHEM,ROOT_N,0.076 -US-Dk3,27830,GRP_ROOT_CHEM,ROOT_N,0.076 -US-Dk3,26019,GRP_ROOT_CHEM,ROOT_N,0.085 -US-Dk3,25898,GRP_ROOT_CHEM,ROOT_N,0.086 -US-Dk3,26968,GRP_ROOT_CHEM,ROOT_N,0.0976 -US-Dk3,27257,GRP_ROOT_CHEM,ROOT_N,0.0976 -US-Dk3,27892,GRP_ROOT_CHEM,ROOT_N,0.0976 -US-Dk3,25898,GRP_ROOT_CHEM,ROOT_SPP,(Unknown) -US-Dk3,26019,GRP_ROOT_CHEM,ROOT_SPP,(Unknown) -US-Dk3,26967,GRP_ROOT_CHEM,ROOT_SPP,(Unknown) -US-Dk3,26968,GRP_ROOT_CHEM,ROOT_SPP,(Unknown) -US-Dk3,26969,GRP_ROOT_CHEM,ROOT_SPP,(Unknown) -US-Dk3,27206,GRP_ROOT_CHEM,ROOT_SPP,(Unknown) -US-Dk3,27257,GRP_ROOT_CHEM,ROOT_SPP,(Unknown) -US-Dk3,27830,GRP_ROOT_CHEM,ROOT_SPP,(Unknown) -US-Dk3,27892,GRP_ROOT_CHEM,ROOT_SPP,(Unknown) -US-Dk3,29089,GRP_ROOT_CHEM,ROOT_SPP,(Unknown) -US-Dk3,26967,GRP_ROOT_CHEM,ROOT_DATE,2001 -US-Dk3,27830,GRP_ROOT_CHEM,ROOT_DATE,2002 -US-Dk3,25898,GRP_ROOT_CHEM,ROOT_DATE,2003 -US-Dk3,29089,GRP_ROOT_CHEM,ROOT_DATE,2003 -US-Dk3,26969,GRP_ROOT_CHEM,ROOT_DATE,2004 -US-Dk3,27206,GRP_ROOT_CHEM,ROOT_DATE,2004 -US-Dk3,26019,GRP_ROOT_CHEM,ROOT_DATE,2005 -US-Dk3,27257,GRP_ROOT_CHEM,ROOT_DATE,2005 -US-Dk3,27892,GRP_ROOT_CHEM,ROOT_DATE,2006 -US-Dk3,26968,GRP_ROOT_CHEM,ROOT_DATE,2007 -US-Dk3,26968,GRP_ROOT_CHEM,ROOT_COMMENT,"all roots, pers. comm. from Rob Jackson and Will Cook" -US-Dk3,27257,GRP_ROOT_CHEM,ROOT_COMMENT,"all roots, pers. comm. from Rob Jackson and Will Cook" -US-Dk3,27892,GRP_ROOT_CHEM,ROOT_COMMENT,"all roots, pers. comm. from Rob Jackson and Will Cook" -US-Dk3,25898,GRP_ROOT_CHEM,ROOT_COMMENT,fine roots only -US-Dk3,26019,GRP_ROOT_CHEM,ROOT_COMMENT,fine roots only -US-Dk3,26967,GRP_ROOT_CHEM,ROOT_COMMENT,fine roots only -US-Dk3,27206,GRP_ROOT_CHEM,ROOT_COMMENT,fine roots only -US-Dk3,27830,GRP_ROOT_CHEM,ROOT_COMMENT,fine roots only -US-Dk3,26969,GRP_ROOT_CHEM,ROOT_COMMENT,pers. comm. from Rob Jackson and Will Cook -US-Dk3,29089,GRP_ROOT_CHEM,ROOT_COMMENT,pers. comm. from Rob Jackson and Will Cook -US-Dk3,27253,GRP_ROOT_PROD,ROOT_PROD_FINE,296 -US-Dk3,28141,GRP_ROOT_PROD,ROOT_PROD_FINE,315 -US-Dk3,27216,GRP_ROOT_PROD,ROOT_PROD_FINE,33 -US-Dk3,28107,GRP_ROOT_PROD,ROOT_PROD_FINE,56 -US-Dk3,28142,GRP_ROOT_PROD,ROOT_PROD_FINE,77 -US-Dk3,27216,GRP_ROOT_PROD,ROOT_PROD_UNIT,gC m-2 -US-Dk3,27253,GRP_ROOT_PROD,ROOT_PROD_UNIT,gC m-2 -US-Dk3,28107,GRP_ROOT_PROD,ROOT_PROD_UNIT,gC m-2 -US-Dk3,28141,GRP_ROOT_PROD,ROOT_PROD_UNIT,gC m-2 -US-Dk3,28142,GRP_ROOT_PROD,ROOT_PROD_UNIT,gC m-2 -US-Dk3,27216,GRP_ROOT_PROD,ROOT_PROD_PROFILE_MIN,0 -US-Dk3,27253,GRP_ROOT_PROD,ROOT_PROD_PROFILE_MIN,0 -US-Dk3,28107,GRP_ROOT_PROD,ROOT_PROD_PROFILE_MIN,0 -US-Dk3,28141,GRP_ROOT_PROD,ROOT_PROD_PROFILE_MIN,0 -US-Dk3,28142,GRP_ROOT_PROD,ROOT_PROD_PROFILE_MIN,0 -US-Dk3,27216,GRP_ROOT_PROD,ROOT_PROD_PROFILE_MAX,30 -US-Dk3,27253,GRP_ROOT_PROD,ROOT_PROD_PROFILE_MAX,30 -US-Dk3,28107,GRP_ROOT_PROD,ROOT_PROD_PROFILE_MAX,30 -US-Dk3,28141,GRP_ROOT_PROD,ROOT_PROD_PROFILE_MAX,30 -US-Dk3,28142,GRP_ROOT_PROD,ROOT_PROD_PROFILE_MAX,30 -US-Dk3,28107,GRP_ROOT_PROD,ROOT_PROD_DATE_START,2001 -US-Dk3,27216,GRP_ROOT_PROD,ROOT_PROD_DATE_START,2002 -US-Dk3,28141,GRP_ROOT_PROD,ROOT_PROD_DATE_START,2003 -US-Dk3,28142,GRP_ROOT_PROD,ROOT_PROD_DATE_START,2004 -US-Dk3,27253,GRP_ROOT_PROD,ROOT_PROD_DATE_START,2005 -US-Dk3,27216,GRP_ROOT_PROD,ROOT_PROD_COMMENT,"(1) McCarthy, H.R. 2007 ( Long-term effects of elevated CO2, soil nutrition, water availability and disturbance on carbon relations in a loblolly pine forest. PhD Dissertation. Nicholas School of the Environment, Duke University." -US-Dk3,27253,GRP_ROOT_PROD,ROOT_PROD_COMMENT,"(1) McCarthy, H.R. 2007 ( Long-term effects of elevated CO2, soil nutrition, water availability and disturbance on carbon relations in a loblolly pine forest. PhD Dissertation. Nicholas School of the Environment, Duke University." -US-Dk3,28107,GRP_ROOT_PROD,ROOT_PROD_COMMENT,"(1) McCarthy, H.R. 2007 ( Long-term effects of elevated CO2, soil nutrition, water availability and disturbance on carbon relations in a loblolly pine forest. PhD Dissertation. Nicholas School of the Environment, Duke University." -US-Dk3,28141,GRP_ROOT_PROD,ROOT_PROD_COMMENT,"(1) McCarthy, H.R. 2007 ( Long-term effects of elevated CO2, soil nutrition, water availability and disturbance on carbon relations in a loblolly pine forest. PhD Dissertation. Nicholas School of the Environment, Duke University." -US-Dk3,28142,GRP_ROOT_PROD,ROOT_PROD_COMMENT,"(1) McCarthy, H.R. 2007 ( Long-term effects of elevated CO2, soil nutrition, water availability and disturbance on carbon relations in a loblolly pine forest. PhD Dissertation. Nicholas School of the Environment, Duke University." -US-Dk3,27847,GRP_SA,SA,20 -US-Dk3,27847,GRP_SA,SA_DATE,2003 -US-Dk3,27847,GRP_SA,SA_COMMENT,Site was established in 1983 -US-Dk3,27848,GRP_SA,SA_DATE,2003 -US-Dk3,27848,GRP_SA,SA_COMMENT,The stand is of uniform age -US-Dk3,27848,GRP_SA,SA_MAX,20 -US-Dk3,8407,GRP_SITE_CHAR,TERRAIN,Gentle slope (<2 %) -US-Dk3,1092,GRP_SITE_DESC,SITE_DESC,The site was established in 1983 following a clear cut and a burn. Pinus taeda L. (loblolly pine) seedlings were planted at 2.4m by 2.4m spacing and ecosystem development has not been managed after planting. Canopy height increased from 16m in 2001 to 18m in 2004. The canopy is comprised primarily of P. taeda with some emergent Liquidambar styraciflua L. and a diverse and growing understory with 26 different woody species of diameter breast height 42.5 cm. The flux tower lies upwind of the CO2-enriched components of the free atmosphere carbon enrichment (FACE) facility located in the same pine forest. EC instrumentation is at 20.2m on a 22m tower. -US-Dk3,6704,GRP_SITE_FUNDING,SITE_FUNDING,DOE/TCP -US-Dk3,27538,GRP_SOIL_CHEM,SOIL_CHEM_C_ORG,24 -US-Dk3,27258,GRP_SOIL_CHEM,SOIL_CHEM_C_ORG,61 -US-Dk3,27259,GRP_SOIL_CHEM,SOIL_CHEM_N_TOT,1.2 -US-Dk3,28147,GRP_SOIL_CHEM,SOIL_CHEM_N_TOT,1.3 -US-Dk3,26971,GRP_SOIL_CHEM,SOIL_CHEM_N_TOT,1.5 -US-Dk3,28148,GRP_SOIL_CHEM,SOIL_CHEM_PH_SALT,4.85 -US-Dk3,28258,GRP_SOIL_CHEM,SOIL_CHEM_PH_SALT,4.87 -US-Dk3,26693,GRP_SOIL_CHEM,SOIL_CHEM_PH_SALT,4.9 -US-Dk3,29449,GRP_SOIL_CHEM,SOIL_CHEM_PH_SALT,4.91 -US-Dk3,29090,GRP_SOIL_CHEM,SOIL_CHEM_PH_SALT,4.95 -US-Dk3,29091,GRP_SOIL_CHEM,SOIL_CHEM_PH_SALT,4.98 -US-Dk3,28486,GRP_SOIL_CHEM,SOIL_CHEM_PH_SALT,5.02 -US-Dk3,26831,GRP_SOIL_CHEM,SOIL_CHEM_PH_SALT,5.04 -US-Dk3,27260,GRP_SOIL_CHEM,SOIL_CHEM_PH_SALT,5.1 -US-Dk3,28487,GRP_SOIL_CHEM,SOIL_CHEM_PH_SALT,5.11 -US-Dk3,26970,GRP_SOIL_CHEM,SOIL_CHEM_PH_SALT,5.24 -US-Dk3,28257,GRP_SOIL_CHEM,SOIL_CHEM_BD,1.27 -US-Dk3,27538,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,0 -US-Dk3,28147,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,0 -US-Dk3,28148,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,0 -US-Dk3,28257,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,0 -US-Dk3,29090,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,115 -US-Dk3,27260,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,12 -US-Dk3,26693,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,140 -US-Dk3,26831,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,225 -US-Dk3,28487,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,275 -US-Dk3,28258,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,29 -US-Dk3,29091,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,325 -US-Dk3,29449,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,48 -US-Dk3,28486,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,75 -US-Dk3,26970,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,80 -US-Dk3,26970,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,115 -US-Dk3,28148,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,12 -US-Dk3,29090,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,140 -US-Dk3,27538,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,15 -US-Dk3,28147,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,15 -US-Dk3,28486,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,225 -US-Dk3,26831,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,275 -US-Dk3,27260,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,29 -US-Dk3,28257,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,30 -US-Dk3,28487,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,325 -US-Dk3,28258,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,48 -US-Dk3,29091,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,700 -US-Dk3,26693,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,75 -US-Dk3,29449,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,80 -US-Dk3,28148,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,A -US-Dk3,27538,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,"A, AE" -US-Dk3,27260,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,AE -US-Dk3,29090,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,B -US-Dk3,26693,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,BC -US-Dk3,28258,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,BE -US-Dk3,26970,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,Bt -US-Dk3,29449,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,Bt -US-Dk3,26831,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,C -US-Dk3,28487,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,C -US-Dk3,29091,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,C -US-Dk3,28486,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,CB -US-Dk3,28257,GRP_SOIL_CHEM,SOIL_CHEM_DATE,2000 -US-Dk3,27258,GRP_SOIL_CHEM,SOIL_CHEM_DATE,2002 -US-Dk3,27538,GRP_SOIL_CHEM,SOIL_CHEM_DATE,2002 -US-Dk3,27258,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,"Forest Service %C data from soil pit with bulk density from http://face.env.duke.edu/pdf/Full_Soil_Profile.pdf. Reference: Lichter J, Barron S, Finzi A, Irving K, Roberts M, Stemmler E and W Schlesinger. 2005. Soil carbon sequestration and turnover in a pine forest after six years of atmospheric CO2 enrichment. Ecology 86(7):1835-1847. Schlesinger and Lichter (2001) Limited carbon storage in soil and litter of experimental forest plots under elevated atmospheric CO2. Nature 411:466-469, See also: http://face.env.duke.edu/pdf/Full_Soil_Profile.pdf. Also: Unpublished data, K. Johnsen et al." -US-Dk3,27259,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,"Forest Service %N data from soil pit with bulk density from http://face.env.duke.edu/pdf/Full_Soil_Profile.pdf. Reference: Lichter J, Barron S, Finzi A, Irving K, Roberts M, Stemmler E and W Schlesinger. 2005. Soil carbon sequestration and turnover in a pine forest after six years of atmospheric CO2 enrichment. Ecology 86(7):1835-1847. Schlesinger and Lichter (2001) Nature. Also: Unpublished data, K. Johnsen et al." -US-Dk3,26693,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,"Oh, N.H. and D.D. Richter. Elemental translocation and loss from three highly weathered soil-bedrock profiles in the southeastern United States. Geoderma 126 (5-25)" -US-Dk3,26831,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,"Oh, N.H. and D.D. Richter. Elemental translocation and loss from three highly weathered soil-bedrock profiles in the southeastern United States. Geoderma 126 (5-25)" -US-Dk3,26970,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,"Oh, N.H. and D.D. Richter. Elemental translocation and loss from three highly weathered soil-bedrock profiles in the southeastern United States. Geoderma 126 (5-25)" -US-Dk3,27260,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,"Oh, N.H. and D.D. Richter. Elemental translocation and loss from three highly weathered soil-bedrock profiles in the southeastern United States. Geoderma 126 (5-25)" -US-Dk3,28148,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,"Oh, N.H. and D.D. Richter. Elemental translocation and loss from three highly weathered soil-bedrock profiles in the southeastern United States. Geoderma 126 (5-25)" -US-Dk3,28258,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,"Oh, N.H. and D.D. Richter. Elemental translocation and loss from three highly weathered soil-bedrock profiles in the southeastern United States. Geoderma 126 (5-25)" -US-Dk3,28486,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,"Oh, N.H. and D.D. Richter. Elemental translocation and loss from three highly weathered soil-bedrock profiles in the southeastern United States. Geoderma 126 (5-25)" -US-Dk3,28487,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,"Oh, N.H. and D.D. Richter. Elemental translocation and loss from three highly weathered soil-bedrock profiles in the southeastern United States. Geoderma 126 (5-25)" -US-Dk3,29090,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,"Oh, N.H. and D.D. Richter. Elemental translocation and loss from three highly weathered soil-bedrock profiles in the southeastern United States. Geoderma 126 (5-25)" -US-Dk3,29091,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,"Oh, N.H. and D.D. Richter. Elemental translocation and loss from three highly weathered soil-bedrock profiles in the southeastern United States. Geoderma 126 (5-25)" -US-Dk3,29449,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,"Oh, N.H. and D.D. Richter. Elemental translocation and loss from three highly weathered soil-bedrock profiles in the southeastern United States. Geoderma 126 (5-25)" -US-Dk3,28257,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,"Reference: Lichter J, Barron S, Finzi A, Irving K, Roberts M, Stemmler E and W Schlesinger. 2005. Soil carbon sequestration and turnover in a pine forest after six years of atmospheric CO2 enrichment. Ecology 86(7):1835-1847" -US-Dk3,26971,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,"Schlesinger and Lichter (2001) Nature. Reference: Lichter J, Barron S, Finzi A, Irving K, Roberts M, Stemmler E and W Schlesinger. 2005. Soil carbon sequestration and turnover in a pine forest after six years of atmospheric CO2 enrichment. Ecology 86(7):1835-1847. Schlesinger and Lichter (2001) Nature. Also: Unpublished data, K. Johnsen et al." -US-Dk3,27538,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,"Spatially variable. Reference: Lichter J, Barron S, Finzi A, Irving K, Roberts M, Stemmler E and W Schlesinger. 2005. Soil carbon sequestration and turnover in a pine forest after six years of atmospheric CO2 enrichment. Ecology 86(7):1835-1847. Schlesinger and Lichter (2001) Limited carbon storage in soil and litter of experimental forest plots under elevated atmospheric CO2. Nature 411:466-469, See also: http://face.env.duke.edu/pdf/Full_Soil_Profile.pdf. Also: Unpublished data, K. Johnsen et al." -US-Dk3,28147,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,"Spatially variable. Reference: Lichter J, Barron S, Finzi A, Irving K, Roberts M, Stemmler E and W Schlesinger. 2005. Soil carbon sequestration and turnover in a pine forest after six years of atmospheric CO2 enrichment. Ecology 86(7):1835-1847. Schlesinger and Lichter (2001) Nature. Also: Unpublished data, K. Johnsen et al." -US-Dk3,27188,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION,"Enon Series, low-fertility, acidic Hapludalf. An imprevious clay pan is located beneath all soils at a depth of 0.30 m." -US-Dk3,27188,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION_TAXONOMY,Other -US-Dk3,24909,GRP_SOIL_DEPTH,SOIL_DEPTH,3000 -US-Dk3,24909,GRP_SOIL_DEPTH,SOIL_DEPTH_COMMENT,A clay-pan underlies the entire Blackwood division of the Duke forest at 30 cm. -US-Dk3,24522,GRP_SOIL_TEX,SOIL_TEX_SAND,25.5 -US-Dk3,24006,GRP_SOIL_TEX,SOIL_TEX_SAND,35.5 -US-Dk3,24362,GRP_SOIL_TEX,SOIL_TEX_SAND,44 -US-Dk3,25162,GRP_SOIL_TEX,SOIL_TEX_SAND,47.6 -US-Dk3,25032,GRP_SOIL_TEX,SOIL_TEX_SAND,48.4 -US-Dk3,24005,GRP_SOIL_TEX,SOIL_TEX_SAND,50.3 -US-Dk3,23736,GRP_SOIL_TEX,SOIL_TEX_SAND,55.1 -US-Dk3,24776,GRP_SOIL_TEX,SOIL_TEX_SAND,61 -US-Dk3,23879,GRP_SOIL_TEX,SOIL_TEX_SAND,63.8 -US-Dk3,24778,GRP_SOIL_TEX,SOIL_TEX_SAND,67.4 -US-Dk3,23880,GRP_SOIL_TEX,SOIL_TEX_SAND,68.9 -US-Dk3,24777,GRP_SOIL_TEX,SOIL_TEX_SILT,26.6 -US-Dk3,23878,GRP_SOIL_TEX,SOIL_TEX_SILT,27.2 -US-Dk3,23738,GRP_SOIL_TEX,SOIL_TEX_SILT,27.5 -US-Dk3,24776,GRP_SOIL_TEX,SOIL_TEX_SILT,29.4 -US-Dk3,23736,GRP_SOIL_TEX,SOIL_TEX_SILT,32.3 -US-Dk3,24362,GRP_SOIL_TEX,SOIL_TEX_SILT,37.6 -US-Dk3,25162,GRP_SOIL_TEX,SOIL_TEX_SILT,38.5 -US-Dk3,24005,GRP_SOIL_TEX,SOIL_TEX_SILT,40.1 -US-Dk3,24268,GRP_SOIL_TEX,SOIL_TEX_SILT,40.1 -US-Dk3,24523,GRP_SOIL_TEX,SOIL_TEX_SILT,40.3 -US-Dk3,25161,GRP_SOIL_TEX,SOIL_TEX_SILT,43.3 -US-Dk3,23736,GRP_SOIL_TEX,SOIL_TEX_CLAY,12.6 -US-Dk3,25162,GRP_SOIL_TEX,SOIL_TEX_CLAY,14.2 -US-Dk3,24362,GRP_SOIL_TEX,SOIL_TEX_CLAY,18.4 -US-Dk3,24102,GRP_SOIL_TEX,SOIL_TEX_CLAY,24.4 -US-Dk3,25141,GRP_SOIL_TEX,SOIL_TEX_CLAY,34.2 -US-Dk3,26054,GRP_SOIL_TEX,SOIL_TEX_CLAY,4 -US-Dk3,25551,GRP_SOIL_TEX,SOIL_TEX_CLAY,6 -US-Dk3,25161,GRP_SOIL_TEX,SOIL_TEX_CLAY,8.6 -US-Dk3,25552,GRP_SOIL_TEX,SOIL_TEX_CLAY,8.7 -US-Dk3,24005,GRP_SOIL_TEX,SOIL_TEX_CLAY,9.6 -US-Dk3,24776,GRP_SOIL_TEX,SOIL_TEX_CLAY,9.6 -US-Dk3,24120,GRP_SOIL_TEX,SOIL_TEX_WATER_HOLD_CAP,0.52 -US-Dk3,24120,GRP_SOIL_TEX,SOIL_TEX_PROFILE_MIN,0 -US-Dk3,24120,GRP_SOIL_TEX,SOIL_TEX_PROFILE_MAX,30 -US-Dk3,25032,GRP_SOIL_TEX,SOIL_TEX_HORIZON,A -US-Dk3,25161,GRP_SOIL_TEX,SOIL_TEX_HORIZON,A -US-Dk3,24005,GRP_SOIL_TEX,SOIL_TEX_HORIZON,AE -US-Dk3,24362,GRP_SOIL_TEX,SOIL_TEX_HORIZON,B -US-Dk3,23736,GRP_SOIL_TEX,SOIL_TEX_HORIZON,BC -US-Dk3,25162,GRP_SOIL_TEX,SOIL_TEX_HORIZON,BE -US-Dk3,24006,GRP_SOIL_TEX,SOIL_TEX_HORIZON,Bt -US-Dk3,24102,GRP_SOIL_TEX,SOIL_TEX_HORIZON,Bt -US-Dk3,24268,GRP_SOIL_TEX,SOIL_TEX_HORIZON,Bt -US-Dk3,24522,GRP_SOIL_TEX,SOIL_TEX_HORIZON,Bt -US-Dk3,24523,GRP_SOIL_TEX,SOIL_TEX_HORIZON,Bt -US-Dk3,25141,GRP_SOIL_TEX,SOIL_TEX_HORIZON,Bt -US-Dk3,23738,GRP_SOIL_TEX,SOIL_TEX_HORIZON,C -US-Dk3,23878,GRP_SOIL_TEX,SOIL_TEX_HORIZON,C -US-Dk3,23879,GRP_SOIL_TEX,SOIL_TEX_HORIZON,C -US-Dk3,23880,GRP_SOIL_TEX,SOIL_TEX_HORIZON,C -US-Dk3,24777,GRP_SOIL_TEX,SOIL_TEX_HORIZON,C -US-Dk3,24778,GRP_SOIL_TEX,SOIL_TEX_HORIZON,C -US-Dk3,25551,GRP_SOIL_TEX,SOIL_TEX_HORIZON,C -US-Dk3,25552,GRP_SOIL_TEX,SOIL_TEX_HORIZON,C -US-Dk3,26054,GRP_SOIL_TEX,SOIL_TEX_HORIZON,C -US-Dk3,24776,GRP_SOIL_TEX,SOIL_TEX_HORIZON,CB -US-Dk3,23736,GRP_SOIL_TEX,SOIL_TEX_COMMENT,"Oh, N.H. and D.D. Richter. Elemental translocation and loss from three highly weathered soil-bedrock profiles in the southeastern United States. Geoderma 126 (5-25)" -US-Dk3,23738,GRP_SOIL_TEX,SOIL_TEX_COMMENT,"Oh, N.H. and D.D. Richter. Elemental translocation and loss from three highly weathered soil-bedrock profiles in the southeastern United States. Geoderma 126 (5-25)" -US-Dk3,23878,GRP_SOIL_TEX,SOIL_TEX_COMMENT,"Oh, N.H. and D.D. Richter. Elemental translocation and loss from three highly weathered soil-bedrock profiles in the southeastern United States. Geoderma 126 (5-25)" -US-Dk3,23879,GRP_SOIL_TEX,SOIL_TEX_COMMENT,"Oh, N.H. and D.D. Richter. Elemental translocation and loss from three highly weathered soil-bedrock profiles in the southeastern United States. Geoderma 126 (5-25)" -US-Dk3,23880,GRP_SOIL_TEX,SOIL_TEX_COMMENT,"Oh, N.H. and D.D. Richter. Elemental translocation and loss from three highly weathered soil-bedrock profiles in the southeastern United States. Geoderma 126 (5-25)" -US-Dk3,24005,GRP_SOIL_TEX,SOIL_TEX_COMMENT,"Oh, N.H. and D.D. Richter. Elemental translocation and loss from three highly weathered soil-bedrock profiles in the southeastern United States. Geoderma 126 (5-25)" -US-Dk3,24006,GRP_SOIL_TEX,SOIL_TEX_COMMENT,"Oh, N.H. and D.D. Richter. Elemental translocation and loss from three highly weathered soil-bedrock profiles in the southeastern United States. Geoderma 126 (5-25)" -US-Dk3,24102,GRP_SOIL_TEX,SOIL_TEX_COMMENT,"Oh, N.H. and D.D. Richter. Elemental translocation and loss from three highly weathered soil-bedrock profiles in the southeastern United States. Geoderma 126 (5-25)" -US-Dk3,24268,GRP_SOIL_TEX,SOIL_TEX_COMMENT,"Oh, N.H. and D.D. Richter. Elemental translocation and loss from three highly weathered soil-bedrock profiles in the southeastern United States. Geoderma 126 (5-25)" -US-Dk3,24362,GRP_SOIL_TEX,SOIL_TEX_COMMENT,"Oh, N.H. and D.D. Richter. Elemental translocation and loss from three highly weathered soil-bedrock profiles in the southeastern United States. Geoderma 126 (5-25)" -US-Dk3,24522,GRP_SOIL_TEX,SOIL_TEX_COMMENT,"Oh, N.H. and D.D. Richter. Elemental translocation and loss from three highly weathered soil-bedrock profiles in the southeastern United States. Geoderma 126 (5-25)" -US-Dk3,24523,GRP_SOIL_TEX,SOIL_TEX_COMMENT,"Oh, N.H. and D.D. Richter. Elemental translocation and loss from three highly weathered soil-bedrock profiles in the southeastern United States. Geoderma 126 (5-25)" -US-Dk3,24776,GRP_SOIL_TEX,SOIL_TEX_COMMENT,"Oh, N.H. and D.D. Richter. Elemental translocation and loss from three highly weathered soil-bedrock profiles in the southeastern United States. Geoderma 126 (5-25)" -US-Dk3,24777,GRP_SOIL_TEX,SOIL_TEX_COMMENT,"Oh, N.H. and D.D. Richter. Elemental translocation and loss from three highly weathered soil-bedrock profiles in the southeastern United States. Geoderma 126 (5-25)" -US-Dk3,24778,GRP_SOIL_TEX,SOIL_TEX_COMMENT,"Oh, N.H. and D.D. Richter. Elemental translocation and loss from three highly weathered soil-bedrock profiles in the southeastern United States. Geoderma 126 (5-25)" -US-Dk3,25141,GRP_SOIL_TEX,SOIL_TEX_COMMENT,"Oh, N.H. and D.D. Richter. Elemental translocation and loss from three highly weathered soil-bedrock profiles in the southeastern United States. Geoderma 126 (5-25)" -US-Dk3,25161,GRP_SOIL_TEX,SOIL_TEX_COMMENT,"Oh, N.H. and D.D. Richter. Elemental translocation and loss from three highly weathered soil-bedrock profiles in the southeastern United States. Geoderma 126 (5-25)" -US-Dk3,25162,GRP_SOIL_TEX,SOIL_TEX_COMMENT,"Oh, N.H. and D.D. Richter. Elemental translocation and loss from three highly weathered soil-bedrock profiles in the southeastern United States. Geoderma 126 (5-25)" -US-Dk3,25551,GRP_SOIL_TEX,SOIL_TEX_COMMENT,"Oh, N.H. and D.D. Richter. Elemental translocation and loss from three highly weathered soil-bedrock profiles in the southeastern United States. Geoderma 126 (5-25)" -US-Dk3,25552,GRP_SOIL_TEX,SOIL_TEX_COMMENT,"Oh, N.H. and D.D. Richter. Elemental translocation and loss from three highly weathered soil-bedrock profiles in the southeastern United States. Geoderma 126 (5-25)" -US-Dk3,26054,GRP_SOIL_TEX,SOIL_TEX_COMMENT,"Oh, N.H. and D.D. Richter. Elemental translocation and loss from three highly weathered soil-bedrock profiles in the southeastern United States. Geoderma 126 (5-25)" -US-Dk3,27849,GRP_SPP_O,SPP_O,PITA (NRCS plant code) -US-Dk3,27849,GRP_SPP_O,SPP_O_PERC,90 -US-Dk3,27849,GRP_SPP_O,SPP_DATE,2002 -US-Dk3,27849,GRP_SPP_O,SPP_COMMENT,90% of basal area was Pinus taeda in 2002 -US-Dk3,27244,GRP_SPP_U,SPP_U,ACRU (NRCS plant code) -US-Dk3,27886,GRP_SPP_U,SPP_U,COFL2 (NRCS plant code) -US-Dk3,28945,GRP_SPP_U,SPP_U,LIST2 (NRCS plant code) -US-Dk3,27245,GRP_SPP_U,SPP_U,ULAL (NRCS plant code) -US-Dk3,27244,GRP_SPP_U,SPP_DATE,2002 -US-Dk3,27245,GRP_SPP_U,SPP_DATE,2002 -US-Dk3,27886,GRP_SPP_U,SPP_DATE,2002 -US-Dk3,28945,GRP_SPP_U,SPP_DATE,2002 -US-Dk3,27244,GRP_SPP_U,SPP_COMMENT,90% of basal area was Pinus taeda in 2002 -US-Dk3,27245,GRP_SPP_U,SPP_COMMENT,90% of basal area was Pinus taeda in 2002 -US-Dk3,27886,GRP_SPP_U,SPP_COMMENT,90% of basal area was Pinus taeda in 2002 -US-Dk3,28945,GRP_SPP_U,SPP_COMMENT,90% of basal area was Pinus taeda in 2002 -US-Dk3,5755,GRP_STATE,STATE,NC -US-Dk3,12689,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Chris Oishi -US-Dk3,12689,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Dk3,12689,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,christopher.oishi@gmail.com -US-Dk3,12689,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,USDA Forest Service -US-Dk3,12686,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Kim Novick -US-Dk3,12686,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Dk3,12686,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,knovick@indiana.edu -US-Dk3,12686,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Indiana University -US-Dk3,12687,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Paul Stoy -US-Dk3,12687,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Dk3,12687,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,paul.stoy@montana.edu -US-Dk3,12687,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Montana State University -US-Dk3,5884,GRP_URL,URL,http://www.nicholas.duke.edu/other/AMERIFLUX/amerflux.html -US-Dk3,24000359,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-Dk3 -US-Dk3,33628,GRP_UTC_OFFSET,UTC_OFFSET,-5 -US-Dk3,33628,GRP_UTC_OFFSET,UTC_OFFSET_COMMENT,Added by AMF data processing team for data QAQC checks. -US-Dk3,25278,GRP_WD_BIOMASS,WD_BIOMASS_CRS,255 -US-Dk3,25278,GRP_WD_BIOMASS,WD_BIOMASS_UNIT,gC m-2 -US-Dk3,25278,GRP_WD_BIOMASS,WD_BIOMASS_DATE,20030115 -US-Dk3,25278,GRP_WD_BIOMASS,WD_BIOMASS_COMMENT,Coarse woody debris following a severe ice storm. See McCarthy et al. (2006) JGR Table 1 and Figure 3 -US-Dmg,98316,GRP_CLIM_AVG,MAT,16.1 -US-Dmg,98316,GRP_CLIM_AVG,MAP,365 -US-Dmg,98316,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Csa -US-Dmg,27001202,GRP_COUNTRY,COUNTRY,USA -US-Dmg,98300,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Hydrologic event -US-Dmg,98312,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Dmg,98312,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-Dmg,98312,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20210902 -US-Dmg,98312,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Dmg,98299,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Dmg,98299,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CH4 -US-Dmg,98299,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20210902 -US-Dmg,98299,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Dmg,98306,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Dmg,98306,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-Dmg,98306,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20210902 -US-Dmg,98306,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Dmg,23001202,GRP_HEADER,SITE_NAME,Dutch Slough Marsh Gilbert Tract -US-Dmg,98305,GRP_IGBP,IGBP,WET -US-Dmg,98305,GRP_IGBP,IGBP_DATE_START,20210902 -US-Dmg,98314,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-Dmg,98314,GRP_LAND_OWNERSHIP,LAND_OWNER,CA Department of Water Resources -US-Dmg,98313,GRP_LOCATION,LOCATION_LAT,38.0015 -US-Dmg,98313,GRP_LOCATION,LOCATION_LONG,-121.6691 -US-Dmg,98313,GRP_LOCATION,LOCATION_ELEV,1 -US-Dmg,98313,GRP_LOCATION,LOCATION_DATE_START,20210902 -US-Dmg,98310,GRP_NETWORK,NETWORK,AmeriFlux -US-Dmg,98304,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"Greenhouse gas exchange, Net Ecoystem Carbon Balance, Tidal exchange of carbon, Wetland restoration" -US-Dmg,98301,GRP_SITE_CHAR,TERRAIN,Flat -US-Dmg,98301,GRP_SITE_CHAR,ASPECT,FLAT -US-Dmg,98301,GRP_SITE_CHAR,WIND_DIRECTION,WNW -US-Dmg,98301,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,750 -US-Dmg,98301,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,0 -US-Dmg,98307,GRP_SITE_DESC,SITE_DESC,"A new restored tidal freshwater wetland located on the west Delta, within Oakley, CA. The tower is located in the eastern side of the Gilbert Parcel seeing the mid marsh transition zone upwind. Restoration work is done by DWR and started in 2018, revegetation planting started in late 2019, followed by tidal action restoration in October 2021." -US-Dmg,98296,GRP_SITE_FUNDING,SITE_FUNDING,Delta Stewardship Council -US-Dmg,98315,GRP_STATE,STATE,CA -US-Dmg,98298,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Dennis Baldocchi -US-Dmg,98298,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Dmg,98298,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,baldocchi@berkeley.edu -US-Dmg,98298,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"University of California, Berkeley" -US-Dmg,98298,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"130 Mulford Hall, Berkeley, CA" -US-Dmg,98303,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Ariane Arias-Ortiz -US-Dmg,98303,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-Dmg,98303,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,aariasortiz@berkeley.edu -US-Dmg,98303,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"University of California, Berkeley" -US-Dmg,98303,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"130 Mulford Hall, Berkeley, CA" -US-Dmg,98297,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Joe Verfaillie -US-Dmg,98297,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,DataManager -US-Dmg,98297,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,jverfail@berkeley.edu -US-Dmg,98297,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"University of California, Berkeley" -US-Dmg,98297,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"130 Mulford Hall, Berkeley, CA" -US-Dmg,98311,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Daphne Szutu -US-Dmg,98311,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Technician -US-Dmg,98311,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,daphneszutu@berkeley.edu -US-Dmg,98311,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"University of California, Berkeley" -US-Dmg,98311,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"130 Mulford Hall, Berkeley, CA" -US-Dmg,98309,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-Dmg,98308,GRP_TOWER_TYPE,TOWER_TYPE,walk-up -US-Dmg,24001202,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-Dmg -US-Dmg,98302,GRP_UTC_OFFSET,UTC_OFFSET,-8 -US-Dmg,98302,GRP_UTC_OFFSET,UTC_OFFSET_DATE_START,20210902 -US-DPP,86719,GRP_CLIM_AVG,MAT,22.6 -US-DPP,86719,GRP_CLIM_AVG,MAP,1142 -US-DPP,86719,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Cwa -US-DPP,27001065,GRP_COUNTRY,COUNTRY,USA -US-DPP,86734,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Fire -US-DPP,86730,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-DPP,86730,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-DPP,86730,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20100121 -US-DPP,86730,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20160313 -US-DPP,86730,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-DPP,86728,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-DPP,86728,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-DPP,86728,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20100121 -US-DPP,86728,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20160313 -US-DPP,86728,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-DPP,86723,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-DPP,86723,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-DPP,86723,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20100121 -US-DPP,86723,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20160313 -US-DPP,86723,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-DPP,23001065,GRP_HEADER,SITE_NAME,Disney Wilderness Preserve Pine Flatwoods -US-DPP,86725,GRP_IGBP,IGBP,ENF -US-DPP,86725,GRP_IGBP,IGBP_COMMENT,Longleaf pine flatwoods -US-DPP,86726,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -US-DPP,86726,GRP_LAND_OWNERSHIP,LAND_OWNER,The Nature Conservancy -US-DPP,86733,GRP_LOCATION,LOCATION_LAT,28.1046 -US-DPP,86733,GRP_LOCATION,LOCATION_LONG,-81.4190 -US-DPP,86733,GRP_LOCATION,LOCATION_ELEV,23 -US-DPP,86733,GRP_LOCATION,LOCATION_DATE_START,20100101 -US-DPP,86720,GRP_NETWORK,NETWORK,AmeriFlux -US-DPP,86731,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"Carbon, water and heat fluxes in a Florida pine flatwoods under fire management" -US-DPP,86735,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"School of Forest Resources & Conservation, University of Florida, Gainesville, FL, 32611." -US-DPP,86717,GRP_SITE_CHAR,TERRAIN,Flat -US-DPP,86717,GRP_SITE_CHAR,ASPECT,FLAT -US-DPP,86717,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,800 -US-DPP,86717,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,0 -US-DPP,86729,GRP_SITE_DESC,SITE_DESC,The area was set aside for conservation as a mitigation site. It was unmanaged Longleaf Pine stand -US-DPP,86722,GRP_SITE_FUNDING,SITE_FUNDING,The Nature Conservancy hosted a research project by UCF funded by DOE -US-DPP,86718,GRP_STATE,STATE,FL -US-DPP,86727,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Charles Ross Hinkle -US-DPP,86727,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-DPP,86727,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,rhinkle@ucf.edu -US-DPP,86727,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Central Florida -US-DPP,86727,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Department of Biology, 4110 Libra Drive , Orlando FL, 32816" -US-DPP,86732,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Rosvel Bracho -US-DPP,86732,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-DPP,86732,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,rbracho@ufl.edu -US-DPP,86732,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Florida -US-DPP,86732,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"School of Forest Resources & Conservation, University of Florida, Gainesville, FL, 32611." -US-DPP,86724,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-DPP,86721,GRP_TOWER_TYPE,TOWER_TYPE,triangle -US-DPP,24001065,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-DPP -US-DPP,86921,GRP_UTC_OFFSET,UTC_OFFSET,-5 -US-DPW,86871,GRP_CLIM_AVG,MAT,22.6 -US-DPW,86871,GRP_CLIM_AVG,MAP,1142 -US-DPW,86871,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Cwa -US-DPW,27001074,GRP_COUNTRY,COUNTRY,USA -US-DPW,87985,GRP_DOI,DOI,10.17190/AMF/1562387 -US-DPW,87985,GRP_DOI,DOI_CITATION,"Charless Ross Hinkle (2019), AmeriFlux BASE US-DPW Disney Wilderness Preserve Wetland, Ver. 1-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1562387" -US-DPW,87985,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-DPW,87966,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-DPW,87966,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Charless Ross Hinkle -US-DPW,87966,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-DPW,87966,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,rhinkle@ucf.edu -US-DPW,87966,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of Central Florida -US-DPW,87979,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,University of Central Florida -US-DPW,87979,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-DPW,93392,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,University of Central Florida (UCF) -US-DPW,93392,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-DPW,93393,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Department of Energy (DOE) -US-DPW,93393,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-DPW,87971,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,The Nature Conservancy hosted a research project by UCF funded by DOE -US-DPW,87971,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-DPW,86889,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Fire -US-DPW,86879,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Hydrologic event -US-DPW,86874,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-DPW,86874,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-DPW,86874,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20130513 -US-DPW,86874,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20170104 -US-DPW,86874,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-DPW,86883,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-DPW,86883,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CH4 -US-DPW,86883,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20130513 -US-DPW,86883,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20170104 -US-DPW,86883,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-DPW,86884,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-DPW,86884,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-DPW,86884,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20130513 -US-DPW,86884,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20170104 -US-DPW,86884,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-DPW,86880,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-DPW,86880,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-DPW,86880,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20130513 -US-DPW,86880,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20170104 -US-DPW,86880,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-DPW,23001074,GRP_HEADER,SITE_NAME,Disney Wilderness Preserve Wetland -US-DPW,86872,GRP_IGBP,IGBP,WET -US-DPW,86872,GRP_IGBP,IGBP_COMMENT,Graminoid marsh -US-DPW,86886,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -US-DPW,86886,GRP_LAND_OWNERSHIP,LAND_OWNER,The Nature Conservancy -US-DPW,86888,GRP_LOCATION,LOCATION_LAT,28.0521 -US-DPW,86888,GRP_LOCATION,LOCATION_LONG,-81.4361 -US-DPW,86888,GRP_LOCATION,LOCATION_ELEV,23 -US-DPW,86888,GRP_LOCATION,LOCATION_DATE_START,20130513 -US-DPW,86876,GRP_NETWORK,NETWORK,AmeriFlux -US-DPW,86873,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"Carbon, water and heat fluxes in a Florida pine flatwoods under fire management and hydrologic restoration" -US-DPW,86891,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"School of Forest Resources & Conservation, University of Florida, Gainesville, FL, 32611." -US-DPW,86890,GRP_SITE_CHAR,TERRAIN,Flat -US-DPW,86890,GRP_SITE_CHAR,ASPECT,FLAT -US-DPW,86890,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,80 -US-DPW,86890,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,0 -US-DPW,86877,GRP_SITE_DESC,SITE_DESC,The area was set aside for conservation as a mitigation site. It was unmanaged depression marsh -US-DPW,86885,GRP_SITE_FUNDING,SITE_FUNDING,The Nature Conservancy hosted a research project by UCF funded by DOE -US-DPW,86887,GRP_STATE,STATE,FL -US-DPW,86882,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Charless Ross Hinkle -US-DPW,86882,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-DPW,86882,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,rhinkle@ucf.edu -US-DPW,86882,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Central Florida -US-DPW,86882,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Department of Biology, 4110 Libra Drive , Orlando FL, 32816" -US-DPW,86881,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Rosvel Bracho -US-DPW,86881,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-DPW,86881,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,rbracho@ufl.edu -US-DPW,86881,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Florida -US-DPW,86881,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"School of Forest Resources & Conservation, University of Florida, Gainesville, FL, 32611." -US-DPW,86878,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-DPW,86875,GRP_TOWER_TYPE,TOWER_TYPE,triangle -US-DPW,24001074,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-DPW -US-DPW,87287,GRP_UTC_OFFSET,UTC_OFFSET,-5 -US-DPW,87287,GRP_UTC_OFFSET,UTC_OFFSET_DATE_START,20130513 -US-DS3,101150,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,Supported by CDFW under GRANT AGREEMENT NUMBER to The Nature Conservancy. -US-DS3,101401,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,"This work is co-funded through CDFW under grant agreement number XXXXX and the U.S. Department of Energy, ARPA-E, under Cooperative Agreement DE-AR0001228 led by ARVA Intelligence Corp. (https://www.arvaintelligence.com/) in collaboration with Lawrence Berkeley National Laboratory (LBNL)." -US-DS3,97285,GRP_CLIM_AVG,MAT,16 -US-DS3,97285,GRP_CLIM_AVG,MAP,432 -US-DS3,97285,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Csa -US-DS3,27001197,GRP_COUNTRY,COUNTRY,USA -US-DS3,97296,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Agriculture -US-DS3,97298,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-DS3,97298,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-DS3,97298,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20210604 -US-DS3,97298,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-DS3,97294,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-DS3,97294,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CH4 -US-DS3,97294,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20210604 -US-DS3,97294,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-DS3,97305,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-DS3,97305,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-DS3,97305,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20210604 -US-DS3,97305,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-DS3,101148,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-DS3,101148,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,N2O -US-DS3,101148,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20210803 -US-DS3,101148,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-DS3,23001197,GRP_HEADER,SITE_NAME,Staten Rice 1 -US-DS3,97768,GRP_IGBP,IGBP,CRO -US-DS3,97768,GRP_IGBP,IGBP_COMMENT,Rice (oryza sativa) -US-DS3,97306,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -US-DS3,97306,GRP_LAND_OWNERSHIP,LAND_OWNER,The Nature Conservancy -US-DS3,101149,GRP_LOCATION,LOCATION_LAT,38.1192 -US-DS3,101149,GRP_LOCATION,LOCATION_LONG,-121.5546 -US-DS3,101149,GRP_LOCATION,LOCATION_ELEV,-7 -US-DS3,101149,GRP_LOCATION,LOCATION_DATE_START,20210604 -US-DS3,97300,GRP_NETWORK,NETWORK,AmeriFlux -US-DS3,101185,GRP_NETWORK,NETWORK,Phenocam -US-DS3,97293,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"Land use, adaptive management, restoration, baseline monitoring, greenhouse gas" -US-DS3,97303,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"32319 N Staten Island Raod, Thornton, CA 95685" -US-DS3,97288,GRP_SITE_CHAR,TERRAIN,Flat -US-DS3,97288,GRP_SITE_CHAR,ASPECT,FLAT -US-DS3,97288,GRP_SITE_CHAR,WIND_DIRECTION,WSW -US-DS3,97288,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,500 -US-DS3,97288,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,0 -US-DS3,97289,GRP_SITE_DESC,SITE_DESC,This tower is located in a rice field in the California Delta on Staten Island. The tower is within a few square kilometers of rice fields that comprise the vast majority of the southwestern portion of Staten Island -US-DS3,97760,GRP_SITE_FUNDING,SITE_FUNDING,"This work is supported by the California Department of Fish and Wildlife and the United States Department of Energy (DOE), Advanced Research Projects Agency - Energy (ARPA-E)." -US-DS3,97287,GRP_STATE,STATE,CA -US-DS3,101186,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Michael R. Schuppenhauer -US-DS3,101186,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-DS3,101186,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,mschuppenhauer@lbl.gov -US-DS3,101186,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Arva Intelligence Corp. -US-DS3,101146,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Sebastien C. Biraud -US-DS3,101146,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-DS3,101146,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,SCBiraud@lbl.gov -US-DS3,101146,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Lawrence Berkeley National Laboratory -US-DS3,101146,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"One Cyclotron Road, Berkeley, CA 94720" -US-DS3,101405,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Steve Deverel -US-DS3,101405,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-DS3,101405,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,sdeverel@hydrofocus.com -US-DS3,101405,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Hydrofocus Inc. -US-DS3,101403,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Nick Christen -US-DS3,101403,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-DS3,101403,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,nchristen@hydrofocus.com -US-DS3,101403,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"Hydrofocus, Inc" -US-DS3,101147,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Stephen W. Chan -US-DS3,101147,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-DS3,101147,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,SWChan@lbl.gov -US-DS3,101147,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Lawrence Berkeley National Laboratory -US-DS3,101147,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"One Cyclotron Road, Berkeley, CA 94720" -US-DS3,97297,GRP_TOWER_POWER,TOWER_POWER,Direct power -US-DS3,97286,GRP_TOWER_TYPE,TOWER_TYPE,walk-up -US-DS3,24001197,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-DS3 -US-DS3,97304,GRP_UTC_OFFSET,UTC_OFFSET,-8 -US-EDN,84722,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Csa -US-EDN,27000993,GRP_COUNTRY,COUNTRY,USA -US-EDN,87119,GRP_DOI,DOI,10.17190/AMF/1543381 -US-EDN,87119,GRP_DOI,DOI_CITATION,"Patty Oikawa (2020), AmeriFlux BASE US-EDN Eden Landing Ecological Reserve, Ver. 2-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1543381" -US-EDN,87119,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-EDN,86898,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-EDN,86898,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Patty Oikawa -US-EDN,86898,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-EDN,86898,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,Patty.oikawa@csueastbay.edu -US-EDN,86898,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"Clifornia State University, East Bay" -US-EDN,93092,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,California State University East Bay -US-EDN,93092,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-EDN,86911,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,"Clifornia State University, East Bay" -US-EDN,86911,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-EDN,86910,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Cal State East Bay (CSUEB) -US-EDN,86910,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-EDN,84725,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-EDN,84725,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-EDN,84725,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20180218 -US-EDN,84725,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-EDN,84723,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-EDN,84723,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CH4 -US-EDN,84723,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20180218 -US-EDN,84723,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-EDN,84707,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-EDN,84707,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-EDN,84707,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20180218 -US-EDN,84707,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-EDN,23000993,GRP_HEADER,SITE_NAME,Eden Landing Ecological Reserve -US-EDN,84715,GRP_IGBP,IGBP,WET -US-EDN,84715,GRP_IGBP,IGBP_DATE_START,20110201 -US-EDN,84715,GRP_IGBP,IGBP_COMMENT,West coast of North America salt marsh plants: pickleweed (Salicornia spp.) and cordgrass (Spartina spp.). These vegetations were the native of this tidal salt marshe in Eden Landing prior to turning the site for Agricultural and catel use in mid 1800 and then salt harvesting production starting late 1800's up to 1972 . -US-EDN,84724,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-EDN,84724,GRP_LAND_OWNERSHIP,LAND_OWNER,California Department of Fish and Wildlife (CDFW) -US-EDN,84717,GRP_LOCATION,LOCATION_LAT,37.6156 -US-EDN,84717,GRP_LOCATION,LOCATION_LONG,-122.1140 -US-EDN,84717,GRP_LOCATION,LOCATION_DATE_START,20180216 -US-EDN,84717,GRP_LOCATION,LOCATION_COMMENT,Location was disturbed from late 1800's up to 1972 for salt harvesting. Location elevation between 36' to 48' inches (0.914m to 1.22m) -US-EDN,84708,GRP_NETWORK,NETWORK,AmeriFlux -US-EDN,1700000384,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Arias‐Ortiz, A., Oikawa, P. Y., Carlin, J., Masqué, P., Shahan, J., Kanneg, S., Paytan, A., Baldocchi, D. D. (2021) Tidal And Nontidal Marsh Restoration: A Trade‐Off Between Carbon Sequestration, Methane Emissions, And Soil Accretion, Journal Of Geophysical Research: Biogeosciences, 126(12), 108350" -US-EDN,1700000384,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2021JG006573 -US-EDN,1700000384,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-EDN,1700005271,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(), 108350" -US-EDN,1700005271,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -US-EDN,1700005271,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-EDN,84713,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"Processing collected flux data, Instrument QA" -US-EDN,84720,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"25800 Carlos Bee Blvd. Hayward, CA 94542" -US-EDN,84712,GRP_SITE_CHAR,TERRAIN,Flat -US-EDN,84712,GRP_SITE_CHAR,WIND_DIRECTION,NW -US-EDN,84712,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,0 -US-EDN,84706,GRP_SITE_DESC,SITE_DESC,"This tower located at Eden Landing Ecological Reserve, a 6400 acres reserve with diked marsh and newly (10 year old) restored salt ponds, managed by the California Department of Fish and Wildlife (CDFW) in the San Francisco Bay." -US-EDN,84714,GRP_SITE_FUNDING,SITE_FUNDING,Cal State East Bay (CSUEB) -US-EDN,84719,GRP_STATE,STATE,CA -US-EDN,84716,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Patty Oikawa -US-EDN,84716,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-EDN,84716,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,Patty.oikawa@csueastbay.edu -US-EDN,84716,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"Clifornia State University, East Bay" -US-EDN,84716,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"25800 Carlos Bee Blvd. Hayward, CA 94542" -US-EDN,84711,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-EDN,84718,GRP_TOWER_TYPE,TOWER_TYPE,other -US-EDN,84710,GRP_URL,URL,https://www.wildlife.ca.gov -US-EDN,24000993,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-EDN -US-EDN,84721,GRP_UTC_OFFSET,UTC_OFFSET,-8 -US-EKH,101319,GRP_CLIM_AVG,MAT,10 -US-EKH,101319,GRP_CLIM_AVG,MAP,894 -US-EKH,101319,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Csb -US-EKH,27001225,GRP_COUNTRY,COUNTRY,USA -US-EKH,101326,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Land cover change -US-EKH,101312,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-EKH,101312,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-EKH,101312,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,202206171500 -US-EKH,101312,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-EKH,101328,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-EKH,101328,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CH4 -US-EKH,101328,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,202206171500 -US-EKH,101328,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-EKH,101324,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-EKH,101324,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-EKH,101324,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,202206171500 -US-EKH,101324,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-EKH,23001225,GRP_HEADER,SITE_NAME,Elkhorn Slough Hester Marsh -US-EKH,101317,GRP_IGBP,IGBP,WET -US-EKH,101317,GRP_IGBP,IGBP_DATE_START,202207011700 -US-EKH,101317,GRP_IGBP,IGBP_COMMENT,limited pickleweed patches -US-EKH,101310,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -US-EKH,101310,GRP_LAND_OWNERSHIP,LAND_OWNER,Elkhorn Slough National Estuarine Reserve -US-EKH,101320,GRP_LOCATION,LOCATION_LAT,36.8094 -US-EKH,101320,GRP_LOCATION,LOCATION_LONG,-121.7523 -US-EKH,101320,GRP_LOCATION,LOCATION_ELEV,0.5 -US-EKH,101320,GRP_LOCATION,LOCATION_DATE_START,202206150800 -US-EKH,101315,GRP_NETWORK,NETWORK,AmeriFlux -US-EKH,101327,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,Greenhouse gas emissions from restored marshes and how they might change throughout the restoration process. -US-EKH,101325,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"1156 High St Mail Stop Ocean Sci. Santa Cruz, California, 95064 United States" -US-EKH,101316,GRP_SITE_CHAR,TERRAIN,Flat -US-EKH,101316,GRP_SITE_CHAR,ASPECT,WNW -US-EKH,101316,GRP_SITE_CHAR,WIND_DIRECTION,WNW -US-EKH,101316,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,200 -US-EKH,101316,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,0 -US-EKH,101313,GRP_SITE_DESC,SITE_DESC,Salt marsh restored in 2018 by adding soil to raise 61 acres of former salt marsh to an elevation that allows marsh plants to return and keep pace with projected sea level rise. Marsh is mostly bare soil and tidal channels. Marsh is flooded and drained diurnally. -US-EKH,101329,GRP_SITE_FUNDING,SITE_FUNDING,Department of Energy -US-EKH,101322,GRP_STATE,STATE,CA -US-EKH,101311,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Adina Paytan -US-EKH,101311,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-EKH,101311,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,apaytan@ucsc.edu -US-EKH,101311,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"University of California, Santa Cruz" -US-EKH,101311,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1156 High St Mail Stop Ocean Sci. Santa Cruz, California, 95064 United States" -US-EKH,101314,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Grace Pearsall -US-EKH,101314,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,AncContact -US-EKH,101314,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,gpearsal@ucsc.edu -US-EKH,101314,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"University of California, Santa Cruz" -US-EKH,101321,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Luna Oslegar -US-EKH,101321,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Technician -US-EKH,101321,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,aoslegar@ucsc.edu -US-EKH,101321,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"University of California, Santa Cruz" -US-EKH,101323,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-EKH,101330,GRP_TOWER_TYPE,TOWER_TYPE,pole -US-EKH,24001225,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-EKH -US-EKH,101318,GRP_UTC_OFFSET,UTC_OFFSET,-8 -US-EKH,101318,GRP_UTC_OFFSET,UTC_OFFSET_DATE_START,202207011700 -US-EKP,101361,GRP_CLIM_AVG,MAT,10 -US-EKP,101361,GRP_CLIM_AVG,MAP,894 -US-EKP,101361,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Csb -US-EKP,27001226,GRP_COUNTRY,COUNTRY,USA -US-EKP,101355,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Hydrologic event -US-EKP,101367,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-EKP,101367,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-EKP,101367,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,202206171500 -US-EKP,101367,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-EKP,101363,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-EKP,101363,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CH4 -US-EKP,101363,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,202206171500 -US-EKP,101363,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-EKP,101353,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-EKP,101353,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-EKP,101353,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,202206171500 -US-EKP,101353,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-EKP,23001226,GRP_HEADER,SITE_NAME,Elkhorn Slough Porter Marsh -US-EKP,101358,GRP_IGBP,IGBP,WET -US-EKP,101358,GRP_IGBP,IGBP_DATE_START,202207011700 -US-EKP,101372,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -US-EKP,101372,GRP_LAND_OWNERSHIP,LAND_OWNER,Elkhorn Slough National Estuarine Reserve -US-EKP,101365,GRP_LOCATION,LOCATION_LAT,36.8558 -US-EKP,101365,GRP_LOCATION,LOCATION_LONG,-121.7488 -US-EKP,101365,GRP_LOCATION,LOCATION_ELEV,0 -US-EKP,101365,GRP_LOCATION,LOCATION_DATE_START,202206150800 -US-EKP,101369,GRP_NETWORK,NETWORK,AmeriFlux -US-EKP,101357,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,Greenhouse gas emissions from tidally restricted salt marshes -US-EKP,101352,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"1156 High St Mail Stop Ocean Sci. Santa Cruz, California, 95064 United States" -US-EKP,101368,GRP_SITE_CHAR,TERRAIN,Flat -US-EKP,101368,GRP_SITE_CHAR,ASPECT,WNW -US-EKP,101368,GRP_SITE_CHAR,WIND_DIRECTION,WNW -US-EKP,101368,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,200 -US-EKP,101368,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,0 -US-EKP,101366,GRP_SITE_DESC,SITE_DESC,"Tidally restricted amd diked salt marsh. Berm and Islands with picklweek, cut by mudlats and an ephemeral creek." -US-EKP,101371,GRP_SITE_FUNDING,SITE_FUNDING,Department of Energy -US-EKP,101370,GRP_STATE,STATE,CA -US-EKP,101364,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Adina Paytan -US-EKP,101364,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-EKP,101364,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,apaytan@ucsc.edu -US-EKP,101364,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"University of California, Santa Cruz" -US-EKP,101364,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1156 High St Mail Stop Ocean Sci. Santa Cruz, California, 95064 United States" -US-EKP,101360,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Grace Pearsall -US-EKP,101360,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,AncContact -US-EKP,101360,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,gpearsal@ucsc.edu -US-EKP,101360,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"University of California, Santa Cruz" -US-EKP,101359,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Luna Oslegar -US-EKP,101359,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Technician -US-EKP,101359,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,aoslegar@ucsc.edu -US-EKP,101359,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"University of California, Santa Cruz" -US-EKP,101356,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-EKP,101354,GRP_TOWER_TYPE,TOWER_TYPE,pole -US-EKP,24001226,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-EKP -US-EKP,101362,GRP_UTC_OFFSET,UTC_OFFSET,-8 -US-EKP,101362,GRP_UTC_OFFSET,UTC_OFFSET_DATE_START,202207011700 -US-EKY,101348,GRP_CLIM_AVG,MAT,10 -US-EKY,101348,GRP_CLIM_AVG,MAP,894 -US-EKY,101348,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Csb -US-EKY,27001227,GRP_COUNTRY,COUNTRY,USA -US-EKY,101337,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Undisturbed -US-EKY,101336,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-EKY,101336,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-EKY,101336,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,202206171500 -US-EKY,101336,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-EKY,101343,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-EKY,101343,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CH4 -US-EKY,101343,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,202206171500 -US-EKY,101343,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-EKY,101350,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-EKY,101350,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-EKY,101350,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,202206171500 -US-EKY,101350,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-EKY,23001227,GRP_HEADER,SITE_NAME,Elkhorn Slough Yampah Marsh -US-EKY,101331,GRP_IGBP,IGBP,WET -US-EKY,101331,GRP_IGBP,IGBP_DATE_START,202207011700 -US-EKY,101331,GRP_IGBP,IGBP_COMMENT,Pickleweed' -US-EKY,101335,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -US-EKY,101335,GRP_LAND_OWNERSHIP,LAND_OWNER,Elkhorn Slough National Estuarine Reserve -US-EKY,101340,GRP_LOCATION,LOCATION_LAT,36.8105 -US-EKY,101340,GRP_LOCATION,LOCATION_LONG,-121.7487 -US-EKY,101340,GRP_LOCATION,LOCATION_ELEV,0 -US-EKY,101340,GRP_LOCATION,LOCATION_DATE_START,202206150800 -US-EKY,101342,GRP_NETWORK,NETWORK,AmeriFlux -US-EKY,101344,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,Greenhouse gas emissions from salt marshes. -US-EKY,101345,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"1156 High St Mail Stop Ocean Sci. Santa Cruz, California, 95064 United States" -US-EKY,101338,GRP_SITE_CHAR,TERRAIN,Flat -US-EKY,101338,GRP_SITE_CHAR,ASPECT,WNW -US-EKY,101338,GRP_SITE_CHAR,WIND_DIRECTION,WNW -US-EKY,101338,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,500 -US-EKY,101338,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,0 -US-EKY,101351,GRP_SITE_DESC,SITE_DESC,Undisturbed salth marsh in the Elkhorn Slough. Islands with dense pickleweek cut by tidal channels. Marsh is inundated and drained diurnally. -US-EKY,101346,GRP_SITE_FUNDING,SITE_FUNDING,Department of Energy -US-EKY,101332,GRP_STATE,STATE,CA -US-EKY,101333,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Adina Paytan -US-EKY,101333,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-EKY,101333,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,apaytan@ucsc.edu -US-EKY,101333,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"University of California, Santa Cruz" -US-EKY,101333,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1156 High St Mail Stop Ocean Sci. Santa Cruz, California, 95064 United States" -US-EKY,101339,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Grace Pearsall -US-EKY,101339,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,AncContact -US-EKY,101339,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,gpearsal@ucsc.edu -US-EKY,101339,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"University of California, Santa Cruz" -US-EKY,101334,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Luna Oslegar -US-EKY,101334,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Technician -US-EKY,101334,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,aoslegar@ucsc.edu -US-EKY,101334,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"University of California, Santa Cruz" -US-EKY,101349,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-EKY,101341,GRP_TOWER_TYPE,TOWER_TYPE,pole -US-EKY,24001227,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-EKY -US-EKY,101347,GRP_UTC_OFFSET,UTC_OFFSET,-8 -US-EKY,101347,GRP_UTC_OFFSET,UTC_OFFSET_DATE_START,202207011700 -US-Elm,27000467,GRP_COUNTRY,COUNTRY,USA -US-Elm,15769,GRP_DOI,DOI,10.17190/AMF/1246118 -US-Elm,15769,GRP_DOI,DOI_CITATION,"Gregory Starr, Steve Oberbauer (2016), AmeriFlux BASE US-Elm Everglades (long hydroperiod marsh), Ver. 4-1, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1246118" -US-Elm,15769,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-Elm,32246,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Elm,32246,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Gregory Starr -US-Elm,32246,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Elm,32246,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,gstarr@bama.ua.edu -US-Elm,32246,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of Alabama -US-Elm,32247,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Elm,32247,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Steve Oberbauer -US-Elm,32247,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Elm,32247,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,oberbaue@fiu.edu -US-Elm,32247,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Florida International University -US-Elm,32249,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Florida International University -US-Elm,32249,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-Elm,32250,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,University of Alabama -US-Elm,32250,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-Elm,32248,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,NSF/OPP -US-Elm,32248,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-Elm,1244,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Elm,1244,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-Elm,1244,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,2007 -US-Elm,1244,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Elm,23000467,GRP_HEADER,SITE_NAME,Everglades (long hydroperiod marsh) -US-Elm,8796,GRP_IGBP,IGBP,WET -US-Elm,6242,GRP_LOCATION,LOCATION_LAT,25.5519 -US-Elm,6242,GRP_LOCATION,LOCATION_LONG,-80.7826 -US-Elm,6242,GRP_LOCATION,LOCATION_ELEV,0.77 -US-Elm,2157,GRP_NETWORK,NETWORK,AmeriFlux -US-Elm,1700002607,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(), 108350" -US-Elm,1700002607,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -US-Elm,1700002607,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Elm,10160,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"1) The CO2 balances of Everglades peat and marl forming wetlands; 2) The relative contributions of physiologically-based exchange and abiotic carbon precipitation to the net CO2 flux; 3) The responses of the CO2 exchange processes to the dominant control, hydroperiod; 4) Contributions of macrophyte CO2 flux vary with hydropreiod across the landscape." -US-Elm,30776,GRP_SITE_DESC,SITE_DESC,None supplied. -US-Elm,750,GRP_SITE_FUNDING,SITE_FUNDING,NSF/OPP -US-Elm,29421,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION,Peat -US-Elm,29421,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION_TAXONOMY,Other -US-Elm,651,GRP_STATE,STATE,FL -US-Elm,3369,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Gregory Starr -US-Elm,3369,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Elm,3369,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,gstarr@bama.ua.edu -US-Elm,3369,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Alabama -US-Elm,3369,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Department of Biological Sciences, A-225C Bevill building, Campus Box 870336,Tuscaloosa,AL 35487" -US-Elm,678,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Steve Oberbauer -US-Elm,678,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Elm,678,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,oberbaue@fiu.edu -US-Elm,678,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Florida International University -US-Elm,678,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Department of Biological Sciences, OE 167, 11200 SW 8th Street,Miami, FL USA 33199" -US-Elm,5885,GRP_URL,URL,http://fcelter.fiu.edu/research/projects/sites.htm?site=SRS2&display=description&keywords=&authors= -US-Elm,24000467,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-Elm -US-Elm,33629,GRP_UTC_OFFSET,UTC_OFFSET,-5 -US-Elm,33629,GRP_UTC_OFFSET,UTC_OFFSET_COMMENT,Added by AMF data processing team for data QAQC checks. -US-EML,11145,GRP_CLIM_AVG,MAT,-1 -US-EML,11145,GRP_CLIM_AVG,MAP,378 -US-EML,11145,GRP_CLIM_AVG,CLIMATE_KOEPPEN,ET -US-EML,27000522,GRP_COUNTRY,COUNTRY,USA -US-EML,79334,GRP_DOI,DOI,10.17190/AMF/1418678 -US-EML,79334,GRP_DOI,DOI_CITATION,"Ted Schuur (2021), AmeriFlux BASE US-EML Eight Mile Lake Permafrost thaw gradient, Healy Alaska., Ver. 4-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1418678" -US-EML,79334,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-EML,33689,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-EML,33689,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Ted Schuur -US-EML,33689,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-EML,33689,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,ted.Schuur@nau.edu -US-EML,33689,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of Northern Arizona -US-EML,95122,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Northern Arizona University -US-EML,95122,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-EML,33697,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,University of Northern Arizona -US-EML,33697,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-EML,33696,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,"DOE, LTER, US-National Park Service" -US-EML,33696,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-EML,11146,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Temperature extreme -US-EML,11147,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-EML,11147,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-EML,11147,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,200806 -US-EML,11147,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-EML,11147,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,Eddy Covariance measurements through the year -US-EML,11165,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-EML,11165,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-EML,11165,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,200806 -US-EML,11165,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-EML,11165,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,Eddy Covariance measurements through the year -US-EML,11161,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-EML,11161,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-EML,11161,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,200806 -US-EML,11161,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-EML,11161,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,Eddy Covariance measurements through the year -US-EML,31014,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-EML,31014,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CH4 -US-EML,31014,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201506 -US-EML,31014,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-EML,31014,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,Eddy Covariance measurements through the year -US-EML,23000522,GRP_HEADER,SITE_NAME,"Eight Mile Lake Permafrost thaw gradient, Healy Alaska." -US-EML,11148,GRP_IGBP,IGBP,OSH -US-EML,11149,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-EML,11149,GRP_LAND_OWNERSHIP,LAND_OWNER,State of Alaska -US-EML,79380,GRP_LOCATION,LOCATION_LAT,63.8784 -US-EML,79380,GRP_LOCATION,LOCATION_LONG,-149.2536 -US-EML,79380,GRP_LOCATION,LOCATION_ELEV,700 -US-EML,11151,GRP_NETWORK,NETWORK,AmeriFlux -US-EML,11162,GRP_NETWORK,NETWORK,LTER -US-EML,1700001440,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Belshe, E. F., Schuur, E. A., Bolker, B. M., Bracho, R. (2012) Incorporating Spatial Heterogeneity Created By Permafrost Thaw Into A Landscape Carbon Estimate, Journal Of Geophysical Research: Biogeosciences, 117(G1), n/a-n/a" -US-EML,1700001440,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2011JG001836 -US-EML,1700001440,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Primary_Citation -US-EML,1700008394,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Belshe, E. F., Schuur, E. A., Grosse, G. (2013) Quantification Of Upland Thermokarst Features With High Resolution Remote Sensing, Environmental Research Letters, 8(3), n/a-n/a" -US-EML,1700008394,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1088/1748-9326/8/3/035016 -US-EML,1700008394,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-EML,1700006459,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(G1), 108350" -US-EML,1700006459,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -US-EML,1700006459,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-EML,1700004803,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Hicks Pries, C. E., Schuur, E. A., Crummer, K. G. (2013) Thawing Permafrost Increases Old Soil And Autotrophic Respiration In Tundra: Partitioning Ecosystem Respiration Using δ13C And ∆14C, Global Change Biology, 19(2), 649-661" -US-EML,1700004803,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/GCB.12058 -US-EML,1700004803,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-EML,1700007794,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Hicks Pries, C. E., Schuur, E. A., Vogel, J. G., Natali, S. M. (2013) Moisture Drives Surface Decomposition In Thawing Tundra, Journal Of Geophysical Research: Biogeosciences, 118(3), 1133-1143" -US-EML,1700007794,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/JGRG.20089 -US-EML,1700007794,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-EML,1700004980,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Lee, H., Schuur, E. A. G., Vogel, J. G. (2010) Soil CO2 Production In Upland Tundra Where Permafrost Is Thawing, Journal Of Geophysical Research: Biogeosciences, 115(G1), n/a-n/a" -US-EML,1700004980,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2008JG000906 -US-EML,1700004980,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-EML,1700008784,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Pries, C. E. H., Schuur, E. A., Crummer, K. G. (2012) Holocene Carbon Stocks And Carbon Accumulation Rates Altered In Soils Undergoing Permafrost Thaw, Ecosystems, 15(1), 162-173" -US-EML,1700008784,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1007/S10021-011-9500-4 -US-EML,1700008784,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-EML,1700006630,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Schuur, E. A., Crummer, K. G., Vogel, J. G., Mack, M. C. (2007) Plant Species Composition And Productivity Following Permafrost Thaw And Thermokarst In Alaskan Tundra, Ecosystems, 10(2), 280-292" -US-EML,1700006630,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1007/S10021-007-9024-0 -US-EML,1700006630,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-EML,1700001566,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Schuur, E. A., Vogel, J. G., Crummer, K. G., Lee, H., Sickman, J. O., Osterkamp, T. E. (2009) The Effect Of Permafrost Thaw On Old Carbon Release And Net Carbon Exchange From Tundra, Nature, 459(7246), 556-559" -US-EML,1700001566,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1038/NATURE08031 -US-EML,1700001566,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-EML,1700007614,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Trucco, C., Schuur, E. A., Natali, S. M., Belshe, E. F., Bracho, R., Vogel, J. (2012) Seven-Year Trends Of CO2 Exchange In A Tundra Ecosystem Affected By Long-Term Permafrost Thaw, Journal Of Geophysical Research: Biogeosciences, 117(G2), n/a-n/a" -US-EML,1700007614,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2011JG001907 -US-EML,1700007614,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-EML,1700005979,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Vogel, J., Schuur, E. A. G., Trucco, C., Lee, H. (2009) Response Of CO2 Exchange In A Tussock Tundra Ecosystem To Permafrost Thaw And Thermokarst Development, Journal Of Geophysical Research: Biogeosciences, 114(G4), n/a-n/a" -US-EML,1700005979,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2008JG000901 -US-EML,1700005979,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-EML,31032,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"CO2, CH4, H20 and heat fluxes fluxes in a permafrost thaw gradient" -US-EML,11154,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"LTER Lab. Institute of Arctic Biology, Irving 1 Bldg. University of Alaska, Fairbanks. Fairbanks, AK 99775" -US-EML,11155,GRP_SITE_CHAR,TERRAIN,"Medium Slope (>2 %, <5%)" -US-EML,11155,GRP_SITE_CHAR,ASPECT,N -US-EML,11155,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,213 -US-EML,11156,GRP_SITE_DESC,SITE_DESC,Tundra permafrost degrading -US-EML,11157,GRP_SITE_FUNDING,SITE_FUNDING,"DOE, LTER, US-National Park Service" -US-EML,11158,GRP_STATE,STATE,AK -US-EML,31040,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Ted Schuur -US-EML,31040,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-EML,31040,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,ted.Schuur@nau.edu -US-EML,31040,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Northern Arizona -US-EML,31040,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"CESS, Department of Bilogical Sciences (Box5640) NAU Flagstaff, AZ, 86011" -US-EML,31039,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Rosvel Bracho -US-EML,31039,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-EML,31039,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,rbracho@ufl.edu -US-EML,31039,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Florida -US-EML,31039,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"School of Forest Resources & Conservation, Unibersity of Florida, Gainesville, FL, 32611." -US-EML,101434,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Craig See -US-EML,101434,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,DataManager -US-EML,101434,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,Craig.See@nau.edu -US-EML,101434,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Northern Arizona University -US-EML,101434,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Center for Ecosystem Science and Society -Department of Biological Sciences (Box 5640) -Northern Arizona University" -US-EML,31038,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Gerardo Celis -US-EML,31038,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,DataManager -US-EML,31038,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,Gerardo.Celis@nau.edu -US-EML,31038,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Northern Arizona -US-EML,31038,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"CESS, Department of Bilogical Sciences (Box5640) NAU Flagstaff, AZ, 86011" -US-EML,95119,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Heidi Rodenhizer -US-EML,95119,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,DataManager -US-EML,95119,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,hgr7@nau.edu -US-EML,95119,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Northern Arizona -US-EML,95119,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"CESS, Department of Bilogical Sciences (Box5640) NAU Flagstaff, AZ, 86011" -US-EML,11160,GRP_URL,URL,http://www.biology.ufl.edu/ecosystemdynamics/research.html -US-EML,24000522,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-EML -US-EML,33630,GRP_UTC_OFFSET,UTC_OFFSET,-9 -US-EML,33630,GRP_UTC_OFFSET,UTC_OFFSET_COMMENT,Added by AMF data processing team for data QAQC checks. -US-EPM,93940,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,Sid Kyle Foundation for initial funding and the Martin family for donating the property -US-EPM,93939,GRP_CLIM_AVG,MAT,19 -US-EPM,93939,GRP_CLIM_AVG,MAP,600 -US-EPM,93939,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Cfa -US-EPM,27001168,GRP_COUNTRY,COUNTRY,USA -US-EPM,93937,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Drought -US-EPM,93947,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Fire -US-EPM,93944,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Grazing -US-EPM,93951,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Land cover change -US-EPM,93935,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-EPM,93935,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-EPM,93935,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,202001240030 -US-EPM,93935,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-EPM,93943,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-EPM,93943,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-EPM,93943,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,202001240030 -US-EPM,93943,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-EPM,23001168,GRP_HEADER,SITE_NAME,Edwards Plateau Martin -US-EPM,93941,GRP_IGBP,IGBP,SAV -US-EPM,93950,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-EPM,93950,GRP_LAND_OWNERSHIP,LAND_OWNER,Texas A&M AgriLife -US-EPM,93932,GRP_LOCATION,LOCATION_LAT,30.8167 -US-EPM,93932,GRP_LOCATION,LOCATION_LONG,-99.8619 -US-EPM,93948,GRP_NETWORK,NETWORK,AmeriFlux -US-EPM,93933,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,Savanna ecosystem C and water vapor fluxes -US-EPM,93952,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"Texas A&M AgriLife Research, 395 ECR 760, Sonora, TX 76950" -US-EPM,93949,GRP_SITE_DESC,SITE_DESC,"This tower is located on the Edwards Plateau at a site known as the ""Martin Ranch."" The overall property is approximately 2,000 ha and is owned by Texas A&M. Broadly, vegetation is a mix of woody (~20%) and herbaceous species (including Prosopis, Juniperus, and Quercus and a number of C4 grass and other herbaceous species). Common soils include the Tarrant series (Clayey-skeletal, smectitic, thermic Lithic Calciustolls ). Historic and current land uses include livestock grazing. Future prescribed burning is also planned at the site and may include areas in the footprint of the tower." -US-EPM,93946,GRP_SITE_FUNDING,SITE_FUNDING,Internal/Sid Kyle Foundation and partial funding from USDA grant #2019-68012-29819 -US-EPM,93945,GRP_STATE,STATE,TX -US-EPM,93936,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Jason West -US-EPM,93936,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-EPM,93936,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,jbwest@tamu.edu -US-EPM,93936,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Texas A&M University -US-EPM,93934,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Nicole Havrilchak -US-EPM,93934,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Affiliate -US-EPM,93934,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,nhavrilchak@tamu.edu -US-EPM,93938,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-EPM,93931,GRP_TOWER_TYPE,TOWER_TYPE,triangle -US-EPM,24001168,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-EPM -US-EPM,93942,GRP_UTC_OFFSET,UTC_OFFSET,-6 -US-Esm,27000468,GRP_COUNTRY,COUNTRY,USA -US-Esm,15643,GRP_DOI,DOI,10.17190/AMF/1246119 -US-Esm,15643,GRP_DOI,DOI_CITATION,"Gregory Starr, Steve Oberbauer (2016), AmeriFlux BASE US-Esm Everglades (short hydroperiod marsh), Ver. 5-1, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1246119" -US-Esm,15643,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-Esm,32251,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Esm,32251,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Gregory Starr -US-Esm,32251,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Esm,32251,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,gstarr@bama.ua.edu -US-Esm,32251,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of Alabama -US-Esm,32252,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Esm,32252,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Steve Oberbauer -US-Esm,32252,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Esm,32252,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,oberbaue@fiu.edu -US-Esm,32252,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Florida International University -US-Esm,32255,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Florida International University -US-Esm,32255,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-Esm,32254,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,University of Alabama -US-Esm,32254,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-Esm,32253,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,NSF/OPP -US-Esm,32253,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-Esm,5505,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Esm,5505,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-Esm,5505,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,2007 -US-Esm,5505,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Esm,23000468,GRP_HEADER,SITE_NAME,Everglades (short hydroperiod marsh) -US-Esm,5384,GRP_IGBP,IGBP,WET -US-Esm,7077,GRP_LOCATION,LOCATION_LAT,25.4379 -US-Esm,7077,GRP_LOCATION,LOCATION_LONG,-80.5946 -US-Esm,7077,GRP_LOCATION,LOCATION_ELEV,1.07 -US-Esm,8955,GRP_NETWORK,NETWORK,AmeriFlux -US-Esm,1623,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"1) The CO2 balances of Everglades peat and marl forming wetlands; 2) The relative contributions of physiologically-based exchange and abiotic carbon precipitation to the net CO2 flux; 3) The responses of the CO2 exchange processes to the dominant control, hydroperiod; 4) Contributions of macrophyte CO2 flux vary with hydropreiod across the landscape." -US-Esm,30778,GRP_SITE_DESC,SITE_DESC,None supplied. -US-Esm,751,GRP_SITE_FUNDING,SITE_FUNDING,NSF/OPP -US-Esm,3196,GRP_STATE,STATE,FL -US-Esm,5088,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Gregory Starr -US-Esm,5088,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Esm,5088,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,gstarr@bama.ua.edu -US-Esm,5088,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Alabama -US-Esm,5088,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Department of Biological Sciences, A-225C Bevill building, Campus Box 870336,Tuscaloosa,AL 35487" -US-Esm,4031,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Steve Oberbauer -US-Esm,4031,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Esm,4031,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,oberbaue@fiu.edu -US-Esm,4031,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Florida International University -US-Esm,4031,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Department of Biological Sciences, OE 167, 11200 SW 8th Street,Miami, FL USA 33199" -US-Esm,2475,GRP_URL,URL,http://fcelter.fiu.edu/research/projects/sites.htm?site=TS/Ph1b&display=description&keywords=&authors= -US-Esm,24000468,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-Esm -US-Esm,33631,GRP_UTC_OFFSET,UTC_OFFSET,-5 -US-Esm,33631,GRP_UTC_OFFSET,UTC_OFFSET_COMMENT,Added by AMF data processing team for data QAQC checks. -US-EvM,99077,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,"This study was supported in part by funds from the Department of Energy's National Institute for Climate Change Research grant (07‐SC‐NICCR‐1059) and the National Science Foundation Division of Atmospheric & Geospace Sciences Atmospheric Chemistry Program awards (1561139, 1233006, and 1807533)." -US-EvM,99064,GRP_CLIM_AVG,MAT,24.2 -US-EvM,99064,GRP_CLIM_AVG,MAP,1200 -US-EvM,27001222,GRP_COUNTRY,COUNTRY,USA -US-EvM,99080,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Storm or wind -US-EvM,99070,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-EvM,99070,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-EvM,99070,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20200101 -US-EvM,99070,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-EvM,99069,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-EvM,99069,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CH4 -US-EvM,99069,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20200101 -US-EvM,99069,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-EvM,99065,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-EvM,99065,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-EvM,99065,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20200101 -US-EvM,99065,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-EvM,99068,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-EvM,99068,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-EvM,99068,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20200101 -US-EvM,99068,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-EvM,23001222,GRP_HEADER,SITE_NAME,Everglades Saltwater intrusion marsh -US-EvM,99062,GRP_IGBP,IGBP,WET -US-EvM,99060,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -US-EvM,99060,GRP_LAND_OWNERSHIP,LAND_OWNER,Florida Power and Light -US-EvM,99074,GRP_LOCATION,LOCATION_LAT,25.3539 -US-EvM,99074,GRP_LOCATION,LOCATION_LONG,-80.3810 -US-EvM,99074,GRP_LOCATION,LOCATION_ELEV,0.332 -US-EvM,99074,GRP_LOCATION,LOCATION_DATE_START,20200101 -US-EvM,99074,GRP_LOCATION,LOCATION_COMMENT,This site is located on Florida Power Property -US-EvM,99079,GRP_NETWORK,NETWORK,AmeriFlux -US-EvM,99073,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,We are study the changes in structure and function of the site with mangrove invasion. We are using Eddy Covariance to study the functional changes and site surveys to determine invasion rates. -US-EvM,99066,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"301 Hackberry Ln, 1325 S and E Complex, Tuscaloosa AL 35487" -US-EvM,99061,GRP_SITE_CHAR,TERRAIN,Flat -US-EvM,99061,GRP_SITE_CHAR,ASPECT,SE -US-EvM,99061,GRP_SITE_CHAR,WIND_DIRECTION,SE -US-EvM,99061,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,3000 -US-EvM,99059,GRP_SITE_DESC,SITE_DESC,This is a site in Southeaster Florida that is experience an ecosystem state shift caused by saltwater flooding. We are seeing sawgrass mortality and mangrove invasion -US-EvM,99075,GRP_SITE_FUNDING,SITE_FUNDING,NSF-Geo - Atmospheric Chemistry -US-EvM,99076,GRP_STATE,STATE,FL -US-EvM,99063,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Gregory Starr -US-EvM,99063,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-EvM,99063,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,gstarr@ua.edu -US-EvM,99063,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Alabama -US-EvM,99063,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"300 Hackberry Ln, 1325 S and E Complex, Tuscaloosa AL 35487" -US-EvM,99078,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Steven F. Oberbuer -US-EvM,99078,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-EvM,99078,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,oberbaue@fiu.edu -US-EvM,99078,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Florida International University -US-EvM,99078,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"11200 SW 8th Street, Miami, FL 33199" -US-EvM,99067,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-EvM,99071,GRP_TOWER_TYPE,TOWER_TYPE,tripod -US-EvM,24001222,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-EvM -US-EvM,99072,GRP_UTC_OFFSET,UTC_OFFSET,-5 -US-Fcr,85268,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,"Supported by grants from JAMSTEC under the JAMSTEC-IARC collaboration study, and JSPS KAKENHI, Japan." -US-Fcr,85268,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT_COMMENT,Acknowledge JSPS KAKENHI. -US-Fcr,85260,GRP_CLIM_AVG,MAT,-2.4 -US-Fcr,85260,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dwc -US-Fcr,27001016,GRP_COUNTRY,COUNTRY,USA -US-Fcr,88090,GRP_DM_ENCROACH,DM_ENCROACH,Other -US-Fcr,88090,GRP_DM_ENCROACH,DM_DATE_START,201005200000 -US-Fcr,88090,GRP_DM_ENCROACH,DM_DATE_END,201006150000 -US-Fcr,88090,GRP_DM_ENCROACH,DM_COMMENT,"Vaccinium vitis-idaea, Ledum groenlandicum, Vaccinium caespitosum, Cornus Canadensis, Polytrichum commune, and Alnus crispa." -US-Fcr,88089,GRP_DM_FIRE,DM_FIRE,Nature induced burn -US-Fcr,88089,GRP_DM_FIRE,DM_SURF,100 -US-Fcr,88089,GRP_DM_FIRE,DM_DATE_START,201005200000 -US-Fcr,88089,GRP_DM_FIRE,DM_DATE_END,201006150000 -US-Fcr,87983,GRP_DOI,DOI,10.17190/AMF/1562388 -US-Fcr,87983,GRP_DOI,DOI_CITATION,"Masahito Ueyama, Hiroki Iwata, Yoshinobu Harazono (2019), AmeriFlux BASE US-Fcr Cascaden Ridge Fire Scar, Ver. 2-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1562388" -US-Fcr,87983,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-Fcr,88043,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Fcr,88043,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Masahito Ueyama -US-Fcr,88043,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Fcr,88043,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,1 -US-Fcr,88043,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0002-4000-4888 -US-Fcr,88043,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,miyabi-flux@muh.biglobe.ne.jp -US-Fcr,88043,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Osaka Prefecture Univeristy -US-Fcr,88056,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Fcr,88056,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Hiroki Iwata -US-Fcr,88056,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Fcr,88056,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,2 -US-Fcr,88056,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,hiwata@shinshu-u.ac.jp -US-Fcr,88056,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Shinshu University -US-Fcr,88059,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Fcr,88059,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Yoshinobu Harazono -US-Fcr,88059,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Fcr,88059,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,3 -US-Fcr,88059,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,harazono2009gl@gmail.com -US-Fcr,88059,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Osaka Prefecture Univeristy -US-Fcr,87976,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Osaka Prefecture Univeristy -US-Fcr,87976,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-Fcr,87980,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Shinshu University -US-Fcr,87980,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-Fcr,87970,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,"ArCS, KAKENHI" -US-Fcr,87970,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-Fcr,85258,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Fire -US-Fcr,85266,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Fcr,85266,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-Fcr,85266,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20110524 -US-Fcr,85266,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20140922 -US-Fcr,85266,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Fcr,85278,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Fcr,85278,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-Fcr,85278,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20110524 -US-Fcr,85278,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20140922 -US-Fcr,85278,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Fcr,85273,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Fcr,85273,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-Fcr,85273,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20110524 -US-Fcr,85273,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20140922 -US-Fcr,85273,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Fcr,23001016,GRP_HEADER,SITE_NAME,Cascaden Ridge Fire Scar -US-Fcr,85259,GRP_IGBP,IGBP,OSH -US-Fcr,85259,GRP_IGBP,IGBP_COMMENT,grasses and low shrubs. -US-Fcr,85269,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -US-Fcr,85271,GRP_LOCATION,LOCATION_LAT,65.3968 -US-Fcr,85271,GRP_LOCATION,LOCATION_LONG,-148.9348 -US-Fcr,85271,GRP_LOCATION,LOCATION_ELEV,265 -US-Fcr,85274,GRP_NETWORK,NETWORK,AmeriFlux -US-Fcr,1700001542,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Iwata, H., Ueyama, M., Harazono, Y., Tsuyuzaki, S., Kondo, M., Uchida, M. (2011) Quick recovery of carbon dioxide exchanges in a burned black spruce forest in interior Alaska, SOLA, 7(), 105-108" -US-Fcr,1700001542,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Fcr,1700000648,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Iwata, H., Ueyama, M., Harazono, Y., Tsuyuzaki, S., Kondo, M., Uchida, M. (2011) Quick recovery of carbon dioxide exchanges in a burned black spruce forest in interior Alaska, SOLA, 7(2), 105-108" -US-Fcr,1700000648,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Fcr,1700005304,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Iwata, H., Ueyama, M., Iwama, C. and Harazono, Y. (2013) Variations in fraction of absorbed photosynthetically active radiation and comparisons with MODIS data in burned black spruce forests of interior Alaska, Polar Science, 7(2), 113-124" -US-Fcr,1700005304,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Fcr,1700006132,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Masahito UEYAMA, Hiroki IWATA, Hirohiko NAGANO, Narumi TAHARA, Chie IWAMA, Yoshinobu HARAZONO (2019) Carbon dioxide balance in early-successional forests after forest fires in interior Alaska, Agricultural and Forest Meteorology, 275(), 196-207" -US-Fcr,1700006132,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Primary_Citation -US-Fcr,1700003198,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Masahito UEYAMA, Hiroki IWATA, Hirohiko NAGANO, Narumi TAHARA, Chie IWAMA, Yoshinobu HARAZONO (2019) Carbon dioxide balance in early-successional forests after forest fires in interior Alaska, Agricultural and Forest Meteorology, 275(2), 196-207" -US-Fcr,1700003198,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Primary_Citation -US-Fcr,85272,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,Understanding energy & CO2 fluxes at early successions after fire. -US-Fcr,85275,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"Syun-Ichi Akasofu Building -2160 Koyukuk Dr -Fairbanks, AK 99775" -US-Fcr,85265,GRP_SITE_CHAR,TERRAIN,"Medium Slope (>2 %, <5%)" -US-Fcr,85265,GRP_SITE_CHAR,ASPECT,SE -US-Fcr,85257,GRP_SITE_DESC,SITE_DESC,Burned black spruce forest by a moderate fire at 2010 -US-Fcr,85262,GRP_SITE_FUNDING,SITE_FUNDING,"ArCS, KAKENHI" -US-Fcr,85270,GRP_STATE,STATE,AK -US-Fcr,85267,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Hiroki Iwata -US-Fcr,85267,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Fcr,85267,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,hiwata@shinshu-u.ac.jp -US-Fcr,85267,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Shinshu University -US-Fcr,95047,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Masahito Ueyama -US-Fcr,95047,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Fcr,95047,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,miyabi-flux@muh.biglobe.ne.jp -US-Fcr,95047,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Osaka Prefecture University -US-Fcr,95036,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Yoshinobu Harazono -US-Fcr,95036,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Fcr,95036,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,harazono2009gl@gmail.com -US-Fcr,95036,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Osaka Prefecture University -US-Fcr,85264,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-Fcr,85276,GRP_TOWER_TYPE,TOWER_TYPE,tripod -US-Fcr,24001016,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-Fcr -US-Fcr,85263,GRP_UTC_OFFSET,UTC_OFFSET,-9 -US-Fmf,29205,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER,12 -US-Fmf,29205,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_ORGAN,Total -US-Fmf,29205,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_PHEN,Mixed/unknown -US-Fmf,29205,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_UNIT,gC m-2 -US-Fmf,29205,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_APPROACH,"4 , 0.5 m2 plot once per year. projected leaf area was measured in the laboratory with an image analyzer (Agvision, Monochrome System, Decagon Devices, Inc., Pullman, WA, USA)." -US-Fmf,29205,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_DATE,20070907 -US-Fmf,29190,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER,6 -US-Fmf,29190,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_ORGAN,Total -US-Fmf,29190,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_PHEN,Mixed/unknown -US-Fmf,29190,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_UNIT,gC m-2 -US-Fmf,29190,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_APPROACH,"4 , 0.5 m2 plot once per year. projected leaf area was measured in the laboratory with an image analyzer (Agvision, Monochrome System, Decagon Devices, Inc., Pullman, WA, USA)." -US-Fmf,29190,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_DATE,20060907 -US-Fmf,28840,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,2660 -US-Fmf,28840,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Total -US-Fmf,28840,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-Fmf,28840,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-Fmf,28840,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,"allometry on 5 25 m radious circular plots. Following equations in Kaye, J. P., Hart, S. C., Fule, P. Z., Covington, W. W., Moore, M. M., Kaye, M. W. 2005. Initial carbon, nitrogen, and phosphorus fluxes following ponderosa pine restoration treatments. Ecological Applications, 15(5) 1581-1593." -US-Fmf,28840,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,20070907 -US-Fmf,28839,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,3910 -US-Fmf,28839,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Total -US-Fmf,28839,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-Fmf,28839,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-Fmf,28839,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,"allometry on 5 25 m radious circular plots. Following equations in Kaye, J. P., Hart, S. C., Fule, P. Z., Covington, W. W., Moore, M. M., Kaye, M. W. 2005. Initial carbon, nitrogen, and phosphorus fluxes following ponderosa pine restoration treatments. Ecological Applications, 15(5) 1581-1593." -US-Fmf,28839,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,20060907 -US-Fmf,27372,GRP_AG_LIT_CHEM,AG_LIT_C,3.4 -US-Fmf,29193,GRP_AG_LIT_CHEM,AG_LIT_C,3.68 -US-Fmf,29208,GRP_AG_LIT_CHEM,AG_LIT_N,0.082 -US-Fmf,29192,GRP_AG_LIT_CHEM,AG_LIT_N,0.084 -US-Fmf,29192,GRP_AG_LIT_CHEM,AG_LIT_DATE,2005 -US-Fmf,29208,GRP_AG_LIT_CHEM,AG_LIT_DATE,2007 -US-Fmf,27372,GRP_AG_LIT_CHEM,AG_LIT_COMMENT,"not litter but organic horizon," -US-Fmf,29192,GRP_AG_LIT_CHEM,AG_LIT_COMMENT,"not litter but organic horizon," -US-Fmf,29193,GRP_AG_LIT_CHEM,AG_LIT_COMMENT,"not litter but organic horizon," -US-Fmf,29208,GRP_AG_LIT_CHEM,AG_LIT_COMMENT,"not litter but organic horizon," -US-Fmf,27988,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT,32 -US-Fmf,29207,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT,50 -US-Fmf,27988,GRP_AG_LIT_PROD,AG_LIT_PROD_UNIT,gC m-2 -US-Fmf,29207,GRP_AG_LIT_PROD,AG_LIT_PROD_UNIT,gC m-2 -US-Fmf,27988,GRP_AG_LIT_PROD,AG_LIT_PROD_COMMENT,only non-woody components -US-Fmf,29207,GRP_AG_LIT_PROD,AG_LIT_PROD_COMMENT,only non-woody components -US-Fmf,27076,GRP_AG_PROD_OTHER,AG_PROD_OTHER,12 -US-Fmf,27076,GRP_AG_PROD_OTHER,AG_PROD_OTHER_ORGAN,Total -US-Fmf,27076,GRP_AG_PROD_OTHER,AG_PROD_OTHER_UNIT,gC m-2 -US-Fmf,27076,GRP_AG_PROD_OTHER,AG_PROD_APPROACH,"clipping of 4 , 0.5 m2 plot once per year." -US-Fmf,27076,GRP_AG_PROD_OTHER,AG_PROD_DATE_START,20070907 -US-Fmf,27623,GRP_AG_PROD_OTHER,AG_PROD_OTHER,6 -US-Fmf,27623,GRP_AG_PROD_OTHER,AG_PROD_OTHER_ORGAN,Total -US-Fmf,27623,GRP_AG_PROD_OTHER,AG_PROD_OTHER_UNIT,gC m-2 -US-Fmf,27623,GRP_AG_PROD_OTHER,AG_PROD_APPROACH,"clipping of 4 , 0.5 m2 plot once per year." -US-Fmf,27623,GRP_AG_PROD_OTHER,AG_PROD_DATE_START,20060907 -US-Fmf,26783,GRP_AG_PROD_TREE,AG_PROD_TREE,64 -US-Fmf,26783,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Total -US-Fmf,26783,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-Fmf,26783,GRP_AG_PROD_TREE,AG_PROD_DATE_START,20060907 -US-Fmf,28843,GRP_AG_PROD_TREE,AG_PROD_TREE,70 -US-Fmf,28843,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Total -US-Fmf,28843,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-Fmf,28843,GRP_AG_PROD_TREE,AG_PROD_DATE_START,20070907 -US-Fmf,27371,GRP_BIOMASS_CHEM,BIOMASS_N,0.12 -US-Fmf,27371,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-Fmf,27371,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-Fmf,27371,GRP_BIOMASS_CHEM,BIOMASS_SPP,PIPO (NRCS plant code) -US-Fmf,27371,GRP_BIOMASS_CHEM,BIOMASS_COMMENT,pinus ponderosa; from different local studies -US-Fmf,11995,GRP_CLIM_AVG,MAT,9.5 -US-Fmf,11995,GRP_CLIM_AVG,MAP,546 -US-Fmf,11995,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Csb -US-Fmf,27000361,GRP_COUNTRY,COUNTRY,USA -US-Fmf,1147,GRP_DM_FORESTRY,DM_FORESTRY,Thinning/pruning -US-Fmf,1147,GRP_DM_FORESTRY,DM_DATE,20060901 -US-Fmf,1147,GRP_DM_FORESTRY,DM_COMMENT,40% LAI -US-Fmf,15691,GRP_DOI,DOI,10.17190/AMF/1246050 -US-Fmf,15691,GRP_DOI,DOI_CITATION,"Sabina Dore, Thomas Kolb (2019), AmeriFlux BASE US-Fmf Flagstaff - Managed Forest, Ver. 6-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1246050" -US-Fmf,15691,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-Fmf,32035,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Fmf,32035,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Sabina Dore -US-Fmf,32035,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Fmf,32035,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,Sabina.Dore@nau.edu -US-Fmf,32035,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Northern Arizona University -US-Fmf,32034,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Fmf,32034,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Thomas Kolb -US-Fmf,32034,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Fmf,32034,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,tom.kolb@nau.edu -US-Fmf,32034,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Northern Arizona University -US-Fmf,32037,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Northern Arizona University -US-Fmf,32037,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-Fmf,32036,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,USDA-NRICGP/NACP -US-Fmf,32036,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-Fmf,11996,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Forestry -US-Fmf,11997,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Fmf,11997,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-Fmf,11997,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20060101 -US-Fmf,11997,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20101231 -US-Fmf,11997,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Fmf,23000361,GRP_HEADER,SITE_NAME,Flagstaff - Managed Forest -US-Fmf,27622,GRP_HEIGHTC,HEIGHTC,18 -US-Fmf,27622,GRP_HEIGHTC,HEIGHTC_DATE,20050927 -US-Fmf,11998,GRP_IGBP,IGBP,ENF -US-Fmf,27369,GRP_LAI,LAI_TYPE,LAI -US-Fmf,27370,GRP_LAI,LAI_TYPE,LAI -US-Fmf,27369,GRP_LAI,LAI_METHOD,Other -US-Fmf,27370,GRP_LAI,LAI_METHOD,Other -US-Fmf,27369,GRP_LAI,LAI_DATE,20061002 -US-Fmf,27370,GRP_LAI,LAI_DATE,20071002 -US-Fmf,27369,GRP_LAI,LAI_COMMENT,"allometry on 5 25 m radious circular plots. Following equations and specific leaf area in Kaye, J. P., Hart, S. C., Fule, P. Z., Covington, W. W., Moore, M. M., Kaye, M. W. 2005. Initial carbon, nitrogen, and phosphorus fluxes following ponderosa pine restoration treatments. Ecological Applications, 15(5) 1581-1593." -US-Fmf,27370,GRP_LAI,LAI_COMMENT,"allometry on 5 25 m radious circular plots. Following equations and specific leaf area in Kaye, J. P., Hart, S. C., Fule, P. Z., Covington, W. W., Moore, M. M., Kaye, M. W. 2005. Initial carbon, nitrogen, and phosphorus fluxes following ponderosa pine restoration treatments. Ecological Applications, 15(5) 1581-1593." -US-Fmf,27370,GRP_LAI,LAI_TOT,0.9 -US-Fmf,27369,GRP_LAI,LAI_TOT,1.5 -US-Fmf,11999,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-Fmf,11999,GRP_LAND_OWNERSHIP,LAND_OWNER,University of northern Arizona -US-Fmf,26784,GRP_LMA,LMA,325 -US-Fmf,26784,GRP_LMA,LMA_SPP,(All) -US-Fmf,12000,GRP_LOCATION,LOCATION_LAT,35.1426 -US-Fmf,12000,GRP_LOCATION,LOCATION_LONG,-111.7273 -US-Fmf,12000,GRP_LOCATION,LOCATION_ELEV,2160 -US-Fmf,12001,GRP_NETWORK,NETWORK,AmeriFlux -US-Fmf,1700003591,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Amiro, B. D., Barr, A. G., Barr, J. G., Black, T. A., Bracho, R., Brown, M., Chen, J., Clark, K. L., Davis, K. J., Desai, A. R., Dore, S., Engel, V., Fuentes, J. D., Goldstein, A. H., Goulden, M. L., Kolb, T. E., Lavigne, M. B., Law, B. E., Margolis, H. A., Martin, T., McCaughey, J. H., Misson, L., Montes-Helu, M., Noormets, A., Randerson, J. T., Starr, G., Xiao, J. (2010) Ecosystem Carbon Dioxide Fluxes After Disturbance In Forests Of North America, Journal Of Geophysical Research, 115(G00K02), n/a-n/a" -US-Fmf,1700003591,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2010JG001390 -US-Fmf,1700003591,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Fmf,1700003255,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Baldocchi, D. D., Poindexter, C., Abraha, M., Desai, A. R., Bohrer, G., Arain, M. A., Griffis, T., Blanken, P. D., O'Halloran, T. L., Thomas, R. Q., Zhang, Q., Burns, S. P., Frank, J. M., Christian, D., Brown, S., Black, T. A., Gough, C. M., Law, B. E., Lee, X., Chen, J., Reed, D. E., Massman, W. J., Clark, K., Hatfield, J., Prueger, J., Bracho, R., Baker, J. M., Martin, T. A. (2018) Temporal Dynamics Of Aerodynamic Canopy Height Derived From Eddy Covariance Momentum Flux Data Across North American Flux Networks, Geophysical Research Letters, 45(11), 9275–9287" -US-Fmf,1700003255,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018GL079306 -US-Fmf,1700003255,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Fmf,1700008838,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Baldocchi, D. D., Poindexter, C., Abraha, M., Desai, A. R., Bohrer, G., Arain, M. A., Griffis, T., Blanken, P. D., O'Halloran, T. L., Thomas, R. Q., Zhang, Q., Burns, S. P., Frank, J. M., Christian, D., Brown, S., Black, T. A., Gough, C. M., Law, B. E., Lee, X., Chen, J., Reed, D. E., Massman, W. J., Clark, K., Hatfield, J., Prueger, J., Bracho, R., Baker, J. M., Martin, T. A. (2018) Temporal Dynamics Of Aerodynamic Canopy Height Derived From Eddy Covariance Momentum Flux Data Across North American Flux Networks, Geophysical Research Letters, 45(G00K02), 9275–9287" -US-Fmf,1700008838,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018GL079306 -US-Fmf,1700008838,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Fmf,1700002529,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(11), 108350" -US-Fmf,1700002529,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -US-Fmf,1700002529,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Fmf,1700000684,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Dore, S., Kolb, T. E., Montes-Helu, M., Eckert, S. E., Sullivan, B. W., Hungate, B. A., Kaye, J. P., Hart, S. C., Koch, G. W., Finkral, A. (2010) Carbon And Water Fluxes From Ponderosa Pine Forests Disturbed By Wildfire And Thinning, Ecological Applications, 20(3), 663-683" -US-Fmf,1700000684,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1890/09-0934.1 -US-Fmf,1700000684,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Fmf,1700001437,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Dore, S., Montes-Helu, M., Hart, S. C., Hungate, B. A., Koch, G. W., Moon, J. B., Finkral, A. J., Kolb, T. E. (2012) Recovery Of Ponderosa Pine Ecosystem Carbon And Water Fluxes From Thinning And Stand-Replacing Fire, Global Change Biology, 18(10), 3171-3185" -US-Fmf,1700001437,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/J.1365-2486.2012.02775.X -US-Fmf,1700001437,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Fmf,1700008034,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Novick, K. A., Ficklin, D. L., Stoy, P. C., Williams, C. A., Bohrer, G., Oishi, A., Papuga, S. A., Blanken, P. D., Noormets, A., Sulman, B. N., Scott, R. L., Wang, L., Phillips, R. P. (2016) The Increasing Importance Of Atmospheric Demand For Ecosystem Water And Carbon Fluxes, Nature Climate Change, 6(11), 1023-1027" -US-Fmf,1700008034,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1038/NCLIMATE3114 -US-Fmf,1700008034,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Fmf,1700008235,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Sullivan, B., Kolb, T., Hart, S., Kaye, J., Dore, S., Montes-Helu, M. (2008) Thinning Reduces Soil Carbon Dioxide But Not Methane Flux From Southwestern Usa Ponderosa Pine Forests, Forest Ecology And Management, 255(12), 4047-4055" -US-Fmf,1700008235,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.FORECO.2008.03.051 -US-Fmf,1700008235,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Fmf,12003,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,The overall goal of our research is to characterize the effect of disturbances by forest management and wildfire on fluxes of carbon dioxide (CO2) and methane (CH4) between the atmosphere and land in ponderosa pine-dominated forests of northern Arizona. -US-Fmf,27366,GRP_ROOT_BIOMASS,ROOT_BIOMASS_CRS,418 -US-Fmf,27365,GRP_ROOT_BIOMASS,ROOT_BIOMASS_CRS,580 -US-Fmf,27367,GRP_ROOT_BIOMASS,ROOT_BIOMASS_FINE,118 -US-Fmf,27621,GRP_ROOT_BIOMASS,ROOT_BIOMASS_FINE,76 -US-Fmf,27365,GRP_ROOT_BIOMASS,ROOT_BIOMASS_UNIT,gC m-2 -US-Fmf,27366,GRP_ROOT_BIOMASS,ROOT_BIOMASS_UNIT,gC m-2 -US-Fmf,27367,GRP_ROOT_BIOMASS,ROOT_BIOMASS_UNIT,gC m-2 -US-Fmf,27621,GRP_ROOT_BIOMASS,ROOT_BIOMASS_UNIT,gC m-2 -US-Fmf,27367,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MIN,0 -US-Fmf,27621,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MIN,0 -US-Fmf,27367,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MAX,15 -US-Fmf,27621,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MAX,15 -US-Fmf,27365,GRP_ROOT_BIOMASS,ROOT_BIOMASS_APPROACH,"allometry on 5 25 m radious circular plots. Following equations in Omdal, D. W. and Jacobi, W. R. 2001. Estimating large-root biomass from breast-height diameters for ponderosa pine in northern New Mexico. WJAF 16(1) 18-21." -US-Fmf,27366,GRP_ROOT_BIOMASS,ROOT_BIOMASS_APPROACH,"allometry on 5 25 m radious circular plots. Following equations in Omdal, D. W. and Jacobi, W. R. 2001. Estimating large-root biomass from breast-height diameters for ponderosa pine in northern New Mexico. WJAF 16(1) 18-21." -US-Fmf,27367,GRP_ROOT_BIOMASS,ROOT_BIOMASS_APPROACH,"three soil cores per 25 m2 radious plot (15 total per site) of 20.4 cm2 in area and a depth of 15 cm. Roots were extracted from the soil with a hydropneumatic elutriation system (Scienceware Bel-Art products, Pequannock, NJ)." -US-Fmf,27621,GRP_ROOT_BIOMASS,ROOT_BIOMASS_APPROACH,"three soil cores per 25 m2 radious plot (15 total per site) of 20.4 cm2 in area and a depth of 15 cm. Roots were extracted from the soil with a hydropneumatic elutriation system (Scienceware Bel-Art products, Pequannock, NJ)." -US-Fmf,27365,GRP_ROOT_BIOMASS,ROOT_BIOMASS_DATE,20060515 -US-Fmf,27367,GRP_ROOT_BIOMASS,ROOT_BIOMASS_DATE,20060515 -US-Fmf,27366,GRP_ROOT_BIOMASS,ROOT_BIOMASS_DATE,20070614 -US-Fmf,27621,GRP_ROOT_BIOMASS,ROOT_BIOMASS_DATE,20070614 -US-Fmf,29206,GRP_ROOT_PROD,ROOT_PROD_CRS,11 -US-Fmf,29191,GRP_ROOT_PROD,ROOT_PROD_CRS,12.5 -US-Fmf,29206,GRP_ROOT_PROD,ROOT_PROD_FINE,132 -US-Fmf,29191,GRP_ROOT_PROD,ROOT_PROD_FINE,95 -US-Fmf,29191,GRP_ROOT_PROD,ROOT_PROD_UNIT,gC m-2 -US-Fmf,29206,GRP_ROOT_PROD,ROOT_PROD_UNIT,gC m-2 -US-Fmf,29191,GRP_ROOT_PROD,ROOT_PROD_PROFILE_MIN,0 -US-Fmf,29206,GRP_ROOT_PROD,ROOT_PROD_PROFILE_MIN,0 -US-Fmf,29191,GRP_ROOT_PROD,ROOT_PROD_PROFILE_MAX,30 -US-Fmf,29206,GRP_ROOT_PROD,ROOT_PROD_PROFILE_MAX,30 -US-Fmf,29191,GRP_ROOT_PROD,ROOT_PROD_APPROACH,"allometry applied to diameter measured in 2007 and for previous years subtracting the diameter growth measured at the site on 5, 25 m radious circular plots. equations in Kaye, J. P., Hart, S. C., Fule, P. Z., Covington, W. W., Moore, M. M., Kaye, M. W. 2005. Initial carbon, nitrogen, and phosphorus fluxes following ponderosa pine restoration treatments. Ecological Applications, 15(5) 1581-1593." -US-Fmf,29206,GRP_ROOT_PROD,ROOT_PROD_APPROACH,"allometry applied to diameter measured in 2007 and for previous years subtracting the diameter growth measured at the site on 5, 25 m radious circular plots. equations in Kaye, J. P., Hart, S. C., Fule, P. Z., Covington, W. W., Moore, M. M., Kaye, M. W. 2005. Initial carbon, nitrogen, and phosphorus fluxes following ponderosa pine restoration treatments. Ecological Applications, 15(5) 1581-1593." -US-Fmf,29206,GRP_ROOT_PROD,ROOT_PROD_DATE_START,2006 -US-Fmf,29191,GRP_ROOT_PROD,ROOT_PROD_DATE_START,2007 -US-Fmf,24036,GRP_SA,SA,100 -US-Fmf,24036,GRP_SA,SA_COMMENT," -circa 100" -US-Fmf,12004,GRP_SITE_CHAR,TERRAIN,Gentle slope (<2 %) -US-Fmf,12004,GRP_SITE_CHAR,ASPECT,FLAT -US-Fmf,12004,GRP_SITE_CHAR,WIND_DIRECTION,SW -US-Fmf,12004,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,600 -US-Fmf,12004,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,60 -US-Fmf,12005,GRP_SITE_DESC,SITE_DESC,Ponderosa pine forest subject to thinning in September 2006. Project webpage http://nau.edu/CEFNS/Forestry/Research/Carbon-Flux/Sites/ -US-Fmf,12006,GRP_SITE_FUNDING,SITE_FUNDING,USDA-NRICGP/NACP -US-Fmf,28601,GRP_SOIL_CHEM,SOIL_CHEM_C_ORG,33.26 -US-Fmf,27373,GRP_SOIL_CHEM,SOIL_CHEM_C_ORG,44.24 -US-Fmf,27373,GRP_SOIL_CHEM,SOIL_CHEM_N_TOT,1.25 -US-Fmf,27373,GRP_SOIL_CHEM,SOIL_CHEM_BD,0.98 -US-Fmf,27373,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,0 -US-Fmf,28601,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,0 -US-Fmf,27373,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,15 -US-Fmf,28601,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,15 -US-Fmf,27373,GRP_SOIL_CHEM,SOIL_CHEM_DATE,2005 -US-Fmf,28601,GRP_SOIL_CHEM,SOIL_CHEM_DATE,2007 -US-Fmf,24401,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION,fine montmorillonitic complex of frigid Typic Argiborolls and Mollic Eutroboralfs -US-Fmf,24401,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION_TAXONOMY,Other -US-Fmf,26933,GRP_SOIL_DEPTH,SOIL_DEPTH,15 -US-Fmf,27375,GRP_SOIL_TEX,SOIL_TEX_SAND,13 -US-Fmf,27374,GRP_SOIL_TEX,SOIL_TEX_SAND,27 -US-Fmf,27375,GRP_SOIL_TEX,SOIL_TEX_SILT,46 -US-Fmf,27374,GRP_SOIL_TEX,SOIL_TEX_SILT,60 -US-Fmf,27374,GRP_SOIL_TEX,SOIL_TEX_CLAY,12 -US-Fmf,27375,GRP_SOIL_TEX,SOIL_TEX_CLAY,40 -US-Fmf,27374,GRP_SOIL_TEX,SOIL_TEX_HORIZON,A -US-Fmf,27375,GRP_SOIL_TEX,SOIL_TEX_HORIZON,B -US-Fmf,27368,GRP_SPP_O,SPP_O,PIPO (NRCS plant code) -US-Fmf,27987,GRP_SPP_O,SPP_O,QUGA (NRCS plant code) -US-Fmf,27987,GRP_SPP_O,SPP_O_PERC,5 -US-Fmf,27368,GRP_SPP_O,SPP_O_PERC,95 -US-Fmf,27368,GRP_SPP_O,SPP_DATE,2005 -US-Fmf,27987,GRP_SPP_O,SPP_DATE,2005 -US-Fmf,27368,GRP_SPP_O,SPP_COMMENT,pinus ponderosa -US-Fmf,27987,GRP_SPP_O,SPP_COMMENT,quercus gambelii -US-Fmf,12007,GRP_STATE,STATE,AZ -US-Fmf,12012,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Sabina Dore -US-Fmf,12012,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Fmf,12012,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,Sabina.Dore@nau.edu -US-Fmf,12012,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Northern Arizona University -US-Fmf,12012,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"School of Forestry, P.O. Box 15018,Flagstaff, AZ USA 86011-5018" -US-Fmf,12008,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Thomas Kolb -US-Fmf,12008,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Fmf,12008,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,tom.kolb@nau.edu -US-Fmf,12008,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Northern Arizona University -US-Fmf,12008,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"School of Forestry, P.O. Box 15018 ,Flagstaff, AZ USA 86011-5018" -US-Fmf,29807,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-Fmf,12009,GRP_TOWER_TYPE,TOWER_TYPE,other -US-Fmf,12010,GRP_URL,URL,http://nau.edu/CEFNS/Forestry/Research/Carbon-Flux/Sites/ -US-Fmf,24000361,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-Fmf -US-Fmf,33632,GRP_UTC_OFFSET,UTC_OFFSET,-7 -US-Fmf,33632,GRP_UTC_OFFSET,UTC_OFFSET_COMMENT,Added by AMF data processing team for data QAQC checks. -US-Fmf,28841,GRP_WD_BIOMASS,WD_BIOMASS_CRS,651 -US-Fmf,28842,GRP_WD_BIOMASS,WD_BIOMASS_CRS,652 -US-Fmf,28841,GRP_WD_BIOMASS,WD_BIOMASS_UNIT,gC m-2 -US-Fmf,28842,GRP_WD_BIOMASS,WD_BIOMASS_UNIT,gC m-2 -US-Fmf,28841,GRP_WD_BIOMASS,WD_BIOMASS_DATE,20050609 -US-Fmf,28842,GRP_WD_BIOMASS,WD_BIOMASS_DATE,20061007 -US-Fmf,28841,GRP_WD_BIOMASS,WD_BIOMASS_COMMENT,including FWD -US-Fmf,28842,GRP_WD_BIOMASS,WD_BIOMASS_COMMENT,including FWD and 414 of slash piles -US-Fuf,29209,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER,7 -US-Fuf,29209,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_ORGAN,Total -US-Fuf,29209,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_PHEN,Mixed/unknown -US-Fuf,29209,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_UNIT,gC m-2 -US-Fuf,29209,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_APPROACH,"4 , 0.5 m2 plot once per year. projected leaf area was measured in the laboratory with an image analyzer (Agvision, Monochrome System, Decagon Devices, Inc., Pullman, WA, USA)." -US-Fuf,29209,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_DATE,20070907 -US-Fuf,29318,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER,7 -US-Fuf,29318,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_ORGAN,Total -US-Fuf,29318,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_PHEN,Mixed/unknown -US-Fuf,29318,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_UNIT,gC m-2 -US-Fuf,29318,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_APPROACH,"4 , 0.5 m2 plot once per year. projected leaf area was measured in the laboratory with an image analyzer (Agvision, Monochrome System, Decagon Devices, Inc., Pullman, WA, USA)." -US-Fuf,29318,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_DATE,20060907 -US-Fuf,27732,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,5533 -US-Fuf,27732,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Total -US-Fuf,27732,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-Fuf,27732,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-Fuf,27732,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,"allometry on 5 25 m radious circular plots. Following equations in Kaye, J. P., Hart, S. C., Fule, P. Z., Covington, W. W., Moore, M. M., Kaye, M. W. 2005. Initial carbon, nitrogen, and phosphorus fluxes following ponderosa pine restoration treatments. Ecological Applications, 15(5) 1581-1593." -US-Fuf,27732,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,20060907 -US-Fuf,28844,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,5601 -US-Fuf,28844,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Total -US-Fuf,28844,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-Fuf,28844,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-Fuf,28844,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,"allometry on 5 25 m radious circular plots. Following equations in Kaye, J. P., Hart, S. C., Fule, P. Z., Covington, W. W., Moore, M. M., Kaye, M. W. 2005. Initial carbon, nitrogen, and phosphorus fluxes following ponderosa pine restoration treatments. Ecological Applications, 15(5) 1581-1593." -US-Fuf,28844,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,20070907 -US-Fuf,27990,GRP_AG_LIT_CHEM,AG_LIT_C,4.19 -US-Fuf,27990,GRP_AG_LIT_CHEM,AG_LIT_N,0.118 -US-Fuf,27990,GRP_AG_LIT_CHEM,AG_LIT_DATE,2007 -US-Fuf,27990,GRP_AG_LIT_CHEM,AG_LIT_COMMENT,"not litter but organic horizon," -US-Fuf,27079,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT,46 -US-Fuf,29534,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT,48 -US-Fuf,27079,GRP_AG_LIT_PROD,AG_LIT_PROD_UNIT,gC m-2 -US-Fuf,29534,GRP_AG_LIT_PROD,AG_LIT_PROD_UNIT,gC m-2 -US-Fuf,27079,GRP_AG_LIT_PROD,AG_LIT_PROD_COMMENT,only non-woody components -US-Fuf,29534,GRP_AG_LIT_PROD,AG_LIT_PROD_COMMENT,only non-woody components -US-Fuf,26785,GRP_AG_PROD_OTHER,AG_PROD_OTHER,7 -US-Fuf,26785,GRP_AG_PROD_OTHER,AG_PROD_OTHER_ORGAN,Total -US-Fuf,26785,GRP_AG_PROD_OTHER,AG_PROD_OTHER_UNIT,gC m-2 -US-Fuf,26785,GRP_AG_PROD_OTHER,AG_PROD_APPROACH,"clipping of 4 , 0.5 m2 plot once per year." -US-Fuf,26785,GRP_AG_PROD_OTHER,AG_PROD_DATE_START,20070907 -US-Fuf,27626,GRP_AG_PROD_OTHER,AG_PROD_OTHER,7 -US-Fuf,27626,GRP_AG_PROD_OTHER,AG_PROD_OTHER_ORGAN,Total -US-Fuf,27626,GRP_AG_PROD_OTHER,AG_PROD_OTHER_UNIT,gC m-2 -US-Fuf,27626,GRP_AG_PROD_OTHER,AG_PROD_APPROACH,"clipping of 4 , 0.5 m2 plot once per year." -US-Fuf,27626,GRP_AG_PROD_OTHER,AG_PROD_DATE_START,20060907 -US-Fuf,29210,GRP_AG_PROD_TREE,AG_PROD_TREE,56 -US-Fuf,29210,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Total -US-Fuf,29210,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-Fuf,29210,GRP_AG_PROD_TREE,AG_PROD_DATE_START,20060907 -US-Fuf,27625,GRP_AG_PROD_TREE,AG_PROD_TREE,66 -US-Fuf,27625,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Total -US-Fuf,27625,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-Fuf,27625,GRP_AG_PROD_TREE,AG_PROD_DATE_START,20070907 -US-Fuf,28602,GRP_BIOMASS_CHEM,BIOMASS_N,0.12 -US-Fuf,28602,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-Fuf,28602,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-Fuf,28602,GRP_BIOMASS_CHEM,BIOMASS_SPP,PIPO (NRCS plant code) -US-Fuf,28602,GRP_BIOMASS_CHEM,BIOMASS_COMMENT,pinus ponderosa; from different local studies -US-Fuf,12015,GRP_CLIM_AVG,MAT,8.7 -US-Fuf,12015,GRP_CLIM_AVG,MAP,562 -US-Fuf,12015,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Csb -US-Fuf,27000362,GRP_COUNTRY,COUNTRY,USA -US-Fuf,15746,GRP_DOI,DOI,10.17190/AMF/1246051 -US-Fuf,15746,GRP_DOI,DOI_CITATION,"Sabina Dore, Thomas Kolb (2019), AmeriFlux BASE US-Fuf Flagstaff - Unmanaged Forest, Ver. 6-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1246051" -US-Fuf,15746,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-Fuf,32038,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Fuf,32038,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Sabina Dore -US-Fuf,32038,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Fuf,32038,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,Sabina.Dore@nau.edu -US-Fuf,32038,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Northern Arizona University -US-Fuf,32039,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Fuf,32039,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Thomas Kolb -US-Fuf,32039,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Fuf,32039,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,tom.kolb@nau.edu -US-Fuf,32039,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Northern Arizona University -US-Fuf,32041,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Northern Arizona University -US-Fuf,32041,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-Fuf,32040,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,USDA-NRICGP/NACP -US-Fuf,32040,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-Fuf,12016,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Undisturbed -US-Fuf,12017,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Fuf,12017,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-Fuf,12017,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20060101 -US-Fuf,12017,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20101231 -US-Fuf,12017,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Fuf,23000362,GRP_HEADER,SITE_NAME,Flagstaff - Unmanaged Forest -US-Fuf,28339,GRP_HEIGHTC,HEIGHTC,18 -US-Fuf,28339,GRP_HEIGHTC,HEIGHTC_DATE,20050927 -US-Fuf,12018,GRP_IGBP,IGBP,ENF -US-Fuf,27077,GRP_LAI,LAI_TYPE,LAI -US-Fuf,27377,GRP_LAI,LAI_TYPE,LAI -US-Fuf,27077,GRP_LAI,LAI_METHOD,Other -US-Fuf,27377,GRP_LAI,LAI_METHOD,Other -US-Fuf,27377,GRP_LAI,LAI_DATE,2006 -US-Fuf,27077,GRP_LAI,LAI_DATE,2007 -US-Fuf,27077,GRP_LAI,LAI_COMMENT,"allometry on 5 25 m radious circular plots. Following equations and specific leaf area in Kaye, J. P., Hart, S. C., Fule, P. Z., Covington, W. W., Moore, M. M., Kaye, M. W. 2005. Initial carbon, nitrogen, and phosphorus fluxes following ponderosa pine restoration treatments. Ecological Applications, 15(5) 1581-1593." -US-Fuf,27377,GRP_LAI,LAI_COMMENT,"allometry on 5 25 m radious circular plots. Following equations and specific leaf area in Kaye, J. P., Hart, S. C., Fule, P. Z., Covington, W. W., Moore, M. M., Kaye, M. W. 2005. Initial carbon, nitrogen, and phosphorus fluxes following ponderosa pine restoration treatments. Ecological Applications, 15(5) 1581-1593." -US-Fuf,27077,GRP_LAI,LAI_TOT,2.2 -US-Fuf,27377,GRP_LAI,LAI_TOT,2.2 -US-Fuf,12019,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-Fuf,12019,GRP_LAND_OWNERSHIP,LAND_OWNER,Northern Arizona University/Arizona State Land Department -US-Fuf,26786,GRP_LMA,LMA,325 -US-Fuf,26786,GRP_LMA,LMA_SPP,(All) -US-Fuf,12020,GRP_LOCATION,LOCATION_LAT,35.0890 -US-Fuf,12020,GRP_LOCATION,LOCATION_LONG,-111.7620 -US-Fuf,12020,GRP_LOCATION,LOCATION_ELEV,2180 -US-Fuf,12021,GRP_NETWORK,NETWORK,AmeriFlux -US-Fuf,1700001836,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Amiro, B. D., Barr, A. G., Barr, J. G., Black, T. A., Bracho, R., Brown, M., Chen, J., Clark, K. L., Davis, K. J., Desai, A. R., Dore, S., Engel, V., Fuentes, J. D., Goldstein, A. H., Goulden, M. L., Kolb, T. E., Lavigne, M. B., Law, B. E., Margolis, H. A., Martin, T., McCaughey, J. H., Misson, L., Montes-Helu, M., Noormets, A., Randerson, J. T., Starr, G., Xiao, J. (2010) Ecosystem Carbon Dioxide Fluxes After Disturbance In Forests Of North America, Journal Of Geophysical Research, 115(G00K02), n/a-n/a" -US-Fuf,1700001836,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2010JG001390 -US-Fuf,1700001836,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Fuf,1700008772,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Baldocchi, D. D., Poindexter, C., Abraha, M., Desai, A. R., Bohrer, G., Arain, M. A., Griffis, T., Blanken, P. D., O'Halloran, T. L., Thomas, R. Q., Zhang, Q., Burns, S. P., Frank, J. M., Christian, D., Brown, S., Black, T. A., Gough, C. M., Law, B. E., Lee, X., Chen, J., Reed, D. E., Massman, W. J., Clark, K., Hatfield, J., Prueger, J., Bracho, R., Baker, J. M., Martin, T. A. (2018) Temporal Dynamics Of Aerodynamic Canopy Height Derived From Eddy Covariance Momentum Flux Data Across North American Flux Networks, Geophysical Research Letters, 45(12), 9275–9287" -US-Fuf,1700008772,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018GL079306 -US-Fuf,1700008772,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Fuf,1700002847,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Baldocchi, D. D., Poindexter, C., Abraha, M., Desai, A. R., Bohrer, G., Arain, M. A., Griffis, T., Blanken, P. D., O'Halloran, T. L., Thomas, R. Q., Zhang, Q., Burns, S. P., Frank, J. M., Christian, D., Brown, S., Black, T. A., Gough, C. M., Law, B. E., Lee, X., Chen, J., Reed, D. E., Massman, W. J., Clark, K., Hatfield, J., Prueger, J., Bracho, R., Baker, J. M., Martin, T. A. (2018) Temporal Dynamics Of Aerodynamic Canopy Height Derived From Eddy Covariance Momentum Flux Data Across North American Flux Networks, Geophysical Research Letters, 45(8), 9275–9287" -US-Fuf,1700002847,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018GL079306 -US-Fuf,1700002847,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Fuf,1700003144,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(12), 108350" -US-Fuf,1700003144,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -US-Fuf,1700003144,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Fuf,1700003549,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Dore, S., Kolb, T. E., Montes-Helu, M., Eckert, S. E., Sullivan, B. W., Hungate, B. A., Kaye, J. P., Hart, S. C., Koch, G. W., Finkral, A. (2010) Carbon And Water Fluxes From Ponderosa Pine Forests Disturbed By Wildfire And Thinning, Ecological Applications, 20(3), 663-683" -US-Fuf,1700003549,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1890/09-0934.1 -US-Fuf,1700003549,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Fuf,1700001590,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Dore, S., Kolb, T. E., Montes-Helu, M., Sullivan, B. W., Winslow, W. D., Hart, S. C., Kaye, J. P., Koch, G. W., Hungate, B. A. (2008) Long-Term Impact Of A Stand-Replacing Fire On Ecosystem CO2 Exchange Of A Ponderosa Pine Forest, Global Change Biology, 14(8), 1801-1820" -US-Fuf,1700001590,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/J.1365-2486.2008.01613.X -US-Fuf,1700001590,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Fuf,1700000336,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Dore, S., Montes-Helu, M., Hart, S. C., Hungate, B. A., Koch, G. W., Moon, J. B., Finkral, A. J., Kolb, T. E. (2012) Recovery Of Ponderosa Pine Ecosystem Carbon And Water Fluxes From Thinning And Stand-Replacing Fire, Global Change Biology, 18(10), 3171-3185" -US-Fuf,1700000336,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/J.1365-2486.2012.02775.X -US-Fuf,1700000336,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Fuf,1700002160,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Guerrieri, R., Belmecheri, S., Ollinger, S. V., Asbjornsen, H., Jennings, K., Xiao, J., Stocker, B. D., Martin, M., Hollinger, D. Y., Bracho-Garrillo, R., Clark, K., Dore, S., Kolb, T., Munger, J. W., Novick, K., Richardson, A. D. (2019) Disentangling The Role Of Photosynthesis And Stomatal Conductance On Rising Forest Water-Use Efficiency, Proceedings Of The National Academy Of Sciences, 116(34), 16909-16914" -US-Fuf,1700002160,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1073/PNAS.1905912116 -US-Fuf,1700002160,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Fuf,1700003732,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Knowles, J. F., Scott, R. L., Biederman, J. A., Blanken, P. D., Burns, S. P., Dore, S., Kolb, T. E., Litvak, M. E., Barron‐Gafford, G. A. (2020) Montane Forest Productivity Across A Semiarid Climatic Gradient, Global Change Biology, 26(12), 6945-6958" -US-Fuf,1700003732,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/GCB.15335 -US-Fuf,1700003732,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Fuf,1700006834,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Kolb, T., Dore, S., Montes-Helu, M. (2013) Extreme Late-Summer Drought Causes Neutral Annual Carbon Balance In Southwestern Ponderosa Pine Forests And Grasslands, Environmental Research Letters, 8(1), n/a-n/a" -US-Fuf,1700006834,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1088/1748-9326/8/1/015015 -US-Fuf,1700006834,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Fuf,1700006738,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Montes-Helu, M., Kolb, T., Dore, S., Sullivan, B., Hart, S., Koch, G., Hungate, B. (2009) Persistent Effects Of Fire-Induced Vegetation Change On Energy Partitioning And Evapotranspiration In Ponderosa Pine Forests, Agricultural And Forest Meteorology, 149(3-4), 491-500" -US-Fuf,1700006738,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2008.09.011 -US-Fuf,1700006738,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Fuf,1700005025,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Novick, K. A., Ficklin, D. L., Stoy, P. C., Williams, C. A., Bohrer, G., Oishi, A., Papuga, S. A., Blanken, P. D., Noormets, A., Sulman, B. N., Scott, R. L., Wang, L., Phillips, R. P. (2016) The Increasing Importance Of Atmospheric Demand For Ecosystem Water And Carbon Fluxes, Nature Climate Change, 6(11), 1023-1027" -US-Fuf,1700005025,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1038/NCLIMATE3114 -US-Fuf,1700005025,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Fuf,1700008481,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Sullivan, B. W., Dore, S., Kolb, T. E., Hart, S. C., Montes-Helu, M. C. (2010) Evaluation Of Methods For Estimating Soil Carbon Dioxide Efflux Across A Gradient Of Forest Disturbance, Global Change Biology, 16(1-3), 2449-2460" -US-Fuf,1700008481,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/J.1365-2486.2009.02139.X -US-Fuf,1700008481,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Fuf,1700006543,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Sullivan, B. W., Kolb, T. E., Hart, S. C., Kaye, J. P., Hungate, B. A., Dore, S., Montes-Helu, M. (2011) Wildfire Reduces Carbon Dioxide Efflux And Increases Methane Uptake In Ponderosa Pine Forest Soils Of The Southwestern USA, Biogeochemistry, 104(1-3), 251-265" -US-Fuf,1700006543,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1007/S10533-010-9499-1 -US-Fuf,1700006543,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Fuf,1700005394,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Sullivan, B., Kolb, T., Hart, S., Kaye, J., Dore, S., Montes-Helu, M. (2008) Thinning Reduces Soil Carbon Dioxide But Not Methane Flux From Southwestern Usa Ponderosa Pine Forests, Forest Ecology And Management, 255(12), 4047-4055" -US-Fuf,1700005394,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.FORECO.2008.03.051 -US-Fuf,1700005394,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Fuf,12023,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,The overall goal of our research is to characterize the effect of disturbances by forest management and wildfire on fluxes of carbon dioxide (CO2) and methane (CH4) between the atmosphere and land in ponderosa pine-dominated forests of northern Arizona. -US-Fuf,27378,GRP_ROOT_BIOMASS,ROOT_BIOMASS_CRS,827 -US-Fuf,28340,GRP_ROOT_BIOMASS,ROOT_BIOMASS_CRS,838 -US-Fuf,27078,GRP_ROOT_BIOMASS,ROOT_BIOMASS_FINE,133 -US-Fuf,27624,GRP_ROOT_BIOMASS,ROOT_BIOMASS_FINE,153 -US-Fuf,27078,GRP_ROOT_BIOMASS,ROOT_BIOMASS_UNIT,gC m-2 -US-Fuf,27378,GRP_ROOT_BIOMASS,ROOT_BIOMASS_UNIT,gC m-2 -US-Fuf,27624,GRP_ROOT_BIOMASS,ROOT_BIOMASS_UNIT,gC m-2 -US-Fuf,28340,GRP_ROOT_BIOMASS,ROOT_BIOMASS_UNIT,gC m-2 -US-Fuf,27078,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MIN,0 -US-Fuf,27624,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MIN,0 -US-Fuf,27078,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MAX,15 -US-Fuf,27624,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MAX,15 -US-Fuf,27378,GRP_ROOT_BIOMASS,ROOT_BIOMASS_APPROACH,"allometry on 5 25 m radious circular plots. Following equations in Omdal, D. W. and Jacobi, W. R. 2001. Estimating large-root biomass from breast-height diameters for ponderosa pine in northern New Mexico. WJAF 16(1) 18-21." -US-Fuf,28340,GRP_ROOT_BIOMASS,ROOT_BIOMASS_APPROACH,"allometry on 5 25 m radious circular plots. Following equations in Omdal, D. W. and Jacobi, W. R. 2001. Estimating large-root biomass from breast-height diameters for ponderosa pine in northern New Mexico. WJAF 16(1) 18-21." -US-Fuf,27078,GRP_ROOT_BIOMASS,ROOT_BIOMASS_APPROACH,"three soil cores per 25 m2 radious plot (15 total per site) of 20.4 cm2 in area and a depth of 15 cm. Roots were extracted from the soil with a hydropneumatic elutriation system (Scienceware Bel-Art products, Pequannock, NJ)." -US-Fuf,27624,GRP_ROOT_BIOMASS,ROOT_BIOMASS_APPROACH,"three soil cores per 25 m2 radious plot (15 total per site) of 20.4 cm2 in area and a depth of 15 cm. Roots were extracted from the soil with a hydropneumatic elutriation system (Scienceware Bel-Art products, Pequannock, NJ)." -US-Fuf,27378,GRP_ROOT_BIOMASS,ROOT_BIOMASS_DATE,20060515 -US-Fuf,27624,GRP_ROOT_BIOMASS,ROOT_BIOMASS_DATE,20060515 -US-Fuf,27078,GRP_ROOT_BIOMASS,ROOT_BIOMASS_DATE,20070614 -US-Fuf,28340,GRP_ROOT_BIOMASS,ROOT_BIOMASS_DATE,20070614 -US-Fuf,27379,GRP_ROOT_PROD,ROOT_PROD_CRS,11 -US-Fuf,29211,GRP_ROOT_PROD,ROOT_PROD_CRS,9 -US-Fuf,27989,GRP_ROOT_PROD,ROOT_PROD_FINE,138 -US-Fuf,27380,GRP_ROOT_PROD,ROOT_PROD_FINE,386 -US-Fuf,27379,GRP_ROOT_PROD,ROOT_PROD_UNIT,gC m-2 -US-Fuf,27380,GRP_ROOT_PROD,ROOT_PROD_UNIT,gC m-2 -US-Fuf,27989,GRP_ROOT_PROD,ROOT_PROD_UNIT,gC m-2 -US-Fuf,29211,GRP_ROOT_PROD,ROOT_PROD_UNIT,gC m-2 -US-Fuf,27380,GRP_ROOT_PROD,ROOT_PROD_PROFILE_MIN,0 -US-Fuf,27989,GRP_ROOT_PROD,ROOT_PROD_PROFILE_MIN,0 -US-Fuf,27380,GRP_ROOT_PROD,ROOT_PROD_PROFILE_MAX,30 -US-Fuf,27989,GRP_ROOT_PROD,ROOT_PROD_PROFILE_MAX,30 -US-Fuf,27379,GRP_ROOT_PROD,ROOT_PROD_APPROACH,"allometry applied to diameter measured in 2007 and for previous years subtracting the diameter growth measured at the site on 5, 25 m radious circular plots. equations in Kaye, J. P., Hart, S. C., Fule, P. Z., Covington, W. W., Moore, M. M., Kaye, M. W. 2005. Initial carbon, nitrogen, and phosphorus fluxes following ponderosa pine restoration treatments. Ecological Applications, 15(5) 1581-1593." -US-Fuf,29211,GRP_ROOT_PROD,ROOT_PROD_APPROACH,"allometry applied to diameter measured in 2007 and for previous years subtracting the diameter growth measured at the site on 5, 25 m radious circular plots. equations in Kaye, J. P., Hart, S. C., Fule, P. Z., Covington, W. W., Moore, M. M., Kaye, M. W. 2005. Initial carbon, nitrogen, and phosphorus fluxes following ponderosa pine restoration treatments. Ecological Applications, 15(5) 1581-1593." -US-Fuf,27380,GRP_ROOT_PROD,ROOT_PROD_APPROACH,"using the minirhizotron technique. Three acrylic minirhizotron tubes (15 total per site), with and internal diameter of 63.5 mm and wall thickness of 3 mm, were inserted in June 2005, digging a trench at an angle of approximately 45 degrees to a depth of 30cm" -US-Fuf,27989,GRP_ROOT_PROD,ROOT_PROD_APPROACH,"using the minirhizotron technique. Three acrylic minirhizotron tubes (15 total per site), with and internal diameter of 63.5 mm and wall thickness of 3 mm, were inserted in June 2005, digging a trench at an angle of approximately 45 degrees to a depth of 30cm" -US-Fuf,27380,GRP_ROOT_PROD,ROOT_PROD_DATE_START,2006 -US-Fuf,29211,GRP_ROOT_PROD,ROOT_PROD_DATE_START,2006 -US-Fuf,27379,GRP_ROOT_PROD,ROOT_PROD_DATE_START,2007 -US-Fuf,27989,GRP_ROOT_PROD,ROOT_PROD_DATE_START,2007 -US-Fuf,25074,GRP_SA,SA,100 -US-Fuf,25074,GRP_SA,SA_COMMENT," -circa 100" -US-Fuf,12024,GRP_SITE_CHAR,TERRAIN,Gentle slope (<2 %) -US-Fuf,12024,GRP_SITE_CHAR,ASPECT,W -US-Fuf,12024,GRP_SITE_CHAR,WIND_DIRECTION,SW -US-Fuf,12024,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,1000 -US-Fuf,12024,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,60 -US-Fuf,12025,GRP_SITE_DESC,SITE_DESC,Ponderosa pine forest not subject to disturbance in the last decades. Project webpage http://nau.edu/CEFNS/Forestry/Research/Carbon-Flux/Sites/. -US-Fuf,12026,GRP_SITE_FUNDING,SITE_FUNDING,USDA-NRICGP/NACP -US-Fuf,28603,GRP_SOIL_CHEM,SOIL_CHEM_C_ORG,39.92 -US-Fuf,28603,GRP_SOIL_CHEM,SOIL_CHEM_N_TOT,2.03 -US-Fuf,28603,GRP_SOIL_CHEM,SOIL_CHEM_BD,0.78 -US-Fuf,28603,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,0 -US-Fuf,28603,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,15 -US-Fuf,28603,GRP_SOIL_CHEM,SOIL_CHEM_DATE,2005 -US-Fuf,24786,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION,fine montmorillonitic complex of frigid Typic Argiborolls and Mollic Eutroboralfs -US-Fuf,24786,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION_TAXONOMY,Other -US-Fuf,27627,GRP_SOIL_DEPTH,SOIL_DEPTH,15 -US-Fuf,28604,GRP_SOIL_TEX,SOIL_TEX_SAND,31 -US-Fuf,27381,GRP_SOIL_TEX,SOIL_TEX_SAND,37 -US-Fuf,28604,GRP_SOIL_TEX,SOIL_TEX_SILT,34 -US-Fuf,27381,GRP_SOIL_TEX,SOIL_TEX_SILT,39 -US-Fuf,27381,GRP_SOIL_TEX,SOIL_TEX_CLAY,24 -US-Fuf,28604,GRP_SOIL_TEX,SOIL_TEX_CLAY,35 -US-Fuf,27381,GRP_SOIL_TEX,SOIL_TEX_HORIZON,A -US-Fuf,28604,GRP_SOIL_TEX,SOIL_TEX_HORIZON,B -US-Fuf,27376,GRP_SPP_O,SPP_O,PIPO (NRCS plant code) -US-Fuf,29533,GRP_SPP_O,SPP_O,QUGA (NRCS plant code) -US-Fuf,29533,GRP_SPP_O,SPP_O_PERC,5 -US-Fuf,27376,GRP_SPP_O,SPP_O_PERC,95 -US-Fuf,27376,GRP_SPP_O,SPP_DATE,2005 -US-Fuf,29533,GRP_SPP_O,SPP_DATE,2005 -US-Fuf,27376,GRP_SPP_O,SPP_COMMENT,pinus ponderosa -US-Fuf,29533,GRP_SPP_O,SPP_COMMENT,quercus gambelii -US-Fuf,12027,GRP_STATE,STATE,AZ -US-Fuf,12032,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Sabina Dore -US-Fuf,12032,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Fuf,12032,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,Sabina.Dore@nau.edu -US-Fuf,12032,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Northern Arizona University -US-Fuf,12032,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"School of Forestry, P.O. Box 15018,Flagstaff, AZ USA 86011-5018" -US-Fuf,12028,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Thomas Kolb -US-Fuf,12028,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Fuf,12028,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,tom.kolb@nau.edu -US-Fuf,12028,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Northern Arizona University -US-Fuf,12028,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"School of Forestry, P.O. Box 15018 ,Flagstaff, AZ USA 86011-5018" -US-Fuf,29808,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-Fuf,12029,GRP_TOWER_TYPE,TOWER_TYPE,other -US-Fuf,12030,GRP_URL,URL,http://nau.edu/CEFNS/Forestry/Research/Carbon-Flux/Sites/ -US-Fuf,24000362,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-Fuf -US-Fuf,33635,GRP_UTC_OFFSET,UTC_OFFSET,-7 -US-Fuf,33635,GRP_UTC_OFFSET,UTC_OFFSET_COMMENT,Added by AMF data processing team for data QAQC checks. -US-Fuf,28845,GRP_WD_BIOMASS,WD_BIOMASS_CRS,498 -US-Fuf,28845,GRP_WD_BIOMASS,WD_BIOMASS_UNIT,gC m-2 -US-Fuf,28845,GRP_WD_BIOMASS,WD_BIOMASS_DATE,20060609 -US-Fuf,28845,GRP_WD_BIOMASS,WD_BIOMASS_COMMENT,including FWD -US-Fwf,29213,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER,46 -US-Fwf,29213,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_ORGAN,Total -US-Fwf,29213,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_PHEN,Mixed/unknown -US-Fwf,29213,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_UNIT,gC m-2 -US-Fwf,29213,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_APPROACH,"4 , 0.5 m2 plot once per year. projected leaf area was measured in the laboratory with an image analyzer (Agvision, Monochrome System, Decagon Devices, Inc., Pullman, WA, USA)." -US-Fwf,29213,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_DATE,20070907 -US-Fwf,27628,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER,69 -US-Fwf,27628,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_ORGAN,Total -US-Fwf,27628,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_PHEN,Mixed/unknown -US-Fwf,27628,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_UNIT,gC m-2 -US-Fwf,27628,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_APPROACH,"4 , 0.5 m2 plot once per year. projected leaf area was measured in the laboratory with an image analyzer (Agvision, Monochrome System, Decagon Devices, Inc., Pullman, WA, USA)." -US-Fwf,27628,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_DATE,20060907 -US-Fwf,27629,GRP_AG_LIT_CHEM,AG_LIT_C,3.67 -US-Fwf,27629,GRP_AG_LIT_CHEM,AG_LIT_N,0.07 -US-Fwf,27629,GRP_AG_LIT_CHEM,AG_LIT_DATE,2007 -US-Fwf,27629,GRP_AG_LIT_CHEM,AG_LIT_COMMENT,"not litter but organic horizon," -US-Fwf,28605,GRP_AG_PROD_OTHER,AG_PROD_OTHER,46 -US-Fwf,28605,GRP_AG_PROD_OTHER,AG_PROD_OTHER_ORGAN,Total -US-Fwf,28605,GRP_AG_PROD_OTHER,AG_PROD_OTHER_UNIT,gC m-2 -US-Fwf,28605,GRP_AG_PROD_OTHER,AG_PROD_APPROACH,"clipping of 4 , 0.5 m2 plot once per year." -US-Fwf,28605,GRP_AG_PROD_OTHER,AG_PROD_DATE_START,20070907 -US-Fwf,29536,GRP_AG_PROD_OTHER,AG_PROD_OTHER,69 -US-Fwf,29536,GRP_AG_PROD_OTHER,AG_PROD_OTHER_ORGAN,Total -US-Fwf,29536,GRP_AG_PROD_OTHER,AG_PROD_OTHER_UNIT,gC m-2 -US-Fwf,29536,GRP_AG_PROD_OTHER,AG_PROD_APPROACH,"clipping of 4 , 0.5 m2 plot once per year." -US-Fwf,29536,GRP_AG_PROD_OTHER,AG_PROD_DATE_START,20060907 -US-Fwf,12040,GRP_CLIM_AVG,MAT,8.4 -US-Fwf,12040,GRP_CLIM_AVG,MAP,557 -US-Fwf,12040,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Csb -US-Fwf,27000363,GRP_COUNTRY,COUNTRY,USA -US-Fwf,5390,GRP_DM_FIRE,DM_FIRE,Nature induced burn -US-Fwf,5390,GRP_DM_FIRE,DM_DATE,1996 -US-Fwf,5390,GRP_DM_FIRE,DM_COMMENT,high; high intensity stand replacing -US-Fwf,15660,GRP_DOI,DOI,10.17190/AMF/1246052 -US-Fwf,15660,GRP_DOI,DOI_CITATION,"Sabina Dore, Thomas Kolb (2019), AmeriFlux BASE US-Fwf Flagstaff - Wildfire, Ver. 8-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1246052" -US-Fwf,15660,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-Fwf,32042,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Fwf,32042,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Sabina Dore -US-Fwf,32042,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Fwf,32042,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,Sabina.Dore@nau.edu -US-Fwf,32042,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Northern Arizona University -US-Fwf,32043,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Fwf,32043,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Thomas Kolb -US-Fwf,32043,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Fwf,32043,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,tom.kolb@nau.edu -US-Fwf,32043,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Northern Arizona University -US-Fwf,32045,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Northern Arizona University -US-Fwf,32045,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-Fwf,32044,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,USDA-NRICGP/NACP -US-Fwf,32044,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-Fwf,12041,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Fire -US-Fwf,12042,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Fwf,12042,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-Fwf,12042,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20060101 -US-Fwf,12042,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20101231 -US-Fwf,12042,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Fwf,23000363,GRP_HEADER,SITE_NAME,Flagstaff - Wildfire -US-Fwf,27991,GRP_HEIGHTC,HEIGHTC,0.3 -US-Fwf,27991,GRP_HEIGHTC,HEIGHTC_DATE,20050927 -US-Fwf,12043,GRP_IGBP,IGBP,GRA -US-Fwf,29212,GRP_LAI,LAI_TYPE,LAI -US-Fwf,29535,GRP_LAI,LAI_TYPE,LAI -US-Fwf,29212,GRP_LAI,LAI_METHOD,Direct -US-Fwf,29535,GRP_LAI,LAI_METHOD,Direct -US-Fwf,29535,GRP_LAI,LAI_DATE,20061002 -US-Fwf,29212,GRP_LAI,LAI_DATE,20071002 -US-Fwf,29212,GRP_LAI,LAI_COMMENT,"4 , 0.5 m2 plot once per year. projected leaf area was measured in the laboratory with an image analyzer (Agvision, Monochrome System, Decagon Devices, Inc., Pullman, WA, USA)." -US-Fwf,29535,GRP_LAI,LAI_COMMENT,"4 , 0.5 m2 plot once per year. projected leaf area was measured in the laboratory with an image analyzer (Agvision, Monochrome System, Decagon Devices, Inc., Pullman, WA, USA)." -US-Fwf,29212,GRP_LAI,LAI_TOT,0.5 -US-Fwf,29535,GRP_LAI,LAI_TOT,0.6 -US-Fwf,12044,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-Fwf,12044,GRP_LAND_OWNERSHIP,LAND_OWNER,USDA Forest Service -US-Fwf,23903,GRP_LMA,LMA,79 -US-Fwf,23903,GRP_LMA,LMA_SPP,(All) -US-Fwf,12045,GRP_LOCATION,LOCATION_LAT,35.4454 -US-Fwf,12045,GRP_LOCATION,LOCATION_LONG,-111.7718 -US-Fwf,12045,GRP_LOCATION,LOCATION_ELEV,2270 -US-Fwf,12046,GRP_NETWORK,NETWORK,AmeriFlux -US-Fwf,1700000987,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Amiro, B. D., Barr, A. G., Barr, J. G., Black, T. A., Bracho, R., Brown, M., Chen, J., Clark, K. L., Davis, K. J., Desai, A. R., Dore, S., Engel, V., Fuentes, J. D., Goldstein, A. H., Goulden, M. L., Kolb, T. E., Lavigne, M. B., Law, B. E., Margolis, H. A., Martin, T., McCaughey, J. H., Misson, L., Montes-Helu, M., Noormets, A., Randerson, J. T., Starr, G., Xiao, J. (2010) Ecosystem Carbon Dioxide Fluxes After Disturbance In Forests Of North America, Journal Of Geophysical Research, 115(G00K02), n/a-n/a" -US-Fwf,1700000987,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2010JG001390 -US-Fwf,1700000987,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Fwf,1700006081,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(8), 108350" -US-Fwf,1700006081,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -US-Fwf,1700006081,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Fwf,1700007803,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Dore, S., Kolb, T. E., Montes-Helu, M., Eckert, S. E., Sullivan, B. W., Hungate, B. A., Kaye, J. P., Hart, S. C., Koch, G. W., Finkral, A. (2010) Carbon And Water Fluxes From Ponderosa Pine Forests Disturbed By Wildfire And Thinning, Ecological Applications, 20(3), 663-683" -US-Fwf,1700007803,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1890/09-0934.1 -US-Fwf,1700007803,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Fwf,1700000390,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Dore, S., Kolb, T. E., Montes-Helu, M., Sullivan, B. W., Winslow, W. D., Hart, S. C., Kaye, J. P., Koch, G. W., Hungate, B. A. (2008) Long-Term Impact Of A Stand-Replacing Fire On Ecosystem CO2 Exchange Of A Ponderosa Pine Forest, Global Change Biology, 14(8), 1801-1820" -US-Fwf,1700000390,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/J.1365-2486.2008.01613.X -US-Fwf,1700000390,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Fwf,1700008763,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Dore, S., Montes-Helu, M., Hart, S. C., Hungate, B. A., Koch, G. W., Moon, J. B., Finkral, A. J., Kolb, T. E. (2012) Recovery Of Ponderosa Pine Ecosystem Carbon And Water Fluxes From Thinning And Stand-Replacing Fire, Global Change Biology, 18(10), 3171-3185" -US-Fwf,1700008763,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/J.1365-2486.2012.02775.X -US-Fwf,1700008763,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Fwf,1700003000,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Kolb, T., Dore, S., Montes-Helu, M. (2013) Extreme Late-Summer Drought Causes Neutral Annual Carbon Balance In Southwestern Ponderosa Pine Forests And Grasslands, Environmental Research Letters, 8(1), n/a-n/a" -US-Fwf,1700003000,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1088/1748-9326/8/1/015015 -US-Fwf,1700003000,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Fwf,1700004311,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Montes-Helu, M., Kolb, T., Dore, S., Sullivan, B., Hart, S., Koch, G., Hungate, B. (2009) Persistent Effects Of Fire-Induced Vegetation Change On Energy Partitioning And Evapotranspiration In Ponderosa Pine Forests, Agricultural And Forest Meteorology, 149(3-4), 491-500" -US-Fwf,1700004311,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2008.09.011 -US-Fwf,1700004311,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Fwf,1700006054,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Sullivan, B. W., Dore, S., Kolb, T. E., Hart, S. C., Montes-Helu, M. C. (2010) Evaluation Of Methods For Estimating Soil Carbon Dioxide Efflux Across A Gradient Of Forest Disturbance, Global Change Biology, 16(2), 2449-2460" -US-Fwf,1700006054,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/J.1365-2486.2009.02139.X -US-Fwf,1700006054,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Fwf,1700001293,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Sullivan, B. W., Dore, S., Montes-Helu, M. C., Kolb, T. E., Hart, S. C. (2012) Pulse Emissions Of Carbon Dioxide During Snowmelt At A High-Elevation Site In Northern Arizona, U.S.A., Arctic, Antarctic, And Alpine Research, 44(2), 247-254" -US-Fwf,1700001293,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1657/1938-4246-44.2.247 -US-Fwf,1700001293,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Fwf,1700002937,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Sullivan, B. W., Kolb, T. E., Hart, S. C., Kaye, J. P., Hungate, B. A., Dore, S., Montes-Helu, M. (2011) Wildfire Reduces Carbon Dioxide Efflux And Increases Methane Uptake In Ponderosa Pine Forest Soils Of The Southwestern USA, Biogeochemistry, 104(1-3), 251-265" -US-Fwf,1700002937,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1007/S10533-010-9499-1 -US-Fwf,1700002937,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Fwf,12048,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,The overall goal of our research is to characterize the effect of disturbances by forest management and wildfire on fluxes of carbon dioxide (CO2) and methane (CH4) between the atmosphere and land in ponderosa pine-dominated forests of northern Arizona. -US-Fwf,27992,GRP_ROOT_BIOMASS,ROOT_BIOMASS_FINE,54 -US-Fwf,29319,GRP_ROOT_BIOMASS,ROOT_BIOMASS_FINE,86 -US-Fwf,27992,GRP_ROOT_BIOMASS,ROOT_BIOMASS_UNIT,gC m-2 -US-Fwf,29319,GRP_ROOT_BIOMASS,ROOT_BIOMASS_UNIT,gC m-2 -US-Fwf,27992,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MIN,0 -US-Fwf,29319,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MIN,0 -US-Fwf,27992,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MAX,15 -US-Fwf,29319,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MAX,15 -US-Fwf,27992,GRP_ROOT_BIOMASS,ROOT_BIOMASS_APPROACH,"three soil cores per 25 m2 radious plot (15 total per site) of 20.4 cm2 in area and a depth of 15 cm. Roots were extracted from the soil with a hydropneumatic elutriation system (Scienceware Bel-Art products, Pequannock, NJ)." -US-Fwf,29319,GRP_ROOT_BIOMASS,ROOT_BIOMASS_APPROACH,"three soil cores per 25 m2 radious plot (15 total per site) of 20.4 cm2 in area and a depth of 15 cm. Roots were extracted from the soil with a hydropneumatic elutriation system (Scienceware Bel-Art products, Pequannock, NJ)." -US-Fwf,27992,GRP_ROOT_BIOMASS,ROOT_BIOMASS_DATE,20060515 -US-Fwf,29319,GRP_ROOT_BIOMASS,ROOT_BIOMASS_DATE,20070614 -US-Fwf,27080,GRP_ROOT_PROD,ROOT_PROD_FINE,131 -US-Fwf,26787,GRP_ROOT_PROD,ROOT_PROD_FINE,227 -US-Fwf,26787,GRP_ROOT_PROD,ROOT_PROD_UNIT,gC m-2 -US-Fwf,27080,GRP_ROOT_PROD,ROOT_PROD_UNIT,gC m-2 -US-Fwf,26787,GRP_ROOT_PROD,ROOT_PROD_PROFILE_MIN,0 -US-Fwf,27080,GRP_ROOT_PROD,ROOT_PROD_PROFILE_MIN,0 -US-Fwf,26787,GRP_ROOT_PROD,ROOT_PROD_PROFILE_MAX,30 -US-Fwf,27080,GRP_ROOT_PROD,ROOT_PROD_PROFILE_MAX,30 -US-Fwf,26787,GRP_ROOT_PROD,ROOT_PROD_APPROACH,"using the minirhizotron technique. Three acrylic minirhizotron tubes (15 total per site), with and internal diameter of 63.5 mm and wall thickness of 3 mm, were inserted in June 2005, digging a trench at an angle of approximately 45 degrees to a depth of 30cm" -US-Fwf,27080,GRP_ROOT_PROD,ROOT_PROD_APPROACH,"using the minirhizotron technique. Three acrylic minirhizotron tubes (15 total per site), with and internal diameter of 63.5 mm and wall thickness of 3 mm, were inserted in June 2005, digging a trench at an angle of approximately 45 degrees to a depth of 30cm" -US-Fwf,26787,GRP_ROOT_PROD,ROOT_PROD_DATE_START,2006 -US-Fwf,27080,GRP_ROOT_PROD,ROOT_PROD_DATE_START,2007 -US-Fwf,12049,GRP_SITE_CHAR,TERRAIN,Flat -US-Fwf,12049,GRP_SITE_CHAR,ASPECT,FLAT -US-Fwf,12049,GRP_SITE_CHAR,WIND_DIRECTION,SW -US-Fwf,12049,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,1000 -US-Fwf,12049,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,60 -US-Fwf,12050,GRP_SITE_DESC,SITE_DESC,Ponderosa pine forest subject to high severity stand replacing wild fire in 1996. Project webpage http://nau.edu/CEFNS/Forestry/Research/Carbon-Flux/Sites/. -US-Fwf,12051,GRP_SITE_FUNDING,SITE_FUNDING,USDA-NRICGP/NACP -US-Fwf,27081,GRP_SOIL_CHEM,SOIL_CHEM_C_ORG,32.73 -US-Fwf,27081,GRP_SOIL_CHEM,SOIL_CHEM_N_TOT,17 -US-Fwf,27081,GRP_SOIL_CHEM,SOIL_CHEM_BD,0.8 -US-Fwf,27081,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,0 -US-Fwf,27081,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,15 -US-Fwf,27081,GRP_SOIL_CHEM,SOIL_CHEM_DATE,2005 -US-Fwf,25041,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION,fine montmorillonitic complex of frigid Typic Argiborolls and Mollic Eutroboralfs -US-Fwf,25041,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION_TAXONOMY,Other -US-Fwf,28846,GRP_SOIL_DEPTH,SOIL_DEPTH,15 -US-Fwf,28341,GRP_SOIL_TEX,SOIL_TEX_SAND,20 -US-Fwf,28606,GRP_SOIL_TEX,SOIL_TEX_SAND,30 -US-Fwf,28341,GRP_SOIL_TEX,SOIL_TEX_SILT,55 -US-Fwf,28606,GRP_SOIL_TEX,SOIL_TEX_SILT,57 -US-Fwf,28606,GRP_SOIL_TEX,SOIL_TEX_CLAY,13 -US-Fwf,28341,GRP_SOIL_TEX,SOIL_TEX_CLAY,25 -US-Fwf,28606,GRP_SOIL_TEX,SOIL_TEX_HORIZON,A -US-Fwf,28341,GRP_SOIL_TEX,SOIL_TEX_HORIZON,B -US-Fwf,27382,GRP_SPP_O,SPP_O,(see comment) -US-Fwf,27382,GRP_SPP_O,SPP_O_PERC,100 -US-Fwf,27382,GRP_SPP_O,SPP_COMMENT,"grasses, early successional shrubs and forbs; before the fire: pinus ponderosa" -US-Fwf,12052,GRP_STATE,STATE,AZ -US-Fwf,12057,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Sabina Dore -US-Fwf,12057,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Fwf,12057,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,Sabina.Dore@nau.edu -US-Fwf,12057,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Northern Arizona University -US-Fwf,12057,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"School of Forestry, P.O. Box 15018,Flagstaff, AZ USA 86011-5018" -US-Fwf,12053,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Thomas Kolb -US-Fwf,12053,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Fwf,12053,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,tom.kolb@nau.edu -US-Fwf,12053,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Northern Arizona University -US-Fwf,12053,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"School of Forestry, P.O. Box 15018 ,Flagstaff, AZ USA 86011-5018" -US-Fwf,29809,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-Fwf,12054,GRP_TOWER_TYPE,TOWER_TYPE,pole -US-Fwf,12055,GRP_URL,URL,http://nau.edu/CEFNS/Forestry/Research/Carbon-Flux/Sites/ -US-Fwf,24000363,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-Fwf -US-Fwf,33636,GRP_UTC_OFFSET,UTC_OFFSET,-7 -US-Fwf,33636,GRP_UTC_OFFSET,UTC_OFFSET_COMMENT,Added by AMF data processing team for data QAQC checks. -US-Fwf,27733,GRP_WD_BIOMASS,WD_BIOMASS_CRS,2483 -US-Fwf,27733,GRP_WD_BIOMASS,WD_BIOMASS_UNIT,gC m-2 -US-Fwf,27733,GRP_WD_BIOMASS,WD_BIOMASS_DATE,20050609 -US-Fwf,27733,GRP_WD_BIOMASS,WD_BIOMASS_COMMENT,including FWD -US-GBT,16016,GRP_CLIM_AVG,MAT,0.80 -US-GBT,16016,GRP_CLIM_AVG,MAP,1200 -US-GBT,16016,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfc -US-GBT,27000666,GRP_COUNTRY,COUNTRY,USA -US-GBT,33551,GRP_DOI,DOI,10.17190/AMF/1375200 -US-GBT,33551,GRP_DOI,DOI_CITATION,"Bill Massman (2016), AmeriFlux BASE US-GBT GLEES Brooklyn Tower, Ver. 1-1, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1375200" -US-GBT,33551,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-GBT,32425,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-GBT,32425,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Bill Massman -US-GBT,32425,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-GBT,32425,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,wmassman@fs.fed.us -US-GBT,32425,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,USDA Forest Service -US-GBT,32427,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,USDA Forest Service -US-GBT,32427,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-GBT,32426,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,USDA/Forest Service -US-GBT,32426,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-GBT,16017,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Undisturbed -US-GBT,16018,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-GBT,16018,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-GBT,16018,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,1991 -US-GBT,16018,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,2006 -US-GBT,16018,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-GBT,16018,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,"Intermittent from 1991-1997, Continuous from 1999-2006" -US-GBT,16032,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-GBT,16032,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-GBT,16032,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,1991 -US-GBT,16032,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,2006 -US-GBT,16032,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-GBT,16034,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-GBT,16034,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-GBT,16034,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,1991 -US-GBT,16034,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,2006 -US-GBT,16034,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-GBT,23000666,GRP_HEADER,SITE_NAME,GLEES Brooklyn Tower -US-GBT,88584,GRP_HEIGHTC,HEIGHTC,2.2 -US-GBT,88584,GRP_HEIGHTC,HEIGHTC_STATISTIC,10th Percentile -US-GBT,88584,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,190 -US-GBT,88584,GRP_HEIGHTC,HEIGHTC_DATE,2010 -US-GBT,88585,GRP_HEIGHTC,HEIGHTC,8.2 -US-GBT,88585,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-GBT,88585,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,190 -US-GBT,88585,GRP_HEIGHTC,HEIGHTC_DATE,2010 -US-GBT,88590,GRP_HEIGHTC,HEIGHTC,19.7 -US-GBT,88590,GRP_HEIGHTC,HEIGHTC_STATISTIC,95th Percentile -US-GBT,88590,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,190 -US-GBT,88590,GRP_HEIGHTC,HEIGHTC_DATE,2010 -US-GBT,88591,GRP_HEIGHTC,HEIGHTC,6.2 -US-GBT,88591,GRP_HEIGHTC,HEIGHTC_STATISTIC,Median - 50th Percentile -US-GBT,88591,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,190 -US-GBT,88591,GRP_HEIGHTC,HEIGHTC_DATE,2010 -US-GBT,88592,GRP_HEIGHTC,HEIGHTC,17.2 -US-GBT,88592,GRP_HEIGHTC,HEIGHTC_STATISTIC,90th Percentile -US-GBT,88592,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,190 -US-GBT,88592,GRP_HEIGHTC,HEIGHTC_DATE,2010 -US-GBT,88594,GRP_HEIGHTC,HEIGHTC,2.2 -US-GBT,88594,GRP_HEIGHTC,HEIGHTC_STATISTIC,5th Percentile -US-GBT,88594,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,190 -US-GBT,88594,GRP_HEIGHTC,HEIGHTC_DATE,2010 -US-GBT,88595,GRP_HEIGHTC,HEIGHTC,12.9 -US-GBT,88595,GRP_HEIGHTC,HEIGHTC_STATISTIC,75th Percentile -US-GBT,88595,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,190 -US-GBT,88595,GRP_HEIGHTC,HEIGHTC_DATE,2010 -US-GBT,88597,GRP_HEIGHTC,HEIGHTC,1.7 -US-GBT,88597,GRP_HEIGHTC,HEIGHTC_STATISTIC,1st Percentile -US-GBT,88597,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,190 -US-GBT,88597,GRP_HEIGHTC,HEIGHTC_DATE,2010 -US-GBT,88598,GRP_HEIGHTC,HEIGHTC,2.8 -US-GBT,88598,GRP_HEIGHTC,HEIGHTC_STATISTIC,25th Percentile -US-GBT,88598,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,190 -US-GBT,88598,GRP_HEIGHTC,HEIGHTC_DATE,2010 -US-GBT,88601,GRP_HEIGHTC,HEIGHTC,24.2 -US-GBT,88601,GRP_HEIGHTC,HEIGHTC_STATISTIC,99th Percentile -US-GBT,88601,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,190 -US-GBT,88601,GRP_HEIGHTC,HEIGHTC_DATE,2010 -US-GBT,88586,GRP_HEIGHTC,HEIGHTC,27.7 -US-GBT,88586,GRP_HEIGHTC,HEIGHTC_STATISTIC,99th Percentile -US-GBT,88586,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,271 -US-GBT,88586,GRP_HEIGHTC,HEIGHTC_DATE,2011 -US-GBT,88587,GRP_HEIGHTC,HEIGHTC,14.6 -US-GBT,88587,GRP_HEIGHTC,HEIGHTC_STATISTIC,Median - 50th Percentile -US-GBT,88587,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,271 -US-GBT,88587,GRP_HEIGHTC,HEIGHTC_DATE,2011 -US-GBT,88588,GRP_HEIGHTC,HEIGHTC,7.8 -US-GBT,88588,GRP_HEIGHTC,HEIGHTC_STATISTIC,10th Percentile -US-GBT,88588,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,271 -US-GBT,88588,GRP_HEIGHTC,HEIGHTC_DATE,2011 -US-GBT,88589,GRP_HEIGHTC,HEIGHTC,4.4 -US-GBT,88589,GRP_HEIGHTC,HEIGHTC_STATISTIC,1st Percentile -US-GBT,88589,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,271 -US-GBT,88589,GRP_HEIGHTC,HEIGHTC_DATE,2011 -US-GBT,88593,GRP_HEIGHTC,HEIGHTC,19.2 -US-GBT,88593,GRP_HEIGHTC,HEIGHTC_STATISTIC,75th Percentile -US-GBT,88593,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,271 -US-GBT,88593,GRP_HEIGHTC,HEIGHTC_DATE,2011 -US-GBT,88596,GRP_HEIGHTC,HEIGHTC,6.3 -US-GBT,88596,GRP_HEIGHTC,HEIGHTC_STATISTIC,5th Percentile -US-GBT,88596,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,271 -US-GBT,88596,GRP_HEIGHTC,HEIGHTC_DATE,2011 -US-GBT,88599,GRP_HEIGHTC,HEIGHTC,23.1 -US-GBT,88599,GRP_HEIGHTC,HEIGHTC_STATISTIC,90th Percentile -US-GBT,88599,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,271 -US-GBT,88599,GRP_HEIGHTC,HEIGHTC_DATE,2011 -US-GBT,88600,GRP_HEIGHTC,HEIGHTC,24.6 -US-GBT,88600,GRP_HEIGHTC,HEIGHTC_STATISTIC,95th Percentile -US-GBT,88600,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,271 -US-GBT,88600,GRP_HEIGHTC,HEIGHTC_DATE,2011 -US-GBT,88602,GRP_HEIGHTC,HEIGHTC,14.9 -US-GBT,88602,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-GBT,88602,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,271 -US-GBT,88602,GRP_HEIGHTC,HEIGHTC_DATE,2011 -US-GBT,88603,GRP_HEIGHTC,HEIGHTC,10.3 -US-GBT,88603,GRP_HEIGHTC,HEIGHTC_STATISTIC,25th Percentile -US-GBT,88603,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,271 -US-GBT,88603,GRP_HEIGHTC,HEIGHTC_DATE,2011 -US-GBT,16019,GRP_IGBP,IGBP,ENF -US-GBT,16019,GRP_IGBP,IGBP_COMMENT,85% Engelmann spruce 15% Subalpine fir -US-GBT,16020,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-GBT,16021,GRP_LOCATION,LOCATION_LAT,41.3658 -US-GBT,16021,GRP_LOCATION,LOCATION_LONG,-106.2397 -US-GBT,16021,GRP_LOCATION,LOCATION_ELEV,3191 -US-GBT,16022,GRP_NETWORK,NETWORK,AmeriFlux -US-GBT,1700004602,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Baldocchi, D., Penuelas, J. (2018) The Physics And Ecology Of Mining Carbon Dioxide From The Atmosphere By Ecosystems, Global Change Biology, 45(2), 9275–9287" -US-GBT,1700004602,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/GCB.14559 -US-GBT,1700004602,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-GBT,1700000081,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Baldocchi, D., Penuelas, J. (2018) The Physics And Ecology Of Mining Carbon Dioxide From The Atmosphere By Ecosystems, Global Change Biology, 45(8), 9275–9287" -US-GBT,1700000081,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/GCB.14559 -US-GBT,1700000081,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-GBT,1700007560,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Baldocchi, D. D., Poindexter, C., Abraha, M., Desai, A. R., Bohrer, G., Arain, M. A., Griffis, T., Blanken, P. D., O'Halloran, T. L., Thomas, R. Q., Zhang, Q., Burns, S. P., Frank, J. M., Christian, D., Brown, S., Black, T. A., Gough, C. M., Law, B. E., Lee, X., Chen, J., Reed, D. E., Massman, W. J., Clark, K., Hatfield, J., Prueger, J., Bracho, R., Baker, J. M., Martin, T. A. (2018) Temporal Dynamics Of Aerodynamic Canopy Height Derived From Eddy Covariance Momentum Flux Data Across North American Flux Networks, Geophysical Research Letters, 45(2), 9275–9287" -US-GBT,1700007560,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018GL079306 -US-GBT,1700007560,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-GBT,1700001398,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Baldocchi, D. D., Poindexter, C., Abraha, M., Desai, A. R., Bohrer, G., Arain, M. A., Griffis, T., Blanken, P. D., O'Halloran, T. L., Thomas, R. Q., Zhang, Q., Burns, S. P., Frank, J. M., Christian, D., Brown, S., Black, T. A., Gough, C. M., Law, B. E., Lee, X., Chen, J., Reed, D. E., Massman, W. J., Clark, K., Hatfield, J., Prueger, J., Bracho, R., Baker, J. M., Martin, T. A. (2018) Temporal Dynamics Of Aerodynamic Canopy Height Derived From Eddy Covariance Momentum Flux Data Across North American Flux Networks, Geophysical Research Letters, 45(8), 9275–9287" -US-GBT,1700001398,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018GL079306 -US-GBT,1700001398,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-GBT,1700005451,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Frank, J. M., Massman, W. J., Ewers, B. E., Williams, D. G. (2019) Bayesian Analyses of 17 Winters of Water Vapor Fluxes Show Bark Beetles Reduce Sublimation, Water Resources Research, 55(2), 1598-1623" -US-GBT,1700005451,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018WR023054 -US-GBT,1700005451,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-GBT,1700008016,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Zeller, K. (2000) Wintertime Ozone Fluxes And Profiles Above A Subalpine Spruce–Fir Forest, Journal Of Applied Meteorology, 39(1), 92-101" -US-GBT,1700008016,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1175/1520-0450(2000)039<0092:WOFAPA>2.0.CO;2 -US-GBT,1700008016,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-GBT,1700006639,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Zeller, K., Hehn, T. (1996) Measurements Of Upward Turbulent Ozone Fluxes Above A Subalpine Spruce-Fir Forest, Geophysical Research Letters, 23(8), 841-844" -US-GBT,1700006639,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/96GL00786 -US-GBT,1700006639,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-GBT,1700005364,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Zeller, K., Nikolov, N. (2000) Quantifying Simultaneous Fluxes Of Ozone, Carbon Dioxide And Water Vapor Above A Subalpine Forest Ecosystem, Environmental Pollution, 107(1), 1-20" -US-GBT,1700005364,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/S0269-7491(99)00156-6 -US-GBT,1700005364,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-GBT,16024,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"The main analytical objectives of the GLEES AmeriFlux site include the flux measurements of momentum, sensible heat, water vapor, latent heat, and CO2 exchange between a sub-alpine forest and the atmosphere. Additional research topics include: 1) examination of the relationship of energy and mass exhanges between the atmosphere and underlying forest ecosystem; 2) ozone depletion; 3) snow hydrology; 4) snow chemistry; 5) nitrogen cycling in sub-alpine forest ecosystems; 6) sub-alpine plant physiology, and 7) the ecosystem response to a spruce beetle outbreak. Recently, significant efforts are being made to quantify the effect of the widespread overstory mortality caused by the spruce beetle (Dendroctonus rufipennis) and the western balsam bark beetle (Dryocoetes confusus)." -US-GBT,16025,GRP_SITE_CHAR,TERRAIN,"Medium Slope (>2 %, <5%)" -US-GBT,16025,GRP_SITE_CHAR,ASPECT,W -US-GBT,16025,GRP_SITE_CHAR,WIND_DIRECTION,W -US-GBT,16025,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,1900 -US-GBT,16025,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,243 -US-GBT,16026,GRP_SITE_DESC,SITE_DESC,"The Glacier Lakes Ecosystem Experiments Site (GLEES) site is located on land owned by the U.S. government and managed by US Forest Service as part of the Medicine Bow National Forest. Many of the trees in the immediate vicinity of the site are older than 400 years, inter-dispersed among trees much younger in age. This widespread age distribution is most likely a derivation of one of two scenarios: 1) A widespread stand replacement about 400 years ago followed by a slow replacement; 2) Intermittent random disturbances over the past 400 years (Bradford et al. 2008). A decade long spruce beetle outbreak that peaked in 2008 resulted in the mortality of 85% of the forested basal area. There are a few private land holdings in the area, with scattered uncorked mining claims. Following the establishment of the National Forest, mining was banned and grazing was closed in the early 1990's in the upper portion of the GLEES site. Recreation in the winter, when snow can remain in patches into the summer months, snow mobiling and cross country skiing are popular. During the limited summer, hiking, camping and fishing are common activities. The site is accessible by vehicle only during the summer on Forest Road FDR 317, and in the winter, the tower is only reachable via snowmobile." -US-GBT,16027,GRP_SITE_FUNDING,SITE_FUNDING,USDA/Forest Service -US-GBT,16028,GRP_STATE,STATE,WY -US-GBT,16029,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Bill Massman -US-GBT,16029,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-GBT,16029,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,wmassman@fs.fed.us -US-GBT,16029,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,USDA Forest Service -US-GBT,16029,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Rocky Mountain Research Station, 240 W. Prospect, Fort Collins, CO USA 80526" -US-GBT,81880,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,John Frank -US-GBT,81880,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,DataManager -US-GBT,81880,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,jfrank@fs.fed.us -US-GBT,81880,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,USDA Forest Service -US-GBT,81880,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Rocky Mountain Research Station, 240 W. Prospect, Fort Collins, CO USA 80526" -US-GBT,29917,GRP_TOWER_POWER,TOWER_POWER,Direct power -US-GBT,16030,GRP_TOWER_TYPE,TOWER_TYPE,triangle -US-GBT,16031,GRP_URL,URL,http://www.fs.fed.us/rmrs/experimental-forests-and-ranges/glees-glacier-lakes-ecosystem-experiments-site -US-GBT,24000666,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-GBT -US-GBT,33637,GRP_UTC_OFFSET,UTC_OFFSET,-7 -US-GBT,33637,GRP_UTC_OFFSET,UTC_OFFSET_COMMENT,Added by AMF data processing team for data QAQC checks. -US-GLE,15995,GRP_CLIM_AVG,MAT,0.80 -US-GLE,15995,GRP_CLIM_AVG,MAP,1200 -US-GLE,15995,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfc -US-GLE,27000368,GRP_COUNTRY,COUNTRY,USA -US-GLE,15740,GRP_DOI,DOI,10.17190/AMF/1246056 -US-GLE,15740,GRP_DOI,DOI_CITATION,"Bill Massman (2021), AmeriFlux BASE US-GLE GLEES, Ver. 8-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1246056" -US-GLE,15740,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-GLE,32055,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-GLE,32055,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Bill Massman -US-GLE,32055,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-GLE,32055,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,wmassman@fs.fed.us -US-GLE,32055,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,USDA Forest Service -US-GLE,32057,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,USDA Forest Service -US-GLE,32057,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-GLE,32056,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,USDA/Forest Service -US-GLE,32056,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-GLE,15996,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Pests and disease -US-GLE,15337,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-GLE,15337,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-GLE,15337,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,2004 -US-GLE,15337,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-GLE,16011,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-GLE,16011,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-GLE,16011,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,2004 -US-GLE,16011,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-GLE,16013,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-GLE,16013,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-GLE,16013,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,2004 -US-GLE,16013,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-GLE,23000368,GRP_HEADER,SITE_NAME,GLEES -US-GLE,88605,GRP_HEIGHTC,HEIGHTC,24.2 -US-GLE,88605,GRP_HEIGHTC,HEIGHTC_STATISTIC,99th Percentile -US-GLE,88605,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,190 -US-GLE,88605,GRP_HEIGHTC,HEIGHTC_DATE,2010 -US-GLE,88606,GRP_HEIGHTC,HEIGHTC,6.2 -US-GLE,88606,GRP_HEIGHTC,HEIGHTC_STATISTIC,Median - 50th Percentile -US-GLE,88606,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,190 -US-GLE,88606,GRP_HEIGHTC,HEIGHTC_DATE,2010 -US-GLE,88608,GRP_HEIGHTC,HEIGHTC,8.2 -US-GLE,88608,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-GLE,88608,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,190 -US-GLE,88608,GRP_HEIGHTC,HEIGHTC_DATE,2010 -US-GLE,88617,GRP_HEIGHTC,HEIGHTC,17.2 -US-GLE,88617,GRP_HEIGHTC,HEIGHTC_STATISTIC,90th Percentile -US-GLE,88617,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,190 -US-GLE,88617,GRP_HEIGHTC,HEIGHTC_DATE,2010 -US-GLE,88619,GRP_HEIGHTC,HEIGHTC,2.2 -US-GLE,88619,GRP_HEIGHTC,HEIGHTC_STATISTIC,5th Percentile -US-GLE,88619,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,190 -US-GLE,88619,GRP_HEIGHTC,HEIGHTC_DATE,2010 -US-GLE,88620,GRP_HEIGHTC,HEIGHTC,2.2 -US-GLE,88620,GRP_HEIGHTC,HEIGHTC_STATISTIC,10th Percentile -US-GLE,88620,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,190 -US-GLE,88620,GRP_HEIGHTC,HEIGHTC_DATE,2010 -US-GLE,88627,GRP_HEIGHTC,HEIGHTC,19.7 -US-GLE,88627,GRP_HEIGHTC,HEIGHTC_STATISTIC,95th Percentile -US-GLE,88627,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,190 -US-GLE,88627,GRP_HEIGHTC,HEIGHTC_DATE,2010 -US-GLE,88629,GRP_HEIGHTC,HEIGHTC,12.9 -US-GLE,88629,GRP_HEIGHTC,HEIGHTC_STATISTIC,75th Percentile -US-GLE,88629,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,190 -US-GLE,88629,GRP_HEIGHTC,HEIGHTC_DATE,2010 -US-GLE,88636,GRP_HEIGHTC,HEIGHTC,2.8 -US-GLE,88636,GRP_HEIGHTC,HEIGHTC_STATISTIC,25th Percentile -US-GLE,88636,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,190 -US-GLE,88636,GRP_HEIGHTC,HEIGHTC_DATE,2010 -US-GLE,88639,GRP_HEIGHTC,HEIGHTC,1.7 -US-GLE,88639,GRP_HEIGHTC,HEIGHTC_STATISTIC,1st Percentile -US-GLE,88639,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,190 -US-GLE,88639,GRP_HEIGHTC,HEIGHTC_DATE,2010 -US-GLE,88609,GRP_HEIGHTC,HEIGHTC,14.9 -US-GLE,88609,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-GLE,88609,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,271 -US-GLE,88609,GRP_HEIGHTC,HEIGHTC_DATE,2011 -US-GLE,88615,GRP_HEIGHTC,HEIGHTC,7.8 -US-GLE,88615,GRP_HEIGHTC,HEIGHTC_STATISTIC,10th Percentile -US-GLE,88615,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,271 -US-GLE,88615,GRP_HEIGHTC,HEIGHTC_DATE,2011 -US-GLE,88622,GRP_HEIGHTC,HEIGHTC,10.3 -US-GLE,88622,GRP_HEIGHTC,HEIGHTC_STATISTIC,25th Percentile -US-GLE,88622,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,271 -US-GLE,88622,GRP_HEIGHTC,HEIGHTC_DATE,2011 -US-GLE,88623,GRP_HEIGHTC,HEIGHTC,6.3 -US-GLE,88623,GRP_HEIGHTC,HEIGHTC_STATISTIC,5th Percentile -US-GLE,88623,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,271 -US-GLE,88623,GRP_HEIGHTC,HEIGHTC_DATE,2011 -US-GLE,88630,GRP_HEIGHTC,HEIGHTC,23.1 -US-GLE,88630,GRP_HEIGHTC,HEIGHTC_STATISTIC,90th Percentile -US-GLE,88630,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,271 -US-GLE,88630,GRP_HEIGHTC,HEIGHTC_DATE,2011 -US-GLE,88634,GRP_HEIGHTC,HEIGHTC,19.2 -US-GLE,88634,GRP_HEIGHTC,HEIGHTC_STATISTIC,75th Percentile -US-GLE,88634,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,271 -US-GLE,88634,GRP_HEIGHTC,HEIGHTC_DATE,2011 -US-GLE,88635,GRP_HEIGHTC,HEIGHTC,27.7 -US-GLE,88635,GRP_HEIGHTC,HEIGHTC_STATISTIC,99th Percentile -US-GLE,88635,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,271 -US-GLE,88635,GRP_HEIGHTC,HEIGHTC_DATE,2011 -US-GLE,88637,GRP_HEIGHTC,HEIGHTC,24.6 -US-GLE,88637,GRP_HEIGHTC,HEIGHTC_STATISTIC,95th Percentile -US-GLE,88637,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,271 -US-GLE,88637,GRP_HEIGHTC,HEIGHTC_DATE,2011 -US-GLE,88641,GRP_HEIGHTC,HEIGHTC,14.6 -US-GLE,88641,GRP_HEIGHTC,HEIGHTC_STATISTIC,Median - 50th Percentile -US-GLE,88641,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,271 -US-GLE,88641,GRP_HEIGHTC,HEIGHTC_DATE,2011 -US-GLE,88643,GRP_HEIGHTC,HEIGHTC,4.4 -US-GLE,88643,GRP_HEIGHTC,HEIGHTC_STATISTIC,1st Percentile -US-GLE,88643,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,271 -US-GLE,88643,GRP_HEIGHTC,HEIGHTC_DATE,2011 -US-GLE,88607,GRP_HEIGHTC,HEIGHTC,1.9 -US-GLE,88607,GRP_HEIGHTC,HEIGHTC_STATISTIC,10th Percentile -US-GLE,88607,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,217 -US-GLE,88607,GRP_HEIGHTC,HEIGHTC_DATE,201808 -US-GLE,88611,GRP_HEIGHTC,HEIGHTC,1.7 -US-GLE,88611,GRP_HEIGHTC,HEIGHTC_STATISTIC,5th Percentile -US-GLE,88611,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,217 -US-GLE,88611,GRP_HEIGHTC,HEIGHTC_DATE,201808 -US-GLE,88612,GRP_HEIGHTC,HEIGHTC,2.8 -US-GLE,88612,GRP_HEIGHTC,HEIGHTC_STATISTIC,25th Percentile -US-GLE,88612,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,217 -US-GLE,88612,GRP_HEIGHTC,HEIGHTC_DATE,201808 -US-GLE,88613,GRP_HEIGHTC,HEIGHTC,12.2 -US-GLE,88613,GRP_HEIGHTC,HEIGHTC_STATISTIC,75th Percentile -US-GLE,88613,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,217 -US-GLE,88613,GRP_HEIGHTC,HEIGHTC_DATE,201808 -US-GLE,88618,GRP_HEIGHTC,HEIGHTC,16.9 -US-GLE,88618,GRP_HEIGHTC,HEIGHTC_STATISTIC,95th Percentile -US-GLE,88618,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,217 -US-GLE,88618,GRP_HEIGHTC,HEIGHTC_DATE,201808 -US-GLE,88621,GRP_HEIGHTC,HEIGHTC,4.9 -US-GLE,88621,GRP_HEIGHTC,HEIGHTC_STATISTIC,Median - 50th Percentile -US-GLE,88621,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,217 -US-GLE,88621,GRP_HEIGHTC,HEIGHTC_DATE,201808 -US-GLE,88625,GRP_HEIGHTC,HEIGHTC,18.7 -US-GLE,88625,GRP_HEIGHTC,HEIGHTC_STATISTIC,99th Percentile -US-GLE,88625,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,217 -US-GLE,88625,GRP_HEIGHTC,HEIGHTC_DATE,201808 -US-GLE,88628,GRP_HEIGHTC,HEIGHTC,7.2 -US-GLE,88628,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-GLE,88628,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,217 -US-GLE,88628,GRP_HEIGHTC,HEIGHTC_DATE,201808 -US-GLE,88631,GRP_HEIGHTC,HEIGHTC,15.5 -US-GLE,88631,GRP_HEIGHTC,HEIGHTC_STATISTIC,90th Percentile -US-GLE,88631,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,217 -US-GLE,88631,GRP_HEIGHTC,HEIGHTC_DATE,201808 -US-GLE,88640,GRP_HEIGHTC,HEIGHTC,1.5 -US-GLE,88640,GRP_HEIGHTC,HEIGHTC_STATISTIC,1st Percentile -US-GLE,88640,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,217 -US-GLE,88640,GRP_HEIGHTC,HEIGHTC_DATE,201808 -US-GLE,88604,GRP_HEIGHTC,HEIGHTC,4.2 -US-GLE,88604,GRP_HEIGHTC,HEIGHTC_STATISTIC,25th Percentile -US-GLE,88604,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,414 -US-GLE,88604,GRP_HEIGHTC,HEIGHTC_DATE,201909 -US-GLE,88610,GRP_HEIGHTC,HEIGHTC,20.4 -US-GLE,88610,GRP_HEIGHTC,HEIGHTC_STATISTIC,99th Percentile -US-GLE,88610,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,414 -US-GLE,88610,GRP_HEIGHTC,HEIGHTC_DATE,201909 -US-GLE,88614,GRP_HEIGHTC,HEIGHTC,2.4 -US-GLE,88614,GRP_HEIGHTC,HEIGHTC_STATISTIC,5th Percentile -US-GLE,88614,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,414 -US-GLE,88614,GRP_HEIGHTC,HEIGHTC_DATE,201909 -US-GLE,88616,GRP_HEIGHTC,HEIGHTC,8.6 -US-GLE,88616,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-GLE,88616,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,414 -US-GLE,88616,GRP_HEIGHTC,HEIGHTC_DATE,201909 -US-GLE,88624,GRP_HEIGHTC,HEIGHTC,1.7 -US-GLE,88624,GRP_HEIGHTC,HEIGHTC_STATISTIC,1st Percentile -US-GLE,88624,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,414 -US-GLE,88624,GRP_HEIGHTC,HEIGHTC_DATE,201909 -US-GLE,88626,GRP_HEIGHTC,HEIGHTC,14.9 -US-GLE,88626,GRP_HEIGHTC,HEIGHTC_STATISTIC,90th Percentile -US-GLE,88626,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,414 -US-GLE,88626,GRP_HEIGHTC,HEIGHTC_DATE,201909 -US-GLE,88632,GRP_HEIGHTC,HEIGHTC,2.9 -US-GLE,88632,GRP_HEIGHTC,HEIGHTC_STATISTIC,10th Percentile -US-GLE,88632,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,414 -US-GLE,88632,GRP_HEIGHTC,HEIGHTC_DATE,201909 -US-GLE,88633,GRP_HEIGHTC,HEIGHTC,12.7 -US-GLE,88633,GRP_HEIGHTC,HEIGHTC_STATISTIC,75th Percentile -US-GLE,88633,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,414 -US-GLE,88633,GRP_HEIGHTC,HEIGHTC_DATE,201909 -US-GLE,88638,GRP_HEIGHTC,HEIGHTC,17.0 -US-GLE,88638,GRP_HEIGHTC,HEIGHTC_STATISTIC,95th Percentile -US-GLE,88638,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,414 -US-GLE,88638,GRP_HEIGHTC,HEIGHTC_DATE,201909 -US-GLE,88642,GRP_HEIGHTC,HEIGHTC,7.7 -US-GLE,88642,GRP_HEIGHTC,HEIGHTC_STATISTIC,Median - 50th Percentile -US-GLE,88642,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,414 -US-GLE,88642,GRP_HEIGHTC,HEIGHTC_DATE,201909 -US-GLE,15338,GRP_IGBP,IGBP,ENF -US-GLE,15338,GRP_IGBP,IGBP_COMMENT,85% Engelmann spruce 15% Subalpine fir -US-GLE,15999,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-GLE,16000,GRP_LOCATION,LOCATION_LAT,41.3665 -US-GLE,16000,GRP_LOCATION,LOCATION_LONG,-106.2399 -US-GLE,16000,GRP_LOCATION,LOCATION_ELEV,3197 -US-GLE,16000,GRP_LOCATION,LOCATION_COMMENT,Change reflects location of new tower -US-GLE,15340,GRP_NETWORK,NETWORK,AmeriFlux -US-GLE,1700001914,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Arain, M. A., Restrepo-Coupe, N. (2005) Net Ecosystem Production In A Temperate Pine Plantation In Southeastern Canada, Agricultural And Forest Meteorology, 128(3-4), 223-241" -US-GLE,1700001914,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2004.10.003 -US-GLE,1700001914,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-GLE,1700002727,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Baldocchi, D., Penuelas, J. (2018) The Physics And Ecology Of Mining Carbon Dioxide From The Atmosphere By Ecosystems, Global Change Biology, 45(2), 9275–9287" -US-GLE,1700002727,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/GCB.14559 -US-GLE,1700002727,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-GLE,1700004416,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Baldocchi, D., Penuelas, J. (2018) The Physics And Ecology Of Mining Carbon Dioxide From The Atmosphere By Ecosystems, Global Change Biology, 45(3-4), 9275–9287" -US-GLE,1700004416,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/GCB.14559 -US-GLE,1700004416,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-GLE,1700006252,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Bradford, J. B., Birdsey, R. A., Joyce, L. A., Ryan, M. G. (2008) Tree Age, Disturbance History, And Carbon Stocks And Fluxes In Subalpine Rocky Mountain Forests, Global Change Biology, 14(12), 2882-2897" -US-GLE,1700006252,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/J.1365-2486.2008.01686.X -US-GLE,1700006252,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-GLE,1700005967,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Burns, S. P., Frank, J. M., Massman, W. J., Patton, E. G., Blanken, P. D. (2021) The Effect Of Static Pressure-Wind Covariance On Vertical Carbon Dioxide Exchange At A Windy Subalpine Forest Site, Agricultural And Forest Meteorology, 306(6), 108402" -US-GLE,1700005967,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108402 -US-GLE,1700005967,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-GLE,1700002964,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Baldocchi, D. D., Poindexter, C., Abraha, M., Desai, A. R., Bohrer, G., Arain, M. A., Griffis, T., Blanken, P. D., O'Halloran, T. L., Thomas, R. Q., Zhang, Q., Burns, S. P., Frank, J. M., Christian, D., Brown, S., Black, T. A., Gough, C. M., Law, B. E., Lee, X., Chen, J., Reed, D. E., Massman, W. J., Clark, K., Hatfield, J., Prueger, J., Bracho, R., Baker, J. M., Martin, T. A. (2018) Temporal Dynamics Of Aerodynamic Canopy Height Derived From Eddy Covariance Momentum Flux Data Across North American Flux Networks, Geophysical Research Letters, 45(2), 9275–9287" -US-GLE,1700002964,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018GL079306 -US-GLE,1700002964,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-GLE,1700002526,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Baldocchi, D. D., Poindexter, C., Abraha, M., Desai, A. R., Bohrer, G., Arain, M. A., Griffis, T., Blanken, P. D., O'Halloran, T. L., Thomas, R. Q., Zhang, Q., Burns, S. P., Frank, J. M., Christian, D., Brown, S., Black, T. A., Gough, C. M., Law, B. E., Lee, X., Chen, J., Reed, D. E., Massman, W. J., Clark, K., Hatfield, J., Prueger, J., Bracho, R., Baker, J. M., Martin, T. A. (2018) Temporal Dynamics Of Aerodynamic Canopy Height Derived From Eddy Covariance Momentum Flux Data Across North American Flux Networks, Geophysical Research Letters, 45(3-4), 9275–9287" -US-GLE,1700002526,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018GL079306 -US-GLE,1700002526,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-GLE,1700004998,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(6), 108350" -US-GLE,1700004998,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -US-GLE,1700004998,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-GLE,1700007365,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Del Grosso, S., Parton, W., Mosier, A., Holland, E., Pendall, E., Schimel, D., Ojima, D. (2005) Modeling Soil CO2 Emissions From Ecosystems, Biogeochemistry, 73(1), 71-91" -US-GLE,1700007365,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1007/S10533-004-0898-Z -US-GLE,1700007365,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-GLE,1700002052,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Frank, J. M., Massman, W. J., Ewers, B. E., Huckaby, L. S., Negrón, J. F. (2014) Ecosystem CO2 /H2O Fluxes Are Explained By Hydraulically Limited Gas Exchange During Tree Mortality From Spruce Bark Beetles, Journal Of Geophysical Research: Biogeosciences, 119(6), 1195-1215" -US-GLE,1700002052,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/2013JG002597 -US-GLE,1700002052,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Primary_Citation -US-GLE,1700007524,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Frank, J. M., Massman, W. J., Ewers, B. E., Williams, D. G. (2019) Bayesian Analyses of 17 Winters of Water Vapor Fluxes Show Bark Beetles Reduce Sublimation, Water Resources Research, 55(2), 1598-1623" -US-GLE,1700007524,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018WR023054 -US-GLE,1700007524,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-GLE,1700002385,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Helliker, B. R., Song, X., Goulden, M. L., Clark, K., Bolstad, P., Munger, J. W., Chen, J., Noormets, A., Hollinger, D., Wofsy, S., Martin, T., Baldocchi, D., Euskirchenn, E., Desai, A., Burns, S. P. (2018) Assessing The Interplay Between Canopy Energy Balance And Photosynthesis With Cellulose δ18o: Large-Scale Patterns And Independent Ground-Truthing, Oecologia, 128(3-4), 223-241" -US-GLE,1700002385,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1007/S00442-018-4198-Z -US-GLE,1700002385,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-GLE,1700002106,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Helliker, B. R., Song, X., Goulden, M. L., Clark, K., Bolstad, P., Munger, J. W., Chen, J., Noormets, A., Hollinger, D., Wofsy, S., Martin, T., Baldocchi, D., Euskirchenn, E., Desai, A., Burns, S. P. (2018) Assessing The Interplay Between Canopy Energy Balance And Photosynthesis With Cellulose δ18o: Large-Scale Patterns And Independent Ground-Truthing, Oecologia, 26(2), 901-918" -US-GLE,1700002106,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1007/S00442-018-4198-Z -US-GLE,1700002106,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-GLE,1700006393,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"McDowell, N. G., Marshall, J. D., Hooker, T. D., Musselman, R. (2000) Estimating CO2 Flux From Snowpacks At Three Sites In The Rocky Mountains, Tree Physiology, 20(11), 745-753" -US-GLE,1700006393,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1093/TREEPHYS/20.11.745 -US-GLE,1700006393,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-GLE,1700001989,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Mercer, J. J., Liefert, D. T., Williams, D. G. (2020) Atmospheric Vapour And Precipitation Are Not In Isotopic Equilibrium In A Continental Mountain Environment, Hydrological Processes, 42(6), 1802-1815" -US-GLE,1700001989,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/HYP.13775 -US-GLE,1700001989,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-GLE,1700005169,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Novick, K. A., Ficklin, D. L., Stoy, P. C., Williams, C. A., Bohrer, G., Oishi, A., Papuga, S. A., Blanken, P. D., Noormets, A., Sulman, B. N., Scott, R. L., Wang, L., Phillips, R. P. (2016) The Increasing Importance Of Atmospheric Demand For Ecosystem Water And Carbon Fluxes, Nature Climate Change, 6(11), 1023-1027" -US-GLE,1700005169,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1038/NCLIMATE3114 -US-GLE,1700005169,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-GLE,1700005184,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Novick, K. A., Konings, A. G., Gentine, P. (2019) Beyond Soil Water Potential: An Expanded View On Isohydricity Including Land–Atmosphere Interactions And Phenology, Plant, Cell & Environment, 42(6), 1802-1815" -US-GLE,1700005184,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/PCE.13517 -US-GLE,1700005184,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-GLE,1700004770,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Speckman, H. N., Frank, J. M., Bradford, J. B., Miles, B. L., Massman, W. J., Parton, W. J., Ryan, M. G. (2015) Forest Ecosystem Respiration Estimated From Eddy Covariance And Chamber Measurements Under High Turbulence And Substantial Tree Mortality From Bark Beetles, Global Change Biology, 21(2), 708-721" -US-GLE,1700004770,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/GCB.12731 -US-GLE,1700004770,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-GLE,1700004671,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Sullivan, R. C., Cook, D. R., Ghate, V. P., Kotamarthi, V. R., Feng, Y. (2019) Improved Spatiotemporal Representativeness And Bias Reduction Of Satellite-Based Evapotranspiration Retrievals Via Use Of In Situ Meteorology And Constrained Canopy Surface Resistance, Journal Of Geophysical Research: Biogeosciences, 124(2), 342-352" -US-GLE,1700004671,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018JG004744 -US-GLE,1700004671,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-GLE,1700007338,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Sullivan, R. C., Kotamarthi, V. R., Feng, Y. (2019) Recovering Evapotranspiration Trends From Biased CMIP5 Simulations And Sensitivity To Changing Climate Over North America, Journal Of Hydrometeorology, 20(8), 1619-1633" -US-GLE,1700007338,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1175/JHM-D-18-0259.1 -US-GLE,1700007338,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-GLE,1700001962,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Xu, B., Arain, M. A., Black, T. A., Law, B. E., Pastorello, G. Z., Chu, H. (2020) Seasonal Variability Of Forest Sensitivity To Heat And Drought Stresses: A Synthesis Based On Carbon Fluxes From North American Forest Ecosystems, Global Change Biology, 26(2), 901-918" -US-GLE,1700001962,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/GCB.14843 -US-GLE,1700001962,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-GLE,1700007161,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Zeller, K., Nikolov, N. (2000) Quantifying Simultaneous Fluxes Of Ozone, Carbon Dioxide And Water Vapor Above A Subalpine Forest Ecosystem, Environmental Pollution, 107(1), 1-20" -US-GLE,1700007161,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/S0269-7491(99)00156-6 -US-GLE,1700007161,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-GLE,1700004137,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Zhang, Q., Ficklin, D. L., Manzoni, S., Wang, L., Way, D., Phillips, R. P., Novick, K. A. (2019) Response Of Ecosystem Intrinsic Water Use Efficiency And Gross Primary Productivity To Rising Vapor Pressure Deficit, Environmental Research Letters, 14(7), 074023" -US-GLE,1700004137,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1088/1748-9326/AB2603 -US-GLE,1700004137,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-GLE,15342,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"The main analytical objectives of the GLEES AmeriFlux site include the flux measurements of momentum, sensible heat, water vapor, latent heat, and CO2 exchange between a sub-alpine forest and the atmosphere. Additional research topics include: 1) examination of the relationship of energy and mass exhanges between the atmosphere and underlying forest ecosystem; 2) ozone depletion; 3) snow hydrology; 4) snow chemistry; 5) nitrogen cycling in sub-alpine forest ecosystems; 6) sub-alpine plant physiology, and 7) the ecosystem response to a spruce beetle outbreak. Recently, significant efforts are being made to quantify the effect of the widespread overstory mortality caused by the spruce beetle (Dendroctonus rufipennis) and the western balsam bark beetle (Dryocoetes confusus)." -US-GLE,16004,GRP_SITE_CHAR,TERRAIN,"Medium Slope (>2 %, <5%)" -US-GLE,16004,GRP_SITE_CHAR,ASPECT,W -US-GLE,16004,GRP_SITE_CHAR,WIND_DIRECTION,W -US-GLE,16004,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,1900 -US-GLE,16004,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,243 -US-GLE,15343,GRP_SITE_DESC,SITE_DESC,"The Glacier Lakes Ecosystem Experiments Site (GLEES) site is located on land owned by the U.S. government and managed by US Forest Service as part of the Medicine Bow National Forest. Many of the trees in the immediate vicinity of the site are older than 400 years, inter-dispersed among trees much younger in age. This widespread age distribution is most likely a derivation of one of two scenarios: 1) A widespread stand replacement about 400 years ago followed by a slow replacement; 2) Intermittent random disturbances over the past 400 years (Bradford et al. 2008). A decade long spruce beetle outbreak that peaked in 2008 resulted in the mortality of 85% of the forested basal area. There are a few private land holdings in the area, with scattered uncorked mining claims. Following the establishment of the National Forest, mining was banned and grazing was closed in the early 1990's in the upper portion of the GLEES site. Recreation in the winter, when snow can remain in patches into the summer months, snow mobiling and cross country skiing are popular. During the limited summer, hiking, camping and fishing are common activities. The site is accessible by vehicle only during the summer on Forest Road FDR 317, and in the winter, the tower is only reachable via snowmobile." -US-GLE,15344,GRP_SITE_FUNDING,SITE_FUNDING,USDA/Forest Service -US-GLE,15345,GRP_STATE,STATE,WY -US-GLE,15346,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Bill Massman -US-GLE,15346,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-GLE,15346,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,wmassman@fs.fed.us -US-GLE,15346,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,USDA Forest Service -US-GLE,15346,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Rocky Mountain Research Station, 240 W. Prospect,Fort Collins, CO USA 80526" -US-GLE,94774,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,John Frank -US-GLE,94774,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-GLE,94774,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,john.frank@usda.gov -US-GLE,94774,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,USDA Forest Service -US-GLE,94774,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Rocky Mountain Research Station, 240 W. Prospect,Fort Collins, CO USA 80526" -US-GLE,94791,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Rob Hubbard -US-GLE,94791,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-GLE,94791,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,robert.hubbard@usda.gov -US-GLE,94791,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,USDA Forest Service -US-GLE,94791,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Rocky Mountain Research Station, 240 W. Prospect,Fort Collins, CO USA 80526" -US-GLE,29810,GRP_TOWER_POWER,TOWER_POWER,Direct power -US-GLE,16009,GRP_TOWER_TYPE,TOWER_TYPE,walk-up -US-GLE,16010,GRP_URL,URL,http://www.fs.fed.us/rmrs/experimental-forests-and-ranges/glees-glacier-lakes-ecosystem-experiments-site -US-GLE,24000368,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-GLE -US-GLE,33638,GRP_UTC_OFFSET,UTC_OFFSET,-7 -US-GLE,33638,GRP_UTC_OFFSET,UTC_OFFSET_COMMENT,Added by AMF data processing team for data QAQC checks. -US-Ha1,90063,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,"Operation of the US-Ha1 site is supported by the AmeriFlux Management Project with funding by the U.S. Department of Energy’s Office of Science under Contract No. DE-AC02-05CH11231, and additionally is a part of the Harvard Forest LTER site supported by the National Science Foundation (DEB-1832210)." -US-Ha1,17353,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB,229 -US-Ha1,17353,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_SPATIAL_VARIABILITY,141 -US-Ha1,17353,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_SPATIAL_REP_NUMBER,33 -US-Ha1,17353,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_ORGAN,Wood -US-Ha1,17353,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_PHEN,Mixed/unknown -US-Ha1,17353,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_UNIT,gC m-2 -US-Ha1,17353,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_APPROACH,"in 34 plots(each 10m radius circles) we band each tree >=10 cm DBH, and scale to biomass using allometric equations. For shrubs # of individuals in each size class were tallied and then multiplied by mean class biomass from allometric equations." -US-Ha1,17353,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_DATE,2010 -US-Ha1,17353,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_COMMENT,"Trees are stems >=10cm DBH, shrubs are stems <10cm and >=1cm DBH" -US-Ha1,17340,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB,238 -US-Ha1,17340,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_SPATIAL_VARIABILITY,142 -US-Ha1,17340,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_SPATIAL_REP_NUMBER,33 -US-Ha1,17340,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_ORGAN,Wood -US-Ha1,17340,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_PHEN,Mixed/unknown -US-Ha1,17340,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_UNIT,gC m-2 -US-Ha1,17340,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_APPROACH,"in 34 plots(each 10m radius circles) we band each tree >=10 cm DBH, and scale to biomass using allometric equations. For shrubs # of individuals in each size class were tallied and then multiplied by mean class biomass from allometric equations." -US-Ha1,17340,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_DATE,2006 -US-Ha1,17340,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_COMMENT,"Trees are stems >=10cm DBH, shrubs are stems <10cm and >=1cm DBH" -US-Ha1,17333,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB,254 -US-Ha1,17333,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_SPATIAL_VARIABILITY,159 -US-Ha1,17333,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_SPATIAL_REP_NUMBER,33 -US-Ha1,17333,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_ORGAN,Wood -US-Ha1,17333,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_PHEN,Mixed/unknown -US-Ha1,17333,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_UNIT,gC m-2 -US-Ha1,17333,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_APPROACH,"in 34 plots(each 10m radius circles) we band each tree >=10 cm DBH, and scale to biomass using allometric equations. For shrubs # of individuals in each size class were tallied and then multiplied by mean class biomass from allometric equations." -US-Ha1,17333,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_DATE,2004 -US-Ha1,17333,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_COMMENT,"Trees are stems >=10cm DBH, shrubs are stems <10cm and >=1cm DBH" -US-Ha1,17298,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,10163 -US-Ha1,17298,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_SPATIAL_VARIABILITY,3129 -US-Ha1,17298,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_SPATIAL_REP_NUMBER,34 -US-Ha1,17298,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Wood -US-Ha1,17298,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-Ha1,17298,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-Ha1,17298,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,"in 34 plots(each 10m radius circles) we band each tree >=10 cm DBH, and scale to biomass using allometric equations." -US-Ha1,17298,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,1993 -US-Ha1,17298,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,"Trees are stems >=10cm DBH, shrubs are stems <10cm and >=1cm DBH" -US-Ha1,17305,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,10696 -US-Ha1,17305,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_SPATIAL_VARIABILITY,3273 -US-Ha1,17305,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_SPATIAL_REP_NUMBER,34 -US-Ha1,17305,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Wood -US-Ha1,17305,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-Ha1,17305,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-Ha1,17305,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,"in 34 plots(each 10m radius circles) we band each tree >=10 cm DBH, and scale to biomass using allometric equations." -US-Ha1,17305,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,1998 -US-Ha1,17305,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,"Trees are stems >=10cm DBH, shrubs are stems <10cm and >=1cm DBH" -US-Ha1,17311,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,10725 -US-Ha1,17311,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_SPATIAL_VARIABILITY,3273 -US-Ha1,17311,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_SPATIAL_REP_NUMBER,34 -US-Ha1,17311,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Wood -US-Ha1,17311,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-Ha1,17311,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-Ha1,17311,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,"in 34 plots(each 10m radius circles) we band each tree >=10 cm DBH, and scale to biomass using allometric equations." -US-Ha1,17311,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,1999 -US-Ha1,17311,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,"Trees are stems >=10cm DBH, shrubs are stems <10cm and >=1cm DBH" -US-Ha1,17317,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,10891 -US-Ha1,17317,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_SPATIAL_VARIABILITY,3303 -US-Ha1,17317,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_SPATIAL_REP_NUMBER,34 -US-Ha1,17317,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Wood -US-Ha1,17317,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-Ha1,17317,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-Ha1,17317,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,"in 34 plots(each 10m radius circles) we band each tree >=10 cm DBH, and scale to biomass using allometric equations." -US-Ha1,17317,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2000 -US-Ha1,17317,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,"Trees are stems >=10cm DBH, shrubs are stems <10cm and >=1cm DBH" -US-Ha1,17323,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,11105 -US-Ha1,17323,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_SPATIAL_VARIABILITY,3355 -US-Ha1,17323,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_SPATIAL_REP_NUMBER,34 -US-Ha1,17323,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Wood -US-Ha1,17323,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-Ha1,17323,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-Ha1,17323,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,"in 34 plots(each 10m radius circles) we band each tree >=10 cm DBH, and scale to biomass using allometric equations." -US-Ha1,17323,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2001 -US-Ha1,17323,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,"Trees are stems >=10cm DBH, shrubs are stems <10cm and >=1cm DBH" -US-Ha1,17327,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,11146 -US-Ha1,17327,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_SPATIAL_VARIABILITY,3458 -US-Ha1,17327,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_SPATIAL_REP_NUMBER,34 -US-Ha1,17327,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Wood -US-Ha1,17327,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-Ha1,17327,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-Ha1,17327,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,"in 34 plots(each 10m radius circles) we band each tree >=10 cm DBH, and scale to biomass using allometric equations." -US-Ha1,17327,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2002 -US-Ha1,17327,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,"Trees are stems >=10cm DBH, shrubs are stems <10cm and >=1cm DBH" -US-Ha1,17330,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,11250 -US-Ha1,17330,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_SPATIAL_VARIABILITY,3496 -US-Ha1,17330,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_SPATIAL_REP_NUMBER,34 -US-Ha1,17330,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Wood -US-Ha1,17330,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-Ha1,17330,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-Ha1,17330,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,"in 34 plots(each 10m radius circles) we band each tree >=10 cm DBH, and scale to biomass using allometric equations." -US-Ha1,17330,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2003 -US-Ha1,17330,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,"Trees are stems >=10cm DBH, shrubs are stems <10cm and >=1cm DBH" -US-Ha1,17334,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,11381 -US-Ha1,17334,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_SPATIAL_VARIABILITY,3520 -US-Ha1,17334,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_SPATIAL_REP_NUMBER,34 -US-Ha1,17334,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Wood -US-Ha1,17334,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-Ha1,17334,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-Ha1,17334,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,"in 34 plots(each 10m radius circles) we band each tree >=10 cm DBH, and scale to biomass using allometric equations. For shrubs # of individuals in each size class were tallied and then multiplied by mean class biomass from allometric equations." -US-Ha1,17334,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2004 -US-Ha1,17334,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,"Trees are stems >=10cm DBH, shrubs are stems <10cm and >=1cm DBH" -US-Ha1,17337,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,11458 -US-Ha1,17337,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_SPATIAL_VARIABILITY,3552 -US-Ha1,17337,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_SPATIAL_REP_NUMBER,34 -US-Ha1,17337,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Wood -US-Ha1,17337,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-Ha1,17337,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-Ha1,17337,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,"in 34 plots(each 10m radius circles) we band each tree >=10 cm DBH, and scale to biomass using allometric equations." -US-Ha1,17337,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2005 -US-Ha1,17337,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,"Trees are stems >=10cm DBH, shrubs are stems <10cm and >=1cm DBH" -US-Ha1,17341,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,11727 -US-Ha1,17341,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_SPATIAL_VARIABILITY,3615 -US-Ha1,17341,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_SPATIAL_REP_NUMBER,34 -US-Ha1,17341,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Wood -US-Ha1,17341,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-Ha1,17341,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-Ha1,17341,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,"in 34 plots(each 10m radius circles) we band each tree >=10 cm DBH, and scale to biomass using allometric equations. For shrubs # of individuals in each size class were tallied and then multiplied by mean class biomass from allometric equations." -US-Ha1,17341,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2006 -US-Ha1,17341,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,"Trees are stems >=10cm DBH, shrubs are stems <10cm and >=1cm DBH" -US-Ha1,17344,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,11843.973153 -US-Ha1,17344,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_SPATIAL_VARIABILITY,3687 -US-Ha1,17344,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_SPATIAL_REP_NUMBER,34 -US-Ha1,17344,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Wood -US-Ha1,17344,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-Ha1,17344,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-Ha1,17344,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,"in 34 plots(each 10m radius circles) we band each tree >=10 cm DBH, and scale to biomass using allometric equations." -US-Ha1,17344,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2007 -US-Ha1,17344,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,"Trees are stems >=10cm DBH, shrubs are stems <10cm and >=1cm DBH" -US-Ha1,17347,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,11981 -US-Ha1,17347,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_SPATIAL_VARIABILITY,3640 -US-Ha1,17347,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_SPATIAL_REP_NUMBER,34 -US-Ha1,17347,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Wood -US-Ha1,17347,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-Ha1,17347,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-Ha1,17347,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,"in 34 plots(each 10m radius circles) we band each tree >=10 cm DBH, and scale to biomass using allometric equations." -US-Ha1,17347,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2008 -US-Ha1,17347,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,"Trees are stems >=10cm DBH, shrubs are stems <10cm and >=1cm DBH" -US-Ha1,17350,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,12125.607432 -US-Ha1,17350,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_SPATIAL_VARIABILITY,3687.2863669 -US-Ha1,17350,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_SPATIAL_REP_NUMBER,34 -US-Ha1,17350,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Wood -US-Ha1,17350,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-Ha1,17350,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-Ha1,17350,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,"in 34 plots(each 10m radius circles) we band each tree >=10 cm DBH, and scale to biomass using allometric equations." -US-Ha1,17350,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2009 -US-Ha1,17350,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,"Trees are stems >=10cm DBH, shrubs are stems <10cm and >=1cm DBH" -US-Ha1,17354,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,12321 -US-Ha1,17354,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_SPATIAL_VARIABILITY,3795 -US-Ha1,17354,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_SPATIAL_REP_NUMBER,34 -US-Ha1,17354,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Wood -US-Ha1,17354,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-Ha1,17354,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-Ha1,17354,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,"in 34 plots(each 10m radius circles) we band each tree >=10 cm DBH, and scale to biomass using allometric equations. For shrubs # of individuals in each size class were tallied and then multiplied by mean class biomass from allometric equations." -US-Ha1,17354,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2010 -US-Ha1,17354,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,"Trees are stems >=10cm DBH, shrubs are stems <10cm and >=1cm DBH" -US-Ha1,17356,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,12466 -US-Ha1,17356,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_SPATIAL_VARIABILITY,3848 -US-Ha1,17356,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_SPATIAL_REP_NUMBER,34 -US-Ha1,17356,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Wood -US-Ha1,17356,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-Ha1,17356,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-Ha1,17356,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,"in 34 plots(each 10m radius circles) we band each tree >=10 cm DBH, and scale to biomass using allometric equations." -US-Ha1,17356,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2011 -US-Ha1,17356,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,"Trees are stems >=10cm DBH, shrubs are stems <10cm and >=1cm DBH" -US-Ha1,17358,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,12604 -US-Ha1,17358,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_SPATIAL_VARIABILITY,3872 -US-Ha1,17358,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_SPATIAL_REP_NUMBER,34 -US-Ha1,17358,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Wood -US-Ha1,17358,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-Ha1,17358,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-Ha1,17358,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,"in 34 plots(each 10m radius circles) we band each tree >=10 cm DBH, and scale to biomass using allometric equations." -US-Ha1,17358,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2012 -US-Ha1,17358,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,"Trees are stems >=10cm DBH, shrubs are stems <10cm and >=1cm DBH" -US-Ha1,17360,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,12943 -US-Ha1,17360,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_SPATIAL_VARIABILITY,3918 -US-Ha1,17360,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_SPATIAL_REP_NUMBER,34 -US-Ha1,17360,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Wood -US-Ha1,17360,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-Ha1,17360,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-Ha1,17360,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,"in 34 plots(each 10m radius circles) we band each tree >=10 cm DBH, and scale to biomass using allometric equations." -US-Ha1,17360,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2013 -US-Ha1,17360,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,"Trees are stems >=10cm DBH, shrubs are stems <10cm and >=1cm DBH" -US-Ha1,23985,GRP_AG_LIT_CHEM,AG_LIT_C,0.089 -US-Ha1,24356,GRP_AG_LIT_CHEM,AG_LIT_C,0.105 -US-Ha1,23986,GRP_AG_LIT_CHEM,AG_LIT_C,0.118 -US-Ha1,23688,GRP_AG_LIT_CHEM,AG_LIT_C,5.113 -US-Ha1,23688,GRP_AG_LIT_CHEM,AG_LIT_N,0.079 -US-Ha1,23986,GRP_AG_LIT_CHEM,AG_LIT_N,5.096 -US-Ha1,24356,GRP_AG_LIT_CHEM,AG_LIT_N,5.187 -US-Ha1,23985,GRP_AG_LIT_CHEM,AG_LIT_N,5.261 -US-Ha1,23688,GRP_AG_LIT_CHEM,AG_LIT_DATE,1998 -US-Ha1,23985,GRP_AG_LIT_CHEM,AG_LIT_DATE,1999 -US-Ha1,24356,GRP_AG_LIT_CHEM,AG_LIT_DATE,2000 -US-Ha1,23986,GRP_AG_LIT_CHEM,AG_LIT_DATE,2007 -US-Ha1,23688,GRP_AG_LIT_CHEM,AG_LIT_COMMENT,leaves only; weighted average -US-Ha1,23985,GRP_AG_LIT_CHEM,AG_LIT_COMMENT,leaves only; weighted average -US-Ha1,23986,GRP_AG_LIT_CHEM,AG_LIT_COMMENT,leaves only; weighted average -US-Ha1,24356,GRP_AG_LIT_CHEM,AG_LIT_COMMENT,leaves only; weighted average -US-Ha1,17299,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT,127 -US-Ha1,17312,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT,127 -US-Ha1,17324,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT,137 -US-Ha1,17331,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT,142 -US-Ha1,17306,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT,143 -US-Ha1,17318,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT,143 -US-Ha1,17348,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT,146 -US-Ha1,17328,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT,147 -US-Ha1,17351,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT,156 -US-Ha1,17338,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT,159 -US-Ha1,17335,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT,160 -US-Ha1,17345,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT,162 -US-Ha1,17342,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT,172 -US-Ha1,17312,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT_SPATIAL_VARIABILITY,24 -US-Ha1,17299,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT_SPATIAL_VARIABILITY,25 -US-Ha1,17331,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT_SPATIAL_VARIABILITY,25 -US-Ha1,17306,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT_SPATIAL_VARIABILITY,26 -US-Ha1,17335,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT_SPATIAL_VARIABILITY,27 -US-Ha1,17342,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT_SPATIAL_VARIABILITY,27 -US-Ha1,17351,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT_SPATIAL_VARIABILITY,27 -US-Ha1,17338,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT_SPATIAL_VARIABILITY,29 -US-Ha1,17348,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT_SPATIAL_VARIABILITY,29 -US-Ha1,17318,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT_SPATIAL_VARIABILITY,31 -US-Ha1,17328,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT_SPATIAL_VARIABILITY,31 -US-Ha1,17324,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT_SPATIAL_VARIABILITY,37 -US-Ha1,17345,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT_SPATIAL_VARIABILITY,45 -US-Ha1,17299,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT_SPATIAL_REP_NUMBER,34 -US-Ha1,17306,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT_SPATIAL_REP_NUMBER,34 -US-Ha1,17312,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT_SPATIAL_REP_NUMBER,34 -US-Ha1,17318,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT_SPATIAL_REP_NUMBER,34 -US-Ha1,17324,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT_SPATIAL_REP_NUMBER,34 -US-Ha1,17328,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT_SPATIAL_REP_NUMBER,34 -US-Ha1,17331,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT_SPATIAL_REP_NUMBER,34 -US-Ha1,17335,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT_SPATIAL_REP_NUMBER,34 -US-Ha1,17338,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT_SPATIAL_REP_NUMBER,34 -US-Ha1,17342,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT_SPATIAL_REP_NUMBER,34 -US-Ha1,17345,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT_SPATIAL_REP_NUMBER,34 -US-Ha1,17348,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT_SPATIAL_REP_NUMBER,34 -US-Ha1,17351,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT_SPATIAL_REP_NUMBER,34 -US-Ha1,17299,GRP_AG_LIT_PROD,AG_LIT_PROD_UNIT,gC m-2 -US-Ha1,17306,GRP_AG_LIT_PROD,AG_LIT_PROD_UNIT,gC m-2 -US-Ha1,17312,GRP_AG_LIT_PROD,AG_LIT_PROD_UNIT,gC m-2 -US-Ha1,17318,GRP_AG_LIT_PROD,AG_LIT_PROD_UNIT,gC m-2 -US-Ha1,17324,GRP_AG_LIT_PROD,AG_LIT_PROD_UNIT,gC m-2 -US-Ha1,17328,GRP_AG_LIT_PROD,AG_LIT_PROD_UNIT,gC m-2 -US-Ha1,17331,GRP_AG_LIT_PROD,AG_LIT_PROD_UNIT,gC m-2 -US-Ha1,17335,GRP_AG_LIT_PROD,AG_LIT_PROD_UNIT,gC m-2 -US-Ha1,17338,GRP_AG_LIT_PROD,AG_LIT_PROD_UNIT,gC m-2 -US-Ha1,17342,GRP_AG_LIT_PROD,AG_LIT_PROD_UNIT,gC m-2 -US-Ha1,17345,GRP_AG_LIT_PROD,AG_LIT_PROD_UNIT,gC m-2 -US-Ha1,17348,GRP_AG_LIT_PROD,AG_LIT_PROD_UNIT,gC m-2 -US-Ha1,17351,GRP_AG_LIT_PROD,AG_LIT_PROD_UNIT,gC m-2 -US-Ha1,17299,GRP_AG_LIT_PROD,AG_LIT_PROD_APPROACH,litter baskets -US-Ha1,17306,GRP_AG_LIT_PROD,AG_LIT_PROD_APPROACH,litter baskets -US-Ha1,17312,GRP_AG_LIT_PROD,AG_LIT_PROD_APPROACH,litter baskets -US-Ha1,17318,GRP_AG_LIT_PROD,AG_LIT_PROD_APPROACH,litter baskets -US-Ha1,17324,GRP_AG_LIT_PROD,AG_LIT_PROD_APPROACH,litter baskets -US-Ha1,17328,GRP_AG_LIT_PROD,AG_LIT_PROD_APPROACH,litter baskets -US-Ha1,17331,GRP_AG_LIT_PROD,AG_LIT_PROD_APPROACH,litter baskets -US-Ha1,17335,GRP_AG_LIT_PROD,AG_LIT_PROD_APPROACH,litter baskets -US-Ha1,17338,GRP_AG_LIT_PROD,AG_LIT_PROD_APPROACH,litter baskets -US-Ha1,17342,GRP_AG_LIT_PROD,AG_LIT_PROD_APPROACH,litter baskets -US-Ha1,17345,GRP_AG_LIT_PROD,AG_LIT_PROD_APPROACH,litter baskets -US-Ha1,17348,GRP_AG_LIT_PROD,AG_LIT_PROD_APPROACH,litter baskets -US-Ha1,17351,GRP_AG_LIT_PROD,AG_LIT_PROD_APPROACH,litter baskets -US-Ha1,17299,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_START,1998 -US-Ha1,17306,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_START,19981113 -US-Ha1,17312,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_START,20000501 -US-Ha1,17318,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_START,20010601 -US-Ha1,17324,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_START,20020425 -US-Ha1,17328,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_START,20030416 -US-Ha1,17331,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_START,20040624 -US-Ha1,17335,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_START,20050603 -US-Ha1,17338,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_START,20060425 -US-Ha1,17342,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_START,20070420 -US-Ha1,17345,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_START,20080429 -US-Ha1,17348,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_START,20090511 -US-Ha1,17351,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_START,20100503 -US-Ha1,17299,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_END,19981113 -US-Ha1,17306,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_END,20000501 -US-Ha1,17312,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_END,20010601 -US-Ha1,17318,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_END,20020425 -US-Ha1,17324,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_END,20030416 -US-Ha1,17328,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_END,20040624 -US-Ha1,17331,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_END,20050603 -US-Ha1,17335,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_END,20060425 -US-Ha1,17338,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_END,20070420 -US-Ha1,17342,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_END,20080429 -US-Ha1,17345,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_END,20090511 -US-Ha1,17348,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_END,20100503 -US-Ha1,17351,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_END,20110526 -US-Ha1,17299,GRP_AG_LIT_PROD,AG_LIT_PROD_COMMENT,all spp leaf litter (leaf by spp and non leaf also available) -US-Ha1,17306,GRP_AG_LIT_PROD,AG_LIT_PROD_COMMENT,all spp leaf litter (leaf by spp and non leaf also available) -US-Ha1,17312,GRP_AG_LIT_PROD,AG_LIT_PROD_COMMENT,all spp leaf litter (leaf by spp and non leaf also available) -US-Ha1,17318,GRP_AG_LIT_PROD,AG_LIT_PROD_COMMENT,all spp leaf litter (leaf by spp and non leaf also available) -US-Ha1,17324,GRP_AG_LIT_PROD,AG_LIT_PROD_COMMENT,all spp leaf litter (leaf by spp and non leaf also available) -US-Ha1,17328,GRP_AG_LIT_PROD,AG_LIT_PROD_COMMENT,all spp leaf litter (leaf by spp and non leaf also available) -US-Ha1,17338,GRP_AG_LIT_PROD,AG_LIT_PROD_COMMENT,all spp leaf litter (leaf by spp and non leaf also available) -US-Ha1,17342,GRP_AG_LIT_PROD,AG_LIT_PROD_COMMENT,all spp leaf litter (leaf by spp and non leaf also available) -US-Ha1,17345,GRP_AG_LIT_PROD,AG_LIT_PROD_COMMENT,all spp leaf litter (leaf by spp and non leaf also available) -US-Ha1,17348,GRP_AG_LIT_PROD,AG_LIT_PROD_COMMENT,all spp leaf litter (leaf by spp and non leaf also available) -US-Ha1,17351,GRP_AG_LIT_PROD,AG_LIT_PROD_COMMENT,all spp leaf litter (leaf by spp and non leaf also available) -US-Ha1,17331,GRP_AG_LIT_PROD,AG_LIT_PROD_COMMENT,all spp leaf litter (non leaf also available) -US-Ha1,17335,GRP_AG_LIT_PROD,AG_LIT_PROD_COMMENT,all spp leaf litter (non leaf also available) -US-Ha1,17307,GRP_AG_PROD_TREE,AG_PROD_TREE,109 -US-Ha1,17307,GRP_AG_PROD_TREE,AG_PROD_TREE_SPATIAL_VARIABILITY,54 -US-Ha1,17307,GRP_AG_PROD_TREE,AG_PROD_TREE_SPATIAL_REP_NUMBER,34 -US-Ha1,17307,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Wood -US-Ha1,17307,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-Ha1,17307,GRP_AG_PROD_TREE,AG_PROD_DATE_START,19980428 -US-Ha1,17307,GRP_AG_PROD_TREE,AG_PROD_DATE_END,19981030 -US-Ha1,17313,GRP_AG_PROD_TREE,AG_PROD_TREE,131 -US-Ha1,17313,GRP_AG_PROD_TREE,AG_PROD_TREE_SPATIAL_VARIABILITY,48 -US-Ha1,17313,GRP_AG_PROD_TREE,AG_PROD_TREE_SPATIAL_REP_NUMBER,34 -US-Ha1,17313,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Wood -US-Ha1,17313,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-Ha1,17313,GRP_AG_PROD_TREE,AG_PROD_DATE_START,19981030 -US-Ha1,17313,GRP_AG_PROD_TREE,AG_PROD_DATE_END,19991027 -US-Ha1,17332,GRP_AG_PROD_TREE,AG_PROD_TREE,145 -US-Ha1,17332,GRP_AG_PROD_TREE,AG_PROD_TREE_SPATIAL_VARIABILITY,61 -US-Ha1,17332,GRP_AG_PROD_TREE,AG_PROD_TREE_SPATIAL_REP_NUMBER,34 -US-Ha1,17332,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Wood -US-Ha1,17332,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-Ha1,17332,GRP_AG_PROD_TREE,AG_PROD_DATE_START,20021114 -US-Ha1,17332,GRP_AG_PROD_TREE,AG_PROD_DATE_END,20031113 -US-Ha1,17325,GRP_AG_PROD_TREE,AG_PROD_TREE,147 -US-Ha1,17325,GRP_AG_PROD_TREE,AG_PROD_TREE_SPATIAL_VARIABILITY,62 -US-Ha1,17325,GRP_AG_PROD_TREE,AG_PROD_TREE_SPATIAL_REP_NUMBER,34 -US-Ha1,17325,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Wood -US-Ha1,17325,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-Ha1,17325,GRP_AG_PROD_TREE,AG_PROD_DATE_START,20001024 -US-Ha1,17325,GRP_AG_PROD_TREE,AG_PROD_DATE_END,20011026 -US-Ha1,17319,GRP_AG_PROD_TREE,AG_PROD_TREE,149 -US-Ha1,17319,GRP_AG_PROD_TREE,AG_PROD_TREE_SPATIAL_VARIABILITY,65 -US-Ha1,17319,GRP_AG_PROD_TREE,AG_PROD_TREE_SPATIAL_REP_NUMBER,34 -US-Ha1,17319,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Wood -US-Ha1,17319,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-Ha1,17319,GRP_AG_PROD_TREE,AG_PROD_DATE_START,19991027 -US-Ha1,17319,GRP_AG_PROD_TREE,AG_PROD_DATE_END,20001024 -US-Ha1,17336,GRP_AG_PROD_TREE,AG_PROD_TREE,164 -US-Ha1,17336,GRP_AG_PROD_TREE,AG_PROD_TREE_SPATIAL_VARIABILITY,61 -US-Ha1,17336,GRP_AG_PROD_TREE,AG_PROD_TREE_SPATIAL_REP_NUMBER,34 -US-Ha1,17336,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Wood -US-Ha1,17336,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-Ha1,17336,GRP_AG_PROD_TREE,AG_PROD_DATE_START,20031113 -US-Ha1,17336,GRP_AG_PROD_TREE,AG_PROD_DATE_END,20040113 -US-Ha1,17329,GRP_AG_PROD_TREE,AG_PROD_TREE,166 -US-Ha1,17329,GRP_AG_PROD_TREE,AG_PROD_TREE_SPATIAL_VARIABILITY,63 -US-Ha1,17329,GRP_AG_PROD_TREE,AG_PROD_TREE_SPATIAL_REP_NUMBER,34 -US-Ha1,17329,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Wood -US-Ha1,17329,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-Ha1,17329,GRP_AG_PROD_TREE,AG_PROD_DATE_START,20011026 -US-Ha1,17329,GRP_AG_PROD_TREE,AG_PROD_DATE_END,20021114 -US-Ha1,17359,GRP_AG_PROD_TREE,AG_PROD_TREE,167 -US-Ha1,17359,GRP_AG_PROD_TREE,AG_PROD_TREE_SPATIAL_VARIABILITY,79 -US-Ha1,17359,GRP_AG_PROD_TREE,AG_PROD_TREE_SPATIAL_REP_NUMBER,34 -US-Ha1,17359,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Wood -US-Ha1,17359,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-Ha1,17359,GRP_AG_PROD_TREE,AG_PROD_DATE_START,20110121 -US-Ha1,17359,GRP_AG_PROD_TREE,AG_PROD_DATE_END,20120124 -US-Ha1,17361,GRP_AG_PROD_TREE,AG_PROD_TREE,177 -US-Ha1,17361,GRP_AG_PROD_TREE,AG_PROD_TREE_SPATIAL_VARIABILITY,58 -US-Ha1,17361,GRP_AG_PROD_TREE,AG_PROD_TREE_SPATIAL_REP_NUMBER,34 -US-Ha1,17361,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Wood -US-Ha1,17361,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-Ha1,17361,GRP_AG_PROD_TREE,AG_PROD_DATE_START,20120124 -US-Ha1,17361,GRP_AG_PROD_TREE,AG_PROD_DATE_END,20131212 -US-Ha1,17343,GRP_AG_PROD_TREE,AG_PROD_TREE,181 -US-Ha1,17343,GRP_AG_PROD_TREE,AG_PROD_TREE_SPATIAL_VARIABILITY,70 -US-Ha1,17343,GRP_AG_PROD_TREE,AG_PROD_TREE_SPATIAL_REP_NUMBER,34 -US-Ha1,17343,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Wood -US-Ha1,17343,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-Ha1,17343,GRP_AG_PROD_TREE,AG_PROD_DATE_START,20050112 -US-Ha1,17343,GRP_AG_PROD_TREE,AG_PROD_DATE_END,20061114 -US-Ha1,17357,GRP_AG_PROD_TREE,AG_PROD_TREE,187 -US-Ha1,17357,GRP_AG_PROD_TREE,AG_PROD_TREE_SPATIAL_VARIABILITY,64 -US-Ha1,17357,GRP_AG_PROD_TREE,AG_PROD_TREE_SPATIAL_REP_NUMBER,34 -US-Ha1,17357,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Wood -US-Ha1,17357,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-Ha1,17357,GRP_AG_PROD_TREE,AG_PROD_DATE_START,20100127 -US-Ha1,17357,GRP_AG_PROD_TREE,AG_PROD_DATE_END,20110121 -US-Ha1,17346,GRP_AG_PROD_TREE,AG_PROD_TREE,189 -US-Ha1,17346,GRP_AG_PROD_TREE,AG_PROD_TREE_SPATIAL_VARIABILITY,70 -US-Ha1,17346,GRP_AG_PROD_TREE,AG_PROD_TREE_SPATIAL_REP_NUMBER,34 -US-Ha1,17346,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Wood -US-Ha1,17346,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-Ha1,17346,GRP_AG_PROD_TREE,AG_PROD_DATE_START,20061114 -US-Ha1,17346,GRP_AG_PROD_TREE,AG_PROD_DATE_END,20071120 -US-Ha1,17339,GRP_AG_PROD_TREE,AG_PROD_TREE,194 -US-Ha1,17339,GRP_AG_PROD_TREE,AG_PROD_TREE_SPATIAL_VARIABILITY,72 -US-Ha1,17339,GRP_AG_PROD_TREE,AG_PROD_TREE_SPATIAL_REP_NUMBER,34 -US-Ha1,17339,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Wood -US-Ha1,17339,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-Ha1,17339,GRP_AG_PROD_TREE,AG_PROD_DATE_START,20040113 -US-Ha1,17339,GRP_AG_PROD_TREE,AG_PROD_DATE_END,20050112 -US-Ha1,17352,GRP_AG_PROD_TREE,AG_PROD_TREE,203 -US-Ha1,17352,GRP_AG_PROD_TREE,AG_PROD_TREE_SPATIAL_VARIABILITY,74 -US-Ha1,17352,GRP_AG_PROD_TREE,AG_PROD_TREE_SPATIAL_REP_NUMBER,34 -US-Ha1,17352,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Wood -US-Ha1,17352,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-Ha1,17352,GRP_AG_PROD_TREE,AG_PROD_DATE_START,20081120 -US-Ha1,17352,GRP_AG_PROD_TREE,AG_PROD_DATE_END,20090121 -US-Ha1,17349,GRP_AG_PROD_TREE,AG_PROD_TREE,216 -US-Ha1,17349,GRP_AG_PROD_TREE,AG_PROD_TREE_SPATIAL_VARIABILITY,101 -US-Ha1,17349,GRP_AG_PROD_TREE,AG_PROD_TREE_SPATIAL_REP_NUMBER,34 -US-Ha1,17349,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Wood -US-Ha1,17349,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-Ha1,17349,GRP_AG_PROD_TREE,AG_PROD_DATE_START,20071120 -US-Ha1,17349,GRP_AG_PROD_TREE,AG_PROD_DATE_END,20081120 -US-Ha1,17355,GRP_AG_PROD_TREE,AG_PROD_TREE,259 -US-Ha1,17355,GRP_AG_PROD_TREE,AG_PROD_TREE_SPATIAL_VARIABILITY,141 -US-Ha1,17355,GRP_AG_PROD_TREE,AG_PROD_TREE_SPATIAL_REP_NUMBER,34 -US-Ha1,17355,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Wood -US-Ha1,17355,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-Ha1,17355,GRP_AG_PROD_TREE,AG_PROD_DATE_START,20090121 -US-Ha1,17355,GRP_AG_PROD_TREE,AG_PROD_DATE_END,20100127 -US-Ha1,17300,GRP_AG_PROD_TREE,AG_PROD_TREE,446 -US-Ha1,17300,GRP_AG_PROD_TREE,AG_PROD_TREE_SPATIAL_VARIABILITY,476 -US-Ha1,17300,GRP_AG_PROD_TREE,AG_PROD_TREE_SPATIAL_REP_NUMBER,34 -US-Ha1,17300,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Wood -US-Ha1,17300,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-Ha1,17300,GRP_AG_PROD_TREE,AG_PROD_DATE_START,1993 -US-Ha1,17300,GRP_AG_PROD_TREE,AG_PROD_DATE_END,19980428 -US-Ha1,17786,GRP_BASAL_AREA,BASAL_AREA,0.01 -US-Ha1,17786,GRP_BASAL_AREA,BASAL_AREA_SPP,Acer pennsylvanicum -US-Ha1,17786,GRP_BASAL_AREA,BASAL_AREA_DATE,20121204 -US-Ha1,17786,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17786,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,0.06 -US-Ha1,17831,GRP_BASAL_AREA,BASAL_AREA,0.01 -US-Ha1,17831,GRP_BASAL_AREA,BASAL_AREA_SPP,Acer pennsylvanicum -US-Ha1,17831,GRP_BASAL_AREA,BASAL_AREA_DATE,20131212 -US-Ha1,17831,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17831,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,0.07 -US-Ha1,17561,GRP_BASAL_AREA,BASAL_AREA,0.02 -US-Ha1,17561,GRP_BASAL_AREA,BASAL_AREA_SPP,Acer pennsylvanicum -US-Ha1,17561,GRP_BASAL_AREA,BASAL_AREA_DATE,20071120 -US-Ha1,17561,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17561,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,0.12 -US-Ha1,17606,GRP_BASAL_AREA,BASAL_AREA,0.02 -US-Ha1,17606,GRP_BASAL_AREA,BASAL_AREA_SPP,Acer pennsylvanicum -US-Ha1,17606,GRP_BASAL_AREA,BASAL_AREA_DATE,20081120 -US-Ha1,17606,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17606,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,0.13 -US-Ha1,17651,GRP_BASAL_AREA,BASAL_AREA,0.02 -US-Ha1,17651,GRP_BASAL_AREA,BASAL_AREA_SPP,Acer pennsylvanicum -US-Ha1,17651,GRP_BASAL_AREA,BASAL_AREA_DATE,20091201 -US-Ha1,17651,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17651,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,0.13 -US-Ha1,17696,GRP_BASAL_AREA,BASAL_AREA,0.02 -US-Ha1,17696,GRP_BASAL_AREA,BASAL_AREA_SPP,Acer pennsylvanicum -US-Ha1,17696,GRP_BASAL_AREA,BASAL_AREA_DATE,20101207 -US-Ha1,17696,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17696,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,0.13 -US-Ha1,17741,GRP_BASAL_AREA,BASAL_AREA,0.02 -US-Ha1,17741,GRP_BASAL_AREA,BASAL_AREA_SPP,Acer pennsylvanicum -US-Ha1,17741,GRP_BASAL_AREA,BASAL_AREA_DATE,20111201 -US-Ha1,17741,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17741,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,0.13 -US-Ha1,18291,GRP_BASAL_AREA,BASAL_AREA,0.02 -US-Ha1,18291,GRP_BASAL_AREA,BASAL_AREA_SPP,Acer pennsylvanicum -US-Ha1,18291,GRP_BASAL_AREA,BASAL_AREA_DATE,20061114 -US-Ha1,18291,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,18291,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,0.12 -US-Ha1,17498,GRP_BASAL_AREA,BASAL_AREA,0.05 -US-Ha1,17498,GRP_BASAL_AREA,BASAL_AREA_SPP,Acer pennsylvanicum -US-Ha1,17498,GRP_BASAL_AREA,BASAL_AREA_DATE,19981030 -US-Ha1,17498,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17498,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,0.23 -US-Ha1,17885,GRP_BASAL_AREA,BASAL_AREA,0.05 -US-Ha1,17885,GRP_BASAL_AREA,BASAL_AREA_SPP,Acer pennsylvanicum -US-Ha1,17885,GRP_BASAL_AREA,BASAL_AREA_DATE,19991027 -US-Ha1,17885,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17885,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,0.22 -US-Ha1,18244,GRP_BASAL_AREA,BASAL_AREA,0.05 -US-Ha1,18244,GRP_BASAL_AREA,BASAL_AREA_SPP,Acer pennsylvanicum -US-Ha1,18244,GRP_BASAL_AREA,BASAL_AREA_DATE,20051102 -US-Ha1,18244,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,18244,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,0.26 -US-Ha1,17424,GRP_BASAL_AREA,BASAL_AREA,0.06 -US-Ha1,17424,GRP_BASAL_AREA,BASAL_AREA_SPP,Acer pennsylvanicum -US-Ha1,17424,GRP_BASAL_AREA,BASAL_AREA_DATE,1993 -US-Ha1,17424,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17424,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,0.29 -US-Ha1,17945,GRP_BASAL_AREA,BASAL_AREA,0.06 -US-Ha1,17945,GRP_BASAL_AREA,BASAL_AREA_SPP,Acer pennsylvanicum -US-Ha1,17945,GRP_BASAL_AREA,BASAL_AREA_DATE,20001024 -US-Ha1,17945,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17945,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,0.32 -US-Ha1,18184,GRP_BASAL_AREA,BASAL_AREA,0.06 -US-Ha1,18184,GRP_BASAL_AREA,BASAL_AREA_SPP,Acer pennsylvanicum -US-Ha1,18184,GRP_BASAL_AREA,BASAL_AREA_DATE,20041103 -US-Ha1,18184,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,18184,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,0.34 -US-Ha1,18004,GRP_BASAL_AREA,BASAL_AREA,0.07 -US-Ha1,18004,GRP_BASAL_AREA,BASAL_AREA_SPP,Acer pennsylvanicum -US-Ha1,18004,GRP_BASAL_AREA,BASAL_AREA_DATE,20011026 -US-Ha1,18004,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,18004,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,0.33 -US-Ha1,18064,GRP_BASAL_AREA,BASAL_AREA,0.07 -US-Ha1,18064,GRP_BASAL_AREA,BASAL_AREA_SPP,Acer pennsylvanicum -US-Ha1,18064,GRP_BASAL_AREA,BASAL_AREA_DATE,20021114 -US-Ha1,18064,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,18064,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,0.33 -US-Ha1,18124,GRP_BASAL_AREA,BASAL_AREA,0.07 -US-Ha1,18124,GRP_BASAL_AREA,BASAL_AREA_SPP,Acer pennsylvanicum -US-Ha1,18124,GRP_BASAL_AREA,BASAL_AREA_DATE,20031113 -US-Ha1,18124,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,18124,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,0.34 -US-Ha1,17681,GRP_BASAL_AREA,BASAL_AREA,0.15 -US-Ha1,17681,GRP_BASAL_AREA,BASAL_AREA_SPP,Betula populifolia -US-Ha1,17681,GRP_BASAL_AREA,BASAL_AREA_DATE,20101207 -US-Ha1,17681,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17681,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,0.73 -US-Ha1,17726,GRP_BASAL_AREA,BASAL_AREA,0.15 -US-Ha1,17726,GRP_BASAL_AREA,BASAL_AREA_SPP,Betula populifolia -US-Ha1,17726,GRP_BASAL_AREA,BASAL_AREA_DATE,20111201 -US-Ha1,17726,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17726,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,0.73 -US-Ha1,17771,GRP_BASAL_AREA,BASAL_AREA,0.15 -US-Ha1,17771,GRP_BASAL_AREA,BASAL_AREA_SPP,Betula populifolia -US-Ha1,17771,GRP_BASAL_AREA,BASAL_AREA_DATE,20121204 -US-Ha1,17771,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17771,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,0.73 -US-Ha1,17816,GRP_BASAL_AREA,BASAL_AREA,0.15 -US-Ha1,17816,GRP_BASAL_AREA,BASAL_AREA_SPP,Betula populifolia -US-Ha1,17816,GRP_BASAL_AREA,BASAL_AREA_DATE,20131212 -US-Ha1,17816,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17816,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,0.75 -US-Ha1,18248,GRP_BASAL_AREA,BASAL_AREA,0.17 -US-Ha1,18248,GRP_BASAL_AREA,BASAL_AREA_SPP,Betula papyrifera -US-Ha1,18248,GRP_BASAL_AREA,BASAL_AREA_DATE,20051102 -US-Ha1,18248,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,18248,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,0.69 -US-Ha1,17519,GRP_BASAL_AREA,BASAL_AREA,0.18 -US-Ha1,17519,GRP_BASAL_AREA,BASAL_AREA_SPP,Betula papyrifera -US-Ha1,17519,GRP_BASAL_AREA,BASAL_AREA_DATE,20061114 -US-Ha1,17519,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17519,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,0.72 -US-Ha1,17546,GRP_BASAL_AREA,BASAL_AREA,0.18 -US-Ha1,17546,GRP_BASAL_AREA,BASAL_AREA_SPP,Betula populifolia -US-Ha1,17546,GRP_BASAL_AREA,BASAL_AREA_DATE,20071120 -US-Ha1,17546,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17546,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,0.92 -US-Ha1,17564,GRP_BASAL_AREA,BASAL_AREA,0.18 -US-Ha1,17564,GRP_BASAL_AREA,BASAL_AREA_SPP,Betula papyrifera -US-Ha1,17564,GRP_BASAL_AREA,BASAL_AREA_DATE,20071120 -US-Ha1,17564,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17564,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,0.72 -US-Ha1,17591,GRP_BASAL_AREA,BASAL_AREA,0.18 -US-Ha1,17591,GRP_BASAL_AREA,BASAL_AREA_SPP,Betula populifolia -US-Ha1,17591,GRP_BASAL_AREA,BASAL_AREA_DATE,20081120 -US-Ha1,17591,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17591,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,0.93 -US-Ha1,17609,GRP_BASAL_AREA,BASAL_AREA,0.18 -US-Ha1,17609,GRP_BASAL_AREA,BASAL_AREA_SPP,Betula papyrifera -US-Ha1,17609,GRP_BASAL_AREA,BASAL_AREA_DATE,20081120 -US-Ha1,17609,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17609,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,0.72 -US-Ha1,17636,GRP_BASAL_AREA,BASAL_AREA,0.18 -US-Ha1,17636,GRP_BASAL_AREA,BASAL_AREA_SPP,Betula populifolia -US-Ha1,17636,GRP_BASAL_AREA,BASAL_AREA_DATE,20091201 -US-Ha1,17636,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17636,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,0.94 -US-Ha1,17654,GRP_BASAL_AREA,BASAL_AREA,0.18 -US-Ha1,17654,GRP_BASAL_AREA,BASAL_AREA_SPP,Betula papyrifera -US-Ha1,17654,GRP_BASAL_AREA,BASAL_AREA_DATE,20091201 -US-Ha1,17654,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17654,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,0.73 -US-Ha1,17699,GRP_BASAL_AREA,BASAL_AREA,0.18 -US-Ha1,17699,GRP_BASAL_AREA,BASAL_AREA_SPP,Betula papyrifera -US-Ha1,17699,GRP_BASAL_AREA,BASAL_AREA_DATE,20101207 -US-Ha1,17699,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17699,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,0.73 -US-Ha1,17744,GRP_BASAL_AREA,BASAL_AREA,0.18 -US-Ha1,17744,GRP_BASAL_AREA,BASAL_AREA_SPP,Betula papyrifera -US-Ha1,17744,GRP_BASAL_AREA,BASAL_AREA_DATE,20111201 -US-Ha1,17744,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17744,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,0.74 -US-Ha1,17789,GRP_BASAL_AREA,BASAL_AREA,0.18 -US-Ha1,17789,GRP_BASAL_AREA,BASAL_AREA_SPP,Betula papyrifera -US-Ha1,17789,GRP_BASAL_AREA,BASAL_AREA_DATE,20121204 -US-Ha1,17789,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17789,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,0.74 -US-Ha1,17834,GRP_BASAL_AREA,BASAL_AREA,0.18 -US-Ha1,17834,GRP_BASAL_AREA,BASAL_AREA_SPP,Betula papyrifera -US-Ha1,17834,GRP_BASAL_AREA,BASAL_AREA_DATE,20131212 -US-Ha1,17834,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17834,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,0.75 -US-Ha1,17853,GRP_BASAL_AREA,BASAL_AREA,0.2 -US-Ha1,17853,GRP_BASAL_AREA,BASAL_AREA_SPP,Fagus grandifolia -US-Ha1,17853,GRP_BASAL_AREA,BASAL_AREA_DATE,19991027 -US-Ha1,17853,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17853,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,0.5 -US-Ha1,17913,GRP_BASAL_AREA,BASAL_AREA,0.2 -US-Ha1,17913,GRP_BASAL_AREA,BASAL_AREA_SPP,Fagus grandifolia -US-Ha1,17913,GRP_BASAL_AREA,BASAL_AREA_DATE,20001024 -US-Ha1,17913,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17913,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,0.51 -US-Ha1,17972,GRP_BASAL_AREA,BASAL_AREA,0.21 -US-Ha1,17972,GRP_BASAL_AREA,BASAL_AREA_SPP,Fagus grandifolia -US-Ha1,17972,GRP_BASAL_AREA,BASAL_AREA_DATE,20011026 -US-Ha1,17972,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17972,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,0.53 -US-Ha1,18032,GRP_BASAL_AREA,BASAL_AREA,0.22 -US-Ha1,18032,GRP_BASAL_AREA,BASAL_AREA_SPP,Fagus grandifolia -US-Ha1,18032,GRP_BASAL_AREA,BASAL_AREA_DATE,20021114 -US-Ha1,18032,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,18032,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,0.55 -US-Ha1,18092,GRP_BASAL_AREA,BASAL_AREA,0.22 -US-Ha1,18092,GRP_BASAL_AREA,BASAL_AREA_SPP,Fagus grandifolia -US-Ha1,18092,GRP_BASAL_AREA,BASAL_AREA_DATE,20031113 -US-Ha1,18092,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,18092,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,0.55 -US-Ha1,18188,GRP_BASAL_AREA,BASAL_AREA,0.23 -US-Ha1,18188,GRP_BASAL_AREA,BASAL_AREA_SPP,Betula papyrifera -US-Ha1,18188,GRP_BASAL_AREA,BASAL_AREA_DATE,20041103 -US-Ha1,18188,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,18188,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,0.75 -US-Ha1,18164,GRP_BASAL_AREA,BASAL_AREA,0.24 -US-Ha1,18164,GRP_BASAL_AREA,BASAL_AREA_SPP,Betula populifolia -US-Ha1,18164,GRP_BASAL_AREA,BASAL_AREA_DATE,20041103 -US-Ha1,18164,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,18164,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,1.25 -US-Ha1,18224,GRP_BASAL_AREA,BASAL_AREA,0.24 -US-Ha1,18224,GRP_BASAL_AREA,BASAL_AREA_SPP,Betula populifolia -US-Ha1,18224,GRP_BASAL_AREA,BASAL_AREA_DATE,20051102 -US-Ha1,18224,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,18224,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,1.26 -US-Ha1,18276,GRP_BASAL_AREA,BASAL_AREA,0.24 -US-Ha1,18276,GRP_BASAL_AREA,BASAL_AREA_SPP,Betula populifolia -US-Ha1,18276,GRP_BASAL_AREA,BASAL_AREA_DATE,20061114 -US-Ha1,18276,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,18276,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,1.27 -US-Ha1,18152,GRP_BASAL_AREA,BASAL_AREA,0.25 -US-Ha1,18152,GRP_BASAL_AREA,BASAL_AREA_SPP,Fagus grandifolia -US-Ha1,18152,GRP_BASAL_AREA,BASAL_AREA_DATE,20041103 -US-Ha1,18152,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,18152,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,0.6 -US-Ha1,17865,GRP_BASAL_AREA,BASAL_AREA,0.27 -US-Ha1,17865,GRP_BASAL_AREA,BASAL_AREA_SPP,Betula populifolia -US-Ha1,17865,GRP_BASAL_AREA,BASAL_AREA_DATE,19991027 -US-Ha1,17865,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17865,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,1.45 -US-Ha1,17925,GRP_BASAL_AREA,BASAL_AREA,0.27 -US-Ha1,17925,GRP_BASAL_AREA,BASAL_AREA_SPP,Betula populifolia -US-Ha1,17925,GRP_BASAL_AREA,BASAL_AREA_DATE,20001024 -US-Ha1,17925,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17925,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,1.46 -US-Ha1,17984,GRP_BASAL_AREA,BASAL_AREA,0.27 -US-Ha1,17984,GRP_BASAL_AREA,BASAL_AREA_SPP,Betula populifolia -US-Ha1,17984,GRP_BASAL_AREA,BASAL_AREA_DATE,20011026 -US-Ha1,17984,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17984,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,1.46 -US-Ha1,18128,GRP_BASAL_AREA,BASAL_AREA,0.27 -US-Ha1,18128,GRP_BASAL_AREA,BASAL_AREA_SPP,Betula papyrifera -US-Ha1,18128,GRP_BASAL_AREA,BASAL_AREA_DATE,20031113 -US-Ha1,18128,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,18128,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,0.75 -US-Ha1,18212,GRP_BASAL_AREA,BASAL_AREA,0.27 -US-Ha1,18212,GRP_BASAL_AREA,BASAL_AREA_SPP,Fagus grandifolia -US-Ha1,18212,GRP_BASAL_AREA,BASAL_AREA_DATE,20051102 -US-Ha1,18212,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,18212,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,0.61 -US-Ha1,18044,GRP_BASAL_AREA,BASAL_AREA,0.28 -US-Ha1,18044,GRP_BASAL_AREA,BASAL_AREA_SPP,Betula populifolia -US-Ha1,18044,GRP_BASAL_AREA,BASAL_AREA_DATE,20021114 -US-Ha1,18044,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,18044,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,1.49 -US-Ha1,18068,GRP_BASAL_AREA,BASAL_AREA,0.28 -US-Ha1,18068,GRP_BASAL_AREA,BASAL_AREA_SPP,Betula papyrifera -US-Ha1,18068,GRP_BASAL_AREA,BASAL_AREA_DATE,20021114 -US-Ha1,18068,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,18068,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,0.76 -US-Ha1,18104,GRP_BASAL_AREA,BASAL_AREA,0.28 -US-Ha1,18104,GRP_BASAL_AREA,BASAL_AREA_SPP,Betula populifolia -US-Ha1,18104,GRP_BASAL_AREA,BASAL_AREA_DATE,20031113 -US-Ha1,18104,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,18104,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,1.5 -US-Ha1,18267,GRP_BASAL_AREA,BASAL_AREA,0.28 -US-Ha1,18267,GRP_BASAL_AREA,BASAL_AREA_SPP,Fagus grandifolia -US-Ha1,18267,GRP_BASAL_AREA,BASAL_AREA_DATE,20061114 -US-Ha1,18267,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,18267,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,0.62 -US-Ha1,17502,GRP_BASAL_AREA,BASAL_AREA,0.29 -US-Ha1,17502,GRP_BASAL_AREA,BASAL_AREA_SPP,Betula papyrifera -US-Ha1,17502,GRP_BASAL_AREA,BASAL_AREA_DATE,19981030 -US-Ha1,17502,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17502,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,0.74 -US-Ha1,17889,GRP_BASAL_AREA,BASAL_AREA,0.29 -US-Ha1,17889,GRP_BASAL_AREA,BASAL_AREA_SPP,Betula papyrifera -US-Ha1,17889,GRP_BASAL_AREA,BASAL_AREA_DATE,19991027 -US-Ha1,17889,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17889,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,0.74 -US-Ha1,17949,GRP_BASAL_AREA,BASAL_AREA,0.29 -US-Ha1,17949,GRP_BASAL_AREA,BASAL_AREA_SPP,Betula papyrifera -US-Ha1,17949,GRP_BASAL_AREA,BASAL_AREA_DATE,20001024 -US-Ha1,17949,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17949,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,0.74 -US-Ha1,18008,GRP_BASAL_AREA,BASAL_AREA,0.3 -US-Ha1,18008,GRP_BASAL_AREA,BASAL_AREA_SPP,Betula papyrifera -US-Ha1,18008,GRP_BASAL_AREA,BASAL_AREA_DATE,20011026 -US-Ha1,18008,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,18008,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,0.75 -US-Ha1,17376,GRP_BASAL_AREA,BASAL_AREA,0.31 -US-Ha1,17376,GRP_BASAL_AREA,BASAL_AREA_SPP,Fagus grandifolia -US-Ha1,17376,GRP_BASAL_AREA,BASAL_AREA_DATE,1993 -US-Ha1,17376,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17376,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,1.04 -US-Ha1,17430,GRP_BASAL_AREA,BASAL_AREA,0.31 -US-Ha1,17430,GRP_BASAL_AREA,BASAL_AREA_SPP,Betula papyrifera -US-Ha1,17430,GRP_BASAL_AREA,BASAL_AREA_DATE,1993 -US-Ha1,17430,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17430,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,0.82 -US-Ha1,17537,GRP_BASAL_AREA,BASAL_AREA,0.31 -US-Ha1,17537,GRP_BASAL_AREA,BASAL_AREA_SPP,Fagus grandifolia -US-Ha1,17537,GRP_BASAL_AREA,BASAL_AREA_DATE,20071120 -US-Ha1,17537,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17537,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,0.64 -US-Ha1,17582,GRP_BASAL_AREA,BASAL_AREA,0.32 -US-Ha1,17582,GRP_BASAL_AREA,BASAL_AREA_SPP,Fagus grandifolia -US-Ha1,17582,GRP_BASAL_AREA,BASAL_AREA_DATE,20081120 -US-Ha1,17582,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17582,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,0.65 -US-Ha1,17627,GRP_BASAL_AREA,BASAL_AREA,0.34 -US-Ha1,17627,GRP_BASAL_AREA,BASAL_AREA_SPP,Fagus grandifolia -US-Ha1,17627,GRP_BASAL_AREA,BASAL_AREA_DATE,20091201 -US-Ha1,17627,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17627,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,0.66 -US-Ha1,17464,GRP_BASAL_AREA,BASAL_AREA,0.36 -US-Ha1,17464,GRP_BASAL_AREA,BASAL_AREA_SPP,Fagus grandifolia -US-Ha1,17464,GRP_BASAL_AREA,BASAL_AREA_DATE,19981030 -US-Ha1,17464,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17464,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,1.1 -US-Ha1,17672,GRP_BASAL_AREA,BASAL_AREA,0.36 -US-Ha1,17672,GRP_BASAL_AREA,BASAL_AREA_SPP,Fagus grandifolia -US-Ha1,17672,GRP_BASAL_AREA,BASAL_AREA_DATE,20101207 -US-Ha1,17672,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17672,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,0.68 -US-Ha1,17762,GRP_BASAL_AREA,BASAL_AREA,0.36 -US-Ha1,17762,GRP_BASAL_AREA,BASAL_AREA_SPP,Fagus grandifolia -US-Ha1,17762,GRP_BASAL_AREA,BASAL_AREA_DATE,20121204 -US-Ha1,17762,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17762,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,0.69 -US-Ha1,17840,GRP_BASAL_AREA,BASAL_AREA,0.36 -US-Ha1,17840,GRP_BASAL_AREA,BASAL_AREA_SPP,Picea glauca -US-Ha1,17840,GRP_BASAL_AREA,BASAL_AREA_DATE,20131212 -US-Ha1,17840,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17840,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,1.26 -US-Ha1,17807,GRP_BASAL_AREA,BASAL_AREA,0.37 -US-Ha1,17807,GRP_BASAL_AREA,BASAL_AREA_SPP,Fagus grandifolia -US-Ha1,17807,GRP_BASAL_AREA,BASAL_AREA_DATE,20131212 -US-Ha1,17807,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17807,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,0.72 -US-Ha1,17909,GRP_BASAL_AREA,BASAL_AREA,0.37 -US-Ha1,17909,GRP_BASAL_AREA,BASAL_AREA_SPP,Betula lenta -US-Ha1,17909,GRP_BASAL_AREA,BASAL_AREA_DATE,20001024 -US-Ha1,17909,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17909,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,1.07 -US-Ha1,17795,GRP_BASAL_AREA,BASAL_AREA,0.38 -US-Ha1,17795,GRP_BASAL_AREA,BASAL_AREA_SPP,Picea glauca -US-Ha1,17795,GRP_BASAL_AREA,BASAL_AREA_DATE,20121204 -US-Ha1,17795,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17795,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,1.36 -US-Ha1,17968,GRP_BASAL_AREA,BASAL_AREA,0.38 -US-Ha1,17968,GRP_BASAL_AREA,BASAL_AREA_SPP,Betula lenta -US-Ha1,17968,GRP_BASAL_AREA,BASAL_AREA_DATE,20011026 -US-Ha1,17968,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17968,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,1.09 -US-Ha1,18028,GRP_BASAL_AREA,BASAL_AREA,0.38 -US-Ha1,18028,GRP_BASAL_AREA,BASAL_AREA_SPP,Betula lenta -US-Ha1,18028,GRP_BASAL_AREA,BASAL_AREA_DATE,20021114 -US-Ha1,18028,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,18028,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,1.09 -US-Ha1,17478,GRP_BASAL_AREA,BASAL_AREA,0.39 -US-Ha1,17478,GRP_BASAL_AREA,BASAL_AREA_SPP,Betula populifolia -US-Ha1,17478,GRP_BASAL_AREA,BASAL_AREA_DATE,19981030 -US-Ha1,17478,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17478,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,1.54 -US-Ha1,17717,GRP_BASAL_AREA,BASAL_AREA,0.39 -US-Ha1,17717,GRP_BASAL_AREA,BASAL_AREA_SPP,Fagus grandifolia -US-Ha1,17717,GRP_BASAL_AREA,BASAL_AREA_DATE,20111201 -US-Ha1,17717,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17717,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,0.7 -US-Ha1,17849,GRP_BASAL_AREA,BASAL_AREA,0.39 -US-Ha1,17849,GRP_BASAL_AREA,BASAL_AREA_SPP,Betula lenta -US-Ha1,17849,GRP_BASAL_AREA,BASAL_AREA_DATE,19991027 -US-Ha1,17849,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17849,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,1.07 -US-Ha1,18088,GRP_BASAL_AREA,BASAL_AREA,0.39 -US-Ha1,18088,GRP_BASAL_AREA,BASAL_AREA_SPP,Betula lenta -US-Ha1,18088,GRP_BASAL_AREA,BASAL_AREA_DATE,20031113 -US-Ha1,18088,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,18088,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,1.11 -US-Ha1,18148,GRP_BASAL_AREA,BASAL_AREA,0.41 -US-Ha1,18148,GRP_BASAL_AREA,BASAL_AREA_SPP,Betula lenta -US-Ha1,18148,GRP_BASAL_AREA,BASAL_AREA_DATE,20041103 -US-Ha1,18148,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,18148,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,1.15 -US-Ha1,18208,GRP_BASAL_AREA,BASAL_AREA,0.42 -US-Ha1,18208,GRP_BASAL_AREA,BASAL_AREA_SPP,Betula lenta -US-Ha1,18208,GRP_BASAL_AREA,BASAL_AREA_DATE,20051102 -US-Ha1,18208,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,18208,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,1.16 -US-Ha1,18264,GRP_BASAL_AREA,BASAL_AREA,0.42 -US-Ha1,18264,GRP_BASAL_AREA,BASAL_AREA_SPP,Betula lenta -US-Ha1,18264,GRP_BASAL_AREA,BASAL_AREA_DATE,20061114 -US-Ha1,18264,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,18264,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,1.16 -US-Ha1,17370,GRP_BASAL_AREA,BASAL_AREA,0.43 -US-Ha1,17370,GRP_BASAL_AREA,BASAL_AREA_SPP,Betula lenta -US-Ha1,17370,GRP_BASAL_AREA,BASAL_AREA_DATE,1993 -US-Ha1,17370,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17370,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,1.05 -US-Ha1,17534,GRP_BASAL_AREA,BASAL_AREA,0.44 -US-Ha1,17534,GRP_BASAL_AREA,BASAL_AREA_SPP,Betula lenta -US-Ha1,17534,GRP_BASAL_AREA,BASAL_AREA_DATE,20071120 -US-Ha1,17534,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17534,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,1.16 -US-Ha1,17579,GRP_BASAL_AREA,BASAL_AREA,0.45 -US-Ha1,17579,GRP_BASAL_AREA,BASAL_AREA_SPP,Betula lenta -US-Ha1,17579,GRP_BASAL_AREA,BASAL_AREA_DATE,20081120 -US-Ha1,17579,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17579,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,1.17 -US-Ha1,17624,GRP_BASAL_AREA,BASAL_AREA,0.45 -US-Ha1,17624,GRP_BASAL_AREA,BASAL_AREA_SPP,Betula lenta -US-Ha1,17624,GRP_BASAL_AREA,BASAL_AREA_DATE,20091201 -US-Ha1,17624,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17624,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,1.18 -US-Ha1,17669,GRP_BASAL_AREA,BASAL_AREA,0.46 -US-Ha1,17669,GRP_BASAL_AREA,BASAL_AREA_SPP,Betula lenta -US-Ha1,17669,GRP_BASAL_AREA,BASAL_AREA_DATE,20101207 -US-Ha1,17669,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17669,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,1.19 -US-Ha1,17459,GRP_BASAL_AREA,BASAL_AREA,0.47 -US-Ha1,17459,GRP_BASAL_AREA,BASAL_AREA_SPP,Betula lenta -US-Ha1,17459,GRP_BASAL_AREA,BASAL_AREA_DATE,19981030 -US-Ha1,17459,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17459,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,1.1 -US-Ha1,17714,GRP_BASAL_AREA,BASAL_AREA,0.48 -US-Ha1,17714,GRP_BASAL_AREA,BASAL_AREA_SPP,Betula lenta -US-Ha1,17714,GRP_BASAL_AREA,BASAL_AREA_DATE,20111201 -US-Ha1,17714,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17714,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,1.22 -US-Ha1,17759,GRP_BASAL_AREA,BASAL_AREA,0.48 -US-Ha1,17759,GRP_BASAL_AREA,BASAL_AREA_SPP,Betula lenta -US-Ha1,17759,GRP_BASAL_AREA,BASAL_AREA_DATE,20121204 -US-Ha1,17759,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17759,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,1.22 -US-Ha1,17394,GRP_BASAL_AREA,BASAL_AREA,0.51 -US-Ha1,17394,GRP_BASAL_AREA,BASAL_AREA_SPP,Betula populifolia -US-Ha1,17394,GRP_BASAL_AREA,BASAL_AREA_DATE,1993 -US-Ha1,17394,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17394,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,1.59 -US-Ha1,17804,GRP_BASAL_AREA,BASAL_AREA,0.52 -US-Ha1,17804,GRP_BASAL_AREA,BASAL_AREA_SPP,Betula lenta -US-Ha1,17804,GRP_BASAL_AREA,BASAL_AREA_DATE,20131212 -US-Ha1,17804,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17804,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,1.29 -US-Ha1,17750,GRP_BASAL_AREA,BASAL_AREA,0.53 -US-Ha1,17750,GRP_BASAL_AREA,BASAL_AREA_SPP,Picea glauca -US-Ha1,17750,GRP_BASAL_AREA,BASAL_AREA_DATE,20111201 -US-Ha1,17750,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17750,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,1.89 -US-Ha1,17705,GRP_BASAL_AREA,BASAL_AREA,0.56 -US-Ha1,17705,GRP_BASAL_AREA,BASAL_AREA_SPP,Picea glauca -US-Ha1,17705,GRP_BASAL_AREA,BASAL_AREA_DATE,20101207 -US-Ha1,17705,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17705,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,1.98 -US-Ha1,17660,GRP_BASAL_AREA,BASAL_AREA,0.62 -US-Ha1,17660,GRP_BASAL_AREA,BASAL_AREA_SPP,Picea glauca -US-Ha1,17660,GRP_BASAL_AREA,BASAL_AREA_DATE,20091201 -US-Ha1,17660,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17660,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,2 -US-Ha1,17525,GRP_BASAL_AREA,BASAL_AREA,0.66 -US-Ha1,17525,GRP_BASAL_AREA,BASAL_AREA_SPP,Picea glauca -US-Ha1,17525,GRP_BASAL_AREA,BASAL_AREA_DATE,20061114 -US-Ha1,17525,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17525,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,2.17 -US-Ha1,17570,GRP_BASAL_AREA,BASAL_AREA,0.67 -US-Ha1,17570,GRP_BASAL_AREA,BASAL_AREA_SPP,Picea glauca -US-Ha1,17570,GRP_BASAL_AREA,BASAL_AREA_DATE,20071120 -US-Ha1,17570,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17570,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,2.17 -US-Ha1,17615,GRP_BASAL_AREA,BASAL_AREA,0.67 -US-Ha1,17615,GRP_BASAL_AREA,BASAL_AREA_SPP,Picea glauca -US-Ha1,17615,GRP_BASAL_AREA,BASAL_AREA_DATE,20081120 -US-Ha1,17615,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17615,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,2.18 -US-Ha1,17897,GRP_BASAL_AREA,BASAL_AREA,0.67 -US-Ha1,17897,GRP_BASAL_AREA,BASAL_AREA_SPP,Picea glauca -US-Ha1,17897,GRP_BASAL_AREA,BASAL_AREA_DATE,19991027 -US-Ha1,17897,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17897,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,2.21 -US-Ha1,17956,GRP_BASAL_AREA,BASAL_AREA,0.67 -US-Ha1,17956,GRP_BASAL_AREA,BASAL_AREA_SPP,Picea glauca -US-Ha1,17956,GRP_BASAL_AREA,BASAL_AREA_DATE,20001024 -US-Ha1,17956,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17956,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,2.21 -US-Ha1,18016,GRP_BASAL_AREA,BASAL_AREA,0.68 -US-Ha1,18016,GRP_BASAL_AREA,BASAL_AREA_SPP,Picea glauca -US-Ha1,18016,GRP_BASAL_AREA,BASAL_AREA_DATE,20011026 -US-Ha1,18016,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,18016,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,2.25 -US-Ha1,18076,GRP_BASAL_AREA,BASAL_AREA,0.68 -US-Ha1,18076,GRP_BASAL_AREA,BASAL_AREA_SPP,Picea glauca -US-Ha1,18076,GRP_BASAL_AREA,BASAL_AREA_DATE,20021114 -US-Ha1,18076,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,18076,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,2.24 -US-Ha1,18136,GRP_BASAL_AREA,BASAL_AREA,0.68 -US-Ha1,18136,GRP_BASAL_AREA,BASAL_AREA_SPP,Picea glauca -US-Ha1,18136,GRP_BASAL_AREA,BASAL_AREA_DATE,20031113 -US-Ha1,18136,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,18136,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,2.23 -US-Ha1,18196,GRP_BASAL_AREA,BASAL_AREA,0.68 -US-Ha1,18196,GRP_BASAL_AREA,BASAL_AREA_SPP,Picea glauca -US-Ha1,18196,GRP_BASAL_AREA,BASAL_AREA_DATE,20041103 -US-Ha1,18196,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,18196,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,2.24 -US-Ha1,18255,GRP_BASAL_AREA,BASAL_AREA,0.68 -US-Ha1,18255,GRP_BASAL_AREA,BASAL_AREA_SPP,Picea glauca -US-Ha1,18255,GRP_BASAL_AREA,BASAL_AREA_DATE,20051102 -US-Ha1,18255,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,18255,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,2.25 -US-Ha1,17510,GRP_BASAL_AREA,BASAL_AREA,0.71 -US-Ha1,17510,GRP_BASAL_AREA,BASAL_AREA_SPP,Picea glauca -US-Ha1,17510,GRP_BASAL_AREA,BASAL_AREA_DATE,19981030 -US-Ha1,17510,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17510,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,2.39 -US-Ha1,17442,GRP_BASAL_AREA,BASAL_AREA,0.75 -US-Ha1,17442,GRP_BASAL_AREA,BASAL_AREA_SPP,Picea glauca -US-Ha1,17442,GRP_BASAL_AREA,BASAL_AREA_DATE,1993 -US-Ha1,17442,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17442,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,2.49 -US-Ha1,17362,GRP_BASAL_AREA,BASAL_AREA,0.81 -US-Ha1,17362,GRP_BASAL_AREA,BASAL_AREA_SPP,Fraxinus americana -US-Ha1,17362,GRP_BASAL_AREA,BASAL_AREA_DATE,1993 -US-Ha1,17362,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17362,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,3.16 -US-Ha1,17518,GRP_BASAL_AREA,BASAL_AREA,0.83 -US-Ha1,17518,GRP_BASAL_AREA,BASAL_AREA_SPP,Fraxinus americana -US-Ha1,17518,GRP_BASAL_AREA,BASAL_AREA_DATE,19991027 -US-Ha1,17518,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17518,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,3.33 -US-Ha1,18204,GRP_BASAL_AREA,BASAL_AREA,0.83 -US-Ha1,18204,GRP_BASAL_AREA,BASAL_AREA_SPP,Fraxinus americana -US-Ha1,18204,GRP_BASAL_AREA,BASAL_AREA_DATE,20051102 -US-Ha1,18204,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,18204,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,3.09 -US-Ha1,18261,GRP_BASAL_AREA,BASAL_AREA,0.84 -US-Ha1,18261,GRP_BASAL_AREA,BASAL_AREA_SPP,Fraxinus americana -US-Ha1,18261,GRP_BASAL_AREA,BASAL_AREA_DATE,20061114 -US-Ha1,18261,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,18261,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,3.14 -US-Ha1,17454,GRP_BASAL_AREA,BASAL_AREA,0.85 -US-Ha1,17454,GRP_BASAL_AREA,BASAL_AREA_SPP,Fraxinus americana -US-Ha1,17454,GRP_BASAL_AREA,BASAL_AREA_DATE,19981030 -US-Ha1,17454,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17454,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,3.3 -US-Ha1,17531,GRP_BASAL_AREA,BASAL_AREA,0.85 -US-Ha1,17531,GRP_BASAL_AREA,BASAL_AREA_SPP,Fraxinus americana -US-Ha1,17531,GRP_BASAL_AREA,BASAL_AREA_DATE,20071120 -US-Ha1,17531,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17531,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,3.17 -US-Ha1,17666,GRP_BASAL_AREA,BASAL_AREA,0.85 -US-Ha1,17666,GRP_BASAL_AREA,BASAL_AREA_SPP,Fraxinus americana -US-Ha1,17666,GRP_BASAL_AREA,BASAL_AREA_DATE,20101207 -US-Ha1,17666,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17666,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,3.2 -US-Ha1,17905,GRP_BASAL_AREA,BASAL_AREA,0.85 -US-Ha1,17905,GRP_BASAL_AREA,BASAL_AREA_SPP,Fraxinus americana -US-Ha1,17905,GRP_BASAL_AREA,BASAL_AREA_DATE,20001024 -US-Ha1,17905,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17905,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,3.35 -US-Ha1,17576,GRP_BASAL_AREA,BASAL_AREA,0.86 -US-Ha1,17576,GRP_BASAL_AREA,BASAL_AREA_SPP,Fraxinus americana -US-Ha1,17576,GRP_BASAL_AREA,BASAL_AREA_DATE,20081120 -US-Ha1,17576,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17576,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,3.2 -US-Ha1,17621,GRP_BASAL_AREA,BASAL_AREA,0.87 -US-Ha1,17621,GRP_BASAL_AREA,BASAL_AREA_SPP,Fraxinus americana -US-Ha1,17621,GRP_BASAL_AREA,BASAL_AREA_DATE,20091201 -US-Ha1,17621,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17621,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,3.23 -US-Ha1,17711,GRP_BASAL_AREA,BASAL_AREA,0.87 -US-Ha1,17711,GRP_BASAL_AREA,BASAL_AREA_SPP,Fraxinus americana -US-Ha1,17711,GRP_BASAL_AREA,BASAL_AREA_DATE,20111201 -US-Ha1,17711,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17711,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,3.25 -US-Ha1,17756,GRP_BASAL_AREA,BASAL_AREA,0.87 -US-Ha1,17756,GRP_BASAL_AREA,BASAL_AREA_SPP,Fraxinus americana -US-Ha1,17756,GRP_BASAL_AREA,BASAL_AREA_DATE,20121204 -US-Ha1,17756,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17756,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,3.25 -US-Ha1,17964,GRP_BASAL_AREA,BASAL_AREA,0.88 -US-Ha1,17964,GRP_BASAL_AREA,BASAL_AREA_SPP,Fraxinus americana -US-Ha1,17964,GRP_BASAL_AREA,BASAL_AREA_DATE,20011026 -US-Ha1,17964,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17964,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,3.4 -US-Ha1,18024,GRP_BASAL_AREA,BASAL_AREA,0.88 -US-Ha1,18024,GRP_BASAL_AREA,BASAL_AREA_SPP,Fraxinus americana -US-Ha1,18024,GRP_BASAL_AREA,BASAL_AREA_DATE,20021114 -US-Ha1,18024,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,18024,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,3.42 -US-Ha1,17678,GRP_BASAL_AREA,BASAL_AREA,0.89 -US-Ha1,17678,GRP_BASAL_AREA,BASAL_AREA_SPP,Prunus serotina -US-Ha1,17678,GRP_BASAL_AREA,BASAL_AREA_DATE,20101207 -US-Ha1,17678,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17678,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,2.59 -US-Ha1,17801,GRP_BASAL_AREA,BASAL_AREA,0.89 -US-Ha1,17801,GRP_BASAL_AREA,BASAL_AREA_SPP,Fraxinus americana -US-Ha1,17801,GRP_BASAL_AREA,BASAL_AREA_DATE,20131212 -US-Ha1,17801,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17801,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,3.31 -US-Ha1,18084,GRP_BASAL_AREA,BASAL_AREA,0.89 -US-Ha1,18084,GRP_BASAL_AREA,BASAL_AREA_SPP,Fraxinus americana -US-Ha1,18084,GRP_BASAL_AREA,BASAL_AREA_DATE,20031113 -US-Ha1,18084,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,18084,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,3.45 -US-Ha1,17723,GRP_BASAL_AREA,BASAL_AREA,0.9 -US-Ha1,17723,GRP_BASAL_AREA,BASAL_AREA_SPP,Prunus serotina -US-Ha1,17723,GRP_BASAL_AREA,BASAL_AREA_DATE,20111201 -US-Ha1,17723,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17723,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,2.61 -US-Ha1,17768,GRP_BASAL_AREA,BASAL_AREA,0.9 -US-Ha1,17768,GRP_BASAL_AREA,BASAL_AREA_SPP,Prunus serotina -US-Ha1,17768,GRP_BASAL_AREA,BASAL_AREA_DATE,20121204 -US-Ha1,17768,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17768,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,2.62 -US-Ha1,18144,GRP_BASAL_AREA,BASAL_AREA,0.9 -US-Ha1,18144,GRP_BASAL_AREA,BASAL_AREA_SPP,Fraxinus americana -US-Ha1,18144,GRP_BASAL_AREA,BASAL_AREA_DATE,20041103 -US-Ha1,18144,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,18144,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,3.47 -US-Ha1,17813,GRP_BASAL_AREA,BASAL_AREA,0.91 -US-Ha1,17813,GRP_BASAL_AREA,BASAL_AREA_SPP,Prunus serotina -US-Ha1,17813,GRP_BASAL_AREA,BASAL_AREA_DATE,20131212 -US-Ha1,17813,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17813,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,2.65 -US-Ha1,17388,GRP_BASAL_AREA,BASAL_AREA,0.92 -US-Ha1,17388,GRP_BASAL_AREA,BASAL_AREA_SPP,Prunus serotina -US-Ha1,17388,GRP_BASAL_AREA,BASAL_AREA_DATE,1993 -US-Ha1,17388,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17388,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,2.39 -US-Ha1,17857,GRP_BASAL_AREA,BASAL_AREA,0.92 -US-Ha1,17857,GRP_BASAL_AREA,BASAL_AREA_SPP,Quercus velutina -US-Ha1,17857,GRP_BASAL_AREA,BASAL_AREA_DATE,19991027 -US-Ha1,17857,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17857,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,2.08 -US-Ha1,17588,GRP_BASAL_AREA,BASAL_AREA,0.93 -US-Ha1,17588,GRP_BASAL_AREA,BASAL_AREA_SPP,Prunus serotina -US-Ha1,17588,GRP_BASAL_AREA,BASAL_AREA_DATE,20081120 -US-Ha1,17588,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17588,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,2.56 -US-Ha1,17633,GRP_BASAL_AREA,BASAL_AREA,0.93 -US-Ha1,17633,GRP_BASAL_AREA,BASAL_AREA_SPP,Prunus serotina -US-Ha1,17633,GRP_BASAL_AREA,BASAL_AREA_DATE,20091201 -US-Ha1,17633,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17633,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,2.58 -US-Ha1,17917,GRP_BASAL_AREA,BASAL_AREA,0.93 -US-Ha1,17917,GRP_BASAL_AREA,BASAL_AREA_SPP,Quercus velutina -US-Ha1,17917,GRP_BASAL_AREA,BASAL_AREA_DATE,20001024 -US-Ha1,17917,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17917,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,2.11 -US-Ha1,18100,GRP_BASAL_AREA,BASAL_AREA,0.93 -US-Ha1,18100,GRP_BASAL_AREA,BASAL_AREA_SPP,Prunus serotina -US-Ha1,18100,GRP_BASAL_AREA,BASAL_AREA_DATE,20031113 -US-Ha1,18100,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,18100,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,2.44 -US-Ha1,18160,GRP_BASAL_AREA,BASAL_AREA,0.93 -US-Ha1,18160,GRP_BASAL_AREA,BASAL_AREA_SPP,Prunus serotina -US-Ha1,18160,GRP_BASAL_AREA,BASAL_AREA_DATE,20041103 -US-Ha1,18160,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,18160,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,2.44 -US-Ha1,17543,GRP_BASAL_AREA,BASAL_AREA,0.94 -US-Ha1,17543,GRP_BASAL_AREA,BASAL_AREA_SPP,Prunus serotina -US-Ha1,17543,GRP_BASAL_AREA,BASAL_AREA_DATE,20071120 -US-Ha1,17543,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17543,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,2.54 -US-Ha1,17980,GRP_BASAL_AREA,BASAL_AREA,0.94 -US-Ha1,17980,GRP_BASAL_AREA,BASAL_AREA_SPP,Prunus serotina -US-Ha1,17980,GRP_BASAL_AREA,BASAL_AREA_DATE,20011026 -US-Ha1,17980,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17980,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,2.42 -US-Ha1,18040,GRP_BASAL_AREA,BASAL_AREA,0.94 -US-Ha1,18040,GRP_BASAL_AREA,BASAL_AREA_SPP,Prunus serotina -US-Ha1,18040,GRP_BASAL_AREA,BASAL_AREA_DATE,20021114 -US-Ha1,18040,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,18040,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,2.48 -US-Ha1,18220,GRP_BASAL_AREA,BASAL_AREA,0.94 -US-Ha1,18220,GRP_BASAL_AREA,BASAL_AREA_SPP,Prunus serotina -US-Ha1,18220,GRP_BASAL_AREA,BASAL_AREA_DATE,20051102 -US-Ha1,18220,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,18220,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,2.46 -US-Ha1,17474,GRP_BASAL_AREA,BASAL_AREA,0.95 -US-Ha1,17474,GRP_BASAL_AREA,BASAL_AREA_SPP,Prunus serotina -US-Ha1,17474,GRP_BASAL_AREA,BASAL_AREA_DATE,19981030 -US-Ha1,17474,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17474,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,2.47 -US-Ha1,17861,GRP_BASAL_AREA,BASAL_AREA,0.95 -US-Ha1,17861,GRP_BASAL_AREA,BASAL_AREA_SPP,Prunus serotina -US-Ha1,17861,GRP_BASAL_AREA,BASAL_AREA_DATE,19991027 -US-Ha1,17861,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17861,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,2.48 -US-Ha1,17921,GRP_BASAL_AREA,BASAL_AREA,0.95 -US-Ha1,17921,GRP_BASAL_AREA,BASAL_AREA_SPP,Prunus serotina -US-Ha1,17921,GRP_BASAL_AREA,BASAL_AREA_DATE,20001024 -US-Ha1,17921,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17921,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,2.5 -US-Ha1,17976,GRP_BASAL_AREA,BASAL_AREA,0.96 -US-Ha1,17976,GRP_BASAL_AREA,BASAL_AREA_SPP,Quercus velutina -US-Ha1,17976,GRP_BASAL_AREA,BASAL_AREA_DATE,20011026 -US-Ha1,17976,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17976,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,2.16 -US-Ha1,18273,GRP_BASAL_AREA,BASAL_AREA,0.96 -US-Ha1,18273,GRP_BASAL_AREA,BASAL_AREA_SPP,Prunus serotina -US-Ha1,18273,GRP_BASAL_AREA,BASAL_AREA_DATE,20061114 -US-Ha1,18273,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,18273,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,2.53 -US-Ha1,18216,GRP_BASAL_AREA,BASAL_AREA,0.97 -US-Ha1,18216,GRP_BASAL_AREA,BASAL_AREA_SPP,Quercus velutina -US-Ha1,18216,GRP_BASAL_AREA,BASAL_AREA_DATE,20051102 -US-Ha1,18216,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,18216,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,2.29 -US-Ha1,18036,GRP_BASAL_AREA,BASAL_AREA,0.98 -US-Ha1,18036,GRP_BASAL_AREA,BASAL_AREA_SPP,Quercus velutina -US-Ha1,18036,GRP_BASAL_AREA,BASAL_AREA_DATE,20021114 -US-Ha1,18036,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,18036,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,2.19 -US-Ha1,18096,GRP_BASAL_AREA,BASAL_AREA,0.99 -US-Ha1,18096,GRP_BASAL_AREA,BASAL_AREA_SPP,Quercus velutina -US-Ha1,18096,GRP_BASAL_AREA,BASAL_AREA_DATE,20031113 -US-Ha1,18096,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,18096,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,2.22 -US-Ha1,17382,GRP_BASAL_AREA,BASAL_AREA,1 -US-Ha1,17382,GRP_BASAL_AREA,BASAL_AREA_SPP,Quercus velutina -US-Ha1,17382,GRP_BASAL_AREA,BASAL_AREA_DATE,1993 -US-Ha1,17382,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17382,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,2.01 -US-Ha1,18270,GRP_BASAL_AREA,BASAL_AREA,1 -US-Ha1,18270,GRP_BASAL_AREA,BASAL_AREA_SPP,Quercus velutina -US-Ha1,18270,GRP_BASAL_AREA,BASAL_AREA_DATE,20061114 -US-Ha1,18270,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,18270,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,2.34 -US-Ha1,18156,GRP_BASAL_AREA,BASAL_AREA,1.01 -US-Ha1,18156,GRP_BASAL_AREA,BASAL_AREA_SPP,Quercus velutina -US-Ha1,18156,GRP_BASAL_AREA,BASAL_AREA_DATE,20041103 -US-Ha1,18156,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,18156,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,2.25 -US-Ha1,18200,GRP_BASAL_AREA,BASAL_AREA,1.01 -US-Ha1,18200,GRP_BASAL_AREA,BASAL_AREA_SPP,Betula alleghaniensis -US-Ha1,18200,GRP_BASAL_AREA,BASAL_AREA_DATE,20041103 -US-Ha1,18200,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,18200,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,1.52 -US-Ha1,17540,GRP_BASAL_AREA,BASAL_AREA,1.02 -US-Ha1,17540,GRP_BASAL_AREA,BASAL_AREA_SPP,Quercus velutina -US-Ha1,17540,GRP_BASAL_AREA,BASAL_AREA_DATE,20071120 -US-Ha1,17540,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17540,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,2.37 -US-Ha1,18258,GRP_BASAL_AREA,BASAL_AREA,1.02 -US-Ha1,18258,GRP_BASAL_AREA,BASAL_AREA_SPP,Betula alleghaniensis -US-Ha1,18258,GRP_BASAL_AREA,BASAL_AREA_DATE,20051102 -US-Ha1,18258,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,18258,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,1.54 -US-Ha1,17528,GRP_BASAL_AREA,BASAL_AREA,1.03 -US-Ha1,17528,GRP_BASAL_AREA,BASAL_AREA_SPP,Betula alleghaniensis -US-Ha1,17528,GRP_BASAL_AREA,BASAL_AREA_DATE,20061114 -US-Ha1,17528,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17528,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,1.56 -US-Ha1,17585,GRP_BASAL_AREA,BASAL_AREA,1.04 -US-Ha1,17585,GRP_BASAL_AREA,BASAL_AREA_SPP,Quercus velutina -US-Ha1,17585,GRP_BASAL_AREA,BASAL_AREA_DATE,20081120 -US-Ha1,17585,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17585,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,2.41 -US-Ha1,17753,GRP_BASAL_AREA,BASAL_AREA,1.04 -US-Ha1,17753,GRP_BASAL_AREA,BASAL_AREA_SPP,Betula alleghaniensis -US-Ha1,17753,GRP_BASAL_AREA,BASAL_AREA_DATE,20111201 -US-Ha1,17753,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17753,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,1.64 -US-Ha1,17798,GRP_BASAL_AREA,BASAL_AREA,1.04 -US-Ha1,17798,GRP_BASAL_AREA,BASAL_AREA_SPP,Betula alleghaniensis -US-Ha1,17798,GRP_BASAL_AREA,BASAL_AREA_DATE,20121204 -US-Ha1,17798,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17798,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,1.67 -US-Ha1,17448,GRP_BASAL_AREA,BASAL_AREA,1.05 -US-Ha1,17448,GRP_BASAL_AREA,BASAL_AREA_SPP,Betula alleghaniensis -US-Ha1,17448,GRP_BASAL_AREA,BASAL_AREA_DATE,1993 -US-Ha1,17448,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17448,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,1.47 -US-Ha1,17573,GRP_BASAL_AREA,BASAL_AREA,1.05 -US-Ha1,17573,GRP_BASAL_AREA,BASAL_AREA_SPP,Betula alleghaniensis -US-Ha1,17573,GRP_BASAL_AREA,BASAL_AREA_DATE,20071120 -US-Ha1,17573,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17573,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,1.57 -US-Ha1,17708,GRP_BASAL_AREA,BASAL_AREA,1.05 -US-Ha1,17708,GRP_BASAL_AREA,BASAL_AREA_SPP,Betula alleghaniensis -US-Ha1,17708,GRP_BASAL_AREA,BASAL_AREA_DATE,20101207 -US-Ha1,17708,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17708,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,1.62 -US-Ha1,17469,GRP_BASAL_AREA,BASAL_AREA,1.06 -US-Ha1,17469,GRP_BASAL_AREA,BASAL_AREA_SPP,Quercus velutina -US-Ha1,17469,GRP_BASAL_AREA,BASAL_AREA_DATE,19981030 -US-Ha1,17469,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17469,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,2.16 -US-Ha1,17514,GRP_BASAL_AREA,BASAL_AREA,1.06 -US-Ha1,17514,GRP_BASAL_AREA,BASAL_AREA_SPP,Betula alleghaniensis -US-Ha1,17514,GRP_BASAL_AREA,BASAL_AREA_DATE,19981030 -US-Ha1,17514,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17514,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,1.47 -US-Ha1,17618,GRP_BASAL_AREA,BASAL_AREA,1.06 -US-Ha1,17618,GRP_BASAL_AREA,BASAL_AREA_SPP,Betula alleghaniensis -US-Ha1,17618,GRP_BASAL_AREA,BASAL_AREA_DATE,20081120 -US-Ha1,17618,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17618,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,1.58 -US-Ha1,17630,GRP_BASAL_AREA,BASAL_AREA,1.06 -US-Ha1,17630,GRP_BASAL_AREA,BASAL_AREA_SPP,Quercus velutina -US-Ha1,17630,GRP_BASAL_AREA,BASAL_AREA_DATE,20091201 -US-Ha1,17630,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17630,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,2.45 -US-Ha1,17663,GRP_BASAL_AREA,BASAL_AREA,1.06 -US-Ha1,17663,GRP_BASAL_AREA,BASAL_AREA_SPP,Betula alleghaniensis -US-Ha1,17663,GRP_BASAL_AREA,BASAL_AREA_DATE,20091201 -US-Ha1,17663,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17663,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,1.61 -US-Ha1,17901,GRP_BASAL_AREA,BASAL_AREA,1.07 -US-Ha1,17901,GRP_BASAL_AREA,BASAL_AREA_SPP,Betula alleghaniensis -US-Ha1,17901,GRP_BASAL_AREA,BASAL_AREA_DATE,19991027 -US-Ha1,17901,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17901,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,1.5 -US-Ha1,18080,GRP_BASAL_AREA,BASAL_AREA,1.07 -US-Ha1,18080,GRP_BASAL_AREA,BASAL_AREA_SPP,Betula alleghaniensis -US-Ha1,18080,GRP_BASAL_AREA,BASAL_AREA_DATE,20021114 -US-Ha1,18080,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,18080,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,1.57 -US-Ha1,18140,GRP_BASAL_AREA,BASAL_AREA,1.07 -US-Ha1,18140,GRP_BASAL_AREA,BASAL_AREA_SPP,Betula alleghaniensis -US-Ha1,18140,GRP_BASAL_AREA,BASAL_AREA_DATE,20031113 -US-Ha1,18140,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,18140,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,1.58 -US-Ha1,17675,GRP_BASAL_AREA,BASAL_AREA,1.09 -US-Ha1,17675,GRP_BASAL_AREA,BASAL_AREA_SPP,Quercus velutina -US-Ha1,17675,GRP_BASAL_AREA,BASAL_AREA_DATE,20101207 -US-Ha1,17675,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17675,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,2.51 -US-Ha1,18020,GRP_BASAL_AREA,BASAL_AREA,1.09 -US-Ha1,18020,GRP_BASAL_AREA,BASAL_AREA_SPP,Betula alleghaniensis -US-Ha1,18020,GRP_BASAL_AREA,BASAL_AREA_DATE,20011026 -US-Ha1,18020,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,18020,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,1.63 -US-Ha1,17843,GRP_BASAL_AREA,BASAL_AREA,1.1 -US-Ha1,17843,GRP_BASAL_AREA,BASAL_AREA_SPP,Betula alleghaniensis -US-Ha1,17843,GRP_BASAL_AREA,BASAL_AREA_DATE,20131212 -US-Ha1,17843,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17843,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,1.75 -US-Ha1,17720,GRP_BASAL_AREA,BASAL_AREA,1.11 -US-Ha1,17720,GRP_BASAL_AREA,BASAL_AREA_SPP,Quercus velutina -US-Ha1,17720,GRP_BASAL_AREA,BASAL_AREA_DATE,20111201 -US-Ha1,17720,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17720,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,2.54 -US-Ha1,17765,GRP_BASAL_AREA,BASAL_AREA,1.13 -US-Ha1,17765,GRP_BASAL_AREA,BASAL_AREA_SPP,Quercus velutina -US-Ha1,17765,GRP_BASAL_AREA,BASAL_AREA_DATE,20121204 -US-Ha1,17765,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17765,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,2.58 -US-Ha1,17960,GRP_BASAL_AREA,BASAL_AREA,1.14 -US-Ha1,17960,GRP_BASAL_AREA,BASAL_AREA_SPP,Betula alleghaniensis -US-Ha1,17960,GRP_BASAL_AREA,BASAL_AREA_DATE,20001024 -US-Ha1,17960,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17960,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,1.57 -US-Ha1,17810,GRP_BASAL_AREA,BASAL_AREA,1.15 -US-Ha1,17810,GRP_BASAL_AREA,BASAL_AREA_SPP,Quercus velutina -US-Ha1,17810,GRP_BASAL_AREA,BASAL_AREA_DATE,20131212 -US-Ha1,17810,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17810,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,2.63 -US-Ha1,17436,GRP_BASAL_AREA,BASAL_AREA,1.93 -US-Ha1,17436,GRP_BASAL_AREA,BASAL_AREA_SPP,Pinus strobus -US-Ha1,17436,GRP_BASAL_AREA,BASAL_AREA_DATE,1993 -US-Ha1,17436,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17436,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,3.95 -US-Ha1,17412,GRP_BASAL_AREA,BASAL_AREA,11.31 -US-Ha1,17412,GRP_BASAL_AREA,BASAL_AREA_SPP,Quercus rubra -US-Ha1,17412,GRP_BASAL_AREA,BASAL_AREA_DATE,1993 -US-Ha1,17412,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17412,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,8.77 -US-Ha1,17877,GRP_BASAL_AREA,BASAL_AREA,11.94 -US-Ha1,17877,GRP_BASAL_AREA,BASAL_AREA_SPP,Quercus rubra -US-Ha1,17877,GRP_BASAL_AREA,BASAL_AREA_DATE,19991027 -US-Ha1,17877,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17877,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,9.55 -US-Ha1,17490,GRP_BASAL_AREA,BASAL_AREA,12.02 -US-Ha1,17490,GRP_BASAL_AREA,BASAL_AREA_SPP,Quercus rubra -US-Ha1,17490,GRP_BASAL_AREA,BASAL_AREA_DATE,19981030 -US-Ha1,17490,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17490,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,9.08 -US-Ha1,17937,GRP_BASAL_AREA,BASAL_AREA,12.1 -US-Ha1,17937,GRP_BASAL_AREA,BASAL_AREA_SPP,Quercus rubra -US-Ha1,17937,GRP_BASAL_AREA,BASAL_AREA_DATE,20001024 -US-Ha1,17937,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17937,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,9.66 -US-Ha1,17996,GRP_BASAL_AREA,BASAL_AREA,12.31 -US-Ha1,17996,GRP_BASAL_AREA,BASAL_AREA_SPP,Quercus rubra -US-Ha1,17996,GRP_BASAL_AREA,BASAL_AREA_DATE,20011026 -US-Ha1,17996,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17996,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,9.78 -US-Ha1,18056,GRP_BASAL_AREA,BASAL_AREA,12.46 -US-Ha1,18056,GRP_BASAL_AREA,BASAL_AREA_SPP,Quercus rubra -US-Ha1,18056,GRP_BASAL_AREA,BASAL_AREA_DATE,20021114 -US-Ha1,18056,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,18056,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,9.93 -US-Ha1,18116,GRP_BASAL_AREA,BASAL_AREA,12.6 -US-Ha1,18116,GRP_BASAL_AREA,BASAL_AREA_SPP,Quercus rubra -US-Ha1,18116,GRP_BASAL_AREA,BASAL_AREA_DATE,20031113 -US-Ha1,18116,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,18116,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,10 -US-Ha1,18176,GRP_BASAL_AREA,BASAL_AREA,12.79 -US-Ha1,18176,GRP_BASAL_AREA,BASAL_AREA_SPP,Quercus rubra -US-Ha1,18176,GRP_BASAL_AREA,BASAL_AREA_DATE,20041103 -US-Ha1,18176,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,18176,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,10.13 -US-Ha1,18236,GRP_BASAL_AREA,BASAL_AREA,12.9 -US-Ha1,18236,GRP_BASAL_AREA,BASAL_AREA_SPP,Quercus rubra -US-Ha1,18236,GRP_BASAL_AREA,BASAL_AREA_DATE,20051102 -US-Ha1,18236,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,18236,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,10.27 -US-Ha1,18285,GRP_BASAL_AREA,BASAL_AREA,13.26 -US-Ha1,18285,GRP_BASAL_AREA,BASAL_AREA_SPP,Quercus rubra -US-Ha1,18285,GRP_BASAL_AREA,BASAL_AREA_DATE,20061114 -US-Ha1,18285,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,18285,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,10.5 -US-Ha1,17555,GRP_BASAL_AREA,BASAL_AREA,13.46 -US-Ha1,17555,GRP_BASAL_AREA,BASAL_AREA_SPP,Quercus rubra -US-Ha1,17555,GRP_BASAL_AREA,BASAL_AREA_DATE,20071120 -US-Ha1,17555,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17555,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,10.63 -US-Ha1,17600,GRP_BASAL_AREA,BASAL_AREA,13.55 -US-Ha1,17600,GRP_BASAL_AREA,BASAL_AREA_SPP,Quercus rubra -US-Ha1,17600,GRP_BASAL_AREA,BASAL_AREA_DATE,20081120 -US-Ha1,17600,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17600,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,10.39 -US-Ha1,17645,GRP_BASAL_AREA,BASAL_AREA,13.74 -US-Ha1,17645,GRP_BASAL_AREA,BASAL_AREA_SPP,Quercus rubra -US-Ha1,17645,GRP_BASAL_AREA,BASAL_AREA_DATE,20091201 -US-Ha1,17645,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17645,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,10.45 -US-Ha1,17690,GRP_BASAL_AREA,BASAL_AREA,14.03 -US-Ha1,17690,GRP_BASAL_AREA,BASAL_AREA_SPP,Quercus rubra -US-Ha1,17690,GRP_BASAL_AREA,BASAL_AREA_DATE,20101207 -US-Ha1,17690,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17690,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,10.68 -US-Ha1,17735,GRP_BASAL_AREA,BASAL_AREA,14.23 -US-Ha1,17735,GRP_BASAL_AREA,BASAL_AREA_SPP,Quercus rubra -US-Ha1,17735,GRP_BASAL_AREA,BASAL_AREA_DATE,20111201 -US-Ha1,17735,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17735,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,10.8 -US-Ha1,17780,GRP_BASAL_AREA,BASAL_AREA,14.44 -US-Ha1,17780,GRP_BASAL_AREA,BASAL_AREA_SPP,Quercus rubra -US-Ha1,17780,GRP_BASAL_AREA,BASAL_AREA_DATE,20121204 -US-Ha1,17780,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17780,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,10.97 -US-Ha1,17825,GRP_BASAL_AREA,BASAL_AREA,14.7 -US-Ha1,17825,GRP_BASAL_AREA,BASAL_AREA_SPP,Quercus rubra -US-Ha1,17825,GRP_BASAL_AREA,BASAL_AREA_DATE,20131212 -US-Ha1,17825,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17825,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,11.11 -US-Ha1,17506,GRP_BASAL_AREA,BASAL_AREA,2.1 -US-Ha1,17506,GRP_BASAL_AREA,BASAL_AREA_SPP,Pinus strobus -US-Ha1,17506,GRP_BASAL_AREA,BASAL_AREA_DATE,19981030 -US-Ha1,17506,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17506,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,4.23 -US-Ha1,17953,GRP_BASAL_AREA,BASAL_AREA,2.14 -US-Ha1,17953,GRP_BASAL_AREA,BASAL_AREA_SPP,Pinus strobus -US-Ha1,17953,GRP_BASAL_AREA,BASAL_AREA_DATE,20001024 -US-Ha1,17953,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17953,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,4.36 -US-Ha1,17893,GRP_BASAL_AREA,BASAL_AREA,2.15 -US-Ha1,17893,GRP_BASAL_AREA,BASAL_AREA_SPP,Pinus strobus -US-Ha1,17893,GRP_BASAL_AREA,BASAL_AREA_DATE,19991027 -US-Ha1,17893,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17893,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,4.35 -US-Ha1,18012,GRP_BASAL_AREA,BASAL_AREA,2.25 -US-Ha1,18012,GRP_BASAL_AREA,BASAL_AREA_SPP,Pinus strobus -US-Ha1,18012,GRP_BASAL_AREA,BASAL_AREA_DATE,20011026 -US-Ha1,18012,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,18012,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,4.72 -US-Ha1,18072,GRP_BASAL_AREA,BASAL_AREA,2.25 -US-Ha1,18072,GRP_BASAL_AREA,BASAL_AREA_SPP,Pinus strobus -US-Ha1,18072,GRP_BASAL_AREA,BASAL_AREA_DATE,20021114 -US-Ha1,18072,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,18072,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,4.69 -US-Ha1,17792,GRP_BASAL_AREA,BASAL_AREA,2.26 -US-Ha1,17792,GRP_BASAL_AREA,BASAL_AREA_SPP,Pinus strobus -US-Ha1,17792,GRP_BASAL_AREA,BASAL_AREA_DATE,20121204 -US-Ha1,17792,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17792,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,4.79 -US-Ha1,18132,GRP_BASAL_AREA,BASAL_AREA,2.29 -US-Ha1,18132,GRP_BASAL_AREA,BASAL_AREA_SPP,Pinus strobus -US-Ha1,18132,GRP_BASAL_AREA,BASAL_AREA_DATE,20031113 -US-Ha1,18132,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,18132,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,4.76 -US-Ha1,17522,GRP_BASAL_AREA,BASAL_AREA,2.3 -US-Ha1,17522,GRP_BASAL_AREA,BASAL_AREA_SPP,Pinus strobus -US-Ha1,17522,GRP_BASAL_AREA,BASAL_AREA_DATE,20061114 -US-Ha1,17522,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17522,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,4.73 -US-Ha1,18252,GRP_BASAL_AREA,BASAL_AREA,2.3 -US-Ha1,18252,GRP_BASAL_AREA,BASAL_AREA_SPP,Pinus strobus -US-Ha1,18252,GRP_BASAL_AREA,BASAL_AREA_DATE,20051102 -US-Ha1,18252,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,18252,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,4.7 -US-Ha1,17747,GRP_BASAL_AREA,BASAL_AREA,2.31 -US-Ha1,17747,GRP_BASAL_AREA,BASAL_AREA_SPP,Pinus strobus -US-Ha1,17747,GRP_BASAL_AREA,BASAL_AREA_DATE,20111201 -US-Ha1,17747,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17747,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,4.75 -US-Ha1,17657,GRP_BASAL_AREA,BASAL_AREA,2.32 -US-Ha1,17657,GRP_BASAL_AREA,BASAL_AREA_SPP,Pinus strobus -US-Ha1,17657,GRP_BASAL_AREA,BASAL_AREA_DATE,20091201 -US-Ha1,17657,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17657,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,4.84 -US-Ha1,17837,GRP_BASAL_AREA,BASAL_AREA,2.32 -US-Ha1,17837,GRP_BASAL_AREA,BASAL_AREA_SPP,Pinus strobus -US-Ha1,17837,GRP_BASAL_AREA,BASAL_AREA_DATE,20131212 -US-Ha1,17837,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17837,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,4.88 -US-Ha1,18192,GRP_BASAL_AREA,BASAL_AREA,2.32 -US-Ha1,18192,GRP_BASAL_AREA,BASAL_AREA_SPP,Pinus strobus -US-Ha1,18192,GRP_BASAL_AREA,BASAL_AREA_DATE,20041103 -US-Ha1,18192,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,18192,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,4.81 -US-Ha1,17567,GRP_BASAL_AREA,BASAL_AREA,2.33 -US-Ha1,17567,GRP_BASAL_AREA,BASAL_AREA_SPP,Pinus strobus -US-Ha1,17567,GRP_BASAL_AREA,BASAL_AREA_DATE,20071120 -US-Ha1,17567,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17567,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,4.79 -US-Ha1,17702,GRP_BASAL_AREA,BASAL_AREA,2.35 -US-Ha1,17702,GRP_BASAL_AREA,BASAL_AREA_SPP,Pinus strobus -US-Ha1,17702,GRP_BASAL_AREA,BASAL_AREA_DATE,20101207 -US-Ha1,17702,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17702,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,4.89 -US-Ha1,17612,GRP_BASAL_AREA,BASAL_AREA,2.37 -US-Ha1,17612,GRP_BASAL_AREA,BASAL_AREA_SPP,Pinus strobus -US-Ha1,17612,GRP_BASAL_AREA,BASAL_AREA_DATE,20081120 -US-Ha1,17612,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17612,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,4.86 -US-Ha1,17418,GRP_BASAL_AREA,BASAL_AREA,2.72 -US-Ha1,17418,GRP_BASAL_AREA,BASAL_AREA_SPP,Pinus resinosa -US-Ha1,17418,GRP_BASAL_AREA,BASAL_AREA_DATE,1993 -US-Ha1,17418,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17418,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,8.95 -US-Ha1,17881,GRP_BASAL_AREA,BASAL_AREA,2.72 -US-Ha1,17881,GRP_BASAL_AREA,BASAL_AREA_SPP,Pinus resinosa -US-Ha1,17881,GRP_BASAL_AREA,BASAL_AREA_DATE,19991027 -US-Ha1,17881,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17881,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,9.04 -US-Ha1,17693,GRP_BASAL_AREA,BASAL_AREA,2.73 -US-Ha1,17693,GRP_BASAL_AREA,BASAL_AREA_SPP,Pinus resinosa -US-Ha1,17693,GRP_BASAL_AREA,BASAL_AREA_DATE,20101207 -US-Ha1,17693,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17693,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,9.3 -US-Ha1,17941,GRP_BASAL_AREA,BASAL_AREA,2.73 -US-Ha1,17941,GRP_BASAL_AREA,BASAL_AREA_SPP,Pinus resinosa -US-Ha1,17941,GRP_BASAL_AREA,BASAL_AREA_DATE,20001024 -US-Ha1,17941,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17941,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,9.09 -US-Ha1,18060,GRP_BASAL_AREA,BASAL_AREA,2.73 -US-Ha1,18060,GRP_BASAL_AREA,BASAL_AREA_SPP,Pinus resinosa -US-Ha1,18060,GRP_BASAL_AREA,BASAL_AREA_DATE,20021114 -US-Ha1,18060,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,18060,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,9.08 -US-Ha1,18120,GRP_BASAL_AREA,BASAL_AREA,2.74 -US-Ha1,18120,GRP_BASAL_AREA,BASAL_AREA_SPP,Pinus resinosa -US-Ha1,18120,GRP_BASAL_AREA,BASAL_AREA_DATE,20031113 -US-Ha1,18120,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,18120,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,9.12 -US-Ha1,17738,GRP_BASAL_AREA,BASAL_AREA,2.75 -US-Ha1,17738,GRP_BASAL_AREA,BASAL_AREA_SPP,Pinus resinosa -US-Ha1,17738,GRP_BASAL_AREA,BASAL_AREA_DATE,20111201 -US-Ha1,17738,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17738,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,9.35 -US-Ha1,18180,GRP_BASAL_AREA,BASAL_AREA,2.75 -US-Ha1,18180,GRP_BASAL_AREA,BASAL_AREA_SPP,Pinus resinosa -US-Ha1,18180,GRP_BASAL_AREA,BASAL_AREA_DATE,20041103 -US-Ha1,18180,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,18180,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,9.16 -US-Ha1,17783,GRP_BASAL_AREA,BASAL_AREA,2.76 -US-Ha1,17783,GRP_BASAL_AREA,BASAL_AREA_SPP,Pinus resinosa -US-Ha1,17783,GRP_BASAL_AREA,BASAL_AREA_DATE,20121204 -US-Ha1,17783,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17783,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,9.4 -US-Ha1,18288,GRP_BASAL_AREA,BASAL_AREA,2.76 -US-Ha1,18288,GRP_BASAL_AREA,BASAL_AREA_SPP,Pinus resinosa -US-Ha1,18288,GRP_BASAL_AREA,BASAL_AREA_DATE,20061114 -US-Ha1,18288,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,18288,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,9.27 -US-Ha1,18000,GRP_BASAL_AREA,BASAL_AREA,2.77 -US-Ha1,18000,GRP_BASAL_AREA,BASAL_AREA_SPP,Pinus resinosa -US-Ha1,18000,GRP_BASAL_AREA,BASAL_AREA_DATE,20011026 -US-Ha1,18000,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,18000,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,9.22 -US-Ha1,18240,GRP_BASAL_AREA,BASAL_AREA,2.77 -US-Ha1,18240,GRP_BASAL_AREA,BASAL_AREA_SPP,Pinus resinosa -US-Ha1,18240,GRP_BASAL_AREA,BASAL_AREA_DATE,20051102 -US-Ha1,18240,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,18240,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,9.24 -US-Ha1,17558,GRP_BASAL_AREA,BASAL_AREA,2.78 -US-Ha1,17558,GRP_BASAL_AREA,BASAL_AREA_SPP,Pinus resinosa -US-Ha1,17558,GRP_BASAL_AREA,BASAL_AREA_DATE,20071120 -US-Ha1,17558,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17558,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,9.33 -US-Ha1,17494,GRP_BASAL_AREA,BASAL_AREA,2.8 -US-Ha1,17494,GRP_BASAL_AREA,BASAL_AREA_SPP,Pinus resinosa -US-Ha1,17494,GRP_BASAL_AREA,BASAL_AREA_DATE,19981030 -US-Ha1,17494,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17494,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,9.28 -US-Ha1,17603,GRP_BASAL_AREA,BASAL_AREA,2.8 -US-Ha1,17603,GRP_BASAL_AREA,BASAL_AREA_SPP,Pinus resinosa -US-Ha1,17603,GRP_BASAL_AREA,BASAL_AREA_DATE,20081120 -US-Ha1,17603,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17603,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,9.39 -US-Ha1,17648,GRP_BASAL_AREA,BASAL_AREA,2.8 -US-Ha1,17648,GRP_BASAL_AREA,BASAL_AREA_SPP,Pinus resinosa -US-Ha1,17648,GRP_BASAL_AREA,BASAL_AREA_DATE,20091201 -US-Ha1,17648,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17648,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,9.4 -US-Ha1,17828,GRP_BASAL_AREA,BASAL_AREA,2.82 -US-Ha1,17828,GRP_BASAL_AREA,BASAL_AREA_SPP,Pinus resinosa -US-Ha1,17828,GRP_BASAL_AREA,BASAL_AREA_DATE,20131212 -US-Ha1,17828,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17828,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,9.59 -US-Ha1,17400,GRP_BASAL_AREA,BASAL_AREA,3.7 -US-Ha1,17400,GRP_BASAL_AREA,BASAL_AREA_SPP,Tsuga canadensis -US-Ha1,17400,GRP_BASAL_AREA,BASAL_AREA_DATE,1993 -US-Ha1,17400,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17400,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,8.24 -US-Ha1,17482,GRP_BASAL_AREA,BASAL_AREA,4.07 -US-Ha1,17482,GRP_BASAL_AREA,BASAL_AREA_SPP,Tsuga canadensis -US-Ha1,17482,GRP_BASAL_AREA,BASAL_AREA_DATE,19981030 -US-Ha1,17482,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17482,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,8.86 -US-Ha1,17929,GRP_BASAL_AREA,BASAL_AREA,4.2 -US-Ha1,17929,GRP_BASAL_AREA,BASAL_AREA_SPP,Tsuga canadensis -US-Ha1,17929,GRP_BASAL_AREA,BASAL_AREA_DATE,20001024 -US-Ha1,17929,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17929,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,9.01 -US-Ha1,17869,GRP_BASAL_AREA,BASAL_AREA,4.21 -US-Ha1,17869,GRP_BASAL_AREA,BASAL_AREA_SPP,Tsuga canadensis -US-Ha1,17869,GRP_BASAL_AREA,BASAL_AREA_DATE,19991027 -US-Ha1,17869,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17869,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,9 -US-Ha1,17988,GRP_BASAL_AREA,BASAL_AREA,4.39 -US-Ha1,17988,GRP_BASAL_AREA,BASAL_AREA_SPP,Tsuga canadensis -US-Ha1,17988,GRP_BASAL_AREA,BASAL_AREA_DATE,20011026 -US-Ha1,17988,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17988,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,9.17 -US-Ha1,18048,GRP_BASAL_AREA,BASAL_AREA,4.45 -US-Ha1,18048,GRP_BASAL_AREA,BASAL_AREA_SPP,Tsuga canadensis -US-Ha1,18048,GRP_BASAL_AREA,BASAL_AREA_DATE,20021114 -US-Ha1,18048,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,18048,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,9.31 -US-Ha1,18108,GRP_BASAL_AREA,BASAL_AREA,4.52 -US-Ha1,18108,GRP_BASAL_AREA,BASAL_AREA_SPP,Tsuga canadensis -US-Ha1,18108,GRP_BASAL_AREA,BASAL_AREA_DATE,20031113 -US-Ha1,18108,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,18108,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,9.44 -US-Ha1,18228,GRP_BASAL_AREA,BASAL_AREA,4.62 -US-Ha1,18228,GRP_BASAL_AREA,BASAL_AREA_SPP,Tsuga canadensis -US-Ha1,18228,GRP_BASAL_AREA,BASAL_AREA_DATE,20051102 -US-Ha1,18228,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,18228,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,9.56 -US-Ha1,18168,GRP_BASAL_AREA,BASAL_AREA,4.64 -US-Ha1,18168,GRP_BASAL_AREA,BASAL_AREA_SPP,Tsuga canadensis -US-Ha1,18168,GRP_BASAL_AREA,BASAL_AREA_DATE,20041103 -US-Ha1,18168,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,18168,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,9.55 -US-Ha1,18279,GRP_BASAL_AREA,BASAL_AREA,4.7 -US-Ha1,18279,GRP_BASAL_AREA,BASAL_AREA_SPP,Tsuga canadensis -US-Ha1,18279,GRP_BASAL_AREA,BASAL_AREA_DATE,20061114 -US-Ha1,18279,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,18279,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,9.69 -US-Ha1,17549,GRP_BASAL_AREA,BASAL_AREA,4.83 -US-Ha1,17549,GRP_BASAL_AREA,BASAL_AREA_SPP,Tsuga canadensis -US-Ha1,17549,GRP_BASAL_AREA,BASAL_AREA_DATE,20071120 -US-Ha1,17549,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17549,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,9.81 -US-Ha1,17594,GRP_BASAL_AREA,BASAL_AREA,4.9 -US-Ha1,17594,GRP_BASAL_AREA,BASAL_AREA_SPP,Tsuga canadensis -US-Ha1,17594,GRP_BASAL_AREA,BASAL_AREA_DATE,20081120 -US-Ha1,17594,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17594,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,9.91 -US-Ha1,17639,GRP_BASAL_AREA,BASAL_AREA,5.01 -US-Ha1,17639,GRP_BASAL_AREA,BASAL_AREA_SPP,Tsuga canadensis -US-Ha1,17639,GRP_BASAL_AREA,BASAL_AREA_DATE,20091201 -US-Ha1,17639,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17639,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,10.03 -US-Ha1,17684,GRP_BASAL_AREA,BASAL_AREA,5.08 -US-Ha1,17684,GRP_BASAL_AREA,BASAL_AREA_SPP,Tsuga canadensis -US-Ha1,17684,GRP_BASAL_AREA,BASAL_AREA_DATE,20101207 -US-Ha1,17684,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17684,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,10.15 -US-Ha1,17729,GRP_BASAL_AREA,BASAL_AREA,5.23 -US-Ha1,17729,GRP_BASAL_AREA,BASAL_AREA_SPP,Tsuga canadensis -US-Ha1,17729,GRP_BASAL_AREA,BASAL_AREA_DATE,20111201 -US-Ha1,17729,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17729,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,10.28 -US-Ha1,17774,GRP_BASAL_AREA,BASAL_AREA,5.35 -US-Ha1,17774,GRP_BASAL_AREA,BASAL_AREA_SPP,Tsuga canadensis -US-Ha1,17774,GRP_BASAL_AREA,BASAL_AREA_DATE,20121204 -US-Ha1,17774,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17774,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,10.4 -US-Ha1,17819,GRP_BASAL_AREA,BASAL_AREA,5.61 -US-Ha1,17819,GRP_BASAL_AREA,BASAL_AREA_SPP,Tsuga canadensis -US-Ha1,17819,GRP_BASAL_AREA,BASAL_AREA_DATE,20131212 -US-Ha1,17819,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17819,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,10.67 -US-Ha1,17486,GRP_BASAL_AREA,BASAL_AREA,7.69 -US-Ha1,17486,GRP_BASAL_AREA,BASAL_AREA_SPP,Acer rubrum -US-Ha1,17486,GRP_BASAL_AREA,BASAL_AREA_DATE,19981030 -US-Ha1,17486,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17486,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,4.7 -US-Ha1,18112,GRP_BASAL_AREA,BASAL_AREA,7.69 -US-Ha1,18112,GRP_BASAL_AREA,BASAL_AREA_SPP,Acer rubrum -US-Ha1,18112,GRP_BASAL_AREA,BASAL_AREA_DATE,20031113 -US-Ha1,18112,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,18112,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,4.49 -US-Ha1,18052,GRP_BASAL_AREA,BASAL_AREA,7.74 -US-Ha1,18052,GRP_BASAL_AREA,BASAL_AREA_SPP,Acer rubrum -US-Ha1,18052,GRP_BASAL_AREA,BASAL_AREA_DATE,20021114 -US-Ha1,18052,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,18052,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,4.62 -US-Ha1,18172,GRP_BASAL_AREA,BASAL_AREA,7.77 -US-Ha1,18172,GRP_BASAL_AREA,BASAL_AREA_SPP,Acer rubrum -US-Ha1,18172,GRP_BASAL_AREA,BASAL_AREA_DATE,20041103 -US-Ha1,18172,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,18172,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,4.5 -US-Ha1,17406,GRP_BASAL_AREA,BASAL_AREA,7.85 -US-Ha1,17406,GRP_BASAL_AREA,BASAL_AREA_SPP,Acer rubrum -US-Ha1,17406,GRP_BASAL_AREA,BASAL_AREA_DATE,1993 -US-Ha1,17406,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17406,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,5.06 -US-Ha1,17552,GRP_BASAL_AREA,BASAL_AREA,7.86 -US-Ha1,17552,GRP_BASAL_AREA,BASAL_AREA_SPP,Acer rubrum -US-Ha1,17552,GRP_BASAL_AREA,BASAL_AREA_DATE,20071120 -US-Ha1,17552,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17552,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,4.6 -US-Ha1,17597,GRP_BASAL_AREA,BASAL_AREA,7.87 -US-Ha1,17597,GRP_BASAL_AREA,BASAL_AREA_SPP,Acer rubrum -US-Ha1,17597,GRP_BASAL_AREA,BASAL_AREA_DATE,20081120 -US-Ha1,17597,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17597,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,4.69 -US-Ha1,17642,GRP_BASAL_AREA,BASAL_AREA,7.87 -US-Ha1,17642,GRP_BASAL_AREA,BASAL_AREA_SPP,Acer rubrum -US-Ha1,17642,GRP_BASAL_AREA,BASAL_AREA_DATE,20091201 -US-Ha1,17642,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17642,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,4.75 -US-Ha1,18232,GRP_BASAL_AREA,BASAL_AREA,7.89 -US-Ha1,18232,GRP_BASAL_AREA,BASAL_AREA_SPP,Acer rubrum -US-Ha1,18232,GRP_BASAL_AREA,BASAL_AREA_DATE,20051102 -US-Ha1,18232,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,18232,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,4.6 -US-Ha1,18282,GRP_BASAL_AREA,BASAL_AREA,7.92 -US-Ha1,18282,GRP_BASAL_AREA,BASAL_AREA_SPP,Acer rubrum -US-Ha1,18282,GRP_BASAL_AREA,BASAL_AREA_DATE,20061114 -US-Ha1,18282,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,18282,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,4.61 -US-Ha1,17687,GRP_BASAL_AREA,BASAL_AREA,7.93 -US-Ha1,17687,GRP_BASAL_AREA,BASAL_AREA_SPP,Acer rubrum -US-Ha1,17687,GRP_BASAL_AREA,BASAL_AREA_DATE,20101207 -US-Ha1,17687,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17687,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,4.78 -US-Ha1,17992,GRP_BASAL_AREA,BASAL_AREA,7.96 -US-Ha1,17992,GRP_BASAL_AREA,BASAL_AREA_SPP,Acer rubrum -US-Ha1,17992,GRP_BASAL_AREA,BASAL_AREA_DATE,20011026 -US-Ha1,17992,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17992,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,4.72 -US-Ha1,17732,GRP_BASAL_AREA,BASAL_AREA,7.97 -US-Ha1,17732,GRP_BASAL_AREA,BASAL_AREA_SPP,Acer rubrum -US-Ha1,17732,GRP_BASAL_AREA,BASAL_AREA_DATE,20111201 -US-Ha1,17732,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17732,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,4.84 -US-Ha1,17777,GRP_BASAL_AREA,BASAL_AREA,7.97 -US-Ha1,17777,GRP_BASAL_AREA,BASAL_AREA_SPP,Acer rubrum -US-Ha1,17777,GRP_BASAL_AREA,BASAL_AREA_DATE,20121204 -US-Ha1,17777,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17777,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,4.85 -US-Ha1,17873,GRP_BASAL_AREA,BASAL_AREA,8.08 -US-Ha1,17873,GRP_BASAL_AREA,BASAL_AREA_SPP,Acer rubrum -US-Ha1,17873,GRP_BASAL_AREA,BASAL_AREA_DATE,19991027 -US-Ha1,17873,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17873,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,4.66 -US-Ha1,17822,GRP_BASAL_AREA,BASAL_AREA,8.21 -US-Ha1,17822,GRP_BASAL_AREA,BASAL_AREA_SPP,Acer rubrum -US-Ha1,17822,GRP_BASAL_AREA,BASAL_AREA_DATE,20131212 -US-Ha1,17822,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17822,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,5.01 -US-Ha1,17933,GRP_BASAL_AREA,BASAL_AREA,8.22 -US-Ha1,17933,GRP_BASAL_AREA,BASAL_AREA_SPP,Acer rubrum -US-Ha1,17933,GRP_BASAL_AREA,BASAL_AREA_DATE,20001024 -US-Ha1,17933,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,34 -US-Ha1,17933,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,4.75 -US-Ha1,27397,GRP_BIOMASS_CHEM,BIOMASS_C,4.804 -US-Ha1,27398,GRP_BIOMASS_CHEM,BIOMASS_C,4.864 -US-Ha1,28621,GRP_BIOMASS_CHEM,BIOMASS_C,4.912 -US-Ha1,24966,GRP_BIOMASS_CHEM,BIOMASS_C,4.995 -US-Ha1,28353,GRP_BIOMASS_CHEM,BIOMASS_C,4.998 -US-Ha1,25099,GRP_BIOMASS_CHEM,BIOMASS_C,5.001 -US-Ha1,24845,GRP_BIOMASS_CHEM,BIOMASS_C,5.005 -US-Ha1,29551,GRP_BIOMASS_CHEM,BIOMASS_C,5.01 -US-Ha1,24197,GRP_BIOMASS_CHEM,BIOMASS_C,5.024 -US-Ha1,24196,GRP_BIOMASS_CHEM,BIOMASS_C,5.036 -US-Ha1,25100,GRP_BIOMASS_CHEM,BIOMASS_C,5.064 -US-Ha1,29552,GRP_BIOMASS_CHEM,BIOMASS_C,5.066 -US-Ha1,27399,GRP_BIOMASS_CHEM,BIOMASS_C,5.074 -US-Ha1,24455,GRP_BIOMASS_CHEM,BIOMASS_C,5.094 -US-Ha1,24964,GRP_BIOMASS_CHEM,BIOMASS_C,5.106 -US-Ha1,24322,GRP_BIOMASS_CHEM,BIOMASS_C,5.126 -US-Ha1,24844,GRP_BIOMASS_CHEM,BIOMASS_C,5.129 -US-Ha1,24965,GRP_BIOMASS_CHEM,BIOMASS_C,5.176 -US-Ha1,24197,GRP_BIOMASS_CHEM,BIOMASS_N,0.102 -US-Ha1,25100,GRP_BIOMASS_CHEM,BIOMASS_N,0.123 -US-Ha1,24965,GRP_BIOMASS_CHEM,BIOMASS_N,0.124 -US-Ha1,29552,GRP_BIOMASS_CHEM,BIOMASS_N,0.146 -US-Ha1,24455,GRP_BIOMASS_CHEM,BIOMASS_N,0.176 -US-Ha1,24322,GRP_BIOMASS_CHEM,BIOMASS_N,0.178 -US-Ha1,24196,GRP_BIOMASS_CHEM,BIOMASS_N,0.2 -US-Ha1,29551,GRP_BIOMASS_CHEM,BIOMASS_N,0.201 -US-Ha1,24966,GRP_BIOMASS_CHEM,BIOMASS_N,0.206 -US-Ha1,27399,GRP_BIOMASS_CHEM,BIOMASS_N,0.213 -US-Ha1,28621,GRP_BIOMASS_CHEM,BIOMASS_N,0.219 -US-Ha1,24844,GRP_BIOMASS_CHEM,BIOMASS_N,0.224 -US-Ha1,24964,GRP_BIOMASS_CHEM,BIOMASS_N,0.229 -US-Ha1,25099,GRP_BIOMASS_CHEM,BIOMASS_N,0.232 -US-Ha1,27398,GRP_BIOMASS_CHEM,BIOMASS_N,0.233 -US-Ha1,28353,GRP_BIOMASS_CHEM,BIOMASS_N,0.244 -US-Ha1,24845,GRP_BIOMASS_CHEM,BIOMASS_N,0.247 -US-Ha1,27397,GRP_BIOMASS_CHEM,BIOMASS_N,0.247 -US-Ha1,24196,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-Ha1,24197,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-Ha1,24322,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-Ha1,24455,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-Ha1,24844,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-Ha1,24845,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-Ha1,24964,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-Ha1,24965,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-Ha1,24966,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-Ha1,25099,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-Ha1,25100,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-Ha1,27397,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-Ha1,27398,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-Ha1,27399,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-Ha1,28353,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-Ha1,28621,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-Ha1,29551,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-Ha1,29552,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-Ha1,24196,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-Ha1,24197,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-Ha1,24322,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-Ha1,24455,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-Ha1,24844,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-Ha1,24845,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-Ha1,24964,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-Ha1,24965,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-Ha1,24966,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-Ha1,25099,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-Ha1,25100,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-Ha1,27397,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-Ha1,27398,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-Ha1,27399,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-Ha1,28353,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-Ha1,28621,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-Ha1,29551,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-Ha1,29552,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-Ha1,24196,GRP_BIOMASS_CHEM,BIOMASS_SPP,ACRU (NRCS plant code) -US-Ha1,24322,GRP_BIOMASS_CHEM,BIOMASS_SPP,ACRU (NRCS plant code) -US-Ha1,24455,GRP_BIOMASS_CHEM,BIOMASS_SPP,ACRU (NRCS plant code) -US-Ha1,24966,GRP_BIOMASS_CHEM,BIOMASS_SPP,ACRU (NRCS plant code) -US-Ha1,29551,GRP_BIOMASS_CHEM,BIOMASS_SPP,ACRU (NRCS plant code) -US-Ha1,27397,GRP_BIOMASS_CHEM,BIOMASS_SPP,BEAL2 (NRCS plant code) -US-Ha1,27398,GRP_BIOMASS_CHEM,BIOMASS_SPP,BEAL2 (NRCS plant code) -US-Ha1,27399,GRP_BIOMASS_CHEM,BIOMASS_SPP,BEAL2 (NRCS plant code) -US-Ha1,28621,GRP_BIOMASS_CHEM,BIOMASS_SPP,BEAL2 (NRCS plant code) -US-Ha1,24844,GRP_BIOMASS_CHEM,BIOMASS_SPP,QURU (NRCS plant code) -US-Ha1,24845,GRP_BIOMASS_CHEM,BIOMASS_SPP,QURU (NRCS plant code) -US-Ha1,24964,GRP_BIOMASS_CHEM,BIOMASS_SPP,QURU (NRCS plant code) -US-Ha1,25099,GRP_BIOMASS_CHEM,BIOMASS_SPP,QURU (NRCS plant code) -US-Ha1,28353,GRP_BIOMASS_CHEM,BIOMASS_SPP,QURU (NRCS plant code) -US-Ha1,24197,GRP_BIOMASS_CHEM,BIOMASS_SPP,TSCA (NRCS plant code) -US-Ha1,24965,GRP_BIOMASS_CHEM,BIOMASS_SPP,TSCA (NRCS plant code) -US-Ha1,25100,GRP_BIOMASS_CHEM,BIOMASS_SPP,TSCA (NRCS plant code) -US-Ha1,29552,GRP_BIOMASS_CHEM,BIOMASS_SPP,TSCA (NRCS plant code) -US-Ha1,24455,GRP_BIOMASS_CHEM,BIOMASS_DATE,19980715 -US-Ha1,24844,GRP_BIOMASS_CHEM,BIOMASS_DATE,19980715 -US-Ha1,24322,GRP_BIOMASS_CHEM,BIOMASS_DATE,20000731 -US-Ha1,24964,GRP_BIOMASS_CHEM,BIOMASS_DATE,20000731 -US-Ha1,24965,GRP_BIOMASS_CHEM,BIOMASS_DATE,20000731 -US-Ha1,27399,GRP_BIOMASS_CHEM,BIOMASS_DATE,20000731 -US-Ha1,24196,GRP_BIOMASS_CHEM,BIOMASS_DATE,20060717 -US-Ha1,24197,GRP_BIOMASS_CHEM,BIOMASS_DATE,20060717 -US-Ha1,25099,GRP_BIOMASS_CHEM,BIOMASS_DATE,20060717 -US-Ha1,27397,GRP_BIOMASS_CHEM,BIOMASS_DATE,20060717 -US-Ha1,24845,GRP_BIOMASS_CHEM,BIOMASS_DATE,20070725 -US-Ha1,24966,GRP_BIOMASS_CHEM,BIOMASS_DATE,20070725 -US-Ha1,25100,GRP_BIOMASS_CHEM,BIOMASS_DATE,20070725 -US-Ha1,27398,GRP_BIOMASS_CHEM,BIOMASS_DATE,20070725 -US-Ha1,28353,GRP_BIOMASS_CHEM,BIOMASS_DATE,20080731 -US-Ha1,29551,GRP_BIOMASS_CHEM,BIOMASS_DATE,20080731 -US-Ha1,28621,GRP_BIOMASS_CHEM,BIOMASS_DATE,20080820 -US-Ha1,29552,GRP_BIOMASS_CHEM,BIOMASS_DATE,20080820 -US-Ha1,11958,GRP_CLIM_AVG,MAT,6.62 -US-Ha1,11958,GRP_CLIM_AVG,MAP,1071 -US-Ha1,11958,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfb -US-Ha1,27000371,GRP_COUNTRY,COUNTRY,USA -US-Ha1,17946,GRP_DBH,DBH,11.85 -US-Ha1,17946,GRP_DBH,DBH_SPP,Acer pennsylvanicum -US-Ha1,17946,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17946,GRP_DBH,DBH_DATE,20001024 -US-Ha1,17946,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17946,GRP_DBH,DBH_SPATIAL_REP_NUMBER,6 -US-Ha1,17946,GRP_DBH,DBH_SPATIAL_VARIABILITY,1.36 -US-Ha1,18292,GRP_DBH,DBH,11.9 -US-Ha1,18292,GRP_DBH,DBH_SPP,Acer pennsylvanicum -US-Ha1,18292,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,18292,GRP_DBH,DBH_DATE,20061114 -US-Ha1,18292,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,18292,GRP_DBH,DBH_SPATIAL_REP_NUMBER,2 -US-Ha1,18292,GRP_DBH,DBH_SPATIAL_VARIABILITY,0.32 -US-Ha1,17499,GRP_DBH,DBH,11.97 -US-Ha1,17499,GRP_DBH,DBH_SPP,Acer pennsylvanicum -US-Ha1,17499,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17499,GRP_DBH,DBH_DATE,19981030 -US-Ha1,17499,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17499,GRP_DBH,DBH_SPATIAL_REP_NUMBER,5 -US-Ha1,17499,GRP_DBH,DBH_SPATIAL_VARIABILITY,1.31 -US-Ha1,17425,GRP_DBH,DBH,12.02 -US-Ha1,17425,GRP_DBH,DBH_SPP,Acer pennsylvanicum -US-Ha1,17425,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17425,GRP_DBH,DBH_DATE,1993 -US-Ha1,17425,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17425,GRP_DBH,DBH_SPATIAL_REP_NUMBER,6 -US-Ha1,17425,GRP_DBH,DBH_SPATIAL_VARIABILITY,1.17 -US-Ha1,17562,GRP_DBH,DBH,12.03 -US-Ha1,17562,GRP_DBH,DBH_SPP,Acer pennsylvanicum -US-Ha1,17562,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17562,GRP_DBH,DBH_DATE,20071120 -US-Ha1,17562,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17562,GRP_DBH,DBH_SPATIAL_REP_NUMBER,2 -US-Ha1,17562,GRP_DBH,DBH_SPATIAL_VARIABILITY,0.36 -US-Ha1,18065,GRP_DBH,DBH,12.09 -US-Ha1,18065,GRP_DBH,DBH_SPP,Acer pennsylvanicum -US-Ha1,18065,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,18065,GRP_DBH,DBH_DATE,20021114 -US-Ha1,18065,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,18065,GRP_DBH,DBH_SPATIAL_REP_NUMBER,6 -US-Ha1,18065,GRP_DBH,DBH_SPATIAL_VARIABILITY,1.33 -US-Ha1,18005,GRP_DBH,DBH,12.1 -US-Ha1,18005,GRP_DBH,DBH_SPP,Acer pennsylvanicum -US-Ha1,18005,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,18005,GRP_DBH,DBH_DATE,20011026 -US-Ha1,18005,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,18005,GRP_DBH,DBH_SPATIAL_REP_NUMBER,6 -US-Ha1,18005,GRP_DBH,DBH_SPATIAL_VARIABILITY,1.35 -US-Ha1,17607,GRP_DBH,DBH,12.15 -US-Ha1,17607,GRP_DBH,DBH_SPP,Acer pennsylvanicum -US-Ha1,17607,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17607,GRP_DBH,DBH_DATE,20081120 -US-Ha1,17607,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17607,GRP_DBH,DBH_SPATIAL_REP_NUMBER,2 -US-Ha1,17607,GRP_DBH,DBH_SPATIAL_VARIABILITY,0.38 -US-Ha1,17787,GRP_DBH,DBH,12.19 -US-Ha1,17787,GRP_DBH,DBH_SPP,Acer pennsylvanicum -US-Ha1,17787,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17787,GRP_DBH,DBH_DATE,20121204 -US-Ha1,17787,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17787,GRP_DBH,DBH_SPATIAL_REP_NUMBER,1 -US-Ha1,17652,GRP_DBH,DBH,12.25 -US-Ha1,17652,GRP_DBH,DBH_SPP,Acer pennsylvanicum -US-Ha1,17652,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17652,GRP_DBH,DBH_DATE,20091201 -US-Ha1,17652,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17652,GRP_DBH,DBH_SPATIAL_REP_NUMBER,2 -US-Ha1,17652,GRP_DBH,DBH_SPATIAL_VARIABILITY,0.34 -US-Ha1,17697,GRP_DBH,DBH,12.3 -US-Ha1,17697,GRP_DBH,DBH_SPP,Acer pennsylvanicum -US-Ha1,17697,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17697,GRP_DBH,DBH_DATE,20101207 -US-Ha1,17697,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17697,GRP_DBH,DBH_SPATIAL_REP_NUMBER,2 -US-Ha1,17697,GRP_DBH,DBH_SPATIAL_VARIABILITY,0.31 -US-Ha1,18125,GRP_DBH,DBH,12.31 -US-Ha1,18125,GRP_DBH,DBH_SPP,Acer pennsylvanicum -US-Ha1,18125,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,18125,GRP_DBH,DBH_DATE,20031113 -US-Ha1,18125,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,18125,GRP_DBH,DBH_SPATIAL_REP_NUMBER,6 -US-Ha1,18125,GRP_DBH,DBH_SPATIAL_VARIABILITY,1.18 -US-Ha1,17742,GRP_DBH,DBH,12.35 -US-Ha1,17742,GRP_DBH,DBH_SPP,Acer pennsylvanicum -US-Ha1,17742,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17742,GRP_DBH,DBH_DATE,20111201 -US-Ha1,17742,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17742,GRP_DBH,DBH_SPATIAL_REP_NUMBER,2 -US-Ha1,17742,GRP_DBH,DBH_SPATIAL_VARIABILITY,0.25 -US-Ha1,18245,GRP_DBH,DBH,12.39 -US-Ha1,18245,GRP_DBH,DBH_SPP,Acer pennsylvanicum -US-Ha1,18245,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,18245,GRP_DBH,DBH_DATE,20051102 -US-Ha1,18245,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,18245,GRP_DBH,DBH_SPATIAL_REP_NUMBER,4 -US-Ha1,18245,GRP_DBH,DBH_SPATIAL_VARIABILITY,1.02 -US-Ha1,17886,GRP_DBH,DBH,12.43 -US-Ha1,17886,GRP_DBH,DBH_SPP,Acer pennsylvanicum -US-Ha1,17886,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17886,GRP_DBH,DBH_DATE,19991027 -US-Ha1,17886,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17886,GRP_DBH,DBH_SPATIAL_REP_NUMBER,4 -US-Ha1,17886,GRP_DBH,DBH_SPATIAL_VARIABILITY,1.21 -US-Ha1,18185,GRP_DBH,DBH,12.54 -US-Ha1,18185,GRP_DBH,DBH_SPP,Acer pennsylvanicum -US-Ha1,18185,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,18185,GRP_DBH,DBH_DATE,20041103 -US-Ha1,18185,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,18185,GRP_DBH,DBH_SPATIAL_REP_NUMBER,5 -US-Ha1,18185,GRP_DBH,DBH_SPATIAL_VARIABILITY,1.12 -US-Ha1,17832,GRP_DBH,DBH,12.93 -US-Ha1,17832,GRP_DBH,DBH_SPP,Acer pennsylvanicum -US-Ha1,17832,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17832,GRP_DBH,DBH_DATE,20131212 -US-Ha1,17832,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17832,GRP_DBH,DBH_SPATIAL_REP_NUMBER,1 -US-Ha1,17628,GRP_DBH,DBH,15.49 -US-Ha1,17628,GRP_DBH,DBH_SPP,Fagus grandifolia -US-Ha1,17628,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17628,GRP_DBH,DBH_DATE,20091201 -US-Ha1,17628,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17628,GRP_DBH,DBH_SPATIAL_REP_NUMBER,17 -US-Ha1,17628,GRP_DBH,DBH_SPATIAL_VARIABILITY,6.07 -US-Ha1,17763,GRP_DBH,DBH,15.5 -US-Ha1,17763,GRP_DBH,DBH_SPP,Fagus grandifolia -US-Ha1,17763,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17763,GRP_DBH,DBH_DATE,20121204 -US-Ha1,17763,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17763,GRP_DBH,DBH_SPATIAL_REP_NUMBER,18 -US-Ha1,17763,GRP_DBH,DBH_SPATIAL_VARIABILITY,5.47 -US-Ha1,17538,GRP_DBH,DBH,15.57 -US-Ha1,17538,GRP_DBH,DBH_SPP,Fagus grandifolia -US-Ha1,17538,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17538,GRP_DBH,DBH_DATE,20071120 -US-Ha1,17538,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17538,GRP_DBH,DBH_SPATIAL_REP_NUMBER,15 -US-Ha1,17538,GRP_DBH,DBH_SPATIAL_VARIABILITY,6.27 -US-Ha1,17718,GRP_DBH,DBH,15.67 -US-Ha1,17718,GRP_DBH,DBH_SPP,Fagus grandifolia -US-Ha1,17718,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17718,GRP_DBH,DBH_DATE,20111201 -US-Ha1,17718,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17718,GRP_DBH,DBH_SPATIAL_REP_NUMBER,19 -US-Ha1,17718,GRP_DBH,DBH_SPATIAL_VARIABILITY,5.79 -US-Ha1,17583,GRP_DBH,DBH,15.82 -US-Ha1,17583,GRP_DBH,DBH_SPP,Fagus grandifolia -US-Ha1,17583,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17583,GRP_DBH,DBH_DATE,20081120 -US-Ha1,17583,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17583,GRP_DBH,DBH_SPATIAL_REP_NUMBER,15 -US-Ha1,17583,GRP_DBH,DBH_SPATIAL_VARIABILITY,6.28 -US-Ha1,17673,GRP_DBH,DBH,15.88 -US-Ha1,17673,GRP_DBH,DBH_SPP,Fagus grandifolia -US-Ha1,17673,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17673,GRP_DBH,DBH_DATE,20101207 -US-Ha1,17673,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17673,GRP_DBH,DBH_SPATIAL_REP_NUMBER,17 -US-Ha1,17673,GRP_DBH,DBH_SPATIAL_VARIABILITY,5.99 -US-Ha1,17808,GRP_DBH,DBH,15.92 -US-Ha1,17808,GRP_DBH,DBH_SPP,Fagus grandifolia -US-Ha1,17808,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17808,GRP_DBH,DBH_DATE,20131212 -US-Ha1,17808,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17808,GRP_DBH,DBH_SPATIAL_REP_NUMBER,18 -US-Ha1,17808,GRP_DBH,DBH_SPATIAL_VARIABILITY,5.41 -US-Ha1,18213,GRP_DBH,DBH,16.31 -US-Ha1,18213,GRP_DBH,DBH_SPP,Fagus grandifolia -US-Ha1,18213,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,18213,GRP_DBH,DBH_DATE,20051102 -US-Ha1,18213,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,18213,GRP_DBH,DBH_SPATIAL_REP_NUMBER,12 -US-Ha1,18213,GRP_DBH,DBH_SPATIAL_VARIABILITY,6.45 -US-Ha1,17449,GRP_DBH,DBH,16.48 -US-Ha1,17449,GRP_DBH,DBH_SPP,Betula alleghaniensis -US-Ha1,17449,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17449,GRP_DBH,DBH_DATE,1993 -US-Ha1,17449,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17449,GRP_DBH,DBH_SPATIAL_REP_NUMBER,49 -US-Ha1,17449,GRP_DBH,DBH_SPATIAL_VARIABILITY,6.8 -US-Ha1,18268,GRP_DBH,DBH,16.53 -US-Ha1,18268,GRP_DBH,DBH_SPP,Fagus grandifolia -US-Ha1,18268,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,18268,GRP_DBH,DBH_DATE,20061114 -US-Ha1,18268,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,18268,GRP_DBH,DBH_SPATIAL_REP_NUMBER,12 -US-Ha1,18268,GRP_DBH,DBH_SPATIAL_VARIABILITY,6.49 -US-Ha1,18153,GRP_DBH,DBH,16.63 -US-Ha1,18153,GRP_DBH,DBH_SPP,Fagus grandifolia -US-Ha1,18153,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,18153,GRP_DBH,DBH_DATE,20041103 -US-Ha1,18153,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,18153,GRP_DBH,DBH_SPATIAL_REP_NUMBER,11 -US-Ha1,18153,GRP_DBH,DBH_SPATIAL_VARIABILITY,6.48 -US-Ha1,17961,GRP_DBH,DBH,16.77 -US-Ha1,17961,GRP_DBH,DBH_SPP,Betula alleghaniensis -US-Ha1,17961,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17961,GRP_DBH,DBH_DATE,20001024 -US-Ha1,17961,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17961,GRP_DBH,DBH_SPATIAL_REP_NUMBER,50 -US-Ha1,17961,GRP_DBH,DBH_SPATIAL_VARIABILITY,6.84 -US-Ha1,17515,GRP_DBH,DBH,17.16 -US-Ha1,17515,GRP_DBH,DBH_SPP,Betula alleghaniensis -US-Ha1,17515,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17515,GRP_DBH,DBH_DATE,19981030 -US-Ha1,17515,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17515,GRP_DBH,DBH_SPATIAL_REP_NUMBER,46 -US-Ha1,17515,GRP_DBH,DBH_SPATIAL_VARIABILITY,6.84 -US-Ha1,17443,GRP_DBH,DBH,17.17 -US-Ha1,17443,GRP_DBH,DBH_SPP,Picea glauca -US-Ha1,17443,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17443,GRP_DBH,DBH_DATE,1993 -US-Ha1,17443,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17443,GRP_DBH,DBH_SPATIAL_REP_NUMBER,33 -US-Ha1,17443,GRP_DBH,DBH_SPATIAL_VARIABILITY,3.72 -US-Ha1,17902,GRP_DBH,DBH,17.35 -US-Ha1,17902,GRP_DBH,DBH_SPP,Betula alleghaniensis -US-Ha1,17902,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17902,GRP_DBH,DBH_DATE,19991027 -US-Ha1,17902,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17902,GRP_DBH,DBH_SPATIAL_REP_NUMBER,44 -US-Ha1,17902,GRP_DBH,DBH_SPATIAL_VARIABILITY,6.98 -US-Ha1,17854,GRP_DBH,DBH,17.49 -US-Ha1,17854,GRP_DBH,DBH_SPP,Fagus grandifolia -US-Ha1,17854,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17854,GRP_DBH,DBH_DATE,19991027 -US-Ha1,17854,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17854,GRP_DBH,DBH_SPATIAL_REP_NUMBER,8 -US-Ha1,17854,GRP_DBH,DBH_SPATIAL_VARIABILITY,6.25 -US-Ha1,17511,GRP_DBH,DBH,17.62 -US-Ha1,17511,GRP_DBH,DBH_SPP,Picea glauca -US-Ha1,17511,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17511,GRP_DBH,DBH_DATE,19981030 -US-Ha1,17511,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17511,GRP_DBH,DBH_SPATIAL_REP_NUMBER,30 -US-Ha1,17511,GRP_DBH,DBH_SPATIAL_VARIABILITY,3.67 -US-Ha1,17914,GRP_DBH,DBH,17.67 -US-Ha1,17914,GRP_DBH,DBH_SPP,Fagus grandifolia -US-Ha1,17914,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17914,GRP_DBH,DBH_DATE,20001024 -US-Ha1,17914,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17914,GRP_DBH,DBH_SPATIAL_REP_NUMBER,8 -US-Ha1,17914,GRP_DBH,DBH_SPATIAL_VARIABILITY,6.25 -US-Ha1,17407,GRP_DBH,DBH,17.94 -US-Ha1,17407,GRP_DBH,DBH_SPP,Acer rubrum -US-Ha1,17407,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17407,GRP_DBH,DBH_DATE,1993 -US-Ha1,17407,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17407,GRP_DBH,DBH_SPATIAL_REP_NUMBER,342 -US-Ha1,17407,GRP_DBH,DBH_SPATIAL_VARIABILITY,6.75 -US-Ha1,17754,GRP_DBH,DBH,17.94 -US-Ha1,17754,GRP_DBH,DBH_SPP,Betula alleghaniensis -US-Ha1,17754,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17754,GRP_DBH,DBH_DATE,20111201 -US-Ha1,17754,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17754,GRP_DBH,DBH_SPATIAL_REP_NUMBER,37 -US-Ha1,17754,GRP_DBH,DBH_SPATIAL_VARIABILITY,7.78 -US-Ha1,17898,GRP_DBH,DBH,18 -US-Ha1,17898,GRP_DBH,DBH_SPP,Picea glauca -US-Ha1,17898,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17898,GRP_DBH,DBH_DATE,19991027 -US-Ha1,17898,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17898,GRP_DBH,DBH_SPATIAL_REP_NUMBER,27 -US-Ha1,17898,GRP_DBH,DBH_SPATIAL_VARIABILITY,3.57 -US-Ha1,17957,GRP_DBH,DBH,18.01 -US-Ha1,17957,GRP_DBH,DBH_SPP,Picea glauca -US-Ha1,17957,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17957,GRP_DBH,DBH_DATE,20001024 -US-Ha1,17957,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17957,GRP_DBH,DBH_SPATIAL_REP_NUMBER,27 -US-Ha1,17957,GRP_DBH,DBH_SPATIAL_VARIABILITY,3.6 -US-Ha1,17973,GRP_DBH,DBH,18.02 -US-Ha1,17973,GRP_DBH,DBH_SPP,Fagus grandifolia -US-Ha1,17973,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17973,GRP_DBH,DBH_DATE,20011026 -US-Ha1,17973,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17973,GRP_DBH,DBH_SPATIAL_REP_NUMBER,8 -US-Ha1,17973,GRP_DBH,DBH_SPATIAL_VARIABILITY,6.37 -US-Ha1,18021,GRP_DBH,DBH,18.06 -US-Ha1,18021,GRP_DBH,DBH_SPP,Betula alleghaniensis -US-Ha1,18021,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,18021,GRP_DBH,DBH_DATE,20011026 -US-Ha1,18021,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,18021,GRP_DBH,DBH_SPATIAL_REP_NUMBER,39 -US-Ha1,18021,GRP_DBH,DBH_SPATIAL_VARIABILITY,7.48 -US-Ha1,18201,GRP_DBH,DBH,18.13 -US-Ha1,18201,GRP_DBH,DBH_SPP,Betula alleghaniensis -US-Ha1,18201,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,18201,GRP_DBH,DBH_DATE,20041103 -US-Ha1,18201,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,18201,GRP_DBH,DBH_SPATIAL_REP_NUMBER,36 -US-Ha1,18201,GRP_DBH,DBH_SPATIAL_VARIABILITY,7.36 -US-Ha1,17574,GRP_DBH,DBH,18.22 -US-Ha1,17574,GRP_DBH,DBH_SPP,Betula alleghaniensis -US-Ha1,17574,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17574,GRP_DBH,DBH_DATE,20071120 -US-Ha1,17574,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17574,GRP_DBH,DBH_SPATIAL_REP_NUMBER,37 -US-Ha1,17574,GRP_DBH,DBH_SPATIAL_VARIABILITY,7.51 -US-Ha1,17799,GRP_DBH,DBH,18.22 -US-Ha1,17799,GRP_DBH,DBH_SPP,Betula alleghaniensis -US-Ha1,17799,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17799,GRP_DBH,DBH_DATE,20121204 -US-Ha1,17799,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17799,GRP_DBH,DBH_SPATIAL_REP_NUMBER,36 -US-Ha1,17799,GRP_DBH,DBH_SPATIAL_VARIABILITY,7.85 -US-Ha1,18259,GRP_DBH,DBH,18.24 -US-Ha1,18259,GRP_DBH,DBH_SPP,Betula alleghaniensis -US-Ha1,18259,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,18259,GRP_DBH,DBH_DATE,20051102 -US-Ha1,18259,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,18259,GRP_DBH,DBH_SPATIAL_REP_NUMBER,36 -US-Ha1,18259,GRP_DBH,DBH_SPATIAL_VARIABILITY,7.37 -US-Ha1,17487,GRP_DBH,DBH,18.27 -US-Ha1,17487,GRP_DBH,DBH_SPP,Acer rubrum -US-Ha1,17487,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17487,GRP_DBH,DBH_DATE,19981030 -US-Ha1,17487,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17487,GRP_DBH,DBH_SPATIAL_REP_NUMBER,322 -US-Ha1,17487,GRP_DBH,DBH_SPATIAL_VARIABILITY,6.93 -US-Ha1,18081,GRP_DBH,DBH,18.3 -US-Ha1,18081,GRP_DBH,DBH_SPP,Betula alleghaniensis -US-Ha1,18081,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,18081,GRP_DBH,DBH_DATE,20021114 -US-Ha1,18081,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,18081,GRP_DBH,DBH_SPATIAL_REP_NUMBER,37 -US-Ha1,18081,GRP_DBH,DBH_SPATIAL_VARIABILITY,7.76 -US-Ha1,17619,GRP_DBH,DBH,18.31 -US-Ha1,17619,GRP_DBH,DBH_SPP,Betula alleghaniensis -US-Ha1,17619,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17619,GRP_DBH,DBH_DATE,20081120 -US-Ha1,17619,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17619,GRP_DBH,DBH_SPATIAL_REP_NUMBER,37 -US-Ha1,17619,GRP_DBH,DBH_SPATIAL_VARIABILITY,7.52 -US-Ha1,17529,GRP_DBH,DBH,18.32 -US-Ha1,17529,GRP_DBH,DBH_SPP,Betula alleghaniensis -US-Ha1,17529,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17529,GRP_DBH,DBH_DATE,20061114 -US-Ha1,17529,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17529,GRP_DBH,DBH_SPATIAL_REP_NUMBER,36 -US-Ha1,17529,GRP_DBH,DBH_SPATIAL_VARIABILITY,7.5 -US-Ha1,17934,GRP_DBH,DBH,18.37 -US-Ha1,17934,GRP_DBH,DBH_SPP,Acer rubrum -US-Ha1,17934,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17934,GRP_DBH,DBH_DATE,20001024 -US-Ha1,17934,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17934,GRP_DBH,DBH_SPATIAL_REP_NUMBER,315 -US-Ha1,17934,GRP_DBH,DBH_SPATIAL_VARIABILITY,6.99 -US-Ha1,18033,GRP_DBH,DBH,18.37 -US-Ha1,18033,GRP_DBH,DBH_SPP,Fagus grandifolia -US-Ha1,18033,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,18033,GRP_DBH,DBH_DATE,20021114 -US-Ha1,18033,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,18033,GRP_DBH,DBH_SPATIAL_REP_NUMBER,8 -US-Ha1,18033,GRP_DBH,DBH_SPATIAL_VARIABILITY,6.37 -US-Ha1,18141,GRP_DBH,DBH,18.38 -US-Ha1,18141,GRP_DBH,DBH_SPP,Betula alleghaniensis -US-Ha1,18141,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,18141,GRP_DBH,DBH_DATE,20031113 -US-Ha1,18141,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,18141,GRP_DBH,DBH_SPATIAL_REP_NUMBER,37 -US-Ha1,18141,GRP_DBH,DBH_SPATIAL_VARIABILITY,7.6 -US-Ha1,17874,GRP_DBH,DBH,18.48 -US-Ha1,17874,GRP_DBH,DBH_SPP,Acer rubrum -US-Ha1,17874,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17874,GRP_DBH,DBH_DATE,19991027 -US-Ha1,17874,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17874,GRP_DBH,DBH_SPATIAL_REP_NUMBER,307 -US-Ha1,17874,GRP_DBH,DBH_SPATIAL_VARIABILITY,6.94 -US-Ha1,17993,GRP_DBH,DBH,18.48 -US-Ha1,17993,GRP_DBH,DBH_SPP,Acer rubrum -US-Ha1,17993,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17993,GRP_DBH,DBH_DATE,20011026 -US-Ha1,17993,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17993,GRP_DBH,DBH_SPATIAL_REP_NUMBER,277 -US-Ha1,17993,GRP_DBH,DBH_SPATIAL_VARIABILITY,7.05 -US-Ha1,17664,GRP_DBH,DBH,18.49 -US-Ha1,17664,GRP_DBH,DBH_SPP,Betula alleghaniensis -US-Ha1,17664,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17664,GRP_DBH,DBH_DATE,20091201 -US-Ha1,17664,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17664,GRP_DBH,DBH_SPATIAL_REP_NUMBER,36 -US-Ha1,17664,GRP_DBH,DBH_SPATIAL_VARIABILITY,7.65 -US-Ha1,18093,GRP_DBH,DBH,18.5 -US-Ha1,18093,GRP_DBH,DBH_SPP,Fagus grandifolia -US-Ha1,18093,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,18093,GRP_DBH,DBH_DATE,20031113 -US-Ha1,18093,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,18093,GRP_DBH,DBH_SPATIAL_REP_NUMBER,8 -US-Ha1,18093,GRP_DBH,DBH_SPATIAL_VARIABILITY,6.4 -US-Ha1,17844,GRP_DBH,DBH,18.54 -US-Ha1,17844,GRP_DBH,DBH_SPP,Betula alleghaniensis -US-Ha1,17844,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17844,GRP_DBH,DBH_DATE,20131212 -US-Ha1,17844,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17844,GRP_DBH,DBH_SPATIAL_REP_NUMBER,37 -US-Ha1,17844,GRP_DBH,DBH_SPATIAL_VARIABILITY,7.93 -US-Ha1,18077,GRP_DBH,DBH,18.56 -US-Ha1,18077,GRP_DBH,DBH_SPP,Picea glauca -US-Ha1,18077,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,18077,GRP_DBH,DBH_DATE,20021114 -US-Ha1,18077,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,18077,GRP_DBH,DBH_SPATIAL_REP_NUMBER,26 -US-Ha1,18077,GRP_DBH,DBH_SPATIAL_VARIABILITY,3.41 -US-Ha1,18017,GRP_DBH,DBH,18.59 -US-Ha1,18017,GRP_DBH,DBH_SPP,Picea glauca -US-Ha1,18017,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,18017,GRP_DBH,DBH_DATE,20011026 -US-Ha1,18017,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,18017,GRP_DBH,DBH_SPATIAL_REP_NUMBER,26 -US-Ha1,18017,GRP_DBH,DBH_SPATIAL_VARIABILITY,3.46 -US-Ha1,18053,GRP_DBH,DBH,18.63 -US-Ha1,18053,GRP_DBH,DBH_SPP,Acer rubrum -US-Ha1,18053,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,18053,GRP_DBH,DBH_DATE,20021114 -US-Ha1,18053,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,18053,GRP_DBH,DBH_SPATIAL_REP_NUMBER,266 -US-Ha1,18053,GRP_DBH,DBH_SPATIAL_VARIABILITY,7.01 -US-Ha1,17709,GRP_DBH,DBH,18.69 -US-Ha1,17709,GRP_DBH,DBH_SPP,Betula alleghaniensis -US-Ha1,17709,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17709,GRP_DBH,DBH_DATE,20101207 -US-Ha1,17709,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17709,GRP_DBH,DBH_SPATIAL_REP_NUMBER,35 -US-Ha1,17709,GRP_DBH,DBH_SPATIAL_VARIABILITY,7.75 -US-Ha1,18113,GRP_DBH,DBH,18.79 -US-Ha1,18113,GRP_DBH,DBH_SPP,Acer rubrum -US-Ha1,18113,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,18113,GRP_DBH,DBH_DATE,20031113 -US-Ha1,18113,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,18113,GRP_DBH,DBH_SPATIAL_REP_NUMBER,260 -US-Ha1,18113,GRP_DBH,DBH_SPATIAL_VARIABILITY,7.02 -US-Ha1,17395,GRP_DBH,DBH,18.8 -US-Ha1,17395,GRP_DBH,DBH_SPP,Betula populifolia -US-Ha1,17395,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17395,GRP_DBH,DBH_DATE,1993 -US-Ha1,17395,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17395,GRP_DBH,DBH_SPATIAL_REP_NUMBER,20 -US-Ha1,17395,GRP_DBH,DBH_SPATIAL_VARIABILITY,4.05 -US-Ha1,17706,GRP_DBH,DBH,18.83 -US-Ha1,17706,GRP_DBH,DBH_SPP,Picea glauca -US-Ha1,17706,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17706,GRP_DBH,DBH_DATE,20101207 -US-Ha1,17706,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17706,GRP_DBH,DBH_SPATIAL_REP_NUMBER,21 -US-Ha1,17706,GRP_DBH,DBH_SPATIAL_VARIABILITY,2.52 -US-Ha1,18173,GRP_DBH,DBH,18.84 -US-Ha1,18173,GRP_DBH,DBH_SPP,Acer rubrum -US-Ha1,18173,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,18173,GRP_DBH,DBH_DATE,20041103 -US-Ha1,18173,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,18173,GRP_DBH,DBH_SPATIAL_REP_NUMBER,261 -US-Ha1,18173,GRP_DBH,DBH_SPATIAL_VARIABILITY,7.07 -US-Ha1,17751,GRP_DBH,DBH,18.85 -US-Ha1,17751,GRP_DBH,DBH_SPP,Picea glauca -US-Ha1,17751,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17751,GRP_DBH,DBH_DATE,20111201 -US-Ha1,17751,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17751,GRP_DBH,DBH_SPATIAL_REP_NUMBER,20 -US-Ha1,17751,GRP_DBH,DBH_SPATIAL_VARIABILITY,2.6 -US-Ha1,18137,GRP_DBH,DBH,18.91 -US-Ha1,18137,GRP_DBH,DBH_SPP,Picea glauca -US-Ha1,18137,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,18137,GRP_DBH,DBH_DATE,20031113 -US-Ha1,18137,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,18137,GRP_DBH,DBH_SPATIAL_REP_NUMBER,25 -US-Ha1,18137,GRP_DBH,DBH_SPATIAL_VARIABILITY,3.51 -US-Ha1,18197,GRP_DBH,DBH,18.93 -US-Ha1,18197,GRP_DBH,DBH_SPP,Picea glauca -US-Ha1,18197,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,18197,GRP_DBH,DBH_DATE,20041103 -US-Ha1,18197,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,18197,GRP_DBH,DBH_SPATIAL_REP_NUMBER,25 -US-Ha1,18197,GRP_DBH,DBH_SPATIAL_VARIABILITY,3.52 -US-Ha1,17661,GRP_DBH,DBH,18.95 -US-Ha1,17661,GRP_DBH,DBH_SPP,Picea glauca -US-Ha1,17661,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17661,GRP_DBH,DBH_DATE,20091201 -US-Ha1,17661,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17661,GRP_DBH,DBH_SPATIAL_REP_NUMBER,23 -US-Ha1,17661,GRP_DBH,DBH_SPATIAL_VARIABILITY,3.03 -US-Ha1,18233,GRP_DBH,DBH,18.95 -US-Ha1,18233,GRP_DBH,DBH_SPP,Acer rubrum -US-Ha1,18233,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,18233,GRP_DBH,DBH_DATE,20051102 -US-Ha1,18233,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,18233,GRP_DBH,DBH_SPATIAL_REP_NUMBER,261 -US-Ha1,18233,GRP_DBH,DBH_SPATIAL_VARIABILITY,7.24 -US-Ha1,18256,GRP_DBH,DBH,18.96 -US-Ha1,18256,GRP_DBH,DBH_SPP,Picea glauca -US-Ha1,18256,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,18256,GRP_DBH,DBH_DATE,20051102 -US-Ha1,18256,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,18256,GRP_DBH,DBH_SPATIAL_REP_NUMBER,25 -US-Ha1,18256,GRP_DBH,DBH_SPATIAL_VARIABILITY,3.53 -US-Ha1,17796,GRP_DBH,DBH,18.99 -US-Ha1,17796,GRP_DBH,DBH_SPP,Picea glauca -US-Ha1,17796,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17796,GRP_DBH,DBH_DATE,20121204 -US-Ha1,17796,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17796,GRP_DBH,DBH_SPATIAL_REP_NUMBER,14 -US-Ha1,17796,GRP_DBH,DBH_SPATIAL_VARIABILITY,2.9 -US-Ha1,17377,GRP_DBH,DBH,19.07 -US-Ha1,17377,GRP_DBH,DBH_SPP,Fagus grandifolia -US-Ha1,17377,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17377,GRP_DBH,DBH_DATE,1993 -US-Ha1,17377,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17377,GRP_DBH,DBH_SPATIAL_REP_NUMBER,9 -US-Ha1,17377,GRP_DBH,DBH_SPATIAL_VARIABILITY,11.92 -US-Ha1,17535,GRP_DBH,DBH,19.09 -US-Ha1,17535,GRP_DBH,DBH_SPP,Betula lenta -US-Ha1,17535,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17535,GRP_DBH,DBH_DATE,20071120 -US-Ha1,17535,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17535,GRP_DBH,DBH_SPATIAL_REP_NUMBER,13 -US-Ha1,17535,GRP_DBH,DBH_SPATIAL_VARIABILITY,10.26 -US-Ha1,17841,GRP_DBH,DBH,19.12 -US-Ha1,17841,GRP_DBH,DBH_SPP,Picea glauca -US-Ha1,17841,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17841,GRP_DBH,DBH_DATE,20131212 -US-Ha1,17841,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17841,GRP_DBH,DBH_SPATIAL_REP_NUMBER,13 -US-Ha1,17841,GRP_DBH,DBH_SPATIAL_VARIABILITY,2.99 -US-Ha1,17526,GRP_DBH,DBH,19.14 -US-Ha1,17526,GRP_DBH,DBH_SPP,Picea glauca -US-Ha1,17526,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17526,GRP_DBH,DBH_DATE,20061114 -US-Ha1,17526,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17526,GRP_DBH,DBH_SPATIAL_REP_NUMBER,24 -US-Ha1,17526,GRP_DBH,DBH_SPATIAL_VARIABILITY,3.18 -US-Ha1,17715,GRP_DBH,DBH,19.15 -US-Ha1,17715,GRP_DBH,DBH_SPP,Betula lenta -US-Ha1,17715,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17715,GRP_DBH,DBH_DATE,20111201 -US-Ha1,17715,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17715,GRP_DBH,DBH_SPATIAL_REP_NUMBER,14 -US-Ha1,17715,GRP_DBH,DBH_SPATIAL_VARIABILITY,10.15 -US-Ha1,17571,GRP_DBH,DBH,19.16 -US-Ha1,17571,GRP_DBH,DBH_SPP,Picea glauca -US-Ha1,17571,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17571,GRP_DBH,DBH_DATE,20071120 -US-Ha1,17571,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17571,GRP_DBH,DBH_SPATIAL_REP_NUMBER,24 -US-Ha1,17571,GRP_DBH,DBH_SPATIAL_VARIABILITY,3.18 -US-Ha1,17616,GRP_DBH,DBH,19.17 -US-Ha1,17616,GRP_DBH,DBH_SPP,Picea glauca -US-Ha1,17616,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17616,GRP_DBH,DBH_DATE,20081120 -US-Ha1,17616,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17616,GRP_DBH,DBH_SPATIAL_REP_NUMBER,24 -US-Ha1,17616,GRP_DBH,DBH_SPATIAL_VARIABILITY,3.19 -US-Ha1,18283,GRP_DBH,DBH,19.24 -US-Ha1,18283,GRP_DBH,DBH_SPP,Acer rubrum -US-Ha1,18283,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,18283,GRP_DBH,DBH_DATE,20061114 -US-Ha1,18283,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,18283,GRP_DBH,DBH_SPATIAL_REP_NUMBER,255 -US-Ha1,18283,GRP_DBH,DBH_SPATIAL_VARIABILITY,7.24 -US-Ha1,17580,GRP_DBH,DBH,19.25 -US-Ha1,17580,GRP_DBH,DBH_SPP,Betula lenta -US-Ha1,17580,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17580,GRP_DBH,DBH_DATE,20081120 -US-Ha1,17580,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17580,GRP_DBH,DBH_SPATIAL_REP_NUMBER,13 -US-Ha1,17580,GRP_DBH,DBH_SPATIAL_VARIABILITY,10.27 -US-Ha1,17760,GRP_DBH,DBH,19.26 -US-Ha1,17760,GRP_DBH,DBH_SPP,Betula lenta -US-Ha1,17760,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17760,GRP_DBH,DBH_DATE,20121204 -US-Ha1,17760,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17760,GRP_DBH,DBH_SPATIAL_REP_NUMBER,14 -US-Ha1,17760,GRP_DBH,DBH_SPATIAL_VARIABILITY,10.13 -US-Ha1,17553,GRP_DBH,DBH,19.29 -US-Ha1,17553,GRP_DBH,DBH_SPP,Acer rubrum -US-Ha1,17553,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17553,GRP_DBH,DBH_DATE,20071120 -US-Ha1,17553,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17553,GRP_DBH,DBH_SPATIAL_REP_NUMBER,251 -US-Ha1,17553,GRP_DBH,DBH_SPATIAL_VARIABILITY,7.33 -US-Ha1,17625,GRP_DBH,DBH,19.45 -US-Ha1,17625,GRP_DBH,DBH_SPP,Betula lenta -US-Ha1,17625,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17625,GRP_DBH,DBH_DATE,20091201 -US-Ha1,17625,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17625,GRP_DBH,DBH_SPATIAL_REP_NUMBER,13 -US-Ha1,17625,GRP_DBH,DBH_SPATIAL_VARIABILITY,10.25 -US-Ha1,17371,GRP_DBH,DBH,19.48 -US-Ha1,17371,GRP_DBH,DBH_SPP,Betula lenta -US-Ha1,17371,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17371,GRP_DBH,DBH_DATE,1993 -US-Ha1,17371,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17371,GRP_DBH,DBH_SPATIAL_REP_NUMBER,14 -US-Ha1,17371,GRP_DBH,DBH_SPATIAL_VARIABILITY,8.55 -US-Ha1,17598,GRP_DBH,DBH,19.49 -US-Ha1,17598,GRP_DBH,DBH_SPP,Acer rubrum -US-Ha1,17598,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17598,GRP_DBH,DBH_DATE,20081120 -US-Ha1,17598,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17598,GRP_DBH,DBH_SPATIAL_REP_NUMBER,246 -US-Ha1,17598,GRP_DBH,DBH_SPATIAL_VARIABILITY,7.44 -US-Ha1,17479,GRP_DBH,DBH,19.53 -US-Ha1,17479,GRP_DBH,DBH_SPP,Betula populifolia -US-Ha1,17479,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17479,GRP_DBH,DBH_DATE,19981030 -US-Ha1,17479,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17479,GRP_DBH,DBH_SPATIAL_REP_NUMBER,14 -US-Ha1,17479,GRP_DBH,DBH_SPATIAL_VARIABILITY,4.45 -US-Ha1,17670,GRP_DBH,DBH,19.68 -US-Ha1,17670,GRP_DBH,DBH_SPP,Betula lenta -US-Ha1,17670,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17670,GRP_DBH,DBH_DATE,20101207 -US-Ha1,17670,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17670,GRP_DBH,DBH_SPATIAL_REP_NUMBER,13 -US-Ha1,17670,GRP_DBH,DBH_SPATIAL_VARIABILITY,10.25 -US-Ha1,17465,GRP_DBH,DBH,19.69 -US-Ha1,17465,GRP_DBH,DBH_SPP,Fagus grandifolia -US-Ha1,17465,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17465,GRP_DBH,DBH_DATE,19981030 -US-Ha1,17465,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17465,GRP_DBH,DBH_SPATIAL_REP_NUMBER,10 -US-Ha1,17465,GRP_DBH,DBH_SPATIAL_VARIABILITY,11.61 -US-Ha1,17643,GRP_DBH,DBH,19.88 -US-Ha1,17643,GRP_DBH,DBH_SPP,Acer rubrum -US-Ha1,17643,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17643,GRP_DBH,DBH_DATE,20091201 -US-Ha1,17643,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17643,GRP_DBH,DBH_SPATIAL_REP_NUMBER,237 -US-Ha1,17643,GRP_DBH,DBH_SPATIAL_VARIABILITY,7.51 -US-Ha1,17688,GRP_DBH,DBH,20.04 -US-Ha1,17688,GRP_DBH,DBH_SPP,Acer rubrum -US-Ha1,17688,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17688,GRP_DBH,DBH_DATE,20101207 -US-Ha1,17688,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17688,GRP_DBH,DBH_SPATIAL_REP_NUMBER,235 -US-Ha1,17688,GRP_DBH,DBH_SPATIAL_VARIABILITY,7.56 -US-Ha1,17733,GRP_DBH,DBH,20.17 -US-Ha1,17733,GRP_DBH,DBH_SPP,Acer rubrum -US-Ha1,17733,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17733,GRP_DBH,DBH_DATE,20111201 -US-Ha1,17733,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17733,GRP_DBH,DBH_SPATIAL_REP_NUMBER,233 -US-Ha1,17733,GRP_DBH,DBH_SPATIAL_VARIABILITY,7.66 -US-Ha1,18149,GRP_DBH,DBH,20.19 -US-Ha1,18149,GRP_DBH,DBH_SPP,Betula lenta -US-Ha1,18149,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,18149,GRP_DBH,DBH_DATE,20041103 -US-Ha1,18149,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,18149,GRP_DBH,DBH_SPATIAL_REP_NUMBER,11 -US-Ha1,18149,GRP_DBH,DBH_SPATIAL_VARIABILITY,10.56 -US-Ha1,17805,GRP_DBH,DBH,20.23 -US-Ha1,17805,GRP_DBH,DBH_SPP,Betula lenta -US-Ha1,17805,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17805,GRP_DBH,DBH_DATE,20131212 -US-Ha1,17805,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17805,GRP_DBH,DBH_SPATIAL_REP_NUMBER,14 -US-Ha1,17805,GRP_DBH,DBH_SPATIAL_VARIABILITY,10.1 -US-Ha1,18209,GRP_DBH,DBH,20.36 -US-Ha1,18209,GRP_DBH,DBH_SPP,Betula lenta -US-Ha1,18209,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,18209,GRP_DBH,DBH_DATE,20051102 -US-Ha1,18209,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,18209,GRP_DBH,DBH_SPATIAL_REP_NUMBER,11 -US-Ha1,18209,GRP_DBH,DBH_SPATIAL_VARIABILITY,10.57 -US-Ha1,17460,GRP_DBH,DBH,20.42 -US-Ha1,17460,GRP_DBH,DBH_SPP,Betula lenta -US-Ha1,17460,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17460,GRP_DBH,DBH_DATE,19981030 -US-Ha1,17460,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17460,GRP_DBH,DBH_SPATIAL_REP_NUMBER,14 -US-Ha1,17460,GRP_DBH,DBH_SPATIAL_VARIABILITY,8.5 -US-Ha1,17778,GRP_DBH,DBH,20.52 -US-Ha1,17778,GRP_DBH,DBH_SPP,Acer rubrum -US-Ha1,17778,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17778,GRP_DBH,DBH_DATE,20121204 -US-Ha1,17778,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17778,GRP_DBH,DBH_SPATIAL_REP_NUMBER,226 -US-Ha1,17778,GRP_DBH,DBH_SPATIAL_VARIABILITY,7.66 -US-Ha1,18265,GRP_DBH,DBH,20.55 -US-Ha1,18265,GRP_DBH,DBH_SPP,Betula lenta -US-Ha1,18265,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,18265,GRP_DBH,DBH_DATE,20061114 -US-Ha1,18265,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,18265,GRP_DBH,DBH_SPATIAL_REP_NUMBER,11 -US-Ha1,18265,GRP_DBH,DBH_SPATIAL_VARIABILITY,10.4 -US-Ha1,17431,GRP_DBH,DBH,20.86 -US-Ha1,17431,GRP_DBH,DBH_SPP,Betula papyrifera -US-Ha1,17431,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17431,GRP_DBH,DBH_DATE,1993 -US-Ha1,17431,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17431,GRP_DBH,DBH_SPATIAL_REP_NUMBER,9 -US-Ha1,17431,GRP_DBH,DBH_SPATIAL_VARIABILITY,6.69 -US-Ha1,17850,GRP_DBH,DBH,20.87 -US-Ha1,17850,GRP_DBH,DBH_SPP,Betula lenta -US-Ha1,17850,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17850,GRP_DBH,DBH_DATE,19991027 -US-Ha1,17850,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17850,GRP_DBH,DBH_SPATIAL_REP_NUMBER,10 -US-Ha1,17850,GRP_DBH,DBH_SPATIAL_VARIABILITY,10.06 -US-Ha1,17823,GRP_DBH,DBH,20.89 -US-Ha1,17823,GRP_DBH,DBH_SPP,Acer rubrum -US-Ha1,17823,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17823,GRP_DBH,DBH_DATE,20131212 -US-Ha1,17823,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17823,GRP_DBH,DBH_SPATIAL_REP_NUMBER,225 -US-Ha1,17823,GRP_DBH,DBH_SPATIAL_VARIABILITY,7.76 -US-Ha1,17866,GRP_DBH,DBH,21.08 -US-Ha1,17866,GRP_DBH,DBH_SPP,Betula populifolia -US-Ha1,17866,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17866,GRP_DBH,DBH_DATE,19991027 -US-Ha1,17866,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17866,GRP_DBH,DBH_SPATIAL_REP_NUMBER,8 -US-Ha1,17866,GRP_DBH,DBH_SPATIAL_VARIABILITY,3.72 -US-Ha1,18165,GRP_DBH,DBH,21.14 -US-Ha1,18165,GRP_DBH,DBH_SPP,Betula populifolia -US-Ha1,18165,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,18165,GRP_DBH,DBH_DATE,20041103 -US-Ha1,18165,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,18165,GRP_DBH,DBH_SPATIAL_REP_NUMBER,7 -US-Ha1,18165,GRP_DBH,DBH_SPATIAL_VARIABILITY,3.81 -US-Ha1,17926,GRP_DBH,DBH,21.16 -US-Ha1,17926,GRP_DBH,DBH_SPP,Betula populifolia -US-Ha1,17926,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17926,GRP_DBH,DBH_DATE,20001024 -US-Ha1,17926,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17926,GRP_DBH,DBH_SPATIAL_REP_NUMBER,8 -US-Ha1,17926,GRP_DBH,DBH_SPATIAL_VARIABILITY,3.73 -US-Ha1,17985,GRP_DBH,DBH,21.19 -US-Ha1,17985,GRP_DBH,DBH_SPP,Betula populifolia -US-Ha1,17985,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17985,GRP_DBH,DBH_DATE,20011026 -US-Ha1,17985,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17985,GRP_DBH,DBH_SPATIAL_REP_NUMBER,8 -US-Ha1,17985,GRP_DBH,DBH_SPATIAL_VARIABILITY,3.75 -US-Ha1,17503,GRP_DBH,DBH,21.2 -US-Ha1,17503,GRP_DBH,DBH_SPP,Betula papyrifera -US-Ha1,17503,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17503,GRP_DBH,DBH_DATE,19981030 -US-Ha1,17503,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17503,GRP_DBH,DBH_SPATIAL_REP_NUMBER,8 -US-Ha1,17503,GRP_DBH,DBH_SPATIAL_VARIABILITY,7.32 -US-Ha1,18225,GRP_DBH,DBH,21.2 -US-Ha1,18225,GRP_DBH,DBH_SPP,Betula populifolia -US-Ha1,18225,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,18225,GRP_DBH,DBH_DATE,20051102 -US-Ha1,18225,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,18225,GRP_DBH,DBH_SPATIAL_REP_NUMBER,7 -US-Ha1,18225,GRP_DBH,DBH_SPATIAL_VARIABILITY,3.82 -US-Ha1,17890,GRP_DBH,DBH,21.25 -US-Ha1,17890,GRP_DBH,DBH_SPP,Betula papyrifera -US-Ha1,17890,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17890,GRP_DBH,DBH_DATE,19991027 -US-Ha1,17890,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17890,GRP_DBH,DBH_SPATIAL_REP_NUMBER,8 -US-Ha1,17890,GRP_DBH,DBH_SPATIAL_VARIABILITY,7.34 -US-Ha1,17950,GRP_DBH,DBH,21.28 -US-Ha1,17950,GRP_DBH,DBH_SPP,Betula papyrifera -US-Ha1,17950,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17950,GRP_DBH,DBH_DATE,20001024 -US-Ha1,17950,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17950,GRP_DBH,DBH_SPATIAL_REP_NUMBER,8 -US-Ha1,17950,GRP_DBH,DBH_SPATIAL_VARIABILITY,7.36 -US-Ha1,18277,GRP_DBH,DBH,21.29 -US-Ha1,18277,GRP_DBH,DBH_SPP,Betula populifolia -US-Ha1,18277,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,18277,GRP_DBH,DBH_DATE,20061114 -US-Ha1,18277,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,18277,GRP_DBH,DBH_SPATIAL_REP_NUMBER,7 -US-Ha1,18277,GRP_DBH,DBH_SPATIAL_VARIABILITY,3.8 -US-Ha1,18009,GRP_DBH,DBH,21.38 -US-Ha1,18009,GRP_DBH,DBH_SPP,Betula papyrifera -US-Ha1,18009,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,18009,GRP_DBH,DBH_DATE,20011026 -US-Ha1,18009,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,18009,GRP_DBH,DBH_SPATIAL_REP_NUMBER,8 -US-Ha1,18009,GRP_DBH,DBH_SPATIAL_VARIABILITY,7.36 -US-Ha1,18045,GRP_DBH,DBH,21.45 -US-Ha1,18045,GRP_DBH,DBH_SPP,Betula populifolia -US-Ha1,18045,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,18045,GRP_DBH,DBH_DATE,20021114 -US-Ha1,18045,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,18045,GRP_DBH,DBH_SPATIAL_REP_NUMBER,8 -US-Ha1,18045,GRP_DBH,DBH_SPATIAL_VARIABILITY,3.65 -US-Ha1,18105,GRP_DBH,DBH,21.46 -US-Ha1,18105,GRP_DBH,DBH_SPP,Betula populifolia -US-Ha1,18105,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,18105,GRP_DBH,DBH_DATE,20031113 -US-Ha1,18105,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,18105,GRP_DBH,DBH_SPATIAL_REP_NUMBER,8 -US-Ha1,18105,GRP_DBH,DBH_SPATIAL_VARIABILITY,3.69 -US-Ha1,17910,GRP_DBH,DBH,21.51 -US-Ha1,17910,GRP_DBH,DBH_SPP,Betula lenta -US-Ha1,17910,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17910,GRP_DBH,DBH_DATE,20001024 -US-Ha1,17910,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17910,GRP_DBH,DBH_SPATIAL_REP_NUMBER,9 -US-Ha1,17910,GRP_DBH,DBH_SPATIAL_VARIABILITY,10.5 -US-Ha1,17969,GRP_DBH,DBH,21.75 -US-Ha1,17969,GRP_DBH,DBH_SPP,Betula lenta -US-Ha1,17969,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17969,GRP_DBH,DBH_DATE,20011026 -US-Ha1,17969,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17969,GRP_DBH,DBH_SPATIAL_REP_NUMBER,9 -US-Ha1,17969,GRP_DBH,DBH_SPATIAL_VARIABILITY,10.51 -US-Ha1,17547,GRP_DBH,DBH,21.77 -US-Ha1,17547,GRP_DBH,DBH_SPP,Betula populifolia -US-Ha1,17547,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17547,GRP_DBH,DBH_DATE,20071120 -US-Ha1,17547,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17547,GRP_DBH,DBH_SPATIAL_REP_NUMBER,5 -US-Ha1,17547,GRP_DBH,DBH_SPATIAL_VARIABILITY,4.63 -US-Ha1,17592,GRP_DBH,DBH,21.85 -US-Ha1,17592,GRP_DBH,DBH_SPP,Betula populifolia -US-Ha1,17592,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17592,GRP_DBH,DBH_DATE,20081120 -US-Ha1,17592,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17592,GRP_DBH,DBH_SPATIAL_REP_NUMBER,5 -US-Ha1,17592,GRP_DBH,DBH_SPATIAL_VARIABILITY,4.65 -US-Ha1,17682,GRP_DBH,DBH,21.86 -US-Ha1,17682,GRP_DBH,DBH_SPP,Betula populifolia -US-Ha1,17682,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17682,GRP_DBH,DBH_DATE,20101207 -US-Ha1,17682,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17682,GRP_DBH,DBH_SPATIAL_REP_NUMBER,4 -US-Ha1,17682,GRP_DBH,DBH_SPATIAL_VARIABILITY,5.37 -US-Ha1,17637,GRP_DBH,DBH,21.92 -US-Ha1,17637,GRP_DBH,DBH_SPP,Betula populifolia -US-Ha1,17637,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17637,GRP_DBH,DBH_DATE,20091201 -US-Ha1,17637,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17637,GRP_DBH,DBH_SPATIAL_REP_NUMBER,5 -US-Ha1,17637,GRP_DBH,DBH_SPATIAL_VARIABILITY,4.64 -US-Ha1,18029,GRP_DBH,DBH,21.92 -US-Ha1,18029,GRP_DBH,DBH_SPP,Betula lenta -US-Ha1,18029,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,18029,GRP_DBH,DBH_DATE,20021114 -US-Ha1,18029,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,18029,GRP_DBH,DBH_SPATIAL_REP_NUMBER,9 -US-Ha1,18029,GRP_DBH,DBH_SPATIAL_VARIABILITY,10.46 -US-Ha1,17727,GRP_DBH,DBH,21.94 -US-Ha1,17727,GRP_DBH,DBH_SPP,Betula populifolia -US-Ha1,17727,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17727,GRP_DBH,DBH_DATE,20111201 -US-Ha1,17727,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17727,GRP_DBH,DBH_SPATIAL_REP_NUMBER,4 -US-Ha1,17727,GRP_DBH,DBH_SPATIAL_VARIABILITY,5.39 -US-Ha1,17772,GRP_DBH,DBH,21.96 -US-Ha1,17772,GRP_DBH,DBH_SPP,Betula populifolia -US-Ha1,17772,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17772,GRP_DBH,DBH_DATE,20121204 -US-Ha1,17772,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17772,GRP_DBH,DBH_SPATIAL_REP_NUMBER,4 -US-Ha1,17772,GRP_DBH,DBH_SPATIAL_VARIABILITY,5.41 -US-Ha1,18089,GRP_DBH,DBH,22.13 -US-Ha1,18089,GRP_DBH,DBH_SPP,Betula lenta -US-Ha1,18089,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,18089,GRP_DBH,DBH_DATE,20031113 -US-Ha1,18089,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,18089,GRP_DBH,DBH_SPATIAL_REP_NUMBER,9 -US-Ha1,18089,GRP_DBH,DBH_SPATIAL_VARIABILITY,10.55 -US-Ha1,17817,GRP_DBH,DBH,22.47 -US-Ha1,17817,GRP_DBH,DBH_SPP,Betula populifolia -US-Ha1,17817,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17817,GRP_DBH,DBH_DATE,20131212 -US-Ha1,17817,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17817,GRP_DBH,DBH_SPATIAL_REP_NUMBER,4 -US-Ha1,17817,GRP_DBH,DBH_SPATIAL_VARIABILITY,5.27 -US-Ha1,18069,GRP_DBH,DBH,22.5 -US-Ha1,18069,GRP_DBH,DBH_SPP,Betula papyrifera -US-Ha1,18069,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,18069,GRP_DBH,DBH_DATE,20021114 -US-Ha1,18069,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,18069,GRP_DBH,DBH_SPATIAL_REP_NUMBER,7 -US-Ha1,18069,GRP_DBH,DBH_SPATIAL_VARIABILITY,7.37 -US-Ha1,17401,GRP_DBH,DBH,22.93 -US-Ha1,17401,GRP_DBH,DBH_SPP,Tsuga canadensis -US-Ha1,17401,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17401,GRP_DBH,DBH_DATE,1993 -US-Ha1,17401,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17401,GRP_DBH,DBH_SPATIAL_REP_NUMBER,82 -US-Ha1,17401,GRP_DBH,DBH_SPATIAL_VARIABILITY,10.37 -US-Ha1,17730,GRP_DBH,DBH,23.22 -US-Ha1,17730,GRP_DBH,DBH_SPP,Tsuga canadensis -US-Ha1,17730,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17730,GRP_DBH,DBH_DATE,20111201 -US-Ha1,17730,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17730,GRP_DBH,DBH_SPATIAL_REP_NUMBER,105 -US-Ha1,17730,GRP_DBH,DBH_SPATIAL_VARIABILITY,11.84 -US-Ha1,17820,GRP_DBH,DBH,23.27 -US-Ha1,17820,GRP_DBH,DBH_SPP,Tsuga canadensis -US-Ha1,17820,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17820,GRP_DBH,DBH_DATE,20131212 -US-Ha1,17820,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17820,GRP_DBH,DBH_SPATIAL_REP_NUMBER,112 -US-Ha1,17820,GRP_DBH,DBH_SPATIAL_VARIABILITY,11.86 -US-Ha1,17775,GRP_DBH,DBH,23.56 -US-Ha1,17775,GRP_DBH,DBH_SPP,Tsuga canadensis -US-Ha1,17775,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17775,GRP_DBH,DBH_DATE,20121204 -US-Ha1,17775,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17775,GRP_DBH,DBH_SPATIAL_REP_NUMBER,105 -US-Ha1,17775,GRP_DBH,DBH_SPATIAL_VARIABILITY,11.8 -US-Ha1,17640,GRP_DBH,DBH,24 -US-Ha1,17640,GRP_DBH,DBH_SPP,Tsuga canadensis -US-Ha1,17640,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17640,GRP_DBH,DBH_DATE,20091201 -US-Ha1,17640,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17640,GRP_DBH,DBH_SPATIAL_REP_NUMBER,96 -US-Ha1,17640,GRP_DBH,DBH_SPATIAL_VARIABILITY,11.63 -US-Ha1,17550,GRP_DBH,DBH,24.01 -US-Ha1,17550,GRP_DBH,DBH_SPP,Tsuga canadensis -US-Ha1,17550,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17550,GRP_DBH,DBH_DATE,20071120 -US-Ha1,17550,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17550,GRP_DBH,DBH_SPATIAL_REP_NUMBER,93 -US-Ha1,17550,GRP_DBH,DBH_SPATIAL_VARIABILITY,11.48 -US-Ha1,17389,GRP_DBH,DBH,24.03 -US-Ha1,17389,GRP_DBH,DBH_SPP,Prunus serotina -US-Ha1,17389,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17389,GRP_DBH,DBH_DATE,1993 -US-Ha1,17389,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17389,GRP_DBH,DBH_SPATIAL_REP_NUMBER,18 -US-Ha1,17389,GRP_DBH,DBH_SPATIAL_VARIABILITY,11.1 -US-Ha1,17930,GRP_DBH,DBH,24.06 -US-Ha1,17930,GRP_DBH,DBH_SPP,Tsuga canadensis -US-Ha1,17930,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17930,GRP_DBH,DBH_DATE,20001024 -US-Ha1,17930,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17930,GRP_DBH,DBH_SPATIAL_REP_NUMBER,85 -US-Ha1,17930,GRP_DBH,DBH_SPATIAL_VARIABILITY,10.71 -US-Ha1,18129,GRP_DBH,DBH,24.11 -US-Ha1,18129,GRP_DBH,DBH_SPP,Betula papyrifera -US-Ha1,18129,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,18129,GRP_DBH,DBH_DATE,20031113 -US-Ha1,18129,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,18129,GRP_DBH,DBH_SPATIAL_REP_NUMBER,6 -US-Ha1,18129,GRP_DBH,DBH_SPATIAL_VARIABILITY,6.34 -US-Ha1,17437,GRP_DBH,DBH,24.2 -US-Ha1,17437,GRP_DBH,DBH_SPP,Pinus strobus -US-Ha1,17437,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17437,GRP_DBH,DBH_DATE,1993 -US-Ha1,17437,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17437,GRP_DBH,DBH_SPATIAL_REP_NUMBER,41 -US-Ha1,17437,GRP_DBH,DBH_SPATIAL_VARIABILITY,10.68 -US-Ha1,17483,GRP_DBH,DBH,24.21 -US-Ha1,17483,GRP_DBH,DBH_SPP,Tsuga canadensis -US-Ha1,17483,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17483,GRP_DBH,DBH_DATE,19981030 -US-Ha1,17483,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17483,GRP_DBH,DBH_SPATIAL_REP_NUMBER,82 -US-Ha1,17483,GRP_DBH,DBH_SPATIAL_VARIABILITY,10.51 -US-Ha1,17595,GRP_DBH,DBH,24.21 -US-Ha1,17595,GRP_DBH,DBH_SPP,Tsuga canadensis -US-Ha1,17595,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17595,GRP_DBH,DBH_DATE,20081120 -US-Ha1,17595,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17595,GRP_DBH,DBH_SPATIAL_REP_NUMBER,93 -US-Ha1,17595,GRP_DBH,DBH_SPATIAL_VARIABILITY,11.49 -US-Ha1,17685,GRP_DBH,DBH,24.33 -US-Ha1,17685,GRP_DBH,DBH_SPP,Tsuga canadensis -US-Ha1,17685,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17685,GRP_DBH,DBH_DATE,20101207 -US-Ha1,17685,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17685,GRP_DBH,DBH_SPATIAL_REP_NUMBER,95 -US-Ha1,17685,GRP_DBH,DBH_SPATIAL_VARIABILITY,11.67 -US-Ha1,17475,GRP_DBH,DBH,24.41 -US-Ha1,17475,GRP_DBH,DBH_SPP,Prunus serotina -US-Ha1,17475,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17475,GRP_DBH,DBH_DATE,19981030 -US-Ha1,17475,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17475,GRP_DBH,DBH_SPATIAL_REP_NUMBER,18 -US-Ha1,17475,GRP_DBH,DBH_SPATIAL_VARIABILITY,11.34 -US-Ha1,18169,GRP_DBH,DBH,24.43 -US-Ha1,18169,GRP_DBH,DBH_SPP,Tsuga canadensis -US-Ha1,18169,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,18169,GRP_DBH,DBH_DATE,20041103 -US-Ha1,18169,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,18169,GRP_DBH,DBH_SPATIAL_REP_NUMBER,88 -US-Ha1,18169,GRP_DBH,DBH_SPATIAL_VARIABILITY,11 -US-Ha1,17862,GRP_DBH,DBH,24.44 -US-Ha1,17862,GRP_DBH,DBH_SPP,Prunus serotina -US-Ha1,17862,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17862,GRP_DBH,DBH_DATE,19991027 -US-Ha1,17862,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17862,GRP_DBH,DBH_SPATIAL_REP_NUMBER,18 -US-Ha1,17862,GRP_DBH,DBH_SPATIAL_VARIABILITY,11.37 -US-Ha1,17989,GRP_DBH,DBH,24.45 -US-Ha1,17989,GRP_DBH,DBH_SPP,Tsuga canadensis -US-Ha1,17989,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17989,GRP_DBH,DBH_DATE,20011026 -US-Ha1,17989,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17989,GRP_DBH,DBH_SPATIAL_REP_NUMBER,84 -US-Ha1,17989,GRP_DBH,DBH_SPATIAL_VARIABILITY,10.68 -US-Ha1,18049,GRP_DBH,DBH,24.63 -US-Ha1,18049,GRP_DBH,DBH_SPP,Tsuga canadensis -US-Ha1,18049,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,18049,GRP_DBH,DBH_DATE,20021114 -US-Ha1,18049,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,18049,GRP_DBH,DBH_SPATIAL_REP_NUMBER,84 -US-Ha1,18049,GRP_DBH,DBH_SPATIAL_VARIABILITY,10.76 -US-Ha1,18229,GRP_DBH,DBH,24.63 -US-Ha1,18229,GRP_DBH,DBH_SPP,Tsuga canadensis -US-Ha1,18229,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,18229,GRP_DBH,DBH_DATE,20051102 -US-Ha1,18229,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,18229,GRP_DBH,DBH_SPATIAL_REP_NUMBER,86 -US-Ha1,18229,GRP_DBH,DBH_SPATIAL_VARIABILITY,11.21 -US-Ha1,17507,GRP_DBH,DBH,24.82 -US-Ha1,17507,GRP_DBH,DBH_SPP,Pinus strobus -US-Ha1,17507,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17507,GRP_DBH,DBH_DATE,19981030 -US-Ha1,17507,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17507,GRP_DBH,DBH_SPATIAL_REP_NUMBER,42 -US-Ha1,17507,GRP_DBH,DBH_SPATIAL_VARIABILITY,11.34 -US-Ha1,17870,GRP_DBH,DBH,24.86 -US-Ha1,17870,GRP_DBH,DBH_SPP,Tsuga canadensis -US-Ha1,17870,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17870,GRP_DBH,DBH_DATE,19991027 -US-Ha1,17870,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17870,GRP_DBH,DBH_SPATIAL_REP_NUMBER,79 -US-Ha1,17870,GRP_DBH,DBH_SPATIAL_VARIABILITY,10.44 -US-Ha1,18280,GRP_DBH,DBH,24.9 -US-Ha1,18280,GRP_DBH,DBH_SPP,Tsuga canadensis -US-Ha1,18280,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,18280,GRP_DBH,DBH_DATE,20061114 -US-Ha1,18280,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,18280,GRP_DBH,DBH_SPATIAL_REP_NUMBER,86 -US-Ha1,18280,GRP_DBH,DBH_SPATIAL_VARIABILITY,11.2 -US-Ha1,18109,GRP_DBH,DBH,25.2 -US-Ha1,18109,GRP_DBH,DBH_SPP,Tsuga canadensis -US-Ha1,18109,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,18109,GRP_DBH,DBH_DATE,20031113 -US-Ha1,18109,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,18109,GRP_DBH,DBH_SPATIAL_REP_NUMBER,82 -US-Ha1,18109,GRP_DBH,DBH_SPATIAL_VARIABILITY,10.77 -US-Ha1,17922,GRP_DBH,DBH,25.23 -US-Ha1,17922,GRP_DBH,DBH_SPP,Prunus serotina -US-Ha1,17922,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17922,GRP_DBH,DBH_DATE,20001024 -US-Ha1,17922,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17922,GRP_DBH,DBH_SPATIAL_REP_NUMBER,17 -US-Ha1,17922,GRP_DBH,DBH_SPATIAL_VARIABILITY,11.33 -US-Ha1,17981,GRP_DBH,DBH,25.26 -US-Ha1,17981,GRP_DBH,DBH_SPP,Prunus serotina -US-Ha1,17981,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17981,GRP_DBH,DBH_DATE,20011026 -US-Ha1,17981,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17981,GRP_DBH,DBH_SPATIAL_REP_NUMBER,17 -US-Ha1,17981,GRP_DBH,DBH_SPATIAL_VARIABILITY,10.98 -US-Ha1,17363,GRP_DBH,DBH,25.81 -US-Ha1,17363,GRP_DBH,DBH_SPP,Fraxinus americana -US-Ha1,17363,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17363,GRP_DBH,DBH_DATE,1993 -US-Ha1,17363,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17363,GRP_DBH,DBH_SPATIAL_REP_NUMBER,15 -US-Ha1,17363,GRP_DBH,DBH_SPATIAL_VARIABILITY,9.88 -US-Ha1,18101,GRP_DBH,DBH,26.12 -US-Ha1,18101,GRP_DBH,DBH_SPP,Prunus serotina -US-Ha1,18101,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,18101,GRP_DBH,DBH_DATE,20031113 -US-Ha1,18101,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,18101,GRP_DBH,DBH_SPATIAL_REP_NUMBER,16 -US-Ha1,18101,GRP_DBH,DBH_SPATIAL_VARIABILITY,10.94 -US-Ha1,18041,GRP_DBH,DBH,26.13 -US-Ha1,18041,GRP_DBH,DBH_SPP,Prunus serotina -US-Ha1,18041,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,18041,GRP_DBH,DBH_DATE,20021114 -US-Ha1,18041,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,18041,GRP_DBH,DBH_SPATIAL_REP_NUMBER,16 -US-Ha1,18041,GRP_DBH,DBH_SPATIAL_VARIABILITY,11.08 -US-Ha1,17954,GRP_DBH,DBH,26.64 -US-Ha1,17954,GRP_DBH,DBH_SPP,Pinus strobus -US-Ha1,17954,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17954,GRP_DBH,DBH_DATE,20001024 -US-Ha1,17954,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17954,GRP_DBH,DBH_SPATIAL_REP_NUMBER,38 -US-Ha1,17954,GRP_DBH,DBH_SPATIAL_VARIABILITY,11.33 -US-Ha1,17894,GRP_DBH,DBH,26.77 -US-Ha1,17894,GRP_DBH,DBH_SPP,Pinus strobus -US-Ha1,17894,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17894,GRP_DBH,DBH_DATE,19991027 -US-Ha1,17894,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17894,GRP_DBH,DBH_SPATIAL_REP_NUMBER,37 -US-Ha1,17894,GRP_DBH,DBH_SPATIAL_VARIABILITY,11.1 -US-Ha1,18161,GRP_DBH,DBH,27.05 -US-Ha1,18161,GRP_DBH,DBH_SPP,Prunus serotina -US-Ha1,18161,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,18161,GRP_DBH,DBH_DATE,20041103 -US-Ha1,18161,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,18161,GRP_DBH,DBH_SPATIAL_REP_NUMBER,15 -US-Ha1,18161,GRP_DBH,DBH_SPATIAL_VARIABILITY,10.82 -US-Ha1,17906,GRP_DBH,DBH,27.07 -US-Ha1,17906,GRP_DBH,DBH_SPP,Fraxinus americana -US-Ha1,17906,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17906,GRP_DBH,DBH_DATE,20001024 -US-Ha1,17906,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17906,GRP_DBH,DBH_SPATIAL_REP_NUMBER,14 -US-Ha1,17906,GRP_DBH,DBH_SPATIAL_VARIABILITY,10.05 -US-Ha1,17455,GRP_DBH,DBH,27.11 -US-Ha1,17455,GRP_DBH,DBH_SPP,Fraxinus americana -US-Ha1,17455,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17455,GRP_DBH,DBH_DATE,19981030 -US-Ha1,17455,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17455,GRP_DBH,DBH_SPATIAL_REP_NUMBER,14 -US-Ha1,17455,GRP_DBH,DBH_SPATIAL_VARIABILITY,9.73 -US-Ha1,18221,GRP_DBH,DBH,27.16 -US-Ha1,18221,GRP_DBH,DBH_SPP,Prunus serotina -US-Ha1,18221,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,18221,GRP_DBH,DBH_DATE,20051102 -US-Ha1,18221,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,18221,GRP_DBH,DBH_SPATIAL_REP_NUMBER,15 -US-Ha1,18221,GRP_DBH,DBH_SPATIAL_VARIABILITY,10.89 -US-Ha1,18249,GRP_DBH,DBH,27.31 -US-Ha1,18249,GRP_DBH,DBH_SPP,Betula papyrifera -US-Ha1,18249,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,18249,GRP_DBH,DBH_DATE,20051102 -US-Ha1,18249,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,18249,GRP_DBH,DBH_SPATIAL_REP_NUMBER,3 -US-Ha1,18249,GRP_DBH,DBH_SPATIAL_VARIABILITY,6.41 -US-Ha1,18189,GRP_DBH,DBH,27.35 -US-Ha1,18189,GRP_DBH,DBH_SPP,Betula papyrifera -US-Ha1,18189,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,18189,GRP_DBH,DBH_DATE,20041103 -US-Ha1,18189,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,18189,GRP_DBH,DBH_SPATIAL_REP_NUMBER,4 -US-Ha1,18189,GRP_DBH,DBH_SPATIAL_VARIABILITY,5.23 -US-Ha1,18274,GRP_DBH,DBH,27.55 -US-Ha1,18274,GRP_DBH,DBH_SPP,Prunus serotina -US-Ha1,18274,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,18274,GRP_DBH,DBH_DATE,20061114 -US-Ha1,18274,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,18274,GRP_DBH,DBH_SPATIAL_REP_NUMBER,15 -US-Ha1,18274,GRP_DBH,DBH_SPATIAL_VARIABILITY,11 -US-Ha1,17965,GRP_DBH,DBH,27.61 -US-Ha1,17965,GRP_DBH,DBH_SPP,Fraxinus americana -US-Ha1,17965,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17965,GRP_DBH,DBH_DATE,20011026 -US-Ha1,17965,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17965,GRP_DBH,DBH_SPATIAL_REP_NUMBER,14 -US-Ha1,17965,GRP_DBH,DBH_SPATIAL_VARIABILITY,9.84 -US-Ha1,18205,GRP_DBH,DBH,27.73 -US-Ha1,18205,GRP_DBH,DBH_SPP,Fraxinus americana -US-Ha1,18205,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,18205,GRP_DBH,DBH_DATE,20051102 -US-Ha1,18205,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,18205,GRP_DBH,DBH_SPATIAL_REP_NUMBER,13 -US-Ha1,18205,GRP_DBH,DBH_SPATIAL_VARIABILITY,10.2 -US-Ha1,17520,GRP_DBH,DBH,27.75 -US-Ha1,17520,GRP_DBH,DBH_SPP,Betula papyrifera -US-Ha1,17520,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17520,GRP_DBH,DBH_DATE,20061114 -US-Ha1,17520,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17520,GRP_DBH,DBH_SPATIAL_REP_NUMBER,3 -US-Ha1,17520,GRP_DBH,DBH_SPATIAL_VARIABILITY,6.69 -US-Ha1,18025,GRP_DBH,DBH,27.76 -US-Ha1,18025,GRP_DBH,DBH_SPP,Fraxinus americana -US-Ha1,18025,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,18025,GRP_DBH,DBH_DATE,20021114 -US-Ha1,18025,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,18025,GRP_DBH,DBH_SPATIAL_REP_NUMBER,14 -US-Ha1,18025,GRP_DBH,DBH_SPATIAL_VARIABILITY,9.79 -US-Ha1,17565,GRP_DBH,DBH,27.81 -US-Ha1,17565,GRP_DBH,DBH_SPP,Betula papyrifera -US-Ha1,17565,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17565,GRP_DBH,DBH_DATE,20071120 -US-Ha1,17565,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17565,GRP_DBH,DBH_SPATIAL_REP_NUMBER,3 -US-Ha1,17565,GRP_DBH,DBH_SPATIAL_VARIABILITY,6.72 -US-Ha1,17846,GRP_DBH,DBH,27.82 -US-Ha1,17846,GRP_DBH,DBH_SPP,Fraxinus americana -US-Ha1,17846,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17846,GRP_DBH,DBH_DATE,19991027 -US-Ha1,17846,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17846,GRP_DBH,DBH_SPATIAL_REP_NUMBER,13 -US-Ha1,17846,GRP_DBH,DBH_SPATIAL_VARIABILITY,9.87 -US-Ha1,17383,GRP_DBH,DBH,27.84 -US-Ha1,17383,GRP_DBH,DBH_SPP,Quercus velutina -US-Ha1,17383,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17383,GRP_DBH,DBH_DATE,1993 -US-Ha1,17383,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17383,GRP_DBH,DBH_SPATIAL_REP_NUMBER,17 -US-Ha1,17383,GRP_DBH,DBH_SPATIAL_VARIABILITY,8.57 -US-Ha1,18085,GRP_DBH,DBH,27.88 -US-Ha1,18085,GRP_DBH,DBH_SPP,Fraxinus americana -US-Ha1,18085,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,18085,GRP_DBH,DBH_DATE,20031113 -US-Ha1,18085,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,18085,GRP_DBH,DBH_SPATIAL_REP_NUMBER,14 -US-Ha1,18085,GRP_DBH,DBH_SPATIAL_VARIABILITY,9.83 -US-Ha1,17610,GRP_DBH,DBH,27.89 -US-Ha1,17610,GRP_DBH,DBH_SPP,Betula papyrifera -US-Ha1,17610,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17610,GRP_DBH,DBH_DATE,20081120 -US-Ha1,17610,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17610,GRP_DBH,DBH_SPATIAL_REP_NUMBER,3 -US-Ha1,17610,GRP_DBH,DBH_SPATIAL_VARIABILITY,6.76 -US-Ha1,17655,GRP_DBH,DBH,27.96 -US-Ha1,17655,GRP_DBH,DBH_SPP,Betula papyrifera -US-Ha1,17655,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17655,GRP_DBH,DBH_DATE,20091201 -US-Ha1,17655,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17655,GRP_DBH,DBH_SPATIAL_REP_NUMBER,3 -US-Ha1,17655,GRP_DBH,DBH_SPATIAL_VARIABILITY,6.83 -US-Ha1,18145,GRP_DBH,DBH,27.98 -US-Ha1,18145,GRP_DBH,DBH_SPP,Fraxinus americana -US-Ha1,18145,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,18145,GRP_DBH,DBH_DATE,20041103 -US-Ha1,18145,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,18145,GRP_DBH,DBH_SPATIAL_REP_NUMBER,14 -US-Ha1,18145,GRP_DBH,DBH_SPATIAL_VARIABILITY,9.87 -US-Ha1,18262,GRP_DBH,DBH,28.02 -US-Ha1,18262,GRP_DBH,DBH_SPP,Fraxinus americana -US-Ha1,18262,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,18262,GRP_DBH,DBH_DATE,20061114 -US-Ha1,18262,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,18262,GRP_DBH,DBH_SPATIAL_REP_NUMBER,13 -US-Ha1,18262,GRP_DBH,DBH_SPATIAL_VARIABILITY,10.21 -US-Ha1,17700,GRP_DBH,DBH,28.04 -US-Ha1,17700,GRP_DBH,DBH_SPP,Betula papyrifera -US-Ha1,17700,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17700,GRP_DBH,DBH_DATE,20101207 -US-Ha1,17700,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17700,GRP_DBH,DBH_SPATIAL_REP_NUMBER,3 -US-Ha1,17700,GRP_DBH,DBH_SPATIAL_VARIABILITY,6.9 -US-Ha1,18013,GRP_DBH,DBH,28.04 -US-Ha1,18013,GRP_DBH,DBH_SPP,Pinus strobus -US-Ha1,18013,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,18013,GRP_DBH,DBH_DATE,20011026 -US-Ha1,18013,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,18013,GRP_DBH,DBH_SPATIAL_REP_NUMBER,33 -US-Ha1,18013,GRP_DBH,DBH_SPATIAL_VARIABILITY,12.04 -US-Ha1,18073,GRP_DBH,DBH,28.06 -US-Ha1,18073,GRP_DBH,DBH_SPP,Pinus strobus -US-Ha1,18073,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,18073,GRP_DBH,DBH_DATE,20021114 -US-Ha1,18073,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,18073,GRP_DBH,DBH_SPATIAL_REP_NUMBER,33 -US-Ha1,18073,GRP_DBH,DBH_SPATIAL_VARIABILITY,11.97 -US-Ha1,17419,GRP_DBH,DBH,28.13 -US-Ha1,17419,GRP_DBH,DBH_SPP,Pinus resinosa -US-Ha1,17419,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17419,GRP_DBH,DBH_DATE,1993 -US-Ha1,17419,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17419,GRP_DBH,DBH_SPATIAL_REP_NUMBER,43 -US-Ha1,17419,GRP_DBH,DBH_SPATIAL_VARIABILITY,8.33 -US-Ha1,17745,GRP_DBH,DBH,28.13 -US-Ha1,17745,GRP_DBH,DBH_SPP,Betula papyrifera -US-Ha1,17745,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17745,GRP_DBH,DBH_DATE,20111201 -US-Ha1,17745,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17745,GRP_DBH,DBH_SPATIAL_REP_NUMBER,3 -US-Ha1,17745,GRP_DBH,DBH_SPATIAL_VARIABILITY,6.98 -US-Ha1,17532,GRP_DBH,DBH,28.14 -US-Ha1,17532,GRP_DBH,DBH_SPP,Fraxinus americana -US-Ha1,17532,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17532,GRP_DBH,DBH_DATE,20071120 -US-Ha1,17532,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17532,GRP_DBH,DBH_SPATIAL_REP_NUMBER,13 -US-Ha1,17532,GRP_DBH,DBH_SPATIAL_VARIABILITY,10.28 -US-Ha1,17790,GRP_DBH,DBH,28.15 -US-Ha1,17790,GRP_DBH,DBH_SPP,Betula papyrifera -US-Ha1,17790,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17790,GRP_DBH,DBH_DATE,20121204 -US-Ha1,17790,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17790,GRP_DBH,DBH_SPATIAL_REP_NUMBER,3 -US-Ha1,17790,GRP_DBH,DBH_SPATIAL_VARIABILITY,6.98 -US-Ha1,18253,GRP_DBH,DBH,28.19 -US-Ha1,18253,GRP_DBH,DBH_SPP,Pinus strobus -US-Ha1,18253,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,18253,GRP_DBH,DBH_DATE,20051102 -US-Ha1,18253,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,18253,GRP_DBH,DBH_SPATIAL_REP_NUMBER,33 -US-Ha1,18253,GRP_DBH,DBH_SPATIAL_VARIABILITY,12.49 -US-Ha1,17544,GRP_DBH,DBH,28.28 -US-Ha1,17544,GRP_DBH,DBH_SPP,Prunus serotina -US-Ha1,17544,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17544,GRP_DBH,DBH_DATE,20071120 -US-Ha1,17544,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17544,GRP_DBH,DBH_SPATIAL_REP_NUMBER,14 -US-Ha1,17544,GRP_DBH,DBH_SPATIAL_VARIABILITY,11.17 -US-Ha1,17577,GRP_DBH,DBH,28.29 -US-Ha1,17577,GRP_DBH,DBH_SPP,Fraxinus americana -US-Ha1,17577,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17577,GRP_DBH,DBH_DATE,20081120 -US-Ha1,17577,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17577,GRP_DBH,DBH_SPATIAL_REP_NUMBER,13 -US-Ha1,17577,GRP_DBH,DBH_SPATIAL_VARIABILITY,10.34 -US-Ha1,18133,GRP_DBH,DBH,28.29 -US-Ha1,18133,GRP_DBH,DBH_SPP,Pinus strobus -US-Ha1,18133,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,18133,GRP_DBH,DBH_DATE,20031113 -US-Ha1,18133,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,18133,GRP_DBH,DBH_SPATIAL_REP_NUMBER,33 -US-Ha1,18133,GRP_DBH,DBH_SPATIAL_VARIABILITY,12.09 -US-Ha1,17835,GRP_DBH,DBH,28.4 -US-Ha1,17835,GRP_DBH,DBH_SPP,Betula papyrifera -US-Ha1,17835,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17835,GRP_DBH,DBH_DATE,20131212 -US-Ha1,17835,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17835,GRP_DBH,DBH_SPATIAL_REP_NUMBER,3 -US-Ha1,17835,GRP_DBH,DBH_SPATIAL_VARIABILITY,6.82 -US-Ha1,17622,GRP_DBH,DBH,28.44 -US-Ha1,17622,GRP_DBH,DBH_SPP,Fraxinus americana -US-Ha1,17622,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17622,GRP_DBH,DBH_DATE,20091201 -US-Ha1,17622,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17622,GRP_DBH,DBH_SPATIAL_REP_NUMBER,13 -US-Ha1,17622,GRP_DBH,DBH_SPATIAL_VARIABILITY,10.39 -US-Ha1,18193,GRP_DBH,DBH,28.48 -US-Ha1,18193,GRP_DBH,DBH_SPP,Pinus strobus -US-Ha1,18193,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,18193,GRP_DBH,DBH_DATE,20041103 -US-Ha1,18193,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,18193,GRP_DBH,DBH_SPATIAL_REP_NUMBER,33 -US-Ha1,18193,GRP_DBH,DBH_SPATIAL_VARIABILITY,12.24 -US-Ha1,17495,GRP_DBH,DBH,28.78 -US-Ha1,17495,GRP_DBH,DBH_SPP,Pinus resinosa -US-Ha1,17495,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17495,GRP_DBH,DBH_DATE,19981030 -US-Ha1,17495,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17495,GRP_DBH,DBH_SPATIAL_REP_NUMBER,42 -US-Ha1,17495,GRP_DBH,DBH_SPATIAL_VARIABILITY,8.98 -US-Ha1,17523,GRP_DBH,DBH,29.17 -US-Ha1,17523,GRP_DBH,DBH_SPP,Pinus strobus -US-Ha1,17523,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17523,GRP_DBH,DBH_DATE,20061114 -US-Ha1,17523,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17523,GRP_DBH,DBH_SPATIAL_REP_NUMBER,31 -US-Ha1,17523,GRP_DBH,DBH_SPATIAL_VARIABILITY,12.86 -US-Ha1,17589,GRP_DBH,DBH,29.3 -US-Ha1,17589,GRP_DBH,DBH_SPP,Prunus serotina -US-Ha1,17589,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17589,GRP_DBH,DBH_DATE,20081120 -US-Ha1,17589,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17589,GRP_DBH,DBH_SPATIAL_REP_NUMBER,13 -US-Ha1,17589,GRP_DBH,DBH_SPATIAL_VARIABILITY,11.09 -US-Ha1,17568,GRP_DBH,DBH,29.32 -US-Ha1,17568,GRP_DBH,DBH_SPP,Pinus strobus -US-Ha1,17568,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17568,GRP_DBH,DBH_DATE,20071120 -US-Ha1,17568,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17568,GRP_DBH,DBH_SPATIAL_REP_NUMBER,31 -US-Ha1,17568,GRP_DBH,DBH_SPATIAL_VARIABILITY,13.02 -US-Ha1,17634,GRP_DBH,DBH,29.36 -US-Ha1,17634,GRP_DBH,DBH_SPP,Prunus serotina -US-Ha1,17634,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17634,GRP_DBH,DBH_DATE,20091201 -US-Ha1,17634,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17634,GRP_DBH,DBH_SPATIAL_REP_NUMBER,13 -US-Ha1,17634,GRP_DBH,DBH_SPATIAL_VARIABILITY,11.12 -US-Ha1,17667,GRP_DBH,DBH,29.42 -US-Ha1,17667,GRP_DBH,DBH_SPP,Fraxinus americana -US-Ha1,17667,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17667,GRP_DBH,DBH_DATE,20101207 -US-Ha1,17667,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17667,GRP_DBH,DBH_SPATIAL_REP_NUMBER,12 -US-Ha1,17667,GRP_DBH,DBH_SPATIAL_VARIABILITY,10.5 -US-Ha1,17613,GRP_DBH,DBH,29.49 -US-Ha1,17613,GRP_DBH,DBH_SPP,Pinus strobus -US-Ha1,17613,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17613,GRP_DBH,DBH_DATE,20081120 -US-Ha1,17613,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17613,GRP_DBH,DBH_SPATIAL_REP_NUMBER,31 -US-Ha1,17613,GRP_DBH,DBH_SPATIAL_VARIABILITY,13.19 -US-Ha1,17712,GRP_DBH,DBH,29.65 -US-Ha1,17712,GRP_DBH,DBH_SPP,Fraxinus americana -US-Ha1,17712,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17712,GRP_DBH,DBH_DATE,20111201 -US-Ha1,17712,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17712,GRP_DBH,DBH_SPATIAL_REP_NUMBER,12 -US-Ha1,17712,GRP_DBH,DBH_SPATIAL_VARIABILITY,10.56 -US-Ha1,17757,GRP_DBH,DBH,29.69 -US-Ha1,17757,GRP_DBH,DBH_SPP,Fraxinus americana -US-Ha1,17757,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17757,GRP_DBH,DBH_DATE,20121204 -US-Ha1,17757,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17757,GRP_DBH,DBH_SPATIAL_REP_NUMBER,12 -US-Ha1,17757,GRP_DBH,DBH_SPATIAL_VARIABILITY,10.59 -US-Ha1,17470,GRP_DBH,DBH,29.74 -US-Ha1,17470,GRP_DBH,DBH_SPP,Quercus velutina -US-Ha1,17470,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17470,GRP_DBH,DBH_DATE,19981030 -US-Ha1,17470,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17470,GRP_DBH,DBH_SPATIAL_REP_NUMBER,16 -US-Ha1,17470,GRP_DBH,DBH_SPATIAL_VARIABILITY,8.45 -US-Ha1,17858,GRP_DBH,DBH,29.75 -US-Ha1,17858,GRP_DBH,DBH_SPP,Quercus velutina -US-Ha1,17858,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17858,GRP_DBH,DBH_DATE,19991027 -US-Ha1,17858,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17858,GRP_DBH,DBH_SPATIAL_REP_NUMBER,13 -US-Ha1,17858,GRP_DBH,DBH_SPATIAL_VARIABILITY,8.91 -US-Ha1,17918,GRP_DBH,DBH,30.01 -US-Ha1,17918,GRP_DBH,DBH_SPP,Quercus velutina -US-Ha1,17918,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17918,GRP_DBH,DBH_DATE,20001024 -US-Ha1,17918,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17918,GRP_DBH,DBH_SPATIAL_REP_NUMBER,13 -US-Ha1,17918,GRP_DBH,DBH_SPATIAL_VARIABILITY,8.97 -US-Ha1,17413,GRP_DBH,DBH,30.08 -US-Ha1,17413,GRP_DBH,DBH_SPP,Quercus rubra -US-Ha1,17413,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17413,GRP_DBH,DBH_DATE,1993 -US-Ha1,17413,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17413,GRP_DBH,DBH_SPATIAL_REP_NUMBER,161 -US-Ha1,17413,GRP_DBH,DBH_SPATIAL_VARIABILITY,11.66 -US-Ha1,17802,GRP_DBH,DBH,30.11 -US-Ha1,17802,GRP_DBH,DBH_SPP,Fraxinus americana -US-Ha1,17802,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17802,GRP_DBH,DBH_DATE,20131212 -US-Ha1,17802,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17802,GRP_DBH,DBH_SPATIAL_REP_NUMBER,12 -US-Ha1,17802,GRP_DBH,DBH_SPATIAL_VARIABILITY,10.64 -US-Ha1,17658,GRP_DBH,DBH,30.19 -US-Ha1,17658,GRP_DBH,DBH_SPP,Pinus strobus -US-Ha1,17658,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17658,GRP_DBH,DBH_DATE,20091201 -US-Ha1,17658,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17658,GRP_DBH,DBH_SPATIAL_REP_NUMBER,29 -US-Ha1,17658,GRP_DBH,DBH_SPATIAL_VARIABILITY,13.6 -US-Ha1,17703,GRP_DBH,DBH,30.33 -US-Ha1,17703,GRP_DBH,DBH_SPP,Pinus strobus -US-Ha1,17703,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17703,GRP_DBH,DBH_DATE,20101207 -US-Ha1,17703,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17703,GRP_DBH,DBH_SPATIAL_REP_NUMBER,29 -US-Ha1,17703,GRP_DBH,DBH_SPATIAL_VARIABILITY,13.74 -US-Ha1,17977,GRP_DBH,DBH,30.39 -US-Ha1,17977,GRP_DBH,DBH_SPP,Quercus velutina -US-Ha1,17977,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17977,GRP_DBH,DBH_DATE,20011026 -US-Ha1,17977,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17977,GRP_DBH,DBH_SPATIAL_REP_NUMBER,13 -US-Ha1,17977,GRP_DBH,DBH_SPATIAL_VARIABILITY,9.11 -US-Ha1,17882,GRP_DBH,DBH,30.49 -US-Ha1,17882,GRP_DBH,DBH_SPP,Pinus resinosa -US-Ha1,17882,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17882,GRP_DBH,DBH_DATE,19991027 -US-Ha1,17882,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17882,GRP_DBH,DBH_SPATIAL_REP_NUMBER,37 -US-Ha1,17882,GRP_DBH,DBH_SPATIAL_VARIABILITY,8.44 -US-Ha1,18037,GRP_DBH,DBH,30.75 -US-Ha1,18037,GRP_DBH,DBH_SPP,Quercus velutina -US-Ha1,18037,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,18037,GRP_DBH,DBH_DATE,20021114 -US-Ha1,18037,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,18037,GRP_DBH,DBH_SPATIAL_REP_NUMBER,13 -US-Ha1,18037,GRP_DBH,DBH_SPATIAL_VARIABILITY,9.12 -US-Ha1,18097,GRP_DBH,DBH,30.96 -US-Ha1,18097,GRP_DBH,DBH_SPP,Quercus velutina -US-Ha1,18097,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,18097,GRP_DBH,DBH_DATE,20031113 -US-Ha1,18097,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,18097,GRP_DBH,DBH_SPATIAL_REP_NUMBER,13 -US-Ha1,18097,GRP_DBH,DBH_SPATIAL_VARIABILITY,9.23 -US-Ha1,17942,GRP_DBH,DBH,31.08 -US-Ha1,17942,GRP_DBH,DBH_SPP,Pinus resinosa -US-Ha1,17942,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17942,GRP_DBH,DBH_DATE,20001024 -US-Ha1,17942,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17942,GRP_DBH,DBH_SPATIAL_REP_NUMBER,36 -US-Ha1,17942,GRP_DBH,DBH_SPATIAL_VARIABILITY,8.19 -US-Ha1,17491,GRP_DBH,DBH,31.17 -US-Ha1,17491,GRP_DBH,DBH_SPP,Quercus rubra -US-Ha1,17491,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17491,GRP_DBH,DBH_DATE,19981030 -US-Ha1,17491,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17491,GRP_DBH,DBH_SPATIAL_REP_NUMBER,160 -US-Ha1,17491,GRP_DBH,DBH_SPATIAL_VARIABILITY,11.88 -US-Ha1,17748,GRP_DBH,DBH,31.18 -US-Ha1,17748,GRP_DBH,DBH_SPP,Pinus strobus -US-Ha1,17748,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17748,GRP_DBH,DBH_DATE,20111201 -US-Ha1,17748,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17748,GRP_DBH,DBH_SPATIAL_REP_NUMBER,27 -US-Ha1,17748,GRP_DBH,DBH_SPATIAL_VARIABILITY,14.04 -US-Ha1,18157,GRP_DBH,DBH,31.25 -US-Ha1,18157,GRP_DBH,DBH_SPP,Quercus velutina -US-Ha1,18157,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,18157,GRP_DBH,DBH_DATE,20041103 -US-Ha1,18157,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,18157,GRP_DBH,DBH_SPATIAL_REP_NUMBER,13 -US-Ha1,18157,GRP_DBH,DBH_SPATIAL_VARIABILITY,9.33 -US-Ha1,18001,GRP_DBH,DBH,31.29 -US-Ha1,18001,GRP_DBH,DBH_SPP,Pinus resinosa -US-Ha1,18001,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,18001,GRP_DBH,DBH_DATE,20011026 -US-Ha1,18001,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,18001,GRP_DBH,DBH_SPATIAL_REP_NUMBER,36 -US-Ha1,18001,GRP_DBH,DBH_SPATIAL_VARIABILITY,8.3 -US-Ha1,17679,GRP_DBH,DBH,31.71 -US-Ha1,17679,GRP_DBH,DBH_SPP,Prunus serotina -US-Ha1,17679,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17679,GRP_DBH,DBH_DATE,20101207 -US-Ha1,17679,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17679,GRP_DBH,DBH_SPATIAL_REP_NUMBER,11 -US-Ha1,17679,GRP_DBH,DBH_SPATIAL_VARIABILITY,10.52 -US-Ha1,17724,GRP_DBH,DBH,31.79 -US-Ha1,17724,GRP_DBH,DBH_SPP,Prunus serotina -US-Ha1,17724,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17724,GRP_DBH,DBH_DATE,20111201 -US-Ha1,17724,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17724,GRP_DBH,DBH_SPATIAL_REP_NUMBER,11 -US-Ha1,17724,GRP_DBH,DBH_SPATIAL_VARIABILITY,10.58 -US-Ha1,17769,GRP_DBH,DBH,31.84 -US-Ha1,17769,GRP_DBH,DBH_SPP,Prunus serotina -US-Ha1,17769,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17769,GRP_DBH,DBH_DATE,20121204 -US-Ha1,17769,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17769,GRP_DBH,DBH_SPATIAL_REP_NUMBER,11 -US-Ha1,17769,GRP_DBH,DBH_SPATIAL_VARIABILITY,10.62 -US-Ha1,18217,GRP_DBH,DBH,31.87 -US-Ha1,18217,GRP_DBH,DBH_SPP,Quercus velutina -US-Ha1,18217,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,18217,GRP_DBH,DBH_DATE,20051102 -US-Ha1,18217,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,18217,GRP_DBH,DBH_SPATIAL_REP_NUMBER,12 -US-Ha1,18217,GRP_DBH,DBH_SPATIAL_VARIABILITY,9.78 -US-Ha1,18271,GRP_DBH,DBH,32.31 -US-Ha1,18271,GRP_DBH,DBH_SPP,Quercus velutina -US-Ha1,18271,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,18271,GRP_DBH,DBH_DATE,20061114 -US-Ha1,18271,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,18271,GRP_DBH,DBH_SPATIAL_REP_NUMBER,12 -US-Ha1,18271,GRP_DBH,DBH_SPATIAL_VARIABILITY,9.96 -US-Ha1,17541,GRP_DBH,DBH,32.59 -US-Ha1,17541,GRP_DBH,DBH_SPP,Quercus velutina -US-Ha1,17541,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17541,GRP_DBH,DBH_DATE,20071120 -US-Ha1,17541,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17541,GRP_DBH,DBH_SPATIAL_REP_NUMBER,12 -US-Ha1,17541,GRP_DBH,DBH_SPATIAL_VARIABILITY,10 -US-Ha1,18061,GRP_DBH,DBH,32.76 -US-Ha1,18061,GRP_DBH,DBH_SPP,Pinus resinosa -US-Ha1,18061,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,18061,GRP_DBH,DBH_DATE,20021114 -US-Ha1,18061,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,18061,GRP_DBH,DBH_SPATIAL_REP_NUMBER,33 -US-Ha1,18061,GRP_DBH,DBH_SPATIAL_VARIABILITY,7.32 -US-Ha1,18121,GRP_DBH,DBH,32.8 -US-Ha1,18121,GRP_DBH,DBH_SPP,Pinus resinosa -US-Ha1,18121,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,18121,GRP_DBH,DBH_DATE,20031113 -US-Ha1,18121,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,18121,GRP_DBH,DBH_SPATIAL_REP_NUMBER,33 -US-Ha1,18121,GRP_DBH,DBH_SPATIAL_VARIABILITY,7.32 -US-Ha1,18181,GRP_DBH,DBH,32.88 -US-Ha1,18181,GRP_DBH,DBH_SPP,Pinus resinosa -US-Ha1,18181,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,18181,GRP_DBH,DBH_DATE,20041103 -US-Ha1,18181,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,18181,GRP_DBH,DBH_SPATIAL_REP_NUMBER,33 -US-Ha1,18181,GRP_DBH,DBH_SPATIAL_VARIABILITY,7.36 -US-Ha1,17586,GRP_DBH,DBH,32.96 -US-Ha1,17586,GRP_DBH,DBH_SPP,Quercus velutina -US-Ha1,17586,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17586,GRP_DBH,DBH_DATE,20081120 -US-Ha1,17586,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17586,GRP_DBH,DBH_SPATIAL_REP_NUMBER,12 -US-Ha1,17586,GRP_DBH,DBH_SPATIAL_VARIABILITY,10.13 -US-Ha1,18241,GRP_DBH,DBH,33.02 -US-Ha1,18241,GRP_DBH,DBH_SPP,Pinus resinosa -US-Ha1,18241,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,18241,GRP_DBH,DBH_DATE,20051102 -US-Ha1,18241,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,18241,GRP_DBH,DBH_SPATIAL_REP_NUMBER,33 -US-Ha1,18241,GRP_DBH,DBH_SPATIAL_VARIABILITY,7.4 -US-Ha1,17793,GRP_DBH,DBH,33.03 -US-Ha1,17793,GRP_DBH,DBH_SPP,Pinus strobus -US-Ha1,17793,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17793,GRP_DBH,DBH_DATE,20121204 -US-Ha1,17793,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17793,GRP_DBH,DBH_SPATIAL_REP_NUMBER,24 -US-Ha1,17793,GRP_DBH,DBH_SPATIAL_VARIABILITY,14.08 -US-Ha1,17631,GRP_DBH,DBH,33.31 -US-Ha1,17631,GRP_DBH,DBH_SPP,Quercus velutina -US-Ha1,17631,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17631,GRP_DBH,DBH_DATE,20091201 -US-Ha1,17631,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17631,GRP_DBH,DBH_SPATIAL_REP_NUMBER,12 -US-Ha1,17631,GRP_DBH,DBH_SPATIAL_VARIABILITY,10.23 -US-Ha1,17878,GRP_DBH,DBH,33.33 -US-Ha1,17878,GRP_DBH,DBH_SPP,Quercus rubra -US-Ha1,17878,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17878,GRP_DBH,DBH_DATE,19991027 -US-Ha1,17878,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17878,GRP_DBH,DBH_SPATIAL_REP_NUMBER,130 -US-Ha1,17878,GRP_DBH,DBH_SPATIAL_VARIABILITY,11.81 -US-Ha1,17838,GRP_DBH,DBH,33.54 -US-Ha1,17838,GRP_DBH,DBH_SPP,Pinus strobus -US-Ha1,17838,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17838,GRP_DBH,DBH_DATE,20131212 -US-Ha1,17838,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17838,GRP_DBH,DBH_SPATIAL_REP_NUMBER,24 -US-Ha1,17838,GRP_DBH,DBH_SPATIAL_VARIABILITY,14.08 -US-Ha1,17938,GRP_DBH,DBH,33.56 -US-Ha1,17938,GRP_DBH,DBH_SPP,Quercus rubra -US-Ha1,17938,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17938,GRP_DBH,DBH_DATE,20001024 -US-Ha1,17938,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17938,GRP_DBH,DBH_SPATIAL_REP_NUMBER,130 -US-Ha1,17938,GRP_DBH,DBH_SPATIAL_VARIABILITY,11.88 -US-Ha1,17676,GRP_DBH,DBH,33.67 -US-Ha1,17676,GRP_DBH,DBH_SPP,Quercus velutina -US-Ha1,17676,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17676,GRP_DBH,DBH_DATE,20101207 -US-Ha1,17676,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17676,GRP_DBH,DBH_SPATIAL_REP_NUMBER,12 -US-Ha1,17676,GRP_DBH,DBH_SPATIAL_VARIABILITY,10.43 -US-Ha1,17997,GRP_DBH,DBH,33.84 -US-Ha1,17997,GRP_DBH,DBH_SPP,Quercus rubra -US-Ha1,17997,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17997,GRP_DBH,DBH_DATE,20011026 -US-Ha1,17997,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17997,GRP_DBH,DBH_SPATIAL_REP_NUMBER,130 -US-Ha1,17997,GRP_DBH,DBH_SPATIAL_VARIABILITY,12.01 -US-Ha1,17721,GRP_DBH,DBH,33.98 -US-Ha1,17721,GRP_DBH,DBH_SPP,Quercus velutina -US-Ha1,17721,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17721,GRP_DBH,DBH_DATE,20111201 -US-Ha1,17721,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17721,GRP_DBH,DBH_SPATIAL_REP_NUMBER,12 -US-Ha1,17721,GRP_DBH,DBH_SPATIAL_VARIABILITY,10.53 -US-Ha1,17814,GRP_DBH,DBH,34.09 -US-Ha1,17814,GRP_DBH,DBH_SPP,Prunus serotina -US-Ha1,17814,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17814,GRP_DBH,DBH_DATE,20131212 -US-Ha1,17814,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17814,GRP_DBH,DBH_SPATIAL_REP_NUMBER,10 -US-Ha1,17814,GRP_DBH,DBH_SPATIAL_VARIABILITY,9.06 -US-Ha1,18289,GRP_DBH,DBH,34.16 -US-Ha1,18289,GRP_DBH,DBH_SPP,Pinus resinosa -US-Ha1,18289,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,18289,GRP_DBH,DBH_DATE,20061114 -US-Ha1,18289,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,18289,GRP_DBH,DBH_SPATIAL_REP_NUMBER,31 -US-Ha1,18289,GRP_DBH,DBH_SPATIAL_VARIABILITY,6.77 -US-Ha1,17559,GRP_DBH,DBH,34.28 -US-Ha1,17559,GRP_DBH,DBH_SPP,Pinus resinosa -US-Ha1,17559,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17559,GRP_DBH,DBH_DATE,20071120 -US-Ha1,17559,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17559,GRP_DBH,DBH_SPATIAL_REP_NUMBER,31 -US-Ha1,17559,GRP_DBH,DBH_SPATIAL_VARIABILITY,6.8 -US-Ha1,17766,GRP_DBH,DBH,34.3 -US-Ha1,17766,GRP_DBH,DBH_SPP,Quercus velutina -US-Ha1,17766,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17766,GRP_DBH,DBH_DATE,20121204 -US-Ha1,17766,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17766,GRP_DBH,DBH_SPATIAL_REP_NUMBER,12 -US-Ha1,17766,GRP_DBH,DBH_SPATIAL_VARIABILITY,10.7 -US-Ha1,17604,GRP_DBH,DBH,34.4 -US-Ha1,17604,GRP_DBH,DBH_SPP,Pinus resinosa -US-Ha1,17604,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17604,GRP_DBH,DBH_DATE,20081120 -US-Ha1,17604,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17604,GRP_DBH,DBH_SPATIAL_REP_NUMBER,31 -US-Ha1,17604,GRP_DBH,DBH_SPATIAL_VARIABILITY,6.83 -US-Ha1,18057,GRP_DBH,DBH,34.43 -US-Ha1,18057,GRP_DBH,DBH_SPP,Quercus rubra -US-Ha1,18057,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,18057,GRP_DBH,DBH_DATE,20021114 -US-Ha1,18057,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,18057,GRP_DBH,DBH_SPATIAL_REP_NUMBER,128 -US-Ha1,18057,GRP_DBH,DBH_SPATIAL_VARIABILITY,11.81 -US-Ha1,17811,GRP_DBH,DBH,34.69 -US-Ha1,17811,GRP_DBH,DBH_SPP,Quercus velutina -US-Ha1,17811,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17811,GRP_DBH,DBH_DATE,20131212 -US-Ha1,17811,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17811,GRP_DBH,DBH_SPATIAL_REP_NUMBER,12 -US-Ha1,17811,GRP_DBH,DBH_SPATIAL_VARIABILITY,10.68 -US-Ha1,18117,GRP_DBH,DBH,34.78 -US-Ha1,18117,GRP_DBH,DBH_SPP,Quercus rubra -US-Ha1,18117,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,18117,GRP_DBH,DBH_DATE,20031113 -US-Ha1,18117,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,18117,GRP_DBH,DBH_SPATIAL_REP_NUMBER,127 -US-Ha1,18117,GRP_DBH,DBH_SPATIAL_VARIABILITY,11.86 -US-Ha1,18177,GRP_DBH,DBH,35.04 -US-Ha1,18177,GRP_DBH,DBH_SPP,Quercus rubra -US-Ha1,18177,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,18177,GRP_DBH,DBH_DATE,20041103 -US-Ha1,18177,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,18177,GRP_DBH,DBH_SPATIAL_REP_NUMBER,127 -US-Ha1,18177,GRP_DBH,DBH_SPATIAL_VARIABILITY,11.94 -US-Ha1,17649,GRP_DBH,DBH,35.11 -US-Ha1,17649,GRP_DBH,DBH_SPP,Pinus resinosa -US-Ha1,17649,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17649,GRP_DBH,DBH_DATE,20091201 -US-Ha1,17649,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17649,GRP_DBH,DBH_SPATIAL_REP_NUMBER,30 -US-Ha1,17649,GRP_DBH,DBH_SPATIAL_VARIABILITY,5.98 -US-Ha1,17694,GRP_DBH,DBH,35.28 -US-Ha1,17694,GRP_DBH,DBH_SPP,Pinus resinosa -US-Ha1,17694,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17694,GRP_DBH,DBH_DATE,20101207 -US-Ha1,17694,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17694,GRP_DBH,DBH_SPATIAL_REP_NUMBER,29 -US-Ha1,17694,GRP_DBH,DBH_SPATIAL_VARIABILITY,6.09 -US-Ha1,18237,GRP_DBH,DBH,35.3 -US-Ha1,18237,GRP_DBH,DBH_SPP,Quercus rubra -US-Ha1,18237,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,18237,GRP_DBH,DBH_DATE,20051102 -US-Ha1,18237,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,18237,GRP_DBH,DBH_SPATIAL_REP_NUMBER,126 -US-Ha1,18237,GRP_DBH,DBH_SPATIAL_VARIABILITY,12.16 -US-Ha1,17739,GRP_DBH,DBH,35.38 -US-Ha1,17739,GRP_DBH,DBH_SPP,Pinus resinosa -US-Ha1,17739,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17739,GRP_DBH,DBH_DATE,20111201 -US-Ha1,17739,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17739,GRP_DBH,DBH_SPATIAL_REP_NUMBER,29 -US-Ha1,17739,GRP_DBH,DBH_SPATIAL_VARIABILITY,6.1 -US-Ha1,17784,GRP_DBH,DBH,35.48 -US-Ha1,17784,GRP_DBH,DBH_SPP,Pinus resinosa -US-Ha1,17784,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17784,GRP_DBH,DBH_DATE,20121204 -US-Ha1,17784,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17784,GRP_DBH,DBH_SPATIAL_REP_NUMBER,29 -US-Ha1,17784,GRP_DBH,DBH_SPATIAL_VARIABILITY,6.12 -US-Ha1,17829,GRP_DBH,DBH,35.85 -US-Ha1,17829,GRP_DBH,DBH_SPP,Pinus resinosa -US-Ha1,17829,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17829,GRP_DBH,DBH_DATE,20131212 -US-Ha1,17829,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17829,GRP_DBH,DBH_SPATIAL_REP_NUMBER,29 -US-Ha1,17829,GRP_DBH,DBH_SPATIAL_VARIABILITY,6.13 -US-Ha1,18286,GRP_DBH,DBH,36.1 -US-Ha1,18286,GRP_DBH,DBH_SPP,Quercus rubra -US-Ha1,18286,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,18286,GRP_DBH,DBH_DATE,20061114 -US-Ha1,18286,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,18286,GRP_DBH,DBH_SPATIAL_REP_NUMBER,125 -US-Ha1,18286,GRP_DBH,DBH_SPATIAL_VARIABILITY,11.84 -US-Ha1,17556,GRP_DBH,DBH,36.37 -US-Ha1,17556,GRP_DBH,DBH_SPP,Quercus rubra -US-Ha1,17556,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17556,GRP_DBH,DBH_DATE,20071120 -US-Ha1,17556,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17556,GRP_DBH,DBH_SPATIAL_REP_NUMBER,125 -US-Ha1,17556,GRP_DBH,DBH_SPATIAL_VARIABILITY,11.93 -US-Ha1,17601,GRP_DBH,DBH,36.8 -US-Ha1,17601,GRP_DBH,DBH_SPP,Quercus rubra -US-Ha1,17601,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17601,GRP_DBH,DBH_DATE,20081120 -US-Ha1,17601,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17601,GRP_DBH,DBH_SPATIAL_REP_NUMBER,123 -US-Ha1,17601,GRP_DBH,DBH_SPATIAL_VARIABILITY,12.06 -US-Ha1,17646,GRP_DBH,DBH,37.25 -US-Ha1,17646,GRP_DBH,DBH_SPP,Quercus rubra -US-Ha1,17646,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17646,GRP_DBH,DBH_DATE,20091201 -US-Ha1,17646,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17646,GRP_DBH,DBH_SPATIAL_REP_NUMBER,122 -US-Ha1,17646,GRP_DBH,DBH_SPATIAL_VARIABILITY,12.08 -US-Ha1,17691,GRP_DBH,DBH,37.79 -US-Ha1,17691,GRP_DBH,DBH_SPP,Quercus rubra -US-Ha1,17691,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17691,GRP_DBH,DBH_DATE,20101207 -US-Ha1,17691,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17691,GRP_DBH,DBH_SPATIAL_REP_NUMBER,121 -US-Ha1,17691,GRP_DBH,DBH_SPATIAL_VARIABILITY,12.27 -US-Ha1,17736,GRP_DBH,DBH,38.05 -US-Ha1,17736,GRP_DBH,DBH_SPP,Quercus rubra -US-Ha1,17736,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17736,GRP_DBH,DBH_DATE,20111201 -US-Ha1,17736,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17736,GRP_DBH,DBH_SPATIAL_REP_NUMBER,121 -US-Ha1,17736,GRP_DBH,DBH_SPATIAL_VARIABILITY,12.34 -US-Ha1,17781,GRP_DBH,DBH,38.35 -US-Ha1,17781,GRP_DBH,DBH_SPP,Quercus rubra -US-Ha1,17781,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17781,GRP_DBH,DBH_DATE,20121204 -US-Ha1,17781,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17781,GRP_DBH,DBH_SPATIAL_REP_NUMBER,121 -US-Ha1,17781,GRP_DBH,DBH_SPATIAL_VARIABILITY,12.41 -US-Ha1,17826,GRP_DBH,DBH,38.73 -US-Ha1,17826,GRP_DBH,DBH_SPP,Quercus rubra -US-Ha1,17826,GRP_DBH,DBH_HEIGHT,1.3 -US-Ha1,17826,GRP_DBH,DBH_DATE,20131212 -US-Ha1,17826,GRP_DBH,DBH_COMMENT,means and standard deviations are across all species in all plots. Spatial variability is # of stems -US-Ha1,17826,GRP_DBH,DBH_SPATIAL_REP_NUMBER,121 -US-Ha1,17826,GRP_DBH,DBH_SPATIAL_VARIABILITY,12.38 -US-Ha1,16126,GRP_DM_ENCROACH,DM_ENCROACH,Woody encroachment -US-Ha1,16126,GRP_DM_ENCROACH,DM_DATE,1850 -US-Ha1,16126,GRP_DM_ENCROACH,DM_DATE_UNC,1825 -US-Ha1,16126,GRP_DM_ENCROACH,DM_COMMENT,agriculture abandoned late 1800s -US-Ha1,16127,GRP_DM_EXT_WEATHER,DM_EXT_WEATHER,Hurricane -US-Ha1,16127,GRP_DM_EXT_WEATHER,DM_DATE,19380921 -US-Ha1,16127,GRP_DM_EXT_WEATHER,DM_COMMENT,overstory at this site was blown down during 1938 hurricane -US-Ha1,16125,GRP_DM_FORESTRY,DM_FORESTRY,Clearcutting -US-Ha1,16125,GRP_DM_FORESTRY,DM_DATE,1733 -US-Ha1,16125,GRP_DM_FORESTRY,DM_DATE_UNC,36500 -US-Ha1,16125,GRP_DM_FORESTRY,DM_COMMENT,"cleared in european settlement," -US-Ha1,16128,GRP_DM_INS_PATH,DM_INS_PATH,Insect -US-Ha1,16128,GRP_DM_INS_PATH,DM_DATE,1985 -US-Ha1,16128,GRP_DM_INS_PATH,DM_DATE_UNC,1825 -US-Ha1,16128,GRP_DM_INS_PATH,DM_COMMENT,gypsy moth infestation evident from tree ring chronology in 1980's -US-Ha1,15667,GRP_DOI,DOI,10.17190/AMF/1246059 -US-Ha1,15667,GRP_DOI,DOI_CITATION,"J. William Munger (2022), AmeriFlux BASE US-Ha1 Harvard Forest EMS Tower (HFR1), Ver. 18-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1246059" -US-Ha1,15667,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-Ha1,31833,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Ha1,31833,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,J. William Munger -US-Ha1,31833,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Ha1,31833,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,jwmunger@seas.harvard.edu -US-Ha1,31833,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Harvard University -US-Ha1,31835,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Harvard University -US-Ha1,31835,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-Ha1,31834,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,"DOE/TES (AmeriFlux Core site), NSF/LTER" -US-Ha1,31834,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-Ha1,22188,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Undisturbed -US-Ha1,11959,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Ha1,11959,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-Ha1,11959,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,1991 -US-Ha1,11959,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Ha1,11977,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Ha1,11977,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-Ha1,11977,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,1991 -US-Ha1,11977,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Ha1,11974,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Ha1,11974,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-Ha1,11974,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,1991 -US-Ha1,11974,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Ha1,23000371,GRP_HEADER,SITE_NAME,Harvard Forest EMS Tower (HFR1) -US-Ha1,89116,GRP_HEIGHTC,HEIGHTC,23 -US-Ha1,89116,GRP_HEIGHTC,HEIGHTC_STATISTIC,Expert estimate -US-Ha1,89116,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,1 -US-Ha1,89116,GRP_HEIGHTC,HEIGHTC_DATE,20070601 -US-Ha1,89116,GRP_HEIGHTC,HEIGHTC_COMMENT,Height estimate based on visual observation of canopy top relative to tower -US-Ha1,89934,GRP_HEIGHTC,HEIGHTC,3.40 -US-Ha1,89934,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Ha1,89934,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Ha1,89934,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,67 -US-Ha1,89934,GRP_HEIGHTC,HEIGHTC_APPROACH,Suunto clinometer -US-Ha1,89934,GRP_HEIGHTC,HEIGHTC_DATE,20180710 -US-Ha1,89934,GRP_HEIGHTC,HEIGHTC_COMMENT,Height from a sample of trees in permanent plots surrounding tower -US-Ha1,89936,GRP_HEIGHTC,HEIGHTC,25.4 -US-Ha1,89936,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ha1,89936,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Ha1,89936,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,67 -US-Ha1,89936,GRP_HEIGHTC,HEIGHTC_APPROACH,Suunto clinometer -US-Ha1,89936,GRP_HEIGHTC,HEIGHTC_DATE,20180710 -US-Ha1,89936,GRP_HEIGHTC,HEIGHTC_COMMENT,Height from a sample of trees in permanent plots surrounding tower -US-Ha1,11960,GRP_IGBP,IGBP,DBF -US-Ha1,17365,GRP_LAI,LAI_TYPE,LAI -US-Ha1,17372,GRP_LAI,LAI_TYPE,LAI -US-Ha1,17378,GRP_LAI,LAI_TYPE,LAI -US-Ha1,17384,GRP_LAI,LAI_TYPE,LAI -US-Ha1,17390,GRP_LAI,LAI_TYPE,LAI -US-Ha1,17396,GRP_LAI,LAI_TYPE,LAI -US-Ha1,17402,GRP_LAI,LAI_TYPE,LAI -US-Ha1,17408,GRP_LAI,LAI_TYPE,LAI -US-Ha1,17414,GRP_LAI,LAI_TYPE,LAI -US-Ha1,17420,GRP_LAI,LAI_TYPE,LAI -US-Ha1,17426,GRP_LAI,LAI_TYPE,LAI -US-Ha1,17432,GRP_LAI,LAI_TYPE,LAI -US-Ha1,17438,GRP_LAI,LAI_TYPE,LAI -US-Ha1,17444,GRP_LAI,LAI_TYPE,LAI -US-Ha1,17450,GRP_LAI,LAI_TYPE,LAI -US-Ha1,17456,GRP_LAI,LAI_TYPE,LAI -US-Ha1,17461,GRP_LAI,LAI_TYPE,LAI -US-Ha1,17466,GRP_LAI,LAI_TYPE,LAI -US-Ha1,17471,GRP_LAI,LAI_TYPE,LAI -US-Ha1,17476,GRP_LAI,LAI_TYPE,LAI -US-Ha1,17480,GRP_LAI,LAI_TYPE,LAI -US-Ha1,17484,GRP_LAI,LAI_TYPE,LAI -US-Ha1,17488,GRP_LAI,LAI_TYPE,LAI -US-Ha1,17492,GRP_LAI,LAI_TYPE,LAI -US-Ha1,17496,GRP_LAI,LAI_TYPE,LAI -US-Ha1,17500,GRP_LAI,LAI_TYPE,LAI -US-Ha1,17504,GRP_LAI,LAI_TYPE,LAI -US-Ha1,17508,GRP_LAI,LAI_TYPE,LAI -US-Ha1,17512,GRP_LAI,LAI_TYPE,LAI -US-Ha1,17516,GRP_LAI,LAI_TYPE,LAI -US-Ha1,17847,GRP_LAI,LAI_TYPE,LAI -US-Ha1,17851,GRP_LAI,LAI_TYPE,LAI -US-Ha1,17855,GRP_LAI,LAI_TYPE,LAI -US-Ha1,17859,GRP_LAI,LAI_TYPE,LAI -US-Ha1,17863,GRP_LAI,LAI_TYPE,LAI -US-Ha1,17867,GRP_LAI,LAI_TYPE,LAI -US-Ha1,17871,GRP_LAI,LAI_TYPE,LAI -US-Ha1,17875,GRP_LAI,LAI_TYPE,LAI -US-Ha1,17879,GRP_LAI,LAI_TYPE,LAI -US-Ha1,17883,GRP_LAI,LAI_TYPE,LAI -US-Ha1,17887,GRP_LAI,LAI_TYPE,LAI -US-Ha1,17891,GRP_LAI,LAI_TYPE,LAI -US-Ha1,17895,GRP_LAI,LAI_TYPE,LAI -US-Ha1,17899,GRP_LAI,LAI_TYPE,LAI -US-Ha1,17903,GRP_LAI,LAI_TYPE,LAI -US-Ha1,17907,GRP_LAI,LAI_TYPE,LAI -US-Ha1,17911,GRP_LAI,LAI_TYPE,LAI -US-Ha1,17915,GRP_LAI,LAI_TYPE,LAI -US-Ha1,17919,GRP_LAI,LAI_TYPE,LAI -US-Ha1,17923,GRP_LAI,LAI_TYPE,LAI -US-Ha1,17927,GRP_LAI,LAI_TYPE,LAI -US-Ha1,17931,GRP_LAI,LAI_TYPE,LAI -US-Ha1,17935,GRP_LAI,LAI_TYPE,LAI -US-Ha1,17939,GRP_LAI,LAI_TYPE,LAI -US-Ha1,17943,GRP_LAI,LAI_TYPE,LAI -US-Ha1,17947,GRP_LAI,LAI_TYPE,LAI -US-Ha1,17951,GRP_LAI,LAI_TYPE,LAI -US-Ha1,17958,GRP_LAI,LAI_TYPE,LAI -US-Ha1,17962,GRP_LAI,LAI_TYPE,LAI -US-Ha1,17966,GRP_LAI,LAI_TYPE,LAI -US-Ha1,17970,GRP_LAI,LAI_TYPE,LAI -US-Ha1,17974,GRP_LAI,LAI_TYPE,LAI -US-Ha1,17978,GRP_LAI,LAI_TYPE,LAI -US-Ha1,17982,GRP_LAI,LAI_TYPE,LAI -US-Ha1,17986,GRP_LAI,LAI_TYPE,LAI -US-Ha1,17990,GRP_LAI,LAI_TYPE,LAI -US-Ha1,17994,GRP_LAI,LAI_TYPE,LAI -US-Ha1,17998,GRP_LAI,LAI_TYPE,LAI -US-Ha1,18002,GRP_LAI,LAI_TYPE,LAI -US-Ha1,18006,GRP_LAI,LAI_TYPE,LAI -US-Ha1,18010,GRP_LAI,LAI_TYPE,LAI -US-Ha1,18014,GRP_LAI,LAI_TYPE,LAI -US-Ha1,18018,GRP_LAI,LAI_TYPE,LAI -US-Ha1,18022,GRP_LAI,LAI_TYPE,LAI -US-Ha1,18026,GRP_LAI,LAI_TYPE,LAI -US-Ha1,18030,GRP_LAI,LAI_TYPE,LAI -US-Ha1,18034,GRP_LAI,LAI_TYPE,LAI -US-Ha1,18038,GRP_LAI,LAI_TYPE,LAI -US-Ha1,18042,GRP_LAI,LAI_TYPE,LAI -US-Ha1,18046,GRP_LAI,LAI_TYPE,LAI -US-Ha1,18050,GRP_LAI,LAI_TYPE,LAI -US-Ha1,18054,GRP_LAI,LAI_TYPE,LAI -US-Ha1,18058,GRP_LAI,LAI_TYPE,LAI -US-Ha1,18062,GRP_LAI,LAI_TYPE,LAI -US-Ha1,18066,GRP_LAI,LAI_TYPE,LAI -US-Ha1,18070,GRP_LAI,LAI_TYPE,LAI -US-Ha1,18074,GRP_LAI,LAI_TYPE,LAI -US-Ha1,18078,GRP_LAI,LAI_TYPE,LAI -US-Ha1,18082,GRP_LAI,LAI_TYPE,LAI -US-Ha1,18086,GRP_LAI,LAI_TYPE,LAI -US-Ha1,18090,GRP_LAI,LAI_TYPE,LAI -US-Ha1,18094,GRP_LAI,LAI_TYPE,LAI -US-Ha1,18098,GRP_LAI,LAI_TYPE,LAI -US-Ha1,18102,GRP_LAI,LAI_TYPE,LAI -US-Ha1,18106,GRP_LAI,LAI_TYPE,LAI -US-Ha1,18110,GRP_LAI,LAI_TYPE,LAI -US-Ha1,18114,GRP_LAI,LAI_TYPE,LAI -US-Ha1,18118,GRP_LAI,LAI_TYPE,LAI -US-Ha1,18122,GRP_LAI,LAI_TYPE,LAI -US-Ha1,18126,GRP_LAI,LAI_TYPE,LAI -US-Ha1,18130,GRP_LAI,LAI_TYPE,LAI -US-Ha1,18134,GRP_LAI,LAI_TYPE,LAI -US-Ha1,18138,GRP_LAI,LAI_TYPE,LAI -US-Ha1,18142,GRP_LAI,LAI_TYPE,LAI -US-Ha1,18146,GRP_LAI,LAI_TYPE,LAI -US-Ha1,18150,GRP_LAI,LAI_TYPE,LAI -US-Ha1,18154,GRP_LAI,LAI_TYPE,LAI -US-Ha1,18158,GRP_LAI,LAI_TYPE,LAI -US-Ha1,18162,GRP_LAI,LAI_TYPE,LAI -US-Ha1,18166,GRP_LAI,LAI_TYPE,LAI -US-Ha1,18170,GRP_LAI,LAI_TYPE,LAI -US-Ha1,18174,GRP_LAI,LAI_TYPE,LAI -US-Ha1,18178,GRP_LAI,LAI_TYPE,LAI -US-Ha1,18182,GRP_LAI,LAI_TYPE,LAI -US-Ha1,18186,GRP_LAI,LAI_TYPE,LAI -US-Ha1,18190,GRP_LAI,LAI_TYPE,LAI -US-Ha1,18194,GRP_LAI,LAI_TYPE,LAI -US-Ha1,18198,GRP_LAI,LAI_TYPE,LAI -US-Ha1,18202,GRP_LAI,LAI_TYPE,LAI -US-Ha1,18206,GRP_LAI,LAI_TYPE,LAI -US-Ha1,18210,GRP_LAI,LAI_TYPE,LAI -US-Ha1,18214,GRP_LAI,LAI_TYPE,LAI -US-Ha1,18218,GRP_LAI,LAI_TYPE,LAI -US-Ha1,18222,GRP_LAI,LAI_TYPE,LAI -US-Ha1,18226,GRP_LAI,LAI_TYPE,LAI -US-Ha1,18230,GRP_LAI,LAI_TYPE,LAI -US-Ha1,18234,GRP_LAI,LAI_TYPE,LAI -US-Ha1,18238,GRP_LAI,LAI_TYPE,LAI -US-Ha1,18242,GRP_LAI,LAI_TYPE,LAI -US-Ha1,18246,GRP_LAI,LAI_TYPE,LAI -US-Ha1,18250,GRP_LAI,LAI_TYPE,LAI -US-Ha1,17365,GRP_LAI,LAI_APPROACH,Deciduous LAI is computed by taking the diffrence between the PAI at each plot/sample date and the minimum plot PAI for an individual year (which is assumed to be the total branch and conifer area). All measurements are taken using an LAI-2000 instrument held above the user's head (~2m above the ground). Raw data and a methods description are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data. -US-Ha1,17372,GRP_LAI,LAI_APPROACH,Deciduous LAI is computed by taking the diffrence between the PAI at each plot/sample date and the minimum plot PAI for an individual year (which is assumed to be the total branch and conifer area). All measurements are taken using an LAI-2000 instrument held above the user's head (~2m above the ground). Raw data and a methods description are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data. -US-Ha1,17378,GRP_LAI,LAI_APPROACH,Deciduous LAI is computed by taking the diffrence between the PAI at each plot/sample date and the minimum plot PAI for an individual year (which is assumed to be the total branch and conifer area). All measurements are taken using an LAI-2000 instrument held above the user's head (~2m above the ground). Raw data and a methods description are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data. -US-Ha1,17384,GRP_LAI,LAI_APPROACH,Deciduous LAI is computed by taking the diffrence between the PAI at each plot/sample date and the minimum plot PAI for an individual year (which is assumed to be the total branch and conifer area). All measurements are taken using an LAI-2000 instrument held above the user's head (~2m above the ground). Raw data and a methods description are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data. -US-Ha1,17390,GRP_LAI,LAI_APPROACH,Deciduous LAI is computed by taking the diffrence between the PAI at each plot/sample date and the minimum plot PAI for an individual year (which is assumed to be the total branch and conifer area). All measurements are taken using an LAI-2000 instrument held above the user's head (~2m above the ground). Raw data and a methods description are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data. -US-Ha1,17396,GRP_LAI,LAI_APPROACH,Deciduous LAI is computed by taking the diffrence between the PAI at each plot/sample date and the minimum plot PAI for an individual year (which is assumed to be the total branch and conifer area). All measurements are taken using an LAI-2000 instrument held above the user's head (~2m above the ground). Raw data and a methods description are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data. -US-Ha1,17402,GRP_LAI,LAI_APPROACH,Deciduous LAI is computed by taking the diffrence between the PAI at each plot/sample date and the minimum plot PAI for an individual year (which is assumed to be the total branch and conifer area). All measurements are taken using an LAI-2000 instrument held above the user's head (~2m above the ground). Raw data and a methods description are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data. -US-Ha1,17408,GRP_LAI,LAI_APPROACH,Deciduous LAI is computed by taking the diffrence between the PAI at each plot/sample date and the minimum plot PAI for an individual year (which is assumed to be the total branch and conifer area). All measurements are taken using an LAI-2000 instrument held above the user's head (~2m above the ground). Raw data and a methods description are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data. -US-Ha1,17414,GRP_LAI,LAI_APPROACH,Deciduous LAI is computed by taking the diffrence between the PAI at each plot/sample date and the minimum plot PAI for an individual year (which is assumed to be the total branch and conifer area). All measurements are taken using an LAI-2000 instrument held above the user's head (~2m above the ground). Raw data and a methods description are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data. -US-Ha1,17420,GRP_LAI,LAI_APPROACH,Deciduous LAI is computed by taking the diffrence between the PAI at each plot/sample date and the minimum plot PAI for an individual year (which is assumed to be the total branch and conifer area). All measurements are taken using an LAI-2000 instrument held above the user's head (~2m above the ground). Raw data and a methods description are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data. -US-Ha1,17426,GRP_LAI,LAI_APPROACH,Deciduous LAI is computed by taking the diffrence between the PAI at each plot/sample date and the minimum plot PAI for an individual year (which is assumed to be the total branch and conifer area). All measurements are taken using an LAI-2000 instrument held above the user's head (~2m above the ground). Raw data and a methods description are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data. -US-Ha1,17432,GRP_LAI,LAI_APPROACH,Deciduous LAI is computed by taking the diffrence between the PAI at each plot/sample date and the minimum plot PAI for an individual year (which is assumed to be the total branch and conifer area). All measurements are taken using an LAI-2000 instrument held above the user's head (~2m above the ground). Raw data and a methods description are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data. -US-Ha1,17438,GRP_LAI,LAI_APPROACH,Deciduous LAI is computed by taking the diffrence between the PAI at each plot/sample date and the minimum plot PAI for an individual year (which is assumed to be the total branch and conifer area). All measurements are taken using an LAI-2000 instrument held above the user's head (~2m above the ground). Raw data and a methods description are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data. -US-Ha1,17444,GRP_LAI,LAI_APPROACH,Deciduous LAI is computed by taking the diffrence between the PAI at each plot/sample date and the minimum plot PAI for an individual year (which is assumed to be the total branch and conifer area). All measurements are taken using an LAI-2000 instrument held above the user's head (~2m above the ground). Raw data and a methods description are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data. -US-Ha1,17450,GRP_LAI,LAI_APPROACH,Deciduous LAI is computed by taking the diffrence between the PAI at each plot/sample date and the minimum plot PAI for an individual year (which is assumed to be the total branch and conifer area). All measurements are taken using an LAI-2000 instrument held above the user's head (~2m above the ground). Raw data and a methods description are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data. -US-Ha1,17456,GRP_LAI,LAI_APPROACH,Deciduous LAI is computed by taking the diffrence between the PAI at each plot/sample date and the minimum plot PAI for an individual year (which is assumed to be the total branch and conifer area). All measurements are taken using an LAI-2000 instrument held above the user's head (~2m above the ground). Raw data and a methods description are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data. -US-Ha1,17461,GRP_LAI,LAI_APPROACH,Deciduous LAI is computed by taking the diffrence between the PAI at each plot/sample date and the minimum plot PAI for an individual year (which is assumed to be the total branch and conifer area). All measurements are taken using an LAI-2000 instrument held above the user's head (~2m above the ground). Raw data and a methods description are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data. -US-Ha1,17466,GRP_LAI,LAI_APPROACH,Deciduous LAI is computed by taking the diffrence between the PAI at each plot/sample date and the minimum plot PAI for an individual year (which is assumed to be the total branch and conifer area). All measurements are taken using an LAI-2000 instrument held above the user's head (~2m above the ground). Raw data and a methods description are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data. -US-Ha1,17471,GRP_LAI,LAI_APPROACH,Deciduous LAI is computed by taking the diffrence between the PAI at each plot/sample date and the minimum plot PAI for an individual year (which is assumed to be the total branch and conifer area). All measurements are taken using an LAI-2000 instrument held above the user's head (~2m above the ground). Raw data and a methods description are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data. -US-Ha1,17476,GRP_LAI,LAI_APPROACH,Deciduous LAI is computed by taking the diffrence between the PAI at each plot/sample date and the minimum plot PAI for an individual year (which is assumed to be the total branch and conifer area). All measurements are taken using an LAI-2000 instrument held above the user's head (~2m above the ground). Raw data and a methods description are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data. -US-Ha1,17480,GRP_LAI,LAI_APPROACH,Deciduous LAI is computed by taking the diffrence between the PAI at each plot/sample date and the minimum plot PAI for an individual year (which is assumed to be the total branch and conifer area). All measurements are taken using an LAI-2000 instrument held above the user's head (~2m above the ground). Raw data and a methods description are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data. -US-Ha1,17484,GRP_LAI,LAI_APPROACH,Deciduous LAI is computed by taking the diffrence between the PAI at each plot/sample date and the minimum plot PAI for an individual year (which is assumed to be the total branch and conifer area). All measurements are taken using an LAI-2000 instrument held above the user's head (~2m above the ground). Raw data and a methods description are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data. -US-Ha1,17488,GRP_LAI,LAI_APPROACH,Deciduous LAI is computed by taking the diffrence between the PAI at each plot/sample date and the minimum plot PAI for an individual year (which is assumed to be the total branch and conifer area). All measurements are taken using an LAI-2000 instrument held above the user's head (~2m above the ground). Raw data and a methods description are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data. -US-Ha1,17492,GRP_LAI,LAI_APPROACH,Deciduous LAI is computed by taking the diffrence between the PAI at each plot/sample date and the minimum plot PAI for an individual year (which is assumed to be the total branch and conifer area). All measurements are taken using an LAI-2000 instrument held above the user's head (~2m above the ground). Raw data and a methods description are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data. -US-Ha1,17496,GRP_LAI,LAI_APPROACH,Deciduous LAI is computed by taking the diffrence between the PAI at each plot/sample date and the minimum plot PAI for an individual year (which is assumed to be the total branch and conifer area). All measurements are taken using an LAI-2000 instrument held above the user's head (~2m above the ground). Raw data and a methods description are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data. -US-Ha1,17500,GRP_LAI,LAI_APPROACH,Deciduous LAI is computed by taking the diffrence between the PAI at each plot/sample date and the minimum plot PAI for an individual year (which is assumed to be the total branch and conifer area). All measurements are taken using an LAI-2000 instrument held above the user's head (~2m above the ground). Raw data and a methods description are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data. -US-Ha1,17504,GRP_LAI,LAI_APPROACH,Deciduous LAI is computed by taking the diffrence between the PAI at each plot/sample date and the minimum plot PAI for an individual year (which is assumed to be the total branch and conifer area). All measurements are taken using an LAI-2000 instrument held above the user's head (~2m above the ground). Raw data and a methods description are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data. -US-Ha1,17508,GRP_LAI,LAI_APPROACH,Deciduous LAI is computed by taking the diffrence between the PAI at each plot/sample date and the minimum plot PAI for an individual year (which is assumed to be the total branch and conifer area). All measurements are taken using an LAI-2000 instrument held above the user's head (~2m above the ground). Raw data and a methods description are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data. -US-Ha1,17512,GRP_LAI,LAI_APPROACH,Deciduous LAI is computed by taking the diffrence between the PAI at each plot/sample date and the minimum plot PAI for an individual year (which is assumed to be the total branch and conifer area). All measurements are taken using an LAI-2000 instrument held above the user's head (~2m above the ground). Raw data and a methods description are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data. -US-Ha1,17516,GRP_LAI,LAI_APPROACH,Deciduous LAI is computed by taking the diffrence between the PAI at each plot/sample date and the minimum plot PAI for an individual year (which is assumed to be the total branch and conifer area). All measurements are taken using an LAI-2000 instrument held above the user's head (~2m above the ground). Raw data and a methods description are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data. -US-Ha1,17847,GRP_LAI,LAI_APPROACH,Deciduous LAI is computed by taking the diffrence between the PAI at each plot/sample date and the minimum plot PAI for an individual year (which is assumed to be the total branch and conifer area). All measurements are taken using an LAI-2000 instrument held above the user's head (~2m above the ground). Raw data and a methods description are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data. -US-Ha1,17851,GRP_LAI,LAI_APPROACH,Deciduous LAI is computed by taking the diffrence between the PAI at each plot/sample date and the minimum plot PAI for an individual year (which is assumed to be the total branch and conifer area). All measurements are taken using an LAI-2000 instrument held above the user's head (~2m above the ground). Raw data and a methods description are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data. -US-Ha1,17855,GRP_LAI,LAI_APPROACH,Deciduous LAI is computed by taking the diffrence between the PAI at each plot/sample date and the minimum plot PAI for an individual year (which is assumed to be the total branch and conifer area). All measurements are taken using an LAI-2000 instrument held above the user's head (~2m above the ground). Raw data and a methods description are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data. -US-Ha1,17859,GRP_LAI,LAI_APPROACH,Deciduous LAI is computed by taking the diffrence between the PAI at each plot/sample date and the minimum plot PAI for an individual year (which is assumed to be the total branch and conifer area). All measurements are taken using an LAI-2000 instrument held above the user's head (~2m above the ground). Raw data and a methods description are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data. -US-Ha1,17863,GRP_LAI,LAI_APPROACH,Deciduous LAI is computed by taking the diffrence between the PAI at each plot/sample date and the minimum plot PAI for an individual year (which is assumed to be the total branch and conifer area). All measurements are taken using an LAI-2000 instrument held above the user's head (~2m above the ground). Raw data and a methods description are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data. -US-Ha1,17867,GRP_LAI,LAI_APPROACH,Deciduous LAI is computed by taking the diffrence between the PAI at each plot/sample date and the minimum plot PAI for an individual year (which is assumed to be the total branch and conifer area). All measurements are taken using an LAI-2000 instrument held above the user's head (~2m above the ground). Raw data and a methods description are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data. -US-Ha1,17871,GRP_LAI,LAI_APPROACH,Deciduous LAI is computed by taking the diffrence between the PAI at each plot/sample date and the minimum plot PAI for an individual year (which is assumed to be the total branch and conifer area). All measurements are taken using an LAI-2000 instrument held above the user's head (~2m above the ground). Raw data and a methods description are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data. -US-Ha1,17875,GRP_LAI,LAI_APPROACH,Deciduous LAI is computed by taking the diffrence between the PAI at each plot/sample date and the minimum plot PAI for an individual year (which is assumed to be the total branch and conifer area). All measurements are taken using an LAI-2000 instrument held above the user's head (~2m above the ground). Raw data and a methods description are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data. -US-Ha1,17879,GRP_LAI,LAI_APPROACH,Deciduous LAI is computed by taking the diffrence between the PAI at each plot/sample date and the minimum plot PAI for an individual year (which is assumed to be the total branch and conifer area). All measurements are taken using an LAI-2000 instrument held above the user's head (~2m above the ground). Raw data and a methods description are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data. -US-Ha1,17883,GRP_LAI,LAI_APPROACH,Deciduous LAI is computed by taking the diffrence between the PAI at each plot/sample date and the minimum plot PAI for an individual year (which is assumed to be the total branch and conifer area). All measurements are taken using an LAI-2000 instrument held above the user's head (~2m above the ground). Raw data and a methods description are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data. -US-Ha1,17887,GRP_LAI,LAI_APPROACH,Deciduous LAI is computed by taking the diffrence between the PAI at each plot/sample date and the minimum plot PAI for an individual year (which is assumed to be the total branch and conifer area). All measurements are taken using an LAI-2000 instrument held above the user's head (~2m above the ground). Raw data and a methods description are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data. -US-Ha1,17891,GRP_LAI,LAI_APPROACH,Deciduous LAI is computed by taking the diffrence between the PAI at each plot/sample date and the minimum plot PAI for an individual year (which is assumed to be the total branch and conifer area). All measurements are taken using an LAI-2000 instrument held above the user's head (~2m above the ground). Raw data and a methods description are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data. -US-Ha1,17895,GRP_LAI,LAI_APPROACH,Deciduous LAI is computed by taking the diffrence between the PAI at each plot/sample date and the minimum plot PAI for an individual year (which is assumed to be the total branch and conifer area). All measurements are taken using an LAI-2000 instrument held above the user's head (~2m above the ground). Raw data and a methods description are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data. -US-Ha1,17899,GRP_LAI,LAI_APPROACH,Deciduous LAI is computed by taking the diffrence between the PAI at each plot/sample date and the minimum plot PAI for an individual year (which is assumed to be the total branch and conifer area). All measurements are taken using an LAI-2000 instrument held above the user's head (~2m above the ground). Raw data and a methods description are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data. -US-Ha1,17903,GRP_LAI,LAI_APPROACH,Deciduous LAI is computed by taking the diffrence between the PAI at each plot/sample date and the minimum plot PAI for an individual year (which is assumed to be the total branch and conifer area). All measurements are taken using an LAI-2000 instrument held above the user's head (~2m above the ground). Raw data and a methods description are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data. -US-Ha1,17907,GRP_LAI,LAI_APPROACH,Deciduous LAI is computed by taking the diffrence between the PAI at each plot/sample date and the minimum plot PAI for an individual year (which is assumed to be the total branch and conifer area). All measurements are taken using an LAI-2000 instrument held above the user's head (~2m above the ground). Raw data and a methods description are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data. -US-Ha1,17911,GRP_LAI,LAI_APPROACH,Deciduous LAI is computed by taking the diffrence between the PAI at each plot/sample date and the minimum plot PAI for an individual year (which is assumed to be the total branch and conifer area). All measurements are taken using an LAI-2000 instrument held above the user's head (~2m above the ground). Raw data and a methods description are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data. -US-Ha1,17915,GRP_LAI,LAI_APPROACH,Deciduous LAI is computed by taking the diffrence between the PAI at each plot/sample date and the minimum plot PAI for an individual year (which is assumed to be the total branch and conifer area). All measurements are taken using an LAI-2000 instrument held above the user's head (~2m above the ground). Raw data and a methods description are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data. -US-Ha1,17919,GRP_LAI,LAI_APPROACH,Deciduous LAI is computed by taking the diffrence between the PAI at each plot/sample date and the minimum plot PAI for an individual year (which is assumed to be the total branch and conifer area). All measurements are taken using an LAI-2000 instrument held above the user's head (~2m above the ground). Raw data and a methods description are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data. -US-Ha1,17923,GRP_LAI,LAI_APPROACH,Deciduous LAI is computed by taking the diffrence between the PAI at each plot/sample date and the minimum plot PAI for an individual year (which is assumed to be the total branch and conifer area). All measurements are taken using an LAI-2000 instrument held above the user's head (~2m above the ground). Raw data and a methods description are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data. -US-Ha1,17927,GRP_LAI,LAI_APPROACH,Deciduous LAI is computed by taking the diffrence between the PAI at each plot/sample date and the minimum plot PAI for an individual year (which is assumed to be the total branch and conifer area). All measurements are taken using an LAI-2000 instrument held above the user's head (~2m above the ground). Raw data and a methods description are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data. -US-Ha1,17931,GRP_LAI,LAI_APPROACH,Deciduous LAI is computed by taking the diffrence between the PAI at each plot/sample date and the minimum plot PAI for an individual year (which is assumed to be the total branch and conifer area). All measurements are taken using an LAI-2000 instrument held above the user's head (~2m above the ground). Raw data and a methods description are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data. -US-Ha1,17935,GRP_LAI,LAI_APPROACH,Deciduous LAI is computed by taking the diffrence between the PAI at each plot/sample date and the minimum plot PAI for an individual year (which is assumed to be the total branch and conifer area). All measurements are taken using an LAI-2000 instrument held above the user's head (~2m above the ground). Raw data and a methods description are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data. -US-Ha1,17939,GRP_LAI,LAI_APPROACH,Deciduous LAI is computed by taking the diffrence between the PAI at each plot/sample date and the minimum plot PAI for an individual year (which is assumed to be the total branch and conifer area). All measurements are taken using an LAI-2000 instrument held above the user's head (~2m above the ground). Raw data and a methods description are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data. -US-Ha1,17943,GRP_LAI,LAI_APPROACH,Deciduous LAI is computed by taking the diffrence between the PAI at each plot/sample date and the minimum plot PAI for an individual year (which is assumed to be the total branch and conifer area). All measurements are taken using an LAI-2000 instrument held above the user's head (~2m above the ground). Raw data and a methods description are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data. -US-Ha1,17947,GRP_LAI,LAI_APPROACH,Deciduous LAI is computed by taking the diffrence between the PAI at each plot/sample date and the minimum plot PAI for an individual year (which is assumed to be the total branch and conifer area). All measurements are taken using an LAI-2000 instrument held above the user's head (~2m above the ground). Raw data and a methods description are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data. -US-Ha1,17951,GRP_LAI,LAI_APPROACH,Deciduous LAI is computed by taking the diffrence between the PAI at each plot/sample date and the minimum plot PAI for an individual year (which is assumed to be the total branch and conifer area). All measurements are taken using an LAI-2000 instrument held above the user's head (~2m above the ground). Raw data and a methods description are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data. -US-Ha1,17958,GRP_LAI,LAI_APPROACH,Deciduous LAI is computed by taking the diffrence between the PAI at each plot/sample date and the minimum plot PAI for an individual year (which is assumed to be the total branch and conifer area). All measurements are taken using an LAI-2000 instrument held above the user's head (~2m above the ground). Raw data and a methods description are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data. -US-Ha1,17962,GRP_LAI,LAI_APPROACH,Deciduous LAI is computed by taking the diffrence between the PAI at each plot/sample date and the minimum plot PAI for an individual year (which is assumed to be the total branch and conifer area). All measurements are taken using an LAI-2000 instrument held above the user's head (~2m above the ground). Raw data and a methods description are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data. -US-Ha1,17966,GRP_LAI,LAI_APPROACH,Deciduous LAI is computed by taking the diffrence between the PAI at each plot/sample date and the minimum plot PAI for an individual year (which is assumed to be the total branch and conifer area). All measurements are taken using an LAI-2000 instrument held above the user's head (~2m above the ground). Raw data and a methods description are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data. -US-Ha1,17970,GRP_LAI,LAI_APPROACH,Deciduous LAI is computed by taking the diffrence between the PAI at each plot/sample date and the minimum plot PAI for an individual year (which is assumed to be the total branch and conifer area). All measurements are taken using an LAI-2000 instrument held above the user's head (~2m above the ground). Raw data and a methods description are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data. -US-Ha1,17974,GRP_LAI,LAI_APPROACH,Deciduous LAI is computed by taking the diffrence between the PAI at each plot/sample date and the minimum plot PAI for an individual year (which is assumed to be the total branch and conifer area). All measurements are taken using an LAI-2000 instrument held above the user's head (~2m above the ground). Raw data and a methods description are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data. -US-Ha1,17978,GRP_LAI,LAI_APPROACH,Deciduous LAI is computed by taking the diffrence between the PAI at each plot/sample date and the minimum plot PAI for an individual year (which is assumed to be the total branch and conifer area). All measurements are taken using an LAI-2000 instrument held above the user's head (~2m above the ground). Raw data and a methods description are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data. -US-Ha1,17982,GRP_LAI,LAI_APPROACH,Deciduous LAI is computed by taking the diffrence between the PAI at each plot/sample date and the minimum plot PAI for an individual year (which is assumed to be the total branch and conifer area). All measurements are taken using an LAI-2000 instrument held above the user's head (~2m above the ground). Raw data and a methods description are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data. -US-Ha1,17986,GRP_LAI,LAI_APPROACH,Deciduous LAI is computed by taking the diffrence between the PAI at each plot/sample date and the minimum plot PAI for an individual year (which is assumed to be the total branch and conifer area). All measurements are taken using an LAI-2000 instrument held above the user's head (~2m above the ground). Raw data and a methods description are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data. -US-Ha1,17990,GRP_LAI,LAI_APPROACH,Deciduous LAI is computed by taking the diffrence between the PAI at each plot/sample date and the minimum plot PAI for an individual year (which is assumed to be the total branch and conifer area). All measurements are taken using an LAI-2000 instrument held above the user's head (~2m above the ground). Raw data and a methods description are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data. -US-Ha1,17994,GRP_LAI,LAI_APPROACH,Deciduous LAI is computed by taking the diffrence between the PAI at each plot/sample date and the minimum plot PAI for an individual year (which is assumed to be the total branch and conifer area). All measurements are taken using an LAI-2000 instrument held above the user's head (~2m above the ground). Raw data and a methods description are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data. -US-Ha1,17998,GRP_LAI,LAI_APPROACH,Deciduous LAI is computed by taking the diffrence between the PAI at each plot/sample date and the minimum plot PAI for an individual year (which is assumed to be the total branch and conifer area). All measurements are taken using an LAI-2000 instrument held above the user's head (~2m above the ground). Raw data and a methods description are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data. -US-Ha1,18002,GRP_LAI,LAI_APPROACH,Deciduous LAI is computed by taking the diffrence between the PAI at each plot/sample date and the minimum plot PAI for an individual year (which is assumed to be the total branch and conifer area). All measurements are taken using an LAI-2000 instrument held above the user's head (~2m above the ground). Raw data and a methods description are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data. -US-Ha1,18006,GRP_LAI,LAI_APPROACH,Deciduous LAI is computed by taking the diffrence between the PAI at each plot/sample date and the minimum plot PAI for an individual year (which is assumed to be the total branch and conifer area). All measurements are taken using an LAI-2000 instrument held above the user's head (~2m above the ground). Raw data and a methods description are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data. -US-Ha1,18010,GRP_LAI,LAI_APPROACH,Deciduous LAI is computed by taking the diffrence between the PAI at each plot/sample date and the minimum plot PAI for an individual year (which is assumed to be the total branch and conifer area). All measurements are taken using an LAI-2000 instrument held above the user's head (~2m above the ground). Raw data and a methods description are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data. -US-Ha1,18014,GRP_LAI,LAI_APPROACH,Deciduous LAI is computed by taking the diffrence between the PAI at each plot/sample date and the minimum plot PAI for an individual year (which is assumed to be the total branch and conifer area). All measurements are taken using an LAI-2000 instrument held above the user's head (~2m above the ground). Raw data and a methods description are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data. -US-Ha1,18018,GRP_LAI,LAI_APPROACH,Deciduous LAI is computed by taking the diffrence between the PAI at each plot/sample date and the minimum plot PAI for an individual year (which is assumed to be the total branch and conifer area). All measurements are taken using an LAI-2000 instrument held above the user's head (~2m above the ground). Raw data and a methods description are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data. -US-Ha1,18022,GRP_LAI,LAI_APPROACH,Deciduous LAI is computed by taking the diffrence between the PAI at each plot/sample date and the minimum plot PAI for an individual year (which is assumed to be the total branch and conifer area). All measurements are taken using an LAI-2000 instrument held above the user's head (~2m above the ground). Raw data and a methods description are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data. -US-Ha1,18026,GRP_LAI,LAI_APPROACH,Deciduous LAI is computed by taking the diffrence between the PAI at each plot/sample date and the minimum plot PAI for an individual year (which is assumed to be the total branch and conifer area). All measurements are taken using an LAI-2000 instrument held above the user's head (~2m above the ground). Raw data and a methods description are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data. -US-Ha1,18030,GRP_LAI,LAI_APPROACH,Deciduous LAI is computed by taking the diffrence between the PAI at each plot/sample date and the minimum plot PAI for an individual year (which is assumed to be the total branch and conifer area). All measurements are taken using an LAI-2000 instrument held above the user's head (~2m above the ground). Raw data and a methods description are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data. -US-Ha1,18034,GRP_LAI,LAI_APPROACH,Deciduous LAI is computed by taking the diffrence between the PAI at each plot/sample date and the minimum plot PAI for an individual year (which is assumed to be the total branch and conifer area). All measurements are taken using an LAI-2000 instrument held above the user's head (~2m above the ground). Raw data and a methods description are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data. -US-Ha1,18038,GRP_LAI,LAI_APPROACH,Deciduous LAI is computed by taking the diffrence between the PAI at each plot/sample date and the minimum plot PAI for an individual year (which is assumed to be the total branch and conifer area). All measurements are taken using an LAI-2000 instrument held above the user's head (~2m above the ground). Raw data and a methods description are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data. -US-Ha1,18042,GRP_LAI,LAI_APPROACH,Deciduous LAI is computed by taking the diffrence between the PAI at each plot/sample date and the minimum plot PAI for an individual year (which is assumed to be the total branch and conifer area). All measurements are taken using an LAI-2000 instrument held above the user's head (~2m above the ground). Raw data and a methods description are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data. -US-Ha1,18046,GRP_LAI,LAI_APPROACH,Deciduous LAI is computed by taking the diffrence between the PAI at each plot/sample date and the minimum plot PAI for an individual year (which is assumed to be the total branch and conifer area). All measurements are taken using an LAI-2000 instrument held above the user's head (~2m above the ground). Raw data and a methods description are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data. -US-Ha1,18050,GRP_LAI,LAI_APPROACH,Deciduous LAI is computed by taking the diffrence between the PAI at each plot/sample date and the minimum plot PAI for an individual year (which is assumed to be the total branch and conifer area). All measurements are taken using an LAI-2000 instrument held above the user's head (~2m above the ground). Raw data and a methods description are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data. -US-Ha1,18054,GRP_LAI,LAI_APPROACH,Deciduous LAI is computed by taking the diffrence between the PAI at each plot/sample date and the minimum plot PAI for an individual year (which is assumed to be the total branch and conifer area). All measurements are taken using an LAI-2000 instrument held above the user's head (~2m above the ground). Raw data and a methods description are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data. -US-Ha1,18058,GRP_LAI,LAI_APPROACH,Deciduous LAI is computed by taking the diffrence between the PAI at each plot/sample date and the minimum plot PAI for an individual year (which is assumed to be the total branch and conifer area). All measurements are taken using an LAI-2000 instrument held above the user's head (~2m above the ground). Raw data and a methods description are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data. -US-Ha1,18062,GRP_LAI,LAI_APPROACH,Deciduous LAI is computed by taking the diffrence between the PAI at each plot/sample date and the minimum plot PAI for an individual year (which is assumed to be the total branch and conifer area). All measurements are taken using an LAI-2000 instrument held above the user's head (~2m above the ground). Raw data and a methods description are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data. -US-Ha1,18066,GRP_LAI,LAI_APPROACH,Deciduous LAI is computed by taking the diffrence between the PAI at each plot/sample date and the minimum plot PAI for an individual year (which is assumed to be the total branch and conifer area). All measurements are taken using an LAI-2000 instrument held above the user's head (~2m above the ground). Raw data and a methods description are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data. -US-Ha1,18070,GRP_LAI,LAI_APPROACH,Deciduous LAI is computed by taking the diffrence between the PAI at each plot/sample date and the minimum plot PAI for an individual year (which is assumed to be the total branch and conifer area). All measurements are taken using an LAI-2000 instrument held above the user's head (~2m above the ground). Raw data and a methods description are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data. -US-Ha1,18074,GRP_LAI,LAI_APPROACH,Deciduous LAI is computed by taking the diffrence between the PAI at each plot/sample date and the minimum plot PAI for an individual year (which is assumed to be the total branch and conifer area). All measurements are taken using an LAI-2000 instrument held above the user's head (~2m above the ground). Raw data and a methods description are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data. -US-Ha1,18078,GRP_LAI,LAI_APPROACH,Deciduous LAI is computed by taking the diffrence between the PAI at each plot/sample date and the minimum plot PAI for an individual year (which is assumed to be the total branch and conifer area). All measurements are taken using an LAI-2000 instrument held above the user's head (~2m above the ground). Raw data and a methods description are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data. -US-Ha1,18082,GRP_LAI,LAI_APPROACH,Deciduous LAI is computed by taking the diffrence between the PAI at each plot/sample date and the minimum plot PAI for an individual year (which is assumed to be the total branch and conifer area). All measurements are taken using an LAI-2000 instrument held above the user's head (~2m above the ground). Raw data and a methods description are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data. -US-Ha1,18086,GRP_LAI,LAI_APPROACH,Deciduous LAI is computed by taking the diffrence between the PAI at each plot/sample date and the minimum plot PAI for an individual year (which is assumed to be the total branch and conifer area). All measurements are taken using an LAI-2000 instrument held above the user's head (~2m above the ground). Raw data and a methods description are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data. -US-Ha1,18090,GRP_LAI,LAI_APPROACH,Deciduous LAI is computed by taking the diffrence between the PAI at each plot/sample date and the minimum plot PAI for an individual year (which is assumed to be the total branch and conifer area). All measurements are taken using an LAI-2000 instrument held above the user's head (~2m above the ground). Raw data and a methods description are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data. -US-Ha1,18094,GRP_LAI,LAI_APPROACH,Deciduous LAI is computed by taking the diffrence between the PAI at each plot/sample date and the minimum plot PAI for an individual year (which is assumed to be the total branch and conifer area). All measurements are taken using an LAI-2000 instrument held above the user's head (~2m above the ground). Raw data and a methods description are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data. -US-Ha1,18098,GRP_LAI,LAI_APPROACH,Deciduous LAI is computed by taking the diffrence between the PAI at each plot/sample date and the minimum plot PAI for an individual year (which is assumed to be the total branch and conifer area). All measurements are taken using an LAI-2000 instrument held above the user's head (~2m above the ground). Raw data and a methods description are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data. -US-Ha1,18102,GRP_LAI,LAI_APPROACH,Deciduous LAI is computed by taking the diffrence between the PAI at each plot/sample date and the minimum plot PAI for an individual year (which is assumed to be the total branch and conifer area). All measurements are taken using an LAI-2000 instrument held above the user's head (~2m above the ground). Raw data and a methods description are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data. -US-Ha1,18106,GRP_LAI,LAI_APPROACH,Deciduous LAI is computed by taking the diffrence between the PAI at each plot/sample date and the minimum plot PAI for an individual year (which is assumed to be the total branch and conifer area). All measurements are taken using an LAI-2000 instrument held above the user's head (~2m above the ground). Raw data and a methods description are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data. -US-Ha1,18110,GRP_LAI,LAI_APPROACH,Deciduous LAI is computed by taking the diffrence between the PAI at each plot/sample date and the minimum plot PAI for an individual year (which is assumed to be the total branch and conifer area). All measurements are taken using an LAI-2000 instrument held above the user's head (~2m above the ground). Raw data and a methods description are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data. -US-Ha1,18114,GRP_LAI,LAI_APPROACH,Deciduous LAI is computed by taking the diffrence between the PAI at each plot/sample date and the minimum plot PAI for an individual year (which is assumed to be the total branch and conifer area). All measurements are taken using an LAI-2000 instrument held above the user's head (~2m above the ground). Raw data and a methods description are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data. -US-Ha1,18118,GRP_LAI,LAI_APPROACH,Deciduous LAI is computed by taking the diffrence between the PAI at each plot/sample date and the minimum plot PAI for an individual year (which is assumed to be the total branch and conifer area). All measurements are taken using an LAI-2000 instrument held above the user's head (~2m above the ground). Raw data and a methods description are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data. -US-Ha1,18122,GRP_LAI,LAI_APPROACH,Deciduous LAI is computed by taking the diffrence between the PAI at each plot/sample date and the minimum plot PAI for an individual year (which is assumed to be the total branch and conifer area). All measurements are taken using an LAI-2000 instrument held above the user's head (~2m above the ground). Raw data and a methods description are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data. -US-Ha1,18126,GRP_LAI,LAI_APPROACH,Deciduous LAI is computed by taking the diffrence between the PAI at each plot/sample date and the minimum plot PAI for an individual year (which is assumed to be the total branch and conifer area). All measurements are taken using an LAI-2000 instrument held above the user's head (~2m above the ground). Raw data and a methods description are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data. -US-Ha1,18130,GRP_LAI,LAI_APPROACH,Deciduous LAI is computed by taking the diffrence between the PAI at each plot/sample date and the minimum plot PAI for an individual year (which is assumed to be the total branch and conifer area). All measurements are taken using an LAI-2000 instrument held above the user's head (~2m above the ground). Raw data and a methods description are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data. -US-Ha1,18134,GRP_LAI,LAI_APPROACH,Deciduous LAI is computed by taking the diffrence between the PAI at each plot/sample date and the minimum plot PAI for an individual year (which is assumed to be the total branch and conifer area). All measurements are taken using an LAI-2000 instrument held above the user's head (~2m above the ground). Raw data and a methods description are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data. -US-Ha1,18138,GRP_LAI,LAI_APPROACH,Deciduous LAI is computed by taking the diffrence between the PAI at each plot/sample date and the minimum plot PAI for an individual year (which is assumed to be the total branch and conifer area). All measurements are taken using an LAI-2000 instrument held above the user's head (~2m above the ground). Raw data and a methods description are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data. -US-Ha1,18142,GRP_LAI,LAI_APPROACH,Deciduous LAI is computed by taking the diffrence between the PAI at each plot/sample date and the minimum plot PAI for an individual year (which is assumed to be the total branch and conifer area). All measurements are taken using an LAI-2000 instrument held above the user's head (~2m above the ground). Raw data and a methods description are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data. -US-Ha1,18146,GRP_LAI,LAI_APPROACH,Deciduous LAI is computed by taking the diffrence between the PAI at each plot/sample date and the minimum plot PAI for an individual year (which is assumed to be the total branch and conifer area). All measurements are taken using an LAI-2000 instrument held above the user's head (~2m above the ground). Raw data and a methods description are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data. -US-Ha1,18150,GRP_LAI,LAI_APPROACH,Deciduous LAI is computed by taking the diffrence between the PAI at each plot/sample date and the minimum plot PAI for an individual year (which is assumed to be the total branch and conifer area). All measurements are taken using an LAI-2000 instrument held above the user's head (~2m above the ground). Raw data and a methods description are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data. -US-Ha1,18154,GRP_LAI,LAI_APPROACH,Deciduous LAI is computed by taking the diffrence between the PAI at each plot/sample date and the minimum plot PAI for an individual year (which is assumed to be the total branch and conifer area). All measurements are taken using an LAI-2000 instrument held above the user's head (~2m above the ground). Raw data and a methods description are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data. -US-Ha1,18158,GRP_LAI,LAI_APPROACH,Deciduous LAI is computed by taking the diffrence between the PAI at each plot/sample date and the minimum plot PAI for an individual year (which is assumed to be the total branch and conifer area). All measurements are taken using an LAI-2000 instrument held above the user's head (~2m above the ground). Raw data and a methods description are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data. -US-Ha1,18162,GRP_LAI,LAI_APPROACH,Deciduous LAI is computed by taking the diffrence between the PAI at each plot/sample date and the minimum plot PAI for an individual year (which is assumed to be the total branch and conifer area). All measurements are taken using an LAI-2000 instrument held above the user's head (~2m above the ground). Raw data and a methods description are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data. -US-Ha1,18166,GRP_LAI,LAI_APPROACH,Deciduous LAI is computed by taking the diffrence between the PAI at each plot/sample date and the minimum plot PAI for an individual year (which is assumed to be the total branch and conifer area). All measurements are taken using an LAI-2000 instrument held above the user's head (~2m above the ground). Raw data and a methods description are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data. -US-Ha1,18170,GRP_LAI,LAI_APPROACH,Deciduous LAI is computed by taking the diffrence between the PAI at each plot/sample date and the minimum plot PAI for an individual year (which is assumed to be the total branch and conifer area). All measurements are taken using an LAI-2000 instrument held above the user's head (~2m above the ground). Raw data and a methods description are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data. -US-Ha1,18174,GRP_LAI,LAI_APPROACH,Deciduous LAI is computed by taking the diffrence between the PAI at each plot/sample date and the minimum plot PAI for an individual year (which is assumed to be the total branch and conifer area). All measurements are taken using an LAI-2000 instrument held above the user's head (~2m above the ground). Raw data and a methods description are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data. -US-Ha1,18178,GRP_LAI,LAI_APPROACH,Deciduous LAI is computed by taking the diffrence between the PAI at each plot/sample date and the minimum plot PAI for an individual year (which is assumed to be the total branch and conifer area). All measurements are taken using an LAI-2000 instrument held above the user's head (~2m above the ground). Raw data and a methods description are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data. -US-Ha1,18182,GRP_LAI,LAI_APPROACH,Deciduous LAI is computed by taking the diffrence between the PAI at each plot/sample date and the minimum plot PAI for an individual year (which is assumed to be the total branch and conifer area). All measurements are taken using an LAI-2000 instrument held above the user's head (~2m above the ground). Raw data and a methods description are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data. -US-Ha1,18186,GRP_LAI,LAI_APPROACH,Deciduous LAI is computed by taking the diffrence between the PAI at each plot/sample date and the minimum plot PAI for an individual year (which is assumed to be the total branch and conifer area). All measurements are taken using an LAI-2000 instrument held above the user's head (~2m above the ground). Raw data and a methods description are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data. -US-Ha1,18190,GRP_LAI,LAI_APPROACH,Deciduous LAI is computed by taking the diffrence between the PAI at each plot/sample date and the minimum plot PAI for an individual year (which is assumed to be the total branch and conifer area). All measurements are taken using an LAI-2000 instrument held above the user's head (~2m above the ground). Raw data and a methods description are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data. -US-Ha1,18194,GRP_LAI,LAI_APPROACH,Deciduous LAI is computed by taking the diffrence between the PAI at each plot/sample date and the minimum plot PAI for an individual year (which is assumed to be the total branch and conifer area). All measurements are taken using an LAI-2000 instrument held above the user's head (~2m above the ground). Raw data and a methods description are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data. -US-Ha1,18198,GRP_LAI,LAI_APPROACH,Deciduous LAI is computed by taking the diffrence between the PAI at each plot/sample date and the minimum plot PAI for an individual year (which is assumed to be the total branch and conifer area). All measurements are taken using an LAI-2000 instrument held above the user's head (~2m above the ground). Raw data and a methods description are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data. -US-Ha1,18202,GRP_LAI,LAI_APPROACH,Deciduous LAI is computed by taking the diffrence between the PAI at each plot/sample date and the minimum plot PAI for an individual year (which is assumed to be the total branch and conifer area). All measurements are taken using an LAI-2000 instrument held above the user's head (~2m above the ground). Raw data and a methods description are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data. -US-Ha1,18206,GRP_LAI,LAI_APPROACH,Deciduous LAI is computed by taking the diffrence between the PAI at each plot/sample date and the minimum plot PAI for an individual year (which is assumed to be the total branch and conifer area). All measurements are taken using an LAI-2000 instrument held above the user's head (~2m above the ground). Raw data and a methods description are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data. -US-Ha1,18210,GRP_LAI,LAI_APPROACH,Deciduous LAI is computed by taking the diffrence between the PAI at each plot/sample date and the minimum plot PAI for an individual year (which is assumed to be the total branch and conifer area). All measurements are taken using an LAI-2000 instrument held above the user's head (~2m above the ground). Raw data and a methods description are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data. -US-Ha1,18214,GRP_LAI,LAI_APPROACH,Deciduous LAI is computed by taking the diffrence between the PAI at each plot/sample date and the minimum plot PAI for an individual year (which is assumed to be the total branch and conifer area). All measurements are taken using an LAI-2000 instrument held above the user's head (~2m above the ground). Raw data and a methods description are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data. -US-Ha1,18218,GRP_LAI,LAI_APPROACH,Deciduous LAI is computed by taking the diffrence between the PAI at each plot/sample date and the minimum plot PAI for an individual year (which is assumed to be the total branch and conifer area). All measurements are taken using an LAI-2000 instrument held above the user's head (~2m above the ground). Raw data and a methods description are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data. -US-Ha1,18222,GRP_LAI,LAI_APPROACH,Deciduous LAI is computed by taking the diffrence between the PAI at each plot/sample date and the minimum plot PAI for an individual year (which is assumed to be the total branch and conifer area). All measurements are taken using an LAI-2000 instrument held above the user's head (~2m above the ground). Raw data and a methods description are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data. -US-Ha1,18226,GRP_LAI,LAI_APPROACH,Deciduous LAI is computed by taking the diffrence between the PAI at each plot/sample date and the minimum plot PAI for an individual year (which is assumed to be the total branch and conifer area). All measurements are taken using an LAI-2000 instrument held above the user's head (~2m above the ground). Raw data and a methods description are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data. -US-Ha1,18230,GRP_LAI,LAI_APPROACH,Deciduous LAI is computed by taking the diffrence between the PAI at each plot/sample date and the minimum plot PAI for an individual year (which is assumed to be the total branch and conifer area). All measurements are taken using an LAI-2000 instrument held above the user's head (~2m above the ground). Raw data and a methods description are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data. -US-Ha1,18234,GRP_LAI,LAI_APPROACH,Deciduous LAI is computed by taking the diffrence between the PAI at each plot/sample date and the minimum plot PAI for an individual year (which is assumed to be the total branch and conifer area). All measurements are taken using an LAI-2000 instrument held above the user's head (~2m above the ground). Raw data and a methods description are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data. -US-Ha1,18238,GRP_LAI,LAI_APPROACH,Deciduous LAI is computed by taking the diffrence between the PAI at each plot/sample date and the minimum plot PAI for an individual year (which is assumed to be the total branch and conifer area). All measurements are taken using an LAI-2000 instrument held above the user's head (~2m above the ground). Raw data and a methods description are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data. -US-Ha1,18242,GRP_LAI,LAI_APPROACH,Deciduous LAI is computed by taking the diffrence between the PAI at each plot/sample date and the minimum plot PAI for an individual year (which is assumed to be the total branch and conifer area). All measurements are taken using an LAI-2000 instrument held above the user's head (~2m above the ground). Raw data and a methods description are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data. -US-Ha1,18246,GRP_LAI,LAI_APPROACH,Deciduous LAI is computed by taking the diffrence between the PAI at each plot/sample date and the minimum plot PAI for an individual year (which is assumed to be the total branch and conifer area). All measurements are taken using an LAI-2000 instrument held above the user's head (~2m above the ground). Raw data and a methods description are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data. -US-Ha1,18250,GRP_LAI,LAI_APPROACH,Deciduous LAI is computed by taking the diffrence between the PAI at each plot/sample date and the minimum plot PAI for an individual year (which is assumed to be the total branch and conifer area). All measurements are taken using an LAI-2000 instrument held above the user's head (~2m above the ground). Raw data and a methods description are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data. -US-Ha1,17365,GRP_LAI,LAI_DATE,19980415 -US-Ha1,17372,GRP_LAI,LAI_DATE,19980424 -US-Ha1,17378,GRP_LAI,LAI_DATE,19980504 -US-Ha1,17384,GRP_LAI,LAI_DATE,19980508 -US-Ha1,17390,GRP_LAI,LAI_DATE,19980513 -US-Ha1,17396,GRP_LAI,LAI_DATE,19980518 -US-Ha1,17402,GRP_LAI,LAI_DATE,19980528 -US-Ha1,17408,GRP_LAI,LAI_DATE,19980609 -US-Ha1,17414,GRP_LAI,LAI_DATE,19980708 -US-Ha1,17420,GRP_LAI,LAI_DATE,19980819 -US-Ha1,17426,GRP_LAI,LAI_DATE,19980916 -US-Ha1,17432,GRP_LAI,LAI_DATE,19981002 -US-Ha1,17438,GRP_LAI,LAI_DATE,19981009 -US-Ha1,17444,GRP_LAI,LAI_DATE,19981016 -US-Ha1,17450,GRP_LAI,LAI_DATE,19981028 -US-Ha1,17456,GRP_LAI,LAI_DATE,19981116 -US-Ha1,17461,GRP_LAI,LAI_DATE,19990413 -US-Ha1,17466,GRP_LAI,LAI_DATE,19990427 -US-Ha1,17471,GRP_LAI,LAI_DATE,19990505 -US-Ha1,17476,GRP_LAI,LAI_DATE,19990510 -US-Ha1,17480,GRP_LAI,LAI_DATE,19990513 -US-Ha1,17484,GRP_LAI,LAI_DATE,19990518 -US-Ha1,17488,GRP_LAI,LAI_DATE,19990525 -US-Ha1,17492,GRP_LAI,LAI_DATE,19990616 -US-Ha1,17496,GRP_LAI,LAI_DATE,19990810 -US-Ha1,17500,GRP_LAI,LAI_DATE,19991005 -US-Ha1,17504,GRP_LAI,LAI_DATE,19991021 -US-Ha1,17508,GRP_LAI,LAI_DATE,20050728 -US-Ha1,17512,GRP_LAI,LAI_DATE,20050822 -US-Ha1,17516,GRP_LAI,LAI_DATE,20050927 -US-Ha1,17847,GRP_LAI,LAI_DATE,20051220 -US-Ha1,17851,GRP_LAI,LAI_DATE,20060417 -US-Ha1,17855,GRP_LAI,LAI_DATE,20060504 -US-Ha1,17859,GRP_LAI,LAI_DATE,20060517 -US-Ha1,17863,GRP_LAI,LAI_DATE,20060525 -US-Ha1,17867,GRP_LAI,LAI_DATE,20060621 -US-Ha1,17871,GRP_LAI,LAI_DATE,20060705 -US-Ha1,17875,GRP_LAI,LAI_DATE,20060717 -US-Ha1,17879,GRP_LAI,LAI_DATE,20060822 -US-Ha1,17883,GRP_LAI,LAI_DATE,20061003 -US-Ha1,17887,GRP_LAI,LAI_DATE,20061016 -US-Ha1,17891,GRP_LAI,LAI_DATE,20061030 -US-Ha1,17895,GRP_LAI,LAI_DATE,20061203 -US-Ha1,17899,GRP_LAI,LAI_DATE,20070411 -US-Ha1,17903,GRP_LAI,LAI_DATE,20070507 -US-Ha1,17907,GRP_LAI,LAI_DATE,20070517 -US-Ha1,17911,GRP_LAI,LAI_DATE,20070528 -US-Ha1,17915,GRP_LAI,LAI_DATE,20070618 -US-Ha1,17919,GRP_LAI,LAI_DATE,20070710 -US-Ha1,17923,GRP_LAI,LAI_DATE,20070806 -US-Ha1,17927,GRP_LAI,LAI_DATE,20070906 -US-Ha1,17931,GRP_LAI,LAI_DATE,20071001 -US-Ha1,17935,GRP_LAI,LAI_DATE,20071016 -US-Ha1,17939,GRP_LAI,LAI_DATE,20071030 -US-Ha1,17943,GRP_LAI,LAI_DATE,20071119 -US-Ha1,17947,GRP_LAI,LAI_DATE,20071214 -US-Ha1,17951,GRP_LAI,LAI_DATE,20080423 -US-Ha1,17958,GRP_LAI,LAI_DATE,20080513 -US-Ha1,17962,GRP_LAI,LAI_DATE,20080529 -US-Ha1,17966,GRP_LAI,LAI_DATE,20080625 -US-Ha1,17970,GRP_LAI,LAI_DATE,20080714 -US-Ha1,17974,GRP_LAI,LAI_DATE,20080807 -US-Ha1,17978,GRP_LAI,LAI_DATE,20080908 -US-Ha1,17982,GRP_LAI,LAI_DATE,20081002 -US-Ha1,17986,GRP_LAI,LAI_DATE,20081015 -US-Ha1,17990,GRP_LAI,LAI_DATE,20081027 -US-Ha1,17994,GRP_LAI,LAI_DATE,20081103 -US-Ha1,17998,GRP_LAI,LAI_DATE,20081121 -US-Ha1,18002,GRP_LAI,LAI_DATE,20090409 -US-Ha1,18006,GRP_LAI,LAI_DATE,20090506 -US-Ha1,18010,GRP_LAI,LAI_DATE,20090514 -US-Ha1,18014,GRP_LAI,LAI_DATE,20090520 -US-Ha1,18018,GRP_LAI,LAI_DATE,20090601 -US-Ha1,18022,GRP_LAI,LAI_DATE,20090625 -US-Ha1,18026,GRP_LAI,LAI_DATE,20090709 -US-Ha1,18030,GRP_LAI,LAI_DATE,20090806 -US-Ha1,18034,GRP_LAI,LAI_DATE,20090909 -US-Ha1,18038,GRP_LAI,LAI_DATE,20091001 -US-Ha1,18042,GRP_LAI,LAI_DATE,20091015 -US-Ha1,18046,GRP_LAI,LAI_DATE,20091029 -US-Ha1,18050,GRP_LAI,LAI_DATE,20091118 -US-Ha1,18054,GRP_LAI,LAI_DATE,20100413 -US-Ha1,18058,GRP_LAI,LAI_DATE,20100429 -US-Ha1,18062,GRP_LAI,LAI_DATE,20100507 -US-Ha1,18066,GRP_LAI,LAI_DATE,20100516 -US-Ha1,18070,GRP_LAI,LAI_DATE,20100524 -US-Ha1,18074,GRP_LAI,LAI_DATE,20100602 -US-Ha1,18078,GRP_LAI,LAI_DATE,20100618 -US-Ha1,18082,GRP_LAI,LAI_DATE,20100630 -US-Ha1,18086,GRP_LAI,LAI_DATE,20100711 -US-Ha1,18090,GRP_LAI,LAI_DATE,20100726 -US-Ha1,18094,GRP_LAI,LAI_DATE,20100808 -US-Ha1,18098,GRP_LAI,LAI_DATE,20100909 -US-Ha1,18102,GRP_LAI,LAI_DATE,20100929 -US-Ha1,18106,GRP_LAI,LAI_DATE,20101013 -US-Ha1,18110,GRP_LAI,LAI_DATE,20101028 -US-Ha1,18114,GRP_LAI,LAI_DATE,20101120 -US-Ha1,18118,GRP_LAI,LAI_DATE,20110422 -US-Ha1,18122,GRP_LAI,LAI_DATE,20110506 -US-Ha1,18126,GRP_LAI,LAI_DATE,20110526 -US-Ha1,18130,GRP_LAI,LAI_DATE,20110608 -US-Ha1,18134,GRP_LAI,LAI_DATE,20110621 -US-Ha1,18138,GRP_LAI,LAI_DATE,20110705 -US-Ha1,18142,GRP_LAI,LAI_DATE,20110721 -US-Ha1,18146,GRP_LAI,LAI_DATE,20110823 -US-Ha1,18150,GRP_LAI,LAI_DATE,20110927 -US-Ha1,18154,GRP_LAI,LAI_DATE,20111021 -US-Ha1,18158,GRP_LAI,LAI_DATE,20111109 -US-Ha1,18162,GRP_LAI,LAI_DATE,20111122 -US-Ha1,18166,GRP_LAI,LAI_DATE,20120328 -US-Ha1,18170,GRP_LAI,LAI_DATE,20120418 -US-Ha1,18174,GRP_LAI,LAI_DATE,20120502 -US-Ha1,18178,GRP_LAI,LAI_DATE,20120516 -US-Ha1,18182,GRP_LAI,LAI_DATE,20120531 -US-Ha1,18186,GRP_LAI,LAI_DATE,20120619 -US-Ha1,18190,GRP_LAI,LAI_DATE,20120718 -US-Ha1,18194,GRP_LAI,LAI_DATE,20120808 -US-Ha1,18198,GRP_LAI,LAI_DATE,20120917 -US-Ha1,18202,GRP_LAI,LAI_DATE,20121003 -US-Ha1,18206,GRP_LAI,LAI_DATE,20121016 -US-Ha1,18210,GRP_LAI,LAI_DATE,20121102 -US-Ha1,18214,GRP_LAI,LAI_DATE,20130417 -US-Ha1,18218,GRP_LAI,LAI_DATE,20130506 -US-Ha1,18222,GRP_LAI,LAI_DATE,20130530 -US-Ha1,18226,GRP_LAI,LAI_DATE,20130612 -US-Ha1,18230,GRP_LAI,LAI_DATE,20130716 -US-Ha1,18234,GRP_LAI,LAI_DATE,20130821 -US-Ha1,18238,GRP_LAI,LAI_DATE,20130924 -US-Ha1,18242,GRP_LAI,LAI_DATE,20131009 -US-Ha1,18246,GRP_LAI,LAI_DATE,20131029 -US-Ha1,18250,GRP_LAI,LAI_DATE,20131115 -US-Ha1,17847,GRP_LAI,LAI_O_DEC,0 -US-Ha1,17951,GRP_LAI,LAI_O_DEC,0 -US-Ha1,17851,GRP_LAI,LAI_O_DEC,0.01 -US-Ha1,18002,GRP_LAI,LAI_O_DEC,0.01 -US-Ha1,17899,GRP_LAI,LAI_O_DEC,0.02 -US-Ha1,18250,GRP_LAI,LAI_O_DEC,0.02 -US-Ha1,17365,GRP_LAI,LAI_O_DEC,0.03 -US-Ha1,17461,GRP_LAI,LAI_O_DEC,0.03 -US-Ha1,18162,GRP_LAI,LAI_O_DEC,0.03 -US-Ha1,18118,GRP_LAI,LAI_O_DEC,0.04 -US-Ha1,18214,GRP_LAI,LAI_O_DEC,0.04 -US-Ha1,18054,GRP_LAI,LAI_O_DEC,0.05 -US-Ha1,18114,GRP_LAI,LAI_O_DEC,0.05 -US-Ha1,18166,GRP_LAI,LAI_O_DEC,0.05 -US-Ha1,17903,GRP_LAI,LAI_O_DEC,0.06 -US-Ha1,17372,GRP_LAI,LAI_O_DEC,0.07 -US-Ha1,17895,GRP_LAI,LAI_O_DEC,0.07 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-US-Ha1,18210,GRP_LAI,LAI_O_DEC_SPATIAL_VARIABILITY,0.12 -US-Ha1,18170,GRP_LAI,LAI_O_DEC_SPATIAL_VARIABILITY,0.13 -US-Ha1,18174,GRP_LAI,LAI_O_DEC_SPATIAL_VARIABILITY,0.13 -US-Ha1,17998,GRP_LAI,LAI_O_DEC_SPATIAL_VARIABILITY,0.14 -US-Ha1,17476,GRP_LAI,LAI_O_DEC_SPATIAL_VARIABILITY,0.15 -US-Ha1,17891,GRP_LAI,LAI_O_DEC_SPATIAL_VARIABILITY,0.15 -US-Ha1,17943,GRP_LAI,LAI_O_DEC_SPATIAL_VARIABILITY,0.16 -US-Ha1,18006,GRP_LAI,LAI_O_DEC_SPATIAL_VARIABILITY,0.16 -US-Ha1,17378,GRP_LAI,LAI_O_DEC_SPATIAL_VARIABILITY,0.17 -US-Ha1,17859,GRP_LAI,LAI_O_DEC_SPATIAL_VARIABILITY,0.18 -US-Ha1,18246,GRP_LAI,LAI_O_DEC_SPATIAL_VARIABILITY,0.18 -US-Ha1,18158,GRP_LAI,LAI_O_DEC_SPATIAL_VARIABILITY,0.2 -US-Ha1,17384,GRP_LAI,LAI_O_DEC_SPATIAL_VARIABILITY,0.21 -US-Ha1,17480,GRP_LAI,LAI_O_DEC_SPATIAL_VARIABILITY,0.22 -US-Ha1,17390,GRP_LAI,LAI_O_DEC_SPATIAL_VARIABILITY,0.23 -US-Ha1,18110,GRP_LAI,LAI_O_DEC_SPATIAL_VARIABILITY,0.23 -US-Ha1,17958,GRP_LAI,LAI_O_DEC_SPATIAL_VARIABILITY,0.24 -US-Ha1,18046,GRP_LAI,LAI_O_DEC_SPATIAL_VARIABILITY,0.24 -US-Ha1,17444,GRP_LAI,LAI_O_DEC_SPATIAL_VARIABILITY,0.27 -US-Ha1,17939,GRP_LAI,LAI_O_DEC_SPATIAL_VARIABILITY,0.28 -US-Ha1,17994,GRP_LAI,LAI_O_DEC_SPATIAL_VARIABILITY,0.3 -US-Ha1,18010,GRP_LAI,LAI_O_DEC_SPATIAL_VARIABILITY,0.32 -US-Ha1,17438,GRP_LAI,LAI_O_DEC_SPATIAL_VARIABILITY,0.33 -US-Ha1,17887,GRP_LAI,LAI_O_DEC_SPATIAL_VARIABILITY,0.33 -US-Ha1,17907,GRP_LAI,LAI_O_DEC_SPATIAL_VARIABILITY,0.33 -US-Ha1,17990,GRP_LAI,LAI_O_DEC_SPATIAL_VARIABILITY,0.35 -US-Ha1,18206,GRP_LAI,LAI_O_DEC_SPATIAL_VARIABILITY,0.35 -US-Ha1,17504,GRP_LAI,LAI_O_DEC_SPATIAL_VARIABILITY,0.36 -US-Ha1,18154,GRP_LAI,LAI_O_DEC_SPATIAL_VARIABILITY,0.36 -US-Ha1,18062,GRP_LAI,LAI_O_DEC_SPATIAL_VARIABILITY,0.38 -US-Ha1,17396,GRP_LAI,LAI_O_DEC_SPATIAL_VARIABILITY,0.39 -US-Ha1,17863,GRP_LAI,LAI_O_DEC_SPATIAL_VARIABILITY,0.39 -US-Ha1,17432,GRP_LAI,LAI_O_DEC_SPATIAL_VARIABILITY,0.4 -US-Ha1,17484,GRP_LAI,LAI_O_DEC_SPATIAL_VARIABILITY,0.41 -US-Ha1,18106,GRP_LAI,LAI_O_DEC_SPATIAL_VARIABILITY,0.41 -US-Ha1,18242,GRP_LAI,LAI_O_DEC_SPATIAL_VARIABILITY,0.42 -US-Ha1,17883,GRP_LAI,LAI_O_DEC_SPATIAL_VARIABILITY,0.43 -US-Ha1,18042,GRP_LAI,LAI_O_DEC_SPATIAL_VARIABILITY,0.43 -US-Ha1,18014,GRP_LAI,LAI_O_DEC_SPATIAL_VARIABILITY,0.44 -US-Ha1,17426,GRP_LAI,LAI_O_DEC_SPATIAL_VARIABILITY,0.46 -US-Ha1,17986,GRP_LAI,LAI_O_DEC_SPATIAL_VARIABILITY,0.48 -US-Ha1,18030,GRP_LAI,LAI_O_DEC_SPATIAL_VARIABILITY,0.48 -US-Ha1,18034,GRP_LAI,LAI_O_DEC_SPATIAL_VARIABILITY,0.48 -US-Ha1,18038,GRP_LAI,LAI_O_DEC_SPATIAL_VARIABILITY,0.48 -US-Ha1,17500,GRP_LAI,LAI_O_DEC_SPATIAL_VARIABILITY,0.49 -US-Ha1,17935,GRP_LAI,LAI_O_DEC_SPATIAL_VARIABILITY,0.51 -US-Ha1,18066,GRP_LAI,LAI_O_DEC_SPATIAL_VARIABILITY,0.51 -US-Ha1,17402,GRP_LAI,LAI_O_DEC_SPATIAL_VARIABILITY,0.53 -US-Ha1,17420,GRP_LAI,LAI_O_DEC_SPATIAL_VARIABILITY,0.53 -US-Ha1,17488,GRP_LAI,LAI_O_DEC_SPATIAL_VARIABILITY,0.53 -US-Ha1,18102,GRP_LAI,LAI_O_DEC_SPATIAL_VARIABILITY,0.53 -US-Ha1,18126,GRP_LAI,LAI_O_DEC_SPATIAL_VARIABILITY,0.53 -US-Ha1,18150,GRP_LAI,LAI_O_DEC_SPATIAL_VARIABILITY,0.54 -US-Ha1,17414,GRP_LAI,LAI_O_DEC_SPATIAL_VARIABILITY,0.55 -US-Ha1,18026,GRP_LAI,LAI_O_DEC_SPATIAL_VARIABILITY,0.55 -US-Ha1,18018,GRP_LAI,LAI_O_DEC_SPATIAL_VARIABILITY,0.56 -US-Ha1,18178,GRP_LAI,LAI_O_DEC_SPATIAL_VARIABILITY,0.56 -US-Ha1,18022,GRP_LAI,LAI_O_DEC_SPATIAL_VARIABILITY,0.57 -US-Ha1,18098,GRP_LAI,LAI_O_DEC_SPATIAL_VARIABILITY,0.57 -US-Ha1,17496,GRP_LAI,LAI_O_DEC_SPATIAL_VARIABILITY,0.58 -US-Ha1,17982,GRP_LAI,LAI_O_DEC_SPATIAL_VARIABILITY,0.58 -US-Ha1,18090,GRP_LAI,LAI_O_DEC_SPATIAL_VARIABILITY,0.58 -US-Ha1,17879,GRP_LAI,LAI_O_DEC_SPATIAL_VARIABILITY,0.59 -US-Ha1,17408,GRP_LAI,LAI_O_DEC_SPATIAL_VARIABILITY,0.6 -US-Ha1,17931,GRP_LAI,LAI_O_DEC_SPATIAL_VARIABILITY,0.6 -US-Ha1,17871,GRP_LAI,LAI_O_DEC_SPATIAL_VARIABILITY,0.61 -US-Ha1,17875,GRP_LAI,LAI_O_DEC_SPATIAL_VARIABILITY,0.61 -US-Ha1,18078,GRP_LAI,LAI_O_DEC_SPATIAL_VARIABILITY,0.61 -US-Ha1,18082,GRP_LAI,LAI_O_DEC_SPATIAL_VARIABILITY,0.61 -US-Ha1,18086,GRP_LAI,LAI_O_DEC_SPATIAL_VARIABILITY,0.61 -US-Ha1,18094,GRP_LAI,LAI_O_DEC_SPATIAL_VARIABILITY,0.61 -US-Ha1,18234,GRP_LAI,LAI_O_DEC_SPATIAL_VARIABILITY,0.61 -US-Ha1,18238,GRP_LAI,LAI_O_DEC_SPATIAL_VARIABILITY,0.61 -US-Ha1,18142,GRP_LAI,LAI_O_DEC_SPATIAL_VARIABILITY,0.62 -US-Ha1,18202,GRP_LAI,LAI_O_DEC_SPATIAL_VARIABILITY,0.62 -US-Ha1,18226,GRP_LAI,LAI_O_DEC_SPATIAL_VARIABILITY,0.62 -US-Ha1,18230,GRP_LAI,LAI_O_DEC_SPATIAL_VARIABILITY,0.62 -US-Ha1,17867,GRP_LAI,LAI_O_DEC_SPATIAL_VARIABILITY,0.63 -US-Ha1,18070,GRP_LAI,LAI_O_DEC_SPATIAL_VARIABILITY,0.63 -US-Ha1,18074,GRP_LAI,LAI_O_DEC_SPATIAL_VARIABILITY,0.63 -US-Ha1,18130,GRP_LAI,LAI_O_DEC_SPATIAL_VARIABILITY,0.63 -US-Ha1,18134,GRP_LAI,LAI_O_DEC_SPATIAL_VARIABILITY,0.63 -US-Ha1,18146,GRP_LAI,LAI_O_DEC_SPATIAL_VARIABILITY,0.63 -US-Ha1,18194,GRP_LAI,LAI_O_DEC_SPATIAL_VARIABILITY,0.64 -US-Ha1,18198,GRP_LAI,LAI_O_DEC_SPATIAL_VARIABILITY,0.64 -US-Ha1,17516,GRP_LAI,LAI_O_DEC_SPATIAL_VARIABILITY,0.65 -US-Ha1,17978,GRP_LAI,LAI_O_DEC_SPATIAL_VARIABILITY,0.65 -US-Ha1,18138,GRP_LAI,LAI_O_DEC_SPATIAL_VARIABILITY,0.65 -US-Ha1,17927,GRP_LAI,LAI_O_DEC_SPATIAL_VARIABILITY,0.66 -US-Ha1,18222,GRP_LAI,LAI_O_DEC_SPATIAL_VARIABILITY,0.66 -US-Ha1,17492,GRP_LAI,LAI_O_DEC_SPATIAL_VARIABILITY,0.67 -US-Ha1,18182,GRP_LAI,LAI_O_DEC_SPATIAL_VARIABILITY,0.68 -US-Ha1,18186,GRP_LAI,LAI_O_DEC_SPATIAL_VARIABILITY,0.68 -US-Ha1,17923,GRP_LAI,LAI_O_DEC_SPATIAL_VARIABILITY,0.7 -US-Ha1,17962,GRP_LAI,LAI_O_DEC_SPATIAL_VARIABILITY,0.71 -US-Ha1,17970,GRP_LAI,LAI_O_DEC_SPATIAL_VARIABILITY,0.71 -US-Ha1,17966,GRP_LAI,LAI_O_DEC_SPATIAL_VARIABILITY,0.73 -US-Ha1,17974,GRP_LAI,LAI_O_DEC_SPATIAL_VARIABILITY,0.73 -US-Ha1,17512,GRP_LAI,LAI_O_DEC_SPATIAL_VARIABILITY,0.74 -US-Ha1,17919,GRP_LAI,LAI_O_DEC_SPATIAL_VARIABILITY,0.77 -US-Ha1,17911,GRP_LAI,LAI_O_DEC_SPATIAL_VARIABILITY,0.81 -US-Ha1,17915,GRP_LAI,LAI_O_DEC_SPATIAL_VARIABILITY,0.81 -US-Ha1,18190,GRP_LAI,LAI_O_DEC_SPATIAL_VARIABILITY,0.81 -US-Ha1,17508,GRP_LAI,LAI_O_DEC_SPATIAL_VARIABILITY,0.82 -US-Ha1,11961,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -US-Ha1,11961,GRP_LAND_OWNERSHIP,LAND_OWNER,Harvard University -US-Ha1,24198,GRP_LMA,LMA,10.4 -US-Ha1,24198,GRP_LMA,LMA_SPP,ACRU (NRCS plant code) -US-Ha1,24198,GRP_LMA,LMA_DATE,19940722 -US-Ha1,24198,GRP_LMA,LMA_COMMENT,"Source: Bassow and Bazzaz, 1997, Intra- and inter-specific variation in canopy photosynthesis in a mixed deciduous forest, Oecologia 109: 507." -US-Ha1,24199,GRP_LMA,LMA,11 -US-Ha1,24199,GRP_LMA,LMA_SPP,QURU (NRCS plant code) -US-Ha1,24199,GRP_LMA,LMA_DATE,19940722 -US-Ha1,24199,GRP_LMA,LMA_COMMENT,"Source: Bassow and Bazzaz, 1997, Intra- and inter-specific variation in canopy photosynthesis in a mixed deciduous forest, Oecologia 109: 507." -US-Ha1,24967,GRP_LMA,LMA,5.9 -US-Ha1,24967,GRP_LMA,LMA_SPP,ACPE (NRCS plant code) -US-Ha1,24967,GRP_LMA,LMA_DATE,19940722 -US-Ha1,24967,GRP_LMA,LMA_COMMENT,"Source: Bassow and Bazzaz, 1997, Intra- and inter-specific variation in canopy photosynthesis in a mixed deciduous forest, Oecologia 109: 507." -US-Ha1,11962,GRP_LOCATION,LOCATION_LAT,42.5378 -US-Ha1,11962,GRP_LOCATION,LOCATION_LONG,-72.1715 -US-Ha1,11962,GRP_LOCATION,LOCATION_ELEV,340 -US-Ha1,23776,GRP_N_DEP,N_DEP_WET,0.84 -US-Ha1,24200,GRP_NEP,NEP,231000 -US-Ha1,24200,GRP_NEP,NEP_APPROACH,"See Barford et al. 2001 for components of budget which yields NEP estimate. Annual CWD respiration estimates derived from a site-specific linear regression model which uses air temperature and decay class; see O'Donnell, 2007, senior thesis, Harvard University for specific details." -US-Ha1,24200,GRP_NEP,NEP_DATE_START,2001 -US-Ha1,24200,GRP_NEP,NEP_DATE_END,2002 -US-Ha1,24200,GRP_NEP,NEP_COMMENT,"See Barford et al. 2001 for components of budget which yields NEP estimate. Annual CWD respiration estimates derived from a site-specific linear regression model which uses air temperature and decay class; see O'Donnell, 2007, senior thesis, Harvard University for specific details." -US-Ha1,24584,GRP_NEP,NEP,291000 -US-Ha1,24584,GRP_NEP,NEP_APPROACH,"See Barford et al. 2001 for components of budget which yields NEP estimate. Annual CWD respiration estimates derived from a site-specific linear regression model which uses air temperature and decay class; see O'Donnell, 2007, senior thesis, Harvard University for specific details." -US-Ha1,24584,GRP_NEP,NEP_DATE_START,2002 -US-Ha1,24584,GRP_NEP,NEP_DATE_END,2003 -US-Ha1,24584,GRP_NEP,NEP_COMMENT,"See Barford et al. 2001 for components of budget which yields NEP estimate. Annual CWD respiration estimates derived from a site-specific linear regression model which uses air temperature and decay class; see O'Donnell, 2007, senior thesis, Harvard University for specific details." -US-Ha1,24201,GRP_NEP,NEP,238000 -US-Ha1,24201,GRP_NEP,NEP_APPROACH,"See Barford et al. 2001 for components of budget which yields NEP estimate. Annual CWD respiration estimates derived from a site-specific linear regression model which uses air temperature and decay class; see O'Donnell, 2007, senior thesis, Harvard University for specific details." -US-Ha1,24201,GRP_NEP,NEP_DATE_START,2003 -US-Ha1,24201,GRP_NEP,NEP_DATE_END,2004 -US-Ha1,24201,GRP_NEP,NEP_COMMENT,"See Barford et al. 2001 for components of budget which yields NEP estimate. Annual CWD respiration estimates derived from a site-specific linear regression model which uses air temperature and decay class; see O'Donnell, 2007, senior thesis, Harvard University for specific details." -US-Ha1,24323,GRP_NEP,NEP,222000 -US-Ha1,24323,GRP_NEP,NEP_APPROACH,"See Barford et al. 2001 for components of budget which yields NEP estimate. Annual CWD respiration estimates derived from a site-specific linear regression model which uses air temperature and decay class; see O'Donnell, 2007, senior thesis, Harvard University for specific details." -US-Ha1,24323,GRP_NEP,NEP_DATE_START,2004 -US-Ha1,24323,GRP_NEP,NEP_DATE_END,2005 -US-Ha1,24323,GRP_NEP,NEP_COMMENT,"See Barford et al. 2001 for components of budget which yields NEP estimate. Annual CWD respiration estimates derived from a site-specific linear regression model which uses air temperature and decay class; see O'Donnell, 2007, senior thesis, Harvard University for specific details." -US-Ha1,24846,GRP_NEP,NEP,257000 -US-Ha1,24846,GRP_NEP,NEP_APPROACH,"See Barford et al. 2001 for components of budget which yields NEP estimate. Annual CWD respiration estimates derived from a site-specific linear regression model which uses air temperature and decay class; see O'Donnell, 2007, senior thesis, Harvard University for specific details." -US-Ha1,24846,GRP_NEP,NEP_DATE_START,2005 -US-Ha1,24846,GRP_NEP,NEP_DATE_END,2006 -US-Ha1,24846,GRP_NEP,NEP_COMMENT,"See Barford et al. 2001 for components of budget which yields NEP estimate. Annual CWD respiration estimates derived from a site-specific linear regression model which uses air temperature and decay class; see O'Donnell, 2007, senior thesis, Harvard University for specific details." -US-Ha1,24324,GRP_NEP,NEP,272000 -US-Ha1,24324,GRP_NEP,NEP_APPROACH,"See Barford et al. 2001 for components of budget which yields NEP estimate. Annual CWD respiration estimates derived from a site-specific linear regression model which uses air temperature and decay class; see O'Donnell, 2007, senior thesis, Harvard University for specific details." -US-Ha1,24324,GRP_NEP,NEP_DATE_START,2006 -US-Ha1,24324,GRP_NEP,NEP_DATE_END,2007 -US-Ha1,24324,GRP_NEP,NEP_COMMENT,"See Barford et al. 2001 for components of budget which yields NEP estimate. Annual CWD respiration estimates derived from a site-specific linear regression model which uses air temperature and decay class; see O'Donnell, 2007, senior thesis, Harvard University for specific details." -US-Ha1,11963,GRP_NETWORK,NETWORK,AmeriFlux -US-Ha1,91447,GRP_NETWORK,NETWORK,LTER -US-Ha1,86965,GRP_NETWORK,NETWORK,Phenocam -US-Ha1,1700000045,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Antonarakis, A. S., Siqueira, P., Munger, J. W. (2017) Using Multi-Source Data From Lidar, Radar, Imaging Spectroscopy, And National Forest Inventories To Simulate Forest Carbon Fluxes, International Journal Of Remote Sensing, 38(19), 5464-5486" -US-Ha1,1700000045,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1080/01431161.2017.1341666 -US-Ha1,1700000045,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ha1,1700006480,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Ashworth, K., Chung, S. H., McKinney, K. A., Liu, Y., Munger, J. W., Martin, S. T., Steiner, A. L. (2016) Modelling Bidirectional Fluxes Of Methanol And Acetaldehyde With The Forcast Canopy Exchange Model, Atmospheric Chemistry And Physics, 16(24), 15461-15484" -US-Ha1,1700006480,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.5194/ACP-16-15461-2016 -US-Ha1,1700006480,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ha1,1700008793,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Barford, C. C., Wofsy, S. C., Goulden, M. L., Munger, J. W., Pyle, E. H., Urbanski, S. P., Hutyra, L., Saleska, S. R., Fitzjarrald, D., Moore, K. (2001) Factors Controlling Long- And Short-Term Sequestration Of Atmospheric CO2 In A Mid-Latitude Forest, Science, 294(5547), 1688-1691" -US-Ha1,1700008793,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1126/SCIENCE.1062962 -US-Ha1,1700008793,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ha1,1700007641,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Barr, A., Richardson, A., Hollinger, D., Papale, D., Arain, M., Black, T., Bohrer, G., Dragoni, D., Fischer, M., Gu, L., Law, B., Margolis, H., McCaughey, J., Munger, J., Oechel, W., Schaeffer, K. (2013) Use Of Change-Point Detection For Friction–Velocity Threshold Evaluation In Eddy-Covariance Studies, Agricultural And Forest Meteorology, 171-172(7458), 31-45" -US-Ha1,1700007641,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2012.11.023 -US-Ha1,1700007641,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ha1,1700003519,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Bassow, S. L., Bazzaz, F. A. (1997) Intra- And Inter-Specific Variation In Canopy Photosynthesis In A Mixed Deciduous Forest, Oecologia, 109(4), 507-515" -US-Ha1,1700003519,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1007/S004420050111 -US-Ha1,1700003519,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ha1,1700008694,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Bassow, S. L., Bazzaz, F. A. (1998) How Environmental Conditions Affect Canopy Leaf-Level Photosynthesis In Four Deciduous Tree Species, Ecology, 79(8), 2660-2675" -US-Ha1,1700008694,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.2307/176508 -US-Ha1,1700008694,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ha1,1700000906,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Battle, M. O., Munger, J. W., Conley, M., Sofen, E., Perry, R., Hart, R., Davis, Z., Scheckman, J., Woogerd, J., Graeter, K., Seekins, S., David, S., Carpenter, J. (2019) Atmospheric Measurements Of The Terrestrial O2 : Co2 Exchange Ratio Of A Midlatitude Forest, Atmospheric Chemistry And Physics, 19(13), 8687-8701" -US-Ha1,1700000906,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.5194/ACP-19-8687-2019 -US-Ha1,1700000906,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ha1,1700000204,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Belmecheri, S., Maxwell, R. S., Taylor, A. H., Davis, K. J., Freeman, K. H., Munger, W. J. (2014) Tree-Ring δ 13c Tracks Flux Tower Ecosystem Productivity Estimates In A Ne Temperate Forest, Environmental Research Letters, 9(7), 074011" -US-Ha1,1700000204,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1088/1748-9326/9/7/074011 -US-Ha1,1700000204,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ha1,1700001122,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Baldocchi, D. D., Poindexter, C., Abraha, M., Desai, A. R., Bohrer, G., Arain, M. A., Griffis, T., Blanken, P. D., O'Halloran, T. L., Thomas, R. Q., Zhang, Q., Burns, S. P., Frank, J. 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S., Arain, M. A., Barr, A. G., Bohrer, G., Chen, G., Chen, J. M., Ciais, P., Davis, K. J., Desai, A. R., Dietze, M. C., Dragoni, D., Garrity, S. R., Gough, C. M., Grant, R., Hollinger, D. Y., Margolis, H. A., McCaughey, H., Migliavacca, M., Monson, R. K., Munger, J. W., Poulter, B., Raczka, B. M., Ricciuto, D. M., Sahoo, A. K., Schaefer, K., Tian, H., Vargas, R., Verbeeck, H., Xiao, J., Xue, Y. (2012) Terrestrial Biosphere Models Need Better Representation Of Vegetation Phenology: Results From The North American Carbon Program Site Synthesis, Global Change Biology, 18(2), 566-584" -US-Ha1,1700002967,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/J.1365-2486.2011.02562.X -US-Ha1,1700002967,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ha1,1700007611,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Savage, K. E., Davidson, E. A. (2001) Interannual Variation Of Soil Respiration In Two New England Forests, Global Biogeochemical Cycles, 15(2), 337-350" -US-Ha1,1700007611,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/1999GB001248 -US-Ha1,1700007611,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ha1,1700002748,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Sihi, D, Davidson, E.A., Chen, M, Savage, K.E., Richardson, A.D., Keenan, T.F., Hollinger, D. Y. (2018) Merging a mechanistic enzymatic model of soil heterotrophic respiration into an ecosystem model in two AmeriFlux sites of northeastern USA, Agricultural and Forest Meteorology, 252(2), 155-166" -US-Ha1,1700002748,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2018.01.026 -US-Ha1,1700002748,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ha1,1700005091,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Silva, S. J., Heald, C. L., Ravela, S., Mammarella, I., Munger, J. W. (2019) A Deep Learning Parameterization For Ozone Dry Deposition Velocities, Geophysical Research Letters, 46(2), 983-989" -US-Ha1,1700005091,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018GL081049 -US-Ha1,1700005091,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ha1,1700002361,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Staebler, R. M., Fitzjarrald, D. R. (2004) Observing Subcanopy CO2 Advection, Agricultural And Forest Meteorology, 122(3-4), 139-156" -US-Ha1,1700002361,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2003.09.011 -US-Ha1,1700002361,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ha1,1700008274,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Staebler, R. M., Fitzjarrald, D. R. (2005) Measuring Canopy Structure And The Kinematics Of Subcanopy Flows In Two Forests, Journal Of Applied Meteorology, 44(8), 1161-1179" -US-Ha1,1700008274,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1175/JAM2265.1 -US-Ha1,1700008274,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ha1,1700007434,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Sullivan, R. C., Cook, D. R., Ghate, V. P., Kotamarthi, V. R., Feng, Y. (2019) Improved Spatiotemporal Representativeness And Bias Reduction Of Satellite-Based Evapotranspiration Retrievals Via Use Of In Situ Meteorology And Constrained Canopy Surface Resistance, Journal Of Geophysical Research: Biogeosciences, 124(2), 342-352" -US-Ha1,1700007434,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018JG004744 -US-Ha1,1700007434,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ha1,1700005763,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Sullivan, R. C., Kotamarthi, V. R., Feng, Y. (2019) Recovering Evapotranspiration Trends From Biased CMIP5 Simulations And Sensitivity To Changing Climate Over North America, Journal Of Hydrometeorology, 20(8), 1619-1633" -US-Ha1,1700005763,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1175/JHM-D-18-0259.1 -US-Ha1,1700005763,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ha1,1700005817,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Toomey, M., Friedl, M. A., Frolking, S., Hufkens, K., Klosterman, S., Sonnentag, O., Baldocchi, D. D., Bernacchi, C. J., Biraud, S. C., Bohrer, G., Brzostek, E., Burns, S. P., Coursolle, C., Hollinger, D. Y., Margolis, H. A., McCaughey, H., Monson, R. K., Munger, J. W., Pallardy, S., Phillips, R. P., Torn, M. S., Wharton, S., Zeri, M., Richardson, A. D. (2015) Greenness Indices From Digital Cameras Predict The Timing And Seasonal Dynamics Of Canopy-Scale Photosynthesis, Ecological Applications, 25(1), 99-115" -US-Ha1,1700005817,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1890/14-0005.1 -US-Ha1,1700005817,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ha1,1700004731,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Urbanski, S., Barford, C., Wofsy, S., Kucharik, C., Pyle, E., Budney, J., McKain, K., Fitzjarrald, D., Czikowsky, M., Munger, J. W. (2007) Factors Controlling CO2 Exchange On Timescales From Hourly To Decadal At Harvard Forest, Journal Of Geophysical Research, 112(G2), 3-19" -US-Ha1,1700004731,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2006JG000293 -US-Ha1,1700004731,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Primary_Citation -US-Ha1,1700007017,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Wang, Y., Tang, X., Yu, L., Hou, X., Munger, J. W. (2016) Comparison Of Net Ecosystem Carbon Exchange Estimation In A Mixed Temperate Forest Using Field Eddy Covariance And Modis Data, Springerplus, 5(1), 15461-15484" -US-Ha1,1700007017,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1186/S40064-016-2134-4 -US-Ha1,1700007017,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ha1,1700004029,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Wehr, R., Commane, R., Munger, J. W., McManus, J. B., Nelson, D. D., Zahniser, M. S., Saleska, S. R., Wofsy, S. C. (2017) Dynamics Of Canopy Stomatal Conductance, Transpiration, And Evaporation In A Temperate Deciduous Forest, Validated By Carbonyl Sulfide Uptake, Biogeosciences, 14(2), 389-401" -US-Ha1,1700004029,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.5194/BG-14-389-2017 -US-Ha1,1700004029,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ha1,1700005664,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Wehr, R., Munger, J. W., McManus, J. B., Nelson, D. D., Zahniser, M. S., Davidson, E. A., Wofsy, S. C., Saleska, S. R. (2016) Seasonality of temperate forest photosynthesis and daytime respiration, Nature, 534(), 680-683" -US-Ha1,1700005664,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1038/NATURE17966 -US-Ha1,1700005664,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ha1,1700008319,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Wofsy, S. C., Goulden, M. L., Munger, J. W., Fan, S., Bakwin, P. S., Daube, B. C., Bassow, S. L., Bazzaz, F. A. (1993) Net Exchange Of CO2 In A Mid-Latitude Forest, Science, 260(5112), 1314-1317" -US-Ha1,1700008319,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1126/SCIENCE.260.5112.1314 -US-Ha1,1700008319,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ha1,1700005142,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Wu, Z. Y., Zhang, L., Wang, X. M., Munger, J. W. (2015) A Modified Micrometeorological Gradient Method For Estimating O3 Dry Depositions Over A Forest Canopy, Atmospheric Chemistry And Physics, 15(13), 7487-7496" -US-Ha1,1700005142,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.5194/ACP-15-7487-2015 -US-Ha1,1700005142,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ha1,1700003321,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Xu, B., Arain, M. A., Black, T. A., Law, B. E., Pastorello, G. Z., Chu, H. (2020) Seasonal Variability Of Forest Sensitivity To Heat And Drought Stresses: A Synthesis Based On Carbon Fluxes From North American Forest Ecosystems, Global Change Biology, 26(2), 901-918" -US-Ha1,1700003321,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/GCB.14843 -US-Ha1,1700003321,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ha1,1700001290,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Yang, H., Yang, X., Zhang, Y., Heskel, M. A., Lu, X., Munger, J. W., Sun, S., Tang, J. (2017) Chlorophyll Fluorescence Tracks Seasonal Variations Of Photosynthesis From Leaf To Canopy In A Temperate Forest, Global Change Biology, 23(7), 2874-2886" -US-Ha1,1700001290,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/GCB.13590 -US-Ha1,1700001290,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ha1,1700006840,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Yue, X., Unger, N., Keenan, T. F., Zhang, X., Vogel, C. S. (2015) Probing The Past 30-Year Phenology Trend Of Us Deciduous Forests, Biogeosciences, 12(15), 4693-4709" -US-Ha1,1700006840,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.5194/BG-12-4693-2015 -US-Ha1,1700006840,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ha1,1700000768,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Zhang, Q., Phillips, R. P., Manzoni, S., Scott, R. L., Oishi, A. C., Finzi, A., Daly, E., Vargas, R., Novick, K. A. (2018) Changes In Photosynthesis And Soil Moisture Drive The Seasonal Soil Respiration-Temperature Hysteresis Relationship, Agricultural And Forest Meteorology, 259(2), 184-195" -US-Ha1,1700000768,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2018.05.005 -US-Ha1,1700000768,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ha1,11965,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,Quantification of net carbon exchange in a temperate deciduous forest and elucidation of physical and biological controls on carbon exchange in the forest. -US-Ha1,17301,GRP_ROOT_BIOMASS,ROOT_BIOMASS_CRS,131 -US-Ha1,17301,GRP_ROOT_BIOMASS,ROOT_BIOMASS_FINE,49 -US-Ha1,17301,GRP_ROOT_BIOMASS,ROOT_BIOMASS_UNIT,gC m-2 -US-Ha1,17301,GRP_ROOT_BIOMASS,ROOT_BIOMASS_DATE,19600401 -US-Ha1,17301,GRP_ROOT_BIOMASS,ROOT_BIOMASS_COMMENT,Coarse and fine root data obtained from soil cores from control plots of DIRT Project; source: DIRT Project ; contact Knute Nadlehoffer (knute@umich.edu) -US-Ha1,17366,GRP_SA,SA,80.5 -US-Ha1,17366,GRP_SA,SA_DATE,2003 -US-Ha1,17366,GRP_SA,SA_COMMENT,"source: Neil Pederson, pHd thesis, Columbia University." -US-Ha1,17366,GRP_SA,SA_MAX,107 -US-Ha1,11966,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"324 N Main St, Petersham, MA 01366" -US-Ha1,11967,GRP_SITE_CHAR,ASPECT,E -US-Ha1,11967,GRP_SITE_CHAR,WIND_DIRECTION,NW -US-Ha1,11967,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,230 -US-Ha1,11967,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,92 -US-Ha1,11968,GRP_SITE_DESC,SITE_DESC,"The Harvard Forest tower is on land owned by Harvard University. The site is designated as an LTER site. Most of the surrounding area was cleared for agrigulture during European settlement in 1600-1700. The site has been regrowing since before 1900 (based on tree ring chronologies) and is now predominantly red oak and red maple, with patches of mature hemlock stand and individual white pine. Overstory trees were uprooted by hurricane in 1938. Climate measurements have been made at Harvard Forest since 1964." -US-Ha1,11969,GRP_SITE_FUNDING,SITE_FUNDING,"DOE/TES (AmeriFlux Core site), NSF/LTER" -US-Ha1,17302,GRP_SNAG_MASS,SNAG_MASS,153 -US-Ha1,17302,GRP_SNAG_MASS,SNAG_MASS_SPATIAL_VARIABILITY,213 -US-Ha1,17302,GRP_SNAG_MASS,SNAG_MASS_UNIT,gC m-2 -US-Ha1,17302,GRP_SNAG_MASS,SNAG_MASS_APPROACH,"CWD survey, biomass estimated from allomteric equations for live trees from DBH of snag (only includes recently dead standing trees)" -US-Ha1,17302,GRP_SNAG_MASS,SNAG_MASS_DATE,2000 -US-Ha1,17314,GRP_SNAG_MASS,SNAG_MASS,155 -US-Ha1,17314,GRP_SNAG_MASS,SNAG_MASS_SPATIAL_VARIABILITY,288 -US-Ha1,17314,GRP_SNAG_MASS,SNAG_MASS_UNIT,gC m-2 -US-Ha1,17314,GRP_SNAG_MASS,SNAG_MASS_APPROACH,"CWD survey, biomass estimated from allomteric equations for live trees from DBH of snag (only includes recently dead standing trees)" -US-Ha1,17314,GRP_SNAG_MASS,SNAG_MASS_DATE,2006 -US-Ha1,17320,GRP_SNAG_MASS,SNAG_MASS,284 -US-Ha1,17320,GRP_SNAG_MASS,SNAG_MASS_SPATIAL_VARIABILITY,401 -US-Ha1,17320,GRP_SNAG_MASS,SNAG_MASS_UNIT,gC m-2 -US-Ha1,17320,GRP_SNAG_MASS,SNAG_MASS_APPROACH,"CWD survey, biomass estimated from allomteric equations for live trees from DBH of snag (only includes recently dead standing trees)" -US-Ha1,17320,GRP_SNAG_MASS,SNAG_MASS_DATE,2009 -US-Ha1,17308,GRP_SNAG_MASS,SNAG_MASS,47 -US-Ha1,17308,GRP_SNAG_MASS,SNAG_MASS_SPATIAL_VARIABILITY,133 -US-Ha1,17308,GRP_SNAG_MASS,SNAG_MASS_UNIT,gC m-2 -US-Ha1,17308,GRP_SNAG_MASS,SNAG_MASS_APPROACH,"CWD survey, biomass estimated from allomteric equations for live trees from DBH of snag (only includes recently dead standing trees)" -US-Ha1,17308,GRP_SNAG_MASS,SNAG_MASS_DATE,2003 -US-Ha1,22048,GRP_SOIL_CHEM,SOIL_CHEM_PH_SALT,3.77 -US-Ha1,22052,GRP_SOIL_CHEM,SOIL_CHEM_PH_SALT,3.88 -US-Ha1,22055,GRP_SOIL_CHEM,SOIL_CHEM_BD,0.68 -US-Ha1,22058,GRP_SOIL_CHEM,SOIL_CHEM_BD,0.93 -US-Ha1,22061,GRP_SOIL_CHEM,SOIL_CHEM_BD,0.96 -US-Ha1,22064,GRP_SOIL_CHEM,SOIL_CHEM_BD,1.18 -US-Ha1,22067,GRP_SOIL_CHEM,SOIL_CHEM_BD,1.34 -US-Ha1,22070,GRP_SOIL_CHEM,SOIL_CHEM_BD,1.45 -US-Ha1,22076,GRP_SOIL_CHEM,SOIL_CHEM_BD,1.66 -US-Ha1,22073,GRP_SOIL_CHEM,SOIL_CHEM_BD,1.75 -US-Ha1,22079,GRP_SOIL_CHEM,SOIL_CHEM_BD,1.79 -US-Ha1,22048,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_ZERO_REF,Top of mineral soil -US-Ha1,22052,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_ZERO_REF,Top of mineral soil -US-Ha1,22055,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_ZERO_REF,Top of mineral soil -US-Ha1,22058,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_ZERO_REF,Top of mineral soil -US-Ha1,22061,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_ZERO_REF,Top of mineral soil -US-Ha1,22064,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_ZERO_REF,Top of mineral soil -US-Ha1,22067,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_ZERO_REF,Top of mineral soil -US-Ha1,22070,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_ZERO_REF,Top of mineral soil -US-Ha1,22073,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_ZERO_REF,Top of mineral soil -US-Ha1,22076,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_ZERO_REF,Top of mineral soil -US-Ha1,22079,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_ZERO_REF,Top of mineral soil -US-Ha1,22048,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,0 -US-Ha1,22055,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,0 -US-Ha1,22061,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,10 -US-Ha1,22064,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,15 -US-Ha1,22067,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,20 -US-Ha1,22070,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,25 -US-Ha1,22073,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,35 -US-Ha1,22076,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,40 -US-Ha1,22079,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,45 -US-Ha1,22058,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,5 -US-Ha1,22058,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,1 -US-Ha1,22048,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,10 -US-Ha1,22052,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,10 -US-Ha1,22061,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,15 -US-Ha1,22064,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,20 -US-Ha1,22067,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,25 -US-Ha1,22070,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,30 -US-Ha1,22073,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,40 -US-Ha1,22076,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,45 -US-Ha1,22055,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,5 -US-Ha1,22079,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,50 -US-Ha1,22048,GRP_SOIL_CHEM,SOIL_CHEM_DATE,19911202 -US-Ha1,22052,GRP_SOIL_CHEM,SOIL_CHEM_DATE,19951103 -US-Ha1,22055,GRP_SOIL_CHEM,SOIL_CHEM_DATE,20061101 -US-Ha1,22058,GRP_SOIL_CHEM,SOIL_CHEM_DATE,20061101 -US-Ha1,22061,GRP_SOIL_CHEM,SOIL_CHEM_DATE,20061101 -US-Ha1,22064,GRP_SOIL_CHEM,SOIL_CHEM_DATE,20061101 -US-Ha1,22067,GRP_SOIL_CHEM,SOIL_CHEM_DATE,20061101 -US-Ha1,22070,GRP_SOIL_CHEM,SOIL_CHEM_DATE,20061101 -US-Ha1,22073,GRP_SOIL_CHEM,SOIL_CHEM_DATE,20061101 -US-Ha1,22076,GRP_SOIL_CHEM,SOIL_CHEM_DATE,20061101 -US-Ha1,22079,GRP_SOIL_CHEM,SOIL_CHEM_DATE,20061101 -US-Ha1,22048,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,Data from control plots of DIRT Project; source: DIRT Project ; contact Knute Nadlehoffer (knute@umich.edu) -US-Ha1,22052,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,Data from control plots of DIRT Project; source: DIRT Project ; contact Knute Nadlehoffer (knute@umich.edu) -US-Ha1,22084,GRP_SOIL_STOCK,SOIL_STOCK_C_ORG,1245 -US-Ha1,22056,GRP_SOIL_STOCK,SOIL_STOCK_C_ORG,1383 -US-Ha1,22062,GRP_SOIL_STOCK,SOIL_STOCK_C_ORG,1632 -US-Ha1,22077,GRP_SOIL_STOCK,SOIL_STOCK_C_ORG,1640 -US-Ha1,22049,GRP_SOIL_STOCK,SOIL_STOCK_C_ORG,1682 -US-Ha1,22068,GRP_SOIL_STOCK,SOIL_STOCK_C_ORG,2121 -US-Ha1,22080,GRP_SOIL_STOCK,SOIL_STOCK_C_ORG,2400 -US-Ha1,22082,GRP_SOIL_STOCK,SOIL_STOCK_C_ORG,2620 -US-Ha1,22059,GRP_SOIL_STOCK,SOIL_STOCK_C_ORG,3277 -US-Ha1,22053,GRP_SOIL_STOCK,SOIL_STOCK_C_ORG,3621 -US-Ha1,22074,GRP_SOIL_STOCK,SOIL_STOCK_C_ORG,380 -US-Ha1,22065,GRP_SOIL_STOCK,SOIL_STOCK_C_ORG,3818 -US-Ha1,22071,GRP_SOIL_STOCK,SOIL_STOCK_C_ORG,3943 -US-Ha1,22086,GRP_SOIL_STOCK,SOIL_STOCK_C_ORG,510 -US-Ha1,22059,GRP_SOIL_STOCK,SOIL_STOCK_N_TOT,172 -US-Ha1,22053,GRP_SOIL_STOCK,SOIL_STOCK_N_TOT,185 -US-Ha1,22071,GRP_SOIL_STOCK,SOIL_STOCK_N_TOT,206 -US-Ha1,22065,GRP_SOIL_STOCK,SOIL_STOCK_N_TOT,291 -US-Ha1,22056,GRP_SOIL_STOCK,SOIL_STOCK_N_TOT,67 -US-Ha1,22049,GRP_SOIL_STOCK,SOIL_STOCK_N_TOT,70 -US-Ha1,22062,GRP_SOIL_STOCK,SOIL_STOCK_N_TOT,71 -US-Ha1,22068,GRP_SOIL_STOCK,SOIL_STOCK_N_TOT,95 -US-Ha1,22053,GRP_SOIL_STOCK,SOIL_STOCK_PROFILE_MIN,0 -US-Ha1,22059,GRP_SOIL_STOCK,SOIL_STOCK_PROFILE_MIN,0 -US-Ha1,22065,GRP_SOIL_STOCK,SOIL_STOCK_PROFILE_MIN,0 -US-Ha1,22071,GRP_SOIL_STOCK,SOIL_STOCK_PROFILE_MIN,0 -US-Ha1,22059,GRP_SOIL_STOCK,SOIL_STOCK_PROFILE_MAX,0.1 -US-Ha1,22065,GRP_SOIL_STOCK,SOIL_STOCK_PROFILE_MAX,0.1 -US-Ha1,22071,GRP_SOIL_STOCK,SOIL_STOCK_PROFILE_MAX,0.1 -US-Ha1,22053,GRP_SOIL_STOCK,SOIL_STOCK_PROFILE_MAX,0.15 -US-Ha1,22049,GRP_SOIL_STOCK,SOIL_STOCK_HORIZON,Oea -US-Ha1,22056,GRP_SOIL_STOCK,SOIL_STOCK_HORIZON,Oea -US-Ha1,22062,GRP_SOIL_STOCK,SOIL_STOCK_HORIZON,Oea -US-Ha1,22068,GRP_SOIL_STOCK,SOIL_STOCK_HORIZON,Oea -US-Ha1,22049,GRP_SOIL_STOCK,SOIL_STOCK_DATE,19901014 -US-Ha1,22053,GRP_SOIL_STOCK,SOIL_STOCK_DATE,19901014 -US-Ha1,22056,GRP_SOIL_STOCK,SOIL_STOCK_DATE,19911202 -US-Ha1,22059,GRP_SOIL_STOCK,SOIL_STOCK_DATE,19911202 -US-Ha1,22062,GRP_SOIL_STOCK,SOIL_STOCK_DATE,19951103 -US-Ha1,22065,GRP_SOIL_STOCK,SOIL_STOCK_DATE,19951103 -US-Ha1,22074,GRP_SOIL_STOCK,SOIL_STOCK_DATE,1996 -US-Ha1,22077,GRP_SOIL_STOCK,SOIL_STOCK_DATE,1996 -US-Ha1,22080,GRP_SOIL_STOCK,SOIL_STOCK_DATE,1996 -US-Ha1,22082,GRP_SOIL_STOCK,SOIL_STOCK_DATE,1996 -US-Ha1,22084,GRP_SOIL_STOCK,SOIL_STOCK_DATE,1996 -US-Ha1,22086,GRP_SOIL_STOCK,SOIL_STOCK_DATE,1996 -US-Ha1,22068,GRP_SOIL_STOCK,SOIL_STOCK_DATE,20000613 -US-Ha1,22071,GRP_SOIL_STOCK,SOIL_STOCK_DATE,20000613 -US-Ha1,22049,GRP_SOIL_STOCK,SOIL_STOCK_COMMENT,Data from control plots of DIRT Project; source: DIRT Project ; contact Knute Nadlehoffer (knute@umich.edu) -US-Ha1,22053,GRP_SOIL_STOCK,SOIL_STOCK_COMMENT,Data from control plots of DIRT Project; source: DIRT Project ; contact Knute Nadlehoffer (knute@umich.edu) -US-Ha1,22056,GRP_SOIL_STOCK,SOIL_STOCK_COMMENT,Data from control plots of DIRT Project; source: DIRT Project ; contact Knute Nadlehoffer (knute@umich.edu) -US-Ha1,22059,GRP_SOIL_STOCK,SOIL_STOCK_COMMENT,Data from control plots of DIRT Project; source: DIRT Project ; contact Knute Nadlehoffer (knute@umich.edu) -US-Ha1,22062,GRP_SOIL_STOCK,SOIL_STOCK_COMMENT,Data from control plots of DIRT Project; source: DIRT Project ; contact Knute Nadlehoffer (knute@umich.edu) -US-Ha1,22065,GRP_SOIL_STOCK,SOIL_STOCK_COMMENT,Data from control plots of DIRT Project; source: DIRT Project ; contact Knute Nadlehoffer (knute@umich.edu) -US-Ha1,22068,GRP_SOIL_STOCK,SOIL_STOCK_COMMENT,Data from control plots of DIRT Project; source: DIRT Project ; contact Knute Nadlehoffer (knute@umich.edu) -US-Ha1,22071,GRP_SOIL_STOCK,SOIL_STOCK_COMMENT,Data from control plots of DIRT Project; source: DIRT Project ; contact Knute Nadlehoffer (knute@umich.edu) -US-Ha1,22074,GRP_SOIL_STOCK,SOIL_STOCK_COMMENT,"Source: Gaudinski JB, Trumbore SE, Davidson EA, Zheng S. 2000. Soil carbon cycling in a temperate forest: radiocarbon-based estimates of residence times, sequestration rates and partitioning of fluxes. Biogeochemistry 51: 33-69." -US-Ha1,22077,GRP_SOIL_STOCK,SOIL_STOCK_COMMENT,"Source: Gaudinski JB, Trumbore SE, Davidson EA, Zheng S. 2000. Soil carbon cycling in a temperate forest: radiocarbon-based estimates of residence times, sequestration rates and partitioning of fluxes. Biogeochemistry 51: 33-69." -US-Ha1,22080,GRP_SOIL_STOCK,SOIL_STOCK_COMMENT,"Source: Gaudinski JB, Trumbore SE, Davidson EA, Zheng S. 2000. Soil carbon cycling in a temperate forest: radiocarbon-based estimates of residence times, sequestration rates and partitioning of fluxes. Biogeochemistry 51: 33-69." -US-Ha1,22082,GRP_SOIL_STOCK,SOIL_STOCK_COMMENT,"Source: Gaudinski JB, Trumbore SE, Davidson EA, Zheng S. 2000. Soil carbon cycling in a temperate forest: radiocarbon-based estimates of residence times, sequestration rates and partitioning of fluxes. Biogeochemistry 51: 33-69." -US-Ha1,22084,GRP_SOIL_STOCK,SOIL_STOCK_COMMENT,"Source: Gaudinski JB, Trumbore SE, Davidson EA, Zheng S. 2000. Soil carbon cycling in a temperate forest: radiocarbon-based estimates of residence times, sequestration rates and partitioning of fluxes. Biogeochemistry 51: 33-69." -US-Ha1,22086,GRP_SOIL_STOCK,SOIL_STOCK_COMMENT,"Source: Gaudinski JB, Trumbore SE, Davidson EA, Zheng S. 2000. Soil carbon cycling in a temperate forest: radiocarbon-based estimates of residence times, sequestration rates and partitioning of fluxes. Biogeochemistry 51: 33-69." -US-Ha1,22050,GRP_SOIL_TEX,SOIL_TEX_SAND,66 -US-Ha1,22050,GRP_SOIL_TEX,SOIL_TEX_SILT,29 -US-Ha1,22050,GRP_SOIL_TEX,SOIL_TEX_CLAY,6 -US-Ha1,22050,GRP_SOIL_TEX,SOIL_TEX_HORIZON,Total -US-Ha1,22050,GRP_SOIL_TEX,SOIL_TEX_DATE,2007 -US-Ha1,22050,GRP_SOIL_TEX,SOIL_TEX_COMMENT,"Source: Kathleen Savage (savage@whrc.org), personal communication" -US-Ha1,17439,GRP_SPP_O,SPP_O,Acer pennsylvanicum -US-Ha1,17373,GRP_SPP_O,SPP_O,Acer rubrum -US-Ha1,23689,GRP_SPP_O,SPP_O,ACRU (NRCS plant code) -US-Ha1,17367,GRP_SPP_O,SPP_O,Betula alleghaniensis -US-Ha1,17397,GRP_SPP_O,SPP_O,Betula lenta -US-Ha1,17445,GRP_SPP_O,SPP_O,Betula papyrifera -US-Ha1,17421,GRP_SPP_O,SPP_O,Betula populifolia -US-Ha1,17391,GRP_SPP_O,SPP_O,Fagus grandifolia -US-Ha1,17415,GRP_SPP_O,SPP_O,Fraxinus americana -US-Ha1,17433,GRP_SPP_O,SPP_O,Picea glauca -US-Ha1,17451,GRP_SPP_O,SPP_O,Pinus resinosa -US-Ha1,17403,GRP_SPP_O,SPP_O,Pinus strobus -US-Ha1,17409,GRP_SPP_O,SPP_O,Prunus serotina -US-Ha1,17379,GRP_SPP_O,SPP_O,Quercus rubra -US-Ha1,17385,GRP_SPP_O,SPP_O,Quercus velutina -US-Ha1,23820,GRP_SPP_O,SPP_O,QURU (NRCS plant code) -US-Ha1,23821,GRP_SPP_O,SPP_O,TSCA (NRCS plant code) -US-Ha1,17427,GRP_SPP_O,SPP_O,Tsuga canadensis -US-Ha1,17439,GRP_SPP_O,SPP_O_PERC,0.03 -US-Ha1,17421,GRP_SPP_O,SPP_O_PERC,0.66 -US-Ha1,17433,GRP_SPP_O,SPP_O_PERC,0.74 -US-Ha1,17391,GRP_SPP_O,SPP_O_PERC,0.91 -US-Ha1,17445,GRP_SPP_O,SPP_O_PERC,1.11 -US-Ha1,17397,GRP_SPP_O,SPP_O_PERC,1.5 -US-Ha1,17415,GRP_SPP_O,SPP_O_PERC,2.48 -US-Ha1,17373,GRP_SPP_O,SPP_O_PERC,20.37 -US-Ha1,17409,GRP_SPP_O,SPP_O_PERC,3.05 -US-Ha1,17367,GRP_SPP_O,SPP_O_PERC,3.41 -US-Ha1,17385,GRP_SPP_O,SPP_O_PERC,3.81 -US-Ha1,17403,GRP_SPP_O,SPP_O_PERC,4.11 -US-Ha1,17379,GRP_SPP_O,SPP_O_PERC,45.24 -US-Ha1,17451,GRP_SPP_O,SPP_O_PERC,5.44 -US-Ha1,17427,GRP_SPP_O,SPP_O_PERC,7.14 -US-Ha1,17367,GRP_SPP_O,SPP_APPROACH,estimates of mass are from diamater measurements scaled using allometric equations -US-Ha1,17367,GRP_SPP_O,SPP_DATE,2010 -US-Ha1,17373,GRP_SPP_O,SPP_DATE,2010 -US-Ha1,17379,GRP_SPP_O,SPP_DATE,2010 -US-Ha1,17385,GRP_SPP_O,SPP_DATE,2010 -US-Ha1,17391,GRP_SPP_O,SPP_DATE,2010 -US-Ha1,17397,GRP_SPP_O,SPP_DATE,2010 -US-Ha1,17403,GRP_SPP_O,SPP_DATE,2010 -US-Ha1,17409,GRP_SPP_O,SPP_DATE,2010 -US-Ha1,17415,GRP_SPP_O,SPP_DATE,2010 -US-Ha1,17421,GRP_SPP_O,SPP_DATE,2010 -US-Ha1,17427,GRP_SPP_O,SPP_DATE,2010 -US-Ha1,17433,GRP_SPP_O,SPP_DATE,2010 -US-Ha1,17439,GRP_SPP_O,SPP_DATE,2010 -US-Ha1,17445,GRP_SPP_O,SPP_DATE,2010 -US-Ha1,17451,GRP_SPP_O,SPP_DATE,2010 -US-Ha1,17367,GRP_SPP_O,SPP_COMMENT,Overstory is >10 cm DBH. Understory is 1-10 cm DBH. Raw data and data descriptions are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data. -US-Ha1,17440,GRP_SPP_U,SPP_U,Acer pensylvanicum -US-Ha1,17428,GRP_SPP_U,SPP_U,Acer rubrum -US-Ha1,23823,GRP_SPP_U,SPP_U,ACPE (NRCS plant code) -US-Ha1,24963,GRP_SPP_U,SPP_U,ACRU (NRCS plant code) -US-Ha1,27098,GRP_SPP_U,SPP_U,BEAL2 (NRCS plant code) -US-Ha1,17472,GRP_SPP_U,SPP_U,Betula alleghaniensis -US-Ha1,17374,GRP_SPP_U,SPP_U,Betula lenta -US-Ha1,17452,GRP_SPP_U,SPP_U,Betula papyrifera -US-Ha1,17392,GRP_SPP_U,SPP_U,Castanea dentata -US-Ha1,17404,GRP_SPP_U,SPP_U,Crataegus spp. -US-Ha1,17380,GRP_SPP_U,SPP_U,Fagus grandifolia -US-Ha1,17368,GRP_SPP_U,SPP_U,Fraxinus americana -US-Ha1,17457,GRP_SPP_U,SPP_U,Hamamelis virginiana L. -US-Ha1,23822,GRP_SPP_U,SPP_U,HAVI4 (NRCS plant code) -US-Ha1,17467,GRP_SPP_U,SPP_U,Picea glauca -US-Ha1,17462,GRP_SPP_U,SPP_U,Pinus strobus -US-Ha1,17398,GRP_SPP_U,SPP_U,Prunus pensylvanica -US-Ha1,17386,GRP_SPP_U,SPP_U,Prunus serotina -US-Ha1,17434,GRP_SPP_U,SPP_U,Quercus rubra -US-Ha1,17446,GRP_SPP_U,SPP_U,Rhus typhina -US-Ha1,24583,GRP_SPP_U,SPP_U,TSCA (NRCS plant code) -US-Ha1,17416,GRP_SPP_U,SPP_U,Tsuga canadensis -US-Ha1,17410,GRP_SPP_U,SPP_U,Vaccinium corymbosum L. -US-Ha1,17422,GRP_SPP_U,SPP_U,Viburnum cassinoides L. -US-Ha1,17386,GRP_SPP_U,SPP_U_PERC,0.01 -US-Ha1,17398,GRP_SPP_U,SPP_U_PERC,0.06 -US-Ha1,17404,GRP_SPP_U,SPP_U_PERC,0.12 -US-Ha1,17446,GRP_SPP_U,SPP_U_PERC,0.25 -US-Ha1,17452,GRP_SPP_U,SPP_U_PERC,0.27 -US-Ha1,17368,GRP_SPP_U,SPP_U_PERC,0.38 -US-Ha1,17422,GRP_SPP_U,SPP_U_PERC,0.53 -US-Ha1,17467,GRP_SPP_U,SPP_U_PERC,1.66 -US-Ha1,17472,GRP_SPP_U,SPP_U_PERC,13.27 -US-Ha1,17462,GRP_SPP_U,SPP_U_PERC,2.47 -US-Ha1,17428,GRP_SPP_U,SPP_U_PERC,22.16 -US-Ha1,17416,GRP_SPP_U,SPP_U_PERC,23.99 -US-Ha1,17410,GRP_SPP_U,SPP_U_PERC,3 -US-Ha1,17434,GRP_SPP_U,SPP_U_PERC,3.06 -US-Ha1,17440,GRP_SPP_U,SPP_U_PERC,3.38 -US-Ha1,17392,GRP_SPP_U,SPP_U_PERC,4.36 -US-Ha1,17457,GRP_SPP_U,SPP_U_PERC,6.09 -US-Ha1,17374,GRP_SPP_U,SPP_U_PERC,6.22 -US-Ha1,17380,GRP_SPP_U,SPP_U_PERC,8.73 -US-Ha1,17368,GRP_SPP_U,SPP_APPROACH,estimates of mass are from diamater measurements scaled using allometric equations -US-Ha1,17368,GRP_SPP_U,SPP_DATE,2010 -US-Ha1,17374,GRP_SPP_U,SPP_DATE,2010 -US-Ha1,17380,GRP_SPP_U,SPP_DATE,2010 -US-Ha1,17386,GRP_SPP_U,SPP_DATE,2010 -US-Ha1,17392,GRP_SPP_U,SPP_DATE,2010 -US-Ha1,17398,GRP_SPP_U,SPP_DATE,2010 -US-Ha1,17404,GRP_SPP_U,SPP_DATE,2010 -US-Ha1,17410,GRP_SPP_U,SPP_DATE,2010 -US-Ha1,17416,GRP_SPP_U,SPP_DATE,2010 -US-Ha1,17422,GRP_SPP_U,SPP_DATE,2010 -US-Ha1,17428,GRP_SPP_U,SPP_DATE,2010 -US-Ha1,17434,GRP_SPP_U,SPP_DATE,2010 -US-Ha1,17440,GRP_SPP_U,SPP_DATE,2010 -US-Ha1,17446,GRP_SPP_U,SPP_DATE,2010 -US-Ha1,17452,GRP_SPP_U,SPP_DATE,2010 -US-Ha1,17457,GRP_SPP_U,SPP_DATE,2010 -US-Ha1,17462,GRP_SPP_U,SPP_DATE,2010 -US-Ha1,17467,GRP_SPP_U,SPP_DATE,2010 -US-Ha1,17472,GRP_SPP_U,SPP_DATE,2010 -US-Ha1,17368,GRP_SPP_U,SPP_COMMENT,Overstory is >10 cm DBH. Understory is 1-10 cm DBH. Raw data and data descriptions are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data. -US-Ha1,11970,GRP_STATE,STATE,MA -US-Ha1,17309,GRP_STUMP_MASS,STUMP_MASS,10 -US-Ha1,17309,GRP_STUMP_MASS,STUMP_MASS_SPATIAL_VARIABILITY,13 -US-Ha1,17309,GRP_STUMP_MASS,STUMP_MASS_SPATIAL_REP_NUMBER,15 -US-Ha1,17309,GRP_STUMP_MASS,STUMP_MASS_UNIT,gC m-2 -US-Ha1,17309,GRP_STUMP_MASS,STUMP_MASS_APPROACH,"CWD survey, volume estimated from height and diameter measurements at base and top, using formula for frustrum of a cone. Converted to biomass using density estimates from Liu et al. 2006." -US-Ha1,17309,GRP_STUMP_MASS,STUMP_MASS_DATE,2003 -US-Ha1,17309,GRP_STUMP_MASS,STUMP_MASS_COMMENT,"there are many plots with 0 stumps, which is why standard deviation is so high." -US-Ha1,17321,GRP_STUMP_MASS,STUMP_MASS,16 -US-Ha1,17321,GRP_STUMP_MASS,STUMP_MASS_SPATIAL_VARIABILITY,23 -US-Ha1,17321,GRP_STUMP_MASS,STUMP_MASS_SPATIAL_REP_NUMBER,33 -US-Ha1,17321,GRP_STUMP_MASS,STUMP_MASS_UNIT,gC m-2 -US-Ha1,17321,GRP_STUMP_MASS,STUMP_MASS_APPROACH,"CWD survey, volume estimated from height and diameter measurements at base and top, using formula for frustrum of a cone. Converted to biomass using density estimates from Liu et al. 2006." -US-Ha1,17321,GRP_STUMP_MASS,STUMP_MASS_DATE,2009 -US-Ha1,17321,GRP_STUMP_MASS,STUMP_MASS_COMMENT,"there are many plots with 0 stumps, which is why standard deviation is so high." -US-Ha1,17315,GRP_STUMP_MASS,STUMP_MASS,17 -US-Ha1,17315,GRP_STUMP_MASS,STUMP_MASS_SPATIAL_VARIABILITY,27 -US-Ha1,17315,GRP_STUMP_MASS,STUMP_MASS_SPATIAL_REP_NUMBER,33 -US-Ha1,17315,GRP_STUMP_MASS,STUMP_MASS_UNIT,gC m-2 -US-Ha1,17315,GRP_STUMP_MASS,STUMP_MASS_APPROACH,"CWD survey, volume estimated from height and diameter measurements at base and top, using formula for frustrum of a cone. Converted to biomass using density estimates from Liu et al. 2006." -US-Ha1,17315,GRP_STUMP_MASS,STUMP_MASS_DATE,2006 -US-Ha1,17315,GRP_STUMP_MASS,STUMP_MASS_COMMENT,"there are many plots with 0 stumps, which is why standard deviation is so high." -US-Ha1,17303,GRP_STUMP_MASS,STUMP_MASS,18 -US-Ha1,17303,GRP_STUMP_MASS,STUMP_MASS_SPATIAL_VARIABILITY,50 -US-Ha1,17303,GRP_STUMP_MASS,STUMP_MASS_SPATIAL_REP_NUMBER,24 -US-Ha1,17303,GRP_STUMP_MASS,STUMP_MASS_UNIT,gC m-2 -US-Ha1,17303,GRP_STUMP_MASS,STUMP_MASS_APPROACH,"CWD survey, volume estimated from height and diameter measurements at base and top, using formula for frustrum of a cone. Converted to biomass using density estimates from Liu et al. 2006." -US-Ha1,17303,GRP_STUMP_MASS,STUMP_MASS_DATE,2000 -US-Ha1,17303,GRP_STUMP_MASS,STUMP_MASS_COMMENT,"there are many plots with 0 stumps, which is why standard deviation is so high." -US-Ha1,22096,GRP_SWC,SWC,13 -US-Ha1,22096,GRP_SWC,SWC_UNIT,Volumetric -US-Ha1,22096,GRP_SWC,SWC_PROFILE_ZERO_REF,Top of surface -US-Ha1,22096,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ha1,22096,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ha1,22096,GRP_SWC,SWC_DATE,20020708 -US-Ha1,22051,GRP_SWC,SWC,19 -US-Ha1,22051,GRP_SWC,SWC_UNIT,Volumetric -US-Ha1,22051,GRP_SWC,SWC_PROFILE_ZERO_REF,Top of surface -US-Ha1,22051,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ha1,22051,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ha1,22051,GRP_SWC,SWC_DATE,20020718 -US-Ha1,22072,GRP_SWC,SWC,22 -US-Ha1,22072,GRP_SWC,SWC_UNIT,Volumetric -US-Ha1,22072,GRP_SWC,SWC_PROFILE_ZERO_REF,Top of surface -US-Ha1,22072,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ha1,22072,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ha1,22072,GRP_SWC,SWC_DATE,20030710 -US-Ha1,22081,GRP_SWC,SWC,22 -US-Ha1,22081,GRP_SWC,SWC_UNIT,Volumetric -US-Ha1,22081,GRP_SWC,SWC_PROFILE_ZERO_REF,Top of surface -US-Ha1,22081,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ha1,22081,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ha1,22081,GRP_SWC,SWC_DATE,20030826 -US-Ha1,22060,GRP_SWC,SWC,23 -US-Ha1,22060,GRP_SWC,SWC_UNIT,Volumetric -US-Ha1,22060,GRP_SWC,SWC_PROFILE_ZERO_REF,Top of surface -US-Ha1,22060,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ha1,22060,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ha1,22060,GRP_SWC,SWC_DATE,20021018 -US-Ha1,22075,GRP_SWC,SWC,24 -US-Ha1,22075,GRP_SWC,SWC_UNIT,Volumetric -US-Ha1,22075,GRP_SWC,SWC_PROFILE_ZERO_REF,Top of surface -US-Ha1,22075,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ha1,22075,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ha1,22075,GRP_SWC,SWC_DATE,20030724 -US-Ha1,22097,GRP_SWC,SWC,26 -US-Ha1,22097,GRP_SWC,SWC_UNIT,Volumetric -US-Ha1,22097,GRP_SWC,SWC_PROFILE_ZERO_REF,Top of surface -US-Ha1,22097,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ha1,22097,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ha1,22097,GRP_SWC,SWC_DATE,20020709 -US-Ha1,22098,GRP_SWC,SWC,26 -US-Ha1,22098,GRP_SWC,SWC_UNIT,Volumetric -US-Ha1,22098,GRP_SWC,SWC_PROFILE_ZERO_REF,Top of surface -US-Ha1,22098,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ha1,22098,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ha1,22098,GRP_SWC,SWC_DATE,20020711 -US-Ha1,22066,GRP_SWC,SWC,27 -US-Ha1,22066,GRP_SWC,SWC_UNIT,Volumetric -US-Ha1,22066,GRP_SWC,SWC_PROFILE_ZERO_REF,Top of surface -US-Ha1,22066,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ha1,22066,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ha1,22066,GRP_SWC,SWC_DATE,20030615 -US-Ha1,22078,GRP_SWC,SWC,29 -US-Ha1,22078,GRP_SWC,SWC_UNIT,Volumetric -US-Ha1,22078,GRP_SWC,SWC_PROFILE_ZERO_REF,Top of surface -US-Ha1,22078,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ha1,22078,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ha1,22078,GRP_SWC,SWC_DATE,20030815 -US-Ha1,22083,GRP_SWC,SWC,29 -US-Ha1,22083,GRP_SWC,SWC_UNIT,Volumetric -US-Ha1,22083,GRP_SWC,SWC_PROFILE_ZERO_REF,Top of surface -US-Ha1,22083,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ha1,22083,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ha1,22083,GRP_SWC,SWC_DATE,20030924 -US-Ha1,22092,GRP_SWC,SWC,29 -US-Ha1,22092,GRP_SWC,SWC_UNIT,Volumetric -US-Ha1,22092,GRP_SWC,SWC_PROFILE_ZERO_REF,Top of surface -US-Ha1,22092,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ha1,22092,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ha1,22092,GRP_SWC,SWC_DATE,20020517 -US-Ha1,22095,GRP_SWC,SWC,29 -US-Ha1,22095,GRP_SWC,SWC_UNIT,Volumetric -US-Ha1,22095,GRP_SWC,SWC_PROFILE_ZERO_REF,Top of surface -US-Ha1,22095,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ha1,22095,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ha1,22095,GRP_SWC,SWC_DATE,20020702 -US-Ha1,22054,GRP_SWC,SWC,30 -US-Ha1,22054,GRP_SWC,SWC_UNIT,Volumetric -US-Ha1,22054,GRP_SWC,SWC_PROFILE_ZERO_REF,Top of surface -US-Ha1,22054,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ha1,22054,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ha1,22054,GRP_SWC,SWC_DATE,20020724 -US-Ha1,22085,GRP_SWC,SWC,31 -US-Ha1,22085,GRP_SWC,SWC_UNIT,Volumetric -US-Ha1,22085,GRP_SWC,SWC_PROFILE_ZERO_REF,Top of surface -US-Ha1,22085,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ha1,22085,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ha1,22085,GRP_SWC,SWC_DATE,20031024 -US-Ha1,22094,GRP_SWC,SWC,31 -US-Ha1,22094,GRP_SWC,SWC_UNIT,Volumetric -US-Ha1,22094,GRP_SWC,SWC_PROFILE_ZERO_REF,Top of surface -US-Ha1,22094,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ha1,22094,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ha1,22094,GRP_SWC,SWC_DATE,20020625 -US-Ha1,22088,GRP_SWC,SWC,32 -US-Ha1,22088,GRP_SWC,SWC_UNIT,Volumetric -US-Ha1,22088,GRP_SWC,SWC_PROFILE_ZERO_REF,Top of surface -US-Ha1,22088,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ha1,22088,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ha1,22088,GRP_SWC,SWC_DATE,20000725 -US-Ha1,22089,GRP_SWC,SWC,32 -US-Ha1,22089,GRP_SWC,SWC_UNIT,Volumetric -US-Ha1,22089,GRP_SWC,SWC_PROFILE_ZERO_REF,Top of surface -US-Ha1,22089,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ha1,22089,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ha1,22089,GRP_SWC,SWC_DATE,20000804 -US-Ha1,22069,GRP_SWC,SWC,33 -US-Ha1,22069,GRP_SWC,SWC_UNIT,Volumetric -US-Ha1,22069,GRP_SWC,SWC_PROFILE_ZERO_REF,Top of surface -US-Ha1,22069,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ha1,22069,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ha1,22069,GRP_SWC,SWC_DATE,20030624 -US-Ha1,22090,GRP_SWC,SWC,34 -US-Ha1,22090,GRP_SWC,SWC_UNIT,Volumetric -US-Ha1,22090,GRP_SWC,SWC_PROFILE_ZERO_REF,Top of surface -US-Ha1,22090,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ha1,22090,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ha1,22090,GRP_SWC,SWC_DATE,20000808 -US-Ha1,22087,GRP_SWC,SWC,37 -US-Ha1,22087,GRP_SWC,SWC_UNIT,Volumetric -US-Ha1,22087,GRP_SWC,SWC_PROFILE_ZERO_REF,Top of surface -US-Ha1,22087,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ha1,22087,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ha1,22087,GRP_SWC,SWC_DATE,20000626 -US-Ha1,22091,GRP_SWC,SWC,37 -US-Ha1,22091,GRP_SWC,SWC_UNIT,Volumetric -US-Ha1,22091,GRP_SWC,SWC_PROFILE_ZERO_REF,Top of surface -US-Ha1,22091,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ha1,22091,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ha1,22091,GRP_SWC,SWC_DATE,20020516 -US-Ha1,22093,GRP_SWC,SWC,41 -US-Ha1,22093,GRP_SWC,SWC_UNIT,Volumetric -US-Ha1,22093,GRP_SWC,SWC_PROFILE_ZERO_REF,Top of surface -US-Ha1,22093,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ha1,22093,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ha1,22093,GRP_SWC,SWC_DATE,20020608 -US-Ha1,22063,GRP_SWC,SWC,42 -US-Ha1,22063,GRP_SWC,SWC_UNIT,Volumetric -US-Ha1,22063,GRP_SWC,SWC_PROFILE_ZERO_REF,Top of surface -US-Ha1,22063,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ha1,22063,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ha1,22063,GRP_SWC,SWC_DATE,20030430 -US-Ha1,22057,GRP_SWC,SWC,8 -US-Ha1,22057,GRP_SWC,SWC_UNIT,Volumetric -US-Ha1,22057,GRP_SWC,SWC_PROFILE_ZERO_REF,Top of surface -US-Ha1,22057,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ha1,22057,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ha1,22057,GRP_SWC,SWC_DATE,20020826 -US-Ha1,11971,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,J. William Munger -US-Ha1,11971,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Ha1,11971,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,jwmunger@seas.harvard.edu -US-Ha1,11971,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Harvard University -US-Ha1,11971,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"School of Engineering and Applied Sciences, 20 Oxford Street,Cambridge, MA USA 02138" -US-Ha1,87883,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Tim Whitby -US-Ha1,87883,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,BADMContact -US-Ha1,87883,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,tgwhitby@g.harvard.edu -US-Ha1,87883,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Harvard University -US-Ha1,87883,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"School of Engineering and Applied Sciences, 20 Oxford Street,Cambridge, MA USA 02138" -US-Ha1,101053,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Jaclyn Matthes -US-Ha1,101053,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Affiliate -US-Ha1,101053,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,jaclyn_matthes@fas.harvard.edu -US-Ha1,101053,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Harvard University -US-Ha1,101053,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Harvard Forest -324 North Main St. -Petersham, MA 01366" -US-Ha1,29811,GRP_TOWER_POWER,TOWER_POWER,Direct power -US-Ha1,22189,GRP_TOWER_TYPE,TOWER_TYPE,triangle -US-Ha1,17429,GRP_TREES_NUM,TREES_NUM,0.39 -US-Ha1,17429,GRP_TREES_NUM,TREES_NUM_SPP,Acer pennsylvanicum -US-Ha1,17429,GRP_TREES_NUM,TREES_NUM_DATE,1993 -US-Ha1,17429,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17429,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,2.28 -US-Ha1,17501,GRP_TREES_NUM,TREES_NUM,0.39 -US-Ha1,17501,GRP_TREES_NUM,TREES_NUM_SPP,Acer pennsylvanicum -US-Ha1,17501,GRP_TREES_NUM,TREES_NUM_DATE,19981030 -US-Ha1,17501,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17501,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,2.28 -US-Ha1,17563,GRP_TREES_NUM,TREES_NUM,0.39 -US-Ha1,17563,GRP_TREES_NUM,TREES_NUM_SPP,Acer pennsylvanicum -US-Ha1,17563,GRP_TREES_NUM,TREES_NUM_DATE,20071120 -US-Ha1,17563,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17563,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,2.28 -US-Ha1,17608,GRP_TREES_NUM,TREES_NUM,0.39 -US-Ha1,17608,GRP_TREES_NUM,TREES_NUM_SPP,Acer pennsylvanicum -US-Ha1,17608,GRP_TREES_NUM,TREES_NUM_DATE,20081120 -US-Ha1,17608,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17608,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,2.28 -US-Ha1,17653,GRP_TREES_NUM,TREES_NUM,0.39 -US-Ha1,17653,GRP_TREES_NUM,TREES_NUM_SPP,Acer pennsylvanicum -US-Ha1,17653,GRP_TREES_NUM,TREES_NUM_DATE,20091201 -US-Ha1,17653,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17653,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,2.28 -US-Ha1,17698,GRP_TREES_NUM,TREES_NUM,0.39 -US-Ha1,17698,GRP_TREES_NUM,TREES_NUM_SPP,Acer pennsylvanicum -US-Ha1,17698,GRP_TREES_NUM,TREES_NUM_DATE,20101207 -US-Ha1,17698,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17698,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,2.28 -US-Ha1,17743,GRP_TREES_NUM,TREES_NUM,0.39 -US-Ha1,17743,GRP_TREES_NUM,TREES_NUM_SPP,Acer pennsylvanicum -US-Ha1,17743,GRP_TREES_NUM,TREES_NUM_DATE,20111201 -US-Ha1,17743,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17743,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,2.28 -US-Ha1,17788,GRP_TREES_NUM,TREES_NUM,0.39 -US-Ha1,17788,GRP_TREES_NUM,TREES_NUM_SPP,Acer pennsylvanicum -US-Ha1,17788,GRP_TREES_NUM,TREES_NUM_DATE,20121204 -US-Ha1,17788,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17788,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,2.28 -US-Ha1,17833,GRP_TREES_NUM,TREES_NUM,0.39 -US-Ha1,17833,GRP_TREES_NUM,TREES_NUM_SPP,Acer pennsylvanicum -US-Ha1,17833,GRP_TREES_NUM,TREES_NUM_DATE,20131212 -US-Ha1,17833,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17833,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,2.28 -US-Ha1,17888,GRP_TREES_NUM,TREES_NUM,0.39 -US-Ha1,17888,GRP_TREES_NUM,TREES_NUM_SPP,Acer pennsylvanicum -US-Ha1,17888,GRP_TREES_NUM,TREES_NUM_DATE,19991027 -US-Ha1,17888,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17888,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,2.28 -US-Ha1,17948,GRP_TREES_NUM,TREES_NUM,0.39 -US-Ha1,17948,GRP_TREES_NUM,TREES_NUM_SPP,Acer pennsylvanicum -US-Ha1,17948,GRP_TREES_NUM,TREES_NUM_DATE,20001024 -US-Ha1,17948,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17948,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,2.28 -US-Ha1,18007,GRP_TREES_NUM,TREES_NUM,0.39 -US-Ha1,18007,GRP_TREES_NUM,TREES_NUM_SPP,Acer pennsylvanicum -US-Ha1,18007,GRP_TREES_NUM,TREES_NUM_DATE,20011026 -US-Ha1,18007,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,18007,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,2.28 -US-Ha1,18067,GRP_TREES_NUM,TREES_NUM,0.39 -US-Ha1,18067,GRP_TREES_NUM,TREES_NUM_SPP,Acer pennsylvanicum -US-Ha1,18067,GRP_TREES_NUM,TREES_NUM_DATE,20021114 -US-Ha1,18067,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,18067,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,2.28 -US-Ha1,18127,GRP_TREES_NUM,TREES_NUM,0.39 -US-Ha1,18127,GRP_TREES_NUM,TREES_NUM_SPP,Acer pennsylvanicum -US-Ha1,18127,GRP_TREES_NUM,TREES_NUM_DATE,20031113 -US-Ha1,18127,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,18127,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,2.28 -US-Ha1,18187,GRP_TREES_NUM,TREES_NUM,0.39 -US-Ha1,18187,GRP_TREES_NUM,TREES_NUM_SPP,Acer pennsylvanicum -US-Ha1,18187,GRP_TREES_NUM,TREES_NUM_DATE,20041103 -US-Ha1,18187,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,18187,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,2.28 -US-Ha1,18247,GRP_TREES_NUM,TREES_NUM,0.39 -US-Ha1,18247,GRP_TREES_NUM,TREES_NUM_SPP,Acer pennsylvanicum -US-Ha1,18247,GRP_TREES_NUM,TREES_NUM_DATE,20051102 -US-Ha1,18247,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,18247,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,2.28 -US-Ha1,18293,GRP_TREES_NUM,TREES_NUM,0.39 -US-Ha1,18293,GRP_TREES_NUM,TREES_NUM_SPP,Acer pennsylvanicum -US-Ha1,18293,GRP_TREES_NUM,TREES_NUM_DATE,20061114 -US-Ha1,18293,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,18293,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,2.28 -US-Ha1,17447,GRP_TREES_NUM,TREES_NUM,11.37 -US-Ha1,17447,GRP_TREES_NUM,TREES_NUM_SPP,Picea glauca -US-Ha1,17447,GRP_TREES_NUM,TREES_NUM_DATE,1993 -US-Ha1,17447,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17447,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,40.04 -US-Ha1,17513,GRP_TREES_NUM,TREES_NUM,11.37 -US-Ha1,17513,GRP_TREES_NUM,TREES_NUM_SPP,Picea glauca -US-Ha1,17513,GRP_TREES_NUM,TREES_NUM_DATE,19981030 -US-Ha1,17513,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17513,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,40.04 -US-Ha1,17527,GRP_TREES_NUM,TREES_NUM,11.37 -US-Ha1,17527,GRP_TREES_NUM,TREES_NUM_SPP,Picea glauca -US-Ha1,17527,GRP_TREES_NUM,TREES_NUM_DATE,20061114 -US-Ha1,17527,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17527,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,40.04 -US-Ha1,17572,GRP_TREES_NUM,TREES_NUM,11.37 -US-Ha1,17572,GRP_TREES_NUM,TREES_NUM_SPP,Picea glauca -US-Ha1,17572,GRP_TREES_NUM,TREES_NUM_DATE,20071120 -US-Ha1,17572,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17572,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,40.04 -US-Ha1,17617,GRP_TREES_NUM,TREES_NUM,11.37 -US-Ha1,17617,GRP_TREES_NUM,TREES_NUM_SPP,Picea glauca -US-Ha1,17617,GRP_TREES_NUM,TREES_NUM_DATE,20081120 -US-Ha1,17617,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17617,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,40.04 -US-Ha1,17662,GRP_TREES_NUM,TREES_NUM,11.37 -US-Ha1,17662,GRP_TREES_NUM,TREES_NUM_SPP,Picea glauca -US-Ha1,17662,GRP_TREES_NUM,TREES_NUM_DATE,20091201 -US-Ha1,17662,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17662,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,40.04 -US-Ha1,17707,GRP_TREES_NUM,TREES_NUM,11.37 -US-Ha1,17707,GRP_TREES_NUM,TREES_NUM_SPP,Picea glauca -US-Ha1,17707,GRP_TREES_NUM,TREES_NUM_DATE,20101207 -US-Ha1,17707,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17707,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,40.04 -US-Ha1,17752,GRP_TREES_NUM,TREES_NUM,11.37 -US-Ha1,17752,GRP_TREES_NUM,TREES_NUM_SPP,Picea glauca -US-Ha1,17752,GRP_TREES_NUM,TREES_NUM_DATE,20111201 -US-Ha1,17752,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17752,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,40.04 -US-Ha1,17797,GRP_TREES_NUM,TREES_NUM,11.37 -US-Ha1,17797,GRP_TREES_NUM,TREES_NUM_SPP,Picea glauca -US-Ha1,17797,GRP_TREES_NUM,TREES_NUM_DATE,20121204 -US-Ha1,17797,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17797,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,40.04 -US-Ha1,17842,GRP_TREES_NUM,TREES_NUM,11.37 -US-Ha1,17842,GRP_TREES_NUM,TREES_NUM_SPP,Picea glauca -US-Ha1,17842,GRP_TREES_NUM,TREES_NUM_DATE,20131212 -US-Ha1,17842,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17842,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,40.04 -US-Ha1,17900,GRP_TREES_NUM,TREES_NUM,11.37 -US-Ha1,17900,GRP_TREES_NUM,TREES_NUM_SPP,Picea glauca -US-Ha1,17900,GRP_TREES_NUM,TREES_NUM_DATE,19991027 -US-Ha1,17900,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17900,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,40.04 -US-Ha1,17959,GRP_TREES_NUM,TREES_NUM,11.37 -US-Ha1,17959,GRP_TREES_NUM,TREES_NUM_SPP,Picea glauca -US-Ha1,17959,GRP_TREES_NUM,TREES_NUM_DATE,20001024 -US-Ha1,17959,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17959,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,40.04 -US-Ha1,18019,GRP_TREES_NUM,TREES_NUM,11.37 -US-Ha1,18019,GRP_TREES_NUM,TREES_NUM_SPP,Picea glauca -US-Ha1,18019,GRP_TREES_NUM,TREES_NUM_DATE,20011026 -US-Ha1,18019,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,18019,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,40.04 -US-Ha1,18079,GRP_TREES_NUM,TREES_NUM,11.37 -US-Ha1,18079,GRP_TREES_NUM,TREES_NUM_SPP,Picea glauca -US-Ha1,18079,GRP_TREES_NUM,TREES_NUM_DATE,20021114 -US-Ha1,18079,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,18079,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,40.04 -US-Ha1,18139,GRP_TREES_NUM,TREES_NUM,11.37 -US-Ha1,18139,GRP_TREES_NUM,TREES_NUM_SPP,Picea glauca -US-Ha1,18139,GRP_TREES_NUM,TREES_NUM_DATE,20031113 -US-Ha1,18139,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,18139,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,40.04 -US-Ha1,18199,GRP_TREES_NUM,TREES_NUM,11.37 -US-Ha1,18199,GRP_TREES_NUM,TREES_NUM_SPP,Picea glauca -US-Ha1,18199,GRP_TREES_NUM,TREES_NUM_DATE,20041103 -US-Ha1,18199,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,18199,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,40.04 -US-Ha1,18257,GRP_TREES_NUM,TREES_NUM,11.37 -US-Ha1,18257,GRP_TREES_NUM,TREES_NUM_SPP,Picea glauca -US-Ha1,18257,GRP_TREES_NUM,TREES_NUM_DATE,20051102 -US-Ha1,18257,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,18257,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,40.04 -US-Ha1,17381,GRP_TREES_NUM,TREES_NUM,11.84 -US-Ha1,17381,GRP_TREES_NUM,TREES_NUM_SPP,Fagus grandifolia -US-Ha1,17381,GRP_TREES_NUM,TREES_NUM_DATE,1993 -US-Ha1,17381,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17381,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,22.88 -US-Ha1,17468,GRP_TREES_NUM,TREES_NUM,11.84 -US-Ha1,17468,GRP_TREES_NUM,TREES_NUM_SPP,Fagus grandifolia -US-Ha1,17468,GRP_TREES_NUM,TREES_NUM_DATE,19981030 -US-Ha1,17468,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17468,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,22.88 -US-Ha1,17539,GRP_TREES_NUM,TREES_NUM,11.84 -US-Ha1,17539,GRP_TREES_NUM,TREES_NUM_SPP,Fagus grandifolia -US-Ha1,17539,GRP_TREES_NUM,TREES_NUM_DATE,20071120 -US-Ha1,17539,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17539,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,22.88 -US-Ha1,17584,GRP_TREES_NUM,TREES_NUM,11.84 -US-Ha1,17584,GRP_TREES_NUM,TREES_NUM_SPP,Fagus grandifolia -US-Ha1,17584,GRP_TREES_NUM,TREES_NUM_DATE,20081120 -US-Ha1,17584,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17584,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,22.88 -US-Ha1,17629,GRP_TREES_NUM,TREES_NUM,11.84 -US-Ha1,17629,GRP_TREES_NUM,TREES_NUM_SPP,Fagus grandifolia -US-Ha1,17629,GRP_TREES_NUM,TREES_NUM_DATE,20091201 -US-Ha1,17629,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17629,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,22.88 -US-Ha1,17674,GRP_TREES_NUM,TREES_NUM,11.84 -US-Ha1,17674,GRP_TREES_NUM,TREES_NUM_SPP,Fagus grandifolia -US-Ha1,17674,GRP_TREES_NUM,TREES_NUM_DATE,20101207 -US-Ha1,17674,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17674,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,22.88 -US-Ha1,17719,GRP_TREES_NUM,TREES_NUM,11.84 -US-Ha1,17719,GRP_TREES_NUM,TREES_NUM_SPP,Fagus grandifolia -US-Ha1,17719,GRP_TREES_NUM,TREES_NUM_DATE,20111201 -US-Ha1,17719,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17719,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,22.88 -US-Ha1,17764,GRP_TREES_NUM,TREES_NUM,11.84 -US-Ha1,17764,GRP_TREES_NUM,TREES_NUM_SPP,Fagus grandifolia -US-Ha1,17764,GRP_TREES_NUM,TREES_NUM_DATE,20121204 -US-Ha1,17764,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17764,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,22.88 -US-Ha1,17809,GRP_TREES_NUM,TREES_NUM,11.84 -US-Ha1,17809,GRP_TREES_NUM,TREES_NUM_SPP,Fagus grandifolia -US-Ha1,17809,GRP_TREES_NUM,TREES_NUM_DATE,20131212 -US-Ha1,17809,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17809,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,22.88 -US-Ha1,17856,GRP_TREES_NUM,TREES_NUM,11.84 -US-Ha1,17856,GRP_TREES_NUM,TREES_NUM_SPP,Fagus grandifolia -US-Ha1,17856,GRP_TREES_NUM,TREES_NUM_DATE,19991027 -US-Ha1,17856,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17856,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,22.88 -US-Ha1,17916,GRP_TREES_NUM,TREES_NUM,11.84 -US-Ha1,17916,GRP_TREES_NUM,TREES_NUM_SPP,Fagus grandifolia -US-Ha1,17916,GRP_TREES_NUM,TREES_NUM_DATE,20001024 -US-Ha1,17916,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17916,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,22.88 -US-Ha1,17975,GRP_TREES_NUM,TREES_NUM,11.84 -US-Ha1,17975,GRP_TREES_NUM,TREES_NUM_SPP,Fagus grandifolia -US-Ha1,17975,GRP_TREES_NUM,TREES_NUM_DATE,20011026 -US-Ha1,17975,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17975,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,22.88 -US-Ha1,18035,GRP_TREES_NUM,TREES_NUM,11.84 -US-Ha1,18035,GRP_TREES_NUM,TREES_NUM_SPP,Fagus grandifolia -US-Ha1,18035,GRP_TREES_NUM,TREES_NUM_DATE,20021114 -US-Ha1,18035,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,18035,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,22.88 -US-Ha1,18095,GRP_TREES_NUM,TREES_NUM,11.84 -US-Ha1,18095,GRP_TREES_NUM,TREES_NUM_SPP,Fagus grandifolia -US-Ha1,18095,GRP_TREES_NUM,TREES_NUM_DATE,20031113 -US-Ha1,18095,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,18095,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,22.88 -US-Ha1,18155,GRP_TREES_NUM,TREES_NUM,11.84 -US-Ha1,18155,GRP_TREES_NUM,TREES_NUM_SPP,Fagus grandifolia -US-Ha1,18155,GRP_TREES_NUM,TREES_NUM_DATE,20041103 -US-Ha1,18155,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,18155,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,22.88 -US-Ha1,18215,GRP_TREES_NUM,TREES_NUM,11.84 -US-Ha1,18215,GRP_TREES_NUM,TREES_NUM_SPP,Fagus grandifolia -US-Ha1,18215,GRP_TREES_NUM,TREES_NUM_DATE,20051102 -US-Ha1,18215,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,18215,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,22.88 -US-Ha1,18269,GRP_TREES_NUM,TREES_NUM,11.84 -US-Ha1,18269,GRP_TREES_NUM,TREES_NUM_SPP,Fagus grandifolia -US-Ha1,18269,GRP_TREES_NUM,TREES_NUM_DATE,20061114 -US-Ha1,18269,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,18269,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,22.88 -US-Ha1,17375,GRP_TREES_NUM,TREES_NUM,16.51 -US-Ha1,17375,GRP_TREES_NUM,TREES_NUM_SPP,Betula lenta -US-Ha1,17375,GRP_TREES_NUM,TREES_NUM_DATE,1993 -US-Ha1,17375,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17375,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,41.22 -US-Ha1,17463,GRP_TREES_NUM,TREES_NUM,16.51 -US-Ha1,17463,GRP_TREES_NUM,TREES_NUM_SPP,Betula lenta -US-Ha1,17463,GRP_TREES_NUM,TREES_NUM_DATE,19981030 -US-Ha1,17463,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17463,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,41.22 -US-Ha1,17536,GRP_TREES_NUM,TREES_NUM,16.51 -US-Ha1,17536,GRP_TREES_NUM,TREES_NUM_SPP,Betula lenta -US-Ha1,17536,GRP_TREES_NUM,TREES_NUM_DATE,20071120 -US-Ha1,17536,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17536,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,41.22 -US-Ha1,17581,GRP_TREES_NUM,TREES_NUM,16.51 -US-Ha1,17581,GRP_TREES_NUM,TREES_NUM_SPP,Betula lenta -US-Ha1,17581,GRP_TREES_NUM,TREES_NUM_DATE,20081120 -US-Ha1,17581,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17581,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,41.22 -US-Ha1,17626,GRP_TREES_NUM,TREES_NUM,16.51 -US-Ha1,17626,GRP_TREES_NUM,TREES_NUM_SPP,Betula lenta -US-Ha1,17626,GRP_TREES_NUM,TREES_NUM_DATE,20091201 -US-Ha1,17626,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17626,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,41.22 -US-Ha1,17671,GRP_TREES_NUM,TREES_NUM,16.51 -US-Ha1,17671,GRP_TREES_NUM,TREES_NUM_SPP,Betula lenta -US-Ha1,17671,GRP_TREES_NUM,TREES_NUM_DATE,20101207 -US-Ha1,17671,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17671,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,41.22 -US-Ha1,17716,GRP_TREES_NUM,TREES_NUM,16.51 -US-Ha1,17716,GRP_TREES_NUM,TREES_NUM_SPP,Betula lenta -US-Ha1,17716,GRP_TREES_NUM,TREES_NUM_DATE,20111201 -US-Ha1,17716,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17716,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,41.22 -US-Ha1,17761,GRP_TREES_NUM,TREES_NUM,16.51 -US-Ha1,17761,GRP_TREES_NUM,TREES_NUM_SPP,Betula lenta -US-Ha1,17761,GRP_TREES_NUM,TREES_NUM_DATE,20121204 -US-Ha1,17761,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17761,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,41.22 -US-Ha1,17806,GRP_TREES_NUM,TREES_NUM,16.51 -US-Ha1,17806,GRP_TREES_NUM,TREES_NUM_SPP,Betula lenta -US-Ha1,17806,GRP_TREES_NUM,TREES_NUM_DATE,20131212 -US-Ha1,17806,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17806,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,41.22 -US-Ha1,17852,GRP_TREES_NUM,TREES_NUM,16.51 -US-Ha1,17852,GRP_TREES_NUM,TREES_NUM_SPP,Betula lenta -US-Ha1,17852,GRP_TREES_NUM,TREES_NUM_DATE,19991027 -US-Ha1,17852,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17852,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,41.22 -US-Ha1,17912,GRP_TREES_NUM,TREES_NUM,16.51 -US-Ha1,17912,GRP_TREES_NUM,TREES_NUM_SPP,Betula lenta -US-Ha1,17912,GRP_TREES_NUM,TREES_NUM_DATE,20001024 -US-Ha1,17912,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17912,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,41.22 -US-Ha1,17971,GRP_TREES_NUM,TREES_NUM,16.51 -US-Ha1,17971,GRP_TREES_NUM,TREES_NUM_SPP,Betula lenta -US-Ha1,17971,GRP_TREES_NUM,TREES_NUM_DATE,20011026 -US-Ha1,17971,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17971,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,41.22 -US-Ha1,18031,GRP_TREES_NUM,TREES_NUM,16.51 -US-Ha1,18031,GRP_TREES_NUM,TREES_NUM_SPP,Betula lenta -US-Ha1,18031,GRP_TREES_NUM,TREES_NUM_DATE,20021114 -US-Ha1,18031,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,18031,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,41.22 -US-Ha1,18091,GRP_TREES_NUM,TREES_NUM,16.51 -US-Ha1,18091,GRP_TREES_NUM,TREES_NUM_SPP,Betula lenta -US-Ha1,18091,GRP_TREES_NUM,TREES_NUM_DATE,20031113 -US-Ha1,18091,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,18091,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,41.22 -US-Ha1,18151,GRP_TREES_NUM,TREES_NUM,16.51 -US-Ha1,18151,GRP_TREES_NUM,TREES_NUM_SPP,Betula lenta -US-Ha1,18151,GRP_TREES_NUM,TREES_NUM_DATE,20041103 -US-Ha1,18151,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,18151,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,41.22 -US-Ha1,18211,GRP_TREES_NUM,TREES_NUM,16.51 -US-Ha1,18211,GRP_TREES_NUM,TREES_NUM_SPP,Betula lenta -US-Ha1,18211,GRP_TREES_NUM,TREES_NUM_DATE,20051102 -US-Ha1,18211,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,18211,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,41.22 -US-Ha1,18266,GRP_TREES_NUM,TREES_NUM,16.51 -US-Ha1,18266,GRP_TREES_NUM,TREES_NUM_SPP,Betula lenta -US-Ha1,18266,GRP_TREES_NUM,TREES_NUM_DATE,20061114 -US-Ha1,18266,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,18266,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,41.22 -US-Ha1,17405,GRP_TREES_NUM,TREES_NUM,178.48 -US-Ha1,17405,GRP_TREES_NUM,TREES_NUM_SPP,Tsuga canadensis -US-Ha1,17405,GRP_TREES_NUM,TREES_NUM_DATE,1993 -US-Ha1,17405,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17405,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,339.75 -US-Ha1,17485,GRP_TREES_NUM,TREES_NUM,178.48 -US-Ha1,17485,GRP_TREES_NUM,TREES_NUM_SPP,Tsuga canadensis -US-Ha1,17485,GRP_TREES_NUM,TREES_NUM_DATE,19981030 -US-Ha1,17485,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17485,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,339.75 -US-Ha1,17551,GRP_TREES_NUM,TREES_NUM,178.48 -US-Ha1,17551,GRP_TREES_NUM,TREES_NUM_SPP,Tsuga canadensis -US-Ha1,17551,GRP_TREES_NUM,TREES_NUM_DATE,20071120 -US-Ha1,17551,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17551,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,339.75 -US-Ha1,17596,GRP_TREES_NUM,TREES_NUM,178.48 -US-Ha1,17596,GRP_TREES_NUM,TREES_NUM_SPP,Tsuga canadensis -US-Ha1,17596,GRP_TREES_NUM,TREES_NUM_DATE,20081120 -US-Ha1,17596,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17596,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,339.75 -US-Ha1,17641,GRP_TREES_NUM,TREES_NUM,178.48 -US-Ha1,17641,GRP_TREES_NUM,TREES_NUM_SPP,Tsuga canadensis -US-Ha1,17641,GRP_TREES_NUM,TREES_NUM_DATE,20091201 -US-Ha1,17641,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17641,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,339.75 -US-Ha1,17686,GRP_TREES_NUM,TREES_NUM,178.48 -US-Ha1,17686,GRP_TREES_NUM,TREES_NUM_SPP,Tsuga canadensis -US-Ha1,17686,GRP_TREES_NUM,TREES_NUM_DATE,20101207 -US-Ha1,17686,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17686,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,339.75 -US-Ha1,17731,GRP_TREES_NUM,TREES_NUM,178.48 -US-Ha1,17731,GRP_TREES_NUM,TREES_NUM_SPP,Tsuga canadensis -US-Ha1,17731,GRP_TREES_NUM,TREES_NUM_DATE,20111201 -US-Ha1,17731,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17731,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,339.75 -US-Ha1,17776,GRP_TREES_NUM,TREES_NUM,178.48 -US-Ha1,17776,GRP_TREES_NUM,TREES_NUM_SPP,Tsuga canadensis -US-Ha1,17776,GRP_TREES_NUM,TREES_NUM_DATE,20121204 -US-Ha1,17776,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17776,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,339.75 -US-Ha1,17821,GRP_TREES_NUM,TREES_NUM,178.48 -US-Ha1,17821,GRP_TREES_NUM,TREES_NUM_SPP,Tsuga canadensis -US-Ha1,17821,GRP_TREES_NUM,TREES_NUM_DATE,20131212 -US-Ha1,17821,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17821,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,339.75 -US-Ha1,17872,GRP_TREES_NUM,TREES_NUM,178.48 -US-Ha1,17872,GRP_TREES_NUM,TREES_NUM_SPP,Tsuga canadensis -US-Ha1,17872,GRP_TREES_NUM,TREES_NUM_DATE,19991027 -US-Ha1,17872,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17872,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,339.75 -US-Ha1,17932,GRP_TREES_NUM,TREES_NUM,178.48 -US-Ha1,17932,GRP_TREES_NUM,TREES_NUM_SPP,Tsuga canadensis -US-Ha1,17932,GRP_TREES_NUM,TREES_NUM_DATE,20001024 -US-Ha1,17932,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17932,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,339.75 -US-Ha1,17991,GRP_TREES_NUM,TREES_NUM,178.48 -US-Ha1,17991,GRP_TREES_NUM,TREES_NUM_SPP,Tsuga canadensis -US-Ha1,17991,GRP_TREES_NUM,TREES_NUM_DATE,20011026 -US-Ha1,17991,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17991,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,339.75 -US-Ha1,18051,GRP_TREES_NUM,TREES_NUM,178.48 -US-Ha1,18051,GRP_TREES_NUM,TREES_NUM_SPP,Tsuga canadensis -US-Ha1,18051,GRP_TREES_NUM,TREES_NUM_DATE,20021114 -US-Ha1,18051,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,18051,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,339.75 -US-Ha1,18111,GRP_TREES_NUM,TREES_NUM,178.48 -US-Ha1,18111,GRP_TREES_NUM,TREES_NUM_SPP,Tsuga canadensis -US-Ha1,18111,GRP_TREES_NUM,TREES_NUM_DATE,20031113 -US-Ha1,18111,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,18111,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,339.75 -US-Ha1,18171,GRP_TREES_NUM,TREES_NUM,178.48 -US-Ha1,18171,GRP_TREES_NUM,TREES_NUM_SPP,Tsuga canadensis -US-Ha1,18171,GRP_TREES_NUM,TREES_NUM_DATE,20041103 -US-Ha1,18171,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,18171,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,339.75 -US-Ha1,18231,GRP_TREES_NUM,TREES_NUM,178.48 -US-Ha1,18231,GRP_TREES_NUM,TREES_NUM_SPP,Tsuga canadensis -US-Ha1,18231,GRP_TREES_NUM,TREES_NUM_DATE,20051102 -US-Ha1,18231,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,18231,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,339.75 -US-Ha1,18281,GRP_TREES_NUM,TREES_NUM,178.48 -US-Ha1,18281,GRP_TREES_NUM,TREES_NUM_SPP,Tsuga canadensis -US-Ha1,18281,GRP_TREES_NUM,TREES_NUM_DATE,20061114 -US-Ha1,18281,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,18281,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,339.75 -US-Ha1,17411,GRP_TREES_NUM,TREES_NUM,261.38 -US-Ha1,17411,GRP_TREES_NUM,TREES_NUM_SPP,Acer rubrum -US-Ha1,17411,GRP_TREES_NUM,TREES_NUM_DATE,1993 -US-Ha1,17411,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17411,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,159.43 -US-Ha1,17489,GRP_TREES_NUM,TREES_NUM,261.38 -US-Ha1,17489,GRP_TREES_NUM,TREES_NUM_SPP,Acer rubrum -US-Ha1,17489,GRP_TREES_NUM,TREES_NUM_DATE,19981030 -US-Ha1,17489,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17489,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,159.43 -US-Ha1,17554,GRP_TREES_NUM,TREES_NUM,261.38 -US-Ha1,17554,GRP_TREES_NUM,TREES_NUM_SPP,Acer rubrum -US-Ha1,17554,GRP_TREES_NUM,TREES_NUM_DATE,20071120 -US-Ha1,17554,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17554,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,159.43 -US-Ha1,17599,GRP_TREES_NUM,TREES_NUM,261.38 -US-Ha1,17599,GRP_TREES_NUM,TREES_NUM_SPP,Acer rubrum -US-Ha1,17599,GRP_TREES_NUM,TREES_NUM_DATE,20081120 -US-Ha1,17599,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17599,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,159.43 -US-Ha1,17644,GRP_TREES_NUM,TREES_NUM,261.38 -US-Ha1,17644,GRP_TREES_NUM,TREES_NUM_SPP,Acer rubrum -US-Ha1,17644,GRP_TREES_NUM,TREES_NUM_DATE,20091201 -US-Ha1,17644,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17644,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,159.43 -US-Ha1,17689,GRP_TREES_NUM,TREES_NUM,261.38 -US-Ha1,17689,GRP_TREES_NUM,TREES_NUM_SPP,Acer rubrum -US-Ha1,17689,GRP_TREES_NUM,TREES_NUM_DATE,20101207 -US-Ha1,17689,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17689,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,159.43 -US-Ha1,17734,GRP_TREES_NUM,TREES_NUM,261.38 -US-Ha1,17734,GRP_TREES_NUM,TREES_NUM_SPP,Acer rubrum -US-Ha1,17734,GRP_TREES_NUM,TREES_NUM_DATE,20111201 -US-Ha1,17734,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17734,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,159.43 -US-Ha1,17779,GRP_TREES_NUM,TREES_NUM,261.38 -US-Ha1,17779,GRP_TREES_NUM,TREES_NUM_SPP,Acer rubrum -US-Ha1,17779,GRP_TREES_NUM,TREES_NUM_DATE,20121204 -US-Ha1,17779,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17779,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,159.43 -US-Ha1,17824,GRP_TREES_NUM,TREES_NUM,261.38 -US-Ha1,17824,GRP_TREES_NUM,TREES_NUM_SPP,Acer rubrum -US-Ha1,17824,GRP_TREES_NUM,TREES_NUM_DATE,20131212 -US-Ha1,17824,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17824,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,159.43 -US-Ha1,17876,GRP_TREES_NUM,TREES_NUM,261.38 -US-Ha1,17876,GRP_TREES_NUM,TREES_NUM_SPP,Acer rubrum -US-Ha1,17876,GRP_TREES_NUM,TREES_NUM_DATE,19991027 -US-Ha1,17876,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17876,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,159.43 -US-Ha1,17936,GRP_TREES_NUM,TREES_NUM,261.38 -US-Ha1,17936,GRP_TREES_NUM,TREES_NUM_SPP,Acer rubrum -US-Ha1,17936,GRP_TREES_NUM,TREES_NUM_DATE,20001024 -US-Ha1,17936,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17936,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,159.43 -US-Ha1,17995,GRP_TREES_NUM,TREES_NUM,261.38 -US-Ha1,17995,GRP_TREES_NUM,TREES_NUM_SPP,Acer rubrum -US-Ha1,17995,GRP_TREES_NUM,TREES_NUM_DATE,20011026 -US-Ha1,17995,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17995,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,159.43 -US-Ha1,18055,GRP_TREES_NUM,TREES_NUM,261.38 -US-Ha1,18055,GRP_TREES_NUM,TREES_NUM_SPP,Acer rubrum -US-Ha1,18055,GRP_TREES_NUM,TREES_NUM_DATE,20021114 -US-Ha1,18055,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,18055,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,159.43 -US-Ha1,18115,GRP_TREES_NUM,TREES_NUM,261.38 -US-Ha1,18115,GRP_TREES_NUM,TREES_NUM_SPP,Acer rubrum -US-Ha1,18115,GRP_TREES_NUM,TREES_NUM_DATE,20031113 -US-Ha1,18115,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,18115,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,159.43 -US-Ha1,18175,GRP_TREES_NUM,TREES_NUM,261.38 -US-Ha1,18175,GRP_TREES_NUM,TREES_NUM_SPP,Acer rubrum -US-Ha1,18175,GRP_TREES_NUM,TREES_NUM_DATE,20041103 -US-Ha1,18175,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,18175,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,159.43 -US-Ha1,18235,GRP_TREES_NUM,TREES_NUM,261.38 -US-Ha1,18235,GRP_TREES_NUM,TREES_NUM_SPP,Acer rubrum -US-Ha1,18235,GRP_TREES_NUM,TREES_NUM_DATE,20051102 -US-Ha1,18235,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,18235,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,159.43 -US-Ha1,18284,GRP_TREES_NUM,TREES_NUM,261.38 -US-Ha1,18284,GRP_TREES_NUM,TREES_NUM_SPP,Acer rubrum -US-Ha1,18284,GRP_TREES_NUM,TREES_NUM_DATE,20061114 -US-Ha1,18284,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,18284,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,159.43 -US-Ha1,17369,GRP_TREES_NUM,TREES_NUM,28.38 -US-Ha1,17369,GRP_TREES_NUM,TREES_NUM_SPP,Fraxinus americana -US-Ha1,17369,GRP_TREES_NUM,TREES_NUM_DATE,1993 -US-Ha1,17369,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17369,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,105.46 -US-Ha1,17458,GRP_TREES_NUM,TREES_NUM,28.38 -US-Ha1,17458,GRP_TREES_NUM,TREES_NUM_SPP,Fraxinus americana -US-Ha1,17458,GRP_TREES_NUM,TREES_NUM_DATE,19981030 -US-Ha1,17458,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17458,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,105.46 -US-Ha1,17533,GRP_TREES_NUM,TREES_NUM,28.38 -US-Ha1,17533,GRP_TREES_NUM,TREES_NUM_SPP,Fraxinus americana -US-Ha1,17533,GRP_TREES_NUM,TREES_NUM_DATE,20071120 -US-Ha1,17533,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17533,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,105.46 -US-Ha1,17578,GRP_TREES_NUM,TREES_NUM,28.38 -US-Ha1,17578,GRP_TREES_NUM,TREES_NUM_SPP,Fraxinus americana -US-Ha1,17578,GRP_TREES_NUM,TREES_NUM_DATE,20081120 -US-Ha1,17578,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17578,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,105.46 -US-Ha1,17623,GRP_TREES_NUM,TREES_NUM,28.38 -US-Ha1,17623,GRP_TREES_NUM,TREES_NUM_SPP,Fraxinus americana -US-Ha1,17623,GRP_TREES_NUM,TREES_NUM_DATE,20091201 -US-Ha1,17623,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17623,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,105.46 -US-Ha1,17668,GRP_TREES_NUM,TREES_NUM,28.38 -US-Ha1,17668,GRP_TREES_NUM,TREES_NUM_SPP,Fraxinus americana -US-Ha1,17668,GRP_TREES_NUM,TREES_NUM_DATE,20101207 -US-Ha1,17668,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17668,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,105.46 -US-Ha1,17713,GRP_TREES_NUM,TREES_NUM,28.38 -US-Ha1,17713,GRP_TREES_NUM,TREES_NUM_SPP,Fraxinus americana -US-Ha1,17713,GRP_TREES_NUM,TREES_NUM_DATE,20111201 -US-Ha1,17713,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17713,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,105.46 -US-Ha1,17758,GRP_TREES_NUM,TREES_NUM,28.38 -US-Ha1,17758,GRP_TREES_NUM,TREES_NUM_SPP,Fraxinus americana -US-Ha1,17758,GRP_TREES_NUM,TREES_NUM_DATE,20121204 -US-Ha1,17758,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17758,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,105.46 -US-Ha1,17803,GRP_TREES_NUM,TREES_NUM,28.38 -US-Ha1,17803,GRP_TREES_NUM,TREES_NUM_SPP,Fraxinus americana -US-Ha1,17803,GRP_TREES_NUM,TREES_NUM_DATE,20131212 -US-Ha1,17803,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17803,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,105.46 -US-Ha1,17848,GRP_TREES_NUM,TREES_NUM,28.38 -US-Ha1,17848,GRP_TREES_NUM,TREES_NUM_SPP,Fraxinus americana -US-Ha1,17848,GRP_TREES_NUM,TREES_NUM_DATE,19991027 -US-Ha1,17848,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17848,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,105.46 -US-Ha1,17908,GRP_TREES_NUM,TREES_NUM,28.38 -US-Ha1,17908,GRP_TREES_NUM,TREES_NUM_SPP,Fraxinus americana -US-Ha1,17908,GRP_TREES_NUM,TREES_NUM_DATE,20001024 -US-Ha1,17908,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17908,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,105.46 -US-Ha1,17967,GRP_TREES_NUM,TREES_NUM,28.38 -US-Ha1,17967,GRP_TREES_NUM,TREES_NUM_SPP,Fraxinus americana -US-Ha1,17967,GRP_TREES_NUM,TREES_NUM_DATE,20011026 -US-Ha1,17967,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17967,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,105.46 -US-Ha1,18027,GRP_TREES_NUM,TREES_NUM,28.38 -US-Ha1,18027,GRP_TREES_NUM,TREES_NUM_SPP,Fraxinus americana -US-Ha1,18027,GRP_TREES_NUM,TREES_NUM_DATE,20021114 -US-Ha1,18027,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,18027,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,105.46 -US-Ha1,18087,GRP_TREES_NUM,TREES_NUM,28.38 -US-Ha1,18087,GRP_TREES_NUM,TREES_NUM_SPP,Fraxinus americana -US-Ha1,18087,GRP_TREES_NUM,TREES_NUM_DATE,20031113 -US-Ha1,18087,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,18087,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,105.46 -US-Ha1,18147,GRP_TREES_NUM,TREES_NUM,28.38 -US-Ha1,18147,GRP_TREES_NUM,TREES_NUM_SPP,Fraxinus americana -US-Ha1,18147,GRP_TREES_NUM,TREES_NUM_DATE,20041103 -US-Ha1,18147,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,18147,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,105.46 -US-Ha1,18207,GRP_TREES_NUM,TREES_NUM,28.38 -US-Ha1,18207,GRP_TREES_NUM,TREES_NUM_SPP,Fraxinus americana -US-Ha1,18207,GRP_TREES_NUM,TREES_NUM_DATE,20051102 -US-Ha1,18207,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,18207,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,105.46 -US-Ha1,18263,GRP_TREES_NUM,TREES_NUM,28.38 -US-Ha1,18263,GRP_TREES_NUM,TREES_NUM_SPP,Fraxinus americana -US-Ha1,18263,GRP_TREES_NUM,TREES_NUM_DATE,20061114 -US-Ha1,18263,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,18263,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,105.46 -US-Ha1,17393,GRP_TREES_NUM,TREES_NUM,28.93 -US-Ha1,17393,GRP_TREES_NUM,TREES_NUM_SPP,Prunus serotina -US-Ha1,17393,GRP_TREES_NUM,TREES_NUM_DATE,1993 -US-Ha1,17393,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17393,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,84.42 -US-Ha1,17477,GRP_TREES_NUM,TREES_NUM,28.93 -US-Ha1,17477,GRP_TREES_NUM,TREES_NUM_SPP,Prunus serotina -US-Ha1,17477,GRP_TREES_NUM,TREES_NUM_DATE,19981030 -US-Ha1,17477,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17477,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,84.42 -US-Ha1,17545,GRP_TREES_NUM,TREES_NUM,28.93 -US-Ha1,17545,GRP_TREES_NUM,TREES_NUM_SPP,Prunus serotina -US-Ha1,17545,GRP_TREES_NUM,TREES_NUM_DATE,20071120 -US-Ha1,17545,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17545,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,84.42 -US-Ha1,17590,GRP_TREES_NUM,TREES_NUM,28.93 -US-Ha1,17590,GRP_TREES_NUM,TREES_NUM_SPP,Prunus serotina -US-Ha1,17590,GRP_TREES_NUM,TREES_NUM_DATE,20081120 -US-Ha1,17590,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17590,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,84.42 -US-Ha1,17635,GRP_TREES_NUM,TREES_NUM,28.93 -US-Ha1,17635,GRP_TREES_NUM,TREES_NUM_SPP,Prunus serotina -US-Ha1,17635,GRP_TREES_NUM,TREES_NUM_DATE,20091201 -US-Ha1,17635,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17635,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,84.42 -US-Ha1,17680,GRP_TREES_NUM,TREES_NUM,28.93 -US-Ha1,17680,GRP_TREES_NUM,TREES_NUM_SPP,Prunus serotina -US-Ha1,17680,GRP_TREES_NUM,TREES_NUM_DATE,20101207 -US-Ha1,17680,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17680,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,84.42 -US-Ha1,17725,GRP_TREES_NUM,TREES_NUM,28.93 -US-Ha1,17725,GRP_TREES_NUM,TREES_NUM_SPP,Prunus serotina -US-Ha1,17725,GRP_TREES_NUM,TREES_NUM_DATE,20111201 -US-Ha1,17725,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17725,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,84.42 -US-Ha1,17770,GRP_TREES_NUM,TREES_NUM,28.93 -US-Ha1,17770,GRP_TREES_NUM,TREES_NUM_SPP,Prunus serotina -US-Ha1,17770,GRP_TREES_NUM,TREES_NUM_DATE,20121204 -US-Ha1,17770,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17770,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,84.42 -US-Ha1,17815,GRP_TREES_NUM,TREES_NUM,28.93 -US-Ha1,17815,GRP_TREES_NUM,TREES_NUM_SPP,Prunus serotina -US-Ha1,17815,GRP_TREES_NUM,TREES_NUM_DATE,20131212 -US-Ha1,17815,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17815,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,84.42 -US-Ha1,17864,GRP_TREES_NUM,TREES_NUM,28.93 -US-Ha1,17864,GRP_TREES_NUM,TREES_NUM_SPP,Prunus serotina -US-Ha1,17864,GRP_TREES_NUM,TREES_NUM_DATE,19991027 -US-Ha1,17864,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17864,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,84.42 -US-Ha1,17924,GRP_TREES_NUM,TREES_NUM,28.93 -US-Ha1,17924,GRP_TREES_NUM,TREES_NUM_SPP,Prunus serotina -US-Ha1,17924,GRP_TREES_NUM,TREES_NUM_DATE,20001024 -US-Ha1,17924,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17924,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,84.42 -US-Ha1,17983,GRP_TREES_NUM,TREES_NUM,28.93 -US-Ha1,17983,GRP_TREES_NUM,TREES_NUM_SPP,Prunus serotina -US-Ha1,17983,GRP_TREES_NUM,TREES_NUM_DATE,20011026 -US-Ha1,17983,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17983,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,84.42 -US-Ha1,18043,GRP_TREES_NUM,TREES_NUM,28.93 -US-Ha1,18043,GRP_TREES_NUM,TREES_NUM_SPP,Prunus serotina -US-Ha1,18043,GRP_TREES_NUM,TREES_NUM_DATE,20021114 -US-Ha1,18043,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,18043,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,84.42 -US-Ha1,18103,GRP_TREES_NUM,TREES_NUM,28.93 -US-Ha1,18103,GRP_TREES_NUM,TREES_NUM_SPP,Prunus serotina -US-Ha1,18103,GRP_TREES_NUM,TREES_NUM_DATE,20031113 -US-Ha1,18103,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,18103,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,84.42 -US-Ha1,18163,GRP_TREES_NUM,TREES_NUM,28.93 -US-Ha1,18163,GRP_TREES_NUM,TREES_NUM_SPP,Prunus serotina -US-Ha1,18163,GRP_TREES_NUM,TREES_NUM_DATE,20041103 -US-Ha1,18163,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,18163,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,84.42 -US-Ha1,18223,GRP_TREES_NUM,TREES_NUM,28.93 -US-Ha1,18223,GRP_TREES_NUM,TREES_NUM_SPP,Prunus serotina -US-Ha1,18223,GRP_TREES_NUM,TREES_NUM_DATE,20051102 -US-Ha1,18223,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,18223,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,84.42 -US-Ha1,18275,GRP_TREES_NUM,TREES_NUM,28.93 -US-Ha1,18275,GRP_TREES_NUM,TREES_NUM_SPP,Prunus serotina -US-Ha1,18275,GRP_TREES_NUM,TREES_NUM_DATE,20061114 -US-Ha1,18275,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,18275,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,84.42 -US-Ha1,17453,GRP_TREES_NUM,TREES_NUM,35.06 -US-Ha1,17453,GRP_TREES_NUM,TREES_NUM_SPP,Betula alleghaniensis -US-Ha1,17453,GRP_TREES_NUM,TREES_NUM_DATE,1993 -US-Ha1,17453,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17453,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,55.81 -US-Ha1,17517,GRP_TREES_NUM,TREES_NUM,35.06 -US-Ha1,17517,GRP_TREES_NUM,TREES_NUM_SPP,Betula alleghaniensis -US-Ha1,17517,GRP_TREES_NUM,TREES_NUM_DATE,19981030 -US-Ha1,17517,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17517,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,55.81 -US-Ha1,17530,GRP_TREES_NUM,TREES_NUM,35.06 -US-Ha1,17530,GRP_TREES_NUM,TREES_NUM_SPP,Betula alleghaniensis -US-Ha1,17530,GRP_TREES_NUM,TREES_NUM_DATE,20061114 -US-Ha1,17530,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17530,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,55.81 -US-Ha1,17575,GRP_TREES_NUM,TREES_NUM,35.06 -US-Ha1,17575,GRP_TREES_NUM,TREES_NUM_SPP,Betula alleghaniensis -US-Ha1,17575,GRP_TREES_NUM,TREES_NUM_DATE,20071120 -US-Ha1,17575,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17575,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,55.81 -US-Ha1,17620,GRP_TREES_NUM,TREES_NUM,35.06 -US-Ha1,17620,GRP_TREES_NUM,TREES_NUM_SPP,Betula alleghaniensis -US-Ha1,17620,GRP_TREES_NUM,TREES_NUM_DATE,20081120 -US-Ha1,17620,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17620,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,55.81 -US-Ha1,17665,GRP_TREES_NUM,TREES_NUM,35.06 -US-Ha1,17665,GRP_TREES_NUM,TREES_NUM_SPP,Betula alleghaniensis -US-Ha1,17665,GRP_TREES_NUM,TREES_NUM_DATE,20091201 -US-Ha1,17665,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17665,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,55.81 -US-Ha1,17710,GRP_TREES_NUM,TREES_NUM,35.06 -US-Ha1,17710,GRP_TREES_NUM,TREES_NUM_SPP,Betula alleghaniensis -US-Ha1,17710,GRP_TREES_NUM,TREES_NUM_DATE,20101207 -US-Ha1,17710,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17710,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,55.81 -US-Ha1,17755,GRP_TREES_NUM,TREES_NUM,35.06 -US-Ha1,17755,GRP_TREES_NUM,TREES_NUM_SPP,Betula alleghaniensis -US-Ha1,17755,GRP_TREES_NUM,TREES_NUM_DATE,20111201 -US-Ha1,17755,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17755,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,55.81 -US-Ha1,17800,GRP_TREES_NUM,TREES_NUM,35.06 -US-Ha1,17800,GRP_TREES_NUM,TREES_NUM_SPP,Betula alleghaniensis -US-Ha1,17800,GRP_TREES_NUM,TREES_NUM_DATE,20121204 -US-Ha1,17800,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17800,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,55.81 -US-Ha1,17845,GRP_TREES_NUM,TREES_NUM,35.06 -US-Ha1,17845,GRP_TREES_NUM,TREES_NUM_SPP,Betula alleghaniensis -US-Ha1,17845,GRP_TREES_NUM,TREES_NUM_DATE,20131212 -US-Ha1,17845,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17845,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,55.81 -US-Ha1,17904,GRP_TREES_NUM,TREES_NUM,35.06 -US-Ha1,17904,GRP_TREES_NUM,TREES_NUM_SPP,Betula alleghaniensis -US-Ha1,17904,GRP_TREES_NUM,TREES_NUM_DATE,19991027 -US-Ha1,17904,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17904,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,55.81 -US-Ha1,17963,GRP_TREES_NUM,TREES_NUM,35.06 -US-Ha1,17963,GRP_TREES_NUM,TREES_NUM_SPP,Betula alleghaniensis -US-Ha1,17963,GRP_TREES_NUM,TREES_NUM_DATE,20001024 -US-Ha1,17963,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17963,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,55.81 -US-Ha1,18023,GRP_TREES_NUM,TREES_NUM,35.06 -US-Ha1,18023,GRP_TREES_NUM,TREES_NUM_SPP,Betula alleghaniensis -US-Ha1,18023,GRP_TREES_NUM,TREES_NUM_DATE,20011026 -US-Ha1,18023,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,18023,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,55.81 -US-Ha1,18083,GRP_TREES_NUM,TREES_NUM,35.06 -US-Ha1,18083,GRP_TREES_NUM,TREES_NUM_SPP,Betula alleghaniensis -US-Ha1,18083,GRP_TREES_NUM,TREES_NUM_DATE,20021114 -US-Ha1,18083,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,18083,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,55.81 -US-Ha1,18143,GRP_TREES_NUM,TREES_NUM,35.06 -US-Ha1,18143,GRP_TREES_NUM,TREES_NUM_SPP,Betula alleghaniensis -US-Ha1,18143,GRP_TREES_NUM,TREES_NUM_DATE,20031113 -US-Ha1,18143,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,18143,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,55.81 -US-Ha1,18203,GRP_TREES_NUM,TREES_NUM,35.06 -US-Ha1,18203,GRP_TREES_NUM,TREES_NUM_SPP,Betula alleghaniensis -US-Ha1,18203,GRP_TREES_NUM,TREES_NUM_DATE,20041103 -US-Ha1,18203,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,18203,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,55.81 -US-Ha1,18260,GRP_TREES_NUM,TREES_NUM,35.06 -US-Ha1,18260,GRP_TREES_NUM,TREES_NUM_SPP,Betula alleghaniensis -US-Ha1,18260,GRP_TREES_NUM,TREES_NUM_DATE,20051102 -US-Ha1,18260,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,18260,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,55.81 -US-Ha1,17387,GRP_TREES_NUM,TREES_NUM,35.69 -US-Ha1,17387,GRP_TREES_NUM,TREES_NUM_SPP,Quercus velutina -US-Ha1,17387,GRP_TREES_NUM,TREES_NUM_DATE,1993 -US-Ha1,17387,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17387,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,82.82 -US-Ha1,17473,GRP_TREES_NUM,TREES_NUM,35.69 -US-Ha1,17473,GRP_TREES_NUM,TREES_NUM_SPP,Quercus velutina -US-Ha1,17473,GRP_TREES_NUM,TREES_NUM_DATE,19981030 -US-Ha1,17473,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17473,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,82.82 -US-Ha1,17542,GRP_TREES_NUM,TREES_NUM,35.69 -US-Ha1,17542,GRP_TREES_NUM,TREES_NUM_SPP,Quercus velutina -US-Ha1,17542,GRP_TREES_NUM,TREES_NUM_DATE,20071120 -US-Ha1,17542,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17542,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,82.82 -US-Ha1,17587,GRP_TREES_NUM,TREES_NUM,35.69 -US-Ha1,17587,GRP_TREES_NUM,TREES_NUM_SPP,Quercus velutina -US-Ha1,17587,GRP_TREES_NUM,TREES_NUM_DATE,20081120 -US-Ha1,17587,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17587,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,82.82 -US-Ha1,17632,GRP_TREES_NUM,TREES_NUM,35.69 -US-Ha1,17632,GRP_TREES_NUM,TREES_NUM_SPP,Quercus velutina -US-Ha1,17632,GRP_TREES_NUM,TREES_NUM_DATE,20091201 -US-Ha1,17632,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17632,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,82.82 -US-Ha1,17677,GRP_TREES_NUM,TREES_NUM,35.69 -US-Ha1,17677,GRP_TREES_NUM,TREES_NUM_SPP,Quercus velutina -US-Ha1,17677,GRP_TREES_NUM,TREES_NUM_DATE,20101207 -US-Ha1,17677,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17677,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,82.82 -US-Ha1,17722,GRP_TREES_NUM,TREES_NUM,35.69 -US-Ha1,17722,GRP_TREES_NUM,TREES_NUM_SPP,Quercus velutina -US-Ha1,17722,GRP_TREES_NUM,TREES_NUM_DATE,20111201 -US-Ha1,17722,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17722,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,82.82 -US-Ha1,17767,GRP_TREES_NUM,TREES_NUM,35.69 -US-Ha1,17767,GRP_TREES_NUM,TREES_NUM_SPP,Quercus velutina -US-Ha1,17767,GRP_TREES_NUM,TREES_NUM_DATE,20121204 -US-Ha1,17767,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17767,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,82.82 -US-Ha1,17812,GRP_TREES_NUM,TREES_NUM,35.69 -US-Ha1,17812,GRP_TREES_NUM,TREES_NUM_SPP,Quercus velutina -US-Ha1,17812,GRP_TREES_NUM,TREES_NUM_DATE,20131212 -US-Ha1,17812,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17812,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,82.82 -US-Ha1,17860,GRP_TREES_NUM,TREES_NUM,35.69 -US-Ha1,17860,GRP_TREES_NUM,TREES_NUM_SPP,Quercus velutina -US-Ha1,17860,GRP_TREES_NUM,TREES_NUM_DATE,19991027 -US-Ha1,17860,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17860,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,82.82 -US-Ha1,17920,GRP_TREES_NUM,TREES_NUM,35.69 -US-Ha1,17920,GRP_TREES_NUM,TREES_NUM_SPP,Quercus velutina -US-Ha1,17920,GRP_TREES_NUM,TREES_NUM_DATE,20001024 -US-Ha1,17920,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17920,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,82.82 -US-Ha1,17979,GRP_TREES_NUM,TREES_NUM,35.69 -US-Ha1,17979,GRP_TREES_NUM,TREES_NUM_SPP,Quercus velutina -US-Ha1,17979,GRP_TREES_NUM,TREES_NUM_DATE,20011026 -US-Ha1,17979,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17979,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,82.82 -US-Ha1,18039,GRP_TREES_NUM,TREES_NUM,35.69 -US-Ha1,18039,GRP_TREES_NUM,TREES_NUM_SPP,Quercus velutina -US-Ha1,18039,GRP_TREES_NUM,TREES_NUM_DATE,20021114 -US-Ha1,18039,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,18039,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,82.82 -US-Ha1,18099,GRP_TREES_NUM,TREES_NUM,35.69 -US-Ha1,18099,GRP_TREES_NUM,TREES_NUM_SPP,Quercus velutina -US-Ha1,18099,GRP_TREES_NUM,TREES_NUM_DATE,20031113 -US-Ha1,18099,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,18099,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,82.82 -US-Ha1,18159,GRP_TREES_NUM,TREES_NUM,35.69 -US-Ha1,18159,GRP_TREES_NUM,TREES_NUM_SPP,Quercus velutina -US-Ha1,18159,GRP_TREES_NUM,TREES_NUM_DATE,20041103 -US-Ha1,18159,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,18159,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,82.82 -US-Ha1,18219,GRP_TREES_NUM,TREES_NUM,35.69 -US-Ha1,18219,GRP_TREES_NUM,TREES_NUM_SPP,Quercus velutina -US-Ha1,18219,GRP_TREES_NUM,TREES_NUM_DATE,20051102 -US-Ha1,18219,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,18219,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,82.82 -US-Ha1,18272,GRP_TREES_NUM,TREES_NUM,35.69 -US-Ha1,18272,GRP_TREES_NUM,TREES_NUM_SPP,Quercus velutina -US-Ha1,18272,GRP_TREES_NUM,TREES_NUM_DATE,20061114 -US-Ha1,18272,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,18272,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,82.82 -US-Ha1,17399,GRP_TREES_NUM,TREES_NUM,4.92 -US-Ha1,17399,GRP_TREES_NUM,TREES_NUM_SPP,Betula populifolia -US-Ha1,17399,GRP_TREES_NUM,TREES_NUM_DATE,1993 -US-Ha1,17399,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17399,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,24.02 -US-Ha1,17481,GRP_TREES_NUM,TREES_NUM,4.92 -US-Ha1,17481,GRP_TREES_NUM,TREES_NUM_SPP,Betula populifolia -US-Ha1,17481,GRP_TREES_NUM,TREES_NUM_DATE,19981030 -US-Ha1,17481,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17481,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,24.02 -US-Ha1,17548,GRP_TREES_NUM,TREES_NUM,4.92 -US-Ha1,17548,GRP_TREES_NUM,TREES_NUM_SPP,Betula populifolia -US-Ha1,17548,GRP_TREES_NUM,TREES_NUM_DATE,20071120 -US-Ha1,17548,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17548,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,24.02 -US-Ha1,17593,GRP_TREES_NUM,TREES_NUM,4.92 -US-Ha1,17593,GRP_TREES_NUM,TREES_NUM_SPP,Betula populifolia -US-Ha1,17593,GRP_TREES_NUM,TREES_NUM_DATE,20081120 -US-Ha1,17593,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17593,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,24.02 -US-Ha1,17638,GRP_TREES_NUM,TREES_NUM,4.92 -US-Ha1,17638,GRP_TREES_NUM,TREES_NUM_SPP,Betula populifolia -US-Ha1,17638,GRP_TREES_NUM,TREES_NUM_DATE,20091201 -US-Ha1,17638,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17638,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,24.02 -US-Ha1,17683,GRP_TREES_NUM,TREES_NUM,4.92 -US-Ha1,17683,GRP_TREES_NUM,TREES_NUM_SPP,Betula populifolia -US-Ha1,17683,GRP_TREES_NUM,TREES_NUM_DATE,20101207 -US-Ha1,17683,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17683,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,24.02 -US-Ha1,17728,GRP_TREES_NUM,TREES_NUM,4.92 -US-Ha1,17728,GRP_TREES_NUM,TREES_NUM_SPP,Betula populifolia -US-Ha1,17728,GRP_TREES_NUM,TREES_NUM_DATE,20111201 -US-Ha1,17728,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17728,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,24.02 -US-Ha1,17773,GRP_TREES_NUM,TREES_NUM,4.92 -US-Ha1,17773,GRP_TREES_NUM,TREES_NUM_SPP,Betula populifolia -US-Ha1,17773,GRP_TREES_NUM,TREES_NUM_DATE,20121204 -US-Ha1,17773,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17773,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,24.02 -US-Ha1,17818,GRP_TREES_NUM,TREES_NUM,4.92 -US-Ha1,17818,GRP_TREES_NUM,TREES_NUM_SPP,Betula populifolia -US-Ha1,17818,GRP_TREES_NUM,TREES_NUM_DATE,20131212 -US-Ha1,17818,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17818,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,24.02 -US-Ha1,17868,GRP_TREES_NUM,TREES_NUM,4.92 -US-Ha1,17868,GRP_TREES_NUM,TREES_NUM_SPP,Betula populifolia -US-Ha1,17868,GRP_TREES_NUM,TREES_NUM_DATE,19991027 -US-Ha1,17868,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17868,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,24.02 -US-Ha1,17928,GRP_TREES_NUM,TREES_NUM,4.92 -US-Ha1,17928,GRP_TREES_NUM,TREES_NUM_SPP,Betula populifolia -US-Ha1,17928,GRP_TREES_NUM,TREES_NUM_DATE,20001024 -US-Ha1,17928,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17928,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,24.02 -US-Ha1,17987,GRP_TREES_NUM,TREES_NUM,4.92 -US-Ha1,17987,GRP_TREES_NUM,TREES_NUM_SPP,Betula populifolia -US-Ha1,17987,GRP_TREES_NUM,TREES_NUM_DATE,20011026 -US-Ha1,17987,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17987,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,24.02 -US-Ha1,18047,GRP_TREES_NUM,TREES_NUM,4.92 -US-Ha1,18047,GRP_TREES_NUM,TREES_NUM_SPP,Betula populifolia -US-Ha1,18047,GRP_TREES_NUM,TREES_NUM_DATE,20021114 -US-Ha1,18047,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,18047,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,24.02 -US-Ha1,18107,GRP_TREES_NUM,TREES_NUM,4.92 -US-Ha1,18107,GRP_TREES_NUM,TREES_NUM_SPP,Betula populifolia -US-Ha1,18107,GRP_TREES_NUM,TREES_NUM_DATE,20031113 -US-Ha1,18107,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,18107,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,24.02 -US-Ha1,18167,GRP_TREES_NUM,TREES_NUM,4.92 -US-Ha1,18167,GRP_TREES_NUM,TREES_NUM_SPP,Betula populifolia -US-Ha1,18167,GRP_TREES_NUM,TREES_NUM_DATE,20041103 -US-Ha1,18167,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,18167,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,24.02 -US-Ha1,18227,GRP_TREES_NUM,TREES_NUM,4.92 -US-Ha1,18227,GRP_TREES_NUM,TREES_NUM_SPP,Betula populifolia -US-Ha1,18227,GRP_TREES_NUM,TREES_NUM_DATE,20051102 -US-Ha1,18227,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,18227,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,24.02 -US-Ha1,18278,GRP_TREES_NUM,TREES_NUM,4.92 -US-Ha1,18278,GRP_TREES_NUM,TREES_NUM_SPP,Betula populifolia -US-Ha1,18278,GRP_TREES_NUM,TREES_NUM_DATE,20061114 -US-Ha1,18278,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,18278,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,24.02 -US-Ha1,17417,GRP_TREES_NUM,TREES_NUM,467.82 -US-Ha1,17417,GRP_TREES_NUM,TREES_NUM_SPP,Quercus rubra -US-Ha1,17417,GRP_TREES_NUM,TREES_NUM_DATE,1993 -US-Ha1,17417,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17417,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,353.57 -US-Ha1,17493,GRP_TREES_NUM,TREES_NUM,467.82 -US-Ha1,17493,GRP_TREES_NUM,TREES_NUM_SPP,Quercus rubra -US-Ha1,17493,GRP_TREES_NUM,TREES_NUM_DATE,19981030 -US-Ha1,17493,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17493,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,353.57 -US-Ha1,17557,GRP_TREES_NUM,TREES_NUM,467.82 -US-Ha1,17557,GRP_TREES_NUM,TREES_NUM_SPP,Quercus rubra -US-Ha1,17557,GRP_TREES_NUM,TREES_NUM_DATE,20071120 -US-Ha1,17557,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17557,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,353.57 -US-Ha1,17602,GRP_TREES_NUM,TREES_NUM,467.82 -US-Ha1,17602,GRP_TREES_NUM,TREES_NUM_SPP,Quercus rubra -US-Ha1,17602,GRP_TREES_NUM,TREES_NUM_DATE,20081120 -US-Ha1,17602,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17602,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,353.57 -US-Ha1,17647,GRP_TREES_NUM,TREES_NUM,467.82 -US-Ha1,17647,GRP_TREES_NUM,TREES_NUM_SPP,Quercus rubra -US-Ha1,17647,GRP_TREES_NUM,TREES_NUM_DATE,20091201 -US-Ha1,17647,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17647,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,353.57 -US-Ha1,17692,GRP_TREES_NUM,TREES_NUM,467.82 -US-Ha1,17692,GRP_TREES_NUM,TREES_NUM_SPP,Quercus rubra -US-Ha1,17692,GRP_TREES_NUM,TREES_NUM_DATE,20101207 -US-Ha1,17692,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17692,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,353.57 -US-Ha1,17737,GRP_TREES_NUM,TREES_NUM,467.82 -US-Ha1,17737,GRP_TREES_NUM,TREES_NUM_SPP,Quercus rubra -US-Ha1,17737,GRP_TREES_NUM,TREES_NUM_DATE,20111201 -US-Ha1,17737,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17737,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,353.57 -US-Ha1,17782,GRP_TREES_NUM,TREES_NUM,467.82 -US-Ha1,17782,GRP_TREES_NUM,TREES_NUM_SPP,Quercus rubra -US-Ha1,17782,GRP_TREES_NUM,TREES_NUM_DATE,20121204 -US-Ha1,17782,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17782,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,353.57 -US-Ha1,17827,GRP_TREES_NUM,TREES_NUM,467.82 -US-Ha1,17827,GRP_TREES_NUM,TREES_NUM_SPP,Quercus rubra -US-Ha1,17827,GRP_TREES_NUM,TREES_NUM_DATE,20131212 -US-Ha1,17827,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17827,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,353.57 -US-Ha1,17880,GRP_TREES_NUM,TREES_NUM,467.82 -US-Ha1,17880,GRP_TREES_NUM,TREES_NUM_SPP,Quercus rubra -US-Ha1,17880,GRP_TREES_NUM,TREES_NUM_DATE,19991027 -US-Ha1,17880,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17880,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,353.57 -US-Ha1,17940,GRP_TREES_NUM,TREES_NUM,467.82 -US-Ha1,17940,GRP_TREES_NUM,TREES_NUM_SPP,Quercus rubra -US-Ha1,17940,GRP_TREES_NUM,TREES_NUM_DATE,20001024 -US-Ha1,17940,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17940,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,353.57 -US-Ha1,17999,GRP_TREES_NUM,TREES_NUM,467.82 -US-Ha1,17999,GRP_TREES_NUM,TREES_NUM_SPP,Quercus rubra -US-Ha1,17999,GRP_TREES_NUM,TREES_NUM_DATE,20011026 -US-Ha1,17999,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17999,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,353.57 -US-Ha1,18059,GRP_TREES_NUM,TREES_NUM,467.82 -US-Ha1,18059,GRP_TREES_NUM,TREES_NUM_SPP,Quercus rubra -US-Ha1,18059,GRP_TREES_NUM,TREES_NUM_DATE,20021114 -US-Ha1,18059,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,18059,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,353.57 -US-Ha1,18119,GRP_TREES_NUM,TREES_NUM,467.82 -US-Ha1,18119,GRP_TREES_NUM,TREES_NUM_SPP,Quercus rubra -US-Ha1,18119,GRP_TREES_NUM,TREES_NUM_DATE,20031113 -US-Ha1,18119,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,18119,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,353.57 -US-Ha1,18179,GRP_TREES_NUM,TREES_NUM,467.82 -US-Ha1,18179,GRP_TREES_NUM,TREES_NUM_SPP,Quercus rubra -US-Ha1,18179,GRP_TREES_NUM,TREES_NUM_DATE,20041103 -US-Ha1,18179,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,18179,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,353.57 -US-Ha1,18239,GRP_TREES_NUM,TREES_NUM,467.82 -US-Ha1,18239,GRP_TREES_NUM,TREES_NUM_SPP,Quercus rubra -US-Ha1,18239,GRP_TREES_NUM,TREES_NUM_DATE,20051102 -US-Ha1,18239,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,18239,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,353.57 -US-Ha1,18287,GRP_TREES_NUM,TREES_NUM,467.82 -US-Ha1,18287,GRP_TREES_NUM,TREES_NUM_SPP,Quercus rubra -US-Ha1,18287,GRP_TREES_NUM,TREES_NUM_DATE,20061114 -US-Ha1,18287,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,18287,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,353.57 -US-Ha1,17435,GRP_TREES_NUM,TREES_NUM,5.88 -US-Ha1,17435,GRP_TREES_NUM,TREES_NUM_SPP,Betula papyrifera -US-Ha1,17435,GRP_TREES_NUM,TREES_NUM_DATE,1993 -US-Ha1,17435,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17435,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,23.88 -US-Ha1,17505,GRP_TREES_NUM,TREES_NUM,5.88 -US-Ha1,17505,GRP_TREES_NUM,TREES_NUM_SPP,Betula papyrifera -US-Ha1,17505,GRP_TREES_NUM,TREES_NUM_DATE,19981030 -US-Ha1,17505,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17505,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,23.88 -US-Ha1,17521,GRP_TREES_NUM,TREES_NUM,5.88 -US-Ha1,17521,GRP_TREES_NUM,TREES_NUM_SPP,Betula papyrifera -US-Ha1,17521,GRP_TREES_NUM,TREES_NUM_DATE,20061114 -US-Ha1,17521,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17521,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,23.88 -US-Ha1,17566,GRP_TREES_NUM,TREES_NUM,5.88 -US-Ha1,17566,GRP_TREES_NUM,TREES_NUM_SPP,Betula papyrifera -US-Ha1,17566,GRP_TREES_NUM,TREES_NUM_DATE,20071120 -US-Ha1,17566,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17566,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,23.88 -US-Ha1,17611,GRP_TREES_NUM,TREES_NUM,5.88 -US-Ha1,17611,GRP_TREES_NUM,TREES_NUM_SPP,Betula papyrifera -US-Ha1,17611,GRP_TREES_NUM,TREES_NUM_DATE,20081120 -US-Ha1,17611,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17611,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,23.88 -US-Ha1,17656,GRP_TREES_NUM,TREES_NUM,5.88 -US-Ha1,17656,GRP_TREES_NUM,TREES_NUM_SPP,Betula papyrifera -US-Ha1,17656,GRP_TREES_NUM,TREES_NUM_DATE,20091201 -US-Ha1,17656,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17656,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,23.88 -US-Ha1,17701,GRP_TREES_NUM,TREES_NUM,5.88 -US-Ha1,17701,GRP_TREES_NUM,TREES_NUM_SPP,Betula papyrifera -US-Ha1,17701,GRP_TREES_NUM,TREES_NUM_DATE,20101207 -US-Ha1,17701,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17701,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,23.88 -US-Ha1,17746,GRP_TREES_NUM,TREES_NUM,5.88 -US-Ha1,17746,GRP_TREES_NUM,TREES_NUM_SPP,Betula papyrifera -US-Ha1,17746,GRP_TREES_NUM,TREES_NUM_DATE,20111201 -US-Ha1,17746,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17746,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,23.88 -US-Ha1,17791,GRP_TREES_NUM,TREES_NUM,5.88 -US-Ha1,17791,GRP_TREES_NUM,TREES_NUM_SPP,Betula papyrifera -US-Ha1,17791,GRP_TREES_NUM,TREES_NUM_DATE,20121204 -US-Ha1,17791,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17791,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,23.88 -US-Ha1,17836,GRP_TREES_NUM,TREES_NUM,5.88 -US-Ha1,17836,GRP_TREES_NUM,TREES_NUM_SPP,Betula papyrifera -US-Ha1,17836,GRP_TREES_NUM,TREES_NUM_DATE,20131212 -US-Ha1,17836,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17836,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,23.88 -US-Ha1,17892,GRP_TREES_NUM,TREES_NUM,5.88 -US-Ha1,17892,GRP_TREES_NUM,TREES_NUM_SPP,Betula papyrifera -US-Ha1,17892,GRP_TREES_NUM,TREES_NUM_DATE,19991027 -US-Ha1,17892,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17892,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,23.88 -US-Ha1,17952,GRP_TREES_NUM,TREES_NUM,5.88 -US-Ha1,17952,GRP_TREES_NUM,TREES_NUM_SPP,Betula papyrifera -US-Ha1,17952,GRP_TREES_NUM,TREES_NUM_DATE,20001024 -US-Ha1,17952,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17952,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,23.88 -US-Ha1,18011,GRP_TREES_NUM,TREES_NUM,5.88 -US-Ha1,18011,GRP_TREES_NUM,TREES_NUM_SPP,Betula papyrifera -US-Ha1,18011,GRP_TREES_NUM,TREES_NUM_DATE,20011026 -US-Ha1,18011,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,18011,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,23.88 -US-Ha1,18071,GRP_TREES_NUM,TREES_NUM,5.88 -US-Ha1,18071,GRP_TREES_NUM,TREES_NUM_SPP,Betula papyrifera -US-Ha1,18071,GRP_TREES_NUM,TREES_NUM_DATE,20021114 -US-Ha1,18071,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,18071,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,23.88 -US-Ha1,18131,GRP_TREES_NUM,TREES_NUM,5.88 -US-Ha1,18131,GRP_TREES_NUM,TREES_NUM_SPP,Betula papyrifera -US-Ha1,18131,GRP_TREES_NUM,TREES_NUM_DATE,20031113 -US-Ha1,18131,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,18131,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,23.88 -US-Ha1,18191,GRP_TREES_NUM,TREES_NUM,5.88 -US-Ha1,18191,GRP_TREES_NUM,TREES_NUM_SPP,Betula papyrifera -US-Ha1,18191,GRP_TREES_NUM,TREES_NUM_DATE,20041103 -US-Ha1,18191,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,18191,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,23.88 -US-Ha1,18251,GRP_TREES_NUM,TREES_NUM,5.88 -US-Ha1,18251,GRP_TREES_NUM,TREES_NUM_SPP,Betula papyrifera -US-Ha1,18251,GRP_TREES_NUM,TREES_NUM_DATE,20051102 -US-Ha1,18251,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,18251,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,23.88 -US-Ha1,17441,GRP_TREES_NUM,TREES_NUM,73.85 -US-Ha1,17441,GRP_TREES_NUM,TREES_NUM_SPP,Pinus strobus -US-Ha1,17441,GRP_TREES_NUM,TREES_NUM_DATE,1993 -US-Ha1,17441,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17441,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,155.41 -US-Ha1,17509,GRP_TREES_NUM,TREES_NUM,73.85 -US-Ha1,17509,GRP_TREES_NUM,TREES_NUM_SPP,Pinus strobus -US-Ha1,17509,GRP_TREES_NUM,TREES_NUM_DATE,19981030 -US-Ha1,17509,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17509,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,155.41 -US-Ha1,17524,GRP_TREES_NUM,TREES_NUM,73.85 -US-Ha1,17524,GRP_TREES_NUM,TREES_NUM_SPP,Pinus strobus -US-Ha1,17524,GRP_TREES_NUM,TREES_NUM_DATE,20061114 -US-Ha1,17524,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17524,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,155.41 -US-Ha1,17569,GRP_TREES_NUM,TREES_NUM,73.85 -US-Ha1,17569,GRP_TREES_NUM,TREES_NUM_SPP,Pinus strobus -US-Ha1,17569,GRP_TREES_NUM,TREES_NUM_DATE,20071120 -US-Ha1,17569,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17569,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,155.41 -US-Ha1,17614,GRP_TREES_NUM,TREES_NUM,73.85 -US-Ha1,17614,GRP_TREES_NUM,TREES_NUM_SPP,Pinus strobus -US-Ha1,17614,GRP_TREES_NUM,TREES_NUM_DATE,20081120 -US-Ha1,17614,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17614,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,155.41 -US-Ha1,17659,GRP_TREES_NUM,TREES_NUM,73.85 -US-Ha1,17659,GRP_TREES_NUM,TREES_NUM_SPP,Pinus strobus -US-Ha1,17659,GRP_TREES_NUM,TREES_NUM_DATE,20091201 -US-Ha1,17659,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17659,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,155.41 -US-Ha1,17704,GRP_TREES_NUM,TREES_NUM,73.85 -US-Ha1,17704,GRP_TREES_NUM,TREES_NUM_SPP,Pinus strobus -US-Ha1,17704,GRP_TREES_NUM,TREES_NUM_DATE,20101207 -US-Ha1,17704,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17704,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,155.41 -US-Ha1,17749,GRP_TREES_NUM,TREES_NUM,73.85 -US-Ha1,17749,GRP_TREES_NUM,TREES_NUM_SPP,Pinus strobus -US-Ha1,17749,GRP_TREES_NUM,TREES_NUM_DATE,20111201 -US-Ha1,17749,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17749,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,155.41 -US-Ha1,17794,GRP_TREES_NUM,TREES_NUM,73.85 -US-Ha1,17794,GRP_TREES_NUM,TREES_NUM_SPP,Pinus strobus -US-Ha1,17794,GRP_TREES_NUM,TREES_NUM_DATE,20121204 -US-Ha1,17794,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17794,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,155.41 -US-Ha1,17839,GRP_TREES_NUM,TREES_NUM,73.85 -US-Ha1,17839,GRP_TREES_NUM,TREES_NUM_SPP,Pinus strobus -US-Ha1,17839,GRP_TREES_NUM,TREES_NUM_DATE,20131212 -US-Ha1,17839,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17839,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,155.41 -US-Ha1,17896,GRP_TREES_NUM,TREES_NUM,73.85 -US-Ha1,17896,GRP_TREES_NUM,TREES_NUM_SPP,Pinus strobus -US-Ha1,17896,GRP_TREES_NUM,TREES_NUM_DATE,19991027 -US-Ha1,17896,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17896,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,155.41 -US-Ha1,17955,GRP_TREES_NUM,TREES_NUM,73.85 -US-Ha1,17955,GRP_TREES_NUM,TREES_NUM_SPP,Pinus strobus -US-Ha1,17955,GRP_TREES_NUM,TREES_NUM_DATE,20001024 -US-Ha1,17955,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17955,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,155.41 -US-Ha1,18015,GRP_TREES_NUM,TREES_NUM,73.85 -US-Ha1,18015,GRP_TREES_NUM,TREES_NUM_SPP,Pinus strobus -US-Ha1,18015,GRP_TREES_NUM,TREES_NUM_DATE,20011026 -US-Ha1,18015,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,18015,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,155.41 -US-Ha1,18075,GRP_TREES_NUM,TREES_NUM,73.85 -US-Ha1,18075,GRP_TREES_NUM,TREES_NUM_SPP,Pinus strobus -US-Ha1,18075,GRP_TREES_NUM,TREES_NUM_DATE,20021114 -US-Ha1,18075,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,18075,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,155.41 -US-Ha1,18135,GRP_TREES_NUM,TREES_NUM,73.85 -US-Ha1,18135,GRP_TREES_NUM,TREES_NUM_SPP,Pinus strobus -US-Ha1,18135,GRP_TREES_NUM,TREES_NUM_DATE,20031113 -US-Ha1,18135,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,18135,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,155.41 -US-Ha1,18195,GRP_TREES_NUM,TREES_NUM,73.85 -US-Ha1,18195,GRP_TREES_NUM,TREES_NUM_SPP,Pinus strobus -US-Ha1,18195,GRP_TREES_NUM,TREES_NUM_DATE,20041103 -US-Ha1,18195,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,18195,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,155.41 -US-Ha1,18254,GRP_TREES_NUM,TREES_NUM,73.85 -US-Ha1,18254,GRP_TREES_NUM,TREES_NUM_SPP,Pinus strobus -US-Ha1,18254,GRP_TREES_NUM,TREES_NUM_DATE,20051102 -US-Ha1,18254,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,18254,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,155.41 -US-Ha1,17423,GRP_TREES_NUM,TREES_NUM,89.7 -US-Ha1,17423,GRP_TREES_NUM,TREES_NUM_SPP,Pinus resinosa -US-Ha1,17423,GRP_TREES_NUM,TREES_NUM_DATE,1993 -US-Ha1,17423,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17423,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,305.36 -US-Ha1,17497,GRP_TREES_NUM,TREES_NUM,89.7 -US-Ha1,17497,GRP_TREES_NUM,TREES_NUM_SPP,Pinus resinosa -US-Ha1,17497,GRP_TREES_NUM,TREES_NUM_DATE,19981030 -US-Ha1,17497,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17497,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,305.36 -US-Ha1,17560,GRP_TREES_NUM,TREES_NUM,89.7 -US-Ha1,17560,GRP_TREES_NUM,TREES_NUM_SPP,Pinus resinosa -US-Ha1,17560,GRP_TREES_NUM,TREES_NUM_DATE,20071120 -US-Ha1,17560,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17560,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,305.36 -US-Ha1,17605,GRP_TREES_NUM,TREES_NUM,89.7 -US-Ha1,17605,GRP_TREES_NUM,TREES_NUM_SPP,Pinus resinosa -US-Ha1,17605,GRP_TREES_NUM,TREES_NUM_DATE,20081120 -US-Ha1,17605,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17605,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,305.36 -US-Ha1,17650,GRP_TREES_NUM,TREES_NUM,89.7 -US-Ha1,17650,GRP_TREES_NUM,TREES_NUM_SPP,Pinus resinosa -US-Ha1,17650,GRP_TREES_NUM,TREES_NUM_DATE,20091201 -US-Ha1,17650,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17650,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,305.36 -US-Ha1,17695,GRP_TREES_NUM,TREES_NUM,89.7 -US-Ha1,17695,GRP_TREES_NUM,TREES_NUM_SPP,Pinus resinosa -US-Ha1,17695,GRP_TREES_NUM,TREES_NUM_DATE,20101207 -US-Ha1,17695,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17695,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,305.36 -US-Ha1,17740,GRP_TREES_NUM,TREES_NUM,89.7 -US-Ha1,17740,GRP_TREES_NUM,TREES_NUM_SPP,Pinus resinosa -US-Ha1,17740,GRP_TREES_NUM,TREES_NUM_DATE,20111201 -US-Ha1,17740,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17740,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,305.36 -US-Ha1,17785,GRP_TREES_NUM,TREES_NUM,89.7 -US-Ha1,17785,GRP_TREES_NUM,TREES_NUM_SPP,Pinus resinosa -US-Ha1,17785,GRP_TREES_NUM,TREES_NUM_DATE,20121204 -US-Ha1,17785,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17785,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,305.36 -US-Ha1,17830,GRP_TREES_NUM,TREES_NUM,89.7 -US-Ha1,17830,GRP_TREES_NUM,TREES_NUM_SPP,Pinus resinosa -US-Ha1,17830,GRP_TREES_NUM,TREES_NUM_DATE,20131212 -US-Ha1,17830,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17830,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,305.36 -US-Ha1,17884,GRP_TREES_NUM,TREES_NUM,89.7 -US-Ha1,17884,GRP_TREES_NUM,TREES_NUM_SPP,Pinus resinosa -US-Ha1,17884,GRP_TREES_NUM,TREES_NUM_DATE,19991027 -US-Ha1,17884,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17884,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,305.36 -US-Ha1,17944,GRP_TREES_NUM,TREES_NUM,89.7 -US-Ha1,17944,GRP_TREES_NUM,TREES_NUM_SPP,Pinus resinosa -US-Ha1,17944,GRP_TREES_NUM,TREES_NUM_DATE,20001024 -US-Ha1,17944,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,17944,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,305.36 -US-Ha1,18003,GRP_TREES_NUM,TREES_NUM,89.7 -US-Ha1,18003,GRP_TREES_NUM,TREES_NUM_SPP,Pinus resinosa -US-Ha1,18003,GRP_TREES_NUM,TREES_NUM_DATE,20011026 -US-Ha1,18003,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,18003,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,305.36 -US-Ha1,18063,GRP_TREES_NUM,TREES_NUM,89.7 -US-Ha1,18063,GRP_TREES_NUM,TREES_NUM_SPP,Pinus resinosa -US-Ha1,18063,GRP_TREES_NUM,TREES_NUM_DATE,20021114 -US-Ha1,18063,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,18063,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,305.36 -US-Ha1,18123,GRP_TREES_NUM,TREES_NUM,89.7 -US-Ha1,18123,GRP_TREES_NUM,TREES_NUM_SPP,Pinus resinosa -US-Ha1,18123,GRP_TREES_NUM,TREES_NUM_DATE,20031113 -US-Ha1,18123,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,18123,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,305.36 -US-Ha1,18183,GRP_TREES_NUM,TREES_NUM,89.7 -US-Ha1,18183,GRP_TREES_NUM,TREES_NUM_SPP,Pinus resinosa -US-Ha1,18183,GRP_TREES_NUM,TREES_NUM_DATE,20041103 -US-Ha1,18183,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,18183,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,305.36 -US-Ha1,18243,GRP_TREES_NUM,TREES_NUM,89.7 -US-Ha1,18243,GRP_TREES_NUM,TREES_NUM_SPP,Pinus resinosa -US-Ha1,18243,GRP_TREES_NUM,TREES_NUM_DATE,20051102 -US-Ha1,18243,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,18243,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,305.36 -US-Ha1,18290,GRP_TREES_NUM,TREES_NUM,89.7 -US-Ha1,18290,GRP_TREES_NUM,TREES_NUM_SPP,Pinus resinosa -US-Ha1,18290,GRP_TREES_NUM,TREES_NUM_DATE,20061114 -US-Ha1,18290,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,34 -US-Ha1,18290,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,305.36 -US-Ha1,11972,GRP_URL,URL,http://atmos.seas.harvard.edu/lab/hf/index.html -US-Ha1,24000371,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-Ha1 -US-Ha1,11973,GRP_UTC_OFFSET,UTC_OFFSET,-5 -US-Ha1,17304,GRP_WD_BIOMASS,WD_BIOMASS_CRS,521 -US-Ha1,17316,GRP_WD_BIOMASS,WD_BIOMASS_CRS,584 -US-Ha1,17322,GRP_WD_BIOMASS,WD_BIOMASS_CRS,649 -US-Ha1,17326,GRP_WD_BIOMASS,WD_BIOMASS_CRS,843 -US-Ha1,17304,GRP_WD_BIOMASS,WD_BIOMASS_CRS_SPATIAL_VARIABILITY,345 -US-Ha1,17322,GRP_WD_BIOMASS,WD_BIOMASS_CRS_SPATIAL_VARIABILITY,428 -US-Ha1,17316,GRP_WD_BIOMASS,WD_BIOMASS_CRS_SPATIAL_VARIABILITY,478 -US-Ha1,17326,GRP_WD_BIOMASS,WD_BIOMASS_CRS_SPATIAL_VARIABILITY,572 -US-Ha1,17316,GRP_WD_BIOMASS,WD_BIOMASS_CRS_SPATIAL_REP_NUMBER,15 -US-Ha1,17304,GRP_WD_BIOMASS,WD_BIOMASS_CRS_SPATIAL_REP_NUMBER,24 -US-Ha1,17322,GRP_WD_BIOMASS,WD_BIOMASS_CRS_SPATIAL_REP_NUMBER,33 -US-Ha1,17326,GRP_WD_BIOMASS,WD_BIOMASS_CRS_SPATIAL_REP_NUMBER,33 -US-Ha1,17310,GRP_WD_BIOMASS,WD_BIOMASS_FINE,105 -US-Ha1,17322,GRP_WD_BIOMASS,WD_BIOMASS_FINE,162 -US-Ha1,17326,GRP_WD_BIOMASS,WD_BIOMASS_FINE,167 -US-Ha1,17316,GRP_WD_BIOMASS,WD_BIOMASS_FINE,173 -US-Ha1,17322,GRP_WD_BIOMASS,WD_BIOMASS_FINE_SPATIAL_VARIABILITY,113 -US-Ha1,17316,GRP_WD_BIOMASS,WD_BIOMASS_FINE_SPATIAL_VARIABILITY,122 -US-Ha1,17326,GRP_WD_BIOMASS,WD_BIOMASS_FINE_SPATIAL_VARIABILITY,127 -US-Ha1,17310,GRP_WD_BIOMASS,WD_BIOMASS_FINE_SPATIAL_VARIABILITY,96 -US-Ha1,17310,GRP_WD_BIOMASS,WD_BIOMASS_FINE_SPATIAL_REP_NUMBER,26 -US-Ha1,17322,GRP_WD_BIOMASS,WD_BIOMASS_FINE_SPATIAL_REP_NUMBER,30 -US-Ha1,17326,GRP_WD_BIOMASS,WD_BIOMASS_FINE_SPATIAL_REP_NUMBER,30 -US-Ha1,17316,GRP_WD_BIOMASS,WD_BIOMASS_FINE_SPATIAL_REP_NUMBER,40 -US-Ha1,17304,GRP_WD_BIOMASS,WD_BIOMASS_UNIT,gC m-2 -US-Ha1,17310,GRP_WD_BIOMASS,WD_BIOMASS_UNIT,gC m-2 -US-Ha1,17316,GRP_WD_BIOMASS,WD_BIOMASS_UNIT,gC m-2 -US-Ha1,17322,GRP_WD_BIOMASS,WD_BIOMASS_UNIT,gC m-2 -US-Ha1,17326,GRP_WD_BIOMASS,WD_BIOMASS_UNIT,gC m-2 -US-Ha1,17304,GRP_WD_BIOMASS,WD_BIOMASS_APPROACH,"CWD is all pieces of dead wood >7.5cm in diameter, measured length and diamter at ends and middle, scaled to volume using Newton's formula, and then scaled to biomass using decay class specific densities from Liu et al. 2006. FWD Includes debris with diameter 2-7.5 cm diameter. Line transect method. Raw data and data descriptions are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data" -US-Ha1,17310,GRP_WD_BIOMASS,WD_BIOMASS_APPROACH,"CWD is all pieces of dead wood >7.5cm in diameter, measured length and diamter at ends and middle, scaled to volume using Newton's formula, and then scaled to biomass using decay class specific densities from Liu et al. 2006. FWD Includes debris with diameter 2-7.5 cm diameter. Line transect method. Raw data and data descriptions are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data" -US-Ha1,17316,GRP_WD_BIOMASS,WD_BIOMASS_APPROACH,"CWD is all pieces of dead wood >7.5cm in diameter, measured length and diamter at ends and middle, scaled to volume using Newton's formula, and then scaled to biomass using decay class specific densities from Liu et al. 2006. FWD Includes debris with diameter 2-7.5 cm diameter. Line transect method. Raw data and data descriptions are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data" -US-Ha1,17322,GRP_WD_BIOMASS,WD_BIOMASS_APPROACH,"CWD is all pieces of dead wood >7.5cm in diameter, measured length and diamter at ends and middle, scaled to volume using Newton's formula, and then scaled to biomass using decay class specific densities from Liu et al. 2006. FWD Includes debris with diameter 2-7.5 cm diameter. Line transect method. Raw data and data descriptions are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data" -US-Ha1,17326,GRP_WD_BIOMASS,WD_BIOMASS_APPROACH,"CWD is all pieces of dead wood >7.5cm in diameter, measured length and diamter at ends and middle, scaled to volume using Newton's formula, and then scaled to biomass using decay class specific densities from Liu et al. 2006. FWD Includes debris with diameter 2-7.5 cm diameter. Line transect method. Raw data and data descriptions are located at ftp.as.harvard.edu/pub/nigec/HU_Wofsy/hf_data/ecological_data" -US-Ha1,17304,GRP_WD_BIOMASS,WD_BIOMASS_DATE,2000 -US-Ha1,17310,GRP_WD_BIOMASS,WD_BIOMASS_DATE,2001 -US-Ha1,17316,GRP_WD_BIOMASS,WD_BIOMASS_DATE,2003 -US-Ha1,17322,GRP_WD_BIOMASS,WD_BIOMASS_DATE,2006 -US-Ha1,17326,GRP_WD_BIOMASS,WD_BIOMASS_DATE,2009 -US-Ha2,79381,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,"Operation of the US-Ha2 site is supported by the AmeriFlux Management Project with funding by the U.S. Department of Energy’s Office of Science under Contract No. DE-AC02-05CH11231, and additionally is a part of the Harvard Forest LTER site supported by the National Science Foundation (DEB-1237491)." -US-Ha2,23633,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER,26 -US-Ha2,23633,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_ORGAN,Total -US-Ha2,23633,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_PHEN,Mixed/unknown -US-Ha2,23633,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_UNIT,kgDM m-2 -US-Ha2,23633,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_COMMENT,"Total organic matter (not C alone) -" -US-Ha2,24410,GRP_BIOMASS_CHEM,BIOMASS_N,0.1425 -US-Ha2,24410,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-Ha2,24410,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-Ha2,24410,GRP_BIOMASS_CHEM,BIOMASS_SPP,(All) -US-Ha2,24410,GRP_BIOMASS_CHEM,BIOMASS_COMMENT,(range 1.18-1.67) (g kg-1) 14.1-16.7 Mature first year foliage measured September 1997 11.8-13.5 1 year old foliage measured September 1997 -US-Ha2,12584,GRP_CLIM_AVG,MAT,6.56 -US-Ha2,12584,GRP_CLIM_AVG,MAP,1071 -US-Ha2,12584,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfb -US-Ha2,27000372,GRP_COUNTRY,COUNTRY,USA -US-Ha2,15703,GRP_DOI,DOI,10.17190/AMF/1246060 -US-Ha2,15703,GRP_DOI,DOI_CITATION,"Julian Hadley, J. William Munger (2022), AmeriFlux BASE US-Ha2 Harvard Forest Hemlock Site, Ver. 7-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1246060" -US-Ha2,15703,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-Ha2,91352,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Ha2,91352,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Julian Hadley -US-Ha2,91352,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Ha2,91352,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,2 -US-Ha2,91352,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Harvard University -US-Ha2,91352,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,2000 -US-Ha2,91352,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_END,2014 -US-Ha2,91360,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Ha2,91360,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,J. William Munger -US-Ha2,91360,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Ha2,91360,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0002-1042-8452 -US-Ha2,91360,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,jwmunger@seas.harvard.edu -US-Ha2,91360,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Harvard University -US-Ha2,91360,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,2014 -US-Ha2,32066,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Harvard University -US-Ha2,32066,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-Ha2,32065,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,"DOE/TCP, NSF" -US-Ha2,32065,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-Ha2,12585,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Pests and disease -US-Ha2,91391,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Ha2,91391,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-Ha2,91391,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20040618 -US-Ha2,91391,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Ha2,91391,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,"In 2014 we began running two flux systems in parallel in preparation for moving of the Flux system to a new Rohn 45G tower. The new tower is 34 meters tall, adjacent to the existing scaffold tower. -Data collection from sensors attached to the original scaffolding tower was discontinued after April 9 2018, and is sporadic during the preceding month" -US-Ha2,91323,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Ha2,91323,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-Ha2,91323,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20040618 -US-Ha2,91323,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Ha2,91323,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,"In 2014 we began running two flux systems in parallel in preparation for moving of the Flux system to a new Rohn 45G tower. The new tower is 34 meters tall, adjacent to the existing scaffold tower. Data collection from sensors attached to the original scaffolding tower was discontinued after April 9 2018, and is sporadic during the preceding month" -US-Ha2,91431,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Ha2,91431,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-Ha2,91431,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20040618 -US-Ha2,91431,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Ha2,91431,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,"In 2014 we began running two flux systems in parallel in preparation for moving of the Flux system to a new Rohn 45G tower. The new tower is 34 meters tall, adjacent to the existing scaffold tower. Data collection from sensors attached to the original scaffolding tower was discontinued after April 9 2018, and is sporadic during the preceding month" -US-Ha2,23000372,GRP_HEADER,SITE_NAME,Harvard Forest Hemlock Site -US-Ha2,24528,GRP_HEIGHTC,HEIGHTC,21 -US-Ha2,12587,GRP_IGBP,IGBP,ENF -US-Ha2,24017,GRP_LAI,LAI_TYPE,LAI -US-Ha2,24017,GRP_LAI,LAI_TOT,4.4 -US-Ha2,23771,GRP_LMA,LMA,131 -US-Ha2,23771,GRP_LMA,LMA_SPP,(All) -US-Ha2,23771,GRP_LMA,LMA_COMMENT,"Based on projected leaf area; average over 3 canopy layers and 3 foliage age classes -" -US-Ha2,12588,GRP_LOCATION,LOCATION_LAT,42.5393 -US-Ha2,12588,GRP_LOCATION,LOCATION_LONG,-72.1779 -US-Ha2,12588,GRP_LOCATION,LOCATION_ELEV,360 -US-Ha2,23777,GRP_N_DEP,N_DEP_WET,0.8 -US-Ha2,24925,GRP_NEP,NEP,740 -US-Ha2,24925,GRP_NEP,NEP_COMMENT,"Total organic matter (not C alone) -" -US-Ha2,12589,GRP_NETWORK,NETWORK,AmeriFlux -US-Ha2,91439,GRP_NETWORK,NETWORK,LTER -US-Ha2,86966,GRP_NETWORK,NETWORK,Phenocam -US-Ha2,1700005883,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Bond-Lamberty, B., Wang, C., Gower, S. T. (2004) A Global Relationship Between The Heterotrophic And Autotrophic Components Of Soil Respiration?, Global Change Biology, 10(10), 1756-1766" -US-Ha2,1700005883,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/J.1365-2486.2004.00816.X -US-Ha2,1700005883,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ha2,1700007209,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Baldocchi, D. D., Poindexter, C., Abraha, M., Desai, A. R., Bohrer, G., Arain, M. A., Griffis, T., Blanken, P. D., O'Halloran, T. L., Thomas, R. Q., Zhang, Q., Burns, S. P., Frank, J. M., Christian, D., Brown, S., Black, T. A., Gough, C. M., Law, B. E., Lee, X., Chen, J., Reed, D. E., Massman, W. J., Clark, K., Hatfield, J., Prueger, J., Bracho, R., Baker, J. M., Martin, T. A. (2018) Temporal Dynamics Of Aerodynamic Canopy Height Derived From Eddy Covariance Momentum Flux Data Across North American Flux Networks, Geophysical Research Letters, 45(6), 9275–9287" -US-Ha2,1700007209,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018GL079306 -US-Ha2,1700007209,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ha2,1700003495,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(4), 108350" -US-Ha2,1700003495,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -US-Ha2,1700003495,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ha2,1700005586,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Compton, J. E., Boone, R. D. (2000) Long-Term Impacts Of Agriculture On Soil Carbon And Nitrogen In New England Forests, Ecology, 81(8), 2314-2330" -US-Ha2,1700005586,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1890/0012-9658(2000)081[2314:LTIOAO]2.0.CO;2 -US-Ha2,1700005586,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ha2,1700004836,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Finzi, A. C., Giasson, M., Barker Plotkin, A. A., Aber, J. D., Boose, E. R., Davidson, E. A., Dietze, M. C., Ellison, A. M., Frey, S. D., Goldman, E., Keenan, T. F., Melillo, J. M., Munger, J. W., Nadelhoffer, K. J., Ollinger, S. V., Orwig, D. A., Pederson, N., Richardson, A. D., Savage, K., Tang, J., Thompson, J. R., Williams, C. A., Wofsy, S. C., Zhou, Z., Foster, D. R. (2020) Carbon Budget Of The Harvard Forest Long‐Term Ecological Research Site: Pattern, Process, And Response To Global Change, Ecological Monographs, 499(7458), 324-327" -US-Ha2,1700004836,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/ECM.1423 -US-Ha2,1700004836,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ha2,1700001179,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Hadley, J. L. (2000) Effect Of Daily Minimum Temperature On Photosynthesis In Eastern Hemlock (Tsuga Canadensis L.) In Autumn And Winter, Arctic, Antarctic, And Alpine Research, 32(4), 368-374" -US-Ha2,1700001179,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.2307/1552384 -US-Ha2,1700001179,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ha2,1700002349,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Hadley, J. L., Schedlbauer, J. L. (2002) Carbon Exchange Of An Old-Growth Eastern Hemlock (Tsuga Canadensis) Forest In Central New England, Tree Physiology, 22(15-16), 1079-1092" -US-Ha2,1700002349,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1093/TREEPHYS/22.15-16.1079 -US-Ha2,1700002349,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ha2,1700004977,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Keenan, T. F., Hollinger, D. Y., Bohrer, G., Dragoni, D., Munger, J. W., Schmid, H. P., Richardson, A. D. (2013) Increase In Forest Water-Use Efficiency As Atmospheric Carbon Dioxide Concentrations Rise, Nature, 499(7458), 324-327" -US-Ha2,1700004977,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1038/NATURE12291 -US-Ha2,1700004977,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ha2,1700001911,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Kim, J. H., Hwang, T., Yang, Y., Schaaf, C. L., Boose, E., Munger, J. W. (2018) Warming-Induced Earlier Greenup Leads To Reduced Stream Discharge In A Temperate Mixed Forest Catchment, Journal Of Geophysical Research: Biogeosciences, 123(6), 1960-1975" -US-Ha2,1700001911,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018JG004438 -US-Ha2,1700001911,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ha2,1700002811,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Kim, J., Hwang, T., Schaaf, C. L., Orwig, D. A., Boose, E., Munger, J. W. (2017) Increased Water Yield Due To The Hemlock Woolly Adelgid Infestation In New England, Geophysical Research Letters, 44(5), 2327-2335" -US-Ha2,1700002811,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/2016GL072327 -US-Ha2,1700002811,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ha2,1700003246,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Magill, A. H., Aber, J. D., Currie, W. S., Nadelhoffer, K. J., Martin, M. E., McDowell, W. H., Melillo, J. M., Steudler, P. (2004) Ecosystem Response To 15 Years Of Chronic Nitrogen Additions At The Harvard Forest LTER, Massachusetts, USA, Forest Ecology And Management, 196(1), 7-28" -US-Ha2,1700003246,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.FORECO.2004.03.033 -US-Ha2,1700003246,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ha2,1700000609,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Turner, D. P., Urbanski, S., Bremer, D., Wofsy, S. C., Meyers, T., Gower, S. T., Gregory, M. (2003) A Cross-Biome Comparison Of Daily Light Use Efficiency For Gross Primary Production, Global Change Biology, 9(3), 383-395" -US-Ha2,1700000609,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1046/J.1365-2486.2003.00573.X -US-Ha2,1700000609,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ha2,1700008325,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Yi, C., Li, R., Bakwin, P. S., Desai, A., Ricciuto, D. M., Burns, S. P., Turnipseed, A. A., Wofsy, S. C., Munger, J. W., Wilson, K., Monson, R. K. (2004) A Nonparametric Method For Separating Photosynthesis And Respiration Components In CO2 Flux Measurements, Geophysical Research Letters, 31(17), n/a-n/a" -US-Ha2,1700008325,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2004GL020490 -US-Ha2,1700008325,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ha2,24427,GRP_SA,SA_MAX,230 -US-Ha2,12591,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"324 North Main St., Petersham, MA 01366" -US-Ha2,12592,GRP_SITE_CHAR,TERRAIN,Flat -US-Ha2,12592,GRP_SITE_CHAR,ASPECT,FLAT -US-Ha2,12592,GRP_SITE_CHAR,WIND_DIRECTION,SW -US-Ha2,12592,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,300 -US-Ha2,12593,GRP_SITE_DESC,SITE_DESC,"The forest surrounding the Hemlock site has remained pristine with two exceptions. In the early to mid-1700s, European settlers cleared the majority of the forest for agricultural purposes. Selective harvesting of hemlock and chestnut trees occurred up until the early 1900s, when the chestnut blight killed all of the chestnut trees. In the current forest, about 83% of the total basal area of trees is hemlock. The remainder is equally divided between eastern white pine (Pinus strobus L.) and deciduous species, including red maple (Acer rubrum), red oak (Quercus rubra) and black birch (Betula lenta). A very thick organic layer (10-20 cm or more) covers the soil surface, and highly decayed coarse woody debris is abundant." -US-Ha2,12594,GRP_SITE_FUNDING,SITE_FUNDING,"DOE/TCP, NSF" -US-Ha2,24025,GRP_SOIL_CHEM,SOIL_CHEM_C_ORG,103 -US-Ha2,24271,GRP_SOIL_CHEM,SOIL_CHEM_C_ORG,47 -US-Ha2,24783,GRP_SOIL_CHEM,SOIL_CHEM_C_ORG,56 -US-Ha2,24783,GRP_SOIL_CHEM,SOIL_CHEM_PH_H2O,3.4 -US-Ha2,24032,GRP_SOIL_CHEM,SOIL_CHEM_PH_H2O,4.3 -US-Ha2,25059,GRP_SOIL_CHEM,SOIL_CHEM_BD,0.13 -US-Ha2,24032,GRP_SOIL_CHEM,SOIL_CHEM_BD,0.86 -US-Ha2,24025,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,0 -US-Ha2,24032,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,2 -US-Ha2,24271,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,2 -US-Ha2,24783,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,7 -US-Ha2,25059,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,7 -US-Ha2,24783,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,20 -US-Ha2,25059,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,20 -US-Ha2,24025,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,35 -US-Ha2,24032,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,4 -US-Ha2,24271,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,4 -US-Ha2,24032,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,A -US-Ha2,24271,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,A -US-Ha2,24783,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,Organic -US-Ha2,25059,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,Organic -US-Ha2,24025,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,Total -US-Ha2,24032,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,"Compton and Boone, Ecology 81:234-2330, 2000." -US-Ha2,25059,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,"Compton and Boone, Ecology 81:234-2330, 2000." -US-Ha2,23784,GRP_SOIL_DEPTH,SOIL_DEPTH,13.5 -US-Ha2,24023,GRP_SOIL_DEPTH,SOIL_DEPTH,35 -US-Ha2,24546,GRP_SOIL_DEPTH,SOIL_DEPTH,3 -US-Ha2,28097,GRP_SOIL_DEPTH,SOIL_DEPTH,35 -US-Ha2,24558,GRP_SPP_O,SPP_O,Tsuga canadensis -US-Ha2,12595,GRP_STATE,STATE,MA -US-Ha2,91001,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,J. William Munger -US-Ha2,91001,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Ha2,91001,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,jwmunger@seas.harvard.edu -US-Ha2,91001,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Harvard University -US-Ha2,91001,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Dept. of Earth and Planetary Sciences, 20 Oxford St., Cambridge, MA 02138" -US-Ha2,12601,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Mark VanScoy -US-Ha2,12601,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Technician -US-Ha2,12601,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,mvanscoy@fas.harvard.edu -US-Ha2,12601,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Harvard University -US-Ha2,12601,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Harvard Forest, 324 North Main St., Petersham, MA 01366" -US-Ha2,29812,GRP_TOWER_POWER,TOWER_POWER,Direct power -US-Ha2,12597,GRP_TOWER_TYPE,TOWER_TYPE,triangle -US-Ha2,12598,GRP_URL,URL,http://harvardforest.fas.harvard.edu/research-facilities-and-resources -US-Ha2,24000372,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-Ha2 -US-Ha2,12599,GRP_UTC_OFFSET,UTC_OFFSET,-5 -US-HB1,86480,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,This site is partially supported by the South Carolina Sea Grant Consortium with NOAA financial assistance number NA18OAR4170091. The site is maintained in cooperation with the North Inlet-Winyah Bay National Estuarine Research Reserve. We thank the Belle W. Baruch Foundation for making the property available for research. -US-HB1,79520,GRP_CLIM_AVG,MAT,18.3 -US-HB1,79520,GRP_CLIM_AVG,MAP,1429 -US-HB1,79520,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Cfa -US-HB1,27000948,GRP_COUNTRY,COUNTRY,USA -US-HB1,93758,GRP_DOI,DOI,10.17190/AMF/1660341 -US-HB1,93758,GRP_DOI,DOI_CITATION,"Jeremy D. Forsythe, Michael A. Kline, Thomas L. O'Halloran (2022), AmeriFlux BASE US-HB1 North Inlet Crab Haul Creek, Ver. 2-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1660341" -US-HB1,93758,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-HB1,91847,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-HB1,91847,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Jeremy D. Forsythe -US-HB1,91847,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-HB1,91842,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-HB1,91842,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Michael A. Kline -US-HB1,91842,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-HB1,91843,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-HB1,91843,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Thomas L. O'Halloran -US-HB1,91843,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-HB1,91854,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Clemson University -US-HB1,91854,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-HB1,91853,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,SC Sea Grant Consortium -US-HB1,91853,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-HB1,86540,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-HB1,86540,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-HB1,86540,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201706150000 -US-HB1,86540,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-HB1,86537,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-HB1,86537,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-HB1,86537,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201706150000 -US-HB1,86537,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-HB1,86538,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-HB1,86538,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-HB1,86538,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201706150000 -US-HB1,86538,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-HB1,86539,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-HB1,86539,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,Other -US-HB1,86539,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201706150000 -US-HB1,86539,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-HB1,97739,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-HB1,97739,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CH4 -US-HB1,97739,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20210110 -US-HB1,97739,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-HB1,97739,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,Thanks to AmeriFlux for loaner LI-7700 -US-HB1,23000948,GRP_HEADER,SITE_NAME,North Inlet Crab Haul Creek -US-HB1,79507,GRP_IGBP,IGBP,WET -US-HB1,79507,GRP_IGBP,IGBP_DATE_START,201706150000 -US-HB1,79507,GRP_IGBP,IGBP_COMMENT,"Does not change. Permanent, natural wetland." -US-HB1,79524,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -US-HB1,79524,GRP_LAND_OWNERSHIP,LAND_OWNER,Belle W. Baruch Foundation -US-HB1,91824,GRP_LOCATION,LOCATION_LAT,33.3455 -US-HB1,91824,GRP_LOCATION,LOCATION_LONG,-79.1957 -US-HB1,91824,GRP_LOCATION,LOCATION_ELEV,0.1 -US-HB1,91824,GRP_LOCATION,LOCATION_DATE_START,201705190000 -US-HB1,79512,GRP_NETWORK,NETWORK,AmeriFlux -US-HB1,86967,GRP_NETWORK,NETWORK,Phenocam -US-HB1,1700003957,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Forsythe, J. D., O’Halloran, T. L., Kline, M. A. (2020) An Eddy Covariance Mesonet For Measuring Greenhouse Gas Fluxes In Coastal South Carolina, Data, 5(4), 97" -US-HB1,1700003957,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.3390/DATA5040097 -US-HB1,1700003957,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Primary_Citation -US-HB1,81385,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"The influence of tidal inundation, salinity and other abiotic drivers of net ecosystem exchange in a coastal wetland" -US-HB1,79515,GRP_SITE_CHAR,TERRAIN,Flat -US-HB1,79515,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,65 -US-HB1,79515,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,0 -US-HB1,81384,GRP_SITE_DESC,SITE_DESC,"The flux footprint includes a tidal salt marsh with approximately 40% tall form Spartina alterniflora, 40% short form Spartina alterniflora and 20% creek." -US-HB1,79522,GRP_SITE_FUNDING,SITE_FUNDING,NOAA SC Sea Grant Consortium -US-HB1,79523,GRP_STATE,STATE,SC -US-HB1,79516,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Erik M. Smith -US-HB1,79516,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-HB1,79516,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,erik@belle.baruch.sc.edu -US-HB1,79516,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of South Carolina -US-HB1,79516,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Baruch Marine Field Lab P.O. Box 1630 Georgetown, SC 29442 USA - -" -US-HB1,79510,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Tom O'Halloran -US-HB1,79510,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-HB1,79510,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,tohallo@clemson.edu -US-HB1,79510,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Clemson University -US-HB1,79510,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Baruch Institute - Clemson University, Hwy 17 North - 177 Hobcaw Rd., Georgetown, SC 29440" -US-HB1,91811,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Jeremy Forsythe -US-HB1,91811,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,DataManager -US-HB1,91811,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,jdforsy@g.clemson.edu -US-HB1,91811,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Clemson University -US-HB1,91826,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Mike Kline -US-HB1,91826,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Technician -US-HB1,91826,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,mkline@clemson.edu -US-HB1,91826,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Clemson University -US-HB1,79521,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-HB1,79508,GRP_TOWER_TYPE,TOWER_TYPE,triangle -US-HB1,91833,GRP_URL,URL,https://sites.google.com/g.clemson.edu/ohalloran/tower-sites -US-HB1,24000948,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-HB1 -US-HB1,79519,GRP_UTC_OFFSET,UTC_OFFSET,-5 -US-HB2,79870,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,Thank you to the Belle W. Baruch Foundation for hosting the site. -US-HB2,79882,GRP_CLIM_AVG,MAT,18.3 -US-HB2,79882,GRP_CLIM_AVG,MAP,1429 -US-HB2,79882,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Cfa -US-HB2,27000964,GRP_COUNTRY,COUNTRY,USA -US-HB2,93750,GRP_DOI,DOI,10.17190/AMF/1660342 -US-HB2,93750,GRP_DOI,DOI_CITATION,"Jeremy D. Forsythe, Michael A. Kline, Thomas L. O'Halloran (2020), AmeriFlux BASE US-HB2 Hobcaw Barony Mature Longleaf Pine, Ver. 1-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1660342" -US-HB2,93750,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-HB2,91849,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-HB2,91849,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Jeremy D. Forsythe -US-HB2,91849,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-HB2,91844,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-HB2,91844,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Michael A. Kline -US-HB2,91844,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-HB2,91846,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-HB2,91846,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Thomas L. O'Halloran -US-HB2,91846,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-HB2,91850,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Clemson University -US-HB2,91850,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-HB2,91817,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-HB2,91817,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-HB2,91817,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20180501 -US-HB2,91817,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-HB2,91823,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-HB2,91823,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-HB2,91823,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20180501 -US-HB2,91823,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-HB2,91830,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-HB2,91830,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-HB2,91830,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20180501 -US-HB2,91830,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-HB2,23000964,GRP_HEADER,SITE_NAME,Hobcaw Barony Mature Longleaf Pine -US-HB2,79881,GRP_IGBP,IGBP,ENF -US-HB2,79881,GRP_IGBP,IGBP_DATE_START,201706150000 -US-HB2,79881,GRP_IGBP,IGBP_COMMENT,Primary species is pinus palustris -US-HB2,79868,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -US-HB2,79868,GRP_LAND_OWNERSHIP,LAND_OWNER,Belle W. Baruch Foundation -US-HB2,79871,GRP_LOCATION,LOCATION_LAT,33.3242 -US-HB2,79871,GRP_LOCATION,LOCATION_LONG,-79.2440 -US-HB2,79871,GRP_LOCATION,LOCATION_ELEV,4.7 -US-HB2,79871,GRP_LOCATION,LOCATION_DATE_START,201706150000 -US-HB2,79879,GRP_NETWORK,NETWORK,AmeriFlux -US-HB2,86968,GRP_NETWORK,NETWORK,Phenocam -US-HB2,1700002163,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Forsythe, J. D., O’Halloran, T. L., Kline, M. A. (2020) An Eddy Covariance Mesonet For Measuring Greenhouse Gas Fluxes In Coastal South Carolina, Data, 5(4), 97" -US-HB2,1700002163,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.3390/DATA5040097 -US-HB2,1700002163,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Primary_Citation -US-HB2,79884,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,Role of fire in affecting longleaf pine carbon and water cycling -US-HB2,79880,GRP_SITE_CHAR,TERRAIN,Flat -US-HB2,79880,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,65 -US-HB2,79880,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,0 -US-HB2,79875,GRP_SITE_DESC,SITE_DESC,A mature longleaf pine forest that is periodically managed with fire -US-HB2,79877,GRP_STATE,STATE,SC -US-HB2,79874,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Tom O'Halloran -US-HB2,79874,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-HB2,79874,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,tohallo@clemson.edu -US-HB2,79874,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Clemson University -US-HB2,79874,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Baruch Institute - Clemson University, Hwy 17 North - 177 Hobcaw Rd., Georgetown, SC 29440" -US-HB2,91815,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Jeremy Forsythe -US-HB2,91815,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,DataManager -US-HB2,91815,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,jdforsy@g.clemson.edu -US-HB2,91815,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Clemson University -US-HB2,91810,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Michael A. Kline -US-HB2,91810,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Technician -US-HB2,91810,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,mkline@clemson.edu -US-HB2,91810,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Clemson University -US-HB2,79883,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-HB2,79867,GRP_TOWER_TYPE,TOWER_TYPE,triangle -US-HB2,91822,GRP_URL,URL,https://sites.google.com/g.clemson.edu/ohalloran/tower-sites -US-HB2,24000964,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-HB2 -US-HB2,79869,GRP_UTC_OFFSET,UTC_OFFSET,-5 -US-HB3,86454,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,Thank you to the Belle W. Baruch Foundation for hosting the site. -US-HB3,86465,GRP_CLIM_AVG,MAT,18.3 -US-HB3,86465,GRP_CLIM_AVG,MAP,1429 -US-HB3,86465,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Cfa -US-HB3,27001062,GRP_COUNTRY,COUNTRY,USA -US-HB3,93760,GRP_DOI,DOI,10.17190/AMF/1660343 -US-HB3,93760,GRP_DOI,DOI_CITATION,"Jeremy D. Forsythe, Michael A. Kline, Thomas L. O'Halloran (2020), AmeriFlux BASE US-HB3 Hobcaw Barony Longleaf Pine Restoration, Ver. 1-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1660343" -US-HB3,93760,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-HB3,91845,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-HB3,91845,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Jeremy D. Forsythe -US-HB3,91845,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-HB3,91841,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-HB3,91841,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Michael A. Kline -US-HB3,91841,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-HB3,91848,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-HB3,91848,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Thomas L. O'Halloran -US-HB3,91848,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-HB3,91852,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Clemson University -US-HB3,91852,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-HB3,86463,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-HB3,86463,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-HB3,86463,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201901050000 -US-HB3,86463,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-HB3,86467,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-HB3,86467,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-HB3,86467,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201901050000 -US-HB3,86467,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-HB3,86466,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-HB3,86466,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-HB3,86466,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201901050000 -US-HB3,86466,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-HB3,86481,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-HB3,86481,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,Other -US-HB3,86481,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201901050000 -US-HB3,86481,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-HB3,86481,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,LE is measured. -US-HB3,23001062,GRP_HEADER,SITE_NAME,Hobcaw Barony Longleaf Pine Restoration -US-HB3,86453,GRP_IGBP,IGBP,ENF -US-HB3,86453,GRP_IGBP,IGBP_DATE_START,201803010000 -US-HB3,86453,GRP_IGBP,IGBP_COMMENT,currently longleaf seedlings mixed with herbaceous and deciduous regrowth -US-HB3,86456,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -US-HB3,86456,GRP_LAND_OWNERSHIP,LAND_OWNER,Belle W. Baruch Foundation -US-HB3,86460,GRP_LOCATION,LOCATION_LAT,33.3482 -US-HB3,86460,GRP_LOCATION,LOCATION_LONG,-79.2322 -US-HB3,86460,GRP_LOCATION,LOCATION_ELEV,7.3 -US-HB3,86460,GRP_LOCATION,LOCATION_DATE_START,201901050000 -US-HB3,86468,GRP_NETWORK,NETWORK,AmeriFlux -US-HB3,86969,GRP_NETWORK,NETWORK,Phenocam -US-HB3,1700008757,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Forsythe, J. D., O’Halloran, T. L., Kline, M. A. (2020) An Eddy Covariance Mesonet For Measuring Greenhouse Gas Fluxes In Coastal South Carolina, Data, 5(4), 97" -US-HB3,1700008757,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.3390/DATA5040097 -US-HB3,1700008757,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Primary_Citation -US-HB3,86461,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,Carbon and water balance during longleaf pine restoration -US-HB3,86451,GRP_SITE_CHAR,TERRAIN,Flat -US-HB3,86451,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,95 -US-HB3,86451,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,0 -US-HB3,86452,GRP_SITE_DESC,SITE_DESC,"A mixed forest that was clearcut, herbicided and planted in containerized longleaf pine seedlings" -US-HB3,86455,GRP_STATE,STATE,SC -US-HB3,86457,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Tom O'Halloran -US-HB3,86457,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-HB3,86457,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,tohallo@clemson.edu -US-HB3,86457,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Clemson University -US-HB3,86457,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Baruch Institute - Clemson University, Hwy 17 North - 177 Hobcaw Rd., Georgetown, SC 29440" -US-HB3,91827,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Jeremy Forsythe -US-HB3,91827,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,DataManager -US-HB3,91827,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,jdforsy@g.clemson.edu -US-HB3,91827,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Clemson University -US-HB3,91821,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Michael A. Kline -US-HB3,91821,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Technician -US-HB3,91821,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,mkline@clemson.edu -US-HB3,91821,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Clemson University -US-HB3,86462,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-HB3,86458,GRP_TOWER_TYPE,TOWER_TYPE,triangle -US-HB3,86464,GRP_URL,URL,https://sites.google.com/g.clemson.edu/ohalloran/tower-sites -US-HB3,24001062,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-HB3 -US-HB3,86459,GRP_UTC_OFFSET,UTC_OFFSET,-5 -US-HBK,81447,GRP_CLIM_AVG,MAT,6 -US-HBK,81447,GRP_CLIM_AVG,MAP,1400 -US-HBK,81447,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfb -US-HBK,27000968,GRP_COUNTRY,COUNTRY,USA -US-HBK,92862,GRP_DOI,DOI,10.17190/AMF/1634881 -US-HBK,92862,GRP_DOI,DOI_CITATION,"Eric Kelsey, Mark Green (2020), AmeriFlux BASE US-HBK Hubbard Brook Experimental Forest, Ver. 1-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1634881" -US-HBK,92862,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-HBK,92827,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-HBK,92827,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Eric Kelsey -US-HBK,92827,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-HBK,92827,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,ekelsey2@plymouth.edu -US-HBK,92827,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Plymouth State University -US-HBK,92828,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-HBK,92828,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Mark Green -US-HBK,92828,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-HBK,92828,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,greenmarkb@gmail.com -US-HBK,92828,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Case Western Reserve University -US-HBK,92851,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Case Western Reserve University -US-HBK,92851,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-HBK,92850,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Plymouth State University -US-HBK,92850,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-HBK,92844,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,"LTER, Plymouth State University," -US-HBK,92844,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-HBK,81461,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Forestry -US-HBK,81460,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-HBK,81460,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-HBK,81460,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20160825 -US-HBK,81460,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-HBK,81452,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-HBK,81452,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-HBK,81452,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20160825 -US-HBK,81452,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-HBK,23000968,GRP_HEADER,SITE_NAME,Hubbard Brook Experimental Forest -US-HBK,81444,GRP_IGBP,IGBP,DBF -US-HBK,81448,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-HBK,81448,GRP_LAND_OWNERSHIP,LAND_OWNER,USFS Hubbard Brook Experimental Forest -US-HBK,81455,GRP_LOCATION,LOCATION_LAT,43.9397 -US-HBK,81455,GRP_LOCATION,LOCATION_LONG,-71.7181 -US-HBK,81455,GRP_LOCATION,LOCATION_ELEV,367 -US-HBK,81455,GRP_LOCATION,LOCATION_DATE_START,20160825 -US-HBK,81445,GRP_NETWORK,NETWORK,AmeriFlux -US-HBK,81446,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"closure of local water and energy budgets, adapabiltiy of eddy covariance methods in sub-optimal environments, adiabatic and kadabatic winds," -US-HBK,81454,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"17 High Street, MSC 48, Plymouth NH 03264" -US-HBK,81451,GRP_SITE_CHAR,TERRAIN,"Significant Slope (>5%, <10%)" -US-HBK,81451,GRP_SITE_CHAR,ASPECT,N -US-HBK,81451,GRP_SITE_CHAR,WIND_DIRECTION,W -US-HBK,81451,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,1000 -US-HBK,81451,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,120 -US-HBK,81450,GRP_SITE_DESC,SITE_DESC,"Mixed forest dominated by BEAL, ACRU with lesser components of PIRU. Gently sloped plateau within mountainous terrain." -US-HBK,81459,GRP_SITE_FUNDING,SITE_FUNDING,"LTER, Plymouth State University," -US-HBK,81457,GRP_STATE,STATE,NH -US-HBK,81456,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Eric Kelsey -US-HBK,81456,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-HBK,81456,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,ekelsey2@plymouth.edu -US-HBK,81456,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Plymouth State University -US-HBK,81456,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"17 High Street, MSC 48, Plymouth NH 03264" -US-HBK,92759,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Mark Green -US-HBK,92759,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-HBK,92759,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,greenmarkb@gmail.com -US-HBK,92759,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Case Western Reserve University -US-HBK,85642,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Daniel Evans -US-HBK,85642,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,DataManager -US-HBK,85642,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,dmevans1@plymouth.edu -US-HBK,85642,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Plymouth State University -US-HBK,81458,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-HBK,81449,GRP_TOWER_TYPE,TOWER_TYPE,triangle -US-HBK,24000968,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-HBK -US-HBK,81453,GRP_UTC_OFFSET,UTC_OFFSET,-5 -US-Hn1,83544,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,"This research was supported by the U.S. Department of Energy (DOE), Office of Biological and Environmental Research (BER), as part of BER's Subsurface Biogeochemistry Research Program (SBR)." -US-Hn1,83533,GRP_CLIM_AVG,MAT,12.8 -US-Hn1,83533,GRP_CLIM_AVG,MAP,197 -US-Hn1,83533,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Bsk -US-Hn1,27000982,GRP_COUNTRY,COUNTRY,USA -US-Hn1,83547,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Hn1,83547,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-Hn1,83547,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20151121 -US-Hn1,83547,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Hn1,83546,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Hn1,83546,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-Hn1,83546,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20151121 -US-Hn1,83546,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Hn1,83548,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Hn1,83548,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-Hn1,83548,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20151121 -US-Hn1,83548,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Hn1,23000982,GRP_HEADER,SITE_NAME,Hanford 300 Area -US-Hn1,83531,GRP_IGBP,IGBP,OSH -US-Hn1,83549,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-Hn1,83549,GRP_LAND_OWNERSHIP,LAND_OWNER,Department of Energy -US-Hn1,83545,GRP_LOCATION,LOCATION_LAT,46.4089 -US-Hn1,83545,GRP_LOCATION,LOCATION_LONG,-119.2750 -US-Hn1,83545,GRP_LOCATION,LOCATION_ELEV,118.58 -US-Hn1,83542,GRP_NETWORK,NETWORK,AmeriFlux -US-Hn1,1700006645,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Gao, Z., Liu, H., Missik, J. E., Yao, J., Huang, M., Chen, X., Arntzen, E., Mcfarland, D. P. (2019) Mechanistic Links between Underestimated CO2 Fluxes and Non-Closure of the Surface Energy Balance in A Semi-Arid Sagebrush Ecosystem, Environmental Research Letters, 14(4), 044016" -US-Hn1,1700006645,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1088/1748-9326/AB082D -US-Hn1,1700006645,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Hn1,1700008283,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Gao, Z., Russell, E. S., Missik, J. E., Huang, M., Chen, X., Strickland, C. E., Clayton, R., Arntzen, E., Ma, Y., Liu, H. (2017) A Novel Approach To Evaluate Soil Heat Flux Calculation: An Analytical Review Of Nine Methods, Journal Of Geophysical Research: Atmospheres, 122(13), 6934-6949" -US-Hn1,1700008283,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/2017JD027160 -US-Hn1,1700008283,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Hn1,1700005889,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Missik, J. E., Liu, H., Gao, Z., Huang, M., Chen, X., Arntzen, E., Mcfarland, D. P., Ren, H., Titzler, P. S., Thomle, J. N., Goldman, A. (2019) Groundwater-River Water Exchange Enhances Growing Season Evapotranspiration And Carbon Uptake In A Semiarid Riparian Ecosystem, Journal Of Geophysical Research: Biogeosciences, (), " -US-Hn1,1700005889,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018JG004666 -US-Hn1,1700005889,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Hn1,1700002472,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Missik, J. E., Liu, H., Gao, Z., Huang, M., Chen, X., Arntzen, E., Mcfarland, D. P., Ren, H., Titzler, P. S., Thomle, J. N., Goldman, A. (2019) Groundwater-River Water Exchange Enhances Growing Season Evapotranspiration And Carbon Uptake In A Semiarid Riparian Ecosystem, Journal Of Geophysical Research: Biogeosciences, 14(4), 044016" -US-Hn1,1700002472,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018JG004666 -US-Hn1,1700002472,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Hn1,83529,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,Semi-arid ecosystem fluxes -US-Hn1,83528,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"PACCAR 423, 2001 NE Grimes Way, Pullman WA 99164" -US-Hn1,83540,GRP_SITE_CHAR,TERRAIN,Flat -US-Hn1,83540,GRP_SITE_CHAR,WIND_DIRECTION,SSE -US-Hn1,85949,GRP_SITE_DESC,SITE_DESC,The site is an upland sagebrush-steppe ecosystem within the Hanford 300 Area. -US-Hn1,83541,GRP_SITE_FUNDING,SITE_FUNDING,"Department of Energy, Office of Science" -US-Hn1,83536,GRP_STATE,STATE,WA -US-Hn1,92274,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Heping Liu -US-Hn1,92274,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Hn1,92274,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,heping.liu@wsu.edu -US-Hn1,92274,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Washington State University -US-Hn1,92274,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Department of Civil and Environmental Engineering, Washington State University, 450 Spokane Street, Pullman, WA 99164" -US-Hn1,83543,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Maoyi Huang -US-Hn1,83543,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Hn1,83543,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,Maoyi.Huang@pnnl.gov -US-Hn1,83543,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Pacific Northwest National Laboratory -US-Hn1,83532,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Xingyuan Chen -US-Hn1,83532,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Hn1,83532,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,Xingyuan.Chen@pnnl.gov -US-Hn1,83532,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Pacific Northwest National Laboratory -US-Hn1,83550,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Justine Missik -US-Hn1,83550,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,DataManager -US-Hn1,83550,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,justine.missik@wsu.edu -US-Hn1,83550,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Washington State University -US-Hn1,83537,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-Hn1,83538,GRP_TOWER_TYPE,TOWER_TYPE,triangle -US-Hn1,83539,GRP_URL,URL,http://micromet.paccar.wsu.edu/land/ -US-Hn1,24000982,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-Hn1 -US-Hn1,83534,GRP_UTC_OFFSET,UTC_OFFSET,-8 -US-Hn2,83485,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,"This research was supported by the U.S. Department of Energy (DOE), Office of Biological and Environmental Research (BER), as part of BER's Subsurface Biogeochemistry Research Program (SBR)." -US-Hn2,83502,GRP_CLIM_AVG,MAT,12.8 -US-Hn2,83502,GRP_CLIM_AVG,MAP,197 -US-Hn2,83502,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Bsk -US-Hn2,27000983,GRP_COUNTRY,COUNTRY,USA -US-Hn2,87989,GRP_DOI,DOI,10.17190/AMF/1562389 -US-Hn2,87989,GRP_DOI,DOI_CITATION,"Heping Liu, Maoyi Huang, Xingyuan Chen (2019), AmeriFlux BASE US-Hn2 Hanford 100H grassland, Ver. 1-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1562389" -US-Hn2,87989,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-Hn2,87960,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Hn2,87960,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Heping Liu -US-Hn2,87960,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Hn2,87960,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,heping.liu@wsu.edu -US-Hn2,87960,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Washington State University -US-Hn2,87959,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Hn2,87959,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Maoyi Huang -US-Hn2,87959,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Hn2,87959,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,Maoyi.Huang@pnnl.gov -US-Hn2,87959,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Pacific Northwest National Laboratory -US-Hn2,87961,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Hn2,87961,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Xingyuan Chen -US-Hn2,87961,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Hn2,87961,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,Xingyuan.Chen@pnnl.gov -US-Hn2,87961,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Pacific Northwest National Laboratory -US-Hn2,87982,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Pacific Northwest National Laboratory -US-Hn2,87982,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-Hn2,87978,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Washington State University -US-Hn2,87978,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-Hn2,87969,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,"Department of Energy, Office of Science" -US-Hn2,87969,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-Hn2,83481,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Hydrologic event -US-Hn2,83490,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Hn2,83490,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-Hn2,83490,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20151204 -US-Hn2,83490,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Hn2,83489,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Hn2,83489,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-Hn2,83489,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20151204 -US-Hn2,83489,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Hn2,83500,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Hn2,83500,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-Hn2,83500,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20151204 -US-Hn2,83500,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Hn2,23000983,GRP_HEADER,SITE_NAME,Hanford 100H grassland -US-Hn2,83487,GRP_IGBP,IGBP,GRA -US-Hn2,83504,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-Hn2,83504,GRP_LAND_OWNERSHIP,LAND_OWNER,Department of Energy -US-Hn2,83492,GRP_LOCATION,LOCATION_LAT,46.6889 -US-Hn2,83492,GRP_LOCATION,LOCATION_LONG,-119.4641 -US-Hn2,83492,GRP_LOCATION,LOCATION_ELEV,117.5 -US-Hn2,83496,GRP_NETWORK,NETWORK,AmeriFlux -US-Hn2,1700004353,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(), 108350" -US-Hn2,1700004353,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -US-Hn2,1700004353,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Hn2,1700000267,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Missik, J. E., Liu, H., Gao, Z., Huang, M., Chen, X., Arntzen, E., Mcfarland, D. P., Ren, H., Titzler, P. S., Thomle, J. N., Goldman, A. (2019) Groundwater-River Water Exchange Enhances Growing Season Evapotranspiration And Carbon Uptake In A Semiarid Riparian Ecosystem, Journal Of Geophysical Research: Biogeosciences, (), " -US-Hn2,1700000267,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018JG004666 -US-Hn2,1700000267,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Hn2,1700006168,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Missik, J. E., Liu, H., Gao, Z., Huang, M., Chen, X., Arntzen, E., Mcfarland, D. P., Ren, H., Titzler, P. S., Thomle, J. N., Goldman, A. (2019) Groundwater-River Water Exchange Enhances Growing Season Evapotranspiration And Carbon Uptake In A Semiarid Riparian Ecosystem, Journal Of Geophysical Research: Biogeosciences, 301-302(), 108350" -US-Hn2,1700006168,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018JG004666 -US-Hn2,1700006168,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Hn2,83499,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"Semi-arid ecosystem fluxes, groundwater-ecosystem interactions" -US-Hn2,83495,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"PACCAR 423, 2001 NE Grimes Way, Pullman WA 99164" -US-Hn2,83503,GRP_SITE_CHAR,TERRAIN,Flat -US-Hn2,83503,GRP_SITE_CHAR,WIND_DIRECTION,SSE -US-Hn2,85950,GRP_SITE_DESC,SITE_DESC,The site is a riparian grassland ecosystem characterized by a shallow water table. -US-Hn2,83486,GRP_SITE_FUNDING,SITE_FUNDING,"Department of Energy, Office of Science" -US-Hn2,83482,GRP_STATE,STATE,WA -US-Hn2,83493,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Heping Liu -US-Hn2,83493,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Hn2,83493,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,heping.liu@wsu.edu -US-Hn2,83493,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Washington State University -US-Hn2,83488,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Maoyi Huang -US-Hn2,83488,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Hn2,83488,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,Maoyi.Huang@pnnl.gov -US-Hn2,83488,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Pacific Northwest National Laboratory -US-Hn2,83497,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Xingyuan Chen -US-Hn2,83497,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Hn2,83497,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,Xingyuan.Chen@pnnl.gov -US-Hn2,83497,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Pacific Northwest National Laboratory -US-Hn2,83494,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Justine Missik -US-Hn2,83494,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,DataManager -US-Hn2,83494,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,justine.missik@wsu.edu -US-Hn2,83494,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Washington State University -US-Hn2,83484,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-Hn2,83483,GRP_TOWER_TYPE,TOWER_TYPE,tripod -US-Hn2,83501,GRP_URL,URL,http://micromet.paccar.wsu.edu/land/ -US-Hn2,24000983,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-Hn2 -US-Hn2,83498,GRP_UTC_OFFSET,UTC_OFFSET,-8 -US-Hn3,83523,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,"This research was supported by the U.S. Department of Energy (DOE), Office of Biological and Environmental Research (BER), as part of BER's Subsurface Biogeochemistry Research Program (SBR)." -US-Hn3,83508,GRP_CLIM_AVG,MAT,12.8 -US-Hn3,83508,GRP_CLIM_AVG,MAP,197 -US-Hn3,83508,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Bsk -US-Hn3,27000984,GRP_COUNTRY,COUNTRY,USA -US-Hn3,87132,GRP_DOI,DOI,10.17190/AMF/1543379 -US-Hn3,87132,GRP_DOI,DOI_CITATION,"Heping Liu, Maoyi Huang, Xingyuan Chen (2019), AmeriFlux BASE US-Hn3 Hanford 100H sagebrush, Ver. 1-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1543379" -US-Hn3,87132,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-Hn3,86895,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Hn3,86895,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Heping Liu -US-Hn3,86895,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Hn3,86895,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,heping.liu@wsu.edu -US-Hn3,86895,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Washington State University -US-Hn3,86896,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Hn3,86896,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Maoyi Huang -US-Hn3,86896,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Hn3,86896,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,Maoyi.Huang@pnnl.gov -US-Hn3,86896,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Pacific Northwest National Laboratory -US-Hn3,86897,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Hn3,86897,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Xingyuan Chen -US-Hn3,86897,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Hn3,86897,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,Xingyuan.Chen@pnnl.gov -US-Hn3,86897,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Pacific Northwest National Laboratory -US-Hn3,86908,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Pacific Northwest National Laboratory -US-Hn3,86908,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-Hn3,86909,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Washington State University -US-Hn3,86909,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-Hn3,86907,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,"Department of Energy, Office of Science" -US-Hn3,86907,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-Hn3,83513,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Hn3,83513,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-Hn3,83513,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20171115 -US-Hn3,83513,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Hn3,83521,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Hn3,83521,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-Hn3,83521,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20171115 -US-Hn3,83521,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Hn3,83509,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Hn3,83509,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-Hn3,83509,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20171115 -US-Hn3,83509,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Hn3,23000984,GRP_HEADER,SITE_NAME,Hanford 100H sagebrush -US-Hn3,83517,GRP_IGBP,IGBP,OSH -US-Hn3,83510,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-Hn3,83510,GRP_LAND_OWNERSHIP,LAND_OWNER,Department of Energy -US-Hn3,83524,GRP_LOCATION,LOCATION_LAT,46.6878 -US-Hn3,83524,GRP_LOCATION,LOCATION_LONG,-119.4614 -US-Hn3,83524,GRP_LOCATION,LOCATION_ELEV,120.9 -US-Hn3,83506,GRP_NETWORK,NETWORK,AmeriFlux -US-Hn3,1700001668,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(), 108350" -US-Hn3,1700001668,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -US-Hn3,1700001668,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Hn3,83507,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"Semi-arid ecosystem fluxes, groundwater-ecosystem interactions" -US-Hn3,83526,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"PACCAR 423, 2001 NE Grimes Way, Pullman WA 99164" -US-Hn3,83522,GRP_SITE_CHAR,TERRAIN,Flat -US-Hn3,83522,GRP_SITE_CHAR,WIND_DIRECTION,SSE -US-Hn3,85951,GRP_SITE_DESC,SITE_DESC,The site is a riparian sagebrush-steppe ecosystem characterized by a shallow water table. -US-Hn3,83519,GRP_SITE_FUNDING,SITE_FUNDING,"Department of Energy, Office of Science" -US-Hn3,83512,GRP_STATE,STATE,WA -US-Hn3,83505,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Heping Liu -US-Hn3,83505,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Hn3,83505,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,heping.liu@wsu.edu -US-Hn3,83505,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Washington State University -US-Hn3,83511,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Maoyi Huang -US-Hn3,83511,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Hn3,83511,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,Maoyi.Huang@pnnl.gov -US-Hn3,83511,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Pacific Northwest National Laboratory -US-Hn3,83514,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Xingyuan Chen -US-Hn3,83514,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Hn3,83514,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,Xingyuan.Chen@pnnl.gov -US-Hn3,83514,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Pacific Northwest National Laboratory -US-Hn3,83527,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Justine Missik -US-Hn3,83527,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,DataManager -US-Hn3,83527,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,justine.missik@wsu.edu -US-Hn3,83527,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Washington State University -US-Hn3,83525,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-Hn3,83518,GRP_TOWER_TYPE,TOWER_TYPE,tripod -US-Hn3,83520,GRP_URL,URL,http://micromet.paccar.wsu.edu/land/ -US-Hn3,24000984,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-Hn3 -US-Hn3,83515,GRP_UTC_OFFSET,UTC_OFFSET,-8 -US-Ho1,23765,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER,23.5 -US-Ho1,23765,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_ORGAN,Total -US-Ho1,23765,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_PHEN,Mixed/unknown -US-Ho1,23765,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_UNIT,kgDM m-2 -US-Ho1,24864,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,10200 -US-Ho1,24864,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Wood -US-Ho1,24864,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-Ho1,24864,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-Ho1,24864,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,Hollinger et al. 2004 -US-Ho1,24864,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,20030719 -US-Ho1,24864,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,Hollinger et al. 2004 -US-Ho1,24229,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,11200 -US-Ho1,24229,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Total -US-Ho1,24229,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-Ho1,24229,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-Ho1,24229,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,Hollinger et al. 2004 -US-Ho1,24229,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,20030719 -US-Ho1,24229,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,Hollinger et al. 2004 -US-Ho1,24863,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,970 -US-Ho1,24863,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Foliage -US-Ho1,24863,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-Ho1,24863,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-Ho1,24863,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,Hollinger et al. 2004 -US-Ho1,24863,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,20030719 -US-Ho1,24863,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,Hollinger et al. 2004 -US-Ho1,24873,GRP_AG_LIT_CHEM,AG_LIT_N,0.12 -US-Ho1,24873,GRP_AG_LIT_CHEM,AG_LIT_DATE,20030818 -US-Ho1,23700,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT,150 -US-Ho1,23700,GRP_AG_LIT_PROD,AG_LIT_PROD_UNIT,gC m-2 -US-Ho1,23700,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_START,2008 -US-Ho1,25118,GRP_BIOMASS_CHEM,BIOMASS_C,4.7 -US-Ho1,24220,GRP_BIOMASS_CHEM,BIOMASS_N,0.0061 -US-Ho1,25136,GRP_BIOMASS_CHEM,BIOMASS_N,0.099 -US-Ho1,24213,GRP_BIOMASS_CHEM,BIOMASS_N,0.106 -US-Ho1,24095,GRP_BIOMASS_CHEM,BIOMASS_N,0.113 -US-Ho1,24095,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-Ho1,24213,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-Ho1,24220,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-Ho1,25118,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-Ho1,25136,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-Ho1,24095,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-Ho1,24213,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-Ho1,24220,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-Ho1,25118,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-Ho1,25136,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-Ho1,24213,GRP_BIOMASS_CHEM,BIOMASS_SPP,(All) -US-Ho1,24220,GRP_BIOMASS_CHEM,BIOMASS_SPP,(All) -US-Ho1,25118,GRP_BIOMASS_CHEM,BIOMASS_SPP,(All) -US-Ho1,25136,GRP_BIOMASS_CHEM,BIOMASS_SPP,PIRU (NRCS plant code) -US-Ho1,24095,GRP_BIOMASS_CHEM,BIOMASS_SPP,TSCA (NRCS plant code) -US-Ho1,25118,GRP_BIOMASS_CHEM,BIOMASS_DATE,19990818 -US-Ho1,24220,GRP_BIOMASS_CHEM,BIOMASS_DATE,20030818 -US-Ho1,24095,GRP_BIOMASS_CHEM,BIOMASS_COMMENT,230/2001-3 -US-Ho1,25136,GRP_BIOMASS_CHEM,BIOMASS_COMMENT,230/2001-3 -US-Ho1,24220,GRP_BIOMASS_CHEM,BIOMASS_COMMENT,heart wood -US-Ho1,24213,GRP_BIOMASS_CHEM,BIOMASS_COMMENT,"PIRU=0.99, TSCA=1.13 (230/2001-3)" -US-Ho1,14805,GRP_CLIM_AVG,MAT,5.27 -US-Ho1,14805,GRP_CLIM_AVG,MAP,1070 -US-Ho1,14805,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfb -US-Ho1,27000373,GRP_COUNTRY,COUNTRY,USA -US-Ho1,9506,GRP_DM_FIRE,DM_FIRE,Nature induced burn -US-Ho1,9506,GRP_DM_FIRE,DM_DATE,1820 -US-Ho1,9506,GRP_DM_FIRE,DM_COMMENT,medium; some single tree harvest > 60 years ago -US-Ho1,15651,GRP_DOI,DOI,10.17190/AMF/1246061 -US-Ho1,15651,GRP_DOI,DOI_CITATION,"David Hollinger (2021), AmeriFlux BASE US-Ho1 Howland Forest (main tower), Ver. 7-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1246061" -US-Ho1,15651,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-Ho1,32067,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Ho1,32067,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,David Hollinger -US-Ho1,32067,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Ho1,32067,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,David.Hollinger@unh.edu -US-Ho1,32067,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,USDA Forest Service -US-Ho1,32069,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,USDA Forest Service -US-Ho1,32069,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-Ho1,32068,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,"DOE/NIGEC, USDA Forest Service" -US-Ho1,32068,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-Ho1,93078,GRP_DOI_RELATED_DATA_DOI,DOI_RELATED_DATA_DOI,https://doi.org/10.6084/m9.figshare.7445657.v1 -US-Ho1,11450,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Fire -US-Ho1,91788,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Chambers -US-Ho1,91788,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-Ho1,91788,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,19960501 -US-Ho1,91788,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20121002 -US-Ho1,91788,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Intermittent -US-Ho1,91788,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,Several times a month during the growing season -US-Ho1,11451,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Ho1,11451,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-Ho1,11451,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,1996 -US-Ho1,11451,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Ho1,91412,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Ho1,91412,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-Ho1,91412,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,1996 -US-Ho1,91412,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Ho1,91442,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Ho1,91442,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-Ho1,91442,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,1996 -US-Ho1,91442,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Ho1,91442,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,FLUX_MEASUREMENTS_COMMENT -US-Ho1,91793,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Chambers -US-Ho1,91793,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-Ho1,91793,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20040514 -US-Ho1,91793,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20161114 -US-Ho1,91793,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Growing season operation only -US-Ho1,91793,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,Automatic soil respiration chambers not operated during winter. -US-Ho1,91784,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Chambers -US-Ho1,91784,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CH4 -US-Ho1,91784,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20120416 -US-Ho1,91784,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20161108 -US-Ho1,91784,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Growing season operation only -US-Ho1,91784,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,Automatic soil chambers not operated during winter. -US-Ho1,91405,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Ho1,91405,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CH4 -US-Ho1,91405,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20120604 -US-Ho1,91405,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Ho1,91405,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,"Closed path Picarro analyzer: CO2, H2O, and CH4" -US-Ho1,91798,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Chambers -US-Ho1,91798,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,N2O -US-Ho1,91798,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20140816 -US-Ho1,91798,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20161107 -US-Ho1,91798,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Growing season operation only -US-Ho1,91798,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,Automatic soil respiration chambers not operated during winter. -US-Ho1,23000373,GRP_HEADER,SITE_NAME,Howland Forest (main tower) -US-Ho1,25106,GRP_HEIGHTC,HEIGHTC,20 -US-Ho1,25106,GRP_HEIGHTC,HEIGHTC_DATE,1999 -US-Ho1,25106,GRP_HEIGHTC,HEIGHTC_COMMENT,emergent PIST -US-Ho1,11452,GRP_IGBP,IGBP,ENF -US-Ho1,11452,GRP_IGBP,IGBP_COMMENT,"~90% ENF and 10% BDF in 1km around tower. Across region forest type is mixed ENF, DBF (no type>60%)." -US-Ho1,23843,GRP_LAI,LAI_TYPE,LAI -US-Ho1,23975,GRP_LAI,LAI_TYPE,LAI -US-Ho1,24485,GRP_LAI,LAI_TYPE,LAI -US-Ho1,24742,GRP_LAI,LAI_TYPE,LAI -US-Ho1,24872,GRP_LAI,LAI_TYPE,LAI -US-Ho1,24990,GRP_LAI,LAI_TYPE,LAI -US-Ho1,25127,GRP_LAI,LAI_TYPE,LAI -US-Ho1,23843,GRP_LAI,LAI_CLUMP,1.6 -US-Ho1,23843,GRP_LAI,LAI_METHOD,LAI_2000 -US-Ho1,23975,GRP_LAI,LAI_METHOD,LAI_2000 -US-Ho1,24485,GRP_LAI,LAI_METHOD,LAI_2000 -US-Ho1,24742,GRP_LAI,LAI_METHOD,LAI_2000 -US-Ho1,24872,GRP_LAI,LAI_METHOD,LAI_2000 -US-Ho1,24990,GRP_LAI,LAI_METHOD,LAI_2000 -US-Ho1,25127,GRP_LAI,LAI_METHOD,LAI_2000 -US-Ho1,23843,GRP_LAI,LAI_DATE,20060425 -US-Ho1,24742,GRP_LAI,LAI_DATE,20060511 -US-Ho1,23975,GRP_LAI,LAI_DATE,20060601 -US-Ho1,25127,GRP_LAI,LAI_DATE,20060627 -US-Ho1,24872,GRP_LAI,LAI_DATE,20060802 -US-Ho1,24485,GRP_LAI,LAI_DATE,20060913 -US-Ho1,24990,GRP_LAI,LAI_DATE,20061213 -US-Ho1,23843,GRP_LAI,LAI_COMMENT,"200 m transect measured every 10m; L = ((1-alpha)*L-sube*Gamma-subE)/(Omega-subE); alpha=0.15, gamma=1.6,omega=0.98" -US-Ho1,23975,GRP_LAI,LAI_COMMENT,"200 m transect measured every 10m; L = ((1-alpha)*L-sube*Gamma-subE)/(Omega-subE); alpha=0.15, gamma=1.6,omega=0.98" -US-Ho1,24485,GRP_LAI,LAI_COMMENT,"200 m transect measured every 10m; L = ((1-alpha)*L-sube*Gamma-subE)/(Omega-subE); alpha=0.15, gamma=1.6,omega=0.98" -US-Ho1,24742,GRP_LAI,LAI_COMMENT,"200 m transect measured every 10m; L = ((1-alpha)*L-sube*Gamma-subE)/(Omega-subE); alpha=0.15, gamma=1.6,omega=0.98" -US-Ho1,24872,GRP_LAI,LAI_COMMENT,"200 m transect measured every 10m; L = ((1-alpha)*L-sube*Gamma-subE)/(Omega-subE); alpha=0.15, gamma=1.6,omega=0.98" -US-Ho1,24990,GRP_LAI,LAI_COMMENT,"200 m transect measured every 10m; L = ((1-alpha)*L-sube*Gamma-subE)/(Omega-subE); alpha=0.15, gamma=1.6,omega=0.98" -US-Ho1,25127,GRP_LAI,LAI_COMMENT,"200 m transect measured every 10m; L = ((1-alpha)*L-sube*Gamma-subE)/(Omega-subE); alpha=0.15, gamma=1.6,omega=0.98" -US-Ho1,24990,GRP_LAI,LAI_TOT,4.6 -US-Ho1,23843,GRP_LAI,LAI_TOT,4.7 -US-Ho1,24742,GRP_LAI,LAI_TOT,4.7 -US-Ho1,23975,GRP_LAI,LAI_TOT,5.3 -US-Ho1,24872,GRP_LAI,LAI_TOT,5.6 -US-Ho1,25127,GRP_LAI,LAI_TOT,5.7 -US-Ho1,24485,GRP_LAI,LAI_TOT,5.8 -US-Ho1,11453,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -US-Ho1,11453,GRP_LAND_OWNERSHIP,LAND_OWNER,Northeast Wilderness Trust -US-Ho1,24860,GRP_LMA,LMA,226 -US-Ho1,24860,GRP_LMA,LMA_SPP,(All) -US-Ho1,24860,GRP_LMA,LMA_DATE,19990729 -US-Ho1,11454,GRP_LOCATION,LOCATION_LAT,45.2041 -US-Ho1,11454,GRP_LOCATION,LOCATION_LONG,-68.7402 -US-Ho1,11454,GRP_LOCATION,LOCATION_ELEV,60 -US-Ho1,11454,GRP_LOCATION,LOCATION_COMMENT,ftp://cdiac.ornl.gov/pub/ameriflux/data/Level1/Sites_ByName/Howland_Forest_Main/readme -US-Ho1,24661,GRP_N_DEP,N_DEP_WET,0.6 -US-Ho1,11455,GRP_NETWORK,NETWORK,AmeriFlux -US-Ho1,87083,GRP_NETWORK,NETWORK,Phenocam -US-Ho1,1700005250,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Arain, M. A., Restrepo-Coupe, N. (2005) Net Ecosystem Production In A Temperate Pine Plantation In Southeastern Canada, Agricultural And Forest Meteorology, 128(3-4), 223-241" -US-Ho1,1700005250,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2004.10.003 -US-Ho1,1700005250,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ho1,1700004509,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Barr, A., Richardson, A., Hollinger, D., Papale, D., Arain, M., Black, T., Bohrer, G., Dragoni, D., Fischer, M., Gu, L., Law, B., Margolis, H., McCaughey, J., Munger, J., Oechel, W., Schaeffer, K. (2013) Use Of Change-Point Detection For Friction–Velocity Threshold Evaluation In Eddy-Covariance Studies, Agricultural And Forest Meteorology, 171-172(7458), 31-45" -US-Ho1,1700004509,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2012.11.023 -US-Ho1,1700004509,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ho1,1700006912,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Bohrer, G., Steiner, A.L., Hollinger, D.Y., Suyker, A., Phillips, R.P., Nadelhoffer, K.J. (2015) Variations in the influence of diffuse light on gross primary productivity in temperate ecosystems, Agricultural & Forest Meteorology, 201(), 98-110" -US-Ho1,1700006912,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2014.11.002 -US-Ho1,1700006912,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ho1,1700000159,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(2), 108350" -US-Ho1,1700000159,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -US-Ho1,1700000159,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ho1,1700008637,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Davidson, E. A., Janssens, I. A., Luo, Y. (2006) On The Variability Of Respiration In Terrestrial Ecosystems: Moving Beyond Q10, Global Change Biology, 12(2), 154-164" -US-Ho1,1700008637,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/J.1365-2486.2005.01065.X -US-Ho1,1700008637,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ho1,1700008646,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Davidson, E. A., Richardson, A. D., Savage, K. E., Hollinger, D. Y. (2006) A Distinct Seasonal Pattern Of The Ratio Of Soil Respiration To Total Ecosystem Respiration In A Spruce-Dominated Forest, Global Change Biology, 12(2), 230-239" -US-Ho1,1700008646,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/J.1365-2486.2005.01062.X -US-Ho1,1700008646,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ho1,1700005892,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Davidson, E., Savage, K., Bolstad, P., Clark, D., Curtis, P., Ellsworth, D., Hanson, P., Law, B., Luo, Y., Pregitzer, K., Randolph, J., Zak, D. (2002) Belowground Carbon Allocation In Forests Estimated From Litterfall And IRGA-Based Soil Respiration Measurements, Agricultural And Forest Meteorology, 113(1-4), 39-51" -US-Ho1,1700005892,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/S0168-1923(02)00101-6 -US-Ho1,1700005892,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ho1,1700006078,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Davidson, E., Savage, K., Verchot, L., Navarro, R. (2002) Minimizing Artifacts And Biases In Chamber-Based Measurements Of Soil Respiration, Agricultural And Forest Meteorology, 113(1-4), 21-37" -US-Ho1,1700006078,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/S0168-1923(02)00100-4 -US-Ho1,1700006078,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ho1,1700003471,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Dennis Baldocchi, Cove Sturtevant (2015) Does day and night sampling reduce spurious correlation between canopy photosynthesis and ecosystem respiration?, Agricultural and Forest Meteorology, 207(1-2), 117-126" -US-Ho1,1700003471,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2015.03.010 -US-Ho1,1700003471,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ho1,1700006408,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Falge, E., Baldocchi, D., Tenhunen, J., Aubinet, M., Bakwin, P., Berbigier, P., Bernhofer, C., Burba, G., Clement, R., Davis, K. J., Elbers, J. A., Goldstein, A. H., Grelle, A., Granier, A., Guðmundsson, J., Hollinger, D., Kowalski, A. S., Katul, G., Law, B. E., Malhi, Y., Meyers, T., Monson, R. K., Munger, J., Oechel, W., Paw U, K. T., Pilegaard, K., Rannik, Ü., Rebmann, C., Suyker, A., Valentini, R., Wilson, K., Wofsy, S. (2002) Seasonality Of Ecosystem Respiration And Gross Primary Production As Derived From FLUXNET Measurements, Agricultural And Forest Meteorology, 113(1-4), 53-74" -US-Ho1,1700006408,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/S0168-1923(02)00102-8 -US-Ho1,1700006408,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ho1,1700002019,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Fernandez, I. J., Rustad, L. E., Lawrence, G. B. (1993) Estimating Total Soil Mass, Nutrient Content, And Trace Metals In Soils Under A Low Elevation Spruce-Fir Forest, Canadian Journal Of Soil Science, 73(3), 317-328" -US-Ho1,1700002019,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.4141/CJSS93-034 -US-Ho1,1700002019,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ho1,1700003585,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Guerrieri, R., Belmecheri, S., Ollinger, S. V., Asbjornsen, H., Jennings, K., Xiao, J., Stocker, B. D., Martin, M., Hollinger, D. Y., Bracho-Garrillo, R., Clark, K., Dore, S., Kolb, T., Munger, J. W., Novick, K., Richardson, A. D. (2019) Disentangling The Role Of Photosynthesis And Stomatal Conductance On Rising Forest Water-Use Efficiency, Proceedings Of The National Academy Of Sciences, 116(34), 16909-16914" -US-Ho1,1700003585,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1073/PNAS.1905912116 -US-Ho1,1700003585,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ho1,1700006825,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Hibbard, K. A., Law, B. E., Reichstein, M., Sulzman, J. (2005) An Analysis Of Soil Respiration Across Northern Hemisphere Temperate Ecosystems, Biogeochemistry, 73(1), 29-70" -US-Ho1,1700006825,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1007/S10533-004-2946-0 -US-Ho1,1700006825,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ho1,1700008703,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Hollinger, D. Y., Aber, J., Dail, B., Davidson, E. A., Goltz, S. M., Hughes, H., Leclerc, M. Y., Lee, J. T., Richardson, A. D., Rodrigues, C., Scott, N., Achuatavarier, D., Walsh, J. (2004) Spatial And Temporal Variability In Forest-Atmosphere CO2 Exchange, Global Change Biology, 10(10), 1689-1706" -US-Ho1,1700008703,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/J.1365-2486.2004.00847.X -US-Ho1,1700008703,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ho1,1700007506,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Hollinger, D. Y., Goltz, S. M., Davidson, E. A., Lee, J. T., Tu, K., Valentine, H. T. (1999) Seasonal Patterns And Environmental Control Of Carbon Dioxide And Water Vapour Exchange In An Ecotonal Boreal Forest, Global Change Biology, 5(8), 891-902" -US-Ho1,1700007506,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1046/J.1365-2486.1999.00281.X -US-Ho1,1700007506,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ho1,1700007515,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Keenan, T. F., Hollinger, D. Y., Bohrer, G., Dragoni, D., Munger, J. W., Schmid, H. P., Richardson, A. D. (2013) Increase In Forest Water-Use Efficiency As Atmospheric Carbon Dioxide Concentrations Rise, Nature, 499(7458), 324-327" -US-Ho1,1700007515,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1038/NATURE12291 -US-Ho1,1700007515,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ho1,1700005913,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Lai, C., Ehleringer, J. R., Tans, P., Wofsy, S. C., Urbanski, S. P., Hollinger, D. Y. (2004) Estimating Photosynthetic C-13 Discrimination In Terrestrial CO2 Exchange From Canopy To Regional Scales, Global Biogeochemical Cycles, 18(1), n/a-n/a" -US-Ho1,1700005913,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2003GB002148 -US-Ho1,1700005913,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ho1,1700003366,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Matheny, A. M., Bohrer, G., Stoy, P. C., Baker, I. T., Black, A. T., Desai, A. R., Dietze, M. C., Gough, C. M., Ivanov, V. Y., Jassal, R. S., Novick, K. A., Schäfer, K. V., Verbeeck, H. (2014) Characterizing The Diurnal Patterns of Errors in The Prediction of Evapotranspiration by Several Land-Surface Models: An Nacp Analysis, Journal Of Geophysical Research: Biogeosciences, 119(7), 1458-1473" -US-Ho1,1700003366,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/2014JG002623 -US-Ho1,1700003366,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ho1,1700003030,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Raczka, B., Biraud, S. C., Ehleringer, J. R., Lai, C., Miller, J. B., Pataki, D. E., Saleska, S. R., Torn, M. S., Vaughn, B. H., Wehr, R., Bowling, D. R. (2017) Does Vapor Pressure Deficit Drive The Seasonality Of δ13C Of The Net Land-Atmosphere Co2 Exchange Across The United States?, Journal Of Geophysical Research: Biogeosciences, 122(8), 1969-1987" -US-Ho1,1700003030,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/2017JG003795 -US-Ho1,1700003030,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ho1,1700007758,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Richardson, A. D., Anderson, R. S., Arain, M. A., Barr, A. G., Bohrer, G., Chen, G., Chen, J. M., Ciais, P., Davis, K. J., Desai, A. R., Dietze, M. C., Dragoni, D., Garrity, S. R., Gough, C. M., Grant, R., Hollinger, D. Y., Margolis, H. A., McCaughey, H., Migliavacca, M., Monson, R. K., Munger, J. W., Poulter, B., Raczka, B. M., Ricciuto, D. M., Sahoo, A. K., Schaefer, K., Tian, H., Vargas, R., Verbeeck, H., Xiao, J., Xue, Y. (2012) Terrestrial Biosphere Models Need Better Representation Of Vegetation Phenology: Results From The North American Carbon Program Site Synthesis, Global Change Biology, 18(2), 566-584" -US-Ho1,1700007758,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/J.1365-2486.2011.02562.X -US-Ho1,1700007758,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ho1,1700008616,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Richardson, A. D., Hollinger, D. Y. (2005) Statistical Modeling Of Ecosystem Respiration Using Eddy Covariance Data: Maximum Likelihood Parameter Estimation, And Monte Carlo Simulation Of Model And Parameter Uncertainty, Applied To Three Simple Models, Agricultural And Forest Meteorology, 131(3-4), 191-208" -US-Ho1,1700008616,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2005.05.008 -US-Ho1,1700008616,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ho1,1700002427,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Richardson, A. D., Hollinger, D. Y., Burba, G. G., Davis, K. J., Flanagan, L. B., Katul, G. G., William Munger, J., Ricciuto, D. M., Stoy, P. C., Suyker, A. E., Verma, S. B., Wofsy, S. C. (2006) A Multi-Site Analysis Of Random Error In Tower-Based Measurements Of Carbon And Energy Fluxes, Agricultural And Forest Meteorology, 136(1-2), 1-18" -US-Ho1,1700002427,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2006.01.007 -US-Ho1,1700002427,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ho1,1700003486,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Savage, K. E., Davidson, E. A. (2001) Interannual Variation Of Soil Respiration In Two New England Forests, Global Biogeochemical Cycles, 15(2), 337-350" -US-Ho1,1700003486,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/1999GB001248 -US-Ho1,1700003486,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ho1,1700001230,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Sihi, D, Davidson, E.A., Chen, M, Savage, K.E., Richardson, A.D., Keenan, T.F., Hollinger, D. Y. (2018) Merging a mechanistic enzymatic model of soil heterotrophic respiration into an ecosystem model in two AmeriFlux sites of northeastern USA, Agricultural and Forest Meteorology, 252(1-2), 155-166" -US-Ho1,1700001230,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2018.01.026 -US-Ho1,1700001230,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ho1,1700003162,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Sihi, D, Davidson, E.A., Chen, M, Savage, K.E., Richardson, A.D., Keenan, T.F., Hollinger, D. Y. (2018) Merging a mechanistic enzymatic model of soil heterotrophic respiration into an ecosystem model in two AmeriFlux sites of northeastern USA, Agricultural and Forest Meteorology, 252(8), 155-166" -US-Ho1,1700003162,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2018.01.026 -US-Ho1,1700003162,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ho1,1700004221,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Sims, D. A., Rahman, A. F., Cordova, V. D., Baldocchi, D. D., Flanagan, L. B., Goldstein, A. H., Hollinger, D. Y., Misson, L., Monson, R. K., Schmid, H. P., Wofsy, S. C., Xu, L. (2005) Midday Values Of Gross CO2 Flux And Light Use Efficiency During Satellite Overpasses Can Be Used To Directly Estimate Eight-Day Mean Flux, Agricultural And Forest Meteorology, 131(1-2), 1-12" -US-Ho1,1700004221,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2005.04.006 -US-Ho1,1700004221,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ho1,1700004404,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Thornton, P., Law, B., Gholz, H. L., Clark, K. L., Falge, E., Ellsworth, D., Goldstein, A., Monson, R., Hollinger, D., Falk, M., Chen, J., Sparks, J. (2002) Modeling And Measuring The Effects Of Disturbance History And Climate On Carbon And Water Budgets In Evergreen Needleleaf Forests, Agricultural And Forest Meteorology, 113(1-4), 185-222" -US-Ho1,1700004404,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/S0168-1923(02)00108-9 -US-Ho1,1700004404,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ho1,1700001710,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Toomey, M., Friedl, M. A., Frolking, S., Hufkens, K., Klosterman, S., Sonnentag, O., Baldocchi, D. D., Bernacchi, C. J., Biraud, S. C., Bohrer, G., Brzostek, E., Burns, S. P., Coursolle, C., Hollinger, D. Y., Margolis, H. A., McCaughey, H., Monson, R. K., Munger, J. W., Pallardy, S., Phillips, R. P., Torn, M. S., Wharton, S., Zeri, M., Richardson, A. D. (2015) Greenness Indices From Digital Cameras Predict The Timing And Seasonal Dynamics Of Canopy-Scale Photosynthesis, Ecological Applications, 25(1), 99-115" -US-Ho1,1700001710,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1890/14-0005.1 -US-Ho1,1700001710,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ho1,1700002865,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Wolf, S., Keenan, T.F., Fisher, J.B., Baldocchi, D.D., Desai, A.R., Richardson, A.D., Scott, R.L., Law, B.E., Litvak, M.E., Brunsell, N.A., Peters, W., van der Laan-Luijkx, I.T. (2016) Warm spring reduced carbon cycle impact of the 2012 US summer drought, Proceedings of the National Academy of Sciences, 113(21), 5880-5885" -US-Ho1,1700002865,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1073/PNAS.1519620113 -US-Ho1,1700002865,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ho1,1700003108,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Xiao, X., Hollinger, D., Aber, J., Goltz, M., Davidson, E. A., Zhang, Q., Moore, B. (2004) Satellite-Based Modeling Of Gross Primary Production In An Evergreen Needleleaf Forest, Remote Sensing Of Environment, 89(4), 519-534" -US-Ho1,1700003108,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.RSE.2003.11.008 -US-Ho1,1700003108,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ho1,1700006765,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Xiao, X., Zhang, Q., Hollinger, D., Aber, J., Moore, B. (2005) Modeling Gross Primary Production Of An Evergreen Needleleaf Forest Using Modis And Climate Data, Ecological Applications, 15(3), 954-969" -US-Ho1,1700006765,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1890/04-0470 -US-Ho1,1700006765,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ho1,1700008223,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Xu, B., Arain, M. A., Black, T. A., Law, B. E., Pastorello, G. Z., Chu, H. (2020) Seasonal Variability Of Forest Sensitivity To Heat And Drought Stresses: A Synthesis Based On Carbon Fluxes From North American Forest Ecosystems, Global Change Biology, 26(2), 901-918" -US-Ho1,1700008223,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/GCB.14843 -US-Ho1,1700008223,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ho1,1700000141,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Zscheischler, J., Fatichi, S., Wolf, S., Blanken, P., Bohrer, G., Clark, K., Desai, A., Hollinger, D., Keenan, T., Novick, K.A., Seneviratne, S.I. (2016) Short-term favorable weather conditions are an important control of interannual variability in carbon and water fluxes, Journal of Geophysical Research - Biogeosciences, 121(8), 2186-2198" -US-Ho1,1700000141,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/2016JG003503 -US-Ho1,1700000141,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ho1,11457,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"Carbon balance * Influence of environmental variables on C-exchange * Soil processes * Isotopic fractionation * Scaling to the region CO2, H2O, sensible heat, and momentum fluxes at 25 and 3 m above the ground *" -US-Ho1,24624,GRP_ROOT_BIOMASS,ROOT_BIOMASS_TOT,1800 -US-Ho1,24624,GRP_ROOT_BIOMASS,ROOT_BIOMASS_UNIT,gC m-2 -US-Ho1,24624,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MIN,0 -US-Ho1,24624,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MAX,9000 -US-Ho1,24624,GRP_ROOT_BIOMASS,ROOT_BIOMASS_APPROACH,"Quantitative soil pit, see Fernandez et al. 1993" -US-Ho1,24624,GRP_ROOT_BIOMASS,ROOT_BIOMASS_DATE,1987 -US-Ho1,24624,GRP_ROOT_BIOMASS,ROOT_BIOMASS_COMMENT,to ~0.9 m; 54% in O horizon for details see Fernandez et al. (1993) Can. J. Soil Sci 73:317-28 -US-Ho1,24726,GRP_SA,SA_DATE,2008 -US-Ho1,24726,GRP_SA,SA_COMMENT,some trees survived 1820 fire -US-Ho1,24726,GRP_SA,SA_MAX,214 -US-Ho1,24970,GRP_SA,SA,109 -US-Ho1,24970,GRP_SA,SA_DATE,2008 -US-Ho1,24970,GRP_SA,SA_COMMENT,mean age of all trees >4 inches DBH -US-Ho1,14814,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"University of Maine, Environmental Sciences Lab, Room 103, Orono, ME 04469" -US-Ho1,11458,GRP_SITE_DESC,SITE_DESC,"Closed conifer forest, minimal disturbance. References: Fernandez et al. (1993), Canadian Journal of Soil Science 73 317-328. Hollinger et al. (1999), Global Change Biology 5: 891-902. Savage KE, Davidson EA (2001), Global Biogeochemical Cycles 15 337-350. Scott et al. (2004), Environmental Management, Vol. 33, Supplement 1, pp. S9-S22. Hollinger et al. (2004), Global Change Biology 10: 1689-1706." -US-Ho1,11459,GRP_SITE_FUNDING,SITE_FUNDING,"DOE/NIGEC, USDA Forest Service" -US-Ho1,23721,GRP_SNAG_MASS,SNAG_MASS,1080 -US-Ho1,23721,GRP_SNAG_MASS,SNAG_MASS_UNIT,gC m-2 -US-Ho1,25110,GRP_SOIL_CHEM,SOIL_CHEM_C_ORG,11 -US-Ho1,25111,GRP_SOIL_CHEM,SOIL_CHEM_C_ORG,19 -US-Ho1,24850,GRP_SOIL_CHEM,SOIL_CHEM_C_ORG,30 -US-Ho1,24211,GRP_SOIL_CHEM,SOIL_CHEM_C_ORG,44 -US-Ho1,24212,GRP_SOIL_CHEM,SOIL_CHEM_C_ORG,8 -US-Ho1,23845,GRP_SOIL_CHEM,SOIL_CHEM_N_TOT,0.3 -US-Ho1,24746,GRP_SOIL_CHEM,SOIL_CHEM_N_TOT,0.32 -US-Ho1,24879,GRP_SOIL_CHEM,SOIL_CHEM_N_TOT,0.68 -US-Ho1,24488,GRP_SOIL_CHEM,SOIL_CHEM_N_TOT,0.98 -US-Ho1,24211,GRP_SOIL_CHEM,SOIL_CHEM_N_TOT,1.03 -US-Ho1,24081,GRP_SOIL_CHEM,SOIL_CHEM_PH_SALT,2.8 -US-Ho1,25128,GRP_SOIL_CHEM,SOIL_CHEM_PH_SALT,3.2 -US-Ho1,24082,GRP_SOIL_CHEM,SOIL_CHEM_PH_SALT,4.2 -US-Ho1,24211,GRP_SOIL_CHEM,SOIL_CHEM_BD,0.14 -US-Ho1,25110,GRP_SOIL_CHEM,SOIL_CHEM_BD,0.65 -US-Ho1,24850,GRP_SOIL_CHEM,SOIL_CHEM_BD,0.89 -US-Ho1,24212,GRP_SOIL_CHEM,SOIL_CHEM_BD,1 -US-Ho1,25111,GRP_SOIL_CHEM,SOIL_CHEM_BD,1.39 -US-Ho1,24081,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,0 -US-Ho1,25128,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,10 -US-Ho1,24746,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,12.5 -US-Ho1,25110,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,12.5 -US-Ho1,24082,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,15 -US-Ho1,24488,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,17.5 -US-Ho1,24850,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,17.5 -US-Ho1,24879,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,50 -US-Ho1,25111,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,50 -US-Ho1,24081,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,10 -US-Ho1,23845,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,12.5 -US-Ho1,24212,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,12.5 -US-Ho1,25128,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,15 -US-Ho1,24746,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,17.5 -US-Ho1,25110,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,17.5 -US-Ho1,24488,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,52.5 -US-Ho1,24850,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,52.5 -US-Ho1,24082,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,65 -US-Ho1,24211,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,7.5 -US-Ho1,24879,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,90 -US-Ho1,25111,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,90 -US-Ho1,23845,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,Ae -US-Ho1,24212,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,Ae -US-Ho1,24211,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,O -US-Ho1,24081,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,Total -US-Ho1,24082,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,Total -US-Ho1,24488,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,Total -US-Ho1,24746,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,Total -US-Ho1,24850,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,Total -US-Ho1,24879,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,Total -US-Ho1,25110,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,Total -US-Ho1,25111,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,Total -US-Ho1,25128,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,Total -US-Ho1,23845,GRP_SOIL_CHEM,SOIL_CHEM_DATE,1987 -US-Ho1,24081,GRP_SOIL_CHEM,SOIL_CHEM_DATE,1987 -US-Ho1,24082,GRP_SOIL_CHEM,SOIL_CHEM_DATE,1987 -US-Ho1,24211,GRP_SOIL_CHEM,SOIL_CHEM_DATE,1987 -US-Ho1,24212,GRP_SOIL_CHEM,SOIL_CHEM_DATE,1987 -US-Ho1,24488,GRP_SOIL_CHEM,SOIL_CHEM_DATE,1987 -US-Ho1,24746,GRP_SOIL_CHEM,SOIL_CHEM_DATE,1987 -US-Ho1,24850,GRP_SOIL_CHEM,SOIL_CHEM_DATE,1987 -US-Ho1,24879,GRP_SOIL_CHEM,SOIL_CHEM_DATE,1987 -US-Ho1,25110,GRP_SOIL_CHEM,SOIL_CHEM_DATE,1987 -US-Ho1,25111,GRP_SOIL_CHEM,SOIL_CHEM_DATE,1987 -US-Ho1,25128,GRP_SOIL_CHEM,SOIL_CHEM_DATE,1987 -US-Ho1,25128,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,A-horizon -US-Ho1,24082,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,B-horizon -US-Ho1,24211,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,for details see Fernandez et al. (1993) Can. J. Soil Sci 73:317-28 -US-Ho1,24212,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,for details see Fernandez et al. (1993) Can. J. Soil Sci 73:317-28 -US-Ho1,24850,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,for details see Fernandez et al. (1993) Can. J. Soil Sci 73:317-28 -US-Ho1,25110,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,for details see Fernandez et al. (1993) Can. J. Soil Sci 73:317-28 -US-Ho1,25111,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,for details see Fernandez et al. (1993) Can. J. Soil Sci 73:317-28 -US-Ho1,24081,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,organic layer -US-Ho1,28812,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION,"Soils throughout the forest are glacial tills, acid in reaction, with low fertility and high organic composition. Upland soils are fine sandy loams, classified as Aquic Haplorthods." -US-Ho1,28812,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION_TAXONOMY,Other -US-Ho1,24882,GRP_SOIL_DEPTH,SOIL_DEPTH,80 -US-Ho1,24882,GRP_SOIL_DEPTH,SOIL_DEPTH_DATE,2008 -US-Ho1,24853,GRP_SOIL_TEX,SOIL_TEX_WATER_HOLD_CAP,100 -US-Ho1,24853,GRP_SOIL_TEX,SOIL_TEX_HORIZON,Total -US-Ho1,24853,GRP_SOIL_TEX,SOIL_TEX_DATE,2008 -US-Ho1,23971,GRP_SPP_O,SPP_O,PIRU (NRCS plant code) -US-Ho1,25126,GRP_SPP_O,SPP_O,TSCA (NRCS plant code) -US-Ho1,25126,GRP_SPP_O,SPP_O_PERC,25 -US-Ho1,23971,GRP_SPP_O,SPP_O_PERC,41 -US-Ho1,23971,GRP_SPP_O,SPP_APPROACH,"FIA Inventory plots at 30 degree radii around tower with subplots located at 50, 100, 200, and 400 m distant from tower" -US-Ho1,25126,GRP_SPP_O,SPP_APPROACH,"FIA Inventory plots at 30 degree radii around tower with subplots located at 50, 100, 200, and 400 m distant from tower" -US-Ho1,23971,GRP_SPP_O,SPP_DATE,1998 -US-Ho1,25126,GRP_SPP_O,SPP_DATE,1998 -US-Ho1,11460,GRP_STATE,STATE,ME -US-Ho1,22350,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,David Hollinger -US-Ho1,22350,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Ho1,22350,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,David.Hollinger@unh.edu -US-Ho1,22350,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,USDA Forest Service -US-Ho1,22350,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Northeastern Forest Exp. Station, 271 Mast Rd, Durham, NH USA 03824" -US-Ho1,81386,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Holly Hughes -US-Ho1,81386,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,DataManager -US-Ho1,81386,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,holly.hughes@maine.edu -US-Ho1,81386,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Maine -US-Ho1,81386,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"University of Maine, CRSF, 103 Environmental Sciences Lab, Orono, ME 04469" -US-Ho1,83403,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Robert Evans -US-Ho1,83403,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Technician -US-Ho1,83403,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,robertevans@fs.fed.us -US-Ho1,83403,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,USDA Forest Service -US-Ho1,83403,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Northeastern Forest Exp. Station, 271 Mast Rd., Durham, NH USA 03824" -US-Ho1,22351,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Aaron Teets -US-Ho1,22351,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Affiliate -US-Ho1,22351,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,aaron.teets@maine.edu -US-Ho1,22351,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Maine -US-Ho1,22351,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"5755 Nutting Hall, University of Maine, Orono, ME 04461" -US-Ho1,84729,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Andrew Richardson -US-Ho1,84729,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Affiliate -US-Ho1,84729,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,Andrew.richardson@nau.edu -US-Ho1,84729,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Northern Arizona University -US-Ho1,91422,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,John Lee -US-Ho1,91422,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Affiliate -US-Ho1,91422,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,jtlee@maine.edu -US-Ho1,91422,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Maine -US-Ho1,91422,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Orono, Maine" -US-Ho1,29813,GRP_TOWER_POWER,TOWER_POWER,Direct power -US-Ho1,11448,GRP_TOWER_TYPE,TOWER_TYPE,walk-up -US-Ho1,11462,GRP_URL,URL,http://howlandforest.org/site_files/site.html -US-Ho1,24000373,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-Ho1 -US-Ho1,11463,GRP_UTC_OFFSET,UTC_OFFSET,-5 -US-Ho1,23720,GRP_WD_BIOMASS,WD_BIOMASS_CRS,410 -US-Ho1,23720,GRP_WD_BIOMASS,WD_BIOMASS_UNIT,gC m-2 -US-Ho1,23720,GRP_WD_BIOMASS,WD_BIOMASS_DATE,19990729 -US-Ho1,23720,GRP_WD_BIOMASS,WD_BIOMASS_COMMENT,aproximate date of measurement -US-Ho2,25124,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,1150 -US-Ho2,25124,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Foliage -US-Ho2,25124,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-Ho2,25124,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-Ho2,25124,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,Hollinger et al. 2004 -US-Ho2,25124,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,20030719 -US-Ho2,25124,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,Hollinger et al. 2004 -US-Ho2,24474,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,13050 -US-Ho2,24474,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Wood -US-Ho2,24474,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-Ho2,24474,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-Ho2,24474,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,Hollinger et al. 2004 -US-Ho2,24474,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,20030719 -US-Ho2,24474,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,Hollinger et al. 2004 -US-Ho2,24603,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,15100 -US-Ho2,24603,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Total -US-Ho2,24603,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-Ho2,24603,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-Ho2,24603,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,Hollinger et al. 2004 -US-Ho2,24603,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,20030719 -US-Ho2,24603,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,Hollinger et al. 2004 -US-Ho2,24744,GRP_AG_LIT_CHEM,AG_LIT_N,0.12 -US-Ho2,24744,GRP_AG_LIT_CHEM,AG_LIT_DATE,20030818 -US-Ho2,23701,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT,150 -US-Ho2,23701,GRP_AG_LIT_PROD,AG_LIT_PROD_UNIT,gC m-2 -US-Ho2,23701,GRP_AG_LIT_PROD,AG_LIT_PROD_COMMENT,same as Main (US-Ho1) -US-Ho2,23963,GRP_BIOMASS_CHEM,BIOMASS_C,4.7 -US-Ho2,24597,GRP_BIOMASS_CHEM,BIOMASS_N,0.0061 -US-Ho2,25005,GRP_BIOMASS_CHEM,BIOMASS_N,0.093 -US-Ho2,25006,GRP_BIOMASS_CHEM,BIOMASS_N,0.096 -US-Ho2,24214,GRP_BIOMASS_CHEM,BIOMASS_N,0.106 -US-Ho2,24249,GRP_BIOMASS_CHEM,BIOMASS_N,0.11 -US-Ho2,24637,GRP_BIOMASS_CHEM,BIOMASS_N,0.123 -US-Ho2,23963,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-Ho2,24214,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-Ho2,24249,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-Ho2,24597,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-Ho2,24637,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-Ho2,25005,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-Ho2,25006,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-Ho2,23963,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-Ho2,24214,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-Ho2,24249,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-Ho2,24597,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-Ho2,24637,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-Ho2,25005,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-Ho2,25006,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-Ho2,23963,GRP_BIOMASS_CHEM,BIOMASS_SPP,(All) -US-Ho2,24214,GRP_BIOMASS_CHEM,BIOMASS_SPP,(All) -US-Ho2,24597,GRP_BIOMASS_CHEM,BIOMASS_SPP,(All) -US-Ho2,25005,GRP_BIOMASS_CHEM,BIOMASS_SPP,PIRU (NRCS plant code) -US-Ho2,25006,GRP_BIOMASS_CHEM,BIOMASS_SPP,PIRU (NRCS plant code) -US-Ho2,24249,GRP_BIOMASS_CHEM,BIOMASS_SPP,TSCA (NRCS plant code) -US-Ho2,24637,GRP_BIOMASS_CHEM,BIOMASS_SPP,TSCA (NRCS plant code) -US-Ho2,23963,GRP_BIOMASS_CHEM,BIOMASS_DATE,19990818 -US-Ho2,24597,GRP_BIOMASS_CHEM,BIOMASS_DATE,20030818 -US-Ho2,24249,GRP_BIOMASS_CHEM,BIOMASS_COMMENT,10degrees-250degrees; Different concentrations in different sectors. -US-Ho2,25005,GRP_BIOMASS_CHEM,BIOMASS_COMMENT,10degrees-250degrees; Different concentrations in different sectors. -US-Ho2,24637,GRP_BIOMASS_CHEM,BIOMASS_COMMENT,250degrees-10degrees; Different concentrations in different sectors. -US-Ho2,25006,GRP_BIOMASS_CHEM,BIOMASS_COMMENT,250degrees-10degrees; Different concentrations in different sectors. -US-Ho2,24597,GRP_BIOMASS_CHEM,BIOMASS_COMMENT,heart wood -US-Ho2,23963,GRP_BIOMASS_CHEM,BIOMASS_COMMENT,same as Main (US-Ho1) -US-Ho2,11481,GRP_CLIM_AVG,MAT,5.13 -US-Ho2,11481,GRP_CLIM_AVG,MAP,1064 -US-Ho2,11481,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfb -US-Ho2,27000374,GRP_COUNTRY,COUNTRY,USA -US-Ho2,7773,GRP_DM_FIRE,DM_FIRE,Nature induced burn -US-Ho2,7773,GRP_DM_FIRE,DM_DATE,1820 -US-Ho2,7773,GRP_DM_FIRE,DM_COMMENT,medium; some single tree harvest > 60 years ago -US-Ho2,15673,GRP_DOI,DOI,10.17190/AMF/1246062 -US-Ho2,15673,GRP_DOI,DOI_CITATION,"David Hollinger (2021), AmeriFlux BASE US-Ho2 Howland Forest (west tower), Ver. 4-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1246062" -US-Ho2,15673,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-Ho2,32070,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Ho2,32070,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,David Hollinger -US-Ho2,32070,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Ho2,32070,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,David.Hollinger@unh.edu -US-Ho2,32070,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,USDA Forest Service -US-Ho2,32072,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,USDA Forest Service -US-Ho2,32072,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-Ho2,32071,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,DOE/TCP -US-Ho2,32071,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-Ho2,11482,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Fire -US-Ho2,11483,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Ho2,11483,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-Ho2,11483,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,1999 -US-Ho2,11483,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Ho2,91456,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Ho2,91456,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-Ho2,91456,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,1999 -US-Ho2,91456,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Ho2,91456,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,FLUX_MEASUREMENTS_COMMENT -US-Ho2,91458,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Ho2,91458,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-Ho2,91458,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,1999 -US-Ho2,91458,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Ho2,91458,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,FLUX_MEASUREMENTS_COMMENT -US-Ho2,23000374,GRP_HEADER,SITE_NAME,Howland Forest (west tower) -US-Ho2,24712,GRP_HEIGHTC,HEIGHTC,20 -US-Ho2,24712,GRP_HEIGHTC,HEIGHTC_DATE,1999 -US-Ho2,24712,GRP_HEIGHTC,HEIGHTC_COMMENT,emergent PIST -US-Ho2,11484,GRP_IGBP,IGBP,ENF -US-Ho2,11484,GRP_IGBP,IGBP_COMMENT,"~90% ENF and 10% BDF in 1km around tower. Across region forest type is mixed ENF, DBF (no type>60%)." -US-Ho2,24342,GRP_LAI,LAI_TYPE,LAI -US-Ho2,24343,GRP_LAI,LAI_TYPE,LAI -US-Ho2,24486,GRP_LAI,LAI_TYPE,LAI -US-Ho2,24611,GRP_LAI,LAI_TYPE,LAI -US-Ho2,24612,GRP_LAI,LAI_TYPE,LAI -US-Ho2,24613,GRP_LAI,LAI_TYPE,LAI -US-Ho2,24991,GRP_LAI,LAI_TYPE,LAI -US-Ho2,24486,GRP_LAI,LAI_CLUMP,1.6 -US-Ho2,24342,GRP_LAI,LAI_METHOD,LAI_2000 -US-Ho2,24343,GRP_LAI,LAI_METHOD,LAI_2000 -US-Ho2,24486,GRP_LAI,LAI_METHOD,LAI_2000 -US-Ho2,24611,GRP_LAI,LAI_METHOD,LAI_2000 -US-Ho2,24612,GRP_LAI,LAI_METHOD,LAI_2000 -US-Ho2,24613,GRP_LAI,LAI_METHOD,LAI_2000 -US-Ho2,24991,GRP_LAI,LAI_METHOD,LAI_2000 -US-Ho2,24486,GRP_LAI,LAI_DATE,20060425 -US-Ho2,24611,GRP_LAI,LAI_DATE,20060511 -US-Ho2,24991,GRP_LAI,LAI_DATE,20060601 -US-Ho2,24613,GRP_LAI,LAI_DATE,20060626 -US-Ho2,24342,GRP_LAI,LAI_DATE,20060801 -US-Ho2,24343,GRP_LAI,LAI_DATE,20060912 -US-Ho2,24612,GRP_LAI,LAI_DATE,20061212 -US-Ho2,24342,GRP_LAI,LAI_COMMENT,"200 m transect measured every 10m; L = ((1-alpha)*L-sube*Gamma-subE)/(Omega-subE); alpha=0.15, gamma=1.6,omega=0.98; Transect runs between Main and West towers" -US-Ho2,24343,GRP_LAI,LAI_COMMENT,"200 m transect measured every 10m; L = ((1-alpha)*L-sube*Gamma-subE)/(Omega-subE); alpha=0.15, gamma=1.6,omega=0.98; Transect runs between Main and West towers" -US-Ho2,24486,GRP_LAI,LAI_COMMENT,"200 m transect measured every 10m; L = ((1-alpha)*L-sube*Gamma-subE)/(Omega-subE); alpha=0.15, gamma=1.6,omega=0.98; Transect runs between Main and West towers" -US-Ho2,24611,GRP_LAI,LAI_COMMENT,"200 m transect measured every 10m; L = ((1-alpha)*L-sube*Gamma-subE)/(Omega-subE); alpha=0.15, gamma=1.6,omega=0.98; Transect runs between Main and West towers" -US-Ho2,24612,GRP_LAI,LAI_COMMENT,"200 m transect measured every 10m; L = ((1-alpha)*L-sube*Gamma-subE)/(Omega-subE); alpha=0.15, gamma=1.6,omega=0.98; Transect runs between Main and West towers" -US-Ho2,24613,GRP_LAI,LAI_COMMENT,"200 m transect measured every 10m; L = ((1-alpha)*L-sube*Gamma-subE)/(Omega-subE); alpha=0.15, gamma=1.6,omega=0.98; Transect runs between Main and West towers" -US-Ho2,24991,GRP_LAI,LAI_COMMENT,"200 m transect measured every 10m; L = ((1-alpha)*L-sube*Gamma-subE)/(Omega-subE); alpha=0.15, gamma=1.6,omega=0.98; Transect runs between Main and West towers" -US-Ho2,24612,GRP_LAI,LAI_TOT,4.6 -US-Ho2,24486,GRP_LAI,LAI_TOT,4.7 -US-Ho2,24611,GRP_LAI,LAI_TOT,4.7 -US-Ho2,24991,GRP_LAI,LAI_TOT,5.3 -US-Ho2,24342,GRP_LAI,LAI_TOT,5.6 -US-Ho2,24613,GRP_LAI,LAI_TOT,5.7 -US-Ho2,24343,GRP_LAI,LAI_TOT,5.8 -US-Ho2,11485,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -US-Ho2,11485,GRP_LAND_OWNERSHIP,LAND_OWNER,Northeast Wilderness Trust -US-Ho2,24983,GRP_LMA,LMA,226 -US-Ho2,24983,GRP_LMA,LMA_SPP,(All) -US-Ho2,24983,GRP_LMA,LMA_DATE,19990729 -US-Ho2,24983,GRP_LMA,LMA_COMMENT,same as Main (US-Ho1) -US-Ho2,94750,GRP_LOCATION,LOCATION_LAT,45.2091 -US-Ho2,94750,GRP_LOCATION,LOCATION_LONG,-68.7470 -US-Ho2,94750,GRP_LOCATION,LOCATION_ELEV,61 -US-Ho2,94750,GRP_LOCATION,LOCATION_COMMENT,masl; GTOPO30 Database using the 45.2091 and -68.7470 coordinates -US-Ho2,11487,GRP_NETWORK,NETWORK,AmeriFlux -US-Ho2,1700006435,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Baldocchi, D. D., Poindexter, C., Abraha, M., Desai, A. R., Bohrer, G., Arain, M. A., Griffis, T., Blanken, P. D., O'Halloran, T. L., Thomas, R. Q., Zhang, Q., Burns, S. P., Frank, J. M., Christian, D., Brown, S., Black, T. A., Gough, C. M., Law, B. E., Lee, X., Chen, J., Reed, D. E., Massman, W. J., Clark, K., Hatfield, J., Prueger, J., Bracho, R., Baker, J. M., Martin, T. A. (2018) Temporal Dynamics Of Aerodynamic Canopy Height Derived From Eddy Covariance Momentum Flux Data Across North American Flux Networks, Geophysical Research Letters, 45(3), 9275–9287" -US-Ho2,1700006435,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018GL079306 -US-Ho2,1700006435,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ho2,1700000786,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(3), 108350" -US-Ho2,1700000786,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -US-Ho2,1700000786,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ho2,1700006558,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Davidson, E. A., Richardson, A. D., Savage, K. E., Hollinger, D. Y. (2006) A Distinct Seasonal Pattern Of The Ratio Of Soil Respiration To Total Ecosystem Respiration In A Spruce-Dominated Forest, Global Change Biology, 12(2), 230-239" -US-Ho2,1700006558,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/J.1365-2486.2005.01062.X -US-Ho2,1700006558,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ho2,1700001797,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Dennis Baldocchi, Cove Sturtevant (2015) Does day and night sampling reduce spurious correlation between canopy photosynthesis and ecosystem respiration?, Agricultural and Forest Meteorology, 207(3), 117-126" -US-Ho2,1700001797,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2015.03.010 -US-Ho2,1700001797,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ho2,1700005562,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Richardson, A. D., Hollinger, D. Y. (2005) Statistical Modeling Of Ecosystem Respiration Using Eddy Covariance Data: Maximum Likelihood Parameter Estimation, And Monte Carlo Simulation Of Model And Parameter Uncertainty, Applied To Three Simple Models, Agricultural And Forest Meteorology, 131(3-4), 191-208" -US-Ho2,1700005562,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2005.05.008 -US-Ho2,1700005562,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ho2,1700003918,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Thornton, P., Law, B., Gholz, H. L., Clark, K. L., Falge, E., Ellsworth, D., Goldstein, A., Monson, R., Hollinger, D., Falk, M., Chen, J., Sparks, J. (2002) Modeling And Measuring The Effects Of Disturbance History And Climate On Carbon And Water Budgets In Evergreen Needleleaf Forests, Agricultural And Forest Meteorology, 113(1-4), 185-222" -US-Ho2,1700003918,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/S0168-1923(02)00108-9 -US-Ho2,1700003918,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ho2,1700006486,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Xiao, X., Hollinger, D., Aber, J., Goltz, M., Davidson, E. A., Zhang, Q., Moore, B. (2004) Satellite-Based Modeling Of Gross Primary Production In An Evergreen Needleleaf Forest, Remote Sensing Of Environment, 89(4), 519-534" -US-Ho2,1700006486,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.RSE.2003.11.008 -US-Ho2,1700006486,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ho2,1700001275,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Xiao, X., Zhang, Q., Hollinger, D., Aber, J., Moore, B. (2005) Modeling Gross Primary Production Of An Evergreen Needleleaf Forest Using Modis And Climate Data, Ecological Applications, 15(3), 954-969" -US-Ho2,1700001275,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1890/04-0470 -US-Ho2,1700001275,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ho2,11489,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,Carbon sequestration -US-Ho2,24625,GRP_ROOT_BIOMASS,ROOT_BIOMASS_TOT,1800 -US-Ho2,28564,GRP_ROOT_BIOMASS,ROOT_BIOMASS_TOT,1800 -US-Ho2,24625,GRP_ROOT_BIOMASS,ROOT_BIOMASS_UNIT,gC m-2 -US-Ho2,28564,GRP_ROOT_BIOMASS,ROOT_BIOMASS_UNIT,gC m-2 -US-Ho2,24625,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MIN,0 -US-Ho2,28564,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MIN,0 -US-Ho2,28564,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MAX,90 -US-Ho2,24625,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MAX,9000 -US-Ho2,24625,GRP_ROOT_BIOMASS,ROOT_BIOMASS_APPROACH,"Quantitative soil pit, see Fernandez et al. 1993" -US-Ho2,28564,GRP_ROOT_BIOMASS,ROOT_BIOMASS_APPROACH,"Quantitative soil pit, see Fernandez et al. 1993" -US-Ho2,24625,GRP_ROOT_BIOMASS,ROOT_BIOMASS_DATE,1987 -US-Ho2,28564,GRP_ROOT_BIOMASS,ROOT_BIOMASS_DATE,1987 -US-Ho2,28564,GRP_ROOT_BIOMASS,ROOT_BIOMASS_COMMENT,54% in O horizon; for details see Fernandez et al. (1993) Can. J. Soil Sci 73:317-28; Same as Main (US-Ho1) -US-Ho2,24625,GRP_ROOT_BIOMASS,ROOT_BIOMASS_COMMENT,to ~0.9 m; 54% in O horizon for details see Fernandez et al. (1993) Can. J. Soil Sci 73:317-28; Same as Main (US-Ho1) -US-Ho2,24457,GRP_SA,SA,109 -US-Ho2,24457,GRP_SA,SA_COMMENT,mean age of all trees >4 inches DBH -US-Ho2,24727,GRP_SA,SA_COMMENT,some trees survived 1820 fire -US-Ho2,24727,GRP_SA,SA_MAX,214 -US-Ho2,14848,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"University of Maine, Environmental Sciences Lab, Room 103, Orono, ME 04469" -US-Ho2,11491,GRP_SITE_DESC,SITE_DESC,"Closed conifer forest, minimal disturbance. References: Fernandez et al. (1993), Canadian Journal of Soil Science 73 317-328. Hollinger et al. (1999), Global Change Biology 5: 891-902. Savage KE, Davidson EA (2001), Global Biogeochemical Cycles 15 337-350. Scott et al. (2004), Environmental Management, Vol. 33, Supplement 1, pp. S9-S22. Hollinger et al. (2004), Global Change Biology 10: 1689-1706." -US-Ho2,11492,GRP_SITE_FUNDING,SITE_FUNDING,DOE/TCP -US-Ho2,23722,GRP_SNAG_MASS,SNAG_MASS,1080 -US-Ho2,23722,GRP_SNAG_MASS,SNAG_MASS_UNIT,gC m-2 -US-Ho2,23722,GRP_SNAG_MASS,SNAG_MASS_COMMENT,same as Main (US-Ho1) -US-Ho2,24062,GRP_SOIL_CHEM,SOIL_CHEM_C_ORG,11 -US-Ho2,23695,GRP_SOIL_CHEM,SOIL_CHEM_C_ORG,19 -US-Ho2,23694,GRP_SOIL_CHEM,SOIL_CHEM_C_ORG,30 -US-Ho2,24061,GRP_SOIL_CHEM,SOIL_CHEM_C_ORG,44 -US-Ho2,27596,GRP_SOIL_CHEM,SOIL_CHEM_C_ORG,44 -US-Ho2,24331,GRP_SOIL_CHEM,SOIL_CHEM_C_ORG,8 -US-Ho2,28319,GRP_SOIL_CHEM,SOIL_CHEM_C_ORG,8 -US-Ho2,24331,GRP_SOIL_CHEM,SOIL_CHEM_N_TOT,0.3 -US-Ho2,28319,GRP_SOIL_CHEM,SOIL_CHEM_N_TOT,0.3 -US-Ho2,24062,GRP_SOIL_CHEM,SOIL_CHEM_N_TOT,0.32 -US-Ho2,23695,GRP_SOIL_CHEM,SOIL_CHEM_N_TOT,0.68 -US-Ho2,23694,GRP_SOIL_CHEM,SOIL_CHEM_N_TOT,0.98 -US-Ho2,24061,GRP_SOIL_CHEM,SOIL_CHEM_N_TOT,1.03 -US-Ho2,27596,GRP_SOIL_CHEM,SOIL_CHEM_N_TOT,1.03 -US-Ho2,25129,GRP_SOIL_CHEM,SOIL_CHEM_PH_SALT,2.8 -US-Ho2,27053,GRP_SOIL_CHEM,SOIL_CHEM_PH_SALT,2.8 -US-Ho2,23715,GRP_SOIL_CHEM,SOIL_CHEM_PH_SALT,3.2 -US-Ho2,29162,GRP_SOIL_CHEM,SOIL_CHEM_PH_SALT,3.2 -US-Ho2,23716,GRP_SOIL_CHEM,SOIL_CHEM_PH_SALT,4.2 -US-Ho2,27054,GRP_SOIL_CHEM,SOIL_CHEM_PH_SALT,4.2 -US-Ho2,24061,GRP_SOIL_CHEM,SOIL_CHEM_BD,0.14 -US-Ho2,27596,GRP_SOIL_CHEM,SOIL_CHEM_BD,0.14 -US-Ho2,24062,GRP_SOIL_CHEM,SOIL_CHEM_BD,0.65 -US-Ho2,23694,GRP_SOIL_CHEM,SOIL_CHEM_BD,0.89 -US-Ho2,24331,GRP_SOIL_CHEM,SOIL_CHEM_BD,1 -US-Ho2,28319,GRP_SOIL_CHEM,SOIL_CHEM_BD,1 -US-Ho2,23695,GRP_SOIL_CHEM,SOIL_CHEM_BD,1.39 -US-Ho2,25129,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,0 -US-Ho2,27053,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,0 -US-Ho2,27596,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,0 -US-Ho2,28319,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,0 -US-Ho2,23715,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,10 -US-Ho2,29162,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,10 -US-Ho2,24062,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,12.5 -US-Ho2,23716,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,15 -US-Ho2,27054,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,15 -US-Ho2,23694,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,17.5 -US-Ho2,23695,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,50 -US-Ho2,25129,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,10 -US-Ho2,27053,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,10 -US-Ho2,24331,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,12.5 -US-Ho2,28319,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,12.5 -US-Ho2,23715,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,15 -US-Ho2,29162,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,15 -US-Ho2,24062,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,17.5 -US-Ho2,23694,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,52.5 -US-Ho2,23716,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,65 -US-Ho2,27054,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,65 -US-Ho2,24061,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,7.5 -US-Ho2,27596,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,7.5 -US-Ho2,23695,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,90 -US-Ho2,29162,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,A-horizon -US-Ho2,24331,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,Ae -US-Ho2,28319,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,Ae horizon -US-Ho2,27054,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,B-horizon -US-Ho2,24061,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,O -US-Ho2,27596,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,O horizon -US-Ho2,27053,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,organic layer -US-Ho2,23694,GRP_SOIL_CHEM,SOIL_CHEM_DATE,1987 -US-Ho2,23695,GRP_SOIL_CHEM,SOIL_CHEM_DATE,1987 -US-Ho2,23715,GRP_SOIL_CHEM,SOIL_CHEM_DATE,1987 -US-Ho2,23716,GRP_SOIL_CHEM,SOIL_CHEM_DATE,1987 -US-Ho2,24061,GRP_SOIL_CHEM,SOIL_CHEM_DATE,1987 -US-Ho2,24062,GRP_SOIL_CHEM,SOIL_CHEM_DATE,1987 -US-Ho2,24331,GRP_SOIL_CHEM,SOIL_CHEM_DATE,1987 -US-Ho2,25129,GRP_SOIL_CHEM,SOIL_CHEM_DATE,1987 -US-Ho2,27053,GRP_SOIL_CHEM,SOIL_CHEM_DATE,1987 -US-Ho2,27054,GRP_SOIL_CHEM,SOIL_CHEM_DATE,1987 -US-Ho2,27596,GRP_SOIL_CHEM,SOIL_CHEM_DATE,1987 -US-Ho2,28319,GRP_SOIL_CHEM,SOIL_CHEM_DATE,1987 -US-Ho2,29162,GRP_SOIL_CHEM,SOIL_CHEM_DATE,1987 -US-Ho2,23715,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,A-horizon; Same as Main (US-Ho1) -US-Ho2,23716,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,B-horizon; Same as Main (US-Ho1) -US-Ho2,23694,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,for details see Fernandez et al. (1993) Can. J. Soil Sci 73:317-28; Same as Main (US-Ho1) -US-Ho2,23695,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,for details see Fernandez et al. (1993) Can. J. Soil Sci 73:317-28; Same as Main (US-Ho1) -US-Ho2,24061,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,for details see Fernandez et al. (1993) Can. J. Soil Sci 73:317-28; Same as Main (US-Ho1) -US-Ho2,24062,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,for details see Fernandez et al. (1993) Can. J. Soil Sci 73:317-28; Same as Main (US-Ho1) -US-Ho2,24331,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,for details see Fernandez et al. (1993) Can. J. Soil Sci 73:317-28; Same as Main (US-Ho1) -US-Ho2,27596,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,for details see Fernandez et al. (1993) Can. J. Soil Sci 73:317-28; Same as Main (US-Ho1) -US-Ho2,28319,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,for details see Fernandez et al. (1993) Can. J. Soil Sci 73:317-28; Same as Main (US-Ho1) -US-Ho2,25129,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,organic layer; Same as Main (US-Ho1) -US-Ho2,27053,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,Same as Main (US-Ho1) -US-Ho2,27054,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,Same as Main (US-Ho1) -US-Ho2,29162,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,Same as Main (US-Ho1) -US-Ho2,28090,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION,"Soils throughout the forest are glacial tills, acid in reaction, with low fertility and high organic composition. Upland soils are fine sandy loams, classified as Aquic Haplorthods." -US-Ho2,28090,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION_TAXONOMY,Other -US-Ho2,25130,GRP_SOIL_DEPTH,SOIL_DEPTH,80 -US-Ho2,24978,GRP_SOIL_TEX,SOIL_TEX_WATER_HOLD_CAP,100 -US-Ho2,24076,GRP_SPP_O,SPP_O,PIRU (NRCS plant code) -US-Ho2,24478,GRP_SPP_O,SPP_O,TSCA (NRCS plant code) -US-Ho2,24478,GRP_SPP_O,SPP_O_PERC,25 -US-Ho2,24076,GRP_SPP_O,SPP_O_PERC,41 -US-Ho2,24076,GRP_SPP_O,SPP_APPROACH,"FIA Inventory plots at 30 degree radii around tower with subplots located at 50, 100, 200, and 400 m distant from tower" -US-Ho2,24478,GRP_SPP_O,SPP_APPROACH,"FIA Inventory plots at 30 degree radii around tower with subplots located at 50, 100, 200, and 400 m distant from tower" -US-Ho2,24076,GRP_SPP_O,SPP_DATE,1998 -US-Ho2,24478,GRP_SPP_O,SPP_DATE,1998 -US-Ho2,11493,GRP_STATE,STATE,ME -US-Ho2,22352,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,David Hollinger -US-Ho2,22352,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Ho2,22352,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,David.Hollinger@unh.edu -US-Ho2,22352,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,USDA Forest Service -US-Ho2,22352,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Northeastern Forest Exp. Station, 271 Mast Rd, Durham, NH USA 03824" -US-Ho2,81387,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Holly Hughes -US-Ho2,81387,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,DataManager -US-Ho2,81387,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,holly.hughes@maine.edu -US-Ho2,81387,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Maine -US-Ho2,81387,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Univ. of Maine, Center for Research Sustainable Forests, 103 Environmental Sciences Lab, Orono, ME 04469" -US-Ho2,91390,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,John Lee -US-Ho2,91390,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Technician -US-Ho2,91390,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,jtlee@maine.edu -US-Ho2,91390,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Maine -US-Ho2,91390,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Orono, ME" -US-Ho2,83404,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Robert Evans -US-Ho2,83404,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Technician -US-Ho2,83404,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,robertevans@fs.fed.us -US-Ho2,83404,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,USDA Forest Service -US-Ho2,83404,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Northeastern Forest Exp. Station, 271 Mast Rd., Durham, NH 03824" -US-Ho2,29816,GRP_TOWER_POWER,TOWER_POWER,Direct power -US-Ho2,11495,GRP_TOWER_TYPE,TOWER_TYPE,triangle -US-Ho2,11496,GRP_URL,URL,http://howlandforest.org/site_files/site.html -US-Ho2,24000374,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-Ho2 -US-Ho2,11497,GRP_UTC_OFFSET,UTC_OFFSET,-5 -US-Ho2,24748,GRP_WD_BIOMASS,WD_BIOMASS_CRS,410 -US-Ho2,24748,GRP_WD_BIOMASS,WD_BIOMASS_UNIT,gC m-2 -US-Ho2,24748,GRP_WD_BIOMASS,WD_BIOMASS_DATE,19990729 -US-Ho2,24748,GRP_WD_BIOMASS,WD_BIOMASS_COMMENT,aproximate date of measurement; same as Main (US-Ho1) -US-Ho3,24604,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,6100 -US-Ho3,24604,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Total -US-Ho3,24604,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-Ho3,24604,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-Ho3,24604,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,Hollinger et al. 2004 -US-Ho3,24604,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,20050719 -US-Ho3,24874,GRP_AG_LIT_CHEM,AG_LIT_N,0.12 -US-Ho3,24874,GRP_AG_LIT_CHEM,AG_LIT_DATE,20030818 -US-Ho3,25119,GRP_BIOMASS_CHEM,BIOMASS_C,4.7 -US-Ho3,24221,GRP_BIOMASS_CHEM,BIOMASS_N,0.0061 -US-Ho3,24221,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-Ho3,25119,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-Ho3,24221,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-Ho3,25119,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-Ho3,24221,GRP_BIOMASS_CHEM,BIOMASS_SPP,(All) -US-Ho3,25119,GRP_BIOMASS_CHEM,BIOMASS_SPP,(All) -US-Ho3,25119,GRP_BIOMASS_CHEM,BIOMASS_DATE,19990818 -US-Ho3,24221,GRP_BIOMASS_CHEM,BIOMASS_DATE,20030818 -US-Ho3,24221,GRP_BIOMASS_CHEM,BIOMASS_COMMENT,heart wood -US-Ho3,25119,GRP_BIOMASS_CHEM,BIOMASS_COMMENT,same as Main (US-Ho1) -US-Ho3,11777,GRP_CLIM_AVG,MAT,5.31 -US-Ho3,11777,GRP_CLIM_AVG,MAP,1072 -US-Ho3,11777,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfb -US-Ho3,27000375,GRP_COUNTRY,COUNTRY,USA -US-Ho3,7772,GRP_DM_FORESTRY,DM_FORESTRY,Thinning/pruning -US-Ho3,7772,GRP_DM_FORESTRY,DM_DATE,2001 -US-Ho3,7772,GRP_DM_FORESTRY,DM_COMMENT,shelterwood harvest; about 1/3 basal area removed -US-Ho3,15753,GRP_DOI,DOI,10.17190/AMF/1246063 -US-Ho3,15753,GRP_DOI,DOI_CITATION,"David Hollinger (2016), AmeriFlux BASE US-Ho3 Howland Forest (harvest site), Ver. 2-1, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1246063" -US-Ho3,15753,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-Ho3,32073,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Ho3,32073,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,David Hollinger -US-Ho3,32073,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Ho3,32073,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,David.Hollinger@unh.edu -US-Ho3,32073,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,USDA Forest Service -US-Ho3,32075,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,USDA Forest Service -US-Ho3,32075,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-Ho3,32074,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,DOE/C Seq. Program -US-Ho3,32074,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-Ho3,11778,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Forestry -US-Ho3,91804,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Ho3,91804,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-Ho3,91804,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20000720 -US-Ho3,91804,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Ho3,23000375,GRP_HEADER,SITE_NAME,Howland Forest (harvest site) -US-Ho3,24459,GRP_HEIGHTC,HEIGHTC,18 -US-Ho3,24459,GRP_HEIGHTC,HEIGHTC_DATE,2005 -US-Ho3,11780,GRP_IGBP,IGBP,ENF -US-Ho3,11780,GRP_IGBP,IGBP_COMMENT,"~80% ENF and 20% BDF in 200m around tower. Across region forest type is mixed ENF, DBF (no type>60%)." -US-Ho3,24487,GRP_LAI,LAI_TYPE,LAI -US-Ho3,24487,GRP_LAI,LAI_CLUMP,1.6 -US-Ho3,24487,GRP_LAI,LAI_METHOD,LAI_2000 -US-Ho3,24487,GRP_LAI,LAI_DATE,20030719 -US-Ho3,24487,GRP_LAI,LAI_COMMENT,"200 m transect measured every 10m; L = ((1-alpha)*L-sube*Gamma-subE)/(Omega-subE); alpha=0.15, gamma=1.6,omega=0.93" -US-Ho3,24487,GRP_LAI,LAI_TOT,3 -US-Ho3,11781,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -US-Ho3,11781,GRP_LAND_OWNERSHIP,LAND_OWNER,John Malone managed by AFM -US-Ho3,24223,GRP_LMA,LMA,226 -US-Ho3,24223,GRP_LMA,LMA_SPP,(All) -US-Ho3,24223,GRP_LMA,LMA_DATE,19990729 -US-Ho3,24223,GRP_LMA,LMA_COMMENT,same as Main (US-Ho1) -US-Ho3,11782,GRP_LOCATION,LOCATION_LAT,45.2072 -US-Ho3,11782,GRP_LOCATION,LOCATION_LONG,-68.7250 -US-Ho3,11782,GRP_LOCATION,LOCATION_ELEV,61 -US-Ho3,11783,GRP_NETWORK,NETWORK,AmeriFlux -US-Ho3,1700002481,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Baldocchi, D. D., Poindexter, C., Abraha, M., Desai, A. R., Bohrer, G., Arain, M. A., Griffis, T., Blanken, P. D., O'Halloran, T. L., Thomas, R. Q., Zhang, Q., Burns, S. P., Frank, J. M., Christian, D., Brown, S., Black, T. A., Gough, C. M., Law, B. E., Lee, X., Chen, J., Reed, D. E., Massman, W. J., Clark, K., Hatfield, J., Prueger, J., Bracho, R., Baker, J. M., Martin, T. A. (2018) Temporal Dynamics Of Aerodynamic Canopy Height Derived From Eddy Covariance Momentum Flux Data Across North American Flux Networks, Geophysical Research Letters, 45(3), 9275–9287" -US-Ho3,1700002481,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018GL079306 -US-Ho3,1700002481,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ho3,1700004293,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(3), 108350" -US-Ho3,1700004293,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -US-Ho3,1700004293,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ho3,1700001470,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Davidson, E. A., Richardson, A. D., Savage, K. E., Hollinger, D. Y. (2006) A Distinct Seasonal Pattern Of The Ratio Of Soil Respiration To Total Ecosystem Respiration In A Spruce-Dominated Forest, Global Change Biology, 12(2), 230-239" -US-Ho3,1700001470,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/J.1365-2486.2005.01062.X -US-Ho3,1700001470,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ho3,1700002247,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Thornton, P., Law, B., Gholz, H. L., Clark, K. L., Falge, E., Ellsworth, D., Goldstein, A., Monson, R., Hollinger, D., Falk, M., Chen, J., Sparks, J. (2002) Modeling And Measuring The Effects Of Disturbance History And Climate On Carbon And Water Budgets In Evergreen Needleleaf Forests, Agricultural And Forest Meteorology, 113(1-4), 185-222" -US-Ho3,1700002247,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/S0168-1923(02)00108-9 -US-Ho3,1700002247,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ho3,1700003456,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Xiao, X., Hollinger, D., Aber, J., Goltz, M., Davidson, E. A., Zhang, Q., Moore, B. (2004) Satellite-Based Modeling Of Gross Primary Production In An Evergreen Needleleaf Forest, Remote Sensing Of Environment, 89(4), 519-534" -US-Ho3,1700003456,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.RSE.2003.11.008 -US-Ho3,1700003456,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ho3,1700001341,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Xiao, X., Zhang, Q., Hollinger, D., Aber, J., Moore, B. (2005) Modeling Gross Primary Production Of An Evergreen Needleleaf Forest Using Modis And Climate Data, Ecological Applications, 15(3), 954-969" -US-Ho3,1700001341,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1890/04-0470 -US-Ho3,1700001341,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ho3,11785,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,Carbon sequestration -US-Ho3,23707,GRP_SA,SA_DATE,2005 -US-Ho3,23707,GRP_SA,SA_COMMENT,a few old trees -US-Ho3,23707,GRP_SA,SA_MAX,141 -US-Ho3,24585,GRP_SA,SA,80 -US-Ho3,24585,GRP_SA,SA_DATE,2005 -US-Ho3,14869,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"University of Maine, Environmental Sciences Lab, Room 103, Orono, ME 04469" -US-Ho3,11787,GRP_SITE_DESC,SITE_DESC,"Closed conifer forest, minimal disturbance. References: Fernandez et al. (1993), Canadian Journal of Soil Science 73 317-328. Hollinger et al. (1999), Global Change Biology 5: 891-902. Savage KE, Davidson EA (2001), Global Biogeochemical Cycles 15 337-350. Scott et al. (2004), Environmental Management, Vol. 33, Supplement 1, pp. S9-S22. Hollinger et al. (2004), Global Change Biology 10: 1689-1706." -US-Ho3,11788,GRP_SITE_FUNDING,SITE_FUNDING,DOE/C Seq. Program -US-Ho3,24716,GRP_SOIL_CHEM,SOIL_CHEM_C_ORG,11 -US-Ho3,23955,GRP_SOIL_CHEM,SOIL_CHEM_C_ORG,19 -US-Ho3,24463,GRP_SOIL_CHEM,SOIL_CHEM_C_ORG,30 -US-Ho3,23696,GRP_SOIL_CHEM,SOIL_CHEM_C_ORG,44 -US-Ho3,27055,GRP_SOIL_CHEM,SOIL_CHEM_C_ORG,44 -US-Ho3,24715,GRP_SOIL_CHEM,SOIL_CHEM_C_ORG,8 -US-Ho3,27597,GRP_SOIL_CHEM,SOIL_CHEM_C_ORG,8 -US-Ho3,24715,GRP_SOIL_CHEM,SOIL_CHEM_N_TOT,0.3 -US-Ho3,27597,GRP_SOIL_CHEM,SOIL_CHEM_N_TOT,0.3 -US-Ho3,24716,GRP_SOIL_CHEM,SOIL_CHEM_N_TOT,0.32 -US-Ho3,23955,GRP_SOIL_CHEM,SOIL_CHEM_N_TOT,0.68 -US-Ho3,24463,GRP_SOIL_CHEM,SOIL_CHEM_N_TOT,0.98 -US-Ho3,23696,GRP_SOIL_CHEM,SOIL_CHEM_N_TOT,1.03 -US-Ho3,27055,GRP_SOIL_CHEM,SOIL_CHEM_N_TOT,1.03 -US-Ho3,24619,GRP_SOIL_CHEM,SOIL_CHEM_PH_SALT,2.8 -US-Ho3,27351,GRP_SOIL_CHEM,SOIL_CHEM_PH_SALT,2.8 -US-Ho3,23717,GRP_SOIL_CHEM,SOIL_CHEM_PH_SALT,3.2 -US-Ho3,28580,GRP_SOIL_CHEM,SOIL_CHEM_PH_SALT,3.2 -US-Ho3,23846,GRP_SOIL_CHEM,SOIL_CHEM_PH_SALT,4.2 -US-Ho3,28581,GRP_SOIL_CHEM,SOIL_CHEM_PH_SALT,4.2 -US-Ho3,23696,GRP_SOIL_CHEM,SOIL_CHEM_BD,0.14 -US-Ho3,27055,GRP_SOIL_CHEM,SOIL_CHEM_BD,0.14 -US-Ho3,24716,GRP_SOIL_CHEM,SOIL_CHEM_BD,0.65 -US-Ho3,24463,GRP_SOIL_CHEM,SOIL_CHEM_BD,0.89 -US-Ho3,24715,GRP_SOIL_CHEM,SOIL_CHEM_BD,1 -US-Ho3,27597,GRP_SOIL_CHEM,SOIL_CHEM_BD,1 -US-Ho3,23955,GRP_SOIL_CHEM,SOIL_CHEM_BD,1.39 -US-Ho3,24619,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,0 -US-Ho3,27055,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,0 -US-Ho3,27351,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,0 -US-Ho3,27597,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,0 -US-Ho3,23717,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,10 -US-Ho3,28580,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,10 -US-Ho3,24716,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,12.5 -US-Ho3,23846,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,15 -US-Ho3,28581,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,15 -US-Ho3,24463,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,17.5 -US-Ho3,23955,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,50 -US-Ho3,24619,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,10 -US-Ho3,27351,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,10 -US-Ho3,24715,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,12.5 -US-Ho3,27597,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,12.5 -US-Ho3,23717,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,15 -US-Ho3,28580,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,15 -US-Ho3,24716,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,17.5 -US-Ho3,24463,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,52.5 -US-Ho3,23846,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,65 -US-Ho3,28581,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,65 -US-Ho3,23696,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,7.5 -US-Ho3,27055,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,7.5 -US-Ho3,23955,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,90 -US-Ho3,28580,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,A-horizon -US-Ho3,24715,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,Ae -US-Ho3,27597,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,Ae horizon -US-Ho3,28581,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,B-horizon -US-Ho3,23696,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,O -US-Ho3,27055,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,O horizon -US-Ho3,27351,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,organic layer -US-Ho3,23696,GRP_SOIL_CHEM,SOIL_CHEM_DATE,1987 -US-Ho3,23717,GRP_SOIL_CHEM,SOIL_CHEM_DATE,1987 -US-Ho3,23846,GRP_SOIL_CHEM,SOIL_CHEM_DATE,1987 -US-Ho3,23955,GRP_SOIL_CHEM,SOIL_CHEM_DATE,1987 -US-Ho3,24463,GRP_SOIL_CHEM,SOIL_CHEM_DATE,1987 -US-Ho3,24619,GRP_SOIL_CHEM,SOIL_CHEM_DATE,1987 -US-Ho3,24715,GRP_SOIL_CHEM,SOIL_CHEM_DATE,1987 -US-Ho3,24716,GRP_SOIL_CHEM,SOIL_CHEM_DATE,1987 -US-Ho3,27055,GRP_SOIL_CHEM,SOIL_CHEM_DATE,1987 -US-Ho3,27351,GRP_SOIL_CHEM,SOIL_CHEM_DATE,1987 -US-Ho3,27597,GRP_SOIL_CHEM,SOIL_CHEM_DATE,1987 -US-Ho3,28580,GRP_SOIL_CHEM,SOIL_CHEM_DATE,1987 -US-Ho3,28581,GRP_SOIL_CHEM,SOIL_CHEM_DATE,1987 -US-Ho3,23717,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,A-horizon; Same as Main (US-Ho1) -US-Ho3,23846,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,B-horizon; Same as Main (US-Ho1) -US-Ho3,23696,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,for details see Fernandez et al. (1993) Can. J. Soil Sci 73:317-28; Same as Main (US-Ho1) -US-Ho3,23955,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,for details see Fernandez et al. (1993) Can. J. Soil Sci 73:317-28; Same as Main (US-Ho1) -US-Ho3,24463,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,for details see Fernandez et al. (1993) Can. J. Soil Sci 73:317-28; Same as Main (US-Ho1) -US-Ho3,24715,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,for details see Fernandez et al. (1993) Can. J. Soil Sci 73:317-28; Same as Main (US-Ho1) -US-Ho3,24716,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,for details see Fernandez et al. (1993) Can. J. Soil Sci 73:317-28; Same as Main (US-Ho1) -US-Ho3,27055,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,for details see Fernandez et al. (1993) Can. J. Soil Sci 73:317-28; Same as Main (US-Ho1) -US-Ho3,27597,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,for details see Fernandez et al. (1993) Can. J. Soil Sci 73:317-28; Same as Main (US-Ho1) -US-Ho3,24619,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,organic layer; Same as Main (US-Ho1) -US-Ho3,27351,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,Same as Main (US-Ho1) -US-Ho3,28580,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,Same as Main (US-Ho1) -US-Ho3,28581,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,Same as Main (US-Ho1) -US-Ho3,27186,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION,"Soils throughout the forest are glacial tills, acid in reaction, with low fertility and high organic composition. Upland soils are fine sandy loams, classified as Aquic Haplorthods." -US-Ho3,27186,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION_TAXONOMY,Other -US-Ho3,23976,GRP_SOIL_DEPTH,SOIL_DEPTH,80 -US-Ho3,24066,GRP_SOIL_TEX,SOIL_TEX_WATER_HOLD_CAP,100 -US-Ho3,26903,GRP_SPP_O,SPP_O,ACRU (NRCS plant code) -US-Ho3,24736,GRP_SPP_O,SPP_O,PIRU (NRCS plant code) -US-Ho3,23712,GRP_SPP_O,SPP_O,TSCA (NRCS plant code) -US-Ho3,24736,GRP_SPP_O,SPP_O_PERC,20 -US-Ho3,23712,GRP_SPP_O,SPP_O_PERC,44 -US-Ho3,23712,GRP_SPP_O,SPP_APPROACH,"FIA Inventory plots at 30 degree radii around tower with subplots located at 50, 100, 200, and 400m distance from tower (n=48)" -US-Ho3,24736,GRP_SPP_O,SPP_APPROACH,"FIA Inventory plots at 30 degree radii around tower with subplots located at 50, 100, 200, and 400m distance from tower (n=48)" -US-Ho3,26903,GRP_SPP_O,SPP_APPROACH,"FIA Inventory plots at 30 degree radii around tower with subplots located at 50, 100, 200, and 400m distance from tower (n=48)" -US-Ho3,23712,GRP_SPP_O,SPP_DATE,2005 -US-Ho3,24736,GRP_SPP_O,SPP_DATE,2005 -US-Ho3,26903,GRP_SPP_O,SPP_DATE,2005 -US-Ho3,11789,GRP_STATE,STATE,ME -US-Ho3,17272,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,David Hollinger -US-Ho3,17272,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Ho3,17272,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,David.Hollinger@unh.edu -US-Ho3,17272,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,USDA Forest Service -US-Ho3,17272,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Northeastern Forest Exp. Station, 271 Mast Rd P.O. Box 640,Durham, NH USA 03824" -US-Ho3,81388,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Holly Hughes -US-Ho3,81388,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,DataManager -US-Ho3,81388,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,holly.hughes@maine.edu -US-Ho3,81388,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Maine -US-Ho3,81388,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Univ. of Maine, Center for Research Sustainable Forests, 103 Environmental Sciences Lab, Orono, ME 04469" -US-Ho3,91787,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,John Lee -US-Ho3,91787,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Technician -US-Ho3,91787,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,jtlee@maine.edu -US-Ho3,91787,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Maine -US-Ho3,91787,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"University of Maine, Environmental Sciences Lab, Room 103, Orono, ME 04469" -US-Ho3,83405,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Robert Evans -US-Ho3,83405,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Technician -US-Ho3,83405,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,robertevans@fs.fed.us -US-Ho3,83405,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,USDA Forest Service -US-Ho3,83405,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Northeastern Forest Exp. Station, 271 Mast Rd., Durham, NH 03824" -US-Ho3,29817,GRP_TOWER_POWER,TOWER_POWER,Solar + generator -US-Ho3,11791,GRP_TOWER_TYPE,TOWER_TYPE,triangle -US-Ho3,11792,GRP_URL,URL,http://howlandforest.org/site_files/site.html -US-Ho3,24000375,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-Ho3 -US-Ho3,11793,GRP_UTC_OFFSET,UTC_OFFSET,-5 -US-HRA,91819,GRP_CLIM_AVG,MAT,16.7 -US-HRA,91819,GRP_CLIM_AVG,MAP,1250 -US-HRA,91819,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Cfa -US-HRA,27000541,GRP_COUNTRY,COUNTRY,USA -US-HRA,87130,GRP_DOI,DOI,10.17190/AMF/1543376 -US-HRA,87130,GRP_DOI,DOI_CITATION,"Benjamin R. K. Runkle (2021), AmeriFlux BASE US-HRA Humnoke Farm Rice Field – Field A, Ver. 3-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1543376" -US-HRA,87130,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-HRA,86614,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-HRA,86614,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Benjamin R. K. Runkle -US-HRA,86614,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-HRA,86614,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,brrunkle@uark.edu -US-HRA,86614,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of Arkansas -US-HRA,86623,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,University of Arkansas -US-HRA,86623,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-HRA,86622,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,"USDA, University of Arkansas, USGS" -US-HRA,86622,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-HRA,91889,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Agriculture -US-HRA,91900,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-HRA,91900,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-HRA,91900,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20150415 -US-HRA,91900,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20170825 -US-HRA,91900,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Intermittent -US-HRA,91900,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,"Intermittent only for brief farm operations (e.g., burning, planting)" -US-HRA,91894,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-HRA,91894,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-HRA,91894,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20150415 -US-HRA,91894,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20170825 -US-HRA,91894,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Intermittent -US-HRA,91894,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,"Intermittent only for brief farm operations (e.g., burning, panting)" -US-HRA,91915,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-HRA,91915,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-HRA,91915,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20150415 -US-HRA,91915,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20170825 -US-HRA,91915,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Intermittent -US-HRA,91915,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,"Intermittent only for brief farm operations (e.g., burning, planting)" -US-HRA,91911,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-HRA,91911,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CH4 -US-HRA,91911,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20150515 -US-HRA,91911,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20170825 -US-HRA,91911,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-HRA,91911,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,"Intermittent only for brief farm operations (e.g., burning, planting)" -US-HRA,23000541,GRP_HEADER,SITE_NAME,Humnoke Farm Rice Field – Field A -US-HRA,12927,GRP_IGBP,IGBP,CRO -US-HRA,12928,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -US-HRA,91905,GRP_LOCATION,LOCATION_LAT,34.5852 -US-HRA,91905,GRP_LOCATION,LOCATION_LONG,-91.7517 -US-HRA,12930,GRP_NETWORK,NETWORK,AmeriFlux -US-HRA,86970,GRP_NETWORK,NETWORK,Phenocam -US-HRA,1700001458,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Benjamin R. K. Runkle, James R. Rigbyb, Michele L. Rebac, Saseendran S. Anapallid, Joydeep Bhattacharjeee, Ken W. Kraussf, Lu Liangg, Martin A. Locke, Kimberly A. Novick, Ruixiu Suid, Kosana Suvočareva and Paul M. White (2017) Delta-Flux: An Eddy Covariance Network for a Climate-Smart Lower Mississippi Basin, Agricultural & Environmental Letters, 2(1), 170003 - 170003" -US-HRA,1700001458,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.2134/AEL2017.01.0003 -US-HRA,1700001458,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-HRA,1700009057,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Runkle, B. R., Suvočarev, K., Reba, M. L., Reavis, C. W., Smith, S. F., Chiu, Y., Fong, B. (2019) Methane Emission Reductions From The Alternate Wetting And Drying Of Rice Fields Detected Using The Eddy Covariance Method, Environmental Science & Technology, 53(2), 671-681" -US-HRA,1700009057,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1021/ACS.EST.8B05535 -US-HRA,1700009057,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Primary_Citation -US-HRA,1700001173,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Suvočarev, K., Castellví, F., Reba, M., Runkle, B. (2019) Surface Renewal Measurements Of H, λE And Co2 Fluxes Over Two Different Agricultural Systems, Agricultural And Forest Meteorology, 279(2), 107763" -US-HRA,1700001173,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2019.107763 -US-HRA,1700001173,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-HRA,12931,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"Agriculture, carbon balance, water balance" -US-HRA,12932,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"1 University of Arkansas, Engineering Hall 231, Fayetteville AR 72701" -US-HRA,12933,GRP_SITE_CHAR,TERRAIN,Flat -US-HRA,12933,GRP_SITE_CHAR,ASPECT,FLAT -US-HRA,12933,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,350 -US-HRA,83445,GRP_SITE_DESC,SITE_DESC,Zero grade rice field (25 ha) under continuous rice operation for > 10 years -US-HRA,12935,GRP_SITE_FUNDING,SITE_FUNDING,"USDA, University of Arkansas, USGS" -US-HRA,12936,GRP_STATE,STATE,AR -US-HRA,12937,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Benjamin R. K. Runkle -US-HRA,12937,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-HRA,12937,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,brrunkle@uark.edu -US-HRA,12937,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Arkansas -US-HRA,12937,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1 University of Arkansas, Engineering Hall 231, Fayetteville AR 72701" -US-HRA,83441,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Kosana Suvocarev -US-HRA,83441,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,AncContact -US-HRA,83441,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,ksuvocar@uark.edu -US-HRA,83441,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Arkansas -US-HRA,12941,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Michele L. Reba -US-HRA,12941,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,AncContact -US-HRA,12941,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,michele.reba@ars.usda.gov -US-HRA,12941,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"USDA, ARS, DELTA WATER MANAGEMENT RESEARCH UNIT" -US-HRA,12941,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"504 UNIVERSITY LOOP EAST, Jonesboro AR 72401" -US-HRA,29875,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-HRA,12938,GRP_TOWER_TYPE,TOWER_TYPE,tripod -US-HRA,24000541,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-HRA -US-HRA,12939,GRP_UTC_OFFSET,UTC_OFFSET,-6 -US-HRC,91829,GRP_CLIM_AVG,MAT,16.7 -US-HRC,91829,GRP_CLIM_AVG,MAP,1250 -US-HRC,91829,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Cfa -US-HRC,27000540,GRP_COUNTRY,COUNTRY,USA -US-HRC,87123,GRP_DOI,DOI,10.17190/AMF/1543375 -US-HRC,87123,GRP_DOI,DOI_CITATION,"Michele L. Reba (2021), AmeriFlux BASE US-HRC Humnoke Farm Rice Field – Field C, Ver. 3-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1543375" -US-HRC,87123,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-HRC,86613,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-HRC,86613,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Michele L. Reba -US-HRC,86613,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-HRC,86613,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,michele.reba@ars.usda.gov -US-HRC,86613,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"USDA, ARS, DELTA WATER MANAGEMENT RESEARCH UNIT" -US-HRC,86621,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,"USDA, ARS, DELTA WATER MANAGEMENT RESEARCH UNIT" -US-HRC,86621,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-HRC,86620,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,"USDA, University of Arkansas, USGS" -US-HRC,86620,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-HRC,92236,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Agriculture -US-HRC,92242,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-HRC,92242,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-HRC,92242,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20150415 -US-HRC,92242,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-HRC,92242,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,"Intermittent only for brief farm operations (e.g., burning, planting)" -US-HRC,92257,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-HRC,92257,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-HRC,92257,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20150415 -US-HRC,92257,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-HRC,92257,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,"Intermittent only for brief farm operations (e.g., burning, planting)" -US-HRC,92255,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-HRC,92255,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CH4 -US-HRC,92255,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20150417 -US-HRC,92255,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-HRC,92255,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,"Intermittent only for brief farm operations (e.g., burning, planting) - generally continuous" -US-HRC,23000540,GRP_HEADER,SITE_NAME,Humnoke Farm Rice Field – Field C -US-HRC,12945,GRP_IGBP,IGBP,CRO -US-HRC,12946,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -US-HRC,92261,GRP_LOCATION,LOCATION_LAT,34.5888 -US-HRC,92261,GRP_LOCATION,LOCATION_LONG,-91.7517 -US-HRC,12948,GRP_NETWORK,NETWORK,AmeriFlux -US-HRC,86971,GRP_NETWORK,NETWORK,Phenocam -US-HRC,1700004644,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Benjamin R. K. Runkle, James R. Rigbyb, Michele L. Rebac, Saseendran S. Anapallid, Joydeep Bhattacharjeee, Ken W. Kraussf, Lu Liangg, Martin A. Locke, Kimberly A. Novick, Ruixiu Suid, Kosana Suvočareva and Paul M. White (2017) Delta-Flux: An Eddy Covariance Network for a Climate-Smart Lower Mississippi Basin, Agricultural & Environmental Letters, 2(1), 170003 - 170003" -US-HRC,1700004644,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.2134/AEL2017.01.0003 -US-HRC,1700004644,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Primary_Citation -US-HRC,1700007440,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Runkle, B. R., Suvočarev, K., Reba, M. L., Reavis, C. W., Smith, S. F., Chiu, Y., Fong, B. (2019) Methane Emission Reductions From The Alternate Wetting And Drying Of Rice Fields Detected Using The Eddy Covariance Method, Environmental Science & Technology, 53(2), 671-681" -US-HRC,1700007440,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1021/ACS.EST.8B05535 -US-HRC,1700007440,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Primary_Citation -US-HRC,12949,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"Agriculture, carbon balance, water balance" -US-HRC,12950,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"504 UNIVERSITY LOOP EAST, Jonesboro AR 72401" -US-HRC,12951,GRP_SITE_CHAR,TERRAIN,Flat -US-HRC,12951,GRP_SITE_CHAR,ASPECT,FLAT -US-HRC,12951,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,350 -US-HRC,12952,GRP_SITE_DESC,SITE_DESC,Conventional flood irrigation method on a rice field under continuous rice operation for 50 years -US-HRC,12953,GRP_SITE_FUNDING,SITE_FUNDING,"USDA, University of Arkansas, USGS" -US-HRC,12954,GRP_STATE,STATE,AR -US-HRC,12955,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Michele L. Reba -US-HRC,12955,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-HRC,12955,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,michele.reba@ars.usda.gov -US-HRC,12955,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"USDA, ARS, DELTA WATER MANAGEMENT RESEARCH UNIT" -US-HRC,12955,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"504 UNIVERSITY LOOP EAST, Jonesboro AR 72401" -US-HRC,12959,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Benjamin R. K. Runkle -US-HRC,12959,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,AncContact -US-HRC,12959,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,brrunkle@uark.edu -US-HRC,12959,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Arkansas -US-HRC,12959,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1 University of Arkansas, Engineering Hall 231, Fayetteville AR 72701" -US-HRC,29874,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-HRC,12956,GRP_TOWER_TYPE,TOWER_TYPE,tripod -US-HRC,24000540,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-HRC -US-HRC,12957,GRP_UTC_OFFSET,UTC_OFFSET,-6 -US-HRP,92228,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,This research was initially funded by the NOAA National Estuarine Research Reserve Science Collaborative (NA09NOS4190153 and NA14NOS4190145) and NSF MRI (DBI-959333). Current funding is USGS Coastal & Marine Hazards and Resources Program. -US-HRP,31132,GRP_CLIM_AVG,MAT,9.9 -US-HRP,31132,GRP_CLIM_AVG,MAP,1195 -US-HRP,31132,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfb -US-HRP,27000715,GRP_COUNTRY,COUNTRY,USA -US-HRP,31136,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Chambers -US-HRP,31136,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-HRP,31136,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20170609 -US-HRP,31136,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Periodic operation -US-HRP,31135,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Chambers -US-HRP,31135,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CH4 -US-HRP,31135,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20170609 -US-HRP,31135,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Periodic operation -US-HRP,31134,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-HRP,31134,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-HRP,31134,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20170609 -US-HRP,31134,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-HRP,31133,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-HRP,31133,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-HRP,31133,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20170609 -US-HRP,31133,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-HRP,92253,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-HRP,92253,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CH4 -US-HRP,92253,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20200521 -US-HRP,92253,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-HRP,23000715,GRP_HEADER,SITE_NAME,Herring River Phragmites -US-HRP,31155,GRP_IGBP,IGBP,WET -US-HRP,31155,GRP_IGBP,IGBP_COMMENT,"Degraded, invasive Phragmites wetland." -US-HRP,31138,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-HRP,31138,GRP_LAND_OWNERSHIP,LAND_OWNER,National Park Service -US-HRP,31139,GRP_LOCATION,LOCATION_LAT,41.9380 -US-HRP,31139,GRP_LOCATION,LOCATION_LONG,-70.0552 -US-HRP,31139,GRP_LOCATION,LOCATION_ELEV,0.5 -US-HRP,31140,GRP_NETWORK,NETWORK,AmeriFlux -US-HRP,1700001941,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Sanders‐DeMott, R., Eagle, M. J., Kroeger, K. D., Wang, F., Brooks, T. W., O'Keefe Suttles, J. A., Nick, S. K., Mann, A. G., Tang, J. (2022) Impoundment Increases Methane Emissions In Phragmites‐Invaded Coastal Wetlands, Global Change Biology, (), " -US-HRP,1700001941,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/GCB.16217 -US-HRP,1700001941,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-HRP,31141,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,Studying carbon and water fluxes in a brackish wetland. -US-HRP,100815,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"384 Woods Hole Road, Woods Hole, MA 02543" -US-HRP,31143,GRP_SITE_CHAR,TERRAIN,Flat -US-HRP,31143,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,100 -US-HRP,31143,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,60 -US-HRP,31144,GRP_SITE_DESC,SITE_DESC,"The tower (tripod) is located in the center of a degraded, invasive Phragmites site in the Herring River basin in Cape Cod, Massachusetts. In the downstream a dike was build about 100 years ago to block tidal seawater flooding in. It is now a brackish wetland site dominated by Phragmites. It is subject to periodical tidal flooding." -US-HRP,31145,GRP_SITE_FUNDING,SITE_FUNDING,Initially funded by NSF and NOAA. -US-HRP,31146,GRP_STATE,STATE,MA -US-HRP,31148,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Jim Tang -US-HRP,31148,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-HRP,31148,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,jtang@mbl.edu -US-HRP,31148,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Marine Biological Laboratory -US-HRP,31148,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"7 MBL St, Woods Hole, MA 02543" -US-HRP,31149,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Kevin Kroeger -US-HRP,31149,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-HRP,31149,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,kkroeger@usgs.gov -US-HRP,31149,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,USGS Woods Hole Center -US-HRP,94789,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Meagan Eagle -US-HRP,94789,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-HRP,94789,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,meagle@usgs.gov -US-HRP,94789,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,USGS Woods Hole Coastal & Marine Science Center -US-HRP,94789,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"384 Woods Hole Rd, Woods Hole, MA 02543" -US-HRP,93315,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Rebecca Sanders-DeMott -US-HRP,93315,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-HRP,93315,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,rsanders-demott@usgs.gov -US-HRP,93315,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,USGS Woods Hole Coastal & Marine Science Center -US-HRP,93315,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"384 Woods Hole Rd, Woods Hole, MA 02543" -US-HRP,31147,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Faming Wang -US-HRP,31147,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,DataManager -US-HRP,31147,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,fwang@mbl.edu -US-HRP,31147,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Marine Biological Laboratory -US-HRP,31152,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-HRP,31150,GRP_TOWER_TYPE,TOWER_TYPE,tripod -US-HRP,24000715,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-HRP -US-HRP,31151,GRP_UTC_OFFSET,UTC_OFFSET,-5 -US-Hsm,95567,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,"Biometeorology Lab, University of California, Berkeley, PI: Dennis Baldocchi" -US-Hsm,95555,GRP_CLIM_AVG,MAT,15.6 -US-Hsm,95555,GRP_CLIM_AVG,MAP,450 -US-Hsm,95555,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Csa -US-Hsm,27001184,GRP_COUNTRY,COUNTRY,USA -US-Hsm,98745,GRP_DM_WATER,DM_WATER,Human induced flooding -US-Hsm,98745,GRP_DM_WATER,DM_SURF,100 -US-Hsm,98745,GRP_DM_WATER,DM_DATE,202110061900 -US-Hsm,98745,GRP_DM_WATER,DM_COMMENT,Tidal action will be restored at the site in Fall 2021. The site was a mixture of upland and managed seasonal wetland at the time of tower installation. -US-Hsm,99679,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Hsm,99679,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Ariane Arias-Ortiz -US-Hsm,99679,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Hsm,99679,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,1 -US-Hsm,99679,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0001-9408-0061 -US-Hsm,99679,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,aariasortiz@berkeley.edu -US-Hsm,99679,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"University of California, Berkeley" -US-Hsm,99679,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,20210311 -US-Hsm,98370,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Hsm,98370,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Daphne Szutu -US-Hsm,98370,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Hsm,98370,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,2 -US-Hsm,98370,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0001-7698-0461 -US-Hsm,98370,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,daphneszutu@berkeley.edu -US-Hsm,98370,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"University of California, Berkeley" -US-Hsm,98370,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,20210311 -US-Hsm,98362,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Hsm,98362,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Joseph Verfaillie -US-Hsm,98362,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Hsm,98362,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,3 -US-Hsm,98362,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0002-7009-8942 -US-Hsm,98362,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,jverfail@berkeley.edu -US-Hsm,98362,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"University of California, Berkeley" -US-Hsm,98362,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,20210311 -US-Hsm,98364,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Hsm,98364,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Dennis Baldocchi -US-Hsm,98364,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Hsm,98364,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,4 -US-Hsm,98364,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0003-3496-4919 -US-Hsm,98364,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,baldocchi@berkeley.edu -US-Hsm,98364,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"University of California, Berkeley" -US-Hsm,98364,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,20210311 -US-Hsm,97759,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,"University of California, Berkeley" -US-Hsm,97759,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-Hsm,95575,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Hydrologic event -US-Hsm,95557,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Hsm,95557,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-Hsm,95557,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20210311 -US-Hsm,95557,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Hsm,95576,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Hsm,95576,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CH4 -US-Hsm,95576,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20210311 -US-Hsm,95576,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Hsm,95573,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Hsm,95573,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-Hsm,95573,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20210311 -US-Hsm,95573,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Hsm,23001184,GRP_HEADER,SITE_NAME,Hill Slough Marsh -US-Hsm,95561,GRP_IGBP,IGBP,WET -US-Hsm,95556,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-Hsm,95556,GRP_LAND_OWNERSHIP,LAND_OWNER,CA Dept of Fish and Wildlife -US-Hsm,95566,GRP_LOCATION,LOCATION_LAT,38.2368 -US-Hsm,95566,GRP_LOCATION,LOCATION_LONG,-122.0211 -US-Hsm,95566,GRP_LOCATION,LOCATION_ELEV,0.6 -US-Hsm,95566,GRP_LOCATION,LOCATION_DATE_START,20210311 -US-Hsm,95566,GRP_LOCATION,LOCATION_COMMENT,The eddy covariance tower is installed on a fenced platform due to its proximity to the urban area. -US-Hsm,95570,GRP_NETWORK,NETWORK,AmeriFlux -US-Hsm,98446,GRP_NETWORK,NETWORK,Phenocam -US-Hsm,95562,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"Greenhouse gas budgets and Net Ecoystem Carbon Balance, including measurements of the tidal exchange of carbon." -US-Hsm,95569,GRP_SITE_CHAR,TERRAIN,Flat -US-Hsm,95569,GRP_SITE_CHAR,ASPECT,FLAT -US-Hsm,95569,GRP_SITE_CHAR,WIND_DIRECTION,WSW -US-Hsm,95569,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,700 -US-Hsm,95569,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,0 -US-Hsm,95630,GRP_SITE_DESC,SITE_DESC,"The site is currently a diked marsh - upland ecotone located at the northern Suisun Marsh. It will undergo tidal restoration in Fall 2021. Restoration work is done by Ducks Unlimited Inc. and will cover an area of 649 acres. After levee breaches, the site tower will be in a high marsh system. Water level at high tide is estimated to be 0.5-1 m above the soil. Ducks Unlimited, Inc. and the Berkeley Biometeorology lab are working together to evaluate the effects of the proposed tidal marsh restoration project." -US-Hsm,95572,GRP_SITE_FUNDING,SITE_FUNDING,Ducks Unlimited Inc. /CA Dept of Fish and Wildlife -US-Hsm,95565,GRP_STATE,STATE,CA -US-Hsm,95568,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Dennis Baldocchi -US-Hsm,95568,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Hsm,95568,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,baldocchi@berkeley.edu -US-Hsm,95568,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"University of California, Berkeley" -US-Hsm,95568,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"130 Mulford Hall, Berkeley CA 94720" -US-Hsm,95560,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Ariane Arias-Ortiz -US-Hsm,95560,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-Hsm,95560,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,aariasortiz@berkeley.edu -US-Hsm,95560,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"University of California, Berkeley" -US-Hsm,95560,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"130 Mulford Hall, Berkeley CA 94720" -US-Hsm,95564,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Daphne Szutu -US-Hsm,95564,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,DataManager -US-Hsm,95564,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,daphneszutu@berkeley.edu -US-Hsm,95564,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"University of California, Berkeley" -US-Hsm,95564,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"130 Mulford Hall, Berkeley CA 94720" -US-Hsm,95574,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Joe Verfaillie -US-Hsm,95574,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Technician -US-Hsm,95574,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,jverfail@berkeley.edu -US-Hsm,95574,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"University of California, Berkeley" -US-Hsm,95574,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"130 Mulford Hall, Berkeley CA 94720" -US-Hsm,95577,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-Hsm,95558,GRP_TOWER_TYPE,TOWER_TYPE,walk-up -US-Hsm,95559,GRP_URL,URL,https://nature.berkeley.edu/biometlab/sites.php -US-Hsm,24001184,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-Hsm -US-Hsm,95563,GRP_UTC_OFFSET,UTC_OFFSET,-8 -US-HWB,95672,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,This research was a contribution from the Long-Term Agroecosystem Research (LTAR) network. LTAR is supported by the United States Department of Agriculture. -US-HWB,95662,GRP_CLIM_AVG,MAT,10.1 -US-HWB,95662,GRP_CLIM_AVG,MAP,1006.35 -US-HWB,95662,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfb -US-HWB,27001186,GRP_COUNTRY,COUNTRY,USA -US-HWB,97421,GRP_DOI,DOI,10.17190/AMF/1811363 -US-HWB,97421,GRP_DOI,DOI_CITATION,"Sarah Goslee (2021), AmeriFlux BASE US-HWB USDA ARS Pasture Sytems and Watershed Management Research Unit- Hawbecker Site, Ver. 1-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1811363" -US-HWB,97421,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-HWB,97415,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-HWB,97415,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Sarah Goslee -US-HWB,97415,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-HWB,97415,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,sarah.goslee@usda.gov -US-HWB,97415,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,USDA ARS PSWMRU -US-HWB,97419,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,USDA ARS PSWMRU -US-HWB,97419,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-HWB,97417,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,USDA ARS -US-HWB,97417,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-HWB,95675,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Agriculture -US-HWB,95669,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-HWB,95669,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-HWB,95669,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201507161500 -US-HWB,95669,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,201808240900 -US-HWB,95669,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-HWB,95666,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-HWB,95666,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-HWB,95666,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201507161500 -US-HWB,95666,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,201808240900 -US-HWB,95666,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-HWB,23001186,GRP_HEADER,SITE_NAME,USDA ARS Pasture Sytems and Watershed Management Research Unit- Hawbecker Site -US-HWB,95674,GRP_IGBP,IGBP,CVM -US-HWB,95674,GRP_IGBP,IGBP_COMMENT,"Land has been privately owned prior to University Ownership, no records exist as to when crop land was cleared in landscape." -US-HWB,95660,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-HWB,95660,GRP_LAND_OWNERSHIP,LAND_OWNER,"Penn State University Land is Public, this field area is gated and has restricted access" -US-HWB,95670,GRP_LOCATION,LOCATION_LAT,40.8608 -US-HWB,95670,GRP_LOCATION,LOCATION_LONG,-77.8488 -US-HWB,95670,GRP_LOCATION,LOCATION_ELEV,378 -US-HWB,95670,GRP_LOCATION,LOCATION_DATE_START,201201010000 -US-HWB,95670,GRP_LOCATION,LOCATION_COMMENT,"Location information started with Met Site located to support GraceNet plots, Plot data started prior to Metsite." -US-HWB,95667,GRP_NETWORK,NETWORK,AmeriFlux -US-HWB,95664,GRP_NETWORK,NETWORK,LTAR -US-HWB,95676,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,Dairy Grazing Farm crop rotation and manure management -US-HWB,95665,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"Curtin Rd, Building 3702, University Park, PA 16802" -US-HWB,95656,GRP_SITE_CHAR,TERRAIN,"Medium Slope (>2 %, <5%)" -US-HWB,95656,GRP_SITE_CHAR,ASPECT,NW -US-HWB,95656,GRP_SITE_CHAR,WIND_DIRECTION,SSW -US-HWB,95656,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,175 -US-HWB,95656,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,18 -US-HWB,95668,GRP_SITE_DESC,SITE_DESC,"Hawbecker farm is owned by Penn State University. The farming that took place was performed by their Farm Operations Division. The ground is rolling terrain, next to wooded areas, the Beef and Sheep Reasearch Farm, The University Airport, and other large fields maintained by Farm Operations. At the time of this collection period, the site housed another Meteorological Site, a Phenocam, and the GraceNet plots. Crop Rotation during period was 2 years Alfalfa, 1 year Corn for grain and 1 year Wheat." -US-HWB,95655,GRP_SITE_FUNDING,SITE_FUNDING,USDA ARS -US-HWB,95659,GRP_STATE,STATE,PA -US-HWB,96446,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Sarah Goslee -US-HWB,96446,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-HWB,96446,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,sarah.goslee@usda.gov -US-HWB,96446,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,USDA ARS PSWMRU -US-HWB,96446,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Curtin Rd, Building 3702, University Park, PA 16802" -US-HWB,96416,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Dan Arthur -US-HWB,96416,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,DataManager -US-HWB,96416,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,dan.arthur@usda.gov -US-HWB,96416,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,USDA ARS PSWMRU -US-HWB,96416,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Curtin Rd, Building 3702, University Park, PA 16802" -US-HWB,95677,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Jeffery Gonet -US-HWB,95677,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Technician -US-HWB,95677,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,jeffery.gonet@usda.gov -US-HWB,95677,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,USDA ARS PSWMRU -US-HWB,95677,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Curtin Rd, Building 3702, University Park, PA 16802" -US-HWB,95673,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-HWB,95658,GRP_TOWER_TYPE,TOWER_TYPE,triangle -US-HWB,24001186,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-HWB -US-HWB,95657,GRP_UTC_OFFSET,UTC_OFFSET,-5 -US-ICh,12065,GRP_CLIM_AVG,MAT,-7.4 -US-ICh,12065,GRP_CLIM_AVG,MAP,318 -US-ICh,12065,GRP_CLIM_AVG,CLIMATE_KOEPPEN,ET -US-ICh,27000499,GRP_COUNTRY,COUNTRY,USA -US-ICh,15766,GRP_DOI,DOI,10.17190/AMF/1246133 -US-ICh,15766,GRP_DOI,DOI_CITATION,"Eugenie Euskirchen, Gaius Shaver, Syndonia Bret-Harte (2022), AmeriFlux BASE US-ICh Imnavait Creek Watershed Heath Tundra, Ver. 4-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1246133" -US-ICh,15766,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-ICh,32302,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-ICh,32302,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Eugenie Euskirchen -US-ICh,32302,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-ICh,32302,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,seeuskirchen@alaska.edu -US-ICh,32302,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of Alaska Fairbanks -US-ICh,32301,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-ICh,32301,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Gaius Shaver -US-ICh,32301,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-ICh,32301,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,gshaver@mbl.edu -US-ICh,32301,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Marine Biological Laboratory -US-ICh,32303,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-ICh,32303,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Syndonia Bret-Harte -US-ICh,32303,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-ICh,32303,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,msbretharte@alaska.edu -US-ICh,32303,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of Alaska Fairbanks -US-ICh,32306,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Marine Biological Laboratory -US-ICh,32306,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-ICh,32305,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,University of Alaska Fairbanks -US-ICh,32305,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-ICh,32304,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,NSF -US-ICh,32304,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-ICh,12066,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Undisturbed -US-ICh,12067,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-ICh,12067,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-ICh,12067,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,2007 -US-ICh,12067,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-ICh,23000499,GRP_HEADER,SITE_NAME,Imnavait Creek Watershed Heath Tundra -US-ICh,12068,GRP_IGBP,IGBP,OSH -US-ICh,88041,GRP_INST,INST_MODEL,SOIL_H-Plate_AUTO -US-ICh,88041,GRP_INST,INST_SN,"001125, 001144, 001112, 001123" -US-ICh,88041,GRP_INST,INST_DATE,201701010000 -US-ICh,88041,GRP_INST,INST_COMMENT,SHF-SC -US-ICh,88041,GRP_INST,INST_SAMPLING_INT,1 -US-ICh,88041,GRP_INST,INST_AVERAGING_INT,1800 -US-ICh,88030,GRP_INST,INST_MODEL,RAD-SW Pyran Class1 -US-ICh,88030,GRP_INST,INST_SN,070013up 070013down -US-ICh,88030,GRP_INST,INST_DATE,201701010000 -US-ICh,88030,GRP_INST,INST_COMMENT,CMA6 -US-ICh,88030,GRP_INST,INST_SAMPLING_INT,1 -US-ICh,88030,GRP_INST,INST_AVERAGING_INT,1800 -US-ICh,88030,GRP_INST,INST_HEAT,Unheated -US-ICh,88033,GRP_INST,INST_MODEL,SNOW-Acoustic -US-ICh,88033,GRP_INST,INST_SN,1115 -US-ICh,88033,GRP_INST,INST_DATE,201701010000 -US-ICh,88033,GRP_INST,INST_COMMENT,SR50-A -US-ICh,88033,GRP_INST,INST_SAMPLING_INT,180 -US-ICh,88033,GRP_INST,INST_AVERAGING_INT,1800 -US-ICh,88032,GRP_INST,INST_MODEL,SA-Campbell CSAT-3 -US-ICh,88032,GRP_INST,INST_SN,1420 -US-ICh,88032,GRP_INST,INST_DATE,201701010000 -US-ICh,88032,GRP_INST,INST_COMMENT,Height is 3.0m -US-ICh,88032,GRP_INST,INST_FIRMWARE,v4 -US-ICh,88032,GRP_INST,INST_SAMPLING_INT,0.1 -US-ICh,88032,GRP_INST,INST_AVERAGING_INT,1800 -US-ICh,88032,GRP_INST,INST_SA_OFFSET_NORTH,112 -US-ICh,88032,GRP_INST,INST_SA_WIND_FORMAT,"U, V, W" -US-ICh,88038,GRP_INST,INST_MODEL,RAIN-TipBucGauge -US-ICh,88038,GRP_INST,INST_SN,42345-507 -US-ICh,88038,GRP_INST,INST_DATE,201701010000 -US-ICh,88038,GRP_INST,INST_SAMPLING_INT,1 -US-ICh,88038,GRP_INST,INST_AVERAGING_INT,1800 -US-ICh,88039,GRP_INST,INST_MODEL,RAD-Net radiometer -US-ICh,88039,GRP_INST,INST_SN,72449 -US-ICh,88039,GRP_INST,INST_DATE,201701010000 -US-ICh,88039,GRP_INST,INST_COMMENT,NRLite -US-ICh,88039,GRP_INST,INST_SAMPLING_INT,1 -US-ICh,88039,GRP_INST,INST_AVERAGING_INT,1800 -US-ICh,88039,GRP_INST,INST_HEAT,Unheated -US-ICh,88035,GRP_INST,INST_MODEL,GA_CP-LI-COR LI-7200RS -US-ICh,88035,GRP_INST,INST_SN,810 -US-ICh,88035,GRP_INST,INST_DATE,201701010000 -US-ICh,88035,GRP_INST,INST_COMMENT,Uses AIU-1701 and Flow Module (I assume has MFC) -US-ICh,88035,GRP_INST,INST_FIRMWARE,8.5.0 -US-ICh,88035,GRP_INST,INST_SAMPLING_INT,0.1 -US-ICh,88035,GRP_INST,INST_AVERAGING_INT,1800 -US-ICh,88035,GRP_INST,INST_HEAT,Unheated -US-ICh,88035,GRP_INST,INST_GA_CP_FILTERS,inlet screen and .5micron swageloc filter near inlet -US-ICh,88035,GRP_INST,INST_GA_CP_TUBE_LENGTH,100 -US-ICh,88035,GRP_INST,INST_GA_CP_TUBE_IN_DIAM,53 -US-ICh,88035,GRP_INST,INST_GA_CP_TUBE_MAT,Other -US-ICh,88035,GRP_INST,INST_GA_CP_TUBE_THERM,Insulated -US-ICh,88035,GRP_INST,INST_GA_CP_FLOW_RATE,15 -US-ICh,88035,GRP_INST,INST_GA_CP_MFC,Yes -US-ICh,88034,GRP_INST,INST_MODEL,TEMP-ElectResis -US-ICh,88034,GRP_INST,INST_SN,C1710020 -US-ICh,88034,GRP_INST,INST_DATE,201701010000 -US-ICh,88034,GRP_INST,INST_COMMENT,HMP45C -US-ICh,88034,GRP_INST,INST_SAMPLING_INT,1 -US-ICh,88034,GRP_INST,INST_AVERAGING_INT,1800 -US-ICh,88034,GRP_INST,INST_SHIELDING,Radiation -US-ICh,88034,GRP_INST,INST_ASPIRATION,Ventilation -US-ICh,88042,GRP_INST,INST_MODEL,RH-ElecRes -US-ICh,88042,GRP_INST,INST_SN,C1710020 -US-ICh,88042,GRP_INST,INST_DATE,201701010000 -US-ICh,88042,GRP_INST,INST_COMMENT,HMP45C -US-ICh,88042,GRP_INST,INST_SAMPLING_INT,1 -US-ICh,88042,GRP_INST,INST_AVERAGING_INT,1800 -US-ICh,88042,GRP_INST,INST_SHIELDING,Radiation -US-ICh,88042,GRP_INST,INST_ASPIRATION,Ventilation -US-ICh,88031,GRP_INST,INST_MODEL,WIND-CupAn -US-ICh,88031,GRP_INST,INST_SN,G4863 -US-ICh,88031,GRP_INST,INST_DATE,201701010000 -US-ICh,88031,GRP_INST,INST_COMMENT,014A MetOne -US-ICh,88031,GRP_INST,INST_SAMPLING_INT,1 -US-ICh,88031,GRP_INST,INST_AVERAGING_INT,1800 -US-ICh,88037,GRP_INST,INST_MODEL,TEMP-TCouple -US-ICh,88037,GRP_INST,INST_SN,"ICh1, Ich2" -US-ICh,88037,GRP_INST,INST_DATE,201701010000 -US-ICh,88037,GRP_INST,INST_COMMENT,Soil TCAV -US-ICh,88037,GRP_INST,INST_SAMPLING_INT,1 -US-ICh,88037,GRP_INST,INST_AVERAGING_INT,1800 -US-ICh,88029,GRP_INST,INST_MODEL,SWC-FDR -US-ICh,88029,GRP_INST,INST_SN,order number 216558 -US-ICh,88029,GRP_INST,INST_DATE,201701010000 -US-ICh,88029,GRP_INST,INST_COMMENT,CS616 -US-ICh,88029,GRP_INST,INST_SAMPLING_INT,1 -US-ICh,88029,GRP_INST,INST_AVERAGING_INT,1800 -US-ICh,88036,GRP_INST,INST_MODEL,PRES-ElectBar -US-ICh,88036,GRP_INST,INST_SN,PX503 -US-ICh,88036,GRP_INST,INST_DATE,201701010000 -US-ICh,88036,GRP_INST,INST_COMMENT,located in AIU-1701 -US-ICh,88036,GRP_INST,INST_SAMPLING_INT,0.1 -US-ICh,88040,GRP_INSTPAIR,INSTPAIR_MODEL_1,SA-Campbell CSAT-3 -US-ICh,88040,GRP_INSTPAIR,INSTPAIR_SN_1,1420 -US-ICh,88040,GRP_INSTPAIR,INSTPAIR_MODEL_2,GA_CP-LI-COR LI-7200RS -US-ICh,88040,GRP_INSTPAIR,INSTPAIR_SN_2,810 -US-ICh,88040,GRP_INSTPAIR,INSTPAIR_DATE,201701010000 -US-ICh,88040,GRP_INSTPAIR,INSTPAIR_COMMENT,CSAT3 and LI7200RS are EC instrument pair for 2017 -US-ICh,88040,GRP_INSTPAIR,INSTPAIR_HEIGHT_SEP,0 -US-ICh,88040,GRP_INSTPAIR,INSTPAIR_EASTWARD_SEP,-0.12 -US-ICh,88040,GRP_INSTPAIR,INSTPAIR_NORTHWARD_SEP,0.02 -US-ICh,12069,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-ICh,12069,GRP_LAND_OWNERSHIP,LAND_OWNER,BLM -US-ICh,12070,GRP_LOCATION,LOCATION_LAT,68.6068 -US-ICh,12070,GRP_LOCATION,LOCATION_LONG,-149.2958 -US-ICh,12070,GRP_LOCATION,LOCATION_ELEV,940 -US-ICh,12071,GRP_NETWORK,NETWORK,AmeriFlux -US-ICh,86972,GRP_NETWORK,NETWORK,Phenocam -US-ICh,1700000345,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Euskirchen, E. S., Bret-Harte, M. S., Scott, G. J., Edgar, C., Shaver, G. R. (2012) Seasonal Patterns Of Carbon Dioxide And Water Fluxes In Three Representative Tundra Ecosystems In Northern Alaska, Ecosphere, 3(1), 1-19" -US-ICh,1700000345,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1890/ES11-00202.1 -US-ICh,1700000345,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-ICh,1700006720,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Euskirchen, E. S., Bret-Harte, M. S., Shaver, G. R., Edgar, C. W., Romanovsky, V. E. (2017) Long-Term Release Of Carbon Dioxide From Arctic Tundra Ecosystems In Alaska, Ecosystems, 20(5), 960-974" -US-ICh,1700006720,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1007/S10021-016-0085-9 -US-ICh,1700006720,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-ICh,1700002997,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Kade, A., Bret-Harte, M. S., Euskirchen, E. S., Edgar, C., Fulweber, R. A. (2012) Upscaling Of CO2 Fluxes From Heterogeneous Tundra Plant Communities In Arctic Alaska, Journal Of Geophysical Research: Biogeosciences, 117(G4), n/a-n/a" -US-ICh,1700002997,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2012JG002065 -US-ICh,1700002997,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-ICh,12073,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"The research approach of the US Study of Environmental Arctic Change (SEARCH) program, created by Arctic Observatory Networks (AON), is to seek development and deployment of a pan-arctic observing system that will measure the full range of continuing changes now underway in the Arctic. This project focuses on simultaneous measurements of carbon, water, and energy fluxes of the terrestrial landscape at hourly, daily, seasonal, and multi-year time scales. These are major regulatory drivers of the Arctic system and form key linkages and feedbacks between the land surface, the atmosphere, and the oceans. There are three automated weather stations deployed at Imnavait Creek in support of the AON objectives: The Ridge Station, the Biocomplexity Station, and the Fen Station. These stations will provide a comprehensive description of the state of the regional Arctic system with respect to these variables, its overall regulation and controlling features, and its interaction with the global system. In the longer-term, this project will provide a legacy of data, a network of observing platforms, and a set of clear protocols for long-term observation and further analysis." -US-ICh,95238,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"AON / Bret-Harte -IAB Toolik 757005 -2120 Koyukuk Dr #138 -Fairbanks, AK 99775-7005" -US-ICh,81667,GRP_SITE_CHAR,TERRAIN,"Significant Slope (>5%, <10%)" -US-ICh,81667,GRP_SITE_CHAR,ASPECT,W -US-ICh,81667,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,300 -US-ICh,81667,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,275 -US-ICh,12075,GRP_SITE_DESC,SITE_DESC,"The Imnavait Creek Watershed Heath Tundra (Ridge Station) is located near Imnavait Creek in Alaska, north of the Brooks Range in the Kuparuk basin near Lake Toolik and the Toolik Field Station. The Kuparuk River has its headwaters in the Brooks Range and drains through northern Alaska into the Arctic Ocean. Within these headwaters lies the Imnavait basin at an average elevation of 930 m. Water tracks run down the hill in parallel zones with a spacing of approximately 10 m. The Ridge Station was deployed at the end of Summer 2007." -US-ICh,12076,GRP_SITE_FUNDING,SITE_FUNDING,NSF -US-ICh,27729,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION,"Embedded in piedmont hills, with a predominance of porous organic peat underlain by silt and glacial till" -US-ICh,27729,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION_TAXONOMY,Other -US-ICh,12077,GRP_STATE,STATE,AK -US-ICh,81389,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Eugenie Euskirchen -US-ICh,81389,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-ICh,81389,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,seeuskirchen@alaska.edu -US-ICh,81389,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Alaska Fairbanks -US-ICh,81389,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Institute of Arctic Biology, 2140 Koyukuk Dr, Irving I rm 402, Fairbanks, AK 99775" -US-ICh,81392,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Syndonia Bret-Harte -US-ICh,81392,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-ICh,81392,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,msbretharte@alaska.edu -US-ICh,81392,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Alaska Fairbanks -US-ICh,81392,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Institute of Arctic Biology, 2140 Koyukuk Dr, Irving I rm 313, Fairbanks, AK 99775" -US-ICh,95242,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Colin Edgar -US-ICh,95242,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-ICh,95242,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,cedgar3@alaska.edu -US-ICh,95242,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Alaska Fairbanks -US-ICh,95242,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"2140 Koyukuk Dr, Irving I rm 313, Fairbanks, AK 99775" -US-ICh,98373,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Gaius Shaver -US-ICh,98373,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Affiliate -US-ICh,98373,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,gshaver@mbl.edu -US-ICh,98373,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Marine Biological Laboratory -US-ICh,98373,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"The Ecosystems Center, 7 MBL Street,Woods Hole, MA USA 02543" -US-ICh,29856,GRP_TOWER_POWER,TOWER_POWER,Other -US-ICh,12079,GRP_TOWER_TYPE,TOWER_TYPE,tripod -US-ICh,12080,GRP_URL,URL,http://aon.iab.uaf.edu/imnavait -US-ICh,24000499,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-ICh -US-ICh,12081,GRP_UTC_OFFSET,UTC_OFFSET,-9 -US-ICs,12085,GRP_CLIM_AVG,MAT,-7.4 -US-ICs,12085,GRP_CLIM_AVG,MAP,318 -US-ICs,12085,GRP_CLIM_AVG,CLIMATE_KOEPPEN,ET -US-ICs,27000496,GRP_COUNTRY,COUNTRY,USA -US-ICs,15750,GRP_DOI,DOI,10.17190/AMF/1246130 -US-ICs,15750,GRP_DOI,DOI_CITATION,"Eugenie Euskirchen, Gaius Shaver, Syndonia Bret-Harte (2022), AmeriFlux BASE US-ICs Imnavait Creek Watershed Wet Sedge Tundra, Ver. 6-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1246130" -US-ICs,15750,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-ICs,32286,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-ICs,32286,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Eugenie Euskirchen -US-ICs,32286,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-ICs,32286,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,seeuskirchen@alaska.edu -US-ICs,32286,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of Alaska Fairbanks -US-ICs,32288,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-ICs,32288,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Gaius Shaver -US-ICs,32288,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-ICs,32288,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,gshaver@mbl.edu -US-ICs,32288,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Marine Biological Laboratory -US-ICs,32287,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-ICs,32287,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Syndonia Bret-Harte -US-ICs,32287,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-ICs,32287,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,msbretharte@alaska.edu -US-ICs,32287,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of Alaska Fairbanks -US-ICs,32290,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Marine Biological Laboratory -US-ICs,32290,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-ICs,32291,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,University of Alaska Fairbanks -US-ICs,32291,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-ICs,93363,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,National Science Foundation -US-ICs,93363,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-ICs,32289,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,NSF -US-ICs,32289,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-ICs,12086,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Undisturbed -US-ICs,12087,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-ICs,12087,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-ICs,12087,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,2007 -US-ICs,12087,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-ICs,91774,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-ICs,91774,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CH4 -US-ICs,91774,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20120712 -US-ICs,91774,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Growing season operation only -US-ICs,91774,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,CH4 measurements are generally from mid-May to mid-September due to power limitations. -US-ICs,23000496,GRP_HEADER,SITE_NAME,Imnavait Creek Watershed Wet Sedge Tundra -US-ICs,12088,GRP_IGBP,IGBP,WET -US-ICs,12089,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-ICs,12089,GRP_LAND_OWNERSHIP,LAND_OWNER,BLM -US-ICs,12090,GRP_LOCATION,LOCATION_LAT,68.6058 -US-ICs,12090,GRP_LOCATION,LOCATION_LONG,-149.3110 -US-ICs,12090,GRP_LOCATION,LOCATION_ELEV,920 -US-ICs,12091,GRP_NETWORK,NETWORK,AmeriFlux -US-ICs,86973,GRP_NETWORK,NETWORK,Phenocam -US-ICs,1700006924,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Euskirchen, E. S., Bret-Harte, M. S., Scott, G. J., Edgar, C., Shaver, G. R. (2012) Seasonal Patterns Of Carbon Dioxide And Water Fluxes In Three Representative Tundra Ecosystems In Northern Alaska, Ecosphere, 3(1), 1-19" -US-ICs,1700006924,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1890/ES11-00202.1 -US-ICs,1700006924,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-ICs,1700008397,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Euskirchen, E. S., Bret-Harte, M. S., Shaver, G. R., Edgar, C. W., Romanovsky, V. E. (2017) Long-Term Release Of Carbon Dioxide From Arctic Tundra Ecosystems In Alaska, Ecosystems, 20(5), 960-974" -US-ICs,1700008397,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1007/S10021-016-0085-9 -US-ICs,1700008397,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-ICs,1700004821,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Kade, A., Bret-Harte, M. S., Euskirchen, E. S., Edgar, C., Fulweber, R. A. (2012) Upscaling Of CO2 Fluxes From Heterogeneous Tundra Plant Communities In Arctic Alaska, Journal Of Geophysical Research: Biogeosciences, 117(G4), n/a-n/a" -US-ICs,1700004821,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2012JG002065 -US-ICs,1700004821,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-ICs,1700003813,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Qiu, C., Zhu, D., Ciais, P., Guenet, B., Krinner, G., Peng, S., Aurela, M., Bernhofer, C., Brümmer, C., Bret-Harte, S., Chu, H., Chen, J., Desai, A. R., Dušek, J., Euskirchen, E. S., Fortuniak, K., Flanagan, L. B., Friborg, T., Grygoruk, M., Gogo, S., Grünwald, T., Hansen, B. U., Holl, D., Humphreys, E., Hurkuck, M., Kiely, G., Klatt, J., Kutzbach, L., Largeron, C., Laggoun-Défarge, F., Lund, M., Lafleur, P. M., Li, X., Mammarella, I., Merbold, L., Nilsson, M. B., Olejnik, J., Ottosson-Löfvenius, M., Oechel, W., Parmentier, F. W., Peichl, M., Pirk, N., Peltola, O., Pawlak, W., Rasse, D., Rinne, J., Shaver, G., Schmid, H. P., Sottocornola, M., Steinbrecher, R., Sachs, T., Urbaniak, M., Zona, D., Ziemblinska, K. (2018) Orchidee-Peat (Revision 4596), A Model For Northern Peatland Co&Lt;Sub&Gt;2&Lt;/Sub&Gt;, Water, And Energy Fluxes On Daily To Annual Scales, Geoscientific Model Development, 11(2), 497-519" -US-ICs,1700003813,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.5194/GMD-11-497-2018 -US-ICs,1700003813,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-ICs,12093,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"The research approach of the US Study of Environmental Arctic Change (SEARCH) program, created by Arctic Observatory Networks (AON), is to seek development and deployment of a pan-arctic observing system that will measure the full range of continuing changes now underway in the Arctic. This project focuses on simultaneous measurements of carbon, water, and energy fluxes of the terrestrial landscape at hourly, daily, seasonal, and multi-year time scales. These are major regulatory drivers of the Arctic system and form key linkages and feedbacks between the land surface, the atmosphere, and the oceans. There are three automated weather stations deployed at Imnavait Creek in support of the AON objectives: The Ridge Station, the Biocomplexity Station, and the Fen Station. These stations will provide a comprehensive description of the state of the regional Arctic system with respect to these variables, its overall regulation and controlling features, and its interaction with the global system. In the longer-term, this project will provide a legacy of data, a network of observing platforms, and a set of clear protocols for long-term observation and further analysis." -US-ICs,95235,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"AON / Bret-Harte -IAB Toolik 757005 -2120 Koyukuk Dr #138 -Fairbanks, AK 99775-7005" -US-ICs,12094,GRP_SITE_CHAR,TERRAIN,"Significant Slope (>5%, <10%)" -US-ICs,12094,GRP_SITE_CHAR,ASPECT,W -US-ICs,12095,GRP_SITE_DESC,SITE_DESC,"The Imnavait Creek Watershed Wet Sedge Tundra (Fen Station) is located near Imnavait Creek in Alaska, north of the Brooks Range in the Kuparuk basin near Lake Toolik and the Toolik Field Station. The Kuparuk River has its headwaters in the Brooks Range and drains through northern Alaska into the Arctic Ocean. Within these headwaters lies the Imnavait basin at an average elevation of 930 m. Water tracks run down the hill in parallel zones with a spacing of approximately 10 m. The Fen Station was deployed at the end of Summer 2007." -US-ICs,12096,GRP_SITE_FUNDING,SITE_FUNDING,NSF -US-ICs,28095,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION,"Embedded in piedmont hills, with a predominance of porous organic peat underlain by silt and glacial till" -US-ICs,28095,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION_TAXONOMY,Other -US-ICs,12097,GRP_STATE,STATE,AK -US-ICs,81395,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Eugenie Euskirchen -US-ICs,81395,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-ICs,81395,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,seeuskirchen@alaska.edu -US-ICs,81395,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Alaska Fairbanks -US-ICs,81395,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Institute of Arctic Biology, Institute of Arctic Biology, 2140 Koyukuk Dr, Irving I rm 402, Fairbanks, AK 99775" -US-ICs,81396,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Syndonia Bret-Harte -US-ICs,81396,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-ICs,81396,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,msbretharte@alaska.edu -US-ICs,81396,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Alaska Fairbanks -US-ICs,81396,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Institute of Arctic Biology, Institute of Arctic Biology, 2140 Koyukuk Dr, Irving I rm 402, Fairbanks, AK 99775" -US-ICs,95237,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Colin Edgar -US-ICs,95237,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-ICs,95237,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,cedgar3@alaska.edu -US-ICs,95237,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Alaska Fairbanks -US-ICs,95237,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Institute of Arctic Biology, 2140 Koyukuk Dr, Irving I rm 313, Fairbanks, AK 99775" -US-ICs,98359,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Gaius Shaver -US-ICs,98359,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Affiliate -US-ICs,98359,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,gshaver@mbl.edu -US-ICs,98359,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Marine Biological Laboratory -US-ICs,98359,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"The Ecosystems Center, 7 MBL Street,Woods Hole, MA USA 02543" -US-ICs,29853,GRP_TOWER_POWER,TOWER_POWER,Other -US-ICs,12099,GRP_TOWER_TYPE,TOWER_TYPE,tripod -US-ICs,12100,GRP_URL,URL,http://aon.iab.uaf.edu/imnavait -US-ICs,24000496,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-ICs -US-ICs,12101,GRP_UTC_OFFSET,UTC_OFFSET,-9 -US-ICt,12105,GRP_CLIM_AVG,MAT,-7.4 -US-ICt,12105,GRP_CLIM_AVG,MAP,318 -US-ICt,12105,GRP_CLIM_AVG,CLIMATE_KOEPPEN,ET -US-ICt,27000497,GRP_COUNTRY,COUNTRY,USA -US-ICt,15621,GRP_DOI,DOI,10.17190/AMF/1246131 -US-ICt,15621,GRP_DOI,DOI_CITATION,"Eugenie Euskirchen, Gaius Shaver, Syndonia Bret-Harte (2022), AmeriFlux BASE US-ICt Imnavait Creek Watershed Tussock Tundra, Ver. 4-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1246131" -US-ICt,15621,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-ICt,32293,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-ICt,32293,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Eugenie Euskirchen -US-ICt,32293,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-ICt,32293,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,seeuskirchen@alaska.edu -US-ICt,32293,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of Alaska Fairbanks -US-ICt,32294,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-ICt,32294,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Gaius Shaver -US-ICt,32294,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-ICt,32294,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,gshaver@mbl.edu -US-ICt,32294,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Marine Biological Laboratory -US-ICt,32292,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-ICt,32292,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Syndonia Bret-Harte -US-ICt,32292,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-ICt,32292,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,msbretharte@alaska.edu -US-ICt,32292,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of Alaska Fairbanks -US-ICt,32297,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Marine Biological Laboratory -US-ICt,32297,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-ICt,32296,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,University of Alaska Fairbanks -US-ICt,32296,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-ICt,32295,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,NSF -US-ICt,32295,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-ICt,12106,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Undisturbed -US-ICt,12107,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-ICt,12107,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-ICt,12107,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,2007 -US-ICt,12107,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-ICt,23000497,GRP_HEADER,SITE_NAME,Imnavait Creek Watershed Tussock Tundra -US-ICt,12108,GRP_IGBP,IGBP,OSH -US-ICt,12109,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-ICt,12109,GRP_LAND_OWNERSHIP,LAND_OWNER,BLM -US-ICt,12110,GRP_LOCATION,LOCATION_LAT,68.6063 -US-ICt,12110,GRP_LOCATION,LOCATION_LONG,-149.3041 -US-ICt,12110,GRP_LOCATION,LOCATION_ELEV,930 -US-ICt,12111,GRP_NETWORK,NETWORK,AmeriFlux -US-ICt,86974,GRP_NETWORK,NETWORK,Phenocam -US-ICt,1700007497,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Euskirchen, E. S., Bret-Harte, M. S., Scott, G. J., Edgar, C., Shaver, G. R. (2012) Seasonal Patterns Of Carbon Dioxide And Water Fluxes In Three Representative Tundra Ecosystems In Northern Alaska, Ecosphere, 3(1), 1-19" -US-ICt,1700007497,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1890/ES11-00202.1 -US-ICt,1700007497,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-ICt,1700000288,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Euskirchen, E. S., Bret-Harte, M. S., Shaver, G. R., Edgar, C. W., Romanovsky, V. E. (2017) Long-Term Release Of Carbon Dioxide From Arctic Tundra Ecosystems In Alaska, Ecosystems, 20(5), 960-974" -US-ICt,1700000288,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1007/S10021-016-0085-9 -US-ICt,1700000288,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-ICt,1700008391,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Kade, A., Bret-Harte, M. S., Euskirchen, E. S., Edgar, C., Fulweber, R. A. (2012) Upscaling Of CO2 Fluxes From Heterogeneous Tundra Plant Communities In Arctic Alaska, Journal Of Geophysical Research: Biogeosciences, 117(G4), n/a-n/a" -US-ICt,1700008391,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2012JG002065 -US-ICt,1700008391,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-ICt,12113,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"The research approach of the US Study of Environmental Arctic Change (SEARCH) program, created by Arctic Observatory Networks (AON), is to seek development and deployment of a pan-arctic observing system that will measure the full range of continuing changes now underway in the Arctic. This project focuses on simultaneous measurements of carbon, water, and energy fluxes of the terrestrial landscape at hourly, daily, seasonal, and multi-year time scales. These are major regulatory drivers of the Arctic system and form key linkages and feedbacks between the land surface, the atmosphere, and the oceans. There are three automated weather stations deployed at Imnavait Creek in support of the AON objectives: The Ridge Station, the Biocomplexity Station, and the Fen Station. These stations will provide a comprehensive description of the state of the regional Arctic system with respect to these variables, its overall regulation and controlling features, and its interaction with the global system. In the longer-term, this project will provide a legacy of data, a network of observing platforms, and a set of clear protocols for long-term observation and further analysis." -US-ICt,95239,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"AON / Bret-Harte -IAB Toolik 757005 -2120 Koyukuk Dr #138 -Fairbanks, AK 99775-7005" -US-ICt,12114,GRP_SITE_CHAR,TERRAIN,"Significant Slope (>5%, <10%)" -US-ICt,12114,GRP_SITE_CHAR,ASPECT,W -US-ICt,12115,GRP_SITE_DESC,SITE_DESC,"The Imnavait Creek Watershed Tussock Tundra (Biocomplexity Station) is located near Imnavait Creek in Alaska, north of the Brooks Range in the Kuparuk basin near Lake Toolik and the Toolik Field Station. The Kuparuk River has its headwaters in the Brooks Range and drains through northern Alaska into the Arctic Ocean. Within these headwaters lies the Imnavait basin at an average elevation of 930 m. Water tracks run down the hill in parallel zones with a spacing of approximately 10 m. The Biocomplexity Station was deployed in 2004, and it has been in operation during the melt seasons ever since." -US-ICt,12116,GRP_SITE_FUNDING,SITE_FUNDING,NSF -US-ICt,28788,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION,"Embedded in piedmont hills, with a predominance of porous organic peat underlain by silt and glacial till" -US-ICt,28788,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION_TAXONOMY,Other -US-ICt,12117,GRP_STATE,STATE,AK -US-ICt,81398,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Eugenie Euskirchen -US-ICt,81398,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-ICt,81398,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,seeuskirchen@alaska.edu -US-ICt,81398,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Alaska Fairbanks -US-ICt,81398,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Institute of Arctic Biology, 2140 Koyukuk Dr, Irving I rm 402, Fairbanks, AK 99775" -US-ICt,81400,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Syndonia Bret-Harte -US-ICt,81400,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-ICt,81400,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,msbretharte@alaska.edu -US-ICt,81400,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Alaska Fairbanks -US-ICt,81400,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Institute of Arctic Biology, 2140 Koyukuk Dr, Irving I rm 313, Fairbanks, AK 99775" -US-ICt,95236,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Colin Edgar -US-ICt,95236,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-ICt,95236,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,cedgar3@alaska.edu -US-ICt,95236,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Alaska Fairbanks -US-ICt,95236,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Institute of Arctic Biology, 2140 Koyukuk Dr, Irving I rm 313, Fairbanks, AK 99775" -US-ICt,98368,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Gaius Shaver -US-ICt,98368,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Affiliate -US-ICt,98368,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,gshaver@mbl.edu -US-ICt,98368,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Marine Biological Laboratory -US-ICt,98368,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"The Ecosystems Center, 7 MBL Street,Woods Hole, MA USA 02543" -US-ICt,29854,GRP_TOWER_POWER,TOWER_POWER,Other -US-ICt,12119,GRP_TOWER_TYPE,TOWER_TYPE,tripod -US-ICt,12120,GRP_URL,URL,http://aon.iab.uaf.edu/imnavait -US-ICt,24000497,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-ICt -US-ICt,12121,GRP_UTC_OFFSET,UTC_OFFSET,-9 -US-IL1,95751,GRP_CLIM_AVG,MAT,22.5 -US-IL1,95751,GRP_CLIM_AVG,MAP,1300 -US-IL1,95751,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Cfa -US-IL1,27001189,GRP_COUNTRY,COUNTRY,USA -US-IL1,95753,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Grazing -US-IL1,95767,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-IL1,95767,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-IL1,95767,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201306031130 -US-IL1,95767,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-IL1,95750,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-IL1,95750,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CH4 -US-IL1,95750,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201306031130 -US-IL1,95750,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-IL1,95764,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-IL1,95764,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-IL1,95764,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201306031130 -US-IL1,95764,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-IL1,23001189,GRP_HEADER,SITE_NAME,Paspalum notatum long rotational grazing -US-IL1,95765,GRP_IGBP,IGBP,GRA -US-IL1,95765,GRP_IGBP,IGBP_COMMENT,Dominant species: Paspalum notatum -US-IL1,95756,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -US-IL1,95756,GRP_LAND_OWNERSHIP,LAND_OWNER,John D. and Catherine T. MacArthur Foundation -US-IL1,95758,GRP_LOCATION,LOCATION_LAT,27.1879 -US-IL1,95758,GRP_LOCATION,LOCATION_LONG,-81.1996 -US-IL1,95758,GRP_LOCATION,LOCATION_ELEV,14.7 -US-IL1,95758,GRP_LOCATION,LOCATION_DATE_START,201607010000 -US-IL1,95758,GRP_LOCATION,LOCATION_COMMENT,Buck Island Ranch (BIR) -US-IL1,95754,GRP_NETWORK,NETWORK,AmeriFlux -US-IL1,95760,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"Biogeochemistry, environemntal sustainability, Ecology, Plant diversity" -US-IL1,95763,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"300 Buck Island Ranch Road, Lake Placid, FL 33852" -US-IL1,95747,GRP_SITE_CHAR,TERRAIN,Flat -US-IL1,95747,GRP_SITE_CHAR,ASPECT,FLAT -US-IL1,95747,GRP_SITE_CHAR,WIND_DIRECTION,S -US-IL1,95747,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,100 -US-IL1,95747,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,0 -US-IL1,95761,GRP_SITE_DESC,SITE_DESC,Improved pasture; no fertilizer/herbicide applied; pasture burned in 2017; no weed removal; long-rotational grazing -US-IL1,95762,GRP_SITE_FUNDING,SITE_FUNDING,USDA -US-IL1,95759,GRP_STATE,STATE,FL -US-IL1,95757,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Carl Bernacchi -US-IL1,95757,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-IL1,95757,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,bernacch@illinois.edu -US-IL1,95757,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,USDA/University of Illinois Urbana-Champaign -US-IL1,95748,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Nuria Gomez-Casanovas -US-IL1,95748,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,AncContact -US-IL1,95748,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,ngomezca@igb.illinois.edu -US-IL1,95748,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,USDA/University of Illinois Urbana-Champaign -US-IL1,95755,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Katie Bowman -US-IL1,95755,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Technician -US-IL1,95755,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,krhodges@illinois.edu -US-IL1,95755,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,USDA/University of Illinois Urbana-Champaign -US-IL1,95766,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Taylor Pederson -US-IL1,95766,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Technician -US-IL1,95766,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,tpeders2@illinois.edu -US-IL1,95766,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,USDA/University of Illinois Urbana-Champaign -US-IL1,95752,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-IL1,95768,GRP_TOWER_TYPE,TOWER_TYPE,other -US-IL1,24001189,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-IL1 -US-IL1,95749,GRP_UTC_OFFSET,UTC_OFFSET,-5 -US-IL1,95749,GRP_UTC_OFFSET,UTC_OFFSET_DATE_START,201306031130 -US-Jo1,89951,GRP_CLIM_AVG,MAT,14.7 -US-Jo1,89951,GRP_CLIM_AVG,MAP,245.1 -US-Jo1,89951,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Bwk -US-Jo1,27001113,GRP_COUNTRY,COUNTRY,USA -US-Jo1,95208,GRP_DOI,DOI,10.17190/AMF/1767833 -US-Jo1,95208,GRP_DOI,DOI_CITATION,"Craig Tweedie (2022), AmeriFlux BASE US-Jo1 Jornada Experimental Range Bajada Site, Ver. 2-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1767833" -US-Jo1,95208,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-Jo1,95185,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Jo1,95185,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Craig Tweedie -US-Jo1,95185,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Jo1,95185,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,ctweedie@utep.edu -US-Jo1,95185,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of Texas at El Paso (UTEP) -US-Jo1,95200,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,University of Texas at El Paso (UTEP) -US-Jo1,95200,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-Jo1,89966,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Drought -US-Jo1,89955,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Grazing -US-Jo1,89970,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Land cover change -US-Jo1,89954,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Jo1,89954,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-Jo1,89954,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201001270000 -US-Jo1,89954,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Jo1,89954,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,measurement height is 5m -US-Jo1,89967,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Jo1,89967,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-Jo1,89967,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201001270000 -US-Jo1,89967,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Jo1,89953,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Jo1,89953,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-Jo1,89953,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201001270000 -US-Jo1,89953,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Jo1,23001113,GRP_HEADER,SITE_NAME,Jornada Experimental Range Bajada Site -US-Jo1,89972,GRP_IGBP,IGBP,OSH -US-Jo1,89972,GRP_IGBP,IGBP_DATE_START,201001270000 -US-Jo1,89968,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -US-Jo1,89968,GRP_LAND_OWNERSHIP,LAND_OWNER,Jornada Experimental Range Long-Term Ecological Research (LTER) Site -US-Jo1,89962,GRP_LOCATION,LOCATION_LAT,32.5820 -US-Jo1,89962,GRP_LOCATION,LOCATION_LONG,-106.6350 -US-Jo1,89962,GRP_LOCATION,LOCATION_ELEV,1188 -US-Jo1,89962,GRP_LOCATION,LOCATION_DATE_START,201001270000 -US-Jo1,89962,GRP_LOCATION,LOCATION_COMMENT,The tower has been in the same location since it was established -US-Jo1,89963,GRP_NETWORK,NETWORK,AmeriFlux -US-Jo1,89971,GRP_NETWORK,NETWORK,LTER -US-Jo1,89960,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"Long-term ecosystem CO2, water, and energy balance monitoring" -US-Jo1,89952,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"The University of Texas at El Paso, Department of Biological Sciences, College of Science, 500 W University, El Paso, TX 79902" -US-Jo1,89973,GRP_SITE_CHAR,TERRAIN,"Medium Slope (>2 %, <5%)" -US-Jo1,89973,GRP_SITE_CHAR,ASPECT,FLAT -US-Jo1,89973,GRP_SITE_CHAR,WIND_DIRECTION,S -US-Jo1,89973,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,300 -US-Jo1,89973,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,5 -US-Jo1,95064,GRP_SITE_DESC,SITE_DESC,"The Jornada Basin Experimental Range (JER) covers 783 km2 in the La Jornada del Muerto Plain of the northern Chihuahuan Desert and is located 20km of Las Cruces, NM. Extensive livestock grazing at the JER and througout the US Southwest was coincident with large-scale grassland deterioration and transition to shrubland begining in the 1800s. The JER was established n 1912 to investigate these rangeland changes and has since become a central location for understanding dryland ecology. This flux tower monitors CO2 and H2O dynamics in a representative shrubland on the piedmont slope (bajada) of the San Andreas mountains. The dominant shrubs are evergreen Larrea tridentata (Creosote) and winter-deciduous Prosopis glandulosa (Honey Mesquite). Other cover types include Flourensia cernua (tarbush) and patchy occurences of the grasses Muhlenbergia porteri (Bush Muhly) and Dasyochloa pulchella (Fluff Grass). The site is occasionally visited by stray domestic cattle, free-ranging introduced Oryx, and other native herbivores (Jack Rabbits, Desert Pronghorn). Soils at the site are Ustic Calciargids and parent material consists of limestone, other sedimentary rock, and some igneous rock. -Virtual Site Visit: https://youtu.be/v1uJCKuicqs​" -US-Jo1,89974,GRP_STATE,STATE,NM -US-Jo1,90964,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Craig Tweedie -US-Jo1,90964,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Jo1,90964,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,ctweedie@utep.edu -US-Jo1,90964,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Texas at El Paso (UTEP) -US-Jo1,90964,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"The University of Texas at El Paso, Department of Biological Sciences, College of Science, 500 W University, El Paso, TX 79902" -US-Jo1,89961,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Marguerite Mauritz -US-Jo1,89961,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-Jo1,89961,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,memauritz@utep.edu -US-Jo1,89961,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Texas at El Paso (UTEP) -US-Jo1,89961,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"The University of Texas at El Paso, Department of Biological Sciences, College of Science, 500 W University, El Paso, TX 79902" -US-Jo1,89964,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Gesuri Ramirez -US-Jo1,89964,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,DataManager -US-Jo1,89964,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,gramirez12@utep.edu -US-Jo1,89964,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Texas at El Paso (UTEP) -US-Jo1,89964,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"The University of Texas at El Paso, Department of Biological Sciences, College of Science, 500 W University, El Paso, TX 79902" -US-Jo1,89959,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-Jo1,89965,GRP_TOWER_TYPE,TOWER_TYPE,triangle -US-Jo1,89956,GRP_URL,URL,https://selutep.squarespace.com -US-Jo1,24001113,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-Jo1 -US-Jo1,89957,GRP_UTC_OFFSET,UTC_OFFSET,-7 -US-Jo1,89957,GRP_UTC_OFFSET,UTC_OFFSET_COMMENT,offset between UTC and US Mountain Standard Time (MST) -US-Jo2,90743,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,Funding for the operation and maintenance of the Jornada Experimental Range Mixed Shrubland was provide by the NSF LTER Program (NSF Grant DEB-1235828) and the US Army Research Office (grant 56059‐EV‐PCS). -US-Jo2,90637,GRP_CLIM_AVG,MAT,17.5 -US-Jo2,90637,GRP_CLIM_AVG,MAP,282.3 -US-Jo2,90637,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Bwk -US-Jo2,27001115,GRP_COUNTRY,COUNTRY,USA -US-Jo2,91677,GRP_DOI,DOI,10.17190/AMF/1617696 -US-Jo2,91677,GRP_DOI,DOI_CITATION,"Enrique R. Vivoni, Eli R. Perez-Ruiz (2022), AmeriFlux BASE US-Jo2 Jornada Experimental Range Mixed Shrubland, Ver. 2-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1617696" -US-Jo2,91677,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-Jo2,91719,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Jo2,91719,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Enrique R. Vivoni -US-Jo2,91719,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Jo2,91719,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,1 -US-Jo2,91719,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0002-2659-9459 -US-Jo2,91719,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,vivoni@asu.edu -US-Jo2,91719,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Arizona State University -US-Jo2,91719,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,2010 -US-Jo2,91719,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_END,2019 -US-Jo2,91717,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Jo2,91717,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Eli R. Perez-Ruiz -US-Jo2,91717,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Jo2,91717,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,2 -US-Jo2,91717,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0003-4954-0238 -US-Jo2,91717,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,eli.perez@asu.edu -US-Jo2,91717,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Arizona State University -US-Jo2,91717,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,2010 -US-Jo2,91717,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_END,2019 -US-Jo2,91649,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Arizona State University -US-Jo2,91649,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-Jo2,91627,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,NSF LTER Program (NSF Grant DEB-1235828) and US Army Research Office (grant 56059‐EV‐PCS). -US-Jo2,91627,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-Jo2,90641,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Grazing -US-Jo2,90642,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Land cover change -US-Jo2,90639,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Jo2,90639,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-Jo2,90639,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20100802 -US-Jo2,90639,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Jo2,90649,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Jo2,90649,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-Jo2,90649,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20100802 -US-Jo2,90649,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Jo2,90651,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Jo2,90651,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-Jo2,90651,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20100802 -US-Jo2,90651,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Jo2,23001115,GRP_HEADER,SITE_NAME,Jornada Experimental Range Mixed Shrubland -US-Jo2,90636,GRP_IGBP,IGBP,OSH -US-Jo2,90636,GRP_IGBP,IGBP_COMMENT,"Vegetation of the study sites correspond to a mixed shrubland of the Chihuahuan desert, with four main shrubs species, mariola (Parthenium incanum), mesquite (Prosopis glandulosa), creosote bush (Larrea tridentata) and tarbush (Flourensia cernua). The site have a small coverage of grasses, mainly mush muhly (Muhlenbergia porteri), tobosa grass (Pleuraphis mutica) and dropseed ( Sporobolus sp.), and weeds, mainly snakeweed (Gurierrezia sarothrae) and globe mallow (Sphaeralcea angustifolia)." -US-Jo2,90646,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-Jo2,90646,GRP_LAND_OWNERSHIP,LAND_OWNER,USDA-ARS -US-Jo2,90653,GRP_LOCATION,LOCATION_LAT,32.5849 -US-Jo2,90653,GRP_LOCATION,LOCATION_LONG,-106.6032 -US-Jo2,90653,GRP_LOCATION,LOCATION_ELEV,1469 -US-Jo2,90653,GRP_LOCATION,LOCATION_DATE_START,20100802 -US-Jo2,90653,GRP_LOCATION,LOCATION_COMMENT,The tower is located in the upstream edge of a small first order watershed in an arid piedmont slope. -US-Jo2,90652,GRP_NETWORK,NETWORK,AmeriFlux -US-Jo2,90645,GRP_NETWORK,NETWORK,LTER -US-Jo2,1700000897,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Anderson, C. A., Vivoni, E. R. (2016) Impact Of Land Surface States Within The Flux Footprint On Daytime Land-Atmosphere Coupling In Two Semiarid Ecosystems Of The Southwestern U.S., Water Resources Research, 52(6), 4785-4800" -US-Jo2,1700000897,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/2015WR018016 -US-Jo2,1700000897,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Jo2,1700006144,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Biederman, J. A., Scott, R. L., Arnone III, J. A., Jasoni, R. L., Litvak, M. E., Moreo, M. T., Papuga, S. A., Ponce-Campos, G. E., Schreiner-McGraw, A. P., Vivoni, E. R. (2018) Shrubland Carbon Sink Depends Upon Winter Water Availability In The Warm Deserts Of North America, Agricultural And Forest Meteorology, 249(1), 407-419" -US-Jo2,1700006144,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2017.11.005 -US-Jo2,1700006144,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Jo2,1700002274,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Mascaro, G., Vivoni, E. R. (2016) On The Observed Hysteresis In Field-Scale Soil Moisture Variability And Its Physical Controls, Environmental Research Letters, 11(8), 084008" -US-Jo2,1700002274,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1088/1748-9326/11/8/084008 -US-Jo2,1700002274,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Jo2,1700008607,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Schreiner-McGraw, A. P., Vivoni, E. R. (2017) Percolation Observations In An Arid Piedmont Watershed And Linkages To Historical Conditions In The Chihuahuan Desert, Ecosphere, 8(11), e02000" -US-Jo2,1700008607,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/ECS2.2000 -US-Jo2,1700008607,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Primary_Citation -US-Jo2,1700006129,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Schreiner-McGraw, A. P., Vivoni, E. R., Ajami, H., Sala, O. E., Throop, H. L., Peters, D. P. (2020) Woody Plant Encroachment Has A Larger Impact Than Climate Change On Dryland Water Budgets, Scientific Reports, 10(1), 4498-4518" -US-Jo2,1700006129,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1038/S41598-020-65094-X -US-Jo2,1700006129,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Jo2,1700004689,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Schreiner-McGraw, A. P., Vivoni, E. R., Mascaro, G., Franz, T. E. (2016) Closing The Water Balance With Cosmic-Ray Soil Moisture Measurements And Assessing Their Relation To Evapotranspiration In Two Semiarid Watersheds, Hydrology And Earth System Sciences, 20(1), 329-345" -US-Jo2,1700004689,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.5194/HESS-20-329-2016 -US-Jo2,1700004689,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Jo2,1700005229,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Schreiner‐McGraw, A. P., Vivoni, E. R. (2018) On The Sensitivity Of Hillslope Runoff And Channel Transmission Losses In Arid Piedmont Slopes, Water Resources Research, 54(7), 4498-4518" -US-Jo2,1700005229,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018WR022842 -US-Jo2,1700005229,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Jo2,1700003237,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Templeton, R. C., Vivoni, E. R., Méndez-Barroso, L. A., Pierini, N. A., Anderson, C. A., Rango, A., Laliberte, A. S., Scott, R. L. (2014) High-Resolution Characterization Of A Semiarid Watershed: Implications On Evapotranspiration Estimates, Journal Of Hydrology, 509(), 306-319" -US-Jo2,1700003237,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.JHYDROL.2013.11.047 -US-Jo2,1700003237,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Primary_Citation -US-Jo2,1700003027,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Templeton, R. C., Vivoni, E. R., Méndez-Barroso, L. A., Pierini, N. A., Anderson, C. A., Rango, A., Laliberte, A. S., Scott, R. L. (2014) High-Resolution Characterization Of A Semiarid Watershed: Implications On Evapotranspiration Estimates, Journal Of Hydrology, 509(8), 306-319" -US-Jo2,1700003027,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.JHYDROL.2013.11.047 -US-Jo2,1700003027,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Primary_Citation -US-Jo2,92876,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,Watershed hydrology and ecohydrology -US-Jo2,90654,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"ISTB4 Room 795, 781 E Terrace Rd, Tempe, AZ 85287" -US-Jo2,90644,GRP_SITE_CHAR,TERRAIN,"Medium Slope (>2 %, <5%)" -US-Jo2,90644,GRP_SITE_CHAR,ASPECT,W -US-Jo2,90644,GRP_SITE_CHAR,WIND_DIRECTION,SSW -US-Jo2,90644,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,450 -US-Jo2,90644,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,3 -US-Jo2,90656,GRP_SITE_DESC,SITE_DESC,"The study area is in a mixed shrub-dominated portion of the San Andres Mountain piedmont, along the southeastern boundary of the Jornada Experimental Range (JER) in southern New Mexico, USA. The JER was established in 1912 as a response of scientis and landowner to the shrub enchroachment and loss of grasses due to extended grazing during the late 1800s, fire and climate change. JER has been a NSF LTER site since 1981.The study site is a small watershed (4.67 ha) in an alluvial slope or bajada, with three major areas (north-, south- and west-facing hillslopes) with low to moderate slopes (∼0–6°) with a mean slope of 2.6°, while the channel banks and propagating channel heads have higher slopes (∼15–25°). The site is charactetized by a high bare soil coverage (∼66%), ∼28% of mixed shrubs coverage and a low coverage of grass (∼4%) and weeds (∼2%)." -US-Jo2,90731,GRP_SITE_FUNDING,SITE_FUNDING,NSF LTER Program (NSF Grant DEB-1235828) and US Army Research Office (grant 56059‐EV‐PCS). -US-Jo2,90655,GRP_STATE,STATE,NM -US-Jo2,90657,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Enrique R. Vivoni -US-Jo2,90657,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Jo2,90657,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,vivoni@asu.edu -US-Jo2,90657,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Arizona State University -US-Jo2,90657,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"ISTB4 Room 769, 781 E Terrace Rd, Tempe, AZ 85287" -US-Jo2,90638,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Eli R. Perez-Ruiz -US-Jo2,90638,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-Jo2,90638,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,eli.perez@asu.edu -US-Jo2,90638,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"Arizona State University -and - Universidad Autonoma de Ciudad Juarez" -US-Jo2,90638,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"ISTB4 Room 768, 781 E Terrace Rd, Tempe, AZ 85287 -and -Edificio E, Av. del Charro # 450 Nte. Col. Partido Romero , Cd Juárez, Chihuahua, México, CP 32310" -US-Jo2,90650,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-Jo2,90640,GRP_TOWER_TYPE,TOWER_TYPE,triangle -US-Jo2,92872,GRP_URL,URL,http://hydrology.asu.edu/wiki/index.php -US-Jo2,24001115,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-Jo2 -US-Jo2,90648,GRP_UTC_OFFSET,UTC_OFFSET,-7 -US-Jo2,90648,GRP_UTC_OFFSET,UTC_OFFSET_COMMENT,"The location of the site observes a Standard Time UTC-7 during the winter and a Daylight Time UTC-6 during the summer. Nevertheless, the fluxes and meteorological measurements are taken using the Standard Time UTC-7" -US-Jo3,98958,GRP_CLIM_AVG,MAT,14.7 -US-Jo3,98958,GRP_CLIM_AVG,MAP,245.1 -US-Jo3,98958,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Bwk -US-Jo3,27001218,GRP_COUNTRY,COUNTRY,USA -US-Jo3,98977,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Drought -US-Jo3,98966,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Grazing -US-Jo3,98976,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Hydrologic event -US-Jo3,98968,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Land cover change -US-Jo3,98973,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Jo3,98973,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-Jo3,98973,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20211031 -US-Jo3,98973,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Jo3,98973,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,Measurement height is 2.5m -US-Jo3,98971,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Jo3,98971,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-Jo3,98971,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20211031 -US-Jo3,98971,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Jo3,98969,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Jo3,98969,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-Jo3,98969,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20211031 -US-Jo3,98969,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Jo3,23001218,GRP_HEADER,SITE_NAME,Jornada Experimental Range Red Lake Playa -US-Jo3,98972,GRP_IGBP,IGBP,BSV -US-Jo3,98975,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-Jo3,98975,GRP_LAND_OWNERSHIP,LAND_OWNER,Jornada Experimental Range Long-Term Ecological Research LTER Site -US-Jo3,98970,GRP_LOCATION,LOCATION_LAT,32.7123 -US-Jo3,98970,GRP_LOCATION,LOCATION_LONG,-106.8303 -US-Jo3,98970,GRP_LOCATION,LOCATION_COMMENT,The tower has been in the same location since it was established -US-Jo3,98981,GRP_NETWORK,NETWORK,AmeriFlux -US-Jo3,98983,GRP_NETWORK,NETWORK,CZNet -US-Jo3,98967,GRP_NETWORK,NETWORK,LTER -US-Jo3,98982,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"dryland carbon dynamics, dryland ephemeral lakes (playa), playa hydrology" -US-Jo3,98980,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"The University of Texas at El Paso, Central Receiving -3120 Sunbowl Dr. -Biological Sciences - Mauritz -El Paso, TX, 79902-0537" -US-Jo3,98957,GRP_SITE_CHAR,TERRAIN,Flat -US-Jo3,98957,GRP_SITE_CHAR,WIND_DIRECTION,SSW -US-Jo3,98957,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,400 -US-Jo3,98957,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,5 -US-Jo3,98965,GRP_SITE_DESC,SITE_DESC,"The Jornada Basin Experimental Range (JER) covers 783km2 in the La Jornada del Muerto plain of the Northen Chihuhua Desert and is located 20km of Las Cruses, NM. The region has witnessed extensive grazing of livestocks, which is coincidental with large-scale grassland detoriation and transition to shrubland begining in the 1800s. The JER was established in 1912 to investigate the rangeland changes and has since become the central location for understanding dryland ecology. The flux tower monitors CO2 and H2O dynamics in Red Lake Playa, a large playa in the watershed of the San Andreas Mountain. Wetlands such as prairie potholes, vernal pools, and playas are both ecologically and economically important systems in North America. Playas are ephemerically flooded, depositional landforms located in topographic low areas of hydrologically closed dryland catchments. There are two main types of Playas, as defined by their primary source of floodwater:(a) Surface water and (b) groundwater playas. Surface water playas, such as Red Lake Playa, are flooded through precipitation and surface run-on from upland areas of their catchment and have the potential to be areas of groundwater recharge. The key concept of understanding how nutrients and water redistribution processes control the ecological functioning of drylands is the connectivity of ecosystem patches. Winds and water driven erosional or depositional processes occur at multiple scales in dryalnds, to shape a mosaic of high and low vegetation cover patches. These patches serve as sinks and sources of organic matter, soil particles, and plant propagules. The differential abiotic and biotic structure of these patches affects community structure and the functioning of ecosystems. In closed basin systems, surface water runoffs from uplands can lead to gains for lowland ecoystems like playas and potentially influence biogeochemical processes such as primary productivity." -US-Jo3,98961,GRP_SITE_FUNDING,SITE_FUNDING,NSF Award 2012475 -US-Jo3,98959,GRP_STATE,STATE,NM -US-Jo3,98956,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Marguerite Mauritz -US-Jo3,98956,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Jo3,98956,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,memauritz@utep.edu -US-Jo3,98956,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,The University of Texas at El Paso -US-Jo3,98956,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"The University of Texas at El Paso, Department of Earth and Environmental Resources Science, College of Science" -US-Jo3,98978,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Anthony Darrouzet-Nardi -US-Jo3,98978,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,AncContact -US-Jo3,98978,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,ajdarrouzetnardi@utep.edu -US-Jo3,98978,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"The University of Texas at El Paso, Department of Earth and Environmental Resources Science, College of Science" -US-Jo3,98984,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Gesuri Ramirez -US-Jo3,98984,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,DataManager -US-Jo3,98984,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,gramirez12@utep.edu -US-Jo3,98984,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"The University of Texas at El Paso, Department of Earth and Environmental Resources Science, College of Science" -US-Jo3,98962,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Craig Tweedie -US-Jo3,98962,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Affiliate -US-Jo3,98962,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,ctweedie@utep.edu -US-Jo3,98962,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"The University of Texas at El Paso, Department of Earth and Environmental Resources Science, College of Science" -US-Jo3,98963,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Ifeanyi H. Nwigboji -US-Jo3,98963,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Affiliate -US-Jo3,98963,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,ihnwigboji@miners.utep.edu -US-Jo3,98963,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"The University of Texas at El Paso, Department of Earth and Environmental Resources Science, College of Science" -US-Jo3,98985,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Lixin Jin -US-Jo3,98985,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Affiliate -US-Jo3,98985,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,ljin2@utep.edu -US-Jo3,98985,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"The University of Texas at El Paso, Department of Earth and Environmental Resources Science, College of Science" -US-Jo3,98974,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-Jo3,98979,GRP_TOWER_TYPE,TOWER_TYPE,triangle -US-Jo3,98960,GRP_URL,URL,https://www.drylandcz.org/ -US-Jo3,24001218,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-Jo3 -US-Jo3,98964,GRP_UTC_OFFSET,UTC_OFFSET,-7 -US-Jo3,98964,GRP_UTC_OFFSET,UTC_OFFSET_COMMENT,offset between UTC and US Mountain Standard Time (MST) -US-JRn,87869,GRP_CLIM_AVG,MAT,13.2 -US-JRn,87869,GRP_CLIM_AVG,MAP,1095.5 -US-JRn,87869,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Cfa -US-JRn,27001106,GRP_COUNTRY,COUNTRY,USA -US-JRn,91700,GRP_DOI,DOI,10.17190/AMF/1617714 -US-JRn,91700,GRP_DOI,DOI_CITATION,"Derek Johnson, Gil Bohrer, Jaclyn Hatala Matthes (2020), AmeriFlux BASE US-JRn WV Jacks Run, Ver. 1-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1617714" -US-JRn,91700,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-JRn,91598,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-JRn,91598,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Derek Johnson -US-JRn,91598,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-JRn,91598,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,Derek.Johnson@mail.wvu.edu -US-JRn,91598,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,West Virginia University -US-JRn,91599,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-JRn,91599,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Gil Bohrer -US-JRn,91599,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-JRn,91599,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,bohrer.17@osu.edu -US-JRn,91599,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Ohio State University -US-JRn,91600,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-JRn,91600,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Jaclyn Hatala Matthes -US-JRn,91600,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-JRn,91600,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,jmatthes@wellesley.edu -US-JRn,91600,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Wellesley College -US-JRn,91645,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Ohio State University -US-JRn,91645,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-JRn,91675,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Wellesley College -US-JRn,91675,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-JRn,91644,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,West Virginia University -US-JRn,91644,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-JRn,91622,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,"NSF, Ohio Water Resources Center" -US-JRn,91622,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-JRn,87872,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-JRn,87872,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-JRn,87872,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201709300000 -US-JRn,87872,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,201812310000 -US-JRn,87872,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-JRn,87879,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-JRn,87879,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CH4 -US-JRn,87879,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201709300000 -US-JRn,87879,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,201812310000 -US-JRn,87879,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-JRn,87857,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-JRn,87857,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-JRn,87857,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201709300000 -US-JRn,87857,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,201812310000 -US-JRn,87857,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-JRn,87864,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-JRn,87864,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-JRn,87864,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201709300000 -US-JRn,87864,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,201812310000 -US-JRn,87864,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-JRn,87860,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-JRn,87860,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,Isotopes -US-JRn,87860,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201709300000 -US-JRn,87860,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,201812310000 -US-JRn,87860,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-JRn,23001106,GRP_HEADER,SITE_NAME,WV Jacks Run -US-JRn,87873,GRP_IGBP,IGBP,GRA -US-JRn,87873,GRP_IGBP,IGBP_DATE_START,200101010000 -US-JRn,87880,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -US-JRn,87876,GRP_LOCATION,LOCATION_LAT,39.6789 -US-JRn,87876,GRP_LOCATION,LOCATION_LONG,-80.1646 -US-JRn,87876,GRP_LOCATION,LOCATION_ELEV,384.048 -US-JRn,87876,GRP_LOCATION,LOCATION_DATE_START,201709300000 -US-JRn,87878,GRP_NETWORK,NETWORK,AmeriFlux -US-JRn,87871,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,Methane emissions from hydrofracking operations -US-JRn,87877,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"405 Hitchcock Hall, 2070 Neil Ave., Columbus OH, 43210" -US-JRn,87865,GRP_SITE_CHAR,TERRAIN,Hilltop -US-JRn,87865,GRP_SITE_CHAR,ASPECT,ESE -US-JRn,87865,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,100 -US-JRn,87865,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,91 -US-JRn,87875,GRP_SITE_DESC,SITE_DESC,"CO2 and CH4 fluxes. Site located in a mowed grass meddow patch surrounded by forest, on a hilltop." -US-JRn,87866,GRP_SITE_FUNDING,SITE_FUNDING,"NSF, Ohio Water Resources Center" -US-JRn,87874,GRP_STATE,STATE,WV -US-JRn,87858,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Derek Johnson -US-JRn,87858,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-JRn,87858,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,Derek.Johnson@mail.wvu.edu -US-JRn,87858,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,West Virginia University -US-JRn,87868,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Gil Bohrer -US-JRn,87868,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-JRn,87868,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,bohrer.17@osu.edu -US-JRn,87868,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Ohio State University -US-JRn,87862,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Jaclyn Hatala Matthes -US-JRn,87862,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-JRn,87862,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,jmatthes@wellesley.edu -US-JRn,87862,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Wellesley College -US-JRn,87885,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Chante Vines -US-JRn,87885,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,DataManager -US-JRn,87885,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,vines.24@buckeyemail.osu.edu -US-JRn,87861,GRP_TOWER_POWER,TOWER_POWER,Direct power -US-JRn,87870,GRP_TOWER_TYPE,TOWER_TYPE,triangle -US-JRn,87867,GRP_URL,URL,http://flux.org.ohio-state.edu/ -US-JRn,24001106,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-JRn -US-JRn,87863,GRP_UTC_OFFSET,UTC_OFFSET,-5 -US-JRn,87863,GRP_UTC_OFFSET,UTC_OFFSET_DATE_START,201709300000 -US-KFB,13167,GRP_CLIM_AVG,MAT,12.77 -US-KFB,13167,GRP_CLIM_AVG,MAP,867 -US-KFB,13167,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Cfa -US-KFB,27000547,GRP_COUNTRY,COUNTRY,USA -US-KFB,13168,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Fire -US-KFB,13181,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Temperature extreme -US-KFB,13169,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-KFB,13169,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-KFB,13169,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,2006 -US-KFB,13169,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-KFB,13182,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-KFB,13182,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-KFB,13182,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,2006 -US-KFB,13182,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-KFB,23000547,GRP_HEADER,SITE_NAME,Konza Prairie LTER (4B) -US-KFB,13170,GRP_IGBP,IGBP,GRA -US-KFB,13171,GRP_LOCATION,LOCATION_LAT,39.0745 -US-KFB,13171,GRP_LOCATION,LOCATION_LONG,-96.5951 -US-KFB,13171,GRP_LOCATION,LOCATION_ELEV,330 -US-KFB,13172,GRP_NETWORK,NETWORK,AmeriFlux -US-KFB,1700008160,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Antunes, M. A. H., Walter-Shea, E. A., Mesarch, M. A. (2001) Test Of An Extended Mathematical Approach To Calculate Maize Leaf Area Index And Leaf Angle Distribution, Agricultural And Forest Meteorology, 108(1), 45-53" -US-KFB,1700008160,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/S0168-1923(01)00219-2 -US-KFB,1700008160,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-KFB,1700008982,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Bremer, D. J., Ham, J. M. (1999) Effect Of Spring Burning On The Surface Energy Balance In A Tallgrass Prairie, Agricultural And Forest Meteorology, 97(1), 43-54" -US-KFB,1700008982,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/S0168-1923(99)00034-9 -US-KFB,1700008982,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-KFB,1700002760,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Danner, B. T., Knapp, A. K. (2003) Abiotic Constraints On The Establishment Of Quercus Seedlings In Grassland, Global Change Biology, 9(2), 266-275" -US-KFB,1700002760,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1046/J.1365-2486.2003.00574.X -US-KFB,1700002760,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-KFB,1700000180,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Reich, P. B., Turner, D. P., Bolstad, P. (1999) An Approach To Spatially Distributed Modeling Of Net Primary Production (NPP) At The Landscape Scale And Its Application In Validation Of EOS NPP Products, Remote Sensing Of Environment, 70(1), 69-81" -US-KFB,1700000180,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/S0034-4257(99)00058-9 -US-KFB,1700000180,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-KFB,1700008760,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Scurlock, J. M., Johnson, K., Olson, R. J. (2002) Estimating Net Primary Productivity From Grassland Biomass Dynamics Measurements, Global Change Biology, 8(8), 736-753" -US-KFB,1700008760,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1046/J.1365-2486.2002.00512.X -US-KFB,1700008760,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-KFB,1700004188,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Smith, M. D., Hartnett, D. C., Wilson, G. W. (1999) Interacting Influence Of Mycorrhizal Symbiosis And Competition On Plant Diversity In Tallgrass Prairie, Oecologia, 121(4), 574-582" -US-KFB,1700004188,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1007/S004420050964 -US-KFB,1700004188,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-KFB,1700008556,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Turner, D. P., Cohen, W. B., Kennedy, R. E., Fassnacht, K. S., Briggs, J. M. (1999) Relationships Between Leaf Area Index And Landsat TM Spectral Vegetation Indices Across Three Temperate Zone Sites, Remote Sensing Of Environment, 70(1), 52-68" -US-KFB,1700008556,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/S0034-4257(99)00057-7 -US-KFB,1700008556,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-KFB,1700005340,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Turner, D. P., Urbanski, S., Bremer, D., Wofsy, S. C., Meyers, T., Gower, S. T., Gregory, M. (2003) A Cross-Biome Comparison Of Daily Light Use Efficiency For Gross Primary Production, Global Change Biology, 9(3), 383-395" -US-KFB,1700005340,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1046/J.1365-2486.2003.00573.X -US-KFB,1700005340,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-KFB,30932,GRP_SITE_CHAR,TERRAIN,Undulated/Variable -US-KFB,30932,GRP_SITE_CHAR,ASPECT,SW -US-KFB,30932,GRP_SITE_CHAR,WIND_DIRECTION,SW -US-KFB,30932,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,100.00 -US-KFB,30932,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,20 -US-KFB,13175,GRP_SITE_DESC,SITE_DESC,Site experiencing woody encroachment and is burned every four years -US-KFB,13176,GRP_SITE_FUNDING,SITE_FUNDING,NSF -US-KFB,13177,GRP_STATE,STATE,KS -US-KFB,13178,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Nathaniel Brunsell -US-KFB,13178,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-KFB,13178,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,brunsell@ku.edu -US-KFB,13178,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Kansas University -US-KFB,13178,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Department of Geography, Atmospheric Science Program, 1475 Jayhawk Blvd.,Lawrence, KS 66045-7613" -US-KFB,81401,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Bryan Conrad -US-KFB,81401,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,DataManager -US-KFB,81401,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,bryan.j.conrad@ku.edu -US-KFB,81401,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Kansas University -US-KFB,81401,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Department of Geography, Atmospheric Science Program, 1475 Jayhawk Blvd.,Lawrence, KS 66045-7613" -US-KFB,29881,GRP_TOWER_POWER,TOWER_POWER,Other -US-KFB,13179,GRP_TOWER_TYPE,TOWER_TYPE,tripod -US-KFB,13180,GRP_URL,URL,http://www.konza.ksu.edu -US-KFB,24000547,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-KFB -US-KFB,30933,GRP_UTC_OFFSET,UTC_OFFSET,-6 -US-KFS,11514,GRP_CLIM_AVG,MAT,12 -US-KFS,11514,GRP_CLIM_AVG,MAP,1014 -US-KFS,11514,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Cfa -US-KFS,27000498,GRP_COUNTRY,COUNTRY,USA -US-KFS,15708,GRP_DOI,DOI,10.17190/AMF/1246132 -US-KFS,15708,GRP_DOI,DOI_CITATION,"Nathaniel Brunsell (2020), AmeriFlux BASE US-KFS Kansas Field Station, Ver. 7-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1246132" -US-KFS,15708,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-KFS,32298,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-KFS,32298,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Nathaniel Brunsell -US-KFS,32298,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-KFS,32298,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,brunsell@ku.edu -US-KFS,32298,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Kansas University -US-KFS,32300,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Kansas University -US-KFS,32300,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-KFS,32299,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,NSF -US-KFS,32299,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-KFS,11526,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Fire -US-KFS,11515,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Temperature extreme -US-KFS,11516,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-KFS,11516,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-KFS,11516,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20070617 -US-KFS,11516,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-KFS,11527,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-KFS,11527,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-KFS,11527,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20070617 -US-KFS,11527,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-KFS,23000498,GRP_HEADER,SITE_NAME,Kansas Field Station -US-KFS,11517,GRP_IGBP,IGBP,GRA -US-KFS,30936,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-KFS,30936,GRP_LAND_OWNERSHIP,LAND_OWNER,University of Kansas -US-KFS,11518,GRP_LOCATION,LOCATION_LAT,39.0561 -US-KFS,11518,GRP_LOCATION,LOCATION_LONG,-95.1907 -US-KFS,11518,GRP_LOCATION,LOCATION_ELEV,310 -US-KFS,11518,GRP_LOCATION,LOCATION_COMMENT,From CDIAC Tom Boden database dump -US-KFS,11519,GRP_NETWORK,NETWORK,AmeriFlux -US-KFS,86976,GRP_NETWORK,NETWORK,Phenocam -US-KFS,1700006009,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(11), 108350" -US-KFS,1700006009,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -US-KFS,1700006009,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-KFS,1700006264,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Novick, K. A., Ficklin, D. L., Stoy, P. C., Williams, C. A., Bohrer, G., Oishi, A., Papuga, S. A., Blanken, P. D., Noormets, A., Sulman, B. N., Scott, R. L., Wang, L., Phillips, R. P. (2016) The Increasing Importance Of Atmospheric Demand For Ecosystem Water And Carbon Fluxes, Nature Climate Change, 6(11), 1023-1027" -US-KFS,1700006264,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1038/NCLIMATE3114 -US-KFS,1700006264,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-KFS,1700004041,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Wolf, S., Keenan, T.F., Fisher, J.B., Baldocchi, D.D., Desai, A.R., Richardson, A.D., Scott, R.L., Law, B.E., Litvak, M.E., Brunsell, N.A., Peters, W., van der Laan-Luijkx, I.T. (2016) Warm spring reduced carbon cycle impact of the 2012 US summer drought, Proceedings of the National Academy of Sciences, 113(21), 5880-5885" -US-KFS,1700004041,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1073/PNAS.1519620113 -US-KFS,1700004041,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-KFS,30934,GRP_SITE_CHAR,TERRAIN,"Medium Slope (>2 %, <5%)" -US-KFS,30934,GRP_SITE_CHAR,ASPECT,S -US-KFS,30934,GRP_SITE_CHAR,WIND_DIRECTION,S -US-KFS,30934,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,100 -US-KFS,30934,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,20 -US-KFS,11521,GRP_SITE_DESC,SITE_DESC,"The study is an abandoned grassland at the Kansas Field Station and Ecological Reserves. The site is located within the tallgrass prairie-deciduous forest ecotonal area. The site was subjected to intensive agriculture from the 1940s through the late 1960s. In the mid-1970s, the site was planted with the cool-season grass Bromus inermis and used as a hay meadow until 1987. Then, mowing and burning approximately every five years maintained it as a grassland until 2007, when the eddy flux tower was installed." -US-KFS,11522,GRP_SITE_FUNDING,SITE_FUNDING,NSF -US-KFS,27190,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION,"Fine, montmorillonitic, mesic Aquic Argiudolls" -US-KFS,27190,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION_TAXONOMY,Other -US-KFS,11523,GRP_STATE,STATE,KS -US-KFS,11524,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Nathaniel Brunsell -US-KFS,11524,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-KFS,11524,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,brunsell@ku.edu -US-KFS,11524,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Kansas University -US-KFS,11524,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Department of Geography, Atmospheric Science Program, 1475 Jayhawk Blvd.,Lawrence, KS 66045-7613" -US-KFS,33643,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Bryan Conrad -US-KFS,33643,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,DataManager -US-KFS,33643,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,bryan.j.conrad@ku.edu -US-KFS,33643,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Kansas -US-KFS,33643,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Department of Geography, Atmospheric Science Program, 1475 Jayhawk Blvd.,Lawrence, KS 66045-7613" -US-KFS,33644,GRP_TOWER_POWER,TOWER_POWER,Direct power -US-KFS,11525,GRP_TOWER_TYPE,TOWER_TYPE,other -US-KFS,24000498,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-KFS -US-KFS,30935,GRP_UTC_OFFSET,UTC_OFFSET,-6 -US-KL1,14587,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,"Supported by DOE (DE-FC02-07ER64494, DE-AC05-76RL01830) & NSF-LTER (DEB 1027253)" -US-KL1,14588,GRP_CLIM_AVG,MAT,9.9 -US-KL1,14588,GRP_CLIM_AVG,MAP,1027 -US-KL1,14588,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfa -US-KL1,27000656,GRP_COUNTRY,COUNTRY,USA -US-KL1,93749,GRP_DOI,DOI,10.17190/AMF/1660344 -US-KL1,93749,GRP_DOI,DOI_CITATION,"G. Philip Robertson, Jiquan Chen (2021), AmeriFlux BASE US-KL1 KBS Lux Arbor Reserve Corn, Ver. 2-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1660344" -US-KL1,93749,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-KL1,93708,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-KL1,93708,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,G. Philip Robertson -US-KL1,93708,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-KL1,93708,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,robert30@msu.edu -US-KL1,93708,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Michigan State University -US-KL1,93709,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-KL1,93709,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Jiquan Chen -US-KL1,93709,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-KL1,93709,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,jqchen@msu.edu -US-KL1,93709,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Michigan State University -US-KL1,93730,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Michigan State University -US-KL1,93730,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-KL1,93719,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,"USDOE-GLBRC, NSF-LTER, MSU AgBioResearch" -US-KL1,93719,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-KL1,14589,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Agriculture -US-KL1,14606,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Drought -US-KL1,14590,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-KL1,14590,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-KL1,14590,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20090101 -US-KL1,14590,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-KL1,14610,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-KL1,14610,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-KL1,14610,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20090101 -US-KL1,14610,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-KL1,14607,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-KL1,14607,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-KL1,14607,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20090101 -US-KL1,14607,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-KL1,23000656,GRP_HEADER,SITE_NAME,KBS Lux Arbor Reserve Corn -US-KL1,14591,GRP_IGBP,IGBP,CRO -US-KL1,14591,GRP_IGBP,IGBP_COMMENT,"corn/soybean row crop rotation before 2008, Soybean in 2009 and continuous corn from 2010 onwards" -US-KL1,14592,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -US-KL1,14592,GRP_LAND_OWNERSHIP,LAND_OWNER,Michigan State University -US-KL1,96718,GRP_LOCATION,LOCATION_LAT,42.4847 -US-KL1,96718,GRP_LOCATION,LOCATION_LONG,-85.4422 -US-KL1,96718,GRP_LOCATION,LOCATION_ELEV,264.6 -US-KL1,14594,GRP_NETWORK,NETWORK,AmeriFlux -US-KL1,1700005694,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Abraha, M., Chen, J., Chu, H., Zenone, T., John, R., Su, Y., Hamilton, S. K., Robertson, G. P. (2015) Evapotranspiration Of Annual And Perennial Biofuel Crops In A Variable Climate, GCB Bioenergy, 7(6), 1344-1356" -US-KL1,1700005694,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/GCBB.12239 -US-KL1,1700005694,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-KL1,1700006621,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Abraha, M., Chen, J., Hamilton, S. K., Robertson, G. P. (2020) Long‐Term Evapotranspiration Rates For Rainfed Corn Versus Perennial Bioenergy Crops In A Mesic Landscape, Hydrological Processes, 34(3), 810-822" -US-KL1,1700006621,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/HYP.13630 -US-KL1,1700006621,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-KL1,1700007923,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Abraha, M., Gelfand, I., Hamilton, S. K., Chen, J., Robertson, G. P. (2019) Carbon Debt Of Field-Scale Conservation Reserve Program Grasslands Converted To Annual And Perennial Bioenergy Crops, Environmental Research Letters, 14(2), 024019" -US-KL1,1700007923,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1088/1748-9326/AAFC10 -US-KL1,1700007923,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-KL1,1700002592,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Abraha, M., Gelfand, I., Hamilton, S. K., Shao, C., Su, Y., Robertson, G. P., Chen, J. (2016) Ecosystem Water-Use Efficiency Of Annual Corn And Perennial Grasslands: Contributions From Land-Use History And Species Composition, Ecosystems, 19(6), 1001-1012" -US-KL1,1700002592,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1007/S10021-016-9981-2 -US-KL1,1700002592,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-KL1,1700007836,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Abraha, M., Hamilton, S. K., Chen, J., Robertson, G. P. (2018) Ecosystem Carbon Exchange On Conversion Of Conservation Reserve Program Grasslands To Annual And Perennial Cropping Systems, Agricultural And Forest Meteorology, 253-254(6), 151-160" -US-KL1,1700007836,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2018.02.016 -US-KL1,1700007836,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-KL1,1700008976,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Baldocchi, D. D., Poindexter, C., Abraha, M., Desai, A. R., Bohrer, G., Arain, M. A., Griffis, T., Blanken, P. D., O'Halloran, T. L., Thomas, R. Q., Zhang, Q., Burns, S. P., Frank, J. M., Christian, D., Brown, S., Black, T. A., Gough, C. M., Law, B. E., Lee, X., Chen, J., Reed, D. E., Massman, W. J., Clark, K., Hatfield, J., Prueger, J., Bracho, R., Baker, J. M., Martin, T. A. (2018) Temporal Dynamics Of Aerodynamic Canopy Height Derived From Eddy Covariance Momentum Flux Data Across North American Flux Networks, Geophysical Research Letters, 45(3), 9275–9287" -US-KL1,1700008976,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018GL079306 -US-KL1,1700008976,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-KL1,1700005124,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Baldocchi, D. D., Poindexter, C., Abraha, M., Desai, A. R., Bohrer, G., Arain, M. A., Griffis, T., Blanken, P. D., O'Halloran, T. L., Thomas, R. Q., Zhang, Q., Burns, S. P., Frank, J. M., Christian, D., Brown, S., Black, T. A., Gough, C. M., Law, B. E., Lee, X., Chen, J., Reed, D. E., Massman, W. J., Clark, K., Hatfield, J., Prueger, J., Bracho, R., Baker, J. M., Martin, T. A. (2018) Temporal Dynamics Of Aerodynamic Canopy Height Derived From Eddy Covariance Momentum Flux Data Across North American Flux Networks, Geophysical Research Letters, 45(6), 9275–9287" -US-KL1,1700005124,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018GL079306 -US-KL1,1700005124,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-KL1,1700007998,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Zenone, T., Gelfand, I., Chen, J., Hamilton, S. K., Robertson, G. P. (2013) From Set-Aside Grassland To Annual And Perennial Cellulosic Biofuel Crops: Effects Of Land Use Change On Carbon Balance, Agricultural And Forest Meteorology, 182-183(6), 1-12" -US-KL1,1700007998,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2013.07.015 -US-KL1,1700007998,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-KL1,14596,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"Land use change, bioenergy, GHG" -US-KL1,14597,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"W.K. Kellogg Biological Station,3700 E Gull Lake Dr, Hickory Corners, MI49060" -US-KL1,14598,GRP_SITE_CHAR,TERRAIN,"Medium Slope (>2 %, <5%)" -US-KL1,14598,GRP_SITE_CHAR,ASPECT,W -US-KL1,14598,GRP_SITE_CHAR,WIND_DIRECTION,SW -US-KL1,14598,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,210 -US-KL1,14598,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,60 -US-KL1,14599,GRP_SITE_DESC,SITE_DESC,The site was under conventional corn/soybean rotation row crop agriculture for decades before conversion. The site was converted to no-till soybean in 2009 and to no-till continuous corn from 2010 onwards. -US-KL1,14600,GRP_SITE_FUNDING,SITE_FUNDING,"USDOE-GLBRC, NSF-LTER, MSU AgBioResearch" -US-KL1,14601,GRP_STATE,STATE,MI -US-KL1,14611,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,G. Philip Robertson -US-KL1,14611,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-KL1,14611,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,robert30@msu.edu -US-KL1,14611,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Michigan State University -US-KL1,14611,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"W.K. Kellogg Biological Station,3700 E Gull Lake Dr, Hickory Corners, MI49060" -US-KL1,14609,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Jiquan Chen -US-KL1,14609,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-KL1,14609,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,jqchen@msu.edu -US-KL1,14609,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Michigan State University -US-KL1,14609,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"202 Manly Miles Bldg. 1405 South Harrison Road Michigan State University, East Lansing, MI 48823" -US-KL1,14602,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Michael Abraha -US-KL1,14602,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-KL1,14602,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,abraha@msu.edu -US-KL1,14602,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Michigan State University -US-KL1,14602,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"W.K. Kellogg Biological Station,3700 E Gull Lake Dr, Hickory Corners, MI49060" -US-KL1,29907,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-KL1,14603,GRP_TOWER_TYPE,TOWER_TYPE,pole -US-KL1,14604,GRP_URL,URL,http://lees.geo.msu.edu/index.html -US-KL1,24000656,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-KL1 -US-KL1,14605,GRP_UTC_OFFSET,UTC_OFFSET,-5 -US-KL2,14612,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,"Supported by DOE (DE-FC02-07ER64494, DE-AC05-76RL01830) & NSF-LTER (DEB 1027253)" -US-KL2,14613,GRP_CLIM_AVG,MAT,9.9 -US-KL2,14613,GRP_CLIM_AVG,MAP,1027 -US-KL2,14613,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfa -US-KL2,27000657,GRP_COUNTRY,COUNTRY,USA -US-KL2,93285,GRP_DOI,DOI,10.17190/AMF/1644212 -US-KL2,93285,GRP_DOI,DOI_CITATION,"G. Philip Robertson, Jiquan Chen (2021), AmeriFlux BASE US-KL2 KBS Lux Arbor Reserve Switchgrass, Ver. 3-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1644212" -US-KL2,93285,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-KL2,93282,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-KL2,93282,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,G. Philip Robertson -US-KL2,93282,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-KL2,93282,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,robert30@msu.edu -US-KL2,93282,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Michigan State University -US-KL2,93281,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-KL2,93281,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Jiquan Chen -US-KL2,93281,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-KL2,93281,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,jqchen@msu.edu -US-KL2,93281,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Michigan State University -US-KL2,93284,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Michigan State University -US-KL2,93284,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-KL2,93283,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,"USDOE-GLBRC, NSF-LTER, MSU AgBioResearch" -US-KL2,93283,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-KL2,14614,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Agriculture -US-KL2,14631,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Drought -US-KL2,14615,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-KL2,14615,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-KL2,14615,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20090101 -US-KL2,14615,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-KL2,14636,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-KL2,14636,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-KL2,14636,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20090101 -US-KL2,14636,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-KL2,14632,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-KL2,14632,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-KL2,14632,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20090101 -US-KL2,14632,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-KL2,23000657,GRP_HEADER,SITE_NAME,KBS Lux Arbor Reserve Switchgrass -US-KL2,14616,GRP_IGBP,IGBP,CRO -US-KL2,14616,GRP_IGBP,IGBP_COMMENT,corn/soybean row crop rotation -US-KL2,14633,GRP_IGBP,IGBP,GRA -US-KL2,14633,GRP_IGBP,IGBP_DATE_START,2010 -US-KL2,14633,GRP_IGBP,IGBP_COMMENT,Switchgrass (Panicum virgatum L.) -US-KL2,14617,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -US-KL2,14617,GRP_LAND_OWNERSHIP,LAND_OWNER,Michigan State University -US-KL2,96669,GRP_LOCATION,LOCATION_LAT,42.4768 -US-KL2,96669,GRP_LOCATION,LOCATION_LONG,-85.4468 -US-KL2,96669,GRP_LOCATION,LOCATION_ELEV,258.3 -US-KL2,14619,GRP_NETWORK,NETWORK,AmeriFlux -US-KL2,1700005703,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Abraha, M., Chen, J., Chu, H., Zenone, T., John, R., Su, Y., Hamilton, S. K., Robertson, G. P. (2015) Evapotranspiration Of Annual And Perennial Biofuel Crops In A Variable Climate, GCB Bioenergy, 7(6), 1344-1356" -US-KL2,1700005703,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/GCBB.12239 -US-KL2,1700005703,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-KL2,1700007914,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Abraha, M., Chen, J., Hamilton, S. K., Robertson, G. P. (2020) Long‐Term Evapotranspiration Rates For Rainfed Corn Versus Perennial Bioenergy Crops In A Mesic Landscape, Hydrological Processes, 34(3), 810-822" -US-KL2,1700007914,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/HYP.13630 -US-KL2,1700007914,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-KL2,1700002484,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Abraha, M., Gelfand, I., Hamilton, S. K., Chen, J., Robertson, G. P. (2019) Carbon Debt Of Field-Scale Conservation Reserve Program Grasslands Converted To Annual And Perennial Bioenergy Crops, Environmental Research Letters, 14(2), 024019" -US-KL2,1700002484,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1088/1748-9326/AAFC10 -US-KL2,1700002484,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-KL2,1700008523,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Abraha, M., Gelfand, I., Hamilton, S. K., Shao, C., Su, Y., Robertson, G. P., Chen, J. (2016) Ecosystem Water-Use Efficiency Of Annual Corn And Perennial Grasslands: Contributions From Land-Use History And Species Composition, Ecosystems, 19(6), 1001-1012" -US-KL2,1700008523,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1007/S10021-016-9981-2 -US-KL2,1700008523,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-KL2,1700000144,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Abraha, M., Hamilton, S. K., Chen, J., Robertson, G. P. (2018) Ecosystem Carbon Exchange On Conversion Of Conservation Reserve Program Grasslands To Annual And Perennial Cropping Systems, Agricultural And Forest Meteorology, 253-254(6), 151-160" -US-KL2,1700000144,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2018.02.016 -US-KL2,1700000144,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-KL2,1700008151,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Bracho, R., Powell, T. L., Dore, S., Li, J., Hinkle, C. R., Drake, B. G. (2008) Environmental And Biological Controls On Water And Energy Exchange In Florida Scrub Oak And Pine Flatwoods Ecosystems, Journal Of Geophysical Research: Biogeosciences, 113(G2), n/a-n/a" -US-KL2,1700008151,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2007JG000469 -US-KL2,1700008151,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-KL2,1700003117,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Baldocchi, D. D., Poindexter, C., Abraha, M., Desai, A. R., Bohrer, G., Arain, M. A., Griffis, T., Blanken, P. D., O'Halloran, T. L., Thomas, R. Q., Zhang, Q., Burns, S. P., Frank, J. M., Christian, D., Brown, S., Black, T. A., Gough, C. M., Law, B. E., Lee, X., Chen, J., Reed, D. E., Massman, W. J., Clark, K., Hatfield, J., Prueger, J., Bracho, R., Baker, J. M., Martin, T. A. (2018) Temporal Dynamics Of Aerodynamic Canopy Height Derived From Eddy Covariance Momentum Flux Data Across North American Flux Networks, Geophysical Research Letters, 45(6), 9275–9287" -US-KL2,1700003117,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018GL079306 -US-KL2,1700003117,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-KL2,1700000933,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Baldocchi, D. D., Poindexter, C., Abraha, M., Desai, A. R., Bohrer, G., Arain, M. A., Griffis, T., Blanken, P. D., O'Halloran, T. L., Thomas, R. Q., Zhang, Q., Burns, S. P., Frank, J. M., Christian, D., Brown, S., Black, T. A., Gough, C. M., Law, B. E., Lee, X., Chen, J., Reed, D. E., Massman, W. J., Clark, K., Hatfield, J., Prueger, J., Bracho, R., Baker, J. M., Martin, T. A. (2018) Temporal Dynamics Of Aerodynamic Canopy Height Derived From Eddy Covariance Momentum Flux Data Across North American Flux Networks, Geophysical Research Letters, 45(G2), 9275–9287" -US-KL2,1700000933,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018GL079306 -US-KL2,1700000933,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-KL2,1700006990,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Zenone, T., Gelfand, I., Chen, J., Hamilton, S. K., Robertson, G. P. (2013) From Set-Aside Grassland To Annual And Perennial Cellulosic Biofuel Crops: Effects Of Land Use Change On Carbon Balance, Agricultural And Forest Meteorology, 182-183(6), 1-12" -US-KL2,1700006990,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2013.07.015 -US-KL2,1700006990,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-KL2,14621,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"Land use change, bioenergy, GHG" -US-KL2,14622,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"W.K. Kellogg Biological Station,3700 E Gull Lake Dr, Hickory Corners, MI49060" -US-KL2,14623,GRP_SITE_CHAR,TERRAIN,"Medium Slope (>2 %, <5%)" -US-KL2,14623,GRP_SITE_CHAR,ASPECT,NW -US-KL2,14623,GRP_SITE_CHAR,WIND_DIRECTION,SW -US-KL2,14623,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,235 -US-KL2,14623,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,60 -US-KL2,14624,GRP_SITE_DESC,SITE_DESC,"The site was under conventional corn/soybean rotation row crop agriculture for decades before conversion. It was converted to no-till soybean in 2009 and to perennial switchgrass from 2010 onwards. Starting from 2011, the switchgrass is harvested every autumn/fall." -US-KL2,14625,GRP_SITE_FUNDING,SITE_FUNDING,"USDOE-GLBRC, NSF-LTER, MSU AgBioResearch" -US-KL2,14626,GRP_STATE,STATE,MI -US-KL2,14637,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,G. Philip Robertson -US-KL2,14637,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-KL2,14637,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,robert30@msu.edu -US-KL2,14637,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Michigan State University -US-KL2,14637,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"W.K. Kellogg Biological Station,3700 E Gull Lake Dr, Hickory Corners, MI49060" -US-KL2,14635,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Jiquan Chen -US-KL2,14635,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-KL2,14635,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,jqchen@msu.edu -US-KL2,14635,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Michigan State University -US-KL2,14635,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"202 Manly Miles Bldg. 1405 South Harrison Road Michigan State University, East Lansing, MI 48823" -US-KL2,14627,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Michael Abraha -US-KL2,14627,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-KL2,14627,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,abraha@msu.edu -US-KL2,14627,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Michigan State University -US-KL2,14627,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"W.K. Kellogg Biological Station,3700 E Gull Lake Dr, Hickory Corners, MI49060" -US-KL2,29908,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-KL2,14628,GRP_TOWER_TYPE,TOWER_TYPE,pole -US-KL2,14629,GRP_URL,URL,http://lees.geo.msu.edu/index.html -US-KL2,24000657,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-KL2 -US-KL2,14630,GRP_UTC_OFFSET,UTC_OFFSET,-5 -US-KL3,14638,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,"Supported by DOE (DE-FC02-07ER64494, DE-AC05-76RL01830) & NSF-LTER (DEB 1027253)" -US-KL3,14639,GRP_CLIM_AVG,MAT,9.9 -US-KL3,14639,GRP_CLIM_AVG,MAP,1027 -US-KL3,14639,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfa -US-KL3,27000658,GRP_COUNTRY,COUNTRY,USA -US-KL3,93313,GRP_DOI,DOI,10.17190/AMF/1647438 -US-KL3,93313,GRP_DOI,DOI_CITATION,"G. Philip Robertson, Jiquan Chen (2021), AmeriFlux BASE US-KL3 KBS Lux Arbor Reserve Prairie, Ver. 3-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1647438" -US-KL3,93313,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-KL3,93303,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-KL3,93303,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,G. Philip Robertson -US-KL3,93303,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-KL3,93303,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,robert30@msu.edu -US-KL3,93303,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Michigan State University -US-KL3,93299,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-KL3,93299,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Jiquan Chen -US-KL3,93299,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-KL3,93299,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,jqchen@msu.edu -US-KL3,93299,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Michigan State University -US-KL3,93308,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Michigan State University -US-KL3,93308,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-KL3,93305,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,"USDOE-GLBRC, NSF-LTER, MSU AgBioResearch" -US-KL3,93305,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-KL3,14640,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Agriculture -US-KL3,14657,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Drought -US-KL3,14641,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-KL3,14641,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-KL3,14641,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20090101 -US-KL3,14641,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-KL3,14662,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-KL3,14662,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-KL3,14662,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20090101 -US-KL3,14662,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-KL3,14658,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-KL3,14658,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-KL3,14658,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20090101 -US-KL3,14658,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-KL3,23000658,GRP_HEADER,SITE_NAME,KBS Lux Arbor Reserve Prairie -US-KL3,14642,GRP_IGBP,IGBP,CRO -US-KL3,14642,GRP_IGBP,IGBP_COMMENT,corn/soybean row crop rotation -US-KL3,14659,GRP_IGBP,IGBP,GRA -US-KL3,14659,GRP_IGBP,IGBP_DATE_START,2010 -US-KL3,14659,GRP_IGBP,IGBP_COMMENT,The site was initially planted to 19 native prairie and forbes dominated by C3 species; but species composition has been changing since then. -US-KL3,14643,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -US-KL3,14643,GRP_LAND_OWNERSHIP,LAND_OWNER,Michigan State University -US-KL3,96717,GRP_LOCATION,LOCATION_LAT,42.4735 -US-KL3,96717,GRP_LOCATION,LOCATION_LONG,-85.4473 -US-KL3,96717,GRP_LOCATION,LOCATION_ELEV,264.7 -US-KL3,14645,GRP_NETWORK,NETWORK,AmeriFlux -US-KL3,1700003345,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Abraha, M., Chen, J., Chu, H., Zenone, T., John, R., Su, Y., Hamilton, S. K., Robertson, G. P. (2015) Evapotranspiration Of Annual And Perennial Biofuel Crops In A Variable Climate, GCB Bioenergy, 7(6), 1344-1356" -US-KL3,1700003345,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/GCBB.12239 -US-KL3,1700003345,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-KL3,1700008862,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Abraha, M., Chen, J., Hamilton, S. K., Robertson, G. P. (2020) Long‐Term Evapotranspiration Rates For Rainfed Corn Versus Perennial Bioenergy Crops In A Mesic Landscape, Hydrological Processes, 34(3), 810-822" -US-KL3,1700008862,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/HYP.13630 -US-KL3,1700008862,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-KL3,1700000129,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Abraha, M., Gelfand, I., Hamilton, S. K., Chen, J., Robertson, G. P. (2019) Carbon Debt Of Field-Scale Conservation Reserve Program Grasslands Converted To Annual And Perennial Bioenergy Crops, Environmental Research Letters, 14(2), 024019" -US-KL3,1700000129,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1088/1748-9326/AAFC10 -US-KL3,1700000129,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-KL3,1700000738,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Abraha, M., Gelfand, I., Hamilton, S. K., Shao, C., Su, Y., Robertson, G. P., Chen, J. (2016) Ecosystem Water-Use Efficiency Of Annual Corn And Perennial Grasslands: Contributions From Land-Use History And Species Composition, Ecosystems, 19(6), 1001-1012" -US-KL3,1700000738,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1007/S10021-016-9981-2 -US-KL3,1700000738,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-KL3,1700007173,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Abraha, M., Hamilton, S. K., Chen, J., Robertson, G. P. (2018) Ecosystem Carbon Exchange On Conversion Of Conservation Reserve Program Grasslands To Annual And Perennial Cropping Systems, Agricultural And Forest Meteorology, 253-254(6), 151-160" -US-KL3,1700007173,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2018.02.016 -US-KL3,1700007173,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-KL3,1700005061,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Baldocchi, D. D., Poindexter, C., Abraha, M., Desai, A. R., Bohrer, G., Arain, M. A., Griffis, T., Blanken, P. D., O'Halloran, T. L., Thomas, R. Q., Zhang, Q., Burns, S. P., Frank, J. M., Christian, D., Brown, S., Black, T. A., Gough, C. M., Law, B. E., Lee, X., Chen, J., Reed, D. E., Massman, W. J., Clark, K., Hatfield, J., Prueger, J., Bracho, R., Baker, J. M., Martin, T. A. (2018) Temporal Dynamics Of Aerodynamic Canopy Height Derived From Eddy Covariance Momentum Flux Data Across North American Flux Networks, Geophysical Research Letters, 45(3), 9275–9287" -US-KL3,1700005061,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018GL079306 -US-KL3,1700005061,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-KL3,1700006537,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Baldocchi, D. D., Poindexter, C., Abraha, M., Desai, A. R., Bohrer, G., Arain, M. A., Griffis, T., Blanken, P. D., O'Halloran, T. L., Thomas, R. Q., Zhang, Q., Burns, S. P., Frank, J. M., Christian, D., Brown, S., Black, T. A., Gough, C. M., Law, B. E., Lee, X., Chen, J., Reed, D. E., Massman, W. J., Clark, K., Hatfield, J., Prueger, J., Bracho, R., Baker, J. M., Martin, T. A. (2018) Temporal Dynamics Of Aerodynamic Canopy Height Derived From Eddy Covariance Momentum Flux Data Across North American Flux Networks, Geophysical Research Letters, 45(6), 9275–9287" -US-KL3,1700006537,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018GL079306 -US-KL3,1700006537,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-KL3,1700000447,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Zenone, T., Gelfand, I., Chen, J., Hamilton, S. K., Robertson, G. P. (2013) From Set-Aside Grassland To Annual And Perennial Cellulosic Biofuel Crops: Effects Of Land Use Change On Carbon Balance, Agricultural And Forest Meteorology, 182-183(6), 1-12" -US-KL3,1700000447,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2013.07.015 -US-KL3,1700000447,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-KL3,14647,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"Land use change, bioenergy, GHG" -US-KL3,14648,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"W.K. Kellogg Biological Station,3700 E Gull Lake Dr, Hickory Corners, MI49060" -US-KL3,14649,GRP_SITE_CHAR,TERRAIN,Gentle slope (<2 %) -US-KL3,14649,GRP_SITE_CHAR,WIND_DIRECTION,SW -US-KL3,14649,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,270 -US-KL3,14649,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,60 -US-KL3,14650,GRP_SITE_DESC,SITE_DESC,"The site was under conventional corn/soybean rotation row crop agriculture for decades before conversion. The site was converted to no-till soybean in 2009 and to perennial native prairie from 2010 onwards. Starting from 2011, the prairie is harvested every autumn/fall." -US-KL3,14651,GRP_SITE_FUNDING,SITE_FUNDING,"USDOE-GLBRC, NSF-LTER, MSU AgBioResearch" -US-KL3,14652,GRP_STATE,STATE,MI -US-KL3,14663,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,G. Philip Robertson -US-KL3,14663,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-KL3,14663,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,robert30@msu.edu -US-KL3,14663,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Michigan State University -US-KL3,14663,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"W.K. Kellogg Biological Station,3700 E Gull Lake Dr, Hickory Corners, MI49060" -US-KL3,14661,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Jiquan Chen -US-KL3,14661,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-KL3,14661,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,jqchen@msu.edu -US-KL3,14661,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Michigan State University -US-KL3,14661,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"202 Manly Miles Bldg. 1405 South Harrison Road Michigan State University, East Lansing, MI 48823" -US-KL3,14653,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Michael Abraha -US-KL3,14653,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-KL3,14653,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,abraha@msu.edu -US-KL3,14653,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Michigan State University -US-KL3,14653,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"W.K. Kellogg Biological Station,3700 E Gull Lake Dr, Hickory Corners, MI49060" -US-KL3,29909,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-KL3,14654,GRP_TOWER_TYPE,TOWER_TYPE,pole -US-KL3,14655,GRP_URL,URL,http://lees.geo.msu.edu/index.html -US-KL3,24000658,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-KL3 -US-KL3,14656,GRP_UTC_OFFSET,UTC_OFFSET,-5 -US-KLS,13193,GRP_CLIM_AVG,MAT,12 -US-KLS,13193,GRP_CLIM_AVG,MAP,812 -US-KLS,13193,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Cfa -US-KLS,27000546,GRP_COUNTRY,COUNTRY,USA -US-KLS,86014,GRP_DOI,DOI,10.17190/AMF/1498745 -US-KLS,86014,GRP_DOI,DOI_CITATION,"Nathaniel Brunsell (2021), AmeriFlux BASE US-KLS Kansas Land Institute, Ver. 2-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1498745" -US-KLS,86014,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-KLS,85645,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-KLS,85645,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Nathaniel Brunsell -US-KLS,85645,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-KLS,85645,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,brunsell@ku.edu -US-KLS,85645,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Kansas University -US-KLS,85659,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Kansas University -US-KLS,85659,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-KLS,85658,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,NSF -US-KLS,85658,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-KLS,13194,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Temperature extreme -US-KLS,13195,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-KLS,13195,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-KLS,13195,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,2012 -US-KLS,13195,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-KLS,13204,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-KLS,13204,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-KLS,13204,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,2012 -US-KLS,13204,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-KLS,23000546,GRP_HEADER,SITE_NAME,Kansas Land Institute -US-KLS,13196,GRP_IGBP,IGBP,GRA -US-KLS,30941,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -US-KLS,30941,GRP_LAND_OWNERSHIP,LAND_OWNER,The Land Institute -US-KLS,13197,GRP_LOCATION,LOCATION_LAT,38.7745 -US-KLS,13197,GRP_LOCATION,LOCATION_LONG,-97.5684 -US-KLS,13197,GRP_LOCATION,LOCATION_ELEV,373 -US-KLS,13198,GRP_NETWORK,NETWORK,AmeriFlux -US-KLS,1700008961,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(), 108350" -US-KLS,1700008961,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -US-KLS,1700008961,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-KLS,30938,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,Climate impacts of perenniel agricultural production -US-KLS,30324,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"1475 Jayhawk Blvd, Lindley Hall.,Department of Geography, Atmospheric Science Program, Lawrence, KS 66045-7613" -US-KLS,30937,GRP_SITE_CHAR,TERRAIN,Flat -US-KLS,30937,GRP_SITE_CHAR,ASPECT,S -US-KLS,30937,GRP_SITE_CHAR,WIND_DIRECTION,S -US-KLS,30937,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,20 -US-KLS,30939,GRP_SITE_DESC,SITE_DESC,Perenniel Agricultural site -US-KLS,13200,GRP_SITE_FUNDING,SITE_FUNDING,NSF -US-KLS,13201,GRP_STATE,STATE,KS -US-KLS,13202,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Nathaniel Brunsell -US-KLS,13202,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-KLS,13202,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,brunsell@ku.edu -US-KLS,13202,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Kansas University -US-KLS,13202,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Department of Geography, Atmospheric Science Program, 1475 Jayhawk Blvd.,Lawrence, KS 66045-7613" -US-KLS,97796,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Noah Ring -US-KLS,97796,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Technician -US-KLS,97796,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,noahring@ku.edu -US-KLS,97796,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Kansas -US-KLS,97796,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1475 Jayhawk Blvd. -Lindley Hall 215 -Lawrence, KS 66044" -US-KLS,29880,GRP_TOWER_POWER,TOWER_POWER,Other -US-KLS,13203,GRP_TOWER_TYPE,TOWER_TYPE,tripod -US-KLS,24000546,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-KLS -US-KLS,30940,GRP_UTC_OFFSET,UTC_OFFSET,-6 -US-KM1,14664,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,"Supported by DOE (DE-FC02-07ER64494, DE-AC05-76RL01830) & NSF-LTER (DEB 1027253)" -US-KM1,14665,GRP_CLIM_AVG,MAT,9.9 -US-KM1,14665,GRP_CLIM_AVG,MAP,1027 -US-KM1,14665,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfa -US-KM1,27000659,GRP_COUNTRY,COUNTRY,USA -US-KM1,93312,GRP_DOI,DOI,10.17190/AMF/1647439 -US-KM1,93312,GRP_DOI,DOI_CITATION,"G. Philip Robertson, Jiquan Chen (2021), AmeriFlux BASE US-KM1 KBS Marshall Farms Corn, Ver. 3-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1647439" -US-KM1,93312,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-KM1,93302,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-KM1,93302,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,G. Philip Robertson -US-KM1,93302,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-KM1,93302,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,robert30@msu.edu -US-KM1,93302,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Michigan State University -US-KM1,93304,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-KM1,93304,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Jiquan Chen -US-KM1,93304,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-KM1,93304,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,jqchen@msu.edu -US-KM1,93304,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Michigan State University -US-KM1,93309,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Michigan State University -US-KM1,93309,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-KM1,93306,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,"USDOE-GLBRC, NSF-LTER, MSU AgBioResearch" -US-KM1,93306,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-KM1,14666,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Agriculture -US-KM1,14683,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Drought -US-KM1,14667,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-KM1,14667,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-KM1,14667,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20090101 -US-KM1,14667,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-KM1,14688,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-KM1,14688,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-KM1,14688,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20090101 -US-KM1,14688,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-KM1,14684,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-KM1,14684,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-KM1,14684,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20090101 -US-KM1,14684,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-KM1,23000659,GRP_HEADER,SITE_NAME,KBS Marshall Farms Corn -US-KM1,14668,GRP_IGBP,IGBP,GRA -US-KM1,14668,GRP_IGBP,IGBP_COMMENT,Smooth brome grass (Bromus inermis L.) -US-KM1,14685,GRP_IGBP,IGBP,CRO -US-KM1,14685,GRP_IGBP,IGBP_DATE_START,2009 -US-KM1,14685,GRP_IGBP,IGBP_COMMENT,Soybean (Glycin max L.) in 2009 and continuous corn (Zea mays L.) from 2010 onwards -US-KM1,14669,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -US-KM1,14669,GRP_LAND_OWNERSHIP,LAND_OWNER,Mrs. Edythe Marshall -US-KM1,96680,GRP_LOCATION,LOCATION_LAT,42.4376 -US-KM1,96680,GRP_LOCATION,LOCATION_LONG,-85.3287 -US-KM1,96680,GRP_LOCATION,LOCATION_ELEV,258.1 -US-KM1,14671,GRP_NETWORK,NETWORK,AmeriFlux -US-KM1,86977,GRP_NETWORK,NETWORK,Phenocam -US-KM1,1700006588,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Abraha, M., Chen, J., Chu, H., Zenone, T., John, R., Su, Y., Hamilton, S. K., Robertson, G. P. (2015) Evapotranspiration Of Annual And Perennial Biofuel Crops In A Variable Climate, GCB Bioenergy, 7(6), 1344-1356" -US-KM1,1700006588,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/GCBB.12239 -US-KM1,1700006588,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-KM1,1700005727,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Abraha, M., Chen, J., Hamilton, S. K., Robertson, G. P. (2020) Long‐Term Evapotranspiration Rates For Rainfed Corn Versus Perennial Bioenergy Crops In A Mesic Landscape, Hydrological Processes, 34(3), 810-822" -US-KM1,1700005727,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/HYP.13630 -US-KM1,1700005727,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-KM1,1700004944,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Abraha, M., Gelfand, I., Hamilton, S. K., Chen, J., Robertson, G. P. (2019) Carbon Debt Of Field-Scale Conservation Reserve Program Grasslands Converted To Annual And Perennial Bioenergy Crops, Environmental Research Letters, 14(2), 024019" -US-KM1,1700004944,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1088/1748-9326/AAFC10 -US-KM1,1700004944,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-KM1,1700000372,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Abraha, M., Gelfand, I., Hamilton, S. K., Shao, C., Su, Y., Robertson, G. P., Chen, J. (2016) Ecosystem Water-Use Efficiency Of Annual Corn And Perennial Grasslands: Contributions From Land-Use History And Species Composition, Ecosystems, 19(6), 1001-1012" -US-KM1,1700000372,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1007/S10021-016-9981-2 -US-KM1,1700000372,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-KM1,1700006468,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Abraha, M., Hamilton, S. K., Chen, J., Robertson, G. P. (2018) Ecosystem Carbon Exchange On Conversion Of Conservation Reserve Program Grasslands To Annual And Perennial Cropping Systems, Agricultural And Forest Meteorology, 253-254(6), 151-160" -US-KM1,1700006468,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2018.02.016 -US-KM1,1700006468,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-KM1,1700003135,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Baldocchi, D. D., Poindexter, C., Abraha, M., Desai, A. R., Bohrer, G., Arain, M. A., Griffis, T., Blanken, P. D., O'Halloran, T. L., Thomas, R. Q., Zhang, Q., Burns, S. P., Frank, J. M., Christian, D., Brown, S., Black, T. A., Gough, C. M., Law, B. E., Lee, X., Chen, J., Reed, D. E., Massman, W. J., Clark, K., Hatfield, J., Prueger, J., Bracho, R., Baker, J. M., Martin, T. A. (2018) Temporal Dynamics Of Aerodynamic Canopy Height Derived From Eddy Covariance Momentum Flux Data Across North American Flux Networks, Geophysical Research Letters, 45(3), 9275–9287" -US-KM1,1700003135,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018GL079306 -US-KM1,1700003135,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-KM1,1700005622,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Baldocchi, D. D., Poindexter, C., Abraha, M., Desai, A. R., Bohrer, G., Arain, M. A., Griffis, T., Blanken, P. D., O'Halloran, T. L., Thomas, R. Q., Zhang, Q., Burns, S. P., Frank, J. M., Christian, D., Brown, S., Black, T. A., Gough, C. M., Law, B. E., Lee, X., Chen, J., Reed, D. E., Massman, W. J., Clark, K., Hatfield, J., Prueger, J., Bracho, R., Baker, J. M., Martin, T. A. (2018) Temporal Dynamics Of Aerodynamic Canopy Height Derived From Eddy Covariance Momentum Flux Data Across North American Flux Networks, Geophysical Research Letters, 45(6), 9275–9287" -US-KM1,1700005622,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018GL079306 -US-KM1,1700005622,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-KM1,1700004191,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Zenone, T., Gelfand, I., Chen, J., Hamilton, S. K., Robertson, G. P. (2013) From Set-Aside Grassland To Annual And Perennial Cellulosic Biofuel Crops: Effects Of Land Use Change On Carbon Balance, Agricultural And Forest Meteorology, 182-183(6), 1-12" -US-KM1,1700004191,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2013.07.015 -US-KM1,1700004191,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-KM1,14673,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"Land use change, bioenergy, GHG" -US-KM1,14674,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"W.K. Kellogg Biological Station,3700 E Gull Lake Dr, Hickory Corners, MI49060" -US-KM1,14675,GRP_SITE_CHAR,TERRAIN,"Medium Slope (>2 %, <5%)" -US-KM1,14675,GRP_SITE_CHAR,ASPECT,NE -US-KM1,14675,GRP_SITE_CHAR,WIND_DIRECTION,SW -US-KM1,14675,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,250 -US-KM1,14675,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,60 -US-KM1,14676,GRP_SITE_DESC,SITE_DESC,The site was planted to smooth brome grass under the USDA’s Conservation Reserve Program (CRP) grassland since 1987 before conversion. The grass was cut every three years but left in place. The site was converted to no-till soybean in 2009 and to no-till continuous corn from 2010 onwards. -US-KM1,14677,GRP_SITE_FUNDING,SITE_FUNDING,"USDOE-GLBRC, NSF-LTER, MSU AgBioResearch" -US-KM1,14678,GRP_STATE,STATE,MI -US-KM1,14689,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,G. Philip Robertson -US-KM1,14689,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-KM1,14689,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,robert30@msu.edu -US-KM1,14689,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Michigan State University -US-KM1,14689,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"W.K. Kellogg Biological Station,3700 E Gull Lake Dr, Hickory Corners, MI49060" -US-KM1,14687,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Jiquan Chen -US-KM1,14687,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-KM1,14687,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,jqchen@msu.edu -US-KM1,14687,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Michigan State University -US-KM1,14687,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"202 Manly Miles Bldg. 1405 South Harrison Road Michigan State University, East Lansing, MI 48823" -US-KM1,14679,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Michael Abraha -US-KM1,14679,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-KM1,14679,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,abraha@msu.edu -US-KM1,14679,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Michigan State University -US-KM1,14679,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"W.K. Kellogg Biological Station,3700 E Gull Lake Dr, Hickory Corners, MI49060" -US-KM1,29910,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-KM1,14680,GRP_TOWER_TYPE,TOWER_TYPE,pole -US-KM1,14681,GRP_URL,URL,http://lees.geo.msu.edu/index.html -US-KM1,24000659,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-KM1 -US-KM1,14682,GRP_UTC_OFFSET,UTC_OFFSET,-5 -US-KM2,14690,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,"Supported by DOE (DE-FC02-07ER64494, DE-AC05-76RL01830) & NSF-LTER (DEB 1027253)" -US-KM2,14691,GRP_CLIM_AVG,MAT,9.9 -US-KM2,14691,GRP_CLIM_AVG,MAP,1027 -US-KM2,14691,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfa -US-KM2,27000660,GRP_COUNTRY,COUNTRY,USA -US-KM2,93311,GRP_DOI,DOI,10.17190/AMF/1647440 -US-KM2,93311,GRP_DOI,DOI_CITATION,"G. Philip Robertson, Jiquan Chen (2021), AmeriFlux BASE US-KM2 KBS Marshall Farms Prairie, Ver. 3-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1647440" -US-KM2,93311,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-KM2,93301,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-KM2,93301,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,G. Philip Robertson -US-KM2,93301,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-KM2,93301,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,robert30@msu.edu -US-KM2,93301,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Michigan State University -US-KM2,93300,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-KM2,93300,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Jiquan Chen -US-KM2,93300,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-KM2,93300,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,jqchen@msu.edu -US-KM2,93300,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Michigan State University -US-KM2,93310,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Michigan State University -US-KM2,93310,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-KM2,93307,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,"USDOE-GLBRC, NSF-LTER, MSU AgBioResearch" -US-KM2,93307,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-KM2,14692,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Agriculture -US-KM2,14709,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Drought -US-KM2,14693,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-KM2,14693,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-KM2,14693,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20090101 -US-KM2,14693,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-KM2,14714,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-KM2,14714,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-KM2,14714,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20090101 -US-KM2,14714,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-KM2,14710,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-KM2,14710,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-KM2,14710,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20090101 -US-KM2,14710,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-KM2,23000660,GRP_HEADER,SITE_NAME,KBS Marshall Farms Prairie -US-KM2,14694,GRP_IGBP,IGBP,GRA -US-KM2,14694,GRP_IGBP,IGBP_COMMENT,Smooth brome grass (Bromus inermis L.) -US-KM2,14711,GRP_IGBP,IGBP,CRO -US-KM2,14711,GRP_IGBP,IGBP_DATE_START,2009 -US-KM2,14711,GRP_IGBP,IGBP_COMMENT,Soybean (Glycine max L.) -US-KM2,14715,GRP_IGBP,IGBP,GRA -US-KM2,14715,GRP_IGBP,IGBP_DATE_START,2010 -US-KM2,14715,GRP_IGBP,IGBP_COMMENT,The site was initially planted to 19 native prairie and forbes dominated by C3 species; but species composition has been changing since then. -US-KM2,14695,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -US-KM2,14695,GRP_LAND_OWNERSHIP,LAND_OWNER,Mrs. Edythe Marshall -US-KM2,96665,GRP_LOCATION,LOCATION_LAT,42.4441 -US-KM2,96665,GRP_LOCATION,LOCATION_LONG,-85.3098 -US-KM2,96665,GRP_LOCATION,LOCATION_ELEV,259.1 -US-KM2,14697,GRP_NETWORK,NETWORK,AmeriFlux -US-KM2,1700007653,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Abraha, M., Chen, J., Chu, H., Zenone, T., John, R., Su, Y., Hamilton, S. K., Robertson, G. P. (2015) Evapotranspiration Of Annual And Perennial Biofuel Crops In A Variable Climate, GCB Bioenergy, 7(6), 1344-1356" -US-KM2,1700007653,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/GCBB.12239 -US-KM2,1700007653,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-KM2,1700007818,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Abraha, M., Chen, J., Hamilton, S. K., Robertson, G. P. (2020) Long‐Term Evapotranspiration Rates For Rainfed Corn Versus Perennial Bioenergy Crops In A Mesic Landscape, Hydrological Processes, 34(3), 810-822" -US-KM2,1700007818,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/HYP.13630 -US-KM2,1700007818,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-KM2,1700003948,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Abraha, M., Gelfand, I., Hamilton, S. K., Chen, J., Robertson, G. P. (2019) Carbon Debt Of Field-Scale Conservation Reserve Program Grasslands Converted To Annual And Perennial Bioenergy Crops, Environmental Research Letters, 14(2), 024019" -US-KM2,1700003948,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1088/1748-9326/AAFC10 -US-KM2,1700003948,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-KM2,1700001350,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Abraha, M., Gelfand, I., Hamilton, S. K., Shao, C., Su, Y., Robertson, G. P., Chen, J. (2016) Ecosystem Water-Use Efficiency Of Annual Corn And Perennial Grasslands: Contributions From Land-Use History And Species Composition, Ecosystems, 19(6), 1001-1012" -US-KM2,1700001350,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1007/S10021-016-9981-2 -US-KM2,1700001350,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-KM2,1700001224,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Abraha, M., Hamilton, S. K., Chen, J., Robertson, G. P. (2018) Ecosystem Carbon Exchange On Conversion Of Conservation Reserve Program Grasslands To Annual And Perennial Cropping Systems, Agricultural And Forest Meteorology, 253-254(6), 151-160" -US-KM2,1700001224,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2018.02.016 -US-KM2,1700001224,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-KM2,1700006954,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Baldocchi, D. D., Poindexter, C., Abraha, M., Desai, A. R., Bohrer, G., Arain, M. A., Griffis, T., Blanken, P. D., O'Halloran, T. L., Thomas, R. Q., Zhang, Q., Burns, S. P., Frank, J. M., Christian, D., Brown, S., Black, T. A., Gough, C. M., Law, B. E., Lee, X., Chen, J., Reed, D. E., Massman, W. J., Clark, K., Hatfield, J., Prueger, J., Bracho, R., Baker, J. M., Martin, T. A. (2018) Temporal Dynamics Of Aerodynamic Canopy Height Derived From Eddy Covariance Momentum Flux Data Across North American Flux Networks, Geophysical Research Letters, 45(3), 9275–9287" -US-KM2,1700006954,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018GL079306 -US-KM2,1700006954,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-KM2,1700007539,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Baldocchi, D. D., Poindexter, C., Abraha, M., Desai, A. R., Bohrer, G., Arain, M. A., Griffis, T., Blanken, P. D., O'Halloran, T. L., Thomas, R. Q., Zhang, Q., Burns, S. P., Frank, J. M., Christian, D., Brown, S., Black, T. A., Gough, C. M., Law, B. E., Lee, X., Chen, J., Reed, D. E., Massman, W. J., Clark, K., Hatfield, J., Prueger, J., Bracho, R., Baker, J. M., Martin, T. A. (2018) Temporal Dynamics Of Aerodynamic Canopy Height Derived From Eddy Covariance Momentum Flux Data Across North American Flux Networks, Geophysical Research Letters, 45(6), 9275–9287" -US-KM2,1700007539,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018GL079306 -US-KM2,1700007539,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-KM2,1700005478,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Zenone, T., Gelfand, I., Chen, J., Hamilton, S. K., Robertson, G. P. (2013) From Set-Aside Grassland To Annual And Perennial Cellulosic Biofuel Crops: Effects Of Land Use Change On Carbon Balance, Agricultural And Forest Meteorology, 182-183(6), 1-12" -US-KM2,1700005478,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2013.07.015 -US-KM2,1700005478,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-KM2,14699,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"Land use change, bioenergy, GHG" -US-KM2,14700,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"W.K. Kellogg Biological Station,3700 E Gull Lake Dr, Hickory Corners, MI49060" -US-KM2,14701,GRP_SITE_CHAR,TERRAIN,Undulated/Variable -US-KM2,14701,GRP_SITE_CHAR,WIND_DIRECTION,SW -US-KM2,14701,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,209 -US-KM2,14701,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,60 -US-KM2,14702,GRP_SITE_DESC,SITE_DESC,"The site was planted to smooth brome grass under the USDA’s Conservation Reserve Program (CRP) grassland since 1987 before conversion. The grass was cut every three years but left in place. The site was converted to no-till soybean in 2009 and to perennial native prairie from 2010 onwards. Starting from 2011, the prairie is harvested every autumn/fall." -US-KM2,14703,GRP_SITE_FUNDING,SITE_FUNDING,"USDOE-GLBRC, NSF-LTER, MSU AgBioResearch" -US-KM2,14704,GRP_STATE,STATE,MI -US-KM2,14716,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,G. Philip Robertson -US-KM2,14716,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-KM2,14716,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,robert30@msu.edu -US-KM2,14716,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Michigan State University -US-KM2,14716,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"W.K. Kellogg Biological Station,3700 E Gull Lake Dr, Hickory Corners, MI49060" -US-KM2,14713,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Jiquan Chen -US-KM2,14713,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-KM2,14713,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,jqchen@msu.edu -US-KM2,14713,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Michigan State University -US-KM2,14713,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"202 Manly Miles Bldg. 1405 South Harrison Road Michigan State University, East Lansing, MI 48823" -US-KM2,14705,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Michael Abraha -US-KM2,14705,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-KM2,14705,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,abraha@msu.edu -US-KM2,14705,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Michigan State University -US-KM2,14705,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"W.K. Kellogg Biological Station,3700 E Gull Lake Dr, Hickory Corners, MI49060" -US-KM2,29911,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-KM2,14706,GRP_TOWER_TYPE,TOWER_TYPE,pole -US-KM2,14707,GRP_URL,URL,http://lees.geo.msu.edu/index.html -US-KM2,24000660,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-KM2 -US-KM2,14708,GRP_UTC_OFFSET,UTC_OFFSET,-5 -US-KM3,14717,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,"Supported by DOE (DE-FC02-07ER64494, DE-AC05-76RL01830) & NSF-LTER (DEB 1027253)" -US-KM3,14718,GRP_CLIM_AVG,MAT,9.9 -US-KM3,14718,GRP_CLIM_AVG,MAP,1027 -US-KM3,14718,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfa -US-KM3,27000661,GRP_COUNTRY,COUNTRY,USA -US-KM3,93746,GRP_DOI,DOI,10.17190/AMF/1660345 -US-KM3,93746,GRP_DOI,DOI_CITATION,"G. Philip Robertson, Jiquan Chen (2021), AmeriFlux BASE US-KM3 KBS Marshall Farms Switchgrass, Ver. 2-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1660345" -US-KM3,93746,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-KM3,93705,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-KM3,93705,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,G. Philip Robertson -US-KM3,93705,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-KM3,93705,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,robert30@msu.edu -US-KM3,93705,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Michigan State University -US-KM3,93710,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-KM3,93710,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Jiquan Chen -US-KM3,93710,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-KM3,93710,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,jqchen@msu.edu -US-KM3,93710,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Michigan State University -US-KM3,93731,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Michigan State University -US-KM3,93731,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-KM3,93723,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,"USDOE-GLBRC, NSF-LTER, MSU AgBioResearch" -US-KM3,93723,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-KM3,14719,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Agriculture -US-KM3,14736,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Drought -US-KM3,14741,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Storm or wind -US-KM3,14720,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-KM3,14720,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-KM3,14720,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20090101 -US-KM3,14720,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-KM3,14742,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-KM3,14742,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-KM3,14742,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20090101 -US-KM3,14742,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-KM3,14737,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-KM3,14737,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-KM3,14737,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20090101 -US-KM3,14737,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-KM3,23000661,GRP_HEADER,SITE_NAME,KBS Marshall Farms Switchgrass -US-KM3,14721,GRP_IGBP,IGBP,GRA -US-KM3,14721,GRP_IGBP,IGBP_COMMENT,Smooth brome grass (Bromus inermis L.) -US-KM3,14738,GRP_IGBP,IGBP,CRO -US-KM3,14738,GRP_IGBP,IGBP_DATE_START,2009 -US-KM3,14738,GRP_IGBP,IGBP_COMMENT,Soybean (Glycine max L.) -US-KM3,14743,GRP_IGBP,IGBP,GRA -US-KM3,14743,GRP_IGBP,IGBP_DATE_START,2010 -US-KM3,14743,GRP_IGBP,IGBP_COMMENT,Switchgrass (Panicum virgatum L.) -US-KM3,14722,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -US-KM3,14722,GRP_LAND_OWNERSHIP,LAND_OWNER,Mrs. Edythe Marshall -US-KM3,96748,GRP_LOCATION,LOCATION_LAT,42.4464 -US-KM3,96748,GRP_LOCATION,LOCATION_LONG,-85.3105 -US-KM3,96748,GRP_LOCATION,LOCATION_ELEV,262.1 -US-KM3,14724,GRP_NETWORK,NETWORK,AmeriFlux -US-KM3,1700007341,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Abraha, M., Chen, J., Chu, H., Zenone, T., John, R., Su, Y., Hamilton, S. K., Robertson, G. P. (2015) Evapotranspiration Of Annual And Perennial Biofuel Crops In A Variable Climate, GCB Bioenergy, 7(6), 1344-1356" -US-KM3,1700007341,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/GCBB.12239 -US-KM3,1700007341,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-KM3,1700002436,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Abraha, M., Chen, J., Hamilton, S. K., Robertson, G. P. (2020) Long‐Term Evapotranspiration Rates For Rainfed Corn Versus Perennial Bioenergy Crops In A Mesic Landscape, Hydrological Processes, 34(3), 810-822" -US-KM3,1700002436,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/HYP.13630 -US-KM3,1700002436,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-KM3,1700004926,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Abraha, M., Gelfand, I., Hamilton, S. K., Chen, J., Robertson, G. P. (2019) Carbon Debt Of Field-Scale Conservation Reserve Program Grasslands Converted To Annual And Perennial Bioenergy Crops, Environmental Research Letters, 14(2), 024019" -US-KM3,1700004926,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1088/1748-9326/AAFC10 -US-KM3,1700004926,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-KM3,1700006336,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Abraha, M., Gelfand, I., Hamilton, S. K., Shao, C., Su, Y., Robertson, G. P., Chen, J. (2016) Ecosystem Water-Use Efficiency Of Annual Corn And Perennial Grasslands: Contributions From Land-Use History And Species Composition, Ecosystems, 19(6), 1001-1012" -US-KM3,1700006336,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1007/S10021-016-9981-2 -US-KM3,1700006336,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-KM3,1700005823,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Abraha, M., Hamilton, S. K., Chen, J., Robertson, G. P. (2018) Ecosystem Carbon Exchange On Conversion Of Conservation Reserve Program Grasslands To Annual And Perennial Cropping Systems, Agricultural And Forest Meteorology, 253-254(6), 151-160" -US-KM3,1700005823,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2018.02.016 -US-KM3,1700005823,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-KM3,1700001884,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Baldocchi, D. D., Poindexter, C., Abraha, M., Desai, A. R., Bohrer, G., Arain, M. A., Griffis, T., Blanken, P. D., O'Halloran, T. L., Thomas, R. Q., Zhang, Q., Burns, S. P., Frank, J. M., Christian, D., Brown, S., Black, T. A., Gough, C. M., Law, B. E., Lee, X., Chen, J., Reed, D. E., Massman, W. J., Clark, K., Hatfield, J., Prueger, J., Bracho, R., Baker, J. M., Martin, T. A. (2018) Temporal Dynamics Of Aerodynamic Canopy Height Derived From Eddy Covariance Momentum Flux Data Across North American Flux Networks, Geophysical Research Letters, 45(3), 9275–9287" -US-KM3,1700001884,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018GL079306 -US-KM3,1700001884,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-KM3,1700003612,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Baldocchi, D. D., Poindexter, C., Abraha, M., Desai, A. R., Bohrer, G., Arain, M. A., Griffis, T., Blanken, P. D., O'Halloran, T. L., Thomas, R. Q., Zhang, Q., Burns, S. P., Frank, J. M., Christian, D., Brown, S., Black, T. A., Gough, C. M., Law, B. E., Lee, X., Chen, J., Reed, D. E., Massman, W. J., Clark, K., Hatfield, J., Prueger, J., Bracho, R., Baker, J. M., Martin, T. A. (2018) Temporal Dynamics Of Aerodynamic Canopy Height Derived From Eddy Covariance Momentum Flux Data Across North American Flux Networks, Geophysical Research Letters, 45(6), 9275–9287" -US-KM3,1700003612,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018GL079306 -US-KM3,1700003612,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-KM3,1700004986,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Zenone, T., Gelfand, I., Chen, J., Hamilton, S. K., Robertson, G. P. (2013) From Set-Aside Grassland To Annual And Perennial Cellulosic Biofuel Crops: Effects Of Land Use Change On Carbon Balance, Agricultural And Forest Meteorology, 182-183(6), 1-12" -US-KM3,1700004986,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2013.07.015 -US-KM3,1700004986,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-KM3,14726,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"Land use change, bioenergy, GHG" -US-KM3,14727,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"W.K. Kellogg Biological Station,3700 E Gull Lake Dr, Hickory Corners, MI49060" -US-KM3,14728,GRP_SITE_CHAR,TERRAIN,"Medium Slope (>2 %, <5%)" -US-KM3,14728,GRP_SITE_CHAR,ASPECT,S -US-KM3,14728,GRP_SITE_CHAR,WIND_DIRECTION,SW -US-KM3,14728,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,150 -US-KM3,14728,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,60 -US-KM3,14729,GRP_SITE_DESC,SITE_DESC,"The site was planted to smooth brome grass under the USDA’s Conservation Reserve Program (CRP) grassland since 1987 before conversion. The grass was cut every three years but left in place. The site was converted to no-till soybean in 2009 and to perennial switchgrass from 2010 onwards. Starting from 2011, the switchgrass is harvested every autumn/fall." -US-KM3,14730,GRP_SITE_FUNDING,SITE_FUNDING,"USDOE-GLBRC, NSF-LTER, MSU AgBioResearch" -US-KM3,14731,GRP_STATE,STATE,MI -US-KM3,14744,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,G. Philip Robertson -US-KM3,14744,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-KM3,14744,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,robert30@msu.edu -US-KM3,14744,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Michigan State University -US-KM3,14744,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"W.K. Kellogg Biological Station,3700 E Gull Lake Dr, Hickory Corners, MI49060" -US-KM3,14740,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Jiquan Chen -US-KM3,14740,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-KM3,14740,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,jqchen@msu.edu -US-KM3,14740,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Michigan State University -US-KM3,14740,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"202 Manly Miles Bldg. 1405 South Harrison Road Michigan State University, East Lansing, MI 48823" -US-KM3,14732,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Michael Abraha -US-KM3,14732,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-KM3,14732,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,abraha@msu.edu -US-KM3,14732,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Michigan State University -US-KM3,14732,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"W.K. Kellogg Biological Station,3700 E Gull Lake Dr, Hickory Corners, MI49060" -US-KM3,29912,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-KM3,14733,GRP_TOWER_TYPE,TOWER_TYPE,pole -US-KM3,14734,GRP_URL,URL,http://lees.geo.msu.edu/index.html -US-KM3,24000661,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-KM3 -US-KM3,14735,GRP_UTC_OFFSET,UTC_OFFSET,-5 -US-KM4,14745,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,"Supported by DOE (DE-FC02-07ER64494, DE-AC05-76RL01830) & NSF-LTER (DEB 1027253)" -US-KM4,14746,GRP_CLIM_AVG,MAT,9.9 -US-KM4,14746,GRP_CLIM_AVG,MAP,1027 -US-KM4,14746,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfa -US-KM4,27000662,GRP_COUNTRY,COUNTRY,USA -US-KM4,92878,GRP_DOI,DOI,10.17190/AMF/1634882 -US-KM4,92878,GRP_DOI,DOI_CITATION,"G. Philip Robertson, Jiquan Chen (2021), AmeriFlux BASE US-KM4 KBS Marshall Farms Smooth Brome Grass (Ref), Ver. 4-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1634882" -US-KM4,92878,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-KM4,92824,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-KM4,92824,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,G. Philip Robertson -US-KM4,92824,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-KM4,92824,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,robert30@msu.edu -US-KM4,92824,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Michigan State University -US-KM4,92823,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-KM4,92823,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Jiquan Chen -US-KM4,92823,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-KM4,92823,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,jqchen@msu.edu -US-KM4,92823,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Michigan State University -US-KM4,92847,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Michigan State University -US-KM4,92847,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-KM4,92841,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,"USDOE-GLBRC, NSF-LTER, MSU AgBioResearch" -US-KM4,92841,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-KM4,14747,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Agriculture -US-KM4,14764,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Drought -US-KM4,14769,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Storm or wind -US-KM4,14748,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-KM4,14748,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-KM4,14748,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20090101 -US-KM4,14748,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-KM4,14770,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-KM4,14770,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-KM4,14770,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20090101 -US-KM4,14770,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-KM4,14765,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-KM4,14765,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-KM4,14765,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20090101 -US-KM4,14765,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-KM4,23000662,GRP_HEADER,SITE_NAME,KBS Marshall Farms Smooth Brome Grass (Ref) -US-KM4,14749,GRP_IGBP,IGBP,CRO -US-KM4,14749,GRP_IGBP,IGBP_COMMENT,row crops and hay at least since 1938 -US-KM4,14766,GRP_IGBP,IGBP,GRA -US-KM4,14766,GRP_IGBP,IGBP_DATE_START,1987 -US-KM4,14766,GRP_IGBP,IGBP_COMMENT,Smooth brome grass (Bromus inermis L.) -US-KM4,14750,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -US-KM4,14750,GRP_LAND_OWNERSHIP,LAND_OWNER,Mrs. Edythe Marshall -US-KM4,96712,GRP_LOCATION,LOCATION_LAT,42.4423 -US-KM4,96712,GRP_LOCATION,LOCATION_LONG,-85.3301 -US-KM4,96712,GRP_LOCATION,LOCATION_ELEV,246.3 -US-KM4,96712,GRP_LOCATION,LOCATION_COMMENT,"The tower was set up in November and continuous measurement began in December, 2008." -US-KM4,14752,GRP_NETWORK,NETWORK,AmeriFlux -US-KM4,1700002142,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Abraha, M., Chen, J., Chu, H., Zenone, T., John, R., Su, Y., Hamilton, S. K., Robertson, G. P. (2015) Evapotranspiration Of Annual And Perennial Biofuel Crops In A Variable Climate, GCB Bioenergy, 7(6), 1344-1356" -US-KM4,1700002142,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/GCBB.12239 -US-KM4,1700002142,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-KM4,1700005007,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Abraha, M., Chen, J., Hamilton, S. K., Robertson, G. P. (2020) Long‐Term Evapotranspiration Rates For Rainfed Corn Versus Perennial Bioenergy Crops In A Mesic Landscape, Hydrological Processes, 34(3), 810-822" -US-KM4,1700005007,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/HYP.13630 -US-KM4,1700005007,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-KM4,1700008058,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Abraha, M., Gelfand, I., Hamilton, S. K., Chen, J., Robertson, G. P. (2019) Carbon Debt Of Field-Scale Conservation Reserve Program Grasslands Converted To Annual And Perennial Bioenergy Crops, Environmental Research Letters, 14(2), 024019" -US-KM4,1700008058,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1088/1748-9326/AAFC10 -US-KM4,1700008058,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-KM4,1700007968,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Abraha, M., Gelfand, I., Hamilton, S. K., Shao, C., Su, Y., Robertson, G. P., Chen, J. (2016) Ecosystem Water-Use Efficiency Of Annual Corn And Perennial Grasslands: Contributions From Land-Use History And Species Composition, Ecosystems, 19(6), 1001-1012" -US-KM4,1700007968,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1007/S10021-016-9981-2 -US-KM4,1700007968,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-KM4,1700003975,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Abraha, M., Hamilton, S. K., Chen, J., Robertson, G. P. (2018) Ecosystem Carbon Exchange On Conversion Of Conservation Reserve Program Grasslands To Annual And Perennial Cropping Systems, Agricultural And Forest Meteorology, 253-254(6), 151-160" -US-KM4,1700003975,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2018.02.016 -US-KM4,1700003975,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-KM4,1700003390,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Baldocchi, D. D., Poindexter, C., Abraha, M., Desai, A. R., Bohrer, G., Arain, M. A., Griffis, T., Blanken, P. D., O'Halloran, T. L., Thomas, R. Q., Zhang, Q., Burns, S. P., Frank, J. M., Christian, D., Brown, S., Black, T. A., Gough, C. M., Law, B. E., Lee, X., Chen, J., Reed, D. E., Massman, W. J., Clark, K., Hatfield, J., Prueger, J., Bracho, R., Baker, J. M., Martin, T. A. (2018) Temporal Dynamics Of Aerodynamic Canopy Height Derived From Eddy Covariance Momentum Flux Data Across North American Flux Networks, Geophysical Research Letters, 45(3), 9275–9287" -US-KM4,1700003390,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018GL079306 -US-KM4,1700003390,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-KM4,1700006204,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Baldocchi, D. D., Poindexter, C., Abraha, M., Desai, A. R., Bohrer, G., Arain, M. A., Griffis, T., Blanken, P. D., O'Halloran, T. L., Thomas, R. Q., Zhang, Q., Burns, S. P., Frank, J. M., Christian, D., Brown, S., Black, T. A., Gough, C. M., Law, B. E., Lee, X., Chen, J., Reed, D. E., Massman, W. J., Clark, K., Hatfield, J., Prueger, J., Bracho, R., Baker, J. M., Martin, T. A. (2018) Temporal Dynamics Of Aerodynamic Canopy Height Derived From Eddy Covariance Momentum Flux Data Across North American Flux Networks, Geophysical Research Letters, 45(6), 9275–9287" -US-KM4,1700006204,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018GL079306 -US-KM4,1700006204,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-KM4,1700000153,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Zenone, T., Gelfand, I., Chen, J., Hamilton, S. K., Robertson, G. P. (2013) From Set-Aside Grassland To Annual And Perennial Cellulosic Biofuel Crops: Effects Of Land Use Change On Carbon Balance, Agricultural And Forest Meteorology, 182-183(6), 1-12" -US-KM4,1700000153,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2013.07.015 -US-KM4,1700000153,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-KM4,14754,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"Land use change, bioenergy, GHG" -US-KM4,14755,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"W.K. Kellogg Biological Station,3700 E Gull Lake Dr, Hickory Corners, MI49060" -US-KM4,14756,GRP_SITE_CHAR,TERRAIN,"Significant Slope (>5%, <10%)" -US-KM4,14756,GRP_SITE_CHAR,ASPECT,NW -US-KM4,14756,GRP_SITE_CHAR,WIND_DIRECTION,SW -US-KM4,14756,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,125 -US-KM4,14756,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,60 -US-KM4,14757,GRP_SITE_DESC,SITE_DESC,The site was recruited to the USDA’s Conservation Reserve Program (CRP) grassland in 1987 when it was planted to smooth brome grass. The grass was cut every three years but left in place until 2009; uncut since then. -US-KM4,14758,GRP_SITE_FUNDING,SITE_FUNDING,"USDOE-GLBRC, NSF-LTER, MSU AgBioResearch" -US-KM4,14759,GRP_STATE,STATE,MI -US-KM4,14771,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,G. Philip Robertson -US-KM4,14771,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-KM4,14771,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,robert30@msu.edu -US-KM4,14771,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Michigan State University -US-KM4,14771,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"W.K. Kellogg Biological Station,3700 E Gull Lake Dr, Hickory Corners, MI49060" -US-KM4,14768,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Jiquan Chen -US-KM4,14768,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-KM4,14768,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,jqchen@msu.edu -US-KM4,14768,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Michigan State University -US-KM4,14768,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"202 Manly Miles Bldg. 1405 South Harrison Road Michigan State University, East Lansing, MI 48823" -US-KM4,14760,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Michael Abraha -US-KM4,14760,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-KM4,14760,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,abraha@msu.edu -US-KM4,14760,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Michigan State University -US-KM4,14760,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"W.K. Kellogg Biological Station,3700 E Gull Lake Dr, Hickory Corners, MI49060" -US-KM4,29913,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-KM4,14761,GRP_TOWER_TYPE,TOWER_TYPE,pole -US-KM4,14762,GRP_URL,URL,http://lees.geo.msu.edu/index.html -US-KM4,24000662,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-KM4 -US-KM4,14763,GRP_UTC_OFFSET,UTC_OFFSET,-5 -US-Kon,11529,GRP_CLIM_AVG,MAT,12.77 -US-Kon,11529,GRP_CLIM_AVG,MAP,867 -US-Kon,11529,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Cfa -US-Kon,27000383,GRP_COUNTRY,COUNTRY,USA -US-Kon,15661,GRP_DOI,DOI,10.17190/AMF/1246068 -US-Kon,15661,GRP_DOI,DOI_CITATION,"Nathaniel Brunsell (2020), AmeriFlux BASE US-Kon Konza Prairie LTER (KNZ), Ver. 5-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1246068" -US-Kon,15661,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-Kon,32089,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Kon,32089,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Nathaniel Brunsell -US-Kon,32089,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Kon,32089,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,brunsell@ku.edu -US-Kon,32089,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Kansas University -US-Kon,32091,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Kansas University -US-Kon,32091,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-Kon,32090,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,NSF -US-Kon,32090,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-Kon,11530,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Fire -US-Kon,11543,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Temperature extreme -US-Kon,11531,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Kon,11531,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-Kon,11531,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,2006 -US-Kon,11531,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Kon,11544,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Kon,11544,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-Kon,11544,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,2006 -US-Kon,11544,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Kon,23000383,GRP_HEADER,SITE_NAME,Konza Prairie LTER (KNZ) -US-Kon,11532,GRP_IGBP,IGBP,GRA -US-Kon,33566,GRP_LOCATION,LOCATION_LAT,39.0824 -US-Kon,33566,GRP_LOCATION,LOCATION_LONG,-96.5603 -US-Kon,33566,GRP_LOCATION,LOCATION_ELEV,417 -US-Kon,11534,GRP_NETWORK,NETWORK,AmeriFlux -US-Kon,86978,GRP_NETWORK,NETWORK,Phenocam -US-Kon,1700006462,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Antunes, M. A. H., Walter-Shea, E. A., Mesarch, M. A. (2001) Test Of An Extended Mathematical Approach To Calculate Maize Leaf Area Index And Leaf Angle Distribution, Agricultural And Forest Meteorology, 108(1), 45-53" -US-Kon,1700006462,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/S0168-1923(01)00219-2 -US-Kon,1700006462,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Kon,1700004263,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Bremer, D. J., Ham, J. M. (1999) Effect Of Spring Burning On The Surface Energy Balance In A Tallgrass Prairie, Agricultural And Forest Meteorology, 97(1), 43-54" -US-Kon,1700004263,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/S0168-1923(99)00034-9 -US-Kon,1700004263,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Kon,1700001395,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(11), 108350" -US-Kon,1700001395,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -US-Kon,1700001395,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Kon,1700002751,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Danner, B. T., Knapp, A. K. (2003) Abiotic Constraints On The Establishment Of Quercus Seedlings In Grassland, Global Change Biology, 9(2), 266-275" -US-Kon,1700002751,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1046/J.1365-2486.2003.00574.X -US-Kon,1700002751,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Kon,1700007155,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Novick, K. A., Ficklin, D. L., Stoy, P. C., Williams, C. A., Bohrer, G., Oishi, A., Papuga, S. A., Blanken, P. D., Noormets, A., Sulman, B. N., Scott, R. L., Wang, L., Phillips, R. P. (2016) The Increasing Importance Of Atmospheric Demand For Ecosystem Water And Carbon Fluxes, Nature Climate Change, 6(11), 1023-1027" -US-Kon,1700007155,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1038/NCLIMATE3114 -US-Kon,1700007155,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Kon,1700001356,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Reich, P. B., Turner, D. P., Bolstad, P. (1999) An Approach To Spatially Distributed Modeling Of Net Primary Production (NPP) At The Landscape Scale And Its Application In Validation Of EOS NPP Products, Remote Sensing Of Environment, 70(1), 69-81" -US-Kon,1700001356,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/S0034-4257(99)00058-9 -US-Kon,1700001356,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Kon,1700008781,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Scurlock, J. M., Johnson, K., Olson, R. J. (2002) Estimating Net Primary Productivity From Grassland Biomass Dynamics Measurements, Global Change Biology, 8(8), 736-753" -US-Kon,1700008781,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1046/J.1365-2486.2002.00512.X -US-Kon,1700008781,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Kon,1700001434,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Smith, M. D., Hartnett, D. C., Wilson, G. W. (1999) Interacting Influence Of Mycorrhizal Symbiosis And Competition On Plant Diversity In Tallgrass Prairie, Oecologia, 121(4), 574-582" -US-Kon,1700001434,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1007/S004420050964 -US-Kon,1700001434,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Kon,1700000639,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Turner, D. P., Cohen, W. B., Kennedy, R. E., Fassnacht, K. S., Briggs, J. M. (1999) Relationships Between Leaf Area Index And Landsat TM Spectral Vegetation Indices Across Three Temperate Zone Sites, Remote Sensing Of Environment, 70(1), 52-68" -US-Kon,1700000639,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/S0034-4257(99)00057-7 -US-Kon,1700000639,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Kon,1700005361,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Turner, D. P., Urbanski, S., Bremer, D., Wofsy, S. C., Meyers, T., Gower, S. T., Gregory, M. (2003) A Cross-Biome Comparison Of Daily Light Use Efficiency For Gross Primary Production, Global Change Biology, 9(3), 383-395" -US-Kon,1700005361,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1046/J.1365-2486.2003.00573.X -US-Kon,1700005361,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Kon,1700000546,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Wolf, S., Keenan, T.F., Fisher, J.B., Baldocchi, D.D., Desai, A.R., Richardson, A.D., Scott, R.L., Law, B.E., Litvak, M.E., Brunsell, N.A., Peters, W., van der Laan-Luijkx, I.T. (2016) Warm spring reduced carbon cycle impact of the 2012 US summer drought, Proceedings of the National Academy of Sciences, 113(21), 5880-5885" -US-Kon,1700000546,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1073/PNAS.1519620113 -US-Kon,1700000546,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Kon,30943,GRP_SITE_CHAR,TERRAIN,Undulated/Variable -US-Kon,30943,GRP_SITE_CHAR,ASPECT,SW -US-Kon,30943,GRP_SITE_CHAR,WIND_DIRECTION,SW -US-Kon,30943,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,100 -US-Kon,30943,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,20 -US-Kon,11537,GRP_SITE_DESC,SITE_DESC,Burned on an annual basis. Bison reintroduced in 1987. Experimental cattle herds in 1992 -US-Kon,11538,GRP_SITE_FUNDING,SITE_FUNDING,NSF -US-Kon,28432,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION,Silty clay loam -US-Kon,28432,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION_TAXONOMY,Other -US-Kon,11539,GRP_STATE,STATE,KS -US-Kon,11540,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Nathaniel Brunsell -US-Kon,11540,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Kon,11540,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,brunsell@ku.edu -US-Kon,11540,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Kansas University -US-Kon,11540,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Department of Geography, Atmospheric Science Program, 1475 Jayhawk Blvd.,Lawrence, KS 66045-7613" -US-Kon,33567,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Bryan Conrad -US-Kon,33567,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,DataManager -US-Kon,33567,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,bryan.j.conrad@ku.edu -US-Kon,33567,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Kansas University -US-Kon,33567,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Department of Geography, Atmospheric Science Program, 1475 Jayhawk Blvd.,Lawrence, KS 66045-7613" -US-Kon,11550,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Jeff Taylor -US-Kon,11550,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Technician -US-Kon,11550,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,jht@ksu.edu -US-Kon,11550,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Kansas State University -US-Kon,29820,GRP_TOWER_POWER,TOWER_POWER,Other -US-Kon,11541,GRP_TOWER_TYPE,TOWER_TYPE,tripod -US-Kon,11542,GRP_URL,URL,http://www.konza.ksu.edu -US-Kon,24000383,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-Kon -US-Kon,30942,GRP_UTC_OFFSET,UTC_OFFSET,-6 -US-KPL,98687,GRP_CLIM_AVG,MAT,1.76 -US-KPL,98687,GRP_CLIM_AVG,MAP,375.8 -US-KPL,98687,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfc -US-KPL,27001194,GRP_COUNTRY,COUNTRY,USA -US-KPL,99516,GRP_DOI,DOI,10.17190/AMF/1865478 -US-KPL,99516,GRP_DOI,DOI_CITATION,"Patrick Sullivan (2022), AmeriFlux BASE US-KPL Lily Lake Fen, Ver. 1-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1865478" -US-KPL,99516,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-KPL,99488,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-KPL,99488,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Patrick Sullivan -US-KPL,99488,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-KPL,99488,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,pfsullivan@alaska.edu -US-KPL,99488,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of Alaska Anchorage -US-KPL,99504,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,University of Alaska Anchorage -US-KPL,99504,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-KPL,95842,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Undisturbed -US-KPL,95850,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-KPL,95850,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-KPL,95850,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,202103200100 -US-KPL,95850,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-KPL,95907,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-KPL,95907,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CH4 -US-KPL,95907,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,202103200100 -US-KPL,95907,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-KPL,95870,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-KPL,95870,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-KPL,95870,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,202103200100 -US-KPL,95870,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-KPL,23001194,GRP_HEADER,SITE_NAME,Lily Lake Fen -US-KPL,95852,GRP_IGBP,IGBP,WET -US-KPL,95849,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-KPL,95849,GRP_LAND_OWNERSHIP,LAND_OWNER,Kenai National Wildlife Refuge -US-KPL,98686,GRP_LOCATION,LOCATION_LAT,60.5382 -US-KPL,98686,GRP_LOCATION,LOCATION_LONG,-150.5061 -US-KPL,98686,GRP_LOCATION,LOCATION_ELEV,100.6 -US-KPL,95854,GRP_NETWORK,NETWORK,AmeriFlux -US-KPL,95847,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"3151 Alumni Loop Rd., Anchorage, AK 99508" -US-KPL,95846,GRP_SITE_CHAR,TERRAIN,Flat -US-KPL,95846,GRP_SITE_CHAR,ASPECT,FLAT -US-KPL,95846,GRP_SITE_CHAR,WIND_DIRECTION,E -US-KPL,95846,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,120 -US-KPL,95846,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,200 -US-KPL,95855,GRP_SITE_DESC,SITE_DESC,fen -US-KPL,95853,GRP_STATE,STATE,AK -US-KPL,95848,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Patrick Sullivan -US-KPL,95848,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-KPL,95848,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,pfsullivan@alaska.edu -US-KPL,95848,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Alaska Anchorage -US-KPL,95843,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-KPL,95856,GRP_TOWER_TYPE,TOWER_TYPE,tripod -US-KPL,24001194,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-KPL -US-KPL,95845,GRP_UTC_OFFSET,UTC_OFFSET,-9 -US-KS1,15539,GRP_CLIM_AVG,MAT,21.90 -US-KS1,15539,GRP_CLIM_AVG,MAP,1266 -US-KS1,15539,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Cwa -US-KS1,27000384,GRP_COUNTRY,COUNTRY,USA -US-KS1,15716,GRP_DOI,DOI,10.17190/AMF/1246069 -US-KS1,15716,GRP_DOI,DOI_CITATION,"Bert Drake, Ross Hinkle (2019), AmeriFlux BASE US-KS1 Kennedy Space Center (slash pine), Ver. 3-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1246069" -US-KS1,15716,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-KS1,32093,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-KS1,32093,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Bert Drake -US-KS1,32093,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-KS1,32093,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,drakeb@si.edu -US-KS1,32093,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Smithsonian Environmental Research Center -US-KS1,32092,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-KS1,32092,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Ross Hinkle -US-KS1,32092,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-KS1,32092,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,rhinkle@ucf.edu -US-KS1,32092,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of Central Florida -US-KS1,32096,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Smithsonian Environmental Research Center -US-KS1,32096,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-KS1,32095,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,University of Central Florida -US-KS1,32095,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-KS1,32094,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,NASA -US-KS1,32094,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-KS1,15540,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Fire -US-KS1,15555,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Storm or wind -US-KS1,91777,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-KS1,91777,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-KS1,91777,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,200201010000 -US-KS1,91777,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,200608 -US-KS1,91777,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-KS1,23000384,GRP_HEADER,SITE_NAME,Kennedy Space Center (slash pine) -US-KS1,88348,GRP_HEIGHTC,HEIGHTC,13 -US-KS1,88348,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-KS1,88348,GRP_HEIGHTC,HEIGHTC_APPROACH,point-centered quarter along two transects -US-KS1,88348,GRP_HEIGHTC,HEIGHTC_DATE,20030215 -US-KS1,88348,GRP_HEIGHTC,HEIGHTC_DATE_UNC,10 -US-KS1,88348,GRP_HEIGHTC,HEIGHTC_COMMENT,Stem density in February of 2003 was 18 +/- 8 stems per ha. The dense understory was 2 m in mean height sampled from 20 2.16-m2 inventory plots. -US-KS1,15542,GRP_IGBP,IGBP,ENF -US-KS1,15542,GRP_IGBP,IGBP_COMMENT,ENF covers approximately 15% of the canopy. CSH comprises the understory. -US-KS1,15543,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-KS1,15543,GRP_LAND_OWNERSHIP,LAND_OWNER,NASA -US-KS1,15544,GRP_LOCATION,LOCATION_LAT,28.4583 -US-KS1,15544,GRP_LOCATION,LOCATION_LONG,-80.6709 -US-KS1,15544,GRP_LOCATION,LOCATION_ELEV,1.00 -US-KS1,15545,GRP_NETWORK,NETWORK,AmeriFlux -US-KS1,1700002064,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Bracho, R., Powell, T. L., Dore, S., Li, J., Hinkle, C. R., Drake, B. G. (2008) Environmental And Biological Controls On Water And Energy Exchange In Florida Scrub Oak And Pine Flatwoods Ecosystems, Journal Of Geophysical Research: Biogeosciences, 113(G02004), n/a-n/a" -US-KS1,1700002064,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2007JG000469 -US-KS1,1700002064,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-KS1,1700002265,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Bracho, R., Powell, T. L., Dore, S., Li, J., Hinkle, C. R., Drake, B. G. (2008) Environmental And Biological Controls On Water And Energy Exchange In Florida Scrub Oak And Pine Flatwoods Ecosystems, Journal Of Geophysical Research: Biogeosciences, 113(G2), n/a-n/a" -US-KS1,1700002265,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2007JG000469 -US-KS1,1700002265,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-KS1,1700006576,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(G2), 108350" -US-KS1,1700006576,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -US-KS1,1700006576,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-KS1,1700001740,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Dore, S., Hymus, G. J., Johnson, D. P., Hinkle, C. R., Valentini, R., Drake, B. G. (2003) Cross Validation Of Open-Top Chamber And Eddy Covariance Measurements Of Ecosystem CO2 Exchange In A Florida Scrub-Oak Ecosystem, Global Change Biology, 9(1), 84-95" -US-KS1,1700001740,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1046/J.1365-2486.2003.00561.X -US-KS1,1700001740,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-KS1,1700002184,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Powell, T. L., Bracho, R., Li, J., Dore, S., Hinkle, C. R., Drake, B. G. (2006) Environmental Controls Over Net Ecosystem Carbon Exchange Of Scrub Oak In Central Florida, Agricultural And Forest Meteorology, 141(1), 19-34" -US-KS1,1700002184,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2006.09.002 -US-KS1,1700002184,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-KS1,15546,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"Research Topics and objectives for the Kennedy Space Center Slash Pine Flatwoods site include the following: 1) Quantify and compare latent heat and sensible heat fluxes of these two adjacent, hydrologically contrasting Florida ecosystems; 2) Determine and compare the biological and environmental factors affecting the partition of the available energy into evapotranspiration and sensible heat flux between the two ecosystems (Bracho et al., 2008)." -US-KS1,15547,GRP_SITE_CHAR,TERRAIN,Flat -US-KS1,15547,GRP_SITE_CHAR,ASPECT,FLAT -US-KS1,15547,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,0 -US-KS1,15548,GRP_SITE_DESC,SITE_DESC,"The Kennedy Space Center Slash Pine Flatwoods site is located in the Merritt Island National Wildlife Refuge at the Kennedy Space Center (KSC) on the east coast of central Florida. Occupying 310 ha of local forest, the slash pine flatwoods ecosystem is managed as an uneven-aged stand with a sparsely populated overstory and a dense oak-dominated understory. Disturbances tend to occur on a 7 to 10 year cycle, mostly related to fire or hurricane activity. Prescribed fires have been conducted since 1969 to control understory fuel. The most recent burn was conducted in February of 1995. Following the burn, the stand was allowed to naturally regenerate into a open canopy of slash pines, less than 15% of canopy coverage ( on the order of 15-30 trees per ha), with a understory mostly composed of saw palmetto and scrub oak. There was a seasonally wet swale to the southeast that was on the margin of the flux tower footprint. A severe drought gripped most of Florida beginning in 1998 until the later half of 2001 resulting in four years of relatively low annual precipitation totals. Exceptionally high annual rainfall amounts in 2004 were the result of a pair of hurricanes that hit the area in August and September of 2004. Wind directions for the site are as follows: W and NW in the winter, afternoon E sea breeze in the summer." -US-KS1,15549,GRP_SITE_FUNDING,SITE_FUNDING,NASA -US-KS1,29417,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION,"Myakka (Aeric Haplaquod), a poorly drained, acidic sandy" -US-KS1,29417,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION_TAXONOMY,Other -US-KS1,15550,GRP_STATE,STATE,FL -US-KS1,15551,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Bert Drake -US-KS1,15551,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-KS1,15551,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,drakeb@si.edu -US-KS1,15551,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Smithsonian Environmental Research Center -US-KS1,15551,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"647 Contees Wharf Road, P.O. Box 28,Edgewater, MD USA 21037-0028" -US-KS1,15557,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Ross Hinkle -US-KS1,15557,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-KS1,15557,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,rhinkle@ucf.edu -US-KS1,15557,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Central Florida -US-KS1,91802,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Rosvel Bracho -US-KS1,91802,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,AncContact -US-KS1,91802,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,rbracho@ufl.edu -US-KS1,91802,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Florida -US-KS1,15559,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Sabina Dore -US-KS1,15559,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,AncContact -US-KS1,15559,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,sabina.dore@nau.edu -US-KS1,15559,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Northern Arizona University -US-KS1,15562,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Tom Powell -US-KS1,15562,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,DataManager -US-KS1,15562,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,tlpowell@lbl.gov -US-KS1,15562,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Lawrence Berkeley National Laboratory -US-KS1,29821,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-KS1,15552,GRP_TOWER_TYPE,TOWER_TYPE,triangle -US-KS1,15553,GRP_URL,URL,http://www.serc.si.edu/labs/co2/florida.aspx -US-KS1,24000384,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-KS1 -US-KS1,15554,GRP_UTC_OFFSET,UTC_OFFSET,-5.00 -US-KS2,23899,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER,2.2 -US-KS2,23899,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_ORGAN,Total -US-KS2,23899,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_PHEN,Mixed/unknown -US-KS2,23899,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_UNIT,kgDM m-2 -US-KS2,23899,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_COMMENT,"1.1; these units are in kg carbon in 2003 source Powell et al. 2006 Ag. For. Met. 141:19-43 -" -US-KS2,23772,GRP_BIOMASS_CHEM,BIOMASS_N,0.12 -US-KS2,23772,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-KS2,23772,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-KS2,23772,GRP_BIOMASS_CHEM,BIOMASS_SPP,(All) -US-KS2,23772,GRP_BIOMASS_CHEM,BIOMASS_COMMENT,"N content between April and December, source: Li et al. 2000 Global Change Biology 6:727-733" -US-KS2,15563,GRP_CLIM_AVG,MAT,21.66 -US-KS2,15563,GRP_CLIM_AVG,MAP,1294 -US-KS2,15563,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Cwa -US-KS2,27000385,GRP_COUNTRY,COUNTRY,USA -US-KS2,15678,GRP_DOI,DOI,10.17190/AMF/1246070 -US-KS2,15678,GRP_DOI,DOI_CITATION,"Bert Drake, Ross Hinkle (2019), AmeriFlux BASE US-KS2 Kennedy Space Center (scrub oak), Ver. 3-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1246070" -US-KS2,15678,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-KS2,32097,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-KS2,32097,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Bert Drake -US-KS2,32097,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-KS2,32097,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,drakeb@si.edu -US-KS2,32097,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Smithsonian Environmental Research Center -US-KS2,32098,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-KS2,32098,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Ross Hinkle -US-KS2,32098,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-KS2,32098,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,rhinkle@ucf.edu -US-KS2,32098,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of Central Florida -US-KS2,32101,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Smithsonian Environmental Research Center -US-KS2,32101,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-KS2,32100,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,University of Central Florida -US-KS2,32100,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-KS2,32099,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,NASA -US-KS2,32099,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-KS2,15564,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Fire -US-KS2,15580,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Storm or wind -US-KS2,91779,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-KS2,91779,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-KS2,91779,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,200004010000 -US-KS2,91779,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,200709 -US-KS2,91779,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-KS2,23000385,GRP_HEADER,SITE_NAME,Kennedy Space Center (scrub oak) -US-KS2,88576,GRP_HEIGHTC,HEIGHTC,1.5 -US-KS2,88576,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-KS2,88576,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,12 -US-KS2,88576,GRP_HEIGHTC,HEIGHTC_APPROACH,estimated from 12 2.16m2 inventory plots -US-KS2,88576,GRP_HEIGHTC,HEIGHTC_DATE,20030128 -US-KS2,88576,GRP_HEIGHTC,HEIGHTC_DATE_UNC,2 -US-KS2,15566,GRP_IGBP,IGBP,CSH -US-KS2,15566,GRP_IGBP,IGBP_COMMENT,Source: template -US-KS2,23630,GRP_LAI,LAI_TYPE,LAI -US-KS2,23630,GRP_LAI,LAI_COMMENT,source: Powell et al. 2006 Ag. For. Met. 141:19-41 -US-KS2,23630,GRP_LAI,LAI_TOT,2.5 -US-KS2,15567,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-KS2,15567,GRP_LAND_OWNERSHIP,LAND_OWNER,NASA -US-KS2,24409,GRP_LMA,LMA,174 -US-KS2,24409,GRP_LMA,LMA_SPP,(All) -US-KS2,24409,GRP_LMA,LMA_COMMENT,"average of green leaves sampled June, September, and November source: Hymus et al. 2002 Global Change Biology 8:931-940 -" -US-KS2,15568,GRP_LOCATION,LOCATION_LAT,28.6086 -US-KS2,15568,GRP_LOCATION,LOCATION_LONG,-80.6715 -US-KS2,15568,GRP_LOCATION,LOCATION_ELEV,3.00 -US-KS2,15568,GRP_LOCATION,LOCATION_DATE_START,200004010000 -US-KS2,23901,GRP_NEP,NEP,4400 -US-KS2,23901,GRP_NEP,NEP_COMMENT,"2.2, these units are in kg carbon in 2003 source Powell et al. 2006 Ag. For. Met. 141:19-44 -" -US-KS2,15569,GRP_NETWORK,NETWORK,AmeriFlux -US-KS2,1700008292,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Baldocchi, D., Penuelas, J. (2018) The Physics And Ecology Of Mining Carbon Dioxide From The Atmosphere By Ecosystems, Global Change Biology, 207(1), 117-126" -US-KS2,1700008292,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/GCB.14559 -US-KS2,1700008292,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-KS2,1700007989,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Baldocchi, D., Penuelas, J. (2018) The Physics And Ecology Of Mining Carbon Dioxide From The Atmosphere By Ecosystems, Global Change Biology, 301-302(6), 108350" -US-KS2,1700007989,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/GCB.14559 -US-KS2,1700007989,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-KS2,1700004098,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Bracho, R., Powell, T. L., Dore, S., Li, J., Hinkle, C. R., Drake, B. G. (2008) Environmental And Biological Controls On Water And Energy Exchange In Florida Scrub Oak And Pine Flatwoods Ecosystems, Journal Of Geophysical Research: Biogeosciences, 113(G02004), n/a-n/a" -US-KS2,1700004098,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2007JG000469 -US-KS2,1700004098,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-KS2,1700008712,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(6), 108350" -US-KS2,1700008712,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -US-KS2,1700008712,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-KS2,1700008100,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Dennis Baldocchi, Cove Sturtevant (2015) Does day and night sampling reduce spurious correlation between canopy photosynthesis and ecosystem respiration?, Agricultural and Forest Meteorology, 207(1), 117-126" -US-KS2,1700008100,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2015.03.010 -US-KS2,1700008100,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-KS2,1700002028,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Dijkstra, P., Hymus, G., Colavito, D., Vieglais, D. A., Cundari, C. M., Johnson, D. P., Hungate, B. A., Hinkle, C. R., Drake, B. G. (2002) Elevated Atmospheric CO2 Stimulates Aboveground Biomass In A Fire-Regenerated Scrub-Oak Ecosystem, Global Change Biology, 8(1), 90-103" -US-KS2,1700002028,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1046/J.1354-1013.2001.00458.X -US-KS2,1700002028,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-KS2,1700000036,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Dore, S., Hymus, G. J., Johnson, D. P., Hinkle, C. R., Valentini, R., Drake, B. G. (2003) Cross Validation Of Open-Top Chamber And Eddy Covariance Measurements Of Ecosystem CO2 Exchange In A Florida Scrub-Oak Ecosystem, Global Change Biology, 9(1), 84-95" -US-KS2,1700000036,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1046/J.1365-2486.2003.00561.X -US-KS2,1700000036,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-KS2,1700008970,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Hungate, B. A., Reichstein, M., Dijkstra, P., Johnson, D., Hymus, G., Tenhunen, J. D., Hinkle, C., Drake, B. G. (2002) Evapotranspiration And Soil Water Content In A Scrub-Oak Woodland Under Carbon Dioxide Enrichment, Global Change Biology, 8(3), 289-298" -US-KS2,1700008970,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1046/J.1365-2486.2002.00468.X -US-KS2,1700008970,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-KS2,1700007473,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Hymus, G. J., Johnson, D. P., Dore, S., Anderson, H. P., Ross Hinkle, C., Drake, B. G. (2003) Effects Of Elevated Atmospheric CO2 On Net Ecosystem CO2 Exchange Of A Scrub-Oak Ecosystem, Global Change Biology, 9(12), 1802-1812" -US-KS2,1700007473,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/J.1365-2486.2003.00675.X -US-KS2,1700007473,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-KS2,1700006057,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Hymus, G. J., Snead, T. G., Johnson, D. P., Hungate, B. A., Drake, B. G. (2002) Acclimation Of Photosynthesis And Respiration To Elevated Atmospheric CO2 In Two Scrub Oaks, Global Change Biology, 8(4), 317-328" -US-KS2,1700006057,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1046/J.1354-1013.2001.00472.X -US-KS2,1700006057,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-KS2,1700001155,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Johnson, D. W., Hungate, B. A., Dijkstra, P., Hymus, G., Hinkle, C. R., Stiling, P., Drake, B. G. (2003) The Effects Of Elevated CO2 On Nutrient Distribution In A Fire-Adapted Scrub Oak Forest, Ecological Applications, 13(5), 1388-1399" -US-KS2,1700001155,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1890/02-5139 -US-KS2,1700001155,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-KS2,1700004743,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Langley, J. A., Drake, B. G., Hungate, B. A. (2002) Extensive Belowground Carbon Storage Supports Roots And Mycorrhizae In Regenerating Scrub Oaks, Oecologia, 131(4), 542-548" -US-KS2,1700004743,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1007/S00442-002-0932-6 -US-KS2,1700004743,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-KS2,1700003288,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Li, J., Dijkstra, P., Hinkle, C. R., Wheeler, R. M., Drake, B. G. (1999) Photosynthetic Acclimation To Elevated Atmospheric CO2 Concentration In The Florida Scrub-Oak Species Quercus Geminata And Quercus Myrtifolia Growing In Their Native Environment, Tree Physiology, 19(4-5), 229-234" -US-KS2,1700003288,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1093/TREEPHYS/19.4-5.229 -US-KS2,1700003288,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-KS2,1700007257,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Li, J., Dijkstra, P., Hymus, G. J., Wheeler, R. M., Piastuch, W. C., Hinkle, C. R., Drake, B. G. (2000) Leaf Senescence Of Quercus Myrtifolia As Affected By Long-Term CO2 Enrichment In Its Native Environment, Global Change Biology, 6(7), 727-733" -US-KS2,1700007257,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1046/J.1365-2486.2000.00347.X -US-KS2,1700007257,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-KS2,1700004197,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Li, J., Dugas, W. A., Hymus, G. J., Johnson, D. P., Hinkle, C. R., Drake, B. G., Hungate, B. A. (2003) Direct And Indirect Effects Of Elevated CO2 On Transpiration From Quercus Myrtifolia In A Scrub-Oak Ecosystem, Global Change Biology, 9(1), 96-105" -US-KS2,1700004197,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1046/J.1365-2486.2003.00557.X -US-KS2,1700004197,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-KS2,1700004920,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Novick, K. A., Ficklin, D. L., Stoy, P. C., Williams, C. A., Bohrer, G., Oishi, A., Papuga, S. A., Blanken, P. D., Noormets, A., Sulman, B. N., Scott, R. L., Wang, L., Phillips, R. P. (2016) The Increasing Importance Of Atmospheric Demand For Ecosystem Water And Carbon Fluxes, Nature Climate Change, 6(11), 1023-1027" -US-KS2,1700004920,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1038/NCLIMATE3114 -US-KS2,1700004920,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-KS2,1700004308,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Novick, K. A., Konings, A. G., Gentine, P. (2019) Beyond Soil Water Potential: An Expanded View On Isohydricity Including Land–Atmosphere Interactions And Phenology, Plant, Cell & Environment, 42(6), 1802-1815" -US-KS2,1700004308,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/PCE.13517 -US-KS2,1700004308,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-KS2,1700003696,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Powell, T. L., Bracho, R., Li, J., Dore, S., Hinkle, C. R., Drake, B. G. (2006) Environmental Controls Over Net Ecosystem Carbon Exchange Of Scrub Oak In Central Florida, Agricultural And Forest Meteorology, 141(1), 19-34" -US-KS2,1700003696,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2006.09.002 -US-KS2,1700003696,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-KS2,1700008790,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Stiling, P., Cattell, M., Moon, D. C., Rossi, A., Hungate, B. A., Hymus, G., Drake, B. (2002) Elevated Atmospheric CO2 Lowers Herbivore Abundance, But Increases Leaf Abscission Rates, Global Change Biology, 8(7), 658-667" -US-KS2,1700008790,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1046/J.1365-2486.2002.00501.X -US-KS2,1700008790,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-KS2,1700001689,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Stiling, P., Moon, D., Hunter, M., Colson, J., Rossi, A., Hymus, G., Drake, B. (2003) Elevated CO2 Lowers Relative And Absolute Herbivore Density Across All Species Of A Scrub-Oak Forest, Oecologia, 134(1), 82-87" -US-KS2,1700001689,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1007/S00442-002-1075-5 -US-KS2,1700001689,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-KS2,1700003615,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Zhang, Q., Ficklin, D. L., Manzoni, S., Wang, L., Way, D., Phillips, R. P., Novick, K. A. (2019) Response Of Ecosystem Intrinsic Water Use Efficiency And Gross Primary Productivity To Rising Vapor Pressure Deficit, Environmental Research Letters, 14(7), 074023" -US-KS2,1700003615,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1088/1748-9326/AB2603 -US-KS2,1700003615,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-KS2,15571,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"Research Topics and objectives for the Kennedy Space Center Scrub Oak site include the following: 1) Investigate the effect of elevated atmospheric CO2 concentration on aboveground biomass of a naturally re- regenerated woody ecosystem; 2) Quantify scrub oak net ecosystem exchange over a range of temporal scales from half-hour to annual; 3) Identify the magnitude and temporal scales that leaf area, air temperature, soil moisture, vapor pressure, and solar radiation influence scrub oak C fluxes; 4) Quantify and compare latent heat and sensible heat fluxes of these two adjacent, hydrologically contrasting Florida ecosystems; 5) Determine and compare the biological and environmental factors affecting the partition of the available energy into evapotranspiration and sensible heat flux between the two ecosystems (Dijkstra et al., 2002, Powell et al., 2006, Bracho et al., 2008)." -US-KS2,23929,GRP_SA,SA,11 -US-KS2,15572,GRP_SITE_CHAR,TERRAIN,Flat -US-KS2,15572,GRP_SITE_CHAR,ASPECT,FLAT -US-KS2,15572,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,150 -US-KS2,15572,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,0 -US-KS2,15573,GRP_SITE_DESC,SITE_DESC,"The Kennedy Space Center Scrub Oak site is located within the Merritt Island National Wildlife Refuge at the Kennedy Space Center (KSC) on the east coast of central Florida. Situated in a 10 ha scrub oak ecosystem, the surrounding stand was completely burned by a prescribed fire in 1996. The purpose of the burn was to control understory fuel load, which has been a common practice since 1969. Within a few weeks of the 1996 burn, the stand began to naturally regenerate from roots and rhizomes. Most scrub oak stands in the region undergo a 7 to 10 year disturbance cycle, mostly related to fire or hurricane activity. A severe drought gripped most of Florida beginning in 1998 until the later half of 2001 resulting in four years of relatively low amount of annual rainfall. Exceptionally high annual rainfall amount in 2004 was the result of a pair of hurricanes that hit the area in August and September of 2004. Prevaling wind directions for the site are as follows: W to NW in the winter, afternoon E sea breeze in the summer." -US-KS2,15574,GRP_SITE_FUNDING,SITE_FUNDING,NASA -US-KS2,24301,GRP_SOIL_CHEM,SOIL_CHEM_C_ORG,30 -US-KS2,24825,GRP_SOIL_CHEM,SOIL_CHEM_C_ORG,6 -US-KS2,24034,GRP_SOIL_CHEM,SOIL_CHEM_PH_SALT,5.2 -US-KS2,24552,GRP_SOIL_CHEM,SOIL_CHEM_PH_SALT,5.2 -US-KS2,24168,GRP_SOIL_CHEM,SOIL_CHEM_BD,0.99 -US-KS2,24945,GRP_SOIL_CHEM,SOIL_CHEM_BD,0.99 -US-KS2,24168,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,0 -US-KS2,24301,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,0 -US-KS2,24552,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,0 -US-KS2,24034,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,100 -US-KS2,24825,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,100 -US-KS2,24945,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,100 -US-KS2,24168,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,100 -US-KS2,24301,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,100 -US-KS2,24552,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,100 -US-KS2,24034,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,150 -US-KS2,24825,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,150 -US-KS2,24945,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,150 -US-KS2,24168,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,A -US-KS2,24301,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,A -US-KS2,24552,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,A -US-KS2,24034,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,B -US-KS2,24825,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,B -US-KS2,24945,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,B -US-KS2,24168,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,"source: Schmalzer et al. 2001, Florida Scientist 64:161-190 -" -US-KS2,24945,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,"source: Schmalzer et al. 2001, Florida Scientist 64:161-190 -" -US-KS2,24034,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,"source: Schmalzer et al. 2001, Florida Scientist 64:161-191 -" -US-KS2,24552,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,"source: Schmalzer et al. 2001, Florida Scientist 64:161-191 -" -US-KS2,27483,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION,Well-drained Pomello (Arenic Haplohumod) sands -US-KS2,27483,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION_TAXONOMY,Other -US-KS2,24029,GRP_SOIL_DEPTH,SOIL_DEPTH,50 -US-KS2,24160,GRP_SOIL_DEPTH,SOIL_DEPTH,150 -US-KS2,24160,GRP_SOIL_DEPTH,SOIL_DEPTH_COMMENT,": ->1,5m" -US-KS2,24804,GRP_SOIL_DEPTH,SOIL_DEPTH,2.5 -US-KS2,24944,GRP_SOIL_DEPTH,SOIL_DEPTH,125 -US-KS2,23653,GRP_SOIL_TEX,SOIL_TEX_SAND,90 -US-KS2,24170,GRP_SOIL_TEX,SOIL_TEX_SAND,90 -US-KS2,23653,GRP_SOIL_TEX,SOIL_TEX_SILT,5 -US-KS2,24170,GRP_SOIL_TEX,SOIL_TEX_SILT,5 -US-KS2,23653,GRP_SOIL_TEX,SOIL_TEX_CLAY,5 -US-KS2,24170,GRP_SOIL_TEX,SOIL_TEX_CLAY,5 -US-KS2,24665,GRP_SOIL_TEX,SOIL_TEX_WATER_HOLD_CAP,0.9 -US-KS2,23653,GRP_SOIL_TEX,SOIL_TEX_PROFILE_MIN,0 -US-KS2,24665,GRP_SOIL_TEX,SOIL_TEX_PROFILE_MIN,0 -US-KS2,24170,GRP_SOIL_TEX,SOIL_TEX_PROFILE_MIN,100 -US-KS2,23653,GRP_SOIL_TEX,SOIL_TEX_PROFILE_MAX,100 -US-KS2,24170,GRP_SOIL_TEX,SOIL_TEX_PROFILE_MAX,150 -US-KS2,24665,GRP_SOIL_TEX,SOIL_TEX_PROFILE_MAX,150 -US-KS2,23653,GRP_SOIL_TEX,SOIL_TEX_HORIZON,A -US-KS2,24170,GRP_SOIL_TEX,SOIL_TEX_HORIZON,B -US-KS2,24665,GRP_SOIL_TEX,SOIL_TEX_HORIZON,Total -US-KS2,24665,GRP_SOIL_TEX,SOIL_TEX_COMMENT,"(range 0.5-1.3) : ->1,5m" -US-KS2,24298,GRP_SPP_O,SPP_O,"Quercus myrtifolia, Q. geminata, Q. Chapmanii, Serenoa, repens" -US-KS2,15575,GRP_STATE,STATE,FL -US-KS2,15576,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Bert Drake -US-KS2,15576,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-KS2,15576,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,drakeb@si.edu -US-KS2,15576,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Smithsonian Environmental Research Center -US-KS2,15576,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"647 Contees Wharf Road, P.O. Box 28,Edgewater, MD USA 21037-0028" -US-KS2,15582,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Ross Hinkle -US-KS2,15582,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-KS2,15582,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,rhinkle@ucf.edu -US-KS2,15582,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Central Florida -US-KS2,91789,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Rosvel Bracho -US-KS2,91789,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,AncContact -US-KS2,91789,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,rbracho@ufl.edu -US-KS2,91789,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Florida -US-KS2,15584,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Sabina Dore -US-KS2,15584,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,AncContact -US-KS2,15584,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,sabina.dore@nau.edu -US-KS2,15584,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Northern Arizona University -US-KS2,15588,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Tom Powell -US-KS2,15588,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,DataManager -US-KS2,15588,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,tlpowell@lbl.gov -US-KS2,15588,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Lawrence Berkeley National Laboratory -US-KS2,29822,GRP_TOWER_POWER,TOWER_POWER,Direct power -US-KS2,15577,GRP_TOWER_TYPE,TOWER_TYPE,pole -US-KS2,15578,GRP_URL,URL,http://www.serc.si.edu/labs/co2/florida.aspx -US-KS2,24000385,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-KS2 -US-KS2,15579,GRP_UTC_OFFSET,UTC_OFFSET,-5.00 -US-KS3,79249,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,"Thanks to AmeriFlux, DOE, NASA Kennedy Space Center, and US Fish and Wildlife Service. -" -US-KS3,79250,GRP_CLIM_AVG,MAT,22.3 -US-KS3,79250,GRP_CLIM_AVG,MAP,1340 -US-KS3,79250,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Cfa -US-KS3,27000942,GRP_COUNTRY,COUNTRY,USA -US-KS3,87984,GRP_DOI,DOI,10.17190/AMF/1562390 -US-KS3,87984,GRP_DOI,DOI_CITATION,"Ross Hinkle (2019), AmeriFlux BASE US-KS3 Kennedy Space Center (salt marsh), Ver. 1-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1562390" -US-KS3,87984,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-KS3,87952,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-KS3,87952,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Ross Hinkle -US-KS3,87952,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-KS3,87952,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,rhinkle@ucf.edu -US-KS3,87952,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of Central Florida -US-KS3,87977,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,University of Central Florida -US-KS3,87977,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-KS3,87968,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,DOE Ameriflux -US-KS3,87968,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-KS3,79251,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Hydrologic event -US-KS3,91780,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-KS3,91780,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-KS3,91780,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201712120000 -US-KS3,91780,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20200227 -US-KS3,91780,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-KS3,91780,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,Rapid Response system deployment -US-KS3,79252,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-KS3,79252,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-KS3,79252,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201712120000 -US-KS3,79252,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-KS3,23000942,GRP_HEADER,SITE_NAME,Kennedy Space Center (salt marsh) -US-KS3,79254,GRP_IGBP,IGBP,WET -US-KS3,79254,GRP_IGBP,IGBP_COMMENT,Salt marsh dominated by Distichlis spicata with mixture of Batis and Salicornia. Encroaching mangrove. -US-KS3,79255,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-KS3,79255,GRP_LAND_OWNERSHIP,LAND_OWNER,Managed as Wildlife Refuge USFWS and Owned by NASA -US-KS3,79256,GRP_LOCATION,LOCATION_LAT,28.7084 -US-KS3,79256,GRP_LOCATION,LOCATION_LONG,-80.7427 -US-KS3,79256,GRP_LOCATION,LOCATION_ELEV,0 -US-KS3,79256,GRP_LOCATION,LOCATION_DATE_START,201712120000 -US-KS3,79256,GRP_LOCATION,LOCATION_COMMENT,The site is in T-9 management area at Merritt Island National Wildlife Refuge -US-KS3,79257,GRP_NETWORK,NETWORK,AmeriFlux -US-KS3,79258,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,Carbon flux of coastal salt marsh related to changes related to woody encroachment -US-KS3,79259,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"UCF Bio Dept., Bio Sci Bldg, 4110 Libra Dr, Bio309, Orlando, FL 32816" -US-KS3,79260,GRP_SITE_CHAR,TERRAIN,Flat -US-KS3,79260,GRP_SITE_CHAR,ASPECT,FLAT -US-KS3,79260,GRP_SITE_CHAR,WIND_DIRECTION,SE -US-KS3,79260,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,100 -US-KS3,79260,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,0 -US-KS3,79261,GRP_SITE_DESC,SITE_DESC,Salt marsh dominated by Distichlis and being encroached by Mangrove -US-KS3,79262,GRP_SITE_FUNDING,SITE_FUNDING,DOE Ameriflux -US-KS3,79263,GRP_STATE,STATE,FL -US-KS3,79264,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Ross Hinkle -US-KS3,79264,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-KS3,79264,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,rhinkle@ucf.edu -US-KS3,79264,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Central Florida -US-KS3,79264,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"4110 Libra Drive, Dept. of Biology, UCF, Orlando, Fl 32816" -US-KS3,86922,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Rosvel Bracho -US-KS3,86922,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-KS3,86922,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,rbracho@ufl.edu -US-KS3,86922,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Florida -US-KS3,86922,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"136 Newins Ziegler Hall -University of Florida -Gainesville FL, 32611" -US-KS3,79265,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-KS3,79266,GRP_TOWER_TYPE,TOWER_TYPE,tripod -US-KS3,24000942,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-KS3 -US-KS3,86923,GRP_UTC_OFFSET,UTC_OFFSET,-5 -US-KS3,86923,GRP_UTC_OFFSET,UTC_OFFSET_DATE_START,201712120000 -US-KUO,11696,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,The KUOM flux study was funded by NASA (NNG04GN80G) as a component of the NACP -US-KUO,11697,GRP_CLIM_AVG,MAT,7.9 -US-KUO,11697,GRP_CLIM_AVG,MAP,777 -US-KUO,11697,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfa -US-KUO,27000386,GRP_COUNTRY,COUNTRY,USA -US-KUO,11698,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Land cover change -US-KUO,11699,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-KUO,11699,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-KUO,11699,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20060627 -US-KUO,11699,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20090626 -US-KUO,11699,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-KUO,11715,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-KUO,11715,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-KUO,11715,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20060627 -US-KUO,11715,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20090626 -US-KUO,11715,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-KUO,11714,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-KUO,11714,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-KUO,11714,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20060627 -US-KUO,11714,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20090626 -US-KUO,11714,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-KUO,23000386,GRP_HEADER,SITE_NAME,KUOM tower -US-KUO,11700,GRP_IGBP,IGBP,URB -US-KUO,11700,GRP_IGBP,IGBP_COMMENT,The site was a suburban residential neighborhood with a mature tree canopy (predominantly deciduous broadleaf trees) and cool-season turfgrass ground cover. It was representative of an open low-rise local climate zone (LCZ 6) in the urban landscape classification system of Stewart and Oke (2012). There was a golf course to the southwest of the tower. -US-KUO,11701,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -US-KUO,11702,GRP_LOCATION,LOCATION_LAT,44.9984 -US-KUO,11702,GRP_LOCATION,LOCATION_LONG,-93.1884 -US-KUO,11702,GRP_LOCATION,LOCATION_ELEV,301 -US-KUO,11702,GRP_LOCATION,LOCATION_COMMENT,Updated to 6 decimal digits accuracy by the PI on 20140507 -US-KUO,11703,GRP_NETWORK,NETWORK,AmeriFlux -US-KUO,1700000213,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Peters, E. B., McFadden, J. P. (2012) Continuous Measurements Of Net CO2 Exchange By Vegetation And Soils In A Suburban Landscape, Journal Of Geophysical Research: Biogeosciences, 117(G03005), n/a-n/a" -US-KUO,1700000213,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2011JG001933 -US-KUO,1700000213,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-KUO,11705,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"The research focus at this site was to quantify the magnitude of CO2, water vapor, and energy fluxes from vegetation and soils in an urban/suburban landscape, and to understand how they affect the spatial and temporal dynamics of the total CO2 flux between the urban environment and the atmosphere." -US-KUO,11706,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"Department of Geography, University of California, 1832 Ellison Hall, Santa Barbara, CA 93106-4060" -US-KUO,11707,GRP_SITE_CHAR,TERRAIN,Flat -US-KUO,11707,GRP_SITE_CHAR,WIND_DIRECTION,NW -US-KUO,11707,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,1500 -US-KUO,11707,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,90 -US-KUO,11708,GRP_SITE_DESC,SITE_DESC,"The site was a first-ring suburban residential neighborhood that experienced rapid residential development in the 1950s. Prior to that time, farms and nurseries were the predominant land-use types. There were no significant changes to the surrounding land use during the study." -US-KUO,11709,GRP_SITE_FUNDING,SITE_FUNDING,NASA -US-KUO,11710,GRP_STATE,STATE,MN -US-KUO,11711,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Joe McFadden -US-KUO,11711,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-KUO,11711,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,mcfadden@ucsb.edu -US-KUO,11711,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"University of California, Santa Barbara" -US-KUO,11711,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Department of Geography, University of California, Santa Barbara, CA 93106-4060" -US-KUO,29823,GRP_TOWER_POWER,TOWER_POWER,Direct power -US-KUO,11712,GRP_TOWER_TYPE,TOWER_TYPE,triangle -US-KUO,7766,GRP_URL,URL,http://mcfaddenlab.umn.edu/research/landuse/ -US-KUO,24000386,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-KUO -US-KUO,11713,GRP_UTC_OFFSET,UTC_OFFSET,-6 -US-KUT,11756,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,The KUOM flux study was funded by NASA (NNG04GN80G) as a component of the NACP -US-KUT,11757,GRP_CLIM_AVG,MAT,7.9 -US-KUT,11757,GRP_CLIM_AVG,MAP,777 -US-KUT,11757,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfa -US-KUT,27000511,GRP_COUNTRY,COUNTRY,USA -US-KUT,15761,GRP_DOI,DOI,10.17190/AMF/1246145 -US-KUT,15761,GRP_DOI,DOI_CITATION,"Joe McFadden (2016), AmeriFlux BASE US-KUT KUOM Turfgrass Field, Ver. 1-1, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1246145" -US-KUT,15761,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-KUT,32361,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-KUT,32361,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Joe McFadden -US-KUT,32361,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-KUT,32361,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,mcfadden@ucsb.edu -US-KUT,32361,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"University of California, Santa Barbara" -US-KUT,32363,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,"University of California, Santa Barbara" -US-KUT,32363,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-KUT,32362,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,NASA -US-KUT,32362,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-KUT,11758,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Land cover change -US-KUT,11759,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-KUT,11759,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-KUT,11759,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20051127 -US-KUT,11759,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20090529 -US-KUT,11759,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-KUT,11775,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-KUT,11775,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-KUT,11775,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20051127 -US-KUT,11775,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20090529 -US-KUT,11775,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-KUT,11774,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-KUT,11774,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-KUT,11774,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20051127 -US-KUT,11774,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20090529 -US-KUT,11774,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-KUT,23000511,GRP_HEADER,SITE_NAME,KUOM Turfgrass Field -US-KUT,11760,GRP_IGBP,IGBP,GRA -US-KUT,11760,GRP_IGBP,IGBP_COMMENT,"The footprint of this tower fell within a large turfgrass field, so the flux measurements represented only grass vegetation. However, the field was located within a suburban residential neighborhood, so the local climate and environment represented urban conditions. Note that the land management of the field site changed (removal of the turfgrass lawn and planting of trees) AFTER the flux study was completed--this means that imagery after 2009 does not show the land conditions during the flux study." -US-KUT,11761,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-KUT,11762,GRP_LOCATION,LOCATION_LAT,44.9950 -US-KUT,11762,GRP_LOCATION,LOCATION_LONG,-93.1863 -US-KUT,11762,GRP_LOCATION,LOCATION_ELEV,301 -US-KUT,11762,GRP_LOCATION,LOCATION_COMMENT,Updated to 6 decimal digits accuracy by the PI on 20140507 -US-KUT,11763,GRP_NETWORK,NETWORK,AmeriFlux -US-KUT,1700000651,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(2), 108350" -US-KUT,1700000651,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -US-KUT,1700000651,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-KUT,1700007686,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Hiller, R. V., McFadden, J. P., Kljun, N. (2011) Interpreting CO2 Fluxes Over A Suburban Lawn: The Influence Of Traffic Emissions, Boundary-Layer Meteorology, 138(2), 215-230" -US-KUT,1700007686,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1007/S10546-010-9558-0 -US-KUT,1700007686,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-KUT,11765,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"This site was located within the footprint area of the KUOM tall tower (US-KUO). The research focus was to quantify the CO2, water vapor, and energy fluxes over lawn-covered areas of the urban/suburban environment. Specifically, the US-KUT site focused on quantifying the CO2 exchange of turfgrasses and soils in order to partition the carbon budget that was measured from the US-KUO tall tower." -US-KUT,11766,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"Department of Geography, University of California, 1832 Ellison Hall, Santa Barbara, CA 93106-4060" -US-KUT,11767,GRP_SITE_CHAR,TERRAIN,Flat -US-KUT,11767,GRP_SITE_CHAR,WIND_DIRECTION,NW -US-KUT,11767,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,100 -US-KUT,11767,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,90 -US-KUT,11768,GRP_SITE_DESC,SITE_DESC,"The site was a low-maintenace lawn consisting of cool-season turfgrasses, typical of residential lawns or urban parks in the study area. It was mowed to a height of 70 mm approximately once per week with clippings left to decompose on the surface, was not irrigated, and received one application of inorganic N fertilizer per year. The surrounding suburban residential neighborhood experienced rapid residential development in the 1950s; prior to that time, farms and nurseries were the predominant land-use types. Note that the land management of the field site changed (removal of the turfgrass lawn and planting of trees) AFTER the flux study was completed--this means that imagery after 2009 does not show the land conditions during the flux study." -US-KUT,11769,GRP_SITE_FUNDING,SITE_FUNDING,NASA -US-KUT,11770,GRP_STATE,STATE,MN -US-KUT,11771,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Joe McFadden -US-KUT,11771,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-KUT,11771,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,mcfadden@ucsb.edu -US-KUT,11771,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"University of California, Santa Barbara" -US-KUT,11771,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Department of Geography, University of California, Santa Barbara, CA 93106-4060" -US-KUT,29862,GRP_TOWER_POWER,TOWER_POWER,Direct power -US-KUT,11772,GRP_TOWER_TYPE,TOWER_TYPE,tripod -US-KUT,24000511,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-KUT -US-KUT,11773,GRP_UTC_OFFSET,UTC_OFFSET,-6 -US-LA3,85161,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,"Funding for this research was provided by the USGS LandCarbon Program and USGS Ecosystems Mission Area. We thank Apache Louisiana Minerals for allowing us to install studies on their lands. Any use of trade, product, or firm names is for descriptive purposes only and does not imply endorsement by the U.S. Government." -US-LA3,85155,GRP_CLIM_AVG,MAT,20.9 -US-LA3,85155,GRP_CLIM_AVG,MAP,1623 -US-LA3,85155,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Cfa -US-LA3,27001011,GRP_COUNTRY,COUNTRY,USA -US-LA3,85148,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Undisturbed -US-LA3,85159,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Chambers -US-LA3,85159,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-LA3,85159,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201912211200 -US-LA3,85159,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Planned -US-LA3,85156,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Chambers -US-LA3,85156,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CH4 -US-LA3,85156,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201912211200 -US-LA3,85156,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Planned -US-LA3,85146,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-LA3,85146,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-LA3,85146,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201912211200 -US-LA3,85146,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Planned -US-LA3,85152,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-LA3,85152,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CH4 -US-LA3,85152,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201912211200 -US-LA3,85152,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Planned -US-LA3,85166,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-LA3,85166,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-LA3,85166,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201912211200 -US-LA3,85166,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Planned -US-LA3,23001011,GRP_HEADER,SITE_NAME,Barataria Bay Saline Marsh -US-LA3,85157,GRP_IGBP,IGBP,WET -US-LA3,85157,GRP_IGBP,IGBP_COMMENT,"Dominated by Spartina alterniflora + Juncus roemarianus, some Spartina patens + Distichlis spicata" -US-LA3,85158,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -US-LA3,85158,GRP_LAND_OWNERSHIP,LAND_OWNER,Apache Corporation -US-LA3,85145,GRP_LOCATION,LOCATION_LAT,29.4936 -US-LA3,85145,GRP_LOCATION,LOCATION_LONG,-89.9153 -US-LA3,85145,GRP_LOCATION,LOCATION_ELEV,0.2 -US-LA3,85145,GRP_LOCATION,LOCATION_COMMENT,near Louisiana Coastwide Reference Monitoring System (CRMS) Site 0224 and NCDC Weather Station USC00165624 -US-LA3,85164,GRP_NETWORK,NETWORK,AmeriFlux -US-LA3,85153,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"Annual carbon and water fluxes, chamber/EC comparison" -US-LA3,85151,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"700 Cajundome Blvd., Lafayette, LA 70506" -US-LA3,85154,GRP_SITE_CHAR,TERRAIN,Flat -US-LA3,85154,GRP_SITE_CHAR,ASPECT,FLAT -US-LA3,85154,GRP_SITE_CHAR,WIND_DIRECTION,SSE -US-LA3,85154,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,300 -US-LA3,85154,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,0 -US-LA3,85162,GRP_SITE_DESC,SITE_DESC,"Saline marsh, 20-40% organic matter, microtidal, dominated by Spartina alterniflora + Juncus roemarianus, patchy open water area" -US-LA3,85147,GRP_SITE_FUNDING,SITE_FUNDING,US Geological Survey -US-LA3,85163,GRP_STATE,STATE,LA -US-LA3,85150,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Eric Ward -US-LA3,85150,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-LA3,85150,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,eward@usgs.gov -US-LA3,85150,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,USGS-Wetland and Aquatic Research Center -US-LA3,85150,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"700 Cajundome Blvd., Lafayette, LA 70506" -US-LA3,101393,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Sergio Merino -US-LA3,101393,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Technician -US-LA3,101393,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,smerino@usgs.gov -US-LA3,101393,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,USGS-Wetland and Aquatic Research Center -US-LA3,101393,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"700 Cajundome Blvd., Lafayette, LA 70506" -US-LA3,85160,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-LA3,85165,GRP_TOWER_TYPE,TOWER_TYPE,tripod -US-LA3,24001011,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-LA3 -US-LA3,85149,GRP_UTC_OFFSET,UTC_OFFSET,-6 -US-Lin,27000513,GRP_COUNTRY,COUNTRY,USA -US-Lin,15820,GRP_DOI,DOI,10.17190/AMF/1246830 -US-Lin,15820,GRP_DOI,DOI_CITATION,"Silvano Fares (2019), AmeriFlux BASE US-Lin Lindcove Orange Orchard, Ver. 2-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1246830" -US-Lin,15820,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-Lin,32367,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Lin,32367,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Silvano Fares -US-Lin,32367,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Lin,32367,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,silvano.fares@crea.gov.it -US-Lin,32367,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Entecra -US-Lin,32369,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Entecra -US-Lin,32369,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-Lin,32368,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,California Air Resources Board and Citrus Research Board -US-Lin,32368,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-Lin,83618,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Lin,83618,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-Lin,83618,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,200910 -US-Lin,83618,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,201011 -US-Lin,83618,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Lin,83618,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,Date start and date end provided by Silvano Fares -US-Lin,23000513,GRP_HEADER,SITE_NAME,Lindcove Orange Orchard -US-Lin,88367,GRP_HEIGHTC,HEIGHTC,3.7 -US-Lin,88367,GRP_HEIGHTC,HEIGHTC_STATISTIC,Single observation -US-Lin,88367,GRP_HEIGHTC,HEIGHTC_DATE,200910010000 -US-Lin,88367,GRP_HEIGHTC,HEIGHTC_COMMENT,the single observation is representative of the canopy height at the site since the citrus trees were all pruned at the same height to facilitate harvesting operations -US-Lin,2478,GRP_IGBP,IGBP,CRO -US-Lin,92795,GRP_LOCATION,LOCATION_LAT,36.3566 -US-Lin,92795,GRP_LOCATION,LOCATION_LONG,-119.0922 -US-Lin,92795,GRP_LOCATION,LOCATION_ELEV,131 -US-Lin,1557,GRP_NETWORK,NETWORK,AmeriFlux -US-Lin,1700000195,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(8), 108350" -US-Lin,1700000195,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -US-Lin,1700000195,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Lin,1700008877,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Fares, S., Vargas, R., Detto, M., Goldstein, A. H., Karlik, J., Paoletti, E., Vitale, M. (2013) Tropospheric Ozone Reduces Carbon Assimilation In Trees: Estimates From Analysis Of Continuous Flux Measurements, Global Change Biology, 19(8), 2427-2443" -US-Lin,1700008877,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/GCB.12222 -US-Lin,1700008877,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Lin,1700004335,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Fares, S., Weber, R., Park, J., Gentner, D., Karlik, J., Goldstein, A. H. (2012) Ozone Deposition To An Orange Orchard: Partitioning Between Stomatal And Non-Stomatal Sinks, Environmental Pollution, 169(), 258-266" -US-Lin,1700004335,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.ENVPOL.2012.01.030 -US-Lin,1700004335,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Lin,1700005337,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Fares, S., Weber, R., Park, J., Gentner, D., Karlik, J., Goldstein, A. H. (2012) Ozone Deposition To An Orange Orchard: Partitioning Between Stomatal And Non-Stomatal Sinks, Environmental Pollution, 169(8), 258-266" -US-Lin,1700005337,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.ENVPOL.2012.01.030 -US-Lin,1700005337,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Lin,92800,GRP_SITE_DESC,SITE_DESC,"The experimental site was a citrus orchard about three km west of the UC Lindcove Research and Experiment Station. The site is characterized by a Mediterranean climate typical of Central California, with warm dry summers and cool wet winters. The soil texture for the upper horizon (0-33 cm) was loam with a particle size distribution of 42% sand, 38% silt, and 20% clay (Kearney Ag Center). Soil pH was 7.4 (Valley Tech Soil Agricultural Laboratory Services). The orchard was drip-irrigated with water applied twice per week in the warm season to ensure water avail- ability close to field capacity. The site was kept clean from understory vegetation and mechanical pruning operations took place twice a year to limit the size ofthe orange trees for harvesting and site maintenance. The block of trees in which the tower and instruments were located was ‘Valencia’ orange on trifoliate rootstock, with a planting date in the 1960’s. The square 4 ha block had dimensions of 200 m NeS and EeW. At the end of the study, we harvested a ‘Valencia’ citrus tree from within the study block to measure citrus leaf area index (LAI) and biomass density. The tree height was 3.7 m as measured with a telescoping pole. We measured canopy radii in the four cardinal directions to calculate a planar area (as seen from above) of 12.2 m2. The mean specific leaf area (SLA) of citrus leaves was 85.4 cm2 g-1 obtained by measuring leaf area of five groups of leaf samples with a LiCor Leaf area meter (mod. LI-3100C) followed by drying and weighing. LAI for the orchard was 3.00, derived using the SLA value and the total dry mass of leaves from the harvested tree, multiplied by the plant population of 237 plants per ha as obtained from spacing measurements and Google Maps imagery." -US-Lin,15776,GRP_SITE_FUNDING,SITE_FUNDING,California Air Resources Board and Citrus Research Board -US-Lin,653,GRP_STATE,STATE,CA -US-Lin,92778,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Silvano Fares -US-Lin,92778,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Lin,92778,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,silvano.fares@cnr.it -US-Lin,92778,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,National Research Council of Italy -US-Lin,92778,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,Rome -US-Lin,7491,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Allen Goldstein -US-Lin,7491,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,AncContact -US-Lin,7491,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,ahg@berkeley.edu -US-Lin,7491,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"University of California, Berkeley" -US-Lin,7491,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Environmental Science, Policy, & Management, 151 Hilgard Hall,Berkeley, CA USA 94720-3110" -US-Lin,2396,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Robin J. Weber -US-Lin,2396,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-Lin,2396,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,rjweber@berkeley.edu -US-Lin,2396,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of California -US-Lin,2396,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Environmental Science, Policy and Management, 151 Hilgard Hall,Berkeley, CA USA 94720-3110" -US-Lin,24000513,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-Lin -US-Lin,33645,GRP_UTC_OFFSET,UTC_OFFSET,-8 -US-Lin,33645,GRP_UTC_OFFSET,UTC_OFFSET_COMMENT,Added by AMF data processing team for data QAQC checks. -US-LL1,83572,GRP_CLIM_AVG,MAT,20 -US-LL1,83572,GRP_CLIM_AVG,MAP,1310 -US-LL1,83572,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Cfa -US-LL1,27000985,GRP_COUNTRY,COUNTRY,USA -US-LL1,86704,GRP_DM_EXT_WEATHER,DM_EXT_WEATHER,Drought -US-LL1,86704,GRP_DM_EXT_WEATHER,DM_DATE_START,201005010800 -US-LL1,86704,GRP_DM_EXT_WEATHER,DM_DATE_END,201208312359 -US-LL1,86704,GRP_DM_EXT_WEATHER,DM_DATE_UNC,20 -US-LL1,86707,GRP_DM_FIRE,DM_FIRE,Prescribed human induced underburn -US-LL1,86707,GRP_DM_FIRE,DM_SURF,100 -US-LL1,86707,GRP_DM_FIRE,DM_SURF_MEAS_UNC,100 -US-LL1,86707,GRP_DM_FIRE,DM_DATE_START,200901140800 -US-LL1,86707,GRP_DM_FIRE,DM_DATE_END,200901142359 -US-LL1,86707,GRP_DM_FIRE,DM_DATE_UNC,2 -US-LL1,86707,GRP_DM_FIRE,DM_COMMENT,fire return interval 2 yrs -US-LL1,86708,GRP_DM_FIRE,DM_FIRE,Prescribed human induced underburn -US-LL1,86708,GRP_DM_FIRE,DM_DATE_START,201103110800 -US-LL1,86708,GRP_DM_FIRE,DM_DATE_END,201103112359 -US-LL1,86708,GRP_DM_FIRE,DM_DATE_UNC,3 -US-LL1,86705,GRP_DM_FIRE,DM_FIRE,Prescribed human induced underburn -US-LL1,86705,GRP_DM_FIRE,DM_DATE_START,201303150800 -US-LL1,86705,GRP_DM_FIRE,DM_DATE_END,201303152359 -US-LL1,86705,GRP_DM_FIRE,DM_DATE_UNC,3 -US-LL1,86709,GRP_DM_FIRE,DM_FIRE,Prescribed human induced underburn -US-LL1,86709,GRP_DM_FIRE,DM_DATE_START,201503040800 -US-LL1,86709,GRP_DM_FIRE,DM_DATE_END,201503042359 -US-LL1,86709,GRP_DM_FIRE,DM_DATE_UNC,3 -US-LL1,86706,GRP_DM_FIRE,DM_FIRE,Prescribed human induced underburn -US-LL1,86706,GRP_DM_FIRE,DM_DATE_START,201703210800 -US-LL1,86706,GRP_DM_FIRE,DM_DATE_END,201703212359 -US-LL1,86706,GRP_DM_FIRE,DM_DATE_UNC,3 -US-LL1,95625,GRP_DOI,DOI,10.17190/AMF/1773395 -US-LL1,95625,GRP_DOI,DOI_CITATION,"Gregory Starr (2021), AmeriFlux BASE US-LL1 Longleaf Pine - Baker (Mesic site), Ver. 2-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1773395" -US-LL1,95625,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-LL1,95580,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-LL1,95580,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Gregory Starr -US-LL1,95580,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-LL1,95580,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,gstarr@ua.edu -US-LL1,95580,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,The University of Alabama -US-LL1,95610,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,The University of Alabama -US-LL1,95610,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-LL1,95602,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,"Joseph W. Jones Center, The University of Alabama" -US-LL1,95602,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-LL1,83558,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Drought -US-LL1,83553,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Fire -US-LL1,83561,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Forestry -US-LL1,83565,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-LL1,83565,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-LL1,83565,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,200810221000 -US-LL1,83565,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,201607052330 -US-LL1,83565,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-LL1,83562,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-LL1,83562,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-LL1,83562,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,200810221000 -US-LL1,83562,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,201607052330 -US-LL1,83562,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-LL1,23000985,GRP_HEADER,SITE_NAME,Longleaf Pine - Baker (Mesic site) -US-LL1,83567,GRP_IGBP,IGBP,SAV -US-LL1,83567,GRP_IGBP,IGBP_DATE_START,19230101 -US-LL1,83567,GRP_IGBP,IGBP_COMMENT,C4 grass in the understory -US-LL1,83554,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -US-LL1,83554,GRP_LAND_OWNERSHIP,LAND_OWNER,Robert W. Woodruff Foundation -US-LL1,83560,GRP_LOCATION,LOCATION_LAT,31.2792 -US-LL1,83560,GRP_LOCATION,LOCATION_LONG,-84.5329 -US-LL1,83560,GRP_LOCATION,LOCATION_ELEV,165 -US-LL1,83560,GRP_LOCATION,LOCATION_DATE_START,200101010700 -US-LL1,83555,GRP_NETWORK,NETWORK,AmeriFlux -US-LL1,83557,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"Carbon, energy and hydrological research" -US-LL1,83571,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"Scott Taylor, Forest Ecology, J.W. Jones Ecological Research Center, 3988 Jones Center Dr, Newton GA 39870" -US-LL1,83566,GRP_SITE_CHAR,TERRAIN,Flat -US-LL1,83566,GRP_SITE_CHAR,ASPECT,FLAT -US-LL1,83566,GRP_SITE_CHAR,WIND_DIRECTION,W -US-LL1,83566,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,600 -US-LL1,83566,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,0 -US-LL1,83552,GRP_SITE_DESC,SITE_DESC,Mesic longleaf pine site with wiregrass in the understory and >90 year old Pinus palustris in the mid- and overstory -US-LL1,83568,GRP_SITE_FUNDING,SITE_FUNDING,"Joseph W. Jones Center, The University of Alabama" -US-LL1,83559,GRP_STATE,STATE,GA -US-LL1,83570,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Gregory Starr -US-LL1,83570,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-LL1,83570,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,gstarr@ua.edu -US-LL1,83570,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,The University of Alabama -US-LL1,83564,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Scott Taylor -US-LL1,83564,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Affiliate -US-LL1,83564,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,staylor@jonesctr.org -US-LL1,83564,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Joseph W. Jones Center -US-LL1,83551,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-LL1,83563,GRP_TOWER_TYPE,TOWER_TYPE,triangle -US-LL1,83569,GRP_URL,URL,http://starrlab.ua.edu -US-LL1,24000985,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-LL1 -US-LL1,83556,GRP_UTC_OFFSET,UTC_OFFSET,-5 -US-LL2,83587,GRP_CLIM_AVG,MAT,20 -US-LL2,83587,GRP_CLIM_AVG,MAP,1310 -US-LL2,83587,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Cfa -US-LL2,27000986,GRP_COUNTRY,COUNTRY,USA -US-LL2,86715,GRP_DM_EXT_WEATHER,DM_EXT_WEATHER,Drought -US-LL2,86715,GRP_DM_EXT_WEATHER,DM_SURF,100 -US-LL2,86715,GRP_DM_EXT_WEATHER,DM_SURF_MEAS_UNC,100 -US-LL2,86715,GRP_DM_EXT_WEATHER,DM_DATE_START,201005010800 -US-LL2,86715,GRP_DM_EXT_WEATHER,DM_DATE_END,201209010000 -US-LL2,86715,GRP_DM_EXT_WEATHER,DM_DATE_UNC,20 -US-LL2,86712,GRP_DM_FIRE,DM_FIRE,Prescribed human induced underburn -US-LL2,86712,GRP_DM_FIRE,DM_SURF,100 -US-LL2,86712,GRP_DM_FIRE,DM_SURF_MEAS_UNC,100 -US-LL2,86712,GRP_DM_FIRE,DM_DATE_START,200901210800 -US-LL2,86712,GRP_DM_FIRE,DM_DATE_END,200901240000 -US-LL2,86712,GRP_DM_FIRE,DM_DATE_UNC,3 -US-LL2,86712,GRP_DM_FIRE,DM_COMMENT,fire return interval 2 yrs -US-LL2,86713,GRP_DM_FIRE,DM_FIRE,Prescribed human induced underburn -US-LL2,86713,GRP_DM_FIRE,DM_SURF,100 -US-LL2,86713,GRP_DM_FIRE,DM_SURF_MEAS_UNC,100 -US-LL2,86713,GRP_DM_FIRE,DM_DATE_START,201103160800 -US-LL2,86713,GRP_DM_FIRE,DM_DATE_END,201103170000 -US-LL2,86713,GRP_DM_FIRE,DM_DATE_UNC,3 -US-LL2,86714,GRP_DM_FIRE,DM_FIRE,Prescribed human induced underburn -US-LL2,86714,GRP_DM_FIRE,DM_SURF,100 -US-LL2,86714,GRP_DM_FIRE,DM_SURF_MEAS_UNC,100 -US-LL2,86714,GRP_DM_FIRE,DM_DATE_START,201302180800 -US-LL2,86714,GRP_DM_FIRE,DM_DATE_END,201302190000 -US-LL2,86714,GRP_DM_FIRE,DM_DATE_UNC,3 -US-LL2,86716,GRP_DM_FIRE,DM_FIRE,Prescribed human induced underburn -US-LL2,86716,GRP_DM_FIRE,DM_SURF,100 -US-LL2,86716,GRP_DM_FIRE,DM_SURF_MEAS_UNC,100 -US-LL2,86716,GRP_DM_FIRE,DM_DATE_START,201504210800 -US-LL2,86716,GRP_DM_FIRE,DM_DATE_END,201504220000 -US-LL2,86716,GRP_DM_FIRE,DM_DATE_UNC,3 -US-LL2,86710,GRP_DM_FIRE,DM_FIRE,Prescribed human induced underburn -US-LL2,86710,GRP_DM_FIRE,DM_SURF,100 -US-LL2,86710,GRP_DM_FIRE,DM_SURF_MEAS_UNC,100 -US-LL2,86710,GRP_DM_FIRE,DM_DATE_START,201703220800 -US-LL2,86710,GRP_DM_FIRE,DM_DATE_END,201703230000 -US-LL2,86710,GRP_DM_FIRE,DM_DATE_UNC,3 -US-LL2,86711,GRP_DM_FORESTRY,DM_FORESTRY,Thinning/pruning -US-LL2,86711,GRP_DM_FORESTRY,DM_SURF,10 -US-LL2,86711,GRP_DM_FORESTRY,DM_SURF_MEAS_UNC,10 -US-LL2,86711,GRP_DM_FORESTRY,DM_DATE_START,201211160800 -US-LL2,86711,GRP_DM_FORESTRY,DM_DATE_END,201211281800 -US-LL2,95623,GRP_DOI,DOI,10.17190/AMF/1773396 -US-LL2,95623,GRP_DOI,DOI_CITATION,"Gregory Starr (2021), AmeriFlux BASE US-LL2 Longleaf Pine - Dubignion (Intermediate site), Ver. 1-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1773396" -US-LL2,95623,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-LL2,95581,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-LL2,95581,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Gregory Starr -US-LL2,95581,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-LL2,95581,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,gstarr@ua.edu -US-LL2,95581,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,The University of Alabama -US-LL2,95611,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,The University of Alabama -US-LL2,95611,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-LL2,95604,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,"Joseph W. Jones Center, The University of Alabama" -US-LL2,95604,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-LL2,83576,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Drought -US-LL2,83577,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Fire -US-LL2,83590,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Forestry -US-LL2,83589,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-LL2,83589,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-LL2,83589,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,200810221000 -US-LL2,83589,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,201607052330 -US-LL2,83589,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-LL2,83585,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-LL2,83585,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-LL2,83585,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,200810221000 -US-LL2,83585,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,201607052330 -US-LL2,83585,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-LL2,23000986,GRP_HEADER,SITE_NAME,Longleaf Pine - Dubignion (Intermediate site) -US-LL2,83591,GRP_IGBP,IGBP,SAV -US-LL2,83591,GRP_IGBP,IGBP_DATE_START,19230101 -US-LL2,83591,GRP_IGBP,IGBP_COMMENT,C4 grass in the understory -US-LL2,83583,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -US-LL2,83583,GRP_LAND_OWNERSHIP,LAND_OWNER,Robert W. Woodruff Foundation -US-LL2,83574,GRP_LOCATION,LOCATION_LAT,31.2010 -US-LL2,83574,GRP_LOCATION,LOCATION_LONG,-84.4449 -US-LL2,83574,GRP_LOCATION,LOCATION_ELEV,155 -US-LL2,83574,GRP_LOCATION,LOCATION_DATE_START,20080101 -US-LL2,83582,GRP_NETWORK,NETWORK,AmeriFlux -US-LL2,83579,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"Carbon, energy and hydrological research" -US-LL2,83592,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"Scott Taylor, Forest Ecology, J.W. Jones Ecological Research Center, 3988 Jones Center Dr, Newton GA 39870" -US-LL2,83581,GRP_SITE_CHAR,TERRAIN,Flat -US-LL2,83581,GRP_SITE_CHAR,ASPECT,FLAT -US-LL2,83581,GRP_SITE_CHAR,WIND_DIRECTION,W -US-LL2,83581,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,600 -US-LL2,83581,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,0 -US-LL2,83594,GRP_SITE_DESC,SITE_DESC,Intermediate longeaf pine site with wiregrass in the understory and >90 year old Pinus palustris and Quercus spp. in the mid- and overstory and Quercus spp. -US-LL2,83586,GRP_SITE_FUNDING,SITE_FUNDING,"Joseph W. Jones Center, The University of Alabama" -US-LL2,83584,GRP_STATE,STATE,GA -US-LL2,83575,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Gregory Starr -US-LL2,83575,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-LL2,83575,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,gstarr@ua.edu -US-LL2,83575,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,The University of Alabama -US-LL2,83580,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Scott Taylor -US-LL2,83580,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Affiliate -US-LL2,83580,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,staylor@jonesctr.org -US-LL2,83580,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Joseph W. Jones Center -US-LL2,83588,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-LL2,83578,GRP_TOWER_TYPE,TOWER_TYPE,triangle -US-LL2,83593,GRP_URL,URL,http://starrlab.ua.edu -US-LL2,24000986,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-LL2 -US-LL2,83573,GRP_UTC_OFFSET,UTC_OFFSET,-5 -US-LL3,83597,GRP_CLIM_AVG,MAT,20 -US-LL3,83597,GRP_CLIM_AVG,MAP,1310 -US-LL3,83597,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Cfa -US-LL3,27000987,GRP_COUNTRY,COUNTRY,USA -US-LL3,86698,GRP_DM_EXT_WEATHER,DM_EXT_WEATHER,Drought -US-LL3,86698,GRP_DM_EXT_WEATHER,DM_DATE_START,201005010800 -US-LL3,86698,GRP_DM_EXT_WEATHER,DM_DATE_END,201209010000 -US-LL3,86698,GRP_DM_EXT_WEATHER,DM_DATE_UNC,20 -US-LL3,86699,GRP_DM_FIRE,DM_FIRE,Prescribed human induced underburn -US-LL3,86699,GRP_DM_FIRE,DM_SURF,100 -US-LL3,86699,GRP_DM_FIRE,DM_SURF_MEAS_UNC,100 -US-LL3,86699,GRP_DM_FIRE,DM_DATE_START,200901120800 -US-LL3,86699,GRP_DM_FIRE,DM_DATE_END,200901130000 -US-LL3,86699,GRP_DM_FIRE,DM_DATE_UNC,2 -US-LL3,86699,GRP_DM_FIRE,DM_COMMENT,fire return interval 2 yrs -US-LL3,86697,GRP_DM_FIRE,DM_FIRE,Prescribed human induced underburn -US-LL3,86697,GRP_DM_FIRE,DM_DATE_START,201103080800 -US-LL3,86697,GRP_DM_FIRE,DM_DATE_END,201103090000 -US-LL3,86697,GRP_DM_FIRE,DM_DATE_UNC,3 -US-LL3,86701,GRP_DM_FIRE,DM_FIRE,Prescribed human induced underburn -US-LL3,86701,GRP_DM_FIRE,DM_DATE_START,201302150800 -US-LL3,86701,GRP_DM_FIRE,DM_DATE_END,201302160000 -US-LL3,86701,GRP_DM_FIRE,DM_DATE_UNC,3 -US-LL3,86703,GRP_DM_FIRE,DM_FIRE,Prescribed human induced underburn -US-LL3,86703,GRP_DM_FIRE,DM_DATE_START,201504210800 -US-LL3,86703,GRP_DM_FIRE,DM_DATE_END,201504220000 -US-LL3,86703,GRP_DM_FIRE,DM_DATE_UNC,3 -US-LL3,86702,GRP_DM_FIRE,DM_FIRE,Prescribed human induced underburn -US-LL3,86702,GRP_DM_FIRE,DM_DATE_START,201704250800 -US-LL3,86702,GRP_DM_FIRE,DM_DATE_END,201704260000 -US-LL3,86702,GRP_DM_FIRE,DM_DATE_UNC,3 -US-LL3,86700,GRP_DM_FORESTRY,DM_FORESTRY,Thinning/pruning -US-LL3,86700,GRP_DM_FORESTRY,DM_DATE_START,201501091000 -US-LL3,86700,GRP_DM_FORESTRY,DM_DATE_END,201501091200 -US-LL3,86700,GRP_DM_FORESTRY,DM_DATE_UNC,1 -US-LL3,95621,GRP_DOI,DOI,10.17190/AMF/1773397 -US-LL3,95621,GRP_DOI,DOI_CITATION,"Gregory Starr (2021), AmeriFlux BASE US-LL3 Longleaf Pine - Red Dirt (Xeric site), Ver. 1-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1773397" -US-LL3,95621,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-LL3,95582,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-LL3,95582,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Gregory Starr -US-LL3,95582,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-LL3,95582,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,gstarr@ua.edu -US-LL3,95582,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,The University of Alabama -US-LL3,95612,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,The University of Alabama -US-LL3,95612,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-LL3,95605,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,"Joseph W. Jones Center, The University of Alabama" -US-LL3,95605,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-LL3,83608,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Drought -US-LL3,83595,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Fire -US-LL3,83613,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Forestry -US-LL3,83606,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-LL3,83606,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-LL3,83606,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,200810221000 -US-LL3,83606,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,201607052330 -US-LL3,83606,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-LL3,83603,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-LL3,83603,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-LL3,83603,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,200810221000 -US-LL3,83603,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,201607052330 -US-LL3,83603,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-LL3,23000987,GRP_HEADER,SITE_NAME,Longleaf Pine - Red Dirt (Xeric site) -US-LL3,83602,GRP_IGBP,IGBP,SAV -US-LL3,83602,GRP_IGBP,IGBP_DATE_START,19230101 -US-LL3,83602,GRP_IGBP,IGBP_COMMENT,C4 grass in the understory -US-LL3,83601,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -US-LL3,83601,GRP_LAND_OWNERSHIP,LAND_OWNER,Robert W. Woodruff Foundation -US-LL3,83607,GRP_LOCATION,LOCATION_LAT,31.2688 -US-LL3,83607,GRP_LOCATION,LOCATION_LONG,-84.4787 -US-LL3,83607,GRP_LOCATION,LOCATION_ELEV,159.5 -US-LL3,83607,GRP_LOCATION,LOCATION_DATE_START,200101010700 -US-LL3,83598,GRP_NETWORK,NETWORK,AmeriFlux -US-LL3,83599,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"Carbon, energy and hydrological research" -US-LL3,83610,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"Scott Taylor, Forest Ecology, J.W. Jones Ecological Research Center, 3988 Jones Center Dr, Newton GA 39870" -US-LL3,83616,GRP_SITE_CHAR,TERRAIN,Flat -US-LL3,83616,GRP_SITE_CHAR,ASPECT,FLAT -US-LL3,83616,GRP_SITE_CHAR,WIND_DIRECTION,W -US-LL3,83616,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,600 -US-LL3,83616,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,0 -US-LL3,83612,GRP_SITE_DESC,SITE_DESC,Xeric longeaf pine site with wiregrass in the understory and >90 year old Pinus palustris and Quercus spp. in the mid- and overstory -US-LL3,83614,GRP_SITE_FUNDING,SITE_FUNDING,"Joseph W. Jones Center, The University of Alabama" -US-LL3,83600,GRP_STATE,STATE,GA -US-LL3,83609,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Gregory Starr -US-LL3,83609,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-LL3,83609,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,gstarr@ua.edu -US-LL3,83609,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,The University of Alabama -US-LL3,83611,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Scott Taylor -US-LL3,83611,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Affiliate -US-LL3,83611,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,staylor@jonesctr.org -US-LL3,83611,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Joseph W. Jones Center -US-LL3,83615,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-LL3,83604,GRP_TOWER_TYPE,TOWER_TYPE,triangle -US-LL3,83596,GRP_URL,URL,http://starrlab.ua.edu -US-LL3,24000987,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-LL3 -US-LL3,83605,GRP_UTC_OFFSET,UTC_OFFSET,-5 -US-Los,27013,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER,79 -US-Los,27013,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_ORGAN,Total -US-Los,27013,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_PHEN,Mixed/unknown -US-Los,27013,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_UNIT,gC m-2 -US-Los,27013,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_DATE,2001 -US-Los,27013,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_COMMENT,"Total biomass: Tang, peronal communication. Biomass of non-woody plants refers to 'sedge'" -US-Los,28193,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB,108 -US-Los,28193,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_ORGAN,Foliage -US-Los,28193,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_PHEN,Mixed/unknown -US-Los,28193,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_UNIT,gC m-2 -US-Los,28193,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_DATE,2001 -US-Los,28193,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_COMMENT,"Total biomass: Tang, peronal communication. Biomass of non-woody plants refers to 'sedge'" -US-Los,28291,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB,164 -US-Los,28291,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_ORGAN,Foliage -US-Los,28291,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_PHEN,Mixed/unknown -US-Los,28291,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_UNIT,gC m-2 -US-Los,28291,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_DATE,2005 -US-Los,28291,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_COMMENT,"Cook et al., (2008)" -US-Los,27930,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB,307 -US-Los,27930,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_ORGAN,Wood -US-Los,27930,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_PHEN,Mixed/unknown -US-Los,27930,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_UNIT,gC m-2 -US-Los,27930,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_DATE,2001 -US-Los,27930,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_COMMENT,"Total biomass: Tang, peronal communication. Biomass of non-woody plants refers to 'sedge'" -US-Los,27569,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB,504 -US-Los,27569,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_ORGAN,Wood -US-Los,27569,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_PHEN,Mixed/unknown -US-Los,27569,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_UNIT,gC m-2 -US-Los,27569,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_DATE,2005 -US-Los,27569,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_COMMENT,"Cook et al., (2008)" -US-Los,27931,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,1000 -US-Los,27931,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Total -US-Los,27931,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-Los,27931,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-Los,27931,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2005 -US-Los,27931,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,"Cook et al., (2008)" -US-Los,27568,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,668 -US-Los,27568,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Total -US-Los,27568,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-Los,27568,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-Los,27568,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2001 -US-Los,27568,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,"Total biomass: Tang, peronal communication. Biomass of non-woody plants refers to 'sedge'" -US-Los,28531,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,78 -US-Los,28531,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Foliage -US-Los,28531,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-Los,28531,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-Los,28531,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2001 -US-Los,28531,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,"Total biomass: Tang, peronal communication. Biomass of non-woody plants refers to 'sedge'" -US-Los,29479,GRP_AG_LIT_CHEM,AG_LIT_C,5.02 -US-Los,29479,GRP_AG_LIT_CHEM,AG_LIT_N,0.267 -US-Los,29479,GRP_AG_LIT_CHEM,AG_LIT_DATE,2006 -US-Los,29479,GRP_AG_LIT_CHEM,AG_LIT_COMMENT,Peter Weishampel -US-Los,28194,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT,19.6 -US-Los,28194,GRP_AG_LIT_PROD,AG_LIT_PROD_UNIT,gC m-2 -US-Los,28194,GRP_AG_LIT_PROD,AG_LIT_PROD_COMMENT,Peter Weishampel -US-Los,27014,GRP_AG_PROD_TREE,AG_PROD_TREE,446 -US-Los,27014,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Total -US-Los,27014,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-Los,27014,GRP_AG_PROD_TREE,AG_PROD_COMMENT,"Tang, personal communication" -US-Los,15278,GRP_CLIM_AVG,MAT,4.08 -US-Los,15278,GRP_CLIM_AVG,MAP,828 -US-Los,15278,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfb -US-Los,27000388,GRP_COUNTRY,COUNTRY,USA -US-Los,1130,GRP_DM_GENERAL,DM_GENERAL,Other -US-Los,1130,GRP_DM_GENERAL,DM_COMMENT,No known disturbances. 1963 land cover map shows shrub wetland cover (consistent with present cover). Shrubs are not that old (max age perhaps 20 years?). Road building and ongoing water table manipulation are probably the most significant disturbances. Data and dates are not available. -US-Los,15763,GRP_DOI,DOI,10.17190/AMF/1246071 -US-Los,15763,GRP_DOI,DOI_CITATION,"Ankur Desai (2022), AmeriFlux BASE US-Los Lost Creek, Ver. 21-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1246071" -US-Los,15763,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-Los,32102,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Los,32102,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Ankur Desai -US-Los,32102,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Los,32102,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,desai@aos.wisc.edu -US-Los,32102,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of Wisconsin -US-Los,32104,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,University of Wisconsin -US-Los,32104,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-Los,32103,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,DOE Ameriflux Network Management Project -US-Los,32103,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-Los,22190,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Hydrologic event -US-Los,15279,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Los,15279,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-Los,15279,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,2001 -US-Los,15279,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Los,15279,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,"Growing season only from 2007-2008, 2010 no measurement in 2009, 2011-2013" -US-Los,15297,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Los,15297,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-Los,15297,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,2001 -US-Los,15297,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Los,15299,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Los,15299,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-Los,15299,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,2001 -US-Los,15299,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Los,15294,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Los,15294,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CH4 -US-Los,15294,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,2014 -US-Los,15294,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Los,23000388,GRP_HEADER,SITE_NAME,Lost Creek -US-Los,88194,GRP_HEIGHTC,HEIGHTC,2 -US-Los,88194,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Los,88194,GRP_HEIGHTC,HEIGHTC_DATE,20050404 -US-Los,88194,GRP_HEIGHTC,HEIGHTC_COMMENT,From Ameriflux Site Info Page -US-Los,15280,GRP_IGBP,IGBP,WET -US-Los,15280,GRP_IGBP,IGBP_COMMENT,"Alder (Alnus incana), willows (Salix spp.)" -US-Los,27929,GRP_LAI,LAI_TYPE,LAI -US-Los,27929,GRP_LAI,LAI_COMMENT,"Jianwu Tang, personal communication, Willow=1.48, Alder=2.76 measured by harvesting" -US-Los,27929,GRP_LAI,LAI_TOT,4.24 -US-Los,15281,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-Los,15281,GRP_LAND_OWNERSHIP,LAND_OWNER,State of Wisconsin Department of Conservation and Natural Resources -US-Los,25052,GRP_LMA,LMA,156 -US-Los,25052,GRP_LMA,LMA_SPP,(All) -US-Los,15282,GRP_LOCATION,LOCATION_LAT,46.0827 -US-Los,15282,GRP_LOCATION,LOCATION_LONG,-89.9792 -US-Los,15282,GRP_LOCATION,LOCATION_ELEV,480.00 -US-Los,24536,GRP_NEP,NEP,446 -US-Los,15283,GRP_NETWORK,NETWORK,AmeriFlux -US-Los,86979,GRP_NETWORK,NETWORK,Phenocam -US-Los,26863,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,BudBreak -US-Los,26863,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,(All) -US-Los,26863,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,19990425 -US-Los,26863,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,"Data are from Willow Creek, an upland site that is close by. Differences between Willow Creek (upland) and Lost Creek (wetland) may exist due to species differences, but interannual variations due to climate should be captured in these data. Data from the WLEF site are also relevant. WLEF wetland phenological data should be very close to Lost Creek phenology. www.cheas.psu.edu/data/cheas/phenology" -US-Los,27308,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,BudBreak -US-Los,27308,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,(All) -US-Los,27308,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20040510 -US-Los,27308,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,"Data are from Willow Creek, an upland site that is close by. Differences between Willow Creek (upland) and Lost Creek (wetland) may exist due to species differences, but interannual variations due to climate should be captured in these data. Data from the WLEF site are also relevant. WLEF wetland phenological data should be very close to Lost Creek phenology. www.cheas.psu.edu/data/cheas/phenology" -US-Los,27570,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,BudBreak -US-Los,27570,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,(All) -US-Los,27570,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20010429 -US-Los,27570,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,"Data are from Willow Creek, an upland site that is close by. Differences between Willow Creek (upland) and Lost Creek (wetland) may exist due to species differences, but interannual variations due to climate should be captured in these data. Data from the WLEF site are also relevant. WLEF wetland phenological data should be very close to Lost Creek phenology. www.cheas.psu.edu/data/cheas/phenology" -US-Los,28293,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,BudBreak -US-Los,28293,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,(All) -US-Los,28293,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20000429 -US-Los,28293,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,"Data are from Willow Creek, an upland site that is close by. Differences between Willow Creek (upland) and Lost Creek (wetland) may exist due to species differences, but interannual variations due to climate should be captured in these data. Data from the WLEF site are also relevant. WLEF wetland phenological data should be very close to Lost Creek phenology. www.cheas.psu.edu/data/cheas/phenology" -US-Los,29020,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,BudBreak -US-Los,29020,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,(All) -US-Los,29020,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20020417 -US-Los,29020,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,"Data are from Willow Creek, an upland site that is close by. Differences between Willow Creek (upland) and Lost Creek (wetland) may exist due to species differences, but interannual variations due to climate should be captured in these data. Data from the WLEF site are also relevant. WLEF wetland phenological data should be very close to Lost Creek phenology. www.cheas.psu.edu/data/cheas/phenology" -US-Los,29021,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,BudBreak -US-Los,29021,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,(All) -US-Los,29021,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20050510 -US-Los,29021,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,"Data are from Willow Creek, an upland site that is close by. Differences between Willow Creek (upland) and Lost Creek (wetland) may exist due to species differences, but interannual variations due to climate should be captured in these data. Data from the WLEF site are also relevant. WLEF wetland phenological data should be very close to Lost Creek phenology. www.cheas.psu.edu/data/cheas/phenology" -US-Los,29133,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,BudBreak -US-Los,29133,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,(All) -US-Los,29133,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20030511 -US-Los,29133,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,"Data are from Willow Creek, an upland site that is close by. Differences between Willow Creek (upland) and Lost Creek (wetland) may exist due to species differences, but interannual variations due to climate should be captured in these data. Data from the WLEF site are also relevant. WLEF wetland phenological data should be very close to Lost Creek phenology. www.cheas.psu.edu/data/cheas/phenology" -US-Los,29134,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,BudBreak -US-Los,29134,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,(All) -US-Los,29134,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20060426 -US-Los,29134,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,"Data are from Willow Creek, an upland site that is close by. Differences between Willow Creek (upland) and Lost Creek (wetland) may exist due to species differences, but interannual variations due to climate should be captured in these data. Data from the WLEF site are also relevant. WLEF wetland phenological data should be very close to Lost Creek phenology. www.cheas.psu.edu/data/cheas/phenology" -US-Los,26724,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,Leaf senescence -US-Los,26724,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,(All) -US-Los,26724,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20010527 -US-Los,26724,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,"Data are from Willow Creek, an upland site that is close by. Differences between Willow Creek (upland) and Lost Creek (wetland) may exist due to species differences, but interannual variations due to climate should be captured in these data. Data from the WLEF site are also relevant. WLEF wetland phenological data should be very close to Lost Creek phenology. www.cheas.psu.edu/data/cheas/phenology" -US-Los,26725,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,Leaf senescence -US-Los,26725,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,(All) -US-Los,26725,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20020425 -US-Los,26725,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,"Data are from Willow Creek, an upland site that is close by. Differences between Willow Creek (upland) and Lost Creek (wetland) may exist due to species differences, but interannual variations due to climate should be captured in these data. Data from the WLEF site are also relevant. WLEF wetland phenological data should be very close to Lost Creek phenology. www.cheas.psu.edu/data/cheas/phenology" -US-Los,27571,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,Leaf senescence -US-Los,27571,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,(All) -US-Los,27571,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20000528 -US-Los,27571,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,"Data are from Willow Creek, an upland site that is close by. Differences between Willow Creek (upland) and Lost Creek (wetland) may exist due to species differences, but interannual variations due to climate should be captured in these data. Data from the WLEF site are also relevant. WLEF wetland phenological data should be very close to Lost Creek phenology. www.cheas.psu.edu/data/cheas/phenology" -US-Los,27934,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,Leaf senescence -US-Los,27934,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,(All) -US-Los,27934,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20040611 -US-Los,27934,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,"Data are from Willow Creek, an upland site that is close by. Differences between Willow Creek (upland) and Lost Creek (wetland) may exist due to species differences, but interannual variations due to climate should be captured in these data. Data from the WLEF site are also relevant. WLEF wetland phenological data should be very close to Lost Creek phenology. www.cheas.psu.edu/data/cheas/phenology" -US-Los,27935,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,Leaf senescence -US-Los,27935,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,(All) -US-Los,27935,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20050607 -US-Los,27935,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,"Data are from Willow Creek, an upland site that is close by. Differences between Willow Creek (upland) and Lost Creek (wetland) may exist due to species differences, but interannual variations due to climate should be captured in these data. Data from the WLEF site are also relevant. WLEF wetland phenological data should be very close to Lost Creek phenology. www.cheas.psu.edu/data/cheas/phenology" -US-Los,28197,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,Leaf senescence -US-Los,28197,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,(All) -US-Los,28197,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20060601 -US-Los,28197,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,"Data are from Willow Creek, an upland site that is close by. Differences between Willow Creek (upland) and Lost Creek (wetland) may exist due to species differences, but interannual variations due to climate should be captured in these data. Data from the WLEF site are also relevant. WLEF wetland phenological data should be very close to Lost Creek phenology. www.cheas.psu.edu/data/cheas/phenology" -US-Los,28294,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,Leaf senescence -US-Los,28294,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,(All) -US-Los,28294,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,19990527 -US-Los,28294,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,"Data are from Willow Creek, an upland site that is close by. Differences between Willow Creek (upland) and Lost Creek (wetland) may exist due to species differences, but interannual variations due to climate should be captured in these data. Data from the WLEF site are also relevant. WLEF wetland phenological data should be very close to Lost Creek phenology. www.cheas.psu.edu/data/cheas/phenology" -US-Los,29022,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,Leaf senescence -US-Los,29022,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,(All) -US-Los,29022,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20030608 -US-Los,29022,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,"Data are from Willow Creek, an upland site that is close by. Differences between Willow Creek (upland) and Lost Creek (wetland) may exist due to species differences, but interannual variations due to climate should be captured in these data. Data from the WLEF site are also relevant. WLEF wetland phenological data should be very close to Lost Creek phenology. www.cheas.psu.edu/data/cheas/phenology" -US-Los,26864,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,Maximum leaf expansion -US-Los,26864,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,(All) -US-Los,26864,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20021023 -US-Los,26864,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,"Data are from Willow Creek, an upland site that is close by. Differences between Willow Creek (upland) and Lost Creek (wetland) may exist due to species differences, but interannual variations due to climate should be captured in these data. Data from the WLEF site are also relevant. WLEF wetland phenological data should be very close to Lost Creek phenology. www.cheas.psu.edu/data/cheas/phenology" -US-Los,26865,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,Maximum leaf expansion -US-Los,26865,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,(All) -US-Los,26865,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20041027 -US-Los,26865,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,"Data are from Willow Creek, an upland site that is close by. Differences between Willow Creek (upland) and Lost Creek (wetland) may exist due to species differences, but interannual variations due to climate should be captured in these data. Data from the WLEF site are also relevant. WLEF wetland phenological data should be very close to Lost Creek phenology. www.cheas.psu.edu/data/cheas/phenology" -US-Los,26866,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,Maximum leaf expansion -US-Los,26866,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,(All) -US-Los,26866,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20051028 -US-Los,26866,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,"Data are from Willow Creek, an upland site that is close by. Differences between Willow Creek (upland) and Lost Creek (wetland) may exist due to species differences, but interannual variations due to climate should be captured in these data. Data from the WLEF site are also relevant. WLEF wetland phenological data should be very close to Lost Creek phenology. www.cheas.psu.edu/data/cheas/phenology" -US-Los,27312,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,Maximum leaf expansion -US-Los,27312,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,(All) -US-Los,27312,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,19991020 -US-Los,27312,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,"Data are from Willow Creek, an upland site that is close by. Differences between Willow Creek (upland) and Lost Creek (wetland) may exist due to species differences, but interannual variations due to climate should be captured in these data. Data from the WLEF site are also relevant. WLEF wetland phenological data should be very close to Lost Creek phenology. www.cheas.psu.edu/data/cheas/phenology" -US-Los,28200,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,Maximum leaf expansion -US-Los,28200,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,(All) -US-Los,28200,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20001021 -US-Los,28200,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,"Data are from Willow Creek, an upland site that is close by. Differences between Willow Creek (upland) and Lost Creek (wetland) may exist due to species differences, but interannual variations due to climate should be captured in these data. Data from the WLEF site are also relevant. WLEF wetland phenological data should be very close to Lost Creek phenology. www.cheas.psu.edu/data/cheas/phenology" -US-Los,28295,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,Maximum leaf expansion -US-Los,28295,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,(All) -US-Los,28295,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20061015 -US-Los,28295,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,"Data are from Willow Creek, an upland site that is close by. Differences between Willow Creek (upland) and Lost Creek (wetland) may exist due to species differences, but interannual variations due to climate should be captured in these data. Data from the WLEF site are also relevant. WLEF wetland phenological data should be very close to Lost Creek phenology. www.cheas.psu.edu/data/cheas/phenology" -US-Los,28536,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,Maximum leaf expansion -US-Los,28536,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,(All) -US-Los,28536,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20011018 -US-Los,28536,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,"Data are from Willow Creek, an upland site that is close by. Differences between Willow Creek (upland) and Lost Creek (wetland) may exist due to species differences, but interannual variations due to climate should be captured in these data. Data from the WLEF site are also relevant. WLEF wetland phenological data should be very close to Lost Creek phenology. www.cheas.psu.edu/data/cheas/phenology" -US-Los,28537,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,Maximum leaf expansion -US-Los,28537,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,(All) -US-Los,28537,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20031026 -US-Los,28537,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,"Data are from Willow Creek, an upland site that is close by. Differences between Willow Creek (upland) and Lost Creek (wetland) may exist due to species differences, but interannual variations due to climate should be captured in these data. Data from the WLEF site are also relevant. WLEF wetland phenological data should be very close to Lost Creek phenology. www.cheas.psu.edu/data/cheas/phenology" -US-Los,27016,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,Total leaf-off -US-Los,27016,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,(All) -US-Los,27016,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20010926 -US-Los,27016,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,"Data are from Willow Creek, an upland site that is close by. Differences between Willow Creek (upland) and Lost Creek (wetland) may exist due to species differences, but interannual variations due to climate should be captured in these data. Data from the WLEF site are also relevant. WLEF wetland phenological data should be very close to Lost Creek phenology. www.cheas.psu.edu/data/cheas/phenology" -US-Los,27311,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,Total leaf-off -US-Los,27311,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,(All) -US-Los,27311,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,19990925 -US-Los,27311,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,"Data are from Willow Creek, an upland site that is close by. Differences between Willow Creek (upland) and Lost Creek (wetland) may exist due to species differences, but interannual variations due to climate should be captured in these data. Data from the WLEF site are also relevant. WLEF wetland phenological data should be very close to Lost Creek phenology. www.cheas.psu.edu/data/cheas/phenology" -US-Los,28198,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,Total leaf-off -US-Los,28198,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,(All) -US-Los,28198,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20000926 -US-Los,28198,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,"Data are from Willow Creek, an upland site that is close by. Differences between Willow Creek (upland) and Lost Creek (wetland) may exist due to species differences, but interannual variations due to climate should be captured in these data. Data from the WLEF site are also relevant. WLEF wetland phenological data should be very close to Lost Creek phenology. www.cheas.psu.edu/data/cheas/phenology" -US-Los,28199,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,Total leaf-off -US-Los,28199,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,(All) -US-Los,28199,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20060925 -US-Los,28199,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,"Data are from Willow Creek, an upland site that is close by. Differences between Willow Creek (upland) and Lost Creek (wetland) may exist due to species differences, but interannual variations due to climate should be captured in these data. Data from the WLEF site are also relevant. WLEF wetland phenological data should be very close to Lost Creek phenology. www.cheas.psu.edu/data/cheas/phenology" -US-Los,29023,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,Total leaf-off -US-Los,29023,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,(All) -US-Los,29023,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20020930 -US-Los,29023,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,"Data are from Willow Creek, an upland site that is close by. Differences between Willow Creek (upland) and Lost Creek (wetland) may exist due to species differences, but interannual variations due to climate should be captured in these data. Data from the WLEF site are also relevant. WLEF wetland phenological data should be very close to Lost Creek phenology. www.cheas.psu.edu/data/cheas/phenology" -US-Los,29024,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,Total leaf-off -US-Los,29024,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,(All) -US-Los,29024,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20041004 -US-Los,29024,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,"Data are from Willow Creek, an upland site that is close by. Differences between Willow Creek (upland) and Lost Creek (wetland) may exist due to species differences, but interannual variations due to climate should be captured in these data. Data from the WLEF site are also relevant. WLEF wetland phenological data should be very close to Lost Creek phenology. www.cheas.psu.edu/data/cheas/phenology" -US-Los,29136,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,Total leaf-off -US-Los,29136,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,(All) -US-Los,29136,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20050926 -US-Los,29136,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,"Data are from Willow Creek, an upland site that is close by. Differences between Willow Creek (upland) and Lost Creek (wetland) may exist due to species differences, but interannual variations due to climate should be captured in these data. Data from the WLEF site are also relevant. WLEF wetland phenological data should be very close to Lost Creek phenology. www.cheas.psu.edu/data/cheas/phenology" -US-Los,29481,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,Total leaf-off -US-Los,29481,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,(All) -US-Los,29481,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20031004 -US-Los,29481,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,"Data are from Willow Creek, an upland site that is close by. Differences between Willow Creek (upland) and Lost Creek (wetland) may exist due to species differences, but interannual variations due to climate should be captured in these data. Data from the WLEF site are also relevant. WLEF wetland phenological data should be very close to Lost Creek phenology. www.cheas.psu.edu/data/cheas/phenology" -US-Los,1700007407,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Baker, I., Denning, A. S., Hanan, N., Prihodko, L., Uliasz, M., Vidale, P., Davis, K., Bakwin, P. (2003) Simulated And Observed Fluxes Of Sensible And Latent Heat And CO2 At The WLEF-TV Tower Using SiB2.5, Global Change Biology, 9(9), 1262-1277" -US-Los,1700007407,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1046/J.1365-2486.2003.00671.X -US-Los,1700007407,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Los,1700002991,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Bakwin, P. S., Davis, K. J., Yi, C., Wofsy, S. C., Munger, J. W., Haszpra, L., Barcza, Z. (2004) Regional Carbon Dioxide Fluxes From Mixing Ratio Data, Tellus Series B-Chemical and Physical Meteorology, 56(4), 301-311" -US-Los,1700002991,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.3402/TELLUSB.V56I4.16446 -US-Los,1700002991,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Los,1700002295,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Barr, A., Richardson, A., Hollinger, D., Papale, D., Arain, M., Black, T., Bohrer, G., Dragoni, D., Fischer, M., Gu, L., Law, B., Margolis, H., McCaughey, J., Munger, J., Oechel, W., Schaeffer, K. (2013) Use Of Change-Point Detection For Friction–Velocity Threshold Evaluation In Eddy-Covariance Studies, Agricultural And Forest Meteorology, 171-172(1-2), 31-45" -US-Los,1700002295,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2012.11.023 -US-Los,1700002295,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Los,1700002775,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Bechtold, M., De Lannoy, G. J., Koster, R. D., Reichle, R. H., Mahanama, S. P., Bleuten, W., Bourgault, M. A., Brümmer, C., Burdun, I., Desai, A. R., Devito, K., Grünwald, T., Grygoruk, M., Humphreys, E. R., Klatt, J., Kurbatova, J., Lohila, A., Munir, T. M., Nilsson, M. B., Price, J. S., Röhl, M., Schneider, A., Tiemeyer, B. (2019) Peat‐Clsm: A Specific Treatment Of Peatland Hydrology In The Nasa Catchment Land Surface Model, Journal Of Advances In Modeling Earth Systems, 11(7), 2130-2162" -US-Los,1700002775,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018MS001574 -US-Los,1700002775,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Los,1700002946,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(1-2), 108350" -US-Los,1700002946,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -US-Los,1700002946,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Los,1700001287,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Cook, B. D., Davis, K. J., Wang, W., Desai, A., Berger, B. W., Teclaw, R. M., Martin, J. G., Bolstad, P. V., Bakwin, P. S., Yi, C., Heilman, W. (2004) Carbon Exchange And Venting Anomalies In An Upland Deciduous Forest In Northern Wisconsin, USA, Agricultural And Forest Meteorology, 126(3-4), 271-295" -US-Los,1700001287,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2004.06.008 -US-Los,1700001287,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Los,1700004371,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Davis, K. J., Bakwin, P. S., Yi, C., Berger, B. W., Zhao, C., Teclaw, R. M., Isebrands, J. G. (2003) The Annual Cycles Of CO2 And H2O Exchange Over A Northern Mixed Forest As Observed From A Very Tall Tower, Global Change Biology, 9(9), 1278-1293" -US-Los,1700004371,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1046/J.1365-2486.2003.00672.X -US-Los,1700004371,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Los,1700002673,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Desai, A. R., Noormets, A., Bolstad, P. V., Chen, J., Cook, B. D., Davis, K. J., Euskirchen, E. S., Gough, C., Martin, J. G., Ricciuto, D. M., Schmid, H. P., Tang, J., Wang, W. (2008) Influence Of Vegetation And Seasonal Forcing On Carbon Dioxide Fluxes Across The Upper Midwest, Usa: Implications For Regional Scaling, Agricultural And Forest Meteorology, 148(2), 288-308" -US-Los,1700002673,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2007.08.001 -US-Los,1700002673,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Los,1700007254,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Desai, A.R. (2010) Climatic And Phenological Controls On Coherent Regional Interannual Variability Of Carbon Dioxide Flux In A Heterogeneous Landscape, Journal Of Geophysical Research, 115(G00J02), n/a-n/a" -US-Los,1700007254,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2010JG001423 -US-Los,1700007254,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Los,1700006042,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Grant, R.F., Desai, A.R.,  Sulman, B.N. (2012) Modelling Contrasting Responses Of Wetland Productivity To Changes In Water Table Depth, Biogeosciences, 9(11), 4215-4231" -US-Los,1700006042,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.5194/BG-9-4215-2012 -US-Los,1700006042,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Los,1700001353,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Kaakinen, S., Kostiainen, K., Ek, F., Saranpaa, P., Kubiske, M. E., Sober, J., Karnosky, D. F., Vapaavuori, E. (2004) Stem Wood Properties Of Populus Tremuloides, Betula Papyrifera And Acer Saccharum Saplings After 3 Years Of Treatments To Elevated Carbon Dioxide And Ozone, Global Change Biology, 10(9), 1513-1525" -US-Los,1700001353,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/J.1365-2486.2004.00814.X -US-Los,1700001353,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Los,1700003786,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Knox, S. H., Jackson, R. B., Poulter, B., McNicol, G., Fluet-Chouinard, E., Zhang, Z., Hugelius, G., Bousquet, P., Canadell, J. G., Saunois, M., Papale, D., Chu, H., Keenan, T. F., Baldocchi, D., Torn, M. S., Mammarella, I., Trotta, C., Aurela, M., Bohrer, G., Campbell, D. I., Cescatti, A., Chamberlain, S., Chen, J., Chen, W., Dengel, S., Desai, A. R., Euskirchen, E., Friborg, T., Gasbarra, D., Goded, I., Goeckede, M., Heimann, M., Helbig, M., Hirano, T., Hollinger, D. Y., Iwata, H., Kang, M., Klatt, J., Krauss, K. W., Kutzbach, L., Lohila, A., Mitra, B., Morin, T. H., Nilsson, M. B., Niu, S., Noormets, A., Oechel, W. C., Peichl, M., Peltola, O., Reba, M. L., Richardson, A. D., Runkle, B. R., Ryu, Y., Sachs, T., Schäfer, K. V., Schmid, H. P., Shurpali, N., Sonnentag, O., Tang, A. C., Ueyama, M., Vargas, R., Vesala, T., Ward, E. J., Windham-Myers, L., Wohlfahrt, G., Zona, D. (2019) Fluxnet-Ch4 Synthesis Activity: Objectives, Observations, And Future Directions, Bulletin Of The American Meteorological Society, 7(8), 1619-1633" -US-Los,1700003786,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1175/BAMS-D-18-0268.1 -US-Los,1700003786,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Los,1700006603,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Pugh, C. A., Reed, D. E., Desai, A. R., Sulman, B. N. (2018) Wetland Flux Controls: How Does Interacting Water Table Levels And Temperature Influence Carbon Dioxide And Methane Fluxes In Northern Wisconsin?, Biogeochemistry, 137(1-2), 15-25" -US-Los,1700006603,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1007/S10533-017-0414-X -US-Los,1700006603,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Los,1700000924,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Qiu, C., Zhu, D., Ciais, P., Guenet, B., Krinner, G., Peng, S., Aurela, M., Bernhofer, C., Brümmer, C., Bret-Harte, S., Chu, H., Chen, J., Desai, A. R., Dušek, J., Euskirchen, E. S., Fortuniak, K., Flanagan, L. B., Friborg, T., Grygoruk, M., Gogo, S., Grünwald, T., Hansen, B. U., Holl, D., Humphreys, E., Hurkuck, M., Kiely, G., Klatt, J., Kutzbach, L., Largeron, C., Laggoun-Défarge, F., Lund, M., Lafleur, P. M., Li, X., Mammarella, I., Merbold, L., Nilsson, M. B., Olejnik, J., Ottosson-Löfvenius, M., Oechel, W., Parmentier, F. W., Peichl, M., Pirk, N., Peltola, O., Pawlak, W., Rasse, D., Rinne, J., Shaver, G., Schmid, H. P., Sottocornola, M., Steinbrecher, R., Sachs, T., Urbaniak, M., Zona, D., Ziemblinska, K. (2018) Orchidee-Peat (Revision 4596), A Model For Northern Peatland Co&Lt;Sub&Gt;2&Lt;/Sub&Gt;, Water, And Energy Fluxes On Daily To Annual Scales, Geoscientific Model Development, 11(2), 497-519" -US-Los,1700000924,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.5194/GMD-11-497-2018 -US-Los,1700000924,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Los,1700001071,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Reed, D. E., Frank, J. M., Ewers, B. E., Desai, A. R. (2018) Time Dependency Of Eddy Covariance Site Energy Balance, Agricultural And Forest Meteorology, 249(1-2), 467-478" -US-Los,1700001071,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2017.08.008 -US-Los,1700001071,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Los,1700008166,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Scott Denning, A., Nicholls, M., Prihodko, L., Baker, I., Vidale, P., Davis, K., Bakwin, P. (2003) Simulated Variations In Atmospheric CO2 Over A Wisconsin Forest Using A Coupled Ecosystem-Atmosphere Model, Global Change Biology, 9(9), 1241-1250" -US-Los,1700008166,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1046/J.1365-2486.2003.00613.X -US-Los,1700008166,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Los,1700000387,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Sullivan, R. C., Cook, D. R., Ghate, V. P., Kotamarthi, V. R., Feng, Y. (2019) Improved Spatiotemporal Representativeness And Bias Reduction Of Satellite-Based Evapotranspiration Retrievals Via Use Of In Situ Meteorology And Constrained Canopy Surface Resistance, Journal Of Geophysical Research: Biogeosciences, 124(2), 342-352" -US-Los,1700000387,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018JG004744 -US-Los,1700000387,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Los,1700003228,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Sullivan, R. C., Kotamarthi, V. R., Feng, Y. (2019) Recovering Evapotranspiration Trends From Biased CMIP5 Simulations And Sensitivity To Changing Climate Over North America, Journal Of Hydrometeorology, 20(8), 1619-1633" -US-Los,1700003228,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1175/JHM-D-18-0259.1 -US-Los,1700003228,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Los,1700008886,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Sulman, B. N., Desai, A. R., Mladenoff, D. J. (2013) Modeling Soil And Biomass Carbon Responses To Declining Water Table In A Wetland-Rich Landscape, Ecosystems, 16(3), 491-507" -US-Los,1700008886,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1007/S10021-012-9624-1 -US-Los,1700008886,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Los,1700004152,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Sulman, B. N., Desai, A. R., Saliendra, N. Z., Lafleur, P. M., Flanagan, L. B., Sonnentag, O., Mackay, D. S., Barr, A. G., van der Kamp, G. (2010) CO2 Fluxes At Northern Fens And Bogs Have Opposite Responses To Inter-Annual Fluctuations In Water Table, Geophysical Research Letters, 37(19), n/a-n/a" -US-Los,1700004152,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2010GL044018 -US-Los,1700004152,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Los,1700003207,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Sulman, B. N., Desai, A. R., Schroeder, N. M., Ricciuto, D., Barr, A., Richardson, A. D., Flanagan, L. B., Lafleur, P. M., Tian, H., Chen, G., Grant, R. F., Poulter, B., Verbeeck, H., Ciais, P., Ringeval, B., Baker, I. T., Schaefer, K., Luo, Y., Weng, E. (2012) Impact of Hydrological Variations on Modeling of Peatland CO2 Fluxes: Results From the North American Carbon Program Site Synthesis, Journal Of Geophysical Research: Biogeosciences, 117(G01031), n/a-n/a" -US-Los,1700003207,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2011JG001862 -US-Los,1700003207,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Los,1700003819,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Sulman, B.N.,  Desai, A.R., Cook, B.D., Saliendra, N., Mackay, D.S. (2009) Contrasting Carbon Dioxide Fluxes Between A Drying Shrub Wetland In Northern Wisconsin, USA, And Nearby Forests, Biogeosciences, 6(6), 1115-1126" -US-Los,1700003819,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.5194/BG-6-1115-2009 -US-Los,1700003819,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Primary_Citation -US-Los,1700002136,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Turner, J., Desai, A. R., Thom, J., Wickland, K. P., Olson, B. (2019) Wind Sheltering Impacts On Land-Atmosphere Fluxes Over Fens, Frontiers In Environmental Science, 7(8), 1619-1633" -US-Los,1700002136,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.3389/FENVS.2019.00179 -US-Los,1700002136,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Los,1700001302,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Werner, C., Davis, K., Bakwin, P., Yi, C., Hurst, D., Lock, L. (2003) Regional-Scale Measurements Of CH4 Exchange From A Tall Tower Over A Mixed Temperate/Boreal Lowland And Wetland Forest, Global Change Biology, 9(9), 1251-1261" -US-Los,1700001302,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1046/J.1365-2486.2003.00670.X -US-Los,1700001302,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Los,1700002820,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Yi, C., Davis, K. J., Bakwin, P. S., Denning, A. S., Zhang, N., Desai, A., Lin, J. C., Gerbig, C. (2004) Observed Covariance Between Ecosystem Carbon Exchange And Atmospheric Boundary Layer Dynamics At A Site In Northern Wisconsin, Journal Of Geophysical Research: Atmospheres, 109(D8), n/a-n/a" -US-Los,1700002820,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2003JD004164 -US-Los,1700002820,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Los,1700003420,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Yi, C., Li, R., Bakwin, P. S., Desai, A., Ricciuto, D. M., Burns, S. P., Turnipseed, A. A., Wofsy, S. C., Munger, J. W., Wilson, K., Monson, R. K. (2004) A Nonparametric Method For Separating Photosynthesis And Respiration Components In CO2 Flux Measurements, Geophysical Research Letters, 31(17), n/a-n/a" -US-Los,1700003420,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2004GL020490 -US-Los,1700003420,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Los,15285,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"The research topics and objectives for the Lost Creek site include the following: 1) Quantify the differential impact of environmental drivers, radiation, and vapor pressure deficit in an shrub wetland; 2) Determine the key driver, radiation or vapor pressure deficit, of flux data for each tower year, and on the basis of this analysis apply the appropriate model to help explain observed intersite, interannual, and interseasonal variation in evapotranspiration; 3) Cross-site examine the variability of net ecosystem exchange of carbon dioxide, ecosystem respiration, gross system production and the attendant parameters; 4) Quantify the role of soil moisture in affecting ecosystem respiration; 5) Identify landscape-level patterns in the temperature and moisture response of ecosystem respiration as determined by shrub wetlands and stages of development. Mackay et al. (2007), Deasi et al. (2008), Noormets et al. (2008)" -US-Los,28530,GRP_SA,SA,45 -US-Los,28530,GRP_SA,SA_COMMENT,personal commun w/ Bruce Cook -US-Los,22191,GRP_SITE_CHAR,TERRAIN,Flat -US-Los,22191,GRP_SITE_CHAR,ASPECT,FLAT -US-Los,22191,GRP_SITE_CHAR,WIND_DIRECTION,W -US-Los,22191,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,500 -US-Los,22191,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,100 -US-Los,15287,GRP_SITE_DESC,SITE_DESC,"Shrub wetland site, chosen to be representative of the wetlands within the WLEF tall tower flux footprint. This is a deciduous shrub wetland. Coniferous and grassy stands also exist within the WLEF flux footprint. Solar power. The site has excellent micrometeorological characteristics." -US-Los,15288,GRP_SITE_FUNDING,SITE_FUNDING,DOE Ameriflux Network Management Project -US-Los,27932,GRP_SOIL_CHEM,SOIL_CHEM_C_ORG,19.04 -US-Los,27307,GRP_SOIL_CHEM,SOIL_CHEM_C_ORG,220 -US-Los,28292,GRP_SOIL_CHEM,SOIL_CHEM_C_ORG,44.96 -US-Los,28195,GRP_SOIL_CHEM,SOIL_CHEM_C_ORG,60 -US-Los,28196,GRP_SOIL_CHEM,SOIL_CHEM_N_TOT,13.1 -US-Los,29019,GRP_SOIL_CHEM,SOIL_CHEM_N_TOT,3.7 -US-Los,27307,GRP_SOIL_CHEM,SOIL_CHEM_BD,0.19 -US-Los,28195,GRP_SOIL_CHEM,SOIL_CHEM_BD,0.64 -US-Los,29132,GRP_SOIL_CHEM,SOIL_CHEM_BD,0.65 -US-Los,27932,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,0 -US-Los,28292,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,0 -US-Los,27932,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,20 -US-Los,28292,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,40 -US-Los,28195,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,"(% not kgC/m2) Mineral Layer, beneath organic layer, Peter Weishampel" -US-Los,27307,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,"(% not kgC/m2) Organic layer, mean depth 22 cm, Peter Weishampel" -US-Los,29019,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,"(% not kgN/m2) Mineral Layer, beneath organic layer, Peter Weishampel" -US-Los,28196,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,"(% not kgN/m2) Organic layer, mean depth 22 cm, Peter Weishampel" -US-Los,29132,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,(0.6-0.7); oven dry soil -US-Los,28292,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,"Soil organic carbon. Tang, personal communication." -US-Los,27932,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,"Soil organic layer. Tang et al., personal communication" -US-Los,29620,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION,"Poorly drained Totagatic-Bowstring-Ausable complex and Seelyeville and Markey mucks formed from outwash sand, and are composed primarily of sapric material about 0.5 m thick" -US-Los,29620,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION_TAXONOMY,Other -US-Los,29480,GRP_SOIL_DEPTH,SOIL_DEPTH,75 -US-Los,29480,GRP_SOIL_DEPTH,SOIL_DEPTH_COMMENT,"Tang, personal communication" -US-Los,27933,GRP_SOIL_TEX,SOIL_TEX_SAND,0 -US-Los,27933,GRP_SOIL_TEX,SOIL_TEX_SILT,0 -US-Los,27933,GRP_SOIL_TEX,SOIL_TEX_CLAY,0 -US-Los,27933,GRP_SOIL_TEX,SOIL_TEX_COMMENT,No mineral soil in top 50 cm. per Bruce Cook -US-Los,26723,GRP_SPP_O,SPP_O,ALINR (NRCS plant code) -US-Los,28532,GRP_SPP_O,SPP_O,ALNUS (NRCS plant code) -US-Los,27310,GRP_SPP_O,SPP_O,BEPU4 (NRCS plant code) -US-Los,29135,GRP_SPP_O,SPP_O,COSE16 (NRCS plant code) -US-Los,28534,GRP_SPP_O,SPP_O,GRAMINOID (NRCS plant code) -US-Los,27309,GRP_SPP_O,SPP_O,SALIX (NRCS plant code) -US-Los,28533,GRP_SPP_O,SPP_O,SALIX (NRCS plant code) -US-Los,29135,GRP_SPP_O,SPP_O_PERC,1 -US-Los,28533,GRP_SPP_O,SPP_O_PERC,13 -US-Los,27310,GRP_SPP_O,SPP_O_PERC,14 -US-Los,27309,GRP_SPP_O,SPP_O_PERC,20 -US-Los,28534,GRP_SPP_O,SPP_O_PERC,3 -US-Los,26723,GRP_SPP_O,SPP_O_PERC,65 -US-Los,28532,GRP_SPP_O,SPP_O_PERC,84 -US-Los,28532,GRP_SPP_O,SPP_DATE,2001 -US-Los,28533,GRP_SPP_O,SPP_DATE,2001 -US-Los,28534,GRP_SPP_O,SPP_DATE,2001 -US-Los,28532,GRP_SPP_O,SPP_COMMENT,Alder ; Jon Martin -US-Los,26723,GRP_SPP_O,SPP_COMMENT,Alnus incana rugosa; Peter Weishampel -US-Los,27310,GRP_SPP_O,SPP_COMMENT,Betual pumila (dwarf birch); Peter Weishampel -US-Los,29135,GRP_SPP_O,SPP_COMMENT,Cornus sericea (red-osier dogwood); Peter Weishampel -US-Los,28534,GRP_SPP_O,SPP_COMMENT,Grass; Jon Martin -US-Los,28533,GRP_SPP_O,SPP_COMMENT,Willow; Jon Martin -US-Los,27309,GRP_SPP_O,SPP_COMMENT,willow; Peter Weishampel -US-Los,28535,GRP_SPP_U,SPP_U,CAREX (NRCS plant code) -US-Los,28535,GRP_SPP_U,SPP_COMMENT,sedge species -US-Los,15289,GRP_STATE,STATE,WI -US-Los,15290,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Ankur Desai -US-Los,15290,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Los,15290,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,desai@aos.wisc.edu -US-Los,15290,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Wisconsin -US-Los,15290,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Department of Atmospheric and Oceanic Sciences, 1225 W Dayton St, Madison, WI 53706" -US-Los,15296,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Jonathan Thom -US-Los,15296,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-Los,15296,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,jthom@ssec.wisc.edu -US-Los,15296,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Wisconsin -US-Los,15296,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Space Sciences and Engineering, 1225 W Dayton St,Madison, WI 53706" -US-Los,29824,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-Los,15291,GRP_TOWER_TYPE,TOWER_TYPE,triangle -US-Los,15292,GRP_URL,URL,http://flux.aos.wisc.edu/twiki/bin/view/Main/ChEASData -US-Los,24000388,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-Los -US-Los,15293,GRP_UTC_OFFSET,UTC_OFFSET,-6 -US-LS1,92901,GRP_CLIM_AVG,MAT,17 -US-LS1,92901,GRP_CLIM_AVG,MAP,288 -US-LS1,92901,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Bwh -US-LS1,27001159,GRP_COUNTRY,COUNTRY,USA -US-LS1,93754,GRP_DOI,DOI,10.17190/AMF/1660346 -US-LS1,93754,GRP_DOI,DOI_CITATION,"Russell Scott (2020), AmeriFlux BASE US-LS1 San Pedro River Lewis Springs Sacaton Grassland, Ver. 1-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1660346" -US-LS1,93754,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-LS1,93712,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-LS1,93712,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Russell Scott -US-LS1,93712,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-LS1,93712,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,russ.scott@ars.usda.gov -US-LS1,93712,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,USDA-ARS -US-LS1,93742,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,USDA-ARS -US-LS1,93742,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-LS1,93718,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,"USDA, NSF" -US-LS1,93718,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-LS1,92894,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Hydrologic event -US-LS1,92898,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-LS1,92898,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-LS1,92898,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,200301010030 -US-LS1,92898,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,200712312330 -US-LS1,92898,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-LS1,92910,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-LS1,92910,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-LS1,92910,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,200301010030 -US-LS1,92910,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,200712312330 -US-LS1,92910,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-LS1,23001159,GRP_HEADER,SITE_NAME,San Pedro River Lewis Springs Sacaton Grassland -US-LS1,92902,GRP_IGBP,IGBP,GRA -US-LS1,92902,GRP_IGBP,IGBP_COMMENT,"Site is a riparian grassland dominated by the perennial bunchgrass, Big Sacaton (Sporobolus Wrightii)." -US-LS1,92906,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-LS1,92906,GRP_LAND_OWNERSHIP,LAND_OWNER,Bureau of Land Management -US-LS1,92903,GRP_LOCATION,LOCATION_LAT,31.5615 -US-LS1,92903,GRP_LOCATION,LOCATION_LONG,-110.1403 -US-LS1,92903,GRP_LOCATION,LOCATION_ELEV,1230 -US-LS1,92911,GRP_NETWORK,NETWORK,AmeriFlux -US-LS1,1700005643,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Scott, R. L., Huxman, T. E., Barron-Gafford, G. A., Darrel Jenerette, G., Young, J. M., Hamerlynck, E. P. (2014) When Vegetation Change Alters Ecosystem Water Availability, Global Change Biology, 20(7), 2198-2210" -US-LS1,1700005643,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/GCB.12511 -US-LS1,1700005643,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-LS1,1700000948,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"SCOTT, R. L., HUXMAN, T. E., WILLIAMS, D. G., GOODRICH, D. C. (2006) Ecohydrological Impacts Of Woody-Plant Encroachment: Seasonal Patterns Of Water And Carbon Dioxide Exchange Within A Semiarid Riparian Environment, Global Change Biology, 12(2), 311-324" -US-LS1,1700000948,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/J.1365-2486.2005.01093.X -US-LS1,1700000948,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-LS1,1700001266,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"SCOTT, R. L., HUXMAN, T. E., WILLIAMS, D. G., GOODRICH, D. C. (2006) Ecohydrological Impacts Of Woody-Plant Encroachment: Seasonal Patterns Of Water And Carbon Dioxide Exchange Within A Semiarid Riparian Environment, Global Change Biology, 12(2), 311-324" -US-LS1,1700001266,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/J.1365-2486.2005.01093.X -US-LS1,1700001266,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Primary_Citation -US-LS1,1700006126,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Scott, R., Cable, W., Huxman, T., Nagler, P., Hernandez, M., Goodrich, D. (2008) Multiyear Riparian Evapotranspiration And Groundwater Use For A Semiarid Watershed, Journal Of Arid Environments, 72(7), 1232-1246" -US-LS1,1700006126,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.JARIDENV.2008.01.001 -US-LS1,1700006126,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-LS1,92908,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"riparian vegetation water use and carbon uptake, groundwater dependent ecosystem functioning, woody plant encroachment" -US-LS1,92897,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"2000 E. Allen Rd. Tucson, AZ USA 85719" -US-LS1,92896,GRP_SITE_CHAR,TERRAIN,Valley -US-LS1,92896,GRP_SITE_CHAR,ASPECT,FLAT -US-LS1,92896,GRP_SITE_CHAR,WIND_DIRECTION,SSW -US-LS1,92896,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,225 -US-LS1,92896,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,0 -US-LS1,92904,GRP_SITE_DESC,SITE_DESC,"This is a riparian grassland located along an old alluvial terrace along the banks of the entrenched San Pedro River in southeastern Arizona. Site climate is semiarid with monsoonal (Jul-Sep) rainfall. The grasses access groundwater (depth of 2-4 m)from an alluvial aquifer recharged elsewhere. Site water balance is not closed and ET greatly exceeds precipitation. The perennial bunchgrasses use both rainfall, groundwater and occasional flood water. This groundwater-using ecosystem is far more ebulliant and productive than the upland vegetation around it (shrublands and grasslands) outside of the San Pedro River corridor." -US-LS1,92905,GRP_SITE_FUNDING,SITE_FUNDING,"USDA, NSF" -US-LS1,92900,GRP_STATE,STATE,AZ -US-LS1,92907,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Russell Scott -US-LS1,92907,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-LS1,92907,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,russ.scott@ars.usda.gov -US-LS1,92907,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,USDA-ARS -US-LS1,96256,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Ross Bryant -US-LS1,96256,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Technician -US-LS1,96256,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,Ross.Bryant@usda.gov -US-LS1,96256,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,USDA -US-LS1,96256,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"ARS-SWRC -2000 East Allen Rd -Tucson, AZ 85719" -US-LS1,92899,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-LS1,92909,GRP_TOWER_TYPE,TOWER_TYPE,tripod -US-LS1,24001159,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-LS1 -US-LS1,92895,GRP_UTC_OFFSET,UTC_OFFSET,-7 -US-LS1,92895,GRP_UTC_OFFSET,UTC_OFFSET_DATE_START,200301010000 -US-LS1,92895,GRP_UTC_OFFSET,UTC_OFFSET_COMMENT,"-7 UTC, no daylight savings time" -US-LS2,92938,GRP_CLIM_AVG,MAT,17 -US-LS2,92938,GRP_CLIM_AVG,MAP,288 -US-LS2,92938,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Bwh -US-LS2,27001160,GRP_COUNTRY,COUNTRY,USA -US-LS2,93756,GRP_DOI,DOI,10.17190/AMF/1660347 -US-LS2,93756,GRP_DOI,DOI_CITATION,"Russell Scott (2020), AmeriFlux BASE US-LS2 San Pedro River Lewis Springs Savanna, Ver. 1-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1660347" -US-LS2,93756,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-LS2,93704,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-LS2,93704,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Russell Scott -US-LS2,93704,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-LS2,93704,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,russ.scott@ars.usda.gov -US-LS2,93704,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,USDA-ARS -US-LS2,93743,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,USDA-ARS -US-LS2,93743,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-LS2,93727,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,"USDA, NSF" -US-LS2,93727,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-LS2,92942,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-LS2,92942,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-LS2,92942,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,200301010030 -US-LS2,92942,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,200712312330 -US-LS2,92942,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-LS2,92949,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-LS2,92949,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-LS2,92949,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,200301010030 -US-LS2,92949,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,200712312330 -US-LS2,92949,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-LS2,23001160,GRP_HEADER,SITE_NAME,San Pedro River Lewis Springs Savanna -US-LS2,92941,GRP_IGBP,IGBP,SAV -US-LS2,92941,GRP_IGBP,IGBP_COMMENT,"Site is a riparian savanna with a mosaic of short-statured trees (Prosopis veluntia) and perennial bunchgrass, Big Sacaton (Sporobolus Wrightii)." -US-LS2,92943,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-LS2,92943,GRP_LAND_OWNERSHIP,LAND_OWNER,Bureau of Land Management -US-LS2,92940,GRP_LOCATION,LOCATION_LAT,31.5659 -US-LS2,92940,GRP_LOCATION,LOCATION_LONG,-110.1344 -US-LS2,92940,GRP_LOCATION,LOCATION_ELEV,1240 -US-LS2,92946,GRP_NETWORK,NETWORK,AmeriFlux -US-LS2,1700008340,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Barron-Gafford, G. A., Scott, R. L., Jenerette, G. D., Hamerlynck, E. P., Huxman, T. E. (2013) Landscape And Environmental Controls Over Leaf And Ecosystem Carbon Dioxide Fluxes Under Woody Plant Expansion, Journal Of Ecology, 101(6), 1471-1483" -US-LS2,1700008340,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/1365-2745.12161 -US-LS2,1700008340,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-LS2,1700005325,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Cable, J. M., Barron-Gafford, G. A., Ogle, K., Pavao-Zuckerman, M., Scott, R. L., Williams, D. G., Huxman, T. E. (2012) Shrub Encroachment Alters Sensitivity Of Soil Respiration To Temperature And Moisture, Journal Of Geophysical Research: Biogeosciences, 117(G1), 1230-1247" -US-LS2,1700005325,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2011JG001757 -US-LS2,1700005325,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-LS2,1700003075,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Cable, J. M., Ogle, K., Barron-Gafford, G. A., Bentley, L. P., Cable, W. L., Scott, R. L., Williams, D. G., Huxman, T. E. (2013) Antecedent Conditions Influence Soil Respiration Differences In Shrub And Grass Patches, Ecosystems, 16(7), 1230-1247" -US-LS2,1700003075,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1007/S10021-013-9679-7 -US-LS2,1700003075,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-LS2,1700005370,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"SCOTT, R. L., HUXMAN, T. E., WILLIAMS, D. G., GOODRICH, D. C. (2006) Ecohydrological Impacts Of Woody-Plant Encroachment: Seasonal Patterns Of Water And Carbon Dioxide Exchange Within A Semiarid Riparian Environment, Global Change Biology, 12(2), 311-324" -US-LS2,1700005370,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/J.1365-2486.2005.01093.X -US-LS2,1700005370,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-LS2,92952,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"riparian vegetation water use and carbon uptake, groundwater dependent ecosystem functioning, woody plant encroachment" -US-LS2,92947,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"2000 E. Allen Rd. Tucson, AZ USA 85719" -US-LS2,92948,GRP_SITE_CHAR,TERRAIN,Valley -US-LS2,92948,GRP_SITE_CHAR,ASPECT,FLAT -US-LS2,92948,GRP_SITE_CHAR,WIND_DIRECTION,SSW -US-LS2,92948,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,200 -US-LS2,92948,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,0 -US-LS2,92939,GRP_SITE_DESC,SITE_DESC,"A riparian savanna located on an old alluvial terrace about 0.5 km from the banks of the entrenched San Pedro River in southeastern Arizona USA. Site climate is semiarid with monsoonal (Jul-Sep) rainfall. The trees access groundwater (depth of ~7 m)from an alluvial aquifer recharged elsewhere. Therefore, site water balance is not closed and ET greatly exceeds precipitation. The perennial bunchgrasses use primarily rainfall. This groundwater-using ecosystem is far more ebulliant and productive than the upland vegetation around it (shrublands and grasslands) outside of the San Pedro River corridor." -US-LS2,92937,GRP_SITE_FUNDING,SITE_FUNDING,"USDA, NSF" -US-LS2,92945,GRP_STATE,STATE,AZ -US-LS2,92936,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Russell Scott -US-LS2,92936,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-LS2,92936,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,russ.scott@ars.usda.gov -US-LS2,92936,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,USDA-ARS -US-LS2,96262,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Ross Bryant -US-LS2,96262,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Technician -US-LS2,96262,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,Ross.Bryant@usda.gov -US-LS2,96262,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,USDA -US-LS2,96262,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"ARS-SWRC -2000 East Allen Rd -Tucson, Arizona, 85719" -US-LS2,92950,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-LS2,92944,GRP_TOWER_TYPE,TOWER_TYPE,walk-up -US-LS2,24001160,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-LS2 -US-LS2,92951,GRP_UTC_OFFSET,UTC_OFFSET,-7 -US-LS2,92951,GRP_UTC_OFFSET,UTC_OFFSET_DATE_START,200301010000 -US-LS2,92951,GRP_UTC_OFFSET,UTC_OFFSET_COMMENT,"-7 UTC, no daylight savings time" -US-MC1,91160,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,We acknowledge support from Montana State University College of Agriculture and the Montana Wheat and Barley Committee -US-MC1,91171,GRP_CLIM_AVG,MAT,6.25 -US-MC1,91171,GRP_CLIM_AVG,MAP,432 -US-MC1,91171,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfb -US-MC1,27001123,GRP_COUNTRY,COUNTRY,USA -US-MC1,93755,GRP_DOI,DOI,10.17190/AMF/1660348 -US-MC1,93755,GRP_DOI,DOI_CITATION,"Paul Stoy (2020), AmeriFlux BASE US-MC1 Creston, Montana pivot-irrigated spring wheat, Ver. 1-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1660348" -US-MC1,93755,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-MC1,93713,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-MC1,93713,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Paul Stoy -US-MC1,93713,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-MC1,93713,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,pcstoy@wisc.edu -US-MC1,93713,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of Wisconsin -US-MC1,93735,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,University of Wisconsin -US-MC1,93735,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-MC1,93729,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,"Montana State University College of Agriculture, Montana Wheat and Barley Committee" -US-MC1,93729,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-MC1,91167,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Agriculture -US-MC1,91164,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-MC1,91164,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-MC1,91164,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201505181800 -US-MC1,91164,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,201509032230 -US-MC1,91164,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Periodic operation -US-MC1,91163,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-MC1,91163,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-MC1,91163,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201505181800 -US-MC1,91163,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,201509032230 -US-MC1,91163,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Periodic operation -US-MC1,91175,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-MC1,91175,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-MC1,91175,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201505181800 -US-MC1,91175,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,201509032230 -US-MC1,91175,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Periodic operation -US-MC1,23001123,GRP_HEADER,SITE_NAME,"Creston, Montana pivot-irrigated spring wheat" -US-MC1,91169,GRP_IGBP,IGBP,CRO -US-MC1,91165,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-MC1,91165,GRP_LAND_OWNERSHIP,LAND_OWNER,Montana State University College of Agriculture -US-MC1,91174,GRP_LOCATION,LOCATION_LAT,48.1873 -US-MC1,91174,GRP_LOCATION,LOCATION_LONG,-114.1548 -US-MC1,91174,GRP_LOCATION,LOCATION_ELEV,900 -US-MC1,91174,GRP_LOCATION,LOCATION_DATE_START,201505181800 -US-MC1,91161,GRP_NETWORK,NETWORK,AmeriFlux -US-MC1,91179,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"irrigation, agriculture" -US-MC1,91173,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"540 Elm Drive, University of Wisconsin – Madison, Madison, WI 53706" -US-MC1,91177,GRP_SITE_CHAR,TERRAIN,Flat -US-MC1,91177,GRP_SITE_CHAR,ASPECT,FLAT -US-MC1,91177,GRP_SITE_CHAR,WIND_DIRECTION,SW -US-MC1,91177,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,600 -US-MC1,91166,GRP_SITE_DESC,SITE_DESC,pivot-irrigated spring wheat -US-MC1,91168,GRP_SITE_FUNDING,SITE_FUNDING,"Montana State University College of Agriculture, Montana Wheat and Barley Committee" -US-MC1,91170,GRP_STATE,STATE,MT -US-MC1,91178,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Paul Stoy -US-MC1,91178,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-MC1,91178,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,pcstoy@wisc.edu -US-MC1,91178,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Wisconsin -US-MC1,91178,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"460 Henry Mall, University of Wisconsin – Madison, Madison, WI 53706" -US-MC1,91162,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Jessica Torrion -US-MC1,91162,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,AncContact -US-MC1,91162,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,jessica.torrion@montana.edu -US-MC1,91176,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-MC1,91172,GRP_TOWER_TYPE,TOWER_TYPE,tripod -US-MC1,24001123,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-MC1 -US-MC1,91159,GRP_UTC_OFFSET,UTC_OFFSET,-7 -US-MC1,91159,GRP_UTC_OFFSET,UTC_OFFSET_DATE_START,201505181800 -US-MC2,91192,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,We acknowledge support from Montana State University College of Agriculture and the Montana Wheat and Barley Committee -US-MC2,91199,GRP_CLIM_AVG,MAT,6.25 -US-MC2,91199,GRP_CLIM_AVG,MAP,432 -US-MC2,91199,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfb -US-MC2,27001128,GRP_COUNTRY,COUNTRY,USA -US-MC2,98618,GRP_DOI,DOI,10.17190/AMF/1829506 -US-MC2,98618,GRP_DOI,DOI_CITATION,"Paul Stoy (2021), AmeriFlux BASE US-MC2 Creston, Montana pivot-irrigated spring wheat 2, Ver. 1-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1829506" -US-MC2,98618,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-MC2,98598,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-MC2,98598,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Paul Stoy -US-MC2,98598,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-MC2,98598,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,pcstoy@wisc.edu -US-MC2,98598,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of Wisconsin -US-MC2,98612,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,University of Wisconsin -US-MC2,98612,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-MC2,98607,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,"Montana State University College of Agriculture, Montana Wheat and Barley Committee" -US-MC2,98607,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-MC2,91193,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Agriculture -US-MC2,91197,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-MC2,91197,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-MC2,91197,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201605100000 -US-MC2,91197,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,201609300400 -US-MC2,91197,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Periodic operation -US-MC2,91191,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-MC2,91191,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-MC2,91191,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201605100000 -US-MC2,91191,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,201609300400 -US-MC2,91191,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Periodic operation -US-MC2,91182,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-MC2,91182,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-MC2,91182,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201605100000 -US-MC2,91182,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,201609300400 -US-MC2,91182,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Periodic operation -US-MC2,23001128,GRP_HEADER,SITE_NAME,"Creston, Montana pivot-irrigated spring wheat 2" -US-MC2,91196,GRP_IGBP,IGBP,CRO -US-MC2,91180,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -US-MC2,91180,GRP_LAND_OWNERSHIP,LAND_OWNER,Montana State University College of Agriculture -US-MC2,91185,GRP_LOCATION,LOCATION_LAT,48.1802 -US-MC2,91185,GRP_LOCATION,LOCATION_LONG,-114.2051 -US-MC2,91185,GRP_LOCATION,LOCATION_ELEV,900 -US-MC2,91185,GRP_LOCATION,LOCATION_DATE_START,201605100000 -US-MC2,91181,GRP_NETWORK,NETWORK,AmeriFlux -US-MC2,91184,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"irrigation, agriculture" -US-MC2,91188,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"540 Elm Drive, University of Wisconsin – Madison, Madison, WI 53706" -US-MC2,91200,GRP_SITE_CHAR,TERRAIN,Flat -US-MC2,91200,GRP_SITE_CHAR,ASPECT,FLAT -US-MC2,91200,GRP_SITE_CHAR,WIND_DIRECTION,SW -US-MC2,91200,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,600 -US-MC2,91189,GRP_SITE_DESC,SITE_DESC,pivot-irrigated spring wheat -US-MC2,91183,GRP_SITE_FUNDING,SITE_FUNDING,"Montana State University College of Agriculture, Montana Wheat and Barley Committee" -US-MC2,91190,GRP_STATE,STATE,MT -US-MC2,91186,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Paul Stoy -US-MC2,91186,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-MC2,91186,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,pcstoy@wisc.edu -US-MC2,91186,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Wisconsin -US-MC2,91186,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"460 Henry Mall, University of Wisconsin – Madison, Madison, WI 53706" -US-MC2,91187,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Jessica Torrion -US-MC2,91187,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,AncContact -US-MC2,91187,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,jessica.torrion@montana.edu -US-MC2,91195,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-MC2,91198,GRP_TOWER_TYPE,TOWER_TYPE,tripod -US-MC2,24001128,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-MC2 -US-MC2,91194,GRP_UTC_OFFSET,UTC_OFFSET,-7 -US-MC2,91194,GRP_UTC_OFFSET,UTC_OFFSET_DATE_START,201605100000 -US-Me2,12961,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,"The Metolius AmeriFlux research was supported by the Office of Science (BER), U.S. Department of Energy, Grant No. DE-FG02-06ER64318)." -US-Me2,19650,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER,0.98536804142 -US-Me2,19650,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_ORGAN,Total -US-Me2,19650,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_PHEN,Mixed/unknown -US-Me2,19650,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_UNIT,gC m-2 -US-Me2,19650,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_DATE,2001 -US-Me2,19662,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB,1.4029941583 -US-Me2,19662,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_ORGAN,Foliage -US-Me2,19662,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_PHEN,Mixed/unknown -US-Me2,19662,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_UNIT,gC m-2 -US-Me2,19662,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_DATE,2001 -US-Me2,19651,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB,93.207592606 -US-Me2,19651,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_ORGAN,Wood -US-Me2,19651,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_PHEN,Mixed/unknown -US-Me2,19651,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_UNIT,gC m-2 -US-Me2,19651,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_DATE,2001 -US-Me2,22111,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,2496 -US-Me2,22111,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_SPATIAL_VARIABILITY,238.3 -US-Me2,22111,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Branches -US-Me2,22111,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-Me2,22111,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-Me2,22111,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,20140429 -US-Me2,19663,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,443.95509503 -US-Me2,19663,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Foliage -US-Me2,19663,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-Me2,19663,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-Me2,19663,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2001 -US-Me2,19652,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,4435.1119994 -US-Me2,19652,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Wood -US-Me2,19652,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-Me2,19652,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-Me2,19652,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2001 -US-Me2,19589,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,452.80554869 -US-Me2,19589,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Foliage -US-Me2,19589,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-Me2,19589,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-Me2,19589,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2002 -US-Me2,19595,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,460.10972745 -US-Me2,19595,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Foliage -US-Me2,19595,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-Me2,19595,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-Me2,19595,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2003 -US-Me2,19666,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,4641.747784 -US-Me2,19666,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Wood -US-Me2,19666,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-Me2,19666,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-Me2,19666,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2002 -US-Me2,19601,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,469.24831463 -US-Me2,19601,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Foliage -US-Me2,19601,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-Me2,19601,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-Me2,19601,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2004 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-US-Me2,19646,GRP_AG_PROD_TREE,AG_PROD_TREE,107.46370753 -US-Me2,19646,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Foliage -US-Me2,19646,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-Me2,19646,GRP_AG_PROD_TREE,AG_PROD_DATE_START,2009 -US-Me2,19606,GRP_AG_PROD_TREE,AG_PROD_TREE,119.47177377 -US-Me2,19606,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Foliage -US-Me2,19606,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-Me2,19606,GRP_AG_PROD_TREE,AG_PROD_DATE_START,2005 -US-Me2,19668,GRP_AG_PROD_TREE,AG_PROD_TREE,121.05663794 -US-Me2,19668,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Foliage -US-Me2,19668,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-Me2,19668,GRP_AG_PROD_TREE,AG_PROD_DATE_START,2002 -US-Me2,19600,GRP_AG_PROD_TREE,AG_PROD_TREE,124.99773258 -US-Me2,19600,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Foliage -US-Me2,19600,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-Me2,19600,GRP_AG_PROD_TREE,AG_PROD_DATE_START,2004 -US-Me2,19612,GRP_AG_PROD_TREE,AG_PROD_TREE,125.99251099 -US-Me2,19612,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Foliage -US-Me2,19612,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-Me2,19612,GRP_AG_PROD_TREE,AG_PROD_DATE_START,2011 -US-Me2,19642,GRP_AG_PROD_TREE,AG_PROD_TREE,135.63499958 -US-Me2,19642,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Foliage -US-Me2,19642,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-Me2,19642,GRP_AG_PROD_TREE,AG_PROD_DATE_START,2008 -US-Me2,19638,GRP_AG_PROD_TREE,AG_PROD_TREE,143.62045972 -US-Me2,19638,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Foliage -US-Me2,19638,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-Me2,19638,GRP_AG_PROD_TREE,AG_PROD_DATE_START,2007 -US-Me2,19597,GRP_AG_PROD_TREE,AG_PROD_TREE,152.05756834 -US-Me2,19597,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Wood -US-Me2,19597,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-Me2,19597,GRP_AG_PROD_TREE,AG_PROD_DATE_START,2003 -US-Me2,19608,GRP_AG_PROD_TREE,AG_PROD_TREE,162.50619939 -US-Me2,19608,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Foliage -US-Me2,19608,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-Me2,19608,GRP_AG_PROD_TREE,AG_PROD_DATE_START,2010 -US-Me2,19636,GRP_AG_PROD_TREE,AG_PROD_TREE,164.74715613 -US-Me2,19636,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Wood -US-Me2,19636,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-Me2,19636,GRP_AG_PROD_TREE,AG_PROD_DATE_START,2006 -US-Me2,19648,GRP_AG_PROD_TREE,AG_PROD_TREE,171.39911648 -US-Me2,19648,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Wood -US-Me2,19648,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-Me2,19648,GRP_AG_PROD_TREE,AG_PROD_DATE_START,2009 -US-Me2,19632,GRP_AG_PROD_TREE,AG_PROD_TREE,171.80625264 -US-Me2,19632,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Wood -US-Me2,19632,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-Me2,19632,GRP_AG_PROD_TREE,AG_PROD_DATE_START,2005 -US-Me2,19603,GRP_AG_PROD_TREE,AG_PROD_TREE,175.07783027 -US-Me2,19603,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Wood -US-Me2,19603,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-Me2,19603,GRP_AG_PROD_TREE,AG_PROD_DATE_START,2004 -US-Me2,19614,GRP_AG_PROD_TREE,AG_PROD_TREE,192.07945562 -US-Me2,19614,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Wood -US-Me2,19614,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-Me2,19614,GRP_AG_PROD_TREE,AG_PROD_DATE_START,2011 -US-Me2,19644,GRP_AG_PROD_TREE,AG_PROD_TREE,195.4205157 -US-Me2,19644,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Wood -US-Me2,19644,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-Me2,19644,GRP_AG_PROD_TREE,AG_PROD_DATE_START,2008 -US-Me2,19640,GRP_AG_PROD_TREE,AG_PROD_TREE,198.83647573 -US-Me2,19640,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Wood -US-Me2,19640,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-Me2,19640,GRP_AG_PROD_TREE,AG_PROD_DATE_START,2007 -US-Me2,19591,GRP_AG_PROD_TREE,AG_PROD_TREE,206.63578456 -US-Me2,19591,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Wood -US-Me2,19591,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-Me2,19591,GRP_AG_PROD_TREE,AG_PROD_DATE_START,2002 -US-Me2,19610,GRP_AG_PROD_TREE,AG_PROD_TREE,229.85215371 -US-Me2,19610,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Wood -US-Me2,19610,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-Me2,19610,GRP_AG_PROD_TREE,AG_PROD_DATE_START,2010 -US-Me2,19594,GRP_AG_PROD_TREE,AG_PROD_TREE,99.906666667 -US-Me2,19594,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Foliage -US-Me2,19594,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-Me2,19594,GRP_AG_PROD_TREE,AG_PROD_DATE_START,2003 -US-Me2,19615,GRP_BASAL_AREA,BASAL_AREA,29.1 -US-Me2,19615,GRP_BASAL_AREA,BASAL_AREA_SPP,(Unknown) -US-Me2,19615,GRP_BASAL_AREA,BASAL_AREA_DATE,2011 -US-Me2,22115,GRP_BASAL_AREA,BASAL_AREA,31.5 -US-Me2,22115,GRP_BASAL_AREA,BASAL_AREA_SPP,(Unknown) -US-Me2,22115,GRP_BASAL_AREA,BASAL_AREA_APPROACH,"PIPO, AGBR, CADE all > 10 cm dbh" -US-Me2,22115,GRP_BASAL_AREA,BASAL_AREA_DATE,20140429 -US-Me2,22115,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,4.46 -US-Me2,24954,GRP_BIOMASS_CHEM,BIOMASS_C,5.3 -US-Me2,24954,GRP_BIOMASS_CHEM,BIOMASS_N,0.093 -US-Me2,24954,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-Me2,24954,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-Me2,24954,GRP_BIOMASS_CHEM,BIOMASS_SPP,PIPO (NRCS plant code) -US-Me2,24954,GRP_BIOMASS_CHEM,BIOMASS_DATE,2001 -US-Me2,12962,GRP_CLIM_AVG,MAT,6.28 -US-Me2,12962,GRP_CLIM_AVG,MAP,523 -US-Me2,12962,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Csb -US-Me2,27000394,GRP_COUNTRY,COUNTRY,USA -US-Me2,19616,GRP_DBH,DBH,32.3 -US-Me2,19616,GRP_DBH,DBH_SPP,(Unknown) -US-Me2,19616,GRP_DBH,DBH_DATE,2011 -US-Me2,19616,GRP_DBH,DBH_SPATIAL_VARIABILITY,1.3 -US-Me2,22118,GRP_DBH,DBH,33.1 -US-Me2,22118,GRP_DBH,DBH_SPP,(Unknown) -US-Me2,22118,GRP_DBH,DBH_DATE,20140429 -US-Me2,22118,GRP_DBH,DBH_COMMENT,"includes PIPO, CADE, AGBR all >10 cm dbh" -US-Me2,22118,GRP_DBH,DBH_SPATIAL_VARIABILITY,10.3 -US-Me2,22116,GRP_DBH,DBH,35.75 -US-Me2,22116,GRP_DBH,DBH_SPP,Pinus ponderosa -US-Me2,22116,GRP_DBH,DBH_DATE,20140429 -US-Me2,22116,GRP_DBH,DBH_SPATIAL_VARIABILITY,7.46 -US-Me2,15668,GRP_DOI,DOI,10.17190/AMF/1246076 -US-Me2,15668,GRP_DOI,DOI_CITATION,"Bev Law (2022), AmeriFlux BASE US-Me2 Metolius mature ponderosa pine, Ver. 18-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1246076" -US-Me2,15668,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-Me2,32114,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Me2,32114,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Bev Law -US-Me2,32114,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Me2,32114,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,bev.law@oregonstate.edu -US-Me2,32114,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Oregon State University -US-Me2,32116,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Oregon State University -US-Me2,32116,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-Me2,32115,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,DOE/TCP -US-Me2,32115,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-Me2,22210,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Undisturbed -US-Me2,91298,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Me2,91298,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-Me2,91298,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,200210 -US-Me2,91298,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Me2,91329,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Me2,91329,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-Me2,91329,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,200210 -US-Me2,91329,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Me2,23000394,GRP_HEADER,SITE_NAME,Metolius mature ponderosa pine -US-Me2,89134,GRP_HEIGHTC,HEIGHTC,14 -US-Me2,89134,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Me2,89134,GRP_HEIGHTC,HEIGHTC_APPROACH,laser rangefinder -US-Me2,89134,GRP_HEIGHTC,HEIGHTC_DATE,2001 -US-Me2,89132,GRP_HEIGHTC,HEIGHTC,0.7 -US-Me2,89132,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Me2,89132,GRP_HEIGHTC,HEIGHTC_APPROACH,laser rangefinder -US-Me2,89132,GRP_HEIGHTC,HEIGHTC_DATE,2011 -US-Me2,89136,GRP_HEIGHTC,HEIGHTC,16.5 -US-Me2,89136,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Me2,89136,GRP_HEIGHTC,HEIGHTC_APPROACH,laser rangefinder -US-Me2,89136,GRP_HEIGHTC,HEIGHTC_DATE,2011 -US-Me2,89133,GRP_HEIGHTC,HEIGHTC,1.52 -US-Me2,89133,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Me2,89133,GRP_HEIGHTC,HEIGHTC_APPROACH,laser rangefinder -US-Me2,89133,GRP_HEIGHTC,HEIGHTC_DATE,20140429 -US-Me2,89135,GRP_HEIGHTC,HEIGHTC,16.49 -US-Me2,89135,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Me2,89135,GRP_HEIGHTC,HEIGHTC_APPROACH,laser rangefinder -US-Me2,89135,GRP_HEIGHTC,HEIGHTC_DATE,20140429 -US-Me2,12964,GRP_IGBP,IGBP,ENF -US-Me2,19618,GRP_LAI,LAI_TYPE,LAI -US-Me2,19623,GRP_LAI,LAI_TYPE,LAI -US-Me2,19626,GRP_LAI,LAI_TYPE,LAI -US-Me2,19627,GRP_LAI,LAI_TYPE,LAI -US-Me2,19628,GRP_LAI,LAI_TYPE,LAI -US-Me2,19629,GRP_LAI,LAI_TYPE,LAI -US-Me2,19630,GRP_LAI,LAI_TYPE,LAI -US-Me2,22123,GRP_LAI,LAI_TYPE,LAI -US-Me2,19618,GRP_LAI,LAI_CLUMP,1.29 -US-Me2,19623,GRP_LAI,LAI_CLUMP,1.29 -US-Me2,19626,GRP_LAI,LAI_CLUMP,1.29 -US-Me2,19627,GRP_LAI,LAI_CLUMP,1.29 -US-Me2,19628,GRP_LAI,LAI_CLUMP,1.29 -US-Me2,19629,GRP_LAI,LAI_CLUMP,1.29 -US-Me2,19630,GRP_LAI,LAI_CLUMP,1.29 -US-Me2,19618,GRP_LAI,LAI_METHOD,LAI_2000 -US-Me2,19623,GRP_LAI,LAI_METHOD,LAI_2000 -US-Me2,19626,GRP_LAI,LAI_METHOD,LAI_2000 -US-Me2,19627,GRP_LAI,LAI_METHOD,LAI_2000 -US-Me2,19628,GRP_LAI,LAI_METHOD,LAI_2000 -US-Me2,19629,GRP_LAI,LAI_METHOD,LAI_2000 -US-Me2,19630,GRP_LAI,LAI_METHOD,LAI_2000 -US-Me2,22123,GRP_LAI,LAI_METHOD,LAI_2200 -US-Me2,19618,GRP_LAI,LAI_DATE,2001 -US-Me2,19623,GRP_LAI,LAI_DATE,20080816 -US-Me2,19626,GRP_LAI,LAI_DATE,20100922 -US-Me2,19627,GRP_LAI,LAI_DATE,20130510 -US-Me2,19628,GRP_LAI,LAI_DATE,20130606 -US-Me2,19629,GRP_LAI,LAI_DATE,20130822 -US-Me2,19630,GRP_LAI,LAI_DATE,20130912 -US-Me2,22123,GRP_LAI,LAI_DATE,20140827 -US-Me2,19630,GRP_LAI,LAI_O_EVG,1.87 -US-Me2,19629,GRP_LAI,LAI_O_EVG,1.96 -US-Me2,19627,GRP_LAI,LAI_O_EVG,2.35 -US-Me2,22123,GRP_LAI,LAI_O_EVG,2.37 -US-Me2,19628,GRP_LAI,LAI_O_EVG,2.7 -US-Me2,19618,GRP_LAI,LAI_O_EVG,2.8 -US-Me2,19626,GRP_LAI,LAI_O_EVG,2.87 -US-Me2,19623,GRP_LAI,LAI_O_EVG,3.01 -US-Me2,19629,GRP_LAI,LAI_O_EVG_SPATIAL_VARIABILITY,0.1 -US-Me2,19630,GRP_LAI,LAI_O_EVG_SPATIAL_VARIABILITY,0.1 -US-Me2,19627,GRP_LAI,LAI_O_EVG_SPATIAL_VARIABILITY,0.2 -US-Me2,19628,GRP_LAI,LAI_O_EVG_SPATIAL_VARIABILITY,0.2 -US-Me2,22123,GRP_LAI,LAI_O_EVG_SPATIAL_VARIABILITY,0.48 -US-Me2,19623,GRP_LAI,LAI_TOT,3.58 -US-Me2,19623,GRP_LAI,LAI_U,0.57 -US-Me2,12965,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -US-Me2,12965,GRP_LAND_OWNERSHIP,LAND_OWNER,"Ponderosa Land & Cattle Timber Products, previously owned by Weyerhauser." -US-Me2,24044,GRP_LMA,LMA,127 -US-Me2,24044,GRP_LMA,LMA_SPP,PIPO (NRCS plant code) -US-Me2,24044,GRP_LMA,LMA_DATE,2001 -US-Me2,12966,GRP_LOCATION,LOCATION_LAT,44.4523 -US-Me2,12966,GRP_LOCATION,LOCATION_LONG,-121.5574 -US-Me2,12966,GRP_LOCATION,LOCATION_ELEV,1253 -US-Me2,23687,GRP_NEP,NEP,115000 -US-Me2,23687,GRP_NEP,NEP_DATE_START,1996 -US-Me2,23687,GRP_NEP,NEP_DATE_END,2006 -US-Me2,12967,GRP_NETWORK,NETWORK,AmeriFlux -US-Me2,86981,GRP_NETWORK,NETWORK,Phenocam -US-Me2,22117,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,BudBreak -US-Me2,22117,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_STATUS,Start -US-Me2,22117,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,Pinus ponderosa -US-Me2,22117,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20140520 -US-Me2,22117,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_UNC,20 -US-Me2,22113,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,Flowering -US-Me2,22113,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_STATUS,Peak -US-Me2,22113,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,Purshia tridentata -US-Me2,22113,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20140520 -US-Me2,22113,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_UNC,20 -US-Me2,22120,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,Total leaf-off -US-Me2,22120,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_STATUS,Start -US-Me2,22120,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,Pinus ponderosa -US-Me2,22120,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20140911 -US-Me2,22120,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_UNC,21 -US-Me2,22122,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,Total leaf-off -US-Me2,22122,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_STATUS,End -US-Me2,22122,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,Pinus ponderosa -US-Me2,22122,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20141016 -US-Me2,22122,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_UNC,7 -US-Me2,1700005706,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Campbell, J. L., Sun, O. J., Law, B. E. (2004) Disturbance And Net Ecosystem Production Across Three Climatically Distinct Forest Landscapes, Global Biogeochemical Cycles, 18(4), n/a-n/a" -US-Me2,1700005706,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2004GB002236 -US-Me2,1700005706,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Me2,1700001197,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Campbell, J. L., Sun, O. J., Law, B. E. (2004) Supply-Side Controls On Soil Respiration Among Oregon Forests, Global Change Biology, 10(11), 1857-1869" -US-Me2,1700001197,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/J.1365-2486.2004.00850.X -US-Me2,1700001197,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Me2,1700007635,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Campbell, J., Law, B. (2005) Forest Soil Respiration Across Three Climatically Distinct Chronosequences In Oregon, Biogeochemistry, 73(1), 109-125" -US-Me2,1700007635,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1007/S10533-004-5165-9 -US-Me2,1700007635,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Me2,1700002943,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Baldocchi, D. D., Poindexter, C., Abraha, M., Desai, A. R., Bohrer, G., Arain, M. A., Griffis, T., Blanken, P. D., O'Halloran, T. L., Thomas, R. Q., Zhang, Q., Burns, S. P., Frank, J. M., Christian, D., Brown, S., Black, T. A., Gough, C. M., Law, B. E., Lee, X., Chen, J., Reed, D. E., Massman, W. J., Clark, K., Hatfield, J., Prueger, J., Bracho, R., Baker, J. M., Martin, T. A. (2018) Temporal Dynamics Of Aerodynamic Canopy Height Derived From Eddy Covariance Momentum Flux Data Across North American Flux Networks, Geophysical Research Letters, 45(22), 9275–9287" -US-Me2,1700002943,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018GL079306 -US-Me2,1700002943,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Me2,1700006708,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(7), 108350" -US-Me2,1700006708,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -US-Me2,1700006708,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Me2,1700007665,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Coops, N. C., Waring, R. H., Law, B. E. (2005) Assessing The Past And Future Distribution And Productivity Of Ponderosa Pine In The Pacific Northwest Using A Process Model, 3-Pg, Ecological Modelling, 183(1), 107-124" -US-Me2,1700007665,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.ECOLMODEL.2004.08.002 -US-Me2,1700007665,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Me2,1700004092,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Hibbard, K. A., Law, B. E., Reichstein, M., Sulzman, J. (2005) An Analysis Of Soil Respiration Across Northern Hemisphere Temperate Ecosystems, Biogeochemistry, 73(1), 29-70" -US-Me2,1700004092,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1007/S10533-004-2946-0 -US-Me2,1700004092,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Me2,1700000198,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Irvine, J., Law, B. E., Kurpius, M. R. (2005) Coupling Of Canopy Gas Exchange With Root And Rhizosphere Respiration In A Semi-Arid Forest, Biogeochemistry, 73(1), 271-282" -US-Me2,1700000198,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1007/S10533-004-2564-X -US-Me2,1700000198,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Me2,1700006384,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Irvine, J., Law, B. E., Kurpius, M. R., Anthoni, P. M., Moore, D., Schwarz, P. A. (2004) Age-Related Changes In Ecosystem Structure And Function And Effects On Water And Carbon Exchange In Ponderosa Pine, Tree Physiology, 24(7), 753-763" -US-Me2,1700006384,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1093/TREEPHYS/24.7.753 -US-Me2,1700006384,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Me2,1700001485,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Irvine, J., Law, B. E., Martin, J. G., Vickers, D. (2008) Interannual Variation In Soil CO2 Efflux And The Response Of Root Respiration To Climate And Canopy Gas Exchange In Mature Ponderosa Pine, Global Change Biology, 14(12), 2848-2859" -US-Me2,1700001485,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/J.1365-2486.2008.01682.X -US-Me2,1700001485,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Me2,1700000138,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Kelliher, F., Ross, D., Law, B., Baldocchi, D., Rodda, N. (2004) Limitations To Carbon Mineralization In Litter And Mineral Soil Of Young And Old Ponderosa Pine Forests, Forest Ecology And Management, 191(1-3), 201-213" -US-Me2,1700000138,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.FORECO.2003.12.005 -US-Me2,1700000138,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Me2,1700003099,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Kwon, H., Law, B. E., Thomas, C. K., Johnson, B. G. (2018) The Influence Of Hydrological Variability On Inherent Water Use Efficiency In Forests Of Contrasting Composition, Age, And Precipitation Regimes In The Pacific Northwest, Agricultural And Forest Meteorology, 249(21), 488-500" -US-Me2,1700003099,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2017.08.006 -US-Me2,1700003099,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Me2,1700008604,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Kwon, H., Law, B. E., Thomas, C. K., Johnson, B. G. (2018) The Influence Of Hydrological Variability On Inherent Water Use Efficiency In Forests Of Contrasting Composition, Age, And Precipitation Regimes In The Pacific Northwest, Agricultural And Forest Meteorology, 249(6), 488-500" -US-Me2,1700008604,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2017.08.006 -US-Me2,1700008604,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Me2,1700007167,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Law, B. E., Turner, D., Campbell, J., Lefsky, M., Guzy, M., Sun, O., Tuyl, S. V., Cohen, W. (2006) Carbon Fluxes Across Regions: Observational Constraints At Multiple Scales, Scaling And Uncertainty Analysis In Ecology, 54(6), 167-190" -US-Me2,1700007167,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1007/1-4020-4663-4_9 -US-Me2,1700007167,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Me2,1700000864,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Law, B. E., Turner, D., Campbell, J., Sun, O. J., Van Tuyl, S., Ritts, W. D., Cohen, W. B. (2004) Disturbance And Climate Effects On Carbon Stocks And Fluxes Across Western Oregon USA, Global Change Biology, 10(9), 1429-1444" -US-Me2,1700000864,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/J.1365-2486.2004.00822.X -US-Me2,1700000864,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Me2,1700008445,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Matheny, A. M., Bohrer, G., Stoy, P. C., Baker, I. T., Black, A. T., Desai, A. R., Dietze, M. C., Gough, C. M., Ivanov, V. Y., Jassal, R. S., Novick, K. A., Schäfer, K. V., Verbeeck, H. (2014) Characterizing The Diurnal Patterns of Errors in The Prediction of Evapotranspiration by Several Land-Surface Models: An Nacp Analysis, Journal Of Geophysical Research: Biogeosciences, 119(7), 1458-1473" -US-Me2,1700008445,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/2014JG002623 -US-Me2,1700008445,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Me2,1700005970,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"McDowell, N. G., Bowling, D. R., Bond, B. J., Irvine, J., Law, B. E., Anthoni, P., Ehleringer, J. R. (2004) Response Of The Carbon Isotopic Content Of Ecosystem, Leaf, And Soil Respiration To Meteorological And Physiological Driving Factors In A Pinus Ponderosa Ecosystem, Global Biogeochemical Cycles, 18(1), n/a-n/a" -US-Me2,1700005970,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2003GB002049 -US-Me2,1700005970,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Me2,1700002625,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Novick, K. A., Ficklin, D. L., Stoy, P. C., Williams, C. A., Bohrer, G., Oishi, A., Papuga, S. A., Blanken, P. D., Noormets, A., Sulman, B. N., Scott, R. L., Wang, L., Phillips, R. P. (2016) The Increasing Importance Of Atmospheric Demand For Ecosystem Water And Carbon Fluxes, Nature Climate Change, 6(11), 1023-1027" -US-Me2,1700002625,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1038/NCLIMATE3114 -US-Me2,1700002625,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Me2,1700004044,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Ruehr, N. K., Martin, J. G., Law, B. E. (2012) Effects Of Water Availability On Carbon And Water Exchange In A Young Ponderosa Pine Forest: Above- And Belowground Responses, Agricultural And Forest Meteorology, 164(2), 136-148" -US-Me2,1700004044,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2012.05.015 -US-Me2,1700004044,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Me2,1700005490,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Schmidt, A., Law, B. E., Göckede, M., Hanson, C., Yang, Z., Conley, S. (2016) Bayesian Optimization Of The Community Land Model Simulated Biosphere–Atmosphere Exchange Using Co2observations From A Dense Tower Network And Aircraft Campaigns Over Oregon, Earth Interactions, 20(22), 1-35" -US-Me2,1700005490,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1175/EI-D-16-0011.1 -US-Me2,1700005490,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Me2,1700005457,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Schwarz, P. A., Law, B. E., Williams, M., Irvine, J., Kurpius, M., Moore, D. (2004) Climatic Versus Biotic Constraints On Carbon And Water Fluxes In Seasonally Drought-Affected Ponderosa Pine Ecosystems, Global Biogeochemical Cycles, 18(GB4007), n/a-n/a" -US-Me2,1700005457,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2004GB002234 -US-Me2,1700005457,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Me2,1700001167,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Still, C. J., Rastogi, B., Page, G. F., Griffith, D. M., Sibley, A., Schulze, M., Hawkins, L., Pau, S., Detto, M., Helliker, B. R. (2021) Imaging Canopy Temperature: Shedding (Thermal) Light On Ecosystem Processes, New Phytologist, 230(5), 1746-1753" -US-Me2,1700001167,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/NPH.17321 -US-Me2,1700001167,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Me2,1700001131,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Still, C., Powell, R., Aubrecht, D., Kim, Y., Helliker, B., Roberts, D., Richardson, A. D., Goulden, M. (2019) Thermal Imaging In Plant And Ecosystem Ecology: Applications And Challenges, Ecosphere, 10(6), 074023" -US-Me2,1700001131,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/ECS2.2768 -US-Me2,1700001131,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Me2,1700008205,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Still, C., Powell, R., Aubrecht, D., Kim, Y., Helliker, B., Roberts, D., Richardson, A. D., Goulden, M. (2019) Thermal Imaging In Plant And Ecosystem Ecology: Applications And Challenges, Ecosphere, 10(6), 108350" -US-Me2,1700008205,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/ECS2.2768 -US-Me2,1700008205,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Me2,1700004767,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Sullivan, R. C., Cook, D. R., Ghate, V. P., Kotamarthi, V. R., Feng, Y. (2019) Improved Spatiotemporal Representativeness And Bias Reduction Of Satellite-Based Evapotranspiration Retrievals Via Use Of In Situ Meteorology And Constrained Canopy Surface Resistance, Journal Of Geophysical Research: Biogeosciences, 124(2), 342-352" -US-Me2,1700004767,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018JG004744 -US-Me2,1700004767,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Me2,1700001524,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Sullivan, R. C., Kotamarthi, V. R., Feng, Y. (2019) Recovering Evapotranspiration Trends From Biased CMIP5 Simulations And Sensitivity To Changing Climate Over North America, Journal Of Hydrometeorology, 20(8), 1619-1633" -US-Me2,1700001524,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1175/JHM-D-18-0259.1 -US-Me2,1700001524,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Me2,1700003243,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Sun, O. J., Campbell, J., Law, B. E., Wolf, V. (2004) Dynamics Of Carbon Stocks In Soils And Detritus Across Chronosequences Of Different Forest Types In The Pacific Northwest, USA, Global Change Biology, 10(9), 1470-1481" -US-Me2,1700003243,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/J.1365-2486.2004.00829.X -US-Me2,1700003243,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Me2,1700002445,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Thomas, C. K., Law, B. E., Irvine, J., Martin, J. G., Pettijohn, J. C., Davis, K. J. (2009) Seasonal Hydrology Explains Interannual And Seasonal Variation In Carbon And Water Exchange In A Semiarid Mature Ponderosa Pine Forest In Central Oregon, Journal Of Geophysical Research: Biogeosciences, 114(G4), n/a-n/a" -US-Me2,1700002445,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2009JG001010 -US-Me2,1700002445,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Me2,1700004206,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Treuhaft, R. N., Law, B. E., Asner, G. P. (2004) Forest Attributes From Radar Interferometric Structure And Its Fusion With Optical Remote Sensing, Bioscience, 54(6), 561-571" -US-Me2,1700004206,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1641/0006-3568(2004)054[0561:FAFRIS]2.0.CO;2 -US-Me2,1700004206,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Me2,1700007572,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Turner, D. P., Guzy, M., Lefsky, M. A., Ritts, W. D., Van Tuyl, S., Law, B. E. (2004) Monitoring Forest Carbon Sequestration With Remote Sensing And Carbon Cycle Modeling, Environmental Management, 33(4), 457-466" -US-Me2,1700007572,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1007/S00267-003-9103-8 -US-Me2,1700007572,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Me2,1700003705,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Turner, D. P., Ritts, W. D., Styles, J. M., Yang, Z., Cohen, W. B., Law, B. E., Thornton, P. E. (2006) A Diagnostic Carbon Flux Model To Monitor The Effects Of Disturbance And Interannual Variation In Climate On Regional NEP, Tellus Series B-Chemical and Physical Meteorology, 58(5), 476-490" -US-Me2,1700003705,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/J.1600-0889.2006.00221.X -US-Me2,1700003705,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Me2,1700003165,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Van Tuyl, S., Law, B., Turner, D., Gitelman, A. (2005) Variability In Net Primary Production And Carbon Storage In Biomass Across Oregon Forests—An Assessment Integrating Data From Forest Inventories, Intensive Sites, And Remote Sensing, Forest Ecology And Management, 209(3), 273-291" -US-Me2,1700003165,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.FORECO.2005.02.002 -US-Me2,1700003165,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Me2,1700004347,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Vickers, D., Göckede, M., Law, B. (2010) Uncertainty Estimates For 1-H Averaged Turbulence Fluxes Of Carbon Dioxide, Latent Heat And Sensible Heat, Tellus Series B-Chemical and Physical Meteorology, 62(2), 87-99" -US-Me2,1700004347,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/J.1600-0889.2009.00449.X -US-Me2,1700004347,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Me2,1700003921,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Vickers, D., Irvine, J., Martin, J. G., Law, B. E. (2012) Nocturnal Subcanopy Flow Regimes And Missing Carbon Dioxide, Agricultural And Forest Meteorology, 152(GB4007), 101-108" -US-Me2,1700003921,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2011.09.004 -US-Me2,1700003921,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Me2,1700001278,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Vickers, D., Thomas, C. K., Martin, J. G., Law, B. (2009) Self-Correlation Between Assimilation And Respiration Resulting From Flux Partitioning Of Eddy-Covariance CO2 Fluxes, Agricultural And Forest Meteorology, 149(9), 1552-1555" -US-Me2,1700001278,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2009.03.009 -US-Me2,1700001278,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Me2,1700001950,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Vickers, D., Thomas, C., Law, B. E. (2009) Random And Systematic CO2 Flux Sampling Errors For Tower Measurements Over Forests In The Convective Boundary Layer, Agricultural And Forest Meteorology, 149(1), 73-83" -US-Me2,1700001950,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2008.07.005 -US-Me2,1700001950,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Me2,1700006456,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Vickers, D., Thomas, C., Pettijohn, C., Martin, J.G., Law, B.E. (2012) Five Years Of Carbon Fluxes And Inherent Water-Use Efficiency At Two Semi-Arid Pine Forests With Different Disturbance Histories, Tellus Series B-Chemical and Physical Meteorology, 64(0), 17159-n/a" -US-Me2,1700006456,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.3402/TELLUSB.V64I0.17159 -US-Me2,1700006456,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Me2,1700003882,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Wolf, S., Keenan, T.F., Fisher, J.B., Baldocchi, D.D., Desai, A.R., Richardson, A.D., Scott, R.L., Law, B.E., Litvak, M.E., Brunsell, N.A., Peters, W., van der Laan-Luijkx, I.T. (2016) Warm spring reduced carbon cycle impact of the 2012 US summer drought, Proceedings of the National Academy of Sciences, 113(21), 5880-5885" -US-Me2,1700003882,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1073/PNAS.1519620113 -US-Me2,1700003882,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Me2,1700007239,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Xu, B., Arain, M. A., Black, T. A., Law, B. E., Pastorello, G. Z., Chu, H. (2020) Seasonal Variability Of Forest Sensitivity To Heat And Drought Stresses: A Synthesis Based On Carbon Fluxes From North American Forest Ecosystems, Global Change Biology, 26(2), 901-918" -US-Me2,1700007239,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/GCB.14843 -US-Me2,1700007239,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Me2,1700001014,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Zhang, Q., Ficklin, D. L., Manzoni, S., Wang, L., Way, D., Phillips, R. P., Novick, K. A. (2019) Response Of Ecosystem Intrinsic Water Use Efficiency And Gross Primary Productivity To Rising Vapor Pressure Deficit, Environmental Research Letters, 14(7), 074023" -US-Me2,1700001014,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1088/1748-9326/AB2603 -US-Me2,1700001014,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Me2,12969,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"The research and science objectives of the Metolius Intermediate Pine site are as follows: 1) To quantify how successional stages and management practices in forest ecosystems influence processes controlling net ecosystem exchange of CO2 in varying climatic conditions; 2) Investigate the effects of disturbance processes controlling carbon storage and CO2 and energy exchange with the atmosphere in varying climatic conditions; 3) Measure the effects of disturbance and climate on the CO2 and energy exchange of ponderosa pine forests in the Pacific Northwest; 4) Evaluate the different statistical models for estimating soil surface CO2 efflux from measurements of abiotic factors such as soil temperature and moisture, and nitrogen and carbon in the soil and litter layers; 5) Compare differences in the seasonal patterns of carbon and energy exchange between stands of different ages; 6) Examine the implications of interannual variation of GPP and ecosystem respiration on net ecosystem exchange of CO2 (NEE); 7) Identify patterns in a multiyear record of soil CO2 efflux and ecosystem processes at an AmeriFlux site to generate a parsimonious seasonal model for soil CO2 efflux that has traits of value to the wider research community; 8) Assess the relationship between substrate supply from the canopy and root/rhizosphere respiration. (Anthoni et al. 2002, Schwarz et al. 2004, Irvine et al. 2008)" -US-Me2,19657,GRP_ROOT_BIOMASS,ROOT_BIOMASS_CRS,2034 -US-Me2,19657,GRP_ROOT_BIOMASS,ROOT_BIOMASS_FINE,278 -US-Me2,19657,GRP_ROOT_BIOMASS,ROOT_BIOMASS_TOT,2312 -US-Me2,19657,GRP_ROOT_BIOMASS,ROOT_BIOMASS_UNIT,gC m-2 -US-Me2,19657,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MIN,0 -US-Me2,19657,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MAX,100 -US-Me2,19657,GRP_ROOT_BIOMASS,ROOT_BIOMASS_DATE,2001 -US-Me2,19658,GRP_ROOT_PROD,ROOT_PROD_CRS,45.371155961 -US-Me2,19658,GRP_ROOT_PROD,ROOT_PROD_FINE,166.8 -US-Me2,19658,GRP_ROOT_PROD,ROOT_PROD_UNIT,gC m-2 -US-Me2,19658,GRP_ROOT_PROD,ROOT_PROD_PROFILE_MIN,0 -US-Me2,19658,GRP_ROOT_PROD,ROOT_PROD_PROFILE_MAX,100 -US-Me2,19658,GRP_ROOT_PROD,ROOT_PROD_DATE_START,2001 -US-Me2,19658,GRP_ROOT_PROD,ROOT_PROD_DATE_END,2001 -US-Me2,19619,GRP_SA,SA,56 -US-Me2,19619,GRP_SA,SA_DATE,2001 -US-Me2,19619,GRP_SA,SA_MAX,89 -US-Me2,19624,GRP_SA,SA_DATE,2011 -US-Me2,19624,GRP_SA,SA_MAX,99 -US-Me2,22121,GRP_SA,SA_APPROACH,increment core -US-Me2,22121,GRP_SA,SA_DATE,2014 -US-Me2,22121,GRP_SA,SA_COMMENT,mean age of oldes 10% of trees -US-Me2,22121,GRP_SA,SA_MAX,106 -US-Me2,12970,GRP_SITE_CHAR,TERRAIN,Flat -US-Me2,12970,GRP_SITE_CHAR,ASPECT,FLAT -US-Me2,12970,GRP_SITE_CHAR,WIND_DIRECTION,SW -US-Me2,12970,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,1000 -US-Me2,12970,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,120 -US-Me2,97308,GRP_SITE_DESC,SITE_DESC,"Site Description before Fire (January, 2002 - August, 2020): - -The mean stand age is 71 years old and the stand age of the oldest 10% of trees is about 108 years old. This site is one of the Metolius core cluster sites with different age and disturbance classes and part of the AmeriFlux network. The overstory is almost exclusively composed of ponderosa pine trees (Pinus ponderosa Doug. Ex P. Laws) with a few scattered incense cedars (Calocedrus decurrens (Torr.) Florin) and has a peak leaf area index (LAI) of 2.1 m2 m-2. Tree height is relatively homogeneous at about 18 m, and the mean tree density is approximately 339 trees ha-1 (Irvine et al., 2008). The understory is sparse with an LAI of 0.2 m2 m-2 and primarily composed of bitterbrush (Purshia tridentata (Push) DC.) and greenleaf manzanita (Arctostaphylos patula Greene). Soils at the site are sandy (69%/24%/7% sand/silt/clay at 0–0.2 m depth and 66%/27%/7% at 0.2–0.5 m depth, and 54%/ 35%/11% at 0.5–1.0 m depth), freely draining with a soil depth of approximately 1.5 m (Irvine et al., 2008; Law et al., 2001b; Schwarz et al., 2004). - -Green Ridge Fire: -On August 20, 2020, the Green Ridge Fire burned through Us-Me2. The fire was ignited by lightning on August 16th, and grew rapidly to the east over the first few days driven by strong, downslope (westerly) afternoon winds. Fire behavior and observed fire effects were highly heterogeneous due to the localized wind pattern carrying the flaming head of the fire forward, and the efforts being made by suppression resources to contain the fire. The site experienced the full range of fire effects, from <1 m high surface fire that charred litter and duff and only consumed shrubs and herbaceous material to full tree (>15 m) crown fire that consumed 100% of needles, small limbs, and surface fuels at high intensity, leaving only ash and bare soil post-fire. - -Salvage Logging: -From late March to late April 2021, salvage logging by the landowner occurred at the site. Almost all trees within the flux footprint were logged except a small area with lower burn severity, where sap flow and automatic soil respiration measurements are continued since the fire." -US-Me2,12972,GRP_SITE_FUNDING,SITE_FUNDING,DOE/TCP -US-Me2,19659,GRP_SNAG_MASS,SNAG_MASS,0 -US-Me2,19659,GRP_SNAG_MASS,SNAG_MASS_UNIT,gC m-2 -US-Me2,19659,GRP_SNAG_MASS,SNAG_MASS_DATE,2001 -US-Me2,19732,GRP_SOIL_CHEM,SOIL_CHEM_C_ORG,0.10518518519 -US-Me2,19731,GRP_SOIL_CHEM,SOIL_CHEM_C_ORG,0.18974358974 -US-Me2,19728,GRP_SOIL_CHEM,SOIL_CHEM_C_ORG,0.37192982456 -US-Me2,19732,GRP_SOIL_CHEM,SOIL_CHEM_N_TOT,0.0057037037037 -US-Me2,19731,GRP_SOIL_CHEM,SOIL_CHEM_N_TOT,0.0084615384615 -US-Me2,19728,GRP_SOIL_CHEM,SOIL_CHEM_N_TOT,0.012105263158 -US-Me2,19728,GRP_SOIL_CHEM,SOIL_CHEM_BD,1.14 -US-Me2,19731,GRP_SOIL_CHEM,SOIL_CHEM_BD,1.17 -US-Me2,19732,GRP_SOIL_CHEM,SOIL_CHEM_BD,1.35 -US-Me2,19728,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,0 -US-Me2,19731,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,20 -US-Me2,19732,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,50 -US-Me2,19732,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,100 -US-Me2,19728,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,20 -US-Me2,19731,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,50 -US-Me2,19728,GRP_SOIL_CHEM,SOIL_CHEM_DATE,2001 -US-Me2,19731,GRP_SOIL_CHEM,SOIL_CHEM_DATE,2001 -US-Me2,19732,GRP_SOIL_CHEM,SOIL_CHEM_DATE,2001 -US-Me2,19729,GRP_SOIL_DEPTH,SOIL_DEPTH,90 -US-Me2,19729,GRP_SOIL_DEPTH,SOIL_DEPTH_DATE,2001 -US-Me2,19730,GRP_SOIL_TEX,SOIL_TEX_SAND,67 -US-Me2,19730,GRP_SOIL_TEX,SOIL_TEX_SILT,26 -US-Me2,19730,GRP_SOIL_TEX,SOIL_TEX_CLAY,7 -US-Me2,19730,GRP_SOIL_TEX,SOIL_TEX_DATE,2001 -US-Me2,19620,GRP_SPP_O,SPP_O,Pinus ponderosa -US-Me2,24443,GRP_SPP_O,SPP_O,PIPO (NRCS plant code) -US-Me2,19620,GRP_SPP_O,SPP_O_PERC,100 -US-Me2,19620,GRP_SPP_O,SPP_DATE,2001 -US-Me2,19620,GRP_SPP_O,SPP_COMMENT,Purshia tridentata is a nitrogen fixer -US-Me2,19625,GRP_SPP_U,SPP_U,Arctostaphylos patula -US-Me2,24045,GRP_SPP_U,SPP_U,ARPA6 (NRCS plant code) -US-Me2,19621,GRP_SPP_U,SPP_U,Purshia tridentata -US-Me2,24574,GRP_SPP_U,SPP_U,PUTR2 (NRCS plant code) -US-Me2,19621,GRP_SPP_U,SPP_U_PERC,40 -US-Me2,19625,GRP_SPP_U,SPP_U_PERC,40 -US-Me2,19621,GRP_SPP_U,SPP_DATE,2001 -US-Me2,19625,GRP_SPP_U,SPP_DATE,2001 -US-Me2,19621,GRP_SPP_U,SPP_COMMENT,Purshia tridentata is a nitrogen fixer -US-Me2,12973,GRP_STATE,STATE,OR -US-Me2,19660,GRP_STUMP_MASS,STUMP_MASS,92.54508247 -US-Me2,19660,GRP_STUMP_MASS,STUMP_MASS_UNIT,gC m-2 -US-Me2,19660,GRP_STUMP_MASS,STUMP_MASS_DATE,2001 -US-Me2,98689,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Chad Hanson -US-Me2,98689,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Me2,98689,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,chad.hanson@oregonstate.edu -US-Me2,98689,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Oregon State University -US-Me2,98689,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Department of Forest Ecosystems and Society, 373 Richardson Hall, Corvallis, OR USA 97331" -US-Me2,95912,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Chris Still -US-Me2,95912,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Me2,95912,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,chris.still@oregonstate.edu -US-Me2,95912,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Oregon State University -US-Me2,95912,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Department of Forest Ecosystems and Society, 326 Richardson Hall, Corvallis, OR USA 97331" -US-Me2,95911,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Alex Irving -US-Me2,95911,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Technician -US-Me2,95911,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,Alex.Irving@oregonstate.edu -US-Me2,95911,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Oregon State University -US-Me2,95911,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Department of Forest Ecosystems and Society, 367 Richardson Hall, Corvallis, OR USA 97331" -US-Me2,29825,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-Me2,22211,GRP_TOWER_TYPE,TOWER_TYPE,walk-up -US-Me2,22114,GRP_TREES_NUM,TREES_NUM,334 -US-Me2,22114,GRP_TREES_NUM,TREES_NUM_SPP,(Unknown) -US-Me2,22114,GRP_TREES_NUM,TREES_NUM_APPROACH,"PIPO, AGBR, CADE all > 10 cm dbh" -US-Me2,22114,GRP_TREES_NUM,TREES_NUM_DATE,20140429 -US-Me2,22114,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,71 -US-Me2,79383,GRP_URL,URL,http://terraweb.forestry.oregonstate.edu/metolius-mature-pine-ameriflux-site-us-me2 -US-Me2,24000394,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-Me2 -US-Me2,12976,GRP_UTC_OFFSET,UTC_OFFSET,-8 -US-Me2,19661,GRP_WD_BIOMASS,WD_BIOMASS_CRS,1426 -US-Me2,19661,GRP_WD_BIOMASS,WD_BIOMASS_FINE,382.36 -US-Me2,19661,GRP_WD_BIOMASS,WD_BIOMASS_UNIT,gC m-2 -US-Me2,19661,GRP_WD_BIOMASS,WD_BIOMASS_DATE,2001 -US-Me6,11555,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,"This research was supported by the Office of Science (BER), US Department of Energy (Award DE SC0005322), and a Leopoldina Research Fellowship to NKR (LPDS 2009-37)" -US-Me6,22141,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,116.9 -US-Me6,22141,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_SPATIAL_VARIABILITY,25 -US-Me6,22141,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Foliage -US-Me6,22141,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-Me6,22141,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-Me6,22141,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,20140430 -US-Me6,19673,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,214.8 -US-Me6,19673,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Wood -US-Me6,19673,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-Me6,19673,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-Me6,19673,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2009 -US-Me6,19679,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,265.43 -US-Me6,19679,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Wood -US-Me6,19679,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-Me6,19679,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-Me6,19679,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2010 -US-Me6,19675,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,273.8070206 -US-Me6,19675,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Total -US-Me6,19675,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-Me6,19675,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-Me6,19675,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2009 -US-Me6,19695,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,32.34 -US-Me6,19695,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Wood -US-Me6,19695,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-Me6,19695,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-Me6,19695,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2011 -US-Me6,22140,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,326.7 -US-Me6,22140,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_SPATIAL_VARIABILITY,57.6 -US-Me6,22140,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Branches -US-Me6,22140,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-Me6,22140,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-Me6,22140,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,20140430 -US-Me6,19693,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,330.4221183 -US-Me6,19693,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Total -US-Me6,19693,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-Me6,19693,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-Me6,19693,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2010 -US-Me6,19696,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,397.16796718 -US-Me6,19696,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Total -US-Me6,19696,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-Me6,19696,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-Me6,19696,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2011 -US-Me6,19669,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,59.01 -US-Me6,19669,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Foliage -US-Me6,19669,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-Me6,19669,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-Me6,19669,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2009 -US-Me6,19677,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,64.99 -US-Me6,19677,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Foliage -US-Me6,19677,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-Me6,19677,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-Me6,19677,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2010 -US-Me6,22139,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,689.7 -US-Me6,22139,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_SPATIAL_VARIABILITY,128.1 -US-Me6,22139,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Trunk -US-Me6,22139,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-Me6,22139,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-Me6,22139,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,20140430 -US-Me6,19694,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,71.83 -US-Me6,19694,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Foliage -US-Me6,19694,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-Me6,19694,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-Me6,19694,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2011 -US-Me6,19670,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS,14.746700196 -US-Me6,19670,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_SPATIAL_VARIABILITY,11.606175903 -US-Me6,19670,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_UNIT,gC m-2 -US-Me6,19670,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_DATE,2010 -US-Me6,22138,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT,11.03 -US-Me6,22137,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT,16.17 -US-Me6,19678,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT,3.3826953125 -US-Me6,19680,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT,4.2144097222 -US-Me6,19674,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT,7.64063 -US-Me6,19671,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT,8.09 -US-Me6,22136,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT,8.09 -US-Me6,19676,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT,9.3159722222 -US-Me6,19674,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT_SPATIAL_VARIABILITY,1.3845 -US-Me6,19680,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT_SPATIAL_VARIABILITY,3.6987637703 -US-Me6,19678,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT_SPATIAL_VARIABILITY,4.5839236161 -US-Me6,19676,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT_SPATIAL_VARIABILITY,6.6288764537 -US-Me6,19671,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT_SPATIAL_VARIABILITY,6.64 -US-Me6,22136,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT_SPATIAL_VARIABILITY,6.64 -US-Me6,22137,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT_SPATIAL_VARIABILITY,7.01 -US-Me6,22138,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT_SPATIAL_VARIABILITY,9.28 -US-Me6,19671,GRP_AG_LIT_PROD,AG_LIT_PROD_UNIT,gC m-2 -US-Me6,19674,GRP_AG_LIT_PROD,AG_LIT_PROD_UNIT,gC m-2 -US-Me6,19676,GRP_AG_LIT_PROD,AG_LIT_PROD_UNIT,gC m-2 -US-Me6,19678,GRP_AG_LIT_PROD,AG_LIT_PROD_UNIT,gC m-2 -US-Me6,19680,GRP_AG_LIT_PROD,AG_LIT_PROD_UNIT,gC m-2 -US-Me6,22136,GRP_AG_LIT_PROD,AG_LIT_PROD_UNIT,gC m-2 -US-Me6,22137,GRP_AG_LIT_PROD,AG_LIT_PROD_UNIT,gC m-2 -US-Me6,22138,GRP_AG_LIT_PROD,AG_LIT_PROD_UNIT,gC m-2 -US-Me6,19671,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_START,19600401 -US-Me6,22136,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_START,20101001 -US-Me6,19674,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_START,20110428 -US-Me6,19676,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_START,20120319 -US-Me6,19678,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_START,20130509 -US-Me6,19680,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_START,20130913 -US-Me6,22137,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_START,20131009 -US-Me6,22138,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_START,20140911 -US-Me6,19671,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_END,20110428 -US-Me6,22136,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_END,20110428 -US-Me6,19674,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_END,20120319 -US-Me6,19676,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_END,20130509 -US-Me6,19678,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_END,20130913 -US-Me6,19680,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_END,20131009 -US-Me6,22137,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_END,20140911 -US-Me6,22138,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_END,20141016 -US-Me6,22136,GRP_AG_LIT_PROD,AG_LIT_PROD_COMMENT,start date is October 2010: no specific day -US-Me6,19671,GRP_AG_LIT_PROD,AG_LIT_PROD_COMMENT,unknown start date -US-Me6,19681,GRP_BASAL_AREA,BASAL_AREA,3.48 -US-Me6,19681,GRP_BASAL_AREA,BASAL_AREA_SPP,(Unknown) -US-Me6,19681,GRP_BASAL_AREA,BASAL_AREA_DATE,20100609 -US-Me6,19681,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,0.03 -US-Me6,22126,GRP_BASAL_AREA,BASAL_AREA,4.86 -US-Me6,22126,GRP_BASAL_AREA,BASAL_AREA_SPP,Pinus ponderosa -US-Me6,22126,GRP_BASAL_AREA,BASAL_AREA_DATE,20140327 -US-Me6,22126,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,1.06 -US-Me6,93280,GRP_CLIM_AVG,MAT,7.59 -US-Me6,93280,GRP_CLIM_AVG,MAP,494 -US-Me6,93280,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Csb -US-Me6,27000493,GRP_COUNTRY,COUNTRY,USA -US-Me6,19682,GRP_DBH,DBH,16.1 -US-Me6,19682,GRP_DBH,DBH_SPP,(Unknown) -US-Me6,19682,GRP_DBH,DBH_DATE,20100609 -US-Me6,19682,GRP_DBH,DBH_SPATIAL_VARIABILITY,3.8 -US-Me6,22127,GRP_DBH,DBH,18.7 -US-Me6,22127,GRP_DBH,DBH_SPP,(Unknown) -US-Me6,22127,GRP_DBH,DBH_DATE,20140327 -US-Me6,22127,GRP_DBH,DBH_SPATIAL_VARIABILITY,4.3 -US-Me6,15609,GRP_DOI,DOI,10.17190/AMF/1246128 -US-Me6,15609,GRP_DOI,DOI_CITATION,"Bev Law (2021), AmeriFlux BASE US-Me6 Metolius Young Pine Burn, Ver. 15-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1246128" -US-Me6,15609,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-Me6,32280,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Me6,32280,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Bev Law -US-Me6,32280,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Me6,32280,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,bev.law@oregonstate.edu -US-Me6,32280,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Oregon State University -US-Me6,32282,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Oregon State University -US-Me6,32282,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-Me6,32281,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,DOE LBL -US-Me6,32281,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-Me6,22212,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Forestry -US-Me6,91463,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Me6,91463,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-Me6,91463,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201003 -US-Me6,91463,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Me6,91401,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Me6,91401,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-Me6,91401,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201003 -US-Me6,91401,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Me6,23000493,GRP_HEADER,SITE_NAME,Metolius Young Pine Burn -US-Me6,89139,GRP_HEIGHTC,HEIGHTC,5.2 -US-Me6,89139,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Me6,89139,GRP_HEIGHTC,HEIGHTC_DATE,20100609 -US-Me6,89137,GRP_HEIGHTC,HEIGHTC,6.51 -US-Me6,89137,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Me6,89137,GRP_HEIGHTC,HEIGHTC_APPROACH,laser rangefinder -US-Me6,89137,GRP_HEIGHTC,HEIGHTC_DATE,20140430 -US-Me6,89138,GRP_HEIGHTC,HEIGHTC,0.35 -US-Me6,89138,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Me6,89138,GRP_HEIGHTC,HEIGHTC_APPROACH,laser rangefinder -US-Me6,89138,GRP_HEIGHTC,HEIGHTC_DATE,20140430 -US-Me6,11558,GRP_IGBP,IGBP,ENF -US-Me6,19684,GRP_LAI,LAI_TYPE,LAI -US-Me6,19688,GRP_LAI,LAI_TYPE,LAI -US-Me6,19690,GRP_LAI,LAI_TYPE,LAI -US-Me6,22133,GRP_LAI,LAI_TYPE,LAI -US-Me6,19684,GRP_LAI,LAI_CLUMP,1.29 -US-Me6,19688,GRP_LAI,LAI_CLUMP,1.29 -US-Me6,19684,GRP_LAI,LAI_APPROACH,LAI_2000 -US-Me6,19688,GRP_LAI,LAI_APPROACH,LAI_2000 -US-Me6,19690,GRP_LAI,LAI_APPROACH,LAI_2000 -US-Me6,22133,GRP_LAI,LAI_APPROACH,LAI-2200 -US-Me6,19684,GRP_LAI,LAI_DATE,20101004 -US-Me6,19688,GRP_LAI,LAI_DATE,20130509 -US-Me6,19690,GRP_LAI,LAI_DATE,20130808 -US-Me6,22133,GRP_LAI,LAI_DATE,20140821 -US-Me6,19688,GRP_LAI,LAI_O_EVG,0.8 -US-Me6,19684,GRP_LAI,LAI_O_EVG,0.9 -US-Me6,22133,GRP_LAI,LAI_O_EVG,1.38 -US-Me6,19690,GRP_LAI,LAI_O_EVG,1.6 -US-Me6,22133,GRP_LAI,LAI_O_EVG_SPATIAL_VARIABILITY,0.19 -US-Me6,19688,GRP_LAI,LAI_O_EVG_SPATIAL_VARIABILITY,0.8 -US-Me6,19690,GRP_LAI,LAI_O_EVG_SPATIAL_VARIABILITY,1.2 -US-Me6,11559,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -US-Me6,11560,GRP_LOCATION,LOCATION_LAT,44.3233 -US-Me6,11560,GRP_LOCATION,LOCATION_LONG,-121.6078 -US-Me6,11560,GRP_LOCATION,LOCATION_ELEV,998 -US-Me6,11561,GRP_NETWORK,NETWORK,AmeriFlux -US-Me6,86982,GRP_NETWORK,NETWORK,Phenocam -US-Me6,22124,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,BudBreak -US-Me6,22124,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,Pinus ponderosa -US-Me6,22124,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20100618 -US-Me6,22132,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,BudBreak -US-Me6,22132,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_STATUS,Start -US-Me6,22132,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,Pinus ponderosa -US-Me6,22132,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20140520 -US-Me6,22132,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_UNC,21 -US-Me6,22129,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,Flowering -US-Me6,22129,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_STATUS,Peak -US-Me6,22129,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,Purshia tridentata -US-Me6,22129,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20140520 -US-Me6,22129,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_UNC,20 -US-Me6,22134,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,Total leaf-off -US-Me6,22134,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_STATUS,Start -US-Me6,22134,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,Pinus ponderosa -US-Me6,22134,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20140911 -US-Me6,22134,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_UNC,21 -US-Me6,22135,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,Total leaf-off -US-Me6,22135,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_STATUS,End -US-Me6,22135,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,Pinus ponderosa -US-Me6,22135,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20141016 -US-Me6,22135,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_UNC,7 -US-Me6,1700003639,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Baldocchi, D. D., Poindexter, C., Abraha, M., Desai, A. R., Bohrer, G., Arain, M. A., Griffis, T., Blanken, P. D., O'Halloran, T. L., Thomas, R. Q., Zhang, Q., Burns, S. P., Frank, J. M., Christian, D., Brown, S., Black, T. A., Gough, C. M., Law, B. E., Lee, X., Chen, J., Reed, D. E., Massman, W. J., Clark, K., Hatfield, J., Prueger, J., Bracho, R., Baker, J. M., Martin, T. A. (2018) Temporal Dynamics Of Aerodynamic Canopy Height Derived From Eddy Covariance Momentum Flux Data Across North American Flux Networks, Geophysical Research Letters, 45(21), 9275–9287" -US-Me6,1700003639,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018GL079306 -US-Me6,1700003639,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Me6,1700002358,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(8), 108350" -US-Me6,1700002358,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -US-Me6,1700002358,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Me6,1700008631,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Ruehr, N. K., Law, B. E., Quandt, D., Williams, M. (2014) Effects Of Heat And Drought On Carbon And Water Dynamics In A Regenerating Semi-Arid Pine Forest: A Combined Experimental And Modeling Approach, Biogeosciences, 11(15), 4139-4156" -US-Me6,1700008631,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.5194/BG-11-4139-2014 -US-Me6,1700008631,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Me6,1700003927,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Ruehr, N. K., Martin, J. G., Law, B. E. (2012) Effects Of Water Availability On Carbon And Water Exchange In A Young Ponderosa Pine Forest: Above- And Belowground Responses, Agricultural And Forest Meteorology, 164(2), 136-148" -US-Me6,1700003927,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2012.05.015 -US-Me6,1700003927,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Me6,1700004437,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Ruehr, N. K., Martin, J. G., Law, B. E. (2012) Effects Of Water Availability On Carbon And Water Exchange In A Young Ponderosa Pine Forest: Above- And Belowground Responses, Agricultural And Forest Meteorology, 164(21), 136-148" -US-Me6,1700004437,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2012.05.015 -US-Me6,1700004437,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Primary_Citation -US-Me6,1700006300,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Sullivan, R. C., Cook, D. R., Ghate, V. P., Kotamarthi, V. R., Feng, Y. (2019) Improved Spatiotemporal Representativeness And Bias Reduction Of Satellite-Based Evapotranspiration Retrievals Via Use Of In Situ Meteorology And Constrained Canopy Surface Resistance, Journal Of Geophysical Research: Biogeosciences, 124(2), 342-352" -US-Me6,1700006300,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018JG004744 -US-Me6,1700006300,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Me6,1700002493,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Sullivan, R. C., Kotamarthi, V. R., Feng, Y. (2019) Recovering Evapotranspiration Trends From Biased CMIP5 Simulations And Sensitivity To Changing Climate Over North America, Journal Of Hydrometeorology, 20(8), 1619-1633" -US-Me6,1700002493,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1175/JHM-D-18-0259.1 -US-Me6,1700002493,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Me6,1700008895,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Wolf, S., Keenan, T.F., Fisher, J.B., Baldocchi, D.D., Desai, A.R., Richardson, A.D., Scott, R.L., Law, B.E., Litvak, M.E., Brunsell, N.A., Peters, W., van der Laan-Luijkx, I.T. (2016) Warm spring reduced carbon cycle impact of the 2012 US summer drought, Proceedings of the National Academy of Sciences, 113(21), 5880-5885" -US-Me6,1700008895,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1073/PNAS.1519620113 -US-Me6,1700008895,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Me6,1700002544,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Xu, B., Arain, M. A., Black, T. A., Law, B. E., Pastorello, G. Z., Chu, H. (2020) Seasonal Variability Of Forest Sensitivity To Heat And Drought Stresses: A Synthesis Based On Carbon Fluxes From North American Forest Ecosystems, Global Change Biology, 26(2), 901-918" -US-Me6,1700002544,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/GCB.14843 -US-Me6,1700002544,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Me6,11563,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,The research and science objectives of the Metolius New Young Pine site are as follows: 1) To quantify how successional stages and management practices in forest ecosystems influence processes controlling net ecosystem exchange of CO2 in varying climatic conditions; 2) Investigate the effects of disturbance processes controlling carbon storage and CO2 and energy exchange with the atmosphere in varying climatic conditions; 3) Measure the effects of disturbance and climate on the CO2 and energy exchange of ponderosa pine forests in the Pacific Northwest. -US-Me6,19672,GRP_ROOT_BIOMASS,ROOT_BIOMASS_CRS,43.716090815 -US-Me6,19672,GRP_ROOT_BIOMASS,ROOT_BIOMASS_FINE,171.72845239 -US-Me6,19672,GRP_ROOT_BIOMASS,ROOT_BIOMASS_TOT,215.4445432 -US-Me6,19672,GRP_ROOT_BIOMASS,ROOT_BIOMASS_UNIT,gC m-2 -US-Me6,19672,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MIN,0 -US-Me6,19672,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MAX,100 -US-Me6,19672,GRP_ROOT_BIOMASS,ROOT_BIOMASS_DATE,2010 -US-Me6,19685,GRP_SA,SA,20 -US-Me6,19685,GRP_SA,SA_DATE,2010 -US-Me6,19685,GRP_SA,SA_MAX,20 -US-Me6,22130,GRP_SA,SA_APPROACH,increment core -US-Me6,22130,GRP_SA,SA_DATE,2014 -US-Me6,22130,GRP_SA,SA_COMMENT,mean age of oldest 10% of trees -US-Me6,22130,GRP_SA,SA_MAX,23 -US-Me6,11564,GRP_SITE_CHAR,TERRAIN,Flat -US-Me6,11564,GRP_SITE_CHAR,ASPECT,FLAT -US-Me6,11564,GRP_SITE_CHAR,WIND_DIRECTION,W -US-Me6,11564,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,700 -US-Me6,11565,GRP_SITE_DESC,SITE_DESC,"The study site is located east of the Cascade mountains, near Sisters, Central Oregon and is part of the Metolius cluster sites with different age and disturbance classes within the AmeriFlux network. After a severe fire in 1979, the site was salvage logged, was acquired by the US Forest Service land and re-forested in 1990. The dominant overstory vegetation are 20-year old ponderosa pine trees with an average height of 5.2 +/- 1.1 m. The season maximum overstory half-sided LAI was 0.6 m2 m-2 in 2010. Tree density is low, with ca. 162 trees ha-1." -US-Me6,15600,GRP_SITE_FUNDING,SITE_FUNDING,DOE LBL -US-Me6,19723,GRP_SOIL_CHEM,SOIL_CHEM_BD,1.31 -US-Me6,19726,GRP_SOIL_CHEM,SOIL_CHEM_BD,1.45 -US-Me6,19727,GRP_SOIL_CHEM,SOIL_CHEM_BD,1.5 -US-Me6,19726,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,27 -US-Me6,19727,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,47 -US-Me6,19723,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,7 -US-Me6,19723,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,13 -US-Me6,19726,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,33 -US-Me6,19727,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,53 -US-Me6,19723,GRP_SOIL_CHEM,SOIL_CHEM_DATE,2004 -US-Me6,19726,GRP_SOIL_CHEM,SOIL_CHEM_DATE,2004 -US-Me6,19727,GRP_SOIL_CHEM,SOIL_CHEM_DATE,2004 -US-Me6,19724,GRP_SOIL_STOCK,SOIL_STOCK_C_ORG,3977.4 -US-Me6,19724,GRP_SOIL_STOCK,SOIL_STOCK_N_TOT,140.225 -US-Me6,19724,GRP_SOIL_STOCK,SOIL_STOCK_PROFILE_MIN,0 -US-Me6,19724,GRP_SOIL_STOCK,SOIL_STOCK_PROFILE_MAX,20 -US-Me6,19724,GRP_SOIL_STOCK,SOIL_STOCK_DATE,20100701 -US-Me6,19725,GRP_SOIL_TEX,SOIL_TEX_SAND,80.341666667 -US-Me6,19725,GRP_SOIL_TEX,SOIL_TEX_SILT,16.858333333 -US-Me6,19725,GRP_SOIL_TEX,SOIL_TEX_CLAY,2.875 -US-Me6,19725,GRP_SOIL_TEX,SOIL_TEX_DATE,20100701 -US-Me6,19686,GRP_SPP_O,SPP_O,Pinus ponderosa -US-Me6,19686,GRP_SPP_O,SPP_O_PERC,100 -US-Me6,19686,GRP_SPP_O,SPP_APPROACH,visual estimate -US-Me6,19686,GRP_SPP_O,SPP_DATE,2010 -US-Me6,19691,GRP_SPP_U,SPP_U,Arctostaphylos patula -US-Me6,19692,GRP_SPP_U,SPP_U,Ericameria nauseosa -US-Me6,19687,GRP_SPP_U,SPP_U,grass -US-Me6,19689,GRP_SPP_U,SPP_U,Purschia tridentata -US-Me6,19691,GRP_SPP_U,SPP_U_PERC,1 -US-Me6,19689,GRP_SPP_U,SPP_U_PERC,12 -US-Me6,19687,GRP_SPP_U,SPP_U_PERC,13 -US-Me6,19692,GRP_SPP_U,SPP_U_PERC,3 -US-Me6,19687,GRP_SPP_U,SPP_APPROACH,visual estimate -US-Me6,19689,GRP_SPP_U,SPP_APPROACH,visual estimate -US-Me6,19691,GRP_SPP_U,SPP_APPROACH,visual estimate -US-Me6,19692,GRP_SPP_U,SPP_APPROACH,visual estimate -US-Me6,19687,GRP_SPP_U,SPP_DATE,2010 -US-Me6,19689,GRP_SPP_U,SPP_DATE,2010 -US-Me6,19691,GRP_SPP_U,SPP_DATE,2010 -US-Me6,19692,GRP_SPP_U,SPP_DATE,2010 -US-Me6,11566,GRP_STATE,STATE,OR -US-Me6,11567,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Bev Law -US-Me6,11567,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Me6,11567,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,bev.law@oregonstate.edu -US-Me6,11567,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Oregon State University -US-Me6,11567,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Department of Forest Ecosystems and Society, 321 Richardson Hall,Corvallis, OR USA 97331" -US-Me6,95910,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Chris Still -US-Me6,95910,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Me6,95910,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,chris.still@oregonstate.edu -US-Me6,95910,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Oregon State University -US-Me6,95910,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Department of Forest Ecosystems and Society, 326 Richardson Hall, Corvallis, OR USA 97331" -US-Me6,91368,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Chad Hanson -US-Me6,91368,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,DataManager -US-Me6,91368,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,chad.hanson@oregonstate.edu -US-Me6,91368,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Oregon State University -US-Me6,91368,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Department of Forest Ecosystems and Society, 373 Richardson Hall, Corvallis, OR USA 97331" -US-Me6,95909,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Alex Irving -US-Me6,95909,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Technician -US-Me6,95909,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,Alex.Irving@oregonstate.edu -US-Me6,95909,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Oregon State University -US-Me6,95909,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Department of Forest Ecosystems and Society, 367 Richardson Hall, Corvallis, OR USA 97331" -US-Me6,29852,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-Me6,22213,GRP_TOWER_TYPE,TOWER_TYPE,triangle -US-Me6,22125,GRP_TREES_NUM,TREES_NUM,168 -US-Me6,22125,GRP_TREES_NUM,TREES_NUM_SPP,(Unknown) -US-Me6,22125,GRP_TREES_NUM,TREES_NUM_DATE,20140327 -US-Me6,22125,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,53 -US-Me6,22131,GRP_TREES_NUM,TREES_NUM,168 -US-Me6,22131,GRP_TREES_NUM,TREES_NUM_SPP,(Unknown) -US-Me6,22131,GRP_TREES_NUM,TREES_NUM_DATE,19600401 -US-Me6,22131,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,53 -US-Me6,79384,GRP_URL,URL,http://terraweb.forestry.oregonstate.edu/metolius-young-pine-burn-ameriflux-site-us-me6 -US-Me6,24000493,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-Me6 -US-Me6,88165,GRP_UTC_OFFSET,UTC_OFFSET,-8 -US-Men,33580,GRP_CLIM_AVG,MAT,7.94 -US-Men,33580,GRP_CLIM_AVG,MAP,875 -US-Men,33580,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfa -US-Men,27000937,GRP_COUNTRY,COUNTRY,USA -US-Men,81464,GRP_DOI,DOI,10.17190/AMF/1433375 -US-Men,81464,GRP_DOI,DOI_CITATION,"Ankur Desai (2018), AmeriFlux BASE US-Men Lake Mendota, Center for Limnology Site, Ver. 3-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1433375" -US-Men,81464,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-Men,81324,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Men,81324,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Ankur Desai -US-Men,81324,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Men,81324,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,desai@aos.wisc.edu -US-Men,81324,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of Wisconsin Madison -US-Men,81326,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,University of Wisconsin Madison -US-Men,81326,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-Men,91395,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Men,91395,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-Men,91395,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201201010000 -US-Men,91395,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20180726 -US-Men,91395,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Men,91341,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Men,91341,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-Men,91341,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201201010000 -US-Men,91341,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20180726 -US-Men,91341,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Men,91450,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Men,91450,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-Men,91450,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201201010000 -US-Men,91450,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20180726 -US-Men,91450,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Men,23000937,GRP_HEADER,SITE_NAME,"Lake Mendota, Center for Limnology Site" -US-Men,33584,GRP_IGBP,IGBP,WAT -US-Men,33584,GRP_IGBP,IGBP_DATE_START,201201010000 -US-Men,33585,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-Men,33585,GRP_LAND_OWNERSHIP,LAND_OWNER,Land owned by UW-Madison -US-Men,33586,GRP_LOCATION,LOCATION_LAT,43.0772 -US-Men,33586,GRP_LOCATION,LOCATION_LONG,-89.4030 -US-Men,33586,GRP_LOCATION,LOCATION_ELEV,260 -US-Men,33587,GRP_NETWORK,NETWORK,AmeriFlux -US-Men,1700005964,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"David E. Reed, Hilary A. Dugan, Amelia L. Flannery, Ankur R. Desai (2018) Carbon Sink And Source Dynamics Of A Eutrophic Deep Lake Using Multiple Flux Observations Over Multiple Years, Limnology And Oceanography Letters, (), " -US-Men,1700005964,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/LOL2.10075 -US-Men,1700005964,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Men,1700003558,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"David E. Reed, Hilary A. Dugan, Amelia L. Flannery, Ankur R. Desai (2018) Carbon Sink And Source Dynamics Of A Eutrophic Deep Lake Using Multiple Flux Observations Over Multiple Years, Limnology And Oceanography Letters, 36(4), 527-534" -US-Men,1700003558,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/LOL2.10075 -US-Men,1700003558,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Men,1700000843,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Reed, D. E., Desai, A. R., Whitaker, E. C., Nuckles, H. (2019) Evaluation Of Low-Cost, Automated Lake Ice Thickness Measurements, Journal Of Atmospheric And Oceanic Technology, 36(4), 527-534" -US-Men,1700000843,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1175/JTECH-D-18-0214.1 -US-Men,1700000843,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Men,33588,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,Lake/Atmosphere flux study -US-Men,33589,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"1225 W Dayton St, Madison, WI 53706" -US-Men,33590,GRP_SITE_CHAR,TERRAIN,Flat -US-Men,33590,GRP_SITE_CHAR,ASPECT,FLAT -US-Men,33590,GRP_SITE_CHAR,WIND_DIRECTION,S -US-Men,33591,GRP_SITE_DESC,SITE_DESC,The site is located on the shoreline of Lake Mendota on the rooftop of UW-Madison's Center for Limnology. -US-Men,95087,GRP_SITE_FUNDING,SITE_FUNDING,NSF DEB-1440297 -US-Men,33592,GRP_STATE,STATE,WI -US-Men,33595,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Ankur Desai -US-Men,33595,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Men,33595,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,desai@aos.wisc.edu -US-Men,33595,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Wisconsin Madison -US-Men,33593,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,David Reed -US-Men,33593,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-Men,33593,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,david.edwin.reed@gmail.com -US-Men,33594,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Jonathan Thom -US-Men,33594,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,DataManager -US-Men,33594,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,jthom@ssec.wisc.edu -US-Men,33598,GRP_TOWER_POWER,TOWER_POWER,Direct power -US-Men,33596,GRP_TOWER_TYPE,TOWER_TYPE,other -US-Men,33597,GRP_URL,URL,http://flux.aos.wisc.edu/data/ -US-Men,24000937,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-Men -US-Men,81403,GRP_UTC_OFFSET,UTC_OFFSET,-6 -US-MH1,91087,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,We acknowledge support from Montana State University College of Agriculture -US-MH1,91089,GRP_CLIM_AVG,MAT,8.9 -US-MH1,91089,GRP_CLIM_AVG,MAP,347 -US-MH1,91089,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Bsk -US-MH1,27001124,GRP_COUNTRY,COUNTRY,USA -US-MH1,93752,GRP_DOI,DOI,10.17190/AMF/1660349 -US-MH1,93752,GRP_DOI,DOI_CITATION,"Paul Stoy (2020), AmeriFlux BASE US-MH1 Huntley, Montana irrigated barley site 1, Ver. 1-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1660349" -US-MH1,93752,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-MH1,93711,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-MH1,93711,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Paul Stoy -US-MH1,93711,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-MH1,93711,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,pcstoy@wisc.edu -US-MH1,93711,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of Wisconsin -US-MH1,93736,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,University of Wisconsin -US-MH1,93736,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-MH1,93717,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Montana State University College of Agriculture -US-MH1,93717,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-MH1,91073,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Agriculture -US-MH1,91074,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-MH1,91074,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-MH1,91074,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201505010000 -US-MH1,91074,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,201508110000 -US-MH1,91074,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Periodic operation -US-MH1,91088,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-MH1,91088,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-MH1,91088,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201505010000 -US-MH1,91088,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,201508110000 -US-MH1,91088,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Periodic operation -US-MH1,91082,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-MH1,91082,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-MH1,91082,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201505010000 -US-MH1,91082,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,201508110000 -US-MH1,91082,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Periodic operation -US-MH1,23001124,GRP_HEADER,SITE_NAME,"Huntley, Montana irrigated barley site 1" -US-MH1,91090,GRP_IGBP,IGBP,CRO -US-MH1,91091,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-MH1,91091,GRP_LAND_OWNERSHIP,LAND_OWNER,Montana State University College of Agriculture -US-MH1,91079,GRP_LOCATION,LOCATION_LAT,45.9206 -US-MH1,91079,GRP_LOCATION,LOCATION_LONG,-108.2414 -US-MH1,91079,GRP_LOCATION,LOCATION_ELEV,919.6 -US-MH1,91079,GRP_LOCATION,LOCATION_DATE_START,201505010000 -US-MH1,91081,GRP_NETWORK,NETWORK,AmeriFlux -US-MH1,91085,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"irrigation, agriculture" -US-MH1,91092,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"540 Elm Drive, University of Wisconsin – Madison, Madison, WI 53706" -US-MH1,91084,GRP_SITE_CHAR,TERRAIN,Flat -US-MH1,91084,GRP_SITE_CHAR,ASPECT,FLAT -US-MH1,91084,GRP_SITE_CHAR,WIND_DIRECTION,SW -US-MH1,91084,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,130 -US-MH1,91076,GRP_SITE_DESC,SITE_DESC,flood-irrigated barley field -US-MH1,91083,GRP_SITE_FUNDING,SITE_FUNDING,Montana State University College of Agriculture -US-MH1,91086,GRP_STATE,STATE,MT -US-MH1,91080,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Paul Stoy -US-MH1,91080,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-MH1,91080,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,pcstoy@wisc.edu -US-MH1,91080,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Wisconsin -US-MH1,91080,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"460 Henry Mall, University of Wisconsin – Madison, Madison, WI 53706" -US-MH1,91271,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Kent McVay -US-MH1,91271,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,AncContact -US-MH1,91271,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,kent.mcvay@montana.edu -US-MH1,91075,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-MH1,91077,GRP_TOWER_TYPE,TOWER_TYPE,tripod -US-MH1,24001124,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-MH1 -US-MH1,91078,GRP_UTC_OFFSET,UTC_OFFSET,-7 -US-MH1,91078,GRP_UTC_OFFSET,UTC_OFFSET_DATE_START,201505010000 -US-MH2,91097,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,We acknowledge support from Montana State University College of Agriculture and the Montana Wheat and Barley Committee -US-MH2,91102,GRP_CLIM_AVG,MAT,8.9 -US-MH2,91102,GRP_CLIM_AVG,MAP,347 -US-MH2,91102,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Bsk -US-MH2,27001125,GRP_COUNTRY,COUNTRY,USA -US-MH2,98496,GRP_DOI,DOI,10.17190/AMF/1825938 -US-MH2,98496,GRP_DOI,DOI_CITATION,"Paul Stoy (2021), AmeriFlux BASE US-MH2 Huntley, Montana irrigated barley site 2, Ver. 1-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1825938" -US-MH2,98496,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-MH2,98474,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-MH2,98474,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Paul Stoy -US-MH2,98474,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-MH2,98474,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,pcstoy@wisc.edu -US-MH2,98474,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of Wisconsin -US-MH2,98491,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,University of Wisconsin -US-MH2,98491,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-MH2,98485,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,"Montana Wheat and Barley Committee, Montana State University College of Agriculture" -US-MH2,98485,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-MH2,91101,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Agriculture -US-MH2,91107,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-MH2,91107,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-MH2,91107,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201603240000 -US-MH2,91107,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,201608120000 -US-MH2,91107,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Periodic operation -US-MH2,91094,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-MH2,91094,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-MH2,91094,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201603240000 -US-MH2,91094,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,201608120000 -US-MH2,91094,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Periodic operation -US-MH2,91104,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-MH2,91104,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-MH2,91104,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201603240000 -US-MH2,91104,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,201608120000 -US-MH2,91104,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Periodic operation -US-MH2,23001125,GRP_HEADER,SITE_NAME,"Huntley, Montana irrigated barley site 2" -US-MH2,91099,GRP_IGBP,IGBP,CRO -US-MH2,91098,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -US-MH2,91098,GRP_LAND_OWNERSHIP,LAND_OWNER,Montana State University College of Agriculture -US-MH2,91103,GRP_LOCATION,LOCATION_LAT,45.9699 -US-MH2,91103,GRP_LOCATION,LOCATION_LONG,-108.1978 -US-MH2,91103,GRP_LOCATION,LOCATION_ELEV,891 -US-MH2,91103,GRP_LOCATION,LOCATION_DATE_START,201603240000 -US-MH2,91093,GRP_NETWORK,NETWORK,AmeriFlux -US-MH2,91100,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"irrigation, agriculture" -US-MH2,91095,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"540 Elm Drive, University of Wisconsin – Madison, Madison, WI 53706" -US-MH2,91106,GRP_SITE_CHAR,TERRAIN,Flat -US-MH2,91106,GRP_SITE_CHAR,ASPECT,FLAT -US-MH2,91106,GRP_SITE_CHAR,WIND_DIRECTION,SW -US-MH2,91106,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,130 -US-MH2,91111,GRP_SITE_DESC,SITE_DESC,flood-irrigated barley field -US-MH2,91109,GRP_SITE_FUNDING,SITE_FUNDING,"Montana Wheat and Barley Committee, Montana State University College of Agriculture" -US-MH2,91112,GRP_STATE,STATE,MT -US-MH2,91096,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Paul Stoy -US-MH2,91096,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-MH2,91096,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,pcstoy@wisc.edu -US-MH2,91096,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Wisconsin -US-MH2,91096,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"460 Henry Mall, University of Wisconsin – Madison, Madison, WI 53706" -US-MH2,91272,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Kent McVay -US-MH2,91272,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,AncContact -US-MH2,91272,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,kent.mcvay@montana.edu -US-MH2,91105,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-MH2,91110,GRP_TOWER_TYPE,TOWER_TYPE,tripod -US-MH2,24001125,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-MH2 -US-MH2,91108,GRP_UTC_OFFSET,UTC_OFFSET,-7 -US-MH2,91108,GRP_UTC_OFFSET,UTC_OFFSET_DATE_START,201505010000 -US-Mi1,98832,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,This research was a contribution from the Long-Term Agroecosystem Research (LTAR) network. LTAR is supported by the United States Department of Agriculture. -US-Mi1,98824,GRP_CLIM_AVG,MAT,10.5 -US-Mi1,98824,GRP_CLIM_AVG,MAP,1012.7 -US-Mi1,98824,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfb -US-Mi1,27001214,GRP_COUNTRY,COUNTRY,USA -US-Mi1,99509,GRP_DOI,DOI,10.17190/AMF/1865479 -US-Mi1,99509,GRP_DOI,DOI_CITATION,"Sarah Goslee (2022), AmeriFlux BASE US-Mi1 LTAR UCB (Upper Chesapeake Bay) Miscanthus 1, Ver. 1-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1865479" -US-Mi1,99509,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-Mi1,99489,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Mi1,99489,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Sarah Goslee -US-Mi1,99489,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Mi1,99489,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,sarah.goslee@usda.gov -US-Mi1,99489,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,USDA ARS Pasture Sytems and Watershed Management Research Unit -US-Mi1,99506,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,USDA ARS Pasture Sytems and Watershed Management Research Unit -US-Mi1,99506,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-Mi1,99491,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,USDA ARS -US-Mi1,99491,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-Mi1,98829,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Agriculture -US-Mi1,98815,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Mi1,98815,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-Mi1,98815,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201506241300 -US-Mi1,98815,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,201912290300 -US-Mi1,98815,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Mi1,98835,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Mi1,98835,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-Mi1,98835,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201506241300 -US-Mi1,98835,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,201912290300 -US-Mi1,98835,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Mi1,23001214,GRP_HEADER,SITE_NAME,LTAR UCB (Upper Chesapeake Bay) Miscanthus 1 -US-Mi1,98827,GRP_IGBP,IGBP,CVM -US-Mi1,98827,GRP_IGBP,IGBP_COMMENT,"Land has been privately owned, no records exist as to when crop land was cleared in landscape." -US-Mi1,98821,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -US-Mi1,98817,GRP_LOCATION,LOCATION_LAT,41.7727 -US-Mi1,98817,GRP_LOCATION,LOCATION_LONG,-80.6313 -US-Mi1,98817,GRP_LOCATION,LOCATION_ELEV,290 -US-Mi1,98817,GRP_LOCATION,LOCATION_DATE_START,201506241300 -US-Mi1,98823,GRP_NETWORK,NETWORK,AmeriFlux -US-Mi1,98820,GRP_NETWORK,NETWORK,LTAR -US-Mi1,98834,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,Carbon sequestration of Miscanthus × giganteus -US-Mi1,98826,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"Curtin Rd, Building 3702, University Park, PA 16802" -US-Mi1,98833,GRP_SITE_CHAR,TERRAIN,Gentle slope (<2 %) -US-Mi1,98833,GRP_SITE_CHAR,ASPECT,NW -US-Mi1,98833,GRP_SITE_CHAR,WIND_DIRECTION,SW -US-Mi1,98833,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,350 -US-Mi1,98833,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,36 -US-Mi1,98818,GRP_SITE_DESC,SITE_DESC,"This Farm was a privately owned farm in Ohio Leased to Aloterra Energy Corporation out of Texas, The crop was Miscanthus grown continually originally for alternative Ethanol production but eventually for fiber as absorbant material. Miscanthus grows upwards of 15 ft tall each year." -US-Mi1,98830,GRP_SITE_FUNDING,SITE_FUNDING,USDA ARS -US-Mi1,98814,GRP_STATE,STATE,OH -US-Mi1,98825,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Sarah Goslee -US-Mi1,98825,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Mi1,98825,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,sarah.goslee@usda.gov -US-Mi1,98825,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,USDA ARS Pasture Sytems and Watershed Management Research Unit -US-Mi1,98828,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Dan Arthur -US-Mi1,98828,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,DataManager -US-Mi1,98828,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,dan.arthur@usda.gov -US-Mi1,98828,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,USDA ARS Pasture Sytems and Watershed Management Research Unit -US-Mi1,98831,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Jeffery Gonet -US-Mi1,98831,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Technician -US-Mi1,98831,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,jeffery.gonet@usda.gov -US-Mi1,98831,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,USDA ARS Pasture Sytems and Watershed Management Research Unit -US-Mi1,98831,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Curtin Rd, Building 3702, University Park, PA 16802" -US-Mi1,98816,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-Mi1,98819,GRP_TOWER_TYPE,TOWER_TYPE,triangle -US-Mi1,24001214,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-Mi1 -US-Mi1,98822,GRP_UTC_OFFSET,UTC_OFFSET,-5 -US-Mi2,98838,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,This research was a contribution from the Long-Term Agroecosystem Research (LTAR) network. LTAR is supported by the United States Department of Agriculture. -US-Mi2,98846,GRP_CLIM_AVG,MAT,10.5 -US-Mi2,98846,GRP_CLIM_AVG,MAP,1012.7 -US-Mi2,98846,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfb -US-Mi2,27001215,GRP_COUNTRY,COUNTRY,USA -US-Mi2,99517,GRP_DOI,DOI,10.17190/AMF/1865480 -US-Mi2,99517,GRP_DOI,DOI_CITATION,"Sarah Goslee (2022), AmeriFlux BASE US-Mi2 LTAR UCB (Upper Chesapeake Bay) Miscanthus 2, Ver. 1-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1865480" -US-Mi2,99517,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-Mi2,99487,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Mi2,99487,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Sarah Goslee -US-Mi2,99487,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Mi2,99487,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,sarah.goslee@usda.gov -US-Mi2,99487,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,USDA ARS Pasture Sytems and Watershed Management Research Unit -US-Mi2,99508,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,USDA ARS Pasture Sytems and Watershed Management Research Unit -US-Mi2,99508,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-Mi2,99492,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,USDA ARS -US-Mi2,99492,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-Mi2,98854,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Agriculture -US-Mi2,98845,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Mi2,98845,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-Mi2,98845,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201506241630 -US-Mi2,98845,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,201704300500 -US-Mi2,98845,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Mi2,98853,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Mi2,98853,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-Mi2,98853,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201506241630 -US-Mi2,98853,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,201704300500 -US-Mi2,98853,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Mi2,23001215,GRP_HEADER,SITE_NAME,LTAR UCB (Upper Chesapeake Bay) Miscanthus 2 -US-Mi2,98848,GRP_IGBP,IGBP,CVM -US-Mi2,98848,GRP_IGBP,IGBP_COMMENT,"Land has been privately owned, no records exist as to when crop land was cleared in landscape." -US-Mi2,98855,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -US-Mi2,98836,GRP_LOCATION,LOCATION_LAT,41.5479 -US-Mi2,98836,GRP_LOCATION,LOCATION_LONG,-80.8550 -US-Mi2,98836,GRP_LOCATION,LOCATION_ELEV,280 -US-Mi2,98836,GRP_LOCATION,LOCATION_DATE_START,201506241630 -US-Mi2,98841,GRP_NETWORK,NETWORK,AmeriFlux -US-Mi2,98844,GRP_NETWORK,NETWORK,LTAR -US-Mi2,98837,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,Carbon sequestration of Miscanthus × giganteus -US-Mi2,98847,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"Curtin Rd, Building 3702, University Park, PA 16802" -US-Mi2,98842,GRP_SITE_CHAR,TERRAIN,Gentle slope (<2 %) -US-Mi2,98842,GRP_SITE_CHAR,ASPECT,NW -US-Mi2,98842,GRP_SITE_CHAR,WIND_DIRECTION,SW -US-Mi2,98842,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,300 -US-Mi2,98842,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,36 -US-Mi2,98843,GRP_SITE_DESC,SITE_DESC,"This Farm was a privately owned farm in Ohio Leased to Aloterra Energy Corporation out of Texas, The crop was Miscanthus grown continually originally for alternative Ethanol production but eventually for fiber as absorbant material. Miscanthus grows upwards of 15 ft tall each year." -US-Mi2,98839,GRP_SITE_FUNDING,SITE_FUNDING,USDA ARS -US-Mi2,98852,GRP_STATE,STATE,OH -US-Mi2,98849,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Sarah Goslee -US-Mi2,98849,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Mi2,98849,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,sarah.goslee@usda.gov -US-Mi2,98849,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,USDA ARS Pasture Sytems and Watershed Management Research Unit -US-Mi2,98851,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Dan Arthur -US-Mi2,98851,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,DataManager -US-Mi2,98851,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,dan.arthur@usda.gov -US-Mi2,98851,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,USDA ARS Pasture Sytems and Watershed Management Research Unit -US-Mi2,98840,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Jeffery Gonet -US-Mi2,98840,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Technician -US-Mi2,98840,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,jeffery.gonet@usda.gov -US-Mi2,98840,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,USDA ARS Pasture Sytems and Watershed Management Research Unit -US-Mi2,98840,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Curtin Rd, Building 3702, University Park, PA 16802" -US-Mi2,98856,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-Mi2,98857,GRP_TOWER_TYPE,TOWER_TYPE,triangle -US-Mi2,24001215,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-Mi2 -US-Mi2,98850,GRP_UTC_OFFSET,UTC_OFFSET,-5 -US-Mi3,98870,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,This research was a contribution from the Long-Term Agroecosystem Research (LTAR) network. LTAR is supported by the United States Department of Agriculture. -US-Mi3,98871,GRP_CLIM_AVG,MAT,10.5 -US-Mi3,98871,GRP_CLIM_AVG,MAP,1012.7 -US-Mi3,98871,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfb -US-Mi3,27001216,GRP_COUNTRY,COUNTRY,USA -US-Mi3,99510,GRP_DOI,DOI,10.17190/AMF/1865481 -US-Mi3,99510,GRP_DOI,DOI_CITATION,"Sarah Goslee (2022), AmeriFlux BASE US-Mi3 LTAR UCB (Upper Chesapeake Bay) Miscanthus 3, Ver. 1-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1865481" -US-Mi3,99510,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-Mi3,99482,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Mi3,99482,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Sarah Goslee -US-Mi3,99482,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Mi3,99482,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,sarah.goslee@usda.gov -US-Mi3,99482,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,USDA ARS Pasture Sytems and Watershed Management Research Unit -US-Mi3,99507,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,USDA ARS Pasture Sytems and Watershed Management Research Unit -US-Mi3,99507,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-Mi3,99493,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,USDA ARS -US-Mi3,99493,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-Mi3,98872,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Agriculture -US-Mi3,98863,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Mi3,98863,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-Mi3,98863,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201506241000 -US-Mi3,98863,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,201912272300 -US-Mi3,98863,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Mi3,98875,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Mi3,98875,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-Mi3,98875,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201506241000 -US-Mi3,98875,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,201912272300 -US-Mi3,98875,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Mi3,23001216,GRP_HEADER,SITE_NAME,LTAR UCB (Upper Chesapeake Bay) Miscanthus 3 -US-Mi3,98874,GRP_IGBP,IGBP,CVM -US-Mi3,98874,GRP_IGBP,IGBP_COMMENT,"Land has been privately owned, no records exist as to when crop land was cleared in landscape." -US-Mi3,98860,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -US-Mi3,98866,GRP_LOCATION,LOCATION_LAT,41.8222 -US-Mi3,98866,GRP_LOCATION,LOCATION_LONG,-80.6370 -US-Mi3,98866,GRP_LOCATION,LOCATION_ELEV,270 -US-Mi3,98866,GRP_LOCATION,LOCATION_DATE_START,201506241000 -US-Mi3,98873,GRP_NETWORK,NETWORK,AmeriFlux -US-Mi3,98862,GRP_NETWORK,NETWORK,LTAR -US-Mi3,98868,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,Carbon sequestration of Miscanthus × giganteus -US-Mi3,98859,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"Curtin Rd, Building 3702, University Park, PA 16802" -US-Mi3,98865,GRP_SITE_CHAR,TERRAIN,Gentle slope (<2 %) -US-Mi3,98865,GRP_SITE_CHAR,ASPECT,NW -US-Mi3,98865,GRP_SITE_CHAR,WIND_DIRECTION,SW -US-Mi3,98865,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,150 -US-Mi3,98865,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,36 -US-Mi3,98867,GRP_SITE_DESC,SITE_DESC,"This Farm was a privately owned farm in Ohio Leased to Aloterra Energy Corporation out of Texas, The crop was Miscanthus grown continually originally for alternative Ethanol production but eventually for fiber as absorbant material. Miscanthus grows upwards of 15 ft tall each year." -US-Mi3,98876,GRP_SITE_FUNDING,SITE_FUNDING,USDA ARS -US-Mi3,98858,GRP_STATE,STATE,OH -US-Mi3,98877,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Sarah Goslee -US-Mi3,98877,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Mi3,98877,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,sarah.goslee@usda.gov -US-Mi3,98877,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,USDA ARS Pasture Sytems and Watershed Management Research Unit -US-Mi3,98864,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Dan Arthur -US-Mi3,98864,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,DataManager -US-Mi3,98864,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,dan.arthur@usda.gov -US-Mi3,98864,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,USDA ARS Pasture Sytems and Watershed Management Research Unit -US-Mi3,98879,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Jeffery Gonet -US-Mi3,98879,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Technician -US-Mi3,98879,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,jeffery.gonet@usda.gov -US-Mi3,98879,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,USDA ARS Pasture Sytems and Watershed Management Research Unit -US-Mi3,98879,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Curtin Rd, Building 3702, University Park, PA 16802" -US-Mi3,98869,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-Mi3,98861,GRP_TOWER_TYPE,TOWER_TYPE,triangle -US-Mi3,24001216,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-Mi3 -US-Mi3,98878,GRP_UTC_OFFSET,UTC_OFFSET,-5 -US-Mj1,29747,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,"Work was supported by the MT Wheat & Barley Committee, USDA NIFA Hatch project 228396, & NSF DEB 1552976." -US-Mj1,29748,GRP_CLIM_AVG,MAT,6.6 -US-Mj1,29748,GRP_CLIM_AVG,MAP,388 -US-Mj1,29748,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Bsk -US-Mj1,27000679,GRP_COUNTRY,COUNTRY,USA -US-Mj1,91702,GRP_DOI,DOI,10.17190/AMF/1617715 -US-Mj1,91702,GRP_DOI,DOI_CITATION,"Paul C. Stoy (2020), AmeriFlux BASE US-Mj1 Montana Judith Basin wheat field, Ver. 1-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1617715" -US-Mj1,91702,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-Mj1,91535,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Mj1,91535,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Paul C. Stoy -US-Mj1,91535,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Mj1,91535,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,paul.stoy@montana.edu -US-Mj1,91535,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Montana State University -US-Mj1,91654,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Montana State University -US-Mj1,91654,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-Mj1,91618,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Montana Wheat and Barley Committee -US-Mj1,91618,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-Mj1,29749,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Agriculture -US-Mj1,29750,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Mj1,29750,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-Mj1,29750,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201301010030 -US-Mj1,29750,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,201412312330 -US-Mj1,29750,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Growing season operation only -US-Mj1,29750,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,LiCor 7500 & CSAT-3 -US-Mj1,29751,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Mj1,29751,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-Mj1,29751,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201301010030 -US-Mj1,29751,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,201412312330 -US-Mj1,29751,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Growing season operation only -US-Mj1,29751,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,LiCor 7500 & CSAT-3 -US-Mj1,29752,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Mj1,29752,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-Mj1,29752,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201301010030 -US-Mj1,29752,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,201412312330 -US-Mj1,29752,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Growing season operation only -US-Mj1,29752,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,LiCor 7500 & CSAT-3 -US-Mj1,23000679,GRP_HEADER,SITE_NAME,Montana Judith Basin wheat field -US-Mj1,29753,GRP_IGBP,IGBP,CRO -US-Mj1,29753,GRP_IGBP,IGBP_COMMENT,Winter wheat (2013). Spring wheat (2014). -US-Mj1,29754,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -US-Mj1,29754,GRP_LAND_OWNERSHIP,LAND_OWNER,NA -US-Mj1,29755,GRP_LOCATION,LOCATION_LAT,46.9948 -US-Mj1,29755,GRP_LOCATION,LOCATION_LONG,-109.6137 -US-Mj1,29755,GRP_LOCATION,LOCATION_ELEV,1285 -US-Mj1,29755,GRP_LOCATION,LOCATION_DATE_START,201301010030 -US-Mj1,29756,GRP_NETWORK,NETWORK,AmeriFlux -US-Mj1,1700000315,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Stoy, P. C., El-Madany, T. S., Fisher, J. B., Gentine, P., Gerken, T., Good, S. P., Klosterhalfen, A., Liu, S., Miralles, D. G., Perez-Priego, O., Rigden, A. J., Skaggs, T. H., Wohlfahrt, G., Anderson, R. G., Coenders-Gerrits, A. M., Jung, M., Maes, W. H., Mammarella, I., Mauder, M., Migliavacca, M., Nelson, J. A., Poyatos, R., Reichstein, M., Scott, R. L., Wolf, S. (2019) Reviews And Syntheses: Turning The Challenges Of Partitioning Ecosystem Evaporation And Transpiration Into Opportunities, Biogeosciences, 16(19), 3747-3775" -US-Mj1,1700000315,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.5194/BG-16-3747-2019 -US-Mj1,1700000315,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Mj1,1700007854,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Vick, E. S., Stoy, P. C., Tang, A. C., Gerken, T. (2016) The Surface-Atmosphere Exchange Of Carbon Dioxide, Water, And Sensible Heat Across A Dryland Wheat-Fallow Rotation, Agriculture, Ecosystems & Environment, 232(), 129-140" -US-Mj1,1700007854,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGEE.2016.07.018 -US-Mj1,1700007854,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Primary_Citation -US-Mj1,29758,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"Wheat carbon uptake, evapotranspiration, and sensible heat flux, and implications for atmospheric boundary layer development" -US-Mj1,29759,GRP_SITE_CHAR,TERRAIN,Flat -US-Mj1,29759,GRP_SITE_CHAR,ASPECT,NW -US-Mj1,29759,GRP_SITE_CHAR,WIND_DIRECTION,W -US-Mj1,29759,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,200 -US-Mj1,29760,GRP_SITE_DESC,SITE_DESC,"see Vick et al. (2016), doi:10.1016/j.agee.2016.07.018" -US-Mj1,29761,GRP_SITE_FUNDING,SITE_FUNDING,Montana Wheat and Barley Committee -US-Mj1,29762,GRP_STATE,STATE,MT -US-Mj1,98542,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Paul C. Stoy -US-Mj1,98542,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Mj1,98542,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,pcstoy@wisc.edu -US-Mj1,98542,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Wisconsin -US-Mj1,29931,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-Mj1,29764,GRP_TOWER_TYPE,TOWER_TYPE,tripod -US-Mj1,29765,GRP_URL,URL,sites.google.com/site/stoylab/home -US-Mj1,24000679,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-Mj1 -US-Mj1,29766,GRP_UTC_OFFSET,UTC_OFFSET,-7 -US-Mj1,29766,GRP_UTC_OFFSET,UTC_OFFSET_COMMENT,Mountain Standard Time -US-Mj2,29727,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,"Work was supported by the MT Wheat & Barley Committee, USDA NIFA Hatch project 228396, & NSF DEB 1552976." -US-Mj2,29728,GRP_CLIM_AVG,MAT,6.6 -US-Mj2,29728,GRP_CLIM_AVG,MAP,388 -US-Mj2,29728,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Bsk -US-Mj2,27000680,GRP_COUNTRY,COUNTRY,USA -US-Mj2,91706,GRP_DOI,DOI,10.17190/AMF/1617716 -US-Mj2,91706,GRP_DOI,DOI_CITATION,"Paul C. Stoy (2020), AmeriFlux BASE US-Mj2 Montana Judith Basin summer fallow field, Ver. 1-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1617716" -US-Mj2,91706,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-Mj2,91536,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Mj2,91536,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Paul C. Stoy -US-Mj2,91536,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Mj2,91536,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,paul.stoy@montana.edu -US-Mj2,91536,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Montana State University -US-Mj2,91663,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Montana State University -US-Mj2,91663,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-Mj2,91612,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Montana Wheat and Barley Committee -US-Mj2,91612,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-Mj2,29729,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Agriculture -US-Mj2,29732,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Mj2,29732,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-Mj2,29732,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201401010030 -US-Mj2,29732,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,201412312330 -US-Mj2,29732,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Growing season operation only -US-Mj2,29732,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,LiCor 7500 & CSAT-3 -US-Mj2,29731,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Mj2,29731,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-Mj2,29731,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201401010030 -US-Mj2,29731,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,201412312330 -US-Mj2,29731,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Growing season operation only -US-Mj2,29731,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,LiCor 7500 & CSAT-3 -US-Mj2,29730,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Mj2,29730,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-Mj2,29730,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201401010030 -US-Mj2,29730,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,201412312330 -US-Mj2,29730,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Growing season operation only -US-Mj2,29730,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,LiCor 7500 & CSAT-3 -US-Mj2,23000680,GRP_HEADER,SITE_NAME,Montana Judith Basin summer fallow field -US-Mj2,29733,GRP_IGBP,IGBP,CRO -US-Mj2,29733,GRP_IGBP,IGBP_COMMENT,Summer fallow -US-Mj2,29734,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -US-Mj2,29734,GRP_LAND_OWNERSHIP,LAND_OWNER,NA -US-Mj2,29767,GRP_LOCATION,LOCATION_LAT,46.9957 -US-Mj2,29767,GRP_LOCATION,LOCATION_LONG,-109.6295 -US-Mj2,29767,GRP_LOCATION,LOCATION_ELEV,1277 -US-Mj2,29767,GRP_LOCATION,LOCATION_DATE_START,201401010030 -US-Mj2,29736,GRP_NETWORK,NETWORK,AmeriFlux -US-Mj2,1700007980,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Vick, E. S., Stoy, P. C., Tang, A. C., Gerken, T. (2016) The Surface-Atmosphere Exchange Of Carbon Dioxide, Water, And Sensible Heat Across A Dryland Wheat-Fallow Rotation, Agriculture, Ecosystems & Environment, 232(), 129-140" -US-Mj2,1700007980,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGEE.2016.07.018 -US-Mj2,1700007980,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Primary_Citation -US-Mj2,29738,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"Summer fallow carbon loss, evapotranspiration, and sensible heat flux, and implications for atmospheric boundary layer development" -US-Mj2,29739,GRP_SITE_CHAR,TERRAIN,Flat -US-Mj2,29739,GRP_SITE_CHAR,ASPECT,NW -US-Mj2,29739,GRP_SITE_CHAR,WIND_DIRECTION,W -US-Mj2,29739,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,200 -US-Mj2,29740,GRP_SITE_DESC,SITE_DESC,"see Vick et al. (2016), doi:10.1016/j.agee.2016.07.018" -US-Mj2,29741,GRP_SITE_FUNDING,SITE_FUNDING,Montana Wheat and Barley Committee -US-Mj2,29742,GRP_STATE,STATE,MT -US-Mj2,98544,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Paul C. Stoy -US-Mj2,98544,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Mj2,98544,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,pcstoy@wisc.edu -US-Mj2,98544,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Wisconsin -US-Mj2,29932,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-Mj2,29744,GRP_TOWER_TYPE,TOWER_TYPE,tripod -US-Mj2,29745,GRP_URL,URL,sites.google.com/site/stoylab/home -US-Mj2,24000680,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-Mj2 -US-Mj2,29746,GRP_UTC_OFFSET,UTC_OFFSET,-7 -US-Mj2,29746,GRP_UTC_OFFSET,UTC_OFFSET_COMMENT,Mountain Standard Time -US-MMS,89976,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,AmeriFlux Management Project -US-MMS,89976,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT_COMMENT,"Since 2013, operations of the US-MMS tower have been supported by the AmeriFlux Management Project, US Department of Energy." -US-MMS,18302,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,10552 -US-MMS,18302,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Wood -US-MMS,18302,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-MMS,18302,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-MMS,18302,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2001 -US-MMS,18378,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,10588 -US-MMS,18378,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Wood -US-MMS,18378,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-MMS,18378,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-MMS,18378,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2000 -US-MMS,18378,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,10 more plots added for 2000 on: data are end of year numbers -US-MMS,18336,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,10618 -US-MMS,18336,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Wood -US-MMS,18336,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-MMS,18336,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-MMS,18336,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2003 -US-MMS,18309,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,10733 -US-MMS,18309,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Wood -US-MMS,18309,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-MMS,18309,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-MMS,18309,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2002 -US-MMS,18299,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,10760 -US-MMS,18299,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Total -US-MMS,18299,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-MMS,18299,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-MMS,18299,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2001 -US-MMS,18365,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,10806.2 -US-MMS,18365,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Total -US-MMS,18365,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-MMS,18365,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-MMS,18365,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,1999 -US-MMS,18365,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,10 more plots added for 2000 on: data are end of year numbers -US-MMS,18313,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,10842 -US-MMS,18313,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Total -US-MMS,18313,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-MMS,18313,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-MMS,18313,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2003 -US-MMS,18307,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,10963 -US-MMS,18307,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Total -US-MMS,18307,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-MMS,18307,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-MMS,18307,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2002 -US-MMS,18342,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,11287 -US-MMS,18342,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Wood -US-MMS,18342,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-MMS,18342,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-MMS,18342,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2004 -US-MMS,18340,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,11506 -US-MMS,18340,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Total -US-MMS,18340,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-MMS,18340,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-MMS,18340,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2004 -US-MMS,18348,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,11611 -US-MMS,18348,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Wood -US-MMS,18348,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-MMS,18348,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-MMS,18348,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2005 -US-MMS,18346,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,11838 -US-MMS,18346,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Total -US-MMS,18346,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-MMS,18346,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-MMS,18346,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2005 -US-MMS,18296,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,208 -US-MMS,18296,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Foliage -US-MMS,18296,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-MMS,18296,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-MMS,18296,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2001 -US-MMS,18374,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,218 -US-MMS,18374,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Foliage -US-MMS,18374,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-MMS,18374,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-MMS,18374,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2000 -US-MMS,18374,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,10 more plots added for 2000 on: data are end of year numbers -US-MMS,18338,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,219 -US-MMS,18338,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Foliage -US-MMS,18338,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-MMS,18338,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-MMS,18338,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2004 -US-MMS,18311,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,224 -US-MMS,18311,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Foliage -US-MMS,18311,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-MMS,18311,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-MMS,18311,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2003 -US-MMS,18358,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,224 -US-MMS,18358,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Foliage -US-MMS,18358,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-MMS,18358,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-MMS,18358,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,1999 -US-MMS,18358,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,10 more plots added for 2000 on: data are end of year numbers -US-MMS,18344,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,227 -US-MMS,18344,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Foliage -US-MMS,18344,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-MMS,18344,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-MMS,18344,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2005 -US-MMS,18305,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,230 -US-MMS,18305,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Foliage -US-MMS,18305,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-MMS,18305,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-MMS,18305,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2002 -US-MMS,18370,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,9038.7 -US-MMS,18370,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Wood -US-MMS,18370,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-MMS,18370,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-MMS,18370,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,1999 -US-MMS,18370,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,10 more plots added for 2000 on: data are end of year numbers -US-MMS,18375,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS,190 -US-MMS,18375,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_UNIT,gC m-2 -US-MMS,18375,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_DATE,2001 -US-MMS,18359,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS,198 -US-MMS,18359,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_UNIT,gC m-2 -US-MMS,18359,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_DATE,1998 -US-MMS,18297,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS,206 -US-MMS,18297,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_UNIT,gC m-2 -US-MMS,18297,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_DATE,2003 -US-MMS,18300,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS,207 -US-MMS,18300,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_UNIT,gC m-2 -US-MMS,18300,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_DATE,2004 -US-MMS,18371,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS,209 -US-MMS,18371,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_UNIT,gC m-2 -US-MMS,18371,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_DATE,2000 -US-MMS,18303,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS,211 -US-MMS,18303,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_UNIT,gC m-2 -US-MMS,18303,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_DATE,2005 -US-MMS,18366,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS,211 -US-MMS,18366,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_UNIT,gC m-2 -US-MMS,18366,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_DATE,1999 -US-MMS,18379,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS,213 -US-MMS,18379,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_UNIT,gC m-2 -US-MMS,18379,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_DATE,2002 -US-MMS,25033,GRP_AG_LIT_CHEM,AG_LIT_C,4.726 -US-MMS,25033,GRP_AG_LIT_CHEM,AG_LIT_N,0.088 -US-MMS,25033,GRP_AG_LIT_CHEM,AG_LIT_COMMENT,Various -US-MMS,18304,GRP_AG_PROD_OTHER,AG_PROD_OTHER,10 -US-MMS,18304,GRP_AG_PROD_OTHER,AG_PROD_OTHER_ORGAN,Total -US-MMS,18304,GRP_AG_PROD_OTHER,AG_PROD_OTHER_UNIT,gC m-2 -US-MMS,18304,GRP_AG_PROD_OTHER,AG_PROD_DATE_START,199801 -US-MMS,18304,GRP_AG_PROD_OTHER,AG_PROD_DATE_END,199812 -US-MMS,18304,GRP_AG_PROD_OTHER,AG_PROD_COMMENT,Non-woody plants average -US-MMS,18294,GRP_AG_PROD_OTHER,AG_PROD_OTHER,11 -US-MMS,18294,GRP_AG_PROD_OTHER,AG_PROD_OTHER_ORGAN,Total -US-MMS,18294,GRP_AG_PROD_OTHER,AG_PROD_OTHER_UNIT,gC m-2 -US-MMS,18294,GRP_AG_PROD_OTHER,AG_PROD_DATE_START,200301 -US-MMS,18294,GRP_AG_PROD_OTHER,AG_PROD_DATE_END,200312 -US-MMS,18294,GRP_AG_PROD_OTHER,AG_PROD_COMMENT,Non-woody plants average -US-MMS,18298,GRP_AG_PROD_OTHER,AG_PROD_OTHER,11 -US-MMS,18298,GRP_AG_PROD_OTHER,AG_PROD_OTHER_ORGAN,Total -US-MMS,18298,GRP_AG_PROD_OTHER,AG_PROD_OTHER_UNIT,gC m-2 -US-MMS,18298,GRP_AG_PROD_OTHER,AG_PROD_DATE_START,200401 -US-MMS,18298,GRP_AG_PROD_OTHER,AG_PROD_DATE_END,200412 -US-MMS,18298,GRP_AG_PROD_OTHER,AG_PROD_COMMENT,Non-woody plants average -US-MMS,18301,GRP_AG_PROD_OTHER,AG_PROD_OTHER,11 -US-MMS,18301,GRP_AG_PROD_OTHER,AG_PROD_OTHER_ORGAN,Total -US-MMS,18301,GRP_AG_PROD_OTHER,AG_PROD_OTHER_UNIT,gC m-2 -US-MMS,18301,GRP_AG_PROD_OTHER,AG_PROD_DATE_START,200501 -US-MMS,18301,GRP_AG_PROD_OTHER,AG_PROD_DATE_END,200512 -US-MMS,18301,GRP_AG_PROD_OTHER,AG_PROD_COMMENT,Non-woody plants average -US-MMS,18360,GRP_AG_PROD_OTHER,AG_PROD_OTHER,11 -US-MMS,18360,GRP_AG_PROD_OTHER,AG_PROD_OTHER_ORGAN,Total -US-MMS,18360,GRP_AG_PROD_OTHER,AG_PROD_OTHER_UNIT,gC m-2 -US-MMS,18360,GRP_AG_PROD_OTHER,AG_PROD_DATE_START,199901 -US-MMS,18360,GRP_AG_PROD_OTHER,AG_PROD_DATE_END,199912 -US-MMS,18360,GRP_AG_PROD_OTHER,AG_PROD_COMMENT,Non-woody plants average -US-MMS,18367,GRP_AG_PROD_OTHER,AG_PROD_OTHER,11 -US-MMS,18367,GRP_AG_PROD_OTHER,AG_PROD_OTHER_ORGAN,Total -US-MMS,18367,GRP_AG_PROD_OTHER,AG_PROD_OTHER_UNIT,gC m-2 -US-MMS,18367,GRP_AG_PROD_OTHER,AG_PROD_DATE_START,200001 -US-MMS,18367,GRP_AG_PROD_OTHER,AG_PROD_DATE_END,200012 -US-MMS,18367,GRP_AG_PROD_OTHER,AG_PROD_COMMENT,Non-woody plants average -US-MMS,18372,GRP_AG_PROD_OTHER,AG_PROD_OTHER,11 -US-MMS,18372,GRP_AG_PROD_OTHER,AG_PROD_OTHER_ORGAN,Total -US-MMS,18372,GRP_AG_PROD_OTHER,AG_PROD_OTHER_UNIT,gC m-2 -US-MMS,18372,GRP_AG_PROD_OTHER,AG_PROD_DATE_START,200101 -US-MMS,18372,GRP_AG_PROD_OTHER,AG_PROD_DATE_END,200112 -US-MMS,18372,GRP_AG_PROD_OTHER,AG_PROD_COMMENT,Non-woody plants average -US-MMS,18376,GRP_AG_PROD_OTHER,AG_PROD_OTHER,11 -US-MMS,18376,GRP_AG_PROD_OTHER,AG_PROD_OTHER_ORGAN,Total -US-MMS,18376,GRP_AG_PROD_OTHER,AG_PROD_OTHER_UNIT,gC m-2 -US-MMS,18376,GRP_AG_PROD_OTHER,AG_PROD_DATE_START,200201 -US-MMS,18376,GRP_AG_PROD_OTHER,AG_PROD_DATE_END,200212 -US-MMS,18376,GRP_AG_PROD_OTHER,AG_PROD_COMMENT,Non-woody plants average -US-MMS,18314,GRP_AG_PROD_TREE,AG_PROD_TREE,208 -US-MMS,18314,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Foliage -US-MMS,18314,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-MMS,18314,GRP_AG_PROD_TREE,AG_PROD_DATE_START,200101 -US-MMS,18314,GRP_AG_PROD_TREE,AG_PROD_DATE_END,200112 -US-MMS,18341,GRP_AG_PROD_TREE,AG_PROD_TREE,210 -US-MMS,18341,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Foliage -US-MMS,18341,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-MMS,18341,GRP_AG_PROD_TREE,AG_PROD_DATE_START,1998 -US-MMS,18312,GRP_AG_PROD_TREE,AG_PROD_TREE,218 -US-MMS,18312,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Foliage -US-MMS,18312,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-MMS,18312,GRP_AG_PROD_TREE,AG_PROD_DATE_START,200001 -US-MMS,18312,GRP_AG_PROD_TREE,AG_PROD_DATE_END,200012 -US-MMS,18308,GRP_AG_PROD_TREE,AG_PROD_TREE,219 -US-MMS,18308,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Foliage -US-MMS,18308,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-MMS,18308,GRP_AG_PROD_TREE,AG_PROD_DATE_START,200401 -US-MMS,18308,GRP_AG_PROD_TREE,AG_PROD_DATE_END,200412 -US-MMS,18306,GRP_AG_PROD_TREE,AG_PROD_TREE,224 -US-MMS,18306,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Foliage -US-MMS,18306,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-MMS,18306,GRP_AG_PROD_TREE,AG_PROD_DATE_START,200301 -US-MMS,18306,GRP_AG_PROD_TREE,AG_PROD_DATE_END,200312 -US-MMS,18339,GRP_AG_PROD_TREE,AG_PROD_TREE,224 -US-MMS,18339,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Foliage -US-MMS,18339,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-MMS,18339,GRP_AG_PROD_TREE,AG_PROD_DATE_START,1999 -US-MMS,18310,GRP_AG_PROD_TREE,AG_PROD_TREE,227 -US-MMS,18310,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Foliage -US-MMS,18310,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-MMS,18310,GRP_AG_PROD_TREE,AG_PROD_DATE_START,200501 -US-MMS,18310,GRP_AG_PROD_TREE,AG_PROD_DATE_END,200512 -US-MMS,18337,GRP_AG_PROD_TREE,AG_PROD_TREE,230 -US-MMS,18337,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Foliage -US-MMS,18337,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-MMS,18337,GRP_AG_PROD_TREE,AG_PROD_DATE_START,2002 -US-MMS,18315,GRP_AG_PROD_TREE,AG_PROD_TREE,279 -US-MMS,18315,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Wood -US-MMS,18315,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-MMS,18315,GRP_AG_PROD_TREE,AG_PROD_DATE_START,2003 -US-MMS,18345,GRP_AG_PROD_TREE,AG_PROD_TREE,285 -US-MMS,18345,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Total -US-MMS,18345,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-MMS,18345,GRP_AG_PROD_TREE,AG_PROD_DATE_START,2003 -US-MMS,18318,GRP_AG_PROD_TREE,AG_PROD_TREE,286 -US-MMS,18318,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Wood -US-MMS,18318,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-MMS,18318,GRP_AG_PROD_TREE,AG_PROD_DATE_START,1998 -US-MMS,18354,GRP_AG_PROD_TREE,AG_PROD_TREE,286 -US-MMS,18354,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Wood -US-MMS,18354,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-MMS,18354,GRP_AG_PROD_TREE,AG_PROD_DATE_START,1999 -US-MMS,18357,GRP_AG_PROD_TREE,AG_PROD_TREE,289 -US-MMS,18357,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Wood -US-MMS,18357,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-MMS,18357,GRP_AG_PROD_TREE,AG_PROD_DATE_START,2002 -US-MMS,18316,GRP_AG_PROD_TREE,AG_PROD_TREE,300 -US-MMS,18316,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Wood -US-MMS,18316,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-MMS,18316,GRP_AG_PROD_TREE,AG_PROD_DATE_START,2004 -US-MMS,18317,GRP_AG_PROD_TREE,AG_PROD_TREE,336 -US-MMS,18317,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Wood -US-MMS,18317,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-MMS,18317,GRP_AG_PROD_TREE,AG_PROD_DATE_START,2005 -US-MMS,18355,GRP_AG_PROD_TREE,AG_PROD_TREE,345 -US-MMS,18355,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Wood -US-MMS,18355,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-MMS,18355,GRP_AG_PROD_TREE,AG_PROD_DATE_START,2000 -US-MMS,18356,GRP_AG_PROD_TREE,AG_PROD_TREE,366 -US-MMS,18356,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Wood -US-MMS,18356,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-MMS,18356,GRP_AG_PROD_TREE,AG_PROD_DATE_START,2001 -US-MMS,18353,GRP_AG_PROD_TREE,AG_PROD_TREE,484 -US-MMS,18353,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Total -US-MMS,18353,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-MMS,18353,GRP_AG_PROD_TREE,AG_PROD_DATE_START,1998 -US-MMS,18349,GRP_AG_PROD_TREE,AG_PROD_TREE,497 -US-MMS,18349,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Total -US-MMS,18349,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-MMS,18349,GRP_AG_PROD_TREE,AG_PROD_DATE_START,1999 -US-MMS,18343,GRP_AG_PROD_TREE,AG_PROD_TREE,502 -US-MMS,18343,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Total -US-MMS,18343,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-MMS,18343,GRP_AG_PROD_TREE,AG_PROD_DATE_START,2002 -US-MMS,18347,GRP_AG_PROD_TREE,AG_PROD_TREE,507 -US-MMS,18347,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Total -US-MMS,18347,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-MMS,18347,GRP_AG_PROD_TREE,AG_PROD_DATE_START,2004 -US-MMS,18352,GRP_AG_PROD_TREE,AG_PROD_TREE,547 -US-MMS,18352,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Total -US-MMS,18352,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-MMS,18352,GRP_AG_PROD_TREE,AG_PROD_DATE_START,2005 -US-MMS,18350,GRP_AG_PROD_TREE,AG_PROD_TREE,554 -US-MMS,18350,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Total -US-MMS,18350,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-MMS,18350,GRP_AG_PROD_TREE,AG_PROD_DATE_START,2000 -US-MMS,18351,GRP_AG_PROD_TREE,AG_PROD_TREE,556 -US-MMS,18351,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Total -US-MMS,18351,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-MMS,18351,GRP_AG_PROD_TREE,AG_PROD_DATE_START,2001 -US-MMS,25554,GRP_BIOMASS_CHEM,BIOMASS_C,4.731 -US-MMS,25554,GRP_BIOMASS_CHEM,BIOMASS_N,0.222 -US-MMS,25554,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-MMS,25554,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-MMS,25554,GRP_BIOMASS_CHEM,BIOMASS_SPP,(All) -US-MMS,25554,GRP_BIOMASS_CHEM,BIOMASS_COMMENT,Various -US-MMS,11717,GRP_CLIM_AVG,MAT,10.85 -US-MMS,11717,GRP_CLIM_AVG,MAP,1032 -US-MMS,11717,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Cfa -US-MMS,27000398,GRP_COUNTRY,COUNTRY,USA -US-MMS,1974,GRP_DM_FORESTRY,DM_FORESTRY,Clearcutting -US-MMS,1974,GRP_DM_FORESTRY,DM_COMMENT,rotational harvest on 20-25 yr. basis in vicinity of tower site. Seed tree harvest in 1991 in area north of tower area. -US-MMS,15722,GRP_DOI,DOI,10.17190/AMF/1246080 -US-MMS,15722,GRP_DOI,DOI_CITATION,"Kim Novick, Rich Phillips (2022), AmeriFlux BASE US-MMS Morgan Monroe State Forest, Ver. 21-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1246080" -US-MMS,15722,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-MMS,32126,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-MMS,32126,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Kim Novick -US-MMS,32126,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-MMS,32126,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,knovick@indiana.edu -US-MMS,32126,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Indiana University -US-MMS,32127,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-MMS,32127,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Rich Phillips -US-MMS,32127,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-MMS,32127,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,rpp6@indiana.edu -US-MMS,32127,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Indiana University -US-MMS,32129,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Indiana University -US-MMS,32129,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-MMS,32128,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,DOE/NIGEC -US-MMS,32128,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-MMS,4167,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Forestry -US-MMS,11718,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-MMS,11718,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-MMS,11718,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,1999 -US-MMS,11718,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-MMS,11732,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-MMS,11732,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-MMS,11732,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,1999 -US-MMS,11732,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-MMS,11735,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-MMS,11735,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-MMS,11735,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,1999 -US-MMS,11735,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-MMS,11738,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Chambers -US-MMS,11738,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-MMS,11738,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,2011 -US-MMS,11738,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-MMS,11738,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,Autochambers in a set of girdled and control plots -US-MMS,11741,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Chambers -US-MMS,11741,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-MMS,11741,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,2011 -US-MMS,11741,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Intermittent -US-MMS,11741,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,Soil collars distributed through footprint measured manually during the growing season -US-MMS,23000398,GRP_HEADER,SITE_NAME,Morgan Monroe State Forest -US-MMS,88582,GRP_HEIGHTC,HEIGHTC,27 -US-MMS,88582,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-MMS,88582,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,1 -US-MMS,88582,GRP_HEIGHTC,HEIGHTC_APPROACH,measured from tower -US-MMS,88582,GRP_HEIGHTC,HEIGHTC_DATE,199901010000 -US-MMS,88582,GRP_HEIGHTC,HEIGHTC_DATE_UNC,200 -US-MMS,88582,GRP_HEIGHTC,HEIGHTC_COMMENT,this is the original mean canopy height reported in the earliest pubs from Morgan-Mornoe -US-MMS,88578,GRP_HEIGHTC,HEIGHTC,36.3 -US-MMS,88578,GRP_HEIGHTC,HEIGHTC_STATISTIC,Maximum -US-MMS,88578,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,374 -US-MMS,88578,GRP_HEIGHTC,HEIGHTC_APPROACH,airborne lidar -US-MMS,88578,GRP_HEIGHTC,HEIGHTC_DATE,201808091200 -US-MMS,88578,GRP_HEIGHTC,HEIGHTC_DATE_UNC,0 -US-MMS,88578,GRP_HEIGHTC,HEIGHTC_COMMENT,number of points refers to the number of LIDAR returns used to estimated the statistic. Each pixel is 100 m^2; the total area used in calculating the statistic is 37400 m^2. -US-MMS,88579,GRP_HEIGHTC,HEIGHTC,25 -US-MMS,88579,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-MMS,88579,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,374 -US-MMS,88579,GRP_HEIGHTC,HEIGHTC_APPROACH,airborne lidar -US-MMS,88579,GRP_HEIGHTC,HEIGHTC_DATE,201808091200 -US-MMS,88579,GRP_HEIGHTC,HEIGHTC_DATE_UNC,0 -US-MMS,88579,GRP_HEIGHTC,HEIGHTC_COMMENT,number of points refers to the number of LIDAR returns used to estimated the statistic. Each pixel is 100 m^2; the total area used in calculating the statistic is 37400 m^2. -US-MMS,88580,GRP_HEIGHTC,HEIGHTC,5 -US-MMS,88580,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-MMS,88580,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,374 -US-MMS,88580,GRP_HEIGHTC,HEIGHTC_APPROACH,airborne lidar -US-MMS,88580,GRP_HEIGHTC,HEIGHTC_DATE,201808091200 -US-MMS,88580,GRP_HEIGHTC,HEIGHTC_DATE_UNC,0 -US-MMS,88580,GRP_HEIGHTC,HEIGHTC_COMMENT,number of points refers to the number of LIDAR returns used to estimated the statistic. Each pixel is 100 m^2; the total area used in calculating the statistic is 37400 m^2. -US-MMS,88581,GRP_HEIGHTC,HEIGHTC,4 -US-MMS,88581,GRP_HEIGHTC,HEIGHTC_STATISTIC,Minimum -US-MMS,88581,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,374 -US-MMS,88581,GRP_HEIGHTC,HEIGHTC_APPROACH,airborne lidar -US-MMS,88581,GRP_HEIGHTC,HEIGHTC_DATE,201808091200 -US-MMS,88581,GRP_HEIGHTC,HEIGHTC_DATE_UNC,0 -US-MMS,88581,GRP_HEIGHTC,HEIGHTC_COMMENT,number of points refers to the number of LIDAR returns used to estimated the statistic. Each pixel is 100 m^2; the total area used in calculating the statistic is 37400 m^2. -US-MMS,11719,GRP_IGBP,IGBP,DBF -US-MMS,11719,GRP_IGBP,IGBP_COMMENT,"secondary successional, 29 tree species" -US-MMS,11720,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-MMS,11720,GRP_LAND_OWNERSHIP,LAND_OWNER,Forestry Division/ DNR -US-MMS,24151,GRP_LMA,LMA,42.5 -US-MMS,24151,GRP_LMA,LMA_SPP,(All) -US-MMS,24151,GRP_LMA,LMA_COMMENT,"ddragoni: -dry weight - -103,7 wet weight" -US-MMS,11721,GRP_LOCATION,LOCATION_LAT,39.3232 -US-MMS,11721,GRP_LOCATION,LOCATION_LONG,-86.4131 -US-MMS,11721,GRP_LOCATION,LOCATION_ELEV,275 -US-MMS,24281,GRP_N_DEP,N_DEP_WET,1.35 -US-MMS,27853,GRP_NEP,NEP,249000 -US-MMS,27853,GRP_NEP,NEP_APPROACH,Both biometric and eddy covariance methods used -US-MMS,27853,GRP_NEP,NEP_DATE_START,1998 -US-MMS,27853,GRP_NEP,NEP_DATE_END,1999 -US-MMS,27853,GRP_NEP,NEP_COMMENT,249 -US-MMS,27854,GRP_NEP,NEP,379000 -US-MMS,27854,GRP_NEP,NEP_APPROACH,Both biometric and eddy covariance methods used -US-MMS,27854,GRP_NEP,NEP_DATE_START,1999 -US-MMS,27854,GRP_NEP,NEP_DATE_END,2000 -US-MMS,27854,GRP_NEP,NEP_COMMENT,± 70 (19%) -US-MMS,27855,GRP_NEP,NEP,294000 -US-MMS,27855,GRP_NEP,NEP_APPROACH,Both biometric and eddy covariance methods used -US-MMS,27855,GRP_NEP,NEP_DATE_START,2000 -US-MMS,27855,GRP_NEP,NEP_DATE_END,2001 -US-MMS,27855,GRP_NEP,NEP_COMMENT,± 78 (27%) -US-MMS,28225,GRP_NEP,NEP,341000 -US-MMS,28225,GRP_NEP,NEP_APPROACH,Both biometric and eddy covariance methods used -US-MMS,28225,GRP_NEP,NEP_DATE_START,2001 -US-MMS,28225,GRP_NEP,NEP_DATE_END,2002 -US-MMS,28225,GRP_NEP,NEP_COMMENT,± 79 (25%) -US-MMS,26033,GRP_NEP,NEP,308000 -US-MMS,26033,GRP_NEP,NEP_APPROACH,Both biometric and eddy covariance methods used -US-MMS,26033,GRP_NEP,NEP_DATE_START,2002 -US-MMS,26033,GRP_NEP,NEP_DATE_END,2003 -US-MMS,26033,GRP_NEP,NEP_COMMENT,± 86 (33%) -US-MMS,28950,GRP_NEP,NEP,304000 -US-MMS,28950,GRP_NEP,NEP_APPROACH,Both biometric and eddy covariance methods used -US-MMS,28950,GRP_NEP,NEP_DATE_START,2003 -US-MMS,28950,GRP_NEP,NEP_DATE_END,2004 -US-MMS,28950,GRP_NEP,NEP_COMMENT,± 71 (27%) -US-MMS,25916,GRP_NEP,NEP,335000 -US-MMS,25916,GRP_NEP,NEP_APPROACH,Both biometric and eddy covariance methods used -US-MMS,25916,GRP_NEP,NEP_DATE_START,2004 -US-MMS,25916,GRP_NEP,NEP_DATE_END,2005 -US-MMS,25916,GRP_NEP,NEP_COMMENT,± 65 (20%) -US-MMS,25411,GRP_NEP,NEP,310000 -US-MMS,25411,GRP_NEP,NEP_APPROACH,Both biometric and eddy covariance methods used -US-MMS,25411,GRP_NEP,NEP_DATE_START,2005 -US-MMS,25411,GRP_NEP,NEP_DATE_END,2006 -US-MMS,25411,GRP_NEP,NEP_COMMENT,± 76 (24%) -US-MMS,11722,GRP_NETWORK,NETWORK,AmeriFlux -US-MMS,86983,GRP_NETWORK,NETWORK,Phenocam -US-MMS,18320,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,BudBreak -US-MMS,18320,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,all -US-MMS,18320,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20000426 -US-MMS,18327,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,BudBreak -US-MMS,18327,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,all -US-MMS,18327,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20020418 -US-MMS,18329,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,BudBreak -US-MMS,18329,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,all -US-MMS,18329,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20030421 -US-MMS,18331,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,BudBreak -US-MMS,18331,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,all -US-MMS,18331,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20040420 -US-MMS,18387,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,Leaf senescence -US-MMS,18387,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,all -US-MMS,18387,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20021029 -US-MMS,18388,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,Leaf senescence -US-MMS,18388,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,all -US-MMS,18388,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20021015 -US-MMS,18388,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,again not sure why we have 2 dates for this year -US-MMS,18389,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,Leaf senescence -US-MMS,18389,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,all -US-MMS,18389,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20041012 -US-MMS,18324,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,Maximum leaf expansion -US-MMS,18324,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,all -US-MMS,18324,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20000426 -US-MMS,18333,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,Maximum leaf expansion -US-MMS,18333,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,all -US-MMS,18333,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20000510 -US-MMS,18333,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,not sure why there are 2 dates for this year -US-MMS,18335,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,Maximum leaf expansion -US-MMS,18335,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,all -US-MMS,18335,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20020425 -US-MMS,18381,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,Maximum leaf expansion -US-MMS,18381,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,all -US-MMS,18381,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20030506 -US-MMS,18383,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,Maximum leaf expansion -US-MMS,18383,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,all -US-MMS,18383,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20040513 -US-MMS,18385,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,Total leaf-off -US-MMS,18385,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,all -US-MMS,18385,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20021112 -US-MMS,18386,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,Total leaf-off -US-MMS,18386,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,all -US-MMS,18386,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20041027 -US-MMS,1700000423,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Baldocchi, D. D., Black, T. A., Curtis, P. S., Falge, E., Fuentes, J. D., Granier, A., Gu, L., Knohl, A., Lee, X., Pilegaard, K., Schmid, H. P., Valentini, R., Wilson, K., Wofsy, S., Xu, L., Yamamoto, S. (2005) Predicting The Onset Of Net Carbon Uptake By Deciduous Forests With Soil Temperature And Climate Data: A Synthesis Of FLUXNET Data, International Journal Of Biometeorology, 49(6), 377-387" -US-MMS,1700000423,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1007/S00484-005-0256-4 -US-MMS,1700000423,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-MMS,1700007293,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Baldocchi, D., Falge, E., Gu, L., Olson, R., Hollinger, D., Running, S., Anthoni, P., Bernhofer, C., Davis, K., Evans, R., Fuentes, J., Goldstein, A., Katul, G., Law, B., Lee, X., Malhi, Y., Meyers, T., Munger, W., Oechel, W., Paw, K. T., Pilegaard, K., Schmid, H. P., Valentini, R., Verma, S., Vesala, T., Wilson, K., Wofsy, S. (2001) FLUXNET: A New Tool To Study The Temporal And Spatial Variability Of Ecosystem–Scale Carbon Dioxide, Water Vapor, And Energy Flux Densities, Bulletin Of The American Meteorological Society, 82(11), 2415-2434" -US-MMS,1700007293,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1175/1520-0477(2001)082<2415:FANTTS>2.3.CO;2 -US-MMS,1700007293,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-MMS,1700004941,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Baldocchi, D., Penuelas, J. (2018) The Physics And Ecology Of Mining Carbon Dioxide From The Atmosphere By Ecosystems, Global Change Biology, 45(15), 9275–9287" -US-MMS,1700004941,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/GCB.14559 -US-MMS,1700004941,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-MMS,1700007626,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Baldocchi, D., Penuelas, J. (2018) The Physics And Ecology Of Mining Carbon Dioxide From The Atmosphere By Ecosystems, Global Change Biology, 45(8), 9275–9287" -US-MMS,1700007626,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/GCB.14559 -US-MMS,1700007626,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-MMS,1700001464,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Barr, A., Richardson, A., Hollinger, D., Papale, D., Arain, M., Black, T., Bohrer, G., Dragoni, D., Fischer, M., Gu, L., Law, B., Margolis, H., McCaughey, J., Munger, J., Oechel, W., Schaeffer, K. (2013) Use Of Change-Point Detection For Friction–Velocity Threshold Evaluation In Eddy-Covariance Studies, Agricultural And Forest Meteorology, 171-172(7458), 31-45" -US-MMS,1700001464,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2012.11.023 -US-MMS,1700001464,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-MMS,1700001560,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Brzostek, E.R., Dragoni, D., Schmid, H.P., Rahman, A.F., Wayson, C.A., Johnson, D.J., Phillips, R.P. (2014) Chronic water stress reduces tree growth and the carbon sink of deciduous hardwood forests, Global Change Biology, 8(), 2531-2539" -US-MMS,1700001560,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-MMS,1700007920,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Baldocchi, D. D., Poindexter, C., Abraha, M., Desai, A. R., Bohrer, G., Arain, M. A., Griffis, T., Blanken, P. D., O'Halloran, T. L., Thomas, R. Q., Zhang, Q., Burns, S. P., Frank, J. M., Christian, D., Brown, S., Black, T. A., Gough, C. M., Law, B. E., Lee, X., Chen, J., Reed, D. E., Massman, W. J., Clark, K., Hatfield, J., Prueger, J., Bracho, R., Baker, J. M., Martin, T. A. (2018) Temporal Dynamics Of Aerodynamic Canopy Height Derived From Eddy Covariance Momentum Flux Data Across North American Flux Networks, Geophysical Research Letters, 45(15), 9275–9287" -US-MMS,1700007920,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018GL079306 -US-MMS,1700007920,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-MMS,1700004533,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Baldocchi, D. D., Poindexter, C., Abraha, M., Desai, A. R., Bohrer, G., Arain, M. A., Griffis, T., Blanken, P. D., O'Halloran, T. L., Thomas, R. Q., Zhang, Q., Burns, S. P., Frank, J. M., Christian, D., Brown, S., Black, T. A., Gough, C. M., Law, B. E., Lee, X., Chen, J., Reed, D. E., Massman, W. J., Clark, K., Hatfield, J., Prueger, J., Bracho, R., Baker, J. M., Martin, T. A. (2018) Temporal Dynamics Of Aerodynamic Canopy Height Derived From Eddy Covariance Momentum Flux Data Across North American Flux Networks, Geophysical Research Letters, 45(8), 9275–9287" -US-MMS,1700004533,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018GL079306 -US-MMS,1700004533,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-MMS,1700004413,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(6), 108350" -US-MMS,1700004413,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -US-MMS,1700004413,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-MMS,1700004392,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Curtis, P. S., Hanson, P. J., Bolstad, P., Barford, C., Randolph, J., Schmid, H., Wilson, K. B. (2002) Biometric And Eddy-Covariance Based Estimates Of Annual Carbon Storage In Five Eastern North American Deciduous Forests, Agricultural And Forest Meteorology, 113(1-4), 3-19" -US-MMS,1700004392,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/S0168-1923(02)00099-0 -US-MMS,1700004392,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-MMS,1700003717,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Davidson, E., Savage, K., Bolstad, P., Clark, D., Curtis, P., Ellsworth, D., Hanson, P., Law, B., Luo, Y., Pregitzer, K., Randolph, J., Zak, D. (2002) Belowground Carbon Allocation In Forests Estimated From Litterfall And IRGA-Based Soil Respiration Measurements, Agricultural And Forest Meteorology, 113(1-4), 39-51" -US-MMS,1700003717,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/S0168-1923(02)00101-6 -US-MMS,1700003717,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-MMS,1700000402,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Dennis Baldocchi, Cove Sturtevant (2015) Does day and night sampling reduce spurious correlation between canopy photosynthesis and ecosystem respiration?, Agricultural and Forest Meteorology, 207(1-4), 117-126" -US-MMS,1700000402,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2015.03.010 -US-MMS,1700000402,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-MMS,1700000909,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"DRAGONI, D., SCHMID, H. P., WAYSON, C. A., POTTER, H., GRIMMOND, C. S., RANDOLPH, J. C. (2011) Evidence Of Increased Net Ecosystem Productivity Associated With A Longer Vegetated Season In A Deciduous Forest In South-Central Indiana, Usa, Global Change Biology, 17(2), 886-897" -US-MMS,1700000909,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/J.1365-2486.2010.02281.X -US-MMS,1700000909,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-MMS,1700007668,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Ehman, J. L., Schmid, H. P., Grimmond, C. S., Randolph, J. C., Hanson, P. J., Wayson, C. A., Cropley, F. D. (2002) An Initial Intercomparison Of Micrometeorological And Ecological Inventory Estimates Of Carbon Exchange In A Mid-Latitude Deciduous Forest, Global Change Biology, 8(6), 575-589" -US-MMS,1700007668,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1046/J.1365-2486.2002.00492.X -US-MMS,1700007668,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-MMS,1700007911,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Guerrieri, R., Belmecheri, S., Ollinger, S. V., Asbjornsen, H., Jennings, K., Xiao, J., Stocker, B. D., Martin, M., Hollinger, D. Y., Bracho-Garrillo, R., Clark, K., Dore, S., Kolb, T., Munger, J. W., Novick, K., Richardson, A. D. (2019) Disentangling The Role Of Photosynthesis And Stomatal Conductance On Rising Forest Water-Use Efficiency, Proceedings Of The National Academy Of Sciences, 116(34), 16909-16914" -US-MMS,1700007911,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1073/PNAS.1905912116 -US-MMS,1700007911,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-MMS,1700000597,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Kannenberg, S. A., Novick, K. A., Alexander, M. R., Maxwell, J. T., Moore, D. J., Phillips, R. P., Anderegg, W. R. (2019) Linking Drought Legacy Effects Across Scales: From Leaves To Tree Rings To Ecosystems, Global Change Biology, 25(9), 2978-2992" -US-MMS,1700000597,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/GCB.14710 -US-MMS,1700000597,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-MMS,1700001623,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Keenan, T. F., Hollinger, D. Y., Bohrer, G., Dragoni, D., Munger, J. W., Schmid, H. P., Richardson, A. D. (2013) Increase In Forest Water-Use Efficiency As Atmospheric Carbon Dioxide Concentrations Rise, Nature, 499(7458), 324-327" -US-MMS,1700001623,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1038/NATURE12291 -US-MMS,1700001623,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-MMS,1700007251,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Matheny, A. M., Bohrer, G., Stoy, P. C., Baker, I. T., Black, A. T., Desai, A. R., Dietze, M. C., Gough, C. M., Ivanov, V. Y., Jassal, R. S., Novick, K. A., Schäfer, K. V., Verbeeck, H. (2014) Characterizing The Diurnal Patterns of Errors in The Prediction of Evapotranspiration by Several Land-Surface Models: An Nacp Analysis, Journal Of Geophysical Research: Biogeosciences, 119(7), 1458-1473" -US-MMS,1700007251,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/2014JG002623 -US-MMS,1700007251,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-MMS,1700005205,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Novick, K. A., Ficklin, D. L., Stoy, P. C., Williams, C. A., Bohrer, G., Oishi, A., Papuga, S. A., Blanken, P. D., Noormets, A., Sulman, B. N., Scott, R. L., Wang, L., Phillips, R. P. (2016) The Increasing Importance Of Atmospheric Demand For Ecosystem Water And Carbon Fluxes, Nature Climate Change, 6(11), 1023-1027" -US-MMS,1700005205,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1038/NCLIMATE3114 -US-MMS,1700005205,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-MMS,1700007002,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Novick, K. A., Konings, A. G., Gentine, P. (2019) Beyond Soil Water Potential: An Expanded View On Isohydricity Including Land–Atmosphere Interactions And Phenology, Plant, Cell & Environment, 42(6), 1802-1815" -US-MMS,1700007002,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/PCE.13517 -US-MMS,1700007002,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-MMS,1700008706,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Oliphant, A., Grimmond, C., Zutter, H., Schmid, H., Su, H., Scott, S., Offerle, B., Randolph, J., Ehman, J. (2004) Heat Storage And Energy Balance Fluxes For A Temperate Deciduous Forest, Agricultural And Forest Meteorology, 126(3-4), 185-201" -US-MMS,1700008706,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2004.07.003 -US-MMS,1700008706,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-MMS,1700007449,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Pryor, S. C., Barthelmie, R. J., Jensen, B. (1999) Nitrogen Dry Deposition At An Ameriflux Site In A Hardwood Forest In The Midwest, Geophysical Research Letters, 26(6), 691-694" -US-MMS,1700007449,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/1999GL900066 -US-MMS,1700007449,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-MMS,1700005145,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Rahman, A. F., Cordova, V. D., Gamon, J. A., Schmid, H. P., Sims, D. A. (2004) Potential Of MODIS Ocean Bands For Estimating CO2flux From Terrestrial Vegetation: A Novel Approach, Geophysical Research Letters, 31(10), n/a-n/a" -US-MMS,1700005145,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2004GL019778 -US-MMS,1700005145,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-MMS,1700001788,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Richardson, A. D., Anderson, R. S., Arain, M. A., Barr, A. G., Bohrer, G., Chen, G., Chen, J. M., Ciais, P., Davis, K. J., Desai, A. R., Dietze, M. C., Dragoni, D., Garrity, S. R., Gough, C. M., Grant, R., Hollinger, D. Y., Margolis, H. A., McCaughey, H., Migliavacca, M., Monson, R. K., Munger, J. W., Poulter, B., Raczka, B. M., Ricciuto, D. M., Sahoo, A. K., Schaefer, K., Tian, H., Vargas, R., Verbeeck, H., Xiao, J., Xue, Y. (2012) Terrestrial Biosphere Models Need Better Representation Of Vegetation Phenology: Results From The North American Carbon Program Site Synthesis, Global Change Biology, 18(2), 566-584" -US-MMS,1700001788,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/J.1365-2486.2011.02562.X -US-MMS,1700001788,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-MMS,1700007383,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Roman, D. T., Novick, K. A., Brzostek, E. R., Dragoni, D., Rahman, F., Phillips, R. P. (2015) The Role Of Isohydric And Anisohydric Species In Determining Ecosystem-Scale Response To Severe Drought, Oecologia, 179(3), 641-654" -US-MMS,1700007383,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1007/S00442-015-3380-9 -US-MMS,1700007383,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-MMS,1700008622,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Schmid, H., Grimmond, C.S.B., Cropley, F., Offerle, B., Su, H.B. (2000) Measurements Of CO2 And Energy Fluxes Over A Mixed Hardwood Forest In The Mid-Western United States, Agricultural And Forest Meteorology, 103(4), 357-374" -US-MMS,1700008622,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/S0168-1923(00)00140-4 -US-MMS,1700008622,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-MMS,1700005019,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Sims, D. A., Rahman, A. F., Cordova, V. D., Baldocchi, D. D., Flanagan, L. B., Goldstein, A. H., Hollinger, D. Y., Misson, L., Monson, R. K., Schmid, H. P., Wofsy, S. C., Xu, L. (2005) Midday Values Of Gross CO2 Flux And Light Use Efficiency During Satellite Overpasses Can Be Used To Directly Estimate Eight-Day Mean Flux, Agricultural And Forest Meteorology, 131(1-2), 1-12" -US-MMS,1700005019,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2005.04.006 -US-MMS,1700005019,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-MMS,1700002199,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Sims, D.A., Brzostek, E.R., Dragoni, D., Rahman, A.F., Phillips, R.P. (2014) An improved approach for remotely sensing water stress impacts on forest C uptake, Global Change Biology, 20(9), 2856-2866" -US-MMS,1700002199,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-MMS,1700000342,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Sullivan, R. C., Cook, D. R., Ghate, V. P., Kotamarthi, V. R., Feng, Y. (2019) Improved Spatiotemporal Representativeness And Bias Reduction Of Satellite-Based Evapotranspiration Retrievals Via Use Of In Situ Meteorology And Constrained Canopy Surface Resistance, Journal Of Geophysical Research: Biogeosciences, 124(2), 342-352" -US-MMS,1700000342,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018JG004744 -US-MMS,1700000342,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-MMS,1700007659,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Sullivan, R. C., Kotamarthi, V. R., Feng, Y. (2019) Recovering Evapotranspiration Trends From Biased CMIP5 Simulations And Sensitivity To Changing Climate Over North America, Journal Of Hydrometeorology, 20(8), 1619-1633" -US-MMS,1700007659,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1175/JHM-D-18-0259.1 -US-MMS,1700007659,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-MMS,1700000312,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Sulman, B.N., Roman, D.T., Scanlon, T.M., Wang, L. and Novick, K.A (2016) Comparing methods for partitioning a decade of carbon dioxide and water vapor fluxes in a temperate fores, Agricultural And Forest Meteorology, 226-227(18), 229-245" -US-MMS,1700000312,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-MMS,1700008592,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Sulman, B.N., Roman, D.T., Yi, K., Wang, L., Phillips, R.P. and Novick, K.A (2016) High atmospheric demand for water can limit forest carbon uptake and transpiration as severely as dry soil., Geophysical Research Letters, 43(18), 9686-9695" -US-MMS,1700008592,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-MMS,1700001035,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Toomey, M., Friedl, M. A., Frolking, S., Hufkens, K., Klosterman, S., Sonnentag, O., Baldocchi, D. D., Bernacchi, C. J., Biraud, S. C., Bohrer, G., Brzostek, E., Burns, S. P., Coursolle, C., Hollinger, D. Y., Margolis, H. A., McCaughey, H., Monson, R. K., Munger, J. W., Pallardy, S., Phillips, R. P., Torn, M. S., Wharton, S., Zeri, M., Richardson, A. D. (2015) Greenness Indices From Digital Cameras Predict The Timing And Seasonal Dynamics Of Canopy-Scale Photosynthesis, Ecological Applications, 25(1), 99-115" -US-MMS,1700001035,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1890/14-0005.1 -US-MMS,1700001035,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-MMS,1700007452,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Wolf, S., Keenan, T.F., Fisher, J.B., Baldocchi, D.D., Desai, A.R., Richardson, A.D., Scott, R.L., Law, B.E., Litvak, M.E., Brunsell, N.A., Peters, W., van der Laan-Luijkx, I.T. (2016) Warm spring reduced carbon cycle impact of the 2012 US summer drought, Proceedings of the National Academy of Sciences, 113(21), 5880-5885" -US-MMS,1700007452,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1073/PNAS.1519620113 -US-MMS,1700007452,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-MMS,1700002766,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Xu, B., Arain, M. A., Black, T. A., Law, B. E., Pastorello, G. Z., Chu, H. (2020) Seasonal Variability Of Forest Sensitivity To Heat And Drought Stresses: A Synthesis Based On Carbon Fluxes From North American Forest Ecosystems, Global Change Biology, 26(2), 901-918" -US-MMS,1700002766,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/GCB.14843 -US-MMS,1700002766,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-MMS,1700000399,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Yi, K., Dragoni, D., Phillips, R. P., Roman, D. T., Novick, K. A. (2017) Dynamics Of Stem Water Uptake Among Isohydric And Anisohydric Species Experiencing A Severe Drought, Tree Physiology, 179(3), 641-654" -US-MMS,1700000399,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1093/TREEPHYS/TPW126 -US-MMS,1700000399,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-MMS,1700005595,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Yi, K., Dragoni, D., Phillips, R. P., Roman, D. T., Novick, K. A. (2017) Dynamics Of Stem Water Uptake Among Isohydric And Anisohydric Species Experiencing A Severe Drought, Tree Physiology, 6(11), 1023-1027" -US-MMS,1700005595,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1093/TREEPHYS/TPW126 -US-MMS,1700005595,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-MMS,1700003411,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Yi, K., Maxwell, J. T., Wenzel, M. K., Roman, D. T., Sauer, P. E., Phillips, R. P., Novick, K. A. (2019) Linking Variation In Intrinsic Water-Use Efficiency To Isohydricity: A Comparison At Multiple Spatiotemporal Scales, New Phytologist, 221(1), 195-208" -US-MMS,1700003411,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/NPH.15384 -US-MMS,1700003411,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-MMS,1700003516,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Yue, X., Unger, N., Keenan, T. F., Zhang, X., Vogel, C. S. (2015) Probing The Past 30-Year Phenology Trend Of Us Deciduous Forests, Biogeosciences, 12(15), 4693-4709" -US-MMS,1700003516,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.5194/BG-12-4693-2015 -US-MMS,1700003516,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-MMS,1700003066,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Zhang, Q., Barnes, M., Benson, M., Burakowski, E., Oishi, A. C., Ouimette, A., Sanders‐DeMott, R., Stoy, P. C., Wenzel, M., Xiong, L., Yi, K., Novick, K. A. (2020) Reforestation And Surface Cooling In Temperate Zones: Mechanisms And Implications, Global Change Biology, 26(6), 3384-3401" -US-MMS,1700003066,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/GCB.15069 -US-MMS,1700003066,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-MMS,1700000636,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Zhang, Q., Ficklin, D. L., Manzoni, S., Wang, L., Way, D., Phillips, R. P., Novick, K. A. (2019) Response Of Ecosystem Intrinsic Water Use Efficiency And Gross Primary Productivity To Rising Vapor Pressure Deficit, Environmental Research Letters, 14(7), 074023" -US-MMS,1700000636,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1088/1748-9326/AB2603 -US-MMS,1700000636,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-MMS,1700002553,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Zhang, Q., Phillips, R. P., Manzoni, S., Scott, R. L., Oishi, A. C., Finzi, A., Daly, E., Vargas, R., Novick, K. A. (2018) Changes In Photosynthesis And Soil Moisture Drive The Seasonal Soil Respiration-Temperature Hysteresis Relationship, Agricultural And Forest Meteorology, 259(1-4), 184-195" -US-MMS,1700002553,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2018.05.005 -US-MMS,1700002553,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-MMS,1700005850,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Zhang, Q., Phillips, R. P., Manzoni, S., Scott, R. L., Oishi, A. C., Finzi, A., Daly, E., Vargas, R., Novick, K. A. (2018) Changes In Photosynthesis And Soil Moisture Drive The Seasonal Soil Respiration-Temperature Hysteresis Relationship, Agricultural And Forest Meteorology, 259(8), 184-195" -US-MMS,1700005850,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2018.05.005 -US-MMS,1700005850,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-MMS,1700003042,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Zscheischler, J., Fatichi, S., Wolf, S., Blanken, P., Bohrer, G., Clark, K., Desai, A., Hollinger, D., Keenan, T., Novick, K.A., Seneviratne, S.I. (2016) Short-term favorable weather conditions are an important control of interannual variability in carbon and water fluxes, Journal of Geophysical Research - Biogeosciences, 121(8), 2186-2198" -US-MMS,1700003042,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/2016JG003503 -US-MMS,1700003042,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-MMS,11724,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"1) Measure current CO2 fluxes and atmospheric controls for a deciduous forest ecosystem in the Midwest. 2) Develop, evaluate, and assess methods to scale-up from point measurements of fluxes to regional budgets." -US-MMS,18361,GRP_ROOT_BIOMASS,ROOT_BIOMASS_CRS,316 -US-MMS,18368,GRP_ROOT_BIOMASS,ROOT_BIOMASS_FINE,252 -US-MMS,18361,GRP_ROOT_BIOMASS,ROOT_BIOMASS_TOT,568 -US-MMS,18361,GRP_ROOT_BIOMASS,ROOT_BIOMASS_UNIT,gC m-2 -US-MMS,18368,GRP_ROOT_BIOMASS,ROOT_BIOMASS_UNIT,gC m-2 -US-MMS,18368,GRP_ROOT_BIOMASS,ROOT_BIOMASS_DATE,1998 -US-MMS,18361,GRP_ROOT_BIOMASS,ROOT_BIOMASS_DATE,2004 -US-MMS,23742,GRP_ROOT_CHEM,ROOT_C,4.53 -US-MMS,23742,GRP_ROOT_CHEM,ROOT_SPP,(Unknown) -US-MMS,23742,GRP_ROOT_CHEM,ROOT_COMMENT,Perkin & Elmer CHN analyzer -US-MMS,18362,GRP_ROOT_PROD,ROOT_PROD_FINE,413 -US-MMS,18362,GRP_ROOT_PROD,ROOT_PROD_UNIT,gC m-2 -US-MMS,18362,GRP_ROOT_PROD,ROOT_PROD_DATE_START,2000 -US-MMS,18362,GRP_ROOT_PROD,ROOT_PROD_DATE_END,2000 -US-MMS,18362,GRP_ROOT_PROD,ROOT_PROD_COMMENT,"MODEL BASED ON 2000 Nmin; Based on soil C, conservation of Mass. (Raich & Nadelhoffer, 1989)" -US-MMS,18321,GRP_SA,SA,70 -US-MMS,18321,GRP_SA,SA_DATE,20020101 -US-MMS,18321,GRP_SA,SA_COMMENT,unsure how this was determined -US-MMS,18321,GRP_SA,SA_MAX,80 -US-MMS,11725,GRP_SITE_CHAR,TERRAIN,Undulated/Variable -US-MMS,11726,GRP_SITE_DESC,SITE_DESC,"Owned by the Indiana Department of Natural Resources (IDNR), the Morgan Monroe State Forest, the site's namesake, is operated thanks to the long-term agreement between Indiana University and IDNR. The first settlers cleared the surrounding ridges for farming, but were largely unsuccessful. The state of Indiana purchased the land in 1929, creating the Morgan Monroe State Forest. Many of the trees in the tower footprint are 60-80 years old, surviving selective logging that ended over the past 10 years. Today, the forest is a secondary successional broadleaf forest within the maple-beech to oak hickory transition zone of the eastern deciduous forest." -US-MMS,11727,GRP_SITE_FUNDING,SITE_FUNDING,DOE/NIGEC -US-MMS,18363,GRP_SNAG_MASS,SNAG_MASS,1234 -US-MMS,18363,GRP_SNAG_MASS,SNAG_MASS_UNIT,gC m-2 -US-MMS,18363,GRP_SNAG_MASS,SNAG_MASS_DATE,2005 -US-MMS,22036,GRP_SOIL_CHEM,SOIL_CHEM_BD,1.22 -US-MMS,22036,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,0 -US-MMS,22036,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,0.1 -US-MMS,22036,GRP_SOIL_CHEM,SOIL_CHEM_DATE,20000520 -US-MMS,22037,GRP_SOIL_STOCK,SOIL_STOCK_C_ORG,6600 -US-MMS,22037,GRP_SOIL_STOCK,SOIL_STOCK_N_TOT,1020 -US-MMS,22037,GRP_SOIL_STOCK,SOIL_STOCK_PROFILE_MIN,0 -US-MMS,22037,GRP_SOIL_STOCK,SOIL_STOCK_PROFILE_MAX,100 -US-MMS,22038,GRP_SOIL_TEX,SOIL_TEX_SAND,34 -US-MMS,22038,GRP_SOIL_TEX,SOIL_TEX_SILT,3 -US-MMS,22038,GRP_SOIL_TEX,SOIL_TEX_CLAY,63 -US-MMS,18322,GRP_SPP_O,SPP_O,Acer saccharum -US-MMS,24524,GRP_SPP_O,SPP_O,ACSAS (NRCS plant code) -US-MMS,18384,GRP_SPP_O,SPP_O,Carya glabra -US-MMS,18382,GRP_SPP_O,SPP_O,Fagus grandifolia -US-MMS,18325,GRP_SPP_O,SPP_O,Liriodendron tulipifera -US-MMS,24910,GRP_SPP_O,SPP_O,LITU (NRCS plant code) -US-MMS,18328,GRP_SPP_O,SPP_O,Quercus alba -US-MMS,18330,GRP_SPP_O,SPP_O,Quercus rubra -US-MMS,18332,GRP_SPP_O,SPP_O,Quercus velutina -US-MMS,18334,GRP_SPP_O,SPP_O,Sassafras albidum -US-MMS,18380,GRP_SPP_O,SPP_O,Ulmus rubra -US-MMS,24524,GRP_SPP_O,SPP_APPROACH,Descriptive -US-MMS,24910,GRP_SPP_O,SPP_APPROACH,Descriptive -US-MMS,18322,GRP_SPP_O,SPP_DATE,19600401 -US-MMS,18325,GRP_SPP_O,SPP_DATE,19600401 -US-MMS,18328,GRP_SPP_O,SPP_DATE,19600401 -US-MMS,18330,GRP_SPP_O,SPP_DATE,19600401 -US-MMS,18332,GRP_SPP_O,SPP_DATE,19600401 -US-MMS,18334,GRP_SPP_O,SPP_DATE,19600401 -US-MMS,18380,GRP_SPP_O,SPP_DATE,19600401 -US-MMS,18382,GRP_SPP_O,SPP_DATE,19600401 -US-MMS,18384,GRP_SPP_O,SPP_DATE,19600401 -US-MMS,18323,GRP_SPP_U,SPP_U,Asimina triloba -US-MMS,18326,GRP_SPP_U,SPP_U,Lindera benzoin -US-MMS,18323,GRP_SPP_U,SPP_DATE,19600401 -US-MMS,18326,GRP_SPP_U,SPP_DATE,19600401 -US-MMS,11728,GRP_STATE,STATE,IN -US-MMS,11729,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Kim Novick -US-MMS,11729,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-MMS,11729,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,knovick@indiana.edu -US-MMS,11729,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Indiana University -US-MMS,11734,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Rich Phillips -US-MMS,11734,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-MMS,11734,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,rpp6@indiana.edu -US-MMS,11734,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Indiana University -US-MMS,85043,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Mike Voyles -US-MMS,85043,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,BADMContact -US-MMS,85043,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,mpvoyles@indiana.edu -US-MMS,85043,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Indiana University -US-MMS,11743,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Steven Scott -US-MMS,11743,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Technician -US-MMS,11743,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,stlscott@indiana.edu -US-MMS,11743,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Indiana University -US-MMS,11751,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Hans Peter Schmid -US-MMS,11751,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Affiliate -US-MMS,11751,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,hape.schmid@kit.edu -US-MMS,11751,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"Karlsruhe Institute of Technology, IMK-IFU" -US-MMS,85044,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Quan Zhang -US-MMS,85044,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Affiliate -US-MMS,85044,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,quazhang@indiana.edu -US-MMS,85044,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Indiana University -US-MMS,89984,GRP_TOWER_POWER,TOWER_POWER,Direct power -US-MMS,89978,GRP_TOWER_TYPE,TOWER_TYPE,triangle -US-MMS,11730,GRP_URL,URL,http://www.indiana.edu/~co2/ -US-MMS,24000398,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-MMS -US-MMS,11731,GRP_UTC_OFFSET,UTC_OFFSET,-5 -US-MMS,18364,GRP_WD_BIOMASS,WD_BIOMASS_CRS,212.1 -US-MMS,18369,GRP_WD_BIOMASS,WD_BIOMASS_FINE,18.56 -US-MMS,18373,GRP_WD_BIOMASS,WD_BIOMASS_FINE,25.39 -US-MMS,18295,GRP_WD_BIOMASS,WD_BIOMASS_FINE,36.04 -US-MMS,18377,GRP_WD_BIOMASS,WD_BIOMASS_FINE,41.04 -US-MMS,18295,GRP_WD_BIOMASS,WD_BIOMASS_UNIT,gC m-2 -US-MMS,18364,GRP_WD_BIOMASS,WD_BIOMASS_UNIT,gC m-2 -US-MMS,18369,GRP_WD_BIOMASS,WD_BIOMASS_UNIT,gC m-2 -US-MMS,18373,GRP_WD_BIOMASS,WD_BIOMASS_UNIT,gC m-2 -US-MMS,18377,GRP_WD_BIOMASS,WD_BIOMASS_UNIT,gC m-2 -US-MMS,18369,GRP_WD_BIOMASS,WD_BIOMASS_DATE,1999 -US-MMS,18373,GRP_WD_BIOMASS,WD_BIOMASS_DATE,2000 -US-MMS,18377,GRP_WD_BIOMASS,WD_BIOMASS_DATE,2001 -US-MMS,18295,GRP_WD_BIOMASS,WD_BIOMASS_DATE,2002 -US-MMS,18364,GRP_WD_BIOMASS,WD_BIOMASS_DATE,2003 -US-MOz,30122,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,"The MOFLUX site is supported by Oak Ridge National Laboratory’s Terrestrial Ecosystem Science (TES) Scientific Focus Area (SFA), which in turn is supported by the U.S. Department of Energy, Office of Science, Office of Biological and Environmental Research Program, Climate and Environmental Sciences Division." -US-MOz,24658,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER,14.9831 -US-MOz,24658,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_ORGAN,Total -US-MOz,24658,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_PHEN,Mixed/unknown -US-MOz,24658,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_UNIT,kgDM m-2 -US-MOz,24489,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS,463.95 -US-MOz,24489,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_UNIT,gC m-2 -US-MOz,24489,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_DATE,2004 -US-MOz,24489,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_COMMENT,Liitter data from frequent collections of 48 0.225 m2 litter traps on 24 permanent plots (2 traps per plot); all data included (twigs >1 cm very small contribution) -US-MOz,24085,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS,539.11 -US-MOz,24085,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_UNIT,gC m-2 -US-MOz,24085,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_DATE,2005 -US-MOz,24085,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_COMMENT,Liitter data from frequent collections of 48 0.225 m2 litter traps on 24 permanent plots (2 traps per plot); all data included (twigs >1 cm very small contribution) -US-MOz,24490,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS,640.31 -US-MOz,24490,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_UNIT,gC m-2 -US-MOz,24490,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_DATE,2006 -US-MOz,24490,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_COMMENT,Liitter data from frequent collections of 48 0.225 m2 litter traps on 24 permanent plots (2 traps per plot); all data included (twigs >1 cm very small contribution) -US-MOz,24982,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT,463.95 -US-MOz,24598,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT,539.11 -US-MOz,24859,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT,640.31 -US-MOz,24598,GRP_AG_LIT_PROD,AG_LIT_PROD_UNIT,gC m-2 -US-MOz,24859,GRP_AG_LIT_PROD,AG_LIT_PROD_UNIT,gC m-2 -US-MOz,24982,GRP_AG_LIT_PROD,AG_LIT_PROD_UNIT,gC m-2 -US-MOz,24598,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_START,2007 -US-MOz,24859,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_START,2007 -US-MOz,24982,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_START,2007 -US-MOz,25116,GRP_BIOMASS_CHEM,BIOMASS_N,0.073 -US-MOz,23959,GRP_BIOMASS_CHEM,BIOMASS_N,0.121 -US-MOz,23960,GRP_BIOMASS_CHEM,BIOMASS_N,0.123 -US-MOz,24595,GRP_BIOMASS_CHEM,BIOMASS_N,0.124 -US-MOz,24215,GRP_BIOMASS_CHEM,BIOMASS_N,0.138 -US-MOz,25115,GRP_BIOMASS_CHEM,BIOMASS_N,0.142 -US-MOz,24217,GRP_BIOMASS_CHEM,BIOMASS_N,0.19 -US-MOz,24067,GRP_BIOMASS_CHEM,BIOMASS_N,0.209 -US-MOz,24216,GRP_BIOMASS_CHEM,BIOMASS_N,0.216 -US-MOz,25117,GRP_BIOMASS_CHEM,BIOMASS_N,0.251 -US-MOz,23959,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-MOz,23960,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-MOz,24067,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-MOz,24215,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-MOz,24216,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-MOz,24217,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-MOz,24595,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-MOz,25115,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-MOz,25116,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-MOz,25117,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-MOz,23959,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-MOz,23960,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-MOz,24067,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-MOz,24215,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-MOz,24216,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-MOz,24217,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-MOz,24595,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-MOz,25115,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-MOz,25116,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-MOz,25117,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-MOz,23959,GRP_BIOMASS_CHEM,BIOMASS_SPP,ACSAF (NRCS plant code) -US-MOz,24217,GRP_BIOMASS_CHEM,BIOMASS_SPP,ACSAF (NRCS plant code) -US-MOz,24215,GRP_BIOMASS_CHEM,BIOMASS_SPP,CAOV2 (NRCS plant code) -US-MOz,25117,GRP_BIOMASS_CHEM,BIOMASS_SPP,CAOV2 (NRCS plant code) -US-MOz,24595,GRP_BIOMASS_CHEM,BIOMASS_SPP,JUVI (NRCS plant code) -US-MOz,25116,GRP_BIOMASS_CHEM,BIOMASS_SPP,JUVI (NRCS plant code) -US-MOz,24216,GRP_BIOMASS_CHEM,BIOMASS_SPP,QUAL (NRCS plant code) -US-MOz,25115,GRP_BIOMASS_CHEM,BIOMASS_SPP,QUAL (NRCS plant code) -US-MOz,23960,GRP_BIOMASS_CHEM,BIOMASS_SPP,QUVE (NRCS plant code) -US-MOz,24067,GRP_BIOMASS_CHEM,BIOMASS_SPP,QUVE (NRCS plant code) -US-MOz,23959,GRP_BIOMASS_CHEM,BIOMASS_DATE,20060613 -US-MOz,23960,GRP_BIOMASS_CHEM,BIOMASS_DATE,20060613 -US-MOz,24215,GRP_BIOMASS_CHEM,BIOMASS_DATE,20060613 -US-MOz,25115,GRP_BIOMASS_CHEM,BIOMASS_DATE,20060613 -US-MOz,25116,GRP_BIOMASS_CHEM,BIOMASS_DATE,20060613 -US-MOz,24067,GRP_BIOMASS_CHEM,BIOMASS_DATE,20070616 -US-MOz,24216,GRP_BIOMASS_CHEM,BIOMASS_DATE,20070616 -US-MOz,24217,GRP_BIOMASS_CHEM,BIOMASS_DATE,20070616 -US-MOz,24595,GRP_BIOMASS_CHEM,BIOMASS_DATE,20070616 -US-MOz,25117,GRP_BIOMASS_CHEM,BIOMASS_DATE,20070616 -US-MOz,23959,GRP_BIOMASS_CHEM,BIOMASS_COMMENT,(Acer saccharum) -US-MOz,24217,GRP_BIOMASS_CHEM,BIOMASS_COMMENT,(Acer saccharum) -US-MOz,24215,GRP_BIOMASS_CHEM,BIOMASS_COMMENT,(Carya ovata) -US-MOz,25117,GRP_BIOMASS_CHEM,BIOMASS_COMMENT,(Carya ovata) -US-MOz,24595,GRP_BIOMASS_CHEM,BIOMASS_COMMENT,(Juniperus virginiana) -US-MOz,25116,GRP_BIOMASS_CHEM,BIOMASS_COMMENT,(Juniperus virginiana) -US-MOz,24216,GRP_BIOMASS_CHEM,BIOMASS_COMMENT,(Quercus alba) -US-MOz,25115,GRP_BIOMASS_CHEM,BIOMASS_COMMENT,(Quercus alba) -US-MOz,23960,GRP_BIOMASS_CHEM,BIOMASS_COMMENT,(Quercus velutina) -US-MOz,24067,GRP_BIOMASS_CHEM,BIOMASS_COMMENT,(Quercus velutina) -US-MOz,17085,GRP_CLIM_AVG,MAT,12.11 -US-MOz,17085,GRP_CLIM_AVG,MAP,986 -US-MOz,17085,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Cfa -US-MOz,27000399,GRP_COUNTRY,COUNTRY,USA -US-MOz,4334,GRP_DM_GENERAL,DM_GENERAL,Other -US-MOz,15624,GRP_DOI,DOI,10.17190/AMF/1246081 -US-MOz,15624,GRP_DOI,DOI_CITATION,"Jeffrey Wood, Lianhong Gu (2021), AmeriFlux BASE US-MOz Missouri Ozark Site, Ver. 9-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1246081" -US-MOz,15624,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-MOz,32131,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-MOz,32131,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Jeffrey Wood -US-MOz,32131,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-MOz,32131,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,woodjd@missouri.edu -US-MOz,32131,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of Missouri -US-MOz,32130,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-MOz,32130,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Lianhong Gu -US-MOz,32130,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-MOz,32130,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,lianhong-gu@ornl.gov -US-MOz,32130,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Oak Ridge National Laboratory -US-MOz,32133,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Oak Ridge National Laboratory -US-MOz,32133,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-MOz,32134,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,University of Missouri -US-MOz,32134,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-MOz,32132,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,DOE/TCP -US-MOz,32132,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-MOz,17086,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-MOz,17086,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-MOz,17086,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,2004 -US-MOz,17086,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-MOz,23000399,GRP_HEADER,SITE_NAME,Missouri Ozark Site -US-MOz,24325,GRP_HEIGHTC,HEIGHTC,24.2 -US-MOz,24325,GRP_HEIGHTC,HEIGHTC_DATE,20070407 -US-MOz,17087,GRP_IGBP,IGBP,DBF -US-MOz,24234,GRP_LAI,LAI_TYPE,LAI -US-MOz,24614,GRP_LAI,LAI_TYPE,LAI -US-MOz,24234,GRP_LAI,LAI_CLUMP,0.9 -US-MOz,24614,GRP_LAI,LAI_CLUMP,0.9 -US-MOz,24234,GRP_LAI,LAI_METHOD,LAI_2000 -US-MOz,24614,GRP_LAI,LAI_METHOD,LAI_2000 -US-MOz,24234,GRP_LAI,LAI_DATE,20060803 -US-MOz,24614,GRP_LAI,LAI_DATE,20070710 -US-MOz,24234,GRP_LAI,LAI_COMMENT,"clumping index (.9) for oak forests from Kucharik et al. (1999). Tree Physiol. 19, 695--706; Woody-to-total area ratio-0.11 for oak hickory forests from FLUXNET protocol manual" -US-MOz,24614,GRP_LAI,LAI_COMMENT,"clumping index (.9) for oak forests from Kucharik et al. (1999). Tree Physiol. 19, 695--706; Woody-to-total area ratio-0.11 for oak hickory forests from FLUXNET protocol manual" -US-MOz,24614,GRP_LAI,LAI_TOT,3.81 -US-MOz,24234,GRP_LAI,LAI_TOT,4.01 -US-MOz,17088,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-MOz,17088,GRP_LAND_OWNERSHIP,LAND_OWNER,"University of Missouri, Columbia, MO" -US-MOz,23964,GRP_LMA,LMA,122.6 -US-MOz,23964,GRP_LMA,LMA_SPP,JUVI (NRCS plant code) -US-MOz,23964,GRP_LMA,LMA_DATE,20060613 -US-MOz,23964,GRP_LMA,LMA_COMMENT,(Juniperus virginiana) -US-MOz,23965,GRP_LMA,LMA,64.87 -US-MOz,23965,GRP_LMA,LMA_SPP,CAOV2 (NRCS plant code) -US-MOz,23965,GRP_LMA,LMA_DATE,20060613 -US-MOz,23965,GRP_LMA,LMA_COMMENT,(Carya ovata) -US-MOz,24724,GRP_LMA,LMA,65.11 -US-MOz,24724,GRP_LMA,LMA_SPP,ACSAF (NRCS plant code) -US-MOz,24724,GRP_LMA,LMA_DATE,20060613 -US-MOz,24724,GRP_LMA,LMA_COMMENT,(Acer saccharum) -US-MOz,24224,GRP_LMA,LMA,74.22 -US-MOz,24224,GRP_LMA,LMA_SPP,ACSAF (NRCS plant code) -US-MOz,24224,GRP_LMA,LMA_DATE,20070616 -US-MOz,24224,GRP_LMA,LMA_COMMENT,(Acer saccharum) 2007 data reflect effects of severe freeze and consequent shoot and leaf injury/death on LMA and %N -US-MOz,24984,GRP_LMA,LMA,77.15 -US-MOz,24984,GRP_LMA,LMA_SPP,QUVE (NRCS plant code) -US-MOz,24984,GRP_LMA,LMA_DATE,20070616 -US-MOz,24984,GRP_LMA,LMA_COMMENT,(Quercus velutina) 2007 data reflect effects of severe freeze and consequent shoot and leaf injury/death on LMA and %N -US-MOz,25120,GRP_LMA,LMA,80.61 -US-MOz,25120,GRP_LMA,LMA_SPP,QUAL (NRCS plant code) -US-MOz,25120,GRP_LMA,LMA_DATE,20070616 -US-MOz,25120,GRP_LMA,LMA_COMMENT,(Quercus alba) 2007 data reflect effects of severe freeze and consequent shoot and leaf injury/death on LMA and %N -US-MOz,23703,GRP_LMA,LMA,86.13 -US-MOz,23703,GRP_LMA,LMA_SPP,QUAL (NRCS plant code) -US-MOz,23703,GRP_LMA,LMA_DATE,20060613 -US-MOz,23703,GRP_LMA,LMA_COMMENT,(Quercus alba) Comment: 2007 data reflect effects of severe freeze and consequent shoot and leaf injury/death on LMA and %N -US-MOz,24985,GRP_LMA,LMA,93 -US-MOz,24985,GRP_LMA,LMA_SPP,CAOV2 (NRCS plant code) -US-MOz,24985,GRP_LMA,LMA_DATE,20070616 -US-MOz,24985,GRP_LMA,LMA_COMMENT,(Carya ovata) 2007 data reflect effects of severe freeze and consequent shoot and leaf injury/death on LMA and %N -US-MOz,24225,GRP_LMA,LMA,96.78 -US-MOz,24225,GRP_LMA,LMA_SPP,JUVI (NRCS plant code) -US-MOz,24225,GRP_LMA,LMA_DATE,20070616 -US-MOz,24225,GRP_LMA,LMA_COMMENT,(Juniperus virginiana) 2007 data reflect effects of severe freeze and consequent shoot and leaf injury/death on LMA and %N -US-MOz,24334,GRP_LMA,LMA,99.48 -US-MOz,24334,GRP_LMA,LMA_SPP,QUVE (NRCS plant code) -US-MOz,24334,GRP_LMA,LMA_DATE,20060613 -US-MOz,24334,GRP_LMA,LMA_COMMENT,(Quercus velutina) -US-MOz,17089,GRP_LOCATION,LOCATION_LAT,38.7441 -US-MOz,17089,GRP_LOCATION,LOCATION_LONG,-92.2000 -US-MOz,17089,GRP_LOCATION,LOCATION_ELEV,219.40 -US-MOz,24021,GRP_N_DEP,N_DEP_WET,0.603 -US-MOz,17090,GRP_NETWORK,NETWORK,AmeriFlux -US-MOz,86984,GRP_NETWORK,NETWORK,Phenocam -US-MOz,24237,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,Leaf senescence -US-MOz,24237,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,(All) -US-MOz,24237,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20070601 -US-MOz,24237,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,Datum above reflects all species (=time of max LAI) -US-MOz,23978,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,Maximum leaf expansion -US-MOz,23978,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,(All) -US-MOz,23978,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20061126 -US-MOz,23978,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,All species (indicated by sharp decline in litterfall data) -US-MOz,24346,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,Maximum leaf expansion -US-MOz,24346,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,(All) -US-MOz,24346,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20041115 -US-MOz,24346,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,All species (indicated by sharp decline in litterfall data) -US-MOz,24747,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,Maximum leaf expansion -US-MOz,24747,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,(All) -US-MOz,24747,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20051117 -US-MOz,24747,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,All species (indicated by sharp decline in litterfall data) -US-MOz,1700005430,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Barr, A., Richardson, A., Hollinger, D., Papale, D., Arain, M., Black, T., Bohrer, G., Dragoni, D., Fischer, M., Gu, L., Law, B., Margolis, H., McCaughey, J., Munger, J., Oechel, W., Schaeffer, K. (2013) Use Of Change-Point Detection For Friction–Velocity Threshold Evaluation In Eddy-Covariance Studies, Agricultural And Forest Meteorology, 171-172(7), 31-45" -US-MOz,1700005430,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2012.11.023 -US-MOz,1700005430,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-MOz,1700008613,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(11), 108350" -US-MOz,1700008613,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -US-MOz,1700008613,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-MOz,1700000705,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Dennis Baldocchi, Cove Sturtevant (2015) Does day and night sampling reduce spurious correlation between canopy photosynthesis and ecosystem respiration?, Agricultural and Forest Meteorology, 207(D16), 117-126" -US-MOz,1700000705,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2015.03.010 -US-MOz,1700000705,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-MOz,1700007146,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Gu, L. (2013) An Eddy Covariance Theory Of Using O2 To CO2 Exchange Ratio To Constrain Measurements Of Net Ecosystem Exchange Of Any Gas Species, Agricultural And Forest Meteorology, 176(3), 104-110" -US-MOz,1700007146,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2013.03.012 -US-MOz,1700007146,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-MOz,1700005526,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Gu, L., Hanson, P. J., Mac Post, W., Liu, Q. (2008) A Novel Approach For Identifying The True Temperature Sensitivity From Soil Respiration Measurements, Global Biogeochemical Cycles, 22(4), n/a-n/a" -US-MOz,1700005526,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2007GB003164 -US-MOz,1700005526,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-MOz,1700007323,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Gu, L., Hanson, P. J., Post, W. M., Kaiser, D. P., Yang, B., Nemani, R., Pallardy, S. G., Meyers, T. (2008) The 2007 Eastern Us Spring Freeze: Increased Cold Damage In A Warming World?, Bioscience, 58(3), 253-262" -US-MOz,1700007323,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1641/B580311 -US-MOz,1700007323,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-MOz,1700007116,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Gu, L., Massman, W. J., Leuning, R., Pallardy, S. G., Meyers, T., Hanson, P. J., Riggs, J. S., Hosman, K. P., Yang, B. (2012) The Fundamental Equation Of Eddy Covariance And Its Application In Flux Measurements, Agricultural And Forest Meteorology, 152(3), 135-148" -US-MOz,1700007116,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2011.09.014 -US-MOz,1700007116,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-MOz,1700007089,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Gu, L., Meyers, T., Pallardy, S. G., Hanson, P. J., Yang, B., Heuer, M., Hosman, K. P., Liu, Q., Riggs, J. S., Sluss, D., Wullschleger, S. D. (2006) Influences Of Biomass Heat And Biochemical Energy Storages On The Land Surface Fluxes And Radiative Temperature, Journal Of Geophysical Research: Atmospheres, 112(D2), n/a-n/a" -US-MOz,1700007089,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2006JD007425 -US-MOz,1700007089,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-MOz,1700004896,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Gu, L., Meyers, T., Pallardy, S. G., Hanson, P. J., Yang, B., Heuer, M., Hosman, K. P., Riggs, J. S., Sluss, D., Wullschleger, S. D. (2006) Direct And Indirect Effects Of Atmospheric Conditions And Soil Moisture On Surface Energy Partitioning Revealed By A Prolonged Drought At A Temperate Forest Site, Journal Of Geophysical Research, 111(D16), n/a-n/a" -US-MOz,1700004896,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2006JD007161 -US-MOz,1700004896,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-MOz,1700000810,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Gu, L., Pallardy, S. G., Hosman, K. P., Sun, Y. (2015) Drought-Influenced Mortality Of Tree Species With Different Predawn Leaf Water Dynamics In A Decade-Long Study Of A Central Us Forest, Biogeosciences, 12(10), 2831-2845" -US-MOz,1700000810,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.5194/BG-12-2831-2015 -US-MOz,1700000810,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-MOz,1700005802,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Gu, L., Pallardy, S. G., Hosman, K. P., Sun, Y. (2016) Impacts of Precipitation Variability on Plant Species and Community Water Stress in a Temperate Deciduous Forest in the Central US, Agricultural And Forest Meteorology, 217(7), 120-136" -US-MOz,1700005802,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2015.11.014 -US-MOz,1700005802,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-MOz,1700008991,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Gu, L., Pallardy, S. G., Yang, B., Hosman, K. P., Mao, J., Ricciuto, D., Shi, X., Sun, Y. (2016) Testing a Land Model In Ecosystem Functional Space via a Comparison of Observed and Modeled Ecosystem Responses to Precipitation Regimes and Associated Stresses in a Central U.S. Forest, Journal Of Geophysical Research: Biogeosciences, 121(7), 1884-1902" -US-MOz,1700008991,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/2015JG003302 -US-MOz,1700008991,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-MOz,1700001161,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Gu, L., Wood, J. D., Chang, C. Y., Sun, Y., Riggs, J. S. (2019) Advancing Terrestrial Ecosystem Science With A Novel Automated Measurement System For Sun-Induced Chlorophyll Fluorescence For Integration With Eddy Covariance Flux Networks, Journal Of Geophysical Research: Biogeosciences, 124(1), 127-146" -US-MOz,1700001161,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018JG004742 -US-MOz,1700001161,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-MOz,1700007314,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Matheny, A. M., Bohrer, G., Stoy, P. C., Baker, I. T., Black, A. T., Desai, A. R., Dietze, M. C., Gough, C. M., Ivanov, V. Y., Jassal, R. S., Novick, K. A., Schäfer, K. V., Verbeeck, H. (2014) Characterizing The Diurnal Patterns of Errors in The Prediction of Evapotranspiration by Several Land-Surface Models: An Nacp Analysis, Journal Of Geophysical Research: Biogeosciences, 119(7), 1458-1473" -US-MOz,1700007314,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/2014JG002623 -US-MOz,1700007314,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-MOz,1700001725,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"McFarlane, K. J., Torn, M. S., Hanson, P. J., Porras, R. C., Swanston, C. W., Callaham, M. A., Guilderson, T. P. (2013) Comparison Of Soil Organic Matter Dynamics At Five Temperate Deciduous Forests With Physical Fractionation And Radiocarbon Measurements, Biogeochemistry, 112(1-3), 457-476" -US-MOz,1700001725,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1007/S10533-012-9740-1 -US-MOz,1700001725,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-MOz,1700005160,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Momen, M., Wood, J. D., Novick, K. A., Pangle, R., Pockman, W. T., McDowell, N. G., Konings, A. G. (2017) Interacting Effects Of Leaf Water Potential And Biomass On Vegetation Optical Depth, Journal Of Geophysical Research: Biogeosciences, 122(11), 3031-3046" -US-MOz,1700005160,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/2017JG004145 -US-MOz,1700005160,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-MOz,1700008439,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Montané, F., Fox, A. M., Arellano, A. F., MacBean, N., Alexander, M. R., Dye, A., Bishop, D. A., Trouet, V., Babst, F., Hessl, A. E., Pederson, N., Blanken, P. D., Bohrer, G., Gough, C. M., Litvak, M. E., Novick, K. A., Phillips, R. P., Wood, J. D., Moore, D. J. (2017) Evaluating The Effect Of Alternative Carbon Allocation Schemes In A Land Surface Model (Clm4.5) On Carbon Fluxes, Pools, And Turnover In Temperate Forests, Geoscientific Model Development, 10(9), 3499-3517" -US-MOz,1700008439,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.5194/GMD-10-3499-2017 -US-MOz,1700008439,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-MOz,1700000540,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Novick, K. A., Ficklin, D. L., Stoy, P. C., Williams, C. A., Bohrer, G., Oishi, A., Papuga, S. A., Blanken, P. D., Noormets, A., Sulman, B. N., Scott, R. L., Wang, L., Phillips, R. P. (2016) The Increasing Importance Of Atmospheric Demand For Ecosystem Water And Carbon Fluxes, Nature Climate Change, 6(11), 1023-1027" -US-MOz,1700000540,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1038/NCLIMATE3114 -US-MOz,1700000540,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-MOz,1700004281,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Pallardy, S. G., Nigh, T. A., Garrett, H. E. (1988) Changes In Forest Composition In Central Missouri: 1968-1982, American Midland Naturalist, 120(2), 380-390" -US-MOz,1700004281,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.2307/2426010 -US-MOz,1700004281,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-MOz,1700003438,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Porras, R. C., Hicks Pries, C. E., McFarlane, K. J., Hanson, P. J., Torn, M. S. (2017) Association With Pedogenic Iron And Aluminum: Effects On Soil Organic Carbon Storage And Stability In Four Temperate Forest Soils, Biogeochemistry, 133(3), 333-345" -US-MOz,1700003438,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1007/S10533-017-0337-6 -US-MOz,1700003438,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-MOz,1700004551,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Potosnak, M. J., LeStourgeon, L., Pallardy, S. G., Hosman, K. P., Gu, L., Karl, T., Geron, C., Guenther, A. B. (2014) Observed And Modeled Ecosystem Isoprene Fluxes From An Oak-Dominated Temperate Forest And The Influence Of Drought Stress, Atmospheric Environment, 84(10), 314-322" -US-MOz,1700004551,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.ATMOSENV.2013.11.055 -US-MOz,1700004551,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-MOz,1700002724,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Seco, R., Karl, T., Guenther, A., Hosman, K. P., Pallardy, S. G., Gu, L., Geron, C., Harley, P., Kim, S. (2015) Ecosystem-Scale Volatile Organic Compound Fluxes During An Extreme Drought In A Broadleaf Temperate Forest Of The Missouri Ozarks (Central USA)), Global Change Biology, 21(10), 3657-3674" -US-MOz,1700002724,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/GCB.12980 -US-MOz,1700002724,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-MOz,1700005844,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Sun, Y., Frankenberg, C., Wood, J. D., Schimel, D. S., Jung, M., Guanter, L., Drewry, D. T., Verma, M., Porcar-Castell, A., Griffis, T. J., Gu, L., Magney, T. S., Köhler, P., Evans, B., Yuen, K. (2017) Oco-2 Advances Photosynthesis Observation From Space Via Solar-Induced Chlorophyll Fluorescence, Science, 358(6360), eaam5747" -US-MOz,1700005844,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1126/SCIENCE.AAM5747 -US-MOz,1700005844,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-MOz,1700006762,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Toomey, M., Friedl, M. A., Frolking, S., Hufkens, K., Klosterman, S., Sonnentag, O., Baldocchi, D. D., Bernacchi, C. J., Biraud, S. C., Bohrer, G., Brzostek, E., Burns, S. P., Coursolle, C., Hollinger, D. Y., Margolis, H. A., McCaughey, H., Monson, R. K., Munger, J. W., Pallardy, S., Phillips, R. P., Torn, M. S., Wharton, S., Zeri, M., Richardson, A. D. (2015) Greenness Indices From Digital Cameras Predict The Timing And Seasonal Dynamics Of Canopy-Scale Photosynthesis, Ecological Applications, 25(1), 99-115" -US-MOz,1700006762,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1890/14-0005.1 -US-MOz,1700006762,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-MOz,1700004425,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Wang, Y., Köhler, P., He, L., Doughty, R., Braghiere, R. K., Wood, J. D., Frankenberg, C. (2021) Testing Stomatal Models At The Stand Level In Deciduous Angiosperm And Evergreen Gymnosperm Forests Using Clima Land (V0.1), Geoscientific Model Development, 14(11), 6741-6763" -US-MOz,1700004425,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.5194/GMD-14-6741-2021 -US-MOz,1700004425,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-MOz,1700008544,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Wood, J. D., Knapp, B. O., Muzika, R., Stambaugh, M. C., Gu, L. (2018) The Importance Of Drought–Pathogen Interactions In Driving Oak Mortality Events In The Ozark Border Region, Environmental Research Letters, 13(1), 015004" -US-MOz,1700008544,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1088/1748-9326/AA94FA -US-MOz,1700008544,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-MOz,1700005127,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Wood, J. D., Sadler, E. J., Fox, N. I., Greer, S. T., Gu, L., Guinan, P. E., Lupo, A. R., Market, P. S., Rochette, S. M., Speck, A., White, L. D. (2019) Land-Atmosphere Responses To A Total Solar Eclipse In Three Ecosystems With Contrasting Structure And Physiology, Journal Of Geophysical Research: Atmospheres, 124(2), 530-543" -US-MOz,1700005127,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018JD029630 -US-MOz,1700005127,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-MOz,1700005733,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"YANG, B., PALLARDY, S. G., MEYERS, T. P., GU, L., HANSON, P. J., WULLSCHLEGER, S. D., HEUER, M., HOSMAN, K. P., RIGGS, J. S., SLUSS, D. W. (2009) Environmental Controls On Water Use Efficiency During Severe Drought In An Ozark Forest In Missouri, Usa, Global Change Biology, 16(8), 2252-2271" -US-MOz,1700005733,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/J.1365-2486.2009.02138.X -US-MOz,1700005733,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-MOz,1700008730,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Yue, X., Unger, N., Keenan, T. F., Zhang, X., Vogel, C. S. (2015) Probing The Past 30-Year Phenology Trend Of Us Deciduous Forests, Biogeosciences, 12(15), 4693-4709" -US-MOz,1700008730,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.5194/BG-12-4693-2015 -US-MOz,1700008730,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-MOz,17092,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"Science objectives include: long term monitoring of carbon dioxide and water vapor concentrations, above canopy and sub-canopy energy fluxes, characterization of meteorological and environmental conditions, soil respiration, sap flow, canopy phenology, and leaf-level photosynthetic biochemistry." -US-MOz,23824,GRP_SA,SA,77 -US-MOz,23824,GRP_SA,SA_DATE,2005 -US-MOz,23824,GRP_SA,SA_MAX,102 -US-MOz,17093,GRP_SITE_DESC,SITE_DESC,"The site is located in the University of Missouri Baskett Wildlife Research area, situated in the Ozark region of central Missouri. The site is uniquely located in the ecologically important transitional zone between the central hardwood region and the central grassland region of the US. The land has been publically owned since the 1930s, and is on a land tract that was forested with the same dominant species before settlement in the early 1800s." -US-MOz,17094,GRP_SITE_FUNDING,SITE_FUNDING,DOE/TCP -US-MOz,24063,GRP_SOIL_CHEM,SOIL_CHEM_BD,1.18 -US-MOz,24718,GRP_SOIL_CHEM,SOIL_CHEM_BD,1.37 -US-MOz,23697,GRP_SOIL_CHEM,SOIL_CHEM_BD,1.41 -US-MOz,24717,GRP_SOIL_CHEM,SOIL_CHEM_BD,1.46 -US-MOz,24064,GRP_SOIL_CHEM,SOIL_CHEM_BD,1.49 -US-MOz,23829,GRP_SOIL_CHEM,SOIL_CHEM_BD,1.52 -US-MOz,24063,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,0 -US-MOz,23697,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,15 -US-MOz,24717,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,23 -US-MOz,23829,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,35 -US-MOz,24718,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,53 -US-MOz,24064,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,70 -US-MOz,23697,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,15 -US-MOz,24717,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,25 -US-MOz,23829,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,35 -US-MOz,24063,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,5 -US-MOz,24718,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,55 -US-MOz,24064,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,72 -US-MOz,23697,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,Total -US-MOz,23829,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,Total -US-MOz,24063,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,Total -US-MOz,24064,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,Total -US-MOz,24717,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,Total -US-MOz,24718,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,Total -US-MOz,23697,GRP_SOIL_CHEM,SOIL_CHEM_DATE,20040608 -US-MOz,23829,GRP_SOIL_CHEM,SOIL_CHEM_DATE,20040608 -US-MOz,24063,GRP_SOIL_CHEM,SOIL_CHEM_DATE,20040608 -US-MOz,24064,GRP_SOIL_CHEM,SOIL_CHEM_DATE,20040608 -US-MOz,24717,GRP_SOIL_CHEM,SOIL_CHEM_DATE,20040608 -US-MOz,24718,GRP_SOIL_CHEM,SOIL_CHEM_DATE,20040608 -US-MOz,29313,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION,"Weller silt loam (typic Hapudalf, fine, montmorillonitic, mesic); rocky thin soil covering, pH 4-7" -US-MOz,29313,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION_TAXONOMY,Other -US-MOz,23787,GRP_SOIL_DEPTH,SOIL_DEPTH,38 -US-MOz,23787,GRP_SOIL_DEPTH,SOIL_DEPTH_COMMENT,"Weller: 0.38 Clinkenbeard: 0.25 -Stephen Pallardy: choose Weller as representative for site" -US-MOz,24553,GRP_SOIL_DEPTH,SOIL_DEPTH,165 -US-MOz,24553,GRP_SOIL_DEPTH,SOIL_DEPTH_COMMENT,Weller: 1.65 Clinkenbeard: 0.36 -US-MOz,25054,GRP_SOIL_DEPTH,SOIL_DEPTH,200 -US-MOz,25054,GRP_SOIL_DEPTH,SOIL_DEPTH_COMMENT,"Weller: 2 Clinkenbeard: 0.65 -Stephen Pallardy: choose Weller as representative for site" -US-MOz,24171,GRP_SOIL_TEX,SOIL_TEX_SAND,10.5 -US-MOz,24937,GRP_SOIL_TEX,SOIL_TEX_SAND,7.5 -US-MOz,24172,GRP_SOIL_TEX,SOIL_TEX_SILT,60 -US-MOz,23655,GRP_SOIL_TEX,SOIL_TEX_SILT,70 -US-MOz,24938,GRP_SOIL_TEX,SOIL_TEX_CLAY,15 -US-MOz,24173,GRP_SOIL_TEX,SOIL_TEX_CLAY,34 -US-MOz,23911,GRP_SOIL_TEX,SOIL_TEX_WATER_HOLD_CAP,305 -US-MOz,23655,GRP_SOIL_TEX,SOIL_TEX_PROFILE_MIN,0 -US-MOz,23911,GRP_SOIL_TEX,SOIL_TEX_PROFILE_MIN,0 -US-MOz,24171,GRP_SOIL_TEX,SOIL_TEX_PROFILE_MIN,0 -US-MOz,24172,GRP_SOIL_TEX,SOIL_TEX_PROFILE_MIN,0 -US-MOz,24173,GRP_SOIL_TEX,SOIL_TEX_PROFILE_MIN,0 -US-MOz,24937,GRP_SOIL_TEX,SOIL_TEX_PROFILE_MIN,0 -US-MOz,24938,GRP_SOIL_TEX,SOIL_TEX_PROFILE_MIN,0 -US-MOz,24171,GRP_SOIL_TEX,SOIL_TEX_PROFILE_MAX,165 -US-MOz,24172,GRP_SOIL_TEX,SOIL_TEX_PROFILE_MAX,165 -US-MOz,24173,GRP_SOIL_TEX,SOIL_TEX_PROFILE_MAX,165 -US-MOz,23911,GRP_SOIL_TEX,SOIL_TEX_PROFILE_MAX,200 -US-MOz,23655,GRP_SOIL_TEX,SOIL_TEX_PROFILE_MAX,38 -US-MOz,24937,GRP_SOIL_TEX,SOIL_TEX_PROFILE_MAX,38 -US-MOz,24938,GRP_SOIL_TEX,SOIL_TEX_PROFILE_MAX,38 -US-MOz,23655,GRP_SOIL_TEX,SOIL_TEX_HORIZON,A -US-MOz,24937,GRP_SOIL_TEX,SOIL_TEX_HORIZON,A -US-MOz,24938,GRP_SOIL_TEX,SOIL_TEX_HORIZON,A -US-MOz,24171,GRP_SOIL_TEX,SOIL_TEX_HORIZON,B -US-MOz,24172,GRP_SOIL_TEX,SOIL_TEX_HORIZON,B -US-MOz,24173,GRP_SOIL_TEX,SOIL_TEX_HORIZON,B -US-MOz,23911,GRP_SOIL_TEX,SOIL_TEX_HORIZON,Total -US-MOz,24171,GRP_SOIL_TEX,SOIL_TEX_COMMENT,(range 1-20) Weller: 1.65 Clinkenbeard: 0.36 -US-MOz,24938,GRP_SOIL_TEX,SOIL_TEX_COMMENT,"(range 12-18) Weller: 0.38 Clinkenbeard: 0.25 -Stephen Pallardy: choose Weller as representative for site" -US-MOz,24173,GRP_SOIL_TEX,SOIL_TEX_COMMENT,(range 20-48) Weller: 1.65 Clinkenbeard: 0.36 -US-MOz,24937,GRP_SOIL_TEX,SOIL_TEX_COMMENT,"(range 5-10) Weller: 0.38 Clinkenbeard: 0.25 -Stephen Pallardy: choose Weller as representative for site" -US-MOz,24172,GRP_SOIL_TEX,SOIL_TEX_COMMENT,(range 50-70) Weller: 1.65 Clinkenbeard: 0.36 -US-MOz,23655,GRP_SOIL_TEX,SOIL_TEX_COMMENT,"(range 60-80) Weller: 0.38 Clinkenbeard: 0.25 -Stephen Pallardy: choose Weller as representative for site" -US-MOz,23911,GRP_SOIL_TEX,SOIL_TEX_COMMENT,"Weller: 305 Clinkenbeard: 51 -Stephen Pallardy: choose Weller as representative for site; Weller: 2 Clinkenbeard: 0.65 -Stephen Pallardy: choose Weller as representative for site" -US-MOz,24336,GRP_SPP_O,SPP_O,ACSAF (NRCS plant code) -US-MOz,24868,GRP_SPP_O,SPP_O,CAOV2 (NRCS plant code) -US-MOz,24867,GRP_SPP_O,SPP_O,JUVI (NRCS plant code) -US-MOz,24607,GRP_SPP_O,SPP_O,QUAL (NRCS plant code) -US-MOz,24337,GRP_SPP_O,SPP_O,QUMU (NRCS plant code) -US-MOz,23840,GRP_SPP_O,SPP_O,QUVE (NRCS plant code) -US-MOz,24337,GRP_SPP_O,SPP_O_PERC,10.65 -US-MOz,24867,GRP_SPP_O,SPP_O_PERC,14.14 -US-MOz,24336,GRP_SPP_O,SPP_O_PERC,14.49 -US-MOz,24607,GRP_SPP_O,SPP_O_PERC,24.87 -US-MOz,23840,GRP_SPP_O,SPP_O_PERC,5.85 -US-MOz,24868,GRP_SPP_O,SPP_O_PERC,9.42 -US-MOz,23840,GRP_SPP_O,SPP_APPROACH,"diameter tape measurments of all trees >= 9 cm diamter breast height on 24, 0.08 ha permanent plots" -US-MOz,24336,GRP_SPP_O,SPP_APPROACH,"diameter tape measurments of all trees >= 9 cm diamter breast height on 24, 0.08 ha permanent plots" -US-MOz,24337,GRP_SPP_O,SPP_APPROACH,"diameter tape measurments of all trees >= 9 cm diamter breast height on 24, 0.08 ha permanent plots" -US-MOz,24607,GRP_SPP_O,SPP_APPROACH,"diameter tape measurments of all trees >= 9 cm diamter breast height on 24, 0.08 ha permanent plots" -US-MOz,24867,GRP_SPP_O,SPP_APPROACH,"diameter tape measurments of all trees >= 9 cm diamter breast height on 24, 0.08 ha permanent plots" -US-MOz,24868,GRP_SPP_O,SPP_APPROACH,"diameter tape measurments of all trees >= 9 cm diamter breast height on 24, 0.08 ha permanent plots" -US-MOz,23840,GRP_SPP_O,SPP_DATE,2005 -US-MOz,24336,GRP_SPP_O,SPP_DATE,2005 -US-MOz,24337,GRP_SPP_O,SPP_DATE,2005 -US-MOz,24607,GRP_SPP_O,SPP_DATE,2005 -US-MOz,24867,GRP_SPP_O,SPP_DATE,2005 -US-MOz,24868,GRP_SPP_O,SPP_DATE,2005 -US-MOz,24607,GRP_SPP_O,SPP_COMMENT,(39.5) (Quercus alba) Comment: (1) number in parentheses for dominant overstory species (>= 9 cm diameter at breast height) is % of total basal area in that species; (2) for understory species (1.3 m in height to 9 cm dbh) relative density is listed -US-MOz,24868,GRP_SPP_O,SPP_COMMENT,(6.13) (Carya ovata) Comment: (1) number in parentheses for dominant overstory species (>= 9 cm diameter at breast height) is % of total basal area in that species; (2) for understory species (1.3 m in height to 9 cm dbh) relative density is listed -US-MOz,24336,GRP_SPP_O,SPP_COMMENT,(6.96) (Acer saccharum) Comment: (1) number in parentheses for dominant overstory species (>= 9 cm diameter at breast height) is % of total basal area in that species; (2) for understory species (1.3 m in height to 9 cm dbh) relative density is listed -US-MOz,24867,GRP_SPP_O,SPP_COMMENT,(8.97) (Juniperus virginiana) Comment: (1) number in parentheses for dominant overstory species (>= 9 cm diameter at breast height) is % of total basal area in that species; (2) for understory species (1.3 m in height to 9 cm dbh) relative density is listed -US-MOz,23840,GRP_SPP_O,SPP_COMMENT,(9.16) (Quercus velutina) Comment: (1) number in parentheses for dominant overstory species (>= 9 cm diameter at breast height) is % of total basal area in that species; (2) for understory species (1.3 m in height to 9 cm dbh) relative density is listed -US-MOz,24337,GRP_SPP_O,SPP_COMMENT,(9.41) (Q. muehlenbergii) Comment: (1) number in parentheses for dominant overstory species (>= 9 cm diameter at breast height) is % of total basal area in that species; (2) for understory species (1.3 m in height to 9 cm dbh) relative density is listed -US-MOz,24340,GRP_SPP_U,SPP_U,ACSAF (NRCS plant code) -US-MOz,24078,GRP_SPP_U,SPP_U,FRAM2 (NRCS plant code) -US-MOz,24341,GRP_SPP_U,SPP_U,JUVI (NRCS plant code) -US-MOz,24870,GRP_SPP_U,SPP_U,OSVI (NRCS plant code) -US-MOz,24740,GRP_SPP_U,SPP_U,QUVE (NRCS plant code) -US-MOz,24870,GRP_SPP_U,SPP_U_PERC,11.7 -US-MOz,24341,GRP_SPP_U,SPP_U_PERC,12.24 -US-MOz,24078,GRP_SPP_U,SPP_U_PERC,15.3 -US-MOz,24340,GRP_SPP_U,SPP_U_PERC,34.11 -US-MOz,24740,GRP_SPP_U,SPP_U_PERC,4.14 -US-MOz,24078,GRP_SPP_U,SPP_APPROACH,"diameter tape measurments of all woody plants < 9 cm diamter breast height and greater than 1.3 m height on 24, 0.04 ha concentric permanent plots" -US-MOz,24340,GRP_SPP_U,SPP_APPROACH,"diameter tape measurments of all woody plants < 9 cm diamter breast height and greater than 1.3 m height on 24, 0.04 ha concentric permanent plots" -US-MOz,24341,GRP_SPP_U,SPP_APPROACH,"diameter tape measurments of all woody plants < 9 cm diamter breast height and greater than 1.3 m height on 24, 0.04 ha concentric permanent plots" -US-MOz,24740,GRP_SPP_U,SPP_APPROACH,"diameter tape measurments of all woody plants < 9 cm diamter breast height and greater than 1.3 m height on 24, 0.04 ha concentric permanent plots" -US-MOz,24870,GRP_SPP_U,SPP_APPROACH,"diameter tape measurments of all woody plants < 9 cm diamter breast height and greater than 1.3 m height on 24, 0.04 ha concentric permanent plots" -US-MOz,24078,GRP_SPP_U,SPP_DATE,2005 -US-MOz,24340,GRP_SPP_U,SPP_DATE,2005 -US-MOz,24341,GRP_SPP_U,SPP_DATE,2005 -US-MOz,24740,GRP_SPP_U,SPP_DATE,2005 -US-MOz,24870,GRP_SPP_U,SPP_DATE,2005 -US-MOz,24340,GRP_SPP_U,SPP_COMMENT,(Acer saccharum) Comment: (1) number in parentheses for dominant overstory species (>= 9 cm diameter at breast height) is % of total basal area in that species; (2) for understory species (1.3 m in height to 9 cm dbh) relative density is listed -US-MOz,24078,GRP_SPP_U,SPP_COMMENT,(Fraxinus americana) Comment: (1) number in parentheses for dominant overstory species (>= 9 cm diameter at breast height) is % of total basal area in that species; (2) for understory species (1.3 m in height to 9 cm dbh) relative density is listed -US-MOz,24341,GRP_SPP_U,SPP_COMMENT,(Juniperus virginiana) Comment: (1) number in parentheses for dominant overstory species (>= 9 cm diameter at breast height) is % of total basal area in that species; (2) for understory species (1.3 m in height to 9 cm dbh) relative density is listed -US-MOz,24870,GRP_SPP_U,SPP_COMMENT,(Ostrya virginiana) Comment: (1) number in parentheses for dominant overstory species (>= 9 cm diameter at breast height) is % of total basal area in that species; (2) for understory species (1.3 m in height to 9 cm dbh) relative density is listed -US-MOz,24740,GRP_SPP_U,SPP_COMMENT,(Quercus velutina) Comment: (1) number in parentheses for dominant overstory species (>= 9 cm diameter at breast height) is % of total basal area in that species; (2) for understory species (1.3 m in height to 9 cm dbh) relative density is listed -US-MOz,17095,GRP_STATE,STATE,MO -US-MOz,17099,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Jeffrey Wood -US-MOz,17099,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-MOz,17099,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,woodjd@missouri.edu -US-MOz,17099,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Missouri -US-MOz,17099,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"School of Natural Resources, 303B ABNR Bldg., University of Missouri, Columbia MO, 65211" -US-MOz,17096,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Lianhong Gu -US-MOz,17096,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-MOz,17096,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,lianhong-gu@ornl.gov -US-MOz,17096,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Oak Ridge National Laboratory -US-MOz,17096,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Environmental Sciences Division, P.O. Box 2008 Bldg. 1509,Oak Ridge, TN USA 37831-6335" -US-MOz,17101,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Yang Bai -US-MOz,17101,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Affiliate -US-MOz,17101,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,yangb@ornl.gov -US-MOz,17101,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Oak Ridge National Laboratory -US-MOz,17101,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Environmental Sciences Division, Building 1509,Oak Ridge, TN USA 37831-6335" -US-MOz,94786,GRP_URL,URL,https://youtu.be/HvAS-wXqMBw -US-MOz,24000399,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-MOz -US-MOz,17097,GRP_UTC_OFFSET,UTC_OFFSET,-6.00 -US-Mpj,30374,GRP_CLIM_AVG,MAT,10.5 -US-Mpj,30374,GRP_CLIM_AVG,MAP,385 -US-Mpj,30374,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Bsk -US-Mpj,27000473,GRP_COUNTRY,COUNTRY,USA -US-Mpj,15704,GRP_DOI,DOI,10.17190/AMF/1246123 -US-Mpj,15704,GRP_DOI,DOI_CITATION,"Marcy Litvak (2022), AmeriFlux BASE US-Mpj Mountainair Pinyon-Juniper Woodland, Ver. 18-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1246123" -US-Mpj,15704,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-Mpj,32265,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Mpj,32265,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Marcy Litvak -US-Mpj,32265,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Mpj,32265,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,mlitvak@unm.edu -US-Mpj,32265,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of New Mexico -US-Mpj,32267,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,University of New Mexico -US-Mpj,32267,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-Mpj,32266,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,"DOE-BER, USFS, DOE EPSCoR" -US-Mpj,32266,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-Mpj,15433,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Drought -US-Mpj,15444,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Pests and disease -US-Mpj,15434,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Mpj,15434,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-Mpj,15434,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,200701010000 -US-Mpj,15434,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Mpj,15445,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Mpj,15445,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-Mpj,15445,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,200701010000 -US-Mpj,15445,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Mpj,23000473,GRP_HEADER,SITE_NAME,Mountainair Pinyon-Juniper Woodland -US-Mpj,12385,GRP_IGBP,IGBP,OSH -US-Mpj,15435,GRP_IGBP,IGBP,ENF -US-Mpj,15435,GRP_IGBP,IGBP_DATE_START,200701010000 -US-Mpj,15435,GRP_IGBP,IGBP_COMMENT,"Pinyon Pine, Juniper" -US-Mpj,15446,GRP_IGBP,IGBP,WSA -US-Mpj,15446,GRP_IGBP,IGBP_DATE_START,201401010000 -US-Mpj,15446,GRP_IGBP,IGBP_COMMENT,Woody savannah after ~100% Pinyon mortality in 2013 -US-Mpj,15436,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -US-Mpj,15436,GRP_LAND_OWNERSHIP,LAND_OWNER,"Deer Canyon Preserve, Heritage Land Conservancy" -US-Mpj,12386,GRP_LOCATION,LOCATION_LAT,34.4384 -US-Mpj,12386,GRP_LOCATION,LOCATION_LONG,-106.2377 -US-Mpj,12386,GRP_LOCATION,LOCATION_ELEV,2138 -US-Mpj,12386,GRP_LOCATION,LOCATION_COMMENT,From CDIAC Tom Boden database dump -US-Mpj,30383,GRP_LOCATION,LOCATION_LAT,34.4385 -US-Mpj,30383,GRP_LOCATION,LOCATION_LONG,-106.2377 -US-Mpj,30383,GRP_LOCATION,LOCATION_ELEV,2196 -US-Mpj,30383,GRP_LOCATION,LOCATION_DATE_START,200701010000 -US-Mpj,12387,GRP_NETWORK,NETWORK,AmeriFlux -US-Mpj,86985,GRP_NETWORK,NETWORK,Phenocam -US-Mpj,1700006699,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Anderson-Teixeira, K. J., Delong, J. P., Fox, A. M., Brese, D. A., Litvak, M. E. (2011) Differential Responses Of Production And Respiration To Temperature And Moisture Drive The Carbon Balance Across A Climatic Gradient In New Mexico, Global Change Biology, 17(1), 410-424" -US-Mpj,1700006699,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/J.1365-2486.2010.02269.X -US-Mpj,1700006699,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Mpj,1700006957,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Biederman, J. A., Scott, R. L., Bell, T. W., Bowling, D. R., Dore, S., Garatuza-Payan, J., Kolb, T. E., Krishnan, P., Krofcheck, D. J., Litvak, M. E., Maurer, G. E., Meyers, T. P., Oechel, W. C., Papuga, S. A., Ponce-Campos, G. E., Rodriguez, J. C., Smith, W. K., Vargas, R., Watts, C. J., Yepez, E. A., Goulden, M. L. (2017) Co2 Exchange And Evapotranspiration Across Dryland Ecosystems Of Southwestern North America, Global Change Biology, 23(10), 4204-4221" -US-Mpj,1700006957,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/GCB.13686 -US-Mpj,1700006957,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Mpj,1700003690,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Biederman, J. A., Scott, R. L., Goulden, M. L., Vargas, R., Litvak, M. E., Kolb, T. E., Yepez, E. A., Oechel, W. C., Blanken, P. D., Bell, T. W., Garatuza-Payan, J., Maurer, G. E., Dore, S., Burns, S. P. (2016) Terrestrial Carbon Balance In A Drier World: The Effects Of Water Availability In Southwestern North America, Global Change Biology, 22(5), 1867-1879" -US-Mpj,1700003690,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/GCB.13222 -US-Mpj,1700003690,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Mpj,1700005103,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Brewer, W. L., Lippitt, C. L., Lippitt, C. D., Litvak, M. E. (2017) Assessing Drought-Induced Change In A PiñOn-Juniper Woodland With Landsat: A Multiple Endmember Spectral Mixture Analysis Approach, International Journal Of Remote Sensing, 38(14), 4156-4176" -US-Mpj,1700005103,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1080/01431161.2017.1317940 -US-Mpj,1700005103,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Mpj,1700005523,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(1), 108350" -US-Mpj,1700005523,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -US-Mpj,1700005523,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Mpj,1700001110,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Dettweiler-Robinson, E., Nuanez, M., Litvak, M. E. (2018) Biocrust Contribution To Ecosystem Carbon Fluxes Varies Along An Elevational Gradient, Ecosphere, 9(6), e02315" -US-Mpj,1700001110,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/ECS2.2315 -US-Mpj,1700001110,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Mpj,1700005532,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Fox, A. M., Hoar, T. J., Anderson, J. L., Arellano, A. F., Smith, W. K., Litvak, M. E., MacBean, N., Schimel, D. S., Moore, D. J. (2018) Evaluation Of A Data Assimilation System For Land Surface Models Using Clm4.5, Journal Of Advances In Modeling Earth Systems, 10(10), 2471-2494" -US-Mpj,1700005532,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018MS001362 -US-Mpj,1700005532,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Mpj,1700008532,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Krofcheck, D. J., Eitel, J. U., Vierling, L. A., Schulthess, U., Hilton, T. M., Dettweiler-Robinson, E., Pendleton, R., Litvak, M. E. (2014) Detecting Mortality Induced Structural And Functional Changes In A PiñOn-Juniper Woodland Using Landsat And Rapideye Time Series, Remote Sensing Of Environment, 151(1), 102-113" -US-Mpj,1700008532,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.RSE.2013.11.009 -US-Mpj,1700008532,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Mpj,1700006372,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Krofcheck, D., Eitel, J., Lippitt, C., Vierling, L., Schulthess, U., Litvak, M. (2015) Remote Sensing Based Simple Models Of Gpp In Both Disturbed And Undisturbed PiñOn-Juniper Woodlands In The Southwestern U.S., Remote Sensing, 8(1), 20" -US-Mpj,1700006372,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.3390/RS8010020 -US-Mpj,1700006372,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Mpj,1700006111,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Montané, F., Fox, A. M., Arellano, A. F., MacBean, N., Alexander, M. R., Dye, A., Bishop, D. A., Trouet, V., Babst, F., Hessl, A. E., Pederson, N., Blanken, P. D., Bohrer, G., Gough, C. M., Litvak, M. E., Novick, K. A., Phillips, R. P., Wood, J. D., Moore, D. J. (2017) Evaluating The Effect Of Alternative Carbon Allocation Schemes In A Land SurfaceModel (Clm4.5) On Carbon Fluxes, Pools And Turnover In Temperate Forests, Geoscientific Model Development, 122(12), 3343-3361" -US-Mpj,1700006111,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.5194/GMD-2017-74 -US-Mpj,1700006111,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Mpj,1700002874,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Morillas, L., Pangle, R. E., Maurer, G. E., Pockman, W. T., McDowell, N., Huang, C., Krofcheck, D. J., Fox, A. M., Sinsabaugh, R. L., Rahn, T. A., Litvak, M. E. (2017) Tree Mortality Decreases Water Availability And Ecosystem Resilience To Drought In PiñOn-Juniper Woodlands In The Southwestern U.S., Journal Of Geophysical Research: Biogeosciences, 122(12), 3343-3361" -US-Mpj,1700002874,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/2017JG004095 -US-Mpj,1700002874,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Mpj,1700005568,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Remy, C. C., Krofcheck, D. J., Keyser, A. R., Litvak, M. E., Collins, S. L., Hurteau, M. D. (2019) Integrating Species‐Specific Information In Models Improves Regional Projections Under Climate Change, Geophysical Research Letters, 46(12), 6554-6562" -US-Mpj,1700005568,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2019GL082762 -US-Mpj,1700005568,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Mpj,1700004467,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Senay, G. B., Schauer, M., Velpuri, N. M., Singh, R. K., Kagone, S., Friedrichs, M., Litvak, M. E., Douglas-Mankin, K. R. (2019) Long-Term (1986–2015) Crop Water Use Characterization Over The Upper Rio Grande Basin Of United States And Mexico Using Landsat-Based Evapotranspiration, Remote Sensing, 11(13), 1587" -US-Mpj,1700004467,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.3390/RS11131587 -US-Mpj,1700004467,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Mpj,1700000876,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Smith, W. K., Biederman, J. A., Scott, R. L., Moore, D. J., He, M., Kimball, J. S., Yan, D., Hudson, A., Barnes, M. L., MacBean, N., Fox, A. M., Litvak, M. E. (2018) Chlorophyll Fluorescence Better Captures Seasonal And Interannual Gross Primary Productivity Dynamics Across Dryland Ecosystems Of Southwestern North America, Geophysical Research Letters, 45(2), 748-757" -US-Mpj,1700000876,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/2017GL075922 -US-Mpj,1700000876,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Mpj,1700000543,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Stark, S. C., Breshears, D. D., Garcia, E. S., Law, D. J., Minor, D. M., Saleska, S. R., Swann, A. L., Villegas, J. C., Aragão, L. E., Bella, E. M., Borma, L. S., Cobb, N. S., Litvak, M. E., Magnusson, W. E., Morton, J. M., Redmond, M. D. (2016) Toward Accounting For Ecoclimate Teleconnections: Intra- And Inter-Continental Consequences Of Altered Energy Balance After Vegetation Change, Landscape Ecology, 31(1), 181-194" -US-Mpj,1700000543,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1007/S10980-015-0282-5 -US-Mpj,1700000543,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Mpj,1700003756,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Wolf, S., Keenan, T. F., Fisher, J. B., Baldocchi, D. D., Desai, A. R., Richardson, A. D., Scott, R. L., Law, B. E., Litvak, M. E., Brunsell, N. A., Peters, W., van der Laan-Luijkx, I. T. (2016) Warm Spring Reduced Carbon Cycle Impact Of The 2012 Us Summer Drought, Proceedings Of The National Academy Of Sciences, 113(21), 5880-5885" -US-Mpj,1700003756,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1073/PNAS.1519620113 -US-Mpj,1700003756,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Mpj,1700004923,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Wolf, S., Keenan, T.F., Fisher, J.B., Baldocchi, D.D., Desai, A.R., Richardson, A.D., Scott, R.L., Law, B.E., Litvak, M.E., Brunsell, N.A., Peters, W., van der Laan-Luijkx, I.T. (2016) Warm spring reduced carbon cycle impact of the 2012 US summer drought, Proceedings of the National Academy of Sciences, 113(21), 5880-5885" -US-Mpj,1700004923,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1073/PNAS.1519620113 -US-Mpj,1700004923,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Mpj,30666,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"Research topics and objectives include 1) To understand the coupled water and energy cycles in semiarid environments; 2) Quantify carbon, water and energy fluxes in addition to inter-annual variability in these fluxes; 3) Quantify the extent to which water and carbon fluxes are controlled by soil moisture and rainfall, and the sensitivity of fluxes in this biome to changes in temperature and precipitation; 4) Quantifying the consequences of large-scale piñon pine dieoff in piñon -juniper woodlands for ecosystem processes such as carbon storage and water availability." -US-Mpj,30387,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"University of New Mexico, Biology - Castetter Hall Room 137, 219 Yale Blvd NE, Albuquerque NM 87131" -US-Mpj,30388,GRP_SITE_CHAR,TERRAIN,"Medium Slope (>2 %, <5%)" -US-Mpj,30388,GRP_SITE_CHAR,ASPECT,SW -US-Mpj,30388,GRP_SITE_CHAR,WIND_DIRECTION,SW -US-Mpj,30668,GRP_SITE_DESC,SITE_DESC,"This site is located in central New Mexico on an extensive mesa approximately 25 km south of Mountainair, NM, owned by the Heritage Land Conservancy. The dominant tree species, Pinus edulis and Juniperus monosperma make up >95% of the area’s tree cover.  Total tree is cover is ~60%. The dominant herbaceous plant at the site is the C4 perennial grass Bouteloua gracilis. In July 2013, we observed pinon mortality at the site, which continued through 2015. We have used a variety of techniques to document the rate of mortality. The mortality was triggered by a combination of drought (2011-2013) and Pinon ips bark beetle outbreak. Juniper was not affected." -US-Mpj,30390,GRP_SITE_FUNDING,SITE_FUNDING,"DOE-BER, USFS, DOE EPSCoR" -US-Mpj,12392,GRP_STATE,STATE,NM -US-Mpj,15441,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Marcy Litvak -US-Mpj,15441,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Mpj,15441,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,mlitvak@unm.edu -US-Mpj,15441,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of New Mexico -US-Mpj,81404,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Tomer Duman -US-Mpj,81404,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,DataManager -US-Mpj,81404,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,tomerduman@gmail.com -US-Mpj,81404,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of New Mexico -US-Mpj,99197,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Anthony Luketich -US-Mpj,99197,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Technician -US-Mpj,99197,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,luketich@unm.edu -US-Mpj,99197,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of New Mexico -US-Mpj,29849,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-Mpj,15442,GRP_TOWER_TYPE,TOWER_TYPE,triangle -US-Mpj,81405,GRP_URL,URL,http://www.litvaklab.org/pinon-juniper-woodland.html -US-Mpj,24000473,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-Mpj -US-Mpj,12395,GRP_UTC_OFFSET,UTC_OFFSET,-7 -US-Mpj,15443,GRP_UTC_OFFSET,UTC_OFFSET,-7 -US-Mpj,15443,GRP_UTC_OFFSET,UTC_OFFSET_DATE_START,200701010000 -US-MSR,91203,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,"Montana Wheat and Barley Committee, NSF DEB #1552976" -US-MSR,91215,GRP_CLIM_AVG,MAT,7 -US-MSR,91215,GRP_CLIM_AVG,MAP,374 -US-MSR,91215,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Bsk -US-MSR,27001129,GRP_COUNTRY,COUNTRY,USA -US-MSR,91705,GRP_DOI,DOI,10.17190/AMF/1617717 -US-MSR,91705,GRP_DOI,DOI_CITATION,"Paul Stoy (2021), AmeriFlux BASE US-MSR Montana Sun River winter wheat , Ver. 2-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1617717" -US-MSR,91705,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-MSR,91603,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-MSR,91603,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Paul Stoy -US-MSR,91603,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-MSR,91603,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,pcstoy@wisc.edu -US-MSR,91603,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of Wisconsin - Madison -US-MSR,91674,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,University of Wisconsin - Madison -US-MSR,91674,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-MSR,91607,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,"Montana Wheat and Barley Committee, NSF ##1552976" -US-MSR,91607,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-MSR,91218,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Agriculture -US-MSR,91206,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-MSR,91206,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-MSR,91206,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201605011900 -US-MSR,91206,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,201606300830 -US-MSR,91206,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Periodic operation -US-MSR,91217,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-MSR,91217,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-MSR,91217,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201605011900 -US-MSR,91217,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,201606300830 -US-MSR,91217,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Periodic operation -US-MSR,91205,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-MSR,91205,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-MSR,91205,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201605011900 -US-MSR,91205,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,201606300830 -US-MSR,91205,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Periodic operation -US-MSR,23001129,GRP_HEADER,SITE_NAME,Montana Sun River winter wheat -US-MSR,91202,GRP_IGBP,IGBP,CRO -US-MSR,91202,GRP_IGBP,IGBP_COMMENT,winter wheat -US-MSR,91219,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -US-MSR,91219,GRP_LAND_OWNERSHIP,LAND_OWNER,Chuck Merja -US-MSR,91212,GRP_LOCATION,LOCATION_LAT,47.4758 -US-MSR,91212,GRP_LOCATION,LOCATION_LONG,-111.7207 -US-MSR,91212,GRP_LOCATION,LOCATION_ELEV,1110 -US-MSR,91212,GRP_LOCATION,LOCATION_DATE_START,201605011900 -US-MSR,91216,GRP_NETWORK,NETWORK,AmeriFlux -US-MSR,1700004518,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Stoy, P. C., El-Madany, T. S., Fisher, J. B., Gentine, P., Gerken, T., Good, S. P., Klosterhalfen, A., Liu, S., Miralles, D. G., Perez-Priego, O., Rigden, A. J., Skaggs, T. H., Wohlfahrt, G., Anderson, R. G., Coenders-Gerrits, A. M., Jung, M., Maes, W. H., Mammarella, I., Mauder, M., Migliavacca, M., Nelson, J. A., Poyatos, R., Reichstein, M., Scott, R. L., Wolf, S. (2019) Reviews And Syntheses: Turning The Challenges Of Partitioning Ecosystem Evaporation And Transpiration Into Opportunities, Biogeosciences, 16(19), 3747-3775" -US-MSR,1700004518,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.5194/BG-16-3747-2019 -US-MSR,1700004518,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-MSR,91213,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,Precision agriculture -US-MSR,91214,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"540 Elm Drive, University of Wisconsin – Madison, Madison, WI 53706" -US-MSR,91204,GRP_SITE_CHAR,TERRAIN,Flat -US-MSR,91204,GRP_SITE_CHAR,ASPECT,FLAT -US-MSR,91204,GRP_SITE_CHAR,WIND_DIRECTION,SW -US-MSR,91204,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,400 -US-MSR,91207,GRP_SITE_DESC,SITE_DESC,winter wheat -US-MSR,91201,GRP_SITE_FUNDING,SITE_FUNDING,"Montana Wheat and Barley Committee, NSF ##1552976" -US-MSR,91210,GRP_STATE,STATE,MT -US-MSR,91209,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Paul Stoy -US-MSR,91209,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-MSR,91209,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,pcstoy@wisc.edu -US-MSR,91209,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Wisconsin - Madison -US-MSR,91209,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"460 Henry Mall, University of Wisconsin – Madison, Madison, WI 53706" -US-MSR,91208,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-MSR,91220,GRP_TOWER_TYPE,TOWER_TYPE,tripod -US-MSR,24001129,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-MSR -US-MSR,91211,GRP_UTC_OFFSET,UTC_OFFSET,-7 -US-MSR,91211,GRP_UTC_OFFSET,UTC_OFFSET_DATE_START,201605011900 -US-MSR,91211,GRP_UTC_OFFSET,UTC_OFFSET_COMMENT,The data logger should be in local (Mountain) standard time -US-MtB,87259,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,Funding for the Mt. Bigelow operation and maintenance was provided by National Science Foundation EAR awards 0724958 and 1331408 to the Catalina-Jemez Critical Zone Observatory. -US-MtB,87252,GRP_CLIM_AVG,MAT,9.3 -US-MtB,87252,GRP_CLIM_AVG,MAP,790 -US-MtB,87252,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dwb -US-MtB,27000400,GRP_COUNTRY,COUNTRY,USA -US-MtB,90050,GRP_DOI,DOI,10.17190/AMF/1579717 -US-MtB,90050,GRP_DOI,DOI_CITATION,"Greg Barron-Gafford (2022), AmeriFlux BASE US-MtB Mt Bigelow, Ver. 4-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1579717" -US-MtB,90050,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-MtB,89993,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-MtB,89993,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Greg Barron-Gafford -US-MtB,89993,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-MtB,89993,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,gregbg@email.arizona.edu -US-MtB,89993,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of Arizona -US-MtB,90032,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,University of Arizona -US-MtB,90032,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-MtB,90021,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,United States National Science Foundation -US-MtB,90021,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-MtB,87255,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Drought -US-MtB,87261,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Forestry -US-MtB,87246,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-MtB,87246,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-MtB,87246,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20091101 -US-MtB,87246,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-MtB,87253,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-MtB,87253,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-MtB,87253,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20091101 -US-MtB,87253,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-MtB,23000400,GRP_HEADER,SITE_NAME,Mt Bigelow -US-MtB,87250,GRP_IGBP,IGBP,ENF -US-MtB,88027,GRP_INST,INST_MODEL,RAD-PAR Quantum -US-MtB,88027,GRP_INST,INST_SN,MtB_190SZ -US-MtB,88027,GRP_INST,INST_DATE,2009 -US-MtB,88027,GRP_INST,INST_SAMPLING_INT,1 -US-MtB,88027,GRP_INST,INST_AVERAGING_INT,1800 -US-MtB,88027,GRP_INST,INST_SA_OFFSET_NORTH,180 -US-MtB,88025,GRP_INST,INST_MODEL,GA_OP-LI-COR LI-7500 -US-MtB,88025,GRP_INST,INST_SN,MtB_7500 -US-MtB,88025,GRP_INST,INST_DATE,2009 -US-MtB,88025,GRP_INST,INST_SAMPLING_INT,0.1 -US-MtB,88025,GRP_INST,INST_AVERAGING_INT,1800 -US-MtB,88025,GRP_INST,INST_SA_OFFSET_NORTH,290 -US-MtB,88025,GRP_INST,INST_GA_OP_AZIM_MOUNT,0 -US-MtB,88025,GRP_INST,INST_GA_OP_VERT_MOUNT,45 -US-MtB,88028,GRP_INST,INST_MODEL,RAD-Pyrrad-SW+LW -US-MtB,88028,GRP_INST,INST_SN,MtB_CNR1 -US-MtB,88028,GRP_INST,INST_DATE,2009 -US-MtB,88028,GRP_INST,INST_SAMPLING_INT,1 -US-MtB,88028,GRP_INST,INST_AVERAGING_INT,1800 -US-MtB,88028,GRP_INST,INST_SA_OFFSET_NORTH,180 -US-MtB,88026,GRP_INST,INST_MODEL,SA-Campbell CSAT-3 -US-MtB,88026,GRP_INST,INST_SN,MtB_CSAT -US-MtB,88026,GRP_INST,INST_DATE,2009 -US-MtB,88026,GRP_INST,INST_SAMPLING_INT,0.1 -US-MtB,88026,GRP_INST,INST_AVERAGING_INT,1800 -US-MtB,88026,GRP_INST,INST_SA_OFFSET_NORTH,290 -US-MtB,88026,GRP_INST,INST_SA_WIND_FORMAT,"U, V, W" -US-MtB,88024,GRP_INST,INST_MODEL,TEMP-ElectResis -US-MtB,88024,GRP_INST,INST_SN,MtB_HMP1 -US-MtB,88024,GRP_INST,INST_DATE,2009 -US-MtB,88024,GRP_INST,INST_SAMPLING_INT,1 -US-MtB,88024,GRP_INST,INST_AVERAGING_INT,1800 -US-MtB,88024,GRP_INST,INST_SHIELDING,Radiation -US-MtB,88024,GRP_INST,INST_SA_OFFSET_NORTH,180 -US-MtB,87258,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-MtB,87258,GRP_LAND_OWNERSHIP,LAND_OWNER,United States Forest Service -US-MtB,5818,GRP_LOCATION,LOCATION_LAT,32.4167 -US-MtB,5818,GRP_LOCATION,LOCATION_LONG,-110.7255 -US-MtB,91812,GRP_LOCATION,LOCATION_LAT,32.4160 -US-MtB,91812,GRP_LOCATION,LOCATION_LONG,-110.7256 -US-MtB,91812,GRP_LOCATION,LOCATION_ELEV,2573 -US-MtB,91812,GRP_LOCATION,LOCATION_DATE_START,2002 -US-MtB,87266,GRP_NETWORK,NETWORK,AmeriFlux -US-MtB,1700002568,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chang, L., Dwivedi, R., Knowles, J. F., Fang, Y., Niu, G., Pelletier, J. D., Rasmussen, C., Durcik, M., Barron-Gafford, G. A., Meixner, T. (2018) Why Do Large-Scale Land Surface Models Produce A Low Ratio Of Transpiration To Evapotranspiration?, Journal Of Geophysical Research: Atmospheres, 123(17), 9109-9130" -US-MtB,1700002568,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018JD029159 -US-MtB,1700002568,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-MtB,1700008337,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(3), 108350" -US-MtB,1700008337,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -US-MtB,1700008337,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-MtB,1700004860,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Dwivedi, R., Eastoe, C., Knowles, J. F., Hamann, L., Meixner, T., Ferre, P.A., Castro, C., Wright, W.E., Niu, G.-Y., Minor, R., Barron-Gafford, G. A., Abramson, N., Mitra, B., Papuga, S.A., Stanley, M., Chorover, J. (2021) An improved practical approach for estimating catchment‐scale response functions through wavelet analysis, Hydrological Processes, 35(3), e14082" -US-MtB,1700004860,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/HYP.14082 -US-MtB,1700004860,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-MtB,1700009060,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Dwivedi, R., Eastoe, C., Knowles, J. F., Wright, W. E., Hamann, L., Minor, R., Mitra, B., Meixner, T., McIntosh, J., Ty Ferre, P. A., Castro, C., Niu, G., Barron‐Gafford, G. A., Abramson, N., Papuga, S. A., Stanley, M., Hu, J., Chorover, J. (2019) Vegetation Source Water Identification Using Isotopic And Hydrometric Observations From A Subhumid Mountain Catchment, Ecohydrology, 13(9), 2866-2882" -US-MtB,1700009060,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/ECO.2167 -US-MtB,1700009060,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-MtB,1700004569,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Javadian, M., Smith, W. K., Lee, K., Knowles, J. F., Scott, R. L., Fisher, J. B., Moore, D. J., Leeuwen, W. J., Barron‐Gafford, G., Behrangi, A. (2022) Canopy Temperature Is Regulated By Ecosystem Structural Traits And Captures The Ecohydrologic Dynamics Of A Semiarid Mixed Conifer Forest Site, Journal Of Geophysical Research: Biogeosciences, 127(2), e2021JG006617" -US-MtB,1700004569,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2021JG006617 -US-MtB,1700004569,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-MtB,1700007815,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Knowles, J. F., Scott, R. L., Biederman, J. A., Blanken, P. D., Burns, S. P., Dore, S., Kolb, T. E., Litvak, M. E., Barron‐Gafford, G. A. (2020) Montane Forest Productivity Across A Semiarid Climatic Gradient, Global Change Biology, 26(12), 6945-6958" -US-MtB,1700007815,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/GCB.15335 -US-MtB,1700007815,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-MtB,1700006897,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Knowles, J. F., Scott, R. L., Minor, R. L., Barron-Gafford, G. A. (2020) Ecosystem Carbon And Water Cycling From A Sky Island Montane Forest, Agricultural And Forest Meteorology, 281(), 107835" -US-MtB,1700006897,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2019.107835 -US-MtB,1700006897,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-MtB,1700000126,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Knowles, J. F., Scott, R. L., Minor, R. L., Barron-Gafford, G. A. (2020) Ecosystem Carbon And Water Cycling From A Sky Island Montane Forest, Agricultural And Forest Meteorology, 281(2), 107835" -US-MtB,1700000126,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2019.107835 -US-MtB,1700000126,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-MtB,1700006993,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Murphy, P. C., Knowles, J. F., Moore, D. J. P., Anchukaitis, K., Potts, D. L., Barron-Gafford, G. A. (2020) Topography Influences Species-Specific Patterns Of Seasonal Primary Productivity In A Semiarid Montane Forest, Tree Physiology, 40(10), 1343-1354" -US-MtB,1700006993,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1093/TREEPHYS/TPAA083 -US-MtB,1700006993,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-MtB,1700005391,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Olshansky, Y., Knowles, J. F., Barron‐Gafford, G. A., Rasmussen, C., Abramson, N., Chorover, J. (2019) Soil Fluid Biogeochemical Response To Climatic Events, Journal Of Geophysical Research: Biogeosciences, 124(9), 2866-2882" -US-MtB,1700005391,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2019JG005216 -US-MtB,1700005391,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-MtB,1700001626,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Yang, J. C., Magney, T. S., Yan, D., Knowles, J. F., Smith, W. K., Scott, R. L., Barron‐Gafford, G. A. (2020) The Photochemical Reflectance Index (Pri) Captures The Ecohydrologic Sensitivity Of A Semiarid Mixed Conifer Forest, Journal Of Geophysical Research: Biogeosciences, 125(11), 2866-2882" -US-MtB,1700001626,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2019JG005624 -US-MtB,1700001626,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-MtB,87251,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,Ecohydrology -US-MtB,87256,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"1041 E. Lowell St., BioSciences West #310, Tucson, AZ, 85721, USA" -US-MtB,87265,GRP_SITE_CHAR,TERRAIN,"Significant Slope (>5%, <10%)" -US-MtB,87265,GRP_SITE_CHAR,ASPECT,NW -US-MtB,87265,GRP_SITE_CHAR,WIND_DIRECTION,WSW -US-MtB,87265,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,5000 -US-MtB,87265,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,30 -US-MtB,87254,GRP_SITE_DESC,SITE_DESC,"Western slope of Mt. Bigelow; 29 km NE of Tucson, AZ, USA; Mixed evergreen conifer forest; Average canopy height = 10 m; Summer monsoon; 30-m tower installed in 2002; Secondary forest re-established in the 1930s" -US-MtB,87247,GRP_SITE_FUNDING,SITE_FUNDING,United States National Science Foundation -US-MtB,8299,GRP_STATE,STATE,AZ -US-MtB,87260,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Greg Barron-Gafford -US-MtB,87260,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-MtB,87260,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,gregbg@email.arizona.edu -US-MtB,87260,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Arizona -US-MtB,87260,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"School of Geography and Development, ENR2 Building, South 4th floor, Tucson, AZ, 85721, USA" -US-MtB,98528,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,John Knowles -US-MtB,98528,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,AncContact -US-MtB,98528,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,jfknowles@csuchico.edu -US-MtB,98528,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"California State University, Chico" -US-MtB,98528,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"400 W 1st St, Chico, CA, 95929" -US-MtB,87264,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Russ Scott -US-MtB,87264,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,AncContact -US-MtB,87264,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,russ.scott@usda.gov -US-MtB,87264,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,USDA ARS Southwest Watershed Research Center -US-MtB,87264,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"2001 E. Allen Road, Tucson, AZ, 85719, USA" -US-MtB,87257,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-MtB,87248,GRP_TOWER_TYPE,TOWER_TYPE,walk-up -US-MtB,89983,GRP_URL,URL,https://www.barrongafford.org/montane-ecosystem--the-critical-zone.html -US-MtB,24000400,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-MtB -US-MtB,87249,GRP_UTC_OFFSET,UTC_OFFSET,-7 -US-MVF,91129,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,"Montana Wheat and Barley Committee, NSF DEB #1552976" -US-MVF,91114,GRP_CLIM_AVG,MAT,7 -US-MVF,91114,GRP_CLIM_AVG,MAP,374 -US-MVF,91114,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Bsk -US-MVF,27001127,GRP_COUNTRY,COUNTRY,USA -US-MVF,98617,GRP_DOI,DOI,10.17190/AMF/1829507 -US-MVF,98617,GRP_DOI,DOI_CITATION,"Paul Stoy (2021), AmeriFlux BASE US-MVF Montana Vaughn Fallow, Ver. 1-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1829507" -US-MVF,98617,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-MVF,98602,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-MVF,98602,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Paul Stoy -US-MVF,98602,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-MVF,98602,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,pcstoy@wisc.edu -US-MVF,98602,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of Wisconsin - Madison -US-MVF,98610,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,University of Wisconsin - Madison -US-MVF,98610,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-MVF,98606,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,"Montana Wheat and Barley Committee, NSF DEB #1552976" -US-MVF,98606,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-MVF,91131,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Agriculture -US-MVF,91118,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-MVF,91118,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-MVF,91118,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201705250830 -US-MVF,91118,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,201709281030 -US-MVF,91118,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Periodic operation -US-MVF,91128,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-MVF,91128,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-MVF,91128,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201705250830 -US-MVF,91128,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,201709281030 -US-MVF,91128,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Periodic operation -US-MVF,91116,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-MVF,91116,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-MVF,91116,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201705250830 -US-MVF,91116,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,201709281030 -US-MVF,91116,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Periodic operation -US-MVF,23001127,GRP_HEADER,SITE_NAME,Montana Vaughn Fallow -US-MVF,91132,GRP_IGBP,IGBP,CRO -US-MVF,91132,GRP_IGBP,IGBP_COMMENT,fallow -US-MVF,91115,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -US-MVF,91115,GRP_LAND_OWNERSHIP,LAND_OWNER,Chuck Merja -US-MVF,91124,GRP_LOCATION,LOCATION_LAT,47.6867 -US-MVF,91124,GRP_LOCATION,LOCATION_LONG,-111.4659 -US-MVF,91124,GRP_LOCATION,LOCATION_ELEV,1128 -US-MVF,91124,GRP_LOCATION,LOCATION_DATE_START,201705240830 -US-MVF,91121,GRP_NETWORK,NETWORK,AmeriFlux -US-MVF,91127,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"Precision agriculture, land management" -US-MVF,91120,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"540 Elm Drive, University of Wisconsin – Madison, Madison, WI 53706" -US-MVF,91113,GRP_SITE_CHAR,TERRAIN,Flat -US-MVF,91113,GRP_SITE_CHAR,ASPECT,FLAT -US-MVF,91113,GRP_SITE_CHAR,WIND_DIRECTION,SW -US-MVF,91113,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,450 -US-MVF,91117,GRP_SITE_DESC,SITE_DESC,spring wheat -US-MVF,91125,GRP_SITE_FUNDING,SITE_FUNDING,"Montana Wheat and Barley Committee, NSF DEB #1552976" -US-MVF,91126,GRP_STATE,STATE,MT -US-MVF,91130,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Paul Stoy -US-MVF,91130,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-MVF,91130,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,pcstoy@wisc.edu -US-MVF,91130,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Wisconsin - Madison -US-MVF,91130,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"460 Henry Mall, University of Wisconsin – Madison, Madison, WI 53706" -US-MVF,91119,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-MVF,91123,GRP_TOWER_TYPE,TOWER_TYPE,tripod -US-MVF,24001127,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-MVF -US-MVF,91122,GRP_UTC_OFFSET,UTC_OFFSET,-7 -US-MVF,91122,GRP_UTC_OFFSET,UTC_OFFSET_DATE_START,201605011900 -US-MVF,91122,GRP_UTC_OFFSET,UTC_OFFSET_COMMENT,The data logger should be in local (Mountain) standard time -US-MVW,91136,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,"Montana Wheat and Barley Committee, NSF DEB #1552976" -US-MVW,91144,GRP_CLIM_AVG,MAT,7 -US-MVW,91144,GRP_CLIM_AVG,MAP,374 -US-MVW,91144,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Bsk -US-MVW,27001126,GRP_COUNTRY,COUNTRY,USA -US-MVW,98616,GRP_DOI,DOI,10.17190/AMF/1829508 -US-MVW,98616,GRP_DOI,DOI_CITATION,"Paul Stoy (2021), AmeriFlux BASE US-MVW Montana Vaughn Wheat, Ver. 1-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1829508" -US-MVW,98616,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-MVW,98601,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-MVW,98601,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Paul Stoy -US-MVW,98601,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-MVW,98601,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,pcstoy@wisc.edu -US-MVW,98601,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of Wisconsin - Madison -US-MVW,98613,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,University of Wisconsin - Madison -US-MVW,98613,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-MVW,98604,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,"Montana Wheat and Barley Committee, NSF DEB #1552976" -US-MVW,98604,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-MVW,91138,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Agriculture -US-MVW,91133,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-MVW,91133,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-MVW,91133,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201705241800 -US-MVW,91133,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,201709281300 -US-MVW,91133,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Periodic operation -US-MVW,91134,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-MVW,91134,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-MVW,91134,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201705241800 -US-MVW,91134,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,201709281300 -US-MVW,91134,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Periodic operation -US-MVW,91135,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-MVW,91135,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-MVW,91135,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201705241800 -US-MVW,91135,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,201709281300 -US-MVW,91135,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Periodic operation -US-MVW,23001126,GRP_HEADER,SITE_NAME,Montana Vaughn Wheat -US-MVW,91151,GRP_IGBP,IGBP,CRO -US-MVW,91151,GRP_IGBP,IGBP_COMMENT,spring wheat -US-MVW,91143,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -US-MVW,91143,GRP_LAND_OWNERSHIP,LAND_OWNER,Chuck Merja -US-MVW,91152,GRP_LOCATION,LOCATION_LAT,47.6729 -US-MVW,91152,GRP_LOCATION,LOCATION_LONG,-111.4889 -US-MVW,91152,GRP_LOCATION,LOCATION_ELEV,1134 -US-MVW,91152,GRP_LOCATION,LOCATION_DATE_START,201705240830 -US-MVW,91146,GRP_NETWORK,NETWORK,AmeriFlux -US-MVW,91148,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"Precision agriculture, land management" -US-MVW,91137,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"540 Elm Drive, University of Wisconsin – Madison, Madison, WI 53706" -US-MVW,91149,GRP_SITE_CHAR,TERRAIN,Flat -US-MVW,91149,GRP_SITE_CHAR,ASPECT,FLAT -US-MVW,91149,GRP_SITE_CHAR,WIND_DIRECTION,SW -US-MVW,91149,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,450 -US-MVW,91142,GRP_SITE_DESC,SITE_DESC,spring wheat -US-MVW,91150,GRP_SITE_FUNDING,SITE_FUNDING,"Montana Wheat and Barley Committee, NSF DEB #1552976" -US-MVW,91140,GRP_STATE,STATE,MT -US-MVW,91145,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Paul Stoy -US-MVW,91145,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-MVW,91145,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,pcstoy@wisc.edu -US-MVW,91145,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Wisconsin - Madison -US-MVW,91145,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"460 Henry Mall, University of Wisconsin – Madison, Madison, WI 53706" -US-MVW,91141,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-MVW,91139,GRP_TOWER_TYPE,TOWER_TYPE,tripod -US-MVW,24001126,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-MVW -US-MVW,91147,GRP_UTC_OFFSET,UTC_OFFSET,-7 -US-MVW,91147,GRP_UTC_OFFSET,UTC_OFFSET_DATE_START,201605011900 -US-MVW,91147,GRP_UTC_OFFSET,UTC_OFFSET_COMMENT,The data logger should be in local (Mountain) standard time -US-Myb,11195,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,"Biometeorology Lab, University of California, Berkeley, PI: Dennis Baldocchi" -US-Myb,11196,GRP_CLIM_AVG,MAT,15.9 -US-Myb,11196,GRP_CLIM_AVG,MAP,338 -US-Myb,11196,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Csa -US-Myb,27000505,GRP_COUNTRY,COUNTRY,USA -US-Myb,15684,GRP_DOI,DOI,10.17190/AMF/1246139 -US-Myb,15684,GRP_DOI,DOI_CITATION,"Jaclyn Hatala Matthes, Cove Sturtevant, Patty Oikawa, Samuel D Chamberlain, Daphne Szutu, Ariane Arias-Ortiz, Joseph Verfaillie, Dennis Baldocchi (2022), AmeriFlux BASE US-Myb Mayberry Wetland, Ver. 13-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1246139" -US-Myb,15684,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-Myb,94069,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Myb,94069,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Jaclyn Hatala Matthes -US-Myb,94069,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Myb,94069,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,1 -US-Myb,94069,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0001-8999-8062 -US-Myb,94069,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,jaclyn.hatala.matthes@gmail.com -US-Myb,94069,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"University of California, Berkeley" -US-Myb,94069,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,20101014 -US-Myb,94069,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_END,20130513 -US-Myb,98279,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Myb,98279,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Cove Sturtevant -US-Myb,98279,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Myb,98279,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,2 -US-Myb,98279,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0002-0341-3228 -US-Myb,98279,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,csturtevant@battelleecology.org -US-Myb,98279,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"University of California, Berkeley" -US-Myb,98279,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,20130328 -US-Myb,98279,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_END,20150708 -US-Myb,98289,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Myb,98289,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Patty Oikawa -US-Myb,98289,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Myb,98289,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,3 -US-Myb,98289,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0001-7852-4435 -US-Myb,98289,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,patty.oikawa@csueastbay.edu -US-Myb,98289,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"University of California, Berkeley" -US-Myb,98289,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,20150708 -US-Myb,98289,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_END,20160815 -US-Myb,98293,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Myb,98293,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Samuel D Chamberlain -US-Myb,98293,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Myb,98293,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,4 -US-Myb,98293,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0002-5570-764X -US-Myb,98293,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,sam.d.chamberlain@gmail.com -US-Myb,98293,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"University of California, Berkeley" -US-Myb,98293,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,20160815 -US-Myb,98293,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_END,20180806 -US-Myb,94066,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Myb,94066,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Daphne Szutu -US-Myb,94066,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Myb,94066,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,5 -US-Myb,94066,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0001-7698-0461 -US-Myb,94066,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,daphneszutu@berkeley.edu -US-Myb,94066,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"University of California, Berkeley" -US-Myb,94066,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,201612 -US-Myb,98456,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Myb,98456,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Ariane Arias-Ortiz -US-Myb,98456,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Myb,98456,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,6 -US-Myb,98456,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0001-9408-0061 -US-Myb,98456,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,aariasortiz@berkeley.edu -US-Myb,98456,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"University of California, Berkeley" -US-Myb,98456,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,20200327 -US-Myb,94134,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Myb,94134,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Joseph Verfaillie -US-Myb,94134,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Myb,94134,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,8 -US-Myb,94134,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0002-7009-8942 -US-Myb,94134,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,jverfail@berkeley.edu -US-Myb,94134,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"University of California, Berkeley" -US-Myb,94134,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,20101014 -US-Myb,94057,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Myb,94057,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Dennis Baldocchi -US-Myb,94057,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Myb,94057,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,9 -US-Myb,94057,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0003-3496-4919 -US-Myb,94057,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,baldocchi@berkeley.edu -US-Myb,94057,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"University of California, Berkeley" -US-Myb,94057,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,20101014 -US-Myb,32336,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,"University of California, Berkeley" -US-Myb,32336,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-Myb,32335,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,California Department of Water Resources -US-Myb,32335,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-Myb,22203,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Hydrologic event -US-Myb,22202,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Land cover change -US-Myb,11197,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Myb,11197,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-Myb,11197,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20101014 -US-Myb,11197,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Myb,11210,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Myb,11210,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CH4 -US-Myb,11210,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20101014 -US-Myb,11210,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Myb,91307,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Myb,91307,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-Myb,91307,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20101014 -US-Myb,91307,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Myb,23000505,GRP_HEADER,SITE_NAME,Mayberry Wetland -US-Myb,88371,GRP_HEIGHTC,HEIGHTC,48 -US-Myb,88371,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Aerenchymatous Plants -US-Myb,88371,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Myb,88371,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Myb,88371,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,53 -US-Myb,88371,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Myb,88371,GRP_HEIGHTC,HEIGHTC_DATE,20140801 -US-Myb,88371,GRP_HEIGHTC,HEIGHTC_COMMENT,Average: Green plants from 30cm x 30cm plots 7m to 10m apart along a transect upwind from the tower. From Sophie -US-Myb,88373,GRP_HEIGHTC,HEIGHTC,0.384 -US-Myb,88373,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Aerenchymatous Plants -US-Myb,88373,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Myb,88373,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Myb,88373,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,22 -US-Myb,88373,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Myb,88373,GRP_HEIGHTC,HEIGHTC_DATE,20150811 -US-Myb,88373,GRP_HEIGHTC,HEIGHTC_COMMENT,Green plants from 30cm x 30cm plots 7m to 10m apart along a transect upwind from the tower. From Sophie -US-Myb,88374,GRP_HEIGHTC,HEIGHTC,2.664 -US-Myb,88374,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Aerenchymatous Plants -US-Myb,88374,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Myb,88374,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Myb,88374,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,22 -US-Myb,88374,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Myb,88374,GRP_HEIGHTC,HEIGHTC_DATE,20150811 -US-Myb,88374,GRP_HEIGHTC,HEIGHTC_COMMENT,Green plants from 30cm x 30cm plots 7m to 10m apart along a transect upwind from the tower. From Sophie -US-Myb,88370,GRP_HEIGHTC,HEIGHTC,2.237 -US-Myb,88370,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Aerenchymatous Plants -US-Myb,88370,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Myb,88370,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Myb,88370,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,35 -US-Myb,88370,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Myb,88370,GRP_HEIGHTC,HEIGHTC_DATE,20160802 -US-Myb,88370,GRP_HEIGHTC,HEIGHTC_COMMENT,Green plants from 30cm x 30cm plots 7m to 10m apart along a transect upwind from the tower. From Sophie -US-Myb,88376,GRP_HEIGHTC,HEIGHTC,0.276 -US-Myb,88376,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Aerenchymatous Plants -US-Myb,88376,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Myb,88376,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Myb,88376,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,35 -US-Myb,88376,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Myb,88376,GRP_HEIGHTC,HEIGHTC_DATE,20160802 -US-Myb,88376,GRP_HEIGHTC,HEIGHTC_COMMENT,Green plants from 30cm x 30cm plots 7m to 10m apart along a transect upwind from the tower. From Sophie -US-Myb,88372,GRP_HEIGHTC,HEIGHTC,0.587 -US-Myb,88372,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Aerenchymatous Plants -US-Myb,88372,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Myb,88372,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Myb,88372,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,23 -US-Myb,88372,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Myb,88372,GRP_HEIGHTC,HEIGHTC_DATE,20170727 -US-Myb,88372,GRP_HEIGHTC,HEIGHTC_COMMENT,Green plants from 30cm x 30cm plots 7m to 10m apart along a transect upwind from the tower. From Sophie -US-Myb,88375,GRP_HEIGHTC,HEIGHTC,2.285 -US-Myb,88375,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Aerenchymatous Plants -US-Myb,88375,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Myb,88375,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Myb,88375,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,23 -US-Myb,88375,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Myb,88375,GRP_HEIGHTC,HEIGHTC_DATE,20170727 -US-Myb,88375,GRP_HEIGHTC,HEIGHTC_COMMENT,Green plants from 30cm x 30cm plots 7m to 10m apart along a transect upwind from the tower. From Sophie -US-Myb,11198,GRP_IGBP,IGBP,WET -US-Myb,11198,GRP_IGBP,IGBP_DATE_START,20101014 -US-Myb,11198,GRP_IGBP,IGBP_COMMENT,cattail and tule vegetation -US-Myb,11199,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-Myb,11199,GRP_LAND_OWNERSHIP,LAND_OWNER,State of California -US-Myb,86658,GRP_LOCATION,LOCATION_LAT,38.0498 -US-Myb,86658,GRP_LOCATION,LOCATION_LONG,-121.7651 -US-Myb,86658,GRP_LOCATION,LOCATION_ELEV,-4 -US-Myb,86658,GRP_LOCATION,LOCATION_DATE_START,20101014 -US-Myb,86658,GRP_LOCATION,LOCATION_COMMENT,Original Eddy: Original location of eddy equipment and minimal micromet sensors - move to main combined tower on 2014-03-19 -US-Myb,90998,GRP_LOCATION,LOCATION_LAT,38.0503 -US-Myb,90998,GRP_LOCATION,LOCATION_LONG,-121.7652 -US-Myb,90998,GRP_LOCATION,LOCATION_ELEV,-4 -US-Myb,90998,GRP_LOCATION,LOCATION_DATE_START,20110301 -US-Myb,90998,GRP_LOCATION,LOCATION_COMMENT,Tule Met Sensors: Full micromet system installed 65m north of eddy equipment near a patch of representative vegetation. -US-Myb,86657,GRP_LOCATION,LOCATION_LAT,38.0499 -US-Myb,86657,GRP_LOCATION,LOCATION_LONG,-121.7650 -US-Myb,86657,GRP_LOCATION,LOCATION_ELEV,-4 -US-Myb,86657,GRP_LOCATION,LOCATION_DATE_START,20140313 -US-Myb,86657,GRP_LOCATION,LOCATION_COMMENT,Main Tower: Wetland vegetation has filled in making it possible to co-locate the eddy and met sensors. The met sensors were moved to this location on 3-13 and the eddy sensors were moved on 3-19 -US-Myb,11201,GRP_NETWORK,NETWORK,AmeriFlux -US-Myb,86986,GRP_NETWORK,NETWORK,Phenocam -US-Myb,1700008787,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Arias‐Ortiz, A., Oikawa, P. Y., Carlin, J., Masqué, P., Shahan, J., Kanneg, S., Paytan, A., Baldocchi, D. D. (2021) Tidal And Nontidal Marsh Restoration: A Trade‐Off Between Carbon Sequestration, Methane Emissions, And Soil Accretion, Journal Of Geophysical Research: Biogeosciences, 126(12), e0248398" -US-Myb,1700008787,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2021JG006573 -US-Myb,1700008787,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Myb,1700006369,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Baldocchi, D., Penuelas, J. (2018) The Physics And Ecology Of Mining Carbon Dioxide From The Atmosphere By Ecosystems, Global Change Biology, 256-257(12), 179-195" -US-Myb,1700006369,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/GCB.14559 -US-Myb,1700006369,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Myb,1700008892,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Baldocchi, D., Penuelas, J. (2018) The Physics And Ecology Of Mining Carbon Dioxide From The Atmosphere By Ecosystems, Global Change Biology, 256-257(7), 179-195" -US-Myb,1700008892,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/GCB.14559 -US-Myb,1700008892,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Myb,1700007131,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chamberlain, S. D., Hemes, K. S., Eichelmann, E., Szutu, D. J., Verfaillie, J. G., Baldocchi, D. D. (2019) Effect Of Drought-Induced Salinization On Wetland Methane Emissions, Gross Ecosystem Productivity, And Their Interactions, Ecosystems, 20(8), 1619-1633" -US-Myb,1700007131,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1007/S10021-019-00430-5 -US-Myb,1700007131,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Myb,1700007371,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chamberlain, S. D., Verfaillie, J., Eichelmann, E., Hemes, K. S., Baldocchi, D. D. (2017) Evaluation Of Density Corrections To Methane Fluxes Measured By Open-Path Eddy Covariance Over Contrasting Landscapes, Boundary-Layer Meteorology, 121(1), nnn-nnn" -US-Myb,1700007371,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1007/S10546-017-0275-9 -US-Myb,1700007371,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Myb,1700008802,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chamberlain, S. D., Verfaillie, J., Eichelmann, E., Hemes, K. S., Baldocchi, D. D. (2017) Evaluation Of Density Corrections To Methane Fluxes Measured By Open-Path Eddy Covariance Over Contrasting Landscapes, Boundary-Layer Meteorology, 121(12), 188-204" -US-Myb,1700008802,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1007/S10546-017-0275-9 -US-Myb,1700008802,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Myb,1700004539,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(8), 108350" -US-Myb,1700004539,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -US-Myb,1700004539,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Myb,1700006837,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Eichelmann, E., Hemes, K. S., Knox, S. H., Oikawa, P. Y., Chamberlain, S. D., Sturtevant, C., Verfaillie, J., Baldocchi, D. D. (2018) The Effect Of Land Cover Type And Structure On Evapotranspiration From Agricultural And Wetland Sites In The Sacramento–San Joaquin River Delta, California, Agricultural And Forest Meteorology, 256-257(12), 179-195" -US-Myb,1700006837,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2018.03.007 -US-Myb,1700006837,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Myb,1700004113,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Eichelmann, E., Hemes, K. S., Knox, S. H., Oikawa, P. Y., Chamberlain, S. D., Sturtevant, C., Verfaillie, J., Baldocchi, D. D. (2018) The Effect Of Land Cover Type And Structure On Evapotranspiration From Agricultural And Wetland Sites In The Sacramento–San Joaquin River Delta, California, Agricultural And Forest Meteorology, 256-257(7), 179-195" -US-Myb,1700004113,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2018.03.007 -US-Myb,1700004113,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Myb,1700002925,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Hemes, K. S., Chamberlain, S. D., Eichelmann, E., Anthony, T., Valach, A., Kasak, K., Szutu, D., Verfaillie, J., Silver, W. L., Baldocchi, D. D. (2019) Assessing The Carbon And Climate Benefit Of Restoring Degraded Agricultural Peat Soils To Managed Wetlands, Agricultural And Forest Meteorology, 268(12), 202-214" -US-Myb,1700002925,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2019.01.017 -US-Myb,1700002925,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Myb,1700001926,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Hemes, K. S., Chamberlain, S. D., Eichelmann, E., Anthony, T., Valach, A., Kasak, K., Szutu, D., Verfaillie, J., Silver, W. L., Baldocchi, D. D. (2019) Assessing The Carbon And Climate Benefit Of Restoring Degraded Agricultural Peat Soils To Managed Wetlands, Agricultural And Forest Meteorology, 268(7), 202-214" -US-Myb,1700001926,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2019.01.017 -US-Myb,1700001926,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Myb,1700000837,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Hemes, K. S., Chamberlain, S. D., Eichelmann, E., Knox, S. H., Baldocchi, D. D. (2018) A Biogeochemical Compromise: The High Methane Cost Of Sequestering Carbon In Restored Wetlands, Geophysical Research Letters, 256-257(12), 179-195" -US-Myb,1700000837,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018GL077747 -US-Myb,1700000837,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Myb,1700006978,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Hemes, K. S., Chamberlain, S. D., Eichelmann, E., Knox, S. H., Baldocchi, D. D. (2018) A Biogeochemical Compromise: The High Methane Cost Of Sequestering Carbon In Restored Wetlands, Geophysical Research Letters, 256-257(7), 179-195" -US-Myb,1700006978,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018GL077747 -US-Myb,1700006978,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Myb,1700007362,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Hemes, K. S., Eichelmann, E., Chamberlain, S., Knox, S. H., Oikawa, P. Y., Sturtevant, C., Verfaillie, J., Szutu, D., Baldocchi, D. D. (2018) A Unique Combination Of Aerodynamic And Surface Properties Contribute To Surface Cooling In Restored Wetlands Of The Sacramento-San Joaquin Delta, California, Journal Of Geophysical Research: Biogeosciences, 256-257(12), 179-195" -US-Myb,1700007362,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018JG004494 -US-Myb,1700007362,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Myb,1700003453,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Hemes, K. S., Eichelmann, E., Chamberlain, S., Knox, S. H., Oikawa, P. Y., Sturtevant, C., Verfaillie, J., Szutu, D., Baldocchi, D. D. (2018) A Unique Combination Of Aerodynamic And Surface Properties Contribute To Surface Cooling In Restored Wetlands Of The Sacramento-San Joaquin Delta, California, Journal Of Geophysical Research: Biogeosciences, 256-257(7), 179-195" -US-Myb,1700003453,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018JG004494 -US-Myb,1700003453,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Myb,1700001308,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Knox, S. H.,, Sturtevant, C., Matthes, J.H., Koteen, L., Verfaillie,J., Baldocchi. D. (2014) Agricultural peatland restoration: effects of land-use change on greenhouse gas (CO2 and CH4) fluxes in the Sacramento-San Joaquin Delta, Global Change Biology, 21(), 750-765" -US-Myb,1700001308,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/GCB.12745 -US-Myb,1700001308,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Myb,1700007932,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Knox, Sara Helen Dronova, Iryna Sturtevant, Cove Oikawa, Patricia Y. Matthes, Jaclyn Hatala Verfaillie, Joseph Baldocchi, Dennis (2017) Using digital camera and Landsat imagery with eddy covariance data to model gross primary production in restored wetlands, Agricultural and Forest Meteorology, 237–238(1), 233-245" -US-Myb,1700007932,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2017.02.020 -US-Myb,1700007932,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Myb,1700008598,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Matthes, J. H., Sturtevant, C., Verfaillie, J., Knox, S., Baldocchi, D. (2014) Parsing The Variability In Ch4 flux At A Spatially Heterogeneous Wetland: Integrating Multiple Eddy Covariance Towers With High-Resolution Flux Footprint Analysis, Journal Of Geophysical Research: Biogeosciences, 119(7), 1322-1339" -US-Myb,1700008598,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/2014JG002642 -US-Myb,1700008598,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Myb,1700001116,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"McNicol, G., C. S. Sturtevant, S. H. Knox, I. Dronova, D. D. Baldocchi, and W. L. Silver. (2016) 2016. Effects of seasonality, transport-pathway, and spatial structure on greenhouse gas fluxes in a restored wetland., Global Change Biology, 121(1), nnn-nnn" -US-Myb,1700001116,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/GCB.13580 -US-Myb,1700001116,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Myb,1700000960,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Oikawa, P. Y.; Jenerette, G. D.; Knox, S. H.; Sturtevant, C.; Verfaillie, J.; Dronova, I.; Poindexter, C. M. ; Eichelmann, E.; Baldocchi, D. D. (2017) Evaluation of a hierarchy of models reveals importance of substrate limitation for predicting carbon dioxide and methane exchange in restored wetlands, Journal of Geophysical Research: Biogeosciences, 122(1), 145-167" -US-Myb,1700000960,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/2016JG003438 -US-Myb,1700000960,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Myb,1700005556,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Rey‐Sanchez, C., Wharton, S., Vilà‐Guerau de Arellano, J., Paw U, K. T., Hemes, K. S., Fuentes, J. D., Osuna, J., Szutu, D., Ribeiro, J. V., Verfaillie, J., Baldocchi, D. (2021) Evaluation Of Atmospheric Boundary Layer Height From Wind Profiling Radar And Slab Models And Its Responses To Seasonality Of Land Cover, Subsidence, And Advection, Journal Of Geophysical Research: Atmospheres, 126(7), e0248398" -US-Myb,1700005556,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2020JD033775 -US-Myb,1700005556,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Myb,1700005580,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Sturtevant, C., B. L. Ruddell, S. H. Knox, J. Verfaillie, J. H. Matthes, P. Y. Oikawa, and D. Baldocchi. (2015) 2015. Identifying scale-emergent, non-linear, asynchronous processes of wetland methane exchange., Journal of Geophysical Research: Biogeosciences, 121(1), 188-204" -US-Myb,1700005580,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/2015JG003054 -US-Myb,1700005580,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Myb,1700004764,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Sturtevant, C., B. L. Ruddell, S. H. Knox, J. Verfaillie, J. H. Matthes, P. Y. Oikawa, and D. Baldocchi. (2015) 2015. Identifying scale-emergent, non-linear, asynchronous processes of wetland methane exchange., Journal of Geophysical Research: Biogeosciences, 121(12), 188-204" -US-Myb,1700004764,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/2015JG003054 -US-Myb,1700004764,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Myb,1700004323,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Sullivan, R. C., Cook, D. R., Ghate, V. P., Kotamarthi, V. R., Feng, Y. (2019) Improved Spatiotemporal Representativeness And Bias Reduction Of Satellite-Based Evapotranspiration Retrievals Via Use Of In Situ Meteorology And Constrained Canopy Surface Resistance, Journal Of Geophysical Research: Biogeosciences, 124(2), 342-352" -US-Myb,1700004323,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018JG004744 -US-Myb,1700004323,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Myb,1700000237,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Sullivan, R. C., Kotamarthi, V. R., Feng, Y. (2019) Recovering Evapotranspiration Trends From Biased CMIP5 Simulations And Sensitivity To Changing Climate Over North America, Journal Of Hydrometeorology, 20(8), 1619-1633" -US-Myb,1700000237,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1175/JHM-D-18-0259.1 -US-Myb,1700000237,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Myb,1700001152,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Valach, A. C., Kasak, K., Hemes, K. S., Anthony, T. L., Dronova, I., Taddeo, S., Silver, W. L., Szutu, D., Verfaillie, J., Baldocchi, D. D. (2021) Productive Wetlands Restored For Carbon Sequestration Quickly Become Net Co2 Sinks With Site-Level Factors Driving Uptake Variability, Plos One, 16(3), e0248398" -US-Myb,1700001152,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1371/JOURNAL.PONE.0248398 -US-Myb,1700001152,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Myb,1700007401,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Valach, Alex C. Kasak, Kuno Hemes, Kyle S. Szutu, Daphne Verfaillie, Joe Baldocchi, Dennis D. (2021) Carbon Flux Trajectories and Site Conditions from Restored Impounded Marshes in the Sacramento-San Joaquin Delta, Wetland Carbon and Environmental Management, 126(7), e0248398" -US-Myb,1700007401,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/9781119639305.CH13 -US-Myb,1700007401,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Myb,11202,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"The research approach of the University of California, Berkeley Biometeorology Laboratory involves the coordinated use of experimental measurements and theoretical models to understand the physical, biological, and chemical processes that control trace gas fluxes between the biosphere and atmosphere and to quantify their temporal and spatial variations. The research objectives of the Mayberry Wetland, Sherman Island, and Twitchell Island sites are as follows: 1) Describe differences in the fluxes of CO2, CH4, H2O, and energy between different land uses; 2) Understand the mechanisms controlling these fluxes; 3) Use ecosystem modeling to understand controls on these mechanisms under different environmental scenarios. These three sites were selected to capture a wide range of inundated conditions within the Sacramento-San Joaquin River Delta. The research focuses on the eddy covariance technique to measure CH4, CO2, H2O, and energy fluxes and works to combine measurements of both net fluxes and partitioned fluxes in order to achieve a mechanistic understanding of the ecological controls on current and future carbon flux in the Delta." -US-Myb,11203,GRP_SITE_CHAR,TERRAIN,Flat -US-Myb,11203,GRP_SITE_CHAR,ASPECT,FLAT -US-Myb,11203,GRP_SITE_CHAR,WIND_DIRECTION,WNW -US-Myb,11203,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,900 -US-Myb,11203,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,0 -US-Myb,11204,GRP_SITE_DESC,SITE_DESC,"The Mayberry Wetland site is a 300-acre restored wetland on Sherman Island, north of Mayberry Slough, that is on the property of Mayberry Farms and managed by the California Department of Water Resources and Ducks Unlimited. During Summer 2010, the site was restored from a pepperweed and annual grassland pasture to a wetland through a project managed by Bryan Brock (bpbrock@water.ca.gov). A flux tower equipped to analyze energy, H2O, CO2, and CH4 fluxes was installed on October 14, 2010. At the time of installation, flooding of the site had only recently begun after extensive reconstruction of the wetland bathymetry conducted during the summer. Although some small patches of tules remain within the site, the site is a patchwork of deep and shallow open water with some remaining vegetation. Currently, there is an intention to flood-to-kill the current pepperweed and upland grasses and let the wetland plants propagate naturally, so no additional plant manipulation will occur." -US-Myb,11205,GRP_SITE_FUNDING,SITE_FUNDING,California Department of Water Resources -US-Myb,27192,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION,"Mixture of peat, clay, and sediments" -US-Myb,27192,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION_TAXONOMY,Other -US-Myb,11206,GRP_STATE,STATE,CA -US-Myb,11211,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Dennis Baldocchi -US-Myb,11211,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Myb,11211,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,baldocchi@berkeley.edu -US-Myb,11211,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"University of California, Berkeley" -US-Myb,11211,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Department of Environmental Science, Policy and Management, Berkeley, CA USA 94720-3110" -US-Myb,11207,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Joe Verfaillie -US-Myb,11207,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,AncContact -US-Myb,11207,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,jverfail@berkeley.edu -US-Myb,11207,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"University of California, Berkeley" -US-Myb,11207,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Department of Environmental Science, Policy and Management, 130 Mulford Hall,Berkeley, CA USA 94720-3110" -US-Myb,93032,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Ariane Arias Ortiz -US-Myb,93032,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-Myb,93032,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,aariasortiz@berkeley.edu -US-Myb,93032,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,UC Berkeley -US-Myb,30328,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Daphne Szutu -US-Myb,30328,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Technician -US-Myb,30328,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,daphneszutu@berkeley.edu -US-Myb,30328,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,UC Berkeley -US-Myb,88150,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-Myb,88149,GRP_TOWER_TYPE,TOWER_TYPE,other -US-Myb,11208,GRP_URL,URL,http://nature.berkeley.edu/biometlab/sites.php?tab=US-Myb -US-Myb,24000505,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-Myb -US-Myb,11209,GRP_UTC_OFFSET,UTC_OFFSET,-8 -US-NC1,12820,GRP_CLIM_AVG,MAT,16.6 -US-NC1,12820,GRP_CLIM_AVG,MAP,1320 -US-NC1,12820,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Cfa -US-NC1,27000401,GRP_COUNTRY,COUNTRY,USA -US-NC1,15625,GRP_DOI,DOI,10.17190/AMF/1246082 -US-NC1,15625,GRP_DOI,DOI_CITATION,"Asko Noormets (2018), AmeriFlux BASE US-NC1 NC_Clearcut, Ver. 3-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1246082" -US-NC1,15625,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-NC1,32135,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-NC1,32135,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Asko Noormets -US-NC1,32135,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-NC1,32135,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,noormets@tamu.edu -US-NC1,32135,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Texas A&M University -US-NC1,32137,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Texas A&M University -US-NC1,32137,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-NC1,32136,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,"USDA FS, DOE" -US-NC1,32136,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-NC1,12837,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Drought -US-NC1,12821,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Forestry -US-NC1,12842,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Hydrologic event -US-NC1,12845,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Storm or wind -US-NC1,12822,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-NC1,12822,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-NC1,12822,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20050101 -US-NC1,12822,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20130129 -US-NC1,12822,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-NC1,12838,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Chambers -US-NC1,12838,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-NC1,12838,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20050307 -US-NC1,12838,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20130104 -US-NC1,12838,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Periodic operation -US-NC1,12843,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Chambers -US-NC1,12843,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-NC1,12843,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20080731 -US-NC1,12843,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20120917 -US-NC1,12843,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-NC1,23000401,GRP_HEADER,SITE_NAME,NC_Clearcut -US-NC1,24400,GRP_HEIGHTC,HEIGHTC,0.35 -US-NC1,12823,GRP_IGBP,IGBP,OSH -US-NC1,12823,GRP_IGBP,IGBP_COMMENT,"Loblolly pine plantation, in the first years after clearcutting, the site was dominated by deciduous shrubs, and could have been viewed as OSH, but since 2008 it is best described as ENF" -US-NC1,12839,GRP_IGBP,IGBP,ENF -US-NC1,12839,GRP_IGBP,IGBP_DATE_START,2008 -US-NC1,24407,GRP_LAI,LAI_TYPE,LAI -US-NC1,24407,GRP_LAI,LAI_TOT,1.5 -US-NC1,24407,GRP_LAI,LAI_U,0 -US-NC1,12824,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -US-NC1,12824,GRP_LAND_OWNERSHIP,LAND_OWNER,Weyerhaeuser Company -US-NC1,12825,GRP_LOCATION,LOCATION_LAT,35.8118 -US-NC1,12825,GRP_LOCATION,LOCATION_LONG,-76.7119 -US-NC1,12825,GRP_LOCATION,LOCATION_ELEV,5 -US-NC1,12825,GRP_LOCATION,LOCATION_COMMENT,Tower Location -US-NC1,12826,GRP_NETWORK,NETWORK,AmeriFlux -US-NC1,84733,GRP_NETWORK,NETWORK,USCCC -US-NC1,1700008088,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Baldocchi, D., Penuelas, J. (2018) The Physics And Ecology Of Mining Carbon Dioxide From The Atmosphere By Ecosystems, Global Change Biology, 45(1), 9275–9287" -US-NC1,1700008088,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/GCB.14559 -US-NC1,1700008088,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-NC1,1700001947,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Baldocchi, D. D., Poindexter, C., Abraha, M., Desai, A. R., Bohrer, G., Arain, M. A., Griffis, T., Blanken, P. D., O'Halloran, T. L., Thomas, R. Q., Zhang, Q., Burns, S. P., Frank, J. M., Christian, D., Brown, S., Black, T. A., Gough, C. M., Law, B. E., Lee, X., Chen, J., Reed, D. E., Massman, W. J., Clark, K., Hatfield, J., Prueger, J., Bracho, R., Baker, J. M., Martin, T. A. (2018) Temporal Dynamics Of Aerodynamic Canopy Height Derived From Eddy Covariance Momentum Flux Data Across North American Flux Networks, Geophysical Research Letters, 45(1), 9275–9287" -US-NC1,1700001947,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018GL079306 -US-NC1,1700001947,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-NC1,1700001572,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(1), 108350" -US-NC1,1700001572,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -US-NC1,1700001572,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-NC1,1700005388,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Domec, J., King, J. S., Noormets, A., Treasure, E., Gavazzi, M. J., Sun, G., McNulty, S. G. (2010) Hydraulic Redistribution Of Soil Water By Roots Affects Whole-Stand Evapotranspiration And Net Ecosystem Carbon Exchange, New Phytologist, 187(1), 171-183" -US-NC1,1700005388,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/J.1469-8137.2010.03245.X -US-NC1,1700005388,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-NC1,1700000084,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Domec, J., Noormets, A., King, J. S., Sun, G., Mcnulty, S. G., Gavazzi, M. J., Boggs, J. L., Treasure, E. A. (2009) Decoupling The Influence Of Leaf And Root Hydraulic Conductances On Stomatal Conductance And Its Sensitivity To Vapour Pressure Deficit As Soil Dries In A Drained Loblolly Pine Plantation, Plant, Cell & Environment, 32(8), 980-991" -US-NC1,1700000084,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/J.1365-3040.2009.01981.X -US-NC1,1700000084,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-NC1,1700008361,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Domec, J., Ogee, J., Noormets, A., Jouangy, J., Gavazzi, M., Treasure, E., Sun, G., McNulty, S. G., King, J. S. (2012) Interactive Effects Of Nocturnal Transpiration And Climate Change On The Root Hydraulic Redistribution And Carbon And Water Budgets Of Southern United States Pine Plantations, Tree Physiology, 32(6), 707-723" -US-NC1,1700008361,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1093/TREEPHYS/TPS018 -US-NC1,1700008361,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Primary_Citation -US-NC1,1700008142,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Domec, J., Sun, G., Noormets, A., Gavazzi, M. J., Treasure, E. A., Cohen, E., Swenson, J. J., McNulty, S. G., King, J. S. (2012) A Comparison Of Three Methods To Estimate Evapotranspiration In Two Contrasting Loblolly Pine Plantations: Age-Related Changes In Water Use And Drought Sensitivity Of Evapotranspiration Components, Forest Science, 58(5), 497-512" -US-NC1,1700008142,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.5849/FORSCI.11-051 -US-NC1,1700008142,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-NC1,1700004230,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Noormets, A., McNulty, S. G., Domec, J., Gavazzi, M., Sun, G., King, J. S. (2012) The Role Of Harvest Residue In Rotation Cycle Carbon Balance In Loblolly Pine Plantations. Respiration Partitioning Approach, Global Change Biology, 18(10), 3186-3201" -US-NC1,1700004230,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/J.1365-2486.2012.02776.X -US-NC1,1700004230,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-NC1,1700003183,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Sun, G., Noormets, A., Gavazzi, M., McNulty, S., Chen, J., Domec, J., King, J., Amatya, D., Skaggs, R. (2010) Energy And Water Balance Of Two Contrasting Loblolly Pine Plantations On The Lower Coastal Plain Of North Carolina, USA, Forest Ecology And Management, 259(7), 1299-1310" -US-NC1,1700003183,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.FORECO.2009.09.016 -US-NC1,1700003183,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Primary_Citation -US-NC1,12828,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"The research and science objectives of the North Carolina Clearcut site are as follows: 1) quantify age-related changes in carbon and water exchange, environmental regulation and stress sensitivity; 2) partition causes of variability between environmental and management factors; 3) Identify primary vulnerabilities to environmental stresses, and develop potential adaptive measures." -US-NC1,25075,GRP_SA,SA,2 -US-NC1,97907,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"Attn: John King, NCSU Forestry, 1025A Biltmore Hall, 2820 Faucette Drive, Raleigh, NC 27695" -US-NC1,12830,GRP_SITE_CHAR,TERRAIN,Flat -US-NC1,12830,GRP_SITE_CHAR,ASPECT,FLAT -US-NC1,12830,GRP_SITE_CHAR,WIND_DIRECTION,SW -US-NC1,12830,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,350 -US-NC1,12830,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,1 -US-NC1,12831,GRP_SITE_DESC,SITE_DESC,"The North Carolina Clearcut site is located in a pine plantation amongst the mixed forests of the North Carolina lower coastal plain. Owned by the Weyerhaeuser Company, the plantation is managed for the purpose of commercial logging. In 2004, 70 ha of 75 year old native hardwoods was harvested. Following the clearcut, the stand was bedded and planted with loblolly pine seedlings. The only significant natural disturbances during the measurement period was a severe drought that lasted from summer of 2007 through 2008. Consequently, the 2007 total amount of precipitation was 486 mm below the 30-year norm." -US-NC1,12832,GRP_SITE_FUNDING,SITE_FUNDING,"USDA FS, DOE" -US-NC1,28431,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION,"Fine, mixed, semiactive, themic tipic Umbraquuits (Utisols)" -US-NC1,28431,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION_TAXONOMY,Other -US-NC1,23930,GRP_SPP_O,SPP_O,"Herbaceous plants," -US-NC1,12833,GRP_STATE,STATE,NC -US-NC1,31198,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Asko Noormets -US-NC1,31198,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-NC1,31198,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,noormets@tamu.edu -US-NC1,31198,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Texas A&M University -US-NC1,84732,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Michael Gavazzi -US-NC1,84732,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Technician -US-NC1,84732,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,mgavazzi@fs.fed.us -US-NC1,84732,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,USDA FS EFETAC -US-NC1,29826,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-NC1,12835,GRP_TOWER_TYPE,TOWER_TYPE,other -US-NC1,84734,GRP_URL,URL,https://sites.google.com/site/ncfluxcoresites/ -US-NC1,24000401,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-NC1 -US-NC1,12836,GRP_UTC_OFFSET,UTC_OFFSET,-5 -US-NC2,12849,GRP_CLIM_AVG,MAT,16.6 -US-NC2,12849,GRP_CLIM_AVG,MAP,1320 -US-NC2,12849,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Cfa -US-NC2,27000402,GRP_COUNTRY,COUNTRY,USA -US-NC2,15675,GRP_DOI,DOI,10.17190/AMF/1246083 -US-NC2,15675,GRP_DOI,DOI_CITATION,"Asko Noormets, Bhaskar Mitra, Ge Sun, Guofang Miao, John King, Kevan Minick, Linqing Yang, Maricar Aguilos, Michael Gavazzi, Prajaya Prajapati, Steve McNulty (2022), AmeriFlux BASE US-NC2 NC_Loblolly Plantation, Ver. 10-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1246083" -US-NC2,15675,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-NC2,32138,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-NC2,32138,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Asko Noormets -US-NC2,32138,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-NC2,32138,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,noormets@tamu.edu -US-NC2,32138,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Texas A&M University -US-NC2,98792,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-NC2,98792,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Bhaskar Mitra -US-NC2,98792,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-NC2,98792,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,2016 -US-NC2,98792,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_END,2019 -US-NC2,98761,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-NC2,98761,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Ge Sun -US-NC2,98761,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-NC2,98761,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,2005 -US-NC2,98788,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-NC2,98788,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Guofang Miao -US-NC2,98788,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-NC2,98788,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,2008 -US-NC2,98788,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_END,2013 -US-NC2,98785,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-NC2,98785,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,John King -US-NC2,98785,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-NC2,98785,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,North Carolina State University -US-NC2,98785,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,2005 -US-NC2,98778,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-NC2,98778,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Kevan Minick -US-NC2,98778,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-NC2,98778,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,2015 -US-NC2,98778,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_END,2020 -US-NC2,98764,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-NC2,98764,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Linqing Yang -US-NC2,98764,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-NC2,98764,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,2020 -US-NC2,98764,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_END,2022 -US-NC2,98791,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-NC2,98791,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Maricar Aguilos -US-NC2,98791,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-NC2,98791,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,2018 -US-NC2,98759,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-NC2,98759,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Michael Gavazzi -US-NC2,98759,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-NC2,98759,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,2005 -US-NC2,98772,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-NC2,98772,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Prajaya Prajapati -US-NC2,98772,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-NC2,98772,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,2018 -US-NC2,98772,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_END,2021 -US-NC2,98747,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-NC2,98747,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Steve McNulty -US-NC2,98747,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-NC2,98747,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,2005 -US-NC2,32140,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Texas A&M University -US-NC2,32140,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-NC2,32139,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,"USDA Forest Service, DOE-BER-TES-AMP" -US-NC2,32139,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-NC2,12866,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Drought -US-NC2,12850,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Forestry -US-NC2,12870,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Hydrologic event -US-NC2,12874,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Storm or wind -US-NC2,12851,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-NC2,12851,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-NC2,12851,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20050101 -US-NC2,12851,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-NC2,12867,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Chambers -US-NC2,12867,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-NC2,12867,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20050309 -US-NC2,12867,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Periodic operation -US-NC2,12871,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Chambers -US-NC2,12871,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-NC2,12871,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20050525 -US-NC2,12871,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-NC2,23000402,GRP_HEADER,SITE_NAME,NC_Loblolly Plantation -US-NC2,24785,GRP_HEIGHTC,HEIGHTC,14 -US-NC2,12852,GRP_IGBP,IGBP,ENF -US-NC2,12852,GRP_IGBP,IGBP_COMMENT,Loblolly pine plantation -US-NC2,24790,GRP_LAI,LAI_TYPE,LAI -US-NC2,24790,GRP_LAI,LAI_TOT,3 -US-NC2,24790,GRP_LAI,LAI_U,0 -US-NC2,12853,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -US-NC2,12853,GRP_LAND_OWNERSHIP,LAND_OWNER,Weyerhaeuser Company -US-NC2,12854,GRP_LOCATION,LOCATION_LAT,35.8030 -US-NC2,12854,GRP_LOCATION,LOCATION_LONG,-76.6685 -US-NC2,12854,GRP_LOCATION,LOCATION_ELEV,5 -US-NC2,12854,GRP_LOCATION,LOCATION_COMMENT,Tower location -US-NC2,12855,GRP_NETWORK,NETWORK,AmeriFlux -US-NC2,86987,GRP_NETWORK,NETWORK,Phenocam -US-NC2,84739,GRP_NETWORK,NETWORK,USCCC -US-NC2,1700006222,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Baldocchi, D., Penuelas, J. (2018) The Physics And Ecology Of Mining Carbon Dioxide From The Atmosphere By Ecosystems, Global Change Biology, 45(6), 9275–9287" -US-NC2,1700006222,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/GCB.14559 -US-NC2,1700006222,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-NC2,1700007461,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Baldocchi, D. D., Poindexter, C., Abraha, M., Desai, A. R., Bohrer, G., Arain, M. A., Griffis, T., Blanken, P. D., O'Halloran, T. L., Thomas, R. Q., Zhang, Q., Burns, S. P., Frank, J. M., Christian, D., Brown, S., Black, T. A., Gough, C. M., Law, B. E., Lee, X., Chen, J., Reed, D. E., Massman, W. J., Clark, K., Hatfield, J., Prueger, J., Bracho, R., Baker, J. M., Martin, T. A. (2018) Temporal Dynamics Of Aerodynamic Canopy Height Derived From Eddy Covariance Momentum Flux Data Across North American Flux Networks, Geophysical Research Letters, 45(6), 9275–9287" -US-NC2,1700007461,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018GL079306 -US-NC2,1700007461,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-NC2,1700005013,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(6), 108350" -US-NC2,1700005013,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -US-NC2,1700005013,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-NC2,1700000489,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Dennis Baldocchi, Cove Sturtevant (2015) Does day and night sampling reduce spurious correlation between canopy photosynthesis and ecosystem respiration?, Agricultural and Forest Meteorology, 207(1), 117-126" -US-NC2,1700000489,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2015.03.010 -US-NC2,1700000489,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-NC2,1700008859,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Domec, J., King, J. S., Noormets, A., Treasure, E., Gavazzi, M. J., Sun, G., McNulty, S. G. (2010) Hydraulic Redistribution Of Soil Water By Roots Affects Whole-Stand Evapotranspiration And Net Ecosystem Carbon Exchange, New Phytologist, 187(1), 171-183" -US-NC2,1700008859,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/J.1469-8137.2010.03245.X -US-NC2,1700008859,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-NC2,1700007695,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Domec, J., Ogee, J., Noormets, A., Jouangy, J., Gavazzi, M., Treasure, E., Sun, G., McNulty, S. G., King, J. S. (2012) Interactive Effects Of Nocturnal Transpiration And Climate Change On The Root Hydraulic Redistribution And Carbon And Water Budgets Of Southern United States Pine Plantations, Tree Physiology, 32(6), 707-723" -US-NC2,1700007695,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1093/TREEPHYS/TPS018 -US-NC2,1700007695,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Primary_Citation -US-NC2,1700008157,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Domec, J., Sun, G., Noormets, A., Gavazzi, M. J., Treasure, E. A., Cohen, E., Swenson, J. J., McNulty, S. G., King, J. S. (2012) A Comparison Of Three Methods To Estimate Evapotranspiration In Two Contrasting Loblolly Pine Plantations: Age-Related Changes In Water Use And Drought Sensitivity Of Evapotranspiration Components, Forest Science, 58(5), 497-512" -US-NC2,1700008157,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.5849/FORSCI.11-051 -US-NC2,1700008157,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-NC2,1700001236,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Middleton, E., Rascher, U., Corp, L., Huemmrich, K., Cook, B., Noormets, A., Schickling, A., Pinto, F., Alonso, L., Damm, A., Guanter, L., Colombo, R., Campbell, P., Landis, D., Zhang, Q., Rossini, M., Schuettemeyer, D., Bianchi, R. (2017) The 2013 Flex—Us Airborne Campaign At The Parker Tract Loblolly Pine Plantation In North Carolina, Usa, Remote Sensing, 9(6), 612-643" -US-NC2,1700001236,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.3390/RS9060612 -US-NC2,1700001236,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-NC2,1700008880,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Noormets, A., Gavazzi, M. J., Mcnulty, S. G., Domec, J., Sun, G., King, J. S., Chen, J. (2010) Response Of Carbon Fluxes To Drought In A Coastal Plain Loblolly Pine Forest, Global Change Biology, 16(1), 272-287" -US-NC2,1700008880,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/J.1365-2486.2009.01928.X -US-NC2,1700008880,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-NC2,1700006789,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Noormets, A., McNulty, S. G., Domec, J., Gavazzi, M., Sun, G., King, J. S. (2012) The Role Of Harvest Residue In Rotation Cycle Carbon Balance In Loblolly Pine Plantations. Respiration Partitioning Approach, Global Change Biology, 18(10), 3186-3201" -US-NC2,1700006789,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/J.1365-2486.2012.02776.X -US-NC2,1700006789,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-NC2,1700007689,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Sun, G., Noormets, A., Gavazzi, M., McNulty, S., Chen, J., Domec, J., King, J., Amatya, D., Skaggs, R. (2010) Energy And Water Balance Of Two Contrasting Loblolly Pine Plantations On The Lower Coastal Plain Of North Carolina, USA, Forest Ecology And Management, 259(7), 1299-1310" -US-NC2,1700007689,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.FORECO.2009.09.016 -US-NC2,1700007689,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Primary_Citation -US-NC2,12857,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"The research and science objectives of the North Carolina Loblolly Pine site are as follows: 1) quantify age-related changes in carbon and water exchange, environmental regulation and stress sensitivity; 2) partition causes of variability between environmental and management factors; 3) Identify primary vulnerabilities to environmental stresses, and develop potential adaptive measures; 4) Characterize the sources of interannual variability in the fluxes, including sensitivity to natural disturbances such as severe droughts; 5) Examine the effects of ecosystem conversion from wetlands to intensively managed forests on plant hydraulic properties and water balances. (Domec et al., 2009, Noormets et al., 2009)" -US-NC2,24817,GRP_SA,SA,14 -US-NC2,97909,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"NCSU Forestry, 1025A Biltmore Hall, 2820 Faucette Drive, Raleigh, NC 27695" -US-NC2,12859,GRP_SITE_CHAR,TERRAIN,Flat -US-NC2,12859,GRP_SITE_CHAR,ASPECT,FLAT -US-NC2,12859,GRP_SITE_CHAR,WIND_DIRECTION,SW -US-NC2,12859,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,500 -US-NC2,12859,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,1 -US-NC2,12860,GRP_SITE_DESC,SITE_DESC,"The North Carolina Loblolly Pine site is located in a pine plantation amongst the mixed forests of the North Carolina lower coastal plain. During the late 19th and early 20th centuries the region was logged extensively. After a series of clearcuts, the land was transformed for agricultural practices. In 1967 and 1969, 4000 ha was sold to the Weyerhauser company for agriculture, preservation, and commercial logging of loblolly pines in a series of plantations. The fifth rotation stand surrounding the tower was established in 1992. The only significant natural disturbances during the measurement period was a severe drought that spanned the entire duration of the 2007 growing season. Consequently, the 2007 total amount of precipitation was 486 mm below the 30-year norm. In the same year, the plantation was thinned and fertilized. The stand was thinned in Oct 2009. The eastern half of the site was fertilized in January 2011, and the entire site was fertilized in October 2012." -US-NC2,12861,GRP_SITE_FUNDING,SITE_FUNDING,"USDA Forest Service, DOE-BER-TES-AMP" -US-NC2,29623,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION,"Loamy, mixed, dysic, thermic terric, Haplosaprists" -US-NC2,29623,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION_TAXONOMY,Other -US-NC2,24297,GRP_SPP_O,SPP_O,Pinus taeda -US-NC2,12862,GRP_STATE,STATE,NC -US-NC2,31199,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Asko Noormets -US-NC2,31199,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-NC2,31199,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,noormets@tamu.edu -US-NC2,31199,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Texas A&M University -US-NC2,84740,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Jean-Christophe Domec -US-NC2,84740,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,AncContact -US-NC2,84740,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,jc.domec@agro-bordeaux.fr -US-NC2,84740,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Bordeaux Sciences Agro -US-NC2,84738,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Michael Gavazzi -US-NC2,84738,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,BADMContact -US-NC2,84738,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,mgavazzi@fs.fed.us -US-NC2,84738,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,USDA FS EFETAC -US-NC2,97914,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Linqing Yang -US-NC2,97914,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,DataManager -US-NC2,97914,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,linqingyang_bnu@tamu.edu -US-NC2,97914,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Texas A&M University -US-NC2,86637,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,John King -US-NC2,86637,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Affiliate -US-NC2,86637,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,john_king@ncsu.edu -US-NC2,86637,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,North Carolina State University -US-NC2,86639,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Maricar Aguilos -US-NC2,86639,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Affiliate -US-NC2,86639,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,mmaguilo@ncsu.edu -US-NC2,86639,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,North Carolina State University -US-NC2,29827,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-NC2,12864,GRP_TOWER_TYPE,TOWER_TYPE,other -US-NC2,84741,GRP_URL,URL,https://sites.google.com/site/ncfluxcoresites/ -US-NC2,24000402,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-NC2 -US-NC2,12865,GRP_UTC_OFFSET,UTC_OFFSET,-5 -US-NC3,12878,GRP_CLIM_AVG,MAT,16.6 -US-NC3,12878,GRP_CLIM_AVG,MAP,1320 -US-NC3,12878,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Cfa -US-NC3,27000538,GRP_COUNTRY,COUNTRY,USA -US-NC3,79476,GRP_DOI,DOI,10.17190/AMF/1419506 -US-NC3,79476,GRP_DOI,DOI_CITATION,"Asko Noormets (2022), AmeriFlux BASE US-NC3 NC_Clearcut#3, Ver. 4-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1419506" -US-NC3,79476,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-NC3,79438,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-NC3,79438,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Asko Noormets -US-NC3,79438,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-NC3,79438,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,noormets@tamu.edu -US-NC3,79438,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Texas A&M University -US-NC3,79440,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Texas A&M University -US-NC3,79440,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-NC3,79439,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,"USDA FS, DOE-TES-AMP" -US-NC3,79439,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-NC3,12894,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Drought -US-NC3,12879,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Forestry -US-NC3,12897,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Hydrologic event -US-NC3,12899,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Storm or wind -US-NC3,12880,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-NC3,12880,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-NC3,12880,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20130220 -US-NC3,12880,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-NC3,12898,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Chambers -US-NC3,12898,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-NC3,12898,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20130605 -US-NC3,12898,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-NC3,12895,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Chambers -US-NC3,12895,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-NC3,12895,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20130611 -US-NC3,12895,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Periodic operation -US-NC3,23000538,GRP_HEADER,SITE_NAME,NC_Clearcut#3 -US-NC3,12881,GRP_IGBP,IGBP,ENF -US-NC3,12882,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -US-NC3,12882,GRP_LAND_OWNERSHIP,LAND_OWNER,Weyerhaeuser Company -US-NC3,12883,GRP_LOCATION,LOCATION_LAT,35.7990 -US-NC3,12883,GRP_LOCATION,LOCATION_LONG,-76.6560 -US-NC3,12883,GRP_LOCATION,LOCATION_ELEV,5 -US-NC3,12883,GRP_LOCATION,LOCATION_COMMENT,Tower Location -US-NC3,12884,GRP_NETWORK,NETWORK,AmeriFlux -US-NC3,84743,GRP_NETWORK,NETWORK,USCCC -US-NC3,1700004992,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(), 108350" -US-NC3,1700004992,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -US-NC3,1700004992,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-NC3,12885,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"The goal is to refine understanding of post-disturbance carbon fluxes, respiration partitioining, and decomposition dynamics." -US-NC3,97913,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"Attn: Maricar Aguilos, NCSU Forestry, 1025A Biltmore Hall, 2820 Faucette Drive, Raleigh, NC 27695" -US-NC3,12887,GRP_SITE_CHAR,TERRAIN,Gentle slope (<2 %) -US-NC3,12887,GRP_SITE_CHAR,ASPECT,FLAT -US-NC3,12887,GRP_SITE_CHAR,WIND_DIRECTION,SW -US-NC3,12887,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,200 -US-NC3,12887,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,1 -US-NC3,100817,GRP_SITE_DESC,SITE_DESC,"The North Carolina Clearcut site #3 was set up to complement NC2, and continue in place of NC1. The previous rotation of loblolly pine was harvested in the spring of 2012, the site was prepared and replanted with 2-yr old seedlings in the winter of 2012/2013. Measurements were terminated in 2021 due to trees outgrowing the tower and infrastructure capability." -US-NC3,12889,GRP_SITE_FUNDING,SITE_FUNDING,"USDA FS, DOE-TES-AMP" -US-NC3,12890,GRP_STATE,STATE,NC -US-NC3,31200,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Asko Noormets -US-NC3,31200,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-NC3,31200,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,noormets@tamu.edu -US-NC3,31200,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Texas A&M University -US-NC3,97911,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Michael Gavazzi -US-NC3,97911,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,BADMContact -US-NC3,97911,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,mgavazzi@fs.fed.us -US-NC3,97911,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,USDA FS EFETAC -US-NC3,97912,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Linqing Yang -US-NC3,97912,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,DataManager -US-NC3,97912,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,linqingyang_bnu@tamu.edu -US-NC3,97912,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Texas A&M University -US-NC3,86641,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,John King -US-NC3,86641,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Affiliate -US-NC3,86641,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,john_king@ncsu.edu -US-NC3,86641,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,North Carolina State University -US-NC3,86640,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Maricar Aguilos -US-NC3,86640,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Affiliate -US-NC3,86640,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,mmaguilo@ncsu.edu -US-NC3,86640,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,North Carolina State University -US-NC3,29872,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-NC3,12892,GRP_TOWER_TYPE,TOWER_TYPE,triangle -US-NC3,24000538,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-NC3 -US-NC3,12893,GRP_UTC_OFFSET,UTC_OFFSET,-5 -US-NC4,12900,GRP_CLIM_AVG,MAT,16.6 -US-NC4,12900,GRP_CLIM_AVG,MAP,1311 -US-NC4,12900,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Cfa -US-NC4,27000539,GRP_COUNTRY,COUNTRY,USA -US-NC4,85248,GRP_DOI,DOI,10.17190/AMF/1480314 -US-NC4,85248,GRP_DOI,DOI_CITATION,"Asko Noormets (2022), AmeriFlux BASE US-NC4 NC_AlligatorRiver, Ver. 5-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1480314" -US-NC4,85248,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-NC4,84782,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-NC4,84782,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Asko Noormets -US-NC4,84782,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-NC4,84782,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,noormets@tamu.edu -US-NC4,84782,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Texas A&M University -US-NC4,84790,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Texas A&M University -US-NC4,84790,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-NC4,84789,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,"USDA FS, DOE-TES, DOE-TES-AMP" -US-NC4,84789,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-NC4,12901,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Hydrologic event -US-NC4,12917,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Storm or wind -US-NC4,12902,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-NC4,12902,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-NC4,12902,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20090215 -US-NC4,12902,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-NC4,12918,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Chambers -US-NC4,12918,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-NC4,12918,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20090605 -US-NC4,12918,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20121231 -US-NC4,12918,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-NC4,12920,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Chambers -US-NC4,12920,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-NC4,12920,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20100307 -US-NC4,12920,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20110818 -US-NC4,12920,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Periodic operation -US-NC4,12922,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-NC4,12922,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CH4 -US-NC4,12922,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20120112 -US-NC4,12922,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-NC4,23000539,GRP_HEADER,SITE_NAME,NC_AlligatorRiver -US-NC4,12903,GRP_IGBP,IGBP,WET -US-NC4,12903,GRP_IGBP,IGBP_COMMENT,Forested wetland -US-NC4,84748,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-NC4,84748,GRP_LAND_OWNERSHIP,LAND_OWNER,"US Fish and Wildlife Service, Alligator River National Wildlife Refuge" -US-NC4,12905,GRP_LOCATION,LOCATION_LAT,35.7879 -US-NC4,12905,GRP_LOCATION,LOCATION_LONG,-75.9038 -US-NC4,12905,GRP_LOCATION,LOCATION_ELEV,1 -US-NC4,12905,GRP_LOCATION,LOCATION_COMMENT,Tower Location -US-NC4,12906,GRP_NETWORK,NETWORK,AmeriFlux -US-NC4,86988,GRP_NETWORK,NETWORK,Phenocam -US-NC4,1700003204,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(2), 108350" -US-NC4,1700003204,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -US-NC4,1700003204,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-NC4,1700000072,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Feagin, R. A., Forbrich, I., Huff, T. P., Barr, J. G., Ruiz‐Plancarte, J., Fuentes, J. D., Najjar, R. G., Vargas, R., Vázquez‐Lule, A., Windham‐Myers, L., Kroeger, K. D., Ward, E. J., Moore, G. W., Leclerc, M., Krauss, K. W., Stagg, C. L., Alber, M., Knox, S. H., Schäfer, K. V., Bianchi, T. S., Hutchings, J. A., Nahrawi, H., Noormets, A., Mitra, B., Jaimes, A., Hinson, A. L., Bergamaschi, B., King, J. S., Miao, G. (2020) Tidal Wetland Gross Primary Production Across The Continental United States, 2000–2019, Global Biogeochemical Cycles, 34(2), 1-11" -US-NC4,1700000072,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2019GB006349 -US-NC4,1700000072,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-NC4,1700006423,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Miao, G., Noormets, A., Domec, J., Fuentes, M., Trettin, C. C., Sun, G., McNulty, S. G., King, J. S. (2017) Hydrology And Microtopography Control Carbon Dynamics In Wetlands: Implications In Partitioning Ecosystem Respiration In A Coastal Plain Forested Wetland, Agricultural And Forest Meteorology, 247(2), 343-355" -US-NC4,1700006423,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2017.08.022 -US-NC4,1700006423,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-NC4,1700006918,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Miao, G., Noormets, A., Domec, J., Trettin, C. C., McNulty, S. G., Sun, G., King, J. S. (2013) The Effect Of Water Table Fluctuation On Soil Respiration In A Lower Coastal Plain Forested Wetland In The Southeastern U.S., Journal Of Geophysical Research: Biogeosciences, 118(4), 1748-1762" -US-NC4,1700006918,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/2013JG002354 -US-NC4,1700006918,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-NC4,1700005709,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Minick, K., Kelley, A., Miao, G., Li, X., Noormets, A., Mitra, B., King, J.S. (2018) Microtopography Alters Hydrology, Phenol Oxidase Activity and Nutrient Availability in Organic Soils of a Coastal Freshwater Forested Wetland, Wetlands, 2(4), 1-11" -US-NC4,1700005709,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-NC4,1700005484,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Minick, K., Kelley, A., Miao, G., Li, X., Noormets, A., Mitra, B., King, J.S. (2018) Microtopography Alters Hydrology, Phenol Oxidase Activity and Nutrient Availability in Organic Soils of a Coastal Freshwater Forested Wetland, Wetlands, 301-302(2), 1-11" -US-NC4,1700005484,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-NC4,12908,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"Hydrological regulation of CO2 and CH4 exchange, dynamics of soil carbon, partitioning of respiration" -US-NC4,97910,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"Attn: Maricar Aguilos, NCSU Forestry, 1025 Biltmore Hall, 2820 Faucette Dr,, North Carolina State University, Raleigh, NC 27695" -US-NC4,12910,GRP_SITE_CHAR,TERRAIN,Flat -US-NC4,12910,GRP_SITE_CHAR,ASPECT,FLAT -US-NC4,12910,GRP_SITE_CHAR,WIND_DIRECTION,SW -US-NC4,12910,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,2000 -US-NC4,12910,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,1 -US-NC4,12911,GRP_SITE_DESC,SITE_DESC,"The North Carolina Alligator River site was established to provide core measurements for understanding carbon cycling in natural coastal forested wetlands. It serves as a reference for NC1, NC2 and NC3, representing an ecosystem type that dominated the area prior to European settlement." -US-NC4,12912,GRP_SITE_FUNDING,SITE_FUNDING,"USDA FS, DOE-TES, DOE-TES-AMP" -US-NC4,12913,GRP_STATE,STATE,NC -US-NC4,31201,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Asko Noormets -US-NC4,31201,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-NC4,31201,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,noormets@tamu.edu -US-NC4,31201,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Texas A&M University -US-NC4,81407,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Jean-Christophe Domec -US-NC4,81407,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,AncContact -US-NC4,81407,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,jc.domec@agro.bordeaux.fr -US-NC4,81407,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Bordeaux Sciences Agro -US-NC4,12919,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,John King -US-NC4,12919,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,AncContact -US-NC4,12919,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,john_king@ncsu.edu -US-NC4,12919,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,North Carolina State University -US-NC4,97906,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Linqing Yang -US-NC4,97906,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,DataManager -US-NC4,97906,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,linqingyang_bnu@tamu.edu -US-NC4,97906,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Texas A&M University -US-NC4,86644,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Maricar Aguilos -US-NC4,86644,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Affiliate -US-NC4,86644,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,mmaguilo@ncsu.edu -US-NC4,86644,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,North Carolina State University -US-NC4,29873,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-NC4,12915,GRP_TOWER_TYPE,TOWER_TYPE,walk-up -US-NC4,84747,GRP_URL,URL,https://sites.google.com/site/ncfluxcoresites/ -US-NC4,24000539,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-NC4 -US-NC4,12916,GRP_UTC_OFFSET,UTC_OFFSET,-5 -US-Ne1,28048,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,0.21533 -US-Ne1,28048,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne1,28048,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne1,28048,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne1,28048,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20020529 -US-Ne1,28048,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne1,28723,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,0.545466 -US-Ne1,28723,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne1,28723,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne1,28723,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne1,28723,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20010529 -US-Ne1,28723,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne1,29262,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,0.815529 -US-Ne1,29262,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne1,29262,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne1,29262,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne1,29262,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20050531 -US-Ne1,29262,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne1,27682,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,0.892291 -US-Ne1,27682,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne1,27682,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne1,27682,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne1,27682,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20030606 -US-Ne1,27682,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne1,29258,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,0.920431 -US-Ne1,29258,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne1,29258,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne1,29258,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne1,29258,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20020603 -US-Ne1,29258,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne1,27770,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,1015.71 -US-Ne1,27770,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne1,27770,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne1,27770,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne1,27770,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20060912 -US-Ne1,27770,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne1,28678,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,103.421 -US-Ne1,28678,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne1,28678,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne1,28678,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne1,28678,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20070619 -US-Ne1,28678,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne1,27132,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,103.468 -US-Ne1,27132,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne1,27132,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne1,27132,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne1,27132,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20010629 -US-Ne1,27132,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne1,28895,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,1065.84 -US-Ne1,28895,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne1,28895,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne1,28895,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne1,28895,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20070924 -US-Ne1,28895,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne1,28726,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,1083.51 -US-Ne1,28726,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne1,28726,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne1,28726,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne1,28726,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20020912 -US-Ne1,28726,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne1,28738,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,1112.15 -US-Ne1,28738,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne1,28738,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne1,28738,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne1,28738,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20070905 -US-Ne1,28738,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne1,29261,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,129.572 -US-Ne1,29261,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne1,29261,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne1,29261,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne1,29261,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20040701 -US-Ne1,29261,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne1,27683,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,143.449 -US-Ne1,27683,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne1,27683,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne1,27683,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne1,27683,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20030708 -US-Ne1,27683,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne1,29259,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,160.285 -US-Ne1,29259,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne1,29259,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne1,29259,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne1,29259,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20020701 -US-Ne1,29259,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne1,28662,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,166.598 -US-Ne1,28662,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne1,28662,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne1,28662,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne1,28662,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20060626 -US-Ne1,28662,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne1,28399,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,19.9757 -US-Ne1,28399,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne1,28399,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne1,28399,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne1,28399,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20070606 -US-Ne1,28399,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne1,29580,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,191.885 -US-Ne1,29580,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne1,29580,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne1,29580,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne1,29580,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20050707 -US-Ne1,29580,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne1,28667,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,2.44095 -US-Ne1,28667,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne1,28667,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne1,28667,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne1,28667,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20040603 -US-Ne1,28667,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne1,27685,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,20.1132 -US-Ne1,27685,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne1,27685,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne1,27685,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne1,27685,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20040615 -US-Ne1,27685,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne1,27679,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,201.247 -US-Ne1,27679,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne1,27679,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne1,27679,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne1,27679,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20010705 -US-Ne1,27679,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne1,27447,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,205.609 -US-Ne1,27447,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne1,27447,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne1,27447,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne1,27447,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20070626 -US-Ne1,27447,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne1,28398,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,21.3839 -US-Ne1,28398,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne1,28398,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne1,28398,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne1,28398,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20060608 -US-Ne1,28398,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne1,27681,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,240.987 -US-Ne1,27681,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne1,27681,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne1,27681,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne1,27681,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20020708 -US-Ne1,27681,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne1,29375,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,26.2745 -US-Ne1,29375,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne1,29375,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne1,29375,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne1,29375,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20050617 -US-Ne1,29375,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne1,27680,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,26.4778 -US-Ne1,27680,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne1,27680,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne1,27680,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne1,27680,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20020618 -US-Ne1,27680,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne1,29374,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,264.278 -US-Ne1,29374,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne1,29374,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne1,29374,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne1,29374,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20040713 -US-Ne1,29374,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne1,28393,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,305.929 -US-Ne1,28393,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne1,28393,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne1,28393,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne1,28393,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20030718 -US-Ne1,28393,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne1,27133,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,307.429 -US-Ne1,27133,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne1,27133,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne1,27133,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne1,27133,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20010713 -US-Ne1,27133,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne1,29260,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,32.6504 -US-Ne1,29260,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne1,29260,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne1,29260,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne1,29260,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20030625 -US-Ne1,29260,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne1,29253,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,337.861 -US-Ne1,29253,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne1,29253,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne1,29253,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne1,29253,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20060706 -US-Ne1,29253,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne1,27775,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,341.663 -US-Ne1,27775,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne1,27775,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne1,27775,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne1,27775,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20020715 -US-Ne1,27775,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne1,28668,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,369.501 -US-Ne1,28668,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne1,28668,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne1,28668,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne1,28668,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20050720 -US-Ne1,28668,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne1,27672,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,378.321 -US-Ne1,27672,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne1,27672,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne1,27672,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne1,27672,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20060712 -US-Ne1,27672,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne1,27678,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,38.6729 -US-Ne1,27678,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne1,27678,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne1,27678,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne1,27678,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20010621 -US-Ne1,27678,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne1,27448,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,381.806 -US-Ne1,27448,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne1,27448,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne1,27448,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne1,27448,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20070709 -US-Ne1,27448,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne1,29250,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,382 -US-Ne1,29250,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Total -US-Ne1,29250,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne1,29250,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne1,29250,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20041004 -US-Ne1,27432,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,394.37 -US-Ne1,27432,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne1,27432,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne1,27432,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne1,27432,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20010719 -US-Ne1,27432,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne1,27699,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,4.01429 -US-Ne1,27699,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne1,27699,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne1,27699,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne1,27699,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20070529 -US-Ne1,27699,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne1,27697,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,4.48646 -US-Ne1,27697,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne1,27697,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne1,27697,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne1,27697,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20060601 -US-Ne1,27697,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne1,27684,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,416.843 -US-Ne1,27684,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne1,27684,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne1,27684,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne1,27684,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20030728 -US-Ne1,27684,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne1,27669,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,436 -US-Ne1,27669,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Total -US-Ne1,27669,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne1,27669,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne1,27669,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20051009 -US-Ne1,27668,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,438 -US-Ne1,27668,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Total -US-Ne1,27668,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne1,27668,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne1,27668,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20031021 -US-Ne1,28039,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,446 -US-Ne1,28039,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Total -US-Ne1,28039,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne1,28039,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne1,28039,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20021015 -US-Ne1,28053,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,46.2953 -US-Ne1,28053,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne1,28053,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne1,28053,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne1,28053,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20070613 -US-Ne1,28053,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne1,27134,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,461.193 -US-Ne1,27134,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne1,27134,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne1,27134,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne1,27134,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20040726 -US-Ne1,27134,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne1,28658,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,486 -US-Ne1,28658,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Total -US-Ne1,28658,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne1,28658,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne1,28658,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20011016 -US-Ne1,27147,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,486.828 -US-Ne1,27147,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne1,27147,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne1,27147,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne1,27147,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20070716 -US-Ne1,27147,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne1,27130,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,487.896 -US-Ne1,27130,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne1,27130,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne1,27130,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne1,27130,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20060720 -US-Ne1,27130,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne1,27776,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,521.729 -US-Ne1,27776,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne1,27776,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne1,27776,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne1,27776,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20040805 -US-Ne1,27776,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne1,28666,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,524.921 -US-Ne1,28666,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne1,28666,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne1,28666,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne1,28666,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20030808 -US-Ne1,28666,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne1,27436,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,529.592 -US-Ne1,27436,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne1,27436,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne1,27436,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne1,27436,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20050801 -US-Ne1,27436,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne1,28724,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,571.758 -US-Ne1,28724,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne1,28724,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne1,28724,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne1,28724,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20020729 -US-Ne1,28724,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne1,27673,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,604.009 -US-Ne1,27673,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne1,27673,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne1,27673,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne1,27673,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20060728 -US-Ne1,27673,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne1,27437,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,604.729 -US-Ne1,27437,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne1,27437,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne1,27437,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne1,27437,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20050809 -US-Ne1,27437,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne1,29584,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,623.304 -US-Ne1,29584,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne1,29584,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne1,29584,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne1,29584,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20070724 -US-Ne1,29584,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne1,28043,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,65.8304 -US-Ne1,28043,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne1,28043,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne1,28043,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne1,28043,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20060616 -US-Ne1,28043,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne1,28720,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,673.598 -US-Ne1,28720,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne1,28720,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne1,28720,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne1,28720,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20060804 -US-Ne1,28720,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne1,27777,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,685.371 -US-Ne1,27777,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne1,27777,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne1,27777,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne1,27777,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20040817 -US-Ne1,27777,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne1,28669,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,698.192 -US-Ne1,28669,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne1,28669,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne1,28669,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne1,28669,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20050919 -US-Ne1,28669,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne1,27433,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,716.088 -US-Ne1,27433,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne1,27433,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne1,27433,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne1,27433,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20010809 -US-Ne1,27433,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne1,28887,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,777.459 -US-Ne1,28887,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne1,28887,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne1,28887,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne1,28887,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20060814 -US-Ne1,28887,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne1,28725,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,779.455 -US-Ne1,28725,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne1,28725,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne1,28725,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne1,28725,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20020812 -US-Ne1,28725,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne1,28047,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,790.954 -US-Ne1,28047,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne1,28047,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne1,28047,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne1,28047,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20010815 -US-Ne1,28047,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne1,29272,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,798.899 -US-Ne1,29272,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne1,29272,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne1,29272,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne1,29272,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20070803 -US-Ne1,29272,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne1,27774,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,8.23232 -US-Ne1,27774,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne1,27774,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne1,27774,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne1,27774,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20010613 -US-Ne1,27774,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne1,27135,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,810.81 -US-Ne1,27135,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne1,27135,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne1,27135,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne1,27135,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20051003 -US-Ne1,27135,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne1,27434,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,830.339 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-US-Ne1,26550,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-Ne1,26580,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-Ne1,26581,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-Ne1,23743,GRP_BIOMASS_CHEM,BIOMASS_SPP,(All) -US-Ne1,23744,GRP_BIOMASS_CHEM,BIOMASS_SPP,(All) -US-Ne1,23745,GRP_BIOMASS_CHEM,BIOMASS_SPP,(All) -US-Ne1,23884,GRP_BIOMASS_CHEM,BIOMASS_SPP,(All) -US-Ne1,23885,GRP_BIOMASS_CHEM,BIOMASS_SPP,(All) -US-Ne1,24009,GRP_BIOMASS_CHEM,BIOMASS_SPP,(All) -US-Ne1,24122,GRP_BIOMASS_CHEM,BIOMASS_SPP,(All) -US-Ne1,24126,GRP_BIOMASS_CHEM,BIOMASS_SPP,(All) -US-Ne1,24127,GRP_BIOMASS_CHEM,BIOMASS_SPP,(All) -US-Ne1,24128,GRP_BIOMASS_CHEM,BIOMASS_SPP,(All) -US-Ne1,24379,GRP_BIOMASS_CHEM,BIOMASS_SPP,(All) -US-Ne1,24383,GRP_BIOMASS_CHEM,BIOMASS_SPP,(All) -US-Ne1,24525,GRP_BIOMASS_CHEM,BIOMASS_SPP,(All) -US-Ne1,24526,GRP_BIOMASS_CHEM,BIOMASS_SPP,(All) -US-Ne1,24782,GRP_BIOMASS_CHEM,BIOMASS_SPP,(All) -US-Ne1,25036,GRP_BIOMASS_CHEM,BIOMASS_SPP,(All) -US-Ne1,25167,GRP_BIOMASS_CHEM,BIOMASS_SPP,(All) -US-Ne1,25295,GRP_BIOMASS_CHEM,BIOMASS_SPP,(All) -US-Ne1,25556,GRP_BIOMASS_CHEM,BIOMASS_SPP,(All) -US-Ne1,25582,GRP_BIOMASS_CHEM,BIOMASS_SPP,(All) -US-Ne1,25583,GRP_BIOMASS_CHEM,BIOMASS_SPP,(All) -US-Ne1,26059,GRP_BIOMASS_CHEM,BIOMASS_SPP,(All) -US-Ne1,26060,GRP_BIOMASS_CHEM,BIOMASS_SPP,(All) -US-Ne1,26172,GRP_BIOMASS_CHEM,BIOMASS_SPP,(All) -US-Ne1,26173,GRP_BIOMASS_CHEM,BIOMASS_SPP,(All) -US-Ne1,26199,GRP_BIOMASS_CHEM,BIOMASS_SPP,(All) -US-Ne1,26200,GRP_BIOMASS_CHEM,BIOMASS_SPP,(All) -US-Ne1,26327,GRP_BIOMASS_CHEM,BIOMASS_SPP,(All) -US-Ne1,26549,GRP_BIOMASS_CHEM,BIOMASS_SPP,(All) -US-Ne1,26550,GRP_BIOMASS_CHEM,BIOMASS_SPP,(All) -US-Ne1,26580,GRP_BIOMASS_CHEM,BIOMASS_SPP,(All) -US-Ne1,26581,GRP_BIOMASS_CHEM,BIOMASS_SPP,(All) -US-Ne1,24379,GRP_BIOMASS_CHEM,BIOMASS_DATE,20010613 -US-Ne1,24122,GRP_BIOMASS_CHEM,BIOMASS_DATE,20010621 -US-Ne1,23743,GRP_BIOMASS_CHEM,BIOMASS_DATE,20010629 -US-Ne1,23884,GRP_BIOMASS_CHEM,BIOMASS_DATE,20010705 -US-Ne1,24782,GRP_BIOMASS_CHEM,BIOMASS_DATE,20010713 -US-Ne1,24126,GRP_BIOMASS_CHEM,BIOMASS_DATE,20010719 -US-Ne1,25167,GRP_BIOMASS_CHEM,BIOMASS_DATE,20010809 -US-Ne1,26172,GRP_BIOMASS_CHEM,BIOMASS_DATE,20010815 -US-Ne1,24525,GRP_BIOMASS_CHEM,BIOMASS_DATE,20020529 -US-Ne1,25556,GRP_BIOMASS_CHEM,BIOMASS_DATE,20020618 -US-Ne1,26059,GRP_BIOMASS_CHEM,BIOMASS_DATE,20020701 -US-Ne1,25036,GRP_BIOMASS_CHEM,BIOMASS_DATE,20020708 -US-Ne1,26060,GRP_BIOMASS_CHEM,BIOMASS_DATE,20020715 -US-Ne1,24127,GRP_BIOMASS_CHEM,BIOMASS_DATE,20020729 -US-Ne1,26549,GRP_BIOMASS_CHEM,BIOMASS_DATE,20020812 -US-Ne1,24009,GRP_BIOMASS_CHEM,BIOMASS_DATE,20020912 -US-Ne1,24526,GRP_BIOMASS_CHEM,BIOMASS_DATE,20030606 -US-Ne1,23744,GRP_BIOMASS_CHEM,BIOMASS_DATE,20030625 -US-Ne1,23745,GRP_BIOMASS_CHEM,BIOMASS_DATE,20030708 -US-Ne1,23885,GRP_BIOMASS_CHEM,BIOMASS_DATE,20030718 -US-Ne1,25295,GRP_BIOMASS_CHEM,BIOMASS_DATE,20030728 -US-Ne1,25582,GRP_BIOMASS_CHEM,BIOMASS_DATE,20030808 -US-Ne1,25583,GRP_BIOMASS_CHEM,BIOMASS_DATE,20030826 -US-Ne1,26580,GRP_BIOMASS_CHEM,BIOMASS_DATE,20030926 -US-Ne1,26199,GRP_BIOMASS_CHEM,BIOMASS_DATE,20040603 -US-Ne1,26581,GRP_BIOMASS_CHEM,BIOMASS_DATE,20040615 -US-Ne1,26200,GRP_BIOMASS_CHEM,BIOMASS_DATE,20040701 -US-Ne1,26327,GRP_BIOMASS_CHEM,BIOMASS_DATE,20040713 -US-Ne1,24383,GRP_BIOMASS_CHEM,BIOMASS_DATE,20040726 -US-Ne1,26173,GRP_BIOMASS_CHEM,BIOMASS_DATE,20040805 -US-Ne1,26550,GRP_BIOMASS_CHEM,BIOMASS_DATE,20040817 -US-Ne1,24128,GRP_BIOMASS_CHEM,BIOMASS_DATE,20040907 -US-Ne1,3413,GRP_CLIM_AVG,MAT,10.07 -US-Ne1,3413,GRP_CLIM_AVG,MAP,790.37 -US-Ne1,3413,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfa -US-Ne1,27000403,GRP_COUNTRY,COUNTRY,USA -US-Ne1,7058,GRP_DM_AGRICULTURE,DM_AGRICULTURE,Harvest -US-Ne1,7058,GRP_DM_AGRICULTURE,DM_DATE,20011018 -US-Ne1,7058,GRP_DM_AGRICULTURE,DM_COMMENT,216 bu/ac. (13.51 Mg ha-1) MC 19.5 % -US-Ne1,4485,GRP_DM_AGRICULTURE,DM_AGRICULTURE,Harvest -US-Ne1,4485,GRP_DM_AGRICULTURE,DM_DATE,20021104 -US-Ne1,4485,GRP_DM_AGRICULTURE,DM_COMMENT,206 bu/ac (12.97 Mg ha-1 ) -US-Ne1,281,GRP_DM_AGRICULTURE,DM_AGRICULTURE,Harvest -US-Ne1,281,GRP_DM_AGRICULTURE,DM_DATE,20021105 -US-Ne1,281,GRP_DM_AGRICULTURE,DM_COMMENT,207 bu/ac (12.97 Mg ha-1 ) -US-Ne1,9628,GRP_DM_AGRICULTURE,DM_AGRICULTURE,Harvest -US-Ne1,9628,GRP_DM_AGRICULTURE,DM_DATE,20021106 -US-Ne1,9628,GRP_DM_AGRICULTURE,DM_COMMENT,208 bu/ac (12.97 Mg ha-1 ) -US-Ne1,1960,GRP_DM_AGRICULTURE,DM_AGRICULTURE,Harvest -US-Ne1,1960,GRP_DM_AGRICULTURE,DM_DATE,20021107 -US-Ne1,1960,GRP_DM_AGRICULTURE,DM_COMMENT,209 bu/ac (12.97 Mg ha-1 ) -US-Ne1,1108,GRP_DM_AGRICULTURE,DM_AGRICULTURE,Harvest -US-Ne1,1108,GRP_DM_AGRICULTURE,DM_DATE,20041014 -US-Ne1,1108,GRP_DM_AGRICULTURE,DM_COMMENT,193 bu/ac (12.12 Mg ha-1 ) corrected from 19.5% MC -US-Ne1,288,GRP_DM_AGRICULTURE,DM_AGRICULTURE,Harvest -US-Ne1,288,GRP_DM_AGRICULTURE,DM_DATE,20041015 -US-Ne1,288,GRP_DM_AGRICULTURE,DM_COMMENT,"193 bu/ac (12.12 Mg ha-1 ) corrected from 19.5% MC, CIH2366 8x30 in" -US-Ne1,2808,GRP_DM_AGRICULTURE,DM_AGRICULTURE,Harvest -US-Ne1,2808,GRP_DM_AGRICULTURE,DM_DATE,20041018 -US-Ne1,2808,GRP_DM_AGRICULTURE,DM_COMMENT,"193 bu/ac (12.12 Mg ha-1 ) corrected from 19.5% MC, CIH2366 8x30 in" -US-Ne1,264,GRP_DM_AGRICULTURE,DM_AGRICULTURE,Harvest -US-Ne1,264,GRP_DM_AGRICULTURE,DM_DATE,20051012 -US-Ne1,264,GRP_DM_AGRICULTURE,DM_COMMENT,192 bu/ac (12.05 Mg ha-1 )15.5% MC basis.15.5% MC -US-Ne1,6194,GRP_DM_AGRICULTURE,DM_AGRICULTURE,Harvest -US-Ne1,6194,GRP_DM_AGRICULTURE,DM_DATE,20051013 -US-Ne1,6194,GRP_DM_AGRICULTURE,DM_COMMENT,192 bu/ac (12.05 Mg ha-1 )15.5% MC basis.15.5% MC -US-Ne1,1950,GRP_DM_AGRICULTURE,DM_AGRICULTURE,Harvest -US-Ne1,1950,GRP_DM_AGRICULTURE,DM_DATE,20051014 -US-Ne1,1950,GRP_DM_AGRICULTURE,DM_COMMENT,192 bu/ac (12.05 Mg ha-1 )15.5% MC basis.15.5% MC -US-Ne1,9630,GRP_DM_AGRICULTURE,DM_AGRICULTURE,Harvest -US-Ne1,9630,GRP_DM_AGRICULTURE,DM_DATE,20061004 -US-Ne1,9630,GRP_DM_AGRICULTURE,DM_COMMENT,167 bu/ac 15.5% basis. 17.9% harvest MC. CaseIH 2366 combine. -US-Ne1,1961,GRP_DM_AGRICULTURE,DM_AGRICULTURE,Harvest -US-Ne1,1961,GRP_DM_AGRICULTURE,DM_DATE,20061005 -US-Ne1,1961,GRP_DM_AGRICULTURE,DM_COMMENT,167 bu/ac 15.5% basis. 17.9% harvest MC. CaseIH 2366 combine. -US-Ne1,7928,GRP_DM_AGRICULTURE,DM_AGRICULTURE,Harvest -US-Ne1,7928,GRP_DM_AGRICULTURE,DM_DATE,20071105 -US-Ne1,7928,GRP_DM_AGRICULTURE,DM_COMMENT,203.8 bu/ac 15.5% basis. -US-Ne1,2810,GRP_DM_AGRICULTURE,DM_AGRICULTURE,Harvest -US-Ne1,2810,GRP_DM_AGRICULTURE,DM_DATE,20071106 -US-Ne1,2810,GRP_DM_AGRICULTURE,DM_COMMENT,203.8 bu/ac 15.5% basis. -US-Ne1,4495,GRP_DM_FERT_M,DM_FERT_M,N -US-Ne1,4495,GRP_DM_FERT_M,DM_DATE,20010510 -US-Ne1,4495,GRP_DM_FERT_M,DM_COMMENT,"28% UAN 114 lb N/ac (127.68 kg N ha-1) North half ; 76 lb N/ac (85.12 kg N ha-1) South half, JD 4440/DMI 8 row Coulter" -US-Ne1,7057,GRP_DM_FERT_M,DM_FERT_M,N -US-Ne1,7057,GRP_DM_FERT_M,DM_DATE,20010618 -US-Ne1,7057,GRP_DM_FERT_M,DM_COMMENT,28% UAN 29.5 lb N/ac (33.04 kg N ha-1) with 0.17in water -US-Ne1,6217,GRP_DM_FERT_M,DM_FERT_M,N -US-Ne1,6217,GRP_DM_FERT_M,DM_DATE,20010702 -US-Ne1,6217,GRP_DM_FERT_M,DM_COMMENT,28%UAN 31.0 lb N/ac ( 34.72 kg N ha-1 ) with 0.17 in water ( 196 kg N ha-1) TOTAL N Applied for 2001 season) -US-Ne1,7901,GRP_DM_FERT_M,DM_FERT_M,N -US-Ne1,7901,GRP_DM_FERT_M,DM_DATE,20020416 -US-Ne1,7901,GRP_DM_FERT_M,DM_COMMENT,120lbs/ac (134.4 kg N ha-1 ) Nitrogen 28%UAN -US-Ne1,1105,GRP_DM_FERT_M,DM_FERT_M,N -US-Ne1,1105,GRP_DM_FERT_M,DM_DATE,20020418 -US-Ne1,1105,GRP_DM_FERT_M,DM_COMMENT,120lbs/ac (134.4 kg N ha-1 ) Nitrogen 28%UAN -US-Ne1,5355,GRP_DM_FERT_M,DM_FERT_M,N -US-Ne1,5355,GRP_DM_FERT_M,DM_DATE,20020425 -US-Ne1,5355,GRP_DM_FERT_M,DM_COMMENT,120lbs/ac (134.4 kg N ha-1 ) Nitrogen 28%UAN -US-Ne1,6206,GRP_DM_FERT_M,DM_FERT_M,N -US-Ne1,6206,GRP_DM_FERT_M,DM_DATE,20020614 -US-Ne1,6206,GRP_DM_FERT_M,DM_COMMENT,80 lb N/ac (89.6 kg N ha-1 ) to outside 32 (circular) rows not fertigated JD 4440/DMI 8 row Coulter -US-Ne1,7921,GRP_DM_FERT_M,DM_FERT_M,N -US-Ne1,7921,GRP_DM_FERT_M,DM_DATE,20020617 -US-Ne1,7921,GRP_DM_FERT_M,DM_COMMENT,40 lbs/acre ( 44.80 kg N ha-1 ) 28% UAN w/ .66 in water -US-Ne1,7042,GRP_DM_FERT_M,DM_FERT_M,N -US-Ne1,7042,GRP_DM_FERT_M,DM_DATE,20020702 -US-Ne1,7042,GRP_DM_FERT_M,DM_COMMENT,40.5 lbs N/acre ( 45.36 kg N ha-1 ) 28% UAN with 1.04 in. water -US-Ne1,8764,GRP_DM_FERT_M,DM_FERT_M,N -US-Ne1,8764,GRP_DM_FERT_M,DM_DATE,20030414 -US-Ne1,8764,GRP_DM_FERT_M,DM_COMMENT,119.2 lb N/ac ( 133.5 kg N ha-1 ) -US-Ne1,6207,GRP_DM_FERT_M,DM_FERT_M,N -US-Ne1,6207,GRP_DM_FERT_M,DM_DATE,20030415 -US-Ne1,6207,GRP_DM_FERT_M,DM_COMMENT,119.2 lb N/ac ( 133.5 kg N ha-1 ) -US-Ne1,5350,GRP_DM_FERT_M,DM_FERT_M,N -US-Ne1,5350,GRP_DM_FERT_M,DM_DATE,20030623 -US-Ne1,5350,GRP_DM_FERT_M,DM_COMMENT,40.6 lb N/ac ( 45.47 kg N ha-1 ) In 0.25 in. water -US-Ne1,9617,GRP_DM_FERT_M,DM_FERT_M,N -US-Ne1,9617,GRP_DM_FERT_M,DM_DATE,20030623 -US-Ne1,9617,GRP_DM_FERT_M,DM_COMMENT,50 lb N/ac ( 56 kg N ha-1 ) -US-Ne1,4471,GRP_DM_FERT_M,DM_FERT_M,N -US-Ne1,4471,GRP_DM_FERT_M,DM_DATE,20030624 -US-Ne1,4471,GRP_DM_FERT_M,DM_COMMENT,51 lb N/ac(57.12 kg N ha-1 ) -US-Ne1,1952,GRP_DM_FERT_M,DM_FERT_M,N -US-Ne1,1952,GRP_DM_FERT_M,DM_DATE,20030625 -US-Ne1,1952,GRP_DM_FERT_M,DM_COMMENT,52 lb N/ac ( 58.24 kg N ha-1 ) -US-Ne1,4472,GRP_DM_FERT_M,DM_FERT_M,N -US-Ne1,4472,GRP_DM_FERT_M,DM_DATE,20030710 -US-Ne1,4472,GRP_DM_FERT_M,DM_COMMENT,40.2 lbs N/acre ( 45.02 kg N ha-1 ) 28% UAN w/ .26 in water -US-Ne1,267,GRP_DM_FERT_M,DM_FERT_M,N -US-Ne1,267,GRP_DM_FERT_M,DM_DATE,20040427 -US-Ne1,267,GRP_DM_FERT_M,DM_COMMENT,142 lb N/ac ( 159.04 kg N ha-1 ) -US-Ne1,1096,GRP_DM_FERT_M,DM_FERT_M,N -US-Ne1,1096,GRP_DM_FERT_M,DM_DATE,20040623 -US-Ne1,1096,GRP_DM_FERT_M,DM_COMMENT,60 lb N/ac ( 67.2 kg N ha-1 ) 32%UAN -US-Ne1,2797,GRP_DM_FERT_M,DM_FERT_M,N -US-Ne1,2797,GRP_DM_FERT_M,DM_DATE,20040628 -US-Ne1,2797,GRP_DM_FERT_M,DM_COMMENT,30.0 lbs N/ac ( 33.6 kg N ha-1 ) 32%UAN with .67 in water. -US-Ne1,6193,GRP_DM_FERT_M,DM_FERT_M,N -US-Ne1,6193,GRP_DM_FERT_M,DM_DATE,20040712 -US-Ne1,6193,GRP_DM_FERT_M,DM_COMMENT,30 lbs N/ac ( 33.6 kg N ha-1 ) 32%UAN.with .66 in water -US-Ne1,9631,GRP_DM_FERT_M,DM_FERT_M,N -US-Ne1,9631,GRP_DM_FERT_M,DM_DATE,20050502 -US-Ne1,9631,GRP_DM_FERT_M,DM_COMMENT,32% UAN 160 lbsN /ac (179.2 kg N ha-1 ) -US-Ne1,289,GRP_DM_FERT_M,DM_FERT_M,N -US-Ne1,289,GRP_DM_FERT_M,DM_DATE,20050503 -US-Ne1,289,GRP_DM_FERT_M,DM_COMMENT,32% UAN 160 lbsN /ac (179.2 kg N ha-1 ) -US-Ne1,290,GRP_DM_FERT_M,DM_FERT_M,N -US-Ne1,290,GRP_DM_FERT_M,DM_DATE,20050614 -US-Ne1,290,GRP_DM_FERT_M,DM_COMMENT,Nitrogen. 32% UAN 60 lbsN /ac ( 67.2 kg N ha-1 ) -US-Ne1,7926,GRP_DM_FERT_M,DM_FERT_M,N -US-Ne1,7926,GRP_DM_FERT_M,DM_DATE,20050615 -US-Ne1,7926,GRP_DM_FERT_M,DM_COMMENT,Nitrogen. 32% UAN 60 lbsN /ac ( 67.2 kg N ha-1 ) -US-Ne1,7023,GRP_DM_FERT_M,DM_FERT_M,N -US-Ne1,7023,GRP_DM_FERT_M,DM_DATE,20050616 -US-Ne1,7023,GRP_DM_FERT_M,DM_COMMENT,Nitrogen. 32% UAN 60 lbsN /ac ( 67.2 kg N ha-1 ) -US-Ne1,8746,GRP_DM_FERT_M,DM_FERT_M,N -US-Ne1,8746,GRP_DM_FERT_M,DM_DATE,20050617 -US-Ne1,8746,GRP_DM_FERT_M,DM_COMMENT,Nitrogen. 32% UAN 60 lbsN /ac ( 67.2 kg N ha-1 ) -US-Ne1,6196,GRP_DM_FERT_M,DM_FERT_M,N -US-Ne1,6196,GRP_DM_FERT_M,DM_DATE,20060505 -US-Ne1,6196,GRP_DM_FERT_M,DM_COMMENT,N 121 lb/ac 32%UAN. -US-Ne1,7043,GRP_DM_FERT_M,DM_FERT_M,N -US-Ne1,7043,GRP_DM_FERT_M,DM_DATE,20060612 -US-Ne1,7043,GRP_DM_FERT_M,DM_COMMENT,35 lb N/ac 32% UAN 0.65 in water using endgun -US-Ne1,283,GRP_DM_FERT_M,DM_FERT_M,N -US-Ne1,283,GRP_DM_FERT_M,DM_DATE,20060701 -US-Ne1,283,GRP_DM_FERT_M,DM_COMMENT,31.5 lb N/ac 31% UAN 0.24 in water using endgun -US-Ne1,4487,GRP_DM_FERT_M,DM_FERT_M,N -US-Ne1,4487,GRP_DM_FERT_M,DM_DATE,20061101 -US-Ne1,4487,GRP_DM_FERT_M,DM_COMMENT,Spray 32% UAN. North half 56 ac. 43#N. -US-Ne1,7046,GRP_DM_FERT_M,DM_FERT_M,N -US-Ne1,7046,GRP_DM_FERT_M,DM_DATE,20070502 -US-Ne1,7046,GRP_DM_FERT_M,DM_COMMENT,101 lb N/ac 32%UAN -US-Ne1,6209,GRP_DM_FERT_M,DM_FERT_M,N -US-Ne1,6209,GRP_DM_FERT_M,DM_DATE,20070608 -US-Ne1,6209,GRP_DM_FERT_M,DM_COMMENT,"30 lb N/ac, 32%UAN 0.36 in water." -US-Ne1,8766,GRP_DM_FERT_M,DM_FERT_M,N -US-Ne1,8766,GRP_DM_FERT_M,DM_DATE,20070625 -US-Ne1,8766,GRP_DM_FERT_M,DM_COMMENT,"31.9 lb N/ac N 32#UAN, 0.36 in water." -US-Ne1,9632,GRP_DM_FERT_M,DM_FERT_M,N -US-Ne1,9632,GRP_DM_FERT_M,DM_DATE,20071113 -US-Ne1,9632,GRP_DM_FERT_M,DM_COMMENT,"32% UAN, 40 lb/ac" -US-Ne1,4492,GRP_DM_FERT_M,DM_FERT_M,N -US-Ne1,4492,GRP_DM_FERT_M,DM_DATE,20071114 -US-Ne1,4492,GRP_DM_FERT_M,DM_COMMENT,32% UAN.40 lb N/ac -US-Ne1,3659,GRP_DM_FERT_M,DM_FERT_M,N -US-Ne1,3659,GRP_DM_FERT_M,DM_DATE,20071115 -US-Ne1,3659,GRP_DM_FERT_M,DM_COMMENT,Apply 32% UAN. 21 ac. 40 lb N/ac -US-Ne1,1115,GRP_DM_PESTICIDE,DM_PESTICIDE,Other -US-Ne1,1115,GRP_DM_PESTICIDE,DM_DATE,20010510 -US-Ne1,1115,GRP_DM_PESTICIDE,DM_COMMENT,"Axiom 15oz/ac, Atrazine 1 lb/ac, Balance PRO .75oz/ac" -US-Ne1,5367,GRP_DM_PESTICIDE,DM_PESTICIDE,Other -US-Ne1,5367,GRP_DM_PESTICIDE,DM_DATE,20010616 -US-Ne1,5367,GRP_DM_PESTICIDE,DM_COMMENT,"Calisto (mesotrine) 3oz/ac., Atrazine 0.5 lb/ac, COC 0.1 gal/ac., AMS 0.9 lb/ac" -US-Ne1,6205,GRP_DM_PESTICIDE,DM_PESTICIDE,Other -US-Ne1,6205,GRP_DM_PESTICIDE,DM_DATE,20020510 -US-Ne1,6205,GRP_DM_PESTICIDE,DM_COMMENT,"BicepII Mag 2.1 qt/ac, Hornet 3 oz/ac pre-emergent" -US-Ne1,280,GRP_DM_PESTICIDE,DM_PESTICIDE,Other -US-Ne1,280,GRP_DM_PESTICIDE,DM_DATE,20020720 -US-Ne1,280,GRP_DM_PESTICIDE,DM_COMMENT,mustang-3.9 oz/ac with 0.20 in water -US-Ne1,8745,GRP_DM_PESTICIDE,DM_PESTICIDE,Other -US-Ne1,8745,GRP_DM_PESTICIDE,DM_DATE,20030515 -US-Ne1,8745,GRP_DM_PESTICIDE,DM_COMMENT,"pre-emergent BicepII Mag 2.1 qt/ac, Hornet 3 oz/ac" -US-Ne1,7903,GRP_DM_PESTICIDE,DM_PESTICIDE,Other -US-Ne1,7903,GRP_DM_PESTICIDE,DM_DATE,20030627 -US-Ne1,2795,GRP_DM_PESTICIDE,DM_PESTICIDE,Other -US-Ne1,2795,GRP_DM_PESTICIDE,DM_DATE,20030718 -US-Ne1,4474,GRP_DM_PESTICIDE,DM_PESTICIDE,Other -US-Ne1,4474,GRP_DM_PESTICIDE,DM_DATE,20030801 -US-Ne1,4474,GRP_DM_PESTICIDE,DM_COMMENT,Baythoid2 1.6oz/ac. 0.14 in water -US-Ne1,268,GRP_DM_PESTICIDE,DM_PESTICIDE,Other -US-Ne1,268,GRP_DM_PESTICIDE,DM_DATE,20040506 -US-Ne1,268,GRP_DM_PESTICIDE,DM_COMMENT,"HarnessXtra5.6L (2.3qt/ac), HornetWDG(3oz/ac), 2,4D4L(.5pt/ac) pre-emergent" -US-Ne1,6211,GRP_DM_PESTICIDE,DM_PESTICIDE,Other -US-Ne1,6211,GRP_DM_PESTICIDE,DM_DATE,20040803 -US-Ne1,6211,GRP_DM_PESTICIDE,DM_COMMENT,Tilt fungicide 4oz/ac .15 in -US-Ne1,7047,GRP_DM_PESTICIDE,DM_PESTICIDE,Other -US-Ne1,7047,GRP_DM_PESTICIDE,DM_DATE,20050506 -US-Ne1,7047,GRP_DM_PESTICIDE,DM_COMMENT,"Herbicide(pre-emergent) Keystone 2.6 qt/ac, Hornet 3.0 oz/ac 2,4D 4LV 0.5pt/ac, COC 1.0pt/ac" -US-Ne1,4490,GRP_DM_PESTICIDE,DM_PESTICIDE,Other -US-Ne1,4490,GRP_DM_PESTICIDE,DM_DATE,20050616 -US-Ne1,4490,GRP_DM_PESTICIDE,DM_COMMENT,"Steadfast 0.75oz/ac, Callisto 2oz/ac, Atrazine 0.5pt/ac, COC/AMS 2lb/ac" -US-Ne1,265,GRP_DM_PESTICIDE,DM_PESTICIDE,Other -US-Ne1,265,GRP_DM_PESTICIDE,DM_DATE,20060505 -US-Ne1,265,GRP_DM_PESTICIDE,DM_COMMENT,"CinchATZ 2.1 qt, Glyphosate 32oz+2,4D 4LV 0.5 pt" -US-Ne1,3649,GRP_DM_PESTICIDE,DM_PESTICIDE,Other -US-Ne1,3649,GRP_DM_PESTICIDE,DM_DATE,20060605 -US-Ne1,3649,GRP_DM_PESTICIDE,DM_COMMENT,"Liberty 32 oz + Callisto 1 oz,AMS 3lbs" -US-Ne1,5362,GRP_DM_PESTICIDE,DM_PESTICIDE,Other -US-Ne1,5362,GRP_DM_PESTICIDE,DM_DATE,20070502 -US-Ne1,5362,GRP_DM_PESTICIDE,DM_COMMENT,"Keystone 2.6 qt, 2-4D 0.5pt, Glyphosate 1 pt w/UAN" -US-Ne1,286,GRP_DM_PESTICIDE,DM_PESTICIDE,Other -US-Ne1,286,GRP_DM_PESTICIDE,DM_DATE,20070612 -US-Ne1,286,GRP_DM_PESTICIDE,DM_COMMENT,"GlystarPlus (glyphosate) 2.5 pt, AMS 2 lb" -US-Ne1,6212,GRP_DM_PESTICIDE,DM_PESTICIDE,Other -US-Ne1,6212,GRP_DM_PESTICIDE,DM_DATE,20070722 -US-Ne1,6212,GRP_DM_PESTICIDE,DM_COMMENT,"Stratego 10oz, NIS 32oz." -US-Ne1,8776,GRP_DM_PLANTING,DM_PLANTING,Sowing crop seeds -US-Ne1,8776,GRP_DM_PLANTING,DM_DATE,20010510 -US-Ne1,8776,GRP_DM_PLANTING,DM_COMMENT,"maize Pioneer 33P67 BT, 33P66 non-BT (refuge), 36,000 seeds/acre ( 82,000 pl ha-1 )" -US-Ne1,5356,GRP_DM_PLANTING,DM_PLANTING,Sowing crop seeds -US-Ne1,5356,GRP_DM_PLANTING,DM_DATE,20020510 -US-Ne1,5356,GRP_DM_PLANTING,DM_COMMENT,"maize Pioneer 33P67 BT, 33P66 non-BT; maize Pioneer 33P67 BT, 33P66 non-BT" -US-Ne1,6208,GRP_DM_PLANTING,DM_PLANTING,Sowing crop seeds -US-Ne1,6208,GRP_DM_PLANTING,DM_DATE,20030415 -US-Ne1,282,GRP_DM_PLANTING,DM_PLANTING,Sowing crop seeds -US-Ne1,282,GRP_DM_PLANTING,DM_DATE,20030515 -US-Ne1,282,GRP_DM_PLANTING,DM_COMMENT,"Maize Pioneer 33B51 BT; 34,000 pl/ac (77,000 pl ha-1 )starter fertilizer and Aztec 2.1G" -US-Ne1,9616,GRP_DM_PLANTING,DM_PLANTING,Sowing crop seeds -US-Ne1,9616,GRP_DM_PLANTING,DM_DATE,20030620 -US-Ne1,9616,GRP_DM_PLANTING,DM_COMMENT,"Maize Pioneer 33B51 BT; 34,000 pl/ac (77,000 pl ha-1 )starter fertilizer and Aztec 2.1G" -US-Ne1,7028,GRP_DM_PLANTING,DM_PLANTING,Sowing crop seeds -US-Ne1,7028,GRP_DM_PLANTING,DM_DATE,20040503 -US-Ne1,7028,GRP_DM_PLANTING,DM_COMMENT,"maize Pioneer 33B51 BT; 34,000 pl/ac, ( 84,012 pl ha-1 )starter fertilizer and Poncho1250 seed treatment" -US-Ne1,8767,GRP_DM_PLANTING,DM_PLANTING,Sowing crop seeds -US-Ne1,8767,GRP_DM_PLANTING,DM_DATE,20040504 -US-Ne1,8767,GRP_DM_PLANTING,DM_COMMENT,"maize Pioneer 33B51 BT; 34,000 pl/ac, ( 84,012 pl ha-1 )starter fertilizer and Poncho1250 seed treatment" -US-Ne1,2806,GRP_DM_PLANTING,DM_PLANTING,Sowing crop seeds -US-Ne1,2806,GRP_DM_PLANTING,DM_DATE,20040505 -US-Ne1,2806,GRP_DM_PLANTING,DM_COMMENT,"maize Pioneer 33B51 BT; 34,000 pl/ac, ( 84,012 pl ha-1 )starter fertilizer and Poncho1250 seed treatment" -US-Ne1,3658,GRP_DM_PLANTING,DM_PLANTING,Sowing crop seeds -US-Ne1,3658,GRP_DM_PLANTING,DM_DATE,20050504 -US-Ne1,3658,GRP_DM_PLANTING,DM_COMMENT,"maize DeKalb 63-75 CRW/BT Poncho 250 treated corn 33,337 seeds/ac ( 82,374 pl ha-1 ), Starter fertilizer 10-34-0 5 gal/ac; 33,337 seeds/ac ( 82,374 pl ha-1 ), Poncho 250 treated,Starter fertilizer 10-34-0 5 gal/ac" -US-Ne1,8768,GRP_DM_PLANTING,DM_PLANTING,Sowing crop seeds -US-Ne1,8768,GRP_DM_PLANTING,DM_DATE,20050505 -US-Ne1,8768,GRP_DM_PLANTING,DM_COMMENT,"maize DeKalb 63-75 CRW/BT Poncho 250 treated corn 33,337 seeds/ac ( 82,374 pl ha-1 ), Starter fertilizer 10-34-0 5 gal/ac; 33,337 seeds/ac ( 82,374 pl ha-1 ), Poncho 250 treated,Starter fertilizer 10-34-0 5 gal/ac" -US-Ne1,7026,GRP_DM_PLANTING,DM_PLANTING,Sowing crop seeds -US-Ne1,7026,GRP_DM_PLANTING,DM_DATE,20060504 -US-Ne1,7026,GRP_DM_PLANTING,DM_COMMENT,"Maize Pioneer 33B53 CRW 113 CRM 2700 GDD. 33,124 seeds/ac ( 84,012 pl ha-1 ) 34,000 Target JD7820 RTK auto steer/ JD1770 16row planter new established rows" -US-Ne1,4486,GRP_DM_PLANTING,DM_PLANTING,Sowing crop seeds -US-Ne1,4486,GRP_DM_PLANTING,DM_DATE,20060505 -US-Ne1,4486,GRP_DM_PLANTING,DM_COMMENT,"Maize Pioneer 33B53 CRW 113 CRM 2700 GDD. 33,124 seeds/ac ( 84,012 pl ha-1 ) 34,000 Target JD7820 RTK auto steer/ JD1770 16row planter new established rows" -US-Ne1,285,GRP_DM_PLANTING,DM_PLANTING,Sowing crop seeds -US-Ne1,285,GRP_DM_PLANTING,DM_DATE,20070501 -US-Ne1,285,GRP_DM_PLANTING,DM_COMMENT,"31,817 seed rate Pioneer 31N30 HX CRW RR2 Poncho250." -US-Ne1,4488,GRP_DM_PLANTING,DM_PLANTING,Sowing crop seeds -US-Ne1,4488,GRP_DM_PLANTING,DM_DATE,20070518 -US-Ne1,4488,GRP_DM_PLANTING,DM_COMMENT,"Pioneer 33N12 and DeKalb 715: 28,000 seeds per acre rate" -US-Ne1,6216,GRP_DM_TILL,DM_TILL,Conventional -US-Ne1,6216,GRP_DM_TILL,DM_DATE,20010418 -US-Ne1,6216,GRP_DM_TILL,DM_COMMENT,field-disk -US-Ne1,8775,GRP_DM_TILL,DM_TILL,Conventional -US-Ne1,8775,GRP_DM_TILL,DM_DATE,20010419 -US-Ne1,8775,GRP_DM_TILL,DM_COMMENT,field-disk -US-Ne1,1114,GRP_DM_TILL,DM_TILL,Conventional -US-Ne1,1114,GRP_DM_TILL,DM_DATE,20010509 -US-Ne1,1114,GRP_DM_TILL,DM_COMMENT,field-cultivator -US-Ne1,294,GRP_DM_TILL,DM_TILL,Other -US-Ne1,294,GRP_DM_TILL,DM_DATE,20011107 -US-Ne1,294,GRP_DM_TILL,DM_COMMENT,subsoiler -US-Ne1,2814,GRP_DM_TILL,DM_TILL,Other -US-Ne1,2814,GRP_DM_TILL,DM_DATE,20011108 -US-Ne1,2814,GRP_DM_TILL,DM_COMMENT,stalk-shredder -US-Ne1,7933,GRP_DM_TILL,DM_TILL,Other -US-Ne1,7933,GRP_DM_TILL,DM_DATE,20011109 -US-Ne1,7933,GRP_DM_TILL,DM_COMMENT,stalk-shredder -US-Ne1,7059,GRP_DM_TILL,DM_TILL,Other -US-Ne1,7059,GRP_DM_TILL,DM_DATE,20011112 -US-Ne1,7059,GRP_DM_TILL,DM_COMMENT,stalk-shredder -US-Ne1,5358,GRP_DM_TILL,DM_TILL,Other -US-Ne1,5358,GRP_DM_TILL,DM_DATE,20021113 -US-Ne1,5358,GRP_DM_TILL,DM_COMMENT,track_fil -US-Ne1,7027,GRP_DM_TILL,DM_TILL,Other -US-Ne1,7027,GRP_DM_TILL,DM_DATE,20030518 -US-Ne1,2796,GRP_DM_TILL,DM_TILL,Stripe till -US-Ne1,2796,GRP_DM_TILL,DM_DATE,20040504 -US-Ne1,8749,GRP_DM_TILL,DM_TILL,Conventional -US-Ne1,8749,GRP_DM_TILL,DM_DATE,20051026 -US-Ne1,8749,GRP_DM_TILL,DM_COMMENT,mini-moldboard plow -US-Ne1,4470,GRP_DM_TILL,DM_TILL,Other -US-Ne1,4470,GRP_DM_TILL,DM_DATE,20060127 -US-Ne1,4470,GRP_DM_TILL,DM_COMMENT,grade -US-Ne1,6195,GRP_DM_TILL,DM_TILL,Other -US-Ne1,6195,GRP_DM_TILL,DM_DATE,20060306 -US-Ne1,6195,GRP_DM_TILL,DM_COMMENT,grade -US-Ne1,8750,GRP_DM_TILL,DM_TILL,Other -US-Ne1,8750,GRP_DM_TILL,DM_DATE,20060307 -US-Ne1,8750,GRP_DM_TILL,DM_COMMENT,grade -US-Ne1,5361,GRP_DM_TILL,DM_TILL,Conventional -US-Ne1,5361,GRP_DM_TILL,DM_DATE,20061101 -US-Ne1,5361,GRP_DM_TILL,DM_COMMENT,mini-moldboard plow -US-Ne1,7045,GRP_DM_TILL,DM_TILL,Conventional -US-Ne1,7045,GRP_DM_TILL,DM_DATE,20061102 -US-Ne1,7045,GRP_DM_TILL,DM_COMMENT,mini-moldboard plow -US-Ne1,8765,GRP_DM_TILL,DM_TILL,Conventional -US-Ne1,8765,GRP_DM_TILL,DM_DATE,20061103 -US-Ne1,8765,GRP_DM_TILL,DM_COMMENT,mini-moldboard plow -US-Ne1,5365,GRP_DM_TILL,DM_TILL,Conventional -US-Ne1,5365,GRP_DM_TILL,DM_DATE,20071113 -US-Ne1,5365,GRP_DM_TILL,DM_COMMENT,mini-moldboard plow -US-Ne1,7051,GRP_DM_TILL,DM_TILL,Conventional -US-Ne1,7051,GRP_DM_TILL,DM_DATE,20071114 -US-Ne1,7051,GRP_DM_TILL,DM_COMMENT,mini-moldboard plow -US-Ne1,8777,GRP_DM_WATER,DM_WATER,Irrigation -US-Ne1,8777,GRP_DM_WATER,DM_DATE,20010625 -US-Ne1,8777,GRP_DM_WATER,DM_COMMENT,CW rotation -US-Ne1,1116,GRP_DM_WATER,DM_WATER,Irrigation -US-Ne1,1116,GRP_DM_WATER,DM_DATE,20010629 -US-Ne1,1116,GRP_DM_WATER,DM_COMMENT,61 Hrs CW rotation -US-Ne1,9637,GRP_DM_WATER,DM_WATER,Irrigation -US-Ne1,9637,GRP_DM_WATER,DM_DATE,20010704 -US-Ne1,9637,GRP_DM_WATER,DM_COMMENT,86.8hr CW rotation -US-Ne1,4496,GRP_DM_WATER,DM_WATER,Irrigation -US-Ne1,4496,GRP_DM_WATER,DM_DATE,20010708 -US-Ne1,4496,GRP_DM_WATER,DM_COMMENT,"3504kw, 86.9 hrs/rev" -US-Ne1,3663,GRP_DM_WATER,DM_WATER,Irrigation -US-Ne1,3663,GRP_DM_WATER,DM_DATE,20010713 -US-Ne1,3663,GRP_DM_WATER,DM_COMMENT,"86.9 hr CW rotation, 3504 kWh" -US-Ne1,6218,GRP_DM_WATER,DM_WATER,Irrigation -US-Ne1,6218,GRP_DM_WATER,DM_DATE,20010718 -US-Ne1,6218,GRP_DM_WATER,DM_COMMENT,"3552 kWh, 86.9 hr CW rotation" -US-Ne1,1967,GRP_DM_WATER,DM_WATER,Irrigation -US-Ne1,1967,GRP_DM_WATER,DM_DATE,20010722 -US-Ne1,1967,GRP_DM_WATER,DM_COMMENT,3744 kWh CW -US-Ne1,3664,GRP_DM_WATER,DM_WATER,Irrigation -US-Ne1,3664,GRP_DM_WATER,DM_DATE,20010729 -US-Ne1,3664,GRP_DM_WATER,DM_COMMENT,"3552 Kwh, 89.3 hrs CW rotation" -US-Ne1,2813,GRP_DM_WATER,DM_WATER,Irrigation -US-Ne1,2813,GRP_DM_WATER,DM_DATE,20010803 -US-Ne1,2813,GRP_DM_WATER,DM_COMMENT,"3648kWhr, 89.4 hr CW rotation" -US-Ne1,5368,GRP_DM_WATER,DM_WATER,Irrigation -US-Ne1,5368,GRP_DM_WATER,DM_DATE,20010807 -US-Ne1,5368,GRP_DM_WATER,DM_COMMENT,"3648kWhr, 89.2 hr CW rotation" -US-Ne1,4497,GRP_DM_WATER,DM_WATER,Irrigation -US-Ne1,4497,GRP_DM_WATER,DM_DATE,20010814 -US-Ne1,9638,GRP_DM_WATER,DM_WATER,Irrigation -US-Ne1,9638,GRP_DM_WATER,DM_DATE,20011001 -US-Ne1,4483,GRP_DM_WATER,DM_WATER,Irrigation -US-Ne1,4483,GRP_DM_WATER,DM_DATE,20020521 -US-Ne1,4484,GRP_DM_WATER,DM_WATER,Irrigation -US-Ne1,4484,GRP_DM_WATER,DM_DATE,20020625 -US-Ne1,3657,GRP_DM_WATER,DM_WATER,Irrigation -US-Ne1,3657,GRP_DM_WATER,DM_DATE,20020628 -US-Ne1,5357,GRP_DM_WATER,DM_WATER,Irrigation -US-Ne1,5357,GRP_DM_WATER,DM_DATE,20020711 -US-Ne1,279,GRP_DM_WATER,DM_WATER,Irrigation -US-Ne1,279,GRP_DM_WATER,DM_DATE,20020715 -US-Ne1,1958,GRP_DM_WATER,DM_WATER,Irrigation -US-Ne1,1958,GRP_DM_WATER,DM_DATE,20020721 -US-Ne1,1106,GRP_DM_WATER,DM_WATER,Irrigation -US-Ne1,1106,GRP_DM_WATER,DM_DATE,20020725 -US-Ne1,2804,GRP_DM_WATER,DM_WATER,Irrigation -US-Ne1,2804,GRP_DM_WATER,DM_DATE,20020731 -US-Ne1,1959,GRP_DM_WATER,DM_WATER,Irrigation -US-Ne1,1959,GRP_DM_WATER,DM_DATE,20020807 -US-Ne1,7922,GRP_DM_WATER,DM_WATER,Irrigation -US-Ne1,7922,GRP_DM_WATER,DM_DATE,20020811 -US-Ne1,266,GRP_DM_WATER,DM_WATER,Irrigation -US-Ne1,266,GRP_DM_WATER,DM_DATE,20030528 -US-Ne1,2793,GRP_DM_WATER,DM_WATER,Irrigation -US-Ne1,2793,GRP_DM_WATER,DM_DATE,20030703 -US-Ne1,4473,GRP_DM_WATER,DM_WATER,Irrigation -US-Ne1,4473,GRP_DM_WATER,DM_DATE,20030712 -US-Ne1,2794,GRP_DM_WATER,DM_WATER,Irrigation -US-Ne1,2794,GRP_DM_WATER,DM_DATE,20030715 -US-Ne1,7904,GRP_DM_WATER,DM_WATER,Irrigation -US-Ne1,7904,GRP_DM_WATER,DM_DATE,20030719 -US-Ne1,3647,GRP_DM_WATER,DM_WATER,Irrigation -US-Ne1,3647,GRP_DM_WATER,DM_DATE,20030724 -US-Ne1,8751,GRP_DM_WATER,DM_WATER,Irrigation -US-Ne1,8751,GRP_DM_WATER,DM_DATE,20030727 -US-Ne1,9618,GRP_DM_WATER,DM_WATER,Irrigation -US-Ne1,9618,GRP_DM_WATER,DM_DATE,20030807 -US-Ne1,1095,GRP_DM_WATER,DM_WATER,Irrigation -US-Ne1,1095,GRP_DM_WATER,DM_DATE,20030811 -US-Ne1,3648,GRP_DM_WATER,DM_WATER,Irrigation -US-Ne1,3648,GRP_DM_WATER,DM_DATE,20030818 -US-Ne1,5363,GRP_DM_WATER,DM_WATER,Irrigation -US-Ne1,5363,GRP_DM_WATER,DM_DATE,20040719 -US-Ne1,287,GRP_DM_WATER,DM_WATER,Irrigation -US-Ne1,287,GRP_DM_WATER,DM_DATE,20040724 -US-Ne1,6210,GRP_DM_WATER,DM_WATER,Irrigation -US-Ne1,6210,GRP_DM_WATER,DM_DATE,20040730 -US-Ne1,6210,GRP_DM_WATER,DM_COMMENT,91 hr -US-Ne1,7905,GRP_DM_WATER,DM_WATER,Irrigation -US-Ne1,7905,GRP_DM_WATER,DM_DATE,20040801 -US-Ne1,4489,GRP_DM_WATER,DM_WATER,Irrigation -US-Ne1,4489,GRP_DM_WATER,DM_DATE,20040806 -US-Ne1,2807,GRP_DM_WATER,DM_WATER,Irrigation -US-Ne1,2807,GRP_DM_WATER,DM_DATE,20040816 -US-Ne1,1963,GRP_DM_WATER,DM_WATER,Irrigation -US-Ne1,1963,GRP_DM_WATER,DM_DATE,20040823 -US-Ne1,7925,GRP_DM_WATER,DM_WATER,Irrigation -US-Ne1,7925,GRP_DM_WATER,DM_DATE,20040909 -US-Ne1,8769,GRP_DM_WATER,DM_WATER,Irrigation -US-Ne1,8769,GRP_DM_WATER,DM_DATE,20050509 -US-Ne1,7024,GRP_DM_WATER,DM_WATER,Irrigation -US-Ne1,7024,GRP_DM_WATER,DM_DATE,20050624 -US-Ne1,2792,GRP_DM_WATER,DM_WATER,Irrigation -US-Ne1,2792,GRP_DM_WATER,DM_DATE,20050625 -US-Ne1,1949,GRP_DM_WATER,DM_WATER,Irrigation -US-Ne1,1949,GRP_DM_WATER,DM_DATE,20050629 -US-Ne1,4468,GRP_DM_WATER,DM_WATER,Irrigation -US-Ne1,4468,GRP_DM_WATER,DM_DATE,20050705 -US-Ne1,9615,GRP_DM_WATER,DM_WATER,Irrigation -US-Ne1,9615,GRP_DM_WATER,DM_DATE,20050709 -US-Ne1,8747,GRP_DM_WATER,DM_WATER,Irrigation -US-Ne1,8747,GRP_DM_WATER,DM_DATE,20050715 -US-Ne1,4469,GRP_DM_WATER,DM_WATER,Irrigation -US-Ne1,4469,GRP_DM_WATER,DM_DATE,20050720 -US-Ne1,7025,GRP_DM_WATER,DM_WATER,Irrigation -US-Ne1,7025,GRP_DM_WATER,DM_DATE,20050723 -US-Ne1,8748,GRP_DM_WATER,DM_WATER,Irrigation -US-Ne1,8748,GRP_DM_WATER,DM_DATE,20050803 -US-Ne1,7902,GRP_DM_WATER,DM_WATER,Irrigation -US-Ne1,7902,GRP_DM_WATER,DM_DATE,20050816 -US-Ne1,263,GRP_DM_WATER,DM_WATER,Irrigation -US-Ne1,263,GRP_DM_WATER,DM_DATE,20050826 -US-Ne1,1951,GRP_DM_WATER,DM_WATER,Irrigation -US-Ne1,1951,GRP_DM_WATER,DM_DATE,20060506 -US-Ne1,1951,GRP_DM_WATER,DM_COMMENT,Apply 0.31 in to incorporate fertilizer and herbicide. 38hr CW. -US-Ne1,5359,GRP_DM_WATER,DM_WATER,Irrigation -US-Ne1,5359,GRP_DM_WATER,DM_DATE,20060620 -US-Ne1,7923,GRP_DM_WATER,DM_WATER,Irrigation -US-Ne1,7923,GRP_DM_WATER,DM_DATE,20060627 -US-Ne1,5360,GRP_DM_WATER,DM_WATER,Irrigation -US-Ne1,5360,GRP_DM_WATER,DM_DATE,20060702 -US-Ne1,5360,GRP_DM_WATER,DM_COMMENT,93.0 hr CW from 270. -US-Ne1,1107,GRP_DM_WATER,DM_WATER,Irrigation -US-Ne1,1107,GRP_DM_WATER,DM_DATE,20060706 -US-Ne1,7044,GRP_DM_WATER,DM_WATER,Irrigation -US-Ne1,7044,GRP_DM_WATER,DM_DATE,20060710 -US-Ne1,9629,GRP_DM_WATER,DM_WATER,Irrigation -US-Ne1,9629,GRP_DM_WATER,DM_DATE,20060717 -US-Ne1,7924,GRP_DM_WATER,DM_WATER,Irrigation -US-Ne1,7924,GRP_DM_WATER,DM_DATE,20060720 -US-Ne1,284,GRP_DM_WATER,DM_WATER,Irrigation -US-Ne1,284,GRP_DM_WATER,DM_DATE,20060728 -US-Ne1,2805,GRP_DM_WATER,DM_WATER,Irrigation -US-Ne1,2805,GRP_DM_WATER,DM_DATE,20060801 -US-Ne1,1962,GRP_DM_WATER,DM_WATER,Irrigation -US-Ne1,1962,GRP_DM_WATER,DM_DATE,20070502 -US-Ne1,7927,GRP_DM_WATER,DM_WATER,Irrigation -US-Ne1,7927,GRP_DM_WATER,DM_DATE,20070627 -US-Ne1,7048,GRP_DM_WATER,DM_WATER,Irrigation -US-Ne1,7048,GRP_DM_WATER,DM_DATE,20070702 -US-Ne1,5364,GRP_DM_WATER,DM_WATER,Irrigation -US-Ne1,5364,GRP_DM_WATER,DM_DATE,20070706 -US-Ne1,4491,GRP_DM_WATER,DM_WATER,Irrigation -US-Ne1,4491,GRP_DM_WATER,DM_DATE,20070712 -US-Ne1,7049,GRP_DM_WATER,DM_WATER,Irrigation -US-Ne1,7049,GRP_DM_WATER,DM_DATE,20070717 -US-Ne1,1109,GRP_DM_WATER,DM_WATER,Irrigation -US-Ne1,1109,GRP_DM_WATER,DM_DATE,20070722 -US-Ne1,7050,GRP_DM_WATER,DM_WATER,Irrigation -US-Ne1,7050,GRP_DM_WATER,DM_DATE,20070728 -US-Ne1,2809,GRP_DM_WATER,DM_WATER,Irrigation -US-Ne1,2809,GRP_DM_WATER,DM_DATE,20070729 -US-Ne1,1964,GRP_DM_WATER,DM_WATER,Irrigation -US-Ne1,1964,GRP_DM_WATER,DM_DATE,20070802 -US-Ne1,291,GRP_DM_WATER,DM_WATER,Irrigation -US-Ne1,291,GRP_DM_WATER,DM_DATE,20070831 -US-Ne1,15714,GRP_DOI,DOI,10.17190/AMF/1246084 -US-Ne1,15714,GRP_DOI,DOI_CITATION,"Andy Suyker (2022), AmeriFlux BASE US-Ne1 Mead - irrigated continuous maize site, Ver. 12-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1246084" -US-Ne1,15714,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-Ne1,32141,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Ne1,32141,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Andy Suyker -US-Ne1,32141,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Ne1,32141,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,asuyker1@unl.edu -US-Ne1,32141,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of Nebraska - Lincoln -US-Ne1,32143,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,University of Nebraska - Lincoln -US-Ne1,32143,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-Ne1,32142,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,DOE (OBER & EPSCoR) -US-Ne1,32142,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-Ne1,2517,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Agriculture -US-Ne1,2119,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Ne1,2119,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-Ne1,2119,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,2001 -US-Ne1,2119,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Ne1,23000403,GRP_HEADER,SITE_NAME,Mead - irrigated continuous maize site -US-Ne1,88653,GRP_HEIGHTC,HEIGHTC,0.000 -US-Ne1,88653,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne1,88653,GRP_HEIGHTC,HEIGHTC_DATE,20010516 -US-Ne1,88654,GRP_HEIGHTC,HEIGHTC,0.168 -US-Ne1,88654,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne1,88654,GRP_HEIGHTC,HEIGHTC_DATE,20010529 -US-Ne1,88655,GRP_HEIGHTC,HEIGHTC,0.520 -US-Ne1,88655,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne1,88655,GRP_HEIGHTC,HEIGHTC_DATE,20010613 -US-Ne1,88656,GRP_HEIGHTC,HEIGHTC,0.882 -US-Ne1,88656,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne1,88656,GRP_HEIGHTC,HEIGHTC_DATE,20010621 -US-Ne1,88657,GRP_HEIGHTC,HEIGHTC,1.208 -US-Ne1,88657,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne1,88657,GRP_HEIGHTC,HEIGHTC_DATE,20010629 -US-Ne1,88658,GRP_HEIGHTC,HEIGHTC,1.870 -US-Ne1,88658,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne1,88658,GRP_HEIGHTC,HEIGHTC_DATE,20010705 -US-Ne1,88659,GRP_HEIGHTC,HEIGHTC,2.548 -US-Ne1,88659,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne1,88659,GRP_HEIGHTC,HEIGHTC_DATE,20010713 -US-Ne1,88660,GRP_HEIGHTC,HEIGHTC,2.914 -US-Ne1,88660,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne1,88660,GRP_HEIGHTC,HEIGHTC_DATE,20010719 -US-Ne1,88661,GRP_HEIGHTC,HEIGHTC,3.315 -US-Ne1,88661,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne1,88661,GRP_HEIGHTC,HEIGHTC_DATE,20010809 -US-Ne1,88662,GRP_HEIGHTC,HEIGHTC,3.506 -US-Ne1,88662,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne1,88662,GRP_HEIGHTC,HEIGHTC_DATE,20010815 -US-Ne1,88663,GRP_HEIGHTC,HEIGHTC,0.000 -US-Ne1,88663,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne1,88663,GRP_HEIGHTC,HEIGHTC_DATE,20020518 -US-Ne1,88664,GRP_HEIGHTC,HEIGHTC,0.115 -US-Ne1,88664,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne1,88664,GRP_HEIGHTC,HEIGHTC_DATE,20020529 -US-Ne1,88665,GRP_HEIGHTC,HEIGHTC,0.255 -US-Ne1,88665,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne1,88665,GRP_HEIGHTC,HEIGHTC_DATE,20020603 -US-Ne1,88666,GRP_HEIGHTC,HEIGHTC,0.587 -US-Ne1,88666,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne1,88666,GRP_HEIGHTC,HEIGHTC_DATE,20020618 -US-Ne1,88667,GRP_HEIGHTC,HEIGHTC,1.373 -US-Ne1,88667,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne1,88667,GRP_HEIGHTC,HEIGHTC_DATE,20020701 -US-Ne1,88668,GRP_HEIGHTC,HEIGHTC,1.959 -US-Ne1,88668,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne1,88668,GRP_HEIGHTC,HEIGHTC_DATE,20020708 -US-Ne1,88669,GRP_HEIGHTC,HEIGHTC,2.288 -US-Ne1,88669,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne1,88669,GRP_HEIGHTC,HEIGHTC_DATE,20020715 -US-Ne1,88670,GRP_HEIGHTC,HEIGHTC,2.923 -US-Ne1,88670,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne1,88670,GRP_HEIGHTC,HEIGHTC_DATE,20020729 -US-Ne1,88671,GRP_HEIGHTC,HEIGHTC,3.278 -US-Ne1,88671,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne1,88671,GRP_HEIGHTC,HEIGHTC_DATE,20020812 -US-Ne1,88672,GRP_HEIGHTC,HEIGHTC,3.120 -US-Ne1,88672,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne1,88672,GRP_HEIGHTC,HEIGHTC_DATE,20020912 -US-Ne1,88673,GRP_HEIGHTC,HEIGHTC,0.000 -US-Ne1,88673,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne1,88673,GRP_HEIGHTC,HEIGHTC_DATE,20030527 -US-Ne1,88674,GRP_HEIGHTC,HEIGHTC,0.237 -US-Ne1,88674,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne1,88674,GRP_HEIGHTC,HEIGHTC_DATE,20030606 -US-Ne1,88675,GRP_HEIGHTC,HEIGHTC,0.888 -US-Ne1,88675,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne1,88675,GRP_HEIGHTC,HEIGHTC_DATE,20030625 -US-Ne1,88676,GRP_HEIGHTC,HEIGHTC,1.656 -US-Ne1,88676,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne1,88676,GRP_HEIGHTC,HEIGHTC_DATE,20030708 -US-Ne1,88677,GRP_HEIGHTC,HEIGHTC,2.331 -US-Ne1,88677,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne1,88677,GRP_HEIGHTC,HEIGHTC_DATE,20030718 -US-Ne1,88678,GRP_HEIGHTC,HEIGHTC,2.743 -US-Ne1,88678,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne1,88678,GRP_HEIGHTC,HEIGHTC_DATE,20030728 -US-Ne1,88679,GRP_HEIGHTC,HEIGHTC,2.814 -US-Ne1,88679,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne1,88679,GRP_HEIGHTC,HEIGHTC_DATE,20030808 -US-Ne1,88680,GRP_HEIGHTC,HEIGHTC,2.763 -US-Ne1,88680,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne1,88680,GRP_HEIGHTC,HEIGHTC_DATE,20030826 -US-Ne1,88681,GRP_HEIGHTC,HEIGHTC,2.799 -US-Ne1,88681,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne1,88681,GRP_HEIGHTC,HEIGHTC_DATE,20030926 -US-Ne1,88682,GRP_HEIGHTC,HEIGHTC,0.000 -US-Ne1,88682,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne1,88682,GRP_HEIGHTC,HEIGHTC_DATE,20040513 -US-Ne1,88683,GRP_HEIGHTC,HEIGHTC,0.292 -US-Ne1,88683,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne1,88683,GRP_HEIGHTC,HEIGHTC_DATE,20040603 -US-Ne1,88684,GRP_HEIGHTC,HEIGHTC,0.707 -US-Ne1,88684,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne1,88684,GRP_HEIGHTC,HEIGHTC_DATE,20040615 -US-Ne1,88685,GRP_HEIGHTC,HEIGHTC,1.539 -US-Ne1,88685,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne1,88685,GRP_HEIGHTC,HEIGHTC_DATE,20040701 -US-Ne1,88686,GRP_HEIGHTC,HEIGHTC,2.281 -US-Ne1,88686,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne1,88686,GRP_HEIGHTC,HEIGHTC_DATE,20040713 -US-Ne1,88687,GRP_HEIGHTC,HEIGHTC,2.967 -US-Ne1,88687,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne1,88687,GRP_HEIGHTC,HEIGHTC_DATE,20040726 -US-Ne1,88688,GRP_HEIGHTC,HEIGHTC,2.950 -US-Ne1,88688,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne1,88688,GRP_HEIGHTC,HEIGHTC_DATE,20040805 -US-Ne1,88689,GRP_HEIGHTC,HEIGHTC,2.929 -US-Ne1,88689,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne1,88689,GRP_HEIGHTC,HEIGHTC_DATE,20040817 -US-Ne1,88690,GRP_HEIGHTC,HEIGHTC,0.000 -US-Ne1,88690,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne1,88690,GRP_HEIGHTC,HEIGHTC_DATE,20050517 -US-Ne1,88691,GRP_HEIGHTC,HEIGHTC,0.208 -US-Ne1,88691,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne1,88691,GRP_HEIGHTC,HEIGHTC_DATE,20050531 -US-Ne1,88692,GRP_HEIGHTC,HEIGHTC,0.746 -US-Ne1,88692,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne1,88692,GRP_HEIGHTC,HEIGHTC_DATE,20050617 -US-Ne1,88693,GRP_HEIGHTC,HEIGHTC,1.248 -US-Ne1,88693,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne1,88693,GRP_HEIGHTC,HEIGHTC_DATE,20050627 -US-Ne1,88694,GRP_HEIGHTC,HEIGHTC,1.868 -US-Ne1,88694,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne1,88694,GRP_HEIGHTC,HEIGHTC_DATE,20050707 -US-Ne1,88695,GRP_HEIGHTC,HEIGHTC,2.545 -US-Ne1,88695,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne1,88695,GRP_HEIGHTC,HEIGHTC_DATE,20050720 -US-Ne1,88696,GRP_HEIGHTC,HEIGHTC,2.711 -US-Ne1,88696,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne1,88696,GRP_HEIGHTC,HEIGHTC_DATE,20050801 -US-Ne1,88697,GRP_HEIGHTC,HEIGHTC,2.749 -US-Ne1,88697,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne1,88697,GRP_HEIGHTC,HEIGHTC_DATE,20050809 -US-Ne1,88698,GRP_HEIGHTC,HEIGHTC,2.760 -US-Ne1,88698,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne1,88698,GRP_HEIGHTC,HEIGHTC_DATE,20050919 -US-Ne1,88699,GRP_HEIGHTC,HEIGHTC,0.000 -US-Ne1,88699,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne1,88699,GRP_HEIGHTC,HEIGHTC_DATE,20060516 -US-Ne1,88700,GRP_HEIGHTC,HEIGHTC,0.407 -US-Ne1,88700,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne1,88700,GRP_HEIGHTC,HEIGHTC_DATE,20060601 -US-Ne1,88701,GRP_HEIGHTC,HEIGHTC,0.779 -US-Ne1,88701,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne1,88701,GRP_HEIGHTC,HEIGHTC_DATE,20060608 -US-Ne1,88702,GRP_HEIGHTC,HEIGHTC,1.096 -US-Ne1,88702,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne1,88702,GRP_HEIGHTC,HEIGHTC_DATE,20060616 -US-Ne1,88703,GRP_HEIGHTC,HEIGHTC,1.743 -US-Ne1,88703,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne1,88703,GRP_HEIGHTC,HEIGHTC_DATE,20060626 -US-Ne1,88704,GRP_HEIGHTC,HEIGHTC,2.438 -US-Ne1,88704,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne1,88704,GRP_HEIGHTC,HEIGHTC_DATE,20060706 -US-Ne1,88705,GRP_HEIGHTC,HEIGHTC,2.935 -US-Ne1,88705,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne1,88705,GRP_HEIGHTC,HEIGHTC_DATE,20060712 -US-Ne1,88706,GRP_HEIGHTC,HEIGHTC,2.985 -US-Ne1,88706,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne1,88706,GRP_HEIGHTC,HEIGHTC_DATE,20060720 -US-Ne1,88707,GRP_HEIGHTC,HEIGHTC,0.000 -US-Ne1,88707,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne1,88707,GRP_HEIGHTC,HEIGHTC_DATE,20060728 -US-Ne1,88708,GRP_HEIGHTC,HEIGHTC,0.000 -US-Ne1,88708,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne1,88708,GRP_HEIGHTC,HEIGHTC_DATE,20070510 -US-Ne1,88709,GRP_HEIGHTC,HEIGHTC,0.333 -US-Ne1,88709,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne1,88709,GRP_HEIGHTC,HEIGHTC_DATE,20070529 -US-Ne1,88710,GRP_HEIGHTC,HEIGHTC,0.578 -US-Ne1,88710,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne1,88710,GRP_HEIGHTC,HEIGHTC_DATE,20070606 -US-Ne1,88711,GRP_HEIGHTC,HEIGHTC,0.858 -US-Ne1,88711,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne1,88711,GRP_HEIGHTC,HEIGHTC_DATE,20070613 -US-Ne1,88712,GRP_HEIGHTC,HEIGHTC,1.238 -US-Ne1,88712,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne1,88712,GRP_HEIGHTC,HEIGHTC_DATE,20070619 -US-Ne1,88713,GRP_HEIGHTC,HEIGHTC,1.842 -US-Ne1,88713,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne1,88713,GRP_HEIGHTC,HEIGHTC_DATE,20070626 -US-Ne1,88714,GRP_HEIGHTC,HEIGHTC,2.644 -US-Ne1,88714,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne1,88714,GRP_HEIGHTC,HEIGHTC_DATE,20070709 -US-Ne1,88715,GRP_HEIGHTC,HEIGHTC,2.927 -US-Ne1,88715,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne1,88715,GRP_HEIGHTC,HEIGHTC_DATE,20070716 -US-Ne1,88716,GRP_HEIGHTC,HEIGHTC,2.901 -US-Ne1,88716,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne1,88716,GRP_HEIGHTC,HEIGHTC_DATE,20070724 -US-Ne1,88717,GRP_HEIGHTC,HEIGHTC,2.966 -US-Ne1,88717,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne1,88717,GRP_HEIGHTC,HEIGHTC_DATE,20070803 -US-Ne1,88718,GRP_HEIGHTC,HEIGHTC,0.000 -US-Ne1,88718,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne1,88718,GRP_HEIGHTC,HEIGHTC_DATE,20080509 -US-Ne1,88719,GRP_HEIGHTC,HEIGHTC,0.149 -US-Ne1,88719,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne1,88719,GRP_HEIGHTC,HEIGHTC_DATE,20080521 -US-Ne1,88720,GRP_HEIGHTC,HEIGHTC,0.206 -US-Ne1,88720,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne1,88720,GRP_HEIGHTC,HEIGHTC_DATE,20080530 -US-Ne1,88721,GRP_HEIGHTC,HEIGHTC,0.557 -US-Ne1,88721,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne1,88721,GRP_HEIGHTC,HEIGHTC_DATE,20080611 -US-Ne1,88722,GRP_HEIGHTC,HEIGHTC,0.904 -US-Ne1,88722,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne1,88722,GRP_HEIGHTC,HEIGHTC_DATE,20080618 -US-Ne1,88723,GRP_HEIGHTC,HEIGHTC,1.301 -US-Ne1,88723,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne1,88723,GRP_HEIGHTC,HEIGHTC_DATE,20080624 -US-Ne1,88724,GRP_HEIGHTC,HEIGHTC,1.844 -US-Ne1,88724,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne1,88724,GRP_HEIGHTC,HEIGHTC_DATE,20080702 -US-Ne1,88725,GRP_HEIGHTC,HEIGHTC,2.242 -US-Ne1,88725,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne1,88725,GRP_HEIGHTC,HEIGHTC_DATE,20080710 -US-Ne1,88726,GRP_HEIGHTC,HEIGHTC,2.542 -US-Ne1,88726,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne1,88726,GRP_HEIGHTC,HEIGHTC_DATE,20080717 -US-Ne1,88727,GRP_HEIGHTC,HEIGHTC,2.709 -US-Ne1,88727,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne1,88727,GRP_HEIGHTC,HEIGHTC_DATE,20080727 -US-Ne1,88728,GRP_HEIGHTC,HEIGHTC,2.683 -US-Ne1,88728,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne1,88728,GRP_HEIGHTC,HEIGHTC_DATE,20080804 -US-Ne1,88729,GRP_HEIGHTC,HEIGHTC,2.708 -US-Ne1,88729,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne1,88729,GRP_HEIGHTC,HEIGHTC_DATE,20080814 -US-Ne1,88730,GRP_HEIGHTC,HEIGHTC,0.000 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-US-Ne1,24392,GRP_LAI,LAI_TOT,4.784 -US-Ne1,25439,GRP_LAI,LAI_TOT,4.80714 -US-Ne1,26430,GRP_LAI,LAI_TOT,4.86427 -US-Ne1,26572,GRP_LAI,LAI_TOT,4.98617 -US-Ne1,26435,GRP_LAI,LAI_TOT,5.0473 -US-Ne1,25303,GRP_LAI,LAI_TOT,5.16325 -US-Ne1,25173,GRP_LAI,LAI_TOT,5.16431 -US-Ne1,26575,GRP_LAI,LAI_TOT,5.17823 -US-Ne1,24396,GRP_LAI,LAI_TOT,5.19254 -US-Ne1,25568,GRP_LAI,LAI_TOT,5.23946 -US-Ne1,25301,GRP_LAI,LAI_TOT,5.28064 -US-Ne1,25422,GRP_LAI,LAI_TOT,5.31928 -US-Ne1,24136,GRP_LAI,LAI_TOT,5.37085 -US-Ne1,26073,GRP_LAI,LAI_TOT,5.42715 -US-Ne1,25676,GRP_LAI,LAI_TOT,5.51438 -US-Ne1,26072,GRP_LAI,LAI_TOT,5.53073 -US-Ne1,26559,GRP_LAI,LAI_TOT,5.6927 -US-Ne1,24137,GRP_LAI,LAI_TOT,5.7383 -US-Ne1,25172,GRP_LAI,LAI_TOT,5.96192 -US-Ne1,25808,GRP_LAI,LAI_TOT,6.02431 -US-Ne1,25569,GRP_LAI,LAI_TOT,6.03694 -US-Ne1,26070,GRP_LAI,LAI_TOT,6.07868 -US-Ne1,25675,GRP_LAI,LAI_TOT,6.11576 -US-Ne1,26319,GRP_LAI,LAI_TOT,6.2836 -US-Ne1,3378,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-Ne1,3378,GRP_LAND_OWNERSHIP,LAND_OWNER,University of Nebraska -US-Ne1,28757,GRP_LMA,LMA,13.19 -US-Ne1,28757,GRP_LMA,LMA_SPP,ZEMAH (NRCS plant code) -US-Ne1,28757,GRP_LMA,LMA_DATE,20050531 -US-Ne1,28403,GRP_LMA,LMA,14.1359 -US-Ne1,28403,GRP_LMA,LMA_SPP,ZEMAH (NRCS plant code) -US-Ne1,28403,GRP_LMA,LMA_DATE,20070529 -US-Ne1,28754,GRP_LMA,LMA,14.62 -US-Ne1,28754,GRP_LMA,LMA_SPP,ZEMAH (NRCS plant code) -US-Ne1,28754,GRP_LMA,LMA_DATE,20010529 -US-Ne1,28401,GRP_LMA,LMA,14.65 -US-Ne1,28401,GRP_LMA,LMA_SPP,ZEMAH (NRCS plant code) -US-Ne1,28401,GRP_LMA,LMA_DATE,20060601 -US-Ne1,28907,GRP_LMA,LMA,14.91 -US-Ne1,28907,GRP_LMA,LMA_SPP,ZEMAH (NRCS plant code) -US-Ne1,28907,GRP_LMA,LMA_DATE,20010613 -US-Ne1,28687,GRP_LMA,LMA,15.81 -US-Ne1,28687,GRP_LMA,LMA_SPP,ZEMAH (NRCS plant code) -US-Ne1,28687,GRP_LMA,LMA_DATE,20020529 -US-Ne1,29386,GRP_LMA,LMA,17.2464 -US-Ne1,29386,GRP_LMA,LMA_SPP,ZEMAH (NRCS plant code) -US-Ne1,29386,GRP_LMA,LMA_DATE,20060608 -US-Ne1,28910,GRP_LMA,LMA,17.65 -US-Ne1,28910,GRP_LMA,LMA_SPP,ZEMAH (NRCS plant code) -US-Ne1,28910,GRP_LMA,LMA_DATE,20030625 -US-Ne1,28688,GRP_LMA,LMA,18.3 -US-Ne1,28688,GRP_LMA,LMA_SPP,ZEMAH (NRCS plant code) -US-Ne1,28688,GRP_LMA,LMA_DATE,20020618 -US-Ne1,27796,GRP_LMA,LMA,18.32 -US-Ne1,27796,GRP_LMA,LMA_SPP,ZEMAH (NRCS plant code) -US-Ne1,27796,GRP_LMA,LMA_DATE,20050617 -US-Ne1,28690,GRP_LMA,LMA,18.4 -US-Ne1,28690,GRP_LMA,LMA_SPP,ZEMAH (NRCS plant code) -US-Ne1,28690,GRP_LMA,LMA_DATE,20040615 -US-Ne1,28063,GRP_LMA,LMA,18.44 -US-Ne1,28063,GRP_LMA,LMA_SPP,ZEMAH (NRCS plant code) -US-Ne1,28063,GRP_LMA,LMA_DATE,20040603 -US-Ne1,27152,GRP_LMA,LMA,18.5988 -US-Ne1,27152,GRP_LMA,LMA_SPP,ZEMAH (NRCS plant code) -US-Ne1,27152,GRP_LMA,LMA_DATE,20060616 -US-Ne1,28404,GRP_LMA,LMA,18.6309 -US-Ne1,28404,GRP_LMA,LMA_SPP,ZEMAH (NRCS plant code) -US-Ne1,28404,GRP_LMA,LMA_DATE,20070709 -US-Ne1,28062,GRP_LMA,LMA,18.73 -US-Ne1,28062,GRP_LMA,LMA_SPP,ZEMAH (NRCS plant code) -US-Ne1,28062,GRP_LMA,LMA_DATE,20020603 -US-Ne1,27711,GRP_LMA,LMA,19.34 -US-Ne1,27711,GRP_LMA,LMA_SPP,ZEMAH (NRCS plant code) -US-Ne1,27711,GRP_LMA,LMA_DATE,20050627 -US-Ne1,28908,GRP_LMA,LMA,19.6 -US-Ne1,28908,GRP_LMA,LMA_SPP,ZEMAH (NRCS plant code) -US-Ne1,28908,GRP_LMA,LMA_DATE,20010621 -US-Ne1,28904,GRP_LMA,LMA,19.6636 -US-Ne1,28904,GRP_LMA,LMA_SPP,ZEMAH (NRCS plant code) -US-Ne1,28904,GRP_LMA,LMA_DATE,20070613 -US-Ne1,28750,GRP_LMA,LMA,19.8744 -US-Ne1,28750,GRP_LMA,LMA_SPP,ZEMAH (NRCS plant code) -US-Ne1,28750,GRP_LMA,LMA_DATE,20070606 -US-Ne1,28911,GRP_LMA,LMA,20.19 -US-Ne1,28911,GRP_LMA,LMA_SPP,ZEMAH (NRCS plant code) -US-Ne1,28911,GRP_LMA,LMA_DATE,20030708 -US-Ne1,28410,GRP_LMA,LMA,20.8 -US-Ne1,28410,GRP_LMA,LMA_SPP,ZEMAH (NRCS plant code) -US-Ne1,28410,GRP_LMA,LMA_DATE,20010705 -US-Ne1,27156,GRP_LMA,LMA,20.9 -US-Ne1,27156,GRP_LMA,LMA_SPP,ZEMAH (NRCS plant code) -US-Ne1,27156,GRP_LMA,LMA_DATE,20010719 -US-Ne1,28755,GRP_LMA,LMA,20.96 -US-Ne1,28755,GRP_LMA,LMA_SPP,ZEMAH (NRCS plant code) -US-Ne1,28755,GRP_LMA,LMA_DATE,20010629 -US-Ne1,28064,GRP_LMA,LMA,20.98 -US-Ne1,28064,GRP_LMA,LMA_SPP,ZEMAH (NRCS plant code) -US-Ne1,28064,GRP_LMA,LMA_DATE,20040701 -US-Ne1,28751,GRP_LMA,LMA,21.1204 -US-Ne1,28751,GRP_LMA,LMA_SPP,ZEMAH (NRCS plant code) -US-Ne1,28751,GRP_LMA,LMA_DATE,20070619 -US-Ne1,29285,GRP_LMA,LMA,21.17 -US-Ne1,29285,GRP_LMA,LMA_SPP,ZEMAH (NRCS plant code) -US-Ne1,29285,GRP_LMA,LMA_DATE,20050707 -US-Ne1,29387,GRP_LMA,LMA,21.2338 -US-Ne1,29387,GRP_LMA,LMA_SPP,ZEMAH (NRCS plant code) -US-Ne1,29387,GRP_LMA,LMA_DATE,20060626 -US-Ne1,27157,GRP_LMA,LMA,22.08 -US-Ne1,27157,GRP_LMA,LMA_SPP,ZEMAH (NRCS plant code) -US-Ne1,27157,GRP_LMA,LMA_DATE,20020708 -US-Ne1,29397,GRP_LMA,LMA,22.23 -US-Ne1,29397,GRP_LMA,LMA_SPP,ZEMAH (NRCS plant code) -US-Ne1,29397,GRP_LMA,LMA_DATE,20010713 -US-Ne1,28905,GRP_LMA,LMA,22.291 -US-Ne1,28905,GRP_LMA,LMA_SPP,ZEMAH (NRCS plant code) -US-Ne1,28905,GRP_LMA,LMA_DATE,20070626 -US-Ne1,27158,GRP_LMA,LMA,22.67 -US-Ne1,27158,GRP_LMA,LMA_SPP,ZEMAH (NRCS plant code) -US-Ne1,27158,GRP_LMA,LMA_DATE,20040713 -US-Ne1,29593,GRP_LMA,LMA,23.28 -US-Ne1,29593,GRP_LMA,LMA_SPP,ZEMAH (NRCS plant code) -US-Ne1,29593,GRP_LMA,LMA_DATE,20020701 -US-Ne1,28745,GRP_LMA,LMA,23.5575 -US-Ne1,28745,GRP_LMA,LMA_SPP,ZEMAH (NRCS plant code) -US-Ne1,28745,GRP_LMA,LMA_DATE,20060706 -US-Ne1,29392,GRP_LMA,LMA,23.8953 -US-Ne1,29392,GRP_LMA,LMA_SPP,ZEMAH (NRCS plant code) -US-Ne1,29392,GRP_LMA,LMA_DATE,20070716 -US-Ne1,29595,GRP_LMA,LMA,24.07 -US-Ne1,29595,GRP_LMA,LMA_SPP,ZEMAH (NRCS plant code) -US-Ne1,29595,GRP_LMA,LMA_DATE,20030718 -US-Ne1,29596,GRP_LMA,LMA,24.2 -US-Ne1,29596,GRP_LMA,LMA_SPP,ZEMAH (NRCS plant code) -US-Ne1,29596,GRP_LMA,LMA_DATE,20050720 -US-Ne1,29594,GRP_LMA,LMA,24.41 -US-Ne1,29594,GRP_LMA,LMA_SPP,ZEMAH (NRCS plant code) -US-Ne1,29594,GRP_LMA,LMA_DATE,20020715 -US-Ne1,27159,GRP_LMA,LMA,24.89 -US-Ne1,27159,GRP_LMA,LMA_SPP,ZEMAH (NRCS plant code) -US-Ne1,27159,GRP_LMA,LMA_DATE,20050801 -US-Ne1,28065,GRP_LMA,LMA,24.97 -US-Ne1,28065,GRP_LMA,LMA_SPP,ZEMAH (NRCS plant code) -US-Ne1,28065,GRP_LMA,LMA_DATE,20050809 -US-Ne1,28901,GRP_LMA,LMA,25.2002 -US-Ne1,28901,GRP_LMA,LMA_SPP,ZEMAH (NRCS plant code) -US-Ne1,28901,GRP_LMA,LMA_DATE,20060720 -US-Ne1,27461,GRP_LMA,LMA,25.24 -US-Ne1,27461,GRP_LMA,LMA_SPP,ZEMAH (NRCS plant code) -US-Ne1,27461,GRP_LMA,LMA_DATE,20010815 -US-Ne1,29398,GRP_LMA,LMA,25.36 -US-Ne1,29398,GRP_LMA,LMA_SPP,ZEMAH (NRCS plant code) -US-Ne1,29398,GRP_LMA,LMA_DATE,20010809 -US-Ne1,29283,GRP_LMA,LMA,25.44 -US-Ne1,29283,GRP_LMA,LMA_SPP,ZEMAH (NRCS plant code) -US-Ne1,29283,GRP_LMA,LMA_DATE,20030728 -US-Ne1,28406,GRP_LMA,LMA,25.6282 -US-Ne1,28406,GRP_LMA,LMA_SPP,ZEMAH (NRCS plant code) -US-Ne1,28406,GRP_LMA,LMA_DATE,20070816 -US-Ne1,29284,GRP_LMA,LMA,25.73 -US-Ne1,29284,GRP_LMA,LMA_SPP,ZEMAH (NRCS plant code) -US-Ne1,29284,GRP_LMA,LMA_DATE,20040805 -US-Ne1,27794,GRP_LMA,LMA,25.84 -US-Ne1,27794,GRP_LMA,LMA_SPP,ZEMAH (NRCS plant code) -US-Ne1,27794,GRP_LMA,LMA_DATE,20030606 -US-Ne1,28691,GRP_LMA,LMA,25.9 -US-Ne1,28691,GRP_LMA,LMA_SPP,ZEMAH (NRCS plant code) -US-Ne1,28691,GRP_LMA,LMA_DATE,20050919 -US-Ne1,28405,GRP_LMA,LMA,26.0424 -US-Ne1,28405,GRP_LMA,LMA_SPP,ZEMAH (NRCS plant code) -US-Ne1,28405,GRP_LMA,LMA_DATE,20070724 -US-Ne1,27708,GRP_LMA,LMA,26.11 -US-Ne1,27708,GRP_LMA,LMA_SPP,ZEMAH (NRCS plant code) -US-Ne1,27708,GRP_LMA,LMA_DATE,20030808 -US-Ne1,27709,GRP_LMA,LMA,26.27 -US-Ne1,27709,GRP_LMA,LMA_SPP,ZEMAH (NRCS plant code) -US-Ne1,27709,GRP_LMA,LMA_DATE,20040726 -US-Ne1,27710,GRP_LMA,LMA,26.43 -US-Ne1,27710,GRP_LMA,LMA_SPP,ZEMAH (NRCS plant code) -US-Ne1,27710,GRP_LMA,LMA_DATE,20040817 -US-Ne1,27792,GRP_LMA,LMA,26.6334 -US-Ne1,27792,GRP_LMA,LMA_SPP,ZEMAH (NRCS plant code) -US-Ne1,27792,GRP_LMA,LMA_DATE,20060712 -US-Ne1,28746,GRP_LMA,LMA,26.8221 -US-Ne1,28746,GRP_LMA,LMA_SPP,ZEMAH (NRCS plant code) -US-Ne1,28746,GRP_LMA,LMA_DATE,20060728 -US-Ne1,28412,GRP_LMA,LMA,27.17 -US-Ne1,28412,GRP_LMA,LMA_SPP,ZEMAH (NRCS plant code) -US-Ne1,28412,GRP_LMA,LMA_DATE,20030826 -US-Ne1,28411,GRP_LMA,LMA,27.19 -US-Ne1,28411,GRP_LMA,LMA_SPP,ZEMAH (NRCS plant code) -US-Ne1,28411,GRP_LMA,LMA_DATE,20020729 -US-Ne1,29388,GRP_LMA,LMA,28.1258 -US-Ne1,29388,GRP_LMA,LMA_SPP,ZEMAH (NRCS plant code) -US-Ne1,29388,GRP_LMA,LMA_DATE,20060804 -US-Ne1,29393,GRP_LMA,LMA,28.3167 -US-Ne1,29393,GRP_LMA,LMA_SPP,ZEMAH (NRCS plant code) -US-Ne1,29393,GRP_LMA,LMA_DATE,20070803 -US-Ne1,28909,GRP_LMA,LMA,28.41 -US-Ne1,28909,GRP_LMA,LMA_SPP,ZEMAH (NRCS plant code) -US-Ne1,28909,GRP_LMA,LMA_DATE,20020812 -US-Ne1,29389,GRP_LMA,LMA,28.6542 -US-Ne1,29389,GRP_LMA,LMA_SPP,ZEMAH (NRCS plant code) -US-Ne1,29389,GRP_LMA,LMA_DATE,20060824 -US-Ne1,29278,GRP_LMA,LMA,28.8982 -US-Ne1,29278,GRP_LMA,LMA_SPP,ZEMAH (NRCS plant code) -US-Ne1,29278,GRP_LMA,LMA_DATE,20060814 -US-Ne1,28686,GRP_LMA,LMA,28.9373 -US-Ne1,28686,GRP_LMA,LMA_SPP,ZEMAH (NRCS plant code) -US-Ne1,28686,GRP_LMA,LMA_DATE,20070905 -US-Ne1,27795,GRP_LMA,LMA,29.02 -US-Ne1,27795,GRP_LMA,LMA_SPP,ZEMAH (NRCS plant code) -US-Ne1,27795,GRP_LMA,LMA_DATE,20040907 -US-Ne1,28066,GRP_LMA,LMA,31.09 -US-Ne1,28066,GRP_LMA,LMA_SPP,ZEMAH (NRCS plant code) -US-Ne1,28066,GRP_LMA,LMA_DATE,20050913 -US-Ne1,28689,GRP_LMA,LMA,32.68 -US-Ne1,28689,GRP_LMA,LMA_SPP,ZEMAH (NRCS plant code) -US-Ne1,28689,GRP_LMA,LMA_DATE,20030926 -US-Ne1,28756,GRP_LMA,LMA,34.51 -US-Ne1,28756,GRP_LMA,LMA_SPP,ZEMAH (NRCS plant code) -US-Ne1,28756,GRP_LMA,LMA_DATE,20020912 -US-Ne1,27458,GRP_LMA,LMA,36.5969 -US-Ne1,27458,GRP_LMA,LMA_SPP,ZEMAH (NRCS plant code) -US-Ne1,27458,GRP_LMA,LMA_DATE,20070924 -US-Ne1,28912,GRP_LMA,LMA,38.83 -US-Ne1,28912,GRP_LMA,LMA_SPP,ZEMAH (NRCS plant code) -US-Ne1,28912,GRP_LMA,LMA_DATE,20040929 -US-Ne1,27153,GRP_LMA,LMA,41.0915 -US-Ne1,27153,GRP_LMA,LMA_SPP,ZEMAH (NRCS plant code) -US-Ne1,27153,GRP_LMA,LMA_DATE,20060912 -US-Ne1,2429,GRP_LOCATION,LOCATION_LAT,41.1651 -US-Ne1,2429,GRP_LOCATION,LOCATION_LONG,-96.4766 -US-Ne1,2429,GRP_LOCATION,LOCATION_ELEV,361 -US-Ne1,9815,GRP_NETWORK,NETWORK,AmeriFlux -US-Ne1,1700007533,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Amos, B., Arkebauer, T. J., Doran, J. W. (2005) Soil Surface Fluxes Of Greenhouse Gases In An Irrigated Maize-Based Agroecosystem, Soil Science Society Of America Journal, 69(2), 387-395" -US-Ne1,1700007533,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.2136/SSSAJ2005.0387 -US-Ne1,1700007533,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ne1,1700001263,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Barr, A., Richardson, A., Hollinger, D., Papale, D., Arain, M., Black, T., Bohrer, G., Dragoni, D., Fischer, M., Gu, L., Law, B., Margolis, H., McCaughey, J., Munger, J., Oechel, W., Schaeffer, K. (2013) Use Of Change-Point Detection For Friction–Velocity Threshold Evaluation In Eddy-Covariance Studies, Agricultural And Forest Meteorology, 171-172(7), 31-45" -US-Ne1,1700001263,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2012.11.023 -US-Ne1,1700001263,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ne1,1700001410,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Baldocchi, D. D., Poindexter, C., Abraha, M., Desai, A. R., Bohrer, G., Arain, M. A., Griffis, T., Blanken, P. D., O'Halloran, T. L., Thomas, R. Q., Zhang, Q., Burns, S. P., Frank, J. M., Christian, D., Brown, S., Black, T. A., Gough, C. M., Law, B. E., Lee, X., Chen, J., Reed, D. E., Massman, W. J., Clark, K., Hatfield, J., Prueger, J., Bracho, R., Baker, J. M., Martin, T. A. (2018) Temporal Dynamics Of Aerodynamic Canopy Height Derived From Eddy Covariance Momentum Flux Data Across North American Flux Networks, Geophysical Research Letters, 45(5), 9275–9287" -US-Ne1,1700001410,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018GL079306 -US-Ne1,1700001410,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ne1,1700001248,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Baldocchi, D. D., Poindexter, C., Abraha, M., Desai, A. R., Bohrer, G., Arain, M. A., Griffis, T., Blanken, P. D., O'Halloran, T. L., Thomas, R. Q., Zhang, Q., Burns, S. P., Frank, J. M., Christian, D., Brown, S., Black, T. A., Gough, C. M., Law, B. E., Lee, X., Chen, J., Reed, D. E., Massman, W. J., Clark, K., Hatfield, J., Prueger, J., Bracho, R., Baker, J. M., Martin, T. A. (2018) Temporal Dynamics Of Aerodynamic Canopy Height Derived From Eddy Covariance Momentum Flux Data Across North American Flux Networks, Geophysical Research Letters, 45(7), 9275–9287" -US-Ne1,1700001248,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018GL079306 -US-Ne1,1700001248,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ne1,1700006399,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(7), 108350" -US-Ne1,1700006399,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -US-Ne1,1700006399,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ne1,1700004317,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Dobermann, A., Ping, J. L. (2004) Geostatistical Integration Of Yield Monitor Data And Remote Sensing Improves Yield Maps, Agronomy Journal, 96(1), 285-297" -US-Ne1,1700004317,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.2134/AGRONJ2004.0285 -US-Ne1,1700004317,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ne1,1700007329,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Dobermann, A., Ping, J. L., Adamchuk, V. I., Simbahan, G. C., Ferguson, R. B. (2003) Classification Of Crop Yield Variability In Irrigated Production Fields, Agronomy Journal, 95(5), 1105-1120" -US-Ne1,1700007329,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.2134/AGRONJ2003.1105 -US-Ne1,1700007329,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ne1,1700005862,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Ginting, D., Eghball, B. (2005) Nitrous Oxide Emission From No-Till Irrigated Corn, Soil Science Society Of America Journal, 69(3), 915-925" -US-Ne1,1700005862,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.2136/SSSAJ2004.0292 -US-Ne1,1700005862,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ne1,1700007065,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Gitelson, A. A. (2004) Wide Dynamic Range Vegetation Index For Remote Quantification Of Biophysical Characteristics Of Vegetation, Journal Of Plant Physiology, 161(2), 165-173" -US-Ne1,1700007065,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1078/0176-1617-01176 -US-Ne1,1700007065,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ne1,1700008082,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Gitelson, A. A., Verma, S. B, Rundquist, D. C., Keydan, G., Leavitt, B., Arkebauer, T. J., Burba, G. G., Suyker, A. E. (2003) Novel Technique For Remote Estimation Of CO2 Flux In Maize, Geophysical Research Letters, 30(9), 1486-n/a" -US-Ne1,1700008082,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2002GL016543 -US-Ne1,1700008082,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ne1,1700004659,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Gitelson, A. A., Viña, A., Arkebauer, T. J., Rundquist, D. C., Keydan, G., Leavitt, B. (2003) Remote Estimation Of Leaf Area Index And Green Leaf Biomass In Maize Canopies, Geophysical Research Letters, 30(5), n/a-n/a" -US-Ne1,1700004659,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2002GL016450 -US-Ne1,1700004659,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ne1,1700003816,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Mahmood, R., Hubbard, K. G. (2005) Assessing Bias In Evapotranspiration And Soil Moisture Estimates Due To The Use Of Modeled Solar Radiation And Dew Point Temperature Data, Agricultural And Forest Meteorology, 130(1-2), 71-84" -US-Ne1,1700003816,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2005.02.004 -US-Ne1,1700003816,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ne1,1700007569,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Matheny, A. M., Bohrer, G., Stoy, P. C., Baker, I. T., Black, A. T., Desai, A. R., Dietze, M. C., Gough, C. M., Ivanov, V. Y., Jassal, R. S., Novick, K. A., Schäfer, K. V., Verbeeck, H. (2014) Characterizing The Diurnal Patterns of Errors in The Prediction of Evapotranspiration by Several Land-Surface Models: An Nacp Analysis, Journal Of Geophysical Research: Biogeosciences, 119(7), 1458-1473" -US-Ne1,1700007569,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/2014JG002623 -US-Ne1,1700007569,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ne1,1700003672,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"McCombs, A. G., Hiscox, A. L., Wang, C., Desai, A. R., Suyker, A. E., Biraud, S. C. (2018) Carbon Flux Phenology From The Sky: Evaluation For Maize And Soybean, Journal Of Atmospheric And Oceanic Technology, 35(4), 877-892" -US-Ne1,1700003672,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1175/JTECH-D-17-0004.1 -US-Ne1,1700003672,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ne1,1700003618,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Novick, K. A., Ficklin, D. L., Stoy, P. C., Williams, C. A., Bohrer, G., Oishi, A., Papuga, S. A., Blanken, P. D., Noormets, A., Sulman, B. N., Scott, R. L., Wang, L., Phillips, R. P. (2016) The Increasing Importance Of Atmospheric Demand For Ecosystem Water And Carbon Fluxes, Nature Climate Change, 6(11), 1023-1027" -US-Ne1,1700003618,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1038/NCLIMATE3114 -US-Ne1,1700003618,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ne1,1700008265,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Ping, J. L., Dobermann, A. (2003) Creating Spatially Contiguous Yield Classes For Site-Specific Management, Agronomy Journal, 95(5), 1121-1131" -US-Ne1,1700008265,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.2134/AGRONJ2003.1121 -US-Ne1,1700008265,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ne1,1700006690,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Ping, J. L., Dobermann, A. (2005) Processing Of Yield Map Data, Precision Agriculture, 6(2), 193-212" -US-Ne1,1700006690,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1007/S11119-005-1035-2 -US-Ne1,1700006690,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ne1,1700006033,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Richardson, A. D., Hollinger, D. Y., Burba, G. G., Davis, K. J., Flanagan, L. B., Katul, G. G., William Munger, J., Ricciuto, D. M., Stoy, P. C., Suyker, A. E., Verma, S. B., Wofsy, S. C. (2006) A Multi-Site Analysis Of Random Error In Tower-Based Measurements Of Carbon And Energy Fluxes, Agricultural And Forest Meteorology, 136(1-2), 1-18" -US-Ne1,1700006033,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2006.01.007 -US-Ne1,1700006033,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ne1,1700001812,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Simbahan, G. C., Dobermann, A., Goovaerts, P., Ping, J., Haddix, M. L. (2006) Fine-Resolution Mapping Of Soil Organic Carbon Based On Multivariate Secondary Data, Geoderma, 132(3-4), 471-489" -US-Ne1,1700001812,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.GEODERMA.2005.07.001 -US-Ne1,1700001812,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ne1,1700004473,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Simbahan, G. C., Dobermann, A., Ping, J. L. (2004) Screening Yield Monitor Data Improves Grain Yield Maps, Agronomy Journal, 96(4), 1091-1102" -US-Ne1,1700004473,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.2134/AGRONJ2004.1091 -US-Ne1,1700004473,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ne1,1700006771,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Sullivan, R. C., Cook, D. R., Ghate, V. P., Kotamarthi, V. R., Feng, Y. (2019) Improved Spatiotemporal Representativeness And Bias Reduction Of Satellite-Based Evapotranspiration Retrievals Via Use Of In Situ Meteorology And Constrained Canopy Surface Resistance, Journal Of Geophysical Research: Biogeosciences, 124(2), 342-352" -US-Ne1,1700006771,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018JG004744 -US-Ne1,1700006771,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ne1,1700001296,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Sullivan, R. C., Kotamarthi, V. R., Feng, Y. (2019) Recovering Evapotranspiration Trends From Biased CMIP5 Simulations And Sensitivity To Changing Climate Over North America, Journal Of Hydrometeorology, 20(8), 1619-1633" -US-Ne1,1700001296,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1175/JHM-D-18-0259.1 -US-Ne1,1700001296,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ne1,1700003051,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Suyker, A. E., Verma, S. B., Burba, G. G., Arkebauer, T. J. (2005) Gross Primary Production And Ecosystem Respiration Of Irrigated Maize And Irrigated Soybean During A Growing Season, Agricultural And Forest Meteorology, 131(3-4), 180-190" -US-Ne1,1700003051,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2005.05.007 -US-Ne1,1700003051,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ne1,1700002319,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Suyker, A., Verma, S., Burba, G., Arkebauer, T., Walters, D., Hubbard, K. (2004) Growing Season Carbon Dioxide Exchange In Irrigated And Rainfed Maize, Agricultural And Forest Meteorology, 124(1-2), 1-13" -US-Ne1,1700002319,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2004.01.011 -US-Ne1,1700002319,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ne1,1700005877,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Verma, S. B., Dobermann, A., Cassman, K. G., Walters, D. T., Knops, J. M., Arkebauer, T. J., Suyker, A. E., Burba, G. G., Amos, B., Yang, H., Ginting, D., Hubbard, K. G., Gitelson, A. A., Walter-Shea, E. A. (2005) Annual Carbon Dioxide Exchange In Irrigated And Rainfed Maize-Based Agroecosystems, Agricultural And Forest Meteorology, 131(1-2), 77-96" -US-Ne1,1700005877,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2005.05.003 -US-Ne1,1700005877,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ne1,1700005409,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Viña, A., Genebry, G.M., Gitelson, A. A. (2004) Satellite Monitoring Of Vegetation Dynamics: Sensitivity Enhancement By The Wide Dynamic Range Vegetation Index, Geophysical Research Letters, 31(4), 1-4" -US-Ne1,1700005409,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2003GL019034 -US-Ne1,1700005409,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ne1,1700003780,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Viña, A., Gitelson, A. A., Rundquist, D. C., Keydan, G., Leavitt, B., Schepers, J. (2004) Monitoring Maize (Zea Mays L.) Phenology With Remote Sensing, Agronomy Journal, 96(4), 1139-1147" -US-Ne1,1700003780,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.2134/AGRONJ2004.1139 -US-Ne1,1700003780,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ne1,1700002649,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Yang, H., Dobermann, A., Lindquist, J., Walters, D., Arkebauer, T., Cassman, K. (2004) Hybrid-Maize—A Maize Simulation Model That Combines Two Crop Modeling Approaches, Field Crops Research, 87(2-3), 131-154" -US-Ne1,1700002649,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.FCR.2003.10.003 -US-Ne1,1700002649,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ne1,1700005730,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Zhang, Q., Ficklin, D. L., Manzoni, S., Wang, L., Way, D., Phillips, R. P., Novick, K. A. (2019) Response Of Ecosystem Intrinsic Water Use Efficiency And Gross Primary Productivity To Rising Vapor Pressure Deficit, Environmental Research Letters, 14(7), 074023" -US-Ne1,1700005730,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1088/1748-9326/AB2603 -US-Ne1,1700005730,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ne1,8428,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,The overall goals are to investigate the C sequestration potential of major rainfed and irrigated agroecosystems in the north-central USA and to understand the biophysical controls on C sequestration. -US-Ne1,10132,GRP_SITE_CHAR,TERRAIN,Gentle slope (<2 %) -US-Ne1,7899,GRP_SITE_DESC,SITE_DESC,"The study site is one of three fields (all located within 1.6 km of each other) at the University of Nebraska Agricultural Research and Development Center near Mead, Nebraska. This site is irrigated with a center pivot system. Prior to the initiation of the study, the irrigated site had a 10-yr history of maize-soybean rotation under no-till. A tillage operation (disking) was done just prior to the 2001 planting to homogenize the top 0.1 m of soil, incorporate P and K fertilizers, as well as previously accumulated surface residues. Since the tillage operation, the site has been under no-till management until the harvest of 2005. Following harvest, a conservation-plow tillage operation was initiated where a small amount of N fertilizer is sprayed on the residue immediately prior to the plow operation. Approximately 1/3 of the crop residue is left on the surface. The post-harvest conservation-plow operation continues as the current practice." -US-Ne1,1612,GRP_SITE_FUNDING,SITE_FUNDING,DOE (OBER & EPSCoR) -US-Ne1,28042,GRP_SOIL_CHEM,SOIL_CHEM_C_ORG,30.7 -US-Ne1,28660,GRP_SOIL_CHEM,SOIL_CHEM_C_ORG,31.4 -US-Ne1,28661,GRP_SOIL_CHEM,SOIL_CHEM_C_ORG,35.4 -US-Ne1,29578,GRP_SOIL_CHEM,SOIL_CHEM_C_ORG,38 -US-Ne1,28042,GRP_SOIL_CHEM,SOIL_CHEM_N_TOT,2.8 -US-Ne1,28660,GRP_SOIL_CHEM,SOIL_CHEM_N_TOT,2.9 -US-Ne1,28661,GRP_SOIL_CHEM,SOIL_CHEM_N_TOT,3.2 -US-Ne1,29578,GRP_SOIL_CHEM,SOIL_CHEM_N_TOT,3.5 -US-Ne1,28719,GRP_SOIL_CHEM,SOIL_CHEM_PH_SALT,6.10 -US-Ne1,28885,GRP_SOIL_CHEM,SOIL_CHEM_PH_SALT,6.40 -US-Ne1,28661,GRP_SOIL_CHEM,SOIL_CHEM_BD,1.35 -US-Ne1,28042,GRP_SOIL_CHEM,SOIL_CHEM_BD,1.40 -US-Ne1,29578,GRP_SOIL_CHEM,SOIL_CHEM_BD,1.43 -US-Ne1,28660,GRP_SOIL_CHEM,SOIL_CHEM_BD,1.51 -US-Ne1,28661,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,0 -US-Ne1,28719,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,0 -US-Ne1,29578,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,0 -US-Ne1,28042,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,15 -US-Ne1,28660,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,15 -US-Ne1,28885,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,20 -US-Ne1,28661,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,15 -US-Ne1,29578,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,15 -US-Ne1,28719,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,20 -US-Ne1,28042,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,30 -US-Ne1,28660,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,30 -US-Ne1,28885,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,50 -US-Ne1,28660,GRP_SOIL_CHEM,SOIL_CHEM_DATE,20010420 -US-Ne1,28719,GRP_SOIL_CHEM,SOIL_CHEM_DATE,20010420 -US-Ne1,28885,GRP_SOIL_CHEM,SOIL_CHEM_DATE,20010420 -US-Ne1,29578,GRP_SOIL_CHEM,SOIL_CHEM_DATE,20010420 -US-Ne1,28042,GRP_SOIL_CHEM,SOIL_CHEM_DATE,20050425 -US-Ne1,28661,GRP_SOIL_CHEM,SOIL_CHEM_DATE,20050425 -US-Ne1,28787,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION,"Deep silty clay loams of: Yutan (fine-silty, mixed, superactive, mesic Mollic Hapludalfs), Tomek (fine, smectitic, mesic Pachic Argialbolls), Filbert (fine, smectitic, mesic Vertic Argialbolls), and Filmore (fine, smectitic, mesic Vertic Argialbolls)." -US-Ne1,28787,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION_TAXONOMY,Other -US-Ne1,27671,GRP_SOIL_DEPTH,SOIL_DEPTH,180 -US-Ne1,28886,GRP_SOIL_TEX,SOIL_TEX_SAND,11 -US-Ne1,28886,GRP_SOIL_TEX,SOIL_TEX_SILT,52 -US-Ne1,28886,GRP_SOIL_TEX,SOIL_TEX_CLAY,37 -US-Ne1,27171,GRP_SPP_O,SPP_O,ZEMAH (NRCS plant code) -US-Ne1,27172,GRP_SPP_O,SPP_O,ZEMAH (NRCS plant code) -US-Ne1,27471,GRP_SPP_O,SPP_O,ZEMAH (NRCS plant code) -US-Ne1,27719,GRP_SPP_O,SPP_O,ZEMAH (NRCS plant code) -US-Ne1,28925,GRP_SPP_O,SPP_O,ZEMAH (NRCS plant code) -US-Ne1,28926,GRP_SPP_O,SPP_O,ZEMAH (NRCS plant code) -US-Ne1,29608,GRP_SPP_O,SPP_O,ZEMAH (NRCS plant code) -US-Ne1,27171,GRP_SPP_O,SPP_O_PERC,100 -US-Ne1,27172,GRP_SPP_O,SPP_O_PERC,100 -US-Ne1,27471,GRP_SPP_O,SPP_O_PERC,100 -US-Ne1,27719,GRP_SPP_O,SPP_O_PERC,100 -US-Ne1,28925,GRP_SPP_O,SPP_O_PERC,100 -US-Ne1,28926,GRP_SPP_O,SPP_O_PERC,100 -US-Ne1,29608,GRP_SPP_O,SPP_O_PERC,100 -US-Ne1,28925,GRP_SPP_O,SPP_DATE,2001 -US-Ne1,28926,GRP_SPP_O,SPP_DATE,2002 -US-Ne1,29608,GRP_SPP_O,SPP_DATE,2003 -US-Ne1,27171,GRP_SPP_O,SPP_DATE,2004 -US-Ne1,27719,GRP_SPP_O,SPP_DATE,2005 -US-Ne1,27172,GRP_SPP_O,SPP_DATE,2006 -US-Ne1,27471,GRP_SPP_O,SPP_DATE,2007 -US-Ne1,1495,GRP_STATE,STATE,NE -US-Ne1,8331,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Andy Suyker -US-Ne1,8331,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Ne1,8331,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,asuyker1@unl.edu -US-Ne1,8331,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Nebraska - Lincoln -US-Ne1,8331,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"School of Natural Resource, 807 Hardin Hall,Lincoln, NE USA 68583-0728" -US-Ne1,87996,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Dan Hatch -US-Ne1,87996,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,DataManager -US-Ne1,87996,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,dhatch2@unl.edu -US-Ne1,87996,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Nebraska -US-Ne1,87996,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,805 Hardin Hall -US-Ne1,5241,GRP_URL,URL,http://csp.unl.edu/public/ -US-Ne1,24000403,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-Ne1 -US-Ne1,5336,GRP_UTC_OFFSET,UTC_OFFSET,-6 -US-Ne2,29376,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,0.397693 -US-Ne2,29376,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne2,29376,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne2,29376,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne2,29376,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20010529 -US-Ne2,29376,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne2,27438,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,1.10535 -US-Ne2,27438,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne2,27438,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne2,27438,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne2,27438,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20030606 -US-Ne2,27438,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne2,28673,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,1.14942 -US-Ne2,28673,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne2,28673,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne2,28673,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne2,28673,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20050531 -US-Ne2,28673,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne2,27688,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,10.6602 -US-Ne2,27688,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne2,27688,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne2,27688,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne2,27688,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20040708 -US-Ne2,27688,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne2,27781,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,1012.39 -US-Ne2,27781,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne2,27781,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne2,27781,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne2,27781,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20030912 -US-Ne2,27781,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne2,29371,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,1028.83 -US-Ne2,29371,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne2,29371,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne2,29371,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne2,29371,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20070927 -US-Ne2,29371,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne2,27789,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,105.228 -US-Ne2,27789,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne2,27789,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne2,27789,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne2,27789,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20070621 -US-Ne2,27789,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne2,27674,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,11.0062 -US-Ne2,27674,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne2,27674,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne2,27674,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne2,27674,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20060620 -US-Ne2,27674,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne2,29256,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,1145.93 -US-Ne2,29256,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne2,29256,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne2,29256,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne2,29256,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20070911 -US-Ne2,29256,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne2,29265,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,14.6292 -US-Ne2,29265,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne2,29265,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne2,29265,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne2,29265,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20020625 -US-Ne2,29265,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne2,29266,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,141.215 -US-Ne2,29266,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne2,29266,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne2,29266,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne2,29266,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20020724 -US-Ne2,29266,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne2,28044,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,147.128 -US-Ne2,28044,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne2,28044,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne2,28044,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne2,28044,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20060724 -US-Ne2,28044,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne2,29268,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,157.884 -US-Ne2,29268,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne2,29268,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne2,29268,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne2,29268,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20040813 -US-Ne2,29268,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne2,29574,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,163 -US-Ne2,29574,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Total -US-Ne2,29574,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne2,29574,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne2,29574,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20041013 -US-Ne2,29377,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,180.586 -US-Ne2,29377,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne2,29377,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne2,29377,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne2,29377,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20030707 -US-Ne2,29377,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne2,28897,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,19.464 -US-Ne2,28897,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne2,28897,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne2,28897,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne2,28897,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20070607 -US-Ne2,28897,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne2,28388,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,19.4998 -US-Ne2,28388,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne2,28388,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne2,28388,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne2,28388,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20060627 -US-Ne2,28388,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne2,28888,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,2.27066 -US-Ne2,28888,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne2,28888,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne2,28888,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne2,28888,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20060602 -US-Ne2,28888,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne2,27782,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,2.55942 -US-Ne2,27782,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne2,27782,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne2,27782,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne2,27782,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20040624 -US-Ne2,27782,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne2,28045,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,201.619 -US-Ne2,28045,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne2,28045,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne2,28045,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne2,28045,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20060731 -US-Ne2,28045,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne2,29585,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,204.608 -US-Ne2,29585,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne2,29585,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne2,29585,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne2,29585,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20070628 -US-Ne2,29585,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne2,27139,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,21.6319 -US-Ne2,27139,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne2,27139,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne2,27139,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne2,27139,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20050613 -US-Ne2,27139,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne2,28727,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,210.774 -US-Ne2,28727,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne2,28727,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne2,28727,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne2,28727,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20010709 -US-Ne2,28727,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne2,28672,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,250.808 -US-Ne2,28672,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne2,28672,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne2,28672,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne2,28672,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20040826 -US-Ne2,28672,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne2,27140,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,251.865 -US-Ne2,27140,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne2,27140,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne2,27140,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne2,27140,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20050706 -US-Ne2,27140,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne2,28670,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,251.943 -US-Ne2,28670,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne2,28670,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne2,28670,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne2,28670,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20020806 -US-Ne2,28670,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne2,27430,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,259.88 -US-Ne2,27430,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne2,27430,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne2,27430,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne2,27430,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20060809 -US-Ne2,27430,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne2,27425,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,268 -US-Ne2,27425,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Total -US-Ne2,27425,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne2,27425,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne2,27425,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20021010 -US-Ne2,28052,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,289.719 -US-Ne2,28052,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne2,28052,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne2,28052,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne2,28052,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20040930 -US-Ne2,28052,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne2,27686,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,29.1908 -US-Ne2,27686,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne2,27686,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne2,27686,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne2,27686,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20010621 -US-Ne2,27686,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne2,29267,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,293.25 -US-Ne2,29267,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne2,29267,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne2,29267,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne2,29267,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20030716 -US-Ne2,29267,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne2,29581,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,3.35063 -US-Ne2,29581,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne2,29581,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne2,29581,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne2,29581,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20020611 -US-Ne2,29581,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne2,28896,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,3.76646 -US-Ne2,28896,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne2,28896,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne2,28896,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne2,28896,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20070529 -US-Ne2,28896,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne2,28046,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,318.6 -US-Ne2,28046,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne2,28046,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne2,28046,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne2,28046,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20060815 -US-Ne2,28046,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne2,28728,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,321.189 -US-Ne2,28728,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne2,28728,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne2,28728,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne2,28728,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20010713 -US-Ne2,28728,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne2,29273,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,330.107 -US-Ne2,29273,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne2,29273,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne2,29273,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne2,29273,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20070710 -US-Ne2,29273,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne2,27131,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,337.497 -US-Ne2,27131,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne2,27131,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne2,27131,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne2,27131,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20060828 -US-Ne2,27131,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne2,27690,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,338.008 -US-Ne2,27690,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne2,27690,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne2,27690,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne2,27690,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20050713 -US-Ne2,27690,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne2,28389,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,343.779 -US-Ne2,28389,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne2,28389,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne2,28389,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne2,28389,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20061005 -US-Ne2,28389,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne2,28051,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,375.294 -US-Ne2,28051,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne2,28051,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne2,28051,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne2,28051,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20040916 -US-Ne2,28051,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne2,29579,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,386.734 -US-Ne2,29579,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne2,29579,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne2,29579,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne2,29579,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20060920 -US-Ne2,29579,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne2,27771,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,4.92941 -US-Ne2,27771,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne2,27771,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne2,27771,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne2,27771,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20060612 -US-Ne2,27771,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne2,28385,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,407 -US-Ne2,28385,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Total -US-Ne2,28385,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne2,28385,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne2,28385,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20051011 -US-Ne2,28050,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,408.681 -US-Ne2,28050,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne2,28050,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne2,28050,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne2,28050,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20020919 -US-Ne2,28050,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne2,27138,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,41.497 -US-Ne2,27138,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne2,27138,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne2,27138,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne2,27138,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20030624 -US-Ne2,27138,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne2,28739,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,42.7688 -US-Ne2,28739,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne2,28739,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne2,28739,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne2,28739,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20070614 -US-Ne2,28739,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne2,29378,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,427.385 -US-Ne2,29378,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne2,29378,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne2,29378,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne2,29378,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20030725 -US-Ne2,29378,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne2,27424,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,446 -US-Ne2,27424,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Total -US-Ne2,27424,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne2,27424,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne2,27424,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20011016 -US-Ne2,28655,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,454 -US-Ne2,28655,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Total -US-Ne2,28655,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne2,28655,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne2,28655,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20031020 -US-Ne2,28394,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,46.2959 -US-Ne2,28394,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne2,28394,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne2,28394,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne2,28394,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20040720 -US-Ne2,28394,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne2,28671,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,461.913 -US-Ne2,28671,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne2,28671,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne2,28671,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne2,28671,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20020910 -US-Ne2,28671,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne2,27675,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,48.4367 -US-Ne2,27675,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne2,27675,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne2,27675,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne2,27675,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20060707 -US-Ne2,27675,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne2,27778,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,481.841 -US-Ne2,27778,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne2,27778,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne2,27778,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne2,27778,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20010720 -US-Ne2,27778,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne2,29385,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,497.89 -US-Ne2,29385,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne2,29385,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne2,29385,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne2,29385,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20070718 -US-Ne2,29385,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne2,28395,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,511.146 -US-Ne2,28395,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne2,28395,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne2,28395,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne2,28395,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20050727 -US-Ne2,28395,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne2,27687,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,57.7363 -US-Ne2,27687,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne2,27687,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne2,27687,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne2,27687,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20020710 -US-Ne2,27687,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne2,28729,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,578.174 -US-Ne2,28729,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne2,28729,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne2,28729,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne2,28729,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20030806 -US-Ne2,28729,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne2,27783,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,619.156 -US-Ne2,27783,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne2,27783,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne2,27783,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne2,27783,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20050804 -US-Ne2,27783,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne2,29274,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,640.068 -US-Ne2,29274,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne2,29274,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne2,29274,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne2,29274,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20070725 -US-Ne2,29274,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne2,27136,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,7.77197 -US-Ne2,27136,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne2,27136,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne2,27136,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne2,27136,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20010613 -US-Ne2,27136,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne2,29254,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,75.9857 -US-Ne2,29254,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne2,29254,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne2,29254,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne2,29254,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20060714 -US-Ne2,29254,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne2,27784,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,751.889 -US-Ne2,27784,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne2,27784,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne2,27784,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne2,27784,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20050815 -US-Ne2,27784,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne2,27779,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,778.997 -US-Ne2,27779,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne2,27779,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne2,27779,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne2,27779,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20010809 -US-Ne2,27779,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne2,29264,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,791.896 -US-Ne2,29264,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne2,29264,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne2,29264,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne2,29264,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20010820 -US-Ne2,29264,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne2,27689,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,80.6233 -US-Ne2,27689,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne2,27689,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne2,27689,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne2,27689,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20040730 -US-Ne2,27689,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne2,27780,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,833.533 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-US-Ne2,26551,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-Ne2,23746,GRP_BIOMASS_CHEM,BIOMASS_SPP,(All) -US-Ne2,23881,GRP_BIOMASS_CHEM,BIOMASS_SPP,(All) -US-Ne2,23882,GRP_BIOMASS_CHEM,BIOMASS_SPP,(All) -US-Ne2,23883,GRP_BIOMASS_CHEM,BIOMASS_SPP,(All) -US-Ne2,24008,GRP_BIOMASS_CHEM,BIOMASS_SPP,(All) -US-Ne2,24010,GRP_BIOMASS_CHEM,BIOMASS_SPP,(All) -US-Ne2,24011,GRP_BIOMASS_CHEM,BIOMASS_SPP,(All) -US-Ne2,24123,GRP_BIOMASS_CHEM,BIOMASS_SPP,(All) -US-Ne2,24124,GRP_BIOMASS_CHEM,BIOMASS_SPP,(All) -US-Ne2,24125,GRP_BIOMASS_CHEM,BIOMASS_SPP,(All) -US-Ne2,24380,GRP_BIOMASS_CHEM,BIOMASS_SPP,(All) -US-Ne2,24381,GRP_BIOMASS_CHEM,BIOMASS_SPP,(All) -US-Ne2,24382,GRP_BIOMASS_CHEM,BIOMASS_SPP,(All) -US-Ne2,24384,GRP_BIOMASS_CHEM,BIOMASS_SPP,(All) -US-Ne2,24781,GRP_BIOMASS_CHEM,BIOMASS_SPP,(All) -US-Ne2,24911,GRP_BIOMASS_CHEM,BIOMASS_SPP,(All) -US-Ne2,24912,GRP_BIOMASS_CHEM,BIOMASS_SPP,(All) -US-Ne2,25034,GRP_BIOMASS_CHEM,BIOMASS_SPP,(All) -US-Ne2,25035,GRP_BIOMASS_CHEM,BIOMASS_SPP,(All) -US-Ne2,25037,GRP_BIOMASS_CHEM,BIOMASS_SPP,(All) -US-Ne2,25038,GRP_BIOMASS_CHEM,BIOMASS_SPP,(All) -US-Ne2,25165,GRP_BIOMASS_CHEM,BIOMASS_SPP,(All) -US-Ne2,25166,GRP_BIOMASS_CHEM,BIOMASS_SPP,(All) -US-Ne2,25555,GRP_BIOMASS_CHEM,BIOMASS_SPP,(All) -US-Ne2,25557,GRP_BIOMASS_CHEM,BIOMASS_SPP,(All) -US-Ne2,26058,GRP_BIOMASS_CHEM,BIOMASS_SPP,(All) -US-Ne2,26171,GRP_BIOMASS_CHEM,BIOMASS_SPP,(All) -US-Ne2,26422,GRP_BIOMASS_CHEM,BIOMASS_SPP,(All) -US-Ne2,26551,GRP_BIOMASS_CHEM,BIOMASS_SPP,(All) -US-Ne2,25037,GRP_BIOMASS_CHEM,BIOMASS_DATE,20010613 -US-Ne2,25038,GRP_BIOMASS_CHEM,BIOMASS_DATE,20010621 -US-Ne2,25557,GRP_BIOMASS_CHEM,BIOMASS_DATE,20010629 -US-Ne2,26422,GRP_BIOMASS_CHEM,BIOMASS_DATE,20010709 -US-Ne2,24010,GRP_BIOMASS_CHEM,BIOMASS_DATE,20010713 -US-Ne2,24384,GRP_BIOMASS_CHEM,BIOMASS_DATE,20010720 -US-Ne2,24011,GRP_BIOMASS_CHEM,BIOMASS_DATE,20010809 -US-Ne2,26551,GRP_BIOMASS_CHEM,BIOMASS_DATE,20010820 -US-Ne2,23746,GRP_BIOMASS_CHEM,BIOMASS_DATE,20020625 -US-Ne2,25165,GRP_BIOMASS_CHEM,BIOMASS_DATE,20020710 -US-Ne2,24008,GRP_BIOMASS_CHEM,BIOMASS_DATE,20020724 -US-Ne2,25166,GRP_BIOMASS_CHEM,BIOMASS_DATE,20020806 -US-Ne2,24123,GRP_BIOMASS_CHEM,BIOMASS_DATE,20020910 -US-Ne2,23881,GRP_BIOMASS_CHEM,BIOMASS_DATE,20020919 -US-Ne2,23882,GRP_BIOMASS_CHEM,BIOMASS_DATE,20030606 -US-Ne2,23883,GRP_BIOMASS_CHEM,BIOMASS_DATE,20030624 -US-Ne2,24781,GRP_BIOMASS_CHEM,BIOMASS_DATE,20030707 -US-Ne2,24911,GRP_BIOMASS_CHEM,BIOMASS_DATE,20030716 -US-Ne2,24380,GRP_BIOMASS_CHEM,BIOMASS_DATE,20030725 -US-Ne2,24124,GRP_BIOMASS_CHEM,BIOMASS_DATE,20030806 -US-Ne2,24381,GRP_BIOMASS_CHEM,BIOMASS_DATE,20030822 -US-Ne2,24912,GRP_BIOMASS_CHEM,BIOMASS_DATE,20030912 -US-Ne2,25034,GRP_BIOMASS_CHEM,BIOMASS_DATE,20040624 -US-Ne2,25555,GRP_BIOMASS_CHEM,BIOMASS_DATE,20040708 -US-Ne2,25035,GRP_BIOMASS_CHEM,BIOMASS_DATE,20040720 -US-Ne2,26058,GRP_BIOMASS_CHEM,BIOMASS_DATE,20040730 -US-Ne2,24125,GRP_BIOMASS_CHEM,BIOMASS_DATE,20040813 -US-Ne2,24382,GRP_BIOMASS_CHEM,BIOMASS_DATE,20040826 -US-Ne2,26171,GRP_BIOMASS_CHEM,BIOMASS_DATE,20040916 -US-Ne2,4231,GRP_CLIM_AVG,MAT,10.08 -US-Ne2,4231,GRP_CLIM_AVG,MAP,788.89 -US-Ne2,4231,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfa -US-Ne2,27000404,GRP_COUNTRY,COUNTRY,USA -US-Ne2,6214,GRP_DM_AGRICULTURE,DM_AGRICULTURE,Harvest -US-Ne2,6214,GRP_DM_AGRICULTURE,DM_DATE,20011024 -US-Ne2,6214,GRP_DM_AGRICULTURE,DM_COMMENT,Yield 213 bu/ac. ( 13.41 MG ha-1) MC% 18.8. -US-Ne2,5366,GRP_DM_AGRICULTURE,DM_AGRICULTURE,Harvest -US-Ne2,5366,GRP_DM_AGRICULTURE,DM_DATE,20011025 -US-Ne2,5366,GRP_DM_AGRICULTURE,DM_COMMENT,Yield 213 bu/ac. ( 13.41 MG ha-1) MC% 18.8. -US-Ne2,2811,GRP_DM_AGRICULTURE,DM_AGRICULTURE,Harvest -US-Ne2,2811,GRP_DM_AGRICULTURE,DM_DATE,20021007 -US-Ne2,2811,GRP_DM_AGRICULTURE,DM_COMMENT,58 bu/ac (3.99 MG ha-1) yield -US-Ne2,1113,GRP_DM_AGRICULTURE,DM_AGRICULTURE,Harvest -US-Ne2,1113,GRP_DM_AGRICULTURE,DM_DATE,20021008 -US-Ne2,1113,GRP_DM_AGRICULTURE,DM_COMMENT,58 bu/ac (3.99 MG ha-1) yield -US-Ne2,293,GRP_DM_AGRICULTURE,DM_AGRICULTURE,Harvest -US-Ne2,293,GRP_DM_AGRICULTURE,DM_DATE,20021009 -US-Ne2,293,GRP_DM_AGRICULTURE,DM_COMMENT,58 bu/ac (3.99 MG ha-1) yield -US-Ne2,7032,GRP_DM_AGRICULTURE,DM_AGRICULTURE,Harvest -US-Ne2,7032,GRP_DM_AGRICULTURE,DM_DATE,20031023 -US-Ne2,7032,GRP_DM_AGRICULTURE,DM_COMMENT,223 bu/ac ( 14.00 MG ha-1) corrected from 18.5% MC -US-Ne2,6198,GRP_DM_AGRICULTURE,DM_AGRICULTURE,Harvest -US-Ne2,6198,GRP_DM_AGRICULTURE,DM_DATE,20031024 -US-Ne2,6198,GRP_DM_AGRICULTURE,DM_COMMENT,223 bu/ac ( 14.00 MG ha-1) corrected from 18.5% MC -US-Ne2,7034,GRP_DM_AGRICULTURE,DM_AGRICULTURE,Harvest -US-Ne2,7034,GRP_DM_AGRICULTURE,DM_DATE,20041013 -US-Ne2,7034,GRP_DM_AGRICULTURE,DM_COMMENT,53.5 bu/acre corrected from 13% MC -US-Ne2,6199,GRP_DM_AGRICULTURE,DM_AGRICULTURE,Harvest -US-Ne2,6199,GRP_DM_AGRICULTURE,DM_DATE,20041018 -US-Ne2,6199,GRP_DM_AGRICULTURE,DM_COMMENT,53.5 bu/acre corrected from 13% MC -US-Ne2,7908,GRP_DM_AGRICULTURE,DM_AGRICULTURE,Harvest -US-Ne2,7908,GRP_DM_AGRICULTURE,DM_DATE,20041019 -US-Ne2,7908,GRP_DM_AGRICULTURE,DM_COMMENT,53.5 bu/acre corrected from 13% MC -US-Ne2,271,GRP_DM_AGRICULTURE,DM_AGRICULTURE,Harvest -US-Ne2,271,GRP_DM_AGRICULTURE,DM_DATE,20041025 -US-Ne2,271,GRP_DM_AGRICULTURE,DM_COMMENT,53.5 bu/acre corrected from 13% MC -US-Ne2,5353,GRP_DM_AGRICULTURE,DM_AGRICULTURE,Harvest -US-Ne2,5353,GRP_DM_AGRICULTURE,DM_DATE,20051017 -US-Ne2,5353,GRP_DM_AGRICULTURE,DM_COMMENT,210 bu/ac ( 13.18 MG ha-1)15.5% basis. 15.2% MC -US-Ne2,1099,GRP_DM_AGRICULTURE,DM_AGRICULTURE,Harvest -US-Ne2,1099,GRP_DM_AGRICULTURE,DM_DATE,20051018 -US-Ne2,1099,GRP_DM_AGRICULTURE,DM_COMMENT,210 bu/ac ( 13.18 MG ha-1)15.5% basis. 15.2% MC -US-Ne2,275,GRP_DM_AGRICULTURE,DM_AGRICULTURE,Harvest -US-Ne2,275,GRP_DM_AGRICULTURE,DM_DATE,20061003 -US-Ne2,275,GRP_DM_AGRICULTURE,DM_COMMENT,62.4 bu/ac as is 9.8% MC basis. -US-Ne2,6201,GRP_DM_AGRICULTURE,DM_AGRICULTURE,Harvest -US-Ne2,6201,GRP_DM_AGRICULTURE,DM_DATE,20061005 -US-Ne2,6201,GRP_DM_AGRICULTURE,DM_COMMENT,62.4 bu/ac as is 9.8% MC basis. -US-Ne2,1954,GRP_DM_AGRICULTURE,DM_AGRICULTURE,Harvest -US-Ne2,1954,GRP_DM_AGRICULTURE,DM_DATE,20061006 -US-Ne2,1954,GRP_DM_AGRICULTURE,DM_COMMENT,62.4 bu/ac as is 9.8% MC basis. -US-Ne2,8760,GRP_DM_AGRICULTURE,DM_AGRICULTURE,Harvest -US-Ne2,8760,GRP_DM_AGRICULTURE,DM_DATE,20071105 -US-Ne2,8760,GRP_DM_AGRICULTURE,DM_COMMENT,210.4 bu/ac 15.5% basis -US-Ne2,7917,GRP_DM_AGRICULTURE,DM_AGRICULTURE,Harvest -US-Ne2,7917,GRP_DM_AGRICULTURE,DM_DATE,20071106 -US-Ne2,7917,GRP_DM_AGRICULTURE,DM_COMMENT,210.4 bu/ac 15.5% basis -US-Ne2,1110,GRP_DM_FERT_M,DM_FERT_M,N -US-Ne2,1110,GRP_DM_FERT_M,DM_DATE,20010514 -US-Ne2,1110,GRP_DM_FERT_M,DM_COMMENT,"28% UAN 114lb N/ac( 127.68 kg N ha-1 ) North; 76 lb/ac ( 85.12 kg N ha-1 ) South," -US-Ne2,292,GRP_DM_FERT_M,DM_FERT_M,N -US-Ne2,292,GRP_DM_FERT_M,DM_DATE,20010619 -US-Ne2,292,GRP_DM_FERT_M,DM_COMMENT,30 lb N/ac( 33.60 kg N ha-1 ) 28% UAN with 0.17 in -US-Ne2,7052,GRP_DM_FERT_M,DM_FERT_M,N -US-Ne2,7052,GRP_DM_FERT_M,DM_DATE,20010703 -US-Ne2,7052,GRP_DM_FERT_M,DM_COMMENT,30.6 lb N/ac ( 34.27 kg N ha-1 ) 28%UAN with 0.17 in water -US-Ne2,9636,GRP_DM_FERT_M,DM_FERT_M,N -US-Ne2,9636,GRP_DM_FERT_M,DM_DATE,20030417 -US-Ne2,9636,GRP_DM_FERT_M,DM_COMMENT,28% UAN 99.9 lb N/ac ( 111.89 kg N ha-1 ) -US-Ne2,7056,GRP_DM_FERT_M,DM_FERT_M,N -US-Ne2,7056,GRP_DM_FERT_M,DM_DATE,20030421 -US-Ne2,7056,GRP_DM_FERT_M,DM_COMMENT,28% UAN 99.9 lb N/ac ( 111.89 kg N ha-1 ) -US-Ne2,1966,GRP_DM_FERT_M,DM_FERT_M,N -US-Ne2,1966,GRP_DM_FERT_M,DM_DATE,20030422 -US-Ne2,1966,GRP_DM_FERT_M,DM_COMMENT,28% UAN 99.9 lb N/ac ( 111.89 kg N ha-1 ) -US-Ne2,2812,GRP_DM_FERT_M,DM_FERT_M,N -US-Ne2,2812,GRP_DM_FERT_M,DM_DATE,20030619 -US-Ne2,2812,GRP_DM_FERT_M,DM_COMMENT,28% UAN 25.8 lb N/ac ( 28.89 kg N ha-1 )with 0.18 in water -US-Ne2,7932,GRP_DM_FERT_M,DM_FERT_M,N -US-Ne2,7932,GRP_DM_FERT_M,DM_DATE,20030708 -US-Ne2,7932,GRP_DM_FERT_M,DM_COMMENT,28% UAN 24.6 lb N/ac ( 27.55 kg N ha-1 ) with 0.18 in water -US-Ne2,3650,GRP_DM_FERT_M,DM_FERT_M,N -US-Ne2,3650,GRP_DM_FERT_M,DM_DATE,20030723 -US-Ne2,3650,GRP_DM_FERT_M,DM_COMMENT,28%UAN 50 lb N/ac ( 56 kg N ha-1 ) -US-Ne2,8757,GRP_DM_FERT_M,DM_FERT_M,N -US-Ne2,8757,GRP_DM_FERT_M,DM_DATE,20050426 -US-Ne2,8757,GRP_DM_FERT_M,DM_COMMENT,32% UAN 90 lb N/ac ( 100 kg N ha-1 ) -US-Ne2,9620,GRP_DM_FERT_M,DM_FERT_M,N -US-Ne2,9620,GRP_DM_FERT_M,DM_DATE,20050427 -US-Ne2,9620,GRP_DM_FERT_M,DM_COMMENT,32% UAN 90 lb N/ac ( 100 kg N ha-1 ) -US-Ne2,7036,GRP_DM_FERT_M,DM_FERT_M,N -US-Ne2,7036,GRP_DM_FERT_M,DM_DATE,20050614 -US-Ne2,7036,GRP_DM_FERT_M,DM_COMMENT,76 lb N/ac ( 85.12 kg N ha-1 ) 32%UAN -US-Ne2,1098,GRP_DM_FERT_M,DM_FERT_M,N -US-Ne2,1098,GRP_DM_FERT_M,DM_DATE,20050615 -US-Ne2,1098,GRP_DM_FERT_M,DM_COMMENT,35 lb N/ac ( 39.2 kg N ha-1 ) 32%UAN with 0.53 in water -US-Ne2,7909,GRP_DM_FERT_M,DM_FERT_M,N -US-Ne2,7909,GRP_DM_FERT_M,DM_DATE,20050705 -US-Ne2,7909,GRP_DM_FERT_M,DM_COMMENT,41lb N/ac ( 45.92 kg N ha-1 ) 32%UAN 0.5 in water -US-Ne2,7037,GRP_DM_FERT_M,DM_FERT_M,N -US-Ne2,7037,GRP_DM_FERT_M,DM_DATE,20070430 -US-Ne2,7037,GRP_DM_FERT_M,DM_COMMENT,103 lb N/ac as 32% UAN -US-Ne2,1955,GRP_DM_FERT_M,DM_FERT_M,N -US-Ne2,1955,GRP_DM_FERT_M,DM_DATE,20070501 -US-Ne2,1955,GRP_DM_FERT_M,DM_COMMENT,103 lb N/ac as 32% UAN -US-Ne2,7915,GRP_DM_FERT_M,DM_FERT_M,N -US-Ne2,7915,GRP_DM_FERT_M,DM_DATE,20070612 -US-Ne2,7915,GRP_DM_FERT_M,DM_COMMENT,"30 lb N/ac, 32%UAN.with 0.31in water" -US-Ne2,1956,GRP_DM_FERT_M,DM_FERT_M,N -US-Ne2,1956,GRP_DM_FERT_M,DM_DATE,20070627 -US-Ne2,1956,GRP_DM_FERT_M,DM_COMMENT,30.7 lb N/ac 32%UAN -US-Ne2,3652,GRP_DM_GENERAL,DM_GENERAL,Other -US-Ne2,3652,GRP_DM_GENERAL,DM_DATE,20031027 -US-Ne2,3652,GRP_DM_GENERAL,DM_COMMENT,cattle-intrusion -US-Ne2,4493,GRP_DM_PESTICIDE,DM_PESTICIDE,Other -US-Ne2,4493,GRP_DM_PESTICIDE,DM_DATE,20010514 -US-Ne2,4493,GRP_DM_PESTICIDE,DM_COMMENT,"Axiom 15oz & Atrazine 1 lb/ac, Balance PRO .75oz/ac" -US-Ne2,6213,GRP_DM_PESTICIDE,DM_PESTICIDE,Other -US-Ne2,6213,GRP_DM_PESTICIDE,DM_DATE,20010616 -US-Ne2,6213,GRP_DM_PESTICIDE,DM_COMMENT,"Calisto (mesotrine) 3oz/ac., Atrazine 0.5 lb/ac, COC 0.1 gal/ac., AMS (ammonium Sulfate) 0.9 lb/ac" -US-Ne2,7054,GRP_DM_PESTICIDE,DM_PESTICIDE,Other -US-Ne2,7054,GRP_DM_PESTICIDE,DM_DATE,20020607 -US-Ne2,7054,GRP_DM_PESTICIDE,DM_COMMENT,"Glyphos 40oz/ac., NIS 6.4oz/ac AMS (ammonium sulfate) 1.7lb/ac." -US-Ne2,3661,GRP_DM_PESTICIDE,DM_PESTICIDE,Other -US-Ne2,3661,GRP_DM_PESTICIDE,DM_DATE,20020717 -US-Ne2,3661,GRP_DM_PESTICIDE,DM_COMMENT,Gylphos 1 qt/ac -US-Ne2,5351,GRP_DM_PESTICIDE,DM_PESTICIDE,Other -US-Ne2,5351,GRP_DM_PESTICIDE,DM_DATE,20030515 -US-Ne2,5351,GRP_DM_PESTICIDE,DM_COMMENT,"Harness Xtra 5.6L 1.8 qt/ac, BalancePRO 2 oz/ac, Roundup II 20 oz/ac, AMS (ammonium sulfate) 2lb/ac" -US-Ne2,8752,GRP_DM_PESTICIDE,DM_PESTICIDE,Other -US-Ne2,8752,GRP_DM_PESTICIDE,DM_DATE,20030718 -US-Ne2,4476,GRP_DM_PESTICIDE,DM_PESTICIDE,Other -US-Ne2,4476,GRP_DM_PESTICIDE,DM_DATE,20040607 -US-Ne2,4476,GRP_DM_PESTICIDE,DM_COMMENT,Roundup Original Max 26 oz/ac -US-Ne2,269,GRP_DM_PESTICIDE,DM_PESTICIDE,Other -US-Ne2,269,GRP_DM_PESTICIDE,DM_DATE,20040712 -US-Ne2,269,GRP_DM_PESTICIDE,DM_COMMENT,Roundup Original Max 26 oz/ac -US-Ne2,6200,GRP_DM_PESTICIDE,DM_PESTICIDE,Other -US-Ne2,6200,GRP_DM_PESTICIDE,DM_DATE,20050504 -US-Ne2,6200,GRP_DM_PESTICIDE,DM_COMMENT,"Keystone 2.6 qt/ac, Hornet 3.0 oz/ac, 2,4D 4LV 0.5pt/ac, COC 1.0pt/ac" -US-Ne2,9623,GRP_DM_PESTICIDE,DM_PESTICIDE,Other -US-Ne2,9623,GRP_DM_PESTICIDE,DM_DATE,20060419 -US-Ne2,9623,GRP_DM_PESTICIDE,DM_COMMENT,"Canopy 3.5 oz/ac, 2-4D 4LV 0.5pt/ac, Crop Oil 0.5 pt/ac" -US-Ne2,3653,GRP_DM_PESTICIDE,DM_PESTICIDE,Other -US-Ne2,3653,GRP_DM_PESTICIDE,DM_DATE,20060621 -US-Ne2,3653,GRP_DM_PESTICIDE,DM_COMMENT,"GlyStarPlus(glyphosate) 32 oz, AMS 2 lb, NIS 1.6 oz" -US-Ne2,2801,GRP_DM_PESTICIDE,DM_PESTICIDE,Other -US-Ne2,2801,GRP_DM_PESTICIDE,DM_DATE,20060623 -US-Ne2,2801,GRP_DM_PESTICIDE,DM_COMMENT,"GlyStarPlus(glyphosate) 48 oz, AMS 2 lb, NIS 1.6 oz" -US-Ne2,1100,GRP_DM_PESTICIDE,DM_PESTICIDE,Other -US-Ne2,1100,GRP_DM_PESTICIDE,DM_DATE,20060815 -US-Ne2,1100,GRP_DM_PESTICIDE,DM_COMMENT,"GlyStarPlus(glyphosate) 64 oz/acre, AMS 2 lb/acre, NIS 1.6 oz/acre spot application 65 acre" -US-Ne2,1101,GRP_DM_PESTICIDE,DM_PESTICIDE,Other -US-Ne2,1101,GRP_DM_PESTICIDE,DM_DATE,20070502 -US-Ne2,1101,GRP_DM_PESTICIDE,DM_COMMENT,"Keystone 2.6qt/acre, 2-4D 0.5pt/acre, Glyphosate 1.5pt/acre, AMS 2 lb" -US-Ne2,7038,GRP_DM_PESTICIDE,DM_PESTICIDE,Other -US-Ne2,7038,GRP_DM_PESTICIDE,DM_DATE,20070611 -US-Ne2,7038,GRP_DM_PESTICIDE,DM_COMMENT,"Impact 0.5oz, AtrazineDF .25lb, MSO 1.25pt/acre, AMS 1.2lb/acre" -US-Ne2,8759,GRP_DM_PESTICIDE,DM_PESTICIDE,Other -US-Ne2,8759,GRP_DM_PESTICIDE,DM_DATE,20070722 -US-Ne2,8759,GRP_DM_PESTICIDE,DM_COMMENT,"Stratego 10oz/acre, NIS 32oz/acre 124.7 acres" -US-Ne2,9634,GRP_DM_PLANTING,DM_PLANTING,Sowing crop seeds -US-Ne2,9634,GRP_DM_PLANTING,DM_DATE,20010511 -US-Ne2,9634,GRP_DM_PLANTING,DM_COMMENT,"Maize Pioneer 33P67, 33P66 non-Bt (refuge), North half - 33,221 seed/ac ( 82,087 seed ha-1), south half - 34,214 seed/ac ( 84,541 seed ha-1)" -US-Ne2,1112,GRP_DM_PLANTING,DM_PLANTING,Sowing crop seeds -US-Ne2,1112,GRP_DM_PLANTING,DM_DATE,20020520 -US-Ne2,1112,GRP_DM_PLANTING,DM_COMMENT,"soybean Asgrow 2703 Roundup Ready 150,000 seed/ac (370,644 seed ha-1 )," -US-Ne2,9619,GRP_DM_PLANTING,DM_PLANTING,Sowing crop seeds -US-Ne2,9619,GRP_DM_PLANTING,DM_DATE,20030514 -US-Ne2,9619,GRP_DM_PLANTING,DM_COMMENT,"Maize Pioneer 33B51 BT Gaucho Treated 1489 seed/lb, 34,128 seeds/ac ( 84,329 seed ha-1) 62.6ac, JD7210/JD1750 36,020 seeds/ac ( 89,004 seed ha-1) 68.6ac" -US-Ne2,7033,GRP_DM_PLANTING,DM_PLANTING,Sowing crop seeds -US-Ne2,7033,GRP_DM_PLANTING,DM_DATE,20040602 -US-Ne2,7033,GRP_DM_PLANTING,DM_COMMENT,"soybean Pioneer 93B09 150,000 seed/ac ( 370,644 seed ha-1)." -US-Ne2,9621,GRP_DM_PLANTING,DM_PLANTING,Sowing crop seeds -US-Ne2,9621,GRP_DM_PLANTING,DM_DATE,20050502 -US-Ne2,9621,GRP_DM_PLANTING,DM_COMMENT,"Maize Pioneer 33B51 BT Poncho250 treated corn 33,671 seed/ac ( 83,200 seed ha-1)" -US-Ne2,7911,GRP_DM_PLANTING,DM_PLANTING,Sowing crop seeds -US-Ne2,7911,GRP_DM_PLANTING,DM_DATE,20060512 -US-Ne2,7911,GRP_DM_PLANTING,DM_COMMENT,"Soybean Pioneer 93M11 150,000 seed/ac ( 370,644 seed ha-1)." -US-Ne2,7914,GRP_DM_PLANTING,DM_PLANTING,Sowing crop seeds -US-Ne2,7914,GRP_DM_PLANTING,DM_DATE,20070501 -US-Ne2,7914,GRP_DM_PLANTING,DM_COMMENT,"31,866 seed/acre Pioneer 31N28 YG Poncho25 treated seed" -US-Ne2,2802,GRP_DM_PLANTING,DM_PLANTING,Sowing crop seeds -US-Ne2,2802,GRP_DM_PLANTING,DM_DATE,20070502 -US-Ne2,2802,GRP_DM_PLANTING,DM_COMMENT,"31,866 seed/acre Pioneer 31N28 YG Poncho25 treated seed" -US-Ne2,3654,GRP_DM_PLANTING,DM_PLANTING,Sowing crop seeds -US-Ne2,3654,GRP_DM_PLANTING,DM_DATE,20070521 -US-Ne2,3654,GRP_DM_PLANTING,DM_COMMENT,"31,866 seed/acre Pioneer 31N28 YG Poncho25 treated seed" -US-Ne2,4481,GRP_DM_PLANTING,DM_PLANTING,Sowing crop seeds -US-Ne2,4481,GRP_DM_PLANTING,DM_DATE,20080514 -US-Ne2,8770,GRP_DM_TILL,DM_TILL,Conventional -US-Ne2,8770,GRP_DM_TILL,DM_DATE,20010418 -US-Ne2,8770,GRP_DM_TILL,DM_COMMENT,field-disk -US-Ne2,3660,GRP_DM_TILL,DM_TILL,Conventional -US-Ne2,3660,GRP_DM_TILL,DM_DATE,20010419 -US-Ne2,3660,GRP_DM_TILL,DM_COMMENT,field-disk -US-Ne2,9633,GRP_DM_TILL,DM_TILL,Conventional -US-Ne2,9633,GRP_DM_TILL,DM_DATE,20010510 -US-Ne2,9633,GRP_DM_TILL,DM_COMMENT,field-cultivator -US-Ne2,1965,GRP_DM_TILL,DM_TILL,Other -US-Ne2,1965,GRP_DM_TILL,DM_DATE,20011107 -US-Ne2,1965,GRP_DM_TILL,DM_COMMENT,subsoiler -US-Ne2,1111,GRP_DM_TILL,DM_TILL,Other -US-Ne2,1111,GRP_DM_TILL,DM_DATE,20011108 -US-Ne2,1111,GRP_DM_TILL,DM_COMMENT,stalk-shredder -US-Ne2,3662,GRP_DM_TILL,DM_TILL,Other -US-Ne2,3662,GRP_DM_TILL,DM_DATE,20021113 -US-Ne2,3662,GRP_DM_TILL,DM_COMMENT,track_fil -US-Ne2,1953,GRP_DM_TILL,DM_TILL,Other -US-Ne2,1953,GRP_DM_TILL,DM_DATE,20031120 -US-Ne2,1953,GRP_DM_TILL,DM_COMMENT,track_fil -US-Ne2,7918,GRP_DM_TILL,DM_TILL,Other -US-Ne2,7918,GRP_DM_TILL,DM_DATE,20071126 -US-Ne2,7918,GRP_DM_TILL,DM_COMMENT,subsoiler -US-Ne2,8771,GRP_DM_WATER,DM_WATER,Irrigation -US-Ne2,8771,GRP_DM_WATER,DM_DATE,20010625 -US-Ne2,7929,GRP_DM_WATER,DM_WATER,Irrigation -US-Ne2,7929,GRP_DM_WATER,DM_DATE,20010629 -US-Ne2,7929,GRP_DM_WATER,DM_COMMENT,0.81 in 66 Hr -US-Ne2,4494,GRP_DM_WATER,DM_WATER,Irrigation -US-Ne2,4494,GRP_DM_WATER,DM_DATE,20010704 -US-Ne2,7053,GRP_DM_WATER,DM_WATER,Irrigation -US-Ne2,7053,GRP_DM_WATER,DM_DATE,20010708 -US-Ne2,9635,GRP_DM_WATER,DM_WATER,Irrigation -US-Ne2,9635,GRP_DM_WATER,DM_DATE,20010713 -US-Ne2,8772,GRP_DM_WATER,DM_WATER,Irrigation -US-Ne2,8772,GRP_DM_WATER,DM_DATE,20020711 -US-Ne2,7930,GRP_DM_WATER,DM_WATER,Irrigation -US-Ne2,7930,GRP_DM_WATER,DM_DATE,20020717 -US-Ne2,8773,GRP_DM_WATER,DM_WATER,Irrigation -US-Ne2,8773,GRP_DM_WATER,DM_DATE,20020722 -US-Ne2,7931,GRP_DM_WATER,DM_WATER,Irrigation -US-Ne2,7931,GRP_DM_WATER,DM_DATE,20020730 -US-Ne2,7055,GRP_DM_WATER,DM_WATER,Irrigation -US-Ne2,7055,GRP_DM_WATER,DM_DATE,20020807 -US-Ne2,8774,GRP_DM_WATER,DM_WATER,Irrigation -US-Ne2,8774,GRP_DM_WATER,DM_DATE,20020814 -US-Ne2,6215,GRP_DM_WATER,DM_WATER,Irrigation -US-Ne2,6215,GRP_DM_WATER,DM_DATE,20030703 -US-Ne2,7029,GRP_DM_WATER,DM_WATER,Irrigation -US-Ne2,7029,GRP_DM_WATER,DM_DATE,20030712 -US-Ne2,6197,GRP_DM_WATER,DM_WATER,Irrigation -US-Ne2,6197,GRP_DM_WATER,DM_DATE,20030716 -US-Ne2,7030,GRP_DM_WATER,DM_WATER,Irrigation -US-Ne2,7030,GRP_DM_WATER,DM_DATE,20030720 -US-Ne2,8753,GRP_DM_WATER,DM_WATER,Irrigation -US-Ne2,8753,GRP_DM_WATER,DM_DATE,20030724 -US-Ne2,4475,GRP_DM_WATER,DM_WATER,Irrigation -US-Ne2,4475,GRP_DM_WATER,DM_DATE,20030728 -US-Ne2,2798,GRP_DM_WATER,DM_WATER,Irrigation -US-Ne2,2798,GRP_DM_WATER,DM_DATE,20030802 -US-Ne2,7906,GRP_DM_WATER,DM_WATER,Irrigation -US-Ne2,7906,GRP_DM_WATER,DM_DATE,20030806 -US-Ne2,3651,GRP_DM_WATER,DM_WATER,Irrigation -US-Ne2,3651,GRP_DM_WATER,DM_DATE,20030811 -US-Ne2,8754,GRP_DM_WATER,DM_WATER,Irrigation -US-Ne2,8754,GRP_DM_WATER,DM_DATE,20030818 -US-Ne2,7907,GRP_DM_WATER,DM_WATER,Irrigation -US-Ne2,7907,GRP_DM_WATER,DM_DATE,20030829 -US-Ne2,7031,GRP_DM_WATER,DM_WATER,Irrigation -US-Ne2,7031,GRP_DM_WATER,DM_DATE,20030902 -US-Ne2,8755,GRP_DM_WATER,DM_WATER,Irrigation -US-Ne2,8755,GRP_DM_WATER,DM_DATE,20040730 -US-Ne2,4477,GRP_DM_WATER,DM_WATER,Irrigation -US-Ne2,4477,GRP_DM_WATER,DM_DATE,20040804 -US-Ne2,2799,GRP_DM_WATER,DM_WATER,Irrigation -US-Ne2,2799,GRP_DM_WATER,DM_DATE,20040811 -US-Ne2,8756,GRP_DM_WATER,DM_WATER,Irrigation -US-Ne2,8756,GRP_DM_WATER,DM_DATE,20040817 -US-Ne2,1097,GRP_DM_WATER,DM_WATER,Irrigation -US-Ne2,1097,GRP_DM_WATER,DM_DATE,20040831 -US-Ne2,270,GRP_DM_WATER,DM_WATER,Irrigation -US-Ne2,270,GRP_DM_WATER,DM_DATE,20040917 -US-Ne2,7035,GRP_DM_WATER,DM_WATER,Irrigation -US-Ne2,7035,GRP_DM_WATER,DM_DATE,20050509 -US-Ne2,4478,GRP_DM_WATER,DM_WATER,Irrigation -US-Ne2,4478,GRP_DM_WATER,DM_DATE,20050623 -US-Ne2,9622,GRP_DM_WATER,DM_WATER,Irrigation -US-Ne2,9622,GRP_DM_WATER,DM_DATE,20050629 -US-Ne2,4479,GRP_DM_WATER,DM_WATER,Irrigation -US-Ne2,4479,GRP_DM_WATER,DM_DATE,20050708 -US-Ne2,272,GRP_DM_WATER,DM_WATER,Irrigation -US-Ne2,272,GRP_DM_WATER,DM_DATE,20050713 -US-Ne2,5352,GRP_DM_WATER,DM_WATER,Irrigation -US-Ne2,5352,GRP_DM_WATER,DM_DATE,20050718 -US-Ne2,5352,GRP_DM_WATER,DM_COMMENT,106 hr CW from 97. Completed 7/23 7:00am -US-Ne2,7910,GRP_DM_WATER,DM_WATER,Irrigation -US-Ne2,7910,GRP_DM_WATER,DM_DATE,20050724 -US-Ne2,273,GRP_DM_WATER,DM_WATER,Irrigation -US-Ne2,273,GRP_DM_WATER,DM_DATE,20050803 -US-Ne2,2800,GRP_DM_WATER,DM_WATER,Irrigation -US-Ne2,2800,GRP_DM_WATER,DM_DATE,20050818 -US-Ne2,4480,GRP_DM_WATER,DM_WATER,Irrigation -US-Ne2,4480,GRP_DM_WATER,DM_DATE,20050827 -US-Ne2,7912,GRP_DM_WATER,DM_WATER,Irrigation -US-Ne2,7912,GRP_DM_WATER,DM_DATE,20060625 -US-Ne2,274,GRP_DM_WATER,DM_WATER,Irrigation -US-Ne2,274,GRP_DM_WATER,DM_DATE,20060724 -US-Ne2,5354,GRP_DM_WATER,DM_WATER,Irrigation -US-Ne2,5354,GRP_DM_WATER,DM_DATE,20060729 -US-Ne2,7913,GRP_DM_WATER,DM_WATER,Irrigation -US-Ne2,7913,GRP_DM_WATER,DM_DATE,20060803 -US-Ne2,7039,GRP_DM_WATER,DM_WATER,Irrigation -US-Ne2,7039,GRP_DM_WATER,DM_DATE,20070628 -US-Ne2,8758,GRP_DM_WATER,DM_WATER,Irrigation -US-Ne2,8758,GRP_DM_WATER,DM_DATE,20070702 -US-Ne2,7916,GRP_DM_WATER,DM_WATER,Irrigation -US-Ne2,7916,GRP_DM_WATER,DM_DATE,20070707 -US-Ne2,3655,GRP_DM_WATER,DM_WATER,Irrigation -US-Ne2,3655,GRP_DM_WATER,DM_DATE,20070713 -US-Ne2,9624,GRP_DM_WATER,DM_WATER,Irrigation -US-Ne2,9624,GRP_DM_WATER,DM_DATE,20070718 -US-Ne2,7040,GRP_DM_WATER,DM_WATER,Irrigation -US-Ne2,7040,GRP_DM_WATER,DM_DATE,20070723 -US-Ne2,2803,GRP_DM_WATER,DM_WATER,Irrigation -US-Ne2,2803,GRP_DM_WATER,DM_DATE,20070728 -US-Ne2,1957,GRP_DM_WATER,DM_WATER,Irrigation -US-Ne2,1957,GRP_DM_WATER,DM_DATE,20070802 -US-Ne2,15665,GRP_DOI,DOI,10.17190/AMF/1246085 -US-Ne2,15665,GRP_DOI,DOI_CITATION,"Andy Suyker (2022), AmeriFlux BASE US-Ne2 Mead - irrigated maize-soybean rotation site, Ver. 12-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1246085" -US-Ne2,15665,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-Ne2,32144,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Ne2,32144,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Andy Suyker -US-Ne2,32144,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Ne2,32144,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,asuyker1@unl.edu -US-Ne2,32144,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of Nebraska - Lincoln -US-Ne2,32146,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,University of Nebraska - Lincoln -US-Ne2,32146,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-Ne2,32145,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,DOE (OBER & EPSCoR) -US-Ne2,32145,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-Ne2,9356,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Agriculture -US-Ne2,1239,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Ne2,1239,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-Ne2,1239,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,2001 -US-Ne2,1239,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Ne2,23000404,GRP_HEADER,SITE_NAME,Mead - irrigated maize-soybean rotation site -US-Ne2,88786,GRP_HEIGHTC,HEIGHTC,0.000 -US-Ne2,88786,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88786,GRP_HEIGHTC,HEIGHTC_DATE,20010518 -US-Ne2,88947,GRP_HEIGHTC,HEIGHTC,0.143 -US-Ne2,88947,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88947,GRP_HEIGHTC,HEIGHTC_DATE,20010529 -US-Ne2,88872,GRP_HEIGHTC,HEIGHTC,0.473 -US-Ne2,88872,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88872,GRP_HEIGHTC,HEIGHTC_DATE,20010613 -US-Ne2,88888,GRP_HEIGHTC,HEIGHTC,0.812 -US-Ne2,88888,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88888,GRP_HEIGHTC,HEIGHTC_DATE,20010621 -US-Ne2,88846,GRP_HEIGHTC,HEIGHTC,1.141 -US-Ne2,88846,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88846,GRP_HEIGHTC,HEIGHTC_DATE,20010629 -US-Ne2,88921,GRP_HEIGHTC,HEIGHTC,1.714 -US-Ne2,88921,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88921,GRP_HEIGHTC,HEIGHTC_DATE,20010709 -US-Ne2,88877,GRP_HEIGHTC,HEIGHTC,2.404 -US-Ne2,88877,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88877,GRP_HEIGHTC,HEIGHTC_DATE,20010713 -US-Ne2,88836,GRP_HEIGHTC,HEIGHTC,2.886 -US-Ne2,88836,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88836,GRP_HEIGHTC,HEIGHTC_DATE,20010720 -US-Ne2,88954,GRP_HEIGHTC,HEIGHTC,3.334 -US-Ne2,88954,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88954,GRP_HEIGHTC,HEIGHTC_DATE,20010809 -US-Ne2,88965,GRP_HEIGHTC,HEIGHTC,3.430 -US-Ne2,88965,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88965,GRP_HEIGHTC,HEIGHTC_DATE,20010820 -US-Ne2,88864,GRP_HEIGHTC,HEIGHTC,0.000 -US-Ne2,88864,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88864,GRP_HEIGHTC,HEIGHTC_DATE,20020528 -US-Ne2,88805,GRP_HEIGHTC,HEIGHTC,0.115 -US-Ne2,88805,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88805,GRP_HEIGHTC,HEIGHTC_DATE,20020611 -US-Ne2,88840,GRP_HEIGHTC,HEIGHTC,0.252 -US-Ne2,88840,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88840,GRP_HEIGHTC,HEIGHTC_DATE,20020625 -US-Ne2,88886,GRP_HEIGHTC,HEIGHTC,0.453 -US-Ne2,88886,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88886,GRP_HEIGHTC,HEIGHTC_DATE,20020710 -US-Ne2,88890,GRP_HEIGHTC,HEIGHTC,0.725 -US-Ne2,88890,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88890,GRP_HEIGHTC,HEIGHTC_DATE,20020724 -US-Ne2,88889,GRP_HEIGHTC,HEIGHTC,1.000 -US-Ne2,88889,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88889,GRP_HEIGHTC,HEIGHTC_DATE,20020806 -US-Ne2,88907,GRP_HEIGHTC,HEIGHTC,1.002 -US-Ne2,88907,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88907,GRP_HEIGHTC,HEIGHTC_DATE,20020910 -US-Ne2,88812,GRP_HEIGHTC,HEIGHTC,0.959 -US-Ne2,88812,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88812,GRP_HEIGHTC,HEIGHTC_DATE,20020919 -US-Ne2,88847,GRP_HEIGHTC,HEIGHTC,0.000 -US-Ne2,88847,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88847,GRP_HEIGHTC,HEIGHTC_DATE,20030525 -US-Ne2,88832,GRP_HEIGHTC,HEIGHTC,0.235 -US-Ne2,88832,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88832,GRP_HEIGHTC,HEIGHTC_DATE,20030606 -US-Ne2,88904,GRP_HEIGHTC,HEIGHTC,0.943 -US-Ne2,88904,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88904,GRP_HEIGHTC,HEIGHTC_DATE,20030624 -US-Ne2,88920,GRP_HEIGHTC,HEIGHTC,1.651 -US-Ne2,88920,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88920,GRP_HEIGHTC,HEIGHTC_DATE,20030707 -US-Ne2,88918,GRP_HEIGHTC,HEIGHTC,2.306 -US-Ne2,88918,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88918,GRP_HEIGHTC,HEIGHTC_DATE,20030716 -US-Ne2,88867,GRP_HEIGHTC,HEIGHTC,2.812 -US-Ne2,88867,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88867,GRP_HEIGHTC,HEIGHTC_DATE,20030725 -US-Ne2,88800,GRP_HEIGHTC,HEIGHTC,2.869 -US-Ne2,88800,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88800,GRP_HEIGHTC,HEIGHTC_DATE,20030806 -US-Ne2,88881,GRP_HEIGHTC,HEIGHTC,2.863 -US-Ne2,88881,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88881,GRP_HEIGHTC,HEIGHTC_DATE,20030822 -US-Ne2,88774,GRP_HEIGHTC,HEIGHTC,2.889 -US-Ne2,88774,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88774,GRP_HEIGHTC,HEIGHTC_DATE,20030912 -US-Ne2,88792,GRP_HEIGHTC,HEIGHTC,0.000 -US-Ne2,88792,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88792,GRP_HEIGHTC,HEIGHTC_DATE,20040608 -US-Ne2,88829,GRP_HEIGHTC,HEIGHTC,0.100 -US-Ne2,88829,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88829,GRP_HEIGHTC,HEIGHTC_DATE,20040624 -US-Ne2,88927,GRP_HEIGHTC,HEIGHTC,0.186 -US-Ne2,88927,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88927,GRP_HEIGHTC,HEIGHTC_DATE,20040708 -US-Ne2,88934,GRP_HEIGHTC,HEIGHTC,0.360 -US-Ne2,88934,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88934,GRP_HEIGHTC,HEIGHTC_DATE,20040720 -US-Ne2,88775,GRP_HEIGHTC,HEIGHTC,0.502 -US-Ne2,88775,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88775,GRP_HEIGHTC,HEIGHTC_DATE,20040730 -US-Ne2,88925,GRP_HEIGHTC,HEIGHTC,0.776 -US-Ne2,88925,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88925,GRP_HEIGHTC,HEIGHTC_DATE,20040813 -US-Ne2,88826,GRP_HEIGHTC,HEIGHTC,0.904 -US-Ne2,88826,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88826,GRP_HEIGHTC,HEIGHTC_DATE,20040826 -US-Ne2,88943,GRP_HEIGHTC,HEIGHTC,0.847 -US-Ne2,88943,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88943,GRP_HEIGHTC,HEIGHTC_DATE,20040916 -US-Ne2,88819,GRP_HEIGHTC,HEIGHTC,0.000 -US-Ne2,88819,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88819,GRP_HEIGHTC,HEIGHTC_DATE,20050514 -US-Ne2,88780,GRP_HEIGHTC,HEIGHTC,0.222 -US-Ne2,88780,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88780,GRP_HEIGHTC,HEIGHTC_DATE,20050531 -US-Ne2,88810,GRP_HEIGHTC,HEIGHTC,0.745 -US-Ne2,88810,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88810,GRP_HEIGHTC,HEIGHTC_DATE,20050613 -US-Ne2,88892,GRP_HEIGHTC,HEIGHTC,1.240 -US-Ne2,88892,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88892,GRP_HEIGHTC,HEIGHTC_DATE,20050623 -US-Ne2,88773,GRP_HEIGHTC,HEIGHTC,2.045 -US-Ne2,88773,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88773,GRP_HEIGHTC,HEIGHTC_DATE,20050706 -US-Ne2,88866,GRP_HEIGHTC,HEIGHTC,2.428 -US-Ne2,88866,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88866,GRP_HEIGHTC,HEIGHTC_DATE,20050713 -US-Ne2,88816,GRP_HEIGHTC,HEIGHTC,2.704 -US-Ne2,88816,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88816,GRP_HEIGHTC,HEIGHTC_DATE,20050727 -US-Ne2,88789,GRP_HEIGHTC,HEIGHTC,2.694 -US-Ne2,88789,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88789,GRP_HEIGHTC,HEIGHTC_DATE,20050804 -US-Ne2,88896,GRP_HEIGHTC,HEIGHTC,2.695 -US-Ne2,88896,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88896,GRP_HEIGHTC,HEIGHTC_DATE,20050815 -US-Ne2,88784,GRP_HEIGHTC,HEIGHTC,0.000 -US-Ne2,88784,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88784,GRP_HEIGHTC,HEIGHTC_DATE,20060523 -US-Ne2,88782,GRP_HEIGHTC,HEIGHTC,0.095 -US-Ne2,88782,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88782,GRP_HEIGHTC,HEIGHTC_DATE,20060602 -US-Ne2,88797,GRP_HEIGHTC,HEIGHTC,0.137 -US-Ne2,88797,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88797,GRP_HEIGHTC,HEIGHTC_DATE,20060612 -US-Ne2,88844,GRP_HEIGHTC,HEIGHTC,0.205 -US-Ne2,88844,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88844,GRP_HEIGHTC,HEIGHTC_DATE,20060620 -US-Ne2,88898,GRP_HEIGHTC,HEIGHTC,0.238 -US-Ne2,88898,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88898,GRP_HEIGHTC,HEIGHTC_DATE,20060627 -US-Ne2,88945,GRP_HEIGHTC,HEIGHTC,0.413 -US-Ne2,88945,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88945,GRP_HEIGHTC,HEIGHTC_DATE,20060707 -US-Ne2,88813,GRP_HEIGHTC,HEIGHTC,0.562 -US-Ne2,88813,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88813,GRP_HEIGHTC,HEIGHTC_DATE,20060714 -US-Ne2,88772,GRP_HEIGHTC,HEIGHTC,0.717 -US-Ne2,88772,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88772,GRP_HEIGHTC,HEIGHTC_DATE,20060724 -US-Ne2,88855,GRP_HEIGHTC,HEIGHTC,0.930 -US-Ne2,88855,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88855,GRP_HEIGHTC,HEIGHTC_DATE,20060731 -US-Ne2,88903,GRP_HEIGHTC,HEIGHTC,1.042 -US-Ne2,88903,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88903,GRP_HEIGHTC,HEIGHTC_DATE,20060809 -US-Ne2,88905,GRP_HEIGHTC,HEIGHTC,1.050 -US-Ne2,88905,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88905,GRP_HEIGHTC,HEIGHTC_DATE,20060815 -US-Ne2,88857,GRP_HEIGHTC,HEIGHTC,1.032 -US-Ne2,88857,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88857,GRP_HEIGHTC,HEIGHTC_DATE,20060828 -US-Ne2,88933,GRP_HEIGHTC,HEIGHTC,0.940 -US-Ne2,88933,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88933,GRP_HEIGHTC,HEIGHTC_DATE,20060920 -US-Ne2,88962,GRP_HEIGHTC,HEIGHTC,0.963 -US-Ne2,88962,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88962,GRP_HEIGHTC,HEIGHTC_DATE,20061005 -US-Ne2,88818,GRP_HEIGHTC,HEIGHTC,0.000 -US-Ne2,88818,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88818,GRP_HEIGHTC,HEIGHTC_DATE,20070511 -US-Ne2,88809,GRP_HEIGHTC,HEIGHTC,0.341 -US-Ne2,88809,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88809,GRP_HEIGHTC,HEIGHTC_DATE,20070529 -US-Ne2,88795,GRP_HEIGHTC,HEIGHTC,0.567 -US-Ne2,88795,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88795,GRP_HEIGHTC,HEIGHTC_DATE,20070607 -US-Ne2,88777,GRP_HEIGHTC,HEIGHTC,0.879 -US-Ne2,88777,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88777,GRP_HEIGHTC,HEIGHTC_DATE,20070614 -US-Ne2,88853,GRP_HEIGHTC,HEIGHTC,1.241 -US-Ne2,88853,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88853,GRP_HEIGHTC,HEIGHTC_DATE,20070621 -US-Ne2,88917,GRP_HEIGHTC,HEIGHTC,1.807 -US-Ne2,88917,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88917,GRP_HEIGHTC,HEIGHTC_DATE,20070628 -US-Ne2,88924,GRP_HEIGHTC,HEIGHTC,2.552 -US-Ne2,88924,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88924,GRP_HEIGHTC,HEIGHTC_DATE,20070710 -US-Ne2,88811,GRP_HEIGHTC,HEIGHTC,2.993 -US-Ne2,88811,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88811,GRP_HEIGHTC,HEIGHTC_DATE,20070718 -US-Ne2,88796,GRP_HEIGHTC,HEIGHTC,3.048 -US-Ne2,88796,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88796,GRP_HEIGHTC,HEIGHTC_DATE,20070725 -US-Ne2,88960,GRP_HEIGHTC,HEIGHTC,3.053 -US-Ne2,88960,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88960,GRP_HEIGHTC,HEIGHTC_DATE,20070807 -US-Ne2,88807,GRP_HEIGHTC,HEIGHTC,0.000 -US-Ne2,88807,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88807,GRP_HEIGHTC,HEIGHTC_DATE,20080525 -US-Ne2,88952,GRP_HEIGHTC,HEIGHTC,0.072 -US-Ne2,88952,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88952,GRP_HEIGHTC,HEIGHTC_DATE,20080604 -US-Ne2,88885,GRP_HEIGHTC,HEIGHTC,0.115 -US-Ne2,88885,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88885,GRP_HEIGHTC,HEIGHTC_DATE,20080613 -US-Ne2,88963,GRP_HEIGHTC,HEIGHTC,0.123 -US-Ne2,88963,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88963,GRP_HEIGHTC,HEIGHTC_DATE,20080620 -US-Ne2,88955,GRP_HEIGHTC,HEIGHTC,0.203 -US-Ne2,88955,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88955,GRP_HEIGHTC,HEIGHTC_DATE,20080630 -US-Ne2,88908,GRP_HEIGHTC,HEIGHTC,0.315 -US-Ne2,88908,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88908,GRP_HEIGHTC,HEIGHTC_DATE,20080708 -US-Ne2,88949,GRP_HEIGHTC,HEIGHTC,0.352 -US-Ne2,88949,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88949,GRP_HEIGHTC,HEIGHTC_DATE,20080715 -US-Ne2,88869,GRP_HEIGHTC,HEIGHTC,0.532 -US-Ne2,88869,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88869,GRP_HEIGHTC,HEIGHTC_DATE,20080723 -US-Ne2,88860,GRP_HEIGHTC,HEIGHTC,0.757 -US-Ne2,88860,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88860,GRP_HEIGHTC,HEIGHTC_DATE,20080731 -US-Ne2,88849,GRP_HEIGHTC,HEIGHTC,0.812 -US-Ne2,88849,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88849,GRP_HEIGHTC,HEIGHTC_DATE,20080807 -US-Ne2,88913,GRP_HEIGHTC,HEIGHTC,0.905 -US-Ne2,88913,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88913,GRP_HEIGHTC,HEIGHTC_DATE,20080818 -US-Ne2,88967,GRP_HEIGHTC,HEIGHTC,0.887 -US-Ne2,88967,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88967,GRP_HEIGHTC,HEIGHTC_DATE,20080829 -US-Ne2,88874,GRP_HEIGHTC,HEIGHTC,0.805 -US-Ne2,88874,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88874,GRP_HEIGHTC,HEIGHTC_DATE,20080919 -US-Ne2,88966,GRP_HEIGHTC,HEIGHTC,0.807 -US-Ne2,88966,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88966,GRP_HEIGHTC,HEIGHTC_DATE,20080930 -US-Ne2,88804,GRP_HEIGHTC,HEIGHTC,0.000 -US-Ne2,88804,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88804,GRP_HEIGHTC,HEIGHTC_DATE,20090506 -US-Ne2,88793,GRP_HEIGHTC,HEIGHTC,0.198 -US-Ne2,88793,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88793,GRP_HEIGHTC,HEIGHTC_DATE,20090520 -US-Ne2,88820,GRP_HEIGHTC,HEIGHTC,0.332 -US-Ne2,88820,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88820,GRP_HEIGHTC,HEIGHTC_DATE,20090529 -US-Ne2,88802,GRP_HEIGHTC,HEIGHTC,0.530 -US-Ne2,88802,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88802,GRP_HEIGHTC,HEIGHTC_DATE,20090604 -US-Ne2,88824,GRP_HEIGHTC,HEIGHTC,0.672 -US-Ne2,88824,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88824,GRP_HEIGHTC,HEIGHTC_DATE,20090610 -US-Ne2,88845,GRP_HEIGHTC,HEIGHTC,1.029 -US-Ne2,88845,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88845,GRP_HEIGHTC,HEIGHTC_DATE,20090617 -US-Ne2,88884,GRP_HEIGHTC,HEIGHTC,1.695 -US-Ne2,88884,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88884,GRP_HEIGHTC,HEIGHTC_DATE,20090624 -US-Ne2,88928,GRP_HEIGHTC,HEIGHTC,2.113 -US-Ne2,88928,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88928,GRP_HEIGHTC,HEIGHTC_DATE,20090630 -US-Ne2,88940,GRP_HEIGHTC,HEIGHTC,2.751 -US-Ne2,88940,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88940,GRP_HEIGHTC,HEIGHTC_DATE,20090709 -US-Ne2,88893,GRP_HEIGHTC,HEIGHTC,3.216 -US-Ne2,88893,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88893,GRP_HEIGHTC,HEIGHTC_DATE,20090721 -US-Ne2,88882,GRP_HEIGHTC,HEIGHTC,3.302 -US-Ne2,88882,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88882,GRP_HEIGHTC,HEIGHTC_DATE,20090730 -US-Ne2,88897,GRP_HEIGHTC,HEIGHTC,3.323 -US-Ne2,88897,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88897,GRP_HEIGHTC,HEIGHTC_DATE,20090811 -US-Ne2,88817,GRP_HEIGHTC,HEIGHTC,0.000 -US-Ne2,88817,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88817,GRP_HEIGHTC,HEIGHTC_DATE,20100513 -US-Ne2,88848,GRP_HEIGHTC,HEIGHTC,0.173 -US-Ne2,88848,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88848,GRP_HEIGHTC,HEIGHTC_DATE,20100526 -US-Ne2,88815,GRP_HEIGHTC,HEIGHTC,0.337 -US-Ne2,88815,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88815,GRP_HEIGHTC,HEIGHTC_DATE,20100602 -US-Ne2,88912,GRP_HEIGHTC,HEIGHTC,1.165 -US-Ne2,88912,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88912,GRP_HEIGHTC,HEIGHTC_DATE,20100624 -US-Ne2,88830,GRP_HEIGHTC,HEIGHTC,1.453 -US-Ne2,88830,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88830,GRP_HEIGHTC,HEIGHTC_DATE,20100702 -US-Ne2,88932,GRP_HEIGHTC,HEIGHTC,2.204 -US-Ne2,88932,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88932,GRP_HEIGHTC,HEIGHTC_DATE,20100713 -US-Ne2,88841,GRP_HEIGHTC,HEIGHTC,2.563 -US-Ne2,88841,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88841,GRP_HEIGHTC,HEIGHTC_DATE,20100729 -US-Ne2,88942,GRP_HEIGHTC,HEIGHTC,2.550 -US-Ne2,88942,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88942,GRP_HEIGHTC,HEIGHTC_DATE,20100810 -US-Ne2,88919,GRP_HEIGHTC,HEIGHTC,0.000 -US-Ne2,88919,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88919,GRP_HEIGHTC,HEIGHTC_DATE,20110526 -US-Ne2,88842,GRP_HEIGHTC,HEIGHTC,0.156 -US-Ne2,88842,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88842,GRP_HEIGHTC,HEIGHTC_DATE,20110603 -US-Ne2,88887,GRP_HEIGHTC,HEIGHTC,0.343 -US-Ne2,88887,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88887,GRP_HEIGHTC,HEIGHTC_DATE,20110610 -US-Ne2,88806,GRP_HEIGHTC,HEIGHTC,0.805 -US-Ne2,88806,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88806,GRP_HEIGHTC,HEIGHTC_DATE,20110621 -US-Ne2,88948,GRP_HEIGHTC,HEIGHTC,1.242 -US-Ne2,88948,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88948,GRP_HEIGHTC,HEIGHTC_DATE,20110701 -US-Ne2,88876,GRP_HEIGHTC,HEIGHTC,2.059 -US-Ne2,88876,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88876,GRP_HEIGHTC,HEIGHTC_DATE,20110712 -US-Ne2,88799,GRP_HEIGHTC,HEIGHTC,2.634 -US-Ne2,88799,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88799,GRP_HEIGHTC,HEIGHTC_DATE,20110720 -US-Ne2,88839,GRP_HEIGHTC,HEIGHTC,2.772 -US-Ne2,88839,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88839,GRP_HEIGHTC,HEIGHTC_DATE,20110729 -US-Ne2,88798,GRP_HEIGHTC,HEIGHTC,2.807 -US-Ne2,88798,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88798,GRP_HEIGHTC,HEIGHTC_DATE,20110808 -US-Ne2,88823,GRP_HEIGHTC,HEIGHTC,0.000 -US-Ne2,88823,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88823,GRP_HEIGHTC,HEIGHTC_DATE,20120503 -US-Ne2,88915,GRP_HEIGHTC,HEIGHTC,0.136 -US-Ne2,88915,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88915,GRP_HEIGHTC,HEIGHTC_DATE,20120510 -US-Ne2,88899,GRP_HEIGHTC,HEIGHTC,0.303 -US-Ne2,88899,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88899,GRP_HEIGHTC,HEIGHTC_DATE,20120518 -US-Ne2,88929,GRP_HEIGHTC,HEIGHTC,0.517 -US-Ne2,88929,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88929,GRP_HEIGHTC,HEIGHTC_DATE,20120525 -US-Ne2,88837,GRP_HEIGHTC,HEIGHTC,0.895 -US-Ne2,88837,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88837,GRP_HEIGHTC,HEIGHTC_DATE,20120604 -US-Ne2,88870,GRP_HEIGHTC,HEIGHTC,1.292 -US-Ne2,88870,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88870,GRP_HEIGHTC,HEIGHTC_DATE,20120612 -US-Ne2,88803,GRP_HEIGHTC,HEIGHTC,1.788 -US-Ne2,88803,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88803,GRP_HEIGHTC,HEIGHTC_DATE,20120619 -US-Ne2,88909,GRP_HEIGHTC,HEIGHTC,2.037 -US-Ne2,88909,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88909,GRP_HEIGHTC,HEIGHTC_DATE,20120626 -US-Ne2,88944,GRP_HEIGHTC,HEIGHTC,2.441 -US-Ne2,88944,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88944,GRP_HEIGHTC,HEIGHTC_DATE,20120703 -US-Ne2,88926,GRP_HEIGHTC,HEIGHTC,2.557 -US-Ne2,88926,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88926,GRP_HEIGHTC,HEIGHTC_DATE,20120710 -US-Ne2,88959,GRP_HEIGHTC,HEIGHTC,2.610 -US-Ne2,88959,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88959,GRP_HEIGHTC,HEIGHTC_DATE,20120718 -US-Ne2,88850,GRP_HEIGHTC,HEIGHTC,2.583 -US-Ne2,88850,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88850,GRP_HEIGHTC,HEIGHTC_DATE,20120725 -US-Ne2,88835,GRP_HEIGHTC,HEIGHTC,0.000 -US-Ne2,88835,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88835,GRP_HEIGHTC,HEIGHTC_DATE,20130515 -US-Ne2,88956,GRP_HEIGHTC,HEIGHTC,0.184 -US-Ne2,88956,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88956,GRP_HEIGHTC,HEIGHTC_DATE,20130523 -US-Ne2,88788,GRP_HEIGHTC,HEIGHTC,0.348 -US-Ne2,88788,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88788,GRP_HEIGHTC,HEIGHTC_DATE,20130531 -US-Ne2,88879,GRP_HEIGHTC,HEIGHTC,0.572 -US-Ne2,88879,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88879,GRP_HEIGHTC,HEIGHTC_DATE,20130610 -US-Ne2,88862,GRP_HEIGHTC,HEIGHTC,1.015 -US-Ne2,88862,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88862,GRP_HEIGHTC,HEIGHTC_DATE,20130619 -US-Ne2,88941,GRP_HEIGHTC,HEIGHTC,1.708 -US-Ne2,88941,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88941,GRP_HEIGHTC,HEIGHTC_DATE,20130627 -US-Ne2,88779,GRP_HEIGHTC,HEIGHTC,2.068 -US-Ne2,88779,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88779,GRP_HEIGHTC,HEIGHTC_DATE,20130705 -US-Ne2,88801,GRP_HEIGHTC,HEIGHTC,2.394 -US-Ne2,88801,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88801,GRP_HEIGHTC,HEIGHTC_DATE,20130712 -US-Ne2,88930,GRP_HEIGHTC,HEIGHTC,2.689 -US-Ne2,88930,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88930,GRP_HEIGHTC,HEIGHTC_DATE,20130723 -US-Ne2,88873,GRP_HEIGHTC,HEIGHTC,2.626 -US-Ne2,88873,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88873,GRP_HEIGHTC,HEIGHTC_DATE,20130801 -US-Ne2,88910,GRP_HEIGHTC,HEIGHTC,2.668 -US-Ne2,88910,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88910,GRP_HEIGHTC,HEIGHTC_DATE,20130812 -US-Ne2,88950,GRP_HEIGHTC,HEIGHTC,0.000 -US-Ne2,88950,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88950,GRP_HEIGHTC,HEIGHTC_DATE,20140526 -US-Ne2,88787,GRP_HEIGHTC,HEIGHTC,0.083 -US-Ne2,88787,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88787,GRP_HEIGHTC,HEIGHTC_DATE,20140602 -US-Ne2,88783,GRP_HEIGHTC,HEIGHTC,0.148 -US-Ne2,88783,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88783,GRP_HEIGHTC,HEIGHTC_DATE,20140609 -US-Ne2,88861,GRP_HEIGHTC,HEIGHTC,0.163 -US-Ne2,88861,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88861,GRP_HEIGHTC,HEIGHTC_DATE,20140616 -US-Ne2,88838,GRP_HEIGHTC,HEIGHTC,0.272 -US-Ne2,88838,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88838,GRP_HEIGHTC,HEIGHTC_DATE,20140623 -US-Ne2,88785,GRP_HEIGHTC,HEIGHTC,0.333 -US-Ne2,88785,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88785,GRP_HEIGHTC,HEIGHTC_DATE,20140630 -US-Ne2,88961,GRP_HEIGHTC,HEIGHTC,0.442 -US-Ne2,88961,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88961,GRP_HEIGHTC,HEIGHTC_DATE,20140707 -US-Ne2,88825,GRP_HEIGHTC,HEIGHTC,0.588 -US-Ne2,88825,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88825,GRP_HEIGHTC,HEIGHTC_DATE,20140715 -US-Ne2,88859,GRP_HEIGHTC,HEIGHTC,0.680 -US-Ne2,88859,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88859,GRP_HEIGHTC,HEIGHTC_DATE,20140721 -US-Ne2,88894,GRP_HEIGHTC,HEIGHTC,0.762 -US-Ne2,88894,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88894,GRP_HEIGHTC,HEIGHTC_DATE,20140728 -US-Ne2,88858,GRP_HEIGHTC,HEIGHTC,0.850 -US-Ne2,88858,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88858,GRP_HEIGHTC,HEIGHTC_DATE,20140804 -US-Ne2,88834,GRP_HEIGHTC,HEIGHTC,0.978 -US-Ne2,88834,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88834,GRP_HEIGHTC,HEIGHTC_DATE,20140811 -US-Ne2,88946,GRP_HEIGHTC,HEIGHTC,1.057 -US-Ne2,88946,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88946,GRP_HEIGHTC,HEIGHTC_DATE,20140818 -US-Ne2,88863,GRP_HEIGHTC,HEIGHTC,1.008 -US-Ne2,88863,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88863,GRP_HEIGHTC,HEIGHTC_DATE,20140903 -US-Ne2,88938,GRP_HEIGHTC,HEIGHTC,0.918 -US-Ne2,88938,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88938,GRP_HEIGHTC,HEIGHTC_DATE,20140917 -US-Ne2,88856,GRP_HEIGHTC,HEIGHTC,0.908 -US-Ne2,88856,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88856,GRP_HEIGHTC,HEIGHTC_DATE,20140929 -US-Ne2,88827,GRP_HEIGHTC,HEIGHTC,0.000 -US-Ne2,88827,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88827,GRP_HEIGHTC,HEIGHTC_DATE,20150511 -US-Ne2,88901,GRP_HEIGHTC,HEIGHTC,0.114 -US-Ne2,88901,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88901,GRP_HEIGHTC,HEIGHTC_DATE,20150521 -US-Ne2,88814,GRP_HEIGHTC,HEIGHTC,0.175 -US-Ne2,88814,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88814,GRP_HEIGHTC,HEIGHTC_DATE,20150528 -US-Ne2,88883,GRP_HEIGHTC,HEIGHTC,0.291 -US-Ne2,88883,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88883,GRP_HEIGHTC,HEIGHTC_DATE,20150604 -US-Ne2,88935,GRP_HEIGHTC,HEIGHTC,0.568 -US-Ne2,88935,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean 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-US-Ne2,88871,GRP_HEIGHTC,HEIGHTC_DATE,20160711 -US-Ne2,88939,GRP_HEIGHTC,HEIGHTC,0.753 -US-Ne2,88939,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88939,GRP_HEIGHTC,HEIGHTC_DATE,20160718 -US-Ne2,88953,GRP_HEIGHTC,HEIGHTC,1.020 -US-Ne2,88953,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88953,GRP_HEIGHTC,HEIGHTC_DATE,20160725 -US-Ne2,88776,GRP_HEIGHTC,HEIGHTC,1.082 -US-Ne2,88776,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88776,GRP_HEIGHTC,HEIGHTC_DATE,20160801 -US-Ne2,88808,GRP_HEIGHTC,HEIGHTC,1.097 -US-Ne2,88808,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88808,GRP_HEIGHTC,HEIGHTC_DATE,20160808 -US-Ne2,88878,GRP_HEIGHTC,HEIGHTC,1.163 -US-Ne2,88878,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88878,GRP_HEIGHTC,HEIGHTC_DATE,20160815 -US-Ne2,88781,GRP_HEIGHTC,HEIGHTC,1.168 -US-Ne2,88781,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88781,GRP_HEIGHTC,HEIGHTC_DATE,20160823 -US-Ne2,88822,GRP_HEIGHTC,HEIGHTC,1.070 -US-Ne2,88822,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88822,GRP_HEIGHTC,HEIGHTC_DATE,20160912 -US-Ne2,88891,GRP_HEIGHTC,HEIGHTC,1.090 -US-Ne2,88891,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88891,GRP_HEIGHTC,HEIGHTC_DATE,20161003 -US-Ne2,88790,GRP_HEIGHTC,HEIGHTC,0.000 -US-Ne2,88790,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88790,GRP_HEIGHTC,HEIGHTC_DATE,20170529 -US-Ne2,88794,GRP_HEIGHTC,HEIGHTC,0.247 -US-Ne2,88794,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88794,GRP_HEIGHTC,HEIGHTC_DATE,20170602 -US-Ne2,88833,GRP_HEIGHTC,HEIGHTC,0.783 -US-Ne2,88833,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88833,GRP_HEIGHTC,HEIGHTC_DATE,20170614 -US-Ne2,88937,GRP_HEIGHTC,HEIGHTC,1.066 -US-Ne2,88937,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88937,GRP_HEIGHTC,HEIGHTC_DATE,20170621 -US-Ne2,88828,GRP_HEIGHTC,HEIGHTC,1.561 -US-Ne2,88828,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88828,GRP_HEIGHTC,HEIGHTC_DATE,20170630 -US-Ne2,88895,GRP_HEIGHTC,HEIGHTC,2.403 -US-Ne2,88895,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88895,GRP_HEIGHTC,HEIGHTC_DATE,20170710 -US-Ne2,88906,GRP_HEIGHTC,HEIGHTC,3.039 -US-Ne2,88906,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88906,GRP_HEIGHTC,HEIGHTC_DATE,20170720 -US-Ne2,88900,GRP_HEIGHTC,HEIGHTC,3.072 -US-Ne2,88900,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88900,GRP_HEIGHTC,HEIGHTC_DATE,20170727 -US-Ne2,88851,GRP_HEIGHTC,HEIGHTC,3.065 -US-Ne2,88851,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88851,GRP_HEIGHTC,HEIGHTC_DATE,20170807 -US-Ne2,88923,GRP_HEIGHTC,HEIGHTC,0.000 -US-Ne2,88923,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88923,GRP_HEIGHTC,HEIGHTC_DATE,20180521 -US-Ne2,88931,GRP_HEIGHTC,HEIGHTC,0.180 -US-Ne2,88931,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88931,GRP_HEIGHTC,HEIGHTC_DATE,20180608 -US-Ne2,88951,GRP_HEIGHTC,HEIGHTC,0.288 -US-Ne2,88951,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88951,GRP_HEIGHTC,HEIGHTC_DATE,20180614 -US-Ne2,88852,GRP_HEIGHTC,HEIGHTC,0.452 -US-Ne2,88852,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88852,GRP_HEIGHTC,HEIGHTC_DATE,20180621 -US-Ne2,88865,GRP_HEIGHTC,HEIGHTC,0.528 -US-Ne2,88865,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88865,GRP_HEIGHTC,HEIGHTC_DATE,20180626 -US-Ne2,88868,GRP_HEIGHTC,HEIGHTC,0.623 -US-Ne2,88868,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88868,GRP_HEIGHTC,HEIGHTC_DATE,20180702 -US-Ne2,88911,GRP_HEIGHTC,HEIGHTC,0.750 -US-Ne2,88911,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88911,GRP_HEIGHTC,HEIGHTC_DATE,20180710 -US-Ne2,88936,GRP_HEIGHTC,HEIGHTC,0.907 -US-Ne2,88936,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88936,GRP_HEIGHTC,HEIGHTC_DATE,20180718 -US-Ne2,88821,GRP_HEIGHTC,HEIGHTC,1.048 -US-Ne2,88821,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88821,GRP_HEIGHTC,HEIGHTC_DATE,20180726 -US-Ne2,88957,GRP_HEIGHTC,HEIGHTC,1.288 -US-Ne2,88957,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne2,88957,GRP_HEIGHTC,HEIGHTC_DATE,20180806 -US-Ne2,4467,GRP_IGBP,IGBP,CRO -US-Ne2,4467,GRP_IGBP,IGBP_COMMENT,Agriculture (maize-soybean rotation) 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-US-Ne2,26087,GRP_LAI,LAI_TOT,1.39734 -US-Ne2,26094,GRP_LAI,LAI_TOT,1.5238 -US-Ne2,26436,GRP_LAI,LAI_TOT,1.69183 -US-Ne2,25440,GRP_LAI,LAI_TOT,1.90678 -US-Ne2,26303,GRP_LAI,LAI_TOT,1.97117 -US-Ne2,26320,GRP_LAI,LAI_TOT,1.99633 -US-Ne2,26088,GRP_LAI,LAI_TOT,2.37816 -US-Ne2,26437,GRP_LAI,LAI_TOT,2.51022 -US-Ne2,25813,GRP_LAI,LAI_TOT,2.6713 -US-Ne2,25306,GRP_LAI,LAI_TOT,2.70311 -US-Ne2,25816,GRP_LAI,LAI_TOT,3.25249 -US-Ne2,24139,GRP_LAI,LAI_TOT,3.5635 -US-Ne2,25168,GRP_LAI,LAI_TOT,3.67849 -US-Ne2,25798,GRP_LAI,LAI_TOT,3.81424 -US-Ne2,25815,GRP_LAI,LAI_TOT,3.86329 -US-Ne2,26438,GRP_LAI,LAI_TOT,3.93665 -US-Ne2,24134,GRP_LAI,LAI_TOT,4.01763 -US-Ne2,26186,GRP_LAI,LAI_TOT,4.29642 -US-Ne2,26439,GRP_LAI,LAI_TOT,4.38551 -US-Ne2,26304,GRP_LAI,LAI_TOT,4.50872 -US-Ne2,26189,GRP_LAI,LAI_TOT,4.51449 -US-Ne2,25797,GRP_LAI,LAI_TOT,4.52538 -US-Ne2,25809,GRP_LAI,LAI_TOT,4.65184 -US-Ne2,26309,GRP_LAI,LAI_TOT,4.67463 -US-Ne2,25314,GRP_LAI,LAI_TOT,4.7252 -US-Ne2,26308,GRP_LAI,LAI_TOT,4.73861 -US-Ne2,26307,GRP_LAI,LAI_TOT,4.83557 -US-Ne2,26095,GRP_LAI,LAI_TOT,4.95206 -US-Ne2,25677,GRP_LAI,LAI_TOT,4.96215 -US-Ne2,25930,GRP_LAI,LAI_TOT,4.98742 -US-Ne2,26557,GRP_LAI,LAI_TOT,4.98819 -US-Ne2,25169,GRP_LAI,LAI_TOT,5.01522 -US-Ne2,26573,GRP_LAI,LAI_TOT,5.20154 -US-Ne2,25680,GRP_LAI,LAI_TOT,5.27396 -US-Ne2,25174,GRP_LAI,LAI_TOT,5.31653 -US-Ne2,25678,GRP_LAI,LAI_TOT,5.38302 -US-Ne2,25578,GRP_LAI,LAI_TOT,5.44315 -US-Ne2,25682,GRP_LAI,LAI_TOT,5.51353 -US-Ne2,25305,GRP_LAI,LAI_TOT,5.52805 -US-Ne2,26322,GRP_LAI,LAI_TOT,5.64467 -US-Ne2,25810,GRP_LAI,LAI_TOT,5.66873 -US-Ne2,25186,GRP_LAI,LAI_TOT,5.86785 -US-Ne2,25681,GRP_LAI,LAI_TOT,6.07038 -US-Ne2,25814,GRP_LAI,LAI_TOT,6.07975 -US-Ne2,5933,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-Ne2,5933,GRP_LAND_OWNERSHIP,LAND_OWNER,University of Nebraska -US-Ne2,27464,GRP_LMA,LMA,13.72 -US-Ne2,27464,GRP_LMA,LMA_SPP,ZEMAH (NRCS plant code) -US-Ne2,27464,GRP_LMA,LMA_DATE,20050531 -US-Ne2,29402,GRP_LMA,LMA,13.83 -US-Ne2,29402,GRP_LMA,LMA_SPP,GLYMA4 (NRCS plant code) -US-Ne2,29402,GRP_LMA,LMA_DATE,20040930 -US-Ne2,27798,GRP_LMA,LMA,14.29 -US-Ne2,27798,GRP_LMA,LMA_SPP,GLYMA4 (NRCS plant code) -US-Ne2,27798,GRP_LMA,LMA_DATE,20020710 -US-Ne2,28057,GRP_LMA,LMA,14.4036 -US-Ne2,28057,GRP_LMA,LMA_SPP,ZEMAH (NRCS plant code) -US-Ne2,28057,GRP_LMA,LMA_DATE,20070529 -US-Ne2,28758,GRP_LMA,LMA,14.5 -US-Ne2,28758,GRP_LMA,LMA_SPP,GLYMA4 (NRCS plant code) -US-Ne2,28758,GRP_LMA,LMA_DATE,20040720 -US-Ne2,28902,GRP_LMA,LMA,15.1153 -US-Ne2,28902,GRP_LMA,LMA_SPP,GLYMA4 (NRCS plant code) -US-Ne2,28902,GRP_LMA,LMA_DATE,20060920 -US-Ne2,28759,GRP_LMA,LMA,15.61 -US-Ne2,28759,GRP_LMA,LMA_SPP,GLYMA4 (NRCS plant code) -US-Ne2,28759,GRP_LMA,LMA_DATE,20040730 -US-Ne2,27161,GRP_LMA,LMA,16.11 -US-Ne2,27161,GRP_LMA,LMA_SPP,GLYMA4 (NRCS plant code) -US-Ne2,27161,GRP_LMA,LMA_DATE,20020724 -US-Ne2,27712,GRP_LMA,LMA,16.81 -US-Ne2,27712,GRP_LMA,LMA_SPP,GLYMA4 (NRCS plant code) -US-Ne2,27712,GRP_LMA,LMA_DATE,20020806 -US-Ne2,27162,GRP_LMA,LMA,16.87 -US-Ne2,27162,GRP_LMA,LMA_SPP,GLYMA4 (NRCS plant code) -US-Ne2,27162,GRP_LMA,LMA_DATE,20040813 -US-Ne2,27163,GRP_LMA,LMA,16.87 -US-Ne2,27163,GRP_LMA,LMA_SPP,GLYMA4 (NRCS plant code) -US-Ne2,27163,GRP_LMA,LMA_DATE,20040916 -US-Ne2,28917,GRP_LMA,LMA,16.9 -US-Ne2,28917,GRP_LMA,LMA_SPP,GLYMA4 (NRCS plant code) -US-Ne2,28917,GRP_LMA,LMA_DATE,20040708 -US-Ne2,28696,GRP_LMA,LMA,17.01 -US-Ne2,28696,GRP_LMA,LMA_SPP,ZEMAH (NRCS plant code) -US-Ne2,28696,GRP_LMA,LMA_DATE,20050613 -US-Ne2,28692,GRP_LMA,LMA,17.28 -US-Ne2,28692,GRP_LMA,LMA_SPP,ZEMAH (NRCS plant code) -US-Ne2,28692,GRP_LMA,LMA_DATE,20010613 -US-Ne2,29279,GRP_LMA,LMA,17.319 -US-Ne2,29279,GRP_LMA,LMA_SPP,GLYMA4 (NRCS plant code) -US-Ne2,29279,GRP_LMA,LMA_DATE,20060809 -US-Ne2,27154,GRP_LMA,LMA,17.3243 -US-Ne2,27154,GRP_LMA,LMA_SPP,GLYMA4 (NRCS plant code) -US-Ne2,27154,GRP_LMA,LMA_DATE,20060724 -US-Ne2,28681,GRP_LMA,LMA,17.3564 -US-Ne2,28681,GRP_LMA,LMA_SPP,GLYMA4 (NRCS plant code) -US-Ne2,28681,GRP_LMA,LMA_DATE,20060620 -US-Ne2,29598,GRP_LMA,LMA,17.47 -US-Ne2,29598,GRP_LMA,LMA_SPP,GLYMA4 (NRCS plant code) -US-Ne2,29598,GRP_LMA,LMA_DATE,20040826 -US-Ne2,27703,GRP_LMA,LMA,17.7273 -US-Ne2,27703,GRP_LMA,LMA_SPP,GLYMA4 (NRCS plant code) -US-Ne2,27703,GRP_LMA,LMA_DATE,20060731 -US-Ne2,28915,GRP_LMA,LMA,17.95 -US-Ne2,28915,GRP_LMA,LMA_SPP,GLYMA4 (NRCS plant code) -US-Ne2,28915,GRP_LMA,LMA_DATE,20020625 -US-Ne2,28683,GRP_LMA,LMA,18.1394 -US-Ne2,28683,GRP_LMA,LMA_SPP,GLYMA4 (NRCS plant code) -US-Ne2,28683,GRP_LMA,LMA_DATE,20060714 -US-Ne2,29390,GRP_LMA,LMA,18.5924 -US-Ne2,29390,GRP_LMA,LMA_SPP,GLYMA4 (NRCS plant code) -US-Ne2,29390,GRP_LMA,LMA_DATE,20060815 -US-Ne2,28693,GRP_LMA,LMA,18.74 -US-Ne2,28693,GRP_LMA,LMA_SPP,ZEMAH (NRCS plant code) -US-Ne2,28693,GRP_LMA,LMA_DATE,20010621 -US-Ne2,28067,GRP_LMA,LMA,18.88 -US-Ne2,28067,GRP_LMA,LMA_SPP,ZEMAH (NRCS plant code) -US-Ne2,28067,GRP_LMA,LMA_DATE,20030624 -US-Ne2,29286,GRP_LMA,LMA,18.88 -US-Ne2,29286,GRP_LMA,LMA_SPP,GLYMA4 (NRCS plant code) -US-Ne2,29286,GRP_LMA,LMA_DATE,20020910 -US-Ne2,27455,GRP_LMA,LMA,19.014 -US-Ne2,27455,GRP_LMA,LMA_SPP,GLYMA4 (NRCS plant code) -US-Ne2,27455,GRP_LMA,LMA_DATE,20060627 -US-Ne2,27459,GRP_LMA,LMA,19.115 -US-Ne2,27459,GRP_LMA,LMA_SPP,ZEMAH (NRCS plant code) -US-Ne2,27459,GRP_LMA,LMA_DATE,20070614 -US-Ne2,29597,GRP_LMA,LMA,19.32 -US-Ne2,29597,GRP_LMA,LMA_SPP,GLYMA4 (NRCS plant code) -US-Ne2,29597,GRP_LMA,LMA_DATE,20020919 -US-Ne2,28916,GRP_LMA,LMA,19.37 -US-Ne2,28916,GRP_LMA,LMA_SPP,GLYMA4 (NRCS plant code) -US-Ne2,28916,GRP_LMA,LMA_DATE,20040624 -US-Ne2,28747,GRP_LMA,LMA,19.4386 -US-Ne2,28747,GRP_LMA,LMA_SPP,GLYMA4 (NRCS plant code) -US-Ne2,28747,GRP_LMA,LMA_DATE,20060828 -US-Ne2,27463,GRP_LMA,LMA,19.86 -US-Ne2,27463,GRP_LMA,LMA_SPP,ZEMAH (NRCS plant code) -US-Ne2,27463,GRP_LMA,LMA_DATE,20030606 -US-Ne2,28058,GRP_LMA,LMA,20.1564 -US-Ne2,28058,GRP_LMA,LMA_SPP,ZEMAH (NRCS plant code) -US-Ne2,28058,GRP_LMA,LMA_DATE,20070607 -US-Ne2,28402,GRP_LMA,LMA,20.1725 -US-Ne2,28402,GRP_LMA,LMA_SPP,GLYMA4 (NRCS plant code) -US-Ne2,28402,GRP_LMA,LMA_DATE,20060612 -US-Ne2,27160,GRP_LMA,LMA,20.26 -US-Ne2,27160,GRP_LMA,LMA_SPP,ZEMAH (NRCS plant code) -US-Ne2,27160,GRP_LMA,LMA_DATE,20010629 -US-Ne2,27465,GRP_LMA,LMA,20.3 -US-Ne2,27465,GRP_LMA,LMA_SPP,ZEMAH (NRCS plant code) -US-Ne2,27465,GRP_LMA,LMA_DATE,20050623 -US-Ne2,27462,GRP_LMA,LMA,20.48 -US-Ne2,27462,GRP_LMA,LMA_SPP,ZEMAH (NRCS plant code) -US-Ne2,27462,GRP_LMA,LMA_DATE,20010529 -US-Ne2,28694,GRP_LMA,LMA,20.73 -US-Ne2,28694,GRP_LMA,LMA_SPP,ZEMAH (NRCS plant code) -US-Ne2,28694,GRP_LMA,LMA_DATE,20030707 -US-Ne2,28682,GRP_LMA,LMA,20.9623 -US-Ne2,28682,GRP_LMA,LMA_SPP,GLYMA4 (NRCS plant code) -US-Ne2,28682,GRP_LMA,LMA_DATE,20060707 -US-Ne2,29399,GRP_LMA,LMA,21.18 -US-Ne2,29399,GRP_LMA,LMA_SPP,ZEMAH (NRCS plant code) -US-Ne2,29399,GRP_LMA,LMA_DATE,20010709 -US-Ne2,28914,GRP_LMA,LMA,21.31 -US-Ne2,28914,GRP_LMA,LMA_SPP,GLYMA4 (NRCS plant code) -US-Ne2,28914,GRP_LMA,LMA_DATE,20020611 -US-Ne2,28413,GRP_LMA,LMA,21.69 -US-Ne2,28413,GRP_LMA,LMA_SPP,ZEMAH (NRCS plant code) -US-Ne2,28413,GRP_LMA,LMA_DATE,20010713 -US-Ne2,28407,GRP_LMA,LMA,22.6339 -US-Ne2,28407,GRP_LMA,LMA_SPP,ZEMAH (NRCS plant code) -US-Ne2,28407,GRP_LMA,LMA_DATE,20070628 -US-Ne2,27466,GRP_LMA,LMA,23.17 -US-Ne2,27466,GRP_LMA,LMA_SPP,ZEMAH (NRCS plant code) -US-Ne2,27466,GRP_LMA,LMA_DATE,20050706 -US-Ne2,29394,GRP_LMA,LMA,23.1785 -US-Ne2,29394,GRP_LMA,LMA_SPP,ZEMAH (NRCS plant code) -US-Ne2,29394,GRP_LMA,LMA_DATE,20070621 -US-Ne2,27797,GRP_LMA,LMA,23.22 -US-Ne2,27797,GRP_LMA,LMA_SPP,ZEMAH (NRCS plant code) -US-Ne2,27797,GRP_LMA,LMA_DATE,20010820 -US-Ne2,28695,GRP_LMA,LMA,23.64 -US-Ne2,28695,GRP_LMA,LMA_SPP,ZEMAH (NRCS plant code) -US-Ne2,28695,GRP_LMA,LMA_DATE,20030716 -US-Ne2,29400,GRP_LMA,LMA,23.97 -US-Ne2,29400,GRP_LMA,LMA_SPP,ZEMAH (NRCS plant code) -US-Ne2,29400,GRP_LMA,LMA_DATE,20010720 -US-Ne2,28068,GRP_LMA,LMA,24.94 -US-Ne2,28068,GRP_LMA,LMA_SPP,ZEMAH (NRCS plant code) -US-Ne2,28068,GRP_LMA,LMA_DATE,20050713 -US-Ne2,29401,GRP_LMA,LMA,25.14 -US-Ne2,29401,GRP_LMA,LMA_SPP,ZEMAH (NRCS plant code) -US-Ne2,29401,GRP_LMA,LMA_DATE,20030725 -US-Ne2,29590,GRP_LMA,LMA,25.7285 -US-Ne2,29590,GRP_LMA,LMA_SPP,GLYMA4 (NRCS plant code) -US-Ne2,29590,GRP_LMA,LMA_DATE,20060602 -US-Ne2,27705,GRP_LMA,LMA,25.79 -US-Ne2,27705,GRP_LMA,LMA_SPP,ZEMAH (NRCS plant code) -US-Ne2,27705,GRP_LMA,LMA_DATE,20070710 -US-Ne2,27164,GRP_LMA,LMA,25.95 -US-Ne2,27164,GRP_LMA,LMA_SPP,ZEMAH (NRCS plant code) -US-Ne2,27164,GRP_LMA,LMA_DATE,20050815 -US-Ne2,29288,GRP_LMA,LMA,26.33 -US-Ne2,29288,GRP_LMA,LMA_SPP,ZEMAH (NRCS plant code) -US-Ne2,29288,GRP_LMA,LMA_DATE,20050727 -US-Ne2,29599,GRP_LMA,LMA,26.43 -US-Ne2,29599,GRP_LMA,LMA_SPP,ZEMAH (NRCS plant code) -US-Ne2,29599,GRP_LMA,LMA_DATE,20050804 -US-Ne2,28414,GRP_LMA,LMA,26.51 -US-Ne2,28414,GRP_LMA,LMA_SPP,ZEMAH (NRCS plant code) -US-Ne2,28414,GRP_LMA,LMA_DATE,20030806 -US-Ne2,28906,GRP_LMA,LMA,26.7094 -US-Ne2,28906,GRP_LMA,LMA_SPP,ZEMAH (NRCS plant code) -US-Ne2,28906,GRP_LMA,LMA_DATE,20070807 -US-Ne2,28913,GRP_LMA,LMA,26.89 -US-Ne2,28913,GRP_LMA,LMA_SPP,ZEMAH (NRCS plant code) -US-Ne2,28913,GRP_LMA,LMA_DATE,20010809 -US-Ne2,28752,GRP_LMA,LMA,27.2102 -US-Ne2,28752,GRP_LMA,LMA_SPP,ZEMAH (NRCS plant code) -US-Ne2,28752,GRP_LMA,LMA_DATE,20070820 -US-Ne2,29287,GRP_LMA,LMA,27.39 -US-Ne2,29287,GRP_LMA,LMA_SPP,ZEMAH (NRCS plant code) -US-Ne2,29287,GRP_LMA,LMA_DATE,20030912 -US-Ne2,27713,GRP_LMA,LMA,27.5 -US-Ne2,27713,GRP_LMA,LMA_SPP,ZEMAH (NRCS plant code) -US-Ne2,27713,GRP_LMA,LMA_DATE,20030822 -US-Ne2,27706,GRP_LMA,LMA,28.9248 -US-Ne2,27706,GRP_LMA,LMA_SPP,ZEMAH (NRCS plant code) -US-Ne2,27706,GRP_LMA,LMA_DATE,20070725 -US-Ne2,29403,GRP_LMA,LMA,29.11 -US-Ne2,29403,GRP_LMA,LMA_SPP,ZEMAH (NRCS plant code) -US-Ne2,29403,GRP_LMA,LMA_DATE,20050901 -US-Ne2,29281,GRP_LMA,LMA,29.5279 -US-Ne2,29281,GRP_LMA,LMA_SPP,ZEMAH (NRCS plant code) -US-Ne2,29281,GRP_LMA,LMA_DATE,20070718 -US-Ne2,28753,GRP_LMA,LMA,31.7216 -US-Ne2,28753,GRP_LMA,LMA_SPP,ZEMAH (NRCS plant code) -US-Ne2,28753,GRP_LMA,LMA_DATE,20070911 -US-Ne2,28760,GRP_LMA,LMA,33.69 -US-Ne2,28760,GRP_LMA,LMA_SPP,ZEMAH (NRCS plant code) -US-Ne2,28760,GRP_LMA,LMA_DATE,20050919 -US-Ne2,27793,GRP_LMA,LMA,38.5263 -US-Ne2,27793,GRP_LMA,LMA_SPP,ZEMAH (NRCS plant code) -US-Ne2,27793,GRP_LMA,LMA_DATE,20070927 -US-Ne2,9261,GRP_LOCATION,LOCATION_LAT,41.1649 -US-Ne2,9261,GRP_LOCATION,LOCATION_LONG,-96.4701 -US-Ne2,9261,GRP_LOCATION,LOCATION_ELEV,362 -US-Ne2,8949,GRP_NETWORK,NETWORK,AmeriFlux -US-Ne2,1700005604,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Amos, B., Arkebauer, T. J., Doran, J. W. (2005) Soil Surface Fluxes Of Greenhouse Gases In An Irrigated Maize-Based Agroecosystem, Soil Science Society Of America Journal, 69(2), 387-395" -US-Ne2,1700005604,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.2136/SSSAJ2005.0387 -US-Ne2,1700005604,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ne2,1700008136,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Barr, A., Richardson, A., Hollinger, D., Papale, D., Arain, M., Black, T., Bohrer, G., Dragoni, D., Fischer, M., Gu, L., Law, B., Margolis, H., McCaughey, J., Munger, J., Oechel, W., Schaeffer, K. (2013) Use Of Change-Point Detection For Friction–Velocity Threshold Evaluation In Eddy-Covariance Studies, Agricultural And Forest Meteorology, 171-172(7), 31-45" -US-Ne2,1700008136,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2012.11.023 -US-Ne2,1700008136,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ne2,1700003303,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Cassman, K. G., Dobermann, A., Walters, D. T., Yang, H. (2003) Meeting Cereal Demand While Protecting Natural Resources And Improving Environmental Quality, Annual Review Of Environment And Resources, 28(1), 315-358" -US-Ne2,1700003303,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1146/ANNUREV.ENERGY.28.040202.122858 -US-Ne2,1700003303,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ne2,1700004824,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Baldocchi, D. D., Poindexter, C., Abraha, M., Desai, A. R., Bohrer, G., Arain, M. A., Griffis, T., Blanken, P. D., O'Halloran, T. L., Thomas, R. Q., Zhang, Q., Burns, S. P., Frank, J. M., Christian, D., Brown, S., Black, T. A., Gough, C. M., Law, B. E., Lee, X., Chen, J., Reed, D. E., Massman, W. J., Clark, K., Hatfield, J., Prueger, J., Bracho, R., Baker, J. M., Martin, T. A. (2018) Temporal Dynamics Of Aerodynamic Canopy Height Derived From Eddy Covariance Momentum Flux Data Across North American Flux Networks, Geophysical Research Letters, 45(5), 9275–9287" -US-Ne2,1700004824,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018GL079306 -US-Ne2,1700004824,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ne2,1700007170,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Baldocchi, D. D., Poindexter, C., Abraha, M., Desai, A. R., Bohrer, G., Arain, M. A., Griffis, T., Blanken, P. D., O'Halloran, T. L., Thomas, R. Q., Zhang, Q., Burns, S. P., Frank, J. M., Christian, D., Brown, S., Black, T. A., Gough, C. M., Law, B. E., Lee, X., Chen, J., Reed, D. E., Massman, W. J., Clark, K., Hatfield, J., Prueger, J., Bracho, R., Baker, J. M., Martin, T. A. (2018) Temporal Dynamics Of Aerodynamic Canopy Height Derived From Eddy Covariance Momentum Flux Data Across North American Flux Networks, Geophysical Research Letters, 45(7), 9275–9287" -US-Ne2,1700007170,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018GL079306 -US-Ne2,1700007170,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ne2,1700003846,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(7), 108350" -US-Ne2,1700003846,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -US-Ne2,1700003846,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ne2,1700003870,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Dobermann, A., Ping, J. L. (2004) Geostatistical Integration Of Yield Monitor Data And Remote Sensing Improves Yield Maps, Agronomy Journal, 96(1), 285-297" -US-Ne2,1700003870,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.2134/AGRONJ2004.0285 -US-Ne2,1700003870,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ne2,1700005757,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Dobermann, A., Ping, J. L., Adamchuk, V. I., Simbahan, G. C., Ferguson, R. B. (2003) Classification Of Crop Yield Variability In Irrigated Production Fields, Agronomy Journal, 95(5), 1105-1120" -US-Ne2,1700005757,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.2134/AGRONJ2003.1105 -US-Ne2,1700005757,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ne2,1700005181,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Ginting, D., Eghball, B. (2005) Nitrous Oxide Emission From No-Till Irrigated Corn, Soil Science Society Of America Journal, 69(3), 915-925" -US-Ne2,1700005181,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.2136/SSSAJ2004.0292 -US-Ne2,1700005181,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ne2,1700005538,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Gitelson, A. A. (2004) Wide Dynamic Range Vegetation Index For Remote Quantification Of Biophysical Characteristics Of Vegetation, Journal Of Plant Physiology, 161(2), 165-173" -US-Ne2,1700005538,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1078/0176-1617-01176 -US-Ne2,1700005538,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ne2,1700000006,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Gitelson, A. A., Verma, S. B, Rundquist, D. C., Keydan, G., Leavitt, B., Arkebauer, T. J., Burba, G. G., Suyker, A. E. (2003) Novel Technique For Remote Estimation Of CO2 Flux In Maize, Geophysical Research Letters, 30(9), 1486-n/a" -US-Ne2,1700000006,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2002GL016543 -US-Ne2,1700000006,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ne2,1700007389,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Gitelson, A. A., Viña, A., Arkebauer, T. J., Rundquist, D. C., Keydan, G., Leavitt, B. (2003) Remote Estimation Of Leaf Area Index And Green Leaf Biomass In Maize Canopies, Geophysical Research Letters, 30(5), n/a-n/a" -US-Ne2,1700007389,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2002GL016450 -US-Ne2,1700007389,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ne2,1700006261,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Mahmood, R., Hubbard, K. G. (2005) Assessing Bias In Evapotranspiration And Soil Moisture Estimates Due To The Use Of Modeled Solar Radiation And Dew Point Temperature Data, Agricultural And Forest Meteorology, 130(1-2), 71-84" -US-Ne2,1700006261,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2005.02.004 -US-Ne2,1700006261,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ne2,1700000855,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Matheny, A. M., Bohrer, G., Stoy, P. C., Baker, I. T., Black, A. T., Desai, A. R., Dietze, M. C., Gough, C. M., Ivanov, V. Y., Jassal, R. S., Novick, K. A., Schäfer, K. V., Verbeeck, H. (2014) Characterizing The Diurnal Patterns of Errors in The Prediction of Evapotranspiration by Several Land-Surface Models: An Nacp Analysis, Journal Of Geophysical Research: Biogeosciences, 119(7), 1458-1473" -US-Ne2,1700000855,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/2014JG002623 -US-Ne2,1700000855,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ne2,1700008883,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"McCombs, A. G., Hiscox, A. L., Wang, C., Desai, A. R., Suyker, A. E., Biraud, S. C. (2018) Carbon Flux Phenology From The Sky: Evaluation For Maize And Soybean, Journal Of Atmospheric And Oceanic Technology, 35(4), 877-892" -US-Ne2,1700008883,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1175/JTECH-D-17-0004.1 -US-Ne2,1700008883,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ne2,1700002952,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Ping, J. L., Dobermann, A. (2003) Creating Spatially Contiguous Yield Classes For Site-Specific Management, Agronomy Journal, 95(5), 1121-1131" -US-Ne2,1700002952,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.2134/AGRONJ2003.1121 -US-Ne2,1700002952,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ne2,1700004050,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Ping, J. L., Dobermann, A. (2005) Processing Of Yield Map Data, Precision Agriculture, 6(2), 193-212" -US-Ne2,1700004050,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1007/S11119-005-1035-2 -US-Ne2,1700004050,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ne2,1700003195,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Richardson, A. D., Hollinger, D. Y., Burba, G. G., Davis, K. J., Flanagan, L. B., Katul, G. G., William Munger, J., Ricciuto, D. M., Stoy, P. C., Suyker, A. E., Verma, S. B., Wofsy, S. C. (2006) A Multi-Site Analysis Of Random Error In Tower-Based Measurements Of Carbon And Energy Fluxes, Agricultural And Forest Meteorology, 136(1-2), 1-18" -US-Ne2,1700003195,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2006.01.007 -US-Ne2,1700003195,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ne2,1700001272,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Simbahan, G. C., Dobermann, A., Goovaerts, P., Ping, J., Haddix, M. L. (2006) Fine-Resolution Mapping Of Soil Organic Carbon Based On Multivariate Secondary Data, Geoderma, 132(3-4), 471-489" -US-Ne2,1700001272,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.GEODERMA.2005.07.001 -US-Ne2,1700001272,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ne2,1700006672,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Simbahan, G. C., Dobermann, A., Ping, J. L. (2004) Screening Yield Monitor Data Improves Grain Yield Maps, Agronomy Journal, 96(4), 1091-1102" -US-Ne2,1700006672,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.2134/AGRONJ2004.1091 -US-Ne2,1700006672,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ne2,1700004167,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Sullivan, R. C., Cook, D. R., Ghate, V. P., Kotamarthi, V. R., Feng, Y. (2019) Improved Spatiotemporal Representativeness And Bias Reduction Of Satellite-Based Evapotranspiration Retrievals Via Use Of In Situ Meteorology And Constrained Canopy Surface Resistance, Journal Of Geophysical Research: Biogeosciences, 124(2), 342-352" -US-Ne2,1700004167,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018JG004744 -US-Ne2,1700004167,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ne2,1700002661,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Sullivan, R. C., Kotamarthi, V. R., Feng, Y. (2019) Recovering Evapotranspiration Trends From Biased CMIP5 Simulations And Sensitivity To Changing Climate Over North America, Journal Of Hydrometeorology, 20(8), 1619-1633" -US-Ne2,1700002661,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1175/JHM-D-18-0259.1 -US-Ne2,1700002661,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ne2,1700003972,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Suyker, A. E., Verma, S. B., Burba, G. G., Arkebauer, T. J. (2005) Gross Primary Production And Ecosystem Respiration Of Irrigated Maize And Irrigated Soybean During A Growing Season, Agricultural And Forest Meteorology, 131(3-4), 180-190" -US-Ne2,1700003972,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2005.05.007 -US-Ne2,1700003972,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ne2,1700001530,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Suyker, A., Verma, S., Burba, G., Arkebauer, T., Walters, D., Hubbard, K. (2004) Growing Season Carbon Dioxide Exchange In Irrigated And Rainfed Maize, Agricultural And Forest Meteorology, 124(1-2), 1-13" -US-Ne2,1700001530,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2004.01.011 -US-Ne2,1700001530,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ne2,1700008826,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Verma, S. B., Dobermann, A., Cassman, K. G., Walters, D. T., Knops, J. M., Arkebauer, T. J., Suyker, A. E., Burba, G. G., Amos, B., Yang, H., Ginting, D., Hubbard, K. G., Gitelson, A. A., Walter-Shea, E. A. (2005) Annual Carbon Dioxide Exchange In Irrigated And Rainfed Maize-Based Agroecosystems, Agricultural And Forest Meteorology, 131(1-2), 77-96" -US-Ne2,1700008826,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2005.05.003 -US-Ne2,1700008826,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ne2,1700001020,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Viña, A., Genebry, G.M., Gitelson, A. A. (2004) Satellite Monitoring Of Vegetation Dynamics: Sensitivity Enhancement By The Wide Dynamic Range Vegetation Index, Geophysical Research Letters, 31(4), 1-4" -US-Ne2,1700001020,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2003GL019034 -US-Ne2,1700001020,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ne2,1700003387,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Viña, A., Gitelson, A. A., Rundquist, D. C., Keydan, G., Leavitt, B., Schepers, J. (2004) Monitoring Maize (Zea Mays L.) Phenology With Remote Sensing, Agronomy Journal, 96(4), 1139-1147" -US-Ne2,1700003387,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.2134/AGRONJ2004.1139 -US-Ne2,1700003387,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ne2,1700004146,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Yang, H., Dobermann, A., Lindquist, J., Walters, D., Arkebauer, T., Cassman, K. (2004) Hybrid-Maize—A Maize Simulation Model That Combines Two Crop Modeling Approaches, Field Crops Research, 87(2-3), 131-154" -US-Ne2,1700004146,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.FCR.2003.10.003 -US-Ne2,1700004146,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ne2,1700003606,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Zhang, Q., Ficklin, D. L., Manzoni, S., Wang, L., Way, D., Phillips, R. P., Novick, K. A. (2019) Response Of Ecosystem Intrinsic Water Use Efficiency And Gross Primary Productivity To Rising Vapor Pressure Deficit, Environmental Research Letters, 14(7), 074023" -US-Ne2,1700003606,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1088/1748-9326/AB2603 -US-Ne2,1700003606,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ne2,4125,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,The overall goals are to investigate the C sequestration potential of major rainfed and irrigated agroecosystems in the north-central USA and to understand the biophysical controls on C sequestration. -US-Ne2,2790,GRP_SITE_DESC,SITE_DESC,"The study site is one of three fields (all located within 1.6 km of each other) at the University of Nebraska Agricultural Research and Development Center near Mead, Nebraska. This site is irrigated with a center pivot system. Prior to the initiation of the study, the irrigated site had a 10-yr history of maize-soybean rotation under no-till. A tillage operation (disking) was done just prior to the 2001 planting to homogenize the top 0.1 m of soil, incorporate P and K fertilizers, as well as previously accumulated surface residues. Since this tillage operation, the site has been under no-till management." -US-Ne2,756,GRP_SITE_FUNDING,SITE_FUNDING,DOE (OBER & EPSCoR) -US-Ne2,27666,GRP_SOIL_CHEM,SOIL_CHEM_C_ORG,25.1 -US-Ne2,28657,GRP_SOIL_CHEM,SOIL_CHEM_C_ORG,25.2 -US-Ne2,27428,GRP_SOIL_CHEM,SOIL_CHEM_C_ORG,30.5 -US-Ne2,27128,GRP_SOIL_CHEM,SOIL_CHEM_C_ORG,32.8 -US-Ne2,27666,GRP_SOIL_CHEM,SOIL_CHEM_N_TOT,2.3 -US-Ne2,28657,GRP_SOIL_CHEM,SOIL_CHEM_N_TOT,2.4 -US-Ne2,27428,GRP_SOIL_CHEM,SOIL_CHEM_N_TOT,2.9 -US-Ne2,27128,GRP_SOIL_CHEM,SOIL_CHEM_N_TOT,3 -US-Ne2,27769,GRP_SOIL_CHEM,SOIL_CHEM_PH_SALT,5.60 -US-Ne2,28718,GRP_SOIL_CHEM,SOIL_CHEM_PH_SALT,5.80 -US-Ne2,27428,GRP_SOIL_CHEM,SOIL_CHEM_BD,1.37 -US-Ne2,27128,GRP_SOIL_CHEM,SOIL_CHEM_BD,1.40 -US-Ne2,28657,GRP_SOIL_CHEM,SOIL_CHEM_BD,1.46 -US-Ne2,27666,GRP_SOIL_CHEM,SOIL_CHEM_BD,1.54 -US-Ne2,27128,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,0 -US-Ne2,27428,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,0 -US-Ne2,27769,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,0 -US-Ne2,27666,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,15 -US-Ne2,28657,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,15 -US-Ne2,28718,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,20 -US-Ne2,27128,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,15 -US-Ne2,27428,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,15 -US-Ne2,27769,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,20 -US-Ne2,27666,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,30 -US-Ne2,28657,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,30 -US-Ne2,28718,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,50 -US-Ne2,27128,GRP_SOIL_CHEM,SOIL_CHEM_DATE,20010420 -US-Ne2,27666,GRP_SOIL_CHEM,SOIL_CHEM_DATE,20010420 -US-Ne2,27769,GRP_SOIL_CHEM,SOIL_CHEM_DATE,20010420 -US-Ne2,28718,GRP_SOIL_CHEM,SOIL_CHEM_DATE,20010420 -US-Ne2,27428,GRP_SOIL_CHEM,SOIL_CHEM_DATE,20050425 -US-Ne2,28657,GRP_SOIL_CHEM,SOIL_CHEM_DATE,20050425 -US-Ne2,28938,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION,"Deep silty clay loams of: Yutan (fine-silty, mixed, superactive, mesic Mollic Hapludalfs), Tomek (fine, smectitic, mesic Pachic Argialbolls), Filbert (fine, smectitic, mesic Vertic Argialbolls), and Filmore (fine, smectitic, mesic Vertic Argialbolls)." -US-Ne2,28938,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION_TAXONOMY,Other -US-Ne2,27129,GRP_SOIL_DEPTH,SOIL_DEPTH,180 -US-Ne2,27667,GRP_SOIL_TEX,SOIL_TEX_SAND,12 -US-Ne2,27667,GRP_SOIL_TEX,SOIL_TEX_SILT,55 -US-Ne2,27667,GRP_SOIL_TEX,SOIL_TEX_CLAY,33 -US-Ne2,27173,GRP_SPP_O,SPP_O,GLYMA4 (NRCS plant code) -US-Ne2,27473,GRP_SPP_O,SPP_O,GLYMA4 (NRCS plant code) -US-Ne2,29408,GRP_SPP_O,SPP_O,GLYMA4 (NRCS plant code) -US-Ne2,27472,GRP_SPP_O,SPP_O,ZEMAH (NRCS plant code) -US-Ne2,28076,GRP_SPP_O,SPP_O,ZEMAH (NRCS plant code) -US-Ne2,28077,GRP_SPP_O,SPP_O,ZEMAH (NRCS plant code) -US-Ne2,29294,GRP_SPP_O,SPP_O,ZEMAH (NRCS plant code) -US-Ne2,27173,GRP_SPP_O,SPP_O_PERC,100 -US-Ne2,27472,GRP_SPP_O,SPP_O_PERC,100 -US-Ne2,27473,GRP_SPP_O,SPP_O_PERC,100 -US-Ne2,28076,GRP_SPP_O,SPP_O_PERC,100 -US-Ne2,28077,GRP_SPP_O,SPP_O_PERC,100 -US-Ne2,29294,GRP_SPP_O,SPP_O_PERC,100 -US-Ne2,29408,GRP_SPP_O,SPP_O_PERC,100 -US-Ne2,29294,GRP_SPP_O,SPP_DATE,2001 -US-Ne2,27473,GRP_SPP_O,SPP_DATE,2002 -US-Ne2,27472,GRP_SPP_O,SPP_DATE,2003 -US-Ne2,27173,GRP_SPP_O,SPP_DATE,2004 -US-Ne2,28076,GRP_SPP_O,SPP_DATE,2005 -US-Ne2,29408,GRP_SPP_O,SPP_DATE,2006 -US-Ne2,28077,GRP_SPP_O,SPP_DATE,2007 -US-Ne2,7442,GRP_STATE,STATE,NE -US-Ne2,9211,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Andy Suyker -US-Ne2,9211,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Ne2,9211,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,asuyker1@unl.edu -US-Ne2,9211,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Nebraska - Lincoln -US-Ne2,9211,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"School of Natural Resource, 807 Hardin Hall,Lincoln, NE USA 68583-0728" -US-Ne2,87991,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Dan Hatch -US-Ne2,87991,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,DataManager -US-Ne2,87991,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,dhatch2@unl.edu -US-Ne2,87991,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Nebraska -US-Ne2,87991,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,805 Hardin Hall -US-Ne2,961,GRP_URL,URL,http://csp.unl.edu/public/ -US-Ne2,24000404,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-Ne2 -US-Ne2,9600,GRP_UTC_OFFSET,UTC_OFFSET,-6 -US-Ne3,28730,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,0.179316 -US-Ne3,28730,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne3,28730,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne3,28730,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne3,28730,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20010529 -US-Ne3,28730,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne3,28894,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,0.616227 -US-Ne3,28894,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne3,28894,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne3,28894,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne3,28894,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20050524 -US-Ne3,28894,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne3,27786,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,1.30296 -US-Ne3,27786,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne3,27786,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne3,27786,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne3,27786,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20030606 -US-Ne3,27786,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne3,28722,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,10.1197 -US-Ne3,28722,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne3,28722,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne3,28722,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne3,28722,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20060621 -US-Ne3,28722,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne3,27787,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,10.9867 -US-Ne3,27787,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne3,27787,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne3,27787,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne3,27787,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20050608 -US-Ne3,27787,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne3,28663,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,113.479 -US-Ne3,28663,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne3,28663,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne3,28663,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne3,28663,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20070625 -US-Ne3,28663,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne3,29582,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,113.902 -US-Ne3,29582,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne3,29582,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne3,29582,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne3,29582,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20020726 -US-Ne3,29582,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne3,27773,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,115.89 -US-Ne3,27773,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne3,27773,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne3,27773,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne3,27773,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20060717 -US-Ne3,27773,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne3,29269,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,119.5 -US-Ne3,29269,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne3,29269,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne3,29269,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne3,29269,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20030703 -US-Ne3,29269,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne3,27141,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,134.91 -US-Ne3,27141,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne3,27141,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne3,27141,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne3,27141,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20010705 -US-Ne3,27141,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne3,27124,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,138 -US-Ne3,27124,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Total -US-Ne3,27124,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne3,27124,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne3,27124,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20041005 -US-Ne3,29382,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,139.718 -US-Ne3,29382,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne3,29382,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne3,29382,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne3,29382,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20050630 -US-Ne3,29382,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne3,29583,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,145.204 -US-Ne3,29583,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne3,29583,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne3,29583,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne3,29583,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20060725 -US-Ne3,29583,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne3,27443,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,15.4433 -US-Ne3,27443,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne3,27443,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne3,27443,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne3,27443,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20040706 -US-Ne3,27443,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne3,27693,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,16.6016 -US-Ne3,27693,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne3,27693,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne3,27693,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne3,27693,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20030619 -US-Ne3,27693,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne3,29380,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,17.1045 -US-Ne3,29380,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne3,29380,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne3,29380,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne3,29380,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20020625 -US-Ne3,29380,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne3,27696,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,179.63 -US-Ne3,27696,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne3,27696,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne3,27696,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne3,27696,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20040810 -US-Ne3,27696,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne3,28649,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,180 -US-Ne3,28649,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Total -US-Ne3,28649,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne3,28649,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne3,28649,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20021011 -US-Ne3,28731,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,186.234 -US-Ne3,28731,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne3,28731,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne3,28731,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne3,28731,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20020809 -US-Ne3,28731,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne3,27677,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,19.6459 -US-Ne3,27677,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne3,27677,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne3,27677,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne3,27677,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20070611 -US-Ne3,27677,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne3,27676,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,2.14858 -US-Ne3,27676,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne3,27676,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne3,27676,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne3,27676,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20060602 -US-Ne3,27676,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne3,28390,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,2.55968 -US-Ne3,28390,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne3,28390,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne3,28390,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne3,28390,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20070530 -US-Ne3,28390,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne3,28676,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,2.69997 -US-Ne3,28676,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne3,28676,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne3,28676,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne3,28676,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20040624 -US-Ne3,28676,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne3,27144,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,202.951 -US-Ne3,27144,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne3,27144,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne3,27144,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne3,27144,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20040819 -US-Ne3,27144,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne3,29271,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,208.307 -US-Ne3,29271,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne3,29271,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne3,29271,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne3,29271,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20060801 -US-Ne3,29271,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne3,27431,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,217.485 -US-Ne3,27431,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne3,27431,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne3,27431,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne3,27431,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20070702 -US-Ne3,27431,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne3,27439,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,228.194 -US-Ne3,27439,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne3,27439,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne3,27439,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne3,27439,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20010711 -US-Ne3,27439,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne3,28396,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,24.5655 -US-Ne3,28396,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne3,28396,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne3,28396,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne3,28396,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20010621 -US-Ne3,28396,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne3,27698,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,258.269 -US-Ne3,27698,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne3,27698,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne3,27698,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne3,27698,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20060810 -US-Ne3,27698,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne3,27694,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,258.393 -US-Ne3,27694,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne3,27694,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne3,27694,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne3,27694,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20030714 -US-Ne3,27694,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne3,28734,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,272.729 -US-Ne3,28734,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne3,28734,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne3,28734,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne3,28734,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20040920 -US-Ne3,28734,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne3,27146,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,286.344 -US-Ne3,27146,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne3,27146,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne3,27146,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne3,27146,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20050714 -US-Ne3,27146,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne3,28674,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,289.93 -US-Ne3,28674,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne3,28674,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne3,28674,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne3,28674,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20010718 -US-Ne3,28674,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne3,28735,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,292.672 -US-Ne3,28735,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne3,28735,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne3,28735,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne3,28735,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20060816 -US-Ne3,28735,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne3,28893,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,295.346 -US-Ne3,28893,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne3,28893,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne3,28893,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne3,28893,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20020904 -US-Ne3,28893,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne3,28650,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,298 -US-Ne3,28650,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Total -US-Ne3,28650,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne3,28650,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne3,28650,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20031002 -US-Ne3,27142,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,3.61066 -US-Ne3,27142,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne3,27142,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne3,27142,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne3,27142,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20020611 -US-Ne3,27142,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne3,28664,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,302.649 -US-Ne3,28664,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne3,28664,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne3,28664,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne3,28664,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20070711 -US-Ne3,28664,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne3,28889,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,32.6058 -US-Ne3,28889,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne3,28889,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne3,28889,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne3,28889,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20060629 -US-Ne3,28889,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne3,28733,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,323.139 -US-Ne3,28733,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne3,28733,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne3,28733,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne3,28733,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20040909 -US-Ne3,28733,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne3,28732,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,326.067 -US-Ne3,28732,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne3,28732,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne3,28732,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne3,28732,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20020918 -US-Ne3,28732,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne3,28736,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,327.974 -US-Ne3,28736,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne3,28736,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne3,28736,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne3,28736,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20060830 -US-Ne3,28736,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne3,27788,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,346.093 -US-Ne3,27788,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne3,27788,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne3,27788,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne3,27788,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20060918 -US-Ne3,27788,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne3,28397,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,346.454 -US-Ne3,28397,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne3,28397,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne3,28397,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne3,28397,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20030723 -US-Ne3,28397,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne3,28737,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,357.581 -US-Ne3,28737,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne3,28737,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne3,28737,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne3,28737,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20061009 -US-Ne3,28737,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne3,29381,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,36.7557 -US-Ne3,29381,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne3,29381,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne3,29381,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne3,29381,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20040716 -US-Ne3,29381,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne3,27421,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,377 -US-Ne3,27421,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Total -US-Ne3,27421,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne3,27421,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne3,27421,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20011011 -US-Ne3,29366,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,397 -US-Ne3,29366,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Total -US-Ne3,29366,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne3,29366,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne3,29366,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20051005 -US-Ne3,27691,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,4.95498 -US-Ne3,27691,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne3,27691,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne3,27691,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne3,27691,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20010613 -US-Ne3,27691,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne3,29383,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,416.621 -US-Ne3,29383,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne3,29383,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne3,29383,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne3,29383,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20050728 -US-Ne3,29383,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne3,27695,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,431.347 -US-Ne3,27695,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne3,27695,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne3,27695,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne3,27695,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20030804 -US-Ne3,27695,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne3,28665,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,467.562 -US-Ne3,28665,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne3,28665,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne3,28665,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne3,28665,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20070723 -US-Ne3,28665,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne3,27444,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,519.051 -US-Ne3,27444,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne3,27444,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne3,27444,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne3,27444,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20050808 -US-Ne3,27444,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne3,27441,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,537.022 -US-Ne3,27441,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne3,27441,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne3,27441,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne3,27441,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20030820 -US-Ne3,27441,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne3,27143,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,54.9586 -US-Ne3,27143,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne3,27143,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne3,27143,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne3,27143,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20020709 -US-Ne3,27143,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne3,28391,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,55.6348 -US-Ne3,28391,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne3,28391,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne3,28391,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne3,28391,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20070618 -US-Ne3,28391,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne3,27442,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,551.576 -US-Ne3,27442,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne3,27442,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne3,27442,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne3,27442,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20030904 -US-Ne3,27442,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne3,28675,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,561.582 -US-Ne3,28675,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne3,28675,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne3,28675,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne3,28675,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20010807 -US-Ne3,28675,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne3,28392,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,571.552 -US-Ne3,28392,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne3,28392,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne3,28392,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne3,28392,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20070801 -US-Ne3,28392,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne3,28677,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,599.219 -US-Ne3,28677,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne3,28677,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne3,28677,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne3,28677,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20050817 -US-Ne3,28677,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne3,27772,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,60.7038 -US-Ne3,27772,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne3,27772,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne3,27772,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne3,27772,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20060711 -US-Ne3,27772,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne3,27440,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,601.871 -US-Ne3,27440,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne3,27440,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne3,27440,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne3,27440,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20010814 -US-Ne3,27440,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne3,29372,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,662.474 -US-Ne3,29372,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne3,29372,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne3,29372,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne3,29372,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20070814 -US-Ne3,29372,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne3,27446,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,693.619 -US-Ne3,27446,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne3,27446,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne3,27446,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne3,27446,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20050926 -US-Ne3,27446,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne3,29255,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,7.23607 -US-Ne3,29255,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne3,29255,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne3,29255,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne3,29255,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20060613 -US-Ne3,29255,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne3,27692,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,70.8217 -US-Ne3,27692,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne3,27692,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne3,27692,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne3,27692,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20010628 -US-Ne3,27692,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne3,27445,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,759.089 -US-Ne3,27445,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne3,27445,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne3,27445,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne3,27445,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20050907 -US-Ne3,27445,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne3,29257,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,783.428 -US-Ne3,29257,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne3,29257,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne3,29257,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne3,29257,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20070828 -US-Ne3,29257,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne3,27145,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,80.4687 -US-Ne3,27145,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne3,27145,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne3,27145,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne3,27145,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20050621 -US-Ne3,27145,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne3,29373,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,813.682 -US-Ne3,29373,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne3,29373,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne3,29373,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne3,29373,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20070917 -US-Ne3,29373,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne3,29270,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP,94.415 -US-Ne3,29270,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_ORGAN,Foliage -US-Ne3,29270,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_PHEN,Mixed/unknown -US-Ne3,29270,GRP_AG_BIOMASS_CROP,AG_BIOMASS_CROP_UNIT,gC m-2 -US-Ne3,29270,GRP_AG_BIOMASS_CROP,AG_BIOMASS_DATE,20040729 -US-Ne3,29270,GRP_AG_BIOMASS_CROP,AG_BIOMASS_COMMENT,(assuming 43#9% C) -US-Ne3,28383,GRP_AG_PROD_CROP,AG_PROD_CROP,153 -US-Ne3,28383,GRP_AG_PROD_CROP,AG_PROD_CROP_ORGAN,Fruits -US-Ne3,28383,GRP_AG_PROD_CROP,AG_PROD_CROP_UNIT,gC m-2 -US-Ne3,28383,GRP_AG_PROD_CROP,AG_PROD_DATE_START,20021011 -US-Ne3,28037,GRP_AG_PROD_CROP,AG_PROD_CROP,157 -US-Ne3,28037,GRP_AG_PROD_CROP,AG_PROD_CROP_ORGAN,Fruits -US-Ne3,28037,GRP_AG_PROD_CROP,AG_PROD_CROP_UNIT,gC m-2 -US-Ne3,28037,GRP_AG_PROD_CROP,AG_PROD_DATE_START,20041005 -US-Ne3,28652,GRP_AG_PROD_CROP,AG_PROD_CROP,295 -US-Ne3,28652,GRP_AG_PROD_CROP,AG_PROD_CROP_ORGAN,Total -US-Ne3,28652,GRP_AG_PROD_CROP,AG_PROD_CROP_UNIT,gC m-2 -US-Ne3,28652,GRP_AG_PROD_CROP,AG_PROD_DATE_START,20041005 -US-Ne3,27422,GRP_AG_PROD_CROP,AG_PROD_CROP,297 -US-Ne3,27422,GRP_AG_PROD_CROP,AG_PROD_CROP_ORGAN,Fruits -US-Ne3,27422,GRP_AG_PROD_CROP,AG_PROD_CROP_UNIT,gC m-2 -US-Ne3,27422,GRP_AG_PROD_CROP,AG_PROD_DATE_START,20031002 -US-Ne3,28651,GRP_AG_PROD_CROP,AG_PROD_CROP,333 -US-Ne3,28651,GRP_AG_PROD_CROP,AG_PROD_CROP_ORGAN,Total -US-Ne3,28651,GRP_AG_PROD_CROP,AG_PROD_CROP_UNIT,gC m-2 -US-Ne3,28651,GRP_AG_PROD_CROP,AG_PROD_DATE_START,20021011 -US-Ne3,27125,GRP_AG_PROD_CROP,AG_PROD_CROP,335 -US-Ne3,27125,GRP_AG_PROD_CROP,AG_PROD_CROP_ORGAN,Fruits -US-Ne3,27125,GRP_AG_PROD_CROP,AG_PROD_CROP_UNIT,gC m-2 -US-Ne3,27125,GRP_AG_PROD_CROP,AG_PROD_DATE_START,20011011 -US-Ne3,29572,GRP_AG_PROD_CROP,AG_PROD_CROP,340 -US-Ne3,29572,GRP_AG_PROD_CROP,AG_PROD_CROP_ORGAN,Fruits -US-Ne3,29572,GRP_AG_PROD_CROP,AG_PROD_CROP_UNIT,gC m-2 -US-Ne3,29572,GRP_AG_PROD_CROP,AG_PROD_DATE_START,20051005 -US-Ne3,27423,GRP_AG_PROD_CROP,AG_PROD_CROP,595 -US-Ne3,27423,GRP_AG_PROD_CROP,AG_PROD_CROP_ORGAN,Total -US-Ne3,27423,GRP_AG_PROD_CROP,AG_PROD_CROP_UNIT,gC m-2 -US-Ne3,27423,GRP_AG_PROD_CROP,AG_PROD_DATE_START,20031002 -US-Ne3,29367,GRP_AG_PROD_CROP,AG_PROD_CROP,713 -US-Ne3,29367,GRP_AG_PROD_CROP,AG_PROD_CROP_ORGAN,Total -US-Ne3,29367,GRP_AG_PROD_CROP,AG_PROD_CROP_UNIT,gC m-2 -US-Ne3,29367,GRP_AG_PROD_CROP,AG_PROD_DATE_START,20011011 -US-Ne3,27126,GRP_AG_PROD_CROP,AG_PROD_CROP,736 -US-Ne3,27126,GRP_AG_PROD_CROP,AG_PROD_CROP_ORGAN,Total -US-Ne3,27126,GRP_AG_PROD_CROP,AG_PROD_CROP_UNIT,gC m-2 -US-Ne3,27126,GRP_AG_PROD_CROP,AG_PROD_DATE_START,20051005 -US-Ne3,24141,GRP_BIOMASS_CHEM,BIOMASS_C,4.1054 -US-Ne3,25307,GRP_BIOMASS_CHEM,BIOMASS_C,4.16348 -US-Ne3,25800,GRP_BIOMASS_CHEM,BIOMASS_C,4.17072 -US-Ne3,26295,GRP_BIOMASS_CHEM,BIOMASS_C,4.17158 -US-Ne3,26311,GRP_BIOMASS_CHEM,BIOMASS_C,4.18227 -US-Ne3,26174,GRP_BIOMASS_CHEM,BIOMASS_C,4.22608 -US-Ne3,26312,GRP_BIOMASS_CHEM,BIOMASS_C,4.23075 -US-Ne3,26313,GRP_BIOMASS_CHEM,BIOMASS_C,4.23995 -US-Ne3,26565,GRP_BIOMASS_CHEM,BIOMASS_C,4.24638 -US-Ne3,26552,GRP_BIOMASS_CHEM,BIOMASS_C,4.37488 -US-Ne3,26423,GRP_BIOMASS_CHEM,BIOMASS_C,4.38292 -US-Ne3,24129,GRP_BIOMASS_CHEM,BIOMASS_C,4.3831 -US-Ne3,26424,GRP_BIOMASS_CHEM,BIOMASS_C,4.45517 -US-Ne3,25558,GRP_BIOMASS_CHEM,BIOMASS_C,4.4558 -US-Ne3,24527,GRP_BIOMASS_CHEM,BIOMASS_C,4.52918 -US-Ne3,26295,GRP_BIOMASS_CHEM,BIOMASS_N,0.15365 -US-Ne3,26174,GRP_BIOMASS_CHEM,BIOMASS_N,0.203583 -US-Ne3,26552,GRP_BIOMASS_CHEM,BIOMASS_N,0.236617 -US-Ne3,25800,GRP_BIOMASS_CHEM,BIOMASS_N,0.245883 -US-Ne3,24527,GRP_BIOMASS_CHEM,BIOMASS_N,0.280483 -US-Ne3,24141,GRP_BIOMASS_CHEM,BIOMASS_N,0.282067 -US-Ne3,24129,GRP_BIOMASS_CHEM,BIOMASS_N,0.284 -US-Ne3,25558,GRP_BIOMASS_CHEM,BIOMASS_N,0.315133 -US-Ne3,26565,GRP_BIOMASS_CHEM,BIOMASS_N,0.342467 -US-Ne3,26313,GRP_BIOMASS_CHEM,BIOMASS_N,0.346633 -US-Ne3,25307,GRP_BIOMASS_CHEM,BIOMASS_N,0.348433 -US-Ne3,26312,GRP_BIOMASS_CHEM,BIOMASS_N,0.379217 -US-Ne3,26311,GRP_BIOMASS_CHEM,BIOMASS_N,0.445867 -US-Ne3,26424,GRP_BIOMASS_CHEM,BIOMASS_N,0.456883 -US-Ne3,26423,GRP_BIOMASS_CHEM,BIOMASS_N,0.505067 -US-Ne3,24129,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-Ne3,24141,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-Ne3,24527,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-Ne3,25307,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-Ne3,25558,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-Ne3,25800,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-Ne3,26174,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-Ne3,26295,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-Ne3,26311,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-Ne3,26312,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-Ne3,26313,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-Ne3,26423,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-Ne3,26424,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-Ne3,26552,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-Ne3,26565,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-Ne3,24129,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-Ne3,24141,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-Ne3,24527,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-Ne3,25307,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-Ne3,25558,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-Ne3,25800,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-Ne3,26174,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-Ne3,26295,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-Ne3,26311,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-Ne3,26312,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-Ne3,26313,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-Ne3,26423,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-Ne3,26424,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-Ne3,26552,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-Ne3,26565,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-Ne3,24129,GRP_BIOMASS_CHEM,BIOMASS_SPP,(All) -US-Ne3,24141,GRP_BIOMASS_CHEM,BIOMASS_SPP,(All) -US-Ne3,24527,GRP_BIOMASS_CHEM,BIOMASS_SPP,(All) -US-Ne3,25307,GRP_BIOMASS_CHEM,BIOMASS_SPP,(All) -US-Ne3,25558,GRP_BIOMASS_CHEM,BIOMASS_SPP,(All) -US-Ne3,25800,GRP_BIOMASS_CHEM,BIOMASS_SPP,(All) -US-Ne3,26174,GRP_BIOMASS_CHEM,BIOMASS_SPP,(All) -US-Ne3,26295,GRP_BIOMASS_CHEM,BIOMASS_SPP,(All) -US-Ne3,26311,GRP_BIOMASS_CHEM,BIOMASS_SPP,(All) -US-Ne3,26312,GRP_BIOMASS_CHEM,BIOMASS_SPP,(All) -US-Ne3,26313,GRP_BIOMASS_CHEM,BIOMASS_SPP,(All) -US-Ne3,26423,GRP_BIOMASS_CHEM,BIOMASS_SPP,(All) -US-Ne3,26424,GRP_BIOMASS_CHEM,BIOMASS_SPP,(All) -US-Ne3,26552,GRP_BIOMASS_CHEM,BIOMASS_SPP,(All) -US-Ne3,26565,GRP_BIOMASS_CHEM,BIOMASS_SPP,(All) -US-Ne3,26311,GRP_BIOMASS_CHEM,BIOMASS_DATE,20010621 -US-Ne3,26312,GRP_BIOMASS_CHEM,BIOMASS_DATE,20010628 -US-Ne3,26313,GRP_BIOMASS_CHEM,BIOMASS_DATE,20010705 -US-Ne3,25307,GRP_BIOMASS_CHEM,BIOMASS_DATE,20010711 -US-Ne3,26565,GRP_BIOMASS_CHEM,BIOMASS_DATE,20010718 -US-Ne3,24141,GRP_BIOMASS_CHEM,BIOMASS_DATE,20010807 -US-Ne3,25800,GRP_BIOMASS_CHEM,BIOMASS_DATE,20010814 -US-Ne3,26423,GRP_BIOMASS_CHEM,BIOMASS_DATE,20030606 -US-Ne3,26424,GRP_BIOMASS_CHEM,BIOMASS_DATE,20030619 -US-Ne3,25558,GRP_BIOMASS_CHEM,BIOMASS_DATE,20030703 -US-Ne3,24527,GRP_BIOMASS_CHEM,BIOMASS_DATE,20030714 -US-Ne3,24129,GRP_BIOMASS_CHEM,BIOMASS_DATE,20030723 -US-Ne3,26552,GRP_BIOMASS_CHEM,BIOMASS_DATE,20030804 -US-Ne3,26174,GRP_BIOMASS_CHEM,BIOMASS_DATE,20030820 -US-Ne3,26295,GRP_BIOMASS_CHEM,BIOMASS_DATE,20030904 -US-Ne3,5129,GRP_CLIM_AVG,MAT,10.11 -US-Ne3,5129,GRP_CLIM_AVG,MAP,783.68 -US-Ne3,5129,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfa -US-Ne3,27000405,GRP_COUNTRY,COUNTRY,USA -US-Ne3,277,GRP_DM_AGRICULTURE,DM_AGRICULTURE,Harvest -US-Ne3,277,GRP_DM_AGRICULTURE,DM_DATE,20011029 -US-Ne3,277,GRP_DM_AGRICULTURE,DM_COMMENT,139 bu/ac ( 8.72 Mg ha-1 ). 16.9% MC. -US-Ne3,1103,GRP_DM_AGRICULTURE,DM_AGRICULTURE,Harvest -US-Ne3,1103,GRP_DM_AGRICULTURE,DM_DATE,20021009 -US-Ne3,1103,GRP_DM_AGRICULTURE,DM_COMMENT,49 bu/ac ( 3.32 MG ha-1) -US-Ne3,278,GRP_DM_AGRICULTURE,DM_AGRICULTURE,Harvest -US-Ne3,278,GRP_DM_AGRICULTURE,DM_DATE,20021010 -US-Ne3,278,GRP_DM_AGRICULTURE,DM_COMMENT,49 bu/ac ( 3.32 MG ha-1) -US-Ne3,9627,GRP_DM_AGRICULTURE,DM_AGRICULTURE,Harvest -US-Ne3,9627,GRP_DM_AGRICULTURE,DM_DATE,20021011 -US-Ne3,9627,GRP_DM_AGRICULTURE,DM_COMMENT,49 bu/ac ( 3.32 MG ha-1) -US-Ne3,3665,GRP_DM_AGRICULTURE,DM_AGRICULTURE,Harvest -US-Ne3,3665,GRP_DM_AGRICULTURE,DM_DATE,20031013 -US-Ne3,2815,GRP_DM_AGRICULTURE,DM_AGRICULTURE,Harvest -US-Ne3,2815,GRP_DM_AGRICULTURE,DM_DATE,20031015 -US-Ne3,2815,GRP_DM_AGRICULTURE,DM_COMMENT,123 bu/ac ( 7.72 MG ha-1) corrected from 16.9% MC -US-Ne3,4498,GRP_DM_AGRICULTURE,DM_AGRICULTURE,Harvest -US-Ne3,4498,GRP_DM_AGRICULTURE,DM_DATE,20031016 -US-Ne3,4498,GRP_DM_AGRICULTURE,DM_COMMENT,123 bu/ac ( 7.72 MG ha-1) corrected from 16.9% MC -US-Ne3,2817,GRP_DM_AGRICULTURE,DM_AGRICULTURE,Harvest -US-Ne3,2817,GRP_DM_AGRICULTURE,DM_DATE,20041006 -US-Ne3,2817,GRP_DM_AGRICULTURE,DM_COMMENT,50 bu/ac ( 3.14 MG ha-1) corrected from 11.9% MC -US-Ne3,8779,GRP_DM_AGRICULTURE,DM_AGRICULTURE,Harvest -US-Ne3,8779,GRP_DM_AGRICULTURE,DM_DATE,20041011 -US-Ne3,8779,GRP_DM_AGRICULTURE,DM_COMMENT,50 bu/ac ( 3.14 MG ha-1) corrected from 11.9% MC -US-Ne3,1117,GRP_DM_AGRICULTURE,DM_AGRICULTURE,Harvest -US-Ne3,1117,GRP_DM_AGRICULTURE,DM_DATE,20041012 -US-Ne3,1117,GRP_DM_AGRICULTURE,DM_COMMENT,50 bu/ac ( 3.14 MG ha-1) corrected from 11.9% MC -US-Ne3,7936,GRP_DM_AGRICULTURE,DM_AGRICULTURE,Harvest -US-Ne3,7936,GRP_DM_AGRICULTURE,DM_DATE,20051017 -US-Ne3,7936,GRP_DM_AGRICULTURE,DM_COMMENT,"145 bu/ac (9.10 MG ha-1) 15.5% basis. Harvest MC 15.7%,JD9560" -US-Ne3,7062,GRP_DM_AGRICULTURE,DM_AGRICULTURE,Harvest -US-Ne3,7062,GRP_DM_AGRICULTURE,DM_DATE,20051018 -US-Ne3,7062,GRP_DM_AGRICULTURE,DM_COMMENT,"145 bu/ac (9.10 MG ha-1) 15.5% basis. Harvest MC 15.7%,JD9560" -US-Ne3,1970,GRP_DM_AGRICULTURE,DM_AGRICULTURE,Harvest -US-Ne3,1970,GRP_DM_AGRICULTURE,DM_DATE,20061003 -US-Ne3,1970,GRP_DM_AGRICULTURE,DM_COMMENT,61.6 bu/ac as is 9.4% MC. -US-Ne3,7063,GRP_DM_AGRICULTURE,DM_AGRICULTURE,Harvest -US-Ne3,7063,GRP_DM_AGRICULTURE,DM_DATE,20061009 -US-Ne3,7063,GRP_DM_AGRICULTURE,DM_COMMENT,61.6 bu/ac as is 9.4% MC. -US-Ne3,9640,GRP_DM_AGRICULTURE,DM_AGRICULTURE,Harvest -US-Ne3,9640,GRP_DM_AGRICULTURE,DM_DATE,20061014 -US-Ne3,9640,GRP_DM_AGRICULTURE,DM_COMMENT,61.6 bu/ac as is 9.4% MC. -US-Ne3,6203,GRP_DM_FERT_M,DM_FERT_M,N -US-Ne3,6203,GRP_DM_FERT_M,DM_DATE,20010516 -US-Ne3,6203,GRP_DM_FERT_M,DM_COMMENT,28% UAN 114lb N/ac ( 127.68 kg N ha-1 ) -US-Ne3,7920,GRP_DM_FERT_M,DM_FERT_M,N -US-Ne3,7920,GRP_DM_FERT_M,DM_DATE,20030421 -US-Ne3,7920,GRP_DM_FERT_M,DM_COMMENT,80.2 lb/ac ( 89.82 kg N ha-1 ) -US-Ne3,8763,GRP_DM_FERT_M,DM_FERT_M,N -US-Ne3,8763,GRP_DM_FERT_M,DM_DATE,20030422 -US-Ne3,8763,GRP_DM_FERT_M,DM_COMMENT,80.2 lb/ac ( 89.82 kg N ha-1 ) -US-Ne3,6204,GRP_DM_FERT_M,DM_FERT_M,N -US-Ne3,6204,GRP_DM_FERT_M,DM_DATE,20030423 -US-Ne3,6204,GRP_DM_FERT_M,DM_COMMENT,Rate 80.2 lb/ac ( 89.82 kg N ha-1 ) -US-Ne3,7935,GRP_DM_FERT_M,DM_FERT_M,N -US-Ne3,7935,GRP_DM_FERT_M,DM_DATE,20050407 -US-Ne3,7935,GRP_DM_FERT_M,DM_COMMENT,32%UAN 105 lb N/ac ( 117.6 kg N ha-1 ) -US-Ne3,6220,GRP_DM_FERT_M,DM_FERT_M,N -US-Ne3,6220,GRP_DM_FERT_M,DM_DATE,20050408 -US-Ne3,6220,GRP_DM_FERT_M,DM_COMMENT,32%UAN 105 lb N/ac ( 117.6 kg N ha-1 ) -US-Ne3,8761,GRP_DM_PESTICIDE,DM_PESTICIDE,Other -US-Ne3,8761,GRP_DM_PESTICIDE,DM_DATE,20010515 -US-Ne3,8761,GRP_DM_PESTICIDE,DM_COMMENT,"Axiom 15oz/ac. & Atrazine 1.0 lb/ac, Balance PRO 0.75oz/ac." -US-Ne3,4482,GRP_DM_PESTICIDE,DM_PESTICIDE,Other -US-Ne3,4482,GRP_DM_PESTICIDE,DM_DATE,20020418 -US-Ne3,4482,GRP_DM_PESTICIDE,DM_COMMENT,Glyphos- spot treatment -US-Ne3,7041,GRP_DM_PESTICIDE,DM_PESTICIDE,Other -US-Ne3,7041,GRP_DM_PESTICIDE,DM_DATE,20020517 -US-Ne3,7041,GRP_DM_PESTICIDE,DM_COMMENT,1 quart/ac -US-Ne3,8762,GRP_DM_PESTICIDE,DM_PESTICIDE,Other -US-Ne3,8762,GRP_DM_PESTICIDE,DM_DATE,20020617 -US-Ne3,8762,GRP_DM_PESTICIDE,DM_COMMENT,"Gyphos (roundup)-spot application, target areas" -US-Ne3,1104,GRP_DM_PESTICIDE,DM_PESTICIDE,Other -US-Ne3,1104,GRP_DM_PESTICIDE,DM_DATE,20021107 -US-Ne3,1104,GRP_DM_PESTICIDE,DM_COMMENT,Atrazine -US-Ne3,295,GRP_DM_PESTICIDE,DM_PESTICIDE,Other -US-Ne3,295,GRP_DM_PESTICIDE,DM_DATE,20030513 -US-Ne3,295,GRP_DM_PESTICIDE,DM_COMMENT,"Harness Xtra 5.6L 1.8 qt/ac, Hornet 3 oz/ac, Roundup II 20 oz/ac, AMS (ammonium sulfate) 2lb/ac" -US-Ne3,6219,GRP_DM_PESTICIDE,DM_PESTICIDE,Other -US-Ne3,6219,GRP_DM_PESTICIDE,DM_DATE,20030617 -US-Ne3,6219,GRP_DM_PESTICIDE,DM_COMMENT,"Spot treatment, Accent .67oz/ac, Calisto 3oz/ac, COC, AMS 2acres" -US-Ne3,1968,GRP_DM_PESTICIDE,DM_PESTICIDE,Other -US-Ne3,1968,GRP_DM_PESTICIDE,DM_DATE,20030623 -US-Ne3,1968,GRP_DM_PESTICIDE,DM_COMMENT,"Spot treatment, Aim 0.5oz/ac, NIS 0.1qt/ac, AMS (ammonium sulfate) 2lb/ac 20ac NW/SE" -US-Ne3,7060,GRP_DM_PESTICIDE,DM_PESTICIDE,Other -US-Ne3,7060,GRP_DM_PESTICIDE,DM_DATE,20030718 -US-Ne3,8778,GRP_DM_PESTICIDE,DM_PESTICIDE,Other -US-Ne3,8778,GRP_DM_PESTICIDE,DM_DATE,20040602 -US-Ne3,8778,GRP_DM_PESTICIDE,DM_COMMENT,"Harness Xtra 5.6L 1.8 qt/ac, Hornet 3 oz/ac, Roundup II 20 oz/ac, AMS (ammonium sulfate) 2lb/ac" -US-Ne3,4499,GRP_DM_PESTICIDE,DM_PESTICIDE,Other -US-Ne3,4499,GRP_DM_PESTICIDE,DM_DATE,20040617 -US-Ne3,4499,GRP_DM_PESTICIDE,DM_COMMENT,"Spot treatment- Accent .67oz, Calisto 3oz, COC, AMS 2ac" -US-Ne3,7061,GRP_DM_PESTICIDE,DM_PESTICIDE,Other -US-Ne3,7061,GRP_DM_PESTICIDE,DM_DATE,20040623 -US-Ne3,7061,GRP_DM_PESTICIDE,DM_COMMENT,"Spot treatment - Aim 0.5oz, NIS 0.1qt, AMS 2lb 20ac NW/SE" -US-Ne3,5369,GRP_DM_PESTICIDE,DM_PESTICIDE,Other -US-Ne3,5369,GRP_DM_PESTICIDE,DM_DATE,20050427 -US-Ne3,5369,GRP_DM_PESTICIDE,DM_COMMENT,"Keystone 2.6 qt/ac, Hornet 3.0 oz/ac, 2,4D 4LV 0.5pt/ac, COC 1.0pt/ac" -US-Ne3,8781,GRP_DM_PESTICIDE,DM_PESTICIDE,Other -US-Ne3,8781,GRP_DM_PESTICIDE,DM_DATE,20051111 -US-Ne3,8781,GRP_DM_PESTICIDE,DM_COMMENT,"2,4D 1.0 qt/ac" -US-Ne3,4500,GRP_DM_PESTICIDE,DM_PESTICIDE,Other -US-Ne3,4500,GRP_DM_PESTICIDE,DM_DATE,20060419 -US-Ne3,4500,GRP_DM_PESTICIDE,DM_COMMENT,"Canopy 3.5 oz/ac, 2-4D 4LV 0.5pt/ac, Crop Oil 0.5 pt/ac" -US-Ne3,1969,GRP_DM_PESTICIDE,DM_PESTICIDE,Other -US-Ne3,1969,GRP_DM_PESTICIDE,DM_DATE,20060621 -US-Ne3,1969,GRP_DM_PESTICIDE,DM_COMMENT,"GlyStarPlus (glyphosate) 48 oz, AMS 2 lb + NIS 1.6 oz Spot 61 acre" -US-Ne3,7937,GRP_DM_PESTICIDE,DM_PESTICIDE,Other -US-Ne3,7937,GRP_DM_PESTICIDE,DM_DATE,20061114 -US-Ne3,7937,GRP_DM_PESTICIDE,DM_COMMENT,"2,4D 4LV 2.0 pt/ac" -US-Ne3,9626,GRP_DM_PLANTING,DM_PLANTING,Sowing crop seeds -US-Ne3,9626,GRP_DM_PLANTING,DM_DATE,20010514 -US-Ne3,9626,GRP_DM_PLANTING,DM_COMMENT,"maize Pioneer 33B51 BT Gaucho 25,187 seed/ac ( 62,236 seed ha-1) 125.8 ac, maize Pioneer 33B50 Gaucho 25,231( 62,344 seed ha-1) (refuge) 35.6 ac" -US-Ne3,3656,GRP_DM_PLANTING,DM_PLANTING,Sowing crop seeds -US-Ne3,3656,GRP_DM_PLANTING,DM_DATE,20020520 -US-Ne3,3656,GRP_DM_PLANTING,DM_COMMENT,"soybeans Asgrow 2703 Roundup Ready 150,000/acre (370,644 seed ha-1 )" -US-Ne3,7934,GRP_DM_PLANTING,DM_PLANTING,Sowing crop seeds -US-Ne3,7934,GRP_DM_PLANTING,DM_DATE,20030513 -US-Ne3,7934,GRP_DM_PLANTING,DM_COMMENT,"maize Pioneer 33B51 BT Gaucho 26,019 ( 64,292 seed ha-1 ) 73.6 ac IH, maize Pioneer 33B51 BT Gaucho 26,754 ( 66,108 seed ha-1 ) 56.7 ac JD, Pioneer 33B50 Gaucho 26,112 ( 64,521 seed ha-1 ) (refuge) 33.7 ac 1367 seeds/lb, JD7410/JD1750 Refuge and 56." -US-Ne3,2816,GRP_DM_PLANTING,DM_PLANTING,Sowing crop seeds -US-Ne3,2816,GRP_DM_PLANTING,DM_DATE,20040602 -US-Ne3,2816,GRP_DM_PLANTING,DM_COMMENT,"soybean Pioneer 93B09 150,000 seed/ac (370,644 seed ha-1)" -US-Ne3,8780,GRP_DM_PLANTING,DM_PLANTING,Sowing crop seeds -US-Ne3,8780,GRP_DM_PLANTING,DM_DATE,20050426 -US-Ne3,8780,GRP_DM_PLANTING,DM_COMMENT,"maize Pioneer 33G66 BT Poncho250 treated corn 23,952 seed/ac ( 59,184 seed ha-1 ) 33.4 ac" -US-Ne3,3666,GRP_DM_PLANTING,DM_PLANTING,Sowing crop seeds -US-Ne3,3666,GRP_DM_PLANTING,DM_DATE,20050427 -US-Ne3,3666,GRP_DM_PLANTING,DM_COMMENT,"maize Pioneer 33G68 BT Poncho250 treated corn 24,427 seed/ac ( 60,358 seed ha-1 ) 129.2 ac," -US-Ne3,9639,GRP_DM_PLANTING,DM_PLANTING,Sowing crop seeds -US-Ne3,9639,GRP_DM_PLANTING,DM_DATE,20060511 -US-Ne3,9639,GRP_DM_PLANTING,DM_COMMENT,"Soybean Pioneer 93M11 150,000 seed/ac (370,644 seed ha-1 )" -US-Ne3,6202,GRP_DM_TILL,DM_TILL,Other -US-Ne3,6202,GRP_DM_TILL,DM_DATE,20010409 -US-Ne3,6202,GRP_DM_TILL,DM_COMMENT,field-disk -US-Ne3,7919,GRP_DM_TILL,DM_TILL,Other -US-Ne3,7919,GRP_DM_TILL,DM_DATE,20010410 -US-Ne3,7919,GRP_DM_TILL,DM_COMMENT,field-disk -US-Ne3,276,GRP_DM_TILL,DM_TILL,Other -US-Ne3,276,GRP_DM_TILL,DM_DATE,20010416 -US-Ne3,276,GRP_DM_TILL,DM_COMMENT,field-disk -US-Ne3,9625,GRP_DM_TILL,DM_TILL,Other -US-Ne3,9625,GRP_DM_TILL,DM_DATE,20010420 -US-Ne3,9625,GRP_DM_TILL,DM_COMMENT,field-cultivator -US-Ne3,1102,GRP_DM_TILL,DM_TILL,Other -US-Ne3,1102,GRP_DM_TILL,DM_DATE,20011108 -US-Ne3,1102,GRP_DM_TILL,DM_COMMENT,subsoiler -US-Ne3,15729,GRP_DOI,DOI,10.17190/AMF/1246086 -US-Ne3,15729,GRP_DOI,DOI_CITATION,"Andy Suyker (2022), AmeriFlux BASE US-Ne3 Mead - rainfed maize-soybean rotation site, Ver. 12-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1246086" -US-Ne3,15729,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-Ne3,32147,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Ne3,32147,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Andy Suyker -US-Ne3,32147,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Ne3,32147,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,asuyker1@unl.edu -US-Ne3,32147,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of Nebraska - Lincoln -US-Ne3,32149,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,University of Nebraska - Lincoln -US-Ne3,32149,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-Ne3,32148,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,DOE (OBER & EPSCoR) -US-Ne3,32148,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-Ne3,1666,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Agriculture -US-Ne3,3785,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Ne3,3785,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-Ne3,3785,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,2001 -US-Ne3,3785,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Ne3,23000405,GRP_HEADER,SITE_NAME,Mead - rainfed maize-soybean rotation site -US-Ne3,88987,GRP_HEIGHTC,HEIGHTC,0.000 -US-Ne3,88987,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne3,88987,GRP_HEIGHTC,HEIGHTC_DATE,20010521 -US-Ne3,89044,GRP_HEIGHTC,HEIGHTC,0.115 -US-Ne3,89044,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne3,89044,GRP_HEIGHTC,HEIGHTC_DATE,20010529 -US-Ne3,89070,GRP_HEIGHTC,HEIGHTC,0.479 -US-Ne3,89070,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne3,89070,GRP_HEIGHTC,HEIGHTC_DATE,20010613 -US-Ne3,89090,GRP_HEIGHTC,HEIGHTC,0.806 -US-Ne3,89090,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne3,89090,GRP_HEIGHTC,HEIGHTC_DATE,20010621 -US-Ne3,89006,GRP_HEIGHTC,HEIGHTC,1.067 -US-Ne3,89006,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne3,89006,GRP_HEIGHTC,HEIGHTC_DATE,20010628 -US-Ne3,89003,GRP_HEIGHTC,HEIGHTC,1.594 -US-Ne3,89003,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne3,89003,GRP_HEIGHTC,HEIGHTC_DATE,20010705 -US-Ne3,89005,GRP_HEIGHTC,HEIGHTC,1.940 -US-Ne3,89005,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne3,89005,GRP_HEIGHTC,HEIGHTC_DATE,20010711 -US-Ne3,89037,GRP_HEIGHTC,HEIGHTC,2.401 -US-Ne3,89037,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne3,89037,GRP_HEIGHTC,HEIGHTC_DATE,20010718 -US-Ne3,89067,GRP_HEIGHTC,HEIGHTC,2.662 -US-Ne3,89067,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne3,89067,GRP_HEIGHTC,HEIGHTC_DATE,20010807 -US-Ne3,89093,GRP_HEIGHTC,HEIGHTC,2.664 -US-Ne3,89093,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne3,89093,GRP_HEIGHTC,HEIGHTC_DATE,20010814 -US-Ne3,89080,GRP_HEIGHTC,HEIGHTC,0.000 -US-Ne3,89080,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne3,89080,GRP_HEIGHTC,HEIGHTC_DATE,20020528 -US-Ne3,88985,GRP_HEIGHTC,HEIGHTC,0.124 -US-Ne3,88985,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne3,88985,GRP_HEIGHTC,HEIGHTC_DATE,20020611 -US-Ne3,88995,GRP_HEIGHTC,HEIGHTC,0.267 -US-Ne3,88995,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne3,88995,GRP_HEIGHTC,HEIGHTC_DATE,20020625 -US-Ne3,89030,GRP_HEIGHTC,HEIGHTC,0.455 -US-Ne3,89030,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne3,89030,GRP_HEIGHTC,HEIGHTC_DATE,20020709 -US-Ne3,89091,GRP_HEIGHTC,HEIGHTC,0.703 -US-Ne3,89091,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne3,89091,GRP_HEIGHTC,HEIGHTC_DATE,20020726 -US-Ne3,89018,GRP_HEIGHTC,HEIGHTC,0.765 -US-Ne3,89018,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne3,89018,GRP_HEIGHTC,HEIGHTC_DATE,20020809 -US-Ne3,89036,GRP_HEIGHTC,HEIGHTC,0.663 -US-Ne3,89036,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne3,89036,GRP_HEIGHTC,HEIGHTC_DATE,20020904 -US-Ne3,89064,GRP_HEIGHTC,HEIGHTC,0.662 -US-Ne3,89064,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne3,89064,GRP_HEIGHTC,HEIGHTC_DATE,20020918 -US-Ne3,89034,GRP_HEIGHTC,HEIGHTC,0.000 -US-Ne3,89034,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne3,89034,GRP_HEIGHTC,HEIGHTC_DATE,20030522 -US-Ne3,89013,GRP_HEIGHTC,HEIGHTC,0.268 -US-Ne3,89013,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne3,89013,GRP_HEIGHTC,HEIGHTC_DATE,20030606 -US-Ne3,89027,GRP_HEIGHTC,HEIGHTC,0.721 -US-Ne3,89027,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne3,89027,GRP_HEIGHTC,HEIGHTC_DATE,20030619 -US-Ne3,89023,GRP_HEIGHTC,HEIGHTC,1.495 -US-Ne3,89023,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne3,89023,GRP_HEIGHTC,HEIGHTC_DATE,20030703 -US-Ne3,89076,GRP_HEIGHTC,HEIGHTC,2.085 -US-Ne3,89076,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne3,89076,GRP_HEIGHTC,HEIGHTC_DATE,20030714 -US-Ne3,89074,GRP_HEIGHTC,HEIGHTC,2.405 -US-Ne3,89074,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne3,89074,GRP_HEIGHTC,HEIGHTC_DATE,20030723 -US-Ne3,88972,GRP_HEIGHTC,HEIGHTC,2.431 -US-Ne3,88972,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne3,88972,GRP_HEIGHTC,HEIGHTC_DATE,20030804 -US-Ne3,89048,GRP_HEIGHTC,HEIGHTC,2.505 -US-Ne3,89048,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne3,89048,GRP_HEIGHTC,HEIGHTC_DATE,20030820 -US-Ne3,89092,GRP_HEIGHTC,HEIGHTC,2.475 -US-Ne3,89092,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne3,89092,GRP_HEIGHTC,HEIGHTC_DATE,20030904 -US-Ne3,89046,GRP_HEIGHTC,HEIGHTC,0.000 -US-Ne3,89046,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne3,89046,GRP_HEIGHTC,HEIGHTC_DATE,20040608 -US-Ne3,89024,GRP_HEIGHTC,HEIGHTC,0.101 -US-Ne3,89024,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne3,89024,GRP_HEIGHTC,HEIGHTC_DATE,20040624 -US-Ne3,88969,GRP_HEIGHTC,HEIGHTC,0.171 -US-Ne3,88969,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne3,88969,GRP_HEIGHTC,HEIGHTC_DATE,20040706 -US-Ne3,89007,GRP_HEIGHTC,HEIGHTC,0.378 -US-Ne3,89007,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne3,89007,GRP_HEIGHTC,HEIGHTC_DATE,20040716 -US-Ne3,89063,GRP_HEIGHTC,HEIGHTC,0.581 -US-Ne3,89063,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne3,89063,GRP_HEIGHTC,HEIGHTC_DATE,20040729 -US-Ne3,89068,GRP_HEIGHTC,HEIGHTC,0.765 -US-Ne3,89068,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne3,89068,GRP_HEIGHTC,HEIGHTC_DATE,20040810 -US-Ne3,88992,GRP_HEIGHTC,HEIGHTC,0.857 -US-Ne3,88992,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne3,88992,GRP_HEIGHTC,HEIGHTC_DATE,20040819 -US-Ne3,89045,GRP_HEIGHTC,HEIGHTC,0.883 -US-Ne3,89045,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne3,89045,GRP_HEIGHTC,HEIGHTC_DATE,20040909 -US-Ne3,89071,GRP_HEIGHTC,HEIGHTC,0.000 -US-Ne3,89071,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne3,89071,GRP_HEIGHTC,HEIGHTC_DATE,20050511 -US-Ne3,88982,GRP_HEIGHTC,HEIGHTC,0.208 -US-Ne3,88982,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne3,88982,GRP_HEIGHTC,HEIGHTC_DATE,20050524 -US-Ne3,89087,GRP_HEIGHTC,HEIGHTC,0.588 -US-Ne3,89087,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne3,89087,GRP_HEIGHTC,HEIGHTC_DATE,20050608 -US-Ne3,89021,GRP_HEIGHTC,HEIGHTC,1.224 -US-Ne3,89021,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne3,89021,GRP_HEIGHTC,HEIGHTC_DATE,20050621 -US-Ne3,89038,GRP_HEIGHTC,HEIGHTC,1.640 -US-Ne3,89038,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne3,89038,GRP_HEIGHTC,HEIGHTC_DATE,20050630 -US-Ne3,89075,GRP_HEIGHTC,HEIGHTC,2.210 -US-Ne3,89075,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne3,89075,GRP_HEIGHTC,HEIGHTC_DATE,20050714 -US-Ne3,89079,GRP_HEIGHTC,HEIGHTC,2.562 -US-Ne3,89079,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne3,89079,GRP_HEIGHTC,HEIGHTC_DATE,20050728 -US-Ne3,89032,GRP_HEIGHTC,HEIGHTC,2.529 -US-Ne3,89032,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne3,89032,GRP_HEIGHTC,HEIGHTC_DATE,20050808 -US-Ne3,89077,GRP_HEIGHTC,HEIGHTC,2.543 -US-Ne3,89077,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne3,89077,GRP_HEIGHTC,HEIGHTC_DATE,20050817 -US-Ne3,89008,GRP_HEIGHTC,HEIGHTC,0.000 -US-Ne3,89008,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne3,89008,GRP_HEIGHTC,HEIGHTC_DATE,20060522 -US-Ne3,89014,GRP_HEIGHTC,HEIGHTC,0.083 -US-Ne3,89014,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne3,89014,GRP_HEIGHTC,HEIGHTC_DATE,20060602 -US-Ne3,89055,GRP_HEIGHTC,HEIGHTC,0.133 -US-Ne3,89055,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne3,89055,GRP_HEIGHTC,HEIGHTC_DATE,20060613 -US-Ne3,88971,GRP_HEIGHTC,HEIGHTC,0.217 -US-Ne3,88971,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne3,88971,GRP_HEIGHTC,HEIGHTC_DATE,20060621 -US-Ne3,88988,GRP_HEIGHTC,HEIGHTC,0.307 -US-Ne3,88988,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne3,88988,GRP_HEIGHTC,HEIGHTC_DATE,20060629 -US-Ne3,88996,GRP_HEIGHTC,HEIGHTC,0.478 -US-Ne3,88996,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne3,88996,GRP_HEIGHTC,HEIGHTC_DATE,20060711 -US-Ne3,89083,GRP_HEIGHTC,HEIGHTC,0.642 -US-Ne3,89083,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne3,89083,GRP_HEIGHTC,HEIGHTC_DATE,20060717 -US-Ne3,89020,GRP_HEIGHTC,HEIGHTC,0.807 -US-Ne3,89020,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne3,89020,GRP_HEIGHTC,HEIGHTC_DATE,20060725 -US-Ne3,89040,GRP_HEIGHTC,HEIGHTC,0.930 -US-Ne3,89040,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne3,89040,GRP_HEIGHTC,HEIGHTC_DATE,20060801 -US-Ne3,88990,GRP_HEIGHTC,HEIGHTC,0.985 -US-Ne3,88990,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne3,88990,GRP_HEIGHTC,HEIGHTC_DATE,20060810 -US-Ne3,89082,GRP_HEIGHTC,HEIGHTC,0.972 -US-Ne3,89082,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne3,89082,GRP_HEIGHTC,HEIGHTC_DATE,20060816 -US-Ne3,88989,GRP_HEIGHTC,HEIGHTC,0.935 -US-Ne3,88989,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne3,88989,GRP_HEIGHTC,HEIGHTC_DATE,20060830 -US-Ne3,89060,GRP_HEIGHTC,HEIGHTC,0.882 -US-Ne3,89060,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne3,89060,GRP_HEIGHTC,HEIGHTC_DATE,20060918 -US-Ne3,88975,GRP_HEIGHTC,HEIGHTC,0.865 -US-Ne3,88975,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne3,88975,GRP_HEIGHTC,HEIGHTC_DATE,20061009 -US-Ne3,89031,GRP_HEIGHTC,HEIGHTC,0.000 -US-Ne3,89031,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne3,89031,GRP_HEIGHTC,HEIGHTC_DATE,20070513 -US-Ne3,89073,GRP_HEIGHTC,HEIGHTC,0.368 -US-Ne3,89073,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne3,89073,GRP_HEIGHTC,HEIGHTC_DATE,20070530 -US-Ne3,89066,GRP_HEIGHTC,HEIGHTC,0.706 -US-Ne3,89066,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne3,89066,GRP_HEIGHTC,HEIGHTC_DATE,20070611 -US-Ne3,89053,GRP_HEIGHTC,HEIGHTC,1.055 -US-Ne3,89053,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne3,89053,GRP_HEIGHTC,HEIGHTC_DATE,20070618 -US-Ne3,89052,GRP_HEIGHTC,HEIGHTC,1.559 -US-Ne3,89052,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne3,89052,GRP_HEIGHTC,HEIGHTC_DATE,20070625 -US-Ne3,89025,GRP_HEIGHTC,HEIGHTC,1.937 -US-Ne3,89025,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne3,89025,GRP_HEIGHTC,HEIGHTC_DATE,20070702 -US-Ne3,88986,GRP_HEIGHTC,HEIGHTC,2.263 -US-Ne3,88986,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne3,88986,GRP_HEIGHTC,HEIGHTC_DATE,20070711 -US-Ne3,89009,GRP_HEIGHTC,HEIGHTC,2.492 -US-Ne3,89009,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne3,89009,GRP_HEIGHTC,HEIGHTC_DATE,20070723 -US-Ne3,89028,GRP_HEIGHTC,HEIGHTC,2.514 -US-Ne3,89028,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne3,89028,GRP_HEIGHTC,HEIGHTC_DATE,20070801 -US-Ne3,89041,GRP_HEIGHTC,HEIGHTC,2.512 -US-Ne3,89041,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne3,89041,GRP_HEIGHTC,HEIGHTC_DATE,20070814 -US-Ne3,89039,GRP_HEIGHTC,HEIGHTC,0.000 -US-Ne3,89039,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne3,89039,GRP_HEIGHTC,HEIGHTC_DATE,20080525 -US-Ne3,89086,GRP_HEIGHTC,HEIGHTC,0.093 -US-Ne3,89086,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne3,89086,GRP_HEIGHTC,HEIGHTC_DATE,20080611 -US-Ne3,89061,GRP_HEIGHTC,HEIGHTC,0.117 -US-Ne3,89061,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne3,89061,GRP_HEIGHTC,HEIGHTC_DATE,20080617 -US-Ne3,89000,GRP_HEIGHTC,HEIGHTC,0.186 -US-Ne3,89000,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne3,89000,GRP_HEIGHTC,HEIGHTC_DATE,20080625 -US-Ne3,89017,GRP_HEIGHTC,HEIGHTC,0.273 -US-Ne3,89017,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne3,89017,GRP_HEIGHTC,HEIGHTC_DATE,20080707 -US-Ne3,89042,GRP_HEIGHTC,HEIGHTC,0.352 -US-Ne3,89042,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne3,89042,GRP_HEIGHTC,HEIGHTC_DATE,20080714 -US-Ne3,89004,GRP_HEIGHTC,HEIGHTC,0.515 -US-Ne3,89004,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne3,89004,GRP_HEIGHTC,HEIGHTC_DATE,20080722 -US-Ne3,89062,GRP_HEIGHTC,HEIGHTC,0.650 -US-Ne3,89062,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne3,89062,GRP_HEIGHTC,HEIGHTC_DATE,20080728 -US-Ne3,89072,GRP_HEIGHTC,HEIGHTC,0.722 -US-Ne3,89072,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne3,89072,GRP_HEIGHTC,HEIGHTC_DATE,20080804 -US-Ne3,89019,GRP_HEIGHTC,HEIGHTC,0.727 -US-Ne3,89019,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne3,89019,GRP_HEIGHTC,HEIGHTC_DATE,20080811 -US-Ne3,89054,GRP_HEIGHTC,HEIGHTC,0.810 -US-Ne3,89054,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne3,89054,GRP_HEIGHTC,HEIGHTC_DATE,20080819 -US-Ne3,89057,GRP_HEIGHTC,HEIGHTC,0.805 -US-Ne3,89057,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne3,89057,GRP_HEIGHTC,HEIGHTC_DATE,20080904 -US-Ne3,88970,GRP_HEIGHTC,HEIGHTC,0.728 -US-Ne3,88970,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne3,88970,GRP_HEIGHTC,HEIGHTC_DATE,20080918 -US-Ne3,89016,GRP_HEIGHTC,HEIGHTC,0.727 -US-Ne3,89016,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne3,89016,GRP_HEIGHTC,HEIGHTC_DATE,20080926 -US-Ne3,89029,GRP_HEIGHTC,HEIGHTC,0.000 -US-Ne3,89029,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne3,89029,GRP_HEIGHTC,HEIGHTC_DATE,20090507 -US-Ne3,89050,GRP_HEIGHTC,HEIGHTC,0.211 -US-Ne3,89050,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne3,89050,GRP_HEIGHTC,HEIGHTC_DATE,20090521 -US-Ne3,88973,GRP_HEIGHTC,HEIGHTC,0.379 -US-Ne3,88973,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne3,88973,GRP_HEIGHTC,HEIGHTC_DATE,20090529 -US-Ne3,88983,GRP_HEIGHTC,HEIGHTC,0.602 -US-Ne3,88983,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne3,88983,GRP_HEIGHTC,HEIGHTC_DATE,20090604 -US-Ne3,89001,GRP_HEIGHTC,HEIGHTC,0.808 -US-Ne3,89001,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne3,89001,GRP_HEIGHTC,HEIGHTC_DATE,20090610 -US-Ne3,88968,GRP_HEIGHTC,HEIGHTC,1.176 -US-Ne3,88968,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne3,88968,GRP_HEIGHTC,HEIGHTC_DATE,20090617 -US-Ne3,89088,GRP_HEIGHTC,HEIGHTC,1.979 -US-Ne3,89088,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne3,89088,GRP_HEIGHTC,HEIGHTC_DATE,20090625 -US-Ne3,89022,GRP_HEIGHTC,HEIGHTC,2.327 -US-Ne3,89022,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne3,89022,GRP_HEIGHTC,HEIGHTC_DATE,20090701 -US-Ne3,88993,GRP_HEIGHTC,HEIGHTC,2.765 -US-Ne3,88993,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne3,88993,GRP_HEIGHTC,HEIGHTC_DATE,20090708 -US-Ne3,88998,GRP_HEIGHTC,HEIGHTC,2.959 -US-Ne3,88998,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne3,88998,GRP_HEIGHTC,HEIGHTC_DATE,20090716 -US-Ne3,89078,GRP_HEIGHTC,HEIGHTC,2.953 -US-Ne3,89078,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne3,89078,GRP_HEIGHTC,HEIGHTC_DATE,20090727 -US-Ne3,88974,GRP_HEIGHTC,HEIGHTC,3.049 -US-Ne3,88974,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne3,88974,GRP_HEIGHTC,HEIGHTC_DATE,20090805 -US-Ne3,89010,GRP_HEIGHTC,HEIGHTC,0.000 -US-Ne3,89010,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne3,89010,GRP_HEIGHTC,HEIGHTC_DATE,20100527 -US-Ne3,89035,GRP_HEIGHTC,HEIGHTC,0.148 -US-Ne3,89035,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne3,89035,GRP_HEIGHTC,HEIGHTC_DATE,20100615 -US-Ne3,89047,GRP_HEIGHTC,HEIGHTC,0.176 -US-Ne3,89047,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne3,89047,GRP_HEIGHTC,HEIGHTC_DATE,20100622 -US-Ne3,89085,GRP_HEIGHTC,HEIGHTC,0.293 -US-Ne3,89085,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne3,89085,GRP_HEIGHTC,HEIGHTC_DATE,20100630 -US-Ne3,88979,GRP_HEIGHTC,HEIGHTC,0.365 -US-Ne3,88979,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne3,88979,GRP_HEIGHTC,HEIGHTC_DATE,20100708 -US-Ne3,89089,GRP_HEIGHTC,HEIGHTC,0.612 -US-Ne3,89089,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne3,89089,GRP_HEIGHTC,HEIGHTC_DATE,20100721 -US-Ne3,88978,GRP_HEIGHTC,HEIGHTC,0.797 -US-Ne3,88978,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne3,88978,GRP_HEIGHTC,HEIGHTC_DATE,20100729 -US-Ne3,89049,GRP_HEIGHTC,HEIGHTC,0.883 -US-Ne3,89049,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne3,89049,GRP_HEIGHTC,HEIGHTC_DATE,20100806 -US-Ne3,89081,GRP_HEIGHTC,HEIGHTC,0.935 -US-Ne3,89081,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne3,89081,GRP_HEIGHTC,HEIGHTC_DATE,20100813 -US-Ne3,89011,GRP_HEIGHTC,HEIGHTC,0.925 -US-Ne3,89011,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne3,89011,GRP_HEIGHTC,HEIGHTC_DATE,20100903 -US-Ne3,89065,GRP_HEIGHTC,HEIGHTC,0.880 -US-Ne3,89065,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne3,89065,GRP_HEIGHTC,HEIGHTC_DATE,20101001 -US-Ne3,89043,GRP_HEIGHTC,HEIGHTC,0.000 -US-Ne3,89043,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne3,89043,GRP_HEIGHTC,HEIGHTC_DATE,20110513 -US-Ne3,88981,GRP_HEIGHTC,HEIGHTC,0.130 -US-Ne3,88981,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne3,88981,GRP_HEIGHTC,HEIGHTC_DATE,20110526 -US-Ne3,88984,GRP_HEIGHTC,HEIGHTC,0.337 -US-Ne3,88984,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne3,88984,GRP_HEIGHTC,HEIGHTC_DATE,20110607 -US-Ne3,88991,GRP_HEIGHTC,HEIGHTC,0.587 -US-Ne3,88991,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne3,88991,GRP_HEIGHTC,HEIGHTC_DATE,20110617 -US-Ne3,89012,GRP_HEIGHTC,HEIGHTC,1.098 -US-Ne3,89012,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne3,89012,GRP_HEIGHTC,HEIGHTC_DATE,20110628 -US-Ne3,89056,GRP_HEIGHTC,HEIGHTC,1.892 -US-Ne3,89056,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne3,89056,GRP_HEIGHTC,HEIGHTC_DATE,20110708 -US-Ne3,88994,GRP_HEIGHTC,HEIGHTC,2.370 -US-Ne3,88994,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne3,88994,GRP_HEIGHTC,HEIGHTC_DATE,20110715 -US-Ne3,89084,GRP_HEIGHTC,HEIGHTC,2.558 -US-Ne3,89084,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne3,89084,GRP_HEIGHTC,HEIGHTC_DATE,20110726 -US-Ne3,89058,GRP_HEIGHTC,HEIGHTC,2.601 -US-Ne3,89058,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne3,89058,GRP_HEIGHTC,HEIGHTC_DATE,20110804 -US-Ne3,89095,GRP_HEIGHTC,HEIGHTC,0.000 -US-Ne3,89095,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne3,89095,GRP_HEIGHTC,HEIGHTC_DATE,20120521 -US-Ne3,89026,GRP_HEIGHTC,HEIGHTC,0.062 -US-Ne3,89026,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne3,89026,GRP_HEIGHTC,HEIGHTC_DATE,20120530 -US-Ne3,89015,GRP_HEIGHTC,HEIGHTC,0.115 -US-Ne3,89015,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne3,89015,GRP_HEIGHTC,HEIGHTC_DATE,20120606 -US-Ne3,88999,GRP_HEIGHTC,HEIGHTC,0.190 -US-Ne3,88999,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne3,88999,GRP_HEIGHTC,HEIGHTC_DATE,20120615 -US-Ne3,89051,GRP_HEIGHTC,HEIGHTC,0.258 -US-Ne3,89051,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne3,89051,GRP_HEIGHTC,HEIGHTC_DATE,20120621 -US-Ne3,89069,GRP_HEIGHTC,HEIGHTC,0.418 -US-Ne3,89069,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne3,89069,GRP_HEIGHTC,HEIGHTC_DATE,20120628 -US-Ne3,89059,GRP_HEIGHTC,HEIGHTC,0.542 -US-Ne3,89059,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne3,89059,GRP_HEIGHTC,HEIGHTC_DATE,20120709 -US-Ne3,88976,GRP_HEIGHTC,HEIGHTC,0.737 -US-Ne3,88976,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne3,88976,GRP_HEIGHTC,HEIGHTC_DATE,20120717 -US-Ne3,89094,GRP_HEIGHTC,HEIGHTC,0.770 -US-Ne3,89094,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne3,89094,GRP_HEIGHTC,HEIGHTC_DATE,20120724 -US-Ne3,89002,GRP_HEIGHTC,HEIGHTC,0.860 -US-Ne3,89002,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne3,89002,GRP_HEIGHTC,HEIGHTC_DATE,20120731 -US-Ne3,88977,GRP_HEIGHTC,HEIGHTC,0.903 -US-Ne3,88977,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne3,88977,GRP_HEIGHTC,HEIGHTC_DATE,20120808 -US-Ne3,88980,GRP_HEIGHTC,HEIGHTC,0.930 -US-Ne3,88980,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne3,88980,GRP_HEIGHTC,HEIGHTC_DATE,20120816 -US-Ne3,89033,GRP_HEIGHTC,HEIGHTC,0.815 -US-Ne3,89033,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne3,89033,GRP_HEIGHTC,HEIGHTC_DATE,20120904 -US-Ne3,88997,GRP_HEIGHTC,HEIGHTC,0.825 -US-Ne3,88997,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ne3,88997,GRP_HEIGHTC,HEIGHTC_DATE,20120920 -US-Ne3,5349,GRP_IGBP,IGBP,CRO -US-Ne3,5349,GRP_IGBP,IGBP_COMMENT,Agriculture (maize-soybean rotation) -US-Ne3,24394,GRP_LAI,LAI_TYPE,LAI -US-Ne3,25170,GRP_LAI,LAI_TYPE,LAI -US-Ne3,25184,GRP_LAI,LAI_TYPE,LAI 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-US-Ne3,28697,GRP_LMA,LMA_DATE,20040706 -US-Ne3,28918,GRP_LMA,LMA,21.5 -US-Ne3,28918,GRP_LMA,LMA_SPP,ZEMAH (NRCS plant code) -US-Ne3,28918,GRP_LMA,LMA_DATE,20010628 -US-Ne3,29592,GRP_LMA,LMA,21.646 -US-Ne3,29592,GRP_LMA,LMA_SPP,ZEMAH (NRCS plant code) -US-Ne3,29592,GRP_LMA,LMA_DATE,20070618 -US-Ne3,28409,GRP_LMA,LMA,22.2231 -US-Ne3,28409,GRP_LMA,LMA_SPP,ZEMAH (NRCS plant code) -US-Ne3,28409,GRP_LMA,LMA_DATE,20070625 -US-Ne3,28919,GRP_LMA,LMA,22.38 -US-Ne3,28919,GRP_LMA,LMA_SPP,ZEMAH (NRCS plant code) -US-Ne3,28919,GRP_LMA,LMA_DATE,20030703 -US-Ne3,27800,GRP_LMA,LMA,23.19 -US-Ne3,27800,GRP_LMA,LMA_SPP,ZEMAH (NRCS plant code) -US-Ne3,27800,GRP_LMA,LMA_DATE,20010621 -US-Ne3,29600,GRP_LMA,LMA,23.47 -US-Ne3,29600,GRP_LMA,LMA_SPP,GLYMA4 (NRCS plant code) -US-Ne3,29600,GRP_LMA,LMA_DATE,20020904 -US-Ne3,27165,GRP_LMA,LMA,23.81 -US-Ne3,27165,GRP_LMA,LMA_SPP,ZEMAH (NRCS plant code) -US-Ne3,27165,GRP_LMA,LMA_DATE,20010705 -US-Ne3,27460,GRP_LMA,LMA,25.1939 -US-Ne3,27460,GRP_LMA,LMA_SPP,ZEMAH (NRCS plant code) -US-Ne3,27460,GRP_LMA,LMA_DATE,20070711 -US-Ne3,29396,GRP_LMA,LMA,25.6199 -US-Ne3,29396,GRP_LMA,LMA_SPP,ZEMAH (NRCS plant code) -US-Ne3,29396,GRP_LMA,LMA_DATE,20070702 -US-Ne3,29404,GRP_LMA,LMA,25.76 -US-Ne3,29404,GRP_LMA,LMA_SPP,ZEMAH (NRCS plant code) -US-Ne3,29404,GRP_LMA,LMA_DATE,20010711 -US-Ne3,28763,GRP_LMA,LMA,25.83 -US-Ne3,28763,GRP_LMA,LMA_SPP,ZEMAH (NRCS plant code) -US-Ne3,28763,GRP_LMA,LMA_DATE,20030714 -US-Ne3,28748,GRP_LMA,LMA,25.932 -US-Ne3,28748,GRP_LMA,LMA_SPP,GLYMA4 (NRCS plant code) -US-Ne3,28748,GRP_LMA,LMA_DATE,20060602 -US-Ne3,28415,GRP_LMA,LMA,26.41 -US-Ne3,28415,GRP_LMA,LMA_SPP,ZEMAH (NRCS plant code) -US-Ne3,28415,GRP_LMA,LMA_DATE,20010718 -US-Ne3,28921,GRP_LMA,LMA,26.54 -US-Ne3,28921,GRP_LMA,LMA_SPP,ZEMAH (NRCS plant code) -US-Ne3,28921,GRP_LMA,LMA_DATE,20050714 -US-Ne3,28061,GRP_LMA,LMA,26.8267 -US-Ne3,28061,GRP_LMA,LMA_SPP,ZEMAH (NRCS plant code) -US-Ne3,28061,GRP_LMA,LMA_DATE,20070814 -US-Ne3,27167,GRP_LMA,LMA,27.23 -US-Ne3,27167,GRP_LMA,LMA_SPP,ZEMAH (NRCS plant code) -US-Ne3,27167,GRP_LMA,LMA_DATE,20030723 -US-Ne3,29604,GRP_LMA,LMA,27.24 -US-Ne3,29604,GRP_LMA,LMA_SPP,ZEMAH (NRCS plant code) -US-Ne3,29604,GRP_LMA,LMA_DATE,20050728 -US-Ne3,27168,GRP_LMA,LMA,27.54 -US-Ne3,27168,GRP_LMA,LMA_SPP,ZEMAH (NRCS plant code) -US-Ne3,27168,GRP_LMA,LMA_DATE,20030820 -US-Ne3,27715,GRP_LMA,LMA,27.68 -US-Ne3,27715,GRP_LMA,LMA_SPP,ZEMAH (NRCS plant code) -US-Ne3,27715,GRP_LMA,LMA_DATE,20030904 -US-Ne3,28059,GRP_LMA,LMA,27.8593 -US-Ne3,28059,GRP_LMA,LMA_SPP,ZEMAH (NRCS plant code) -US-Ne3,28059,GRP_LMA,LMA_DATE,20070723 -US-Ne3,27166,GRP_LMA,LMA,28.25 -US-Ne3,27166,GRP_LMA,LMA_SPP,GLYMA4 (NRCS plant code) -US-Ne3,27166,GRP_LMA,LMA_DATE,20020918 -US-Ne3,29292,GRP_LMA,LMA,28.27 -US-Ne3,29292,GRP_LMA,LMA_SPP,ZEMAH (NRCS plant code) -US-Ne3,29292,GRP_LMA,LMA_DATE,20050808 -US-Ne3,28060,GRP_LMA,LMA,28.5217 -US-Ne3,28060,GRP_LMA,LMA_SPP,ZEMAH (NRCS plant code) -US-Ne3,28060,GRP_LMA,LMA_DATE,20070801 -US-Ne3,27716,GRP_LMA,LMA,28.63 -US-Ne3,27716,GRP_LMA,LMA_SPP,ZEMAH (NRCS plant code) -US-Ne3,27716,GRP_LMA,LMA_DATE,20050817 -US-Ne3,29601,GRP_LMA,LMA,29.12 -US-Ne3,29601,GRP_LMA,LMA_SPP,ZEMAH (NRCS plant code) -US-Ne3,29601,GRP_LMA,LMA_DATE,20030804 -US-Ne3,27707,GRP_LMA,LMA,29.6683 -US-Ne3,27707,GRP_LMA,LMA_SPP,ZEMAH (NRCS plant code) -US-Ne3,27707,GRP_LMA,LMA_DATE,20070828 -US-Ne3,28069,GRP_LMA,LMA,29.72 -US-Ne3,28069,GRP_LMA,LMA_SPP,ZEMAH (NRCS plant code) -US-Ne3,28069,GRP_LMA,LMA_DATE,20010814 -US-Ne3,28417,GRP_LMA,LMA,31.5 -US-Ne3,28417,GRP_LMA,LMA_SPP,ZEMAH (NRCS plant code) -US-Ne3,28417,GRP_LMA,LMA_DATE,20050907 -US-Ne3,27714,GRP_LMA,LMA,32.52 -US-Ne3,27714,GRP_LMA,LMA_SPP,ZEMAH (NRCS plant code) -US-Ne3,27714,GRP_LMA,LMA_DATE,20010807 -US-Ne3,27468,GRP_LMA,LMA,34.75 -US-Ne3,27468,GRP_LMA,LMA_SPP,ZEMAH (NRCS plant code) -US-Ne3,27468,GRP_LMA,LMA_DATE,20050926 -US-Ne3,29282,GRP_LMA,LMA,40.1062 -US-Ne3,29282,GRP_LMA,LMA_SPP,ZEMAH (NRCS plant code) -US-Ne3,29282,GRP_LMA,LMA_DATE,20070917 -US-Ne3,5833,GRP_LOCATION,LOCATION_LAT,41.1797 -US-Ne3,5833,GRP_LOCATION,LOCATION_LONG,-96.4397 -US-Ne3,5833,GRP_LOCATION,LOCATION_ELEV,363 -US-Ne3,1273,GRP_NETWORK,NETWORK,AmeriFlux -US-Ne3,1700007848,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Amos, B., Arkebauer, T. J., Doran, J. W. (2005) Soil Surface Fluxes Of Greenhouse Gases In An Irrigated Maize-Based Agroecosystem, Soil Science Society Of America Journal, 69(2), 387-395" -US-Ne3,1700007848,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.2136/SSSAJ2005.0387 -US-Ne3,1700007848,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ne3,1700003981,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Barr, A., Richardson, A., Hollinger, D., Papale, D., Arain, M., Black, T., Bohrer, G., Dragoni, D., Fischer, M., Gu, L., Law, B., Margolis, H., McCaughey, J., Munger, J., Oechel, W., Schaeffer, K. (2013) Use Of Change-Point Detection For Friction–Velocity Threshold Evaluation In Eddy-Covariance Studies, Agricultural And Forest Meteorology, 171-172(7), 31-45" -US-Ne3,1700003981,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2012.11.023 -US-Ne3,1700003981,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ne3,1700000603,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Cassman, K. G., Dobermann, A., Walters, D. T., Yang, H. (2003) Meeting Cereal Demand While Protecting Natural Resources And Improving Environmental Quality, Annual Review Of Environment And Resources, 28(1), 315-358" -US-Ne3,1700000603,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1146/ANNUREV.ENERGY.28.040202.122858 -US-Ne3,1700000603,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ne3,1700002688,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Baldocchi, D. D., Poindexter, C., Abraha, M., Desai, A. R., Bohrer, G., Arain, M. A., Griffis, T., Blanken, P. D., O'Halloran, T. L., Thomas, R. Q., Zhang, Q., Burns, S. P., Frank, J. M., Christian, D., Brown, S., Black, T. A., Gough, C. M., Law, B. E., Lee, X., Chen, J., Reed, D. E., Massman, W. J., Clark, K., Hatfield, J., Prueger, J., Bracho, R., Baker, J. M., Martin, T. A. (2018) Temporal Dynamics Of Aerodynamic Canopy Height Derived From Eddy Covariance Momentum Flux Data Across North American Flux Networks, Geophysical Research Letters, 45(5), 9275–9287" -US-Ne3,1700002688,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018GL079306 -US-Ne3,1700002688,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ne3,1700006240,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Baldocchi, D. D., Poindexter, C., Abraha, M., Desai, A. R., Bohrer, G., Arain, M. A., Griffis, T., Blanken, P. D., O'Halloran, T. L., Thomas, R. Q., Zhang, Q., Burns, S. P., Frank, J. M., Christian, D., Brown, S., Black, T. A., Gough, C. M., Law, B. E., Lee, X., Chen, J., Reed, D. E., Massman, W. J., Clark, K., Hatfield, J., Prueger, J., Bracho, R., Baker, J. M., Martin, T. A. (2018) Temporal Dynamics Of Aerodynamic Canopy Height Derived From Eddy Covariance Momentum Flux Data Across North American Flux Networks, Geophysical Research Letters, 45(6), 9275–9287" -US-Ne3,1700006240,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018GL079306 -US-Ne3,1700006240,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ne3,1700002103,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(6), 108350" -US-Ne3,1700002103,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -US-Ne3,1700002103,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ne3,1700005559,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Dobermann, A., Ping, J. L., Adamchuk, V. I., Simbahan, G. C., Ferguson, R. B. (2003) Classification Of Crop Yield Variability In Irrigated Production Fields, Agronomy Journal, 95(5), 1105-1120" -US-Ne3,1700005559,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.2134/AGRONJ2003.1105 -US-Ne3,1700005559,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ne3,1700007620,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Ginting, D., Eghball, B. (2005) Nitrous Oxide Emission From No-Till Irrigated Corn, Soil Science Society Of America Journal, 69(3), 915-925" -US-Ne3,1700007620,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.2136/SSSAJ2004.0292 -US-Ne3,1700007620,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ne3,1700000753,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Gitelson, A. A. (2004) Wide Dynamic Range Vegetation Index For Remote Quantification Of Biophysical Characteristics Of Vegetation, Journal Of Plant Physiology, 161(2), 165-173" -US-Ne3,1700000753,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1078/0176-1617-01176 -US-Ne3,1700000753,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ne3,1700005685,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Gitelson, A. A., Verma, S. B., Rundquist, D. C., Keydan, G., Leavitt, B., Arkebauer, T. J., Burba, G. G., Suyker, A. E. (2003) Novel Technique For Remote Estimation Of CO2 Flux In Maize, Geophysical Research Letters, 30(9), 1486-n/a" -US-Ne3,1700005685,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2002GL016543 -US-Ne3,1700005685,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ne3,1700005157,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Gitelson, A. A., Viña, A., Arkebauer, T. J., Rundquist, D. C., Keydan, G., Leavitt, B. (2003) Remote Estimation Of Leaf Area Index And Green Leaf Biomass In Maize Canopies, Geophysical Research Letters, 30(5), n/a-n/a" -US-Ne3,1700005157,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2002GL016450 -US-Ne3,1700005157,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ne3,1700001419,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Mahmood, R., Hubbard, K. G. (2005) Assessing Bias In Evapotranspiration And Soil Moisture Estimates Due To The Use Of Modeled Solar Radiation And Dew Point Temperature Data, Agricultural And Forest Meteorology, 130(1-2), 71-84" -US-Ne3,1700001419,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2005.02.004 -US-Ne3,1700001419,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ne3,1700001002,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Matheny, A. M., Bohrer, G., Stoy, P. C., Baker, I. T., Black, A. T., Desai, A. R., Dietze, M. C., Gough, C. M., Ivanov, V. Y., Jassal, R. S., Novick, K. A., Schäfer, K. V., Verbeeck, H. (2014) Characterizing The Diurnal Patterns of Errors in The Prediction of Evapotranspiration by Several Land-Surface Models: An Nacp Analysis, Journal Of Geophysical Research: Biogeosciences, 119(7), 1458-1473" -US-Ne3,1700001002,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/2014JG002623 -US-Ne3,1700001002,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ne3,1700008517,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"McCombs, A. G., Hiscox, A. L., Wang, C., Desai, A. R., Suyker, A. E., Biraud, S. C. (2018) Carbon Flux Phenology From The Sky: Evaluation For Maize And Soybean, Journal Of Atmospheric And Oceanic Technology, 35(4), 877-892" -US-Ne3,1700008517,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1175/JTECH-D-17-0004.1 -US-Ne3,1700008517,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ne3,1700006540,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Novick, K. A., Ficklin, D. L., Stoy, P. C., Williams, C. A., Bohrer, G., Oishi, A., Papuga, S. A., Blanken, P. D., Noormets, A., Sulman, B. N., Scott, R. L., Wang, L., Phillips, R. P. (2016) The Increasing Importance Of Atmospheric Demand For Ecosystem Water And Carbon Fluxes, Nature Climate Change, 6(11), 1023-1027" -US-Ne3,1700006540,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1038/NCLIMATE3114 -US-Ne3,1700006540,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ne3,1700002286,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Novick, K. A., Konings, A. G., Gentine, P. (2019) Beyond Soil Water Potential: An Expanded View On Isohydricity Including Land–Atmosphere Interactions And Phenology, Plant, Cell & Environment, 42(6), 1802-1815" -US-Ne3,1700002286,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/PCE.13517 -US-Ne3,1700002286,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ne3,1700004251,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Ping, J. L., Dobermann, A. (2003) Creating Spatially Contiguous Yield Classes For Site-Specific Management, Agronomy Journal, 95(5), 1121-1131" -US-Ne3,1700004251,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.2134/AGRONJ2003.1121 -US-Ne3,1700004251,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ne3,1700005598,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Ping, J. L., Dobermann, A. (2005) Processing Of Yield Map Data, Precision Agriculture, 6(2), 193-212" -US-Ne3,1700005598,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1007/S11119-005-1035-2 -US-Ne3,1700005598,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ne3,1700005139,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Richardson, A. D., Hollinger, D. Y., Burba, G. G., Davis, K. J., Flanagan, L. B., Katul, G. G., William Munger, J., Ricciuto, D. M., Stoy, P. C., Suyker, A. E., Verma, S. B., Wofsy, S. C. (2006) A Multi-Site Analysis Of Random Error In Tower-Based Measurements Of Carbon And Energy Fluxes, Agricultural And Forest Meteorology, 136(1-2), 1-18" -US-Ne3,1700005139,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2006.01.007 -US-Ne3,1700005139,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ne3,1700004905,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Simbahan, G. C., Dobermann, A., Goovaerts, P., Ping, J., Haddix, M. L. (2006) Fine-Resolution Mapping Of Soil Organic Carbon Based On Multivariate Secondary Data, Geoderma, 132(3-4), 471-489" -US-Ne3,1700004905,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.GEODERMA.2005.07.001 -US-Ne3,1700004905,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ne3,1700002793,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Simbahan, G. C., Dobermann, A., Ping, J. L. (2004) Screening Yield Monitor Data Improves Grain Yield Maps, Agronomy Journal, 96(4), 1091-1102" -US-Ne3,1700002793,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.2134/AGRONJ2004.1091 -US-Ne3,1700002793,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ne3,1700001455,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Sullivan, R. C., Cook, D. R., Ghate, V. P., Kotamarthi, V. R., Feng, Y. (2019) Improved Spatiotemporal Representativeness And Bias Reduction Of Satellite-Based Evapotranspiration Retrievals Via Use Of In Situ Meteorology And Constrained Canopy Surface Resistance, Journal Of Geophysical Research: Biogeosciences, 124(2), 342-352" -US-Ne3,1700001455,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018JG004744 -US-Ne3,1700001455,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ne3,1700008118,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Sullivan, R. C., Kotamarthi, V. R., Feng, Y. (2019) Recovering Evapotranspiration Trends From Biased CMIP5 Simulations And Sensitivity To Changing Climate Over North America, Journal Of Hydrometeorology, 20(8), 1619-1633" -US-Ne3,1700008118,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1175/JHM-D-18-0259.1 -US-Ne3,1700008118,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ne3,1700007188,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Suyker, A. E., Verma, S. B., Burba, G. G., Arkebauer, T. J. (2005) Gross Primary Production And Ecosystem Respiration Of Irrigated Maize And Irrigated Soybean During A Growing Season, Agricultural And Forest Meteorology, 131(3-4), 180-190" -US-Ne3,1700007188,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2005.05.007 -US-Ne3,1700007188,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ne3,1700004089,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Suyker, A., Verma, S., Burba, G., Arkebauer, T., Walters, D., Hubbard, K. (2004) Growing Season Carbon Dioxide Exchange In Irrigated And Rainfed Maize, Agricultural And Forest Meteorology, 124(1-2), 1-13" -US-Ne3,1700004089,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2004.01.011 -US-Ne3,1700004089,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ne3,1700004590,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Verma, S. B., Dobermann, A., Cassman, K. G., Walters, D. T., Knops, J. M., Arkebauer, T. J., Suyker, A. E., Burba, G. G., Amos, B., Yang, H., Ginting, D., Hubbard, K. G., Gitelson, A. A., Walter-Shea, E. A. (2005) Annual Carbon Dioxide Exchange In Irrigated And Rainfed Maize-Based Agroecosystems, Agricultural And Forest Meteorology, 131(1-2), 77-96" -US-Ne3,1700004590,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2005.05.003 -US-Ne3,1700004590,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ne3,1700005739,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Viña, A., Genebry, G.M., Gitelson, A. A. (2004) Satellite Monitoring Of Vegetation Dynamics: Sensitivity Enhancement By The Wide Dynamic Range Vegetation Index, Geophysical Research Letters, 31(4), 1-4" -US-Ne3,1700005739,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2003GL019034 -US-Ne3,1700005739,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ne3,1700007392,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Viña, A., Gitelson, A. A., Rundquist, D. C., Keydan, G., Leavitt, B., Schepers, J. (2004) Monitoring Maize (Zea Mays L.) Phenology With Remote Sensing, Agronomy Journal, 96(4), 1139-1147" -US-Ne3,1700007392,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.2134/AGRONJ2004.1139 -US-Ne3,1700007392,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ne3,1700001605,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Yang, H., Dobermann, A., Lindquist, J., Walters, D., Arkebauer, T., Cassman, K. (2004) Hybrid-Maize—A Maize Simulation Model That Combines Two Crop Modeling Approaches, Field Crops Research, 87(2-3), 131-154" -US-Ne3,1700001605,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.FCR.2003.10.003 -US-Ne3,1700001605,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ne3,1700008214,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Zhang, Q., Ficklin, D. L., Manzoni, S., Wang, L., Way, D., Phillips, R. P., Novick, K. A. (2019) Response Of Ecosystem Intrinsic Water Use Efficiency And Gross Primary Productivity To Rising Vapor Pressure Deficit, Environmental Research Letters, 14(7), 074023" -US-Ne3,1700008214,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1088/1748-9326/AB2603 -US-Ne3,1700008214,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ne3,10156,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,The overall goals are to investigate the C sequestration potential of major rainfed and irrigated agroecosystems in the north-central USA and to understand the biophysical controls on C sequestration. -US-Ne3,259,GRP_SITE_DESC,SITE_DESC,"The study site is one of three fields (all located within 1.6 km of each other) at the University of Nebraska Agricultural Research and Development Center near Mead, Nebraska. While the other two sites are equipped with irrigation systems, this site relies on rainfall. A tillage operation (disking) was done just prior to the 2001 planting to homogenize the top 0.1 m of soil, incorporate P and K fertilizers, as well as previously accumulated surface residues. Since initiation of the study in 2001, this site has been under no-till management." -US-Ne3,6708,GRP_SITE_FUNDING,SITE_FUNDING,DOE (OBER & EPSCoR) -US-Ne3,28654,GRP_SOIL_CHEM,SOIL_CHEM_C_ORG,27.8 -US-Ne3,29249,GRP_SOIL_CHEM,SOIL_CHEM_C_ORG,28.1 -US-Ne3,28653,GRP_SOIL_CHEM,SOIL_CHEM_C_ORG,31.9 -US-Ne3,29368,GRP_SOIL_CHEM,SOIL_CHEM_C_ORG,33.1 -US-Ne3,28654,GRP_SOIL_CHEM,SOIL_CHEM_N_TOT,2.5 -US-Ne3,29249,GRP_SOIL_CHEM,SOIL_CHEM_N_TOT,2.5 -US-Ne3,28653,GRP_SOIL_CHEM,SOIL_CHEM_N_TOT,3 -US-Ne3,29368,GRP_SOIL_CHEM,SOIL_CHEM_N_TOT,3 -US-Ne3,27767,GRP_SOIL_CHEM,SOIL_CHEM_PH_SALT,5.40 -US-Ne3,27768,GRP_SOIL_CHEM,SOIL_CHEM_PH_SALT,6.20 -US-Ne3,28653,GRP_SOIL_CHEM,SOIL_CHEM_BD,1.36 -US-Ne3,29368,GRP_SOIL_CHEM,SOIL_CHEM_BD,1.39 -US-Ne3,28654,GRP_SOIL_CHEM,SOIL_CHEM_BD,1.41 -US-Ne3,29249,GRP_SOIL_CHEM,SOIL_CHEM_BD,1.51 -US-Ne3,27767,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,0 -US-Ne3,28653,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,0 -US-Ne3,29368,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,0 -US-Ne3,28654,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,15 -US-Ne3,29249,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,15 -US-Ne3,27768,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,20 -US-Ne3,28653,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,15 -US-Ne3,29368,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,15 -US-Ne3,27767,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,20 -US-Ne3,28654,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,30 -US-Ne3,29249,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,30 -US-Ne3,27768,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,50 -US-Ne3,27767,GRP_SOIL_CHEM,SOIL_CHEM_DATE,20010420 -US-Ne3,27768,GRP_SOIL_CHEM,SOIL_CHEM_DATE,20010420 -US-Ne3,29249,GRP_SOIL_CHEM,SOIL_CHEM_DATE,20010420 -US-Ne3,29368,GRP_SOIL_CHEM,SOIL_CHEM_DATE,20010420 -US-Ne3,28653,GRP_SOIL_CHEM,SOIL_CHEM_DATE,20050425 -US-Ne3,28654,GRP_SOIL_CHEM,SOIL_CHEM_DATE,20050425 -US-Ne3,27817,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION,"Deep silty clay loams of: Yutan (fine-silty, mixed, superactive, mesic Mollic Hapludalfs), Tomek (fine, smectitic, mesic Pachic Argialbolls), Filbert (fine, smectitic, mesic Vertic Argialbolls), and Filmore (fine, smectitic, mesic Vertic Argialbolls)." -US-Ne3,27817,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION_TAXONOMY,Other -US-Ne3,29573,GRP_SOIL_DEPTH,SOIL_DEPTH,180 -US-Ne3,28384,GRP_SOIL_TEX,SOIL_TEX_SAND,8 -US-Ne3,28384,GRP_SOIL_TEX,SOIL_TEX_SILT,57 -US-Ne3,28384,GRP_SOIL_TEX,SOIL_TEX_CLAY,35 -US-Ne3,27174,GRP_SPP_O,SPP_O,GLYMA4 (NRCS plant code) -US-Ne3,27720,GRP_SPP_O,SPP_O,GLYMA4 (NRCS plant code) -US-Ne3,28421,GRP_SPP_O,SPP_O,GLYMA4 (NRCS plant code) -US-Ne3,27805,GRP_SPP_O,SPP_O,ZEMAH (NRCS plant code) -US-Ne3,28765,GRP_SPP_O,SPP_O,ZEMAH (NRCS plant code) -US-Ne3,28927,GRP_SPP_O,SPP_O,ZEMAH (NRCS plant code) -US-Ne3,28928,GRP_SPP_O,SPP_O,ZEMAH (NRCS plant code) -US-Ne3,27174,GRP_SPP_O,SPP_O_PERC,100 -US-Ne3,27720,GRP_SPP_O,SPP_O_PERC,100 -US-Ne3,27805,GRP_SPP_O,SPP_O_PERC,100 -US-Ne3,28421,GRP_SPP_O,SPP_O_PERC,100 -US-Ne3,28765,GRP_SPP_O,SPP_O_PERC,100 -US-Ne3,28927,GRP_SPP_O,SPP_O_PERC,100 -US-Ne3,28928,GRP_SPP_O,SPP_O_PERC,100 -US-Ne3,28927,GRP_SPP_O,SPP_DATE,2001 -US-Ne3,27174,GRP_SPP_O,SPP_DATE,2002 -US-Ne3,28765,GRP_SPP_O,SPP_DATE,2003 -US-Ne3,27720,GRP_SPP_O,SPP_DATE,2004 -US-Ne3,28928,GRP_SPP_O,SPP_DATE,2005 -US-Ne3,28421,GRP_SPP_O,SPP_DATE,2006 -US-Ne3,27805,GRP_SPP_O,SPP_DATE,2007 -US-Ne3,10010,GRP_STATE,STATE,NE -US-Ne3,10050,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Andy Suyker -US-Ne3,10050,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Ne3,10050,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,asuyker1@unl.edu -US-Ne3,10050,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Nebraska - Lincoln -US-Ne3,10050,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"School of Natural Resource, 807 Hardin Hall,Lincoln, NE USA 68583-0728" -US-Ne3,87994,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Dan Hatch -US-Ne3,87994,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,DataManager -US-Ne3,87994,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,dhatch2@unl.edu -US-Ne3,87994,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Nebraska -US-Ne3,87994,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,805 Hardin Hall -US-Ne3,3525,GRP_URL,URL,http://csp.unl.edu/public/ -US-Ne3,24000405,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-Ne3 -US-Ne3,7002,GRP_UTC_OFFSET,UTC_OFFSET,-6 -US-NGB,13254,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,"This work was supported by the U.S. Department of Energy, Office of Science, Biological and Environmental Research" -US-NGB,13254,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT_COMMENT,"Users are expected to acknowledge data products with a citation, web site information downloads with a citation, or general NGEE Arctic information as an acknowledgment or personal bibliographic web communication, if no other citation form is applicable. When publishing original analyses and results based on NGEE Arctic data, users are expected to acknowledge the agency or organization that supported the collection of the original data." -US-NGB,13255,GRP_CLIM_AVG,MAT,-11.27 -US-NGB,13255,GRP_CLIM_AVG,MAP,171 -US-NGB,13255,GRP_CLIM_AVG,CLIMATE_KOEPPEN,ET -US-NGB,27000533,GRP_COUNTRY,COUNTRY,USA -US-NGB,81564,GRP_DOI,DOI,10.17190/AMF/1436326 -US-NGB,81564,GRP_DOI,DOI_CITATION,"Margaret Torn, Sigrid Dengel (2020), AmeriFlux BASE US-NGB NGEE Arctic Barrow, Ver. 3-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1436326" -US-NGB,81564,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-NGB,81539,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-NGB,81539,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Margaret Torn -US-NGB,81539,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-NGB,81539,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,mstorn@lbl.gov -US-NGB,81539,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Lawrence Berkeley National Laboratory -US-NGB,93294,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-NGB,93294,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Sigrid Dengel -US-NGB,93294,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-NGB,93294,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,sdengel@lbl.gov -US-NGB,93294,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Lawrence Berkeley National Laboratory -US-NGB,81541,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Lawrence Berkeley National Laboratory -US-NGB,81541,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-NGB,81540,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,DOE_BER -US-NGB,81540,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-NGB,13276,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Chambers -US-NGB,13276,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-NGB,13276,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20120701 -US-NGB,13276,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Periodic operation -US-NGB,13275,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Chambers -US-NGB,13275,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CH4 -US-NGB,13275,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20120701 -US-NGB,13275,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Periodic operation -US-NGB,13277,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Chambers -US-NGB,13277,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-NGB,13277,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20120701 -US-NGB,13277,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Periodic operation -US-NGB,13269,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-NGB,13269,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-NGB,13269,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20120906 -US-NGB,13269,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Growing season operation only -US-NGB,13256,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-NGB,13256,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CH4 -US-NGB,13256,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20120906 -US-NGB,13256,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Growing season operation only -US-NGB,13271,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-NGB,13271,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-NGB,13271,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20120906 -US-NGB,13271,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Growing season operation only -US-NGB,13273,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-NGB,13273,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-NGB,13273,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20120906 -US-NGB,13273,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Growing season operation only -US-NGB,23000533,GRP_HEADER,SITE_NAME,NGEE Arctic Barrow -US-NGB,13257,GRP_IGBP,IGBP,SNO -US-NGB,13257,GRP_IGBP,IGBP_COMMENT,sedge/grass moss wetland (CAVM) -US-NGB,13258,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -US-NGB,13258,GRP_LAND_OWNERSHIP,LAND_OWNER,"Native American Corporation. Owned by the Ukpeaġvik Iñupiat Corporation (UIC) and managed by UMIAQ, LLC, a subsidiary of UIC" -US-NGB,13345,GRP_LOCATION,LOCATION_LAT,71.2800 -US-NGB,13345,GRP_LOCATION,LOCATION_LONG,-156.6092 -US-NGB,13345,GRP_LOCATION,LOCATION_ELEV,5.273 -US-NGB,13260,GRP_NETWORK,NETWORK,AmeriFlux -US-NGB,86989,GRP_NETWORK,NETWORK,Phenocam -US-NGB,1700005901,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(), 108350" -US-NGB,1700005901,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -US-NGB,1700005901,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-NGB,13261,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"Experiments, observations, and process models to quantify the response of physical, ecological, and biogeochemical processes to atmospheric and climatic change across molecular to landscape scales." -US-NGB,13262,GRP_SITE_CHAR,TERRAIN,Flat -US-NGB,13262,GRP_SITE_CHAR,ASPECT,FLAT -US-NGB,13262,GRP_SITE_CHAR,WIND_DIRECTION,E -US-NGB,13262,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,245 -US-NGB,13263,GRP_SITE_DESC,SITE_DESC,The ecosystem is an Arctic coastal tundra. This site measures greenhouse gasses and meteorological variables at the Barrow Environmental Observatory (BEO) as part of the Next-Generation Ecosystem Experiment - Arctic. -US-NGB,13264,GRP_SITE_FUNDING,SITE_FUNDING,DOE_BER -US-NGB,13265,GRP_STATE,STATE,AK -US-NGB,13266,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Margaret Torn -US-NGB,13266,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-NGB,13266,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,mstorn@lbl.gov -US-NGB,13266,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Lawrence Berkeley National Laboratory -US-NGB,13266,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1 Cyclotron Rd, Berkeley CA 94720" -US-NGB,30453,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Sigrid Dengel -US-NGB,30453,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-NGB,30453,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,sdengel@lbl.gov -US-NGB,30453,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Lawrence Berkeley National Laboratory -US-NGB,30453,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1 Cyclotron Rd, Berkeley CA 94720" -US-NGB,13267,GRP_URL,URL,http://ngee-arctic.ornl.gov/ -US-NGB,24000533,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-NGB -US-NGB,13268,GRP_UTC_OFFSET,UTC_OFFSET,-9 -US-NGC,79386,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,The Next-Generation Ecosystem Experiments (NGEE Arctic) project is supported by the Office of Biological and Environmental Research in the DOE Office of Science. -US-NGC,79236,GRP_CLIM_AVG,CLIMATE_KOEPPEN,ET -US-NGC,27000940,GRP_COUNTRY,COUNTRY,USA -US-NGC,92858,GRP_DOI,DOI,10.17190/AMF/1634883 -US-NGC,92858,GRP_DOI,DOI_CITATION,"Margaret Torn, Sigrid Dengel (2020), AmeriFlux BASE US-NGC NGEE Arctic Council, Ver. 1-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1634883" -US-NGC,92858,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-NGC,92826,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-NGC,92826,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Margaret Torn -US-NGC,92826,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-NGC,92826,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,mstorn@lbl.gov -US-NGC,92826,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Berkeley Lab -US-NGC,93295,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-NGC,93295,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Sigrid Dengel -US-NGC,93295,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-NGC,93295,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,sdengel@lbl.gov -US-NGC,93295,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Lawrence Berkeley National Laboratory -US-NGC,92849,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Berkeley Lab -US-NGC,92849,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-NGC,93329,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Lawrence Berkeley National Laboratory -US-NGC,93329,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-NGC,92840,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,U.S. Department of Energy -US-NGC,92840,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-NGC,85185,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Undisturbed -US-NGC,85191,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-NGC,85191,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-NGC,85191,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20170701 -US-NGC,85191,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Growing season operation only -US-NGC,85189,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-NGC,85189,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CH4 -US-NGC,85189,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20170701 -US-NGC,85189,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Growing season operation only -US-NGC,85188,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-NGC,85188,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-NGC,85188,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20170701 -US-NGC,85188,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Growing season operation only -US-NGC,23000940,GRP_HEADER,SITE_NAME,NGEE Arctic Council -US-NGC,79240,GRP_IGBP,IGBP,GRA -US-NGC,79240,GRP_IGBP,IGBP_COMMENT,The more precise IGBP should be Tussock Tundra. -US-NGC,79241,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -US-NGC,79241,GRP_LAND_OWNERSHIP,LAND_OWNER,Council Native Corporation -US-NGC,101454,GRP_LOCATION,LOCATION_LAT,64.8618 -US-NGC,101454,GRP_LOCATION,LOCATION_LONG,-163.7002 -US-NGC,101454,GRP_LOCATION,LOCATION_ELEV,35 -US-NGC,79243,GRP_NETWORK,NETWORK,AmeriFlux -US-NGC,79244,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"One Cyclotron Road, Bld. 84-153, Berkeley, 94720" -US-NGC,79245,GRP_SITE_CHAR,TERRAIN,Flat -US-NGC,79245,GRP_SITE_CHAR,WIND_DIRECTION,NNW -US-NGC,85184,GRP_SITE_DESC,SITE_DESC,"Subarctic tussock tundra, discontinuous permafrost" -US-NGC,85183,GRP_SITE_FUNDING,SITE_FUNDING,U.S. Department of Energy -US-NGC,79247,GRP_STATE,STATE,AK -US-NGC,85186,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Margaret Torn -US-NGC,85186,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-NGC,85186,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,mstorn@lbl.gov -US-NGC,85186,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Berkeley Lab -US-NGC,85186,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"One Cyclotron Rd, Berkeley Lab, Berkeley, CA, 94720" -US-NGC,85187,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Sigrid Dengel -US-NGC,85187,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,AncContact -US-NGC,85187,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,Sdengel@lbl.gov -US-NGC,85187,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Lawrence Berkeley National Laboratory -US-NGC,85187,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"One Cyclotron Road, Bldg 84-153, Berkeley, 94720" -US-NGC,85182,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-NGC,85190,GRP_TOWER_TYPE,TOWER_TYPE,tripod -US-NGC,24000940,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-NGC -US-NGC,87882,GRP_UTC_OFFSET,UTC_OFFSET,-9 -US-NMj,8517,GRP_CLIM_AVG,MAT,4.73 -US-NMj,8517,GRP_CLIM_AVG,MAP,854.01 -US-NMj,8517,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfb -US-NMj,27000406,GRP_COUNTRY,COUNTRY,USA -US-NMj,15699,GRP_DOI,DOI,10.17190/AMF/1246087 -US-NMj,15699,GRP_DOI,DOI_CITATION,"Jiquan Chen (2019), AmeriFlux BASE US-NMj Northern Michigan Jack Pine Stand, Ver. 3-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1246087" -US-NMj,15699,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-NMj,32150,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-NMj,32150,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Jiquan Chen -US-NMj,32150,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-NMj,32150,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,jqchen@msu.edu -US-NMj,32150,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Michigan State University -US-NMj,32152,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Michigan State University -US-NMj,32152,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-NMj,32151,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,NSF -US-NMj,32151,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-NMj,409,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-NMj,409,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-NMj,409,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,2001 -US-NMj,409,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,2007 -US-NMj,409,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-NMj,23000406,GRP_HEADER,SITE_NAME,Northern Michigan Jack Pine Stand -US-NMj,6821,GRP_IGBP,IGBP,ENF -US-NMj,8534,GRP_LOCATION,LOCATION_LAT,46.6465 -US-NMj,8534,GRP_LOCATION,LOCATION_LONG,-88.5194 -US-NMj,8534,GRP_LOCATION,LOCATION_ELEV,394 -US-NMj,8107,GRP_NETWORK,NETWORK,AmeriFlux -US-NMj,9314,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"The jack pine site is owned by Michigan Technological University. The stand is managed, and thus thinned and harvested depending on stand age. This jack pine site is naturally regenerating following a clearcut around 1989. Heavy snow in December 2001 caused the site to be down during early 2002." -US-NMj,866,GRP_SITE_DESC,SITE_DESC,"The jack pine site is owned by Michigan Technological University. The stand is managed, and thus thinned and harvested depending on stand age. This jack pine site is naturally regenerating following a clearcut around 1989. Heavy snow in December 2001 c" -US-NMj,6709,GRP_SITE_FUNDING,SITE_FUNDING,NSF -US-NMj,3990,GRP_STATE,STATE,MI -US-NMj,12546,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Jiquan Chen -US-NMj,12546,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-NMj,12546,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,jqchen@msu.edu -US-NMj,12546,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Michigan State University -US-NMj,24000406,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-NMj -US-NMj,33649,GRP_UTC_OFFSET,UTC_OFFSET,-5 -US-NMj,33649,GRP_UTC_OFFSET,UTC_OFFSET_COMMENT,Added by AMF data processing team for data QAQC checks. -US-NP1,95716,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,This research was a contribution from the Long-Term Agroecosystem Research (LTAR) network. LTAR is supported by the United States Department of Agriculture. -US-NP1,95716,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT_COMMENT,We acknowledge the contribution of the Area 4 Soil Conservation Districts in North Dakota for providing land to conduct research. https://www.area4farm.org/ -US-NP1,95724,GRP_CLIM_AVG,MAT,5.4 -US-NP1,95724,GRP_CLIM_AVG,MAP,420 -US-NP1,95724,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Bsh -US-NP1,27001187,GRP_COUNTRY,COUNTRY,USA -US-NP1,95721,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Agriculture -US-NP1,95711,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-NP1,95711,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-NP1,95711,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201504301000 -US-NP1,95711,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-NP1,95717,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-NP1,95717,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-NP1,95717,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201504301000 -US-NP1,95717,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-NP1,95702,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-NP1,95702,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-NP1,95702,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201504301000 -US-NP1,95702,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-NP1,23001187,GRP_HEADER,SITE_NAME,Business-As-Usual Management (mandanh5) -US-NP1,95720,GRP_IGBP,IGBP,CRO -US-NP1,95720,GRP_IGBP,IGBP_DATE_START,198402230000 -US-NP1,95708,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -US-NP1,95708,GRP_LAND_OWNERSHIP,LAND_OWNER,Leased to USDA ARS NGPRL -US-NP1,95723,GRP_LOCATION,LOCATION_LAT,46.7756 -US-NP1,95723,GRP_LOCATION,LOCATION_LONG,-100.9510 -US-NP1,95723,GRP_LOCATION,LOCATION_ELEV,593 -US-NP1,95723,GRP_LOCATION,LOCATION_DATE_START,200905310000 -US-NP1,95703,GRP_NETWORK,NETWORK,AmeriFlux -US-NP1,95712,GRP_NETWORK,NETWORK,LTAR -US-NP1,95719,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"Management, business-as-usual, effects on eddy fluxes" -US-NP1,95714,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"1701 10th Avenue SW, PO Box 459, Mandan, ND, USA 58554" -US-NP1,95722,GRP_SITE_CHAR,TERRAIN,Gentle slope (<2 %) -US-NP1,95722,GRP_SITE_CHAR,ASPECT,FLAT -US-NP1,95722,GRP_SITE_CHAR,WIND_DIRECTION,NW -US-NP1,95722,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,300 -US-NP1,95722,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,67 -US-NP1,95705,GRP_SITE_DESC,SITE_DESC,"Cropland, no-till, rainfed, 3-year rotation of spring wheat-corn-soybean" -US-NP1,95710,GRP_SITE_FUNDING,SITE_FUNDING,USDA ARS LTAR -US-NP1,95715,GRP_STATE,STATE,ND -US-NP1,95707,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Mark Liebig -US-NP1,95707,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-NP1,95707,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,mark.liebig@usda.gov -US-NP1,95707,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,USDA ARS LTAR -US-NP1,95713,GRP_TOWER_POWER,TOWER_POWER,Direct power -US-NP1,95704,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-NP1,95709,GRP_TOWER_TYPE,TOWER_TYPE,tripod -US-NP1,95718,GRP_URL,URL,https://www.ars.usda.gov/plains-area/mandan-nd/ngprl/ -US-NP1,24001187,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-NP1 -US-NP1,95706,GRP_UTC_OFFSET,UTC_OFFSET,-6 -US-NP2,95737,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,This research was a contribution from the Long-Term Agroecosystem Research (LTAR) network. LTAR is supported by the United States Department of Agriculture. -US-NP2,95737,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT_COMMENT,We acknowledge the contribution of the Area 4 Soil Conservation Districts in North Dakota for providing land to conduct research. https://www.area4farm.org/ -US-NP2,95739,GRP_CLIM_AVG,MAT,5.4 -US-NP2,95739,GRP_CLIM_AVG,MAP,420 -US-NP2,95739,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Bsh -US-NP2,27001188,GRP_COUNTRY,COUNTRY,USA -US-NP2,95731,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Agriculture -US-NP2,95734,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-NP2,95734,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-NP2,95734,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201604081600 -US-NP2,95734,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-NP2,95743,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-NP2,95743,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-NP2,95743,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201604081600 -US-NP2,95743,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-NP2,95733,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-NP2,95733,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-NP2,95733,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201604081600 -US-NP2,95733,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-NP2,23001188,GRP_HEADER,SITE_NAME,ASPirational Management (mandani2) -US-NP2,95730,GRP_IGBP,IGBP,CRO -US-NP2,95730,GRP_IGBP,IGBP_DATE_START,198402230000 -US-NP2,95727,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -US-NP2,95727,GRP_LAND_OWNERSHIP,LAND_OWNER,Leased to USDA ARS NGPRL -US-NP2,95736,GRP_LOCATION,LOCATION_LAT,46.7613 -US-NP2,95736,GRP_LOCATION,LOCATION_LONG,-100.9257 -US-NP2,95736,GRP_LOCATION,LOCATION_ELEV,590 -US-NP2,95736,GRP_LOCATION,LOCATION_DATE_START,201604080000 -US-NP2,95740,GRP_NETWORK,NETWORK,AmeriFlux -US-NP2,95735,GRP_NETWORK,NETWORK,LTAR -US-NP2,95729,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"Management, aspirational (starting in May 2019), effects on eddy fluxes" -US-NP2,95744,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"1701 10th Avenue SW, PO Box 459, Mandan, ND, USA 58554" -US-NP2,95746,GRP_SITE_CHAR,TERRAIN,Gentle slope (<2 %) -US-NP2,95746,GRP_SITE_CHAR,ASPECT,FLAT -US-NP2,95746,GRP_SITE_CHAR,WIND_DIRECTION,NW -US-NP2,95746,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,320 -US-NP2,95746,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,67 -US-NP2,95725,GRP_SITE_DESC,SITE_DESC,"Cropland, no-till, rainfed, 3-year rotation of spring wheat-corn-soybean" -US-NP2,95741,GRP_SITE_FUNDING,SITE_FUNDING,USDA ARS LTAR -US-NP2,95732,GRP_STATE,STATE,ND -US-NP2,95726,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Mark Liebig -US-NP2,95726,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-NP2,95726,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,mark.liebig@usda.gov -US-NP2,95726,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,USDA ARS LTAR -US-NP2,95728,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-NP2,95742,GRP_TOWER_TYPE,TOWER_TYPE,tripod -US-NP2,95738,GRP_URL,URL,https://www.ars.usda.gov/plains-area/mandan-nd/ngprl/ -US-NP2,24001188,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-NP2 -US-NP2,95745,GRP_UTC_OFFSET,UTC_OFFSET,-6 -US-NR1,88068,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,Funding for the AmeriFlux core site US-NR1 data was provided by the U.S. Department of Energy’s Office of Science. -US-NR1,24149,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER,23 -US-NR1,24149,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_ORGAN,Total -US-NR1,24149,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_PHEN,Mixed/unknown -US-NR1,24149,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_UNIT,kgDM m-2 -US-NR1,23833,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,14500 -US-NR1,23833,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Wood -US-NR1,23833,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-NR1,23833,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-NR1,23833,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2001 -US-NR1,23969,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,14500 -US-NR1,23969,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Wood -US-NR1,23969,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-NR1,23969,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-NR1,23969,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2006 -US-NR1,24494,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,14500 -US-NR1,24494,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Wood -US-NR1,24494,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-NR1,24494,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-NR1,24494,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2005 -US-NR1,24622,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,14500 -US-NR1,24622,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Wood -US-NR1,24622,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-NR1,24622,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-NR1,24622,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2002 -US-NR1,24745,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,14500 -US-NR1,24745,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Wood -US-NR1,24745,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-NR1,24745,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-NR1,24745,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2000 -US-NR1,24884,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,14500 -US-NR1,24884,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Wood -US-NR1,24884,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-NR1,24884,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-NR1,24884,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2003 -US-NR1,25001,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,14500 -US-NR1,25001,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Wood -US-NR1,25001,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-NR1,25001,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-NR1,25001,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2004 -US-NR1,23973,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,17750 -US-NR1,23973,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Total -US-NR1,23973,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-NR1,23973,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-NR1,23973,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2001 -US-NR1,24090,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,17750 -US-NR1,24090,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Total -US-NR1,24090,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-NR1,24090,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-NR1,24090,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2005 -US-NR1,24349,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,17750 -US-NR1,24349,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Total -US-NR1,24349,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-NR1,24349,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-NR1,24349,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2002 -US-NR1,24605,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,17750 -US-NR1,24605,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Total -US-NR1,24605,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-NR1,24605,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-NR1,24605,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2006 -US-NR1,24628,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,17750 -US-NR1,24628,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Total -US-NR1,24628,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-NR1,24628,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-NR1,24628,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2003 -US-NR1,24629,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,17750 -US-NR1,24629,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Total -US-NR1,24629,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-NR1,24629,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-NR1,24629,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2004 -US-NR1,24994,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,17750 -US-NR1,24994,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Total -US-NR1,24994,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-NR1,24994,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-NR1,24994,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2000 -US-NR1,24072,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,2950 -US-NR1,24072,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Foliage -US-NR1,24072,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-NR1,24072,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-NR1,24072,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2006 -US-NR1,24089,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,2950 -US-NR1,24089,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Foliage -US-NR1,24089,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-NR1,24089,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-NR1,24089,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2005 -US-NR1,24242,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,2950 -US-NR1,24242,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Foliage -US-NR1,24242,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-NR1,24242,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-NR1,24242,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2004 -US-NR1,24351,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,2950 -US-NR1,24351,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Foliage -US-NR1,24351,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-NR1,24351,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-NR1,24351,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2003 -US-NR1,24468,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,2950 -US-NR1,24468,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Foliage -US-NR1,24468,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-NR1,24468,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-NR1,24468,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2001 -US-NR1,24618,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,2950 -US-NR1,24618,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Foliage -US-NR1,24618,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-NR1,24618,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-NR1,24618,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2000 -US-NR1,24620,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,2950 -US-NR1,24620,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Foliage -US-NR1,24620,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-NR1,24620,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-NR1,24620,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2002 -US-NR1,23702,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT,215.8 -US-NR1,23702,GRP_AG_LIT_PROD,AG_LIT_PROD_UNIT,gC m-2 -US-NR1,23702,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_START,2008 -US-NR1,23702,GRP_AG_LIT_PROD,AG_LIT_PROD_COMMENT,"summer 2006; Ten plots, 4 litter bins/plot. Tree litter was collected in the bins year-round then harvested after spring snow melt and brought to the lab to be dried and weighed. Help for this section was provided by Maggie Prater (maggie.prater@colorado.edu)." -US-NR1,24855,GRP_BIOMASS_CHEM,BIOMASS_C,4.75 -US-NR1,24856,GRP_BIOMASS_CHEM,BIOMASS_C,4.8 -US-NR1,24332,GRP_BIOMASS_CHEM,BIOMASS_C,5.1 -US-NR1,24332,GRP_BIOMASS_CHEM,BIOMASS_N,0.088 -US-NR1,24855,GRP_BIOMASS_CHEM,BIOMASS_N,0.101 -US-NR1,24465,GRP_BIOMASS_CHEM,BIOMASS_N,0.106 -US-NR1,24332,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-NR1,24465,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-NR1,24855,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-NR1,24856,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-NR1,24332,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-NR1,24465,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-NR1,24855,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-NR1,24856,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-NR1,24465,GRP_BIOMASS_CHEM,BIOMASS_SPP,ABLA (NRCS plant code) -US-NR1,24856,GRP_BIOMASS_CHEM,BIOMASS_SPP,ABLA (NRCS plant code) -US-NR1,24332,GRP_BIOMASS_CHEM,BIOMASS_SPP,PICO (NRCS plant code) -US-NR1,24855,GRP_BIOMASS_CHEM,BIOMASS_SPP,PIEN (NRCS plant code) -US-NR1,24332,GRP_BIOMASS_CHEM,BIOMASS_DATE,20000718 -US-NR1,24465,GRP_BIOMASS_CHEM,BIOMASS_DATE,20000718 -US-NR1,24855,GRP_BIOMASS_CHEM,BIOMASS_DATE,20000718 -US-NR1,24856,GRP_BIOMASS_CHEM,BIOMASS_DATE,20000718 -US-NR1,24465,GRP_BIOMASS_CHEM,BIOMASS_COMMENT,"ABLA=subalpine fir; PIEN=Engelmann spruce, PICO=lodgepole pine. Unpublished data from summer 2000. Help for this section was provided by Jia Hu (jia.hu@colorado.edu) and Maggie Prater (maggie.prater@colorado.edu)." -US-NR1,24332,GRP_BIOMASS_CHEM,BIOMASS_COMMENT,ABLA=subalpine fir; PIEN=Engelmann spruce; PICO=lodgepole pine. Unpublished data from summer 2000. Help for this section was provided by Jia Hu (jia.hu@colorado.edu) and Maggie Prater (maggie.prater@colorado.edu). -US-NR1,24855,GRP_BIOMASS_CHEM,BIOMASS_COMMENT,ABLA=subalpine fir; PIEN=Engelmann spruce; PICO=lodgepole pine. Unpublished data from summer 2000. Help for this section was provided by Jia Hu (jia.hu@colorado.edu) and Maggie Prater (maggie.prater@colorado.edu). -US-NR1,24856,GRP_BIOMASS_CHEM,BIOMASS_COMMENT,ABLA=subalpine fir; PIEN=Engelmann spruce; PICO=lodgepole pine. Unpublished data from summer 2000. Help for this section was provided by Jia Hu (jia.hu@colorado.edu) and Maggie Prater (maggie.prater@colorado.edu). -US-NR1,11574,GRP_CLIM_AVG,MAT,1.5 -US-NR1,11574,GRP_CLIM_AVG,MAP,800 -US-NR1,11574,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfc -US-NR1,27000408,GRP_COUNTRY,COUNTRY,USA -US-NR1,16129,GRP_DM_FORESTRY,DM_FORESTRY,Clearcutting -US-NR1,16129,GRP_DM_FORESTRY,DM_DATE,1900 -US-NR1,16129,GRP_DM_FORESTRY,DM_COMMENT,"(~99%) The spruce-fir-lodgepole forest where the tower resides was logged in clear-cut fashion in the early part of the 20th century, and is currently in a state of aggradation (Monson, et al. Global Change Biology (2002), 8 459-478). The response and recovery of the Niwot Ridge forest from logging disturbance was included as a topic in the modeling paper by Thornton et al. Agricultural and Forest Meteorology (2002) 113: 185-222." -US-NR1,15757,GRP_DOI,DOI,10.17190/AMF/1246088 -US-NR1,15757,GRP_DOI,DOI_CITATION,"Peter D. Blanken, Russel K. Monson, Sean P. Burns, David R. Bowling, Andrew A. Turnipseed (2022), AmeriFlux BASE US-NR1 Niwot Ridge Forest (LTER NWT1), Ver. 19-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1246088" -US-NR1,15757,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-NR1,88049,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-NR1,88049,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Peter D. Blanken -US-NR1,88049,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-NR1,88049,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,1 -US-NR1,88049,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,Blanken@colorado.edu -US-NR1,88049,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of Colorado -US-NR1,88046,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-NR1,88046,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Russel K. Monson -US-NR1,88046,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-NR1,88046,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,2 -US-NR1,88046,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,russell.monson@colorado.edu -US-NR1,88046,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of Colorado -US-NR1,88001,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-NR1,88001,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Sean P. Burns -US-NR1,88001,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-NR1,88001,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,3 -US-NR1,88001,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0002-6258-1838 -US-NR1,88001,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,sean.burns@colorado.edu -US-NR1,88001,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of Colorado -US-NR1,88001,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,20030101 -US-NR1,87998,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-NR1,87998,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,David R. Bowling -US-NR1,87998,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-NR1,87998,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,4 -US-NR1,87998,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,david.bowling@utah.edu -US-NR1,87998,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of Utah -US-NR1,87999,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-NR1,87999,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Andrew A. Turnipseed -US-NR1,87999,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-NR1,87999,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,5 -US-NR1,87999,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of Colorado -US-NR1,32155,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,University of Colorado -US-NR1,32155,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-NR1,32154,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,NSF -US-NR1,32154,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-NR1,11575,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Forestry -US-NR1,11576,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-NR1,11576,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-NR1,11576,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,19981101 -US-NR1,11576,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-NR1,11591,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-NR1,11591,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-NR1,11591,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,19981101 -US-NR1,11591,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-NR1,23000408,GRP_HEADER,SITE_NAME,Niwot Ridge Forest (LTER NWT1) -US-NR1,88652,GRP_HEIGHTC,HEIGHTC,11.4 -US-NR1,88652,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-NR1,88652,GRP_HEIGHTC,HEIGHTC_DATE,20000718 -US-NR1,88652,GRP_HEIGHTC,HEIGHTC_COMMENT,"Monson, et al. Global Change Biology (2002), 8 459-478." -US-NR1,88651,GRP_HEIGHTC,HEIGHTC,13 -US-NR1,88651,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-NR1,88651,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,600 -US-NR1,88651,GRP_HEIGHTC,HEIGHTC_APPROACH,Manual -US-NR1,88651,GRP_HEIGHTC,HEIGHTC_DATE,20060701 -US-NR1,88651,GRP_HEIGHTC,HEIGHTC_COMMENT,"The range of heights is 12-14m, from Monson, et al. Oecologia (2010), 162 491-504." -US-NR1,88650,GRP_HEIGHTC,HEIGHTC,15.9 -US-NR1,88650,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-NR1,88650,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,8000 -US-NR1,88650,GRP_HEIGHTC,HEIGHTC_APPROACH,Lidar -US-NR1,88650,GRP_HEIGHTC,HEIGHTC_DATE,20100810 -US-NR1,88650,GRP_HEIGHTC,HEIGHTC_COMMENT,"Mean heights from lidar returns between 15-18m, from Burns, S. P. (2018), see Table 4.1 and Fig. 4.7" -US-NR1,11577,GRP_IGBP,IGBP,ENF -US-NR1,11577,GRP_IGBP,IGBP_COMMENT,"Subalpine fir (Abies lasiocarpa), Engelmann spruce (Picea engelmannii), and lodgepole pine (Pinus contorta) comprise the overstory. The understory is relatively sparse, containing tree seedlings from all three species and patches of whortleberry (Vaccinium myrtillus). There are aspens (Populus tremuloides) near the tower, but not within the tower's dominat east-west footprint. The presence of aspens may influence fluxes when the footprint shifts to the northwesterly direction from the tower (wind directions from 270-290 degrees)." -US-NR1,24743,GRP_LAI,LAI_TYPE,LAI -US-NR1,24743,GRP_LAI,LAI_METHOD,Other -US-NR1,24743,GRP_LAI,LAI_DATE,20000718 -US-NR1,24743,GRP_LAI,LAI_COMMENT,"(range 3.1-4.2) (midsummer) LAI has been determined in three different efforts, with all values falling within the range 3.1-5.6 m2/m2. (1) Trees were destructively harvested in the field during 2000-2002 with an LAI determined from allometric scaling measurements and producing an estimated value of 3.8-4.2 m2/m2 (total range in east-west flux footprint). (2) A photometric method as reported by Chen, J.M. (1995) Agric. Forest Meteorol. 80: 135-163, was used in 2001 and provided an estimate for LAI of 5.0-5.6 m2/m2 (total range in east-west flux footprint). (3) An independent allomtetric study was done in 2006 using different harvested trees from the earlier study. This study resulted in an LAI estimate of 3.1-3.8 m2/m2 (total range in the east-west footprint). Taking all studies together a good representative LAI for the site is 4.2 m2/m2." -US-NR1,24743,GRP_LAI,LAI_TOT,3.65 -US-NR1,11578,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-NR1,11578,GRP_LAND_OWNERSHIP,LAND_OWNER,USDA Forest Service (Roosevelt National Forest) -US-NR1,23704,GRP_LMA,LMA,193.7 -US-NR1,23704,GRP_LMA,LMA_SPP,ABLA (NRCS plant code) -US-NR1,23704,GRP_LMA,LMA_DATE,20000718 -US-NR1,23704,GRP_LMA,LMA_COMMENT,BLA=subalpine fir; PIEN=Engelmann spruce; PICO=lodgepole pine. Unpublished data from summer 2000. Help for this section was provided by Maggie Prater (maggie.prater@colorado.edu). -US-NR1,23966,GRP_LMA,LMA,205.1 -US-NR1,23966,GRP_LMA,LMA_SPP,PICO (NRCS plant code) -US-NR1,23966,GRP_LMA,LMA_DATE,20000718 -US-NR1,23966,GRP_LMA,LMA_COMMENT,BLA=subalpine fir; PIEN=Engelmann spruce; PICO=lodgepole pine. Unpublished data from summer 2000. Help for this section was provided by Maggie Prater (maggie.prater@colorado.edu). -US-NR1,24470,GRP_LMA,LMA,237.7 -US-NR1,24470,GRP_LMA,LMA_SPP,PIEN (NRCS plant code) -US-NR1,24470,GRP_LMA,LMA_DATE,20000718 -US-NR1,24470,GRP_LMA,LMA_COMMENT,BLA=subalpine fir; PIEN=Engelmann spruce; PICO=lodgepole pine. Unpublished data from summer 2000. Help for this section was provided by Maggie Prater (maggie.prater@colorado.edu). -US-NR1,11579,GRP_LOCATION,LOCATION_LAT,40.0329 -US-NR1,11579,GRP_LOCATION,LOCATION_LONG,-105.5464 -US-NR1,11579,GRP_LOCATION,LOCATION_ELEV,3050 -US-NR1,11579,GRP_LOCATION,LOCATION_COMMENT,Fluxnet -US-NR1,23636,GRP_NEP,NEP,200 -US-NR1,11580,GRP_NETWORK,NETWORK,AmeriFlux -US-NR1,86990,GRP_NETWORK,NETWORK,Phenocam -US-NR1,24236,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,BudBreak -US-NR1,24236,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,POTR5 (NRCS plant code) -US-NR1,24236,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20070611 -US-NR1,24236,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,POTR5=aspen. From forest phenology photos taken in 2007. See http://urquell.colorado.edu/photos/photos_pheno.html -US-NR1,24084,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,Maximum leaf expansion -US-NR1,24084,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,POTR5 (NRCS plant code) -US-NR1,24084,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20070920 -US-NR1,24084,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,POTR5=aspen. From forest phenology photos taken in 2007. See http://urquell.colorado.edu/photos/photos_pheno.html -US-NR1,25132,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,Total leaf-off -US-NR1,25132,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,POTR5 (NRCS plant code) -US-NR1,25132,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20070913 -US-NR1,25132,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,POTR5=aspen. From forest phenology photos taken in 2007. See http://urquell.colorado.edu/photos/photos_pheno.html -US-NR1,1700007260,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Albert, L. P., Keenan, T. F., Burns, S. P., Huxman, T. E., Monson, R. K. (2017) Climate Controls Over Ecosystem Metabolism: Insights From A Fifteen-Year Inductive Artificial Neural Network Synthesis For A Subalpine Forest, Oecologia, 184(1), 25-41" -US-NR1,1700007260,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1007/S00442-017-3853-0 -US-NR1,1700007260,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-NR1,1700007419,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Arain, M. A., Restrepo-Coupe, N. (2005) Net Ecosystem Production In A Temperate Pine Plantation In Southeastern Canada, Agricultural And Forest Meteorology, 128(3-4), 223-241" -US-NR1,1700007419,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2004.10.003 -US-NR1,1700007419,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-NR1,1700002502,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Barr, A., Richardson, A., Hollinger, D., Papale, D., Arain, M., Black, T., Bohrer, G., Dragoni, D., Fischer, M., Gu, L., Law, B., Margolis, H., McCaughey, J., Munger, J., Oechel, W., Schaeffer, K. (2013) Use Of Change-Point Detection For Friction–Velocity Threshold Evaluation In Eddy-Covariance Studies, Agricultural And Forest Meteorology, 171-172(7), 31-45" -US-NR1,1700002502,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2012.11.023 -US-NR1,1700002502,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-NR1,1700004728,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Berkelhammer, M., Noone, D. C., Wong, T. E., Burns, S. P., Knowles, J. F., Kaushik, A., Blanken, P. D., Williams, M. W. (2016) Convergent Approaches To Determine An Ecosystem'S Transpiration Fraction, Global Biogeochemical Cycles, 30(6), 933-951" -US-NR1,1700004728,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/2016GB005392 -US-NR1,1700004728,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-NR1,1700001317,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Berryman, E. M., Vanderhoof, M. K., Bradford, J. B., Hawbaker, T. J., Henne, P. D., Burns, S. P., Frank, J. M., Birdsey, R. A., Ryan, M. G. (2018) Estimating Soil Respiration In A Subalpine Landscape Using Point, Terrain, Climate, And Greenness Data, Journal Of Geophysical Research: Biogeosciences, 123(10), 3231-3249" -US-NR1,1700001317,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018JG004613 -US-NR1,1700001317,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-NR1,1700003723,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Blanken, P. D., Williams, M. W., Burns, S. P., Monson, R. K., Knowles, J. F., Chowanski, K., Ackerman, T. (2009) A Comparison Of Water And Carbon Dioxide Exchange At A Windy Alpine Tundra And Subalpine Forest Site Near Niwot Ridge, Colorado, Biogeochemistry, 95(1), 61-76" -US-NR1,1700003723,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1007/S10533-009-9325-9 -US-NR1,1700003723,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-NR1,1700005199,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Blanken, P. D., Williams, M. W., Burns, S. P., Monson, R. K., Knowles, J., Chowanski, K., Ackerman, T. (2009) A Comparison Of Water And Carbon Dioxide Exchange At A Windy Alpine Tundra And Subalpine Forest Site Near Niwot Ridge, Colorado, Biogeochemistry, 95(1), 61-76" -US-NR1,1700005199,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1007/S10533-009-9325-9 -US-NR1,1700005199,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-NR1,1700004305,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Bowling, D. R., Ballantyne, A. P., Miller, J. B., Burns, S. P., Conway, T. J., Menzer, O., Stephens, B. B., Vaughn, B. H. (2014) Ecological Processes Dominate The13c Land Disequilibrium In A Rocky Mountain Subalpine Forest, Global Biogeochemical Cycles, 28(4), 352-370" -US-NR1,1700004305,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/2013GB004686 -US-NR1,1700004305,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-NR1,1700008310,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Bowling, D. R., Burns, S. P., Conway, T. J., Monson, R. K., White, J. W. (2005) Extensive Observations Of Co2carbon Isotope Content In And Above A High-Elevation Subalpine Forest, Global Biogeochemical Cycles, 19(3), n/a-n/a" -US-NR1,1700008310,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2004GB002394 -US-NR1,1700008310,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-NR1,1700002304,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Bowling, D. R., Logan, B. A., Hufkens, K., Aubrecht, D. M., Richardson, A. D., Burns, S. P., Anderegg, W. R., Blanken, P. D., Eiriksson, D. P. (2018) Limitations To Winter And Spring Photosynthesis Of A Rocky Mountain Subalpine Forest, Agricultural And Forest Meteorology, 252(8), 241-255" -US-NR1,1700002304,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2018.01.025 -US-NR1,1700002304,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-NR1,1700000516,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Bowling, D. R., Massman, W. J., Schaeffer, S. M., Burns, S. P., Monson, R. K., Williams, M. W. (2009) Biological And Physical Influences On The Carbon Isotope Content Of Co2 In A Subalpine Forest Snowpack, Niwot Ridge, Colorado, Biogeochemistry, 95(1), 37-59" -US-NR1,1700000516,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1007/S10533-008-9233-4 -US-NR1,1700000516,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-NR1,1700004938,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Bowling, D. R., Miller, J. B., Rhodes, M. E., Burns, S. P., Monson, R. K., Baer, D. (2009) Soil, Plant, And Transport Influences On Methane In A Subalpine Forest Under High Ultraviolet Irradiance, Biogeosciences, 6(7), 1311-1324" -US-NR1,1700004938,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.5194/BG-6-1311-2009 -US-NR1,1700004938,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-NR1,1700000513,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Braghiere,R.K., Wang,Y., Doughty,R., Sousa,D., Magney,T., Widlowski,J.-L., Longo,M., Bloom,A.A., Worden,J., Gentine,P., Frankenberg,C. (2021) Accounting for canopy structure improves hyperspectral radiative transfer and sun-induced chlorophyll fluorescence representations in a new generation Earth System model, Remote Sensing of Environment, 261(12), 108350" -US-NR1,1700000513,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.RSE.2021.112497 -US-NR1,1700000513,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-NR1,1700005136,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Burns, S. P., Blanken, P. D., Turnipseed, A. A., Hu, J., Monson, R. K. (2015) The Influence Of Warm-Season Precipitation On The Diel Cycle Of The Surface Energy Balance And Carbon Dioxide At A Colorado Subalpine Forest Site, Biogeosciences, 12(23), 7349-7377" -US-NR1,1700005136,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.5194/BG-12-7349-2015 -US-NR1,1700005136,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Primary_Citation -US-NR1,1700006945,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Burns, S. P., Delany, A. C., Sun, J., Stephens, B. B., Oncley, S. P., Maclean, G. D., Semmer, S. R., Schröter, J., Ruppert, J. (2009) An Evaluation Of Calibration Techniques For In Situ Carbon Dioxide Measurements Using A Programmable Portable Trace-Gas Measuring System, Journal Of Atmospheric And Oceanic Technology, 26(2), 291-316" -US-NR1,1700006945,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1175/2008JTECHA1080.1 -US-NR1,1700006945,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-NR1,1700005115,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Burns, S. P., Frank, J. M., Massman, W. J., Patton, E. G., Blanken, P. D. (2021) The Effect Of Static Pressure-Wind Covariance On Vertical Carbon Dioxide Exchange At A Windy Subalpine Forest Site, Agricultural And Forest Meteorology, 306(11), 108402" -US-NR1,1700005115,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108402 -US-NR1,1700005115,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-NR1,1700002595,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Burns, S. P., Horst, T. W., Jacobsen, L., Blanken, P. D., Monson, R. K. (2012) Using Sonic Anemometer Temperature To Measure Sensible Heat Flux In Strong Winds, Atmospheric Measurement Techniques, 5(9), 2095-2111" -US-NR1,1700002595,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.5194/AMT-5-2095-2012 -US-NR1,1700002595,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-NR1,1700001497,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Burns, S. P., Maclean, G. D., Blanken, P. D., Oncley, S. P., Semmer, S. R., Monson, R. K. (2016) The Niwot Ridge Subalpine Forest Us-Nr1 Ameriflux Site - Part 1: Data Acquisition And Site Record-Keeping, Geoscientific Instrumentation, Methods And Data Systems, 5(2), 451-471" -US-NR1,1700001497,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.5194/GI-5-451-2016 -US-NR1,1700001497,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-NR1,1700002883,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Burns, S. P., Molotch, N. P., Williams, M. W., Knowles, J. F., Seok, B., Monson, R. K., Turnipseed, A. A., Blanken, P. D. (2014) Snow Temperature Changes Within A Seasonal Snowpack And Their Relationship To Turbulent Fluxes Of Sensible And Latent Heat, Journal Of Hydrometeorology, 15(1), 117-142" -US-NR1,1700002883,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1175/JHM-D-13-026.1 -US-NR1,1700002883,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-NR1,1700008907,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Burns, S. P., Sun, J., Lenschow, D. H., Oncley, S. P., Stephens, B. B., Yi, C., Anderson, D. E., Hu, J., Monson, R. K. (2011) Atmospheric Stability Effects On Wind Fields And Scalar Mixing Within And Just Above A Subalpine Forest In Sloping Terrain, Boundary-Layer Meteorology, 138(2), 231-262" -US-NR1,1700008907,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1007/S10546-010-9560-6 -US-NR1,1700008907,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-NR1,1700001164,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Burns, S. P., Swenson, S. C., Wieder, W. R., Lawrence, D. M., Bonan, G. B., Knowles, J. F., Blanken, P. D. (2018) A Comparison Of The Diel Cycle Of Modeled And Measured Latent Heat Flux During The Warm Season In A Colorado Subalpine Forest, Journal Of Advances In Modeling Earth Systems, 8(5-6), 663-676" -US-NR1,1700001164,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/2017MS001248 -US-NR1,1700001164,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-NR1,1700001701,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Baldocchi, D. D., Poindexter, C., Abraha, M., Desai, A. R., Bohrer, G., Arain, M. A., Griffis, T., Blanken, P. D., O'Halloran, T. L., Thomas, R. Q., Zhang, Q., Burns, S. P., Frank, J. M., Christian, D., Brown, S., Black, T. A., Gough, C. M., Law, B. E., Lee, X., Chen, J., Reed, D. E., Massman, W. J., Clark, K., Hatfield, J., Prueger, J., Bracho, R., Baker, J. M., Martin, T. A. (2018) Temporal Dynamics Of Aerodynamic Canopy Height Derived From Eddy Covariance Momentum Flux Data Across North American Flux Networks, Geophysical Research Letters, 45(1), 9275–9287" -US-NR1,1700001701,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018GL079306 -US-NR1,1700001701,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-NR1,1700000657,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(12), 108350" -US-NR1,1700000657,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -US-NR1,1700000657,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-NR1,1700001479,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Churkina, G., Schimel, D., Braswell, B. H., Xiao, X. (2005) Spatial Analysis Of Growing Season Length Control Over Net Ecosystem Exchange, Global Change Biology, 11(10), 1777-1787" -US-NR1,1700001479,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/J.1365-2486.2005.001012.X -US-NR1,1700001479,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-NR1,1700008754,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Dennis Baldocchi, Cove Sturtevant (2015) Does day and night sampling reduce spurious correlation between canopy photosynthesis and ecosystem respiration?, Agricultural and Forest Meteorology, 207(3-4), 117-126" -US-NR1,1700008754,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2015.03.010 -US-NR1,1700008754,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-NR1,1700003069,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Desai, A.R., Moore, D.J.P., Ahue, W.K.M., Wilkes, P.T.V., De Wekker, S.F.J., Brooks, B.G., Campos, T.L., Stephens, B.B., Monson, R.K., Burns, S.P., Quaife, T., Aulenbach, S.M., Schimel, D.S. (2011) Seasonal Pattern Of Regional Carbon Balance In The Central Rocky Mountains From Surface And Airborne Measurements, Journal Of Geophysical Research, 116(G04009), 1-16" -US-NR1,1700003069,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2011JG001655 -US-NR1,1700003069,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-NR1,1700001311,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Hibbard, K. A., Law, B. E., Reichstein, M., Sulzman, J. (2005) An Analysis Of Soil Respiration Across Northern Hemisphere Temperate Ecosystems, Biogeochemistry, 73(1), 29-70" -US-NR1,1700001311,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1007/S10533-004-2946-0 -US-NR1,1700001311,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-NR1,1700008421,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Hu, J., Moore, D. J., Burns, S. P., Monson, R. K. (2010) Longer Growing Seasons Lead To Less Carbon Sequestration By A Subalpine Forest, Global Change Biology, 16(2), 771-783" -US-NR1,1700008421,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/J.1365-2486.2009.01967.X -US-NR1,1700008421,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-NR1,1700003885,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Hu, J., Moore, D. J., Riveros-Iregui, D. A., Burns, S. P., Monson, R. K. (2010) Modeling Whole-Tree Carbon Assimilation Rate Using Observed Transpiration Rates And Needle Sugar Carbon Isotope Ratios, New Phytologist, 185(4), 1000-1015" -US-NR1,1700003885,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/J.1469-8137.2009.03154.X -US-NR1,1700003885,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-NR1,1700005442,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Hui, D., Wan, S., Su, B., Katul, G., Monson, R., Luo, Y. (2004) Gap-Filling Missing Data In Eddy Covariance Measurements Using Multiple Imputation (MI) For Annual Estimations, Agricultural And Forest Meteorology, 121(1-2), 93-111" -US-NR1,1700005442,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/S0168-1923(03)00158-8 -US-NR1,1700005442,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-NR1,1700005754,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Huxman, T. E., Turnipseed, A. A., Sparks, J. P., Harley, P. C., Monson, R. K. (2003) Temperature As A Control Over Ecosystem CO2 Fluxes In A High-Elevation, Subalpine Forest, Oecologia, 134(4), 537-546" -US-NR1,1700005754,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1007/S00442-002-1131-1 -US-NR1,1700005754,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-NR1,1700005043,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Knowles, J. F., Burns, S. P., Blanken, P. D., Monson, R. K. 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(2020) Seasonal Variability Of Forest Sensitivity To Heat And Drought Stresses: A Synthesis Based On Carbon Fluxes From North American Forest Ecosystems, Global Change Biology, 26(2), 901-918" -US-NR1,1700007059,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/GCB.14843 -US-NR1,1700007059,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-NR1,1700003405,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Yi, C., Anderson, D. E., Turnipseed, A. A., Burns, S. P., Sparks, J. P., Stannard, D. I., Monson, R. K. (2008) The Contribution Of Advective Fluxes To Net Ecosystem Exchange In A High-Elevation, Subalpine Forest, Ecological Applications, 18(6), 1379-1390" -US-NR1,1700003405,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1890/06-0908.1 -US-NR1,1700003405,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-NR1,1700006711,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Yi, C., Li, R., Bakwin, P. S., Desai, A., Ricciuto, D. M., Burns, S. P., Turnipseed, A. A., Wofsy, S. C., Munger, J. W., Wilson, K., Monson, R. K. (2004) A Nonparametric Method For Separating Photosynthesis And Respiration Components In CO2 Flux Measurements, Geophysical Research Letters, 31(17), n/a-n/a" -US-NR1,1700006711,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2004GL020490 -US-NR1,1700006711,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-NR1,1700000993,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Yi, C., Monson, R. K., Zhai, Z., Anderson, D. E., Lamb, B., Allwine, G., Turnipseed, A. A., Burns, S. P. (2005) Modeling And Measuring The Nocturnal Drainage Flow In A High-Elevation, Subalpine Forest With Complex Terrain, Journal Of Geophysical Research, 110(D22303), n/a-n/a" -US-NR1,1700000993,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2005JD006282 -US-NR1,1700000993,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-NR1,1700004242,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Zhang, Q., Ficklin, D. L., Manzoni, S., Wang, L., Way, D., Phillips, R. P., Novick, K. A. (2019) Response Of Ecosystem Intrinsic Water Use Efficiency And Gross Primary Productivity To Rising Vapor Pressure Deficit, Environmental Research Letters, 14(7), 074023" -US-NR1,1700004242,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1088/1748-9326/AB2603 -US-NR1,1700004242,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-NR1,1700009006,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Zobitz, J. M., Burns, S. P., Ogée, J., Reichstein, M., Bowling, D. R. (2007) Partitioning Net Ecosystem Exchange Of Co2: A Comparison Of A Bayesian/Isotope Approach To Environmental Regression Methods, Journal Of Geophysical Research: Biogeosciences, 112(G3), n/a-n/a" -US-NR1,1700009006,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2006JG000282 -US-NR1,1700009006,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-NR1,1700003285,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"ZOBITZ, J. M., BURNS, S. P., REICHSTEIN, M., BOWLING, D. R. (2008) Partitioning Net Ecosystem Carbon Exchange And The Carbon Isotopic Disequilibrium In A Subalpine Forest, Global Change Biology, 14(8), 1785-1800" -US-NR1,1700003285,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/J.1365-2486.2008.01609.X -US-NR1,1700003285,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-NR1,1700008973,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Zscheischler, J., Fatichi, S., Wolf, S., Blanken, P., Bohrer, G., Clark, K., Desai, A., Hollinger, D., Keenan, T., Novick, K.A., Seneviratne, S.I. (2016) Short-term favorable weather conditions are an important control of interannual variability in carbon and water fluxes, Journal of Geophysical Research - Biogeosciences, 121(8), 2186-2198" -US-NR1,1700008973,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/2016JG003503 -US-NR1,1700008973,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-NR1,11582,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,The objectives and topics include the following: 1) Quantify the potential of forests in the mountainous Western US to sequester carbon and the effects of soil moisture and temperature on seasonal and annual patterns of NEE; 2) Examination of the large-scale flow features associated with mountainous terrains in an effort to determine how they affect local flux measurements; 3) Assessment of the energy budget of a subalpine forest in complex terrain; 4) Determine the difficulties surrounding a precise definition of the time of transition from winter net ecosystem CO2 loss to spring net ecosystem CO2 gain; 5) Establish a quantitative relationship between interannual variation in the rate of carbon uptake during spring snow melt and interannual variation in the rate of total annual carbon uptake; 6) Evaluate the environmental variables that are most important in triggering the forest turn-on date; 7) Investigate the physiological processes that are most limiting to the springtime upregulation of photosynthetic CO2 assimilation. -US-NR1,24971,GRP_SA,SA,100 -US-NR1,24971,GRP_SA,SA_COMMENT,"(Date) Not formally determined, only estimated as time since cessation of logging.; approx; Monson et al. Global Change Biology (2002), 8 459-478" -US-NR1,11583,GRP_SITE_CHAR,TERRAIN,"Significant Slope (>5%, <10%)" -US-NR1,11583,GRP_SITE_CHAR,ASPECT,E -US-NR1,11583,GRP_SITE_CHAR,WIND_DIRECTION,W -US-NR1,11583,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,250 -US-NR1,11583,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,210 -US-NR1,98270,GRP_SITE_DESC,SITE_DESC,"The Niwot Ridge AmeriFlux site is located in a subalpine forest ecosystem just below the Continental Divide near Nederland, CO. The site is located at 3050 m elevation, within 600m of the NOAA C1 long-term monitoring station, approximately 8 km east of the Continental Divide. The surrounding subalpine forest is ~97 years old and in a state of aggradation, having recovered from early twentieth century logging (Monson, et al. Global Change Biology (2002), 8 459-478). - -Additional data, photos, and information can be found at: - -Burns S. P., P. D. Blanken, and R. K. Monson (2020): Data, Photographs, Videos, and Information for the Niwot Ridge Subalpine Forest (US-NR1) AmeriFlux site. AmeriFlux Management Project. https://doi.org/10.15485/1671825" -US-NR1,11585,GRP_SITE_FUNDING,SITE_FUNDING,NSF -US-NR1,23956,GRP_SOIL_CHEM,SOIL_CHEM_BD,1.483 -US-NR1,23956,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,Total -US-NR1,23956,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,"From Laura E. Scott-Denton, et al. Soil Biology and Biochemistry. Volume 35, issue 4, April 2003, 525-534." -US-NR1,29309,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION,Extremely rocky (granite) consisting primarily of mineral clays covered with a surface layer (~10 cm) of organic material -US-NR1,29309,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION_TAXONOMY,Other -US-NR1,24669,GRP_SOIL_DEPTH,SOIL_DEPTH,15 -US-NR1,25055,GRP_SOIL_DEPTH,SOIL_DEPTH,15 -US-NR1,24666,GRP_SOIL_TEX,SOIL_TEX_WATER_HOLD_CAP,150 -US-NR1,24666,GRP_SOIL_TEX,SOIL_TEX_PROFILE_MIN,0 -US-NR1,24666,GRP_SOIL_TEX,SOIL_TEX_PROFILE_MAX,15 -US-NR1,24666,GRP_SOIL_TEX,SOIL_TEX_HORIZON,Total -US-NR1,24338,GRP_SPP_O,SPP_O,ABLA (NRCS plant code) -US-NR1,24989,GRP_SPP_O,SPP_O,PICO (NRCS plant code) -US-NR1,24231,GRP_SPP_O,SPP_O,PIEN (NRCS plant code) -US-NR1,24989,GRP_SPP_O,SPP_O_PERC,26 -US-NR1,24231,GRP_SPP_O,SPP_O_PERC,28 -US-NR1,24338,GRP_SPP_O,SPP_O_PERC,46 -US-NR1,24231,GRP_SPP_O,SPP_DATE,20000718 -US-NR1,24338,GRP_SPP_O,SPP_DATE,20000718 -US-NR1,24989,GRP_SPP_O,SPP_DATE,20000718 -US-NR1,24231,GRP_SPP_O,SPP_COMMENT,"BLA=subalpine fir, PIEN=Engelmann spruce; PICO=lodgepole pine. The overstory dominant species percentages can be found in Monson, et al. Oecologia (2005) 146: 130-147. The understory is relatively sparse, containing tree seedlings from all three species and patches of whortelberry (Vaccinium myrtillus, VAMY2) at ~25% average coverage, from Monson, et al. Global Change Biology (2002), 8 459-478. Aspens (POTR5) are found ~.5mi northeast of the tower, but not within the tower's dominant east-west footprint." -US-NR1,24338,GRP_SPP_O,SPP_COMMENT,"BLA=subalpine fir, PIEN=Engelmann spruce; PICO=lodgepole pine. The overstory dominant species percentages can be found in Monson, et al. Oecologia (2005) 146: 130-147. The understory is relatively sparse, containing tree seedlings from all three species and patches of whortelberry (Vaccinium myrtillus, VAMY2) at ~25% average coverage, from Monson, et al. Global Change Biology (2002), 8 459-478. Aspens (POTR5) are found ~.5mi northeast of the tower, but not within the tower's dominant east-west footprint." -US-NR1,24989,GRP_SPP_O,SPP_COMMENT,"BLA=subalpine fir, PIEN=Engelmann spruce; PICO=lodgepole pine. The overstory dominant species percentages can be found in Monson, et al. Oecologia (2005) 146: 130-147. The understory is relatively sparse, containing tree seedlings from all three species and patches of whortelberry (Vaccinium myrtillus, VAMY2) at ~25% average coverage, from Monson, et al. Global Change Biology (2002), 8 459-478. Aspens (POTR5) are found ~.5mi northeast of the tower, but not within the tower's dominant east-west footprint." -US-NR1,11586,GRP_STATE,STATE,CO -US-NR1,11587,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Peter Blanken -US-NR1,11587,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-NR1,11587,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,Blanken@Colorado.EDU -US-NR1,11587,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Colorado -US-NR1,11587,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Department of Geography, 260 UCB,Boulder,CO,USA,80309-0260" -US-NR1,85192,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Sean Burns -US-NR1,85192,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,AncContact -US-NR1,85192,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,sean.burns@colorado.edu -US-NR1,85192,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Colorado -US-NR1,85192,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Department of Geography, Campus Box 260, University of Colorado, Boulder, CO 80309-0260, USA" -US-NR1,11593,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Russell Monson -US-NR1,11593,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-NR1,11593,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,Russell.Monson@colorado.edu -US-NR1,11593,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,The University of Arizona -US-NR1,11593,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"School of Natural Resources and the Environment, PO Box 210158b,Tucson, AZ USA 85721" -US-NR1,22255,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,David Bowling -US-NR1,22255,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Affiliate -US-NR1,22255,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,david.bowling@utah.edu -US-NR1,22255,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Utah -US-NR1,22255,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Department of Biology, 257 S. 1400 E.,Salt Lake City, UT USA 84112-0840" -US-NR1,29828,GRP_TOWER_POWER,TOWER_POWER,Direct power -US-NR1,11588,GRP_TOWER_TYPE,TOWER_TYPE,walk-up -US-NR1,11589,GRP_URL,URL,http://urquell.colorado.edu/data_ameriflux -US-NR1,24000408,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-NR1 -US-NR1,11590,GRP_UTC_OFFSET,UTC_OFFSET,-7 -US-NR3,94708,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,"Funding was provided by National Science Foundation DEB awards 0423662, 1027341, and 1637686 to the Niwot Ridge LTER." -US-NR3,94727,GRP_CLIM_AVG,MAT,-2.2 -US-NR3,94727,GRP_CLIM_AVG,MAP,884 -US-NR3,94727,GRP_CLIM_AVG,CLIMATE_KOEPPEN,ET -US-NR3,27001170,GRP_COUNTRY,COUNTRY,USA -US-NR3,96781,GRP_DOI,DOI,10.17190/AMF/1804491 -US-NR3,96781,GRP_DOI,DOI_CITATION,"John Knowles (2022), AmeriFlux BASE US-NR3 Niwot Ridge Alpine (T-Van West), Ver. 3-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1804491" -US-NR3,96781,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-NR3,96768,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-NR3,96768,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,John Knowles -US-NR3,96768,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-NR3,96768,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,john.knowles@usda.gov -US-NR3,96768,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,USDA ARS Southwest Watershed Research Center -US-NR3,96776,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,USDA ARS Southwest Watershed Research Center -US-NR3,96776,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-NR3,96772,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,United States National Science Foundation -US-NR3,96772,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-NR3,94724,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Undisturbed -US-NR3,96470,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-NR3,96470,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-NR3,96470,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20070509 -US-NR3,96470,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-NR3,96423,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-NR3,96423,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-NR3,96423,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20070509 -US-NR3,96423,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-NR3,23001170,GRP_HEADER,SITE_NAME,Niwot Ridge Alpine (T-Van West) -US-NR3,94710,GRP_IGBP,IGBP,GRA -US-NR3,94720,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-NR3,94720,GRP_LAND_OWNERSHIP,LAND_OWNER,United States Forest Service -US-NR3,94712,GRP_LOCATION,LOCATION_LAT,40.0520 -US-NR3,94712,GRP_LOCATION,LOCATION_LONG,-105.5864 -US-NR3,94712,GRP_LOCATION,LOCATION_ELEV,3504 -US-NR3,94712,GRP_LOCATION,LOCATION_DATE_START,1967 -US-NR3,94712,GRP_LOCATION,LOCATION_COMMENT,T-Van site established by the NOAA/ESRL/GML CCGG cooperative air sampling network -US-NR3,94717,GRP_NETWORK,NETWORK,AmeriFlux -US-NR3,1700003336,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Blanken, P. D., Williams, M. W., Burns, S. P., Monson, R. K., Knowles, J. F., Chowanski, K., Ackerman, T. (2009) A Comparison Of Water And Carbon Dioxide Exchange At A Windy Alpine Tundra And Subalpine Forest Site Near Niwot Ridge, Colorado, Biogeochemistry, 95(1), 61-76" -US-NR3,1700003336,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1007/S10533-009-9325-9 -US-NR3,1700003336,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-NR3,1700001113,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Knowles, J. F., Blanken, P. D., Lawrence, C. R., Williams, M. W. (2019) Evidence For Non-Steady-State Carbon Emissions From Snow-Scoured Alpine Tundra, Nature Communications, 10(1), 1191-1211" -US-NR3,1700001113,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1038/S41467-019-09149-2 -US-NR3,1700001113,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-NR3,1700008457,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Knowles, J. F., Blanken, P. D., Williams, M. W. (2015) Soil Respiration Variability Across A Soil Moisture And Vegetation Community Gradient Within A Snow-Scoured Alpine Meadow, Biogeochemistry, 125(2), 185-202" -US-NR3,1700008457,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1007/S10533-015-0122-3 -US-NR3,1700008457,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-NR3,1700000474,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Knowles, J. F., Blanken, P. D., Williams, M. W. (2016) Wet Meadow Ecosystems Contribute The Majority Of Overwinter Soil Respiration From Snow-Scoured Alpine Tundra, Journal Of Geophysical Research: Biogeosciences, 121(4), 1118-1130" -US-NR3,1700000474,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/2015JG003081 -US-NR3,1700000474,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-NR3,1700001413,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Knowles, J. F., Blanken, P. D., Williams, M. W., Chowanski, K. M. (2012) Energy And Surface Moisture Seasonally Limit Evaporation And Sublimation From Snow-Free Alpine Tundra, Agricultural And Forest Meteorology, 157(), 106-115" -US-NR3,1700001413,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2012.01.017 -US-NR3,1700001413,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-NR3,1700005187,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Knowles, J. F., Blanken, P. D., Williams, M. W., Chowanski, K. M. (2012) Energy And Surface Moisture Seasonally Limit Evaporation And Sublimation From Snow-Free Alpine Tundra, Agricultural And Forest Meteorology, 157(1), 106-115" -US-NR3,1700005187,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2012.01.017 -US-NR3,1700005187,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-NR3,1700001845,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Knowles, J. F., Burns, S. P., Blanken, P. D., Monson, R. K. (2015) Fluxes Of Energy, Water, And Carbon Dioxide From Mountain Ecosystems At Niwot Ridge, Colorado, Plant Ecology & Diversity, 8(5-6), 663-676" -US-NR3,1700001845,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1080/17550874.2014.904950 -US-NR3,1700001845,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-NR3,1700004341,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Knowles, J. F., Harpold, A. A., Cowie, R., Zeliff, M., Barnard, H. R., Burns, S. P., Blanken, P. D., Morse, J. F., Williams, M. W. (2015) The Relative Contributions Of Alpine And Subalpine Ecosystems To The Water Balance Of A Mountainous, Headwater Catchment, Hydrological Processes, 29(22), 4794-4808" -US-NR3,1700004341,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/HYP.10526 -US-NR3,1700004341,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-NR3,1700008052,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Sexstone, G. A., Clow, D. W., Fassnacht, S. R., Liston, G. E., Hiemstra, C. A., Knowles, J. F., Penn, C. A. (2018) Snow Sublimation In Mountain Environments And Its Sensitivity To Forest Disturbance And Climate Warming, Water Resources Research, 54(2), 1191-1211" -US-NR3,1700008052,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/2017WR021172 -US-NR3,1700008052,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-NR3,1700004254,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Wieder, W. R., Knowles, J. F., Blanken, P. D., Swenson, S. C., Suding, K. N. (2017) Ecosystem Function In Complex Mountain Terrain: Combining Models And Long-Term Observations To Advance Process-Based Understanding, Journal Of Geophysical Research: Biogeosciences, 122(4), 825-845" -US-NR3,1700004254,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/2016JG003704 -US-NR3,1700004254,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-NR3,94718,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,Sublimation; Carbon cycle; Water balance; Ecosystem function in complex mountain terrain -US-NR3,94721,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"2000 E. Allen Road, Tucson, AZ, 85719, USA" -US-NR3,94725,GRP_SITE_CHAR,TERRAIN,"Significant Slope (>5%, <10%)" -US-NR3,94725,GRP_SITE_CHAR,ASPECT,E -US-NR3,94725,GRP_SITE_CHAR,WIND_DIRECTION,W -US-NR3,94725,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,500 -US-NR3,94725,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,50 -US-NR3,96448,GRP_SITE_DESC,SITE_DESC,"Nearby (<500 m; NWT Saddle) incoming solar radiation and other met data: doi:10.6073/pasta/09ee081d2bf08f50c2a30e1e2b4c9d04; Reliable daily precipitation data (NWT D1): doi:10.6073/pasta/63b912a406254df036e89c84a1b59230. Snow-scoured alpine tundra; Dry meadow vegetation; 3-m tower located 50 m W of US-NR4, 420 m SW of US-xNW, and 28 km west of Boulder, CO, USA." -US-NR3,94711,GRP_SITE_FUNDING,SITE_FUNDING,United States National Science Foundation -US-NR3,94716,GRP_STATE,STATE,CO -US-NR3,98524,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,John Knowles -US-NR3,98524,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-NR3,98524,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,jfknowles@csuchico.edu -US-NR3,98524,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"California State University, Chico" -US-NR3,98524,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"400 W 1st St, Chico, CA 95929" -US-NR3,94722,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Sarah Elmendorf -US-NR3,94722,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,AncContact -US-NR3,94722,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,Sarah.Elmendorf@Colorado.edu -US-NR3,94722,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Colorado Boulder -US-NR3,94709,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Peter Blanken -US-NR3,94709,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-NR3,94709,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,blanken@Colorado.edu -US-NR3,94709,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Colorado Boulder -US-NR3,94719,GRP_TOWER_POWER,TOWER_POWER,Direct power -US-NR3,94707,GRP_TOWER_TYPE,TOWER_TYPE,tripod -US-NR3,96458,GRP_URL,URL,https://nwt.lternet.edu/ -US-NR3,24001170,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-NR3 -US-NR3,94713,GRP_UTC_OFFSET,UTC_OFFSET,-7 -US-NR4,94741,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,"Funding was provided by National Science Foundation DEB awards 0423662, 1027341, and 1637686 to the Niwot Ridge LTER." -US-NR4,94738,GRP_CLIM_AVG,MAT,-2.2 -US-NR4,94738,GRP_CLIM_AVG,MAP,884 -US-NR4,94738,GRP_CLIM_AVG,CLIMATE_KOEPPEN,ET -US-NR4,27001171,GRP_COUNTRY,COUNTRY,USA -US-NR4,96780,GRP_DOI,DOI,10.17190/AMF/1804492 -US-NR4,96780,GRP_DOI,DOI_CITATION,"John Knowles (2022), AmeriFlux BASE US-NR4 Niwot Ridge Alpine (T-Van East), Ver. 3-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1804492" -US-NR4,96780,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-NR4,96769,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-NR4,96769,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,John Knowles -US-NR4,96769,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-NR4,96769,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,john.knowles@usda.gov -US-NR4,96769,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,USDA ARS Southwest Watershed Research Center -US-NR4,96777,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,USDA ARS Southwest Watershed Research Center -US-NR4,96777,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-NR4,96771,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,United States National Science Foundation -US-NR4,96771,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-NR4,94748,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Undisturbed -US-NR4,96459,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-NR4,96459,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-NR4,96459,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20070829 -US-NR4,96459,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-NR4,96390,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-NR4,96390,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-NR4,96390,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20070829 -US-NR4,96390,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-NR4,23001171,GRP_HEADER,SITE_NAME,Niwot Ridge Alpine (T-Van East) -US-NR4,94731,GRP_IGBP,IGBP,GRA -US-NR4,94733,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-NR4,94733,GRP_LAND_OWNERSHIP,LAND_OWNER,United States Forest Service -US-NR4,94744,GRP_LOCATION,LOCATION_LAT,40.0520 -US-NR4,94744,GRP_LOCATION,LOCATION_LONG,-105.5859 -US-NR4,94744,GRP_LOCATION,LOCATION_ELEV,3502 -US-NR4,94744,GRP_LOCATION,LOCATION_DATE_START,1967 -US-NR4,94744,GRP_LOCATION,LOCATION_COMMENT,T-Van site established by the NOAA/ESRL/GML CCGG cooperative air sampling network -US-NR4,94739,GRP_NETWORK,NETWORK,AmeriFlux -US-NR4,1700000708,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Blanken, P. D., Williams, M. W., Burns, S. P., Monson, R. K., Knowles, J. F., Chowanski, K., Ackerman, T. (2009) A Comparison Of Water And Carbon Dioxide Exchange At A Windy Alpine Tundra And Subalpine Forest Site Near Niwot Ridge, Colorado, Biogeochemistry, 95(1), 61-76" -US-NR4,1700000708,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1007/S10533-009-9325-9 -US-NR4,1700000708,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-NR4,1700001971,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Knowles, J. F., Blanken, P. D., Lawrence, C. R., Williams, M. W. (2019) Evidence For Non-Steady-State Carbon Emissions From Snow-Scoured Alpine Tundra, Nature Communications, 10(1), 1191-1211" -US-NR4,1700001971,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1038/S41467-019-09149-2 -US-NR4,1700001971,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-NR4,1700001527,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Knowles, J. F., Blanken, P. D., Williams, M. W. (2015) Soil Respiration Variability Across A Soil Moisture And Vegetation Community Gradient Within A Snow-Scoured Alpine Meadow, Biogeochemistry, 125(2), 185-202" -US-NR4,1700001527,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1007/S10533-015-0122-3 -US-NR4,1700001527,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-NR4,1700001206,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Knowles, J. F., Blanken, P. D., Williams, M. W. (2016) Wet Meadow Ecosystems Contribute The Majority Of Overwinter Soil Respiration From Snow-Scoured Alpine Tundra, Journal Of Geophysical Research: Biogeosciences, 121(4), 1118-1130" -US-NR4,1700001206,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/2015JG003081 -US-NR4,1700001206,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-NR4,1700007992,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Knowles, J. F., Blanken, P. D., Williams, M. W., Chowanski, K. M. (2012) Energy And Surface Moisture Seasonally Limit Evaporation And Sublimation From Snow-Free Alpine Tundra, Agricultural And Forest Meteorology, 157(), 106-115" -US-NR4,1700007992,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2012.01.017 -US-NR4,1700007992,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-NR4,1700008775,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Knowles, J. F., Blanken, P. D., Williams, M. W., Chowanski, K. M. (2012) Energy And Surface Moisture Seasonally Limit Evaporation And Sublimation From Snow-Free Alpine Tundra, Agricultural And Forest Meteorology, 157(1), 106-115" -US-NR4,1700008775,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2012.01.017 -US-NR4,1700008775,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-NR4,1700001494,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Knowles, J. F., Burns, S. P., Blanken, P. D., Monson, R. K. (2015) Fluxes Of Energy, Water, And Carbon Dioxide From Mountain Ecosystems At Niwot Ridge, Colorado, Plant Ecology & Diversity, 8(5-6), 663-676" -US-NR4,1700001494,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1080/17550874.2014.904950 -US-NR4,1700001494,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-NR4,1700005826,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Knowles, J. F., Harpold, A. A., Cowie, R., Zeliff, M., Barnard, H. R., Burns, S. P., Blanken, P. D., Morse, J. F., Williams, M. W. (2015) The Relative Contributions Of Alpine And Subalpine Ecosystems To The Water Balance Of A Mountainous, Headwater Catchment, Hydrological Processes, 29(22), 4794-4808" -US-NR4,1700005826,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/HYP.10526 -US-NR4,1700005826,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-NR4,1700002763,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Sexstone, G. A., Clow, D. W., Fassnacht, S. R., Liston, G. E., Hiemstra, C. A., Knowles, J. F., Penn, C. A. (2018) Snow Sublimation In Mountain Environments And Its Sensitivity To Forest Disturbance And Climate Warming, Water Resources Research, 54(2), 1191-1211" -US-NR4,1700002763,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/2017WR021172 -US-NR4,1700002763,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-NR4,1700003219,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Wieder, W. R., Knowles, J. F., Blanken, P. D., Swenson, S. C., Suding, K. N. (2017) Ecosystem Function In Complex Mountain Terrain: Combining Models And Long-Term Observations To Advance Process-Based Understanding, Journal Of Geophysical Research: Biogeosciences, 122(4), 825-845" -US-NR4,1700003219,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/2016JG003704 -US-NR4,1700003219,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-NR4,94746,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,Sublimation; Carbon cycle; Water balance; Ecosystem function in complex mountain terrain -US-NR4,94742,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"2000 E. Allen Road, Tucson, AZ, 85719, USA" -US-NR4,94728,GRP_SITE_CHAR,TERRAIN,"Significant Slope (>5%, <10%)" -US-NR4,94728,GRP_SITE_CHAR,ASPECT,E -US-NR4,94728,GRP_SITE_CHAR,WIND_DIRECTION,W -US-NR4,94728,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,550 -US-NR4,94728,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,40 -US-NR4,96392,GRP_SITE_DESC,SITE_DESC,"Nearby (<500 m; NWT Saddle) incoming solar radiation and other met data: doi:10.6073/pasta/09ee081d2bf08f50c2a30e1e2b4c9d04; Reliable daily precipitation data (NWT D1): doi:10.6073/pasta/63b912a406254df036e89c84a1b59230. Snow-scoured alpine tundra; Fellfield vegetation; 3-m tower located 50 m E of US-NR3, 387 m SW of US-xNW, and 28 km west of Boulder, CO, USA." -US-NR4,94747,GRP_SITE_FUNDING,SITE_FUNDING,United States National Science Foundation -US-NR4,94734,GRP_STATE,STATE,CO -US-NR4,98527,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,John Knowles -US-NR4,98527,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-NR4,98527,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,jfknowles@csuchico.edu -US-NR4,98527,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"California State University, Chico" -US-NR4,98527,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"400 W 1st St, Chico, CA 95929" -US-NR4,94735,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Sarah Elmendorf -US-NR4,94735,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,AncContact -US-NR4,94735,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,Sarah.Elmendorf@Colorado.edu -US-NR4,94735,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Colorado Boulder -US-NR4,94745,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Peter Blanken -US-NR4,94745,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-NR4,94745,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,blanken@Colorado.edu -US-NR4,94745,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Colorado Boulder -US-NR4,94736,GRP_TOWER_POWER,TOWER_POWER,Direct power -US-NR4,94729,GRP_TOWER_TYPE,TOWER_TYPE,tripod -US-NR4,96413,GRP_URL,URL,https://nwt.lternet.edu/ -US-NR4,24001171,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-NR4 -US-NR4,94740,GRP_UTC_OFFSET,UTC_OFFSET,-7 -US-Nrf,30902,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,USGS Land Carbon Program and United States Fish and Wildlife Service -US-Nrf,30902,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT_COMMENT,This project also leverages existing research from the National Aeronautics and Space Administration-Carbon Monitoring System program (Project #: NNH14AY67I) and the Estuary and Salmon Restoration Program (Project #: 13-1583P). -US-Nrf,30903,GRP_CLIM_AVG,MAT,10.3 -US-Nrf,30903,GRP_CLIM_AVG,MAP,1269 -US-Nrf,30903,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Csb -US-Nrf,27000711,GRP_COUNTRY,COUNTRY,USA -US-Nrf,30904,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Storm or wind -US-Nrf,30906,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Nrf,30906,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-Nrf,30906,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201706010000 -US-Nrf,30906,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Nrf,30905,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Nrf,30905,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CH4 -US-Nrf,30905,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201706010000 -US-Nrf,30905,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Nrf,30908,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Nrf,30908,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-Nrf,30908,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201706010000 -US-Nrf,30908,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Nrf,30907,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Nrf,30907,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-Nrf,30907,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201706010000 -US-Nrf,30907,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Nrf,23000711,GRP_HEADER,SITE_NAME,Nisqually reference -US-Nrf,30909,GRP_IGBP,IGBP,WET -US-Nrf,30909,GRP_IGBP,IGBP_COMMENT,"Lyngbi sedge, Pickleweed, Puget Sound gumweed" -US-Nrf,30910,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-Nrf,30910,GRP_LAND_OWNERSHIP,LAND_OWNER,Billy Frank Jr. Nisqually National Wildlife Refuge -US-Nrf,30911,GRP_LOCATION,LOCATION_LAT,47.0935 -US-Nrf,30911,GRP_LOCATION,LOCATION_LONG,-122.6927 -US-Nrf,30911,GRP_LOCATION,LOCATION_ELEV,8 -US-Nrf,30911,GRP_LOCATION,LOCATION_DATE_START,201706010000 -US-Nrf,30912,GRP_NETWORK,NETWORK,AmeriFlux -US-Nrf,90059,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"This project aims to quantify the net ecosystem carbon balance (NECB) of the marsh and assess how the NECB of this natural (or ""reference"") marsh compares to a nearby recently (2009) restored marsh (US-Nrs)." -US-Nrf,90066,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"6000 J Street, Placer Hall, Sacramento, CA 95819" -US-Nrf,30916,GRP_SITE_CHAR,TERRAIN,Flat -US-Nrf,30916,GRP_SITE_CHAR,ASPECT,FLAT -US-Nrf,30916,GRP_SITE_CHAR,WIND_DIRECTION,S -US-Nrf,30916,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,1700 -US-Nrf,30916,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,5 -US-Nrf,90068,GRP_SITE_DESC,SITE_DESC,"This site is a natural, undisturbed tidal salt marsh in the Nisqually River Delta, WA, USA." -US-Nrf,30918,GRP_SITE_FUNDING,SITE_FUNDING,"USGS, USFWS" -US-Nrf,30919,GRP_STATE,STATE,WA -US-Nrf,90064,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Brian Bergamaschi -US-Nrf,90064,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Nrf,90064,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,bbergama@usgs.gov -US-Nrf,90064,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,USGS -US-Nrf,90064,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"6000 J Street, Placer Hall, Sacramento, CA 95819" -US-Nrf,30922,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Lisamarie Windham-Myers -US-Nrf,30922,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Nrf,30922,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,lwindham-myers@usgs.gov -US-Nrf,30922,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,USGS -US-Nrf,30922,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"345 Middlefield Road, Menlo Park, CA, 94025" -US-Nrf,90062,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Ellen Stuart-Haëntjens -US-Nrf,90062,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,AncContact -US-Nrf,90062,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,egoodrich-stuart@usgs.gov -US-Nrf,90062,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,USGS -US-Nrf,90062,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"6000 J Street, Placer Hall, Sacramento, CA 95819" -US-Nrf,90069,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Sara Knox -US-Nrf,90069,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,AncContact -US-Nrf,90069,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,sara.knox@ubc.ca -US-Nrf,90069,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,UBC Geography -US-Nrf,90061,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Frank Anderson -US-Nrf,90061,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Affiliate -US-Nrf,90061,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,fanders@usgs.gov -US-Nrf,30927,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-Nrf,30924,GRP_TOWER_TYPE,TOWER_TYPE,tripod -US-Nrf,30925,GRP_URL,URL,https://www.werc.usgs.gov/ProjectSubWebPage.aspx?SubWebPageID=10&ProjectID=279 -US-Nrf,24000711,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-Nrf -US-Nrf,30926,GRP_UTC_OFFSET,UTC_OFFSET,-8 -US-Nrs,30865,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,USGS Land Carbon Program and United States Fish and Wildlife Service -US-Nrs,30865,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT_COMMENT,This project also leverages existing research from the National Aeronautics and Space Administration-Carbon Monitoring System program (Project #: NNH14AY67I) and the Estuary and Salmon Restoration Program (Project #: 13-1583P). -US-Nrs,30866,GRP_CLIM_AVG,MAT,10.3 -US-Nrs,30866,GRP_CLIM_AVG,MAP,1269 -US-Nrs,30866,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Csb -US-Nrs,27000710,GRP_COUNTRY,COUNTRY,USA -US-Nrs,30867,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Storm or wind -US-Nrs,30868,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Nrs,30868,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-Nrs,30868,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201706010000 -US-Nrs,30868,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Nrs,30889,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Nrs,30889,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CH4 -US-Nrs,30889,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201706010000 -US-Nrs,30889,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Nrs,30887,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Nrs,30887,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-Nrs,30887,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201706010000 -US-Nrs,30887,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Nrs,30885,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Nrs,30885,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-Nrs,30885,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201706010000 -US-Nrs,30885,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Nrs,23000710,GRP_HEADER,SITE_NAME,Nisqually restoring -US-Nrs,30869,GRP_IGBP,IGBP,WET -US-Nrs,30869,GRP_IGBP,IGBP_COMMENT,"Lyngbi sedge, Pickleweed, Puget Sound gumweed" -US-Nrs,30870,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-Nrs,30870,GRP_LAND_OWNERSHIP,LAND_OWNER,Billy Frank Jr. Nisqually National Wildlife Refuge -US-Nrs,30871,GRP_LOCATION,LOCATION_LAT,47.0936 -US-Nrs,30871,GRP_LOCATION,LOCATION_LONG,-122.7079 -US-Nrs,30871,GRP_LOCATION,LOCATION_ELEV,8 -US-Nrs,30871,GRP_LOCATION,LOCATION_DATE_START,201706010000 -US-Nrs,30872,GRP_NETWORK,NETWORK,AmeriFlux -US-Nrs,90058,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"This project aims to quantify the net ecosystem carbon balance (NECB) of the marsh and assess how the NECB of this restoring marsh compares to a nearby natural, undisturbed (i.e. “reference”) marsh (US-Nrf)." -US-Nrs,90057,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"6000 J Street, Placer Hall, Sacramento, CA 95819" -US-Nrs,30876,GRP_SITE_CHAR,TERRAIN,Flat -US-Nrs,30876,GRP_SITE_CHAR,ASPECT,FLAT -US-Nrs,30876,GRP_SITE_CHAR,WIND_DIRECTION,S -US-Nrs,30876,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,1700 -US-Nrs,30876,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,5 -US-Nrs,90067,GRP_SITE_DESC,SITE_DESC,"This site is a restored tidal salt marsh in the Nisqually River Delta, WA, USA. The historical marsh was diked for a century for agricultural use and then restored to tidal influence in October 2009." -US-Nrs,30878,GRP_SITE_FUNDING,SITE_FUNDING,"USGS, USFWS" -US-Nrs,30879,GRP_STATE,STATE,WA -US-Nrs,90065,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Brian Bergamaschi -US-Nrs,90065,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Nrs,90065,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,bbergama@usgs.gov -US-Nrs,90065,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,USGS -US-Nrs,90065,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"6000 J Street, Placer Hall, Sacramento, CA 95819" -US-Nrs,30888,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Lisamarie Windham-Myers -US-Nrs,30888,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Nrs,30888,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,lwindham-myers@usgs.gov -US-Nrs,30888,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,USGS -US-Nrs,30888,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"345 Middlefield Road, Menlo Park, CA, 94025" -US-Nrs,90060,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Ellen Stuart-Haëntjens -US-Nrs,90060,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,AncContact -US-Nrs,90060,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,egoodrich-stuart@usgs.gov -US-Nrs,90060,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,USGS -US-Nrs,90060,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"6000 J Street, Placer Hall, Sacramento, CA 95819" -US-Nrs,90055,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Sara Knox -US-Nrs,90055,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,AncContact -US-Nrs,90055,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,sara.knox@ubc.ca -US-Nrs,90055,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,UBC Geography -US-Nrs,90056,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Frank Anderson -US-Nrs,90056,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Affiliate -US-Nrs,90056,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,fanders@usgs.gov -US-Nrs,30881,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-Nrs,30882,GRP_TOWER_TYPE,TOWER_TYPE,tripod -US-Nrs,30883,GRP_URL,URL,https://www.werc.usgs.gov/ProjectSubWebPage.aspx?SubWebPageID=10&ProjectID=279 -US-Nrs,24000710,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-Nrs -US-Nrs,30884,GRP_UTC_OFFSET,UTC_OFFSET,-8 -US-OF1,30645,GRP_CLIM_AVG,MAT,-16.3 -US-OF1,30645,GRP_CLIM_AVG,MAP,1277.1 -US-OF1,30645,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Cfa -US-OF1,27000699,GRP_COUNTRY,COUNTRY,USA -US-OF1,30647,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-OF1,30647,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-OF1,30647,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20170401 -US-OF1,30647,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Planned -US-OF1,30648,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-OF1,30648,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CH4 -US-OF1,30648,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20170401 -US-OF1,30648,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Planned -US-OF1,30646,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-OF1,30646,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-OF1,30646,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20170401 -US-OF1,30646,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Planned -US-OF1,23000699,GRP_HEADER,SITE_NAME,Osceola Farm Rice Field - SW -US-OF1,30649,GRP_IGBP,IGBP,CRO -US-OF1,30649,GRP_IGBP,IGBP_COMMENT,rice-soybean-rice annual rotation -US-OF1,30650,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -US-OF1,30772,GRP_LOCATION,LOCATION_LAT,35.7371 -US-OF1,30772,GRP_LOCATION,LOCATION_LONG,-90.0492 -US-OF1,30772,GRP_LOCATION,LOCATION_ELEV,69.8 -US-OF1,30772,GRP_LOCATION,LOCATION_DATE_START,20170401 -US-OF1,30652,GRP_NETWORK,NETWORK,AmeriFlux -US-OF1,86991,GRP_NETWORK,NETWORK,Phenocam -US-OF1,30653,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"Agriculture, irrigation management, water balance, carbon balance" -US-OF1,30654,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"504 UNIVERSITY LOOP EAST, Jonesboro AR 72401" -US-OF1,30655,GRP_SITE_CHAR,TERRAIN,Flat -US-OF1,30655,GRP_SITE_CHAR,ASPECT,S -US-OF1,30655,GRP_SITE_CHAR,WIND_DIRECTION,S -US-OF1,30655,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,396 -US-OF1,30655,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,10 -US-OF1,30656,GRP_SITE_DESC,SITE_DESC,Alternate wetting and drying irrigation method using multiple inlet in rice fields under annual rice-soybean rotation -US-OF1,30657,GRP_SITE_FUNDING,SITE_FUNDING,"USDA, Arkansas State University, University of Arkansas" -US-OF1,30658,GRP_STATE,STATE,AR -US-OF1,30659,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Michele L Reba -US-OF1,30659,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-OF1,30659,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,michele.reba@ars.usda.gov -US-OF1,30659,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"USDA, ARS, DELTA WATER MANAGEMENT RESEARCH UNIT" -US-OF1,30659,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"504 UNIVERSITY LOOP EAST, Jonesboro AR 72401" -US-OF1,30660,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Benjamin R.K. Runkle -US-OF1,30660,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,AncContact -US-OF1,30660,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,brrunkle@uark.edu -US-OF1,30660,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Arkansas -US-OF1,30660,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1 University of Arkansas, Engineering Hall 231, Fayetteville, AR 72701" -US-OF1,30663,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-OF1,30661,GRP_TOWER_TYPE,TOWER_TYPE,tripod -US-OF1,24000699,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-OF1 -US-OF1,30662,GRP_UTC_OFFSET,UTC_OFFSET,-6 -US-OF2,30626,GRP_CLIM_AVG,MAT,-16.3 -US-OF2,30626,GRP_CLIM_AVG,MAP,1277.1 -US-OF2,30626,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Cfa -US-OF2,27000700,GRP_COUNTRY,COUNTRY,USA -US-OF2,30627,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-OF2,30627,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-OF2,30627,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20170401 -US-OF2,30627,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Planned -US-OF2,30628,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-OF2,30628,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CH4 -US-OF2,30628,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20170401 -US-OF2,30628,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Planned -US-OF2,30629,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-OF2,30629,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-OF2,30629,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20170401 -US-OF2,30629,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Planned -US-OF2,23000700,GRP_HEADER,SITE_NAME,Osceola Farm Rice Field - NW -US-OF2,30630,GRP_IGBP,IGBP,CRO -US-OF2,30630,GRP_IGBP,IGBP_COMMENT,rice-soybean-rice annual rotation -US-OF2,30631,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -US-OF2,85046,GRP_LOCATION,LOCATION_LAT,35.7406 -US-OF2,85046,GRP_LOCATION,LOCATION_LONG,-90.0489 -US-OF2,85046,GRP_LOCATION,LOCATION_ELEV,69.4 -US-OF2,85046,GRP_LOCATION,LOCATION_DATE_START,20170401 -US-OF2,30633,GRP_NETWORK,NETWORK,AmeriFlux -US-OF2,86992,GRP_NETWORK,NETWORK,Phenocam -US-OF2,30634,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"Agriculture, irrigation management, water balance, carbon balance" -US-OF2,30635,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"504 UNIVERSITY LOOP EAST, Jonesboro AR 72401" -US-OF2,30636,GRP_SITE_CHAR,TERRAIN,Flat -US-OF2,30636,GRP_SITE_CHAR,ASPECT,S -US-OF2,30636,GRP_SITE_CHAR,WIND_DIRECTION,S -US-OF2,30636,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,396 -US-OF2,30636,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,10 -US-OF2,30637,GRP_SITE_DESC,SITE_DESC,Conventional irrigation method using multiple inlet in rice fields under annual rice-soybean rotation -US-OF2,30638,GRP_SITE_FUNDING,SITE_FUNDING,"USDA, Arkansas State University, University of Arkansas" -US-OF2,30639,GRP_STATE,STATE,AR -US-OF2,30641,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Michele L Reba -US-OF2,30641,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-OF2,30641,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,michele.reba@ars.usda.gov -US-OF2,30641,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"USDA, ARS, DELTA WATER MANAGEMENT RESEARCH UNIT" -US-OF2,30641,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"504 UNIVERSITY LOOP EAST, Jonesboro AR 72401" -US-OF2,30640,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Benjamin R.K. Runkle -US-OF2,30640,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,AncContact -US-OF2,30640,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,brrunkle@uark.edu -US-OF2,30640,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Arkansas -US-OF2,30640,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1 University of Arkansas, Engineering Hall 231, Fayetteville, AR 72701" -US-OF2,30644,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-OF2,30642,GRP_TOWER_TYPE,TOWER_TYPE,tripod -US-OF2,24000700,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-OF2 -US-OF2,30643,GRP_UTC_OFFSET,UTC_OFFSET,-6 -US-Oho,12788,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,USDA FS Southern Global Change Program (cooperative agreements 03-CA-11330147-073 and 04-CA-11330147-238) -US-Oho,12788,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT_COMMENT,"Tim Schetter, Karen Menard, Russ Maneval, and the Metroparks of the Toledo Area provide the access to the Oak Openings Preserve Park and offer logistical support." -US-Oho,24276,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER,9.6 -US-Oho,24276,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_ORGAN,Total -US-Oho,24276,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_PHEN,Mixed/unknown -US-Oho,24276,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_UNIT,kgDM m-2 -US-Oho,12789,GRP_CLIM_AVG,MAT,10.1 -US-Oho,12789,GRP_CLIM_AVG,MAP,849 -US-Oho,12789,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfa -US-Oho,27000411,GRP_COUNTRY,COUNTRY,USA -US-Oho,15721,GRP_DOI,DOI,10.17190/AMF/1246089 -US-Oho,15721,GRP_DOI,DOI_CITATION,"Jiquan Chen, Housen Chu, Asko Noormets (2021), AmeriFlux BASE US-Oho Oak Openings, Ver. 7-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1246089" -US-Oho,15721,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-Oho,88154,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Oho,88154,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Jiquan Chen -US-Oho,88154,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Oho,88154,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,1 -US-Oho,88154,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,jqchen@msu.edu -US-Oho,88154,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of Toledo / Michigan State University -US-Oho,88157,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Oho,88157,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Housen Chu -US-Oho,88157,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Oho,88157,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,2 -US-Oho,88157,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0002-8131-4938 -US-Oho,88153,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Oho,88153,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Asko Noormets -US-Oho,88153,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Oho,88153,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,3 -US-Oho,32158,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,University of Toledo / Michigan State University -US-Oho,32158,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-Oho,32157,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,USDA -US-Oho,32157,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-Oho,12811,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Drought -US-Oho,12805,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Storm or wind -US-Oho,12790,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Temperature extreme -US-Oho,12791,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Oho,12791,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-Oho,12791,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,2004 -US-Oho,12791,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,2013 -US-Oho,12791,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Oho,12812,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Oho,12812,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-Oho,12812,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,2004 -US-Oho,12812,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,2013 -US-Oho,12812,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Oho,12806,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Oho,12806,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-Oho,12806,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,2004 -US-Oho,12806,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,2013 -US-Oho,12806,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Oho,23000411,GRP_HEADER,SITE_NAME,Oak Openings -US-Oho,88200,GRP_HEIGHTC,HEIGHTC,24 -US-Oho,88200,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Oho,88200,GRP_HEIGHTC,HEIGHTC_DATE,20040701 -US-Oho,88200,GRP_HEIGHTC,HEIGHTC_DATE_UNC,30 -US-Oho,88201,GRP_HEIGHTC,HEIGHTC,24.5 -US-Oho,88201,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Oho,88201,GRP_HEIGHTC,HEIGHTC_DATE,20130701 -US-Oho,88201,GRP_HEIGHTC,HEIGHTC_DATE_UNC,30 -US-Oho,12792,GRP_IGBP,IGBP,DBF -US-Oho,23896,GRP_LAI,LAI_TYPE,LAI -US-Oho,23896,GRP_LAI,LAI_TOT,4 -US-Oho,23896,GRP_LAI,LAI_U,0.7 -US-Oho,12793,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-Oho,12793,GRP_LAND_OWNERSHIP,LAND_OWNER,The Meteroparks of Toledo Area -US-Oho,12794,GRP_LOCATION,LOCATION_LAT,41.5545 -US-Oho,12794,GRP_LOCATION,LOCATION_LONG,-83.8438 -US-Oho,12794,GRP_LOCATION,LOCATION_ELEV,230 -US-Oho,12794,GRP_LOCATION,LOCATION_COMMENT,The tower was constructed in Novemmber 2003 and continuous measurement began in 2004. -US-Oho,24795,GRP_NEP,NEP,600 -US-Oho,24795,GRP_NEP,NEP_COMMENT,(range 0.59-0.61) 2004: 0.61; 2005: 0.59 -US-Oho,12795,GRP_NETWORK,NETWORK,AmeriFlux -US-Oho,12807,GRP_NETWORK,NETWORK,USCCC -US-Oho,1700000408,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Baldocchi, D. D., Poindexter, C., Abraha, M., Desai, A. R., Bohrer, G., Arain, M. A., Griffis, T., Blanken, P. D., O'Halloran, T. L., Thomas, R. Q., Zhang, Q., Burns, S. P., Frank, J. M., Christian, D., Brown, S., Black, T. A., Gough, C. M., Law, B. E., Lee, X., Chen, J., Reed, D. E., Massman, W. J., Clark, K., Hatfield, J., Prueger, J., Bracho, R., Baker, J. M., Martin, T. A. (2018) Temporal Dynamics Of Aerodynamic Canopy Height Derived From Eddy Covariance Momentum Flux Data Across North American Flux Networks, Geophysical Research Letters, 45(2), 9275–9287" -US-Oho,1700000408,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018GL079306 -US-Oho,1700000408,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Oho,1700001767,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Baldocchi, D. D., Poindexter, C., Abraha, M., Desai, A. R., Bohrer, G., Arain, M. A., Griffis, T., Blanken, P. D., O'Halloran, T. L., Thomas, R. Q., Zhang, Q., Burns, S. P., Frank, J. M., Christian, D., Brown, S., Black, T. A., Gough, C. M., Law, B. E., Lee, X., Chen, J., Reed, D. E., Massman, W. J., Clark, K., Hatfield, J., Prueger, J., Bracho, R., Baker, J. M., Martin, T. A. (2018) Temporal Dynamics Of Aerodynamic Canopy Height Derived From Eddy Covariance Momentum Flux Data Across North American Flux Networks, Geophysical Research Letters, 45(3), 9275–9287" -US-Oho,1700001767,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018GL079306 -US-Oho,1700001767,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Oho,1700004911,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Chen, J., Gottgens, J. F., Desai, A. R., Ouyang, Z., Qian, S. S. (2016) Response And Biophysical Regulation Of Carbon Dioxide Fluxes To Climate Variability And Anomaly In Contrasting Ecosystems In Northwestern Ohio, Usa, Agricultural And Forest Meteorology, 220(2), 50-68" -US-Oho,1700004911,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2016.01.008 -US-Oho,1700004911,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Oho,1700008472,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Chen, J., Gottgens, J. F., Desai, A. R., Ouyang, Z., Qian, S. S. (2016) Response And Biophysical Regulation Of Carbon Dioxide Fluxes To Climate Variability And Anomaly In Contrasting Ecosystems In Northwestern Ohio, Usa, Agricultural And Forest Meteorology, 220(3), 50-68" -US-Oho,1700008472,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2016.01.008 -US-Oho,1700008472,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Oho,1700004011,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(11), 108350" -US-Oho,1700004011,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -US-Oho,1700004011,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Oho,1700006414,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"DeForest, J. L., Noormets, A., McNulty, S. G., Sun, G., Tenney, G., Chen, J. (2006) Phenophases Alter The Soil Respiration–Temperature Relationship In An Oak-Dominated Forest, International Journal Of Biometeorology, 51(2), 135-144" -US-Oho,1700006414,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1007/S00484-006-0046-7 -US-Oho,1700006414,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Oho,1700008289,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Noormets, A., McNulty, S. G., DeForest, J. L., Sun, G., Li, Q., Chen, J. (2008) Drought During Canopy Development Has Lasting Effect On Annual Carbon Balance In A Deciduous Temperate Forest, New Phytologist, 179(3), 818-828" -US-Oho,1700008289,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/J.1469-8137.2008.02501.X -US-Oho,1700008289,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Primary_Citation -US-Oho,1700007788,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Novick, K. A., Ficklin, D. L., Stoy, P. C., Williams, C. A., Bohrer, G., Oishi, A., Papuga, S. A., Blanken, P. D., Noormets, A., Sulman, B. N., Scott, R. L., Wang, L., Phillips, R. P. (2016) The Increasing Importance Of Atmospheric Demand For Ecosystem Water And Carbon Fluxes, Nature Climate Change, 6(11), 1023-1027" -US-Oho,1700007788,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1038/NCLIMATE3114 -US-Oho,1700007788,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Oho,1700006282,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Ouyang, Z., Chen, J., Becker, R., Chu, H., Xie, J., Shao, C., John, R. (2014) Disentangling The Confounding Effects Of PAR And Air Temperature On Net Ecosystem Exchange At Multiple Time Scales, Ecological Complexity, 19(), 46-58" -US-Oho,1700006282,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.ECOCOM.2014.04.005 -US-Oho,1700006282,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Oho,1700001149,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Xie, J., Chen, J., Sun, G., Chu, H., Noormets, A., Ouyang, Z., John, R., Wan, S., Guan, W. (2014) Long-Term Variability And Environmental Control Of The Carbon Cycle In An Oak-Dominated Temperate Forest, Forest Ecology And Management, 313(1), 319-328" -US-Oho,1700001149,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.FORECO.2013.10.032 -US-Oho,1700001149,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Oho,1700000927,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Xie, J., Chen, J., Sun, G., Zha, T., Yang, B., Chu, H., Liu, J., Wan, S., Zhou, C., Ma, H., Bourque, C. P., Shao, C., John, R., Ouyang, Z. (2016) Ten-Year Variability In Ecosystem Water Use Efficiency In An Oak-Dominated Temperate Forest Under A Warming Climate, Agricultural And Forest Meteorology, 218-219(3), 209-217" -US-Oho,1700000927,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2015.12.059 -US-Oho,1700000927,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Oho,1700003348,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Xie, J., Sun, G., Chu, H., Liu, J., McNulty, S. G., Noormets, A., John, R., Ouyang, Z., Zha, T., Li, H., Guan, W., Chen, J. (2014) Long-Term Variability In The Water Budget And Its Controls In An Oak-Dominated Temperate Forest, Hydrological Processes, 28(25), 6054-6066" -US-Oho,1700003348,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/HYP.10079 -US-Oho,1700003348,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Oho,1700002604,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Xu, B., Arain, M. A., Black, T. A., Law, B. E., Pastorello, G. Z., Chu, H. (2020) Seasonal Variability Of Forest Sensitivity To Heat And Drought Stresses: A Synthesis Based On Carbon Fluxes From North American Forest Ecosystems, Global Change Biology, 26(2), 901-918" -US-Oho,1700002604,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/GCB.14843 -US-Oho,1700002604,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Oho,5038,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"The research and science objectives of the Ohio Oak Openings site are as follows: 1) Quantify and partition the effect of a moderate drought on the carbon balance of a temperate forest; 2) Determine the magnitudes and dynamics of Estimate Litter Respiration, Mineral Soil Respiration, and Soil Respiration (total) through manipulations of litter horizon in an oak-dominated forest; 3) Determine the relative importance of temperature and moisture mediating Mineral Soil Respiration and Estimate Litter Respiration; 4) Investigate how this mediation changes seasonally as determined by plant phenophases; 5) Account for the seasonal environmental changes in the regulation in Soil Respiration. (DeForest et al., 2009, Noormets et al., 2008, DeForest et al., 2006)" -US-Oho,25076,GRP_SA,SA,46 -US-Oho,12809,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"202 Manly Miles Bldg. 1405 South Harrison Road Michigan State University, East Lansing, MI 48823" -US-Oho,12797,GRP_SITE_CHAR,TERRAIN,Flat -US-Oho,12797,GRP_SITE_CHAR,ASPECT,FLAT -US-Oho,12797,GRP_SITE_CHAR,WIND_DIRECTION,WNW -US-Oho,12797,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,600 -US-Oho,12797,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,60 -US-Oho,12798,GRP_SITE_DESC,SITE_DESC,"The Ohio Oak Openings site is located within the Oak Openings Preserve Metropark of northwest Ohio, one of the few remaining oak woodlands/savanna/prairie complexes in the Midwest. Declared one of the ""One of America's Last Great Places"" by the Nature Conservancy the area consists of four main vegetation types: Oak Woodlands, Oak Savanna, Floodplain Forests and Wet Prairies. The stand surrounding the tower is mainly Oak Woodlands dominated by red, white and black oaks with a relatively abundant population of red maples indicating high soil moisture retention and a history of limited fire disturbances. Most of the area was cleared for agriculture at the time of Euro-American settlements in the mid to late-19th century. A large fraction of the cleared land was later abandoned due to the poor sandy soils. These areas reverted to Oak Savannas and in cases where fire was limited progressively made the transition to Oak Woodlands. Today patches of the forest are burned every few years as part of prescribed burning cycle to control stand density." -US-Oho,12799,GRP_SITE_FUNDING,SITE_FUNDING,USDA -US-Oho,24565,GRP_SOIL_CHEM,SOIL_CHEM_C_ORG,28.1 -US-Oho,24565,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,A -US-Oho,24565,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,Soil C 28.1 g C kg-1 (0-20cm) in DeForest et al 2006. International Journal of Biometeorology. 51:135-144. -US-Oho,28093,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION,"Sandy mixed, mesic, Spodic Udipsamments" -US-Oho,28093,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION_TAXONOMY,Other -US-Oho,24682,GRP_SPP_O,SPP_O,"Quercus rubra, Q. alba, Acer rubrum" -US-Oho,24682,GRP_SPP_O,SPP_COMMENT,"Q. rubra (red oak; 32%), Q. alba (white oak; 27%), Q. velutina (black oak; 14%), Acer rubra (red maple; 20%) in the understory with the remaining 7% Prunus serotina (black cherry) and Sassafras albidum (sassafras) DeForest et al 2006. Phenophases in an oak-dominated forest alter the soil respiration-temperature relationship. International Journal of Biometeorology. 51:135-144." -US-Oho,12800,GRP_STATE,STATE,OH -US-Oho,12810,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Jiquan Chen -US-Oho,12810,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Oho,12810,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,jqchen@msu.edu -US-Oho,12810,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Toledo / Michigan State University -US-Oho,12810,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"202 Manly Miles Bldg. 1405 South Harrison Road Michigan State University, East Lansing, MI 48823" -US-Oho,95523,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Housen Chu -US-Oho,95523,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-Oho,95523,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,chu.housen@gmail.com -US-Oho,95523,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Lawrence Berkeley National Lab -US-Oho,31202,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Asko Noormets -US-Oho,31202,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Affiliate -US-Oho,31202,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,noormets@tamu.edu -US-Oho,31202,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Texas A&M University -US-Oho,29829,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-Oho,12802,GRP_TOWER_TYPE,TOWER_TYPE,walk-up -US-Oho,12803,GRP_URL,URL,http://lees.geo.msu.edu/index.html -US-Oho,24000411,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-Oho -US-Oho,12804,GRP_UTC_OFFSET,UTC_OFFSET,-5 -US-ONA,90616,GRP_CLIM_AVG,MAT,22.3 -US-ONA,90616,GRP_CLIM_AVG,MAP,1268 -US-ONA,90616,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Cfa -US-ONA,27001114,GRP_COUNTRY,COUNTRY,USA -US-ONA,93759,GRP_DOI,DOI,10.17190/AMF/1660350 -US-ONA,93759,GRP_DOI,DOI_CITATION,"Maria Silveira (2022), AmeriFlux BASE US-ONA Florida pine flatwoods, Ver. 3-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1660350" -US-ONA,93759,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-ONA,93706,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-ONA,93706,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Maria Silveira -US-ONA,93706,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-ONA,93706,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,mlas@ufl.edu -US-ONA,93706,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"Range Cattle Research and Education Center, IFAS/UF" -US-ONA,93733,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,"Range Cattle Research and Education Center, IFAS/UF" -US-ONA,93733,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-ONA,93724,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,"University of Florida, USDA" -US-ONA,93724,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-ONA,90609,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Fire -US-ONA,90613,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Grazing -US-ONA,90626,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Hydrologic event -US-ONA,90627,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Storm or wind -US-ONA,90615,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-ONA,90615,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-ONA,90615,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201603301758 -US-ONA,90615,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-ONA,92268,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-ONA,92268,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-ONA,92268,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201603301800 -US-ONA,92268,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-ONA,23001114,GRP_HEADER,SITE_NAME,Florida pine flatwoods -US-ONA,90608,GRP_IGBP,IGBP,GRA -US-ONA,90608,GRP_IGBP,IGBP_COMMENT,Native vegetation. Naturally introduced. -US-ONA,90612,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-ONA,90612,GRP_LAND_OWNERSHIP,LAND_OWNER,"Institute of Food and Agricultural Sciences, University of Florida" -US-ONA,90621,GRP_LOCATION,LOCATION_LAT,27.3836 -US-ONA,90621,GRP_LOCATION,LOCATION_LONG,-81.9509 -US-ONA,90621,GRP_LOCATION,LOCATION_ELEV,25 -US-ONA,90621,GRP_LOCATION,LOCATION_DATE_START,201603301758 -US-ONA,90607,GRP_NETWORK,NETWORK,AmeriFlux -US-ONA,90623,GRP_NETWORK,NETWORK,LTAR -US-ONA,90617,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,Effect of fire frequency on soil-plant-animal-environment system -US-ONA,90611,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"3401, Experiment Station, Ona, FL, 33865" -US-ONA,90614,GRP_SITE_CHAR,TERRAIN,Gentle slope (<2 %) -US-ONA,90614,GRP_SITE_CHAR,ASPECT,FLAT -US-ONA,90614,GRP_SITE_CHAR,WIND_DIRECTION,NE -US-ONA,90614,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,300 -US-ONA,90614,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,0 -US-ONA,90620,GRP_SITE_DESC,SITE_DESC,"Florida Pine flatwoods, continuously with native pastures. Soils are predominantly Spodosols, subject to periodic flooding." -US-ONA,90624,GRP_SITE_FUNDING,SITE_FUNDING,"University of Florida, USDA" -US-ONA,90619,GRP_STATE,STATE,FL -US-ONA,90625,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Maria Silveira -US-ONA,90625,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-ONA,90625,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,mlas@ufl.edu -US-ONA,90625,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"Range Cattle Research and Education Center, IFAS/UF" -US-ONA,90625,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"3401, Experiment Station, Ona, FL, 33865" -US-ONA,94186,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Joao Marcelo Dalmazo Sanchez -US-ONA,94186,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Affiliate -US-ONA,94186,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,joaomdsanchez@ufl.edu -US-ONA,94186,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"Range Cattle Research and Education Center, IFAS/UF" -US-ONA,94186,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"3401, Experiment station, Ona, FL, 33865" -US-ONA,94201,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Rosvel Bracho -US-ONA,94201,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Affiliate -US-ONA,94201,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,rbracho@ufl.edu -US-ONA,94201,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"School of Forest Resources and Conservation, IFAS/UF" -US-ONA,94201,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"223 Newins-Ziegler Hall, Gainesville, FL 32611-0410" -US-ONA,90610,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-ONA,90618,GRP_TOWER_TYPE,TOWER_TYPE,tripod -US-ONA,24001114,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-ONA -US-ONA,90628,GRP_UTC_OFFSET,UTC_OFFSET,-5 -US-ORv,11215,GRP_CLIM_AVG,MAT,11.63 -US-ORv,11215,GRP_CLIM_AVG,MAP,1499.1 -US-ORv,11215,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Cfa -US-ORv,27000501,GRP_COUNTRY,COUNTRY,USA -US-ORv,16130,GRP_DM_GENERAL,DM_GENERAL,Other -US-ORv,16130,GRP_DM_GENERAL,DM_SURF,100 -US-ORv,16130,GRP_DM_GENERAL,DM_SURF_MEAS_UNC,100 -US-ORv,16130,GRP_DM_GENERAL,DM_DATE_START,1993 -US-ORv,16130,GRP_DM_GENERAL,DM_DATE_END,1994 -US-ORv,16130,GRP_DM_GENERAL,DM_COMMENT,Wetland park was created and 2 experimental wetlands flooded. Vegetation in the western experimental wetland was planted with ndigenous species. -US-ORv,16131,GRP_DM_PLANTING,DM_PLANTING,Planting live grasses -US-ORv,16131,GRP_DM_PLANTING,DM_SURF,100 -US-ORv,16131,GRP_DM_PLANTING,DM_SURF_MEAS_UNC,100 -US-ORv,16131,GRP_DM_PLANTING,DM_DATE_START,1993 -US-ORv,16131,GRP_DM_PLANTING,DM_DATE_END,1994 -US-ORv,16131,GRP_DM_PLANTING,DM_COMMENT,Wetland park was created and 2 experimental wetlands flooded. Vegetation in the western experimental wetland was planted with ndigenous species. -US-ORv,16132,GRP_DM_WATER,DM_WATER,Human induced flooding -US-ORv,16132,GRP_DM_WATER,DM_SURF,100 -US-ORv,16132,GRP_DM_WATER,DM_SURF_MEAS_UNC,100 -US-ORv,16132,GRP_DM_WATER,DM_DATE_START,1993 -US-ORv,16132,GRP_DM_WATER,DM_DATE_END,1994 -US-ORv,16132,GRP_DM_WATER,DM_COMMENT,Wetland park was created and 2 experimental wetlands flooded. Vegetation in the western experimental wetland was planted with ndigenous species. -US-ORv,15652,GRP_DOI,DOI,10.17190/AMF/1246135 -US-ORv,15652,GRP_DOI,DOI_CITATION,"Gil Bohrer (2020), AmeriFlux BASE US-ORv Olentangy River Wetland Research Park, Ver. 3-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1246135" -US-ORv,15652,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-ORv,32313,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-ORv,32313,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Gil Bohrer -US-ORv,32313,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-ORv,32313,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,bohrer.17@osu.edu -US-ORv,32313,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,The Ohio State University -US-ORv,32315,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,The Ohio State University -US-ORv,32315,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-ORv,32314,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,"NSF, The Ohio State University, USGS, Ohio Water Development Authority" -US-ORv,32314,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-ORv,83622,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-ORv,83622,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-ORv,83622,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201104 -US-ORv,83622,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20161030 -US-ORv,83622,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-ORv,83623,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-ORv,83623,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CH4 -US-ORv,83623,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201104 -US-ORv,83623,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20161030 -US-ORv,83623,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-ORv,23000501,GRP_HEADER,SITE_NAME,Olentangy River Wetland Research Park -US-ORv,88198,GRP_HEIGHTC,HEIGHTC,8 -US-ORv,88198,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-ORv,88198,GRP_HEIGHTC,HEIGHTC_DATE,20120401 -US-ORv,88198,GRP_HEIGHTC,HEIGHTC_COMMENT,Canopy ht estimated from flux tower. No replicates. -US-ORv,11217,GRP_IGBP,IGBP,WET -US-ORv,11217,GRP_IGBP,IGBP_DATE_START,1994 -US-ORv,11218,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-ORv,11218,GRP_LAND_OWNERSHIP,LAND_OWNER,The Ohio State University -US-ORv,11219,GRP_LOCATION,LOCATION_LAT,40.0201 -US-ORv,11219,GRP_LOCATION,LOCATION_LONG,-83.0183 -US-ORv,11219,GRP_LOCATION,LOCATION_ELEV,221 -US-ORv,11219,GRP_LOCATION,LOCATION_COMMENT,Confirmed by Gil Bohrer -US-ORv,11220,GRP_NETWORK,NETWORK,AmeriFlux -US-ORv,1700007218,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Brooker, M. R., Bohrer, G., Mouser, P. J. (2014) Variations In Potential Ch4 Flux And Co2 Respiration From Freshwater Wetland Sediments That Differ By Microsite Location, Depth And Temperature, Ecological Engineering, 72(8), 84-94" -US-ORv,1700007218,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.ECOLENG.2014.05.028 -US-ORv,1700007218,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-ORv,1700003012,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(8), 108350" -US-ORv,1700003012,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -US-ORv,1700003012,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-ORv,1700002343,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Mitsch, W. J., Zhang, L., Stefanik, K. C., Nahlik, A. M., Anderson, C. J., Bernal, B., Hernandez, M., Song, K. (2012) Creating Wetlands: Primary Succession, Water Quality Changes, And Self-Design Over 15 Years, Bioscience, 62(3), 237-250" -US-ORv,1700002343,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1525/BIO.2012.62.3.5 -US-ORv,1700002343,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-ORv,1700001773,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Morin, T.H. Bohrer, G. Frasson, R.P.dM. Naor-Azrieli, L. Mesi, S. Stefanik, K.C. Schäfer, K.V.R. (2014) Environmental drivers of methane fluxes from an urban temperate wetland park, Journal of Geophysical Research-Biogeosciences, 119(), 2188-2208" -US-ORv,1700001773,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/2014JG002750 -US-ORv,1700001773,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-ORv,1700004056,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Morin, T.H. Bohrer, G. Naor-Azrieli, L. Mesi, S. Kenny, W.T. Mitsch, W.J. Schäfer, K.V.R. (2014) The seasonal and diurnal dynamics of methane flux at a created urban wetland, Ecological Engineering, 72(), 74-83" -US-ORv,1700004056,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.ECOLENG.2014.02.002 -US-ORv,1700004056,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-ORv,1700006201,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Morin, T.H., Bohrer, G., Stefanik, K.C., Rey-Sanchez, A.C., Matheny, A.M., Mitsch, W.J. (2017) Combining eddy-covariance and chamber measurements to determine the methane budget from a small, heterogeneous urban floodplain wetland park, Agricultural and Forest Meteorology, 301-302(8), 108350" -US-ORv,1700006201,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-ORv,1700004593,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Morin, T.H., Bohrer, G., Stefanik, K.C., Rey-Sanchez, A.C., Matheny, A.M., Mitsch, W.J. (2017) Combining eddy-covariance and chamber measurements to determine the methane budget from a small, heterogeneous urban floodplain wetland park, Agricultural and Forest Meteorology, 62(3), 237-250" -US-ORv,1700004593,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-ORv,1700008589,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Sullivan, R. C., Cook, D. R., Ghate, V. P., Kotamarthi, V. R., Feng, Y. (2019) Improved Spatiotemporal Representativeness And Bias Reduction Of Satellite-Based Evapotranspiration Retrievals Via Use Of In Situ Meteorology And Constrained Canopy Surface Resistance, Journal Of Geophysical Research: Biogeosciences, 124(2), 342-352" -US-ORv,1700008589,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018JG004744 -US-ORv,1700008589,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-ORv,1700004761,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Sullivan, R. C., Kotamarthi, V. R., Feng, Y. (2019) Recovering Evapotranspiration Trends From Biased CMIP5 Simulations And Sensitivity To Changing Climate Over North America, Journal Of Hydrometeorology, 20(8), 1619-1633" -US-ORv,1700004761,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1175/JHM-D-18-0259.1 -US-ORv,1700004761,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-ORv,11222,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"The research objectives of the Wilma H. Schiermeier Olentangy River Wetland Research Park site are to understand: 1) how wetlands function, and 2) if and how we can create and restore wetlands." -US-ORv,11223,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"417E Hitchcock Hall, 2070 neil Ave. Columbus, OH, 43210" -US-ORv,11224,GRP_SITE_CHAR,TERRAIN,Flat -US-ORv,11224,GRP_SITE_CHAR,ASPECT,FLAT -US-ORv,11224,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,15 -US-ORv,11225,GRP_SITE_DESC,SITE_DESC,"The ORWRP site is a 21-ha large-scale, long-term wetland campus facility that is owned by Ohio State University. It is designed to provide teaching, research, and service related to wetland and river science and ecological engineering. The site has been developed in several phases: Phase 1 (1992 - 1994) - Construction of two 2.5-acre deepwater marshes and a river water delivery system began, with pumps installed on the floodplain to bring water from the Olentangy River. In May 1994, one wetland was planted with marsh vegetation, while the other remained as an unplanted control; Phase 2 (1994 - 1999) - Development of a research and teaching infrastructure took place with the construction of boardwalks, a pavilion, and a compound. The creation of the 7-acre naturally flooded oxbow was also included; Phase 3 (2000 - 2003) - As a research building was created, three additional wetlands were created in the vicinity of the building, including a stormwater wetland that receives runoff from the roof of the building; Phase 4 - The current phase involves research access to the Olentangy River." -US-ORv,11226,GRP_SITE_FUNDING,SITE_FUNDING,"NSF, The Ohio State University, USGS, Ohio Water Development Authority" -US-ORv,11227,GRP_STATE,STATE,OH -US-ORv,11228,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Gil Bohrer -US-ORv,11228,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-ORv,11228,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,bohrer.17@osu.edu -US-ORv,11228,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,The Ohio State University -US-ORv,11228,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"417E Hitchcock Hall, 2070 neil Ave. Columbus, OH, 43210" -US-ORv,95857,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Justine Missik -US-ORv,95857,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,DataManager -US-ORv,95857,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,missik.2@osu.edu -US-ORv,95857,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Ohio State University -US-ORv,95857,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"2070 Neil Ave., Columbus, OH, 43210" -US-ORv,86425,GRP_TOWER_POWER,TOWER_POWER,Direct power -US-ORv,83624,GRP_URL,URL,http://flux.org.ohio-state.edu/ -US-ORv,24000501,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-ORv -US-ORv,11230,GRP_UTC_OFFSET,UTC_OFFSET,-5 -US-OWC,85897,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,NOAA National Estuarine Research Reserve System (NERRS). System-wide Monitoring Program. Data accessed from the NOAA NERRS Centralized Data Management Office website: http://www.nerrsdata.org/ -US-OWC,85897,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT_COMMENT,"Additional to the Ameriflux acknowledgement. Use http://www.nerrsdata.org/ for additional met data for this site, not available through Ameriflux." -US-OWC,91715,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,Ohio Department of Natural Resources -US-OWC,14788,GRP_CLIM_AVG,MAT,10.7 -US-OWC,14788,GRP_CLIM_AVG,MAP,930 -US-OWC,14788,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfb -US-OWC,27000663,GRP_COUNTRY,COUNTRY,USA -US-OWC,79337,GRP_DOI,DOI,10.17190/AMF/1418679 -US-OWC,79337,GRP_DOI,DOI_CITATION,"Gil Bohrer, Janice Kerns (2018), AmeriFlux BASE US-OWC Old Woman Creek, Ver. 2-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1418679" -US-OWC,79337,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-OWC,33727,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-OWC,33727,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Gil Bohrer -US-OWC,33727,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-OWC,33727,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,bohrer.17@osu.edu -US-OWC,33727,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,The Ohio State University -US-OWC,91718,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-OWC,91718,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Janice Kerns -US-OWC,91718,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-OWC,91718,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"Old Woman Creek National Estuarine Research reserve, Ohio Department of Natural Resources" -US-OWC,91718,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,20200101 -US-OWC,91716,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Old Woman Creek National Estuarine Research Reserve -US-OWC,91716,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-OWC,33728,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,The Ohio State University -US-OWC,33728,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-OWC,85896,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Hydrologic event -US-OWC,91407,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-OWC,91407,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-OWC,91407,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20150717 -US-OWC,91407,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,201610 -US-OWC,91407,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Growing season operation only -US-OWC,91417,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-OWC,91417,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CH4 -US-OWC,91417,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20150717 -US-OWC,91417,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,201610 -US-OWC,91417,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Growing season operation only -US-OWC,91303,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-OWC,91303,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-OWC,91303,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20150717 -US-OWC,91303,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,201610 -US-OWC,91303,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Growing season operation only -US-OWC,91396,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-OWC,91396,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-OWC,91396,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20150717 -US-OWC,91396,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,201610 -US-OWC,91396,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Growing season operation only -US-OWC,91340,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-OWC,91340,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-OWC,91340,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201906 -US-OWC,91340,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-OWC,91320,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-OWC,91320,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CH4 -US-OWC,91320,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201906 -US-OWC,91320,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-OWC,91366,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-OWC,91366,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-OWC,91366,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201906 -US-OWC,91366,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-OWC,91355,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-OWC,91355,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-OWC,91355,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201906 -US-OWC,91355,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-OWC,23000663,GRP_HEADER,SITE_NAME,Old Woman Creek -US-OWC,14790,GRP_IGBP,IGBP,WET -US-OWC,14790,GRP_IGBP,IGBP_COMMENT,"Typha spp., Nelumbo spp., and Phragmites Australis are dominant plant types" -US-OWC,14791,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-OWC,14791,GRP_LAND_OWNERSHIP,LAND_OWNER,"Managed as a cooperative partnership between NOAA and the Ohio Department of Natural Resources, Division of Wildlife" -US-OWC,14792,GRP_LOCATION,LOCATION_LAT,41.3795 -US-OWC,14792,GRP_LOCATION,LOCATION_LONG,-82.5125 -US-OWC,14792,GRP_LOCATION,LOCATION_ELEV,174 -US-OWC,14792,GRP_LOCATION,LOCATION_DATE_START,20150510 -US-OWC,14793,GRP_NETWORK,NETWORK,AmeriFlux -US-OWC,1700004692,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Angle, J. C., Morin, T. H., Solden, L. M., Narrowe, A. B., Smith, G. J., Borton, M. A., Rey-Sanchez, C., Daly, R. A., Mirfenderesgi, G., Hoyt, D. W., Riley, W. J., Miller, C. S., Bohrer, G., Wrighton, K. C. (2017) Methanogenesis In Oxygenated Soils Is A Substantial Fraction Of Wetland Methane Emissions, Nature Communications, 8(1), 1567" -US-OWC,1700004692,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1038/S41467-017-01753-4 -US-OWC,1700004692,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-OWC,1700008043,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Bohrer, G., Ju, Y., Arend, K., Morin, T., Rey-Sanchez, C., Wrighton, K., Villa, J. (2019) Methane And CO2 Chamber Fluxes And Porewater Concentrations Us-OWC Ameriflux Wetland Site, 2015-2018, ESS-DiVE, 767(7), 144498" -US-OWC,1700008043,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.15485/1568865 -US-OWC,1700008043,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-OWC,1700001137,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Rey-Sanchez, A., Morin, T., Stefanik, K., Wrighton, K., Bohrer, G. (2017) Determining Total Emissions And Environmental Drivers Of Methane Flux In A Lake Erie Estuarine Marsh, Ecological Engineering, in press(1), 1567" -US-OWC,1700001137,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.ECOLENG.2017.06.042 -US-OWC,1700001137,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Primary_Citation -US-OWC,1700002175,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Smith, G. J., Angle, J. C., Solden, L. M., Borton, M. A., Morin, T. H., Daly, R. A., Johnston, M. D., Stefanik, K. C., Wolfe, R., Bohrer, G., Wrighton, K. C. (2018) Members of the genus Methylobacter are inferred to account for the majority of aerobic methane oxidation in oxic soils from a freshwater wetland, mBio, 9(6), e00815-18" -US-OWC,1700002175,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-OWC,1700007671,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Villa, J. A., Ju, Y., Stephen, T., Rey‐Sanchez, C., Wrighton, K. C., Bohrer, G. (2020) Plant‐Mediated Methane Transport In Emergent And Floating‐Leaved Species Of A Temperate Freshwater Mineral‐Soil Wetland, Limnology And Oceanography, 65(7), 1635-1650" -US-OWC,1700007671,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/LNO.11467 -US-OWC,1700007671,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-OWC,1700008493,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Villa, J. A., Ju, Y., Yazbeck, T., Waldo, S., Wrighton, K. C., Bohrer, G. (2021) Ebullition Dominates Methane Fluxes From The Water Surface Across Different Ecohydrological Patches In A Temperate Freshwater Marsh At The End Of The Growing Season, Science Of The Total Environment, 767(7), 144498" -US-OWC,1700008493,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.SCITOTENV.2020.144498 -US-OWC,1700008493,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-OWC,1700001881,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Villa, J., Ju, Y., Vines, C., Rey-Sanchez, C., Morin, T.H., Wrighton, K.C., Bohrer, G. (2019) Relationships Between Methane and Carbon Dioxide Fluxes in a Temperate Cattail‐Dominated Freshwater Wetland, Journal of Geophysical Research-Biogeosciences, 124(7), 2076-2089" -US-OWC,1700001881,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2019JG005167 -US-OWC,1700001881,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-OWC,14794,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,Coupling methane formation and transport with microbial data. -US-OWC,14795,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"470 Hitchcock Hall, 2070 Neil Avenue, Columbus, OH 43210" -US-OWC,85894,GRP_SITE_CHAR,TERRAIN,Flat -US-OWC,85894,GRP_SITE_CHAR,ASPECT,FLAT -US-OWC,85894,GRP_SITE_CHAR,WIND_DIRECTION,SW -US-OWC,85894,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,10 -US-OWC,95032,GRP_SITE_DESC,SITE_DESC,"Old Woman Creek is a natural freshwater estuary connected to Lake Erie in northern Ohio. It is one of few natuaral estuary systems left in Ohio. The site is permanently flooded and contains a mixture of wetland vegetation, open water, and mud flats. -VIrtual Site Visit: https://youtu.be/Tju8nc8J3H0" -US-OWC,98543,GRP_SITE_FUNDING,SITE_FUNDING,NOAA/NERR/DoE/ODNR/OWDA/OWRC -US-OWC,14798,GRP_STATE,STATE,OH -US-OWC,14799,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Gil Bohrer -US-OWC,14799,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-OWC,14799,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,bohrer.17@osu.edu -US-OWC,14799,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,The Ohio State University -US-OWC,14799,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"470 Hitchcock Hall, 2070 Neil Avenue, Columbus, OH 43210" -US-OWC,91714,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Janice Kerns -US-OWC,91714,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,AncContact -US-OWC,91714,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,Janice.Kerns@dnr.state.oh.us -US-OWC,91714,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"Old Woman Creek National Estuarine Research Reserve, Ohio Department of Natural Resources" -US-OWC,91714,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"2514 Cleveland Rd East -Huron, OH 44839" -US-OWC,95899,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Justine Missik -US-OWC,95899,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,DataManager -US-OWC,95899,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,missik.2@osu.edu -US-OWC,95899,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Ohio State University -US-OWC,95899,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"2070 Neil Ave., Columbus, OH, 43210" -US-OWC,29914,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-OWC,14800,GRP_TOWER_TYPE,TOWER_TYPE,triangle -US-OWC,85895,GRP_URL,URL,http://coastal.ohiodnr.gov/oldwomancreek -US-OWC,24000663,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-OWC -US-OWC,14801,GRP_UTC_OFFSET,UTC_OFFSET,-5 -US-PAS,98892,GRP_CLIM_AVG,MAT,22.3 -US-PAS,98892,GRP_CLIM_AVG,MAP,1268 -US-PAS,98892,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Cfa -US-PAS,27001217,GRP_COUNTRY,COUNTRY,USA -US-PAS,100770,GRP_DOI,DOI,10.17190/AMF/1870590 -US-PAS,100770,GRP_DOI,DOI_CITATION,"Maria Lucia Silveira, Rosvel Bracho (2022), AmeriFlux BASE US-PAS Florida, Paspalum notatum pasture, Ver. 1-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1870590" -US-PAS,100770,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-PAS,100758,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-PAS,100758,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Maria Lucia Silveira -US-PAS,100758,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-PAS,100758,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,mlas@ufl.edu -US-PAS,100758,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of Florida -US-PAS,100755,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-PAS,100755,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Rosvel Bracho -US-PAS,100755,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-PAS,100755,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,rbracho@ufl.edu -US-PAS,100755,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of Florida -US-PAS,100767,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,University of Florida -US-PAS,100767,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-PAS,100759,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,"University of Florida, USDA" -US-PAS,100759,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-PAS,98902,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Agriculture -US-PAS,98896,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Grazing -US-PAS,98905,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-PAS,98905,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-PAS,98905,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,202102101830 -US-PAS,98905,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-PAS,98903,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-PAS,98903,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-PAS,98903,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,202102101830 -US-PAS,98903,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-PAS,98899,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-PAS,98899,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,Other -US-PAS,98899,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,202102101830 -US-PAS,98899,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-PAS,98899,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,LE measurement -US-PAS,98887,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-PAS,98887,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CH4 -US-PAS,98887,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,202107141330 -US-PAS,98887,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-PAS,23001217,GRP_HEADER,SITE_NAME,"Florida, Paspalum notatum pasture" -US-PAS,98895,GRP_IGBP,IGBP,GRA -US-PAS,98895,GRP_IGBP,IGBP_COMMENT,"Paspalum notatum, cultivated grass pasture" -US-PAS,98897,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-PAS,98897,GRP_LAND_OWNERSHIP,LAND_OWNER,"Institute of Food and Agricultural Sciences, University of Florida" -US-PAS,98888,GRP_LOCATION,LOCATION_LAT,27.3944 -US-PAS,98888,GRP_LOCATION,LOCATION_LONG,-81.9510 -US-PAS,98888,GRP_LOCATION,LOCATION_ELEV,27.1 -US-PAS,98888,GRP_LOCATION,LOCATION_DATE_START,202102101830 -US-PAS,98891,GRP_NETWORK,NETWORK,AmeriFlux -US-PAS,98885,GRP_NETWORK,NETWORK,LTAR -US-PAS,98907,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,Effects of grazing on soil-plant-animal-atmosphere continuum -US-PAS,98894,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"3401, Experiment Station, Ona, FL, 33865" -US-PAS,98884,GRP_SITE_CHAR,TERRAIN,Gentle slope (<2 %) -US-PAS,98884,GRP_SITE_CHAR,ASPECT,FLAT -US-PAS,98884,GRP_SITE_CHAR,WIND_DIRECTION,NE -US-PAS,98884,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,300 -US-PAS,98884,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,0 -US-PAS,98901,GRP_SITE_DESC,SITE_DESC,"Florida cultivated grass (Paspalum notatum) pasture rotationally stocked year-round. Soils are predominatly spodosols, subject to periodoc flooding." -US-PAS,98893,GRP_SITE_FUNDING,SITE_FUNDING,"University of Florida, USDA" -US-PAS,98900,GRP_STATE,STATE,FL -US-PAS,98889,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Maria Lucia Silveira -US-PAS,98889,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-PAS,98889,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,mlas@ufl.edu -US-PAS,98889,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Florida -US-PAS,98889,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"3401, Experiment Station, Ona, FL, 33865" -US-PAS,98898,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Rosvel Bracho -US-PAS,98898,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-PAS,98898,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,rbracho@ufl.edu -US-PAS,98898,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Florida -US-PAS,98898,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"223 Newins-Ziegler Hall, Gainesville, FL 32611-0410" -US-PAS,98906,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Abmael da Silva Cardoso -US-PAS,98906,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Affiliate -US-PAS,98906,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,adasilvacardoso@ufl.edu -US-PAS,98890,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-PAS,98904,GRP_TOWER_TYPE,TOWER_TYPE,triangle -US-PAS,98886,GRP_URL,URL,https://ltar.ars.usda.gov/ -US-PAS,24001217,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-PAS -US-PAS,98908,GRP_UTC_OFFSET,UTC_OFFSET,-5 -US-PFa,27578,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,100.7 -US-PFa,27578,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Foliage -US-PFa,27578,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-PFa,27578,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-PFa,27578,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,1998 -US-PFa,27578,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,annual average leaf litterfall 1998-2000= 100.7 (P. Bolstad) -US-PFa,29034,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,100.7 -US-PFa,29034,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Foliage -US-PFa,29034,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-PFa,29034,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-PFa,29034,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,1999 -US-PFa,29034,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,annual average leaf litterfall 1998-2000= 100.7 (P. Bolstad) -US-PFa,29143,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,100.7 -US-PFa,29143,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Foliage -US-PFa,29143,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-PFa,29143,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-PFa,29143,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2000 -US-PFa,29143,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,annual average leaf litterfall 1998-2000= 100.7 (P. Bolstad) -US-PFa,27022,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,1452 -US-PFa,27022,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Wood -US-PFa,27022,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-PFa,27022,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-PFa,27022,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,Live Aboveground Woody BioMass; www.cheas.psu.edu/data/cheas/biometry -US-PFa,27022,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2004 -US-PFa,27022,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,2004/2006 average from summer sampling; Upland Conifer (Ryan Anderson) -US-PFa,28212,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,1452 -US-PFa,28212,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Wood -US-PFa,28212,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-PFa,28212,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-PFa,28212,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,Live Aboveground Woody BioMass; www.cheas.psu.edu/data/cheas/biometry -US-PFa,28212,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2004 -US-PFa,28212,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,"branch biomass P. Bolstad, Taken at Willow Creek" -US-PFa,28306,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,1452 -US-PFa,28306,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Wood -US-PFa,28306,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-PFa,28306,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-PFa,28306,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,Live Aboveground Woody BioMass; www.cheas.psu.edu/data/cheas/biometry -US-PFa,28306,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2005 -US-PFa,28306,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,2004/2006 average from summer sampling; Upland Conifer (Ryan Anderson) -US-PFa,29036,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,1452 -US-PFa,29036,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Wood -US-PFa,29036,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-PFa,29036,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-PFa,29036,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,Live Aboveground Woody BioMass; www.cheas.psu.edu/data/cheas/biometry -US-PFa,29036,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2006 -US-PFa,29036,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,2004/2006 average from summer sampling; Upland Conifer (Ryan Anderson) -US-PFa,27580,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,1795 -US-PFa,27580,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Wood -US-PFa,27580,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-PFa,27580,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-PFa,27580,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,Live Aboveground Woody BioMass; www.cheas.psu.edu/data/cheas/biometry -US-PFa,27580,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2005 -US-PFa,27580,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,2004/2006 average from summer sampling; Alder (Ryan Anderson) -US-PFa,28548,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,1795 -US-PFa,28548,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Wood -US-PFa,28548,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-PFa,28548,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-PFa,28548,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,Live Aboveground Woody BioMass; www.cheas.psu.edu/data/cheas/biometry -US-PFa,28548,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2006 -US-PFa,28548,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,2004/2006 average from summer sampling; Alder (Ryan Anderson) -US-PFa,29145,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,1795 -US-PFa,29145,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Wood -US-PFa,29145,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-PFa,29145,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-PFa,29145,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,Live Aboveground Woody BioMass; www.cheas.psu.edu/data/cheas/biometry -US-PFa,29145,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2004 -US-PFa,29145,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,2004/2006 average from summer sampling; Alder (Ryan Anderson) -US-PFa,26736,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,2354 -US-PFa,26736,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Wood -US-PFa,26736,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-PFa,26736,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-PFa,26736,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,Live Aboveground Woody BioMass; www.cheas.psu.edu/data/cheas/biometry -US-PFa,26736,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2004 -US-PFa,26736,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,2004/2006 average from summer sampling; Black Spruce (Ryan Anderson) -US-PFa,26873,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,2354 -US-PFa,26873,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Wood -US-PFa,26873,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-PFa,26873,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-PFa,26873,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,Live Aboveground Woody BioMass; www.cheas.psu.edu/data/cheas/biometry -US-PFa,26873,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2006 -US-PFa,26873,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,2004/2006 average from summer sampling; Black Spruce (Ryan Anderson) -US-PFa,28215,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,2354 -US-PFa,28215,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Wood -US-PFa,28215,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-PFa,28215,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-PFa,28215,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,Live Aboveground Woody BioMass; www.cheas.psu.edu/data/cheas/biometry -US-PFa,28215,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2005 -US-PFa,28215,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,2004/2006 average from summer sampling; Black Spruce (Ryan Anderson) -US-PFa,27579,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,3610 -US-PFa,27579,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Wood -US-PFa,27579,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-PFa,27579,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-PFa,27579,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,Live Aboveground Woody BioMass; www.cheas.psu.edu/data/cheas/biometry -US-PFa,27579,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2005 -US-PFa,27579,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,2004/2006 average from summer sampling; Lowland Conifer (Ryan Anderson) -US-PFa,29144,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,3610 -US-PFa,29144,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Wood -US-PFa,29144,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-PFa,29144,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-PFa,29144,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,Live Aboveground Woody BioMass; www.cheas.psu.edu/data/cheas/biometry -US-PFa,29144,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2004 -US-PFa,29144,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,2004/2006 average from summer sampling; Lowland Conifer (Ryan Anderson) -US-PFa,29146,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,3610 -US-PFa,29146,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Wood -US-PFa,29146,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-PFa,29146,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-PFa,29146,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,Live Aboveground Woody BioMass; www.cheas.psu.edu/data/cheas/biometry -US-PFa,29146,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2006 -US-PFa,29146,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,2004/2006 average from summer sampling; Lowland Conifer (Ryan Anderson) -US-PFa,26737,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,4029.8 -US-PFa,26737,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Wood -US-PFa,26737,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-PFa,26737,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-PFa,26737,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,Live Aboveground Woody BioMass; www.cheas.psu.edu/data/cheas/biometry -US-PFa,26737,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2004 -US-PFa,26737,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,2004/2006 average from summer sampling; Lowland Hardwood (Ryan Anderson) -US-PFa,26874,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,4029.8 -US-PFa,26874,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Wood -US-PFa,26874,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-PFa,26874,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-PFa,26874,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,Live Aboveground Woody BioMass; www.cheas.psu.edu/data/cheas/biometry -US-PFa,26874,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2006 -US-PFa,26874,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,2004/2006 average from summer sampling; Lowland Hardwood (Ryan Anderson) -US-PFa,27326,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,4029.8 -US-PFa,27326,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Wood -US-PFa,27326,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-PFa,27326,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-PFa,27326,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,Live Aboveground Woody BioMass; www.cheas.psu.edu/data/cheas/biometry -US-PFa,27326,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2005 -US-PFa,27326,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,2004/2006 average from summer sampling; Lowland Hardwood (Ryan Anderson) -US-PFa,28213,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,4164 -US-PFa,28213,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Wood -US-PFa,28213,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-PFa,28213,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-PFa,28213,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,Live Aboveground Woody BioMass; www.cheas.psu.edu/data/cheas/biometry -US-PFa,28213,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,(dry basis); Live Aboveground Woody BioMass = 91.8 Dry Tons/Ha -US-PFa,26871,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,4287 -US-PFa,26871,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Wood -US-PFa,26871,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-PFa,26871,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-PFa,26871,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,Live Aboveground Woody BioMass; www.cheas.psu.edu/data/cheas/biometry -US-PFa,26871,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2005 -US-PFa,26871,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,2004/2006 average from summer sampling; Aspen/Fir (Ryan Anderson) -US-PFa,27946,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,4287 -US-PFa,27946,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Wood -US-PFa,27946,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-PFa,27946,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-PFa,27946,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,Live Aboveground Woody BioMass; www.cheas.psu.edu/data/cheas/biometry -US-PFa,27946,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2004 -US-PFa,27946,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,2004/2006 average from summer sampling; Aspen/Fir (Ryan Anderson) -US-PFa,29496,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,4287 -US-PFa,29496,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Wood -US-PFa,29496,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-PFa,29496,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-PFa,29496,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,Live Aboveground Woody BioMass; www.cheas.psu.edu/data/cheas/biometry -US-PFa,29496,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2006 -US-PFa,29496,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,2004/2006 average from summer sampling; Aspen/Fir (Ryan Anderson) -US-PFa,27023,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,4890 -US-PFa,27023,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Wood -US-PFa,27023,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-PFa,27023,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-PFa,27023,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,Live Aboveground Woody BioMass; www.cheas.psu.edu/data/cheas/biometry -US-PFa,27023,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2004 -US-PFa,27023,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,2004/2006 average from summer sampling; Upland Hardwood (Ryan Anderson) -US-PFa,29035,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,4890 -US-PFa,29035,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Wood -US-PFa,29035,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-PFa,29035,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-PFa,29035,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,Live Aboveground Woody BioMass; www.cheas.psu.edu/data/cheas/biometry -US-PFa,29035,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2005 -US-PFa,29035,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,2004/2006 average from summer sampling; Upland Hardwood (Ryan Anderson) -US-PFa,29037,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,4890 -US-PFa,29037,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Wood -US-PFa,29037,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-PFa,29037,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-PFa,29037,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,Live Aboveground Woody BioMass; www.cheas.psu.edu/data/cheas/biometry -US-PFa,29037,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2006 -US-PFa,29037,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,2004/2006 average from summer sampling; Upland Hardwood (Ryan Anderson) -US-PFa,26735,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,5265 -US-PFa,26735,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Wood -US-PFa,26735,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-PFa,26735,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-PFa,26735,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,Live Aboveground Woody BioMass; www.cheas.psu.edu/data/cheas/biometry -US-PFa,26735,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2004 -US-PFa,26735,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,2004/2006 average from summer sampling; Mixed Forest (Ryan Anderson) -US-PFa,27947,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,5265 -US-PFa,27947,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Wood -US-PFa,27947,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-PFa,27947,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-PFa,27947,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,Live Aboveground Woody BioMass; www.cheas.psu.edu/data/cheas/biometry -US-PFa,27947,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2005 -US-PFa,27947,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,2004/2006 average from summer sampling; Mixed Forest (Ryan Anderson) -US-PFa,28549,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,5265 -US-PFa,28549,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Wood -US-PFa,28549,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-PFa,28549,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-PFa,28549,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,Live Aboveground Woody BioMass; www.cheas.psu.edu/data/cheas/biometry -US-PFa,28549,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2006 -US-PFa,28549,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,2004/2006 average from summer sampling; Mixed Forest (Ryan Anderson) -US-PFa,27021,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,6299.5 -US-PFa,27021,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Wood -US-PFa,27021,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-PFa,27021,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-PFa,27021,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,Live Aboveground Woody BioMass; www.cheas.psu.edu/data/cheas/biometry -US-PFa,27021,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2004 -US-PFa,27021,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,"Stemwood Biomass,P. Bolstad, Taken at Willow Creek" -US-PFa,26872,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,865.9 -US-PFa,26872,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Wood -US-PFa,26872,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-PFa,26872,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-PFa,26872,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,Live Aboveground Woody BioMass; www.cheas.psu.edu/data/cheas/biometry -US-PFa,26872,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2006 -US-PFa,26872,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,2004/2006 average from summer sampling; Non-Forest (Ryan Anderson) -US-PFa,28214,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,865.9 -US-PFa,28214,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Wood -US-PFa,28214,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-PFa,28214,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-PFa,28214,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,Live Aboveground Woody BioMass; www.cheas.psu.edu/data/cheas/biometry -US-PFa,28214,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2005 -US-PFa,28214,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,2004/2006 average from summer sampling; Non-Forest (Ryan Anderson) -US-PFa,28305,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,865.9 -US-PFa,28305,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Wood -US-PFa,28305,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-PFa,28305,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-PFa,28305,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,Live Aboveground Woody BioMass; www.cheas.psu.edu/data/cheas/biometry -US-PFa,28305,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2004 -US-PFa,28305,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,2004/2006 average from summer sampling; Non-Forest (Ryan Anderson) -US-PFa,29482,GRP_AG_LIT_CHEM,AG_LIT_C,3.7 -US-PFa,29482,GRP_AG_LIT_CHEM,AG_LIT_N,0.1163 -US-PFa,29482,GRP_AG_LIT_CHEM,AG_LIT_COMMENT,"P. Bolstad, from Willow Creek" -US-PFa,27575,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT,100.7 -US-PFa,29028,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT,100.7 -US-PFa,29489,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT,100.7 -US-PFa,27575,GRP_AG_LIT_PROD,AG_LIT_PROD_UNIT,gC m-2 -US-PFa,29028,GRP_AG_LIT_PROD,AG_LIT_PROD_UNIT,gC m-2 -US-PFa,29489,GRP_AG_LIT_PROD,AG_LIT_PROD_UNIT,gC m-2 -US-PFa,29489,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_START,1998 -US-PFa,29028,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_START,1999 -US-PFa,27575,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_START,2000 -US-PFa,27575,GRP_AG_LIT_PROD,AG_LIT_PROD_COMMENT,annual average leaf litterfall 1998-2000= 100.7 (P. Bolstad) taken at Willow Creek -US-PFa,29028,GRP_AG_LIT_PROD,AG_LIT_PROD_COMMENT,annual average leaf litterfall 1998-2000= 100.7 (P. Bolstad) taken at Willow Creek -US-PFa,29489,GRP_AG_LIT_PROD,AG_LIT_PROD_COMMENT,annual average leaf litterfall 1998-2000= 100.7 (P. Bolstad) taken at Willow Creek -US-PFa,28299,GRP_AG_PROD_SHRUB,AG_PROD_SHRUB,54 -US-PFa,28299,GRP_AG_PROD_SHRUB,AG_PROD_SHRUB_ORGAN,Total -US-PFa,28299,GRP_AG_PROD_SHRUB,AG_PROD_SHRUB_UNIT,gC m-2 -US-PFa,28299,GRP_AG_PROD_SHRUB,AG_PROD_COMMENT,Ground Cover = 54 (dry basis); Burrows dissertation -US-PFa,29029,GRP_AG_PROD_TREE,AG_PROD_TREE,102.5 -US-PFa,29029,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Foliage -US-PFa,29029,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-PFa,29029,GRP_AG_PROD_TREE,AG_PROD_COMMENT,NPP Foliage = 102.5 (dry basis); Burrows dissertation -US-PFa,27576,GRP_AG_PROD_TREE,AG_PROD_TREE,120 -US-PFa,27576,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Wood -US-PFa,27576,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-PFa,27576,GRP_AG_PROD_TREE,AG_PROD_COMMENT,NPP Wood =120 (dry basis); Burrows dissertation -US-PFa,28300,GRP_AG_PROD_TREE,AG_PROD_TREE,200 -US-PFa,28300,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Total -US-PFa,28300,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-PFa,28300,GRP_AG_PROD_TREE,AG_PROD_COMMENT,nonforest wetland = 200 (dry basis); Burrows dissertation -US-PFa,28543,GRP_AG_PROD_TREE,AG_PROD_TREE,201 -US-PFa,28543,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Total -US-PFa,28543,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-PFa,28543,GRP_AG_PROD_TREE,AG_PROD_COMMENT,Forest Wetland = 201 (dry basis); Burrows dissertation -US-PFa,28301,GRP_AG_PROD_TREE,AG_PROD_TREE,220 -US-PFa,28301,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Total -US-PFa,28301,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-PFa,28301,GRP_AG_PROD_TREE,AG_PROD_COMMENT,upland conifer = 220 (dry basis); Burrows dissertation -US-PFa,29490,GRP_AG_PROD_TREE,AG_PROD_TREE,250 -US-PFa,29490,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Total -US-PFa,29490,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-PFa,29490,GRP_AG_PROD_TREE,AG_PROD_COMMENT,red pine =250 (dry basis); Burrows dissertation -US-PFa,29140,GRP_AG_PROD_TREE,AG_PROD_TREE,260 -US-PFa,29140,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Total -US-PFa,29140,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-PFa,29140,GRP_AG_PROD_TREE,AG_PROD_COMMENT,Site Mean = 260 (dry basis); Burrows dissertation -US-PFa,26869,GRP_AG_PROD_TREE,AG_PROD_TREE,290 -US-PFa,26869,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Total -US-PFa,26869,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-PFa,26869,GRP_AG_PROD_TREE,AG_PROD_COMMENT,mixed = 290 (dry basis); Burrows dissertation -US-PFa,29030,GRP_AG_PROD_TREE,AG_PROD_TREE,340 -US-PFa,29030,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Total -US-PFa,29030,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-PFa,29030,GRP_AG_PROD_TREE,AG_PROD_COMMENT,Aspen = 340 (dry basis); Burrows dissertation -US-PFa,28544,GRP_AG_PROD_TREE,AG_PROD_TREE,350 -US-PFa,28544,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Total -US-PFa,28544,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-PFa,28544,GRP_AG_PROD_TREE,AG_PROD_COMMENT,hardwood= 350 (dry basis); Burrows dissertation -US-PFa,27944,GRP_AG_PROD_TREE,AG_PROD_TREE,95 -US-PFa,27944,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Total -US-PFa,27944,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-PFa,27944,GRP_AG_PROD_TREE,AG_PROD_DATE_START,2004 -US-PFa,27944,GRP_AG_PROD_TREE,AG_PROD_COMMENT,Mean Annual Aboveground Biomass Increment =95 (dry basis); 2004/2006 average summer sampling; Ryan Anderson -US-PFa,28204,GRP_AG_PROD_TREE,AG_PROD_TREE,95 -US-PFa,28204,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Total -US-PFa,28204,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-PFa,28204,GRP_AG_PROD_TREE,AG_PROD_DATE_START,2005 -US-PFa,28204,GRP_AG_PROD_TREE,AG_PROD_COMMENT,Mean Annual Aboveground Biomass Increment =95 (dry basis); 2004/2006 average summer sampling; Ryan Anderson -US-PFa,28205,GRP_AG_PROD_TREE,AG_PROD_TREE,95 -US-PFa,28205,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Total -US-PFa,28205,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-PFa,28205,GRP_AG_PROD_TREE,AG_PROD_DATE_START,2006 -US-PFa,28205,GRP_AG_PROD_TREE,AG_PROD_COMMENT,Mean Annual Aboveground Biomass Increment =95 (dry basis); 2004/2006 average summer sampling; Ryan Anderson -US-PFa,29483,GRP_BIOMASS_CHEM,BIOMASS_C,4.74 -US-PFa,27315,GRP_BIOMASS_CHEM,BIOMASS_N,0.184 -US-PFa,27314,GRP_BIOMASS_CHEM,BIOMASS_N,0.245 -US-PFa,27314,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-PFa,27315,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-PFa,29483,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-PFa,27314,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-PFa,27315,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-PFa,29483,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-PFa,29483,GRP_BIOMASS_CHEM,BIOMASS_SPP,(All) -US-PFa,27315,GRP_BIOMASS_CHEM,BIOMASS_SPP,ACSA3 (NRCS plant code) -US-PFa,27314,GRP_BIOMASS_CHEM,BIOMASS_SPP,FRPE (NRCS plant code) -US-PFa,27314,GRP_BIOMASS_CHEM,BIOMASS_DATE,2000 -US-PFa,27315,GRP_BIOMASS_CHEM,BIOMASS_DATE,2000 -US-PFa,27315,GRP_BIOMASS_CHEM,BIOMASS_COMMENT,"A. Saccharum; Paul. Bolstad, 126 leaf samples, taken at Willow Creek" -US-PFa,29483,GRP_BIOMASS_CHEM,BIOMASS_COMMENT,"average over all species; Paul Bolstad, from Willow Creek" -US-PFa,27314,GRP_BIOMASS_CHEM,BIOMASS_COMMENT,"Fraxinus pennsylvanica; Paul. Bolstad, 126 leaf samples, taken at Willow Creek" -US-PFa,15233,GRP_CLIM_AVG,MAT,4.33 -US-PFa,15233,GRP_CLIM_AVG,MAP,823 -US-PFa,15233,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfb -US-PFa,27000412,GRP_COUNTRY,COUNTRY,USA -US-PFa,2827,GRP_DM_GENERAL,DM_GENERAL,Other -US-PFa,2827,GRP_DM_GENERAL,DM_COMMENT,"WLEF should have no single disturbance listed - it represents a complex landscape that has been disturbed, but not at a single time or in a single way that represents the whole flux footprint. See the following spreadsheet for approximate ages of the various stand types in the WLEF flux footprint. Note that Willow Creek and Lost Creek are representative of a significant subsets of the WLEF flux footprint." -US-PFa,15745,GRP_DOI,DOI,10.17190/AMF/1246090 -US-PFa,15745,GRP_DOI,DOI_CITATION,"Ankur Desai (2022), AmeriFlux BASE US-PFa Park Falls/WLEF, Ver. 20-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1246090" -US-PFa,15745,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-PFa,32159,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-PFa,32159,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Ankur Desai -US-PFa,32159,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-PFa,32159,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,desai@aos.wisc.edu -US-PFa,32159,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of Wisconsin -US-PFa,32161,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,University of Wisconsin -US-PFa,32161,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-PFa,32160,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,"DOE Ameriflux Network Management Project, NOAA ESRL" -US-PFa,32160,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-PFa,22197,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Agriculture -US-PFa,22195,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Forestry -US-PFa,22194,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Land cover change -US-PFa,22196,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Pests and disease -US-PFa,15234,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-PFa,15234,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-PFa,15234,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,1996 -US-PFa,15234,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-PFa,15234,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,"Tall tower, 3 measurement heights" -US-PFa,15248,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-PFa,15248,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-PFa,15248,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,1996 -US-PFa,15248,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-PFa,15251,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-PFa,15251,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-PFa,15251,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,1996 -US-PFa,15251,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-PFa,15254,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-PFa,15254,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CH4 -US-PFa,15254,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,2011 -US-PFa,15254,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-PFa,23000412,GRP_HEADER,SITE_NAME,Park Falls/WLEF -US-PFa,88199,GRP_HEIGHTC,HEIGHTC,24 -US-PFa,88199,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-PFa,88199,GRP_HEIGHTC,HEIGHTC_DATE,20040701 -US-PFa,88199,GRP_HEIGHTC,HEIGHTC_COMMENT,"Paul Bolstad, note, canopy dominant height averaged about 24m - this mean height includes all trees > 4 cm dbh" -US-PFa,15235,GRP_IGBP,IGBP,MF -US-PFa,15235,GRP_IGBP,IGBP_COMMENT,"70% deciduous (aspen, birch, maple, basswood, alder) and 30% conifer (balsam fir, jack pine, black spruce, white cedar)" -US-PFa,26731,GRP_LAI,LAI_TYPE,LAI -US-PFa,26732,GRP_LAI,LAI_TYPE,LAI -US-PFa,26733,GRP_LAI,LAI_TYPE,LAI -US-PFa,27020,GRP_LAI,LAI_TYPE,LAI -US-PFa,27324,GRP_LAI,LAI_TYPE,LAI -US-PFa,27325,GRP_LAI,LAI_TYPE,LAI -US-PFa,27577,GRP_LAI,LAI_TYPE,LAI -US-PFa,27945,GRP_LAI,LAI_TYPE,LAI -US-PFa,28209,GRP_LAI,LAI_TYPE,LAI -US-PFa,28210,GRP_LAI,LAI_TYPE,LAI -US-PFa,28211,GRP_LAI,LAI_TYPE,LAI -US-PFa,28303,GRP_LAI,LAI_TYPE,LAI -US-PFa,28304,GRP_LAI,LAI_TYPE,LAI -US-PFa,28546,GRP_LAI,LAI_TYPE,LAI -US-PFa,28547,GRP_LAI,LAI_TYPE,LAI -US-PFa,29033,GRP_LAI,LAI_TYPE,LAI -US-PFa,29142,GRP_LAI,LAI_TYPE,LAI -US-PFa,29493,GRP_LAI,LAI_TYPE,LAI -US-PFa,29493,GRP_LAI,LAI_DATE,1998 -US-PFa,27945,GRP_LAI,LAI_DATE,1999 -US-PFa,28211,GRP_LAI,LAI_DATE,2000 -US-PFa,27325,GRP_LAI,LAI_COMMENT,"(1%); Barren or Water ; Remotely Sensed (LIDAR) LAI (Bruce Cook) Averages for 2000-05 (6X6 km area centered on WLEF tower, 28.8 m resolution). Number in parenthesis is the percentage of area covered by this forest type." -US-PFa,29033,GRP_LAI,LAI_COMMENT,"(1%); Open Shrubland ; Remotely Sensed (LIDAR) LAI (Bruce Cook) Averages for 2000-05 (6X6 km area centered on WLEF tower, 28.8 m resolution). Number in parenthesis is the percentage of area covered by this forest type." -US-PFa,28546,GRP_LAI,LAI_COMMENT,"(16%); ENF ; Remotely Sensed (LIDAR) LAI (Bruce Cook) Averages for 2000-05 (6X6 km area centered on WLEF tower, 28.8 m resolution). Number in parenthesis is the percentage of area covered by this forest type." -US-PFa,27020,GRP_LAI,LAI_COMMENT,"(28%); Wetland ; Remotely Sensed (LIDAR) LAI (Bruce Cook) Averages for 2000-05 (6X6 km area centered on WLEF tower, 28.8 m resolution). Number in parenthesis is the percentage of area covered by this forest type." -US-PFa,29142,GRP_LAI,LAI_COMMENT,"(3%); Grassland ; Remotely Sensed (LIDAR) LAI (Bruce Cook) Averages for 2000-05 (6X6 km area centered on WLEF tower, 28.8 m resolution). Number in parenthesis is the percentage of area covered by this forest type." -US-PFa,28547,GRP_LAI,LAI_COMMENT,"(31%); Woodland ; Remotely Sensed (LIDAR) LAI (Bruce Cook) Averages for 2000-05 (6X6 km area centered on WLEF tower, 28.8 m resolution). Number in parenthesis is the percentage of area covered by this forest type." -US-PFa,26732,GRP_LAI,LAI_COMMENT,"(5%); MF ; Remotely Sensed (LIDAR) LAI (Bruce Cook) Averages for 2000-05 (6X6 km area centered on WLEF tower, 28.8 m resolution). Number in parenthesis is the percentage of area covered by this forest type." -US-PFa,26733,GRP_LAI,LAI_COMMENT,"(6%); Wooded Grassland/Shrubland ; Remotely Sensed (LIDAR) LAI (Bruce Cook) Averages for 2000-05 (6X6 km area centered on WLEF tower, 28.8 m resolution). Number in parenthesis is the percentage of area covered by this forest type." -US-PFa,26731,GRP_LAI,LAI_COMMENT,"(9%); DBF ; Remotely Sensed (LIDAR) LAI (Bruce Cook) Averages for 2000-05 (6X6 km area centered on WLEF tower, 28.8 m resolution). Number in parenthesis is the percentage of area covered by this forest type." -US-PFa,27945,GRP_LAI,LAI_COMMENT,"1998-2000, Paul Bolstad" -US-PFa,28211,GRP_LAI,LAI_COMMENT,"1998-2000, Paul Bolstad" -US-PFa,29493,GRP_LAI,LAI_COMMENT,"1998-2000, Paul Bolstad" -US-PFa,28209,GRP_LAI,LAI_COMMENT,Ameriflux page -US-PFa,28210,GRP_LAI,LAI_COMMENT,"Aspen, Burrows dissertation" -US-PFa,27324,GRP_LAI,LAI_COMMENT,"Forest Wetland, Burrows dissertation" -US-PFa,28303,GRP_LAI,LAI_COMMENT,"Grass, Burrows dissertation" -US-PFa,27577,GRP_LAI,LAI_COMMENT,"Northern Hardwood, Burrows dissertation" -US-PFa,28304,GRP_LAI,LAI_COMMENT,"Upland Conifer, Burrows dissertation" -US-PFa,27325,GRP_LAI,LAI_TOT,0 -US-PFa,29142,GRP_LAI,LAI_TOT,0.3 -US-PFa,29033,GRP_LAI,LAI_TOT,1.1 -US-PFa,28303,GRP_LAI,LAI_TOT,1.14 -US-PFa,26733,GRP_LAI,LAI_TOT,1.6 -US-PFa,27020,GRP_LAI,LAI_TOT,2.7 -US-PFa,28547,GRP_LAI,LAI_TOT,3 -US-PFa,27577,GRP_LAI,LAI_TOT,3.45 -US-PFa,28210,GRP_LAI,LAI_TOT,3.57 -US-PFa,27324,GRP_LAI,LAI_TOT,3.82 -US-PFa,26731,GRP_LAI,LAI_TOT,3.9 -US-PFa,26732,GRP_LAI,LAI_TOT,3.9 -US-PFa,28304,GRP_LAI,LAI_TOT,3.99 -US-PFa,28546,GRP_LAI,LAI_TOT,4 -US-PFa,27945,GRP_LAI,LAI_TOT,4.05 -US-PFa,28211,GRP_LAI,LAI_TOT,4.05 -US-PFa,29493,GRP_LAI,LAI_TOT,4.05 -US-PFa,28209,GRP_LAI,LAI_TOT,5 -US-PFa,15236,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -US-PFa,15236,GRP_LAND_OWNERSHIP,LAND_OWNER,"Wisconsin Public Broadcasting. Note that while the tower itself is on private land, most of the surrounding land is US Forest Service land (Chequamegon-Nicollet National Forest). The flux footprint also includes state land and additional private land." -US-PFa,15237,GRP_LOCATION,LOCATION_LAT,45.9459 -US-PFa,15237,GRP_LOCATION,LOCATION_LONG,-90.2723 -US-PFa,15237,GRP_LOCATION,LOCATION_ELEV,470.00 -US-PFa,15237,GRP_LOCATION,LOCATION_COMMENT,Luyssaert -US-PFa,27943,GRP_NEP,NEP,384000 -US-PFa,27943,GRP_NEP,NEP_COMMENT,384 +/- 26; Cook dissertation -US-PFa,15238,GRP_NETWORK,NETWORK,AmeriFlux -US-PFa,27321,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,Leaf senescence -US-PFa,27321,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,(All) -US-PFa,27321,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20010520 -US-PFa,27321,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,"Estimated from site PAR data, Brett Raczka" -US-PFa,27941,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,Leaf senescence -US-PFa,27941,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,(All) -US-PFa,27941,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20000508 -US-PFa,27941,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,"Estimated from site PAR data, Brett Raczka" -US-PFa,29488,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,Leaf senescence -US-PFa,29488,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,(All) -US-PFa,29488,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20030519 -US-PFa,29488,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,"Estimated from site PAR data, Brett Raczka" -US-PFa,27939,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,Maximum leaf expansion -US-PFa,27939,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,(All) -US-PFa,27939,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20011012 -US-PFa,27939,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,"Estimated from site PAR data, Brett Raczka" -US-PFa,27940,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,Maximum leaf expansion -US-PFa,27940,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,(All) -US-PFa,27940,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20031017 -US-PFa,27940,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,"Estimated from site PAR data, Brett Raczka" -US-PFa,29139,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,Maximum leaf expansion -US-PFa,29139,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,(All) -US-PFa,29139,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20001019 -US-PFa,29139,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,"Estimated from site PAR data, Brett Raczka" -US-PFa,1700001029,GRP_REFERENCE_PAPER,REFERENCE_PAPER," (2012) The Imprint Of Surface Fluxes And Transport On Variations In Total Column Carbon Dioxide, Biogeosciences, 9(3), 875-891" -US-PFa,1700001029,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.5194/BG-9-875-2012 -US-PFa,1700001029,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-PFa,1700006759,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Andrews, A.E., Kofler, J.D., Trudeau, M.E., Williams, J.C., Neff, D.H., Masarie, K.A., Chao, D.Y., Kitzis, D.R., Novelli, P.C., Zhao, C.L., Dlugokencky, E.J., Lang, P.M., Crotwell, M.J., Fischer, M.L., Parker, M.J., Lee, J.T., Baumann, D.D., Desai, A.R., Stanier, C.O., de Wekker, S.F.J., Wolfe, D.E., Munger, J.W., Tans, P.P. (2014) CO2, CO, And CH4 Measurements From Tall Towers In The NOAA Earth System Research Laboratory's Global Greenhouse Gas Reference Network: Instrumentation, Uncertainty Analysis, And Recommendations For Future High-Accuracy Greenhouse Gas Monitoring Efforts, Atmospheric Measurement Techniques, 7(2), 647-687" -US-PFa,1700006759,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.5194/AMT-7-647-2014 -US-PFa,1700006759,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-PFa,1700005466,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Baker, I., Denning, A. S., Hanan, N., Prihodko, L., Uliasz, M., Vidale, P., Davis, K., Bakwin, P. (2003) Simulated And Observed Fluxes Of Sensible And Latent Heat And CO2 At The WLEF-TV Tower Using SiB2.5, Global Change Biology, 9(9), 1262-1277" -US-PFa,1700005466,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1046/J.1365-2486.2003.00671.X -US-PFa,1700005466,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-PFa,1700007983,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Bakwin, P. S., Davis, K. J., Yi, C., Wofsy, S. C., Munger, J. W., Haszpra, L., Barcza, Z. (2004) Regional Carbon Dioxide Fluxes From Mixing Ratio Data, Tellus Series B-Chemical and Physical Meteorology, 56(4), 301-311" -US-PFa,1700007983,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.3402/TELLUSB.V56I4.16446 -US-PFa,1700007983,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-PFa,1700004650,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Baldocchi, D., Penuelas, J. (2018) The Physics And Ecology Of Mining Carbon Dioxide From The Atmosphere By Ecosystems, Global Change Biology, 121(8), 2186-2198" -US-PFa,1700004650,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/GCB.14559 -US-PFa,1700004650,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-PFa,1700003624,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Baldocchi, D., Penuelas, J. (2018) The Physics And Ecology Of Mining Carbon Dioxide From The Atmosphere By Ecosystems, Global Change Biology, 136(1-2), 1-18" -US-PFa,1700003624,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/GCB.14559 -US-PFa,1700003624,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-PFa,1700004917,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Berger, B. W., Davis, K. J., Yi, C., Bakwin, P. S., Zhao, C. L. (2001) Long-Term Carbon Dioxide Fluxes From A Very Tall Tower In A Northern Forest: Flux Measurement Methodology, Journal Of Atmospheric And Oceanic Technology, 18(4), 529-542" -US-PFa,1700004917,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1175/1520-0426(2001)018<0529:LTCDFF>2.0.CO;2 -US-PFa,1700004917,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-PFa,1700006039,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Cook, B. D., Davis, K. J., Wang, W., Desai, A., Berger, B. W., Teclaw, R. M., Martin, J. G., Bolstad, P. V., Bakwin, P. S., Yi, C., Heilman, W. (2004) Carbon Exchange And Venting Anomalies In An Upland Deciduous Forest In Northern Wisconsin, USA, Agricultural And Forest Meteorology, 126(3-4), 271-295" -US-PFa,1700006039,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2004.06.008 -US-PFa,1700006039,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-PFa,1700007233,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Davis, K. J., Bakwin, P. S., Yi, C., Berger, B. W., Zhao, C., Teclaw, R. M., Isebrands, J. G. (2003) The Annual Cycles Of CO2 And H2O Exchange Over A Northern Mixed Forest As Observed From A Very Tall Tower, Global Change Biology, 9(9), 1278-1293" -US-PFa,1700007233,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1046/J.1365-2486.2003.00672.X -US-PFa,1700007233,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-PFa,1700007032,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Desai, A. R. (2014) Influence And Predictive Capacity Of Climate Anomalies On Daily To Decadal Extremes In Canopy Photosynthesis, Photosynthesis Research, 119(1-2), 31-47" -US-PFa,1700007032,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1007/S11120-013-9925-Z -US-PFa,1700007032,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-PFa,1700001575,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Desai, A. R., Helliker, B. R., Moorcroft, P. R., Andrews, A. E., Berry, J. A. (2010) Climatic Controls Of Interannual Variability In Regional Carbon Fluxes From Top-Down And Bottom-Up Perspectives, Journal Of Geophysical Research: Biogeosciences, 115(G2), n/a-n/a" -US-PFa,1700001575,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2009JG001122 -US-PFa,1700001575,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-PFa,1700005634,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Desai, A. R., Noormets, A., Bolstad, P. V., Chen, J., Cook, B. D., Davis, K. J., Euskirchen, E. S., Gough, C., Martin, J. G., Ricciuto, D. M., Schmid, H. P., Tang, J., Wang, W. (2008) Influence Of Vegetation And Seasonal Forcing On Carbon Dioxide Fluxes Across The Upper Midwest, Usa: Implications For Regional Scaling, Agricultural And Forest Meteorology, 148(2), 288-308" -US-PFa,1700005634,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2007.08.001 -US-PFa,1700005634,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-PFa,1700004449,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Desai, A. R., Xu, K., Tian, H., Weishampel, P., Thom, J., Baumann, D., Andrews, A. E., Cook, B. D., King, J. Y., Kolka, R. (2015) Landscape-Level Terrestrial Methane Flux Observed From A Very Tall Tower, Agricultural And Forest Meteorology, 201(2), 61-75" -US-PFa,1700004449,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2014.10.017 -US-PFa,1700004449,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-PFa,1700002907,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Desai, A.R. (2010) Climatic And Phenological Controls On Coherent Regional Interannual Variability Of Carbon Dioxide Flux In A Heterogeneous Landscape, Journal Of Geophysical Research, 115(G00J02), n/a-n/a" -US-PFa,1700002907,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2010JG001423 -US-PFa,1700002907,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-PFa,1700008538,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Desai, A.R., Moorcroft, P.R., Bolstad, P.V., and Davis, K.J. (2007) Regional Carbon Fluxes From An Observationally Constrained Dynamic Ecosystem Model: Impacts Of Disturbance, CO2 Fertilization, And Heterogeneous Land Cover, Journal Of Geophysical Research: Biogeosciences, 112(G1), n/a-n/a" -US-PFa,1700008538,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2006JG000264 -US-PFa,1700008538,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-PFa,1700008271,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Desai, A.R., Xu, K., Tian, H., Weishampel, P., Thom, J., Baumann, D., Andrews, A.E., Cook, B.D., King, J.Y., Kolka, R. (2015) Landscape-level terrestrial methane flux observed from a very tall tower, Agricultural and Forest Meteorology, 201(), 61-75" -US-PFa,1700008271,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2014.10.017 -US-PFa,1700008271,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Primary_Citation -US-PFa,1700003021,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Donnelly, A., Yu, R., Liu, L., Hanes, J. M., Liang, L., Schwartz, M. D., Desai, A. R. (2019) Comparing In-Situ Leaf Observations In Early Spring With Flux Tower Co2 Exchange, Modis Evi And Modeled Lai In A Northern Mixed Forest, Agricultural And Forest Meteorology, 278(8), 107673" -US-PFa,1700003021,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2019.107673 -US-PFa,1700003021,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-PFa,1700002328,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Hurwitz, M. D., Ricciuto, D. M., Bakwin, P. S., Davis, K. J., Wang, W., Yi, C., Butler, M. P. (2004) Transport Of Carbon Dioxide In The Presence Of Storm Systems Over A Northern Wisconsin Forest, Journal Of The Atmospheric Sciences, 61(5), 607-618" -US-PFa,1700002328,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1175/1520-0469(2004)061<0607:TOCDIT>2.0.CO;2 -US-PFa,1700002328,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-PFa,1700000501,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Jones, L. A., Kimball, J. S., Reichle, R. H., Madani, N., Glassy, J., Ardizzone, J. V., Ardizzone, J. V., Colliander, A., Cleverly, J., Desai, A. R., Eamus, D., Euskirchen, E. S., Hutley, L., Macfarlane, C., Scott, R. L. (2017) The Smap Level 4 Carbon Product For Monitoring Ecosystem Land–Atmosphere Co2exchange, Ieee Transactions On Geoscience And Remote Sensing, 55(11), 6517-6532" -US-PFa,1700000501,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1109/TGRS.2017.2729343 -US-PFa,1700000501,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-PFa,1700008658,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Knox, S. H., Jackson, R. B., Poulter, B., McNicol, G., Fluet-Chouinard, E., Zhang, Z., Hugelius, G., Bousquet, P., Canadell, J. G., Saunois, M., Papale, D., Chu, H., Keenan, T. F., Baldocchi, D., Torn, M. S., Mammarella, I., Trotta, C., Aurela, M., Bohrer, G., Campbell, D. I., Cescatti, A., Chamberlain, S., Chen, J., Chen, W., Dengel, S., Desai, A. R., Euskirchen, E., Friborg, T., Gasbarra, D., Goded, I., Goeckede, M., Heimann, M., Helbig, M., Hirano, T., Hollinger, D. Y., Iwata, H., Kang, M., Klatt, J., Krauss, K. W., Kutzbach, L., Lohila, A., Mitra, B., Morin, T. H., Nilsson, M. B., Niu, S., Noormets, A., Oechel, W. C., Peichl, M., Peltola, O., Reba, M. L., Richardson, A. D., Runkle, B. R., Ryu, Y., Sachs, T., Schäfer, K. V., Schmid, H. P., Shurpali, N., Sonnentag, O., Tang, A. C., Ueyama, M., Vargas, R., Vesala, T., Ward, E. J., Windham-Myers, L., Wohlfahrt, G., Zona, D. (2019) Fluxnet-Ch4 Synthesis Activity: Objectives, Observations, And Future Directions, Bulletin Of The American Meteorological Society, 20(8), 1619-1633" -US-PFa,1700008658,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1175/BAMS-D-18-0268.1 -US-PFa,1700008658,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-PFa,1700007662,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Mackay, D. S., Ahl, D. E., Ewers, B. E., Gower, S. T., Burrows, S. N., Samanta, S., Davis, K. J. (2002) Effects Of Aggregated Classifications Of Forest Composition On Estimates Of Evapotranspiration In A Northern Wisconsin Forest, Global Change Biology, 8(12), 1253-1265" -US-PFa,1700007662,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1046/J.1365-2486.2002.00554.X -US-PFa,1700007662,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-PFa,1700001614,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Matheny, A. M., Bohrer, G., Stoy, P. C., Baker, I. T., Black, A. T., Desai, A. R., Dietze, M. C., Gough, C. M., Ivanov, V. Y., Jassal, R. S., Novick, K. A., Schäfer, K. V., Verbeeck, H. (2014) Characterizing The Diurnal Patterns of Errors in The Prediction of Evapotranspiration by Several Land-Surface Models: An Nacp Analysis, Journal Of Geophysical Research: Biogeosciences, 119(7), 1458-1473" -US-PFa,1700001614,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/2014JG002623 -US-PFa,1700001614,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-PFa,1700005715,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Petrescu, A. M., Lohila, A., Tuovinen, J., Baldocchi, D. D., Desai, A. R., Roulet, N. T., Vesala, T., Dolman, A. J., Oechel, W. C., Marcolla, B., Friborg, T., Rinne, J., Matthes, J. H., Merbold, L., Meijide, A., Kiely, G., Sottocornola, M., Sachs, T., Zona, D., Varlagin, A., Lai, D. Y., Veenendaal, E., Parmentier, F. W., Skiba, U., Lund, M., Hensen, A., van Huissteden, J., Flanagan, L. B., Shurpali, N. J., Grünwald, T., Humphreys, E. R., Jackowicz-Korczyński, M., Aurela, M. A., Laurila, T., Grüning, C., Corradi, C. A., Schrier-Uijl, A. P., Christensen, T. R., Tamstorf, M. P., Mastepanov, M., Martikainen, P. J., Verma, S. B., Bernhofer, C., Cescatti, A. (2015) The Uncertain Climate Footprint Of Wetlands Under Human Pressure, Proceedings Of The National Academy Of Sciences, 112(15), 4594-4599" -US-PFa,1700005715,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1073/PNAS.1416267112 -US-PFa,1700005715,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-PFa,1700007206,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Pressel, K. G., Collins, W. D., Desai, A. R. (2014) The Spatial Scale Dependence Of Water Vapor Variability Inferred From Observations From A Very Tall Tower, Journal Of Geophysical Research: Atmospheres, 119(16), 9822-9837" -US-PFa,1700007206,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/2013JD021141 -US-PFa,1700007206,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-PFa,1700005487,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Richardson, A. D., Hollinger, D. Y., Burba, G. G., Davis, K. J., Flanagan, L. B., Katul, G. G., William Munger, J., Ricciuto, D. M., Stoy, P. C., Suyker, A. E., Verma, S. B., Wofsy, S. C. (2006) A Multi-Site Analysis Of Random Error In Tower-Based Measurements Of Carbon And Energy Fluxes, Agricultural And Forest Meteorology, 136(1-2), 1-18" -US-PFa,1700005487,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2006.01.007 -US-PFa,1700005487,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-PFa,1700000777,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Scott Denning, A., Nicholls, M., Prihodko, L., Baker, I., Vidale, P., Davis, K., Bakwin, P. (2003) Simulated Variations In Atmospheric CO2 Over A Wisconsin Forest Using A Coupled Ecosystem-Atmosphere Model, Global Change Biology, 9(9), 1241-1250" -US-PFa,1700000777,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1046/J.1365-2486.2003.00613.X -US-PFa,1700000777,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-PFa,1700004983,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Sullivan, R. C., Cook, D. R., Ghate, V. P., Kotamarthi, V. R., Feng, Y. (2019) Improved Spatiotemporal Representativeness And Bias Reduction Of Satellite-Based Evapotranspiration Retrievals Via Use Of In Situ Meteorology And Constrained Canopy Surface Resistance, Journal Of Geophysical Research: Biogeosciences, 124(2), 342-352" -US-PFa,1700004983,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018JG004744 -US-PFa,1700004983,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-PFa,1700005958,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Sullivan, R. C., Kotamarthi, V. R., Feng, Y. (2019) Recovering Evapotranspiration Trends From Biased CMIP5 Simulations And Sensitivity To Changing Climate Over North America, Journal Of Hydrometeorology, 20(8), 1619-1633" -US-PFa,1700005958,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1175/JHM-D-18-0259.1 -US-PFa,1700005958,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-PFa,1700000846,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Vasys, V. N., Desai, A. R., McKinley, G. A., Bennington, V., Michalak, A. M., Andrews, A. E. (2011) The Influence Of Carbon Exchange Of A Large Lake On Regional Tracer-Transport Inversions: Results From Lake Superior, Environmental Research Letters, 6(3), n/a-n/a" -US-PFa,1700000846,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1088/1748-9326/6/3/034016 -US-PFa,1700000846,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-PFa,1700003072,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Werner, C., Davis, K., Bakwin, P., Yi, C., Hurst, D., Lock, L. (2003) Regional-Scale Measurements Of CH4 Exchange From A Tall Tower Over A Mixed Temperate/Boreal Lowland And Wetland Forest, Global Change Biology, 9(9), 1251-1261" -US-PFa,1700003072,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1046/J.1365-2486.2003.00670.X -US-PFa,1700003072,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-PFa,1700008328,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Wolf, S., Keenan, T.F., Fisher, J.B., Baldocchi, D.D., Desai, A.R., Richardson, A.D., Scott, R.L., Law, B.E., Litvak, M.E., Brunsell, N.A., Peters, W., van der Laan-Luijkx, I.T. (2016) Warm spring reduced carbon cycle impact of the 2012 US summer drought, Proceedings of the National Academy of Sciences, 113(21), 5880-5885" -US-PFa,1700008328,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1073/PNAS.1519620113 -US-PFa,1700008328,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-PFa,1700007629,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Xu, B., Arain, M. A., Black, T. A., Law, B. E., Pastorello, G. Z., Chu, H. (2020) Seasonal Variability Of Forest Sensitivity To Heat And Drought Stresses: A Synthesis Based On Carbon Fluxes From North American Forest Ecosystems, Global Change Biology, 26(2), 901-918" -US-PFa,1700007629,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/GCB.14843 -US-PFa,1700007629,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-PFa,1700007176,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Xu, K., Metzger, S., Desai, A. R. (2017) Upscaling Tower-Observed Turbulent Exchange At Fine Spatio-Temporal Resolution Using Environmental Response Functions, Agricultural And Forest Meteorology, 232(11), 10-22" -US-PFa,1700007176,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2016.07.019 -US-PFa,1700007176,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-PFa,1700006024,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Xu, K., Metzger, S., Desai, A. R. (2018) Surface-Atmosphere Exchange In A Box: Space-Time Resolved Storage And Net Vertical Fluxes From Tower-Based Eddy Covariance, Agricultural And Forest Meteorology, 255(8), 81-91" -US-PFa,1700006024,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2017.10.011 -US-PFa,1700006024,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-PFa,1700005040,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Yi, C., Davis, K. J., Bakwin, P. S., Denning, A. S., Zhang, N., Desai, A., Lin, J. C., Gerbig, C. (2004) Observed Covariance Between Ecosystem Carbon Exchange And Atmospheric Boundary Layer Dynamics At A Site In Northern Wisconsin, Journal Of Geophysical Research: Atmospheres, 109(D8), n/a-n/a" -US-PFa,1700005040,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2003JD004164 -US-PFa,1700005040,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-PFa,1700003153,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Yi, C., Davis, K. J., Berger, B. W., Bakwin, P. S. (2001) Long-Term Observations Of The Dynamics Of The Continental Planetary Boundary Layer, Journal Of The Atmospheric Sciences, 58(10), 1288-1299" -US-PFa,1700003153,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1175/1520-0469(2001)058<1288:LTOOTD>2.0.CO;2 -US-PFa,1700003153,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-PFa,1700004269,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Yi, C., Li, R., Bakwin, P. S., Desai, A., Ricciuto, D. M., Burns, S. P., Turnipseed, A. A., Wofsy, S. C., Munger, J. W., Wilson, K., Monson, R. K. (2004) A Nonparametric Method For Separating Photosynthesis And Respiration Components In CO2 Flux Measurements, Geophysical Research Letters, 31(17), n/a-n/a" -US-PFa,1700004269,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2004GL020490 -US-PFa,1700004269,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-PFa,1700001746,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Zscheischler, J., Fatichi, S., Wolf, S., Blanken, P., Bohrer, G., Clark, K., Desai, A., Hollinger, D., Keenan, T., Novick, K.A., Seneviratne, S.I. (2016) Short-term favorable weather conditions are an important control of interannual variability in carbon and water fluxes, Journal of Geophysical Research - Biogeosciences, 121(8), 2186-2198" -US-PFa,1700001746,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/2016JG003503 -US-PFa,1700001746,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-PFa,15240,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"The research objectives of the 'Observations of carbon dioxide mixing ratios and surface exchange fluxes at WLEF' project include the following: 1) Examine the annual carbon balance of the forest on a large scale (several square kilometers); 2) Determine which environmental variables are most important in setting the net carbon balance on seasonal and annual time scales; 3) Examine the role of PBL dynamics in carbon exchange and the influence of carbon dioxide mixing ratios near the surface; 4) Quantify the PBL-free troposphere exchange; 5) Determine the mixing ratios of carbon dioxide obtained at up to 500 m height on towers can best be used, in combination with data from other existing sites and from aircraft, to constrain the terrestrial carbon balance on regional and global scales; 6) Examine how anthropogenic pollution can influence the regional mixing ratios and variability of carbon dioxide and other greenhouse and ozone-depleting gases. (Project description by Peter S. Bakwin available at http://cheas.psu.edu/projects/WLEFflux). In addition, the usage of multiple-level flux measurements, examine systematic errors in our estimates of NEE of CO2, and in the joint evaluation of the seasonal cycles of both NEE of CO2 and the atmospheric boundary layer (ABL) CO2 mixing ratio (Davis et al. 2003)." -US-PFa,28206,GRP_ROOT_BIOMASS,ROOT_BIOMASS_CRS,966 -US-PFa,28302,GRP_ROOT_BIOMASS,ROOT_BIOMASS_CRS,966 -US-PFa,28206,GRP_ROOT_BIOMASS,ROOT_BIOMASS_FINE,1330 -US-PFa,28302,GRP_ROOT_BIOMASS,ROOT_BIOMASS_FINE,1330 -US-PFa,28206,GRP_ROOT_BIOMASS,ROOT_BIOMASS_UNIT,gC m-2 -US-PFa,28302,GRP_ROOT_BIOMASS,ROOT_BIOMASS_UNIT,gC m-2 -US-PFa,28206,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MIN,0 -US-PFa,28302,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MIN,0 -US-PFa,28206,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MAX,30 -US-PFa,28302,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MAX,30 -US-PFa,28206,GRP_ROOT_BIOMASS,ROOT_BIOMASS_DATE,1998 -US-PFa,28302,GRP_ROOT_BIOMASS,ROOT_BIOMASS_DATE,1999 -US-PFa,28206,GRP_ROOT_BIOMASS,ROOT_BIOMASS_COMMENT,"Med. Root biomass= 966; 1998/99 average; Paul Bolstad, from WC, fine root <2 mm, med. Root >2mm, less then 1 cm" -US-PFa,28302,GRP_ROOT_BIOMASS,ROOT_BIOMASS_COMMENT,"Med. Root biomass= 966; 1998/99 average; Paul Bolstad, from WC, fine root <2 mm, med. Root >2mm, less then 1 cm" -US-PFa,27322,GRP_ROOT_CHEM,ROOT_C,12.54 -US-PFa,27942,GRP_ROOT_CHEM,ROOT_N,0.068 -US-PFa,27313,GRP_ROOT_CHEM,ROOT_N,0.073 -US-PFa,27323,GRP_ROOT_CHEM,ROOT_N,0.091 -US-PFa,27313,GRP_ROOT_CHEM,ROOT_SPP,(Unknown) -US-PFa,27322,GRP_ROOT_CHEM,ROOT_SPP,(Unknown) -US-PFa,27323,GRP_ROOT_CHEM,ROOT_SPP,(Unknown) -US-PFa,27942,GRP_ROOT_CHEM,ROOT_SPP,(Unknown) -US-PFa,27313,GRP_ROOT_CHEM,ROOT_DATE,1999 -US-PFa,27323,GRP_ROOT_CHEM,ROOT_DATE,1999 -US-PFa,27942,GRP_ROOT_CHEM,ROOT_DATE,1999 -US-PFa,27322,GRP_ROOT_CHEM,ROOT_COMMENT,"12.54 t/ha; P. Bolstad, from Willow Creek" -US-PFa,27323,GRP_ROOT_CHEM,ROOT_COMMENT,"1998-99 average; 0-30 cm, P. Bolstad, taken from Willow Creek" -US-PFa,27942,GRP_ROOT_CHEM,ROOT_COMMENT,"1998-99 average; 30-60 cm, P. Bolstad, taken from Willow Creek" -US-PFa,27313,GRP_ROOT_CHEM,ROOT_COMMENT,"1998-99 average; 60-100 cm, P. Bolstad, taken from Willow Creek" -US-PFa,28545,GRP_SA,SA,61 -US-PFa,28545,GRP_SA,SA_COMMENT,From Ryan Anderson WLEF biomass spreadsheet -US-PFa,26870,GRP_SA,SA,138 -US-PFa,26870,GRP_SA,SA_DATE,2005 -US-PFa,26870,GRP_SA,SA_COMMENT,"125-150; ~2005; Wetland Stands, P. Bolstad" -US-PFa,26870,GRP_SA,SA_MAX,150 -US-PFa,27019,GRP_SA,SA,75 -US-PFa,27019,GRP_SA,SA_DATE,2005 -US-PFa,27019,GRP_SA,SA_COMMENT,"70-80; ~2005; Sugar Maple, P. Bolstad" -US-PFa,29032,GRP_SA,SA,18 -US-PFa,29032,GRP_SA,SA_DATE,2005 -US-PFa,29032,GRP_SA,SA_COMMENT,"15-20; ~2005; Aspen, P. Bolstad" -US-PFa,29141,GRP_SA,SA,38 -US-PFa,29141,GRP_SA,SA_DATE,2005 -US-PFa,29141,GRP_SA,SA_COMMENT,"35-40; ~2005; Mean age, P. Bolstad" -US-PFa,29492,GRP_SA,SA,65 -US-PFa,29492,GRP_SA,SA_DATE,2005 -US-PFa,29492,GRP_SA,SA_COMMENT,"60-70; ~2005; Red Pine, P. Bolstad" -US-PFa,22198,GRP_SITE_CHAR,TERRAIN,Undulated/Variable -US-PFa,22198,GRP_SITE_CHAR,ASPECT,FLAT -US-PFa,22198,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,100 -US-PFa,22198,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,100 -US-PFa,15241,GRP_SITE_DESC,SITE_DESC,"The flux footprint encompasses a highly heterogeneous landscape of upland forests and wetlands (forested and nonforested). The forests are mainly deciduous but also include substantial coniferous coverage. The upland/lowland variability occurs on spatial scales of a few hundred meters. This heterogeneous landscape is further complicated by a nonuniform, small scale mosaic of thinning and clearcutting of the forest. At larger scales (1 km or greater) the forest cover mosaic is quite homogeneous for many kilometers. The site was chosen not for study of a simple stand, but for upscaling experiments. The daytime fetch of flux measurements from the 396m level is on the order of 5-10 km, yielding a flux footprint roughly 100x the area of a typical stand-level flux tower. AC power (tower is a TV transmitter)." -US-PFa,95086,GRP_SITE_FUNDING,SITE_FUNDING,"DOE Ameriflux Network Management Project, NOAA ESRL, NSF 1822420" -US-PFa,26868,GRP_SOIL_CHEM,SOIL_CHEM_C_ORG,107 -US-PFa,27574,GRP_SOIL_CHEM,SOIL_CHEM_C_ORG,94.73 -US-PFa,26868,GRP_SOIL_CHEM,SOIL_CHEM_N_TOT,7.4 -US-PFa,26730,GRP_SOIL_CHEM,SOIL_CHEM_BD,1.6 -US-PFa,26730,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,0 -US-PFa,26868,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,0 -US-PFa,27574,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,0 -US-PFa,26730,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,30 -US-PFa,26868,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,30 -US-PFa,27574,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,60 -US-PFa,26868,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,"(0-30 cm, including litter layer); pulled from Willow Creek" -US-PFa,27574,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,(top 60 cm); pulled from Willow Creek -US-PFa,26730,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,"0-30 cm range, Jon Martin" -US-PFa,29621,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION,"Outwash sand gravel, sandy-loamy till" -US-PFa,29621,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION_TAXONOMY,Other -US-PFa,28542,GRP_SOIL_TEX,SOIL_TEX_SAND,59.31 -US-PFa,28542,GRP_SOIL_TEX,SOIL_TEX_SILT,34 -US-PFa,28542,GRP_SOIL_TEX,SOIL_TEX_CLAY,6.63 -US-PFa,28542,GRP_SOIL_TEX,SOIL_TEX_COMMENT,0-30 cm. P. Bolstad -US-PFa,26883,GRP_SPP_O,SPP_O,(see comment) -US-PFa,27024,GRP_SPP_O,SPP_O,(see comment) -US-PFa,27583,GRP_SPP_O,SPP_O,(see comment) -US-PFa,27950,GRP_SPP_O,SPP_O,(see comment) -US-PFa,26880,GRP_SPP_O,SPP_O,ABBA (NRCS plant code) -US-PFa,28308,GRP_SPP_O,SPP_O,ABBA (NRCS plant code) -US-PFa,27952,GRP_SPP_O,SPP_O,ACRU (NRCS plant code) -US-PFa,29497,GRP_SPP_O,SPP_O,ACRU (NRCS plant code) -US-PFa,26875,GRP_SPP_O,SPP_O,ACSA3 (NRCS plant code) -US-PFa,27584,GRP_SPP_O,SPP_O,ACSA3 (NRCS plant code) -US-PFa,29151,GRP_SPP_O,SPP_O,ACSA3 (NRCS plant code) -US-PFa,26741,GRP_SPP_O,SPP_O,ACSP2 (NRCS plant code) -US-PFa,27948,GRP_SPP_O,SPP_O,ALNUS (NRCS plant code) -US-PFa,29500,GRP_SPP_O,SPP_O,ALNUS (NRCS plant code) -US-PFa,26886,GRP_SPP_O,SPP_O,AMELA (NRCS plant code) -US-PFa,27026,GRP_SPP_O,SPP_O,BEAL2 (NRCS plant code) -US-PFa,29155,GRP_SPP_O,SPP_O,BEAL2 (NRCS plant code) -US-PFa,26738,GRP_SPP_O,SPP_O,BENI (NRCS plant code) -US-PFa,27030,GRP_SPP_O,SPP_O,BENI (NRCS plant code) -US-PFa,27328,GRP_SPP_O,SPP_O,BEPA (NRCS plant code) -US-PFa,29039,GRP_SPP_O,SPP_O,BEPA (NRCS plant code) -US-PFa,28568,GRP_SPP_O,SPP_O,COAM3 (NRCS plant code) -US-PFa,27031,GRP_SPP_O,SPP_O,COSES (NRCS plant code) -US-PFa,26887,GRP_SPP_O,SPP_O,EUSID (NRCS plant code) -US-PFa,27027,GRP_SPP_O,SPP_O,EUSID (NRCS plant code) -US-PFa,29498,GRP_SPP_O,SPP_O,FRAM2 (NRCS plant code) -US-PFa,27582,GRP_SPP_O,SPP_O,FRNI (NRCS plant code) -US-PFa,27951,GRP_SPP_O,SPP_O,FRNI (NRCS plant code) -US-PFa,26878,GRP_SPP_O,SPP_O,FRPE (NRCS plant code) -US-PFa,28217,GRP_SPP_O,SPP_O,FRPE (NRCS plant code) -US-PFa,28569,GRP_SPP_O,SPP_O,ILVE (NRCS plant code) -US-PFa,28553,GRP_SPP_O,SPP_O,LALA (NRCS plant code) -US-PFa,29148,GRP_SPP_O,SPP_O,LALA (NRCS plant code) -US-PFa,28311,GRP_SPP_O,SPP_O,PIBA2 (NRCS plant code) -US-PFa,28551,GRP_SPP_O,SPP_O,PIBA2 (NRCS plant code) -US-PFa,26876,GRP_SPP_O,SPP_O,PIGL (NRCS plant code) -US-PFa,29499,GRP_SPP_O,SPP_O,PIGL (NRCS plant code) -US-PFa,26879,GRP_SPP_O,SPP_O,PIMA (NRCS plant code) -US-PFa,27025,GRP_SPP_O,SPP_O,PIMA (NRCS plant code) -US-PFa,28307,GRP_SPP_O,SPP_O,PIRE (NRCS plant code) -US-PFa,29040,GRP_SPP_O,SPP_O,PIRE (NRCS plant code) -US-PFa,28550,GRP_SPP_O,SPP_O,PIST (NRCS plant code) -US-PFa,28570,GRP_SPP_O,SPP_O,PIST (NRCS plant code) -US-PFa,27329,GRP_SPP_O,SPP_O,POGR4 (NRCS plant code) -US-PFa,28565,GRP_SPP_O,SPP_O,POGR4 (NRCS plant code) -US-PFa,26881,GRP_SPP_O,SPP_O,POTR5 (NRCS plant code) -US-PFa,27581,GRP_SPP_O,SPP_O,POTR5 (NRCS plant code) -US-PFa,28309,GRP_SPP_O,SPP_O,PRPEP (NRCS plant code) -US-PFa,29152,GRP_SPP_O,SPP_O,PRPEP (NRCS plant code) -US-PFa,29038,GRP_SPP_O,SPP_O,PRSE2 (NRCS plant code) -US-PFa,26884,GRP_SPP_O,SPP_O,PRSES (NRCS plant code) -US-PFa,27028,GRP_SPP_O,SPP_O,SALIX (NRCS plant code) -US-PFa,29501,GRP_SPP_O,SPP_O,SALIX (NRCS plant code) -US-PFa,27585,GRP_SPP_O,SPP_O,SOAM3 (NRCS plant code) -US-PFa,27032,GRP_SPP_O,SPP_O,TIAM (NRCS plant code) -US-PFa,27327,GRP_SPP_O,SPP_O,TIAM (NRCS plant code) -US-PFa,27953,GRP_SPP_O,SPP_O,TSCA (NRCS plant code) -US-PFa,29147,GRP_SPP_O,SPP_O,TSCA (NRCS plant code) -US-PFa,26739,GRP_SPP_O,SPP_O,ULAM (NRCS plant code) -US-PFa,27331,GRP_SPP_O,SPP_O,ULTH (NRCS plant code) -US-PFa,27333,GRP_SPP_O,SPP_O,ULTH (NRCS plant code) -US-PFa,27331,GRP_SPP_O,SPP_O_PERC,0.001 -US-PFa,27585,GRP_SPP_O,SPP_O_PERC,0.004 -US-PFa,27028,GRP_SPP_O,SPP_O_PERC,0.005 -US-PFa,29498,GRP_SPP_O,SPP_O_PERC,0.008 -US-PFa,27032,GRP_SPP_O,SPP_O_PERC,0.013 -US-PFa,26887,GRP_SPP_O,SPP_O_PERC,0.017 -US-PFa,29155,GRP_SPP_O,SPP_O_PERC,0.017 -US-PFa,26886,GRP_SPP_O,SPP_O_PERC,0.021 -US-PFa,26741,GRP_SPP_O,SPP_O_PERC,0.028 -US-PFa,28309,GRP_SPP_O,SPP_O_PERC,0.054 -US-PFa,29501,GRP_SPP_O,SPP_O_PERC,0.054 -US-PFa,28570,GRP_SPP_O,SPP_O_PERC,0.059 -US-PFa,28569,GRP_SPP_O,SPP_O_PERC,0.062 -US-PFa,28568,GRP_SPP_O,SPP_O_PERC,0.064 -US-PFa,27333,GRP_SPP_O,SPP_O_PERC,0.077 -US-PFa,29152,GRP_SPP_O,SPP_O_PERC,0.078 -US-PFa,27584,GRP_SPP_O,SPP_O_PERC,0.098 -US-PFa,27031,GRP_SPP_O,SPP_O_PERC,0.105 -US-PFa,26739,GRP_SPP_O,SPP_O_PERC,0.114 -US-PFa,29151,GRP_SPP_O,SPP_O_PERC,0.194 -US-PFa,27030,GRP_SPP_O,SPP_O_PERC,0.205 -US-PFa,26738,GRP_SPP_O,SPP_O_PERC,0.3 -US-PFa,26884,GRP_SPP_O,SPP_O_PERC,0.301 -US-PFa,26878,GRP_SPP_O,SPP_O_PERC,0.343 -US-PFa,27027,GRP_SPP_O,SPP_O_PERC,0.371 -US-PFa,26883,GRP_SPP_O,SPP_O_PERC,0.426 -US-PFa,29148,GRP_SPP_O,SPP_O_PERC,0.619 -US-PFa,28311,GRP_SPP_O,SPP_O_PERC,0.662 -US-PFa,27953,GRP_SPP_O,SPP_O_PERC,0.779 -US-PFa,27329,GRP_SPP_O,SPP_O_PERC,0.813 -US-PFa,27948,GRP_SPP_O,SPP_O_PERC,0.853 -US-PFa,28565,GRP_SPP_O,SPP_O_PERC,0.943 -US-PFa,28217,GRP_SPP_O,SPP_O_PERC,1.028 -US-PFa,29147,GRP_SPP_O,SPP_O_PERC,1.047 -US-PFa,29038,GRP_SPP_O,SPP_O_PERC,1.054 -US-PFa,27583,GRP_SPP_O,SPP_O_PERC,1.089 -US-PFa,27026,GRP_SPP_O,SPP_O_PERC,1.425 -US-PFa,27952,GRP_SPP_O,SPP_O_PERC,1.553 -US-PFa,29040,GRP_SPP_O,SPP_O_PERC,1.587 -US-PFa,26876,GRP_SPP_O,SPP_O_PERC,1.676 -US-PFa,28551,GRP_SPP_O,SPP_O_PERC,1.79 -US-PFa,27951,GRP_SPP_O,SPP_O_PERC,10.251 -US-PFa,28307,GRP_SPP_O,SPP_O_PERC,12.987 -US-PFa,27581,GRP_SPP_O,SPP_O_PERC,17.377 -US-PFa,29500,GRP_SPP_O,SPP_O_PERC,2.065 -US-PFa,28550,GRP_SPP_O,SPP_O_PERC,2.181 -US-PFa,27025,GRP_SPP_O,SPP_O_PERC,2.628 -US-PFa,27582,GRP_SPP_O,SPP_O_PERC,2.887 -US-PFa,26875,GRP_SPP_O,SPP_O_PERC,20.06 -US-PFa,29039,GRP_SPP_O,SPP_O_PERC,3.63 -US-PFa,27024,GRP_SPP_O,SPP_O_PERC,3.887 -US-PFa,27328,GRP_SPP_O,SPP_O_PERC,4.739 -US-PFa,29499,GRP_SPP_O,SPP_O_PERC,4.891 -US-PFa,26881,GRP_SPP_O,SPP_O_PERC,4.968 -US-PFa,27950,GRP_SPP_O,SPP_O_PERC,41.523 -US-PFa,27327,GRP_SPP_O,SPP_O_PERC,6.232 -US-PFa,28553,GRP_SPP_O,SPP_O_PERC,6.531 -US-PFa,28308,GRP_SPP_O,SPP_O_PERC,7.638 -US-PFa,29497,GRP_SPP_O,SPP_O_PERC,7.722 -US-PFa,26880,GRP_SPP_O,SPP_O_PERC,8.911 -US-PFa,26879,GRP_SPP_O,SPP_O_PERC,8.955 -US-PFa,27948,GRP_SPP_O,SPP_COMMENT,"Alder, upland; Ryan Anderson, % based upon amount of measured biomass for each species. The WLEF tower reprsents multiple stand types (upland & wetland). Each stand has different species distribution" -US-PFa,29500,GRP_SPP_O,SPP_COMMENT,"Alder, wetland; Ryan Anderson, % based upon amount of measured biomass for each species. The WLEF tower reprsents multiple stand types (upland & wetland). Each stand has different species distribution" -US-PFa,26739,GRP_SPP_O,SPP_COMMENT,"American elm, upland; Ryan Anderson, % based upon amount of measured biomass for each species. The WLEF tower reprsents multiple stand types (upland & wetland). Each stand has different species distribution" -US-PFa,28308,GRP_SPP_O,SPP_COMMENT,"Balsam Fir, upland; Ryan Anderson, % based upon amount of measured biomass for each species. The WLEF tower reprsents multiple stand types (upland & wetland). Each stand has different species distribution" -US-PFa,26880,GRP_SPP_O,SPP_COMMENT,"Balsam Fir, wetland; Ryan Anderson, % based upon amount of measured biomass for each species. The WLEF tower reprsents multiple stand types (upland & wetland). Each stand has different species distribution" -US-PFa,27327,GRP_SPP_O,SPP_COMMENT,"Basswood, upland; Ryan Anderson, % based upon amount of measured biomass for each species. The WLEF tower reprsents multiple stand types (upland & wetland). Each stand has different species distribution" -US-PFa,27032,GRP_SPP_O,SPP_COMMENT,"Basswood, wetland; Ryan Anderson, % based upon amount of measured biomass for each species. The WLEF tower reprsents multiple stand types (upland & wetland). Each stand has different species distribution" -US-PFa,27329,GRP_SPP_O,SPP_COMMENT,"Bigooth Aspen, upland; Ryan Anderson, % based upon amount of measured biomass for each species. The WLEF tower reprsents multiple stand types (upland & wetland). Each stand has different species distribution" -US-PFa,28565,GRP_SPP_O,SPP_COMMENT,"Bigtooth Aspen, wetland; Ryan Anderson, % based upon amount of measured biomass for each species. The WLEF tower reprsents multiple stand types (upland & wetland). Each stand has different species distribution" -US-PFa,27582,GRP_SPP_O,SPP_COMMENT,"Black Ash, upland; Ryan Anderson, % based upon amount of measured biomass for each species. The WLEF tower reprsents multiple stand types (upland & wetland). Each stand has different species distribution" -US-PFa,27951,GRP_SPP_O,SPP_COMMENT,"Black Ash, wetland; Ryan Anderson, % based upon amount of measured biomass for each species. The WLEF tower reprsents multiple stand types (upland & wetland). Each stand has different species distribution" -US-PFa,29038,GRP_SPP_O,SPP_COMMENT,"Black Cherry, upland ; Ryan Anderson, % based upon amount of measured biomass for each species. The WLEF tower reprsents multiple stand types (upland & wetland). Each stand has different species distribution" -US-PFa,26884,GRP_SPP_O,SPP_COMMENT,"Black Cherry, wetland; Ryan Anderson, % based upon amount of measured biomass for each species. The WLEF tower reprsents multiple stand types (upland & wetland). Each stand has different species distribution" -US-PFa,27025,GRP_SPP_O,SPP_COMMENT,"Black Spruce, upland; Ryan Anderson, % based upon amount of measured biomass for each species. The WLEF tower reprsents multiple stand types (upland & wetland). Each stand has different species distribution" -US-PFa,26879,GRP_SPP_O,SPP_COMMENT,"Black Spruce, wetland; Ryan Anderson, % based upon amount of measured biomass for each species. The WLEF tower reprsents multiple stand types (upland & wetland). Each stand has different species distribution" -US-PFa,27031,GRP_SPP_O,SPP_COMMENT,"Dogwood, wetland; Ryan Anderson, % based upon amount of measured biomass for each species. The WLEF tower reprsents multiple stand types (upland & wetland). Each stand has different species distribution" -US-PFa,29147,GRP_SPP_O,SPP_COMMENT,"Eastern Hemlock, upland; Ryan Anderson, % based upon amount of measured biomass for each species. The WLEF tower reprsents multiple stand types (upland & wetland). Each stand has different species distribution" -US-PFa,27953,GRP_SPP_O,SPP_COMMENT,"Eastern Hemlock, wetland; Ryan Anderson, % based upon amount of measured biomass for each species. The WLEF tower reprsents multiple stand types (upland & wetland). Each stand has different species distribution" -US-PFa,26878,GRP_SPP_O,SPP_COMMENT,"Green Ash, upland; Ryan Anderson, % based upon amount of measured biomass for each species. The WLEF tower reprsents multiple stand types (upland & wetland). Each stand has different species distribution" -US-PFa,28217,GRP_SPP_O,SPP_COMMENT,"Green Ash, wetland; Ryan Anderson, % based upon amount of measured biomass for each species. The WLEF tower reprsents multiple stand types (upland & wetland). Each stand has different species distribution" -US-PFa,28568,GRP_SPP_O,SPP_COMMENT,"Hazelnut, wetland; Ryan Anderson, % based upon amount of measured biomass for each species. The WLEF tower reprsents multiple stand types (upland & wetland). Each stand has different species distribution" -US-PFa,27027,GRP_SPP_O,SPP_COMMENT,"Ironwood, upland; Ryan Anderson, % based upon amount of measured biomass for each species. The WLEF tower reprsents multiple stand types (upland & wetland). Each stand has different species distribution" -US-PFa,26887,GRP_SPP_O,SPP_COMMENT,"Ironwood, wetland; Ryan Anderson, % based upon amount of measured biomass for each species. The WLEF tower reprsents multiple stand types (upland & wetland). Each stand has different species distribution" -US-PFa,28551,GRP_SPP_O,SPP_COMMENT,"Jack Pine, upland; Ryan Anderson, % based upon amount of measured biomass for each species. The WLEF tower reprsents multiple stand types (upland & wetland). Each stand has different species distribution" -US-PFa,28311,GRP_SPP_O,SPP_COMMENT,"Jack Pine, wetland; Ryan Anderson, % based upon amount of measured biomass for each species. The WLEF tower reprsents multiple stand types (upland & wetland). Each stand has different species distribution" -US-PFa,27585,GRP_SPP_O,SPP_COMMENT,"Mountain Ash, wetland; Ryan Anderson, % based upon amount of measured biomass for each species. The WLEF tower reprsents multiple stand types (upland & wetland). Each stand has different species distribution" -US-PFa,26741,GRP_SPP_O,SPP_COMMENT,"Mountain Maple, wetland; Ryan Anderson, % based upon amount of measured biomass for each species. The WLEF tower reprsents multiple stand types (upland & wetland). Each stand has different species distribution" -US-PFa,27024,GRP_SPP_O,SPP_COMMENT,"N. White Cedar, upland; Ryan Anderson, % based upon amount of measured biomass for each species. The WLEF tower reprsents multiple stand types (upland & wetland). Each stand has different species distribution" -US-PFa,27950,GRP_SPP_O,SPP_COMMENT,"Northern White Cedar, wetland; Ryan Anderson, % based upon amount of measured biomass for each species. The WLEF tower reprsents multiple stand types (upland & wetland). Each stand has different species distribution" -US-PFa,27328,GRP_SPP_O,SPP_COMMENT,"Paper Birch, upland; Ryan Anderson, % based upon amount of measured biomass for each species. The WLEF tower reprsents multiple stand types (upland & wetland). Each stand has different species distribution" -US-PFa,29039,GRP_SPP_O,SPP_COMMENT,"Paper Birch, wetland; Ryan Anderson, % based upon amount of measured biomass for each species. The WLEF tower reprsents multiple stand types (upland & wetland). Each stand has different species distribution" -US-PFa,28309,GRP_SPP_O,SPP_COMMENT,"Pin Cherry, upland; Ryan Anderson, % based upon amount of measured biomass for each species. The WLEF tower reprsents multiple stand types (upland & wetland). Each stand has different species distribution" -US-PFa,29152,GRP_SPP_O,SPP_COMMENT,"Pin Cherry, wetland; Ryan Anderson, % based upon amount of measured biomass for each species. The WLEF tower reprsents multiple stand types (upland & wetland). Each stand has different species distribution" -US-PFa,27581,GRP_SPP_O,SPP_COMMENT,"Quaking aspen, upland; Ryan Anderson, % based upon amount of measured biomass for each species. The WLEF tower reprsents multiple stand types (upland & wetland). Each stand has different species distribution" -US-PFa,26881,GRP_SPP_O,SPP_COMMENT,"Quaking Aspen, wetland; Ryan Anderson, % based upon amount of measured biomass for each species. The WLEF tower reprsents multiple stand types (upland & wetland). Each stand has different species distribution" -US-PFa,29497,GRP_SPP_O,SPP_COMMENT,"Red Maple, upland; Ryan Anderson, % based upon amount of measured biomass for each species. The WLEF tower reprsents multiple stand types (upland & wetland). Each stand has different species distribution" -US-PFa,27952,GRP_SPP_O,SPP_COMMENT,"Red Maple, wetland; Ryan Anderson, % based upon amount of measured biomass for each species. The WLEF tower reprsents multiple stand types (upland & wetland). Each stand has different species distribution" -US-PFa,28307,GRP_SPP_O,SPP_COMMENT,"Red Pine, upland; Ryan Anderson, % based upon amount of measured biomass for each species. The WLEF tower reprsents multiple stand types (upland & wetland). Each stand has different species distribution" -US-PFa,29040,GRP_SPP_O,SPP_COMMENT,"Red Pine, wetland; Ryan Anderson, % based upon amount of measured biomass for each species. The WLEF tower reprsents multiple stand types (upland & wetland). Each stand has different species distribution" -US-PFa,26738,GRP_SPP_O,SPP_COMMENT,"River Birch, upland; Ryan Anderson, % based upon amount of measured biomass for each species. The WLEF tower reprsents multiple stand types (upland & wetland). Each stand has different species distribution" -US-PFa,27030,GRP_SPP_O,SPP_COMMENT,"River Birch, wetland; Ryan Anderson, % based upon amount of measured biomass for each species. The WLEF tower reprsents multiple stand types (upland & wetland). Each stand has different species distribution" -US-PFa,27331,GRP_SPP_O,SPP_COMMENT,"Rock Elm, upland; Ryan Anderson, % based upon amount of measured biomass for each species. The WLEF tower reprsents multiple stand types (upland & wetland). Each stand has different species distribution" -US-PFa,27333,GRP_SPP_O,SPP_COMMENT,"Rock Elm, wetland; Ryan Anderson, % based upon amount of measured biomass for each species. The WLEF tower reprsents multiple stand types (upland & wetland). Each stand has different species distribution" -US-PFa,26886,GRP_SPP_O,SPP_COMMENT,"Serviceberry, wetland; Ryan Anderson, % based upon amount of measured biomass for each species. The WLEF tower reprsents multiple stand types (upland & wetland). Each stand has different species distribution" -US-PFa,27584,GRP_SPP_O,SPP_COMMENT,"Silver Maple, upland; Ryan Anderson, % based upon amount of measured biomass for each species. The WLEF tower reprsents multiple stand types (upland & wetland). Each stand has different species distribution" -US-PFa,26875,GRP_SPP_O,SPP_COMMENT,"Sugar Maple, upland; Ryan Anderson, % based upon amount of measured biomass for each species. The WLEF tower reprsents multiple stand types (upland & wetland). Each stand has different species distribution" -US-PFa,29151,GRP_SPP_O,SPP_COMMENT,"Sugar Maple, wetland; Ryan Anderson, % based upon amount of measured biomass for each species. The WLEF tower reprsents multiple stand types (upland & wetland). Each stand has different species distribution" -US-PFa,29148,GRP_SPP_O,SPP_COMMENT,"Tamarack, upland; Ryan Anderson, % based upon amount of measured biomass for each species. The WLEF tower reprsents multiple stand types (upland & wetland). Each stand has different species distribution" -US-PFa,28553,GRP_SPP_O,SPP_COMMENT,"Tamarack, wetland; Ryan Anderson, % based upon amount of measured biomass for each species. The WLEF tower reprsents multiple stand types (upland & wetland). Each stand has different species distribution" -US-PFa,27583,GRP_SPP_O,SPP_COMMENT,"Unknown, upland; Ryan Anderson, % based upon amount of measured biomass for each species. The WLEF tower reprsents multiple stand types (upland & wetland). Each stand has different species distribution" -US-PFa,26883,GRP_SPP_O,SPP_COMMENT,"Unknown, wetland; Ryan Anderson, % based upon amount of measured biomass for each species. The WLEF tower reprsents multiple stand types (upland & wetland). Each stand has different species distribution" -US-PFa,29498,GRP_SPP_O,SPP_COMMENT,"White Ash, upland; Ryan Anderson, % based upon amount of measured biomass for each species. The WLEF tower reprsents multiple stand types (upland & wetland). Each stand has different species distribution" -US-PFa,28550,GRP_SPP_O,SPP_COMMENT,"White Pine, upland; Ryan Anderson, % based upon amount of measured biomass for each species. The WLEF tower reprsents multiple stand types (upland & wetland). Each stand has different species distribution" -US-PFa,28570,GRP_SPP_O,SPP_COMMENT,"White Pine, wetland; Ryan Anderson, % based upon amount of measured biomass for each species. The WLEF tower reprsents multiple stand types (upland & wetland). Each stand has different species distribution" -US-PFa,26876,GRP_SPP_O,SPP_COMMENT,"White Spruce, upland; Ryan Anderson, % based upon amount of measured biomass for each species. The WLEF tower reprsents multiple stand types (upland & wetland). Each stand has different species distribution" -US-PFa,29499,GRP_SPP_O,SPP_COMMENT,"White Spruce, wetland; Ryan Anderson, % based upon amount of measured biomass for each species. The WLEF tower reprsents multiple stand types (upland & wetland). Each stand has different species distribution" -US-PFa,27028,GRP_SPP_O,SPP_COMMENT,"Willow, upland; Ryan Anderson, % based upon amount of measured biomass for each species. The WLEF tower reprsents multiple stand types (upland & wetland). Each stand has different species distribution" -US-PFa,29501,GRP_SPP_O,SPP_COMMENT,"Willow, wetland; Ryan Anderson, % based upon amount of measured biomass for each species. The WLEF tower reprsents multiple stand types (upland & wetland). Each stand has different species distribution" -US-PFa,28569,GRP_SPP_O,SPP_COMMENT,"Winterberry, wetland; Ryan Anderson, % based upon amount of measured biomass for each species. The WLEF tower reprsents multiple stand types (upland & wetland). Each stand has different species distribution" -US-PFa,27026,GRP_SPP_O,SPP_COMMENT,"Yellow Birch, upland; Ryan Anderson, % based upon amount of measured biomass for each species. The WLEF tower reprsents multiple stand types (upland & wetland). Each stand has different species distribution" -US-PFa,29155,GRP_SPP_O,SPP_COMMENT,"Yellow Birch, wetland; Ryan Anderson, % based upon amount of measured biomass for each species. The WLEF tower reprsents multiple stand types (upland & wetland). Each stand has different species distribution" -US-PFa,15243,GRP_STATE,STATE,WI -US-PFa,15244,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Ankur Desai -US-PFa,15244,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-PFa,15244,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,desai@aos.wisc.edu -US-PFa,15244,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Wisconsin -US-PFa,15244,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Department of Atmospheric and Oceanic Sciences, 1225 W Dayton St, Madison, WI 53706" -US-PFa,15250,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Jonathan Thom -US-PFa,15250,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-PFa,15250,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,jthom@ssec.wisc.edu -US-PFa,15250,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Wisconsin -US-PFa,15250,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Space Sciences and Engineering, 1225 W Dayton St,Madison, WI 53706" -US-PFa,15253,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Arlyn E. Andrews -US-PFa,15253,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Affiliate -US-PFa,15253,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,arlyn.andrews@noaa.gov -US-PFa,15253,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,National Oceanic and Atmospheric Administration (NOAA) -US-PFa,15253,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"NOAA/ESRL Global Monitoring Division, CCGG, 325 Broadway, R/GMD1,Boulder, CO USA" -US-PFa,15258,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Dan Baumann -US-PFa,15258,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Affiliate -US-PFa,15258,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,dbaumann@usgs.gov -US-PFa,15258,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,USGS -US-PFa,15258,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"3654 Nursery Rd, Rhinelander, WI 53501" -US-PFa,15256,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Paul Bolstad -US-PFa,15256,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Affiliate -US-PFa,15256,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,pbolstad@umn.edu -US-PFa,15256,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Minnesota -US-PFa,15256,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Department of Forest Resources, 1530 N. Cleveland Ave.,St. Paul, MN USA 55108" -US-PFa,29830,GRP_TOWER_POWER,TOWER_POWER,Direct power -US-PFa,15245,GRP_TOWER_TYPE,TOWER_TYPE,other -US-PFa,15246,GRP_URL,URL,http://flux.aos.wisc.edu/twiki/bin/view/Main/ChEASData -US-PFa,24000412,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-PFa -US-PFa,15247,GRP_UTC_OFFSET,UTC_OFFSET,-6 -US-PFa,28208,GRP_WD_BIOMASS,WD_BIOMASS_CRS,244 -US-PFa,28207,GRP_WD_BIOMASS,WD_BIOMASS_CRS,998 -US-PFa,29031,GRP_WD_BIOMASS,WD_BIOMASS_CRS,998 -US-PFa,29491,GRP_WD_BIOMASS,WD_BIOMASS_CRS,998 -US-PFa,28207,GRP_WD_BIOMASS,WD_BIOMASS_UNIT,gC m-2 -US-PFa,28208,GRP_WD_BIOMASS,WD_BIOMASS_UNIT,gC m-2 -US-PFa,29031,GRP_WD_BIOMASS,WD_BIOMASS_UNIT,gC m-2 -US-PFa,29491,GRP_WD_BIOMASS,WD_BIOMASS_UNIT,gC m-2 -US-PFa,28208,GRP_WD_BIOMASS,WD_BIOMASS_DATE,2000 -US-PFa,29031,GRP_WD_BIOMASS,WD_BIOMASS_DATE,2004 -US-PFa,29491,GRP_WD_BIOMASS,WD_BIOMASS_DATE,2005 -US-PFa,28207,GRP_WD_BIOMASS,WD_BIOMASS_DATE,2006 -US-PFa,28207,GRP_WD_BIOMASS,WD_BIOMASS_COMMENT,998 (Dry Basis); 2004/2006 average from summer sampling; From Ryan Anderson -US-PFa,29031,GRP_WD_BIOMASS,WD_BIOMASS_COMMENT,998 (Dry Basis); 2004/2006 average from summer sampling; From Ryan Anderson -US-PFa,29491,GRP_WD_BIOMASS,WD_BIOMASS_COMMENT,998 (Dry Basis); 2004/2006 average from summer sampling; From Ryan Anderson -US-PFa,28208,GRP_WD_BIOMASS,WD_BIOMASS_COMMENT,"P. Bolstad, Taken at Willow Creek" -US-PFb,87419,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,Supported by National Science Foundation (NSF) Award #1822420 -US-PFb,87421,GRP_CLIM_AVG,MAT,4.33 -US-PFb,87421,GRP_CLIM_AVG,MAP,823 -US-PFb,87421,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfb -US-PFb,27001086,GRP_COUNTRY,COUNTRY,USA -US-PFb,94886,GRP_DOI,DOI,10.17190/AMF/1717850 -US-PFb,94886,GRP_DOI,DOI_CITATION,"Ankur Desai, Brian Butterworth, Steven Oncley (2020), AmeriFlux BASE US-PFb NW1 Pine-1 CHEESEHEAD 2019, Ver. 1-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1717850" -US-PFb,94886,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-PFb,95012,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-PFb,95012,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Ankur Desai -US-PFb,95012,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-PFb,95012,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,1 -US-PFb,95012,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0002-5226-6041 -US-PFb,95012,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,desai@aos.wisc.edu -US-PFb,95012,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of Wisconsin-Madison -US-PFb,95066,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-PFb,95066,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Brian Butterworth -US-PFb,95066,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-PFb,95066,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,2 -US-PFb,95066,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0002-8457-5308 -US-PFb,95066,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,bbutterworth@wisc.edu -US-PFb,95066,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of Wisconsin-Madison -US-PFb,95022,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-PFb,95022,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Steven Oncley -US-PFb,95022,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-PFb,95022,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,3 -US-PFb,95022,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,oncley@ucar.edu -US-PFb,95022,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,National Center for Atmospheric Research -US-PFb,94858,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,University of Wisconsin-Madison -US-PFb,94858,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-PFb,94852,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,National Science Foundation (NSF) -US-PFb,94852,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-PFb,91311,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-PFb,91311,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-PFb,91311,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20190624 -US-PFb,91311,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20191018 -US-PFb,91311,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-PFb,91462,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-PFb,91462,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-PFb,91462,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20190624 -US-PFb,91462,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20191018 -US-PFb,91462,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-PFb,91316,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-PFb,91316,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-PFb,91316,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20190624 -US-PFb,91316,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20191018 -US-PFb,91316,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-PFb,23001086,GRP_HEADER,SITE_NAME,NW1 Pine-1 CHEESEHEAD 2019 -US-PFb,87416,GRP_IGBP,IGBP,ENF -US-PFb,87417,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-PFb,87417,GRP_LAND_OWNERSHIP,LAND_OWNER,US Forest Service -US-PFb,87415,GRP_LOCATION,LOCATION_LAT,45.9720 -US-PFb,87415,GRP_LOCATION,LOCATION_LONG,-90.3232 -US-PFb,87415,GRP_LOCATION,LOCATION_ELEV,474 -US-PFb,87415,GRP_LOCATION,LOCATION_DATE_START,20190624 -US-PFb,87407,GRP_NETWORK,NETWORK,AmeriFlux -US-PFb,87413,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,This tower was erected as one of 19 towers installed in the Chequamegon-Nicolet National Forest for the summer and fall of 2019 as part of the CHEESEHEAD 2019 (Chequamegon Heterogeneous Ecosystem Energy-balance Study Enabled by a High-density Extensive Array of Detectors) project. -US-PFb,87406,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"1225 W Dayton St, Madison, WI 53706" -US-PFb,87422,GRP_SITE_CHAR,TERRAIN,"Medium Slope (>2 %, <5%)" -US-PFb,87422,GRP_SITE_CHAR,ASPECT,W -US-PFb,87422,GRP_SITE_CHAR,WIND_DIRECTION,SW -US-PFb,87422,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,125 -US-PFb,87412,GRP_SITE_DESC,SITE_DESC,"This tower (32m, trailer-based, telescoping) is the northwestern most tower in the 10 x 10km study domain. It is located in a red pine forest (canopy height ~25m). There is a regrowing/trap layer consisting of broadleaf aspen and other deciduous vegetation." -US-PFb,87414,GRP_SITE_FUNDING,SITE_FUNDING,National Science Foundation (NSF) -US-PFb,87411,GRP_STATE,STATE,WI -US-PFb,87402,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Ankur Desai -US-PFb,87402,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-PFb,87402,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,desai@aos.wisc.edu -US-PFb,87402,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Wisconsin-Madison -US-PFb,87402,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1225 W Dayton St, Madison, WI 53706" -US-PFb,87404,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Brian Butterworth -US-PFb,87404,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-PFb,87404,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,bbutterworth@wisc.edu -US-PFb,87404,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Wisconsin-Madison -US-PFb,87405,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Jonathan Thom -US-PFb,87405,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-PFb,87405,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,jthom@ssec.wisc.edu -US-PFb,87405,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Wisconsin-Madison -US-PFb,87403,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Steve Oncley -US-PFb,87403,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-PFb,87403,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,oncley@ucar.edu -US-PFb,87403,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,National Center for Atmospheric Research -US-PFb,87424,GRP_TOWER_POWER,TOWER_POWER,Other -US-PFb,87423,GRP_TOWER_TYPE,TOWER_TYPE,triangle -US-PFb,87418,GRP_URL,URL,https://www.eol.ucar.edu/field_projects/cheesehead -US-PFb,24001086,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-PFb -US-PFb,94192,GRP_UTC_OFFSET,UTC_OFFSET,-6 -US-PFc,87442,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,Supported by National Science Foundation (NSF) Award #1822420 -US-PFc,87444,GRP_CLIM_AVG,MAT,4.33 -US-PFc,87444,GRP_CLIM_AVG,MAP,823 -US-PFc,87444,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfb -US-PFc,27001087,GRP_COUNTRY,COUNTRY,USA -US-PFc,94887,GRP_DOI,DOI,10.17190/AMF/1717851 -US-PFc,94887,GRP_DOI,DOI_CITATION,"Ankur Desai, Brian Butterworth, Steven Oncley (2020), AmeriFlux BASE US-PFc NW2 Aspen-1 CHEESEHEAD 2019, Ver. 1-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1717851" -US-PFc,94887,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-PFc,95019,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-PFc,95019,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Ankur Desai -US-PFc,95019,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-PFc,95019,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,1 -US-PFc,95019,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0002-5226-6041 -US-PFc,95019,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,desai@aos.wisc.edu -US-PFc,95019,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of Wisconsin-Madison -US-PFc,95041,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-PFc,95041,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Brian Butterworth -US-PFc,95041,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-PFc,95041,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,2 -US-PFc,95041,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0002-8457-5308 -US-PFc,95041,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,bbutterworth@wisc.edu -US-PFc,95041,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of Wisconsin-Madison -US-PFc,95021,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-PFc,95021,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Steven Oncley -US-PFc,95021,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-PFc,95021,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,3 -US-PFc,95021,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,oncley@ucar.edu -US-PFc,95021,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,National Center for Atmospheric Research -US-PFc,94859,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,University of Wisconsin-Madison -US-PFc,94859,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-PFc,94853,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,National Science Foundation (NSF) -US-PFc,94853,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-PFc,91453,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-PFc,91453,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-PFc,91453,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20190624 -US-PFc,91453,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20191018 -US-PFc,91453,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-PFc,91402,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-PFc,91402,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-PFc,91402,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20190624 -US-PFc,91402,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20191018 -US-PFc,91402,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-PFc,91376,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-PFc,91376,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-PFc,91376,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20190624 -US-PFc,91376,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20191018 -US-PFc,91376,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-PFc,23001087,GRP_HEADER,SITE_NAME,NW2 Aspen-1 CHEESEHEAD 2019 -US-PFc,87439,GRP_IGBP,IGBP,DBF -US-PFc,87440,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-PFc,87440,GRP_LAND_OWNERSHIP,LAND_OWNER,US Forest Service -US-PFc,87438,GRP_LOCATION,LOCATION_LAT,45.9677 -US-PFc,87438,GRP_LOCATION,LOCATION_LONG,-90.3088 -US-PFc,87438,GRP_LOCATION,LOCATION_ELEV,473 -US-PFc,87438,GRP_LOCATION,LOCATION_DATE_START,20190624 -US-PFc,87430,GRP_NETWORK,NETWORK,AmeriFlux -US-PFc,87436,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,This tower was erected as one of 19 towers installed in the Chequamegon-Nicolet National Forest for the summer and fall of 2019 as part of the CHEESEHEAD 2019 (Chequamegon Heterogeneous Ecosystem Energy-balance Study Enabled by a High-density Extensive Array of Detectors) project. -US-PFc,87429,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"1225 W Dayton St, Madison, WI 53706" -US-PFc,87445,GRP_SITE_CHAR,TERRAIN,"Medium Slope (>2 %, <5%)" -US-PFc,87445,GRP_SITE_CHAR,ASPECT,SW -US-PFc,87445,GRP_SITE_CHAR,WIND_DIRECTION,SW -US-PFc,87435,GRP_SITE_DESC,SITE_DESC,This tower (12m Rohn) is located in the northwestern quadrant of the 10 x 10km study domain. It is located in a forest of short aspen (3m tall). Several older aspen and conifers are interspersed within the regrowing aspen forest (15-20m tall). -US-PFc,87437,GRP_SITE_FUNDING,SITE_FUNDING,National Science Foundation (NSF) -US-PFc,87434,GRP_STATE,STATE,WI -US-PFc,87425,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Ankur Desai -US-PFc,87425,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-PFc,87425,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,desai@aos.wisc.edu -US-PFc,87425,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Wisconsin-Madison -US-PFc,87425,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1225 W Dayton St, Madison, WI 53706" -US-PFc,87427,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Brian Butterworth -US-PFc,87427,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-PFc,87427,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,bbutterworth@wisc.edu -US-PFc,87427,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Wisconsin-Madison -US-PFc,87428,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Jonathan Thom -US-PFc,87428,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-PFc,87428,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,jthom@ssec.wisc.edu -US-PFc,87428,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Wisconsin-Madison -US-PFc,87426,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Steve Oncley -US-PFc,87426,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-PFc,87426,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,oncley@ucar.edu -US-PFc,87426,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,National Center for Atmospheric Research -US-PFc,87447,GRP_TOWER_POWER,TOWER_POWER,Other -US-PFc,87446,GRP_TOWER_TYPE,TOWER_TYPE,triangle -US-PFc,87441,GRP_URL,URL,https://www.eol.ucar.edu/field_projects/cheesehead -US-PFc,24001087,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-PFc -US-PFc,94188,GRP_UTC_OFFSET,UTC_OFFSET,-6 -US-PFd,87465,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,Supported by National Science Foundation (NSF) Award #1822420 -US-PFd,87467,GRP_CLIM_AVG,MAT,4.33 -US-PFd,87467,GRP_CLIM_AVG,MAP,823 -US-PFd,87467,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfb -US-PFd,27001088,GRP_COUNTRY,COUNTRY,USA -US-PFd,94893,GRP_DOI,DOI,10.17190/AMF/1717852 -US-PFd,94893,GRP_DOI,DOI_CITATION,"Ankur Desai, Brian Butterworth, Steven Oncley (2020), AmeriFlux BASE US-PFd NW3 Tussock-1 CHEESEHEAD 2019, Ver. 1-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1717852" -US-PFd,94893,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-PFd,95065,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-PFd,95065,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Ankur Desai -US-PFd,95065,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-PFd,95065,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,1 -US-PFd,95065,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0002-5226-6041 -US-PFd,95065,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,desai@aos.wisc.edu -US-PFd,95065,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of Wisconsin-Madison -US-PFd,94998,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-PFd,94998,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Brian Butterworth -US-PFd,94998,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-PFd,94998,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,2 -US-PFd,94998,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0002-8457-5308 -US-PFd,94998,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,bbutterworth@wisc.edu -US-PFd,94998,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of Wisconsin-Madison -US-PFd,95058,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-PFd,95058,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Steven Oncley -US-PFd,95058,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-PFd,95058,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,3 -US-PFd,95058,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,oncley@ucar.edu -US-PFd,95058,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,National Center for Atmospheric Research -US-PFd,94860,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,University of Wisconsin-Madison -US-PFd,94860,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-PFd,94840,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,National Science Foundation (NSF) -US-PFd,94840,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-PFd,91432,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-PFd,91432,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-PFd,91432,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20190624 -US-PFd,91432,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20191018 -US-PFd,91432,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-PFd,91321,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-PFd,91321,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-PFd,91321,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20190624 -US-PFd,91321,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20191018 -US-PFd,91321,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-PFd,91330,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-PFd,91330,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-PFd,91330,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20190624 -US-PFd,91330,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20191018 -US-PFd,91330,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-PFd,23001088,GRP_HEADER,SITE_NAME,NW3 Tussock-1 CHEESEHEAD 2019 -US-PFd,87462,GRP_IGBP,IGBP,WET -US-PFd,87463,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-PFd,87463,GRP_LAND_OWNERSHIP,LAND_OWNER,US Forest Service -US-PFd,87461,GRP_LOCATION,LOCATION_LAT,45.9689 -US-PFd,87461,GRP_LOCATION,LOCATION_LONG,-90.3010 -US-PFd,87461,GRP_LOCATION,LOCATION_ELEV,473 -US-PFd,87461,GRP_LOCATION,LOCATION_DATE_START,20190624 -US-PFd,87453,GRP_NETWORK,NETWORK,AmeriFlux -US-PFd,87459,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,This tower was erected as one of 19 towers installed in the Chequamegon-Nicolet National Forest for the summer and fall of 2019 as part of the CHEESEHEAD 2019 (Chequamegon Heterogeneous Ecosystem Energy-balance Study Enabled by a High-density Extensive Array of Detectors) project. -US-PFd,87452,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"1225 W Dayton St, Madison, WI 53706" -US-PFd,87468,GRP_SITE_CHAR,TERRAIN,Flat -US-PFd,87468,GRP_SITE_CHAR,ASPECT,FLAT -US-PFd,87468,GRP_SITE_CHAR,WIND_DIRECTION,SW -US-PFd,87458,GRP_SITE_DESC,SITE_DESC,This tower (3m tripod) is located in the northwestern quadrant of the 10 x 10km study domain. It is located in a tussock (1 - 1.5m tall grasses). There is a southwest-to-north-oriented stream that passes by the east side of the tower. -US-PFd,87460,GRP_SITE_FUNDING,SITE_FUNDING,National Science Foundation (NSF) -US-PFd,87457,GRP_STATE,STATE,WI -US-PFd,87448,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Ankur Desai -US-PFd,87448,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-PFd,87448,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,desai@aos.wisc.edu -US-PFd,87448,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Wisconsin-Madison -US-PFd,87448,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1225 W Dayton St, Madison, WI 53706" -US-PFd,87450,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Brian Butterworth -US-PFd,87450,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-PFd,87450,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,bbutterworth@wisc.edu -US-PFd,87450,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Wisconsin-Madison -US-PFd,87451,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Jonathan Thom -US-PFd,87451,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-PFd,87451,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,jthom@ssec.wisc.edu -US-PFd,87451,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Wisconsin-Madison -US-PFd,87449,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Steve Oncley -US-PFd,87449,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-PFd,87449,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,oncley@ucar.edu -US-PFd,87449,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,National Center for Atmospheric Research -US-PFd,87470,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-PFd,87469,GRP_TOWER_TYPE,TOWER_TYPE,tripod -US-PFd,87464,GRP_URL,URL,https://www.eol.ucar.edu/field_projects/cheesehead -US-PFd,24001088,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-PFd -US-PFd,94187,GRP_UTC_OFFSET,UTC_OFFSET,-6 -US-PFe,87488,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,Supported by National Science Foundation (NSF) Award #1822420 -US-PFe,87490,GRP_CLIM_AVG,MAT,4.33 -US-PFe,87490,GRP_CLIM_AVG,MAP,823 -US-PFe,87490,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfb -US-PFe,27001089,GRP_COUNTRY,COUNTRY,USA -US-PFe,94882,GRP_DOI,DOI,10.17190/AMF/1717853 -US-PFe,94882,GRP_DOI,DOI_CITATION,"Ankur Desai, Brian Butterworth, Steven Oncley (2020), AmeriFlux BASE US-PFe NW4 Lake-1 CHEESEHEAD 2019, Ver. 1-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1717853" -US-PFe,94882,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-PFe,95010,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-PFe,95010,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Ankur Desai -US-PFe,95010,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-PFe,95010,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,1 -US-PFe,95010,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0002-5226-6041 -US-PFe,95010,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,desai@aos.wisc.edu -US-PFe,95010,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of Wisconsin-Madison -US-PFe,95026,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-PFe,95026,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Brian Butterworth -US-PFe,95026,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-PFe,95026,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,2 -US-PFe,95026,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0002-8457-5308 -US-PFe,95026,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,bbutterworth@wisc.edu -US-PFe,95026,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of Wisconsin-Madison -US-PFe,95050,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-PFe,95050,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Steven Oncley -US-PFe,95050,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-PFe,95050,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,3 -US-PFe,95050,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,oncley@ucar.edu -US-PFe,95050,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,National Center for Atmospheric Research -US-PFe,94861,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,University of Wisconsin-Madison -US-PFe,94861,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-PFe,94839,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,National Science Foundation (NSF) -US-PFe,94839,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-PFe,91381,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-PFe,91381,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-PFe,91381,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20190624 -US-PFe,91381,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20191018 -US-PFe,91381,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-PFe,91423,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-PFe,91423,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-PFe,91423,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20190624 -US-PFe,91423,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20191018 -US-PFe,91423,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-PFe,91297,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-PFe,91297,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-PFe,91297,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20190624 -US-PFe,91297,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20191018 -US-PFe,91297,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-PFe,23001089,GRP_HEADER,SITE_NAME,NW4 Lake-1 CHEESEHEAD 2019 -US-PFe,87485,GRP_IGBP,IGBP,WAT -US-PFe,87486,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-PFe,87486,GRP_LAND_OWNERSHIP,LAND_OWNER,US Forest Service -US-PFe,87484,GRP_LOCATION,LOCATION_LAT,45.9793 -US-PFe,87484,GRP_LOCATION,LOCATION_LONG,-90.3004 -US-PFe,87484,GRP_LOCATION,LOCATION_ELEV,480 -US-PFe,87484,GRP_LOCATION,LOCATION_DATE_START,20190624 -US-PFe,87476,GRP_NETWORK,NETWORK,AmeriFlux -US-PFe,87482,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,This tower was erected as one of 19 towers installed in the Chequamegon-Nicolet National Forest for the summer and fall of 2019 as part of the CHEESEHEAD 2019 (Chequamegon Heterogeneous Ecosystem Energy-balance Study Enabled by a High-density Extensive Array of Detectors) project. -US-PFe,87475,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"1225 W Dayton St, Madison, WI 53706" -US-PFe,87491,GRP_SITE_CHAR,TERRAIN,"Medium Slope (>2 %, <5%)" -US-PFe,87491,GRP_SITE_CHAR,ASPECT,N -US-PFe,87491,GRP_SITE_CHAR,WIND_DIRECTION,SW -US-PFe,87481,GRP_SITE_DESC,SITE_DESC,"This tower (32m, trailer-based, telescoping) is located in the northwestern quadrant of the 10 x 10km study domain. It is located in a red pine and aspen forest (20.1 m height) on the bank of a lake (500m across)." -US-PFe,87483,GRP_SITE_FUNDING,SITE_FUNDING,National Science Foundation (NSF) -US-PFe,87480,GRP_STATE,STATE,WI -US-PFe,87471,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Ankur Desai -US-PFe,87471,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-PFe,87471,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,desai@aos.wisc.edu -US-PFe,87471,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Wisconsin-Madison -US-PFe,87471,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1225 W Dayton St, Madison, WI 53706" -US-PFe,87473,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Brian Butterworth -US-PFe,87473,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-PFe,87473,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,bbutterworth@wisc.edu -US-PFe,87473,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Wisconsin-Madison -US-PFe,87474,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Jonathan Thom -US-PFe,87474,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-PFe,87474,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,jthom@ssec.wisc.edu -US-PFe,87474,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Wisconsin-Madison -US-PFe,87472,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Steve Oncley -US-PFe,87472,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-PFe,87472,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,oncley@ucar.edu -US-PFe,87472,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,National Center for Atmospheric Research -US-PFe,87493,GRP_TOWER_POWER,TOWER_POWER,Other -US-PFe,87492,GRP_TOWER_TYPE,TOWER_TYPE,triangle -US-PFe,87487,GRP_URL,URL,https://www.eol.ucar.edu/field_projects/cheesehead -US-PFe,24001089,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-PFe -US-PFe,94205,GRP_UTC_OFFSET,UTC_OFFSET,-6 -US-PFf,87511,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,Supported by National Science Foundation (NSF) Award #1822420 -US-PFf,87513,GRP_CLIM_AVG,MAT,4.33 -US-PFf,87513,GRP_CLIM_AVG,MAP,823 -US-PFf,87513,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfb -US-PFf,27001090,GRP_COUNTRY,COUNTRY,USA -US-PFf,91371,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-PFf,91371,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-PFf,91371,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20190620 -US-PFf,91371,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20191018 -US-PFf,91371,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-PFf,91380,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-PFf,91380,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-PFf,91380,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20190620 -US-PFf,91380,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20191018 -US-PFf,91380,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-PFf,91318,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-PFf,91318,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-PFf,91318,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20190620 -US-PFf,91318,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20191018 -US-PFf,91318,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-PFf,23001090,GRP_HEADER,SITE_NAME,NW5 Grass-1 CHEESEHEAD 2019 -US-PFf,87508,GRP_IGBP,IGBP,GRA -US-PFf,87509,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -US-PFf,87509,GRP_LAND_OWNERSHIP,LAND_OWNER,Ann Wojcieszak -US-PFf,87507,GRP_LOCATION,LOCATION_LAT,45.9458 -US-PFf,87507,GRP_LOCATION,LOCATION_LONG,-90.2944 -US-PFf,87507,GRP_LOCATION,LOCATION_ELEV,464 -US-PFf,87507,GRP_LOCATION,LOCATION_DATE_START,20190620 -US-PFf,87499,GRP_NETWORK,NETWORK,AmeriFlux -US-PFf,87505,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,This tower was erected as one of 19 towers installed in the Chequamegon-Nicolet National Forest for the summer and fall of 2019 as part of the CHEESEHEAD 2019 (Chequamegon Heterogeneous Ecosystem Energy-balance Study Enabled by a High-density Extensive Array of Detectors) project. -US-PFf,87498,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"1225 W Dayton St, Madison, WI 53706" -US-PFf,87514,GRP_SITE_CHAR,TERRAIN,Flat -US-PFf,87514,GRP_SITE_CHAR,ASPECT,FLAT -US-PFf,87514,GRP_SITE_CHAR,WIND_DIRECTION,SW -US-PFf,87504,GRP_SITE_DESC,SITE_DESC,This tower (2m tripod) is located in the northwestern quadrant of the 10 x 10km study domain. It is located in a grassy field. It is ocassionally mowed. It was located near (~200m) several different types of sounding systems. -US-PFf,87506,GRP_SITE_FUNDING,SITE_FUNDING,National Science Foundation (NSF) -US-PFf,87503,GRP_STATE,STATE,WI -US-PFf,87494,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Ankur Desai -US-PFf,87494,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-PFf,87494,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,desai@aos.wisc.edu -US-PFf,87494,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Wisconsin-Madison -US-PFf,87494,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1225 W Dayton St, Madison, WI 53706" -US-PFf,87496,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Brian Butterworth -US-PFf,87496,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-PFf,87496,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,bbutterworth@wisc.edu -US-PFf,87496,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Wisconsin-Madison -US-PFf,87497,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Jonathan Thom -US-PFf,87497,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-PFf,87497,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,jthom@ssec.wisc.edu -US-PFf,87497,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Wisconsin-Madison -US-PFf,87495,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Paul Stoy -US-PFf,87495,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-PFf,87495,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,paul.stoy@montana.edu -US-PFf,87495,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Montana State University -US-PFf,87516,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-PFf,87515,GRP_TOWER_TYPE,TOWER_TYPE,tripod -US-PFf,87510,GRP_URL,URL,https://www.eol.ucar.edu/field_projects/cheesehead -US-PFf,24001090,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-PFf -US-PFf,94200,GRP_UTC_OFFSET,UTC_OFFSET,-6 -US-PFg,87521,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,Supported by National Science Foundation (NSF) Award #1822420 -US-PFg,87523,GRP_CLIM_AVG,MAT,4.33 -US-PFg,87523,GRP_CLIM_AVG,MAP,823 -US-PFg,87523,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfb -US-PFg,27001091,GRP_COUNTRY,COUNTRY,USA -US-PFg,94894,GRP_DOI,DOI,10.17190/AMF/1717854 -US-PFg,94894,GRP_DOI,DOI_CITATION,"Ankur Desai, Brian Butterworth, Steven Oncley (2020), AmeriFlux BASE US-PFg NE1 Pine-2 CHEESEHEAD 2019, Ver. 1-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1717854" -US-PFg,94894,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-PFg,95054,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-PFg,95054,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Ankur Desai -US-PFg,95054,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-PFg,95054,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,1 -US-PFg,95054,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0002-5226-6041 -US-PFg,95054,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,desai@aos.wisc.edu -US-PFg,95054,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of Wisconsin-Madison -US-PFg,95011,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-PFg,95011,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Brian Butterworth -US-PFg,95011,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-PFg,95011,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,2 -US-PFg,95011,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0002-8457-5308 -US-PFg,95011,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,bbutterworth@wisc.edu -US-PFg,95011,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of Wisconsin-Madison -US-PFg,95008,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-PFg,95008,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Steven Oncley -US-PFg,95008,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-PFg,95008,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,3 -US-PFg,95008,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,oncley@ucar.edu -US-PFg,95008,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,National Center for Atmospheric Research -US-PFg,94862,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,University of Wisconsin-Madison -US-PFg,94862,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-PFg,94848,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,National Science Foundation (NSF) -US-PFg,94848,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-PFg,91403,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-PFg,91403,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-PFg,91403,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20190624 -US-PFg,91403,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20191018 -US-PFg,91403,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-PFg,91434,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-PFg,91434,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-PFg,91434,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20190624 -US-PFg,91434,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20191018 -US-PFg,91434,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-PFg,91327,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-PFg,91327,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-PFg,91327,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20190624 -US-PFg,91327,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20191018 -US-PFg,91327,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-PFg,23001091,GRP_HEADER,SITE_NAME,NE1 Pine-2 CHEESEHEAD 2019 -US-PFg,87518,GRP_IGBP,IGBP,ENF -US-PFg,87519,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-PFg,87519,GRP_LAND_OWNERSHIP,LAND_OWNER,US Forest Service -US-PFg,87517,GRP_LOCATION,LOCATION_LAT,45.9735 -US-PFg,87517,GRP_LOCATION,LOCATION_LONG,-90.2723 -US-PFg,87517,GRP_LOCATION,LOCATION_ELEV,475 -US-PFg,87517,GRP_LOCATION,LOCATION_DATE_START,20190624 -US-PFg,87543,GRP_NETWORK,NETWORK,AmeriFlux -US-PFg,87536,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,This tower was erected as one of 19 towers installed in the Chequamegon-Nicolet National Forest for the summer and fall of 2019 as part of the CHEESEHEAD 2019 (Chequamegon Heterogeneous Ecosystem Energy-balance Study Enabled by a High-density Extensive Array of Detectors) project. -US-PFg,87542,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"1225 W Dayton St, Madison, WI 53706" -US-PFg,87524,GRP_SITE_CHAR,TERRAIN,Flat -US-PFg,87524,GRP_SITE_CHAR,ASPECT,FLAT -US-PFg,87524,GRP_SITE_CHAR,WIND_DIRECTION,SW -US-PFg,87535,GRP_SITE_DESC,SITE_DESC,"This tower (32m, trailer-based, telescoping) is located in the northeastern quadrant of the 10 x 10km study domain. It is located in a forest with red pine (~32m) overstory and maple (10-15m) understory." -US-PFg,87537,GRP_SITE_FUNDING,SITE_FUNDING,National Science Foundation (NSF) -US-PFg,87534,GRP_STATE,STATE,WI -US-PFg,87538,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Ankur Desai -US-PFg,87538,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-PFg,87538,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,desai@aos.wisc.edu -US-PFg,87538,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Wisconsin-Madison -US-PFg,87538,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1225 W Dayton St, Madison, WI 53706" -US-PFg,87540,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Brian Butterworth -US-PFg,87540,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-PFg,87540,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,bbutterworth@wisc.edu -US-PFg,87540,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Wisconsin-Madison -US-PFg,87541,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Jonathan Thom -US-PFg,87541,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-PFg,87541,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,jthom@ssec.wisc.edu -US-PFg,87541,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Wisconsin-Madison -US-PFg,87539,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Steve Oncley -US-PFg,87539,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-PFg,87539,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,oncley@ucar.edu -US-PFg,87539,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,National Center for Atmospheric Research -US-PFg,87526,GRP_TOWER_POWER,TOWER_POWER,Other -US-PFg,87525,GRP_TOWER_TYPE,TOWER_TYPE,triangle -US-PFg,87520,GRP_URL,URL,https://www.eol.ucar.edu/field_projects/cheesehead -US-PFg,24001091,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-PFg -US-PFg,94195,GRP_UTC_OFFSET,UTC_OFFSET,-6 -US-PFh,87561,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,Supported by National Science Foundation (NSF) Award #1822420 -US-PFh,87563,GRP_CLIM_AVG,MAT,4.33 -US-PFh,87563,GRP_CLIM_AVG,MAP,823 -US-PFh,87563,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfb -US-PFh,27001092,GRP_COUNTRY,COUNTRY,USA -US-PFh,94888,GRP_DOI,DOI,10.17190/AMF/1717855 -US-PFh,94888,GRP_DOI,DOI_CITATION,"Ankur Desai, Brian Butterworth, Steven Oncley (2020), AmeriFlux BASE US-PFh NE2 Pine-3 CHEESEHEAD 2019, Ver. 1-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1717855" -US-PFh,94888,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-PFh,95016,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-PFh,95016,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Ankur Desai -US-PFh,95016,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-PFh,95016,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,1 -US-PFh,95016,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0002-5226-6041 -US-PFh,95016,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,desai@aos.wisc.edu -US-PFh,95016,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of Wisconsin-Madison -US-PFh,94994,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-PFh,94994,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Brian Butterworth -US-PFh,94994,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-PFh,94994,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,2 -US-PFh,94994,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0002-8457-5308 -US-PFh,94994,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,bbutterworth@wisc.edu -US-PFh,94994,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of Wisconsin-Madison -US-PFh,95029,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-PFh,95029,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Steven Oncley -US-PFh,95029,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-PFh,95029,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,3 -US-PFh,95029,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,oncley@ucar.edu -US-PFh,95029,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,National Center for Atmospheric Research -US-PFh,94863,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,University of Wisconsin-Madison -US-PFh,94863,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-PFh,94849,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,National Science Foundation (NSF) -US-PFh,94849,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-PFh,91373,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-PFh,91373,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-PFh,91373,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20190624 -US-PFh,91373,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20191018 -US-PFh,91373,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-PFh,91338,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-PFh,91338,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-PFh,91338,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20190624 -US-PFh,91338,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20191018 -US-PFh,91338,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-PFh,91322,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-PFh,91322,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-PFh,91322,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20190624 -US-PFh,91322,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20191018 -US-PFh,91322,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-PFh,23001092,GRP_HEADER,SITE_NAME,NE2 Pine-3 CHEESEHEAD 2019 -US-PFh,87558,GRP_IGBP,IGBP,ENF -US-PFh,87559,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-PFh,87559,GRP_LAND_OWNERSHIP,LAND_OWNER,US Forest Service -US-PFh,87557,GRP_LOCATION,LOCATION_LAT,45.9557 -US-PFh,87557,GRP_LOCATION,LOCATION_LONG,-90.2406 -US-PFh,87557,GRP_LOCATION,LOCATION_ELEV,463 -US-PFh,87557,GRP_LOCATION,LOCATION_DATE_START,20190624 -US-PFh,87549,GRP_NETWORK,NETWORK,AmeriFlux -US-PFh,87555,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,This tower was erected as one of 19 towers installed in the Chequamegon-Nicolet National Forest for the summer and fall of 2019 as part of the CHEESEHEAD 2019 (Chequamegon Heterogeneous Ecosystem Energy-balance Study Enabled by a High-density Extensive Array of Detectors) project. -US-PFh,87548,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"1225 W Dayton St, Madison, WI 53706" -US-PFh,87564,GRP_SITE_CHAR,TERRAIN,Flat -US-PFh,87564,GRP_SITE_CHAR,ASPECT,FLAT -US-PFh,87564,GRP_SITE_CHAR,WIND_DIRECTION,SW -US-PFh,87554,GRP_SITE_DESC,SITE_DESC,"This tower (32m, trailer-based, telescoping) is located in the northeastern quadrant of the 10 x 10km study domain. It is located in a forest jack pine forest (18 - 20m), with some aspens." -US-PFh,87556,GRP_SITE_FUNDING,SITE_FUNDING,National Science Foundation (NSF) -US-PFh,87553,GRP_STATE,STATE,WI -US-PFh,87544,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Ankur Desai -US-PFh,87544,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-PFh,87544,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,desai@aos.wisc.edu -US-PFh,87544,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Wisconsin-Madison -US-PFh,87544,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1225 W Dayton St, Madison, WI 53706" -US-PFh,87546,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Brian Butterworth -US-PFh,87546,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-PFh,87546,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,bbutterworth@wisc.edu -US-PFh,87546,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Wisconsin-Madison -US-PFh,87547,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Jonathan Thom -US-PFh,87547,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-PFh,87547,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,jthom@ssec.wisc.edu -US-PFh,87547,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Wisconsin-Madison -US-PFh,87545,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Steve Oncley -US-PFh,87545,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-PFh,87545,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,oncley@ucar.edu -US-PFh,87545,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,National Center for Atmospheric Research -US-PFh,87566,GRP_TOWER_POWER,TOWER_POWER,Other -US-PFh,87565,GRP_TOWER_TYPE,TOWER_TYPE,triangle -US-PFh,87560,GRP_URL,URL,https://www.eol.ucar.edu/field_projects/cheesehead -US-PFh,24001092,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-PFh -US-PFh,94198,GRP_UTC_OFFSET,UTC_OFFSET,-6 -US-PFi,87527,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,Supported by National Science Foundation (NSF) Award #1822420 -US-PFi,87529,GRP_CLIM_AVG,MAT,4.33 -US-PFi,87529,GRP_CLIM_AVG,MAP,823 -US-PFi,87529,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfb -US-PFi,27001093,GRP_COUNTRY,COUNTRY,USA -US-PFi,94885,GRP_DOI,DOI,10.17190/AMF/1717856 -US-PFi,94885,GRP_DOI,DOI_CITATION,"Ankur Desai, Brian Butterworth, Steven Oncley (2020), AmeriFlux BASE US-PFi NE3 Hardwood-1 CHEESEHEAD 2019, Ver. 1-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1717856" -US-PFi,94885,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-PFi,95003,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-PFi,95003,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Ankur Desai -US-PFi,95003,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-PFi,95003,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,1 -US-PFi,95003,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0002-5226-6041 -US-PFi,95003,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,desai@aos.wisc.edu -US-PFi,95003,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of Wisconsin-Madison -US-PFi,95046,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-PFi,95046,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Brian Butterworth -US-PFi,95046,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-PFi,95046,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,2 -US-PFi,95046,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0002-8457-5308 -US-PFi,95046,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,bbutterworth@wisc.edu -US-PFi,95046,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of Wisconsin-Madison -US-PFi,95057,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-PFi,95057,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Steven Oncley -US-PFi,95057,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-PFi,95057,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,3 -US-PFi,95057,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,oncley@ucar.edu -US-PFi,95057,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,National Center for Atmospheric Research -US-PFi,94864,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,University of Wisconsin-Madison -US-PFi,94864,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-PFi,94847,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,National Science Foundation (NSF) -US-PFi,94847,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-PFi,91345,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-PFi,91345,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-PFi,91345,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20190624 -US-PFi,91345,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20191018 -US-PFi,91345,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-PFi,91375,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-PFi,91375,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-PFi,91375,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20190624 -US-PFi,91375,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20191018 -US-PFi,91375,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-PFi,91468,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-PFi,91468,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-PFi,91468,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20190624 -US-PFi,91468,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20191018 -US-PFi,91468,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-PFi,23001093,GRP_HEADER,SITE_NAME,NE3 Hardwood-1 CHEESEHEAD 2019 -US-PFi,87581,GRP_IGBP,IGBP,DBF -US-PFi,87582,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-PFi,87582,GRP_LAND_OWNERSHIP,LAND_OWNER,US Forest Service -US-PFi,87580,GRP_LOCATION,LOCATION_LAT,45.9749 -US-PFi,87580,GRP_LOCATION,LOCATION_LONG,-90.2327 -US-PFi,87580,GRP_LOCATION,LOCATION_ELEV,488 -US-PFi,87580,GRP_LOCATION,LOCATION_DATE_START,20190624 -US-PFi,87572,GRP_NETWORK,NETWORK,AmeriFlux -US-PFi,87578,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,This tower was erected as one of 19 towers installed in the Chequamegon-Nicolet National Forest for the summer and fall of 2019 as part of the CHEESEHEAD 2019 (Chequamegon Heterogeneous Ecosystem Energy-balance Study Enabled by a High-density Extensive Array of Detectors) project. -US-PFi,87571,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"1225 W Dayton St, Madison, WI 53706" -US-PFi,87583,GRP_SITE_CHAR,TERRAIN,"Medium Slope (>2 %, <5%)" -US-PFi,87583,GRP_SITE_CHAR,ASPECT,W -US-PFi,87583,GRP_SITE_CHAR,WIND_DIRECTION,SW -US-PFi,87577,GRP_SITE_DESC,SITE_DESC,"This tower (32m, trailer-based, telescoping) is located in the northeastern quadrant of the 10 x 10km study domain. It is located in a mixed hardwood forest (canopy height: 18 - 20m)." -US-PFi,87579,GRP_SITE_FUNDING,SITE_FUNDING,National Science Foundation (NSF) -US-PFi,87576,GRP_STATE,STATE,WI -US-PFi,87567,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Ankur Desai -US-PFi,87567,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-PFi,87567,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,desai@aos.wisc.edu -US-PFi,87567,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Wisconsin-Madison -US-PFi,87567,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1225 W Dayton St, Madison, WI 53706" -US-PFi,87569,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Brian Butterworth -US-PFi,87569,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-PFi,87569,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,bbutterworth@wisc.edu -US-PFi,87569,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Wisconsin-Madison -US-PFi,87570,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Jonathan Thom -US-PFi,87570,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-PFi,87570,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,jthom@ssec.wisc.edu -US-PFi,87570,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Wisconsin-Madison -US-PFi,87568,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Steve Oncley -US-PFi,87568,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-PFi,87568,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,oncley@ucar.edu -US-PFi,87568,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,National Center for Atmospheric Research -US-PFi,87585,GRP_TOWER_POWER,TOWER_POWER,Other -US-PFi,87584,GRP_TOWER_TYPE,TOWER_TYPE,triangle -US-PFi,87532,GRP_URL,URL,https://www.eol.ucar.edu/field_projects/cheesehead -US-PFi,24001093,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-PFi -US-PFi,94183,GRP_UTC_OFFSET,UTC_OFFSET,-6 -US-PFj,87607,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,Supported by National Science Foundation (NSF) Award #1822420 -US-PFj,87586,GRP_CLIM_AVG,MAT,4.33 -US-PFj,87586,GRP_CLIM_AVG,MAP,823 -US-PFj,87586,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfb -US-PFj,27001094,GRP_COUNTRY,COUNTRY,USA -US-PFj,94889,GRP_DOI,DOI,10.17190/AMF/1717857 -US-PFj,94889,GRP_DOI,DOI_CITATION,"Ankur Desai, Brian Butterworth, Steven Oncley (2020), AmeriFlux BASE US-PFj NE4 Maple-1 CHEESEHEAD 2019, Ver. 1-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1717857" -US-PFj,94889,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-PFj,95070,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-PFj,95070,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Ankur Desai -US-PFj,95070,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-PFj,95070,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,1 -US-PFj,95070,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0002-5226-6041 -US-PFj,95070,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,desai@aos.wisc.edu -US-PFj,95070,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of Wisconsin-Madison -US-PFj,95051,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-PFj,95051,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Brian Butterworth -US-PFj,95051,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-PFj,95051,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,2 -US-PFj,95051,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0002-8457-5308 -US-PFj,95051,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,bbutterworth@wisc.edu -US-PFj,95051,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of Wisconsin-Madison -US-PFj,95000,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-PFj,95000,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Steven Oncley -US-PFj,95000,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-PFj,95000,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,3 -US-PFj,95000,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,oncley@ucar.edu -US-PFj,95000,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,National Center for Atmospheric Research -US-PFj,94865,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,University of Wisconsin-Madison -US-PFj,94865,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-PFj,94850,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,National Science Foundation (NSF) -US-PFj,94850,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-PFj,91433,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-PFj,91433,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-PFj,91433,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20190624 -US-PFj,91433,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20191018 -US-PFj,91433,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-PFj,91440,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-PFj,91440,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-PFj,91440,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20190624 -US-PFj,91440,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20191018 -US-PFj,91440,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-PFj,91425,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-PFj,91425,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-PFj,91425,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20190624 -US-PFj,91425,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20191018 -US-PFj,91425,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-PFj,23001094,GRP_HEADER,SITE_NAME,NE4 Maple-1 CHEESEHEAD 2019 -US-PFj,87604,GRP_IGBP,IGBP,DBF -US-PFj,87605,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-PFj,87605,GRP_LAND_OWNERSHIP,LAND_OWNER,US Forest Service -US-PFj,87603,GRP_LOCATION,LOCATION_LAT,45.9619 -US-PFj,87603,GRP_LOCATION,LOCATION_LONG,-90.2270 -US-PFj,87603,GRP_LOCATION,LOCATION_ELEV,484 -US-PFj,87603,GRP_LOCATION,LOCATION_DATE_START,20190624 -US-PFj,87595,GRP_NETWORK,NETWORK,AmeriFlux -US-PFj,87601,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,This tower was erected as one of 19 towers installed in the Chequamegon-Nicolet National Forest for the summer and fall of 2019 as part of the CHEESEHEAD 2019 (Chequamegon Heterogeneous Ecosystem Energy-balance Study Enabled by a High-density Extensive Array of Detectors) project. -US-PFj,87594,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"1225 W Dayton St, Madison, WI 53706" -US-PFj,87587,GRP_SITE_CHAR,TERRAIN,"Medium Slope (>2 %, <5%)" -US-PFj,87587,GRP_SITE_CHAR,ASPECT,W -US-PFj,87587,GRP_SITE_CHAR,WIND_DIRECTION,SW -US-PFj,87600,GRP_SITE_DESC,SITE_DESC,"This tower (32m, trailer-based, telescoping) is located in the northeastern quadrant of the 10 x 10km study domain. It is located in a maple forest (canopy height: 18 - 20m). Some conifers mixed in, more conifers to the NNW." -US-PFj,87602,GRP_SITE_FUNDING,SITE_FUNDING,National Science Foundation (NSF) -US-PFj,87599,GRP_STATE,STATE,WI -US-PFj,87590,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Ankur Desai -US-PFj,87590,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-PFj,87590,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,desai@aos.wisc.edu -US-PFj,87590,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Wisconsin-Madison -US-PFj,87590,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1225 W Dayton St, Madison, WI 53706" -US-PFj,87592,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Brian Butterworth -US-PFj,87592,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-PFj,87592,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,bbutterworth@wisc.edu -US-PFj,87592,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Wisconsin-Madison -US-PFj,87593,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Jonathan Thom -US-PFj,87593,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-PFj,87593,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,jthom@ssec.wisc.edu -US-PFj,87593,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Wisconsin-Madison -US-PFj,87591,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Steve Oncley -US-PFj,87591,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-PFj,87591,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,oncley@ucar.edu -US-PFj,87591,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,National Center for Atmospheric Research -US-PFj,87589,GRP_TOWER_POWER,TOWER_POWER,Other -US-PFj,87588,GRP_TOWER_TYPE,TOWER_TYPE,triangle -US-PFj,87606,GRP_URL,URL,https://www.eol.ucar.edu/field_projects/cheesehead -US-PFj,24001094,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-PFj -US-PFj,94196,GRP_UTC_OFFSET,UTC_OFFSET,-6 -US-PFk,87626,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,Supported by National Science Foundation (NSF) Award #1822420 -US-PFk,87628,GRP_CLIM_AVG,MAT,4.33 -US-PFk,87628,GRP_CLIM_AVG,MAP,823 -US-PFk,87628,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfb -US-PFk,27001095,GRP_COUNTRY,COUNTRY,USA -US-PFk,94896,GRP_DOI,DOI,10.17190/AMF/1717858 -US-PFk,94896,GRP_DOI,DOI_CITATION,"Ankur Desai, Brian Butterworth, Steven Oncley (2020), AmeriFlux BASE US-PFk SW1 Aspen-2 CHEESEHEAD 2019, Ver. 1-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1717858" -US-PFk,94896,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-PFk,94995,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-PFk,94995,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Ankur Desai -US-PFk,94995,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-PFk,94995,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,1 -US-PFk,94995,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0002-5226-6041 -US-PFk,94995,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,desai@aos.wisc.edu -US-PFk,94995,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of Wisconsin-Madison -US-PFk,95030,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-PFk,95030,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Brian Butterworth -US-PFk,95030,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-PFk,95030,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,2 -US-PFk,95030,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0002-8457-5308 -US-PFk,95030,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,bbutterworth@wisc.edu -US-PFk,95030,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of Wisconsin-Madison -US-PFk,95015,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-PFk,95015,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Steven Oncley -US-PFk,95015,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-PFk,95015,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,3 -US-PFk,95015,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,oncley@ucar.edu -US-PFk,95015,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,National Center for Atmospheric Research -US-PFk,94866,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,University of Wisconsin-Madison -US-PFk,94866,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-PFk,94843,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,National Science Foundation (NSF) -US-PFk,94843,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-PFk,91313,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-PFk,91313,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-PFk,91313,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20190624 -US-PFk,91313,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20191018 -US-PFk,91313,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-PFk,91326,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-PFk,91326,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-PFk,91326,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20190624 -US-PFk,91326,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20191018 -US-PFk,91326,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-PFk,91467,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-PFk,91467,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-PFk,91467,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20190624 -US-PFk,91467,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20191018 -US-PFk,91467,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-PFk,23001095,GRP_HEADER,SITE_NAME,SW1 Aspen-2 CHEESEHEAD 2019 -US-PFk,87623,GRP_IGBP,IGBP,DBF -US-PFk,87624,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-PFk,87624,GRP_LAND_OWNERSHIP,LAND_OWNER,US Forest Service -US-PFk,87622,GRP_LOCATION,LOCATION_LAT,45.9149 -US-PFk,87622,GRP_LOCATION,LOCATION_LONG,-90.3425 -US-PFk,87622,GRP_LOCATION,LOCATION_ELEV,476 -US-PFk,87622,GRP_LOCATION,LOCATION_DATE_START,20190624 -US-PFk,87614,GRP_NETWORK,NETWORK,AmeriFlux -US-PFk,87620,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,This tower was erected as one of 19 towers installed in the Chequamegon-Nicolet National Forest for the summer and fall of 2019 as part of the CHEESEHEAD 2019 (Chequamegon Heterogeneous Ecosystem Energy-balance Study Enabled by a High-density Extensive Array of Detectors) project. -US-PFk,87613,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"1225 W Dayton St, Madison, WI 53706" -US-PFk,87629,GRP_SITE_CHAR,TERRAIN,Flat -US-PFk,87629,GRP_SITE_CHAR,ASPECT,FLAT -US-PFk,87629,GRP_SITE_CHAR,WIND_DIRECTION,SW -US-PFk,87619,GRP_SITE_DESC,SITE_DESC,"This tower (32m, trailer-based, telescoping) is located in the southwestern quadrant of the 10 x 10km study domain. It is located in an aspen forest (canopy height: immediate vicinity - 10m; greater area - 24.4 m)." -US-PFk,87621,GRP_SITE_FUNDING,SITE_FUNDING,National Science Foundation (NSF) -US-PFk,87618,GRP_STATE,STATE,WI -US-PFk,87609,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Ankur Desai -US-PFk,87609,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-PFk,87609,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,desai@aos.wisc.edu -US-PFk,87609,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Wisconsin-Madison -US-PFk,87609,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1225 W Dayton St, Madison, WI 53706" -US-PFk,87611,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Brian Butterworth -US-PFk,87611,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-PFk,87611,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,bbutterworth@wisc.edu -US-PFk,87611,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Wisconsin-Madison -US-PFk,87612,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Jonathan Thom -US-PFk,87612,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-PFk,87612,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,jthom@ssec.wisc.edu -US-PFk,87612,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Wisconsin-Madison -US-PFk,87610,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Steve Oncley -US-PFk,87610,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-PFk,87610,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,oncley@ucar.edu -US-PFk,87610,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,National Center for Atmospheric Research -US-PFk,87631,GRP_TOWER_POWER,TOWER_POWER,Other -US-PFk,87630,GRP_TOWER_TYPE,TOWER_TYPE,triangle -US-PFk,87625,GRP_URL,URL,https://www.eol.ucar.edu/field_projects/cheesehead -US-PFk,24001095,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-PFk -US-PFk,94191,GRP_UTC_OFFSET,UTC_OFFSET,-6 -US-PFL,87649,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,Supported by National Science Foundation (NSF) Award #1822420 -US-PFL,87634,GRP_CLIM_AVG,MAT,4.33 -US-PFL,87634,GRP_CLIM_AVG,MAP,823 -US-PFL,87634,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfb -US-PFL,27001096,GRP_COUNTRY,COUNTRY,USA -US-PFL,94895,GRP_DOI,DOI,10.17190/AMF/1717859 -US-PFL,94895,GRP_DOI,DOI_CITATION,"Ankur Desai, Brian Butterworth, Steven Oncley (2020), AmeriFlux BASE US-PFL SW2 Aspen-3 CHEESEHEAD 2019, Ver. 1-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1717859" -US-PFL,94895,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-PFL,95004,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-PFL,95004,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Ankur Desai -US-PFL,95004,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-PFL,95004,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,1 -US-PFL,95004,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0002-5226-6041 -US-PFL,95004,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,desai@aos.wisc.edu -US-PFL,95004,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of Wisconsin-Madison -US-PFL,95072,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-PFL,95072,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Brian Butterworth -US-PFL,95072,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-PFL,95072,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,2 -US-PFL,95072,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0002-8457-5308 -US-PFL,95072,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,bbutterworth@wisc.edu -US-PFL,95072,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of Wisconsin-Madison -US-PFL,95062,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-PFL,95062,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Steven Oncley -US-PFL,95062,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-PFL,95062,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,3 -US-PFL,95062,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,oncley@ucar.edu -US-PFL,95062,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,National Center for Atmospheric Research -US-PFL,94867,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,University of Wisconsin-Madison -US-PFL,94867,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-PFL,94854,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,National Science Foundation (NSF) -US-PFL,94854,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-PFL,91308,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-PFL,91308,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-PFL,91308,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20190624 -US-PFL,91308,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20191018 -US-PFL,91308,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-PFL,91446,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-PFL,91446,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-PFL,91446,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20190624 -US-PFL,91446,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20191018 -US-PFL,91446,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-PFL,91430,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-PFL,91430,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-PFL,91430,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20190624 -US-PFL,91430,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20191018 -US-PFL,91430,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-PFL,23001096,GRP_HEADER,SITE_NAME,SW2 Aspen-3 CHEESEHEAD 2019 -US-PFL,87650,GRP_IGBP,IGBP,DBF -US-PFL,87638,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-PFL,87638,GRP_LAND_OWNERSHIP,LAND_OWNER,US Forest Service -US-PFL,87654,GRP_LOCATION,LOCATION_LAT,45.9409 -US-PFL,87654,GRP_LOCATION,LOCATION_LONG,-90.3177 -US-PFL,87654,GRP_LOCATION,LOCATION_ELEV,464 -US-PFL,87654,GRP_LOCATION,LOCATION_DATE_START,20190624 -US-PFL,87642,GRP_NETWORK,NETWORK,AmeriFlux -US-PFL,87632,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,This tower was erected as one of 19 towers installed in the Chequamegon-Nicolet National Forest for the summer and fall of 2019 as part of the CHEESEHEAD 2019 (Chequamegon Heterogeneous Ecosystem Energy-balance Study Enabled by a High-density Extensive Array of Detectors) project. -US-PFL,87644,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"1225 W Dayton St, Madison, WI 53706" -US-PFL,87646,GRP_SITE_CHAR,TERRAIN,"Medium Slope (>2 %, <5%)" -US-PFL,87646,GRP_SITE_CHAR,ASPECT,NW -US-PFL,87646,GRP_SITE_CHAR,WIND_DIRECTION,SW -US-PFL,87652,GRP_SITE_DESC,SITE_DESC,This tower (25m Rohn) is located in the southwestern quadrant of the 10 x 10km study domain. It is located in an aspen forest (canopy height: 15 - 19.2 m). -US-PFL,87653,GRP_SITE_FUNDING,SITE_FUNDING,National Science Foundation (NSF) -US-PFL,87648,GRP_STATE,STATE,WI -US-PFL,87643,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Ankur Desai -US-PFL,87643,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-PFL,87643,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,desai@aos.wisc.edu -US-PFL,87643,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Wisconsin-Madison -US-PFL,87643,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1225 W Dayton St, Madison, WI 53706" -US-PFL,87635,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Brian Butterworth -US-PFL,87635,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-PFL,87635,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,bbutterworth@wisc.edu -US-PFL,87635,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Wisconsin-Madison -US-PFL,87647,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Jonathan Thom -US-PFL,87647,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-PFL,87647,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,jthom@ssec.wisc.edu -US-PFL,87647,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Wisconsin-Madison -US-PFL,87645,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Steve Oncley -US-PFL,87645,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-PFL,87645,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,oncley@ucar.edu -US-PFL,87645,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,National Center for Atmospheric Research -US-PFL,87651,GRP_TOWER_POWER,TOWER_POWER,Other -US-PFL,87633,GRP_TOWER_TYPE,TOWER_TYPE,triangle -US-PFL,87640,GRP_URL,URL,https://www.eol.ucar.edu/field_projects/cheesehead -US-PFL,24001096,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-PFL -US-PFL,94203,GRP_UTC_OFFSET,UTC_OFFSET,-6 -US-PFm,87672,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,Supported by National Science Foundation (NSF) Award #1822420 -US-PFm,87672,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT_COMMENT,"Acknowledge the National Center for Atmospheric Research Earth Observing Laboratory, National Science Foundation, AmeriFlux Management Project" -US-PFm,87674,GRP_CLIM_AVG,MAT,4.33 -US-PFm,87674,GRP_CLIM_AVG,MAP,823 -US-PFm,87674,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfb -US-PFm,27001097,GRP_COUNTRY,COUNTRY,USA -US-PFm,94891,GRP_DOI,DOI,10.17190/AMF/1717860 -US-PFm,94891,GRP_DOI,DOI_CITATION,"Ankur Desai, Brian Butterworth, Steven Oncley (2020), AmeriFlux BASE US-PFm SW3 Hardwood-2 CHEESEHEAD 2019, Ver. 1-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1717860" -US-PFm,94891,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-PFm,95052,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-PFm,95052,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Ankur Desai -US-PFm,95052,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-PFm,95052,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,1 -US-PFm,95052,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0002-5226-6041 -US-PFm,95052,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,desai@aos.wisc.edu -US-PFm,95052,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of Wisconsin-Madison -US-PFm,94996,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-PFm,94996,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Brian Butterworth -US-PFm,94996,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-PFm,94996,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,2 -US-PFm,94996,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0002-8457-5308 -US-PFm,94996,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,bbutterworth@wisc.edu -US-PFm,94996,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of Wisconsin-Madison -US-PFm,95068,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-PFm,95068,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Steven Oncley -US-PFm,95068,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-PFm,95068,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,3 -US-PFm,95068,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,oncley@ucar.edu -US-PFm,95068,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,National Center for Atmospheric Research -US-PFm,94868,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,University of Wisconsin-Madison -US-PFm,94868,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-PFm,94856,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,National Science Foundation (NSF) -US-PFm,94856,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-PFm,91438,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-PFm,91438,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-PFm,91438,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20190624 -US-PFm,91438,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20191018 -US-PFm,91438,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-PFm,91351,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-PFm,91351,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-PFm,91351,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20190624 -US-PFm,91351,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20191018 -US-PFm,91351,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-PFm,91343,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-PFm,91343,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-PFm,91343,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20190624 -US-PFm,91343,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20191018 -US-PFm,91343,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-PFm,23001097,GRP_HEADER,SITE_NAME,SW3 Hardwood-2 CHEESEHEAD 2019 -US-PFm,87669,GRP_IGBP,IGBP,DBF -US-PFm,87670,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-PFm,87670,GRP_LAND_OWNERSHIP,LAND_OWNER,US Forest Service -US-PFm,87668,GRP_LOCATION,LOCATION_LAT,45.9207 -US-PFm,87668,GRP_LOCATION,LOCATION_LONG,-90.3099 -US-PFm,87668,GRP_LOCATION,LOCATION_ELEV,484 -US-PFm,87668,GRP_LOCATION,LOCATION_DATE_START,20190624 -US-PFm,87660,GRP_NETWORK,NETWORK,AmeriFlux -US-PFm,87666,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,This tower was erected as one of 19 towers installed in the Chequamegon-Nicolet National Forest for the summer and fall of 2019 as part of the CHEESEHEAD 2019 (Chequamegon Heterogeneous Ecosystem Energy-balance Study Enabled by a High-density Extensive Array of Detectors) project. -US-PFm,87659,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"1225 W Dayton St, Madison, WI 53706" -US-PFm,87675,GRP_SITE_CHAR,TERRAIN,Gentle slope (<2 %) -US-PFm,87675,GRP_SITE_CHAR,ASPECT,NE -US-PFm,87675,GRP_SITE_CHAR,WIND_DIRECTION,SW -US-PFm,87665,GRP_SITE_DESC,SITE_DESC,"This tower (32m, trailer-based, telescoping) is located in the southwestern quadrant of the 10 x 10km study domain. It is located in an aspen and maple forest (canopy height: 15 m)." -US-PFm,87667,GRP_SITE_FUNDING,SITE_FUNDING,National Science Foundation (NSF) -US-PFm,87664,GRP_STATE,STATE,WI -US-PFm,87655,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Ankur Desai -US-PFm,87655,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-PFm,87655,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,desai@aos.wisc.edu -US-PFm,87655,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Wisconsin-Madison -US-PFm,87655,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1225 W Dayton St, Madison, WI 53706" -US-PFm,87657,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Brian Butterworth -US-PFm,87657,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-PFm,87657,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,bbutterworth@wisc.edu -US-PFm,87657,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Wisconsin-Madison -US-PFm,87658,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Jonathan Thom -US-PFm,87658,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-PFm,87658,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,jthom@ssec.wisc.edu -US-PFm,87658,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Wisconsin-Madison -US-PFm,87656,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Steve Oncley -US-PFm,87656,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-PFm,87656,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,oncley@ucar.edu -US-PFm,87656,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,National Center for Atmospheric Research -US-PFm,87677,GRP_TOWER_POWER,TOWER_POWER,Other -US-PFm,87676,GRP_TOWER_TYPE,TOWER_TYPE,triangle -US-PFm,87671,GRP_URL,URL,https://www.eol.ucar.edu/field_projects/cheesehead -US-PFm,24001097,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-PFm -US-PFm,94204,GRP_UTC_OFFSET,UTC_OFFSET,-6 -US-PFn,87695,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,Supported by National Science Foundation (NSF) Award #1822420 -US-PFn,87697,GRP_CLIM_AVG,MAT,4.33 -US-PFn,87697,GRP_CLIM_AVG,MAP,823 -US-PFn,87697,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfb -US-PFn,27001098,GRP_COUNTRY,COUNTRY,USA -US-PFn,94880,GRP_DOI,DOI,10.17190/AMF/1717861 -US-PFn,94880,GRP_DOI,DOI_CITATION,"Ankur Desai, Brian Butterworth, Steven Oncley (2020), AmeriFlux BASE US-PFn SW4 Hardwood-3 CHEESEHEAD 2019, Ver. 1-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1717861" -US-PFn,94880,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-PFn,95007,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-PFn,95007,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Ankur Desai -US-PFn,95007,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-PFn,95007,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,1 -US-PFn,95007,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0002-5226-6041 -US-PFn,95007,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,desai@aos.wisc.edu -US-PFn,95007,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of Wisconsin-Madison -US-PFn,94993,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-PFn,94993,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Brian Butterworth -US-PFn,94993,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-PFn,94993,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,2 -US-PFn,94993,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0002-8457-5308 -US-PFn,94993,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,bbutterworth@wisc.edu -US-PFn,94993,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of Wisconsin-Madison -US-PFn,95067,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-PFn,95067,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Steven Oncley -US-PFn,95067,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-PFn,95067,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,3 -US-PFn,95067,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,oncley@ucar.edu -US-PFn,95067,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,National Center for Atmospheric Research -US-PFn,94869,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,University of Wisconsin-Madison -US-PFn,94869,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-PFn,94851,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,National Science Foundation (NSF) -US-PFn,94851,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-PFn,91392,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-PFn,91392,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-PFn,91392,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20190624 -US-PFn,91392,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20191018 -US-PFn,91392,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-PFn,91459,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-PFn,91459,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-PFn,91459,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20190624 -US-PFn,91459,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20191018 -US-PFn,91459,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-PFn,91364,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-PFn,91364,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-PFn,91364,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20190624 -US-PFn,91364,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20191018 -US-PFn,91364,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-PFn,23001098,GRP_HEADER,SITE_NAME,SW4 Hardwood-3 CHEESEHEAD 2019 -US-PFn,87692,GRP_IGBP,IGBP,DBF -US-PFn,87693,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-PFn,87693,GRP_LAND_OWNERSHIP,LAND_OWNER,US Forest Service -US-PFn,87691,GRP_LOCATION,LOCATION_LAT,45.9392 -US-PFn,87691,GRP_LOCATION,LOCATION_LONG,-90.2823 -US-PFn,87691,GRP_LOCATION,LOCATION_ELEV,478 -US-PFn,87691,GRP_LOCATION,LOCATION_DATE_START,20190624 -US-PFn,87683,GRP_NETWORK,NETWORK,AmeriFlux -US-PFn,87689,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,This tower was erected as one of 19 towers installed in the Chequamegon-Nicolet National Forest for the summer and fall of 2019 as part of the CHEESEHEAD 2019 (Chequamegon Heterogeneous Ecosystem Energy-balance Study Enabled by a High-density Extensive Array of Detectors) project. -US-PFn,87682,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"1225 W Dayton St, Madison, WI 53706" -US-PFn,87698,GRP_SITE_CHAR,TERRAIN,Hilltop -US-PFn,87698,GRP_SITE_CHAR,ASPECT,FLAT -US-PFn,87698,GRP_SITE_CHAR,WIND_DIRECTION,SW -US-PFn,87688,GRP_SITE_DESC,SITE_DESC,"This tower (32m, trailer-based, telescoping) is located in the southwestern quadrant of the 10 x 10km study domain. It is located in a mixed hardwood forest - aspen, oak, birch, some pines (canopy height: 20 - 26 m)." -US-PFn,87690,GRP_SITE_FUNDING,SITE_FUNDING,National Science Foundation (NSF) -US-PFn,87687,GRP_STATE,STATE,WI -US-PFn,87678,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Ankur Desai -US-PFn,87678,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-PFn,87678,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,desai@aos.wisc.edu -US-PFn,87678,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Wisconsin-Madison -US-PFn,87678,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1225 W Dayton St, Madison, WI 53706" -US-PFn,87680,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Brian Butterworth -US-PFn,87680,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-PFn,87680,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,bbutterworth@wisc.edu -US-PFn,87680,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Wisconsin-Madison -US-PFn,87681,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Jonathan Thom -US-PFn,87681,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-PFn,87681,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,jthom@ssec.wisc.edu -US-PFn,87681,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Wisconsin-Madison -US-PFn,87679,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Steve Oncley -US-PFn,87679,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-PFn,87679,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,oncley@ucar.edu -US-PFn,87679,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,National Center for Atmospheric Research -US-PFn,87700,GRP_TOWER_POWER,TOWER_POWER,Other -US-PFn,87699,GRP_TOWER_TYPE,TOWER_TYPE,triangle -US-PFn,87694,GRP_URL,URL,https://www.eol.ucar.edu/field_projects/cheesehead -US-PFn,24001098,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-PFn -US-PFn,94184,GRP_UTC_OFFSET,UTC_OFFSET,-6 -US-PFo,87718,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,Supported by National Science Foundation (NSF) Award #1822420 -US-PFo,87720,GRP_CLIM_AVG,MAT,4.33 -US-PFo,87720,GRP_CLIM_AVG,MAP,823 -US-PFo,87720,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfb -US-PFo,27001099,GRP_COUNTRY,COUNTRY,USA -US-PFo,91451,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-PFo,91451,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-PFo,91451,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20190620 -US-PFo,91451,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20191031 -US-PFo,91451,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-PFo,91464,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-PFo,91464,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-PFo,91464,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20190620 -US-PFo,91464,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20191031 -US-PFo,91464,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-PFo,91356,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-PFo,91356,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-PFo,91356,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20190620 -US-PFo,91356,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20191031 -US-PFo,91356,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-PFo,23001099,GRP_HEADER,SITE_NAME,SE1 Lake-2 CHEESEHEAD 2019 -US-PFo,87715,GRP_IGBP,IGBP,WAT -US-PFo,87716,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-PFo,87716,GRP_LAND_OWNERSHIP,LAND_OWNER,US Forest Service -US-PFo,87714,GRP_LOCATION,LOCATION_LAT,45.9229 -US-PFo,87714,GRP_LOCATION,LOCATION_LONG,-90.2728 -US-PFo,87714,GRP_LOCATION,LOCATION_ELEV,476 -US-PFo,87714,GRP_LOCATION,LOCATION_DATE_START,20190620 -US-PFo,87706,GRP_NETWORK,NETWORK,AmeriFlux -US-PFo,87712,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,This tower was erected as one of 19 towers installed in the Chequamegon-Nicolet National Forest for the summer and fall of 2019 as part of the CHEESEHEAD 2019 (Chequamegon Heterogeneous Ecosystem Energy-balance Study Enabled by a High-density Extensive Array of Detectors) project. -US-PFo,87705,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"1225 W Dayton St, Madison, WI 53706" -US-PFo,87721,GRP_SITE_CHAR,TERRAIN,Flat -US-PFo,87721,GRP_SITE_CHAR,ASPECT,FLAT -US-PFo,87721,GRP_SITE_CHAR,WIND_DIRECTION,SW -US-PFo,87711,GRP_SITE_DESC,SITE_DESC,"This tower (1.17m buoy) is located in the southeastern quadrant of the 10 x 10km study domain. It is located on a buoy (1.17 m asl) in the center of a small bog lake (50-70 m across) surrounded by mixed hardwood forest (maple, oak) about 16 m high." -US-PFo,87713,GRP_SITE_FUNDING,SITE_FUNDING,National Science Foundation (NSF) -US-PFo,87710,GRP_STATE,STATE,WI -US-PFo,87701,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Ankur Desai -US-PFo,87701,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-PFo,87701,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,desai@aos.wisc.edu -US-PFo,87701,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Wisconsin-Madison -US-PFo,87701,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1225 W Dayton St, Madison, WI 53706" -US-PFo,87703,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Brian Butterworth -US-PFo,87703,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-PFo,87703,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,bbutterworth@wisc.edu -US-PFo,87703,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Wisconsin-Madison -US-PFo,87704,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Jonathan Thom -US-PFo,87704,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-PFo,87704,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,jthom@ssec.wisc.edu -US-PFo,87704,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Wisconsin-Madison -US-PFo,87702,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Paul Stoy -US-PFo,87702,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-PFo,87702,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,paul.stoy@montana.edu -US-PFo,87702,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Montana State University -US-PFo,87723,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-PFo,87722,GRP_TOWER_TYPE,TOWER_TYPE,other -US-PFo,87717,GRP_URL,URL,https://www.eol.ucar.edu/field_projects/cheesehead -US-PFo,24001099,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-PFo -US-PFo,94197,GRP_UTC_OFFSET,UTC_OFFSET,-6 -US-PFp,87741,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,Supported by National Science Foundation (NSF) Award #1822420 -US-PFp,87743,GRP_CLIM_AVG,MAT,4.33 -US-PFp,87743,GRP_CLIM_AVG,MAP,823 -US-PFp,87743,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfb -US-PFp,27001100,GRP_COUNTRY,COUNTRY,USA -US-PFp,94881,GRP_DOI,DOI,10.17190/AMF/1717862 -US-PFp,94881,GRP_DOI,DOI_CITATION,"Ankur Desai, Brian Butterworth, Steven Oncley (2020), AmeriFlux BASE US-PFp SE2 Hardwood-4 CHEESEHEAD 2019, Ver. 1-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1717862" -US-PFp,94881,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-PFp,95027,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-PFp,95027,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Ankur Desai -US-PFp,95027,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-PFp,95027,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,1 -US-PFp,95027,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0002-5226-6041 -US-PFp,95027,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,desai@aos.wisc.edu -US-PFp,95027,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of Wisconsin-Madison -US-PFp,95042,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-PFp,95042,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Brian Butterworth -US-PFp,95042,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-PFp,95042,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,2 -US-PFp,95042,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0002-8457-5308 -US-PFp,95042,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,bbutterworth@wisc.edu -US-PFp,95042,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of Wisconsin-Madison -US-PFp,95001,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-PFp,95001,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Steven Oncley -US-PFp,95001,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-PFp,95001,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,3 -US-PFp,95001,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,oncley@ucar.edu -US-PFp,95001,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,National Center for Atmospheric Research -US-PFp,94870,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,University of Wisconsin-Madison -US-PFp,94870,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-PFp,94855,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,National Science Foundation (NSF) -US-PFp,94855,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-PFp,91315,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-PFp,91315,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-PFp,91315,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20190624 -US-PFp,91315,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20191018 -US-PFp,91315,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-PFp,91448,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-PFp,91448,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-PFp,91448,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20190624 -US-PFp,91448,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20191018 -US-PFp,91448,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-PFp,91398,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-PFp,91398,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-PFp,91398,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20190624 -US-PFp,91398,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20191018 -US-PFp,91398,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-PFp,23001100,GRP_HEADER,SITE_NAME,SE2 Hardwood-4 CHEESEHEAD 2019 -US-PFp,87738,GRP_IGBP,IGBP,DBF -US-PFp,87739,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-PFp,87739,GRP_LAND_OWNERSHIP,LAND_OWNER,US Forest Service -US-PFp,87737,GRP_LOCATION,LOCATION_LAT,45.9365 -US-PFp,87737,GRP_LOCATION,LOCATION_LONG,-90.2641 -US-PFp,87737,GRP_LOCATION,LOCATION_ELEV,497 -US-PFp,87737,GRP_LOCATION,LOCATION_DATE_START,20190624 -US-PFp,87729,GRP_NETWORK,NETWORK,AmeriFlux -US-PFp,87735,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,This tower was erected as one of 19 towers installed in the Chequamegon-Nicolet National Forest for the summer and fall of 2019 as part of the CHEESEHEAD 2019 (Chequamegon Heterogeneous Ecosystem Energy-balance Study Enabled by a High-density Extensive Array of Detectors) project. -US-PFp,87728,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"1225 W Dayton St, Madison, WI 53706" -US-PFp,87744,GRP_SITE_CHAR,TERRAIN,Flat -US-PFp,87744,GRP_SITE_CHAR,ASPECT,FLAT -US-PFp,87744,GRP_SITE_CHAR,WIND_DIRECTION,SW -US-PFp,87734,GRP_SITE_DESC,SITE_DESC,"This tower (32m, trailer-based, telescoping) is located in the southeastern quadrant of the 10 x 10km study domain. It is located in a mixed hardwood forest - black ash and red maple (canopy height: 20 - 24.4 m)." -US-PFp,87736,GRP_SITE_FUNDING,SITE_FUNDING,National Science Foundation (NSF) -US-PFp,87733,GRP_STATE,STATE,WI -US-PFp,87724,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Ankur Desai -US-PFp,87724,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-PFp,87724,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,desai@aos.wisc.edu -US-PFp,87724,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Wisconsin-Madison -US-PFp,87724,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1225 W Dayton St, Madison, WI 53706" -US-PFp,87726,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Brian Butterworth -US-PFp,87726,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-PFp,87726,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,bbutterworth@wisc.edu -US-PFp,87726,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Wisconsin-Madison -US-PFp,87727,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Jonathan Thom -US-PFp,87727,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-PFp,87727,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,jthom@ssec.wisc.edu -US-PFp,87727,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Wisconsin-Madison -US-PFp,87725,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Steve Oncley -US-PFp,87725,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-PFp,87725,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,oncley@ucar.edu -US-PFp,87725,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,National Center for Atmospheric Research -US-PFp,87746,GRP_TOWER_POWER,TOWER_POWER,Other -US-PFp,87745,GRP_TOWER_TYPE,TOWER_TYPE,triangle -US-PFp,87740,GRP_URL,URL,https://www.eol.ucar.edu/field_projects/cheesehead -US-PFp,24001100,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-PFp -US-PFp,94190,GRP_UTC_OFFSET,UTC_OFFSET,-6 -US-PFq,87792,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,Supported by National Science Foundation (NSF) Award #1822420 -US-PFq,87794,GRP_CLIM_AVG,MAT,4.33 -US-PFq,87794,GRP_CLIM_AVG,MAP,823 -US-PFq,87794,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfb -US-PFq,27001101,GRP_COUNTRY,COUNTRY,USA -US-PFq,94897,GRP_DOI,DOI,10.17190/AMF/1717863 -US-PFq,94897,GRP_DOI,DOI_CITATION,"Ankur Desai, Brian Butterworth, Steven Oncley (2020), AmeriFlux BASE US-PFq SE3 Aspen-4 CHEESEHEAD 2019, Ver. 1-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1717863" -US-PFq,94897,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-PFq,95043,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-PFq,95043,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Ankur Desai -US-PFq,95043,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-PFq,95043,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,1 -US-PFq,95043,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0002-5226-6041 -US-PFq,95043,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,desai@aos.wisc.edu -US-PFq,95043,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of Wisconsin-Madison -US-PFq,95020,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-PFq,95020,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Brian Butterworth -US-PFq,95020,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-PFq,95020,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,2 -US-PFq,95020,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0002-8457-5308 -US-PFq,95020,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,bbutterworth@wisc.edu -US-PFq,95020,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of Wisconsin-Madison -US-PFq,95038,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-PFq,95038,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Steven Oncley -US-PFq,95038,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-PFq,95038,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,3 -US-PFq,95038,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,oncley@ucar.edu -US-PFq,95038,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,National Center for Atmospheric Research -US-PFq,94871,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,University of Wisconsin-Madison -US-PFq,94871,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-PFq,94844,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,National Science Foundation (NSF) -US-PFq,94844,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-PFq,91455,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-PFq,91455,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-PFq,91455,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20190624 -US-PFq,91455,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20191018 -US-PFq,91455,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-PFq,91445,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-PFq,91445,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-PFq,91445,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20190624 -US-PFq,91445,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20191018 -US-PFq,91445,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-PFq,91419,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-PFq,91419,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-PFq,91419,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20190624 -US-PFq,91419,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20191018 -US-PFq,91419,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-PFq,23001101,GRP_HEADER,SITE_NAME,SE3 Aspen-4 CHEESEHEAD 2019 -US-PFq,87789,GRP_IGBP,IGBP,DBF -US-PFq,87790,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-PFq,87790,GRP_LAND_OWNERSHIP,LAND_OWNER,US Forest Service -US-PFq,87788,GRP_LOCATION,LOCATION_LAT,45.9271 -US-PFq,87788,GRP_LOCATION,LOCATION_LONG,-90.2475 -US-PFq,87788,GRP_LOCATION,LOCATION_ELEV,473 -US-PFq,87788,GRP_LOCATION,LOCATION_DATE_START,20190624 -US-PFq,87780,GRP_NETWORK,NETWORK,AmeriFlux -US-PFq,87786,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,This tower was erected as one of 19 towers installed in the Chequamegon-Nicolet National Forest for the summer and fall of 2019 as part of the CHEESEHEAD 2019 (Chequamegon Heterogeneous Ecosystem Energy-balance Study Enabled by a High-density Extensive Array of Detectors) project. -US-PFq,87779,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"1225 W Dayton St, Madison, WI 53706" -US-PFq,87795,GRP_SITE_CHAR,TERRAIN,Gentle slope (<2 %) -US-PFq,87795,GRP_SITE_CHAR,ASPECT,E -US-PFq,87795,GRP_SITE_CHAR,WIND_DIRECTION,SW -US-PFq,87785,GRP_SITE_DESC,SITE_DESC,"This tower (32m, trailer-based, telescoping) is located in the southeastern quadrant of the 10 x 10km study domain. It is located in an aspen forest (canopy height: 10 - 14.3 m)." -US-PFq,87787,GRP_SITE_FUNDING,SITE_FUNDING,National Science Foundation (NSF) -US-PFq,87784,GRP_STATE,STATE,WI -US-PFq,87775,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Ankur Desai -US-PFq,87775,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-PFq,87775,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,desai@aos.wisc.edu -US-PFq,87775,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Wisconsin-Madison -US-PFq,87775,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1225 W Dayton St, Madison, WI 53706" -US-PFq,87777,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Brian Butterworth -US-PFq,87777,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-PFq,87777,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,bbutterworth@wisc.edu -US-PFq,87777,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Wisconsin-Madison -US-PFq,87778,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Jonathan Thom -US-PFq,87778,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-PFq,87778,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,jthom@ssec.wisc.edu -US-PFq,87778,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Wisconsin-Madison -US-PFq,87776,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Steve Oncley -US-PFq,87776,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-PFq,87776,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,oncley@ucar.edu -US-PFq,87776,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,National Center for Atmospheric Research -US-PFq,87797,GRP_TOWER_POWER,TOWER_POWER,Other -US-PFq,87796,GRP_TOWER_TYPE,TOWER_TYPE,triangle -US-PFq,87791,GRP_URL,URL,https://www.eol.ucar.edu/field_projects/cheesehead -US-PFq,24001101,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-PFq -US-PFq,94194,GRP_UTC_OFFSET,UTC_OFFSET,-6 -US-PFr,87769,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,Supported by National Science Foundation (NSF) Award #1822420 -US-PFr,87771,GRP_CLIM_AVG,MAT,4.33 -US-PFr,87771,GRP_CLIM_AVG,MAP,823 -US-PFr,87771,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfb -US-PFr,27001102,GRP_COUNTRY,COUNTRY,USA -US-PFr,94883,GRP_DOI,DOI,10.17190/AMF/1717864 -US-PFr,94883,GRP_DOI,DOI_CITATION,"Ankur Desai, Brian Butterworth, Steven Oncley (2020), AmeriFlux BASE US-PFr SE4 Tussock-2 CHEESEHEAD 2019, Ver. 1-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1717864" -US-PFr,94883,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-PFr,95024,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-PFr,95024,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Ankur Desai -US-PFr,95024,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-PFr,95024,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,1 -US-PFr,95024,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0002-5226-6041 -US-PFr,95024,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,desai@aos.wisc.edu -US-PFr,95024,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of Wisconsin-Madison -US-PFr,95039,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-PFr,95039,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Brian Butterworth -US-PFr,95039,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-PFr,95039,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,2 -US-PFr,95039,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0002-8457-5308 -US-PFr,95039,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,bbutterworth@wisc.edu -US-PFr,95039,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of Wisconsin-Madison -US-PFr,95063,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-PFr,95063,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Steven Oncley -US-PFr,95063,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-PFr,95063,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,3 -US-PFr,95063,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,oncley@ucar.edu -US-PFr,95063,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,National Center for Atmospheric Research -US-PFr,94872,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,University of Wisconsin-Madison -US-PFr,94872,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-PFr,94841,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,National Science Foundation (NSF) -US-PFr,94841,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-PFr,91346,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-PFr,91346,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-PFr,91346,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20190624 -US-PFr,91346,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20191018 -US-PFr,91346,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-PFr,91397,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-PFr,91397,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-PFr,91397,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20190624 -US-PFr,91397,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20191018 -US-PFr,91397,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-PFr,91332,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-PFr,91332,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-PFr,91332,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20190624 -US-PFr,91332,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20191018 -US-PFr,91332,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-PFr,23001102,GRP_HEADER,SITE_NAME,SE4 Tussock-2 CHEESEHEAD 2019 -US-PFr,87766,GRP_IGBP,IGBP,WET -US-PFr,87767,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-PFr,87767,GRP_LAND_OWNERSHIP,LAND_OWNER,US Forest Service -US-PFr,87765,GRP_LOCATION,LOCATION_LAT,45.9245 -US-PFr,87765,GRP_LOCATION,LOCATION_LONG,-90.2475 -US-PFr,87765,GRP_LOCATION,LOCATION_ELEV,490 -US-PFr,87765,GRP_LOCATION,LOCATION_DATE_START,20190624 -US-PFr,87757,GRP_NETWORK,NETWORK,AmeriFlux -US-PFr,87763,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,This tower was erected as one of 19 towers installed in the Chequamegon-Nicolet National Forest for the summer and fall of 2019 as part of the CHEESEHEAD 2019 (Chequamegon Heterogeneous Ecosystem Energy-balance Study Enabled by a High-density Extensive Array of Detectors) project. -US-PFr,87756,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"1225 W Dayton St, Madison, WI 53706" -US-PFr,87772,GRP_SITE_CHAR,TERRAIN,Flat -US-PFr,87772,GRP_SITE_CHAR,ASPECT,FLAT -US-PFr,87772,GRP_SITE_CHAR,WIND_DIRECTION,SW -US-PFr,87762,GRP_SITE_DESC,SITE_DESC,This tower (3m tripod) is located in the southeastern quadrant of the 10 x 10km study domain. It is located in a tussock (0.3 - 1m grasses). Located next to stream. -US-PFr,87764,GRP_SITE_FUNDING,SITE_FUNDING,National Science Foundation (NSF) -US-PFr,87761,GRP_STATE,STATE,WI -US-PFr,87752,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Ankur Desai -US-PFr,87752,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-PFr,87752,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,desai@aos.wisc.edu -US-PFr,87752,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Wisconsin-Madison -US-PFr,87752,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1225 W Dayton St, Madison, WI 53706" -US-PFr,87754,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Brian Butterworth -US-PFr,87754,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-PFr,87754,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,bbutterworth@wisc.edu -US-PFr,87754,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Wisconsin-Madison -US-PFr,87755,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Jonathan Thom -US-PFr,87755,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-PFr,87755,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,jthom@ssec.wisc.edu -US-PFr,87755,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Wisconsin-Madison -US-PFr,87753,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Steve Oncley -US-PFr,87753,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-PFr,87753,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,oncley@ucar.edu -US-PFr,87753,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,National Center for Atmospheric Research -US-PFr,87774,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-PFr,87773,GRP_TOWER_TYPE,TOWER_TYPE,tripod -US-PFr,87768,GRP_URL,URL,https://www.eol.ucar.edu/field_projects/cheesehead -US-PFr,24001102,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-PFr -US-PFr,94185,GRP_UTC_OFFSET,UTC_OFFSET,-6 -US-PFs,87810,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,Supported by National Science Foundation (NSF) Award #1822420 -US-PFs,87812,GRP_CLIM_AVG,MAT,4.33 -US-PFs,87812,GRP_CLIM_AVG,MAP,823 -US-PFs,87812,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfb -US-PFs,27001103,GRP_COUNTRY,COUNTRY,USA -US-PFs,94890,GRP_DOI,DOI,10.17190/AMF/1717865 -US-PFs,94890,GRP_DOI,DOI_CITATION,"Ankur Desai, Brian Butterworth, Steven Oncley (2020), AmeriFlux BASE US-PFs SE5 Aspen-5 CHEESEHEAD 2019, Ver. 1-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1717865" -US-PFs,94890,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-PFs,95055,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-PFs,95055,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Ankur Desai -US-PFs,95055,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-PFs,95055,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,1 -US-PFs,95055,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0002-5226-6041 -US-PFs,95055,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,desai@aos.wisc.edu -US-PFs,95055,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of Wisconsin-Madison -US-PFs,95005,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-PFs,95005,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Brian Butterworth -US-PFs,95005,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-PFs,95005,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,2 -US-PFs,95005,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0002-8457-5308 -US-PFs,95005,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,bbutterworth@wisc.edu -US-PFs,95005,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of Wisconsin-Madison -US-PFs,95044,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-PFs,95044,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Steven Oncley -US-PFs,95044,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-PFs,95044,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,3 -US-PFs,95044,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,oncley@ucar.edu -US-PFs,95044,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,National Center for Atmospheric Research -US-PFs,94873,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,University of Wisconsin-Madison -US-PFs,94873,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-PFs,94842,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,National Science Foundation (NSF) -US-PFs,94842,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-PFs,91306,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-PFs,91306,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-PFs,91306,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20190624 -US-PFs,91306,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20191018 -US-PFs,91306,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-PFs,91339,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-PFs,91339,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-PFs,91339,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20190624 -US-PFs,91339,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20191018 -US-PFs,91339,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-PFs,91299,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-PFs,91299,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-PFs,91299,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20190624 -US-PFs,91299,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20191018 -US-PFs,91299,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-PFs,23001103,GRP_HEADER,SITE_NAME,SE5 Aspen-5 CHEESEHEAD 2019 -US-PFs,87807,GRP_IGBP,IGBP,DBF -US-PFs,87808,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-PFs,87808,GRP_LAND_OWNERSHIP,LAND_OWNER,US Forest Service -US-PFs,87806,GRP_LOCATION,LOCATION_LAT,45.9381 -US-PFs,87806,GRP_LOCATION,LOCATION_LONG,-90.2382 -US-PFs,87806,GRP_LOCATION,LOCATION_ELEV,489 -US-PFs,87806,GRP_LOCATION,LOCATION_DATE_START,20190624 -US-PFs,87749,GRP_NETWORK,NETWORK,AmeriFlux -US-PFs,87804,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,This tower was erected as one of 19 towers installed in the Chequamegon-Nicolet National Forest for the summer and fall of 2019 as part of the CHEESEHEAD 2019 (Chequamegon Heterogeneous Ecosystem Energy-balance Study Enabled by a High-density Extensive Array of Detectors) project. -US-PFs,87748,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"1225 W Dayton St, Madison, WI 53706" -US-PFs,87813,GRP_SITE_CHAR,TERRAIN,Gentle slope (<2 %) -US-PFs,87813,GRP_SITE_CHAR,ASPECT,SE -US-PFs,87813,GRP_SITE_CHAR,WIND_DIRECTION,SW -US-PFs,87803,GRP_SITE_DESC,SITE_DESC,This tower (12m Rohn) is located in the southeastern quadrant of the 10 x 10km study domain. It is located in an aspen regrowth forest (canopy height: 3.1 - 6 m). -US-PFs,87805,GRP_SITE_FUNDING,SITE_FUNDING,National Science Foundation (NSF) -US-PFs,87802,GRP_STATE,STATE,WI -US-PFs,87798,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Ankur Desai -US-PFs,87798,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-PFs,87798,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,desai@aos.wisc.edu -US-PFs,87798,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Wisconsin-Madison -US-PFs,87798,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1225 W Dayton St, Madison, WI 53706" -US-PFs,87800,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Brian Butterworth -US-PFs,87800,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-PFs,87800,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,bbutterworth@wisc.edu -US-PFs,87800,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Wisconsin-Madison -US-PFs,87747,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Jonathan Thom -US-PFs,87747,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-PFs,87747,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,jthom@ssec.wisc.edu -US-PFs,87747,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Wisconsin-Madison -US-PFs,87799,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Steve Oncley -US-PFs,87799,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-PFs,87799,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,oncley@ucar.edu -US-PFs,87799,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,National Center for Atmospheric Research -US-PFs,87815,GRP_TOWER_POWER,TOWER_POWER,Other -US-PFs,87814,GRP_TOWER_TYPE,TOWER_TYPE,triangle -US-PFs,87809,GRP_URL,URL,https://www.eol.ucar.edu/field_projects/cheesehead -US-PFs,24001103,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-PFs -US-PFs,94182,GRP_UTC_OFFSET,UTC_OFFSET,-6 -US-PFt,87833,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,Supported by National Science Foundation (NSF) Award #1822420 -US-PFt,87835,GRP_CLIM_AVG,MAT,4.33 -US-PFt,87835,GRP_CLIM_AVG,MAP,823 -US-PFt,87835,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfb -US-PFt,27001104,GRP_COUNTRY,COUNTRY,USA -US-PFt,94884,GRP_DOI,DOI,10.17190/AMF/1717866 -US-PFt,94884,GRP_DOI,DOI_CITATION,"Ankur Desai, Brian Butterworth, Steven Oncley (2020), AmeriFlux BASE US-PFt SE6 Pine-4 CHEESEHEAD 2019, Ver. 1-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1717866" -US-PFt,94884,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-PFt,95033,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-PFt,95033,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Ankur Desai -US-PFt,95033,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-PFt,95033,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,1 -US-PFt,95033,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0002-5226-6041 -US-PFt,95033,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,desai@aos.wisc.edu -US-PFt,95033,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of Wisconsin-Madison -US-PFt,95002,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-PFt,95002,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Brian Butterworth -US-PFt,95002,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-PFt,95002,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,2 -US-PFt,95002,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0002-8457-5308 -US-PFt,95002,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,bbutterworth@wisc.edu -US-PFt,95002,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of Wisconsin-Madison -US-PFt,95049,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-PFt,95049,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Steven Oncley -US-PFt,95049,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-PFt,95049,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,3 -US-PFt,95049,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,oncley@ucar.edu -US-PFt,95049,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,National Center for Atmospheric Research -US-PFt,94874,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,University of Wisconsin-Madison -US-PFt,94874,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-PFt,94845,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,National Science Foundation (NSF) -US-PFt,94845,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-PFt,91362,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-PFt,91362,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-PFt,91362,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20190624 -US-PFt,91362,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20191018 -US-PFt,91362,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-PFt,91461,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-PFt,91461,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-PFt,91461,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20190624 -US-PFt,91461,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20191018 -US-PFt,91461,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-PFt,91408,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-PFt,91408,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-PFt,91408,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20190624 -US-PFt,91408,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20191018 -US-PFt,91408,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-PFt,23001104,GRP_HEADER,SITE_NAME,SE6 Pine-4 CHEESEHEAD 2019 -US-PFt,87830,GRP_IGBP,IGBP,ENF -US-PFt,87831,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-PFt,87831,GRP_LAND_OWNERSHIP,LAND_OWNER,US Forest Service -US-PFt,87829,GRP_LOCATION,LOCATION_LAT,45.9197 -US-PFt,87829,GRP_LOCATION,LOCATION_LONG,-90.2288 -US-PFt,87829,GRP_LOCATION,LOCATION_ELEV,466 -US-PFt,87829,GRP_LOCATION,LOCATION_DATE_START,20190624 -US-PFt,87821,GRP_NETWORK,NETWORK,AmeriFlux -US-PFt,87827,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,This tower was erected as one of 19 towers installed in the Chequamegon-Nicolet National Forest for the summer and fall of 2019 as part of the CHEESEHEAD 2019 (Chequamegon Heterogeneous Ecosystem Energy-balance Study Enabled by a High-density Extensive Array of Detectors) project. -US-PFt,87820,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"1225 W Dayton St, Madison, WI 53706" -US-PFt,87836,GRP_SITE_CHAR,TERRAIN,Valley -US-PFt,87836,GRP_SITE_CHAR,ASPECT,FLAT -US-PFt,87836,GRP_SITE_CHAR,WIND_DIRECTION,SW -US-PFt,87826,GRP_SITE_DESC,SITE_DESC,"This tower (32m, trailer-based, telescoping) is located in the southeastern quadrant of the 10 x 10km study domain. It is located in a red pine forest (canopy height: 15 - 21.6 m)." -US-PFt,87828,GRP_SITE_FUNDING,SITE_FUNDING,National Science Foundation (NSF) -US-PFt,87825,GRP_STATE,STATE,WI -US-PFt,87816,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Ankur Desai -US-PFt,87816,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-PFt,87816,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,desai@aos.wisc.edu -US-PFt,87816,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Wisconsin-Madison -US-PFt,87816,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1225 W Dayton St, Madison, WI 53706" -US-PFt,87818,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Brian Butterworth -US-PFt,87818,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-PFt,87818,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,bbutterworth@wisc.edu -US-PFt,87818,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Wisconsin-Madison -US-PFt,87819,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Jonathan Thom -US-PFt,87819,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-PFt,87819,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,jthom@ssec.wisc.edu -US-PFt,87819,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Wisconsin-Madison -US-PFt,87817,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Steve Oncley -US-PFt,87817,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-PFt,87817,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,oncley@ucar.edu -US-PFt,87817,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,National Center for Atmospheric Research -US-PFt,87838,GRP_TOWER_POWER,TOWER_POWER,Other -US-PFt,87837,GRP_TOWER_TYPE,TOWER_TYPE,triangle -US-PFt,87832,GRP_URL,URL,https://www.eol.ucar.edu/field_projects/cheesehead -US-PFt,24001104,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-PFt -US-PFt,94202,GRP_UTC_OFFSET,UTC_OFFSET,-6 -US-PHM,30023,GRP_CLIM_AVG,MAT,7.2 -US-PHM,30023,GRP_CLIM_AVG,MAP,1262 -US-PHM,30023,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfa -US-PHM,27000677,GRP_COUNTRY,COUNTRY,USA -US-PHM,87129,GRP_DOI,DOI,10.17190/AMF/1543377 -US-PHM,87129,GRP_DOI,DOI_CITATION,"Anne Giblin (2021), AmeriFlux BASE US-PHM Plum Island High Marsh, Ver. 3-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1543377" -US-PHM,87129,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-PHM,86892,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-PHM,86892,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Anne Giblin -US-PHM,86892,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-PHM,86892,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,agiblin@mbl.edu -US-PHM,86892,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Marine Biological Laboratory -US-PHM,86904,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Marine Biological Laboratory -US-PHM,86904,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-PHM,86903,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,NSF-OCE -US-PHM,86903,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-PHM,30025,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Drought -US-PHM,30024,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Hydrologic event -US-PHM,30026,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-PHM,30026,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-PHM,30026,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20130101 -US-PHM,30026,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-PHM,30027,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-PHM,30027,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-PHM,30027,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20130101 -US-PHM,30027,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-PHM,30028,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-PHM,30028,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-PHM,30028,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20130101 -US-PHM,30028,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-PHM,23000677,GRP_HEADER,SITE_NAME,Plum Island High Marsh -US-PHM,30029,GRP_IGBP,IGBP,WET -US-PHM,30029,GRP_IGBP,IGBP_COMMENT,Spartina -US-PHM,30030,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-PHM,30030,GRP_LAND_OWNERSHIP,LAND_OWNER,US Fish and Wildlife Service -US-PHM,30031,GRP_LOCATION,LOCATION_LAT,42.7423 -US-PHM,30031,GRP_LOCATION,LOCATION_LONG,-70.8301 -US-PHM,30031,GRP_LOCATION,LOCATION_ELEV,1.4 -US-PHM,30032,GRP_NETWORK,NETWORK,AmeriFlux -US-PHM,92761,GRP_NETWORK,NETWORK,LTER -US-PHM,1700006093,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"A.E. Giblin, C.S. Hopkinson (2018) Constraining marsh carbon budgets using long‐term C burial and contemporary atmospheric CO2 fluxes, JGR-Biogeosciences, 34(2), " -US-PHM,1700006093,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/2017JG004336 -US-PHM,1700006093,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-PHM,1700002187,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"A.E. Giblin, C.S. Hopkinson (2018) Constraining marsh carbon budgets using long‐term C burial and contemporary atmospheric CO2 fluxes, JGR-Biogeosciences, 34(2), 108350" -US-PHM,1700002187,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/2017JG004336 -US-PHM,1700002187,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-PHM,1700007164,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(2), 108350" -US-PHM,1700007164,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -US-PHM,1700007164,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-PHM,1700003306,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Feagin, R. A., Forbrich, I., Huff, T. P., Barr, J. G., Ruiz‐Plancarte, J., Fuentes, J. D., Najjar, R. G., Vargas, R., Vázquez‐Lule, A., Windham‐Myers, L., Kroeger, K. D., Ward, E. J., Moore, G. W., Leclerc, M., Krauss, K. W., Stagg, C. L., Alber, M., Knox, S. H., Schäfer, K. V., Bianchi, T. S., Hutchings, J. A., Nahrawi, H., Noormets, A., Mitra, B., Jaimes, A., Hinson, A. L., Bergamaschi, B., King, J. S., Miao, G. (2020) Tidal Wetland Gross Primary Production Across The Continental United States, 2000–2019, Global Biogeochemical Cycles, 34(2), " -US-PHM,1700003306,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2019GB006349 -US-PHM,1700003306,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-PHM,1700005652,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Feagin, R. A., Forbrich, I., Huff, T. P., Barr, J. G., Ruiz‐Plancarte, J., Fuentes, J. D., Najjar, R. G., Vargas, R., Vázquez‐Lule, A., Windham‐Myers, L., Kroeger, K. D., Ward, E. J., Moore, G. W., Leclerc, M., Krauss, K. W., Stagg, C. L., Alber, M., Knox, S. H., Schäfer, K. V., Bianchi, T. S., Hutchings, J. A., Nahrawi, H., Noormets, A., Mitra, B., Jaimes, A., Hinson, A. L., Bergamaschi, B., King, J. S., Miao, G. (2020) Tidal Wetland Gross Primary Production Across The Continental United States, 2000–2019, Global Biogeochemical Cycles, 34(2), 108350" -US-PHM,1700005652,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2019GB006349 -US-PHM,1700005652,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-PHM,30034,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"estuarine carbon cycling, sea level rise" -US-PHM,30035,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"7 MBL Street, Woods Hole, MA 02540" -US-PHM,30036,GRP_SITE_CHAR,TERRAIN,Flat -US-PHM,30036,GRP_SITE_CHAR,ASPECT,FLAT -US-PHM,30036,GRP_SITE_CHAR,WIND_DIRECTION,SW -US-PHM,30036,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,1000 -US-PHM,30036,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,30 -US-PHM,30037,GRP_SITE_DESC,SITE_DESC,"The site is a salt marsh located within the Plum Island Sound estuary, which is characterized by a tidal range of 2.5-3m and a vegetation cover of Spartina patens, Spartina alterniflora, Distichils spicata. Elevation of the high marsh is about 1.4m NAVD88." -US-PHM,30038,GRP_SITE_FUNDING,SITE_FUNDING,NSF-OCE -US-PHM,30039,GRP_STATE,STATE,MA -US-PHM,30041,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Anne Giblin -US-PHM,30041,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-PHM,30041,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,agiblin@mbl.edu -US-PHM,30041,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Marine Biological Laboratory -US-PHM,30041,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"7 MBL Street, Woods Hole, MA 02540" -US-PHM,92784,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Inke Forbrich -US-PHM,92784,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-PHM,92784,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,iforbrich@mbl.edu -US-PHM,92784,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Marine Biological Laboratory -US-PHM,30040,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Hap Garritt -US-PHM,30040,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,DataManager -US-PHM,30040,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,hgarritt@mbl.edu -US-PHM,30040,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Marine Biological Laboratory -US-PHM,30045,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-PHM,30043,GRP_TOWER_TYPE,TOWER_TYPE,triangle -US-PHM,24000677,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-PHM -US-PHM,30044,GRP_UTC_OFFSET,UTC_OFFSET,-5 -US-PiU,90658,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,USGS Priority Ecosystem Science Everglades Program -US-PiU,90658,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT_COMMENT,Tower construction funded by South Florida Water Management District -US-PiU,90680,GRP_CLIM_AVG,MAT,23.1 -US-PiU,90680,GRP_CLIM_AVG,MAP,1312 -US-PiU,90680,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Cwa -US-PiU,27001118,GRP_COUNTRY,COUNTRY,USA -US-PiU,90676,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Fire -US-PiU,90677,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Hydrologic event -US-PiU,90662,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Storm or wind -US-PiU,90670,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-PiU,90670,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-PiU,90670,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20120315 -US-PiU,90670,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,201412080000 -US-PiU,90670,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-PiU,90668,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-PiU,90668,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-PiU,90668,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20120315 -US-PiU,90668,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,201412080000 -US-PiU,90668,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-PiU,90666,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-PiU,90666,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,Other -US-PiU,90666,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20120315 -US-PiU,90666,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,201412080000 -US-PiU,90666,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-PiU,90666,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,Measured for LE -US-PiU,23001118,GRP_HEADER,SITE_NAME,Pine Upland -US-PiU,90669,GRP_IGBP,IGBP,WET -US-PiU,90678,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-PiU,90678,GRP_LAND_OWNERSHIP,LAND_OWNER,National Preserve -US-PiU,90673,GRP_LOCATION,LOCATION_LAT,26.0004 -US-PiU,90673,GRP_LOCATION,LOCATION_LONG,-80.9261 -US-PiU,90673,GRP_LOCATION,LOCATION_ELEV,3.04 -US-PiU,90673,GRP_LOCATION,LOCATION_DATE_START,20121203 -US-PiU,90673,GRP_LOCATION,LOCATION_COMMENT,Located in Big Cypress National Preserve -US-PiU,90675,GRP_NETWORK,NETWORK,AmeriFlux -US-PiU,90663,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,Carbon and water fluxes -US-PiU,90672,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"3321 College Ave, Davie FL 33314" -US-PiU,90674,GRP_SITE_CHAR,TERRAIN,Flat -US-PiU,90674,GRP_SITE_CHAR,ASPECT,S -US-PiU,90674,GRP_SITE_CHAR,WIND_DIRECTION,NNE -US-PiU,90674,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,0 -US-PiU,90659,GRP_SITE_DESC,SITE_DESC,Pine Upland -US-PiU,90681,GRP_SITE_FUNDING,SITE_FUNDING,USGS Priority Ecosystem Science Everglades Program -US-PiU,90665,GRP_STATE,STATE,FL -US-PiU,90756,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Andre Daniels -US-PiU,90756,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-PiU,90756,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,andre_daniels@usgs.gov -US-PiU,90756,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,USGS -US-PiU,90664,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,W. Barclay Shoemaker -US-PiU,90664,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-PiU,90664,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,bshoemak@usgs.gov -US-PiU,90664,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,USGS -US-PiU,90664,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"3321 College Ave, Davie FL 33314" -US-PiU,93492,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,"Rosvel Bracho-Garrillo," -US-PiU,93492,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,DataManager -US-PiU,93492,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,rbracho@ufl.edu -US-PiU,93492,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Florida -US-PiU,90661,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-PiU,90671,GRP_TOWER_TYPE,TOWER_TYPE,triangle -US-PiU,90679,GRP_URL,URL,https://sites.google.com/site/floridaetwiki/home -US-PiU,24001118,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-PiU -US-PiU,90660,GRP_UTC_OFFSET,UTC_OFFSET,-5 -US-PiU,90660,GRP_UTC_OFFSET,UTC_OFFSET_DATE_START,20200113 -US-PiU,90660,GRP_UTC_OFFSET,UTC_OFFSET_COMMENT,Eastern Standard Time Zone -US-PLM,79846,GRP_CLIM_AVG,MAT,8.7 -US-PLM,79846,GRP_CLIM_AVG,MAP,1262 -US-PLM,79846,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfa -US-PLM,27000963,GRP_COUNTRY,COUNTRY,USA -US-PLM,79847,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Hydrologic event -US-PLM,91897,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-PLM,91897,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-PLM,91897,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20150701 -US-PLM,91897,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Growing season operation only -US-PLM,91897,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,seasonally operated (mid-April -November) -US-PLM,91896,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-PLM,91896,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-PLM,91896,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20150701 -US-PLM,91896,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Growing season operation only -US-PLM,91896,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,seasonally operated (mid-April -November) -US-PLM,91898,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-PLM,91898,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-PLM,91898,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20150701 -US-PLM,91898,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Growing season operation only -US-PLM,91898,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,seasonally operated (mid-April -November) -US-PLM,91902,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-PLM,91902,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CH4 -US-PLM,91902,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201904 -US-PLM,91902,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,201911 -US-PLM,91902,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Growing season operation only -US-PLM,23000963,GRP_HEADER,SITE_NAME,Plum Island Low Marsh -US-PLM,79851,GRP_IGBP,IGBP,WET -US-PLM,79851,GRP_IGBP,IGBP_COMMENT,Spartina -US-PLM,91910,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-PLM,91910,GRP_LAND_OWNERSHIP,LAND_OWNER,Town -US-PLM,85898,GRP_LOCATION,LOCATION_LAT,42.7345 -US-PLM,85898,GRP_LOCATION,LOCATION_LONG,-70.8382 -US-PLM,85898,GRP_LOCATION,LOCATION_ELEV,1 -US-PLM,79854,GRP_NETWORK,NETWORK,AmeriFlux -US-PLM,92792,GRP_NETWORK,NETWORK,LTER -US-PLM,1700008238,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Feagin, R. A., Forbrich, I., Huff, T. P., Barr, J. G., Ruiz‐Plancarte, J., Fuentes, J. D., Najjar, R. G., Vargas, R., Vázquez‐Lule, A., Windham‐Myers, L., Kroeger, K. D., Ward, E. J., Moore, G. W., Leclerc, M., Krauss, K. W., Stagg, C. L., Alber, M., Knox, S. H., Schäfer, K. V., Bianchi, T. S., Hutchings, J. A., Nahrawi, H., Noormets, A., Mitra, B., Jaimes, A., Hinson, A. L., Bergamaschi, B., King, J. S., Miao, G. (2020) Tidal Wetland Gross Primary Production Across The Continental United States, 2000–2019, Global Biogeochemical Cycles, 34(2), " -US-PLM,1700008238,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2019GB006349 -US-PLM,1700008238,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-PLM,79855,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"estuarine carbon cycling, sea level rise" -US-PLM,79856,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"7 MBL Street, Woods Hole, MA 02540" -US-PLM,79857,GRP_SITE_CHAR,TERRAIN,Flat -US-PLM,79857,GRP_SITE_CHAR,ASPECT,FLAT -US-PLM,79857,GRP_SITE_CHAR,WIND_DIRECTION,SW -US-PLM,79857,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,600 -US-PLM,79857,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,30 -US-PLM,79858,GRP_SITE_DESC,SITE_DESC,"The site is a salt marsh located within the Plum Island Sound estuary, which is characterized by a tidal range of 2.5-3m and a vegetation cover of Spartina alterniflora. Elevation of the low marsh is about 1m NAVD88." -US-PLM,79859,GRP_SITE_FUNDING,SITE_FUNDING,NSF-OCE -US-PLM,79860,GRP_STATE,STATE,MA -US-PLM,79863,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Anne Giblin -US-PLM,79863,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-PLM,79863,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,agiblin@mbl.edu -US-PLM,79863,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Marine Biological Laboratory -US-PLM,79863,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"7 MBL Street, Woods Hole, MA 02540" -US-PLM,92765,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Inke Forbrich -US-PLM,92765,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-PLM,92765,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,iforbrich@mbl.edu -US-PLM,92765,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Marine Biological Laboratory -US-PLM,79862,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Hap Garritt -US-PLM,79862,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,DataManager -US-PLM,79862,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,hgarritt@mbl.edu -US-PLM,79862,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Marine Biological Laboratory -US-PLM,79864,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-PLM,79865,GRP_TOWER_TYPE,TOWER_TYPE,triangle -US-PLM,24000963,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-PLM -US-PLM,79866,GRP_UTC_OFFSET,UTC_OFFSET,-5 -US-Pnp,79410,GRP_CLIM_AVG,MAT,7.94 -US-Pnp,79410,GRP_CLIM_AVG,MAP,875 -US-Pnp,79410,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfa -US-Pnp,27000938,GRP_COUNTRY,COUNTRY,USA -US-Pnp,81463,GRP_DOI,DOI,10.17190/AMF/1433376 -US-Pnp,81463,GRP_DOI,DOI_CITATION,"Ankur Desai (2022), AmeriFlux BASE US-Pnp Lake Mendota, Picnic Point Site, Ver. 7-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1433376" -US-Pnp,81463,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-Pnp,81325,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Pnp,81325,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Ankur Desai -US-Pnp,81325,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Pnp,81325,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,desai@aos.wisc.edu -US-Pnp,81325,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of Wisconsin Madison -US-Pnp,81327,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,University of Wisconsin Madison -US-Pnp,81327,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-Pnp,91454,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Pnp,91454,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-Pnp,91454,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20160617 -US-Pnp,91454,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Pnp,91387,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Pnp,91387,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-Pnp,91387,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20160617 -US-Pnp,91387,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Pnp,91426,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Pnp,91426,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-Pnp,91426,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20160617 -US-Pnp,91426,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Pnp,23000938,GRP_HEADER,SITE_NAME,"Lake Mendota, Picnic Point Site" -US-Pnp,79414,GRP_IGBP,IGBP,WAT -US-Pnp,79414,GRP_IGBP,IGBP_DATE_START,201607010000 -US-Pnp,79407,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-Pnp,79407,GRP_LAND_OWNERSHIP,LAND_OWNER,Land owned by UW-Madison -US-Pnp,79406,GRP_LOCATION,LOCATION_LAT,43.0896 -US-Pnp,79406,GRP_LOCATION,LOCATION_LONG,-89.4158 -US-Pnp,79406,GRP_LOCATION,LOCATION_ELEV,260 -US-Pnp,79419,GRP_NETWORK,NETWORK,AmeriFlux -US-Pnp,1700003849,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"David E. Reed, Hilary A. Dugan, Amelia L. Flannery, Ankur R. Desai (2018) Carbon Sink And Source Dynamics Of A Eutrophic Deep Lake Using Multiple Flux Observations Over Multiple Years, Limnology And Oceanography Letters, (), " -US-Pnp,1700003849,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/LOL2.10075 -US-Pnp,1700003849,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Pnp,1700008967,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"David E. Reed, Hilary A. Dugan, Amelia L. Flannery, Ankur R. Desai (2018) Carbon Sink And Source Dynamics Of A Eutrophic Deep Lake Using Multiple Flux Observations Over Multiple Years, Limnology And Oceanography Letters, 36(4), 527-534" -US-Pnp,1700008967,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/LOL2.10075 -US-Pnp,1700008967,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Pnp,1700000972,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Reed, D. E., Desai, A. R., Whitaker, E. C., Nuckles, H. (2019) Evaluation Of Low-Cost, Automated Lake Ice Thickness Measurements, Journal Of Atmospheric And Oceanic Technology, 36(4), 527-534" -US-Pnp,1700000972,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1175/JTECH-D-18-0214.1 -US-Pnp,1700000972,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Pnp,79418,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,Lake/Atmosphere flux study -US-Pnp,79417,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"1225 W Dayton St, Madison, WI 53706" -US-Pnp,79405,GRP_SITE_CHAR,TERRAIN,Flat -US-Pnp,79405,GRP_SITE_CHAR,ASPECT,FLAT -US-Pnp,79405,GRP_SITE_CHAR,WIND_DIRECTION,S -US-Pnp,79412,GRP_SITE_DESC,SITE_DESC,The site is located on the shoreline of Lake Mendota on the rooftop of UW-Madison's Center for Limnology. -US-Pnp,95079,GRP_SITE_FUNDING,SITE_FUNDING,NSF DEB-1440297 -US-Pnp,79421,GRP_STATE,STATE,WI -US-Pnp,79408,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Ankur Desai -US-Pnp,79408,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Pnp,79408,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,desai@aos.wisc.edu -US-Pnp,79408,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Wisconsin Madison -US-Pnp,79416,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,David Reed -US-Pnp,79416,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-Pnp,79416,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,david.edwin.reed@gmail.com -US-Pnp,79413,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Jonathan Thom -US-Pnp,79413,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,DataManager -US-Pnp,79413,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,jthom@ssec.wisc.edu -US-Pnp,79409,GRP_TOWER_POWER,TOWER_POWER,Direct power -US-Pnp,79415,GRP_TOWER_TYPE,TOWER_TYPE,pole -US-Pnp,79422,GRP_URL,URL,http://flux.aos.wisc.edu/data/ -US-Pnp,24000938,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-Pnp -US-Pnp,81410,GRP_UTC_OFFSET,UTC_OFFSET,-6 -US-Prr,93954,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,"The US-Prr site is supported by JAMSTEC and IARC/UAF collaboration study (JICS) and Arctic Challenge for Sustainability Project (ArCS, Sept 2015 - Mar 2020) and ArCSII (Jul 2020-)." -US-Prr,11882,GRP_CLIM_AVG,MAT,-2 -US-Prr,11882,GRP_CLIM_AVG,MAP,275 -US-Prr,11882,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dwc -US-Prr,27000525,GRP_COUNTRY,COUNTRY,USA -US-Prr,15616,GRP_DOI,DOI,10.17190/AMF/1246153 -US-Prr,15616,GRP_DOI,DOI_CITATION,"Hideki Kobayashi, Hiroki Ikawa, Rikie Suzuki (2019), AmeriFlux BASE US-Prr Poker Flat Research Range Black Spruce Forest, Ver. 3-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1246153" -US-Prr,15616,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-Prr,32390,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Prr,32390,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Hideki Kobayashi -US-Prr,32390,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Prr,32390,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,hkoba@jamstec.go.jp -US-Prr,32390,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Japan Agency for Marine-Earth Science and Technology -US-Prr,91890,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Prr,91890,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Hiroki Ikawa -US-Prr,91890,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Prr,91890,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,hirokiikawa@affrc.go.jp -US-Prr,91890,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,National Agriculture and Food Research Organization -US-Prr,32389,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Prr,32389,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Rikie Suzuki -US-Prr,32389,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Prr,32389,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,rikie@jamstec.go.jp -US-Prr,32389,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Japan Agency for Marine-Earth Science and Technology -US-Prr,32392,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Japan Agency for Marine-Earth Science and Technology -US-Prr,32392,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-Prr,32391,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,JAMSTEC -US-Prr,32391,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-Prr,84750,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Undisturbed -US-Prr,11883,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Prr,11883,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-Prr,11883,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20110101 -US-Prr,11883,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Prr,11899,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Prr,11899,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-Prr,11899,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20110101 -US-Prr,11899,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Prr,11897,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Prr,11897,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-Prr,11897,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20110101 -US-Prr,11897,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Prr,23000525,GRP_HEADER,SITE_NAME,Poker Flat Research Range Black Spruce Forest -US-Prr,89120,GRP_HEIGHTC,HEIGHTC,2.53 -US-Prr,89120,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Prr,89120,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,353 -US-Prr,89120,GRP_HEIGHTC,HEIGHTC_APPROACH,"When Height < 5m, Direct measurements by a sounding rod. When height >= 5m, Laser RangeFinder" -US-Prr,89120,GRP_HEIGHTC,HEIGHTC_DATE,20140911 -US-Prr,89120,GRP_HEIGHTC,HEIGHTC_COMMENT,The mean canopy height was evalulated only trees > 1.3 m -US-Prr,11884,GRP_IGBP,IGBP,ENF -US-Prr,11884,GRP_IGBP,IGBP_COMMENT,Open black spruce forest (1.A.2.f) (Viereck et al. 1992) -US-Prr,11885,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -US-Prr,11885,GRP_LAND_OWNERSHIP,LAND_OWNER,"University of Alaska, Fairbanks" -US-Prr,11886,GRP_LOCATION,LOCATION_LAT,65.1237 -US-Prr,11886,GRP_LOCATION,LOCATION_LONG,-147.4876 -US-Prr,11886,GRP_LOCATION,LOCATION_ELEV,210 -US-Prr,11886,GRP_LOCATION,LOCATION_DATE_START,20110101 -US-Prr,11887,GRP_NETWORK,NETWORK,AmeriFlux -US-Prr,1700003384,GRP_REFERENCE_PAPER,REFERENCE_PAPER," (2015) Understory CO2, Sensible Heat, and Latent Heat Fluxes in a Black Spruce Forest in Interior Alaska, Agricultural And Forest Meteorology, 214-215(2), 80-90" -US-Prr,1700003384,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2015.08.247 -US-Prr,1700003384,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Prr,1700004215,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Byun, E., Yang, J., Kim, Y., Ahn, J. (2017) Trapped Greenhouse Gases In The Permafrost Active Layer: Preliminary Results For Methane Peaks In Vertical Profiles Of Frozen Alaskan Soil Cores, Permafrost And Periglacial Processes, 28(2), 477-484" -US-Prr,1700004215,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/PPP.1935 -US-Prr,1700004215,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Prr,1700001632,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Baldocchi, D. D., Poindexter, C., Abraha, M., Desai, A. R., Bohrer, G., Arain, M. A., Griffis, T., Blanken, P. D., O'Halloran, T. L., Thomas, R. Q., Zhang, Q., Burns, S. P., Frank, J. M., Christian, D., Brown, S., Black, T. A., Gough, C. M., Law, B. E., Lee, X., Chen, J., Reed, D. E., Massman, W. J., Clark, K., Hatfield, J., Prueger, J., Bracho, R., Baker, J. M., Martin, T. A. (2018) Temporal Dynamics Of Aerodynamic Canopy Height Derived From Eddy Covariance Momentum Flux Data Across North American Flux Networks, Geophysical Research Letters, 45(3), 9275–9287" -US-Prr,1700001632,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018GL079306 -US-Prr,1700001632,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Prr,1700004443,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(3), 108350" -US-Prr,1700004443,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -US-Prr,1700004443,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Prr,1700006597,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Fischer, R., Walsh, J. E., Euskirchen, E. S., Bieniek, P. A. (2018) Regional Climate Model Simulation Of Surface Moisture Flux Variations In Northern Terrestrial Regions, Atmospheric And Climate Sciences, 08(01), 29-54" -US-Prr,1700006597,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.4236/ACS.2018.81003 -US-Prr,1700006597,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Prr,1700003741,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Ikawa, H., Nakai, T., Busey, R. C., Kim, Y., Kobayashi, H., Nagai, S., Ueyama, M., Saito, K., Nagano, H., Suzuki, R., Hinzman, L. (2015) Understory Co 2 , Sensible Heat, And Latent Heat Fluxes In A Black Spruce Forest In Interior Alaska, Agricultural And Forest Meteorology, 214-215(2), 80-90" -US-Prr,1700003741,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2015.08.247 -US-Prr,1700003741,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Prr,1700008343,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Kobayashi, H., Nagai, S., Kim, Y., Yang, W., Ikeda, K., Ikawa, H., Nagano, H., Suzuki, R. (2018) In Situ Observations Reveal How Spectral Reflectance Responds To Growing Season Phenology Of An Open Evergreen Forest In Alaska, Remote Sensing, 10(7), 1071" -US-Prr,1700008343,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.3390/RS10071071 -US-Prr,1700008343,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Prr,1700002679,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Kobayashi, H., Suzuki, R., Nagai, S., Nakai, T., Kim, Y. (2014) Spatial Scale And Landscape Heterogeneity Effects On Fapar In An Open-Canopy Black Spruce Forest In Interior Alaska, Ieee Geoscience And Remote Sensing Letters, 11(2), 564-568" -US-Prr,1700002679,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1109/LGRS.2013.2278426 -US-Prr,1700002679,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Prr,1700000066,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Kobayashi, H., Yunus, A. P., Nagai, S., Sugiura, K., Kim, Y., Van Dam, B., Nagano, H., Zona, D., Harazono, Y., Bret-Harte, M. S., Ichii, K., Ikawa, H., Iwata, H., Oechel, W. C., Ueyama, M., Suzuki, R. (2016) Latitudinal Gradient Of Spruce Forest Understory And Tundra Phenology In Alaska As Observed From Satellite And Ground-Based Data, Remote Sensing Of Environment, 177(2), 160-170" -US-Prr,1700000066,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.RSE.2016.02.020 -US-Prr,1700000066,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Prr,1700002133,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Nagai, S., Akitsu, T., Saitoh, T. M., Busey, R. C., Fukuzawa, K., Honda, Y., Ichie, T., Ide, R., Ikawa, H., Iwasaki, A., Iwao, K., Kajiwara, K., Kang, S., Kim, Y., Khoon, K. L., Kononov, A. V., Kosugi, Y., Maeda, T., Mamiya, W., Matsuoka, M., Maximov, T. C., Menzel, A., Miura, T., Mizunuma, T., Morozumi, T., Motohka, T., Muraoka, H., Nagano, H., Nakai, T., Nakaji, T., Oguma, H., Ohta, T., Ono, K., Pungga, R. A., Petrov, R. E., Sakai, R., Schunk, C., Sekikawa, S., Shakhmatov, R., Son, Y., Sugimoto, A., Suzuki, R., Takagi, K., Takanashi, S., Tei, S., Tsuchida, S., Yamamoto, H., Yamasaki, E., Yamashita, M., Yoon, T. K., Yoshida, T., Yoshimura, M., Yoshitake, S., Wilkinson, M., Wingate, L., Nasahara, K. N. (2018) 8 Million Phenological And Sky Images From 29 Ecosystems From The Arctic To The Tropics: The Phenological Eyes Network, Ecological Research, 7(3), 223-234" -US-Prr,1700002133,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1007/S11284-018-1633-X -US-Prr,1700002133,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Prr,1700004632,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Nagai, S., Nakai, T., Saitoh, T. M., Busey, R. C., Kobayashi, H., Suzuki, R., Muraoka, H., Kim, Y. (2013) Seasonal Changes In Camera-Based Indices From An Open Canopy Black Spruce Forest In Alaska, And Comparison With Indices From A Closed Canopy Evergreen Coniferous Forest In Japan, Polar Science, 7(2), 125-135" -US-Prr,1700004632,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.POLAR.2012.12.001 -US-Prr,1700004632,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Prr,1700001521,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Nagano, H., Ikawa, H., Nakai, T., Matsushima-Yashima, M., Kobayashi, H., Kim, Y., Suzuki, R. (2018) Extremely Dry Environment Down-Regulates Nighttime Respiration Of A Black Spruce Forest In Interior Alaska, Agricultural And Forest Meteorology, 249(2), 297-309" -US-Prr,1700001521,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2017.11.001 -US-Prr,1700001521,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Prr,1700007413,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Nakai, T., Kim, Y., Busey, R. C., Suzuki, R., Nagai, S., Kobayashi, H., Park, H., Sugiura, K., Ito, A. (2013) Characteristics Of Evapotranspiration From A Permafrost Black Spruce Forest In Interior Alaska, Polar Science, 7(2), 136-148" -US-Prr,1700007413,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.POLAR.2013.03.003 -US-Prr,1700007413,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Primary_Citation -US-Prr,1700001017,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Saito, K., Iwahana, G., Ikawa, H., Nagano, H., Busey, R. C. (2018) Links Between Annual Surface Temperature Variation And Land Cover Heterogeneity For A Boreal Forest As Characterized By Continuous, Fibre-Optic Dts Monitoring, Geoscientific Instrumentation, Methods And Data Systems, 7(3), 223-234" -US-Prr,1700001017,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.5194/GI-7-223-2018 -US-Prr,1700001017,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Prr,1700005193,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Suzuki, R., Kim, Y., Ishii, R. (2013) Sensitivity Of The Backscatter Intensity Of Alos/Palsar To The Above-Ground Biomass And Other Biophysical Parameters Of Boreal Forest In Alaska, Polar Science, 7(2), 100-112" -US-Prr,1700005193,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.POLAR.2013.03.001 -US-Prr,1700005193,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Prr,1700000150,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Tripathi, B. M., Kim, M., Kim, Y., Byun, E., Yang, J., Ahn, J., Lee, Y. K. (2018) Variations In Bacterial And Archaeal Communities Along Depth Profiles Of Alaskan Soil Cores, Scientific Reports, 8(1), 477-484" -US-Prr,1700000150,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1038/S41598-017-18777-X -US-Prr,1700000150,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Prr,1700000867,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Tripathi, B. M., Kim, M., Kim, Y., Byun, E., Yang, J., Ahn, J., Lee, Y. K. (2018) Variations In Bacterial And Archaeal Communities Along Depth Profiles Of Alaskan Soil Cores, Scientific Reports, 8(1), 98-111" -US-Prr,1700000867,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1038/S41598-017-18777-X -US-Prr,1700000867,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Prr,1700006003,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Ueyama, M., Kudo, S., Iwama, C., Nagano, H., Kobayashi, H., Harazono, Y. and Yoshikawa, K. (2014) Does summer warming reduce black spruce productivity in interior Alaska?, J. Forest Res., 20(2), 52-59" -US-Prr,1700006003,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Prr,1700005418,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Ueyama, M., Tahara, N., Iwata, H., Euskirchen, E. S., Ikawa, H., Kobayashi, H., Nagano, H., Nakai, T., and Harazono, Y. (2016) Optimization of a biochemical model with eddy covariance measurements in black spruce forests of Alaska for estimating CO2 fertilization effects, Agric. Forest Meteorol., 222(2), 98-111" -US-Prr,1700005418,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Prr,1700001323,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Ueyama, M., Tahara, N., Iwata, H., Euskirchen, E. S., Ikawa, H., Kobayashi, H., Nagano, H., Nakai, T., Harazono, Y. (2016) Optimization Of A Biochemical Model With Eddy Covariance Measurements In Black Spruce Forests Of Alaska For Estimating Co 2 Fertilization Effects, Agricultural And Forest Meteorology, 222(2), 98-111" -US-Prr,1700001323,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2016.03.007 -US-Prr,1700001323,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Prr,1700006870,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Xinchen Lu , Xiao Cheng, Xianglan Li Jiquan Chen, Minmin Sun, Ming Ji, Hong He, Siyu Wang, Sen Li, Jianwu Tang (2018) Seasonal patterns of canopy photosynthesis captured by remotely sensed sun-induced fluorescence and vegetation indexes in mid-to-high latitude forests: A cross-platform comparison, Science of the Total Environment, 644(2), 439-451" -US-Prr,1700006870,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.SCITOTENV.2018.06.269 -US-Prr,1700006870,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Prr,1700008076,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Xu, B., Arain, M. A., Black, T. A., Law, B. E., Pastorello, G. Z., Chu, H. (2020) Seasonal Variability Of Forest Sensitivity To Heat And Drought Stresses: A Synthesis Based On Carbon Fluxes From North American Forest Ecosystems, Global Change Biology, 26(2), 901-918" -US-Prr,1700008076,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/GCB.14843 -US-Prr,1700008076,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Prr,1700003465,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Yang, W., Kobayashi, H., Chen, X., Nasahara, K. N., Suzuki, R., Kondoh, A. (2017) Modeling Three-Dimensional Forest Structures To Drive Canopy Radiative Transfer Simulations Of Bidirectional Reflectance Factor, International Journal Of Digital Earth, 249(2), 1-20" -US-Prr,1700003465,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1080/17538947.2017.1353146 -US-Prr,1700003465,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Prr,11889,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"soil CO2 flux measurements, phenological camera" -US-Prr,30725,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"3173-25 Showamachi, Kanazawa-ku, Yokohama, 236-0001, Japan" -US-Prr,11891,GRP_SITE_CHAR,TERRAIN,Flat -US-Prr,11891,GRP_SITE_CHAR,ASPECT,FLAT -US-Prr,11891,GRP_SITE_CHAR,WIND_DIRECTION,SW -US-Prr,11891,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,300 -US-Prr,11891,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,210 -US-Prr,85193,GRP_SITE_DESC,SITE_DESC,"This site is located in a blackspruce forest within the property of the Poker Flat Research Range, University of Alaska, Fairbanks. Time-lapse image of the canopy is measured at the same time to relate flux data to satellite images." -US-Prr,11893,GRP_SITE_FUNDING,SITE_FUNDING,JAMSTEC -US-Prr,11894,GRP_STATE,STATE,AK -US-Prr,30723,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Hideki Kobayashi -US-Prr,30723,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Prr,30723,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,hkoba@jamstec.go.jp -US-Prr,30723,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Japan Agency for Marine-Earth Science and Technology -US-Prr,30723,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"3173-25 Showamachi, Kanazawa-ku, Yokohama, 236-0001, Japan" -US-Prr,84751,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Hiroki Ikawa -US-Prr,84751,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Prr,84751,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,hikawa.biomet@gmail.com -US-Prr,84751,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"Institute for Agro-Environmental Sciences, NARO" -US-Prr,85194,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Robert Busey -US-Prr,85194,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Technician -US-Prr,85194,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,rcbusey@alaska.edu -US-Prr,85194,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"International Arctic Research Center, University of Alaska, Fairbanks" -US-Prr,85194,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"930 N Koyukuk Dr, Fairbanks, AK 99775" -US-Prr,85195,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Go Iwahana -US-Prr,85195,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Affiliate -US-Prr,85195,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,giwahana@alaska.edu -US-Prr,85195,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"International Arctic Research Center, University of Alaska, Fairbanks" -US-Prr,81411,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Rikie Suzuki -US-Prr,81411,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Affiliate -US-Prr,81411,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,rikie@jamstec.go.jp -US-Prr,81411,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Japan Agency for Marine-Earth Science and Technology -US-Prr,81411,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"3173-25 Showamachi, Kanazawa-ku, Yokohama, 236-0001, Japan" -US-Prr,84752,GRP_TOWER_POWER,TOWER_POWER,Direct power -US-Prr,84753,GRP_TOWER_TYPE,TOWER_TYPE,walk-up -US-Prr,79387,GRP_URL,URL,http://monitors.iarc.uaf.edu/poker-flat-research-range/data.php -US-Prr,24000525,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-Prr -US-Prr,11896,GRP_UTC_OFFSET,UTC_OFFSET,-9 -US-PSH,86808,GRP_CLIM_AVG,MAT,15.6 -US-PSH,86808,GRP_CLIM_AVG,MAP,191 -US-PSH,86808,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Bsk -US-PSH,27001071,GRP_COUNTRY,COUNTRY,USA -US-PSH,91695,GRP_DOI,DOI,10.17190/AMF/1617719 -US-PSH,91695,GRP_DOI,DOI_CITATION,"Ray G. Anderson (2020), AmeriFlux BASE US-PSH USSL San Joaquin Valley Pistachio High, Ver. 1-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1617719" -US-PSH,91695,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-PSH,91592,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-PSH,91592,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Ray G. Anderson -US-PSH,91592,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-PSH,91592,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,ray.anderson@usda.gov -US-PSH,91592,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"USDA-Agricultural Research Service, US Salinity Laboratory" -US-PSH,91652,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,"USDA-Agricultural Research Service, US Salinity Laboratory" -US-PSH,91652,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-PSH,91617,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,USDA ARS Office of National Programs (NP 211) -US-PSH,91617,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-PSH,86811,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Agriculture -US-PSH,86803,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-PSH,86803,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-PSH,86803,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201610141730 -US-PSH,86803,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-PSH,86803,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,Will be operational through end of 2019 growing season -US-PSH,86798,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-PSH,86798,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-PSH,86798,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201610141730 -US-PSH,86798,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-PSH,86798,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,Will be operational through end of 2019 growing season -US-PSH,86796,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-PSH,86796,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-PSH,86796,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201610141730 -US-PSH,86796,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-PSH,86796,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,Will be operational through end of 2019 growing season -US-PSH,23001071,GRP_HEADER,SITE_NAME,USSL San Joaquin Valley Pistachio High -US-PSH,94753,GRP_IGBP,IGBP,DBF -US-PSH,94753,GRP_IGBP,IGBP_DATE_START,200802010000 -US-PSH,94753,GRP_IGBP,IGBP_COMMENT,pistachio orchard -US-PSH,86797,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -US-PSH,86797,GRP_LAND_OWNERSHIP,LAND_OWNER,Not public at this time -US-PSH,94749,GRP_LOCATION,LOCATION_LAT,36.2347 -US-PSH,94749,GRP_LOCATION,LOCATION_LONG,-119.9247 -US-PSH,94749,GRP_LOCATION,LOCATION_ELEV,70 -US-PSH,94749,GRP_LOCATION,LOCATION_DATE_START,201610141730 -US-PSH,94749,GRP_LOCATION,LOCATION_COMMENT,64.8 ha orchard -US-PSH,86799,GRP_NETWORK,NETWORK,AmeriFlux -US-PSH,86805,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,Soil and water salinity impact on crop productivity and water use -US-PSH,86807,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"George E. Brown Jr. Salinity Laboratory Building, 450 W. Big Springs Rd., Riverside, CA 92507-4617USA" -US-PSH,86809,GRP_SITE_CHAR,TERRAIN,Flat -US-PSH,86809,GRP_SITE_CHAR,ASPECT,NW -US-PSH,86809,GRP_SITE_CHAR,WIND_DIRECTION,NW -US-PSH,86809,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,750 -US-PSH,86809,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,0 -US-PSH,86795,GRP_SITE_DESC,SITE_DESC,High soil salinity pistachio orchard in San Joaquin Valley. -US-PSH,86810,GRP_SITE_FUNDING,SITE_FUNDING,USDA ARS Office of National Programs (NP 211) -US-PSH,86802,GRP_STATE,STATE,CA -US-PSH,86793,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Ray G. Anderson -US-PSH,86793,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-PSH,86793,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,ray.anderson@usda.gov -US-PSH,86793,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"USDA-Agricultural Research Service, US Salinity Laboratory" -US-PSH,86793,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"George E. Brown Jr. Salinity Laboratory Building, 450 W. Big Springs Rd., Riverside, CA 92507-4617 USA" -US-PSH,86804,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-PSH,86794,GRP_TOWER_TYPE,TOWER_TYPE,walk-up -US-PSH,24001071,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-PSH -US-PSH,86806,GRP_UTC_OFFSET,UTC_OFFSET,-7 -US-PSH,86806,GRP_UTC_OFFSET,UTC_OFFSET_DATE_START,201610141730 -US-PSH,86806,GRP_UTC_OFFSET,UTC_OFFSET_COMMENT,Dataloggers kept in Pacific Daylight Time (GMT-7) year round -US-PSL,86776,GRP_CLIM_AVG,MAT,16.7 -US-PSL,86776,GRP_CLIM_AVG,MAP,311 -US-PSL,86776,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Bsk -US-PSL,27001070,GRP_COUNTRY,COUNTRY,USA -US-PSL,91686,GRP_DOI,DOI,10.17190/AMF/1617720 -US-PSL,91686,GRP_DOI,DOI_CITATION,"Ray G. Anderson (2020), AmeriFlux BASE US-PSL USSL San Joaquin Valley Pistachio Low, Ver. 1-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1617720" -US-PSL,91686,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-PSL,91591,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-PSL,91591,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Ray G. Anderson -US-PSL,91591,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-PSL,91591,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,ray.anderson@usda.gov -US-PSL,91591,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"USDA-Agricultural Research Service, US Salinity Laboratory" -US-PSL,91660,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,"USDA-Agricultural Research Service, US Salinity Laboratory" -US-PSL,91660,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-PSL,91638,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,USDA ARS Office of National Programs (NP 211) -US-PSL,91638,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-PSL,86791,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Agriculture -US-PSL,86788,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-PSL,86788,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-PSL,86788,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201608061230 -US-PSL,86788,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-PSL,86788,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,Will be operational through end of 2019 growing season -US-PSL,86786,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-PSL,86786,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-PSL,86786,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201608061230 -US-PSL,86786,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-PSL,86786,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,Will be operational through end of 2019 growing season -US-PSL,86774,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-PSL,86774,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-PSL,86774,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201608061230 -US-PSL,86774,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-PSL,86774,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,Will be operational through end of 2019 growing season -US-PSL,23001070,GRP_HEADER,SITE_NAME,USSL San Joaquin Valley Pistachio Low -US-PSL,86787,GRP_IGBP,IGBP,DBF -US-PSL,86787,GRP_IGBP,IGBP_DATE_START,200602010000 -US-PSL,86787,GRP_IGBP,IGBP_COMMENT,pistachio orchard -US-PSL,86775,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -US-PSL,86775,GRP_LAND_OWNERSHIP,LAND_OWNER,Not public at this time -US-PSL,86778,GRP_LOCATION,LOCATION_LAT,36.8276 -US-PSL,86778,GRP_LOCATION,LOCATION_LONG,-120.1397 -US-PSL,86778,GRP_LOCATION,LOCATION_ELEV,65 -US-PSL,86778,GRP_LOCATION,LOCATION_DATE_START,201608061230 -US-PSL,86778,GRP_LOCATION,LOCATION_COMMENT,64.8 ha orchard -US-PSL,86779,GRP_NETWORK,NETWORK,AmeriFlux -US-PSL,86785,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,Soil and water salinity impact on crop productivity and water use -US-PSL,86789,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"George E. Brown Jr. Salinity Laboratory Building, 450 W. Big Springs Rd., Riverside, CA 92507-4617USA" -US-PSL,86792,GRP_SITE_CHAR,TERRAIN,Flat -US-PSL,86792,GRP_SITE_CHAR,ASPECT,NW -US-PSL,86792,GRP_SITE_CHAR,WIND_DIRECTION,NW -US-PSL,86792,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,200 -US-PSL,86792,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,0 -US-PSL,86782,GRP_SITE_DESC,SITE_DESC,Low soil salinity pistachio orchard in San Joaquin Valley. -US-PSL,86783,GRP_SITE_FUNDING,SITE_FUNDING,USDA ARS Office of National Programs (NP 211) -US-PSL,86777,GRP_STATE,STATE,CA -US-PSL,86780,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Ray G. Anderson -US-PSL,86780,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-PSL,86780,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,ray.anderson@usda.gov -US-PSL,86780,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"USDA-Agricultural Research Service, US Salinity Laboratory" -US-PSL,86780,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"George E. Brown Jr. Salinity Laboratory Building, 450 W. Big Springs Rd., Riverside, CA 92507-4617 USA" -US-PSL,86790,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-PSL,86784,GRP_TOWER_TYPE,TOWER_TYPE,walk-up -US-PSL,24001070,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-PSL -US-PSL,86781,GRP_UTC_OFFSET,UTC_OFFSET,-7 -US-PSL,86781,GRP_UTC_OFFSET,UTC_OFFSET_DATE_START,201608061230 -US-PSL,86781,GRP_UTC_OFFSET,UTC_OFFSET_COMMENT,Dataloggers kept in Pacific Daylight Time (GMT-7) year round -US-RGA,101394,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,"This work was funded through the U.S. Department of Energy, ARPA-E, under Cooperative Agreement DE-AR0001228 led by ARVA Intelligence Corp. (https://www.arvaintelligence.com/) in collaboration with Lawrence Berkeley National Laboratory (LBNL)." -US-RGA,96281,GRP_CLIM_AVG,MAT,16.7 -US-RGA,96281,GRP_CLIM_AVG,MAP,1250 -US-RGA,96281,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Csa -US-RGA,27001195,GRP_COUNTRY,COUNTRY,USA -US-RGA,96271,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Agriculture -US-RGA,96264,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-RGA,96264,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-RGA,96264,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,202104080000 -US-RGA,96264,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-RGA,96265,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-RGA,96265,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CH4 -US-RGA,96265,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,202104080000 -US-RGA,96265,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-RGA,96268,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-RGA,96268,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-RGA,96268,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,202104080000 -US-RGA,96268,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-RGA,101163,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-RGA,101163,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,N2O -US-RGA,101163,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,202105250000 -US-RGA,101163,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-RGA,23001195,GRP_HEADER,SITE_NAME,Arkansas Corn Farm -US-RGA,96267,GRP_IGBP,IGBP,CRO -US-RGA,96267,GRP_IGBP,IGBP_COMMENT,Corn (zea mays) -US-RGA,101164,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -US-RGA,101164,GRP_LAND_OWNERSHIP,LAND_OWNER,Glennoe Farmland Partners LLC -US-RGA,101165,GRP_LOCATION,LOCATION_LAT,34.4121 -US-RGA,101165,GRP_LOCATION,LOCATION_LONG,-91.6752 -US-RGA,101165,GRP_LOCATION,LOCATION_ELEV,61.00 -US-RGA,101165,GRP_LOCATION,LOCATION_DATE_START,202104080000 -US-RGA,96285,GRP_NETWORK,NETWORK,AmeriFlux -US-RGA,101181,GRP_NETWORK,NETWORK,Phenocam -US-RGA,96274,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,Sustainability of bioenergy crops and residues; Reduction of vegetation and fallow season GHG emissions -US-RGA,101162,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"10 State Highway 152, Humphrey, AR 72073" -US-RGA,96273,GRP_SITE_CHAR,TERRAIN,Flat -US-RGA,96273,GRP_SITE_CHAR,ASPECT,S -US-RGA,96273,GRP_SITE_CHAR,WIND_DIRECTION,S -US-RGA,96273,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,400 -US-RGA,96273,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,5 -US-RGA,96280,GRP_SITE_DESC,SITE_DESC,"Commercially farmed corn variety, field in Arkansas County, Arkansas. Part of a multi-year, ground-truthing field study under the DOE ARPA-E SMARTFARM project (https://arpa-e.energy.gov/news-and-media/blog-posts/smartfarm-changing-whats-possible-agriculture)." -US-RGA,96275,GRP_SITE_FUNDING,SITE_FUNDING,"This work is supported by the United States Department of Energy (DOE), Advanced Research Projects Agency - Energy (ARPA-E)." -US-RGA,101196,GRP_STATE,STATE,AR -US-RGA,101182,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Michael R. Schuppenhauer -US-RGA,101182,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-RGA,101182,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,mschuppenhauer@lbl.gov -US-RGA,101182,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Arva Intelligence Corp. -US-RGA,101161,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Sebastien C. Biraud -US-RGA,101161,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-RGA,101161,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,SCBiraud@lbl.gov -US-RGA,101161,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Lawrence Berkeley National Laboratory -US-RGA,101161,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"One Cyclotron Road, Berkeley, CA 94720" -US-RGA,101160,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Stephen W. Chan -US-RGA,101160,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-RGA,101160,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,SWChan@lbl.gov -US-RGA,101160,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Lawrence Berkeley National Laboratory -US-RGA,101160,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"One Cyclotron Road, Berkeley, CA 94720" -US-RGA,96283,GRP_TOWER_POWER,TOWER_POWER,Direct power -US-RGA,96286,GRP_TOWER_TYPE,TOWER_TYPE,tripod -US-RGA,24001195,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-RGA -US-RGA,96270,GRP_UTC_OFFSET,UTC_OFFSET,-6 -US-RGA,96270,GRP_UTC_OFFSET,UTC_OFFSET_DATE_START,202104080000 -US-RGB,101392,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,"This work was funded through the U.S. Department of Energy, ARPA-E, under Cooperative Agreement DE-AR0001228 led by ARVA Intelligence Corp. (https://www.arvaintelligence.com/) in collaboration with Lawrence Berkeley National Laboratory (LBNL)." -US-RGB,95114,GRP_CLIM_AVG,MAT,16 -US-RGB,95114,GRP_CLIM_AVG,MAP,737 -US-RGB,95114,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Csa -US-RGB,27001175,GRP_COUNTRY,COUNTRY,USA -US-RGB,100771,GRP_DOI,DOI,10.17190/AMF/1870591 -US-RGB,100771,GRP_DOI,DOI_CITATION,"Michael Schuppenhauer, Sebastien C. Biraud (2022), AmeriFlux BASE US-RGB Butte County Rice Farm, Ver. 2-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1870591" -US-RGB,100771,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-RGB,100753,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-RGB,100753,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Michael Schuppenhauer -US-RGB,100753,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-RGB,100753,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,m.schuppenhauer@arvaintelligence.com -US-RGB,100753,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Arva Intelligence Corp -US-RGB,100756,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-RGB,100756,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Sebastien C. Biraud -US-RGB,100756,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-RGB,100756,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,SCBiraud@lbl.gov -US-RGB,100756,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Lawrence Berkeley National Laboratory -US-RGB,100766,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Arva Intelligence Corp -US-RGB,100766,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-RGB,100763,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Lawrence Berkeley National Laboratory -US-RGB,100763,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-RGB,100760,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,"This work is supported by the United States Department of Energy (DOE), Advanced Research Projects Agency - Energy (ARPA-E)." -US-RGB,100760,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-RGB,95103,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Agriculture -US-RGB,95108,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-RGB,95108,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-RGB,95108,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,202101240000 -US-RGB,95108,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-RGB,95095,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-RGB,95095,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CH4 -US-RGB,95095,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,202101240000 -US-RGB,95095,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-RGB,95101,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-RGB,95101,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-RGB,95101,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,202101240000 -US-RGB,95101,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-RGB,101170,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-RGB,101170,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,N2O -US-RGB,101170,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,202103250000 -US-RGB,101170,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-RGB,23001175,GRP_HEADER,SITE_NAME,Butte County Rice Farm -US-RGB,95115,GRP_IGBP,IGBP,CRO -US-RGB,95115,GRP_IGBP,IGBP_COMMENT,Rice (oryza sativa) -US-RGB,101172,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -US-RGB,101172,GRP_LAND_OWNERSHIP,LAND_OWNER,Tenndoor Farms LLC -US-RGB,101171,GRP_LOCATION,LOCATION_LAT,39.5771 -US-RGB,101171,GRP_LOCATION,LOCATION_LONG,-121.8670 -US-RGB,101171,GRP_LOCATION,LOCATION_ELEV,33 -US-RGB,101171,GRP_LOCATION,LOCATION_DATE_START,202101240000 -US-RGB,95112,GRP_NETWORK,NETWORK,AmeriFlux -US-RGB,101387,GRP_NETWORK,NETWORK,Phenocam -US-RGB,95105,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,Sustainability of bioenergy crops and residues; Reduction of vegetation and fallow season GHG emissions -US-RGB,101169,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"One Cyclotron Road, Berkeley, CA 94720" -US-RGB,95098,GRP_SITE_CHAR,TERRAIN,Flat -US-RGB,95098,GRP_SITE_CHAR,ASPECT,NNW -US-RGB,95098,GRP_SITE_CHAR,WIND_DIRECTION,NNW -US-RGB,95098,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,500 -US-RGB,95098,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,0 -US-RGB,101390,GRP_SITE_DESC,SITE_DESC,"Commercially farmed, mid-grain japonica rice variety, field in Glenn County, California. Part of a multi-year, ground-truthing field study under the DOE ARPA-E SMARTFARM project (https://arpa-e.energy.gov/news-and-media/blog-posts/smartfarm-changing-whats-possible-agriculture). Field is approx. 30 ha in size in three checks with commercial rice over rice rotation on silty clay loam." -US-RGB,95102,GRP_SITE_FUNDING,SITE_FUNDING,"This work is supported by the United States Department of Energy (DOE), Advanced Research Projects Agency - Energy (ARPA-E)." -US-RGB,95094,GRP_STATE,STATE,CA -US-RGB,101166,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Michael R. Schuppenhauer -US-RGB,101166,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-RGB,101166,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,mschuppenhauer@lbl.gov -US-RGB,101166,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Arva Intelligence Corp. -US-RGB,101167,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Sebastien C. Biraud -US-RGB,101167,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-RGB,101167,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,SCBiraud@lbl.gov -US-RGB,101167,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Lawrence Berkeley National Laboratory -US-RGB,101167,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"One Cyclotron Road, Berkeley, CA 94720" -US-RGB,101168,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Stephen W. Chan -US-RGB,101168,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-RGB,101168,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,SWChan@lbl.gov -US-RGB,101168,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Lawrence Berkeley National Laboratory -US-RGB,101168,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"One Cyclotron Road, Berkeley, CA 94720" -US-RGB,95111,GRP_TOWER_POWER,TOWER_POWER,Direct power -US-RGB,95110,GRP_TOWER_TYPE,TOWER_TYPE,tripod -US-RGB,24001175,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-RGB -US-RGB,95107,GRP_UTC_OFFSET,UTC_OFFSET,-8 -US-RGB,95107,GRP_UTC_OFFSET,UTC_OFFSET_DATE_START,202101240000 -US-RGG,101399,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,"This work was funded through the U.S. Department of Energy, ARPA-E, under Cooperative Agreement DE-AR0001228 led by ARVA Intelligence Corp. (https://www.arvaintelligence.com/) in collaboration with Lawrence Berkeley National Laboratory (LBNL)." -US-RGG,94809,GRP_CLIM_AVG,MAT,16 -US-RGG,94809,GRP_CLIM_AVG,MAP,610 -US-RGG,94809,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Csa -US-RGG,27001172,GRP_COUNTRY,COUNTRY,USA -US-RGG,94819,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Agriculture -US-RGG,101174,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-RGG,101174,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-RGG,101174,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,202011110000 -US-RGG,101174,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20210616 -US-RGG,101174,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-RGG,101175,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-RGG,101175,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CH4 -US-RGG,101175,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,202011110000 -US-RGG,101175,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20210616 -US-RGG,101175,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-RGG,101176,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-RGG,101176,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-RGG,101176,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,202011110000 -US-RGG,101176,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20210616 -US-RGG,101176,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-RGG,23001172,GRP_HEADER,SITE_NAME,Glenn County Rice Farm -US-RGG,94808,GRP_IGBP,IGBP,CRO -US-RGG,94808,GRP_IGBP,IGBP_COMMENT,Rice (oryza sativa) -US-RGG,101173,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -US-RGG,101173,GRP_LAND_OWNERSHIP,LAND_OWNER,Fiack & Fiack -US-RGG,94803,GRP_LOCATION,LOCATION_LAT,39.5944 -US-RGG,94803,GRP_LOCATION,LOCATION_LONG,-122.0253 -US-RGG,94803,GRP_LOCATION,LOCATION_ELEV,36 -US-RGG,94803,GRP_LOCATION,LOCATION_DATE_START,202011110000 -US-RGG,94817,GRP_NETWORK,NETWORK,AmeriFlux -US-RGG,94814,GRP_NETWORK,NETWORK,Phenocam -US-RGG,94820,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,Sustainability of bioenergy crops and residues; Reduction of vegetation and fallow season GHG emissions -US-RGG,101177,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"One Cyclotron Road, Berkeley, CA 94720" -US-RGG,94807,GRP_SITE_CHAR,TERRAIN,Flat -US-RGG,94807,GRP_SITE_CHAR,ASPECT,NNW -US-RGG,94807,GRP_SITE_CHAR,WIND_DIRECTION,NNW -US-RGG,94807,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,500 -US-RGG,94807,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,0 -US-RGG,94810,GRP_SITE_DESC,SITE_DESC,"Commercially farmed, mid-grain japonica rice variety, field in Glenn County, California. Part of a multi-year, ground-truthing field study under the DOE ARPA-E SMARTFARM project (https://arpa-e.energy.gov/news-and-media/blog-posts/smartfarm-changing-whats-possible-agriculture). Field is approx. 12 ha in size (1,300 ft by 400 ft), part of a 80+ acre site in several checks with commercial rice over rice rotation on silty clay loam." -US-RGG,94799,GRP_SITE_FUNDING,SITE_FUNDING,"This work is supported by the United States Department of Energy (DOE), Advanced Research Projects Agency - Energy (ARPA-E)." -US-RGG,94805,GRP_STATE,STATE,CA -US-RGG,101180,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Michael Schuppenhauer -US-RGG,101180,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-RGG,101180,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,mschuppenhauer@lbl.gov -US-RGG,101180,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Arva Intelligence Corp. -US-RGG,101179,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Sebastien C. Biraud -US-RGG,101179,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-RGG,101179,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,SCBiraud@lbl.gov -US-RGG,101179,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Lawrence Berkeley National Laboratory -US-RGG,101179,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"One Cyclotron Road, Berkeley, CA 94720" -US-RGG,101178,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Stephen W. Chan -US-RGG,101178,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-RGG,101178,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,SWChan@lbl.gov -US-RGG,101178,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Lawrence Berkeley National Laboratory -US-RGG,101178,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"One Cyclotron Road, Berkeley, CA 94720" -US-RGG,94806,GRP_TOWER_POWER,TOWER_POWER,Direct power -US-RGG,94800,GRP_TOWER_TYPE,TOWER_TYPE,tripod -US-RGG,24001172,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-RGG -US-RGG,94811,GRP_UTC_OFFSET,UTC_OFFSET,-8 -US-RGG,94811,GRP_UTC_OFFSET,UTC_OFFSET_DATE_START,202011110000 -US-RGo,101397,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,"This work was funded through the U.S. Department of Energy, ARPA-E, under Cooperative Agreement DE-AR0001228 led by ARVA Intelligence Corp. (https://www.arvaintelligence.com/) in collaboration with Lawrence Berkeley National Laboratory (LBNL)." -US-RGo,97668,GRP_CLIM_AVG,MAT,16 -US-RGo,97668,GRP_CLIM_AVG,MAP,610 -US-RGo,97668,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Csa -US-RGo,27001201,GRP_COUNTRY,COUNTRY,USA -US-RGo,97648,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Agriculture -US-RGo,97655,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-RGo,97655,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-RGo,97655,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,202106170000 -US-RGo,97655,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-RGo,97665,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-RGo,97665,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CH4 -US-RGo,97665,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,202106170000 -US-RGo,97665,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-RGo,97661,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-RGo,97661,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-RGo,97661,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,202106170000 -US-RGo,97661,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-RGo,101189,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-RGo,101189,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,N2O -US-RGo,101189,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,202107190000 -US-RGo,101189,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-RGo,23001201,GRP_HEADER,SITE_NAME,Glenn County Organic Rice Farm -US-RGo,97650,GRP_IGBP,IGBP,CRO -US-RGo,97650,GRP_IGBP,IGBP_COMMENT,Rice (oryza sativa) -US-RGo,101195,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -US-RGo,101195,GRP_LAND_OWNERSHIP,LAND_OWNER,Massa Organics LLC -US-RGo,101191,GRP_LOCATION,LOCATION_LAT,39.6769 -US-RGo,101191,GRP_LOCATION,LOCATION_LONG,-122.0052 -US-RGo,101191,GRP_LOCATION,LOCATION_ELEV,40 -US-RGo,101191,GRP_LOCATION,LOCATION_DATE_START,202106170000 -US-RGo,97649,GRP_NETWORK,NETWORK,AmeriFlux -US-RGo,101188,GRP_NETWORK,NETWORK,Phenocam -US-RGo,97670,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,Sustainability of bioenergy crops and residues; Reduction of vegetation and fallow season GHG emissions -US-RGo,101187,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"One Cyclotron Road, Berkeley, CA 94720" -US-RGo,97667,GRP_SITE_CHAR,TERRAIN,Flat -US-RGo,97667,GRP_SITE_CHAR,ASPECT,NNW -US-RGo,97667,GRP_SITE_CHAR,WIND_DIRECTION,NNW -US-RGo,97667,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,500 -US-RGo,97667,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,0 -US-RGo,97652,GRP_SITE_DESC,SITE_DESC,"Organically farmed medium-grain brown rice field in Glenn County, California. Part of a multi-year, ground-truthing field study under the DOE ARPA-E SMARTFARM project (https://arpa-e.energy.gov/news-and-media/blog-posts/smartfarm-changing-whats-possible-agriculture). Field check is approx. 7 ha in size (1,250 ft by 250 ft), part of a 75+ acre site in several checks with commercial rice over rice rotation on Tehama silt loam, management practices include winter cover crops and AWD." -US-RGo,97656,GRP_SITE_FUNDING,SITE_FUNDING,"This work is supported by the United States Department of Energy (DOE), Advanced Research Projects Agency - Energy (ARPA-E)." -US-RGo,97664,GRP_STATE,STATE,CA -US-RGo,101194,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Michael R. Schuppenhauer -US-RGo,101194,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-RGo,101194,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,mschuppenhauer@lbl.gov -US-RGo,101194,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Arva Intelligence Corp. -US-RGo,101192,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Sebastien C. Biraud -US-RGo,101192,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-RGo,101192,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,SCBiraud@lbl.gov -US-RGo,101192,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Lawrence Berkeley National Laboratory -US-RGo,101192,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"One Cyclotron Road, Berkeley, CA 94720" -US-RGo,101193,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Stephen W. Chan -US-RGo,101193,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-RGo,101193,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,SWChan@lbl.gov -US-RGo,101193,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Lawrence Berkeley National Laboratory -US-RGo,101193,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"One Cyclotron Road, Berkeley, CA 94720" -US-RGo,97660,GRP_TOWER_POWER,TOWER_POWER,Direct power -US-RGo,97657,GRP_TOWER_TYPE,TOWER_TYPE,tripod -US-RGo,24001201,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-RGo -US-RGo,97658,GRP_UTC_OFFSET,UTC_OFFSET,-8 -US-RGo,97658,GRP_UTC_OFFSET,UTC_OFFSET_DATE_START,202106170000 -US-RGW,101395,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,"This work was funded through the U.S. Department of Energy, ARPA-E, under Cooperative Agreement DE-AR0001228 led by ARVA Intelligence Corp. (https://www.arvaintelligence.com/) in collaboration with Lawrence Berkeley National Laboratory (LBNL)." -US-RGW,99003,GRP_CLIM_AVG,MAT,16.7 -US-RGW,99003,GRP_CLIM_AVG,MAP,1283 -US-RGW,99003,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Csa -US-RGW,27001219,GRP_COUNTRY,COUNTRY,USA -US-RGW,99006,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Agriculture -US-RGW,101154,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-RGW,101154,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-RGW,101154,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20220323 -US-RGW,101154,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-RGW,101155,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-RGW,101155,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CH4 -US-RGW,101155,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20220323 -US-RGW,101155,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-RGW,101156,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-RGW,101156,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-RGW,101156,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20220323 -US-RGW,101156,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-RGW,101153,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-RGW,101153,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,N2O -US-RGW,101153,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20220527 -US-RGW,101153,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-RGW,23001219,GRP_HEADER,SITE_NAME,Desha County Rice Farm -US-RGW,99008,GRP_IGBP,IGBP,CRO -US-RGW,99008,GRP_IGBP,IGBP_COMMENT,Rice -US-RGW,101151,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -US-RGW,101151,GRP_LAND_OWNERSHIP,LAND_OWNER,Trinity Farms Partnership LLC -US-RGW,101152,GRP_LOCATION,LOCATION_LAT,33.6183 -US-RGW,101152,GRP_LOCATION,LOCATION_LONG,-91.4355 -US-RGW,101152,GRP_LOCATION,LOCATION_ELEV,41.00 -US-RGW,101152,GRP_LOCATION,LOCATION_DATE_START,202203100000 -US-RGW,99002,GRP_NETWORK,NETWORK,AmeriFlux -US-RGW,101184,GRP_NETWORK,NETWORK,Phenocam -US-RGW,99010,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,Sustainability of bioenergy crops and residues; Reduction of vegetation and fallow season GHG emissions -US-RGW,101157,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"One Cyclotron Road, Berkeley, CA 94720" -US-RGW,99012,GRP_SITE_CHAR,TERRAIN,Flat -US-RGW,99012,GRP_SITE_CHAR,ASPECT,S -US-RGW,99012,GRP_SITE_CHAR,WIND_DIRECTION,S -US-RGW,99012,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,400 -US-RGW,99012,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,0 -US-RGW,99011,GRP_SITE_DESC,SITE_DESC,"Commercially farmed corn variety, field in Desha County, Arkansas. Part of a multi-year, ground-truthing field study under the DOE ARPA-E SMARTFARM project (https://arpa-e.energy.gov/news-and-media/blog-posts/smartfarm-changing-whats-possible-agriculture)." -US-RGW,99001,GRP_SITE_FUNDING,SITE_FUNDING,"This work is supported by the United States Department of Energy (DOE), Advanced Research Projects Agency - Energy (ARPA-E)." -US-RGW,98995,GRP_STATE,STATE,AR -US-RGW,101183,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Michael R. Schuppenhauer -US-RGW,101183,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-RGW,101183,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,mschuppenhauer@lbl.gov -US-RGW,101183,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Arva Intelligence Corp. -US-RGW,101159,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Sebastien C. Biraud -US-RGW,101159,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-RGW,101159,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,SCBiraud@lbl.gov -US-RGW,101159,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Lawrence Berkeley National Laboratory -US-RGW,101159,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"One Cyclotron Road, Berkeley, CA 94720" -US-RGW,101158,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Stephen W. Chan -US-RGW,101158,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-RGW,101158,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,SWChan@lbl.gov -US-RGW,101158,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Lawrence Berkeley National Laboratory -US-RGW,101158,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"One Cyclotron Road, Berkeley, CA 94720" -US-RGW,98994,GRP_TOWER_POWER,TOWER_POWER,Direct power -US-RGW,98997,GRP_TOWER_TYPE,TOWER_TYPE,tripod -US-RGW,24001219,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-RGW -US-RGW,99016,GRP_UTC_OFFSET,UTC_OFFSET,-6 -US-RGW,99016,GRP_UTC_OFFSET,UTC_OFFSET_DATE_START,202203100000 -US-Rls,33706,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,Support for the Reynolds Creek Critical Zone Observatory Cooperative is provided by USDA ARS and NSF Grant #EAR 1331872. -US-Rls,30716,GRP_CLIM_AVG,MAT,8.4 -US-Rls,30716,GRP_CLIM_AVG,MAP,333 -US-Rls,30716,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Bsh -US-Rls,27000702,GRP_COUNTRY,COUNTRY,USA -US-Rls,79336,GRP_DOI,DOI,10.17190/AMF/1418682 -US-Rls,79336,GRP_DOI,DOI_CITATION,"Gerald Flerchinger (2021), AmeriFlux BASE US-Rls RCEW Low Sagebrush, Ver. 4-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1418682" -US-Rls,79336,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-Rls,33692,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Rls,33692,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Gerald Flerchinger -US-Rls,33692,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Rls,33692,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,gerald.flerchinger@ars.usda.gov -US-Rls,33692,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,USDA Agricultural Research Service -US-Rls,33702,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,USDA Agricultural Research Service -US-Rls,33702,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-Rls,33701,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,USDA -ARS; NSF Critical Zone Observatory Network -US-Rls,33701,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-Rls,30708,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Rls,30708,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-Rls,30708,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20140910 -US-Rls,30708,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Rls,30717,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Rls,30717,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-Rls,30717,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20140910 -US-Rls,30717,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Rls,23000702,GRP_HEADER,SITE_NAME,RCEW Low Sagebrush -US-Rls,30704,GRP_IGBP,IGBP,CSH -US-Rls,30704,GRP_IGBP,IGBP_COMMENT,The site is a grazing alotment with light cattle grazing in spring. -US-Rls,30709,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-Rls,30709,GRP_LAND_OWNERSHIP,LAND_OWNER,USDI Bureau of Land Management -US-Rls,30727,GRP_LOCATION,LOCATION_LAT,43.1439 -US-Rls,30727,GRP_LOCATION,LOCATION_LONG,-116.7356 -US-Rls,30727,GRP_LOCATION,LOCATION_ELEV,1608 -US-Rls,30727,GRP_LOCATION,LOCATION_DATE_START,19841205 -US-Rls,30727,GRP_LOCATION,LOCATION_COMMENT,Full meteorological station has been in place since 1984; streamflow and precipitation go much further back. -US-Rls,30710,GRP_NETWORK,NETWORK,AmeriFlux -US-Rls,1700004401,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(2), 108350" -US-Rls,1700004401,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -US-Rls,1700004401,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Rls,1700004086,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Fellows, A. W., Flerchinger, G. N., Seyfried, M. S., Biederman, J. A., Lohse, K. A. (2020) Winter Co 2 Efflux From Sagebrush Shrublands Distributed Across The Rain‐To‐Snow Transition Zone, Journal Of Geophysical Research: Biogeosciences, 125(2), 246-263" -US-Rls,1700004086,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2019JG005325 -US-Rls,1700004086,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Rls,1700001800,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Flerchinger, G. N., Fellows, A. W., Seyfried, M. S., Clark, P. E., Lohse, K. A. (2019) Water And Carbon Fluxes Along An Elevational Gradient In A Sagebrush Ecosystem, Ecosystems, 115(37), E8604-E8613" -US-Rls,1700001800,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1007/S10021-019-00400-X -US-Rls,1700001800,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Primary_Citation -US-Rls,1700008115,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Flerchinger, G. N., Fellows, A. W., Seyfried, M. S., Clark, P. E., Lohse, K. A. (2020) Water And Carbon Fluxes Along An Elevational Gradient In A Sagebrush Ecosystem, Ecosystems, 23(2), 246-263" -US-Rls,1700008115,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1007/S10021-019-00400-X -US-Rls,1700008115,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Rls,1700005811,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Goodwell, A. E., Kumar, P., Fellows, A. W., Flerchinger, G. N. (2018) Dynamic Process Connectivity Explains Ecohydrologic Responses To Rainfall Pulses And Drought, Proceedings Of The National Academy Of Sciences, 115(37), E8604-E8613" -US-Rls,1700005811,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1073/PNAS.1800236115 -US-Rls,1700005811,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Rls,1700005856,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Parajuli, K., Jones, S. B., Tarboton, D. G., Flerchinger, G. N., Hipps, L. E., Allen, L. N., Seyfried, M. S. (2019) Estimating Actual Evapotranspiration From Stony-Soils In Montane Ecosystems, Agricultural And Forest Meteorology, 265(1), 183-194" -US-Rls,1700005856,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2018.11.019 -US-Rls,1700005856,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Rls,1700006600,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Renwick, K. M., Fellows, A., Flerchinger, G. N., Lohse, K. A., Clark, P. E., Smith, W. K., Emmett, K., Poulter, B. (2019) Modeling Phenological Controls On Carbon Dynamics In Dryland Sagebrush Ecosystems, Agricultural And Forest Meteorology, 274(), 85-94" -US-Rls,1700006600,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2019.04.003 -US-Rls,1700006600,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Rls,1700005463,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Seyfried, M., Lohse, K., Marks, D., Flerchinger, G., Pierson, F., Holbrook, W. S. (2018) Reynolds Creek Experimental Watershed And Critical Zone Observatory, Vadose Zone Journal, 17(1), 0" -US-Rls,1700005463,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.2136/VZJ2018.07.0129 -US-Rls,1700005463,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Rls,30719,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,Ecosystem productivity and soil carbon storage -US-Rls,30713,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"800 Park Blvd., Suite 105, Boise, Idaho 83712" -US-Rls,30702,GRP_SITE_CHAR,TERRAIN,"Significant Slope (>5%, <10%)" -US-Rls,30702,GRP_SITE_CHAR,ASPECT,N -US-Rls,30702,GRP_SITE_CHAR,WIND_DIRECTION,SSW -US-Rls,30702,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,200 -US-Rls,30702,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,60 -US-Rls,30711,GRP_SITE_DESC,SITE_DESC,The site is located on the USDA-ARS's Reynolds Creek Experimental Watershed. It is dominated by low sagebrush on land managed by USDI Bureau of Land Management. -US-Rls,33705,GRP_SITE_FUNDING,SITE_FUNDING,"USDA -ARS; NSF Critical Zone Observatory Network, NSF Grant #EAR 1331872" -US-Rls,30712,GRP_STATE,STATE,ID -US-Rls,30718,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Gerald Flerchinger -US-Rls,30718,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Rls,30718,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,gerald.flerchinger@ars.usda.gov -US-Rls,30718,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,USDA Agricultural Research Service -US-Rls,30706,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Aaron Fellows -US-Rls,30706,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,AncContact -US-Rls,30706,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,aarron.fellows@ars.usda.gov -US-Rls,30706,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,USDA Agricultural Research Service -US-Rls,30705,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-Rls,30715,GRP_TOWER_TYPE,TOWER_TYPE,triangle -US-Rls,24000702,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-Rls -US-Rls,30707,GRP_UTC_OFFSET,UTC_OFFSET,-7 -US-Rms,33707,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,Support for the Reynolds Creek Critical Zone Observatory Cooperative is provided by USDA ARS and NSF Grant #EAR 1331872. -US-Rms,30608,GRP_CLIM_AVG,MAT,5.4 -US-Rms,30608,GRP_CLIM_AVG,MAP,800 -US-Rms,30608,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Bsh -US-Rms,27000698,GRP_COUNTRY,COUNTRY,USA -US-Rms,33568,GRP_DOI,DOI,10.17190/AMF/1375202 -US-Rms,33568,GRP_DOI,DOI_CITATION,"Gerald Flerchinger (2021), AmeriFlux BASE US-Rms RCEW Mountain Big Sagebrush, Ver. 4-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1375202" -US-Rms,33568,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-Rms,32431,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Rms,32431,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Gerald Flerchinger -US-Rms,32431,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Rms,32431,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,gerald.flerchinger@ars.usda.gov -US-Rms,32431,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,USDA Agricultural Research Service -US-Rms,32433,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,USDA Agricultural Research Service -US-Rms,32433,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-Rms,32432,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,USDA -ARS; NSF Critical Zone Observatory Network -US-Rms,32432,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-Rms,30610,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Rms,30610,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-Rms,30610,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20140916 -US-Rms,30610,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Rms,30609,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Rms,30609,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-Rms,30609,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20140916 -US-Rms,30609,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Rms,23000698,GRP_HEADER,SITE_NAME,RCEW Mountain Big Sagebrush -US-Rms,30611,GRP_IGBP,IGBP,CSH -US-Rms,30611,GRP_IGBP,IGBP_COMMENT,The site is a grazing alotment with light cattle grazing in summer. -US-Rms,30612,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-Rms,30612,GRP_LAND_OWNERSHIP,LAND_OWNER,USDI Bureau of Land Management -US-Rms,30613,GRP_LOCATION,LOCATION_LAT,43.0645 -US-Rms,30613,GRP_LOCATION,LOCATION_LONG,-116.7486 -US-Rms,30613,GRP_LOCATION,LOCATION_ELEV,2111 -US-Rms,30613,GRP_LOCATION,LOCATION_DATE_START,19830224 -US-Rms,30613,GRP_LOCATION,LOCATION_COMMENT,Full meteorological station has been in place since 1983; streamflow and precipitation go much further back. -US-Rms,30614,GRP_NETWORK,NETWORK,AmeriFlux -US-Rms,86993,GRP_NETWORK,NETWORK,Phenocam -US-Rms,1700001938,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(2), 108350" -US-Rms,1700001938,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -US-Rms,1700001938,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Rms,1700000366,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Fellows, A. W., Flerchinger, G. N., Seyfried, M. S., Biederman, J. A., Lohse, K. A. (2020) Winter Co 2 Efflux From Sagebrush Shrublands Distributed Across The Rain‐To‐Snow Transition Zone, Journal Of Geophysical Research: Biogeosciences, 125(2), 246-263" -US-Rms,1700000366,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2019JG005325 -US-Rms,1700000366,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Rms,1700002448,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Flerchinger, G. N., Fellows, A. W., Seyfried, M. S., Clark, P. E., Lohse, K. A. (2019) Water And Carbon Fluxes Along An Elevational Gradient In A Sagebrush Ecosystem, Ecosystems, 115(37), E8604-E8613" -US-Rms,1700002448,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1007/S10021-019-00400-X -US-Rms,1700002448,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Primary_Citation -US-Rms,1700004842,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Flerchinger, G. N., Fellows, A. W., Seyfried, M. S., Clark, P. E., Lohse, K. A. (2020) Water And Carbon Fluxes Along An Elevational Gradient In A Sagebrush Ecosystem, Ecosystems, 23(2), 246-263" -US-Rms,1700004842,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1007/S10021-019-00400-X -US-Rms,1700004842,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Rms,1700003906,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Goodwell, A. E., Kumar, P., Fellows, A. W., Flerchinger, G. N. (2018) Dynamic Process Connectivity Explains Ecohydrologic Responses To Rainfall Pulses And Drought, Proceedings Of The National Academy Of Sciences, 115(37), E8604-E8613" -US-Rms,1700003906,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1073/PNAS.1800236115 -US-Rms,1700003906,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Rms,1700006804,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Renwick, K. M., Fellows, A., Flerchinger, G. N., Lohse, K. A., Clark, P. E., Smith, W. K., Emmett, K., Poulter, B. (2019) Modeling Phenological Controls On Carbon Dynamics In Dryland Sagebrush Ecosystems, Agricultural And Forest Meteorology, 274(), 85-94" -US-Rms,1700006804,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2019.04.003 -US-Rms,1700006804,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Rms,1700007494,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Seyfried, M., Lohse, K., Marks, D., Flerchinger, G., Pierson, F., Holbrook, W. S. (2018) Reynolds Creek Experimental Watershed And Critical Zone Observatory, Vadose Zone Journal, 17(1), 0" -US-Rms,1700007494,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.2136/VZJ2018.07.0129 -US-Rms,1700007494,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Rms,30615,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,Ecosystem productivity and soil carbon storage -US-Rms,30616,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"800 Park Blvd., Suite 105, Boise, Idaho 83712" -US-Rms,30617,GRP_SITE_CHAR,TERRAIN,Strong Slope (>10%) -US-Rms,30617,GRP_SITE_CHAR,ASPECT,N -US-Rms,30617,GRP_SITE_CHAR,WIND_DIRECTION,SSW -US-Rms,30617,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,110 -US-Rms,30617,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,180 -US-Rms,30618,GRP_SITE_DESC,SITE_DESC,The site is located on the USDA-ARS's Reynolds Creek Experimental Watershed. It is dominated by mountain big sagebrush on land managed by USDI Bureau of Land Management. -US-Rms,33708,GRP_SITE_FUNDING,SITE_FUNDING,"USDA -ARS; NSF Critical Zone Observatory Network, NSF Grant #EAR 1331872" -US-Rms,30620,GRP_STATE,STATE,ID -US-Rms,30621,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Gerald Flerchinger -US-Rms,30621,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Rms,30621,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,gerald.flerchinger@ars.usda.gov -US-Rms,30621,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,USDA Agricultural Research Service -US-Rms,30622,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Aaron Fellows -US-Rms,30622,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,AncContact -US-Rms,30622,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,aarron.fellows@ars.usda.gov -US-Rms,30622,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,USDA Agricultural Research Service -US-Rms,30625,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-Rms,30623,GRP_TOWER_TYPE,TOWER_TYPE,triangle -US-Rms,24000698,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-Rms -US-Rms,30624,GRP_UTC_OFFSET,UTC_OFFSET,-7 -US-Ro1,14509,GRP_CLIM_AVG,MAT,6.4 -US-Ro1,14509,GRP_CLIM_AVG,MAP,879 -US-Ro1,14509,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfa -US-Ro1,27000417,GRP_COUNTRY,COUNTRY,USA -US-Ro1,15760,GRP_DOI,DOI,10.17190/AMF/1246092 -US-Ro1,15760,GRP_DOI,DOI_CITATION,"John Baker, Tim Griffis, Timothy Griffis (2018), AmeriFlux BASE US-Ro1 Rosemount- G21, Ver. 5-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1246092" -US-Ro1,15760,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-Ro1,32165,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Ro1,32165,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,John Baker -US-Ro1,32165,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Ro1,32165,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,john.baker@ars.usda.gov -US-Ro1,32165,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,USDA-ARS -US-Ro1,32167,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Ro1,32167,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Tim Griffis -US-Ro1,32167,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Ro1,32167,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,tgriffis@soils.umn.edu -US-Ro1,32167,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of Minnesota -US-Ro1,32166,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Ro1,32166,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Timothy Griffis -US-Ro1,32166,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Ro1,32166,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,timgriffis@umn.edu -US-Ro1,32166,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of Minnesota -US-Ro1,32169,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,University of Minnesota -US-Ro1,32169,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-Ro1,32170,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,USDA-ARS -US-Ro1,32170,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-Ro1,32168,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,DOE/TCP -US-Ro1,32168,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-Ro1,14510,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Agriculture -US-Ro1,30208,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Ro1,30208,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-Ro1,30208,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,200305210000 -US-Ro1,30208,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,201701010000 -US-Ro1,30208,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Ro1,30206,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Ro1,30206,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-Ro1,30206,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,200305210000 -US-Ro1,30206,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,201701010000 -US-Ro1,30206,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Ro1,30205,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Ro1,30205,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-Ro1,30205,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,200305210000 -US-Ro1,30205,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,201701010000 -US-Ro1,30205,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Ro1,23000417,GRP_HEADER,SITE_NAME,Rosemount- G21 -US-Ro1,12290,GRP_IGBP,IGBP,CRO -US-Ro1,12290,GRP_IGBP,IGBP_COMMENT,"Agricultural, corn and soybean rotation" -US-Ro1,14512,GRP_IGBP,IGBP,CRO -US-Ro1,14512,GRP_IGBP,IGBP_DATE_START,200305210000 -US-Ro1,14512,GRP_IGBP,IGBP_COMMENT,"Corn-Soybean annual rotation (corn: 2003, 2005, 2007, 2009, 2011, 2013; soybean: 2004, 2006, 2008, 2010, 2012, 2014)" -US-Ro1,14513,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-Ro1,14513,GRP_LAND_OWNERSHIP,LAND_OWNER,University of Minnesota -US-Ro1,12291,GRP_LOCATION,LOCATION_LAT,44.7143 -US-Ro1,12291,GRP_LOCATION,LOCATION_LONG,-93.0898 -US-Ro1,12291,GRP_LOCATION,LOCATION_ELEV,260 -US-Ro1,30211,GRP_LOCATION,LOCATION_LAT,44.7143 -US-Ro1,30211,GRP_LOCATION,LOCATION_LONG,-93.0898 -US-Ro1,30211,GRP_LOCATION,LOCATION_ELEV,290 -US-Ro1,30211,GRP_LOCATION,LOCATION_DATE_START,200305210000 -US-Ro1,30211,GRP_LOCATION,LOCATION_COMMENT,Site is being retired in 2017 to make way for gravel mining and an asphalt plant. New site(s) are being applied for concurrently -US-Ro1,12292,GRP_NETWORK,NETWORK,AmeriFlux -US-Ro1,86994,GRP_NETWORK,NETWORK,Phenocam -US-Ro1,1700007086,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Baker, J., Griffis, T. (2005) Examining Strategies To Improve The Carbon Balance Of Corn/Soybean Agriculture Using Eddy Covariance And Mass Balance Techniques, Agricultural And Forest Meteorology, 128(3-4), 163-177" -US-Ro1,1700007086,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2004.11.005 -US-Ro1,1700007086,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Primary_Citation -US-Ro1,1700005577,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Bavin, T., Griffis, T., Baker, J., Venterea, R. (2009) Impact Of Reduced Tillage And Cover Cropping On The Greenhouse Gas Budget Of A Maize/Soybean Rotation Ecosystem, Agriculture, Ecosystems & Environment, 134(3-4), 234-242" -US-Ro1,1700005577,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGEE.2009.07.005 -US-Ro1,1700005577,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ro1,1700008682,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Baldocchi, D. D., Poindexter, C., Abraha, M., Desai, A. R., Bohrer, G., Arain, M. A., Griffis, T., Blanken, P. D., O'Halloran, T. L., Thomas, R. Q., Zhang, Q., Burns, S. P., Frank, J. M., Christian, D., Brown, S., Black, T. A., Gough, C. M., Law, B. E., Lee, X., Chen, J., Reed, D. E., Massman, W. J., Clark, K., Hatfield, J., Prueger, J., Bracho, R., Baker, J. M., Martin, T. A. (2018) Temporal Dynamics Of Aerodynamic Canopy Height Derived From Eddy Covariance Momentum Flux Data Across North American Flux Networks, Geophysical Research Letters, 45(1-2), 9275–9287" -US-Ro1,1700008682,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018GL079306 -US-Ro1,1700008682,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ro1,1700005088,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Baldocchi, D. D., Poindexter, C., Abraha, M., Desai, A. R., Bohrer, G., Arain, M. A., Griffis, T., Blanken, P. D., O'Halloran, T. L., Thomas, R. Q., Zhang, Q., Burns, S. P., Frank, J. M., Christian, D., Brown, S., Black, T. A., Gough, C. M., Law, B. E., Lee, X., Chen, J., Reed, D. E., Massman, W. J., Clark, K., Hatfield, J., Prueger, J., Bracho, R., Baker, J. M., Martin, T. A. (2018) Temporal Dynamics Of Aerodynamic Canopy Height Derived From Eddy Covariance Momentum Flux Data Across North American Flux Networks, Geophysical Research Letters, 45(4), 9275–9287" -US-Ro1,1700005088,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018GL079306 -US-Ro1,1700005088,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ro1,1700003192,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(4), 108350" -US-Ro1,1700003192,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -US-Ro1,1700003192,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ro1,1700003132,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Fassbinder, J. J., Griffis, T. J., Baker, J. M. (2012) Interannual, Seasonal, And Diel Variability In The Carbon Isotope Composition Of Respiration In A C3/C4 Agricultural Ecosystem, Agricultural And Forest Meteorology, 153(3-4), 144-153" -US-Ro1,1700003132,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2011.09.018 -US-Ro1,1700003132,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ro1,1700003450,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Griffis, T. J., Baker, J. M., Sargent, S. D., Erickson, M., Corcoran, J., Chen, M., Billmark, K. (2010) Influence Of C4 Vegetation On 13CO2 Discrimination And Isoforcing In The Upper Midwest, United States, Global Biogeochemical Cycles, 24(4), n/a-n/a" -US-Ro1,1700003450,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2009GB003768 -US-Ro1,1700003450,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ro1,1700008985,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Griffis, T. J., Sargent, S. D., Lee, X., Baker, J. M., Greene, J., Erickson, M., Zhang, X., Billmark, K., Schultz, N., Xiao, W., Hu, N. (2010) Determining The Oxygen Isotope Composition Of Evapotranspiration Using Eddy Covariance, Boundary-Layer Meteorology, 137(2), 307-326" -US-Ro1,1700008985,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1007/S10546-010-9529-5 -US-Ro1,1700008985,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ro1,1700000633,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Griffis, T., Baker, J., Zhang, J. (2005) Seasonal Dynamics And Partitioning Of Isotopic CO2 Exchange In A C3/C4 Managed Ecosystem, Agricultural And Forest Meteorology, 132(1-2), 1-19" -US-Ro1,1700000633,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2005.06.005 -US-Ro1,1700000633,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ro1,1700000174,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Griffis, T.J., Lee, X., Baker, J.M., Billmark, K., Erickson, N. Schultz,M., Zhang, X., Fassbinder, J., Xiao, W., Hu, N. (2011) Oxygen Isotope Composition Of Evapotranspiration And Its Relation To C4 Photosynthetic Discrimination, Journal Of Geophysical Research: Biogeosciences, 116(G1), n/a-n/a" -US-Ro1,1700000174,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2010JG001514 -US-Ro1,1700000174,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ro1,1700006966,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Griffis, T.J., Sargent, S.D., Baker, J.M., Lee, X., Tanner, B.D., Greene, J., Swiatek, E., Billmark, K. (2008) Direct Measurement Of Biosphere-Atmosphere Isotopic Co2exchange Using The Eddy Covariance Technique, Journal Of Geophysical Research, 113(D8), n/a-n/a" -US-Ro1,1700006966,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2007JD009297 -US-Ro1,1700006966,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ro1,1700005772,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"McCombs, A. G., Hiscox, A. L., Wang, C., Desai, A. R., Suyker, A. E., Biraud, S. C. (2018) Carbon Flux Phenology From The Sky: Evaluation For Maize And Soybean, Journal Of Atmospheric And Oceanic Technology, 35(4), 877-892" -US-Ro1,1700005772,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1175/JTECH-D-17-0004.1 -US-Ro1,1700005772,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ro1,14517,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,Quantify the seasonal and interannual variation of net ecosystem CO2 exchange (FN) of agricultural ecosystems in the Upper Midwest grown under different management strategies; -US-Ro1,30216,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"Room 470 1991 UPPER BUFORD CIRCLE SAINT PAUL, MN, 55108-0000" -US-Ro1,15834,GRP_SITE_CHAR,TERRAIN,Flat -US-Ro1,15834,GRP_SITE_CHAR,ASPECT,FLAT -US-Ro1,15834,GRP_SITE_CHAR,WIND_DIRECTION,SSE -US-Ro1,15834,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,190 -US-Ro1,15834,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,150 -US-Ro1,14520,GRP_SITE_DESC,SITE_DESC,This tower is located in a farm field farmed in accordance with the dominant farming practice in the region: a corn/soybean rotation with chisel plow tillage in the fall following corn harvest and in the spring following soybeans. -US-Ro1,14521,GRP_SITE_FUNDING,SITE_FUNDING,DOE/TCP -US-Ro1,28091,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION,"Waukegan silt loam (fine, mixed, mesic typic hapludoll) with a surface layer of high organic carbon content (2.6% average) and variable thickness (0.3-2.0 m) underlain by coarse outwash sand and gravel" -US-Ro1,28091,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION_TAXONOMY,Other -US-Ro1,12298,GRP_STATE,STATE,MN -US-Ro1,100736,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,John Baker -US-Ro1,100736,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Ro1,100736,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,john.baker2@usda.gov -US-Ro1,100736,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,USDA-ARS -US-Ro1,86924,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Timothy Griffis -US-Ro1,86924,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Ro1,86924,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,tgriffis@umn.edu -US-Ro1,86924,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Minnesota -US-Ro1,86924,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Department of Soil, Water, and Climate, S325 Soils Bldg, 1529 Gortner Ave,St. Paul, MN 55108" -US-Ro1,100735,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Cody Winker -US-Ro1,100735,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,DataManager -US-Ro1,100735,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,cdwinker@umn.edu -US-Ro1,100735,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Minnesota -US-Ro1,100728,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Bill Breiter -US-Ro1,100728,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Technician -US-Ro1,100728,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,wbreiter@umn.edu -US-Ro1,100728,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,USDA-ARS -US-Ro1,30228,GRP_TOWER_POWER,TOWER_POWER,Direct power -US-Ro1,12300,GRP_TOWER_TYPE,TOWER_TYPE,triangle -US-Ro1,12301,GRP_URL,URL,http://www.biometeorology.umn.edu/ -US-Ro1,24000417,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-Ro1 -US-Ro1,15841,GRP_UTC_OFFSET,UTC_OFFSET,-6 -US-Ro1,15841,GRP_UTC_OFFSET,UTC_OFFSET_DATE_START,200305210000 -US-Ro1,15841,GRP_UTC_OFFSET,UTC_OFFSET_COMMENT,Local: CST -US-Ro2,14535,GRP_CLIM_AVG,MAT,6.4 -US-Ro2,14535,GRP_CLIM_AVG,MAP,879 -US-Ro2,14535,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfa -US-Ro2,27000418,GRP_COUNTRY,COUNTRY,USA -US-Ro2,79339,GRP_DOI,DOI,10.17190/AMF/1418683 -US-Ro2,79339,GRP_DOI,DOI_CITATION,"John Baker, Tim Griffis (2018), AmeriFlux BASE US-Ro2 Rosemount- C7, Ver. 1-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1418683" -US-Ro2,79339,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-Ro2,33688,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Ro2,33688,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,John Baker -US-Ro2,33688,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Ro2,33688,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,john.baker@ars.usda.gov -US-Ro2,33688,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,USDA-ARS -US-Ro2,33687,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Ro2,33687,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Tim Griffis -US-Ro2,33687,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Ro2,33687,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,tgriffis@soils.umn.edu -US-Ro2,33687,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of Minnesota -US-Ro2,33694,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,University of Minnesota -US-Ro2,33694,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-Ro2,33695,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,USDA-ARS -US-Ro2,33695,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-Ro2,33693,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,DOE/TCP -US-Ro2,33693,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-Ro2,14536,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Agriculture -US-Ro2,30179,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Ro2,30179,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-Ro2,30179,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,200305210000 -US-Ro2,30179,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,201701010000 -US-Ro2,30179,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Ro2,30180,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Ro2,30180,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-Ro2,30180,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,200305210000 -US-Ro2,30180,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,201701010000 -US-Ro2,30180,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Ro2,30181,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Ro2,30181,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-Ro2,30181,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,200305210000 -US-Ro2,30181,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,201701010000 -US-Ro2,30181,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Ro2,23000418,GRP_HEADER,SITE_NAME,Rosemount- C7 -US-Ro2,14538,GRP_IGBP,IGBP,CRO -US-Ro2,14538,GRP_IGBP,IGBP_DATE_START,200305210000 -US-Ro2,14538,GRP_IGBP,IGBP_COMMENT,Corn-Soybean-Kura Clover annual rotation -US-Ro2,14539,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-Ro2,14539,GRP_LAND_OWNERSHIP,LAND_OWNER,University of Minnesota -US-Ro2,30185,GRP_LOCATION,LOCATION_LAT,44.7288 -US-Ro2,30185,GRP_LOCATION,LOCATION_LONG,-93.0888 -US-Ro2,30185,GRP_LOCATION,LOCATION_ELEV,292 -US-Ro2,30185,GRP_LOCATION,LOCATION_DATE_START,200305210000 -US-Ro2,30185,GRP_LOCATION,LOCATION_COMMENT,Site is being retired in 2017 to make way for gravel mining and an asphalt plant. New site(s) are being applied for concurrently. -US-Ro2,14541,GRP_NETWORK,NETWORK,AmeriFlux -US-Ro2,86995,GRP_NETWORK,NETWORK,Phenocam -US-Ro2,1700000831,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(G1), 108350" -US-Ro2,1700000831,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -US-Ro2,1700000831,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ro2,1700002424,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Griffis, T. J., Baker, J. M., Sargent, S. D., Erickson, M., Corcoran, J., Chen, M., Billmark, K. (2010) Influence Of C4 Vegetation On 13CO2 Discrimination And Isoforcing In The Upper Midwest, United States, Global Biogeochemical Cycles, 24(4), n/a-n/a" -US-Ro2,1700002424,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2009GB003768 -US-Ro2,1700002424,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ro2,1700006120,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Griffis, T.J., Lee, X., Baker, J.M., Billmark, K., Erickson, N. Schultz,M., Zhang, X., Fassbinder, J., Xiao, W., Hu, N. (2011) Oxygen Isotope Composition Of Evapotranspiration And Its Relation To C4 Photosynthetic Discrimination, Journal Of Geophysical Research: Biogeosciences, 116(G1), n/a-n/a" -US-Ro2,1700006120,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2010JG001514 -US-Ro2,1700006120,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ro2,14543,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,Quantify the seasonal and interannual variation of net ecosystem CO2 exchange (FN) of agricultural ecosystems in the Upper Midwest grown under different management strategies; -US-Ro2,30190,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"Room 470 1991 UPPER BUFORD CIRCLE SAINT PAUL, MN, 55108-0000" -US-Ro2,15860,GRP_SITE_CHAR,TERRAIN,Flat -US-Ro2,15860,GRP_SITE_CHAR,ASPECT,FLAT -US-Ro2,15860,GRP_SITE_CHAR,WIND_DIRECTION,S -US-Ro2,15860,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,210 -US-Ro2,15860,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,150 -US-Ro2,14546,GRP_SITE_DESC,SITE_DESC,This tower is located in a farm field farmed in accordance with the dominant farming practice in the region: a corn/soybean/clover rotation with chisel plow tillage in the fall following corn harvest and in the spring following soybeans. -US-Ro2,14547,GRP_SITE_FUNDING,SITE_FUNDING,DOE/TCP -US-Ro2,14548,GRP_STATE,STATE,MN -US-Ro2,100739,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,John Baker -US-Ro2,100739,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Ro2,100739,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,john.baker2@usda.gov -US-Ro2,100739,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,USDA-ARS -US-Ro2,86927,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Timothy Griffis -US-Ro2,86927,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Ro2,86927,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,tgriffis@umn.edu -US-Ro2,86927,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Minnesota -US-Ro2,100738,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Cody Winker -US-Ro2,100738,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,DataManager -US-Ro2,100738,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,cdwinker@umn.edu -US-Ro2,100738,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Minnesota -US-Ro2,100730,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Bill Breiter -US-Ro2,100730,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Technician -US-Ro2,100730,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,wbreiter@umn.edu -US-Ro2,100730,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,USDA-ARS -US-Ro2,14558,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Peter Turner -US-Ro2,14558,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Affiliate -US-Ro2,14558,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,turne289@umn.edu -US-Ro2,29835,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-Ro2,14550,GRP_TOWER_TYPE,TOWER_TYPE,triangle -US-Ro2,14551,GRP_URL,URL,http://www.biometeorology.umn.edu/ -US-Ro2,24000418,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-Ro2 -US-Ro2,15867,GRP_UTC_OFFSET,UTC_OFFSET,-6 -US-Ro2,15867,GRP_UTC_OFFSET,UTC_OFFSET_DATE_START,200305210000 -US-Ro2,15867,GRP_UTC_OFFSET,UTC_OFFSET_COMMENT,local: CST -US-Ro3,14561,GRP_CLIM_AVG,MAT,6.4 -US-Ro3,14561,GRP_CLIM_AVG,MAP,879 -US-Ro3,14561,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfa -US-Ro3,27000419,GRP_COUNTRY,COUNTRY,USA -US-Ro3,15619,GRP_DOI,DOI,10.17190/AMF/1246093 -US-Ro3,15619,GRP_DOI,DOI_CITATION,"John Baker, Tim Griffis (2019), AmeriFlux BASE US-Ro3 Rosemount- G19, Ver. 4-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1246093" -US-Ro3,15619,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-Ro3,32172,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Ro3,32172,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,John Baker -US-Ro3,32172,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Ro3,32172,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,John.Baker@ARS.USDA.GOV -US-Ro3,32172,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,USDA-ARS -US-Ro3,32171,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Ro3,32171,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Tim Griffis -US-Ro3,32171,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Ro3,32171,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,tgriffis@soils.umn.edu -US-Ro3,32171,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of Minnesota -US-Ro3,32175,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,University of Minnesota -US-Ro3,32175,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-Ro3,32174,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,USDA-ARS -US-Ro3,32174,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-Ro3,32173,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,DOE/TCP -US-Ro3,32173,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-Ro3,14562,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Agriculture -US-Ro3,14563,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Ro3,14563,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-Ro3,14563,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,200305210000 -US-Ro3,14563,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,201011010000 -US-Ro3,14563,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Ro3,14563,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,Site operated continuously from mid 2003 through end of season 2010 when the site had to be closed due to a land ownership conflict. Site G21 (Ro1) has replaced this site for these purposes. -US-Ro3,14579,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Ro3,14579,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-Ro3,14579,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,200305210000 -US-Ro3,14579,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,201011010000 -US-Ro3,14579,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Ro3,14582,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Ro3,14582,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-Ro3,14582,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,200305210000 -US-Ro3,14582,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,201011010000 -US-Ro3,14582,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Ro3,23000419,GRP_HEADER,SITE_NAME,Rosemount- G19 -US-Ro3,14564,GRP_IGBP,IGBP,CRO -US-Ro3,14564,GRP_IGBP,IGBP_DATE_START,200305210000 -US-Ro3,14564,GRP_IGBP,IGBP_COMMENT,"Corn-Soybean annual rotation (corn: 2003, 2005, 2007, 2009, 2011, 2013; soybean: 2004, 2006, 2008, 2010, 2012, 2014)" -US-Ro3,14565,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-Ro3,14565,GRP_LAND_OWNERSHIP,LAND_OWNER,University of Minnesota -US-Ro3,14566,GRP_LOCATION,LOCATION_LAT,44.7217 -US-Ro3,14566,GRP_LOCATION,LOCATION_LONG,-93.0893 -US-Ro3,14566,GRP_LOCATION,LOCATION_ELEV,260 -US-Ro3,14566,GRP_LOCATION,LOCATION_DATE_START,200305210000 -US-Ro3,14567,GRP_NETWORK,NETWORK,AmeriFlux -US-Ro3,1700007899,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Baldocchi, D. D., Poindexter, C., Abraha, M., Desai, A. R., Bohrer, G., Arain, M. A., Griffis, T., Blanken, P. D., O'Halloran, T. L., Thomas, R. Q., Zhang, Q., Burns, S. P., Frank, J. M., Christian, D., Brown, S., Black, T. A., Gough, C. M., Law, B. E., Lee, X., Chen, J., Reed, D. E., Massman, W. J., Clark, K., Hatfield, J., Prueger, J., Bracho, R., Baker, J. M., Martin, T. A. (2018) Temporal Dynamics Of Aerodynamic Canopy Height Derived From Eddy Covariance Momentum Flux Data Across North American Flux Networks, Geophysical Research Letters, 45(G1), 9275–9287" -US-Ro3,1700007899,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018GL079306 -US-Ro3,1700007899,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ro3,1700000246,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Griffis, T. J., Baker, J. M., Sargent, S. D., Erickson, M., Corcoran, J., Chen, M., Billmark, K. (2010) Influence Of C4 Vegetation On 13CO2 Discrimination And Isoforcing In The Upper Midwest, United States, Global Biogeochemical Cycles, 24(4), n/a-n/a" -US-Ro3,1700000246,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2009GB003768 -US-Ro3,1700000246,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ro3,1700007119,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Griffis, T.J., Lee, X., Baker, J.M., Billmark, K., Erickson, N. Schultz,M., Zhang, X., Fassbinder, J., Xiao, W., Hu, N. (2011) Oxygen Isotope Composition Of Evapotranspiration And Its Relation To C4 Photosynthetic Discrimination, Journal Of Geophysical Research: Biogeosciences, 116(G1), n/a-n/a" -US-Ro3,1700007119,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2010JG001514 -US-Ro3,1700007119,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ro3,14569,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,Quantify the seasonal and interannual variation of net ecosystem CO2 exchange (FN) of agricultural ecosystems in the Upper Midwest grown under different management strategies; -US-Ro3,15885,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"439 Borlaug Hall 1991 Upper Buford Circle Saint Paul, MN 55108" -US-Ro3,14571,GRP_SITE_CHAR,TERRAIN,Flat -US-Ro3,14571,GRP_SITE_CHAR,ASPECT,FLAT -US-Ro3,14571,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,150 -US-Ro3,14572,GRP_SITE_DESC,SITE_DESC,This tower is located in a farm field farmed in accordance with the cominant farming practice in the region: a corn/soybean rotation with chisel plow tillage in the fall following corn harvest and in the spring following soybeans. -US-Ro3,14573,GRP_SITE_FUNDING,SITE_FUNDING,DOE/TCP -US-Ro3,14574,GRP_STATE,STATE,MN -US-Ro3,100742,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,John Baker -US-Ro3,100742,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Ro3,100742,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,john.baker2@usda.gov -US-Ro3,100742,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,USDA-ARS -US-Ro3,86928,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Timothy Griffis -US-Ro3,86928,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Ro3,86928,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,tgriffis@umn.edu -US-Ro3,86928,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Minnesota -US-Ro3,100741,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Cody Winker -US-Ro3,100741,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,DataManager -US-Ro3,100741,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,cdwinker@umn.edu -US-Ro3,100741,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Minnesota -US-Ro3,100731,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Bill Breiter -US-Ro3,100731,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Technician -US-Ro3,100731,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,wbreiter@umn.edu -US-Ro3,100731,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,USDA-ARS -US-Ro3,29836,GRP_TOWER_POWER,TOWER_POWER,Direct power -US-Ro3,14576,GRP_TOWER_TYPE,TOWER_TYPE,triangle -US-Ro3,14577,GRP_URL,URL,http://www.biometeorology.umn.edu/ -US-Ro3,24000419,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-Ro3 -US-Ro3,14578,GRP_UTC_OFFSET,UTC_OFFSET,-6 -US-Ro3,14578,GRP_UTC_OFFSET,UTC_OFFSET_DATE_START,200305210000 -US-Ro3,14578,GRP_UTC_OFFSET,UTC_OFFSET_COMMENT,Local: CST -US-Ro4,14483,GRP_CLIM_AVG,MAT,6.4 -US-Ro4,14483,GRP_CLIM_AVG,MAP,879 -US-Ro4,14483,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfa -US-Ro4,27000655,GRP_COUNTRY,COUNTRY,USA -US-Ro4,79481,GRP_DOI,DOI,10.17190/AMF/1419507 -US-Ro4,79481,GRP_DOI,DOI_CITATION,"John Baker, Tim Griffis (2022), AmeriFlux BASE US-Ro4 Rosemount Prairie, Ver. 16-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1419507" -US-Ro4,79481,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-Ro4,79442,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Ro4,79442,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,John Baker -US-Ro4,79442,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Ro4,79442,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,John.Baker@ARS.USDA.GOV -US-Ro4,79442,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,USDA-ARS -US-Ro4,79441,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Ro4,79441,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Tim Griffis -US-Ro4,79441,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Ro4,79441,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,tgriffis@soils.umn.edu -US-Ro4,79441,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of Minnesota -US-Ro4,79444,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,University of Minnesota -US-Ro4,79444,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-Ro4,79445,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,USDA-ARS -US-Ro4,79445,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-Ro4,79443,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,DOE/TCP -US-Ro4,79443,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-Ro4,14484,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Agriculture -US-Ro4,14485,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Ro4,14485,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-Ro4,14485,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201401100000 -US-Ro4,14485,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Ro4,14504,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Ro4,14504,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-Ro4,14504,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201401100000 -US-Ro4,14504,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Ro4,14501,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Ro4,14501,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-Ro4,14501,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201401100000 -US-Ro4,14501,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Ro4,23000655,GRP_HEADER,SITE_NAME,Rosemount Prairie -US-Ro4,14486,GRP_IGBP,IGBP,GRA -US-Ro4,14486,GRP_IGBP,IGBP_DATE_START,201401100000 -US-Ro4,14486,GRP_IGBP,IGBP_COMMENT,Restored tallgrass prairie -US-Ro4,14487,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-Ro4,14487,GRP_LAND_OWNERSHIP,LAND_OWNER,MN Department of Natural Resources -US-Ro4,15798,GRP_LOCATION,LOCATION_LAT,44.6781 -US-Ro4,15798,GRP_LOCATION,LOCATION_LONG,-93.0723 -US-Ro4,15798,GRP_LOCATION,LOCATION_ELEV,274 -US-Ro4,15798,GRP_LOCATION,LOCATION_DATE_START,2014 -US-Ro4,14489,GRP_NETWORK,NETWORK,AmeriFlux -US-Ro4,86996,GRP_NETWORK,NETWORK,Phenocam -US-Ro4,1700003831,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Griffis, T. J., Baker, J. M., Sargent, S. D., Erickson, M., Corcoran, J., Chen, M., Billmark, K. (2010) Influence Of C4 Vegetation On 13CO2 Discrimination And Isoforcing In The Upper Midwest, United States, Global Biogeochemical Cycles, 24(4), n/a-n/a" -US-Ro4,1700003831,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2009GB003768 -US-Ro4,1700003831,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ro4,1700000003,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Griffis, T.J., Lee, X., Baker, J.M., Billmark, K., Erickson, N. Schultz,M., Zhang, X., Fassbinder, J., Xiao, W., Hu, N. (2011) Oxygen Isotope Composition Of Evapotranspiration And Its Relation To C4 Photosynthetic Discrimination, Journal Of Geophysical Research: Biogeosciences, 116(G1), n/a-n/a" -US-Ro4,1700000003,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2010JG001514 -US-Ro4,1700000003,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ro4,14491,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,Quantify the seasonal and interannual variation of net ecosystem CO2 exchange (FN) of agricultural and restored ecosystems in the Upper Midwest grown under different management strategies -US-Ro4,14492,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"Room 439 1991 UPPER BUFORD CIRCLE SAINT PAUL, MN, 55108-0000" -US-Ro4,14493,GRP_SITE_CHAR,TERRAIN,Flat -US-Ro4,14493,GRP_SITE_CHAR,ASPECT,FLAT -US-Ro4,14493,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,150 -US-Ro4,14494,GRP_SITE_DESC,SITE_DESC,"This tower is located in restored prairie in a former agricultural area. Dominant species include Andropogon gerardii, Sorghastrum nutans and Elymus canadensis" -US-Ro4,14495,GRP_SITE_FUNDING,SITE_FUNDING,DOE/TCP -US-Ro4,14496,GRP_STATE,STATE,MN -US-Ro4,100745,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,John Baker -US-Ro4,100745,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Ro4,100745,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,john.baker2@usda.gov -US-Ro4,100745,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,USDA-ARS -US-Ro4,86930,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Timothy Griffis -US-Ro4,86930,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Ro4,86930,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,tgriffis@umn.edu -US-Ro4,86930,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Minnesota -US-Ro4,100744,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Cody Winker -US-Ro4,100744,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,DataManager -US-Ro4,100744,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,cdwinker@umn.edu -US-Ro4,100744,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Minnesota -US-Ro4,100732,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Bill Breiter -US-Ro4,100732,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Technician -US-Ro4,100732,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,wbreiter@umn.edu -US-Ro4,100732,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,USDA-ARS -US-Ro4,29906,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-Ro4,14498,GRP_TOWER_TYPE,TOWER_TYPE,triangle -US-Ro4,14499,GRP_URL,URL,http://www.biometeorology.umn.edu/ -US-Ro4,24000655,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-Ro4 -US-Ro4,14500,GRP_UTC_OFFSET,UTC_OFFSET,-6 -US-Ro4,14500,GRP_UTC_OFFSET,UTC_OFFSET_DATE_START,201401100000 -US-Ro4,14500,GRP_UTC_OFFSET,UTC_OFFSET_COMMENT,Local Time: CST -US-Ro5,30125,GRP_CLIM_AVG,MAT,6.4 -US-Ro5,30125,GRP_CLIM_AVG,MAP,879 -US-Ro5,30125,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfa -US-Ro5,27000688,GRP_COUNTRY,COUNTRY,USA -US-Ro5,79478,GRP_DOI,DOI,10.17190/AMF/1419508 -US-Ro5,79478,GRP_DOI,DOI_CITATION,"John Baker, Tim Griffis (2022), AmeriFlux BASE US-Ro5 Rosemount I18_South, Ver. 16-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1419508" -US-Ro5,79478,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-Ro5,79447,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Ro5,79447,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,John Baker -US-Ro5,79447,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Ro5,79447,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,john.baker@ars.usda.gov -US-Ro5,79447,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,USDA-ARS -US-Ro5,79446,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Ro5,79446,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Tim Griffis -US-Ro5,79446,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Ro5,79446,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,tgriffis@soils.umn.edu -US-Ro5,79446,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of Minnesota -US-Ro5,79450,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,University of Minnesota -US-Ro5,79450,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-Ro5,79449,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,USDA-ARS -US-Ro5,79449,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-Ro5,79448,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,DOE/TCP -US-Ro5,79448,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-Ro5,30126,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Agriculture -US-Ro5,30128,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Ro5,30128,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-Ro5,30128,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201701010000 -US-Ro5,30128,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Ro5,30130,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Ro5,30130,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-Ro5,30130,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201701010000 -US-Ro5,30130,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Ro5,30127,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Ro5,30127,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-Ro5,30127,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201701010000 -US-Ro5,30127,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Ro5,91336,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Gradients -US-Ro5,91336,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,N2O -US-Ro5,91336,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201705 -US-Ro5,91336,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Ro5,23000688,GRP_HEADER,SITE_NAME,Rosemount I18_South -US-Ro5,30131,GRP_IGBP,IGBP,CRO -US-Ro5,30131,GRP_IGBP,IGBP_DATE_START,200305210000 -US-Ro5,30132,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-Ro5,30132,GRP_LAND_OWNERSHIP,LAND_OWNER,Minnesota Department of Natural Resources -US-Ro5,30133,GRP_LOCATION,LOCATION_LAT,44.6910 -US-Ro5,30133,GRP_LOCATION,LOCATION_LONG,-93.0576 -US-Ro5,30133,GRP_LOCATION,LOCATION_ELEV,283 -US-Ro5,30133,GRP_LOCATION,LOCATION_DATE_START,201610241500 -US-Ro5,30134,GRP_NETWORK,NETWORK,AmeriFlux -US-Ro5,86997,GRP_NETWORK,NETWORK,Phenocam -US-Ro5,1700005886,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(), 108350" -US-Ro5,1700005886,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -US-Ro5,1700005886,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ro5,30137,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,Quantify the seasonal and interannual variation of net ecosystem CO2 exchange (FN) of agricultural ecosystems in the Upper Midwest grown under different management strategies; -US-Ro5,30331,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"439 Borlaug Hall, 1991 UPPER BUFORD CIRCLE SAINT PAUL, MN, 55108-0000" -US-Ro5,30139,GRP_SITE_CHAR,TERRAIN,Flat -US-Ro5,30139,GRP_SITE_CHAR,ASPECT,FLAT -US-Ro5,30139,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,200 -US-Ro5,30139,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,150 -US-Ro5,30140,GRP_SITE_DESC,SITE_DESC,This tower is located in a farm field farmed in accordance with the dominant farming practice in the region: a corn/soybean rotation with chisel plow tillage in the fall following corn harvest and in the spring following soybeans. -US-Ro5,30141,GRP_SITE_FUNDING,SITE_FUNDING,DOE/TCP -US-Ro5,30142,GRP_STATE,STATE,MN -US-Ro5,100748,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,John Baker -US-Ro5,100748,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Ro5,100748,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,john.baker2@usda.gov -US-Ro5,100748,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,USDA-ARS -US-Ro5,86933,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Timothy Griffis -US-Ro5,86933,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Ro5,86933,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,tgriffis@umn.edu -US-Ro5,86933,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Minnesota -US-Ro5,100747,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Cody Winker -US-Ro5,100747,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,DataManager -US-Ro5,100747,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,cdwinker@umn.edu -US-Ro5,100747,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Minnesota -US-Ro5,100733,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Bill Breiter -US-Ro5,100733,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Technician -US-Ro5,100733,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,wbreiter@umn.edu -US-Ro5,100733,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,USDA-ARS -US-Ro5,30150,GRP_TOWER_POWER,TOWER_POWER,Direct power -US-Ro5,30147,GRP_TOWER_TYPE,TOWER_TYPE,triangle -US-Ro5,30148,GRP_URL,URL,http://www.biometeorology.umn.edu/ -US-Ro5,24000688,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-Ro5 -US-Ro5,30149,GRP_UTC_OFFSET,UTC_OFFSET,-6 -US-Ro5,30149,GRP_UTC_OFFSET,UTC_OFFSET_DATE_START,200305210000 -US-Ro5,30149,GRP_UTC_OFFSET,UTC_OFFSET_COMMENT,Local: CST -US-Ro6,30151,GRP_CLIM_AVG,MAT,6.4 -US-Ro6,30151,GRP_CLIM_AVG,MAP,879 -US-Ro6,30151,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfa -US-Ro6,27000689,GRP_COUNTRY,COUNTRY,USA -US-Ro6,79482,GRP_DOI,DOI,10.17190/AMF/1419509 -US-Ro6,79482,GRP_DOI,DOI_CITATION,"John Baker, Tim Griffis (2022), AmeriFlux BASE US-Ro6 Rosemount I18_North, Ver. 16-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1419509" -US-Ro6,79482,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-Ro6,79452,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Ro6,79452,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,John Baker -US-Ro6,79452,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Ro6,79452,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,john.baker@ars.usda.gov -US-Ro6,79452,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,USDA-ARS -US-Ro6,79451,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Ro6,79451,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Tim Griffis -US-Ro6,79451,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Ro6,79451,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,tgriffis@soils.umn.edu -US-Ro6,79451,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of Minnesota -US-Ro6,79454,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,University of Minnesota -US-Ro6,79454,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-Ro6,79455,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,USDA-ARS -US-Ro6,79455,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-Ro6,79453,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,DOE/TCP -US-Ro6,79453,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-Ro6,30152,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Agriculture -US-Ro6,30153,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Ro6,30153,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-Ro6,30153,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201701010000 -US-Ro6,30153,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Ro6,30156,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Ro6,30156,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-Ro6,30156,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201701010000 -US-Ro6,30156,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Ro6,30155,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Ro6,30155,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-Ro6,30155,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201701010000 -US-Ro6,30155,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Ro6,91310,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Gradients -US-Ro6,91310,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,N2O -US-Ro6,91310,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201705 -US-Ro6,91310,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Ro6,23000689,GRP_HEADER,SITE_NAME,Rosemount I18_North -US-Ro6,30157,GRP_IGBP,IGBP,CRO -US-Ro6,30157,GRP_IGBP,IGBP_DATE_START,200305210000 -US-Ro6,30158,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-Ro6,30158,GRP_LAND_OWNERSHIP,LAND_OWNER,Minnesota Department of Natural Resources -US-Ro6,30159,GRP_LOCATION,LOCATION_LAT,44.6946 -US-Ro6,30159,GRP_LOCATION,LOCATION_LONG,-93.0578 -US-Ro6,30159,GRP_LOCATION,LOCATION_ELEV,282 -US-Ro6,30159,GRP_LOCATION,LOCATION_DATE_START,201610241500 -US-Ro6,30160,GRP_NETWORK,NETWORK,AmeriFlux -US-Ro6,86998,GRP_NETWORK,NETWORK,Phenocam -US-Ro6,1700002490,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(), 108350" -US-Ro6,1700002490,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -US-Ro6,1700002490,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ro6,30163,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,Quantify the seasonal and interannual variation of net ecosystem CO2 exchange (FN) of agricultural ecosystems in the Upper Midwest grown under different management strategies -US-Ro6,30332,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"439 Borlaug Hall, 1991 UPPER BUFORD CIRCLE SAINT PAUL, MN, 55108-0000" -US-Ro6,30165,GRP_SITE_CHAR,TERRAIN,Flat -US-Ro6,30165,GRP_SITE_CHAR,ASPECT,FLAT -US-Ro6,30165,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,200 -US-Ro6,30165,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,150 -US-Ro6,30166,GRP_SITE_DESC,SITE_DESC,This tower is located in a farm field farmed in accordance with a conservation type agricultural practice in the region: a corn/soybean/clover (living mulch/cover crop) rotation with chisel plow tillage in the fall following corn harvest and in the spring following soybeans. -US-Ro6,30167,GRP_SITE_FUNDING,SITE_FUNDING,DOE/TCP -US-Ro6,30168,GRP_STATE,STATE,MN -US-Ro6,100751,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,John Baker -US-Ro6,100751,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Ro6,100751,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,john.baker2@usda.gov -US-Ro6,100751,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,USDA-ARS -US-Ro6,86935,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Timothy Griffis -US-Ro6,86935,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Ro6,86935,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,tgriffis@umn.edu -US-Ro6,86935,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Minnesota -US-Ro6,100750,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Cody Winker -US-Ro6,100750,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,DataManager -US-Ro6,100750,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,cdwinker@umn.edu -US-Ro6,100750,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Minnesota -US-Ro6,100734,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Bill Breiter -US-Ro6,100734,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Technician -US-Ro6,100734,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,wbreiter@umn.edu -US-Ro6,100734,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,USDA-ARS -US-Ro6,30176,GRP_TOWER_POWER,TOWER_POWER,Direct power -US-Ro6,30173,GRP_TOWER_TYPE,TOWER_TYPE,triangle -US-Ro6,30174,GRP_URL,URL,http://www.biometeorology.umn.edu/ -US-Ro6,24000689,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-Ro6 -US-Ro6,30175,GRP_UTC_OFFSET,UTC_OFFSET,-6 -US-Ro6,30175,GRP_UTC_OFFSET,UTC_OFFSET_DATE_START,200305210000 -US-Ro6,30175,GRP_UTC_OFFSET,UTC_OFFSET_COMMENT,Local: CST -US-Rpf,85286,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,"Supported by Arctic Challenge for Sustainability (ArCS) project by the Ministry of Education, Culture, Sports, Science and Technology, Japan." -US-Rpf,85286,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT_COMMENT,Acknowledge the ArCS Project -US-Rpf,85294,GRP_CLIM_AVG,MAT,-0.8 -US-Rpf,85294,GRP_CLIM_AVG,MAP,450 -US-Rpf,85294,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dwc -US-Rpf,27001015,GRP_COUNTRY,COUNTRY,USA -US-Rpf,88087,GRP_DM_ENCROACH,DM_ENCROACH,Other -US-Rpf,88087,GRP_DM_ENCROACH,DM_DATE_START,200406260000 -US-Rpf,88087,GRP_DM_ENCROACH,DM_DATE_END,200408010000 -US-Rpf,88087,GRP_DM_ENCROACH,DM_COMMENT,"Rhododendron groenlandicum, Vaccinium uliginosum, Epilobium angustifolium, Carex spp., were dominant with young saplings of Betula papyrifera var. neoalaskana (paper birch), Populus tremuloides (aspen), and Salix (willow) spp. and small saplings of Picea mariana (black spruce)." -US-Rpf,88088,GRP_DM_FIRE,DM_FIRE,Nature induced burn -US-Rpf,88088,GRP_DM_FIRE,DM_SURF,100 -US-Rpf,88088,GRP_DM_FIRE,DM_DATE_START,200406260000 -US-Rpf,88088,GRP_DM_FIRE,DM_DATE_END,200408010000 -US-Rpf,90041,GRP_DOI,DOI,10.17190/AMF/1579540 -US-Rpf,90041,GRP_DOI,DOI_CITATION,"Masahito Ueyama, Hiroki Iwata, Yoshinobu Harazono (2022), AmeriFlux BASE US-Rpf Poker Flat Research Range: Succession from fire scar to deciduous forest, Ver. 7-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1579540" -US-Rpf,90041,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-Rpf,88067,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Rpf,88067,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Masahito Ueyama -US-Rpf,88067,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Rpf,88067,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,1 -US-Rpf,88067,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0002-4000-4888 -US-Rpf,88067,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,miyabi-flux@muh.biglobe.ne.jp -US-Rpf,88067,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Osaka Prefecture University -US-Rpf,88064,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Rpf,88064,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Hiroki Iwata -US-Rpf,88064,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Rpf,88064,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,2 -US-Rpf,88064,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,hiwata@shinshu-u.ac.jp -US-Rpf,88064,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Shinshu University -US-Rpf,88062,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Rpf,88062,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Yoshinobu Harazono -US-Rpf,88062,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Rpf,88062,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,3 -US-Rpf,88062,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,harazono2009gl@gmail.com -US-Rpf,88062,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Osaka Prefecture University -US-Rpf,88066,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Osaka Prefecture University -US-Rpf,88066,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-Rpf,88063,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Shinshu University -US-Rpf,88063,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-Rpf,88065,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,"ArCS, KAKENHI" -US-Rpf,88065,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-Rpf,85300,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Fire -US-Rpf,85285,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Rpf,85285,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-Rpf,85285,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20080820 -US-Rpf,85285,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Rpf,85297,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Rpf,85297,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-Rpf,85297,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20080820 -US-Rpf,85297,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Rpf,85281,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Rpf,85281,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-Rpf,85281,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20080820 -US-Rpf,85281,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Rpf,23001015,GRP_HEADER,SITE_NAME,Poker Flat Research Range: Succession from fire scar to deciduous forest -US-Rpf,85296,GRP_IGBP,IGBP,DBF -US-Rpf,85296,GRP_IGBP,IGBP_COMMENT,Birch and aspen forest with low shrubs. -US-Rpf,85287,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-Rpf,85287,GRP_LAND_OWNERSHIP,LAND_OWNER,Poker Flat Research Range -US-Rpf,85299,GRP_LOCATION,LOCATION_LAT,65.1198 -US-Rpf,85299,GRP_LOCATION,LOCATION_LONG,-147.4290 -US-Rpf,85299,GRP_LOCATION,LOCATION_ELEV,497 -US-Rpf,85298,GRP_NETWORK,NETWORK,AmeriFlux -US-Rpf,1700000903,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(18), 108350" -US-Rpf,1700000903,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -US-Rpf,1700000903,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Rpf,1700004272,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Iwata, H., Ueyama, M., Harazono, Y., Tsuyuzaki, S., Kondo, M., Uchida, M. (2011) Quick recovery of carbon dioxide exchanges in a burned black spruce forest in interior Alaska, SOLA, 7(), 105-108" -US-Rpf,1700004272,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Rpf,1700002169,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Iwata, H., Ueyama, M., Harazono, Y., Tsuyuzaki, S., Kondo, M., Uchida, M. (2011) Quick recovery of carbon dioxide exchanges in a burned black spruce forest in interior Alaska, SOLA, 7(18), 105-108" -US-Rpf,1700002169,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Rpf,1700008364,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Iwata, H., Ueyama, M., Iwama, C. and Harazono, Y. (2013) Variations in fraction of absorbed photosynthetically active radiation and comparisons with MODIS data in burned black spruce forests of interior Alaska, Polar Science, 7(2), 113-124" -US-Rpf,1700008364,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Rpf,1700004950,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Masahito UEYAMA, Narumi TAHARA, Hirohiko NAGANO, Naoki MAKITA, Hiroki IWATA, Yoshinobu HARAZONO (2018) Leaf- and ecosystem-scale photosynthetic parameters for the overstory and understory of boreal forests in interior Alaska, journal of Agricultural Meteorology, 74(2), 79-86" -US-Rpf,1700004950,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Rpf,1700008937,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Masahito UEYAMA, Hiroki IWATA, Hirohiko NAGANO, Narumi TAHARA, Chie IWAMA, Yoshinobu HARAZONO (2019) Carbon dioxide balance in early-successional forests after forest fires in interior Alaska, Agricultural and Forest Meteorology, 275(), 196-207" -US-Rpf,1700008937,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Primary_Citation -US-Rpf,1700000132,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Masahito UEYAMA, Hiroki IWATA, Hirohiko NAGANO, Narumi TAHARA, Chie IWAMA, Yoshinobu HARAZONO (2019) Carbon dioxide balance in early-successional forests after forest fires in interior Alaska, Agricultural and Forest Meteorology, 275(18), 196-207" -US-Rpf,1700000132,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Primary_Citation -US-Rpf,1700004557,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Ueyama, M., Yamamori, T., Iwata, H., Harazono, Y. (2020) Cooling And Moistening Of The Planetary Boundary Layer In Interior Alaska Due To A Postfire Change In Surface Energy Exchange, Journal Of Geophysical Research: Atmospheres, 125(18), 79-86" -US-Rpf,1700004557,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2020JD032968 -US-Rpf,1700004557,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Rpf,85282,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,Long-term monitoring energy & CO2 fluxes after forest fires. -US-Rpf,85280,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"Syun-Ichi Akasofu Building -2160 Koyukuk Dr -Fairbanks, AK 99775" -US-Rpf,85284,GRP_SITE_CHAR,TERRAIN,"Medium Slope (>2 %, <5%)" -US-Rpf,85284,GRP_SITE_CHAR,ASPECT,N -US-Rpf,85284,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,500 -US-Rpf,85283,GRP_SITE_DESC,SITE_DESC,"This tower is located near Davis Center, Poker Flat Research Range. Deciduous trees and shrubs are dominated at the burned black spruce forest." -US-Rpf,85289,GRP_SITE_FUNDING,SITE_FUNDING,"ArCS, KAKENHI" -US-Rpf,85291,GRP_STATE,STATE,AK -US-Rpf,85293,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Hiroki Iwata -US-Rpf,85293,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Rpf,85293,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,hiwata@shinshu-u.ac.jp -US-Rpf,85293,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Shinshu University -US-Rpf,95031,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Masahito Ueyama -US-Rpf,95031,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Rpf,95031,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,miyabi-flux@muh.biglobe.ne.jp -US-Rpf,95031,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Osaka Prefecture University -US-Rpf,94992,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Yoshinobu Harazono -US-Rpf,94992,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Rpf,94992,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,harazono2009gl@gmail.com -US-Rpf,94992,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Osaka Prefecture University -US-Rpf,85279,GRP_TOWER_POWER,TOWER_POWER,Direct power -US-Rpf,85295,GRP_TOWER_TYPE,TOWER_TYPE,walk-up -US-Rpf,24001015,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-Rpf -US-Rpf,85292,GRP_UTC_OFFSET,UTC_OFFSET,-9 -US-RRC,79843,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,We acknowledge Virginia Commonwealth University and the Dominion Charitable Foundation for support. -US-RRC,79839,GRP_CLIM_AVG,MAT,15.4 -US-RRC,79839,GRP_CLIM_AVG,MAP,1117 -US-RRC,79839,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfa -US-RRC,27000962,GRP_COUNTRY,COUNTRY,USA -US-RRC,79831,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Land cover change -US-RRC,79827,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-RRC,79827,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-RRC,79827,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201701010101 -US-RRC,79827,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-RRC,79833,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-RRC,79833,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CH4 -US-RRC,79833,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201701010101 -US-RRC,79833,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-RRC,79836,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-RRC,79836,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-RRC,79836,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201701010101 -US-RRC,79836,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-RRC,23000962,GRP_HEADER,SITE_NAME,Rice Rivers Center Marsh -US-RRC,91384,GRP_IGBP,IGBP,WET -US-RRC,91384,GRP_IGBP,IGBP_DATE_START,201001010101 -US-RRC,91384,GRP_IGBP,IGBP_COMMENT,Restored back to wetland following 90 years of inundation -US-RRC,91324,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -US-RRC,91324,GRP_LAND_OWNERSHIP,LAND_OWNER,Owned by Virginia Commonwealth University -US-RRC,81412,GRP_LOCATION,LOCATION_LAT,37.3344 -US-RRC,81412,GRP_LOCATION,LOCATION_LONG,-77.2065 -US-RRC,81412,GRP_LOCATION,LOCATION_ELEV,0.1 -US-RRC,81412,GRP_LOCATION,LOCATION_DATE_START,201001010101 -US-RRC,81412,GRP_LOCATION,LOCATION_COMMENT,https://ricerivers.vcu.edu/research/real-time-data-and-tools/ -US-RRC,79824,GRP_NETWORK,NETWORK,AmeriFlux -US-RRC,79834,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,Biophysical drivers of CO2 and CH4 fluxes -US-RRC,79845,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"3701 John Tyler Memorial Hwy, Charles City, VA 23030" -US-RRC,79835,GRP_SITE_CHAR,TERRAIN,Flat -US-RRC,79835,GRP_SITE_CHAR,ASPECT,FLAT -US-RRC,79835,GRP_SITE_CHAR,WIND_DIRECTION,W -US-RRC,79835,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,300 -US-RRC,79835,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,5 -US-RRC,79844,GRP_SITE_DESC,SITE_DESC,"Restored freshwater, tidal wetland" -US-RRC,79841,GRP_STATE,STATE,VA -US-RRC,79828,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Christopher Gough -US-RRC,79828,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-RRC,79828,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,cmgough@vcu.edu -US-RRC,79828,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Virginia Commonwealth University -US-RRC,79828,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1000 W. Cary Street, Richmond, VA 23284-2012" -US-RRC,79838,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Ellen Stuart Haëntjens -US-RRC,79838,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-RRC,79838,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,goodrichstej@mymail.vcu.edu -US-RRC,79838,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Virginia Commonwealth University -US-RRC,91317,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Lisa Haber -US-RRC,91317,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-RRC,91317,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,haberlt@mymail.vcu.edu -US-RRC,91317,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Virginia Commonwealth University -US-RRC,79842,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Scott Neubauer -US-RRC,79842,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-RRC,79842,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,sneubauer@VCU.EDU -US-RRC,79842,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Virginia Commonwealth University -US-RRC,79830,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-RRC,79829,GRP_TOWER_TYPE,TOWER_TYPE,triangle -US-RRC,79840,GRP_URL,URL,http://www.people.vcu.edu/~cmgough/ -US-RRC,24000962,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-RRC -US-Rwe,88143,GRP_CLIM_AVG,MAT,5.4 -US-Rwe,88143,GRP_CLIM_AVG,MAP,800 -US-Rwe,88143,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Bsh -US-Rwe,27001111,GRP_COUNTRY,COUNTRY,USA -US-Rwe,91682,GRP_DOI,DOI,10.17190/AMF/1617721 -US-Rwe,91682,GRP_DOI,DOI_CITATION,"Gerald Flerchinger, Michele L. Reba (2020), AmeriFlux BASE US-Rwe RCEW Reynolds Mountain East, Ver. 1-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1617721" -US-Rwe,91682,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-Rwe,91530,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Rwe,91530,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Gerald Flerchinger -US-Rwe,91530,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Rwe,91530,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,gerald.flerchinger@ars.usda.gov -US-Rwe,91530,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,USDA Agricultural Research Service -US-Rwe,91529,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Rwe,91529,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Michele L. Reba -US-Rwe,91529,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Rwe,91529,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,michele.reba@ars.usda.gov -US-Rwe,91529,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,USDA Agricultural Research Service -US-Rwe,91673,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,USDA Agricultural Research Service -US-Rwe,91673,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-Rwe,91634,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,USDA -ARS -US-Rwe,91634,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-Rwe,88136,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Rwe,88136,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-Rwe,88136,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,200302040000 -US-Rwe,88136,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,200710010000 -US-Rwe,88136,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Rwe,88135,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Rwe,88135,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-Rwe,88135,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,200302040000 -US-Rwe,88135,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,200710010000 -US-Rwe,88135,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Rwe,23001111,GRP_HEADER,SITE_NAME,RCEW Reynolds Mountain East -US-Rwe,88142,GRP_IGBP,IGBP,CSH -US-Rwe,88142,GRP_IGBP,IGBP_COMMENT,The site is a grazing alotment with light cattle grazing in summer. -US-Rwe,88140,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-Rwe,88140,GRP_LAND_OWNERSHIP,LAND_OWNER,USDI Bureau of Land Management -US-Rwe,91722,GRP_LOCATION,LOCATION_LAT,43.0653 -US-Rwe,91722,GRP_LOCATION,LOCATION_LONG,-116.7591 -US-Rwe,91722,GRP_LOCATION,LOCATION_ELEV,2098 -US-Rwe,91722,GRP_LOCATION,LOCATION_DATE_START,19830224 -US-Rwe,91722,GRP_LOCATION,LOCATION_COMMENT,Full meteorological station has been in place since 1983; streamflow and precipitation go much further back. -US-Rwe,88139,GRP_NETWORK,NETWORK,AmeriFlux -US-Rwe,1700007491,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Fellows, A. W., Flerchinger, G. N., Seyfried, M. S., Biederman, J. A., Lohse, K. A. (2020) Winter Co 2 Efflux From Sagebrush Shrublands Distributed Across The Rain‐To‐Snow Transition Zone, Journal Of Geophysical Research: Biogeosciences, 125(2), 246-263" -US-Rwe,1700007491,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2019JG005325 -US-Rwe,1700007491,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Rwe,1700002112,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Flerchinger, G. N., Fellows, A. W., Seyfried, M. S., Clark, P. E., Lohse, K. A. (2020) Water And Carbon Fluxes Along An Elevational Gradient In A Sagebrush Ecosystem, Ecosystems, 23(2), 246-263" -US-Rwe,1700002112,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1007/S10021-019-00400-X -US-Rwe,1700002112,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Rwe,1700007959,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Flerchinger, G. N., Marks, D., Reba, M. L., Yu, Q., Seyfried, M. S. (2010) Surface Fluxes And Water Balance Of Spatially Varying Vegetation Within A Small Mountainous Headwater Catchment, Hydrology And Earth System Sciences, 14(6), 965-978" -US-Rwe,1700007959,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.5194/HESS-14-965-2010 -US-Rwe,1700007959,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Rwe,1700006996,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Flerchinger, G. N., Reba, M. L., Marks, D. (2012) Measurement Of Surface Energy Fluxes From Two Rangeland Sites And Comparison With A Multilayer Canopy Model, Journal Of Hydrometeorology, 13(3), 1038-1051" -US-Rwe,1700006996,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1175/JHM-D-11-093.1 -US-Rwe,1700006996,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Rwe,1700007785,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Reba, M. L., Link, T. E., Marks, D., Pomeroy, J. (2009) An Assessment Of Corrections For Eddy Covariance Measured Turbulent Fluxes Over Snow In Mountain Environments, Water Resources Research, 45(4), 1038-1051" -US-Rwe,1700007785,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2008WR007045 -US-Rwe,1700007785,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Rwe,1700004665,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Reba, M. L., Marks, D., Seyfried, M., Winstral, A., Kumar, M., Flerchinger, G. (2011) A Long-Term Data Set For Hydrologic Modeling In A Snow-Dominated Mountain Catchment, Water Resources Research, 47(7), 1038-1051" -US-Rwe,1700004665,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2010WR010030 -US-Rwe,1700004665,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Rwe,88141,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,Ecosystem productivity and soil carbon storage -US-Rwe,88146,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"800 Park Blvd., Suite 105, Boise, Idaho 83712" -US-Rwe,88148,GRP_SITE_CHAR,TERRAIN,Gentle slope (<2 %) -US-Rwe,88148,GRP_SITE_CHAR,ASPECT,NW -US-Rwe,88148,GRP_SITE_CHAR,WIND_DIRECTION,SSW -US-Rwe,88148,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,180 -US-Rwe,88134,GRP_SITE_DESC,SITE_DESC,The site is located on the USDA-ARS's Reynolds Creek Experimental Watershed. It is a mixed sagebrush site on land managed by USDI Bureau of Land Management. -US-Rwe,88144,GRP_SITE_FUNDING,SITE_FUNDING,USDA -ARS -US-Rwe,88133,GRP_STATE,STATE,ID -US-Rwe,88138,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Gerald Flerchinger -US-Rwe,88138,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Rwe,88138,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,gerald.flerchinger@ars.usda.gov -US-Rwe,88138,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,USDA Agricultural Research Service -US-Rwe,88137,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Michele L. Reba -US-Rwe,88137,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Rwe,88137,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,michele.reba@ars.usda.gov -US-Rwe,88137,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,USDA Agricultural Research Service -US-Rwe,88147,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-Rwe,88131,GRP_TOWER_TYPE,TOWER_TYPE,triangle -US-Rwe,24001111,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-Rwe -US-Rwe,88145,GRP_UTC_OFFSET,UTC_OFFSET,-7 -US-Rwf,88124,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,Support for the Reynolds Creek Critical Zone Observatory Cooperative is provided by USDA ARS and NSF Grant #EAR 1331872. -US-Rwf,88130,GRP_CLIM_AVG,MAT,6.5 -US-Rwf,88130,GRP_CLIM_AVG,MAP,505 -US-Rwf,88130,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Bsh -US-Rwf,27001112,GRP_COUNTRY,COUNTRY,USA -US-Rwf,91703,GRP_DOI,DOI,10.17190/AMF/1617724 -US-Rwf,91703,GRP_DOI,DOI_CITATION,"Gerald Flerchinger (2021), AmeriFlux BASE US-Rwf RCEW Upper Sheep Prescibed Fire, Ver. 2-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1617724" -US-Rwf,91703,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-Rwf,91531,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Rwf,91531,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Gerald Flerchinger -US-Rwf,91531,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Rwf,91531,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,gerald.flerchinger@ars.usda.gov -US-Rwf,91531,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,USDA Agricultural Research Service -US-Rwf,91669,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,USDA Agricultural Research Service -US-Rwf,91669,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-Rwf,91624,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,USDA -ARS; NSF Critical Zone Observatory Network -US-Rwf,91624,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-Rwf,88126,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Fire -US-Rwf,88120,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Rwf,88120,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-Rwf,88120,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201406041000 -US-Rwf,88120,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Rwf,23001112,GRP_HEADER,SITE_NAME,RCEW Upper Sheep Prescibed Fire -US-Rwf,88118,GRP_IGBP,IGBP,CSH -US-Rwf,88118,GRP_IGBP,IGBP_COMMENT,The site is within an exclosure excluded from since 1984; a presribed fire was conducted in September 2007 -US-Rwf,88127,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-Rwf,88127,GRP_LAND_OWNERSHIP,LAND_OWNER,USDI Bureau of Land Management -US-Rwf,88125,GRP_LOCATION,LOCATION_LAT,43.1207 -US-Rwf,88125,GRP_LOCATION,LOCATION_LONG,-116.7231 -US-Rwf,88125,GRP_LOCATION,LOCATION_ELEV,1878 -US-Rwf,88125,GRP_LOCATION,LOCATION_DATE_START,19841001 -US-Rwf,88125,GRP_LOCATION,LOCATION_COMMENT,Full meteorological station has been in place since 1984 -US-Rwf,88121,GRP_NETWORK,NETWORK,AmeriFlux -US-Rwf,1700008199,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Fellows, A. W., Flerchinger, G. N., Lohse, K. A., Seyfried, M. S. (2018) Rapid Recovery Of Gross Production And Respiration In A Mesic Mountain Big Sagebrush Ecosystem Following Prescribed Fire, Ecosystems, 21(7), 1283-1294" -US-Rwf,1700008199,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1007/S10021-017-0218-9 -US-Rwf,1700008199,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Rwf,1700006156,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Fellows, A. W., Flerchinger, G. N., Seyfried, M. S., Biederman, J. A., Lohse, K. A. (2020) Winter Co 2 Efflux From Sagebrush Shrublands Distributed Across The Rain‐To‐Snow Transition Zone, Journal Of Geophysical Research: Biogeosciences, 125(2), 1283-1294" -US-Rwf,1700006156,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2019JG005325 -US-Rwf,1700006156,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Rwf,1700003240,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Flerchinger, G. N., Fellows, A. W., Seyfried, M. S., Clark, P. E., Lohse, K. A. (2019) Water And Carbon Fluxes Along An Elevational Gradient In A Sagebrush Ecosystem, Ecosystems, (), " -US-Rwf,1700003240,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1007/S10021-019-00400-X -US-Rwf,1700003240,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Primary_Citation -US-Rwf,1700001059,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Flerchinger, G. N., Fellows, A. W., Seyfried, M. S., Clark, P. E., Lohse, K. A. (2019) Water And Carbon Fluxes Along An Elevational Gradient In A Sagebrush Ecosystem, Ecosystems, 125(2), 1283-1294" -US-Rwf,1700001059,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1007/S10021-019-00400-X -US-Rwf,1700001059,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Primary_Citation -US-Rwf,1700004668,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Flerchinger, G. N., Fellows, A. W., Seyfried, M. S., Clark, P. E., Lohse, K. A. (2020) Water And Carbon Fluxes Along An Elevational Gradient In A Sagebrush Ecosystem, Ecosystems, 23(2), 246-263" -US-Rwf,1700004668,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1007/S10021-019-00400-X -US-Rwf,1700004668,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Rwf,1700002976,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Flerchinger, G. N., Seyfried, M. S., Hardegree, S. P. (2016) Hydrologic Response And Recovery To Prescribed Fire And Vegetation Removal In A Small Rangeland Catchment, Ecohydrology, 9(8), 1604-1619" -US-Rwf,1700002976,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/ECO.1751 -US-Rwf,1700002976,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Rwf,1700005052,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Flerchinger, G., Seyfried, M. (2014) Comparison Of Methods For Estimating Evapotranspiration In A Small Rangeland Catchment, Vadose Zone Journal, 13(4), vzj2013.08.0152" -US-Rwf,1700005052,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.2136/VZJ2013.08.0152 -US-Rwf,1700005052,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Rwf,88119,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,Post-fire ecosystem recovery and productivity -US-Rwf,88128,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"800 Park Blvd., Suite 105, Boise, Idaho 83712" -US-Rwf,88115,GRP_SITE_CHAR,TERRAIN,Strong Slope (>10%) -US-Rwf,88115,GRP_SITE_CHAR,ASPECT,NE -US-Rwf,88115,GRP_SITE_CHAR,WIND_DIRECTION,WNW -US-Rwf,88115,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,120 -US-Rwf,88115,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,120 -US-Rwf,88114,GRP_SITE_DESC,SITE_DESC,The site is located on the USDA-ARS's Reynolds Creek Experimental Watershed. It is a recovering mountain big sagebrush site after a 2007 prescrobed fire -US-Rwf,88113,GRP_SITE_FUNDING,SITE_FUNDING,USDA -ARS; NSF Critical Zone Observatory Network -US-Rwf,88129,GRP_STATE,STATE,ID -US-Rwf,88123,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Gerald Flerchinger -US-Rwf,88123,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Rwf,88123,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,gerald.flerchinger@ars.usda.gov -US-Rwf,88123,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,USDA Agricultural Research Service -US-Rwf,88116,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-Rwf,88122,GRP_TOWER_TYPE,TOWER_TYPE,triangle -US-Rwf,24001112,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-Rwf -US-Rwf,88117,GRP_UTC_OFFSET,UTC_OFFSET,-7 -US-Rws,33709,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,Support for the Reynolds Creek Critical Zone Observatory Cooperative is provided by USDA ARS and NSF Grant #EAR 1331872. -US-Rws,17067,GRP_CLIM_AVG,MAT,8.9 -US-Rws,17067,GRP_CLIM_AVG,MAP,290 -US-Rws,17067,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Bsk -US-Rws,27000674,GRP_COUNTRY,COUNTRY,USA -US-Rws,33569,GRP_DOI,DOI,10.17190/AMF/1375201 -US-Rws,33569,GRP_DOI,DOI_CITATION,"Gerald Flerchinger (2021), AmeriFlux BASE US-Rws Reynolds Creek Wyoming big sagebrush, Ver. 4-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1375201" -US-Rws,33569,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-Rws,32428,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Rws,32428,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Gerald Flerchinger -US-Rws,32428,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Rws,32428,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,gerald.flerchinger@ars.usda.gov -US-Rws,32428,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,USDA Agricultural Research Service -US-Rws,32430,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,USDA Agricultural Research Service -US-Rws,32430,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-Rws,32429,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,USDA -ARS; NSF Critical Zone Observatory Network -US-Rws,32429,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-Rws,17068,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Undisturbed -US-Rws,17083,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Rws,17083,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-Rws,17083,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20140916 -US-Rws,17083,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Rws,17069,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Rws,17069,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-Rws,17069,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20140916 -US-Rws,17069,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Rws,23000674,GRP_HEADER,SITE_NAME,Reynolds Creek Wyoming big sagebrush -US-Rws,17070,GRP_IGBP,IGBP,OSH -US-Rws,17070,GRP_IGBP,IGBP_COMMENT,The site is a grazing alotment with light cattle grazing in spring. -US-Rws,17071,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-Rws,17071,GRP_LAND_OWNERSHIP,LAND_OWNER,USDI Bureau of Land Management -US-Rws,17072,GRP_LOCATION,LOCATION_LAT,43.1675 -US-Rws,17072,GRP_LOCATION,LOCATION_LONG,-116.7132 -US-Rws,17072,GRP_LOCATION,LOCATION_ELEV,1425 -US-Rws,17072,GRP_LOCATION,LOCATION_DATE_START,20110827 -US-Rws,17072,GRP_LOCATION,LOCATION_COMMENT,"Full meteorological station has been in place since 2011; temperature, wind, and streamflow are available much further back." -US-Rws,17073,GRP_NETWORK,NETWORK,AmeriFlux -US-Rws,86999,GRP_NETWORK,NETWORK,Phenocam -US-Rws,1700000000,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(2), 108350" -US-Rws,1700000000,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -US-Rws,1700000000,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Rws,1700000795,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Fellows, A. W., Flerchinger, G. N., Seyfried, M. S., Biederman, J. A., Lohse, K. A. (2020) Winter Co 2 Efflux From Sagebrush Shrublands Distributed Across The Rain‐To‐Snow Transition Zone, Journal Of Geophysical Research: Biogeosciences, 125(2), E8604-E8613" -US-Rws,1700000795,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2019JG005325 -US-Rws,1700000795,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Rws,1700000417,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Flerchinger, G. N., Fellows, A. W., Seyfried, M. S., Clark, P. E., Lohse, K. A. (2019) Water And Carbon Fluxes Along An Elevational Gradient In A Sagebrush Ecosystem, Ecosystems, 115(37), E8604-E8613" -US-Rws,1700000417,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1007/S10021-019-00400-X -US-Rws,1700000417,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Primary_Citation -US-Rws,1700005310,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Goodwell, A. E., Kumar, P., Fellows, A. W., Flerchinger, G. N. (2018) Dynamic Process Connectivity Explains Ecohydrologic Responses To Rainfall Pulses And Drought, Proceedings Of The National Academy Of Sciences, 115(37), E8604-E8613" -US-Rws,1700005310,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1073/PNAS.1800236115 -US-Rws,1700005310,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Rws,1700000090,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Renwick, K. M., Fellows, A., Flerchinger, G. N., Lohse, K. A., Clark, P. E., Smith, W. K., Emmett, K., Poulter, B. (2019) Modeling Phenological Controls On Carbon Dynamics In Dryland Sagebrush Ecosystems, Agricultural And Forest Meteorology, 274(), 85-94" -US-Rws,1700000090,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2019.04.003 -US-Rws,1700000090,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Rws,1700008019,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Seyfried, M., Lohse, K., Marks, D., Flerchinger, G., Pierson, F., Holbrook, W. S. (2018) Reynolds Creek Experimental Watershed And Critical Zone Observatory, Vadose Zone Journal, 17(1), 0" -US-Rws,1700008019,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.2136/VZJ2018.07.0129 -US-Rws,1700008019,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Rws,17074,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,Ecosystem productivity and soil carbon storage -US-Rws,17075,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"800 Park Blvd., Suite 105, Boise, Idaho 83712" -US-Rws,17076,GRP_SITE_CHAR,TERRAIN,"Significant Slope (>5%, <10%)" -US-Rws,17076,GRP_SITE_CHAR,ASPECT,N -US-Rws,17076,GRP_SITE_CHAR,WIND_DIRECTION,SSW -US-Rws,17076,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,150 -US-Rws,17076,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,15 -US-Rws,17077,GRP_SITE_DESC,SITE_DESC,The site is located on the USDA-ARS's Reynolds Creek Experimental Watershed. It is dominated by Wyoming big sagebrush on land managed by USDI Bureau of Land Management. -US-Rws,33710,GRP_SITE_FUNDING,SITE_FUNDING,"USDA -ARS; NSF Critical Zone Observatory Network, NSF Grant #EAR 1331872" -US-Rws,17079,GRP_STATE,STATE,ID -US-Rws,17080,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Gerald Flerchinger -US-Rws,17080,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Rws,17080,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,gerald.flerchinger@ars.usda.gov -US-Rws,17080,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,USDA Agricultural Research Service -US-Rws,17084,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Aaron Fellows -US-Rws,17084,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,AncContact -US-Rws,17084,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,aarron.fellows@ars.usda.gov -US-Rws,17084,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,USDA Agricultural Research Service -US-Rws,29929,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-Rws,17081,GRP_TOWER_TYPE,TOWER_TYPE,triangle -US-Rws,24000674,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-Rws -US-Rws,17082,GRP_UTC_OFFSET,UTC_OFFSET,-7 -US-SdH,12271,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dsb -US-SdH,27000502,GRP_COUNTRY,COUNTRY,USA -US-SdH,15767,GRP_DOI,DOI,10.17190/AMF/1246136 -US-SdH,15767,GRP_DOI,DOI_CITATION,"Dave Billesbach, Tim J. Arkebauer (2016), AmeriFlux BASE US-SdH Nebraska SandHills Dry Valley, Ver. 1-1, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1246136" -US-SdH,15767,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-SdH,32316,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-SdH,32316,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Dave Billesbach -US-SdH,32316,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-SdH,32316,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,dbillesbach1@unl.edu -US-SdH,32316,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of Nebraska -US-SdH,32317,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-SdH,32317,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Tim J. Arkebauer -US-SdH,32317,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-SdH,32317,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,tarkebauer1@unl.edu -US-SdH,32317,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of Nebraska -US-SdH,32319,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,University of Nebraska -US-SdH,32319,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-SdH,32318,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Not funded -US-SdH,32318,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-SdH,12272,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Grazing -US-SdH,12273,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-SdH,12273,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-SdH,12273,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20040505 -US-SdH,12273,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-SdH,12285,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-SdH,12285,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-SdH,12285,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20040505 -US-SdH,12285,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-SdH,12287,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-SdH,12287,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-SdH,12287,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20040505 -US-SdH,12287,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-SdH,23000502,GRP_HEADER,SITE_NAME,Nebraska SandHills Dry Valley -US-SdH,12274,GRP_IGBP,IGBP,GRA -US-SdH,12275,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-SdH,12275,GRP_LAND_OWNERSHIP,LAND_OWNER,University of Nebraska -US-SdH,12276,GRP_LOCATION,LOCATION_LAT,42.0693 -US-SdH,12276,GRP_LOCATION,LOCATION_LONG,-101.4072 -US-SdH,12276,GRP_LOCATION,LOCATION_ELEV,1081 -US-SdH,12276,GRP_LOCATION,LOCATION_COMMENT,From CDIAC Tom Boden database dump -US-SdH,12277,GRP_NETWORK,NETWORK,AmeriFlux -US-SdH,1700005721,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(), 108350" -US-SdH,1700005721,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -US-SdH,1700005721,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-SdH,12278,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"The research focus of the Nebraska SandHills Dry Valley site is to examine the Atmosphere, Vegetation, Aquifer couplings, and their relationships with climate." -US-SdH,12279,GRP_SITE_CHAR,TERRAIN,Flat -US-SdH,12279,GRP_SITE_CHAR,WIND_DIRECTION,S -US-SdH,12279,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,700 -US-SdH,12280,GRP_SITE_DESC,SITE_DESC,The Nebraska SandHills Dry Valley tower is located on public land owned by the University of Nebraska-Lincoln. The site is on a research cattle ranch where grazing primarily takes place. -US-SdH,12281,GRP_SITE_FUNDING,SITE_FUNDING,Not funded -US-SdH,27191,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION,Sandy mixed mesic Mollic Endoaquepts -US-SdH,27191,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION_TAXONOMY,Other -US-SdH,12282,GRP_STATE,STATE,NE -US-SdH,12283,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Dave Billesbach -US-SdH,12283,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-SdH,12283,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,dbillesbach1@unl.edu -US-SdH,12283,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Nebraska -US-SdH,12283,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Department of Biological Systems Engineering, 157 L.W. Chase Hall,Lincoln, NE USA 68583-0726" -US-SdH,12286,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Tim J. Arkebauer -US-SdH,12286,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-SdH,12286,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,tarkebauer1@unl.edu -US-SdH,12286,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Nebraska -US-SdH,12286,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Department of Agronomy and Horticulture, EC 0817, 106 Kiesselbach Crops Research Laboratory,Lincoln, NE USA 68583-0817" -US-SdH,29858,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-SdH,12284,GRP_TOWER_TYPE,TOWER_TYPE,tripod -US-SdH,24000502,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-SdH -US-SdH,33652,GRP_UTC_OFFSET,UTC_OFFSET,-6 -US-SdH,33652,GRP_UTC_OFFSET,UTC_OFFSET_COMMENT,Added by AMF data processing team for data QAQC checks. -US-Seg,30400,GRP_CLIM_AVG,MAT,13.667 -US-Seg,30400,GRP_CLIM_AVG,MAP,273.304 -US-Seg,30400,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Bsk -US-Seg,27000476,GRP_COUNTRY,COUNTRY,USA -US-Seg,15646,GRP_DOI,DOI,10.17190/AMF/1246124 -US-Seg,15646,GRP_DOI,DOI_CITATION,"Marcy Litvak (2022), AmeriFlux BASE US-Seg Sevilleta grassland, Ver. 18-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1246124" -US-Seg,15646,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-Seg,32268,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Seg,32268,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Marcy Litvak -US-Seg,32268,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Seg,32268,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,mlitvak@unm.edu -US-Seg,32268,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of New Mexico -US-Seg,32270,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,University of New Mexico -US-Seg,32270,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-Seg,32269,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,"NSF, DOE-EPSCoR" -US-Seg,32269,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-Seg,15451,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Drought -US-Seg,15462,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Fire -US-Seg,15465,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Temperature extreme -US-Seg,15452,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Seg,15452,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-Seg,15452,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,200701010000 -US-Seg,15452,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Seg,15463,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Seg,15463,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-Seg,15463,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,200701010000 -US-Seg,15463,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Seg,23000476,GRP_HEADER,SITE_NAME,Sevilleta grassland -US-Seg,11618,GRP_IGBP,IGBP,GRA -US-Seg,15453,GRP_IGBP,IGBP,GRA -US-Seg,15453,GRP_IGBP,IGBP_DATE_START,200701010000 -US-Seg,15453,GRP_IGBP,IGBP_COMMENT,Chihuahuan Desert grassland -US-Seg,15454,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-Seg,15454,GRP_LAND_OWNERSHIP,LAND_OWNER,Sevilleta Fish and Wildlife Refuge -US-Seg,11620,GRP_LOCATION,LOCATION_LAT,34.3623 -US-Seg,11620,GRP_LOCATION,LOCATION_LONG,-106.7019 -US-Seg,11620,GRP_LOCATION,LOCATION_ELEV,1622 -US-Seg,11620,GRP_LOCATION,LOCATION_COMMENT,From CDIAC Tom Boden database dump -US-Seg,30409,GRP_LOCATION,LOCATION_LAT,34.3623 -US-Seg,30409,GRP_LOCATION,LOCATION_LONG,-106.7020 -US-Seg,30409,GRP_LOCATION,LOCATION_ELEV,1596 -US-Seg,30409,GRP_LOCATION,LOCATION_DATE_START,200701010000 -US-Seg,11621,GRP_NETWORK,NETWORK,AmeriFlux -US-Seg,87003,GRP_NETWORK,NETWORK,Phenocam -US-Seg,1700006948,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Anderson-Teixeira, K. J., Delong, J. P., Fox, A. M., Brese, D. A., Litvak, M. E. (2011) Differential Responses Of Production And Respiration To Temperature And Moisture Drive The Carbon Balance Across A Climatic Gradient In New Mexico, Global Change Biology, 17(1), 410-424" -US-Seg,1700006948,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/J.1365-2486.2010.02269.X -US-Seg,1700006948,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Seg,1700005592,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Biederman, J. A., Scott, R. L., Bell, T. W., Bowling, D. R., Dore, S., Garatuza-Payan, J., Kolb, T. E., Krishnan, P., Krofcheck, D. J., Litvak, M. E., Maurer, G. E., Meyers, T. P., Oechel, W. C., Papuga, S. A., Ponce-Campos, G. E., Rodriguez, J. C., Smith, W. K., Vargas, R., Watts, C. J., Yepez, E. A., Goulden, M. L. (2017) Co2 Exchange And Evapotranspiration Across Dryland Ecosystems Of Southwestern North America, Global Change Biology, 23(10), 4204-4221" -US-Seg,1700005592,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/GCB.13686 -US-Seg,1700005592,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Seg,1700003279,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Biederman, J. A., Scott, R. L., Goulden, M. L., Vargas, R., Litvak, M. E., Kolb, T. E., Yepez, E. A., Oechel, W. C., Blanken, P. D., Bell, T. W., Garatuza-Payan, J., Maurer, G. E., Dore, S., Burns, S. P. (2016) Terrestrial Carbon Balance In A Drier World: The Effects Of Water Availability In Southwestern North America, Global Change Biology, 22(5), 1867-1879" -US-Seg,1700003279,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/GCB.13222 -US-Seg,1700003279,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Seg,1700007020,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(3), 108350" -US-Seg,1700007020,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -US-Seg,1700007020,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Seg,1700003942,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Dettweiler-Robinson, E., Nuanez, M., Litvak, M. E. (2018) Biocrust Contribution To Ecosystem Carbon Fluxes Varies Along An Elevational Gradient, Ecosphere, 9(6), e02315" -US-Seg,1700003942,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/ECS2.2315 -US-Seg,1700003942,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Seg,1700006519,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Petrie, M. D., Collins, S. L., Swann, A. M., Ford, P. L., Litvak, M. (2015) Grassland To Shrubland State Transitions Enhance Carbon Sequestration In The Northern Chihuahuan Desert, Global Change Biology, 21(3), 1226-1235" -US-Seg,1700006519,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/GCB.12743 -US-Seg,1700006519,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Seg,1700005100,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Senay, G. B., Schauer, M., Velpuri, N. M., Singh, R. K., Kagone, S., Friedrichs, M., Litvak, M. E., Douglas-Mankin, K. R. (2019) Long-Term (1986–2015) Crop Water Use Characterization Over The Upper Rio Grande Basin Of United States And Mexico Using Landsat-Based Evapotranspiration, Remote Sensing, 11(13), 1587" -US-Seg,1700005100,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.3390/RS11131587 -US-Seg,1700005100,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Seg,1700007062,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Wolf, S., Keenan, T. F., Fisher, J. B., Baldocchi, D. D., Desai, A. R., Richardson, A. D., Scott, R. L., Law, B. E., Litvak, M. E., Brunsell, N. A., Peters, W., van der Laan-Luijkx, I. T. (2016) Warm Spring Reduced Carbon Cycle Impact Of The 2012 Us Summer Drought, Proceedings Of The National Academy Of Sciences, 113(21), 5880-5885" -US-Seg,1700007062,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1073/PNAS.1519620113 -US-Seg,1700007062,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Seg,30667,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"Research topics and objectives include 1) To understand the coupled water and energy cycles in semiarid environments; 2) Quantify carbon, water and energy fluxes in addition to inter-annual variability in these fluxes; 3) Quantify the extent to which water and carbon fluxes are controlled by soil moisture and rainfall, and the sensitivity of fluxes in this biome to changes in temperature and precipitation." -US-Seg,30413,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"University of New Mexico, Biology - Castetter Hall Room 137, 219 Yale Blvd NE, Albuquerque NM 87131" -US-Seg,30414,GRP_SITE_CHAR,TERRAIN,Flat -US-Seg,30414,GRP_SITE_CHAR,ASPECT,FLAT -US-Seg,30414,GRP_SITE_CHAR,WIND_DIRECTION,S -US-Seg,30669,GRP_SITE_DESC,SITE_DESC,"The Sevilleta Desert Grassland site is located within the McKenzie Flats area of the Sevilleta National Wildlife Refuge (NWR), central New Mexico. Historically, this area has been used for livestock grazing; however, the McKenzie Flats have not been grazed since 1973 and the effects of this previous grazing are considered negligible for the purposes of this study. As the name suggests, McKenzie Flats is an extensive (~130 km2), nearly flat, mixed-species desert grassland bounded on the east by Los Pinos Mountains and on the west by the Rio Grande. This site experienced a severe burn in August 2009." -US-Seg,30416,GRP_SITE_FUNDING,SITE_FUNDING,"NSF, DOE-EPSCoR" -US-Seg,29626,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION,Loamy Sand - Top 40 cm; Sandy Loam - Below 40 cm; Shallow root depth derived from the vegetation dominance of grasses. -US-Seg,29626,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION_TAXONOMY,Other -US-Seg,11627,GRP_STATE,STATE,NM -US-Seg,15459,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Marcy Litvak -US-Seg,15459,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Seg,15459,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,mlitvak@unm.edu -US-Seg,15459,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of New Mexico -US-Seg,81421,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Tomer Duman -US-Seg,81421,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,DataManager -US-Seg,81421,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,tomerduman@gmail.com -US-Seg,81421,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of New Mexico -US-Seg,99193,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Anthony Luketich -US-Seg,99193,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Technician -US-Seg,99193,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,luketich@unm.edu -US-Seg,99193,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of New Mexico -US-Seg,29850,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-Seg,15460,GRP_TOWER_TYPE,TOWER_TYPE,tripod -US-Seg,81420,GRP_URL,URL,http://www.litvaklab.org/grassland.html -US-Seg,24000476,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-Seg -US-Seg,11630,GRP_UTC_OFFSET,UTC_OFFSET,-7 -US-Seg,15461,GRP_UTC_OFFSET,UTC_OFFSET,-7 -US-Seg,15461,GRP_UTC_OFFSET,UTC_OFFSET_DATE_START,200701010000 -US-Ses,30425,GRP_CLIM_AVG,MAT,13.722 -US-Ses,30425,GRP_CLIM_AVG,MAP,275.082 -US-Ses,30425,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Bsk -US-Ses,27000477,GRP_COUNTRY,COUNTRY,USA -US-Ses,15717,GRP_DOI,DOI,10.17190/AMF/1246125 -US-Ses,15717,GRP_DOI,DOI_CITATION,"Marcy Litvak (2022), AmeriFlux BASE US-Ses Sevilleta shrubland, Ver. 18-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1246125" -US-Ses,15717,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-Ses,32271,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Ses,32271,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Marcy Litvak -US-Ses,32271,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Ses,32271,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,mlitvak@unm.edu -US-Ses,32271,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of New Mexico -US-Ses,32273,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,University of New Mexico -US-Ses,32273,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-Ses,32272,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,NSF EPSCoR -US-Ses,32272,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-Ses,15469,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Drought -US-Ses,15480,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Temperature extreme -US-Ses,15470,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Ses,15470,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-Ses,15470,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,200701010000 -US-Ses,15470,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Ses,15481,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Ses,15481,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-Ses,15481,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,200701010000 -US-Ses,15481,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Ses,23000477,GRP_HEADER,SITE_NAME,Sevilleta shrubland -US-Ses,11638,GRP_IGBP,IGBP,OSH -US-Ses,15471,GRP_IGBP,IGBP,OSH -US-Ses,15471,GRP_IGBP,IGBP_DATE_START,200701010000 -US-Ses,15471,GRP_IGBP,IGBP_COMMENT,Chihuahuan Desert creosote shrubland -US-Ses,15472,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-Ses,15472,GRP_LAND_OWNERSHIP,LAND_OWNER,Sevilleta Fish and Wildlife Refuge -US-Ses,11640,GRP_LOCATION,LOCATION_LAT,34.3349 -US-Ses,11640,GRP_LOCATION,LOCATION_LONG,-106.7442 -US-Ses,11640,GRP_LOCATION,LOCATION_ELEV,1593 -US-Ses,11640,GRP_LOCATION,LOCATION_COMMENT,From CDIAC Tom Boden database dump -US-Ses,30433,GRP_LOCATION,LOCATION_LAT,34.3349 -US-Ses,30433,GRP_LOCATION,LOCATION_LONG,-106.7442 -US-Ses,30433,GRP_LOCATION,LOCATION_ELEV,1604 -US-Ses,30433,GRP_LOCATION,LOCATION_DATE_START,200701010000 -US-Ses,11641,GRP_NETWORK,NETWORK,AmeriFlux -US-Ses,87084,GRP_NETWORK,NETWORK,Phenocam -US-Ses,1700007656,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Anderson-Teixeira, K. J., Delong, J. P., Fox, A. M., Brese, D. A., Litvak, M. E. (2011) Differential Responses Of Production And Respiration To Temperature And Moisture Drive The Carbon Balance Across A Climatic Gradient In New Mexico, Global Change Biology, 17(1), 410-424" -US-Ses,1700007656,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/J.1365-2486.2010.02269.X -US-Ses,1700007656,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ses,1700002058,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Biederman, J. A., Scott, R. L., Arnone III, J. A., Jasoni, R. L., Litvak, M. E., Moreo, M. T., Papuga, S. A., Ponce-Campos, G. E., Schreiner-McGraw, A. P., Vivoni, E. R. (2018) Shrubland Carbon Sink Depends Upon Winter Water Availability In The Warm Deserts Of North America, Agricultural And Forest Meteorology, 249(6), 407-419" -US-Ses,1700002058,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2017.11.005 -US-Ses,1700002058,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ses,1700001320,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Biederman, J. A., Scott, R. L., Bell, T. W., Bowling, D. R., Dore, S., Garatuza-Payan, J., Kolb, T. E., Krishnan, P., Krofcheck, D. J., Litvak, M. E., Maurer, G. E., Meyers, T. P., Oechel, W. C., Papuga, S. A., Ponce-Campos, G. E., Rodriguez, J. C., Smith, W. K., Vargas, R., Watts, C. J., Yepez, E. A., Goulden, M. L. (2017) Co2 Exchange And Evapotranspiration Across Dryland Ecosystems Of Southwestern North America, Global Change Biology, 23(10), 4204-4221" -US-Ses,1700001320,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/GCB.13686 -US-Ses,1700001320,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ses,1700006849,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Biederman, J. A., Scott, R. L., Goulden, M. L., Vargas, R., Litvak, M. E., Kolb, T. E., Yepez, E. A., Oechel, W. C., Blanken, P. D., Bell, T. W., Garatuza-Payan, J., Maurer, G. E., Dore, S., Burns, S. P. (2016) Terrestrial Carbon Balance In A Drier World: The Effects Of Water Availability In Southwestern North America, Global Change Biology, 22(5), 1867-1879" -US-Ses,1700006849,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/GCB.13222 -US-Ses,1700006849,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ses,1700000087,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(3), 108350" -US-Ses,1700000087,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -US-Ses,1700000087,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ses,1700004125,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Dettweiler-Robinson, E., Nuanez, M., Litvak, M. E. (2018) Biocrust Contribution To Ecosystem Carbon Fluxes Varies Along An Elevational Gradient, Ecosphere, 9(6), e02315" -US-Ses,1700004125,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/ECS2.2315 -US-Ses,1700004125,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ses,1700002031,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Petrie, M. D., Collins, S. L., Swann, A. M., Ford, P. L., Litvak, M. (2015) Grassland To Shrubland State Transitions Enhance Carbon Sequestration In The Northern Chihuahuan Desert, Global Change Biology, 21(3), 1226-1235" -US-Ses,1700002031,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/GCB.12743 -US-Ses,1700002031,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ses,1700001935,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Senay, G. B., Schauer, M., Velpuri, N. M., Singh, R. K., Kagone, S., Friedrichs, M., Litvak, M. E., Douglas-Mankin, K. R. (2019) Long-Term (1986–2015) Crop Water Use Characterization Over The Upper Rio Grande Basin Of United States And Mexico Using Landsat-Based Evapotranspiration, Remote Sensing, 11(13), 1587" -US-Ses,1700001935,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.3390/RS11131587 -US-Ses,1700001935,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ses,1700002088,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Wolf, S., Keenan, T. F., Fisher, J. B., Baldocchi, D. D., Desai, A. R., Richardson, A. D., Scott, R. L., Law, B. E., Litvak, M. E., Brunsell, N. A., Peters, W., van der Laan-Luijkx, I. T. (2016) Warm Spring Reduced Carbon Cycle Impact Of The 2012 Us Summer Drought, Proceedings Of The National Academy Of Sciences, 113(21), 5880-5885" -US-Ses,1700002088,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1073/PNAS.1519620113 -US-Ses,1700002088,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ses,30670,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"Research topics and objectives include 1) To understand the coupled water and energy cycles in semiarid environments; 2) Quantify carbon, water and energy fluxes in addition to inter-annual variability in these fluxes; 3) Quantify the extent to which water and carbon fluxes are controlled by soil moisture and rainfall, and the sensitivity of fluxes in this biome to changes in temperature and precipitation." -US-Ses,30437,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"University of New Mexico, Biology - Castetter Hall Room 137, 219 Yale Blvd NE, Albuquerque NM 87131" -US-Ses,30438,GRP_SITE_CHAR,TERRAIN,Flat -US-Ses,30438,GRP_SITE_CHAR,ASPECT,FLAT -US-Ses,30438,GRP_SITE_CHAR,WIND_DIRECTION,S -US-Ses,30438,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,200 -US-Ses,30439,GRP_SITE_DESC,SITE_DESC,"The Sevilleta Desert Shrubland site is located in Larrea-dominated shrubland in the northern Chihuahuan Desert of the Rio Grande Valley, on the Sevilleta National Wildlife Refuge (SNWR). The site is within the McKenzie Flats area of the Sevilleta National Wildlife Refuge (NWR). McKenzie Flats is an extensive (~130 km2), nearly flat, mixed-species desert grassland bounded on the east by Los Pinos Mountains and on the west by the Rio Grande. Historically, this area has been used for livestock grazing; however, the McKenzie Flats have not been grazed since 1973 and the effects of this previous grazing are considered negligible for the purposes of this study. The density of Larrea at this site is 0.9 m-2 , interspersed with C4 perennial grasses (Bouteloua gracilis, B. eriopoda, Sporobolis spp., Hilaria jamesii, Muhlenbergia spp.). Sixty percent of mean annual precipitation comes in isolated, short duration showers during the monsoon season (July – September); the remainder arrives with winter frontal systems, although with considerable year-to-year variation." -US-Ses,30440,GRP_SITE_FUNDING,SITE_FUNDING,NSF EPSCoR -US-Ses,29627,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION,"Sandy Loam - Below 40 cm; Deep rooth depth, 20-40 cm, derived from the vegetation dominance of shurbs." -US-Ses,29627,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION_TAXONOMY,Other -US-Ses,11647,GRP_STATE,STATE,NM -US-Ses,15477,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Marcy Litvak -US-Ses,15477,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Ses,15477,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,mlitvak@unm.edu -US-Ses,15477,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of New Mexico -US-Ses,81424,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Tomer Duman -US-Ses,81424,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,DataManager -US-Ses,81424,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,tomerduman@gmail.com -US-Ses,81424,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of New Mexico -US-Ses,99206,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Anthony Luketich -US-Ses,99206,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Technician -US-Ses,99206,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,luketich@unm.edu -US-Ses,99206,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of New Mexico -US-Ses,29851,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-Ses,15478,GRP_TOWER_TYPE,TOWER_TYPE,tripod -US-Ses,81423,GRP_URL,URL,http://www.litvaklab.org/shrubland.html -US-Ses,24000477,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-Ses -US-Ses,11650,GRP_UTC_OFFSET,UTC_OFFSET,-7 -US-Ses,15479,GRP_UTC_OFFSET,UTC_OFFSET,-7 -US-Ses,15479,GRP_UTC_OFFSET,UTC_OFFSET_DATE_START,200701010000 -US-Slt,27175,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER,0.0 -US-Slt,27175,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_SPATIAL_VARIABILITY,0.1 -US-Slt,27175,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_ORGAN,Total -US-Slt,27175,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_PHEN,Mixed/unknown -US-Slt,27175,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_UNIT,gC m-2 -US-Slt,27175,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_APPROACH,"Ten to twenty 1 m2 plots, harvested annually at time of peak biomass. Samples separated into foliage and stems, dried at 60 C" -US-Slt,27175,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_DATE,2007 -US-Slt,27809,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER,0.0 -US-Slt,27809,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_SPATIAL_VARIABILITY,0.0 -US-Slt,27809,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_ORGAN,Total -US-Slt,27809,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_PHEN,Mixed/unknown -US-Slt,27809,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_UNIT,gC m-2 -US-Slt,27809,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_APPROACH,"Ten to twenty 1 m2 plots, harvested annually at time of peak biomass. Samples separated into foliage and stems, dried at 60 C" -US-Slt,27809,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_DATE,2004 -US-Slt,29617,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER,0.2 -US-Slt,29617,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_SPATIAL_VARIABILITY,0.3 -US-Slt,29617,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_ORGAN,Total -US-Slt,29617,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_PHEN,Mixed/unknown -US-Slt,29617,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_UNIT,gC m-2 -US-Slt,29617,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_APPROACH,"Ten to twenty 1 m2 plots, harvested annually at time of peak biomass. Samples separated into foliage and stems, dried at 60 C" -US-Slt,29617,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_DATE,2006 -US-Slt,28084,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER,0.4 -US-Slt,28084,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_SPATIAL_VARIABILITY,0.7 -US-Slt,28084,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_ORGAN,Total -US-Slt,28084,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_PHEN,Mixed/unknown -US-Slt,28084,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_UNIT,gC m-2 -US-Slt,28084,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_APPROACH,"Ten to twenty 1 m2 plots, harvested annually at time of peak biomass. Samples separated into foliage and stems, dried at 60 C" -US-Slt,28084,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_DATE,2005 -US-Slt,28773,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB,14.5 -US-Slt,28773,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_SPATIAL_VARIABILITY,3.7 -US-Slt,28773,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_ORGAN,Foliage -US-Slt,28773,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_PHEN,Mixed/unknown -US-Slt,28773,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_UNIT,gC m-2 -US-Slt,28773,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_APPROACH,"Ten to twenty 1 m2 plots, harvested annually at time of peak biomass. Samples separated into foliage and stems, dried at 60 C" -US-Slt,28773,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_DATE,2006 -US-Slt,28083,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB,16.2 -US-Slt,28083,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_SPATIAL_VARIABILITY,3.6 -US-Slt,28083,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_ORGAN,Foliage -US-Slt,28083,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_PHEN,Mixed/unknown -US-Slt,28083,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_UNIT,gC m-2 -US-Slt,28083,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_APPROACH,"Ten to twenty 1 m2 plots, harvested annually at time of peak biomass. Samples separated into foliage and stems, dried at 60 C" -US-Slt,28083,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_DATE,2005 -US-Slt,28929,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB,18.1 -US-Slt,28929,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_SPATIAL_VARIABILITY,15.1 -US-Slt,28929,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_ORGAN,Foliage -US-Slt,28929,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_PHEN,Mixed/unknown -US-Slt,28929,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_UNIT,gC m-2 -US-Slt,28929,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_APPROACH,"Ten to twenty 1 m2 plots, harvested annually at time of peak biomass. Samples separated into foliage and stems, dried at 60 C" -US-Slt,28929,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_DATE,2004 -US-Slt,28774,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB,64.8 -US-Slt,28774,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_SPATIAL_VARIABILITY,22.6 -US-Slt,28774,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_ORGAN,Wood -US-Slt,28774,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_PHEN,Mixed/unknown -US-Slt,28774,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_UNIT,gC m-2 -US-Slt,28774,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_APPROACH,"Ten to twenty 1 m2 plots, harvested annually at time of peak biomass. Samples separated into foliage and stems, dried at 60 C" -US-Slt,28774,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_DATE,2006 -US-Slt,27725,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB,69.4 -US-Slt,27725,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_SPATIAL_VARIABILITY,22.5 -US-Slt,27725,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_ORGAN,Wood -US-Slt,27725,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_PHEN,Mixed/unknown -US-Slt,27725,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_UNIT,gC m-2 -US-Slt,27725,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_APPROACH,"Ten to twenty 1 m2 plots, harvested annually at time of peak biomass. Samples separated into foliage and stems, dried at 60 C" -US-Slt,27725,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_DATE,2007 -US-Slt,29297,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB,70.7 -US-Slt,29297,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_SPATIAL_VARIABILITY,48.0 -US-Slt,29297,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_ORGAN,Wood -US-Slt,29297,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_PHEN,Mixed/unknown -US-Slt,29297,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_UNIT,gC m-2 -US-Slt,29297,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_APPROACH,"Ten to twenty 1 m2 plots, harvested annually at time of peak biomass. Samples separated into foliage and stems, dried at 60 C" -US-Slt,29297,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_DATE,2004 -US-Slt,28427,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB,74.8 -US-Slt,28427,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_SPATIAL_VARIABILITY,36.7 -US-Slt,28427,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_ORGAN,Wood -US-Slt,28427,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_PHEN,Mixed/unknown -US-Slt,28427,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_UNIT,gC m-2 -US-Slt,28427,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_APPROACH,"Ten to twenty 1 m2 plots, harvested annually at time of peak biomass. Samples separated into foliage and stems, dried at 60 C" -US-Slt,28427,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_DATE,2005 -US-Slt,28807,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB,78.9 -US-Slt,28807,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_SPATIAL_VARIABILITY,23.5 -US-Slt,28807,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_ORGAN,Total -US-Slt,28807,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_PHEN,Mixed/unknown -US-Slt,28807,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_UNIT,gC m-2 -US-Slt,28807,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_APPROACH,"Ten to twenty 1 m2 plots, harvested annually at time of peak biomass. Samples separated into foliage and stems, dried at 60 C" -US-Slt,28807,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_DATE,2007 -US-Slt,28934,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB,79.4 -US-Slt,28934,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_SPATIAL_VARIABILITY,25.7 -US-Slt,28934,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_ORGAN,Total -US-Slt,28934,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_PHEN,Mixed/unknown -US-Slt,28934,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_UNIT,gC m-2 -US-Slt,28934,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_APPROACH,"Ten to twenty 1 m2 plots, harvested annually at time of peak biomass. Samples separated into foliage and stems, dried at 60 C" -US-Slt,28934,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_DATE,2006 -US-Slt,29412,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB,88.8 -US-Slt,29412,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_SPATIAL_VARIABILITY,49.4 -US-Slt,29412,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_ORGAN,Total -US-Slt,29412,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_PHEN,Mixed/unknown -US-Slt,29412,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_UNIT,gC m-2 -US-Slt,29412,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_APPROACH,"Ten to twenty 1 m2 plots, harvested annually at time of peak biomass. Samples separated into foliage and stems, dried at 60 C" -US-Slt,29412,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_DATE,2004 -US-Slt,29304,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB,9.5 -US-Slt,29304,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_SPATIAL_VARIABILITY,3.5 -US-Slt,29304,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_ORGAN,Foliage -US-Slt,29304,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_PHEN,Mixed/unknown -US-Slt,29304,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_UNIT,gC m-2 -US-Slt,29304,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_APPROACH,"Ten to twenty 1 m2 plots, harvested annually at time of peak biomass. Samples separated into foliage and stems, dried at 60 C" -US-Slt,29304,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_DATE,2007 -US-Slt,29414,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB,91.0 -US-Slt,29414,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_SPATIAL_VARIABILITY,38.0 -US-Slt,29414,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_ORGAN,Total -US-Slt,29414,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_PHEN,Mixed/unknown -US-Slt,29414,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_UNIT,gC m-2 -US-Slt,29414,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_APPROACH,"Ten to twenty 1 m2 plots, harvested annually at time of peak biomass. Samples separated into foliage and stems, dried at 60 C" -US-Slt,29414,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_DATE,2005 -US-Slt,27179,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,217.2 -US-Slt,27179,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_SPATIAL_VARIABILITY,50.5 -US-Slt,27179,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Foliage -US-Slt,27179,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-Slt,27179,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-Slt,27179,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,"Five 201 m2 plots within 100 m of the flux tower, censused annually. Published allometric equations used to calculate foliage biomass. Litterfall collected monthly in ten 0.4 m2 traps within 100 m of the flux tower. 48 168 m2 plots in a 1 km2 grid, censused every 5 years. See Skowronski et al. 2007 for details." -US-Slt,27179,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2004 -US-Slt,27724,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,221.7 -US-Slt,27724,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_SPATIAL_VARIABILITY,50.2 -US-Slt,27724,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Foliage -US-Slt,27724,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-Slt,27724,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-Slt,27724,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,"Five 201 m2 plots within 100 m of the flux tower, censused annually. Published allometric equations used to calculate foliage biomass. Litterfall collected monthly in ten 0.4 m2 traps within 100 m of the flux tower. 48 168 m2 plots in a 1 km2 grid, censused every 5 years. See Skowronski et al. 2007 for details." -US-Slt,27724,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2005 -US-Slt,27482,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,224.8 -US-Slt,27482,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_SPATIAL_VARIABILITY,50.2 -US-Slt,27482,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Foliage -US-Slt,27482,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-Slt,27482,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-Slt,27482,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,"Five 201 m2 plots within 100 m of the flux tower, censused annually. Published allometric equations used to calculate foliage biomass. Litterfall collected monthly in ten 0.4 m2 traps within 100 m of the flux tower. 48 168 m2 plots in a 1 km2 grid, censused every 5 years. See Skowronski et al. 2007 for details." -US-Slt,27482,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2006 -US-Slt,28422,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,3788.6 -US-Slt,28422,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_SPATIAL_VARIABILITY,1176.3 -US-Slt,28422,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Wood -US-Slt,28422,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-Slt,28422,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-Slt,28422,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,"Five 201 m2 plots within 100 m of the flux tower, censused annually. Published allometric equations used to calculate aboveground biomass. 48 168 m2 plots in a 1 km2 grid, censused every 5 years. See Skowronski et al. 2007 for details." -US-Slt,28422,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2004 -US-Slt,28426,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,3887.7 -US-Slt,28426,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_SPATIAL_VARIABILITY,1180.3 -US-Slt,28426,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Wood -US-Slt,28426,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-Slt,28426,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-Slt,28426,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,"Five 201 m2 plots within 100 m of the flux tower, censused annually. Published allometric equations used to calculate aboveground biomass. 48 168 m2 plots in a 1 km2 grid, censused every 5 years. See Skowronski et al. 2007 for details." -US-Slt,28426,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2005 -US-Slt,27810,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,4002.1 -US-Slt,27810,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_SPATIAL_VARIABILITY,1168.3 -US-Slt,27810,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Wood -US-Slt,27810,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-Slt,27810,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-Slt,27810,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,"Five 201 m2 plots within 100 m of the flux tower, censused annually. Published allometric equations used to calculate aboveground biomass. 48 168 m2 plots in a 1 km2 grid, censused every 5 years. See Skowronski et al. 2007 for details." -US-Slt,27810,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2007 -US-Slt,29609,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,4005.8 -US-Slt,29609,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_SPATIAL_VARIABILITY,1227.3 -US-Slt,29609,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Total -US-Slt,29609,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-Slt,29609,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-Slt,29609,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,"Five 201 m2 plots within 100 m of the flux tower, censused annually. Published allometric equations used to calculate aboveground biomass. 48 168 m2 plots in a 1 km2 grid, censused every 5 years. See Skowronski et al. 2007 for details." -US-Slt,29609,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2004 -US-Slt,28806,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,4006.7 -US-Slt,28806,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_SPATIAL_VARIABILITY,1195.0 -US-Slt,28806,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Wood -US-Slt,28806,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-Slt,28806,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-Slt,28806,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,"Five 201 m2 plots within 100 m of the flux tower, censused annually. Published allometric equations used to calculate aboveground biomass. 48 168 m2 plots in a 1 km2 grid, censused every 5 years. See Skowronski et al. 2007 for details." -US-Slt,28806,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2006 -US-Slt,29413,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,4109.4 -US-Slt,29413,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_SPATIAL_VARIABILITY,1229.6 -US-Slt,29413,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Total -US-Slt,29413,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-Slt,29413,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-Slt,29413,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,"Five 201 m2 plots within 100 m of the flux tower, censused annually. Published allometric equations used to calculate aboveground biomass. 48 168 m2 plots in a 1 km2 grid, censused every 5 years. See Skowronski et al. 2007 for details." -US-Slt,29413,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2005 -US-Slt,29415,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,4231.5 -US-Slt,29415,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_SPATIAL_VARIABILITY,1244.4 -US-Slt,29415,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Total -US-Slt,29415,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-Slt,29415,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-Slt,29415,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,"Five 201 m2 plots within 100 m of the flux tower, censused annually. Published allometric equations used to calculate aboveground biomass. 48 168 m2 plots in a 1 km2 grid, censused every 5 years. See Skowronski et al. 2007 for details." -US-Slt,29415,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2006 -US-Slt,29610,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS,397.0 -US-Slt,29610,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_SPATIAL_VARIABILITY,62.8 -US-Slt,29610,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_UNIT,gC m-2 -US-Slt,29610,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_DATE,20040601 -US-Slt,29610,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_COMMENT,"10 1 m2 plots, L horizon only" -US-Slt,29298,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS,453.0 -US-Slt,29298,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_SPATIAL_VARIABILITY,92.0 -US-Slt,29298,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_UNIT,gC m-2 -US-Slt,29298,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_DATE,20080601 -US-Slt,29298,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_COMMENT,"24 1 m2 plots, L horizon only" -US-Slt,28768,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT,182.8 -US-Slt,29301,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT,207.2 -US-Slt,29612,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT,240.4 -US-Slt,29612,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT_SPATIAL_VARIABILITY,123.5 -US-Slt,28768,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT_SPATIAL_VARIABILITY,28.7 -US-Slt,29301,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT_SPATIAL_VARIABILITY,49.2 -US-Slt,28768,GRP_AG_LIT_PROD,AG_LIT_PROD_UNIT,gC m-2 -US-Slt,29301,GRP_AG_LIT_PROD,AG_LIT_PROD_UNIT,gC m-2 -US-Slt,29612,GRP_AG_LIT_PROD,AG_LIT_PROD_UNIT,gC m-2 -US-Slt,29612,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_START,2004 -US-Slt,29301,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_START,2005 -US-Slt,28768,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_START,2006 -US-Slt,28768,GRP_AG_LIT_PROD,AG_LIT_PROD_COMMENT,140.4 +- 12.3 Foliar; 29.7 +- 20.3 Wood -US-Slt,29612,GRP_AG_LIT_PROD,AG_LIT_PROD_COMMENT,158.8 +- 26.1 Foliar; 68.4 +- 135.9 Wood -US-Slt,29301,GRP_AG_LIT_PROD,AG_LIT_PROD_COMMENT,159.4 +- 17.8 Foliar; 40.3 +- 44.4 Wood -US-Slt,28767,GRP_AG_PROD_OTHER,AG_PROD_OTHER,0.0 -US-Slt,28767,GRP_AG_PROD_OTHER,AG_PROD_OTHER_SPATIAL_VARIABILITY,0.0 -US-Slt,28767,GRP_AG_PROD_OTHER,AG_PROD_OTHER_ORGAN,Total -US-Slt,28767,GRP_AG_PROD_OTHER,AG_PROD_OTHER_UNIT,gC m-2 -US-Slt,28767,GRP_AG_PROD_OTHER,AG_PROD_APPROACH,"Ten to twenty 1 m2 plots, harvested annually at time of peak biomass. Samples separated into foliage and stems, dried at 60 C" -US-Slt,28767,GRP_AG_PROD_OTHER,AG_PROD_DATE_START,2004 -US-Slt,28767,GRP_AG_PROD_OTHER,AG_PROD_COMMENT,"Five 201 m2 plots for trees, ten to twenty 1 m2 plots for clip plots for shrubs and herbs" -US-Slt,28933,GRP_AG_PROD_OTHER,AG_PROD_OTHER,0.0 -US-Slt,28933,GRP_AG_PROD_OTHER,AG_PROD_OTHER_SPATIAL_VARIABILITY,0.1 -US-Slt,28933,GRP_AG_PROD_OTHER,AG_PROD_OTHER_ORGAN,Total -US-Slt,28933,GRP_AG_PROD_OTHER,AG_PROD_OTHER_UNIT,gC m-2 -US-Slt,28933,GRP_AG_PROD_OTHER,AG_PROD_APPROACH,"Ten to twenty 1 m2 plots, harvested annually at time of peak biomass. Samples separated into foliage and stems, dried at 60 C" -US-Slt,28933,GRP_AG_PROD_OTHER,AG_PROD_DATE_START,2007 -US-Slt,28933,GRP_AG_PROD_OTHER,AG_PROD_COMMENT,"Five 201 m2 plots for trees, ten to twenty 1 m2 plots for clip plots for shrubs and herbs" -US-Slt,29614,GRP_AG_PROD_OTHER,AG_PROD_OTHER,0.2 -US-Slt,29614,GRP_AG_PROD_OTHER,AG_PROD_OTHER_SPATIAL_VARIABILITY,0.3 -US-Slt,29614,GRP_AG_PROD_OTHER,AG_PROD_OTHER_ORGAN,Total -US-Slt,29614,GRP_AG_PROD_OTHER,AG_PROD_OTHER_UNIT,gC m-2 -US-Slt,29614,GRP_AG_PROD_OTHER,AG_PROD_APPROACH,"Ten to twenty 1 m2 plots, harvested annually at time of peak biomass. Samples separated into foliage and stems, dried at 60 C" -US-Slt,29614,GRP_AG_PROD_OTHER,AG_PROD_DATE_START,2006 -US-Slt,29614,GRP_AG_PROD_OTHER,AG_PROD_COMMENT,"Five 201 m2 plots for trees, ten to twenty 1 m2 plots for clip plots for shrubs and herbs" -US-Slt,28079,GRP_AG_PROD_OTHER,AG_PROD_OTHER,0.4 -US-Slt,28079,GRP_AG_PROD_OTHER,AG_PROD_OTHER_SPATIAL_VARIABILITY,0.7 -US-Slt,28079,GRP_AG_PROD_OTHER,AG_PROD_OTHER_ORGAN,Total -US-Slt,28079,GRP_AG_PROD_OTHER,AG_PROD_OTHER_UNIT,gC m-2 -US-Slt,28079,GRP_AG_PROD_OTHER,AG_PROD_APPROACH,"Ten to twenty 1 m2 plots, harvested annually at time of peak biomass. Samples separated into foliage and stems, dried at 60 C" -US-Slt,28079,GRP_AG_PROD_OTHER,AG_PROD_DATE_START,2005 -US-Slt,28079,GRP_AG_PROD_OTHER,AG_PROD_COMMENT,"Five 201 m2 plots for trees, ten to twenty 1 m2 plots for clip plots for shrubs and herbs" -US-Slt,29613,GRP_AG_PROD_SHRUB,AG_PROD_SHRUB,-5.1 -US-Slt,29613,GRP_AG_PROD_SHRUB,AG_PROD_SHRUB_SPATIAL_VARIABILITY,8.0 -US-Slt,29613,GRP_AG_PROD_SHRUB,AG_PROD_SHRUB_ORGAN,Wood -US-Slt,29613,GRP_AG_PROD_SHRUB,AG_PROD_SHRUB_UNIT,gC m-2 -US-Slt,29613,GRP_AG_PROD_SHRUB,AG_PROD_APPROACH,"Ten to twenty 1 m2 plots, harvested annually at time of peak biomass. Samples separated into foliage and stems, dried at 60 C" -US-Slt,29613,GRP_AG_PROD_SHRUB,AG_PROD_DATE_START,2006 -US-Slt,29613,GRP_AG_PROD_SHRUB,AG_PROD_COMMENT,"Five 201 m2 plots for trees, ten to twenty 1 m2 plots for clip plots for shrubs and herbs" -US-Slt,27177,GRP_AG_PROD_SHRUB,AG_PROD_SHRUB,14.5 -US-Slt,27177,GRP_AG_PROD_SHRUB,AG_PROD_SHRUB_SPATIAL_VARIABILITY,3.7 -US-Slt,27177,GRP_AG_PROD_SHRUB,AG_PROD_SHRUB_ORGAN,Foliage -US-Slt,27177,GRP_AG_PROD_SHRUB,AG_PROD_SHRUB_UNIT,gC m-2 -US-Slt,27177,GRP_AG_PROD_SHRUB,AG_PROD_APPROACH,"Ten to twenty 1 m2 plots, harvested annually at time of peak biomass. Samples separated into foliage and stems, dried at 60 C" -US-Slt,27177,GRP_AG_PROD_SHRUB,AG_PROD_DATE_START,2006 -US-Slt,27177,GRP_AG_PROD_SHRUB,AG_PROD_COMMENT,"Five 201 m2 plots for trees, ten to twenty 1 m2 plots for clip plots for shrubs and herbs" -US-Slt,29300,GRP_AG_PROD_SHRUB,AG_PROD_SHRUB,16.2 -US-Slt,29300,GRP_AG_PROD_SHRUB,AG_PROD_SHRUB_SPATIAL_VARIABILITY,3.6 -US-Slt,29300,GRP_AG_PROD_SHRUB,AG_PROD_SHRUB_ORGAN,Foliage -US-Slt,29300,GRP_AG_PROD_SHRUB,AG_PROD_SHRUB_UNIT,gC m-2 -US-Slt,29300,GRP_AG_PROD_SHRUB,AG_PROD_APPROACH,"Ten to twenty 1 m2 plots, harvested annually at time of peak biomass. Samples separated into foliage and stems, dried at 60 C" -US-Slt,29300,GRP_AG_PROD_SHRUB,AG_PROD_DATE_START,2005 -US-Slt,29300,GRP_AG_PROD_SHRUB,AG_PROD_COMMENT,"Five 201 m2 plots for trees, ten to twenty 1 m2 plots for clip plots for shrubs and herbs" -US-Slt,27475,GRP_AG_PROD_SHRUB,AG_PROD_SHRUB,18.1 -US-Slt,27475,GRP_AG_PROD_SHRUB,AG_PROD_SHRUB_SPATIAL_VARIABILITY,15.1 -US-Slt,27475,GRP_AG_PROD_SHRUB,AG_PROD_SHRUB_ORGAN,Foliage -US-Slt,27475,GRP_AG_PROD_SHRUB,AG_PROD_SHRUB_UNIT,gC m-2 -US-Slt,27475,GRP_AG_PROD_SHRUB,AG_PROD_APPROACH,"Ten to twenty 1 m2 plots, harvested annually at time of peak biomass. Samples separated into foliage and stems, dried at 60 C" -US-Slt,27475,GRP_AG_PROD_SHRUB,AG_PROD_DATE_START,2004 -US-Slt,27475,GRP_AG_PROD_SHRUB,AG_PROD_COMMENT,"Five 201 m2 plots for trees, ten to twenty 1 m2 plots for clip plots for shrubs and herbs" -US-Slt,28769,GRP_AG_PROD_SHRUB,AG_PROD_SHRUB,4.1 -US-Slt,28769,GRP_AG_PROD_SHRUB,AG_PROD_SHRUB_SPATIAL_VARIABILITY,17.2 -US-Slt,28769,GRP_AG_PROD_SHRUB,AG_PROD_SHRUB_ORGAN,Wood -US-Slt,28769,GRP_AG_PROD_SHRUB,AG_PROD_SHRUB_UNIT,gC m-2 -US-Slt,28769,GRP_AG_PROD_SHRUB,AG_PROD_APPROACH,"Ten to twenty 1 m2 plots, harvested annually at time of peak biomass. Samples separated into foliage and stems, dried at 60 C" -US-Slt,28769,GRP_AG_PROD_SHRUB,AG_PROD_DATE_START,2005 -US-Slt,28769,GRP_AG_PROD_SHRUB,AG_PROD_COMMENT,"Five 201 m2 plots for trees, ten to twenty 1 m2 plots for clip plots for shrubs and herbs" -US-Slt,28080,GRP_AG_PROD_SHRUB,AG_PROD_SHRUB,4.6 -US-Slt,28080,GRP_AG_PROD_SHRUB,AG_PROD_SHRUB_SPATIAL_VARIABILITY,7.1 -US-Slt,28080,GRP_AG_PROD_SHRUB,AG_PROD_SHRUB_ORGAN,Wood -US-Slt,28080,GRP_AG_PROD_SHRUB,AG_PROD_SHRUB_UNIT,gC m-2 -US-Slt,28080,GRP_AG_PROD_SHRUB,AG_PROD_APPROACH,"Ten to twenty 1 m2 plots, harvested annually at time of peak biomass. Samples separated into foliage and stems, dried at 60 C" -US-Slt,28080,GRP_AG_PROD_SHRUB,AG_PROD_DATE_START,2007 -US-Slt,28080,GRP_AG_PROD_SHRUB,AG_PROD_COMMENT,"Five 201 m2 plots for trees, ten to twenty 1 m2 plots for clip plots for shrubs and herbs" -US-Slt,27476,GRP_AG_PROD_SHRUB,AG_PROD_SHRUB,9.5 -US-Slt,27476,GRP_AG_PROD_SHRUB,AG_PROD_SHRUB_SPATIAL_VARIABILITY,3.5 -US-Slt,27476,GRP_AG_PROD_SHRUB,AG_PROD_SHRUB_ORGAN,Foliage -US-Slt,27476,GRP_AG_PROD_SHRUB,AG_PROD_SHRUB_UNIT,gC m-2 -US-Slt,27476,GRP_AG_PROD_SHRUB,AG_PROD_APPROACH,"Ten to twenty 1 m2 plots, harvested annually at time of peak biomass. Samples separated into foliage and stems, dried at 60 C" -US-Slt,27476,GRP_AG_PROD_SHRUB,AG_PROD_DATE_START,2007 -US-Slt,27476,GRP_AG_PROD_SHRUB,AG_PROD_COMMENT,"Five 201 m2 plots for trees, ten to twenty 1 m2 plots for clip plots for shrubs and herbs" -US-Slt,27722,GRP_AG_PROD_TREE,AG_PROD_TREE,-4.5 -US-Slt,27722,GRP_AG_PROD_TREE,AG_PROD_TREE_SPATIAL_VARIABILITY,47.5 -US-Slt,27722,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Wood -US-Slt,27722,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-Slt,27722,GRP_AG_PROD_TREE,AG_PROD_APPROACH,"Five 201 m2 plots within 100 m of the flux tower, censused annually. Published allometric equations used to calculate foliage biomass. Litterfall collected monthly in ten 0.4 m2 traps within 100 m of the flux tower." -US-Slt,27722,GRP_AG_PROD_TREE,AG_PROD_DATE_START,2007 -US-Slt,27722,GRP_AG_PROD_TREE,AG_PROD_COMMENT,"Five 201 m2 plots for trees, ten to twenty 1 m2 plots for clip plots for shrubs and herbs" -US-Slt,28932,GRP_AG_PROD_TREE,AG_PROD_TREE,119.0 -US-Slt,28932,GRP_AG_PROD_TREE,AG_PROD_TREE_SPATIAL_VARIABILITY,77.7 -US-Slt,28932,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Wood -US-Slt,28932,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-Slt,28932,GRP_AG_PROD_TREE,AG_PROD_APPROACH,"Five 201 m2 plots within 100 m of the flux tower, censused annually. Published allometric equations used to calculate foliage biomass. Litterfall collected monthly in ten 0.4 m2 traps within 100 m of the flux tower." -US-Slt,28932,GRP_AG_PROD_TREE,AG_PROD_DATE_START,2006 -US-Slt,28932,GRP_AG_PROD_TREE,AG_PROD_COMMENT,"Five 201 m2 plots for trees, ten to twenty 1 m2 plots for clip plots for shrubs and herbs" -US-Slt,27806,GRP_AG_PROD_TREE,AG_PROD_TREE,214.2 -US-Slt,27806,GRP_AG_PROD_TREE,AG_PROD_TREE_SPATIAL_VARIABILITY,50.4 -US-Slt,27806,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Foliage -US-Slt,27806,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-Slt,27806,GRP_AG_PROD_TREE,AG_PROD_APPROACH,"Five 201 m2 plots within 100 m of the flux tower, censused annually. Published allometric equations used to calculate foliage biomass. Litterfall collected monthly in ten 0.4 m2 traps within 100 m of the flux tower." -US-Slt,27806,GRP_AG_PROD_TREE,AG_PROD_DATE_START,2004 -US-Slt,27806,GRP_AG_PROD_TREE,AG_PROD_COMMENT,"Five 201 m2 plots for trees, ten to twenty 1 m2 plots for clip plots for shrubs and herbs" -US-Slt,28797,GRP_AG_PROD_TREE,AG_PROD_TREE,217.2 -US-Slt,28797,GRP_AG_PROD_TREE,AG_PROD_TREE_SPATIAL_VARIABILITY,50.5 -US-Slt,28797,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Foliage -US-Slt,28797,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-Slt,28797,GRP_AG_PROD_TREE,AG_PROD_APPROACH,"Five 201 m2 plots within 100 m of the flux tower, censused annually. Published allometric equations used to calculate foliage biomass. Litterfall collected monthly in ten 0.4 m2 traps within 100 m of the flux tower." -US-Slt,28797,GRP_AG_PROD_TREE,AG_PROD_DATE_START,2005 -US-Slt,28797,GRP_AG_PROD_TREE,AG_PROD_COMMENT,"Five 201 m2 plots for trees, ten to twenty 1 m2 plots for clip plots for shrubs and herbs" -US-Slt,28931,GRP_AG_PROD_TREE,AG_PROD_TREE,221.4 -US-Slt,28931,GRP_AG_PROD_TREE,AG_PROD_TREE_SPATIAL_VARIABILITY,50.2 -US-Slt,28931,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Foliage -US-Slt,28931,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-Slt,28931,GRP_AG_PROD_TREE,AG_PROD_APPROACH,"Five 201 m2 plots within 100 m of the flux tower, censused annually. Published allometric equations used to calculate foliage biomass. Litterfall collected monthly in ten 0.4 m2 traps within 100 m of the flux tower." -US-Slt,28931,GRP_AG_PROD_TREE,AG_PROD_DATE_START,2006 -US-Slt,28931,GRP_AG_PROD_TREE,AG_PROD_COMMENT,"Five 201 m2 plots for trees, ten to twenty 1 m2 plots for clip plots for shrubs and herbs" -US-Slt,29611,GRP_AG_PROD_TREE,AG_PROD_TREE,281.1 -US-Slt,29611,GRP_AG_PROD_TREE,AG_PROD_TREE_SPATIAL_VARIABILITY,69.4 -US-Slt,29611,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Total -US-Slt,29611,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-Slt,29611,GRP_AG_PROD_TREE,AG_PROD_APPROACH,"Five 201 m2 plots within 100 m of the flux tower, censused annually. Published allometric equations used to calculate foliage biomass. Litterfall collected monthly in ten 0.4 m2 traps within 100 m of the flux tower." -US-Slt,29611,GRP_AG_PROD_TREE,AG_PROD_DATE_START,2004 -US-Slt,29611,GRP_AG_PROD_TREE,AG_PROD_COMMENT,"Five 201 m2 plots for trees, ten to twenty 1 m2 plots for clip plots for shrubs and herbs" -US-Slt,28799,GRP_AG_PROD_TREE,AG_PROD_TREE,308.5 -US-Slt,28799,GRP_AG_PROD_TREE,AG_PROD_TREE_SPATIAL_VARIABILITY,51.8 -US-Slt,28799,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Total -US-Slt,28799,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-Slt,28799,GRP_AG_PROD_TREE,AG_PROD_APPROACH,"Five 201 m2 plots within 100 m of the flux tower, censused annually. Published allometric equations used to calculate foliage biomass. Litterfall collected monthly in ten 0.4 m2 traps within 100 m of the flux tower." -US-Slt,28799,GRP_AG_PROD_TREE,AG_PROD_DATE_START,2005 -US-Slt,28799,GRP_AG_PROD_TREE,AG_PROD_COMMENT,"Five 201 m2 plots for trees, ten to twenty 1 m2 plots for clip plots for shrubs and herbs" -US-Slt,27807,GRP_AG_PROD_TREE,AG_PROD_TREE,340.7 -US-Slt,27807,GRP_AG_PROD_TREE,AG_PROD_TREE_SPATIAL_VARIABILITY,93.2 -US-Slt,27807,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Total -US-Slt,27807,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-Slt,27807,GRP_AG_PROD_TREE,AG_PROD_APPROACH,"Five 201 m2 plots within 100 m of the flux tower, censused annually. Published allometric equations used to calculate foliage biomass. Litterfall collected monthly in ten 0.4 m2 traps within 100 m of the flux tower." -US-Slt,27807,GRP_AG_PROD_TREE,AG_PROD_DATE_START,2006 -US-Slt,27807,GRP_AG_PROD_TREE,AG_PROD_COMMENT,"Five 201 m2 plots for trees, ten to twenty 1 m2 plots for clip plots for shrubs and herbs" -US-Slt,27176,GRP_AG_PROD_TREE,AG_PROD_TREE,66.8 -US-Slt,27176,GRP_AG_PROD_TREE,AG_PROD_TREE_SPATIAL_VARIABILITY,40.7 -US-Slt,27176,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Wood -US-Slt,27176,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-Slt,27176,GRP_AG_PROD_TREE,AG_PROD_APPROACH,"Five 201 m2 plots within 100 m of the flux tower, censused annually. Published allometric equations used to calculate foliage biomass. Litterfall collected monthly in ten 0.4 m2 traps within 100 m of the flux tower." -US-Slt,27176,GRP_AG_PROD_TREE,AG_PROD_DATE_START,2004 -US-Slt,27176,GRP_AG_PROD_TREE,AG_PROD_COMMENT,"Five 201 m2 plots for trees, ten to twenty 1 m2 plots for clip plots for shrubs and herbs" -US-Slt,28798,GRP_AG_PROD_TREE,AG_PROD_TREE,90.9 -US-Slt,28798,GRP_AG_PROD_TREE,AG_PROD_TREE_SPATIAL_VARIABILITY,13.9 -US-Slt,28798,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Wood -US-Slt,28798,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-Slt,28798,GRP_AG_PROD_TREE,AG_PROD_APPROACH,"Five 201 m2 plots within 100 m of the flux tower, censused annually. Published allometric equations used to calculate foliage biomass. Litterfall collected monthly in ten 0.4 m2 traps within 100 m of the flux tower." -US-Slt,28798,GRP_AG_PROD_TREE,AG_PROD_DATE_START,2005 -US-Slt,28798,GRP_AG_PROD_TREE,AG_PROD_COMMENT,"Five 201 m2 plots for trees, ten to twenty 1 m2 plots for clip plots for shrubs and herbs" -US-Slt,28081,GRP_BIOMASS_CHEM,BIOMASS_N,0.186 -US-Slt,27477,GRP_BIOMASS_CHEM,BIOMASS_N,0.196 -US-Slt,28800,GRP_BIOMASS_CHEM,BIOMASS_N,0.215 -US-Slt,28800,GRP_BIOMASS_CHEM,BIOMASS_N_SPATIAL_VARIABILITY,0.016 -US-Slt,27477,GRP_BIOMASS_CHEM,BIOMASS_N_SPATIAL_VARIABILITY,0.018 -US-Slt,28081,GRP_BIOMASS_CHEM,BIOMASS_N_SPATIAL_VARIABILITY,0.025 -US-Slt,27477,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-Slt,28081,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-Slt,28800,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-Slt,27477,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-Slt,28081,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-Slt,28800,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-Slt,28081,GRP_BIOMASS_CHEM,BIOMASS_SPP,QUCO (NRCS plant code) -US-Slt,27477,GRP_BIOMASS_CHEM,BIOMASS_SPP,QUPR (NRCS plant code) -US-Slt,28800,GRP_BIOMASS_CHEM,BIOMASS_SPP,QUVE (NRCS plant code) -US-Slt,27477,GRP_BIOMASS_CHEM,BIOMASS_DATE,20060715 -US-Slt,28081,GRP_BIOMASS_CHEM,BIOMASS_DATE,20060715 -US-Slt,28800,GRP_BIOMASS_CHEM,BIOMASS_DATE,20060715 -US-Slt,27477,GRP_BIOMASS_CHEM,BIOMASS_COMMENT,Ash-free dry weight basis -US-Slt,28081,GRP_BIOMASS_CHEM,BIOMASS_COMMENT,Ash-free dry weight basis -US-Slt,28800,GRP_BIOMASS_CHEM,BIOMASS_COMMENT,Ash-free dry weight basis -US-Slt,13030,GRP_CLIM_AVG,MAT,11.04 -US-Slt,13030,GRP_CLIM_AVG,MAP,1138 -US-Slt,13030,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfa -US-Slt,27000426,GRP_COUNTRY,COUNTRY,USA -US-Slt,7225,GRP_DM_FIRE,DM_FIRE,Prescribed human induced underburn -US-Slt,7225,GRP_DM_FIRE,DM_DATE,2001 -US-Slt,7225,GRP_DM_FIRE,DM_COMMENT,Prescribed fire conducted by NJ Forest Fire Service -US-Slt,8116,GRP_DM_INS_PATH,DM_INS_PATH,Insect -US-Slt,8116,GRP_DM_INS_PATH,DM_DATE,2007 -US-Slt,8116,GRP_DM_INS_PATH,DM_COMMENT,Site completely defoliated by Gypsy moth -US-Slt,15662,GRP_DOI,DOI,10.17190/AMF/1246096 -US-Slt,15662,GRP_DOI,DOI_CITATION,"Ken Clark (2016), AmeriFlux BASE US-Slt Silas Little- New Jersey, Ver. 5-1, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1246096" -US-Slt,15662,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-Slt,32182,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Slt,32182,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Ken Clark -US-Slt,32182,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Slt,32182,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,kennethclark@fs.fed.us -US-Slt,32182,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,USDA Forest Service -US-Slt,32184,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,USDA Forest Service -US-Slt,32184,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-Slt,32183,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,USDA/Forest Service -US-Slt,32183,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-Slt,13048,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Fire -US-Slt,13031,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Pests and disease -US-Slt,13032,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Slt,13032,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-Slt,13032,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20040430 -US-Slt,13032,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Slt,13032,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,"Closed path system using a LI-7000 with a short inlet tube, resulting in a lag time of approx. 2.5 seconds." -US-Slt,13049,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Slt,13049,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-Slt,13049,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20040430 -US-Slt,13049,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Slt,13051,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Slt,13051,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-Slt,13051,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20040430 -US-Slt,13051,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Slt,23000426,GRP_HEADER,SITE_NAME,Silas Little- New Jersey -US-Slt,28775,GRP_HEIGHTC,HEIGHTC,9.52 -US-Slt,28775,GRP_HEIGHTC,HEIGHTC_DATE,2005 -US-Slt,28775,GRP_HEIGHTC,HEIGHTC_COMMENT,See Skowronski et al. 2007 for LIDAR data for this site -US-Slt,28775,GRP_HEIGHTC,HEIGHTC_SPATIAL_VARIABILITY,2.28 -US-Slt,13033,GRP_IGBP,IGBP,DBF -US-Slt,13033,GRP_IGBP,IGBP_DATE_START,20031001 -US-Slt,13033,GRP_IGBP,IGBP_COMMENT,"The oak-dominated stand at Silas Little consists of chestnut oak (Quercus prinus L.), black oak (Q. velutina Lam.), white oak (Q. alba L.), scarlet oak (Q. coccinea Münchh.), and scattered -pitch pine (Pinus rigida Mill.) and shortleaf pine (P. echinata Mill.). Ericaceous shrubs occur in the -understory in all stands, primarily huckleberry (Gaylussacia baccata (Wangenh.) K. Koch) and blueberry (Vaccinium spp.). Sedges, mosses and lichens also occur in the understory." -US-Slt,27481,GRP_LAI,LAI_TYPE,LAI -US-Slt,28804,GRP_LAI,LAI_TYPE,LAI -US-Slt,28805,GRP_LAI,LAI_TYPE,LAI -US-Slt,27481,GRP_LAI,LAI_METHOD,Litterfall -US-Slt,28804,GRP_LAI,LAI_METHOD,Litterfall -US-Slt,28805,GRP_LAI,LAI_METHOD,Litterfall -US-Slt,27481,GRP_LAI,LAI_DATE,20050701 -US-Slt,28804,GRP_LAI,LAI_DATE,20060701 -US-Slt,28805,GRP_LAI,LAI_DATE,20070701 -US-Slt,27481,GRP_LAI,LAI_COMMENT,Litterfall and specific leaf area measurements; 2007 and 2008 reduced due to Gypsy moth defoliation -US-Slt,28804,GRP_LAI,LAI_COMMENT,Litterfall and specific leaf area measurements; 2007 and 2008 reduced due to Gypsy moth defoliation -US-Slt,28805,GRP_LAI,LAI_COMMENT,Litterfall and specific leaf area measurements; 2007 and 2008 reduced due to Gypsy moth defoliation -US-Slt,28805,GRP_LAI,LAI_TOT,2.12 -US-Slt,28804,GRP_LAI,LAI_TOT,4.10 -US-Slt,27481,GRP_LAI,LAI_TOT,4.77 -US-Slt,28805,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.25 -US-Slt,28804,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.34 -US-Slt,27481,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.49 -US-Slt,13034,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-Slt,13034,GRP_LAND_OWNERSHIP,LAND_OWNER,"Brendan Byrne State Forest, leased to USFS" -US-Slt,13035,GRP_LOCATION,LOCATION_LAT,39.9138 -US-Slt,13035,GRP_LOCATION,LOCATION_LONG,-74.5960 -US-Slt,13035,GRP_LOCATION,LOCATION_ELEV,30 -US-Slt,13035,GRP_LOCATION,LOCATION_DATE_START,20031001 -US-Slt,13035,GRP_LOCATION,LOCATION_COMMENT,"Annual tree census data, annual clip plots for understory vegetation, approx. monthly litterfall collection, forest floor sampling in 2003, 2006, 2008, 2012, 2013. Extensive soil sampling was conducted in 2008 and 2011-12." -US-Slt,13036,GRP_NETWORK,NETWORK,AmeriFlux -US-Slt,87004,GRP_NETWORK,NETWORK,Phenocam -US-Slt,1700004173,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Baldocchi, D. D., Poindexter, C., Abraha, M., Desai, A. R., Bohrer, G., Arain, M. A., Griffis, T., Blanken, P. D., O'Halloran, T. L., Thomas, R. Q., Zhang, Q., Burns, S. P., Frank, J. M., Christian, D., Brown, S., Black, T. A., Gough, C. M., Law, B. E., Lee, X., Chen, J., Reed, D. E., Massman, W. J., Clark, K., Hatfield, J., Prueger, J., Bracho, R., Baker, J. M., Martin, T. A. (2018) Temporal Dynamics Of Aerodynamic Canopy Height Derived From Eddy Covariance Momentum Flux Data Across North American Flux Networks, Geophysical Research Letters, 45(3), 9275–9287" -US-Slt,1700004173,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018GL079306 -US-Slt,1700004173,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Slt,1700007746,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(3), 108350" -US-Slt,1700007746,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -US-Slt,1700007746,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Slt,1700005334,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Clark, K. L., Heilman, W. E., Skowronski, N. S., Gallagher, M. R., Mueller, E., Hadden, R. M., Simeoni, A. (2020) Fire Behavior, Fuel Consumption, And Turbulence And Energy Exchange During Prescribed Fires In Pitch Pine Forests, Atmosphere, 11(3), 25" -US-Slt,1700005334,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.3390/ATMOS11030242 -US-Slt,1700005334,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Slt,1700007677,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Clark, K. L., Skowronski, N. S., Gallagher, M. R., Renninger, H., Schäfer, K. V. R. (2014) Contrasting Effects Of Invasive Insects And Fire On Ecosystem Water Use Efficiency, Biogeosciences, 11(23), 6509-6523" -US-Slt,1700007677,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.5194/BG-11-6509-2014 -US-Slt,1700007677,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Slt,1700004935,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Clark, K. L., Skowronski, N., Gallagher, M., Renninger, H., Schäfer, K. (2012) Effects Of Invasive Insects And Fire On Forest Energy Exchange And Evapotranspiration In The New Jersey Pinelands, Agricultural And Forest Meteorology, 166-167(1), 50-61" -US-Slt,1700004935,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2012.07.007 -US-Slt,1700004935,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Slt,1700001365,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Clark, K. L., Skowronski, N., Hom, J. (2010) Invasive Insects Impact Forest Carbon Dynamics, Global Change Biology, 16(1), 88-101" -US-Slt,1700001365,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/J.1365-2486.2009.01983.X -US-Slt,1700001365,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Slt,1700002622,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Clark, K., Renninger, H., Skowronski, N., Gallagher, M., Schäfer, K. (2018) Decadal-Scale Reduction In Forest Net Ecosystem Production Following Insect Defoliation Contrasts With Short-Term Impacts Of Prescribed Fires, Forests, 9(3), 145" -US-Slt,1700002622,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.3390/F9030145 -US-Slt,1700002622,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Slt,1700004080,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Guerrieri, R., Belmecheri, S., Ollinger, S. V., Asbjornsen, H., Jennings, K., Xiao, J., Stocker, B. D., Martin, M., Hollinger, D. Y., Bracho-Garrillo, R., Clark, K., Dore, S., Kolb, T., Munger, J. W., Novick, K., Richardson, A. D. (2019) Disentangling The Role Of Photosynthesis And Stomatal Conductance On Rising Forest Water-Use Efficiency, Proceedings Of The National Academy Of Sciences, 116(34), 16909-16914" -US-Slt,1700004080,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1073/PNAS.1905912116 -US-Slt,1700004080,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Slt,1700003924,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Hannun, R. A., Wolfe, G. M., Kawa, S. R., Hanisco, T. F., Newman, P. A., Alfieri, J. G., Barrick, J., Clark, K. L., DiGangi, J. P., Diskin, G. S., King, J., Kustas, W. P., Mitra, B., Noormets, A., Nowak, J. B., Thornhill, K. L., Vargas, R. (2020) Spatial Heterogeneity In Co2, Ch4, And Energy Fluxes: Insights From Airborne Eddy Covariance Measurements Over The Mid-Atlantic Region, Environmental Research Letters, 15(3), 035008" -US-Slt,1700003924,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1088/1748-9326/AB7391 -US-Slt,1700003924,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Slt,1700001284,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Renninger, H. J., Carlo, N., Clark, K. L., Schäfer, K. V. (2014) Modeling Respiration From Snags And Coarse Woody Debris Before And After An Invasive Gypsy Moth Disturbance, Journal Of Geophysical Research: Biogeosciences, 119(4), 630-644" -US-Slt,1700001284,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/2013JG002542 -US-Slt,1700001284,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Slt,1700000693,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Skowronski, N. S., Clark, K. L., Gallagher, M., Birdsey, R. A., Hom, J. L. (2014) Airborne Laser Scanner-Assisted Estimation Of Aboveground Biomass Change In A Temperate Oak–Pine Forest, Remote Sensing Of Environment, 151(), 166-174" -US-Slt,1700000693,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.RSE.2013.12.015 -US-Slt,1700000693,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Slt,1700003111,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"SKOWRONSKI, N., CLARK, K., NELSON, R., HOM, J., PATTERSON, M. (2007) Remotely Sensed Measurements Of Forest Structure And Fuel Loads In The Pinelands Of New Jersey, Remote Sensing Of Environment, 108(2), 123-129" -US-Slt,1700003111,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.RSE.2006.09.032 -US-Slt,1700003111,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Slt,1700004752,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Wolf, S., Keenan, T.F., Fisher, J.B., Baldocchi, D.D., Desai, A.R., Richardson, A.D., Scott, R.L., Law, B.E., Litvak, M.E., Brunsell, N.A., Peters, W., van der Laan-Luijkx, I.T. (2016) Warm spring reduced carbon cycle impact of the 2012 US summer drought, Proceedings of the National Academy of Sciences, 113(21), 5880-5885" -US-Slt,1700004752,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1073/PNAS.1519620113 -US-Slt,1700004752,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Slt,1700005676,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Zscheischler, J., Fatichi, S., Wolf, S., Blanken, P., Bohrer, G., Clark, K., Desai, A., Hollinger, D., Keenan, T., Novick, K.A., Seneviratne, S.I. (2016) Short-term favorable weather conditions are an important control of interannual variability in carbon and water fluxes, Journal of Geophysical Research - Biogeosciences, 121(8), 2186-2198" -US-Slt,1700005676,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/2016JG003503 -US-Slt,1700005676,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Slt,13038,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"1) Impact of fire management activities on stand carbon dynamics, 2) Flux measurements and smoke emissions during prescribed burns, 3) Comparision of biometric, remotely sensed (LiDAR), and flux-based measurements of stand carbon dynamics." -US-Slt,27721,GRP_ROOT_BIOMASS,ROOT_BIOMASS_CRS,4.5 -US-Slt,27721,GRP_ROOT_BIOMASS,ROOT_BIOMASS_CRS_SPATIAL_VARIABILITY,7.8 -US-Slt,29299,GRP_ROOT_BIOMASS,ROOT_BIOMASS_FINE,48.2 -US-Slt,29299,GRP_ROOT_BIOMASS,ROOT_BIOMASS_FINE_SPATIAL_VARIABILITY,30.8 -US-Slt,29299,GRP_ROOT_BIOMASS,ROOT_BIOMASS_TOT,52.7 -US-Slt,27721,GRP_ROOT_BIOMASS,ROOT_BIOMASS_UNIT,gC m-2 -US-Slt,29299,GRP_ROOT_BIOMASS,ROOT_BIOMASS_UNIT,gC m-2 -US-Slt,27721,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MIN,0 -US-Slt,29299,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MIN,0 -US-Slt,29299,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MAX,10 -US-Slt,27721,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MAX,2 -US-Slt,27721,GRP_ROOT_BIOMASS,ROOT_BIOMASS_DATE,20080601 -US-Slt,29299,GRP_ROOT_BIOMASS,ROOT_BIOMASS_DATE,20080601 -US-Slt,27721,GRP_ROOT_BIOMASS,ROOT_BIOMASS_COMMENT,0-2 mm and 2-100 mm in O horizon only. -US-Slt,29299,GRP_ROOT_BIOMASS,ROOT_BIOMASS_COMMENT,0-2 mm and 2-100 mm in O horizon only. -US-Slt,29305,GRP_SA,SA_DATE,2004 -US-Slt,29305,GRP_SA,SA_COMMENT,"ca. 10% of trees, largest in plots" -US-Slt,29305,GRP_SA,SA_MAX,90 -US-Slt,13039,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"501 Four Mile Road, New Lisbon, NJ USA 08064" -US-Slt,13040,GRP_SITE_CHAR,TERRAIN,Flat -US-Slt,13040,GRP_SITE_CHAR,ASPECT,FLAT -US-Slt,13040,GRP_SITE_CHAR,WIND_DIRECTION,WNW -US-Slt,13040,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,1260 -US-Slt,13040,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,20 -US-Slt,13041,GRP_SITE_DESC,SITE_DESC,"Wildfires, prescribed fires, insect defoliation events and windstorms are the common disturbances in the NJ Pinelands. The oak-dominated forest at Silas Little Experimental Forest was most recently defoliated by Gypsy moth (Lymantria dispar L.) in 2006 to 2008, with complete defoliation occuring in 2007. Following this multi-year defoliation event, oak mortality was significant, and resulted in the death of approximately 20 % of the overstory oaks, and a similar reduction in stand biomass. Previous disturbances have included windstorms and earlier Gypsy moth defoliation events in the 1990's. The last major wildfire to occur at and near the Experimental Forest was in 1963. Since then, a number of prescribed fires have been conducted in the vicinity of the Silas Little flux site." -US-Slt,13042,GRP_SITE_FUNDING,SITE_FUNDING,USDA/Forest Service -US-Slt,27178,GRP_SOIL_CHEM,SOIL_CHEM_C_ORG,14 -US-Slt,28801,GRP_SOIL_CHEM,SOIL_CHEM_C_ORG,6 -US-Slt,29302,GRP_SOIL_CHEM,SOIL_CHEM_C_ORG,8 -US-Slt,27723,GRP_SOIL_CHEM,SOIL_CHEM_C_ORG,9 -US-Slt,28801,GRP_SOIL_CHEM,SOIL_CHEM_C_ORG_SPATIAL_VARIABILITY,1 -US-Slt,29302,GRP_SOIL_CHEM,SOIL_CHEM_C_ORG_SPATIAL_VARIABILITY,1 -US-Slt,27723,GRP_SOIL_CHEM,SOIL_CHEM_C_ORG_SPATIAL_VARIABILITY,2 -US-Slt,27178,GRP_SOIL_CHEM,SOIL_CHEM_C_ORG_SPATIAL_VARIABILITY,3 -US-Slt,27478,GRP_SOIL_CHEM,SOIL_CHEM_PH_SALT,4.4 -US-Slt,28423,GRP_SOIL_CHEM,SOIL_CHEM_PH_SALT,4.7 -US-Slt,28802,GRP_SOIL_CHEM,SOIL_CHEM_PH_SALT,4.7 -US-Slt,27479,GRP_SOIL_CHEM,SOIL_CHEM_PH_SALT,4.8 -US-Slt,27479,GRP_SOIL_CHEM,SOIL_CHEM_PH_SALT_SPATIAL_VARIABILITY,0.1 -US-Slt,28423,GRP_SOIL_CHEM,SOIL_CHEM_PH_SALT_SPATIAL_VARIABILITY,0.1 -US-Slt,28802,GRP_SOIL_CHEM,SOIL_CHEM_PH_SALT_SPATIAL_VARIABILITY,0.1 -US-Slt,27478,GRP_SOIL_CHEM,SOIL_CHEM_PH_SALT_SPATIAL_VARIABILITY,0.2 -US-Slt,27178,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,0 -US-Slt,27478,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,0 -US-Slt,27723,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,10 -US-Slt,28802,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,10 -US-Slt,27479,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,20 -US-Slt,29302,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,20 -US-Slt,28423,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,40 -US-Slt,28801,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,40 -US-Slt,27178,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,10 -US-Slt,27478,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,10 -US-Slt,27723,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,20 -US-Slt,28802,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,20 -US-Slt,27479,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,40 -US-Slt,29302,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,40 -US-Slt,28423,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,80 -US-Slt,28801,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,80 -US-Slt,27178,GRP_SOIL_CHEM,SOIL_CHEM_DATE,20080601 -US-Slt,27478,GRP_SOIL_CHEM,SOIL_CHEM_DATE,20080601 -US-Slt,27479,GRP_SOIL_CHEM,SOIL_CHEM_DATE,20080601 -US-Slt,27723,GRP_SOIL_CHEM,SOIL_CHEM_DATE,20080601 -US-Slt,28423,GRP_SOIL_CHEM,SOIL_CHEM_DATE,20080601 -US-Slt,28801,GRP_SOIL_CHEM,SOIL_CHEM_DATE,20080601 -US-Slt,28802,GRP_SOIL_CHEM,SOIL_CHEM_DATE,20080601 -US-Slt,29302,GRP_SOIL_CHEM,SOIL_CHEM_DATE,20080601 -US-Slt,27478,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,"n = 15 total, 3 soil cores per tree census plot. pH in DI H20" -US-Slt,27479,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,"n = 15 total, 3 soil cores per tree census plot. pH in DI H20" -US-Slt,28423,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,"n = 15 total, 3 soil cores per tree census plot. pH in DI H20" -US-Slt,28802,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,"n = 15 total, 3 soil cores per tree census plot. pH in DI H20" -US-Slt,27178,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,Organic matter derived from LOI measurements as % -US-Slt,27723,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,Organic matter derived from LOI measurements as % -US-Slt,28801,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,Organic matter derived from LOI measurements as % -US-Slt,29302,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,Organic matter derived from LOI measurements as % -US-Slt,27189,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION,"Podzol, underlain by late Miocene fluvial sediments of the Kirkwood formation, and overlain with Cohansey sandy soil with low nutrient and cation exchange capacity" -US-Slt,27189,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION_TAXONOMY,Other -US-Slt,28772,GRP_SOIL_TEX,SOIL_TEX_SAND,50.8 -US-Slt,27808,GRP_SOIL_TEX,SOIL_TEX_SAND,79.3 -US-Slt,28770,GRP_SOIL_TEX,SOIL_TEX_SAND,82.9 -US-Slt,28771,GRP_SOIL_TEX,SOIL_TEX_SAND,83.6 -US-Slt,29303,GRP_SOIL_TEX,SOIL_TEX_SAND,95.1 -US-Slt,28424,GRP_SOIL_TEX,SOIL_TEX_SAND,95.2 -US-Slt,29615,GRP_SOIL_TEX,SOIL_TEX_SAND,95.6 -US-Slt,29411,GRP_SOIL_TEX,SOIL_TEX_SAND,95.7 -US-Slt,27480,GRP_SOIL_TEX,SOIL_TEX_SILT,2.6 -US-Slt,28082,GRP_SOIL_TEX,SOIL_TEX_SILT,3.6 -US-Slt,28770,GRP_SOIL_TEX,SOIL_TEX_SILT,3.8 -US-Slt,28803,GRP_SOIL_TEX,SOIL_TEX_SILT,4.3 -US-Slt,29411,GRP_SOIL_TEX,SOIL_TEX_SILT,4.3 -US-Slt,29615,GRP_SOIL_TEX,SOIL_TEX_SILT,4.4 -US-Slt,28424,GRP_SOIL_TEX,SOIL_TEX_SILT,4.8 -US-Slt,29303,GRP_SOIL_TEX,SOIL_TEX_SILT,4.9 -US-Slt,28771,GRP_SOIL_TEX,SOIL_TEX_ROCK,12.1 -US-Slt,28770,GRP_SOIL_TEX,SOIL_TEX_ROCK,13.3 -US-Slt,27808,GRP_SOIL_TEX,SOIL_TEX_ROCK,17.1 -US-Slt,28772,GRP_SOIL_TEX,SOIL_TEX_ROCK,46.6 -US-Slt,28771,GRP_SOIL_TEX,SOIL_TEX_ROCK_SPATIAL_VARIABILITY,15.5 -US-Slt,27808,GRP_SOIL_TEX,SOIL_TEX_ROCK_SPATIAL_VARIABILITY,16.7 -US-Slt,28770,GRP_SOIL_TEX,SOIL_TEX_ROCK_SPATIAL_VARIABILITY,20.0 -US-Slt,28772,GRP_SOIL_TEX,SOIL_TEX_ROCK_SPATIAL_VARIABILITY,22.6 -US-Slt,28770,GRP_SOIL_TEX,SOIL_TEX_PROFILE_MIN,0 -US-Slt,29615,GRP_SOIL_TEX,SOIL_TEX_PROFILE_MIN,0 -US-Slt,28771,GRP_SOIL_TEX,SOIL_TEX_PROFILE_MIN,10 -US-Slt,28803,GRP_SOIL_TEX,SOIL_TEX_PROFILE_MIN,10 -US-Slt,29303,GRP_SOIL_TEX,SOIL_TEX_PROFILE_MIN,10 -US-Slt,27808,GRP_SOIL_TEX,SOIL_TEX_PROFILE_MIN,20 -US-Slt,28082,GRP_SOIL_TEX,SOIL_TEX_PROFILE_MIN,20 -US-Slt,29411,GRP_SOIL_TEX,SOIL_TEX_PROFILE_MIN,20 -US-Slt,27480,GRP_SOIL_TEX,SOIL_TEX_PROFILE_MIN,40 -US-Slt,28424,GRP_SOIL_TEX,SOIL_TEX_PROFILE_MIN,40 -US-Slt,28772,GRP_SOIL_TEX,SOIL_TEX_PROFILE_MIN,40 -US-Slt,28770,GRP_SOIL_TEX,SOIL_TEX_PROFILE_MAX,10 -US-Slt,29615,GRP_SOIL_TEX,SOIL_TEX_PROFILE_MAX,10 -US-Slt,28771,GRP_SOIL_TEX,SOIL_TEX_PROFILE_MAX,20 -US-Slt,28803,GRP_SOIL_TEX,SOIL_TEX_PROFILE_MAX,20 -US-Slt,29303,GRP_SOIL_TEX,SOIL_TEX_PROFILE_MAX,20 -US-Slt,27808,GRP_SOIL_TEX,SOIL_TEX_PROFILE_MAX,40 -US-Slt,28082,GRP_SOIL_TEX,SOIL_TEX_PROFILE_MAX,40 -US-Slt,29411,GRP_SOIL_TEX,SOIL_TEX_PROFILE_MAX,40 -US-Slt,27480,GRP_SOIL_TEX,SOIL_TEX_PROFILE_MAX,80 -US-Slt,28424,GRP_SOIL_TEX,SOIL_TEX_PROFILE_MAX,80 -US-Slt,28772,GRP_SOIL_TEX,SOIL_TEX_PROFILE_MAX,80 -US-Slt,27808,GRP_SOIL_TEX,SOIL_TEX_COMMENT,"in > 2 mm fraction; n = 15 total, 3 soil cores per tree census plot." -US-Slt,28770,GRP_SOIL_TEX,SOIL_TEX_COMMENT,"in > 2 mm fraction; n = 15 total, 3 soil cores per tree census plot." -US-Slt,28771,GRP_SOIL_TEX,SOIL_TEX_COMMENT,"in > 2 mm fraction; n = 15 total, 3 soil cores per tree census plot." -US-Slt,28772,GRP_SOIL_TEX,SOIL_TEX_COMMENT,"in > 2 mm fraction; n = 15 total, 3 soil cores per tree census plot." -US-Slt,28424,GRP_SOIL_TEX,SOIL_TEX_COMMENT,"includes clay; in < 2 mm fraction; n = 15 total, 3 soil cores per tree census plot." -US-Slt,29303,GRP_SOIL_TEX,SOIL_TEX_COMMENT,"includes clay; in < 2 mm fraction; n = 15 total, 3 soil cores per tree census plot." -US-Slt,29411,GRP_SOIL_TEX,SOIL_TEX_COMMENT,"includes clay; in < 2 mm fraction; n = 15 total, 3 soil cores per tree census plot." -US-Slt,29615,GRP_SOIL_TEX,SOIL_TEX_COMMENT,"includes clay; in < 2 mm fraction; n = 15 total, 3 soil cores per tree census plot." -US-Slt,27480,GRP_SOIL_TEX,SOIL_TEX_COMMENT,"includes clay; in > 2 mm fraction; n = 15 total, 3 soil cores per tree census plot." -US-Slt,28082,GRP_SOIL_TEX,SOIL_TEX_COMMENT,"includes clay; in > 2 mm fraction; n = 15 total, 3 soil cores per tree census plot." -US-Slt,28803,GRP_SOIL_TEX,SOIL_TEX_COMMENT,"includes clay; in > 2 mm fraction; n = 15 total, 3 soil cores per tree census plot." -US-Slt,29409,GRP_SPP_O,SPP_O,PIEC (NRCS plant code) -US-Slt,29295,GRP_SPP_O,SPP_O,PIRI (NRCS plant code) -US-Slt,27474,GRP_SPP_O,SPP_O,QUAL (NRCS plant code) -US-Slt,28078,GRP_SPP_O,SPP_O,QUCO (NRCS plant code) -US-Slt,29410,GRP_SPP_O,SPP_O,QUPR (NRCS plant code) -US-Slt,29296,GRP_SPP_O,SPP_O,QUVE (NRCS plant code) -US-Slt,28078,GRP_SPP_O,SPP_O_PERC,0.10 -US-Slt,29409,GRP_SPP_O,SPP_O_PERC,11.20 -US-Slt,29295,GRP_SPP_O,SPP_O_PERC,15.40 -US-Slt,27474,GRP_SPP_O,SPP_O_PERC,17.60 -US-Slt,29410,GRP_SPP_O,SPP_O_PERC,24.50 -US-Slt,29296,GRP_SPP_O,SPP_O_PERC,31.20 -US-Slt,27474,GRP_SPP_O,SPP_APPROACH,"Five 201 m2 plots, censused annually" -US-Slt,28078,GRP_SPP_O,SPP_APPROACH,"Five 201 m2 plots, censused annually" -US-Slt,29295,GRP_SPP_O,SPP_APPROACH,"Five 201 m2 plots, censused annually" -US-Slt,29296,GRP_SPP_O,SPP_APPROACH,"Five 201 m2 plots, censused annually" -US-Slt,29409,GRP_SPP_O,SPP_APPROACH,"Five 201 m2 plots, censused annually" -US-Slt,29410,GRP_SPP_O,SPP_APPROACH,"Five 201 m2 plots, censused annually" -US-Slt,27474,GRP_SPP_O,SPP_DATE,2003 -US-Slt,28078,GRP_SPP_O,SPP_DATE,2003 -US-Slt,29295,GRP_SPP_O,SPP_DATE,2003 -US-Slt,29296,GRP_SPP_O,SPP_DATE,2003 -US-Slt,29409,GRP_SPP_O,SPP_DATE,2003 -US-Slt,29410,GRP_SPP_O,SPP_DATE,2003 -US-Slt,27474,GRP_SPP_O,SPP_COMMENT,"2003-2008; Trees in 5 201 m2 plots, Dominance calculated from basal area" -US-Slt,28078,GRP_SPP_O,SPP_COMMENT,"2003-2008; Trees in 5 201 m2 plots, Dominance calculated from basal area" -US-Slt,29295,GRP_SPP_O,SPP_COMMENT,"2003-2008; Trees in 5 201 m2 plots, Dominance calculated from basal area" -US-Slt,29296,GRP_SPP_O,SPP_COMMENT,"2003-2008; Trees in 5 201 m2 plots, Dominance calculated from basal area" -US-Slt,29409,GRP_SPP_O,SPP_COMMENT,"2003-2008; Trees in 5 201 m2 plots, Dominance calculated from basal area" -US-Slt,29410,GRP_SPP_O,SPP_COMMENT,"2003-2008; Trees in 5 201 m2 plots, Dominance calculated from basal area" -US-Slt,28425,GRP_SPP_U,SPP_U,GABA (NRCS plant code) -US-Slt,29616,GRP_SPP_U,SPP_U,VAVA (NRCS plant code) -US-Slt,28425,GRP_SPP_U,SPP_U_PERC,0.00 -US-Slt,29616,GRP_SPP_U,SPP_U_PERC,0.00 -US-Slt,28425,GRP_SPP_U,SPP_DATE,2003 -US-Slt,29616,GRP_SPP_U,SPP_DATE,2003 -US-Slt,28425,GRP_SPP_U,SPP_COMMENT,"2003-2008; Trees in 5 201 m2 plots, Dominance calculated from basal area" -US-Slt,29616,GRP_SPP_U,SPP_COMMENT,"2003-2008; Trees in 5 201 m2 plots, Dominance calculated from basal area" -US-Slt,13043,GRP_STATE,STATE,NJ -US-Slt,13044,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Ken Clark -US-Slt,13044,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Slt,13044,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,kennethclark@fs.fed.us -US-Slt,13044,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,USDA Forest Service -US-Slt,13044,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Silas Little Experimental Forest, P.O. Box 232,New Lisbon, NJ USA 08064" -US-Slt,29839,GRP_TOWER_POWER,TOWER_POWER,Direct power -US-Slt,13045,GRP_TOWER_TYPE,TOWER_TYPE,triangle -US-Slt,13046,GRP_URL,URL,http://www.nrs.fs.fed.us/ef/locations/nj/silas-little/ -US-Slt,24000426,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-Slt -US-Slt,13047,GRP_UTC_OFFSET,UTC_OFFSET,5 -US-Slt,28930,GRP_WD_BIOMASS,WD_BIOMASS_FINE,105.0 -US-Slt,28766,GRP_WD_BIOMASS,WD_BIOMASS_FINE,61.3 -US-Slt,28766,GRP_WD_BIOMASS,WD_BIOMASS_FINE_SPATIAL_VARIABILITY,45.5 -US-Slt,28930,GRP_WD_BIOMASS,WD_BIOMASS_FINE_SPATIAL_VARIABILITY,66.7 -US-Slt,28766,GRP_WD_BIOMASS,WD_BIOMASS_UNIT,gC m-2 -US-Slt,28930,GRP_WD_BIOMASS,WD_BIOMASS_UNIT,gC m-2 -US-Slt,28930,GRP_WD_BIOMASS,WD_BIOMASS_DATE,20040601 -US-Slt,28766,GRP_WD_BIOMASS,WD_BIOMASS_DATE,20080601 -US-Slt,28930,GRP_WD_BIOMASS,WD_BIOMASS_COMMENT,"10 1 m2 plots, L horizon only" -US-Slt,28766,GRP_WD_BIOMASS,WD_BIOMASS_COMMENT,"24 1 m2 plots, L horizon only" -US-Snd,11233,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,"Biometeorology Lab, University of California, Berkeley, PI: Dennis Baldocchi" -US-Snd,11233,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT_COMMENT,This work was funded by NSF-ATM grant number AGS-0628720 and the California Department of Water Resources grant #006550 -US-Snd,11234,GRP_CLIM_AVG,MAT,15.6 -US-Snd,11234,GRP_CLIM_AVG,MAP,358 -US-Snd,11234,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Csa -US-Snd,27000424,GRP_COUNTRY,COUNTRY,USA -US-Snd,15640,GRP_DOI,DOI,10.17190/AMF/1246094 -US-Snd,15640,GRP_DOI,DOI_CITATION,"Matteo Detto, Cove Sturtevant, Patty Oikawa, Joseph Verfaillie, Dennis Baldocchi (2016), AmeriFlux BASE US-Snd Sherman Island, Ver. 2-1, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1246094" -US-Snd,15640,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-Snd,94021,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Snd,94021,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Matteo Detto -US-Snd,94021,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Snd,94021,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,1 -US-Snd,94021,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0003-0494-188X -US-Snd,94021,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,teoparaglider@gmail.com -US-Snd,94021,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"University of California, Berkeley" -US-Snd,94021,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,20070405 -US-Snd,94021,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_END,20100901 -US-Snd,94139,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Snd,94139,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Cove Sturtevant -US-Snd,94139,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Snd,94139,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,2 -US-Snd,94139,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0002-0341-3228 -US-Snd,94139,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,csturtevant@battelleecology.org -US-Snd,94139,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"University of California, Berkeley" -US-Snd,94139,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,20130620 -US-Snd,94139,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_END,20141008 -US-Snd,94091,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Snd,94091,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Patty Oikawa -US-Snd,94091,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Snd,94091,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,3 -US-Snd,94091,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0002-5570-764X -US-Snd,94091,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,patty.oikawa@csueastbay.edu -US-Snd,94091,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"University of California, Berkeley" -US-Snd,94091,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,20140304 -US-Snd,94091,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_END,20150708 -US-Snd,94060,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Snd,94060,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Joseph Verfaillie -US-Snd,94060,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Snd,94060,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,8 -US-Snd,94060,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0002-7009-8942 -US-Snd,94060,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,jverfail@berkeley.edu -US-Snd,94060,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"University of California, Berkeley" -US-Snd,94060,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,200809 -US-Snd,94060,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_END,20150708 -US-Snd,98288,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Snd,98288,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Dennis Baldocchi -US-Snd,98288,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Snd,98288,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,9 -US-Snd,98288,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0003-3496-4919 -US-Snd,98288,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,Baldocchi@berkeley.edu -US-Snd,98288,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"University of California, Berkeley" -US-Snd,98288,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,20070405 -US-Snd,98288,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_END,20150708 -US-Snd,32178,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,"University of California, Berkeley" -US-Snd,32178,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-Snd,32177,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,NSF/California Department of Water Resources -US-Snd,32177,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-Snd,22214,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Grazing -US-Snd,91350,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Snd,91350,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-Snd,91350,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20070405 -US-Snd,91350,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20150507 -US-Snd,91350,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Snd,91414,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Snd,91414,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-Snd,91414,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20070405 -US-Snd,91414,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20150507 -US-Snd,91414,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Snd,29991,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Snd,29991,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CH4 -US-Snd,29991,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20070723 -US-Snd,29991,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20150507 -US-Snd,29991,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Snd,23000424,GRP_HEADER,SITE_NAME,Sherman Island -US-Snd,94671,GRP_HEIGHTC,HEIGHTC,0.141 -US-Snd,94671,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Snd,94671,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Snd,94671,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Snd,94671,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Snd,94671,GRP_HEIGHTC,HEIGHTC_DATE,20131016 -US-Snd,94676,GRP_HEIGHTC,HEIGHTC,0.186 -US-Snd,94676,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Snd,94676,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Snd,94676,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Snd,94676,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Snd,94676,GRP_HEIGHTC,HEIGHTC_DATE,20131016 -US-Snd,94642,GRP_HEIGHTC,HEIGHTC,0.147 -US-Snd,94642,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Snd,94642,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Snd,94642,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Snd,94642,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Snd,94642,GRP_HEIGHTC,HEIGHTC_DATE,20131106 -US-Snd,94696,GRP_HEIGHTC,HEIGHTC,0.127 -US-Snd,94696,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Snd,94696,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Snd,94696,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Snd,94696,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Snd,94696,GRP_HEIGHTC,HEIGHTC_DATE,20131106 -US-Snd,94643,GRP_HEIGHTC,HEIGHTC,0.226 -US-Snd,94643,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Snd,94643,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Snd,94643,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Snd,94643,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Snd,94643,GRP_HEIGHTC,HEIGHTC_DATE,20131121 -US-Snd,94668,GRP_HEIGHTC,HEIGHTC,0.183 -US-Snd,94668,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Snd,94668,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Snd,94668,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Snd,94668,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Snd,94668,GRP_HEIGHTC,HEIGHTC_DATE,20131121 -US-Snd,94700,GRP_HEIGHTC,HEIGHTC,0.032 -US-Snd,94700,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Snd,94700,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Snd,94700,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Snd,94700,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Snd,94700,GRP_HEIGHTC,HEIGHTC_DATE,20140225 -US-Snd,94700,GRP_HEIGHTC,HEIGHTC_COMMENT,short green grass layer and new green leaves at base of pepperweed skeletons -US-Snd,94702,GRP_HEIGHTC,HEIGHTC,0.041 -US-Snd,94702,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Snd,94702,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Snd,94702,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Snd,94702,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Snd,94702,GRP_HEIGHTC,HEIGHTC_DATE,20140225 -US-Snd,94702,GRP_HEIGHTC,HEIGHTC_COMMENT,short green grass layer and new green leaves at base of pepperweed skeletons -US-Snd,94698,GRP_HEIGHTC,HEIGHTC,0.072 -US-Snd,94698,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Snd,94698,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Snd,94698,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Snd,94698,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Snd,94698,GRP_HEIGHTC,HEIGHTC_DATE,20140313 -US-Snd,94698,GRP_HEIGHTC,HEIGHTC_COMMENT,short green grass layer and pepperweed srtating to grow again -US-Snd,94703,GRP_HEIGHTC,HEIGHTC,0.095 -US-Snd,94703,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Snd,94703,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Snd,94703,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Snd,94703,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Snd,94703,GRP_HEIGHTC,HEIGHTC_DATE,20140313 -US-Snd,94703,GRP_HEIGHTC,HEIGHTC_COMMENT,short green grass layer and pepperweed srtating to grow again -US-Snd,94658,GRP_HEIGHTC,HEIGHTC,0.276 -US-Snd,94658,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Snd,94658,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Snd,94658,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Snd,94658,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Snd,94658,GRP_HEIGHTC,HEIGHTC_DATE,20140403 -US-Snd,94658,GRP_HEIGHTC,HEIGHTC_COMMENT,short green grass layer and pepperweed really taking off -US-Snd,94667,GRP_HEIGHTC,HEIGHTC,0.403 -US-Snd,94667,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Snd,94667,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Snd,94667,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Snd,94667,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Snd,94667,GRP_HEIGHTC,HEIGHTC_DATE,20140403 -US-Snd,94667,GRP_HEIGHTC,HEIGHTC_COMMENT,short green grass layer and pepperweed really taking off -US-Snd,94682,GRP_HEIGHTC,HEIGHTC,0.346 -US-Snd,94682,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Snd,94682,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Snd,94682,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Snd,94682,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Snd,94682,GRP_HEIGHTC,HEIGHTC_DATE,20140428 -US-Snd,94682,GRP_HEIGHTC,HEIGHTC_COMMENT,"short green grass layer, pepperweed super dense and tall" -US-Snd,94699,GRP_HEIGHTC,HEIGHTC,0.547 -US-Snd,94699,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Snd,94699,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Snd,94699,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Snd,94699,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Snd,94699,GRP_HEIGHTC,HEIGHTC_DATE,20140428 -US-Snd,94699,GRP_HEIGHTC,HEIGHTC_COMMENT,"short green grass layer, pepperweed super dense and tall" -US-Snd,94670,GRP_HEIGHTC,HEIGHTC,0.873 -US-Snd,94670,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Snd,94670,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Snd,94670,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Snd,94670,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Snd,94670,GRP_HEIGHTC,HEIGHTC_DATE,20140513 -US-Snd,94670,GRP_HEIGHTC,HEIGHTC_COMMENT,pepperweed dense and blooming -US-Snd,94701,GRP_HEIGHTC,HEIGHTC,0.136 -US-Snd,94701,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Snd,94701,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Snd,94701,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Snd,94701,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Snd,94701,GRP_HEIGHTC,HEIGHTC_DATE,20140513 -US-Snd,94701,GRP_HEIGHTC,HEIGHTC_COMMENT,pepperweed dense and blooming -US-Snd,94689,GRP_HEIGHTC,HEIGHTC,0.137 -US-Snd,94689,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Snd,94689,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Snd,94689,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Snd,94689,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Snd,94689,GRP_HEIGHTC,HEIGHTC_DATE,20140521 -US-Snd,94689,GRP_HEIGHTC,HEIGHTC_COMMENT,pepperweed dense and blooming -US-Snd,94705,GRP_HEIGHTC,HEIGHTC,0.842 -US-Snd,94705,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Snd,94705,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Snd,94705,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Snd,94705,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Snd,94705,GRP_HEIGHTC,HEIGHTC_DATE,20140521 -US-Snd,94705,GRP_HEIGHTC,HEIGHTC_COMMENT,pepperweed dense and blooming -US-Snd,94655,GRP_HEIGHTC,HEIGHTC,0.269 -US-Snd,94655,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Snd,94655,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Snd,94655,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Snd,94655,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Snd,94655,GRP_HEIGHTC,HEIGHTC_DATE,20140529 -US-Snd,94655,GRP_HEIGHTC,HEIGHTC_COMMENT,pepperweed fully flowered but duller and a bit wilted. Grass gone to seed. -US-Snd,94657,GRP_HEIGHTC,HEIGHTC,0.545 -US-Snd,94657,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Snd,94657,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Snd,94657,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Snd,94657,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Snd,94657,GRP_HEIGHTC,HEIGHTC_DATE,20140529 -US-Snd,94657,GRP_HEIGHTC,HEIGHTC_COMMENT,pepperweed fully flowered but duller and a bit wilted. Grass gone to seed. -US-Snd,94653,GRP_HEIGHTC,HEIGHTC,0.272 -US-Snd,94653,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Snd,94653,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Snd,94653,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Snd,94653,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Snd,94653,GRP_HEIGHTC,HEIGHTC_DATE,20140605 -US-Snd,94653,GRP_HEIGHTC,HEIGHTC_COMMENT,pepperweed dull green and flowers dry. Some spots of vibrant veg still. Grass dry. -US-Snd,94662,GRP_HEIGHTC,HEIGHTC,0.547 -US-Snd,94662,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Snd,94662,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Snd,94662,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Snd,94662,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Snd,94662,GRP_HEIGHTC,HEIGHTC_DATE,20140605 -US-Snd,94662,GRP_HEIGHTC,HEIGHTC_COMMENT,pepperweed dull green and flowers dry. Some spots of vibrant veg still. Grass dry. -US-Snd,94641,GRP_HEIGHTC,HEIGHTC,0.713 -US-Snd,94641,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Snd,94641,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Snd,94641,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Snd,94641,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Snd,94641,GRP_HEIGHTC,HEIGHTC_DATE,20140612 -US-Snd,94641,GRP_HEIGHTC,HEIGHTC_COMMENT,pepperweed mostly dried out.Grass dry. -US-Snd,94649,GRP_HEIGHTC,HEIGHTC,0.135 -US-Snd,94649,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Snd,94649,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Snd,94649,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Snd,94649,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Snd,94649,GRP_HEIGHTC,HEIGHTC_DATE,20140612 -US-Snd,94649,GRP_HEIGHTC,HEIGHTC_COMMENT,pepperweed mostly dried out.Grass dry. -US-Snd,94646,GRP_HEIGHTC,HEIGHTC,0.328 -US-Snd,94646,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Snd,94646,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Snd,94646,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Snd,94646,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Snd,94646,GRP_HEIGHTC,HEIGHTC_DATE,20140617 -US-Snd,94646,GRP_HEIGHTC,HEIGHTC_COMMENT,pepperweed mostly dried out.Grass dry. -US-Snd,94695,GRP_HEIGHTC,HEIGHTC,0.709 -US-Snd,94695,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Snd,94695,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Snd,94695,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Snd,94695,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Snd,94695,GRP_HEIGHTC,HEIGHTC_DATE,20140617 -US-Snd,94695,GRP_HEIGHTC,HEIGHTC_COMMENT,pepperweed mostly dried out.Grass dry. -US-Snd,94645,GRP_HEIGHTC,HEIGHTC,0.275 -US-Snd,94645,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Snd,94645,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Snd,94645,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Snd,94645,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Snd,94645,GRP_HEIGHTC,HEIGHTC_DATE,20140626 -US-Snd,94645,GRP_HEIGHTC,HEIGHTC_COMMENT,pepperweed mostly dried out.Grass dry. -US-Snd,94679,GRP_HEIGHTC,HEIGHTC,0.569 -US-Snd,94679,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Snd,94679,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Snd,94679,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Snd,94679,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Snd,94679,GRP_HEIGHTC,HEIGHTC_DATE,20140626 -US-Snd,94679,GRP_HEIGHTC,HEIGHTC_COMMENT,pepperweed mostly dried out.Grass dry. -US-Snd,94647,GRP_HEIGHTC,HEIGHTC,0.325 -US-Snd,94647,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Snd,94647,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Snd,94647,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Snd,94647,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Snd,94647,GRP_HEIGHTC,HEIGHTC_DATE,20140702 -US-Snd,94647,GRP_HEIGHTC,HEIGHTC_COMMENT,pepperweed mostly dried out.Grass dry. -US-Snd,94666,GRP_HEIGHTC,HEIGHTC,0.518 -US-Snd,94666,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Snd,94666,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Snd,94666,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Snd,94666,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Snd,94666,GRP_HEIGHTC,HEIGHTC_DATE,20140702 -US-Snd,94666,GRP_HEIGHTC,HEIGHTC_COMMENT,pepperweed mostly dried out.Grass dry. -US-Snd,94637,GRP_HEIGHTC,HEIGHTC,0.704 -US-Snd,94637,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Snd,94637,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Snd,94637,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Snd,94637,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Snd,94637,GRP_HEIGHTC,HEIGHTC_DATE,20140708 -US-Snd,94637,GRP_HEIGHTC,HEIGHTC_COMMENT,pepperweed mostly dried out.Grass dry. -US-Snd,94677,GRP_HEIGHTC,HEIGHTC,0.238 -US-Snd,94677,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Snd,94677,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Snd,94677,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Snd,94677,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Snd,94677,GRP_HEIGHTC,HEIGHTC_DATE,20140708 -US-Snd,94677,GRP_HEIGHTC,HEIGHTC_COMMENT,pepperweed mostly dried out.Grass dry. -US-Snd,94675,GRP_HEIGHTC,HEIGHTC,0.554 -US-Snd,94675,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Snd,94675,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Snd,94675,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Snd,94675,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Snd,94675,GRP_HEIGHTC,HEIGHTC_DATE,20140715 -US-Snd,94675,GRP_HEIGHTC,HEIGHTC_COMMENT,pepperweed mostly dried out.Grass dry. -US-Snd,94686,GRP_HEIGHTC,HEIGHTC,0.322 -US-Snd,94686,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Snd,94686,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Snd,94686,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Snd,94686,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Snd,94686,GRP_HEIGHTC,HEIGHTC_DATE,20140715 -US-Snd,94686,GRP_HEIGHTC,HEIGHTC_COMMENT,pepperweed mostly dried out.Grass dry. -US-Snd,94644,GRP_HEIGHTC,HEIGHTC,0.091 -US-Snd,94644,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Snd,94644,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Snd,94644,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Snd,94644,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Snd,94644,GRP_HEIGHTC,HEIGHTC_DATE,20140723 -US-Snd,94644,GRP_HEIGHTC,HEIGHTC_COMMENT,pepperweed mostly dried out.Grass dry. -US-Snd,94691,GRP_HEIGHTC,HEIGHTC,0.745 -US-Snd,94691,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Snd,94691,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Snd,94691,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Snd,94691,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Snd,94691,GRP_HEIGHTC,HEIGHTC_DATE,20140723 -US-Snd,94691,GRP_HEIGHTC,HEIGHTC_COMMENT,pepperweed mostly dried out.Grass dry. -US-Snd,94678,GRP_HEIGHTC,HEIGHTC,0.503 -US-Snd,94678,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Snd,94678,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Snd,94678,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Snd,94678,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Snd,94678,GRP_HEIGHTC,HEIGHTC_DATE,20140731 -US-Snd,94678,GRP_HEIGHTC,HEIGHTC_COMMENT,some green pepperweed and green grass/forb understory -US-Snd,94687,GRP_HEIGHTC,HEIGHTC,0.263 -US-Snd,94687,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Snd,94687,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Snd,94687,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Snd,94687,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Snd,94687,GRP_HEIGHTC,HEIGHTC_DATE,20140731 -US-Snd,94687,GRP_HEIGHTC,HEIGHTC_COMMENT,some green pepperweed and green grass/forb understory -US-Snd,94640,GRP_HEIGHTC,HEIGHTC,0.419 -US-Snd,94640,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Snd,94640,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Snd,94640,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Snd,94640,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Snd,94640,GRP_HEIGHTC,HEIGHTC_DATE,20140807 -US-Snd,94640,GRP_HEIGHTC,HEIGHTC_COMMENT,mostly dried out -US-Snd,94652,GRP_HEIGHTC,HEIGHTC,0.244 -US-Snd,94652,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Snd,94652,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Snd,94652,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Snd,94652,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Snd,94652,GRP_HEIGHTC,HEIGHTC_DATE,20140807 -US-Snd,94652,GRP_HEIGHTC,HEIGHTC_COMMENT,mostly dried out -US-Snd,94648,GRP_HEIGHTC,HEIGHTC,0.173 -US-Snd,94648,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Snd,94648,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Snd,94648,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Snd,94648,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Snd,94648,GRP_HEIGHTC,HEIGHTC_DATE,20140813 -US-Snd,94648,GRP_HEIGHTC,HEIGHTC_COMMENT,"patchy green, mostly brown" -US-Snd,94683,GRP_HEIGHTC,HEIGHTC,0.669 -US-Snd,94683,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Snd,94683,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Snd,94683,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Snd,94683,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Snd,94683,GRP_HEIGHTC,HEIGHTC_DATE,20140813 -US-Snd,94683,GRP_HEIGHTC,HEIGHTC_COMMENT,"patchy green, mostly brown" -US-Snd,94661,GRP_HEIGHTC,HEIGHTC,0.476 -US-Snd,94661,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Snd,94661,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Snd,94661,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Snd,94661,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Snd,94661,GRP_HEIGHTC,HEIGHTC_DATE,20140819 -US-Snd,94661,GRP_HEIGHTC,HEIGHTC_COMMENT,"patchy green, mostly brown, grass seems fairly tall" -US-Snd,94669,GRP_HEIGHTC,HEIGHTC,0.169 -US-Snd,94669,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Snd,94669,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Snd,94669,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Snd,94669,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Snd,94669,GRP_HEIGHTC,HEIGHTC_DATE,20140819 -US-Snd,94669,GRP_HEIGHTC,HEIGHTC_COMMENT,"patchy green, mostly brown, grass seems fairly tall" -US-Snd,94654,GRP_HEIGHTC,HEIGHTC,0.209 -US-Snd,94654,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Snd,94654,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Snd,94654,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Snd,94654,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Snd,94654,GRP_HEIGHTC,HEIGHTC_DATE,20140827 -US-Snd,94654,GRP_HEIGHTC,HEIGHTC_COMMENT,"patchy green, mostly brown, grass seems fairly tall" -US-Snd,94672,GRP_HEIGHTC,HEIGHTC,0.529 -US-Snd,94672,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Snd,94672,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Snd,94672,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Snd,94672,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Snd,94672,GRP_HEIGHTC,HEIGHTC_DATE,20140827 -US-Snd,94672,GRP_HEIGHTC,HEIGHTC_COMMENT,"patchy green, mostly brown, grass seems fairly tall" -US-Snd,94704,GRP_HEIGHTC,HEIGHTC,0.662 -US-Snd,94704,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Snd,94704,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Snd,94704,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Snd,94704,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Snd,94704,GRP_HEIGHTC,HEIGHTC_DATE,20140904 -US-Snd,94706,GRP_HEIGHTC,HEIGHTC,0.147 -US-Snd,94706,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Snd,94706,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Snd,94706,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Snd,94706,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Snd,94706,GRP_HEIGHTC,HEIGHTC_DATE,20140904 -US-Snd,94656,GRP_HEIGHTC,HEIGHTC,0.463 -US-Snd,94656,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Snd,94656,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Snd,94656,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Snd,94656,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Snd,94656,GRP_HEIGHTC,HEIGHTC_DATE,20140908 -US-Snd,94659,GRP_HEIGHTC,HEIGHTC,0.153 -US-Snd,94659,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Snd,94659,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Snd,94659,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Snd,94659,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Snd,94659,GRP_HEIGHTC,HEIGHTC_DATE,20140908 -US-Snd,94673,GRP_HEIGHTC,HEIGHTC,0.56 -US-Snd,94673,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Snd,94673,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Snd,94673,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Snd,94673,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Snd,94673,GRP_HEIGHTC,HEIGHTC_DATE,20140918 -US-Snd,94694,GRP_HEIGHTC,HEIGHTC,0.155 -US-Snd,94694,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Snd,94694,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Snd,94694,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Snd,94694,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Snd,94694,GRP_HEIGHTC,HEIGHTC_DATE,20140918 -US-Snd,94664,GRP_HEIGHTC,HEIGHTC,0.179 -US-Snd,94664,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Snd,94664,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Snd,94664,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Snd,94664,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Snd,94664,GRP_HEIGHTC,HEIGHTC_DATE,20140925 -US-Snd,94681,GRP_HEIGHTC,HEIGHTC,0.333 -US-Snd,94681,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Snd,94681,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Snd,94681,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Snd,94681,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Snd,94681,GRP_HEIGHTC,HEIGHTC_DATE,20140925 -US-Snd,94685,GRP_HEIGHTC,HEIGHTC,0.233 -US-Snd,94685,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Snd,94685,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Snd,94685,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Snd,94685,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Snd,94685,GRP_HEIGHTC,HEIGHTC_DATE,20141002 -US-Snd,94692,GRP_HEIGHTC,HEIGHTC,0.355 -US-Snd,94692,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Snd,94692,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Snd,94692,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Snd,94692,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Snd,94692,GRP_HEIGHTC,HEIGHTC_DATE,20141002 -US-Snd,94650,GRP_HEIGHTC,HEIGHTC,0.505 -US-Snd,94650,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Snd,94650,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Snd,94650,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Snd,94650,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Snd,94650,GRP_HEIGHTC,HEIGHTC_DATE,20141009 -US-Snd,94684,GRP_HEIGHTC,HEIGHTC,0.238 -US-Snd,94684,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Snd,94684,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Snd,94684,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Snd,94684,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Snd,94684,GRP_HEIGHTC,HEIGHTC_DATE,20141009 -US-Snd,94638,GRP_HEIGHTC,HEIGHTC,0.323 -US-Snd,94638,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Snd,94638,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Snd,94638,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Snd,94638,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Snd,94638,GRP_HEIGHTC,HEIGHTC_DATE,20141016 -US-Snd,94693,GRP_HEIGHTC,HEIGHTC,0.246 -US-Snd,94693,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Snd,94693,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Snd,94693,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Snd,94693,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Snd,94693,GRP_HEIGHTC,HEIGHTC_DATE,20141016 -US-Snd,94688,GRP_HEIGHTC,HEIGHTC,0.525 -US-Snd,94688,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Snd,94688,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Snd,94688,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Snd,94688,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Snd,94688,GRP_HEIGHTC,HEIGHTC_DATE,20141030 -US-Snd,94697,GRP_HEIGHTC,HEIGHTC,0.238 -US-Snd,94697,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Snd,94697,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Snd,94697,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Snd,94697,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Snd,94697,GRP_HEIGHTC,HEIGHTC_DATE,20141030 -US-Snd,94639,GRP_HEIGHTC,HEIGHTC,0.693 -US-Snd,94639,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Snd,94639,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Snd,94639,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,18 -US-Snd,94639,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Snd,94639,GRP_HEIGHTC,HEIGHTC_DATE,20141111 -US-Snd,94663,GRP_HEIGHTC,HEIGHTC,0.209 -US-Snd,94663,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Snd,94663,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Snd,94663,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,18 -US-Snd,94663,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Snd,94663,GRP_HEIGHTC,HEIGHTC_DATE,20141111 -US-Snd,94660,GRP_HEIGHTC,HEIGHTC,0.206 -US-Snd,94660,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Snd,94660,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Snd,94660,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Snd,94660,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Snd,94660,GRP_HEIGHTC,HEIGHTC_DATE,20141125 -US-Snd,94674,GRP_HEIGHTC,HEIGHTC,0.617 -US-Snd,94674,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Snd,94674,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Snd,94674,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Snd,94674,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Snd,94674,GRP_HEIGHTC,HEIGHTC_DATE,20141125 -US-Snd,94651,GRP_HEIGHTC,HEIGHTC,0.032 -US-Snd,94651,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Snd,94651,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Snd,94651,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,10 -US-Snd,94651,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Snd,94651,GRP_HEIGHTC,HEIGHTC_DATE,20150205 -US-Snd,94651,GRP_HEIGHTC,HEIGHTC_COMMENT,mostly short green grass (represented by measurements here) and standing litter (between 40 and 90 cm in height) -US-Snd,94680,GRP_HEIGHTC,HEIGHTC,0.023 -US-Snd,94680,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Snd,94680,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Snd,94680,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,10 -US-Snd,94680,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Snd,94680,GRP_HEIGHTC,HEIGHTC_DATE,20150205 -US-Snd,94680,GRP_HEIGHTC,HEIGHTC_COMMENT,mostly short green grass (represented by measurements here) and standing litter (between 40 and 90 cm in height) -US-Snd,94665,GRP_HEIGHTC,HEIGHTC,0.074 -US-Snd,94665,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Snd,94665,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Snd,94665,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Snd,94665,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Snd,94665,GRP_HEIGHTC,HEIGHTC_DATE,20150219 -US-Snd,94665,GRP_HEIGHTC,HEIGHTC_COMMENT,green grass measurements -US-Snd,94690,GRP_HEIGHTC,HEIGHTC,0.049 -US-Snd,94690,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Snd,94690,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Snd,94690,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Snd,94690,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Snd,94690,GRP_HEIGHTC,HEIGHTC_DATE,20150219 -US-Snd,94690,GRP_HEIGHTC,HEIGHTC_COMMENT,green grass measurements -US-Snd,11236,GRP_IGBP,IGBP,GRA -US-Snd,11237,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-Snd,11237,GRP_LAND_OWNERSHIP,LAND_OWNER,State of California -US-Snd,94775,GRP_LOCATION,LOCATION_LAT,38.0366 -US-Snd,94775,GRP_LOCATION,LOCATION_LONG,-121.7540 -US-Snd,94775,GRP_LOCATION,LOCATION_ELEV,-5 -US-Snd,94775,GRP_LOCATION,LOCATION_DATE_START,20070723 -US-Snd,94775,GRP_LOCATION,LOCATION_COMMENT,Confirmed by Joe Verfaillie -US-Snd,11239,GRP_NETWORK,NETWORK,AmeriFlux -US-Snd,87005,GRP_NETWORK,NETWORK,Phenocam -US-Snd,1700005283,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Baldocchi, D., Detto, M., Sonnentag, O., Verfaillie, J., Teh, Y. A., Silver, W., Kelly, N. M. (2012) The Challenges Of Measuring Methane Fluxes And Concentrations Over A Peatland Pasture, Agricultural And Forest Meteorology, 153(3), 177-187" -US-Snd,1700005283,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2011.04.013 -US-Snd,1700005283,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Snd,1700004359,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Baldocchi, D., Penuelas, J. (2018) The Physics And Ecology Of Mining Carbon Dioxide From The Atmosphere By Ecosystems, Global Change Biology, 256-257(G1), 179-195" -US-Snd,1700004359,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/GCB.14559 -US-Snd,1700004359,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Snd,1700003555,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chamberlain, S. D., Verfaillie, J., Eichelmann, E., Hemes, K. S., Baldocchi, D. D. (2017) Evaluation Of Density Corrections To Methane Fluxes Measured By Open-Path Eddy Covariance Over Contrasting Landscapes, Boundary-Layer Meteorology, 116(G1), n/a-n/a" -US-Snd,1700003555,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1007/S10546-017-0275-9 -US-Snd,1700003555,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Snd,1700000723,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chamberlain, S. D., Verfaillie, J., Eichelmann, E., Hemes, K. S., Baldocchi, D. D. (2017) Evaluation Of Density Corrections To Methane Fluxes Measured By Open-Path Eddy Covariance Over Contrasting Landscapes, Boundary-Layer Meteorology, 301-302(G1), 108350" -US-Snd,1700000723,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1007/S10546-017-0275-9 -US-Snd,1700000723,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Snd,1700005385,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(G1), 108350" -US-Snd,1700005385,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -US-Snd,1700005385,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Snd,1700007563,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Detto, M., Baldocchi, D., Katul, G. G. (2010) Scaling Properties Of Biologically Active Scalar Concentration Fluctuations In The Atmospheric Surface Layer Over A Managed Peatland, Boundary-Layer Meteorology, 136(3), 407-430" -US-Snd,1700007563,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1007/S10546-010-9514-Z -US-Snd,1700007563,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Snd,1700002520,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Detto, M., Verfaillie, J., Anderson, F., Xu, L., Baldocchi, D. (2011) Comparing Laser-Based Open- And Closed-Path Gas Analyzers To Measure Methane Fluxes Using The Eddy Covariance Method, Agricultural And Forest Meteorology, 151(10), 1312-1324" -US-Snd,1700002520,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2011.05.014 -US-Snd,1700002520,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Snd,1700006015,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Eichelmann, E., Hemes, K. S., Knox, S. H., Oikawa, P. Y., Chamberlain, S. D., Sturtevant, C., Verfaillie, J., Baldocchi, D. D. (2018) The Effect Of Land Cover Type And Structure On Evapotranspiration From Agricultural And Wetland Sites In The Sacramento–San Joaquin River Delta, California, Agricultural And Forest Meteorology, 256-257(G1), 179-195" -US-Snd,1700006015,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2018.03.007 -US-Snd,1700006015,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Snd,1700001893,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Hatala, J. A., Detto, M., Sonnentag, O., Deverel, S. J., Verfaillie, J., Baldocchi, D. D. (2012) Greenhouse Gas (CO2, CH4, H2O) Fluxes From Drained And Flooded Agricultural Peatlands In The Sacramento-San Joaquin Delta, Agriculture, Ecosystems & Environment, 150(3), 1-18" -US-Snd,1700001893,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGEE.2012.01.009 -US-Snd,1700001893,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Primary_Citation -US-Snd,1700000825,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Hemes, K. S., Chamberlain, S. D., Eichelmann, E., Anthony, T., Valach, A., Kasak, K., Szutu, D., Verfaillie, J., Silver, W. L., Baldocchi, D. D. (2019) Assessing The Carbon And Climate Benefit Of Restoring Degraded Agricultural Peat Soils To Managed Wetlands, Agricultural And Forest Meteorology, 268(G1), 202-214" -US-Snd,1700000825,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2019.01.017 -US-Snd,1700000825,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Snd,1700000021,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Knox, S. H.,, Sturtevant, C., Matthes, J.H., Koteen, L., Verfaillie,J., Baldocchi. D. (2014) Agricultural peatland restoration: effects of land-use change on greenhouse gas (CO2 and CH4) fluxes in the Sacramento-San Joaquin Delta, Global Change Biology, 21(), 750-765" -US-Snd,1700000021,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/GCB.12745 -US-Snd,1700000021,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Snd,1700005919,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Ma, S., Baldocchi, D. D., Hatala, J. A., Detto, M., Curiel Yuste, J. (2012) Are Rain-Induced Ecosystem Respiration Pulses Enhanced By Legacies Of Antecedent Photodegradation In Semi-Arid Environments?, Agricultural And Forest Meteorology, 154-155(), 203-213" -US-Snd,1700005919,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2011.11.007 -US-Snd,1700005919,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Snd,1700007929,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Sonnentag, O., Detto, M., Runkle, B. R. K., Teh, Y. A., Silver, W. L., Kelly, M., Baldocchi, D. D. (2011) Carbon Dioxide Exchange Of A Pepperweed ( Lepidium Latifolium L.) Infestation: How Do Flowering And Mowing Affect Canopy Photosynthesis And Autotrophic Respiration?, Journal Of Geophysical Research, 116(G1), n/a-n/a" -US-Snd,1700007929,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2010JG001522 -US-Snd,1700007929,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Snd,1700004782,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Sonnentag, O., Detto, M., Vargas, R., Ryu, Y., Runkle, B., Kelly, M., Baldocchi, D. (2011) Tracking The Structural And Functional Development Of A Perennial Pepperweed (Lepidium Latifolium L.) Infestation Using A Multi-Year Archive Of Webcam Imagery And Eddy Covariance Measurements, Agricultural And Forest Meteorology, 151(7), 916-926" -US-Snd,1700004782,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2011.02.011 -US-Snd,1700004782,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Snd,1700009039,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Teh, Y. A., Silver, W. L., Sonnentag, O., Detto, M., Kelly, M., Baldocchi, D. D. (2011) Large Greenhouse Gas Emissions From A Temperate Peatland Pasture, Ecosystems, 14(2), 311-325" -US-Snd,1700009039,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1007/S10021-011-9411-4 -US-Snd,1700009039,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Snd,11241,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"The research approach of the University of California, Berkeley Biometeorology Laboratory involves the coordinated use of experimental measurements and theoretical models to understand the physical, biological, and chemical processes that control trace gas fluxes between the biosphere and atmosphere and to quantify their temporal and spatial variations. By developing and testing methane efflux models within a peatland pasture, new methane emission algorithms can later be implemented in coupled climate-carbon cycle models. The research objectives of the Mayberry Wetland, Sherman Island, and Twitchell Island sites are as follows: 1) Describe differences in the fluxes of CO2, CH4, H2O, and energy between different land uses; 2) Understand the mechanisms controlling these fluxes; 3) Use ecosystem modeling to understand controls on these mechanisms under different environmental scenarios. These three sites were selected to capture a wide range of inundated conditions within the Sacramento-San Joaquin River Delta. The research focuses on the eddy covariance technique to measure CH4, CO2, H2O, and energy fluxes and works to combine measurements of both net fluxes and partitioned fluxes in order to achieve a mechanistic understanding of the ecological controls on current and future carbon flux in the Delta." -US-Snd,11242,GRP_SITE_CHAR,TERRAIN,Flat -US-Snd,11242,GRP_SITE_CHAR,ASPECT,FLAT -US-Snd,11242,GRP_SITE_CHAR,WIND_DIRECTION,WNW -US-Snd,11242,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,900 -US-Snd,11242,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,0 -US-Snd,30333,GRP_SITE_DESC,SITE_DESC,"The Sherman Island site is a 38-ha peatland pasture, west of the Delta, that is owned by the state and managed by the California Department of Water Resources. The site is degraded and heavily grazed with ~100 cattle in the area that circumscribes the main field and fetch. The island has been drained and farmed since the late 1800s. The soils of the Delta overlay deep peat that was sequestered over the Holocene period as sea-level rose and flooding of archaic wetlands prevented decomposition of roots and stems. Hence, the upper 10 m of peatland has been lost to decomposition, compaction, and subsidence. Today a mineral soil overlays a peat layer, which coincides with the general depth of the water table. - -This site was discontinued in 2015 as the land was converted into a restored wetland. A new site was established in 2016 nearby, US_Sne" -US-Snd,11244,GRP_SITE_FUNDING,SITE_FUNDING,NSF/California Department of Water Resources -US-Snd,27818,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION,Carbon content levels in the upper layer is ~5 - 10% and quickly increases to 15 - 50% at depth. Nitrogen content levels are 0.4 - 0.6% in the mineral soil and >1% at depth. -US-Snd,27818,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION_TAXONOMY,Other -US-Snd,11245,GRP_STATE,STATE,CA -US-Snd,11251,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Dennis Baldocchi -US-Snd,11251,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Snd,11251,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,Baldocchi@berkeley.edu -US-Snd,11251,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"University of California, Berkeley" -US-Snd,11251,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Department of Environmental Science, Policy and Management, 130 Mulford Hall, 345 Hilgard Hall,Berkeley, CA USA 94720-3110" -US-Snd,11246,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Joe Verfaillie -US-Snd,11246,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,AncContact -US-Snd,11246,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,jverfail@berkeley.edu -US-Snd,11246,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"University of California, Berkeley" -US-Snd,11246,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Department of Environmental Science, Policy and Management, 130 Mulford Hall, 345 Hilgard Hall,Berkeley, CA USA 94720-3110" -US-Snd,30335,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Patty Oikwawa -US-Snd,30335,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-Snd,30335,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,patty.oikawa@csueastbay.edu -US-Snd,30335,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"Cal State East Bay, Hayward, CA" -US-Snd,30334,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Matteo Detto -US-Snd,30334,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Affiliate -US-Snd,30334,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,teoparaglider@gmail.com -US-Snd,30334,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Smithsonian Tropical Research Institute -US-Snd,30334,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Smithsonian Tropical Research Institute, Unit 9100, Box 0948, DPO AA 34002-9998, USA" -US-Snd,29992,GRP_TOWER_POWER,TOWER_POWER,Direct power -US-Snd,29990,GRP_TOWER_TYPE,TOWER_TYPE,pole -US-Snd,11247,GRP_URL,URL,http://nature.berkeley.edu/biometlab/sites.php?tab=US-Snd -US-Snd,24000424,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-Snd -US-Snd,11248,GRP_UTC_OFFSET,UTC_OFFSET,-8 -US-Sne,30000,GRP_CLIM_AVG,MAT,16.09 -US-Sne,30000,GRP_CLIM_AVG,MAP,311 -US-Sne,30000,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Csa -US-Sne,27000675,GRP_COUNTRY,COUNTRY,USA -US-Sne,79338,GRP_DOI,DOI,10.17190/AMF/1418684 -US-Sne,79338,GRP_DOI,DOI_CITATION,"Robert Shortt, Kyle Hemes, Daphne Szutu, Joseph Verfaillie, Dennis Baldocchi (2021), AmeriFlux BASE US-Sne Sherman Island Restored Wetland, Ver. 7-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1418684" -US-Sne,79338,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-Sne,98295,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Sne,98295,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Robert Shortt -US-Sne,98295,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Sne,98295,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,1 -US-Sne,98295,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0001-5690-4656 -US-Sne,98295,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,robert_shortt@berkeley.edu -US-Sne,98295,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"University of California, Berkeley" -US-Sne,98295,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,20190714 -US-Sne,98295,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_END,20210902 -US-Sne,98281,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Sne,98281,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Kyle Hemes -US-Sne,98281,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Sne,98281,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,2 -US-Sne,98281,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0001-5090-1083 -US-Sne,98281,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,khemes@stanford.edu -US-Sne,98281,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"University of California, Berkeley" -US-Sne,98281,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,20160524 -US-Sne,98281,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_END,20190417 -US-Sne,98286,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Sne,98286,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Daphne Szutu -US-Sne,98286,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Sne,98286,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,3 -US-Sne,98286,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0001-7698-0461 -US-Sne,98286,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,daphneszutu@berkeley.edu -US-Sne,98286,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"University of California, Berkeley" -US-Sne,98286,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,201612 -US-Sne,98286,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_END,20210902 -US-Sne,98283,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Sne,98283,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Joseph Verfaillie -US-Sne,98283,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Sne,98283,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,8 -US-Sne,98283,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0002-7009-8942 -US-Sne,98283,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,jverfail@berkeley.edu -US-Sne,98283,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"University of California, Berkeley" -US-Sne,98283,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,20160524 -US-Sne,98283,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_END,20210902 -US-Sne,98277,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Sne,98277,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Dennis Baldocchi -US-Sne,98277,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Sne,98277,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,9 -US-Sne,98277,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0001-5090-1083 -US-Sne,98277,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,Baldocchi@berkeley.edu -US-Sne,98277,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"University of California, Berkeley" -US-Sne,98277,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,20160524 -US-Sne,98277,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_END,20210902 -US-Sne,33699,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,"University of California, Berkeley" -US-Sne,33699,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-Sne,33698,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Department of Water Resources -US-Sne,33698,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-Sne,30001,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Agriculture -US-Sne,30004,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Sne,30004,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-Sne,30004,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20160524 -US-Sne,30004,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Sne,30003,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Sne,30003,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CH4 -US-Sne,30003,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20160524 -US-Sne,30003,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Sne,30002,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Sne,30002,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-Sne,30002,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20160524 -US-Sne,30002,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Sne,23000675,GRP_HEADER,SITE_NAME,Sherman Island Restored Wetland -US-Sne,30005,GRP_IGBP,IGBP,GRA -US-Sne,30005,GRP_IGBP,IGBP_COMMENT,restored wetland with tules and cattails after flooding; pepperweed before flooding -US-Sne,30006,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-Sne,30006,GRP_LAND_OWNERSHIP,LAND_OWNER,Ca Dept Water Resources -US-Sne,30007,GRP_LOCATION,LOCATION_LAT,38.0369 -US-Sne,30007,GRP_LOCATION,LOCATION_LONG,-121.7547 -US-Sne,30007,GRP_LOCATION,LOCATION_ELEV,-5 -US-Sne,30007,GRP_LOCATION,LOCATION_DATE_START,201605240000 -US-Sne,30008,GRP_NETWORK,NETWORK,AmeriFlux -US-Sne,87006,GRP_NETWORK,NETWORK,Phenocam -US-Sne,1700000702,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(), 108350" -US-Sne,1700000702,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -US-Sne,1700000702,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Sne,1700007179,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Hemes, K. S., Chamberlain, S. D., Eichelmann, E., Anthony, T., Valach, A., Kasak, K., Szutu, D., Verfaillie, J., Silver, W. L., Baldocchi, D. D. (2019) Assessing The Carbon And Climate Benefit Of Restoring Degraded Agricultural Peat Soils To Managed Wetlands, Agricultural And Forest Meteorology, 268(), 202-214" -US-Sne,1700007179,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2019.01.017 -US-Sne,1700007179,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Sne,1700007719,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Hemes, K. S., Chamberlain, S. D., Eichelmann, E., Anthony, T., Valach, A., Kasak, K., Szutu, D., Verfaillie, J., Silver, W. L., Baldocchi, D. D. (2019) Assessing The Carbon And Climate Benefit Of Restoring Degraded Agricultural Peat Soils To Managed Wetlands, Agricultural And Forest Meteorology, 268(3), 202-214" -US-Sne,1700007719,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2019.01.017 -US-Sne,1700007719,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Sne,1700005649,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Valach, A. C., Kasak, K., Hemes, K. S., Anthony, T. L., Dronova, I., Taddeo, S., Silver, W. L., Szutu, D., Verfaillie, J., Baldocchi, D. D. (2021) Productive Wetlands Restored For Carbon Sequestration Quickly Become Net Co2 Sinks With Site-Level Factors Driving Uptake Variability, Plos One, 16(3), e0248398" -US-Sne,1700005649,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1371/JOURNAL.PONE.0248398 -US-Sne,1700005649,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Sne,1700001347,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Valach, Alex C. Kasak, Kuno Hemes, Kyle S. Szutu, Daphne Verfaillie, Joe Baldocchi, Dennis D. (2021) Carbon Flux Trajectories and Site Conditions from Restored Impounded Marshes in the Sacramento-San Joaquin Delta, Wetland Carbon and Environmental Management, 16(3), e0248398" -US-Sne,1700001347,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/9781119639305.CH13 -US-Sne,1700001347,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Sne,30011,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"wetland restoration, greenhouse gas fluxes" -US-Sne,30012,GRP_SITE_CHAR,TERRAIN,Flat -US-Sne,30012,GRP_SITE_CHAR,ASPECT,FLAT -US-Sne,30012,GRP_SITE_CHAR,WIND_DIRECTION,W -US-Sne,30012,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,1770 -US-Sne,30012,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,0 -US-Sne,91004,GRP_SITE_DESC,SITE_DESC,"A new restored wetland on the old Sherman Pasture site. The new tower is about 67m northwest (300deg) of the old tower site (US-Snd). On Jan 30, 2020 a temporary tower was set up in the western portion of Sherman Wetland to capture the more vegetated areas and compare with the main tower." -US-Sne,30014,GRP_SITE_FUNDING,SITE_FUNDING,Department of Water Resources -US-Sne,30015,GRP_STATE,STATE,CA -US-Sne,30018,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Dennis Baldocchi -US-Sne,30018,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Sne,30018,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,Baldocchi@berkeley.edu -US-Sne,30018,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"University of California, Berkeley" -US-Sne,30018,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Department of Environmental Science, Policy and Management, 130 Mulford Hall, 345 Hilgard Hall,Berkeley, CA USA 94720-3110" -US-Sne,87135,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Robert Shortt -US-Sne,87135,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-Sne,87135,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,robert_shortt@berkeley.edu -US-Sne,87135,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,UC Berkeley -US-Sne,87135,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"130 Mulford Hall, Berkeley, CA USA 94720" -US-Sne,30337,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Daphne Szutu -US-Sne,30337,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Technician -US-Sne,30337,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,daphneszutu@berkeley.edu -US-Sne,30337,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,UC Berkeley -US-Sne,30019,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Joe Verfaillie -US-Sne,30019,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Technician -US-Sne,30019,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,jverfail@berkeley.edu -US-Sne,30019,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"University of California, Berkeley" -US-Sne,30019,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Department of Environmental Science, Policy and Management, 137 Mulford Hall, 345 Hilgard Hall,Berkeley, CA USA 94720-3110" -US-Sne,30022,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-Sne,30020,GRP_TOWER_TYPE,TOWER_TYPE,walk-up -US-Sne,24000675,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-Sne -US-Sne,30021,GRP_UTC_OFFSET,UTC_OFFSET,-8 -US-Sne,30021,GRP_UTC_OFFSET,UTC_OFFSET_DATE_START,20160524 -US-Snf,84761,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,"Biometeorology Lab, University of California, Berkeley, PI: Dennis Baldocchi" -US-Snf,84762,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Csa -US-Snf,27000994,GRP_COUNTRY,COUNTRY,USA -US-Snf,90049,GRP_DOI,DOI,10.17190/AMF/1579718 -US-Snf,90049,GRP_DOI,DOI_CITATION,"Kuno Kusak, Camilo Rey Sanchez, Daphne Szutu, Dennis Baldocchi (2020), AmeriFlux BASE US-Snf Sherman Barn, Ver. 3-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1579718" -US-Snf,90049,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-Snf,94033,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Snf,94033,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Kuno Kusak -US-Snf,94033,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Snf,94033,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,1 -US-Snf,94033,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0002-0810-2154 -US-Snf,94033,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,kuno.kasak@ut.ee -US-Snf,94033,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of Taartu -US-Snf,94033,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,20180711 -US-Snf,94033,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_END,20190927 -US-Snf,94132,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Snf,94132,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Camilo Rey Sanchez -US-Snf,94132,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Snf,94132,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,2 -US-Snf,94132,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0003-4762-9001 -US-Snf,94132,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,rey.1@berkeley.edu -US-Snf,94132,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"University of California, Berkeley" -US-Snf,94132,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,20200129 -US-Snf,94132,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_END,20200709 -US-Snf,94049,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Snf,94049,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Daphne Szutu -US-Snf,94049,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Snf,94049,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,3 -US-Snf,94049,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0001-7698-0461 -US-Snf,94049,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,daphneszutu@berkeley.edu -US-Snf,94049,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"University of California, Berkeley" -US-Snf,94049,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,20180711 -US-Snf,94049,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_END,20200709 -US-Snf,94013,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Snf,94013,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Dennis Baldocchi -US-Snf,94013,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Snf,94013,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,9 -US-Snf,94013,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0001-5090-1083 -US-Snf,94013,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,baldocchi@berkeley.edu -US-Snf,94013,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"University of California, Berkeley" -US-Snf,94013,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,20180711 -US-Snf,94013,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_END,20200709 -US-Snf,90035,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,"University of California, Berkeley" -US-Snf,90035,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-Snf,90020,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,California Department of Water Resources -US-Snf,90020,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-Snf,84768,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Grazing -US-Snf,93026,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Snf,93026,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-Snf,93026,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20180719 -US-Snf,93026,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20200709 -US-Snf,93026,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Snf,93025,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Snf,93025,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CH4 -US-Snf,93025,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20180719 -US-Snf,93025,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20200709 -US-Snf,93025,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Snf,93024,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Snf,93024,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-Snf,93024,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20180719 -US-Snf,93024,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20200709 -US-Snf,93024,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Snf,23000994,GRP_HEADER,SITE_NAME,Sherman Barn -US-Snf,84779,GRP_IGBP,IGBP,GRA -US-Snf,84780,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-Snf,84780,GRP_LAND_OWNERSHIP,LAND_OWNER,California Department of Water Resources -US-Snf,94783,GRP_LOCATION,LOCATION_LAT,38.0402 -US-Snf,94783,GRP_LOCATION,LOCATION_LONG,-121.7272 -US-Snf,94783,GRP_LOCATION,LOCATION_ELEV,-4 -US-Snf,94783,GRP_LOCATION,LOCATION_DATE_START,20180711 -US-Snf,84764,GRP_NETWORK,NETWORK,AmeriFlux -US-Snf,87007,GRP_NETWORK,NETWORK,Phenocam -US-Snf,1700002001,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(), 108350" -US-Snf,1700002001,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -US-Snf,1700002001,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Snf,84781,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"The research approach of the University of California, Berkeley Biometeorology Laboratory involves the coordinated use of experimental measurements and theoretical models to understand the physical, biological, and chemical processes that control trace gas fluxes between the biosphere and atmosphere and to quantify their temporal and spatial variations. The research objectives of the Mayberry wetland, Sherman Wetland, East End, West Pond, East Pond, Bouldin alfalfa, Bouldin corn and Sherman barn sites are as follows: 1) Describe differences in the fluxes of CO2, CH4, H2O, and energy between different land uses; 2) Understand the mechanisms controlling these fluxes; 3) Use ecosystem modeling to understand controls on these mechanisms under different environmental scenarios. These eight sites were selected to capture a wide range of inundated conditions within the Sacramento-San Joaquin River Delta. The research focuses on the eddy covariance technique to measure CH4, CO2, H2O, and energy fluxes and works to combine measurements of both net fluxes and partitioned fluxes in order to achieve a mechanistic understanding of the ecological controls on current and future carbon flux in the Delta." -US-Snf,84773,GRP_SITE_CHAR,TERRAIN,Flat -US-Snf,84773,GRP_SITE_CHAR,ASPECT,FLAT -US-Snf,84773,GRP_SITE_CHAR,WIND_DIRECTION,W -US-Snf,84773,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,0 -US-Snf,84775,GRP_SITE_DESC,SITE_DESC,"The Sherman Barn is pasture site on Sherman Island, that is managed by the California Department of Water Resources (DWR). A flux tower equipped to analyze energy, H2O, CO2, and CH4 fluxes was installed on June, 2018" -US-Snf,84778,GRP_SITE_FUNDING,SITE_FUNDING,California Department of Water Resources -US-Snf,84763,GRP_STATE,STATE,CA -US-Snf,84766,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Dennis Baldocchi -US-Snf,84766,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Snf,84766,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,baldocchi@berkeley.edu -US-Snf,84766,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"University of California, Berkeley" -US-Snf,84766,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Department of Environmental Science, Policy and Management, 137 Mulford Hall, 345 Hilgard Hall,Berkeley, CA USA 94720-3110" -US-Snf,93031,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Camilo Rey-Sanchez -US-Snf,93031,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-Snf,93031,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,rey.1@berkeley.edu -US-Snf,93031,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"University of California, Berkeley" -US-Snf,84772,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Daphne Szutu -US-Snf,84772,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Technician -US-Snf,84772,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,daphneszutu@berkeley.edu -US-Snf,84772,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"University of California, Berkeley" -US-Snf,84777,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Joe Verfaillie -US-Snf,84777,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Technician -US-Snf,84777,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,jverfail@berkeley.edu -US-Snf,84777,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"University of California, Berkeley" -US-Snf,84765,GRP_TOWER_POWER,TOWER_POWER,Direct power -US-Snf,84769,GRP_TOWER_TYPE,TOWER_TYPE,pole -US-Snf,84774,GRP_URL,URL,https://nature.berkeley.edu/biometlab/sites.php?tab=US-Tw5 -US-Snf,24000994,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-Snf -US-Snf,84770,GRP_UTC_OFFSET,UTC_OFFSET,-8 -US-Snf,84770,GRP_UTC_OFFSET,UTC_OFFSET_DATE_START,201807190000 -US-SP1,29553,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER,23.9 -US-SP1,29553,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_ORGAN,Total -US-SP1,29553,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_PHEN,Mixed/unknown -US-SP1,29553,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_UNIT,gC m-2 -US-SP1,29553,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_DATE,2007 -US-SP1,27400,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB,230.3 -US-SP1,27400,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_ORGAN,Wood -US-SP1,27400,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_PHEN,Mixed/unknown -US-SP1,27400,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_UNIT,gC m-2 -US-SP1,27400,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_APPROACH,10 1m2 plots were clipped -US-SP1,27400,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_DATE,2007 -US-SP1,27401,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB,268.8 -US-SP1,27401,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_ORGAN,Total -US-SP1,27401,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_PHEN,Mixed/unknown -US-SP1,27401,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_UNIT,gC m-2 -US-SP1,27401,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_DATE,2007 -US-SP1,28008,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB,38.5 -US-SP1,28008,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_ORGAN,Foliage -US-SP1,28008,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_PHEN,Mixed/unknown -US-SP1,28008,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_UNIT,gC m-2 -US-SP1,28008,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_DATE,2007 -US-SP1,29229,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,131.5 -US-SP1,29229,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Foliage -US-SP1,29229,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-SP1,29229,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-SP1,29229,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,literrfall -US-SP1,29229,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2007 -US-SP1,28337,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,6846 -US-SP1,28337,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Wood -US-SP1,28337,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-SP1,28337,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-SP1,28337,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,Allometric equations developed on site were applied to dbh and height measurements -US-SP1,28337,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2007 -US-SP1,28007,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,6977.5 -US-SP1,28007,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Total -US-SP1,28007,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-SP1,28007,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-SP1,28007,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,Inventory on 4 625 m2 plots -US-SP1,28007,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2007 -US-SP1,29202,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS,842 -US-SP1,29202,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_UNIT,gC m-2 -US-SP1,29202,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_DATE,2007 -US-SP1,29202,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_COMMENT,842 ± 277 -US-SP1,29173,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT,124.2 -US-SP1,29173,GRP_AG_LIT_PROD,AG_LIT_PROD_UNIT,gC m-2 -US-SP1,28587,GRP_AG_PROD_OTHER,AG_PROD_OTHER,23.9 -US-SP1,28587,GRP_AG_PROD_OTHER,AG_PROD_OTHER_ORGAN,Total -US-SP1,28587,GRP_AG_PROD_OTHER,AG_PROD_OTHER_UNIT,gC m-2 -US-SP1,28587,GRP_AG_PROD_OTHER,AG_PROD_APPROACH,10 1m2 Clipping plots -US-SP1,28587,GRP_AG_PROD_OTHER,AG_PROD_DATE_START,2007 -US-SP1,26766,GRP_AG_PROD_SHRUB,AG_PROD_SHRUB,38.5 -US-SP1,26766,GRP_AG_PROD_SHRUB,AG_PROD_SHRUB_ORGAN,Foliage -US-SP1,26766,GRP_AG_PROD_SHRUB,AG_PROD_SHRUB_UNIT,gC m-2 -US-SP1,26766,GRP_AG_PROD_SHRUB,AG_PROD_APPROACH,10 1m2 Clipping plots -US-SP1,26766,GRP_AG_PROD_SHRUB,AG_PROD_DATE_START,2007 -US-SP1,26767,GRP_AG_PROD_SHRUB,AG_PROD_SHRUB,51.4 -US-SP1,26767,GRP_AG_PROD_SHRUB,AG_PROD_SHRUB_ORGAN,Wood -US-SP1,26767,GRP_AG_PROD_SHRUB,AG_PROD_SHRUB_UNIT,gC m-2 -US-SP1,26767,GRP_AG_PROD_SHRUB,AG_PROD_APPROACH,Clipping plots -US-SP1,26767,GRP_AG_PROD_SHRUB,AG_PROD_DATE_START,2007 -US-SP1,26768,GRP_AG_PROD_SHRUB,AG_PROD_SHRUB,89.9 -US-SP1,26768,GRP_AG_PROD_SHRUB,AG_PROD_SHRUB_ORGAN,Total -US-SP1,26768,GRP_AG_PROD_SHRUB,AG_PROD_SHRUB_UNIT,gC m-2 -US-SP1,26768,GRP_AG_PROD_SHRUB,AG_PROD_APPROACH,Clipping plots -US-SP1,26768,GRP_AG_PROD_SHRUB,AG_PROD_DATE_START,2007 -US-SP1,29058,GRP_AG_PROD_TREE,AG_PROD_TREE,131.5 -US-SP1,29058,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Foliage -US-SP1,29058,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-SP1,29058,GRP_AG_PROD_TREE,AG_PROD_APPROACH,10 1m2 litterfall traps -US-SP1,29058,GRP_AG_PROD_TREE,AG_PROD_DATE_START,2007 -US-SP1,27607,GRP_AG_PROD_TREE,AG_PROD_TREE,183.5 -US-SP1,27607,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Wood -US-SP1,27607,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-SP1,27607,GRP_AG_PROD_TREE,AG_PROD_APPROACH,Increments in biomass from inventory. -US-SP1,27607,GRP_AG_PROD_TREE,AG_PROD_DATE_START,2007 -US-SP1,29059,GRP_AG_PROD_TREE,AG_PROD_TREE,315 -US-SP1,29059,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Total -US-SP1,29059,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-SP1,29059,GRP_AG_PROD_TREE,AG_PROD_APPROACH,Increments in biomass plus foliage production. -US-SP1,29059,GRP_AG_PROD_TREE,AG_PROD_DATE_START,2007 -US-SP1,29204,GRP_BIOMASS_CHEM,BIOMASS_N,0.11 -US-SP1,29204,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-SP1,29204,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-SP1,29204,GRP_BIOMASS_CHEM,BIOMASS_SPP,(All) -US-SP1,6800,GRP_CLIM_AVG,MAT,20.06 -US-SP1,6800,GRP_CLIM_AVG,MAP,1309.77 -US-SP1,6800,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Cfa -US-SP1,27000430,GRP_COUNTRY,COUNTRY,USA -US-SP1,5380,GRP_DM_FIRE,DM_FIRE,Prescribed human induced underburn -US-SP1,5380,GRP_DM_FIRE,DM_DATE,2003 -US-SP1,6239,GRP_DM_FIRE,DM_FIRE,Prescribed human induced underburn -US-SP1,6239,GRP_DM_FIRE,DM_DATE,2006 -US-SP1,1135,GRP_DM_FORESTRY,DM_FORESTRY,Thinning/pruning -US-SP1,1135,GRP_DM_FORESTRY,DM_DATE,1991 -US-SP1,1135,GRP_DM_FORESTRY,DM_COMMENT,27% of basal area removed. -US-SP1,3675,GRP_DM_GENERAL,DM_GENERAL,Other -US-SP1,3675,GRP_DM_GENERAL,DM_DATE,1936 -US-SP1,3675,GRP_DM_GENERAL,DM_COMMENT,The site is on a 3 years understory fire cycle with the last fire in Jan 2006 -US-SP1,15709,GRP_DOI,DOI,10.17190/AMF/1246100 -US-SP1,15709,GRP_DOI,DOI_CITATION,"Tim Martin (2016), AmeriFlux BASE US-SP1 Slashpine-Austin Cary- 65yrs nat regen, Ver. 4-1, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1246100" -US-SP1,15709,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-SP1,32194,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-SP1,32194,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Tim Martin -US-SP1,32194,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-SP1,32194,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,tamartin@ufl.edu -US-SP1,32194,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of Florida -US-SP1,32196,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,University of Florida -US-SP1,32196,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-SP1,32195,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,"DOE/NIGEC, NASA, UF" -US-SP1,32195,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-SP1,3363,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Fire -US-SP1,8468,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Forestry -US-SP1,91808,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-SP1,91808,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-SP1,91808,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,200007 -US-SP1,91808,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-SP1,91797,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-SP1,91797,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-SP1,91797,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,200007 -US-SP1,91797,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-SP1,91792,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-SP1,91792,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-SP1,91792,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,200007 -US-SP1,91792,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-SP1,23000430,GRP_HEADER,SITE_NAME,Slashpine-Austin Cary- 65yrs nat regen -US-SP1,29057,GRP_HEIGHTC,HEIGHTC,24.2 -US-SP1,29057,GRP_HEIGHTC,HEIGHTC_DATE,2008 -US-SP1,6238,GRP_IGBP,IGBP,ENF -US-SP1,26774,GRP_LAI,LAI_TYPE,LAI -US-SP1,26775,GRP_LAI,LAI_TYPE,LAI -US-SP1,26776,GRP_LAI,LAI_TYPE,LAI -US-SP1,26777,GRP_LAI,LAI_TYPE,LAI -US-SP1,26778,GRP_LAI,LAI_TYPE,LAI -US-SP1,26779,GRP_LAI,LAI_TYPE,LAI -US-SP1,26780,GRP_LAI,LAI_TYPE,LAI -US-SP1,26917,GRP_LAI,LAI_TYPE,LAI -US-SP1,26918,GRP_LAI,LAI_TYPE,LAI -US-SP1,26919,GRP_LAI,LAI_TYPE,LAI -US-SP1,26920,GRP_LAI,LAI_TYPE,LAI -US-SP1,26921,GRP_LAI,LAI_TYPE,LAI -US-SP1,26922,GRP_LAI,LAI_TYPE,LAI -US-SP1,26923,GRP_LAI,LAI_TYPE,LAI -US-SP1,26924,GRP_LAI,LAI_TYPE,LAI -US-SP1,26925,GRP_LAI,LAI_TYPE,LAI -US-SP1,26926,GRP_LAI,LAI_TYPE,LAI -US-SP1,26927,GRP_LAI,LAI_TYPE,LAI -US-SP1,26928,GRP_LAI,LAI_TYPE,LAI -US-SP1,27069,GRP_LAI,LAI_TYPE,LAI -US-SP1,27070,GRP_LAI,LAI_TYPE,LAI -US-SP1,27071,GRP_LAI,LAI_TYPE,LAI -US-SP1,27072,GRP_LAI,LAI_TYPE,LAI -US-SP1,27073,GRP_LAI,LAI_TYPE,LAI -US-SP1,27358,GRP_LAI,LAI_TYPE,LAI -US-SP1,27359,GRP_LAI,LAI_TYPE,LAI -US-SP1,27360,GRP_LAI,LAI_TYPE,LAI -US-SP1,27361,GRP_LAI,LAI_TYPE,LAI -US-SP1,27362,GRP_LAI,LAI_TYPE,LAI -US-SP1,27363,GRP_LAI,LAI_TYPE,LAI -US-SP1,27364,GRP_LAI,LAI_TYPE,LAI -US-SP1,27613,GRP_LAI,LAI_TYPE,LAI -US-SP1,27614,GRP_LAI,LAI_TYPE,LAI -US-SP1,27615,GRP_LAI,LAI_TYPE,LAI -US-SP1,27616,GRP_LAI,LAI_TYPE,LAI -US-SP1,27617,GRP_LAI,LAI_TYPE,LAI -US-SP1,27618,GRP_LAI,LAI_TYPE,LAI -US-SP1,27982,GRP_LAI,LAI_TYPE,LAI -US-SP1,27983,GRP_LAI,LAI_TYPE,LAI -US-SP1,27984,GRP_LAI,LAI_TYPE,LAI -US-SP1,27985,GRP_LAI,LAI_TYPE,LAI -US-SP1,27986,GRP_LAI,LAI_TYPE,LAI -US-SP1,28332,GRP_LAI,LAI_TYPE,LAI -US-SP1,28333,GRP_LAI,LAI_TYPE,LAI -US-SP1,28334,GRP_LAI,LAI_TYPE,LAI -US-SP1,28335,GRP_LAI,LAI_TYPE,LAI -US-SP1,28336,GRP_LAI,LAI_TYPE,LAI -US-SP1,28593,GRP_LAI,LAI_TYPE,LAI -US-SP1,28594,GRP_LAI,LAI_TYPE,LAI -US-SP1,28595,GRP_LAI,LAI_TYPE,LAI -US-SP1,28596,GRP_LAI,LAI_TYPE,LAI -US-SP1,28597,GRP_LAI,LAI_TYPE,LAI -US-SP1,28598,GRP_LAI,LAI_TYPE,LAI -US-SP1,28599,GRP_LAI,LAI_TYPE,LAI -US-SP1,28600,GRP_LAI,LAI_TYPE,LAI -US-SP1,28832,GRP_LAI,LAI_TYPE,LAI -US-SP1,28833,GRP_LAI,LAI_TYPE,LAI -US-SP1,28834,GRP_LAI,LAI_TYPE,LAI -US-SP1,28835,GRP_LAI,LAI_TYPE,LAI -US-SP1,28836,GRP_LAI,LAI_TYPE,LAI -US-SP1,29066,GRP_LAI,LAI_TYPE,LAI -US-SP1,29067,GRP_LAI,LAI_TYPE,LAI -US-SP1,29177,GRP_LAI,LAI_TYPE,LAI -US-SP1,29178,GRP_LAI,LAI_TYPE,LAI -US-SP1,29179,GRP_LAI,LAI_TYPE,LAI -US-SP1,29180,GRP_LAI,LAI_TYPE,LAI -US-SP1,29181,GRP_LAI,LAI_TYPE,LAI -US-SP1,29182,GRP_LAI,LAI_TYPE,LAI -US-SP1,29183,GRP_LAI,LAI_TYPE,LAI -US-SP1,29184,GRP_LAI,LAI_TYPE,LAI -US-SP1,29185,GRP_LAI,LAI_TYPE,LAI -US-SP1,29186,GRP_LAI,LAI_TYPE,LAI -US-SP1,29194,GRP_LAI,LAI_TYPE,LAI -US-SP1,29195,GRP_LAI,LAI_TYPE,LAI -US-SP1,29196,GRP_LAI,LAI_TYPE,LAI -US-SP1,29197,GRP_LAI,LAI_TYPE,LAI -US-SP1,29198,GRP_LAI,LAI_TYPE,LAI -US-SP1,29199,GRP_LAI,LAI_TYPE,LAI -US-SP1,29200,GRP_LAI,LAI_TYPE,LAI -US-SP1,29527,GRP_LAI,LAI_TYPE,LAI -US-SP1,29528,GRP_LAI,LAI_TYPE,LAI -US-SP1,29529,GRP_LAI,LAI_TYPE,LAI -US-SP1,29530,GRP_LAI,LAI_TYPE,LAI -US-SP1,29531,GRP_LAI,LAI_TYPE,LAI -US-SP1,26774,GRP_LAI,LAI_METHOD,Litterfall -US-SP1,26775,GRP_LAI,LAI_METHOD,Litterfall -US-SP1,26776,GRP_LAI,LAI_METHOD,Litterfall -US-SP1,26777,GRP_LAI,LAI_METHOD,Litterfall -US-SP1,26778,GRP_LAI,LAI_METHOD,Litterfall -US-SP1,26779,GRP_LAI,LAI_METHOD,Litterfall -US-SP1,26780,GRP_LAI,LAI_METHOD,Litterfall -US-SP1,26917,GRP_LAI,LAI_METHOD,Litterfall -US-SP1,26918,GRP_LAI,LAI_METHOD,Litterfall -US-SP1,26919,GRP_LAI,LAI_METHOD,Litterfall -US-SP1,26920,GRP_LAI,LAI_METHOD,Litterfall -US-SP1,26921,GRP_LAI,LAI_METHOD,Litterfall -US-SP1,26922,GRP_LAI,LAI_METHOD,Litterfall -US-SP1,26923,GRP_LAI,LAI_METHOD,Litterfall -US-SP1,26924,GRP_LAI,LAI_METHOD,Litterfall -US-SP1,26925,GRP_LAI,LAI_METHOD,Litterfall -US-SP1,26926,GRP_LAI,LAI_METHOD,Litterfall -US-SP1,26927,GRP_LAI,LAI_METHOD,Litterfall -US-SP1,26928,GRP_LAI,LAI_METHOD,Litterfall -US-SP1,27069,GRP_LAI,LAI_METHOD,Litterfall -US-SP1,27070,GRP_LAI,LAI_METHOD,Litterfall -US-SP1,27071,GRP_LAI,LAI_METHOD,Litterfall -US-SP1,27072,GRP_LAI,LAI_METHOD,Litterfall -US-SP1,27073,GRP_LAI,LAI_METHOD,Litterfall -US-SP1,27358,GRP_LAI,LAI_METHOD,Litterfall -US-SP1,27359,GRP_LAI,LAI_METHOD,Litterfall -US-SP1,27360,GRP_LAI,LAI_METHOD,Litterfall -US-SP1,27361,GRP_LAI,LAI_METHOD,Litterfall -US-SP1,27362,GRP_LAI,LAI_METHOD,Litterfall -US-SP1,27363,GRP_LAI,LAI_METHOD,Litterfall -US-SP1,27364,GRP_LAI,LAI_METHOD,Litterfall -US-SP1,27613,GRP_LAI,LAI_METHOD,Litterfall -US-SP1,27614,GRP_LAI,LAI_METHOD,Litterfall -US-SP1,27615,GRP_LAI,LAI_METHOD,Litterfall -US-SP1,27616,GRP_LAI,LAI_METHOD,Litterfall -US-SP1,27617,GRP_LAI,LAI_METHOD,Litterfall -US-SP1,27618,GRP_LAI,LAI_METHOD,Litterfall -US-SP1,27982,GRP_LAI,LAI_METHOD,Litterfall -US-SP1,27983,GRP_LAI,LAI_METHOD,Litterfall -US-SP1,27984,GRP_LAI,LAI_METHOD,Litterfall -US-SP1,27985,GRP_LAI,LAI_METHOD,Litterfall -US-SP1,27986,GRP_LAI,LAI_METHOD,Litterfall -US-SP1,28332,GRP_LAI,LAI_METHOD,Litterfall -US-SP1,28333,GRP_LAI,LAI_METHOD,Litterfall -US-SP1,28334,GRP_LAI,LAI_METHOD,Litterfall -US-SP1,28335,GRP_LAI,LAI_METHOD,Litterfall -US-SP1,28336,GRP_LAI,LAI_METHOD,Litterfall -US-SP1,28593,GRP_LAI,LAI_METHOD,Litterfall -US-SP1,28594,GRP_LAI,LAI_METHOD,Litterfall -US-SP1,28595,GRP_LAI,LAI_METHOD,Litterfall -US-SP1,28596,GRP_LAI,LAI_METHOD,Litterfall -US-SP1,28597,GRP_LAI,LAI_METHOD,Litterfall -US-SP1,28598,GRP_LAI,LAI_METHOD,Litterfall -US-SP1,28599,GRP_LAI,LAI_METHOD,Litterfall -US-SP1,28600,GRP_LAI,LAI_METHOD,Litterfall -US-SP1,28832,GRP_LAI,LAI_METHOD,Litterfall -US-SP1,28833,GRP_LAI,LAI_METHOD,Litterfall -US-SP1,28834,GRP_LAI,LAI_METHOD,Litterfall -US-SP1,28835,GRP_LAI,LAI_METHOD,Litterfall -US-SP1,28836,GRP_LAI,LAI_METHOD,Litterfall -US-SP1,29066,GRP_LAI,LAI_METHOD,Litterfall -US-SP1,29067,GRP_LAI,LAI_METHOD,Litterfall -US-SP1,29177,GRP_LAI,LAI_METHOD,Litterfall -US-SP1,29178,GRP_LAI,LAI_METHOD,Litterfall 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-US-SP1,28333,GRP_LAI,LAI_TOT,3.69 -US-SP1,28596,GRP_LAI,LAI_TOT,3.74 -US-SP1,27613,GRP_LAI,LAI_TOT,3.77 -US-SP1,27614,GRP_LAI,LAI_TOT,3.81 -US-SP1,27986,GRP_LAI,LAI_TOT,3.85 -US-SP1,29197,GRP_LAI,LAI_TOT,3.93 -US-SP1,27073,GRP_LAI,LAI_TOT,3.95 -US-SP1,27358,GRP_LAI,LAI_TOT,3.95 -US-SP1,27359,GRP_LAI,LAI_TOT,3.95 -US-SP1,26922,GRP_LAI,LAI_TOT,3.96 -US-SP1,27985,GRP_LAI,LAI_TOT,4.01 -US-SP1,27069,GRP_LAI,LAI_TOT,4.03 -US-SP1,26919,GRP_LAI,LAI_TOT,4.04 -US-SP1,27070,GRP_LAI,LAI_TOT,4.05 -US-SP1,27617,GRP_LAI,LAI_TOT,4.11 -US-SP1,29527,GRP_LAI,LAI_TOT,4.13 -US-SP1,29184,GRP_LAI,LAI_TOT,4.14 -US-SP1,26778,GRP_LAI,LAI_TOT,4.25 -US-SP1,29067,GRP_LAI,LAI_TOT,4.29 -US-SP1,26920,GRP_LAI,LAI_TOT,4.39 -US-SP1,28833,GRP_LAI,LAI_TOT,4.42 -US-SP1,27615,GRP_LAI,LAI_TOT,4.48 -US-SP1,29198,GRP_LAI,LAI_TOT,4.52 -US-SP1,29179,GRP_LAI,LAI_TOT,4.54 -US-SP1,26921,GRP_LAI,LAI_TOT,4.57 -US-SP1,28335,GRP_LAI,LAI_TOT,4.61 -US-SP1,27072,GRP_LAI,LAI_TOT,4.63 -US-SP1,29183,GRP_LAI,LAI_TOT,4.73 -US-SP1,26779,GRP_LAI,LAI_TOT,4.83 -US-SP1,29182,GRP_LAI,LAI_TOT,4.95 -US-SP1,29185,GRP_LAI,LAI_TOT,5.16 -US-SP1,26926,GRP_LAI,LAI_TOT,5.22 -US-SP1,28334,GRP_LAI,LAI_TOT,5.31 -US-SP1,26925,GRP_LAI,LAI_TOT,5.50 -US-SP1,28835,GRP_LAI,LAI_TOT,5.50 -US-SP1,1134,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-SP1,1134,GRP_LAND_OWNERSHIP,LAND_OWNER,University of Florida -US-SP1,4981,GRP_LOCATION,LOCATION_LAT,29.7381 -US-SP1,4981,GRP_LOCATION,LOCATION_LONG,-82.2188 -US-SP1,4981,GRP_LOCATION,LOCATION_ELEV,50 -US-SP1,4981,GRP_LOCATION,LOCATION_COMMENT,http://public.ornl.gov/ameriflux/Site_Info/siteInfo.cfm?KEYID=us.slash_longleaf_regen.01 -US-SP1,29203,GRP_NEP,NEP,217040 -US-SP1,29203,GRP_NEP,NEP_APPROACH,Eddy covariance -US-SP1,29203,GRP_NEP,NEP_DATE_START,2006 -US-SP1,29203,GRP_NEP,NEP_DATE_END,2007 -US-SP1,29203,GRP_NEP,NEP_COMMENT,Measured using Eddy covariance -US-SP1,5546,GRP_NETWORK,NETWORK,AmeriFlux -US-SP1,87008,GRP_NETWORK,NETWORK,Phenocam -US-SP1,1700007716,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Burton, A. J., Pregitzer, K. S. (2002) Measurement Carbon Dioxide Concentration Does Not Affect Root Respiration Of Nine Tree Species In The Field, Tree Physiology, 22(1), 67-72" -US-SP1,1700007716,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1093/TREEPHYS/22.1.67 -US-SP1,1700007716,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-SP1,1700007083,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Castro, M. S., Gholz, H. L., Clark, K. L., Steudler, P. A. (2000) Effects Of Forest Harvesting On Soil Methane Fluxes In Florida Slash Pine Plantations, Canadian Journal Of Forest Research, 30(10), 1534-1542" -US-SP1,1700007083,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1139/CJFR-30-10-1534 -US-SP1,1700007083,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-SP1,1700002406,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Baldocchi, D. D., Poindexter, C., Abraha, M., Desai, A. R., Bohrer, G., Arain, M. A., Griffis, T., Blanken, P. D., O'Halloran, T. L., Thomas, R. Q., Zhang, Q., Burns, S. P., Frank, J. M., Christian, D., Brown, S., Black, T. A., Gough, C. M., Law, B. E., Lee, X., Chen, J., Reed, D. E., Massman, W. J., Clark, K., Hatfield, J., Prueger, J., Bracho, R., Baker, J. M., Martin, T. A. (2018) Temporal Dynamics Of Aerodynamic Canopy Height Derived From Eddy Covariance Momentum Flux Data Across North American Flux Networks, Geophysical Research Letters, 45(34), 9275–9287" -US-SP1,1700002406,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018GL079306 -US-SP1,1700002406,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-SP1,1700007311,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Baldocchi, D. D., Poindexter, C., Abraha, M., Desai, A. R., Bohrer, G., Arain, M. A., Griffis, T., Blanken, P. D., O'Halloran, T. L., Thomas, R. Q., Zhang, Q., Burns, S. P., Frank, J. M., Christian, D., Brown, S., Black, T. A., Gough, C. M., Law, B. E., Lee, X., Chen, J., Reed, D. E., Massman, W. J., Clark, K., Hatfield, J., Prueger, J., Bracho, R., Baker, J. M., Martin, T. A. (2018) Temporal Dynamics Of Aerodynamic Canopy Height Derived From Eddy Covariance Momentum Flux Data Across North American Flux Networks, Geophysical Research Letters, 45(4), 9275–9287" -US-SP1,1700007311,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018GL079306 -US-SP1,1700007311,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-SP1,1700000477,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(34), 108350" -US-SP1,1700000477,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -US-SP1,1700000477,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-SP1,1700007902,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Clark, K. L., Gholz, H. L., Castro, M. S. (2004) Carbon Dynamics Along A Chronosequence Of Slash Pine Plantations In North Florida, Ecological Applications, 14(4), 1154-1171" -US-SP1,1700007902,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1890/02-5391 -US-SP1,1700007902,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-SP1,1700008469,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Clark, K. L., Gholz, H. L., Moncrieff, J. B., Cropley, F., Loescher, H. W. (1999) Environmental Controls Over Net Exchanges Of Carbon Dioxide From Contrasting Florida Ecosystems, Ecological Applications, 9(3), 936-948" -US-SP1,1700008469,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.2307/2641340 -US-SP1,1700008469,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-SP1,1700003267,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Fang, C., Moncrieff, J. (1998) Simple And Fast Technique To Measure CO2 Profiles In Soil, Soil Biology And Biochemistry, 30(14), 2107-2112" -US-SP1,1700003267,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/S0038-0717(98)00088-1 -US-SP1,1700003267,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-SP1,1700008316,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Gholz, H. L., Clark, K. L. (2002) Energy Exchange Across A Chronosequence Of Slash Pine Forests In Florida, Agricultural And Forest Meteorology, 112(2), 87-102" -US-SP1,1700008316,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/S0168-1923(02)00059-X -US-SP1,1700008316,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-SP1,1700001803,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Gholz, H. L., Guerin, D. N., Cropper, W. P. (1999) Phenology And Productivity Of Saw Palmetto ( Serenoa Repens ) In A North Florida Slash Pine Plantation, Canadian Journal Of Forest Research, 29(8), 1248-1253" -US-SP1,1700001803,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1139/CJFR-29-8-1248 -US-SP1,1700001803,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-SP1,1700002232,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Gholz, H. L., Vogel, S. A., Cropper, W. P., McKelvey, K., Ewel, K. C., Teskey, R. O., Curran, P. J. (1991) Dynamics Of Canopy Structure And Light Interception In Pinus Elliottii Stands, North Florida, Ecological Monographs, 61(1), 33-51" -US-SP1,1700002232,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.2307/1942998 -US-SP1,1700002232,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-SP1,1700006798,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Guerrieri, R., Belmecheri, S., Ollinger, S. V., Asbjornsen, H., Jennings, K., Xiao, J., Stocker, B. D., Martin, M., Hollinger, D. Y., Bracho-Garrillo, R., Clark, K., Dore, S., Kolb, T., Munger, J. W., Novick, K., Richardson, A. D. (2019) Disentangling The Role Of Photosynthesis And Stomatal Conductance On Rising Forest Water-Use Efficiency, Proceedings Of The National Academy Of Sciences, 116(34), 16909-16914" -US-SP1,1700006798,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1073/PNAS.1905912116 -US-SP1,1700006798,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-SP1,1700007632,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Kim, J., Guo, Q., Baldocchi, D., Leclerc, M., Xu, L., Schmid, H. (2006) Upscaling Fluxes From Tower To Landscape: Overlaying Flux Footprints On High-Resolution (IKONOS) Images Of Vegetation Cover, Agricultural And Forest Meteorology, 136(3-4), 132-146" -US-SP1,1700007632,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2004.11.015 -US-SP1,1700007632,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-SP1,1700004209,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Moncrieff, J. B., Fang, C. (1999) A Model For Soil CO2 Production And Transport 2: Application To A Florida Pinus Elliotte Plantation, Agricultural And Forest Meteorology, 95(4), 237-256" -US-SP1,1700004209,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/S0168-1923(99)00035-0 -US-SP1,1700004209,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-SP1,1700003252,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"POWELL, T. L., GHOLZ, H. L., CLARK, K. L., STARR, G., CROPPER, W. P., MARTIN, T. A. (2008) Carbon Exchange Of A Mature, Naturally Regenerated Pine Forest In North Florida, Global Change Biology, 45(34), 9275–9287" -US-SP1,1700003252,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/J.1365-2486.2008.01675.X -US-SP1,1700003252,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-SP1,1700005085,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"POWELL, T. L., GHOLZ, H. L., CLARK, K. L., STARR, G., CROPPER, W. P., MARTIN, T. A. (2008) Carbon Exchange Of A Mature, Naturally Regenerated Pine Forest In North Florida, Global Change Biology, 45(4), 9275–9287" -US-SP1,1700005085,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/J.1365-2486.2008.01675.X -US-SP1,1700005085,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-SP1,1700005499,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Powell, T. L., Starr, G., Clark, K. L., Martin, T. A., Gholz, H. L. (2005) Ecosystem And Understory Water And Energy Exchange For A Mature, Naturally Regenerated Pine Flatwoods Forest In North Florida, Canadian Journal Of Forest Research, 35(7), 1568-1580" -US-SP1,1700005499,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1139/X05-075 -US-SP1,1700005499,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-SP1,1700006432,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Teskey, R. O., Gholz, H. L., Cropper, W. P. (1994) Influence Of Climate And Fertilization On Net Photosynthesis Of Mature Slash Pine, Tree Physiology, 14(11), 1215-1227" -US-SP1,1700006432,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1093/TREEPHYS/14.11.1215 -US-SP1,1700006432,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-SP1,3327,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"The research and science objectives of the Austin Cary site are as follows: 1) Characterize the C dynamics and annual carbon sequestration of a mature, naturally regenerated Florida pine flatwoods ecosystem; 2) Investigate the effects of precipitation and water stress on interannual variation in net ecosystem C exchange; 3) Determine the role of understory vegetation in ecosystem exchanges of water and energy; 4) Quantify ecosystem water and energy budgets and the determining environmental variables; 5) Determine the dominant environmental factors controlling the seasonal partitioning of net radiation into the main energy budget components of latent energy flux and sensible heat flux. (Powell et al., 2008, Powell et al., 2005)" -US-SP1,26764,GRP_SA,SA,80 -US-SP1,26764,GRP_SA,SA_COMMENT,Most of the dominat trees are 80 years old -US-SP1,728,GRP_SITE_CHAR,TERRAIN,Flat -US-SP1,2835,GRP_SITE_DESC,SITE_DESC,The ACMF site is a 67 hectare naturally regenerated Pinus palustris and Pinus elliottii mixed stand. -US-SP1,8421,GRP_SITE_FUNDING,SITE_FUNDING,"DOE/NIGEC, NASA, UF" -US-SP1,28326,GRP_SNAG_MASS,SNAG_MASS,49.6 -US-SP1,28326,GRP_SNAG_MASS,SNAG_MASS_UNIT,gC m-2 -US-SP1,28326,GRP_SNAG_MASS,SNAG_MASS_DATE,2008 -US-SP1,27184,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION,"Poorly drained ultic alaquods (sandy, silicecous, thermic) overlying a discontinuous spodic horizon spanning from 0.30 - 0.80 m deep transitioning to an argillic horizon at depths below 0.80 m" -US-SP1,27184,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION_TAXONOMY,Other -US-SP1,29060,GRP_SOIL_DEPTH,SOIL_DEPTH,300 -US-SP1,27977,GRP_SOIL_TEX,SOIL_TEX_SAND,99 -US-SP1,27977,GRP_SOIL_TEX,SOIL_TEX_SILT,0 -US-SP1,27977,GRP_SOIL_TEX,SOIL_TEX_CLAY,1 -US-SP1,26765,GRP_SPP_O,SPP_O,PIELE2 (NRCS plant code) -US-SP1,28826,GRP_SPP_O,SPP_O,PIPA2 (NRCS plant code) -US-SP1,26765,GRP_SPP_O,SPP_O_PERC,27 -US-SP1,28826,GRP_SPP_O,SPP_O_PERC,73 -US-SP1,26765,GRP_SPP_O,SPP_APPROACH,Inventory -US-SP1,28826,GRP_SPP_O,SPP_APPROACH,Inventory -US-SP1,26765,GRP_SPP_O,SPP_DATE,2008 -US-SP1,28826,GRP_SPP_O,SPP_DATE,2008 -US-SP1,27356,GRP_SPP_U,SPP_U,ARST5 (NRCS plant code) -US-SP1,27355,GRP_SPP_U,SPP_U,ILGL (NRCS plant code) -US-SP1,27976,GRP_SPP_U,SPP_U,MYCE (NRCS plant code) -US-SP1,29524,GRP_SPP_U,SPP_U,SERE2 (NRCS plant code) -US-SP1,27355,GRP_SPP_U,SPP_APPROACH,Clipping plots -US-SP1,27356,GRP_SPP_U,SPP_APPROACH,Clipping plots -US-SP1,27976,GRP_SPP_U,SPP_APPROACH,Clipping plots -US-SP1,29524,GRP_SPP_U,SPP_APPROACH,Clipping plots -US-SP1,27355,GRP_SPP_U,SPP_DATE,2008 -US-SP1,27356,GRP_SPP_U,SPP_DATE,2008 -US-SP1,27976,GRP_SPP_U,SPP_DATE,2008 -US-SP1,29524,GRP_SPP_U,SPP_DATE,2008 -US-SP1,3993,GRP_STATE,STATE,FL -US-SP1,91806,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Rosvel Bracho -US-SP1,91806,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-SP1,91806,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,rbracho@ufl.edu -US-SP1,91806,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Florida -US-SP1,91806,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"School of Forest Resources and Conservation, 224B Newins-Ziegler Hall,Gainesville, FL USA 32611" -US-SP1,91783,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Gregory Starr -US-SP1,91783,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Affiliate -US-SP1,91783,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,gstarr@ua.edu -US-SP1,91783,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,The University of Alabama -US-SP1,5924,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Henry L. Gholz -US-SP1,5924,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Affiliate -US-SP1,5924,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,hgholz@nsf.edu -US-SP1,5924,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,National Science Foundation -US-SP1,5924,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Long-Term Ecological Research, 4201 Wilson Boulevard,Arlington, VA USA 22230" -US-SP1,91791,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Tim Martin -US-SP1,91791,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Affiliate -US-SP1,91791,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,tamartin@ufl.edu -US-SP1,91791,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Florida -US-SP1,91791,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"P.O. Box 110410, 326 Newins Ziegler Hall,Gainesville, FL USA 32611-0410" -US-SP1,741,GRP_URL,URL,http://carboncenter.ifas.ufl.edu/ameriflux.shtml -US-SP1,24000430,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-SP1 -US-SP1,9601,GRP_UTC_OFFSET,UTC_OFFSET,-5 -US-SP1,28827,GRP_WD_BIOMASS,WD_BIOMASS_CRS,86.9 -US-SP1,28827,GRP_WD_BIOMASS,WD_BIOMASS_UNIT,gC m-2 -US-SP1,28827,GRP_WD_BIOMASS,WD_BIOMASS_DATE,2007 -US-SP1,28827,GRP_WD_BIOMASS,WD_BIOMASS_COMMENT,Total in one year -US-SP2,28354,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER,1.1 -US-SP2,28354,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_ORGAN,Total -US-SP2,28354,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_PHEN,Mixed/unknown -US-SP2,28354,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_UNIT,gC m-2 -US-SP2,28354,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_DATE,2007 -US-SP2,26930,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB,70 -US-SP2,26930,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_ORGAN,Wood -US-SP2,26930,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_PHEN,Mixed/unknown -US-SP2,26930,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_UNIT,gC m-2 -US-SP2,26930,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_APPROACH,10 1m2 plots were clipped -US-SP2,26930,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_DATE,2007 -US-SP2,27619,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB,79.5 -US-SP2,27619,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_ORGAN,Total -US-SP2,27619,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_PHEN,Mixed/unknown -US-SP2,27619,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_UNIT,gC m-2 -US-SP2,27619,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_DATE,2007 -US-SP2,26929,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB,9.5 -US-SP2,26929,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_ORGAN,Foliage -US-SP2,26929,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_PHEN,Mixed/unknown -US-SP2,26929,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_UNIT,gC m-2 -US-SP2,26929,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_DATE,2007 -US-SP2,27643,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,197.5 -US-SP2,27643,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Foliage -US-SP2,27643,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-SP2,27643,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-SP2,27643,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,literrfall -US-SP2,27643,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2007 -US-SP2,28338,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,2182 -US-SP2,28338,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Wood -US-SP2,28338,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-SP2,28338,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-SP2,28338,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,Allometric equations developed on site were applied to dbh and height measurements -US-SP2,28338,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2007 -US-SP2,29188,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,2379.5 -US-SP2,29188,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Total -US-SP2,29188,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-SP2,29188,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-SP2,29188,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,Inventory on 4 625 m2 plots -US-SP2,29188,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2007 -US-SP2,26913,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT,182.3 -US-SP2,26913,GRP_AG_LIT_PROD,AG_LIT_PROD_UNIT,gC m-2 -US-SP2,26913,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_START,2006 -US-SP2,26913,GRP_AG_LIT_PROD,AG_LIT_PROD_COMMENT,Value measured in 2006 -US-SP2,29062,GRP_AG_PROD_OTHER,AG_PROD_OTHER,28.94 -US-SP2,29062,GRP_AG_PROD_OTHER,AG_PROD_OTHER_ORGAN,Total -US-SP2,29062,GRP_AG_PROD_OTHER,AG_PROD_OTHER_UNIT,gC m-2 -US-SP2,29062,GRP_AG_PROD_OTHER,AG_PROD_APPROACH,10 1m2 Clipping plots -US-SP2,29062,GRP_AG_PROD_OTHER,AG_PROD_DATE_START,2007 -US-SP2,29526,GRP_AG_PROD_SHRUB,AG_PROD_SHRUB,38.6 -US-SP2,29526,GRP_AG_PROD_SHRUB,AG_PROD_SHRUB_ORGAN,Wood -US-SP2,29526,GRP_AG_PROD_SHRUB,AG_PROD_SHRUB_UNIT,gC m-2 -US-SP2,29526,GRP_AG_PROD_SHRUB,AG_PROD_APPROACH,Clipping plots -US-SP2,29526,GRP_AG_PROD_SHRUB,AG_PROD_DATE_START,2007 -US-SP2,27067,GRP_AG_PROD_SHRUB,AG_PROD_SHRUB,48 -US-SP2,27067,GRP_AG_PROD_SHRUB,AG_PROD_SHRUB_ORGAN,Total -US-SP2,27067,GRP_AG_PROD_SHRUB,AG_PROD_SHRUB_UNIT,gC m-2 -US-SP2,27067,GRP_AG_PROD_SHRUB,AG_PROD_APPROACH,Clipping plots -US-SP2,27067,GRP_AG_PROD_SHRUB,AG_PROD_DATE_START,2007 -US-SP2,28327,GRP_AG_PROD_SHRUB,AG_PROD_SHRUB,9.4 -US-SP2,28327,GRP_AG_PROD_SHRUB,AG_PROD_SHRUB_ORGAN,Foliage -US-SP2,28327,GRP_AG_PROD_SHRUB,AG_PROD_SHRUB_UNIT,gC m-2 -US-SP2,28327,GRP_AG_PROD_SHRUB,AG_PROD_APPROACH,10 1m2 Clipping plots -US-SP2,28327,GRP_AG_PROD_SHRUB,AG_PROD_DATE_START,2007 -US-SP2,29061,GRP_AG_PROD_TREE,AG_PROD_TREE,197.5 -US-SP2,29061,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Foliage -US-SP2,29061,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-SP2,29061,GRP_AG_PROD_TREE,AG_PROD_APPROACH,10 1m2 litterfall traps -US-SP2,29061,GRP_AG_PROD_TREE,AG_PROD_DATE_START,2007 -US-SP2,27978,GRP_AG_PROD_TREE,AG_PROD_TREE,520.5 -US-SP2,27978,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Wood -US-SP2,27978,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-SP2,27978,GRP_AG_PROD_TREE,AG_PROD_APPROACH,Increments in biomass from inventory. -US-SP2,27978,GRP_AG_PROD_TREE,AG_PROD_DATE_START,2007 -US-SP2,28588,GRP_AG_PROD_TREE,AG_PROD_TREE,718 -US-SP2,28588,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Total -US-SP2,28588,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-SP2,28588,GRP_AG_PROD_TREE,AG_PROD_APPROACH,Increments in biomass plus foliage production. -US-SP2,28588,GRP_AG_PROD_TREE,AG_PROD_DATE_START,2007 -US-SP2,27620,GRP_BIOMASS_CHEM,BIOMASS_N,0.095 -US-SP2,27620,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-SP2,27620,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-SP2,27620,GRP_BIOMASS_CHEM,BIOMASS_SPP,(All) -US-SP2,3418,GRP_CLIM_AVG,MAT,20.07 -US-SP2,3418,GRP_CLIM_AVG,MAP,1314.41 -US-SP2,3418,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Cfa -US-SP2,27000431,GRP_COUNTRY,COUNTRY,USA -US-SP2,7965,GRP_DM_FERT_M,DM_FERT_M,Other -US-SP2,7965,GRP_DM_FERT_M,DM_DATE,20021001 -US-SP2,7965,GRP_DM_FERT_M,DM_COMMENT,40 Kg ha-1 N; 45 Kg ha-1 P; Fall -US-SP2,2004,GRP_DM_FORESTRY,DM_FORESTRY,Clearcutting -US-SP2,2004,GRP_DM_FORESTRY,DM_DATE,19970501 -US-SP2,2004,GRP_DM_FORESTRY,DM_COMMENT,Stem only harvest in a 25 years old slash pine plantation; dates from 05/1997 to 01/1998 -US-SP2,9652,GRP_DM_PLANTING,DM_PLANTING,Planting live trees -US-SP2,9652,GRP_DM_PLANTING,DM_DATE,19981201 -US-SP2,9652,GRP_DM_PLANTING,DM_COMMENT,Prior to planting the site was double bedded and herbicided. It was planted at ~ 1800 trees ha-1 -US-SP2,15689,GRP_DOI,DOI,10.17190/AMF/1246101 -US-SP2,15689,GRP_DOI,DOI_CITATION,"Tim Martin (2016), AmeriFlux BASE US-SP2 Slashpine-Mize-clearcut-3yr,regen, Ver. 3-1, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1246101" -US-SP2,15689,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-SP2,32197,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-SP2,32197,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Tim Martin -US-SP2,32197,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-SP2,32197,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,tamartin@ufl.edu -US-SP2,32197,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of Florida -US-SP2,32199,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,University of Florida -US-SP2,32199,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-SP2,32198,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,DOE/NIGEC -US-SP2,32198,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-SP2,5920,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Forestry -US-SP2,91796,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-SP2,91796,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-SP2,91796,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,199909 -US-SP2,91796,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,200903 -US-SP2,91796,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-SP2,91794,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-SP2,91794,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-SP2,91794,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,199909 -US-SP2,91794,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,200903 -US-SP2,91794,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-SP2,91782,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-SP2,91782,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-SP2,91782,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,199909 -US-SP2,91782,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,200903 -US-SP2,91782,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-SP2,23000431,GRP_HEADER,SITE_NAME,"Slashpine-Mize-clearcut-3yr,regen" -US-SP2,29525,GRP_HEIGHTC,HEIGHTC,10.1 -US-SP2,29525,GRP_HEIGHTC,HEIGHTC_DATE,2008 -US-SP2,29525,GRP_HEIGHTC,HEIGHTC_COMMENT,Value obtained from Inventory -US-SP2,9650,GRP_IGBP,IGBP,ENF -US-SP2,26781,GRP_LAI,LAI_TYPE,LAI -US-SP2,26788,GRP_LAI,LAI_TYPE,LAI -US-SP2,26789,GRP_LAI,LAI_TYPE,LAI -US-SP2,26790,GRP_LAI,LAI_TYPE,LAI -US-SP2,26791,GRP_LAI,LAI_TYPE,LAI -US-SP2,26792,GRP_LAI,LAI_TYPE,LAI -US-SP2,26793,GRP_LAI,LAI_TYPE,LAI -US-SP2,26794,GRP_LAI,LAI_TYPE,LAI -US-SP2,26795,GRP_LAI,LAI_TYPE,LAI -US-SP2,26796,GRP_LAI,LAI_TYPE,LAI -US-SP2,27074,GRP_LAI,LAI_TYPE,LAI -US-SP2,27082,GRP_LAI,LAI_TYPE,LAI -US-SP2,27083,GRP_LAI,LAI_TYPE,LAI -US-SP2,27084,GRP_LAI,LAI_TYPE,LAI -US-SP2,27085,GRP_LAI,LAI_TYPE,LAI -US-SP2,27086,GRP_LAI,LAI_TYPE,LAI -US-SP2,27087,GRP_LAI,LAI_TYPE,LAI -US-SP2,27383,GRP_LAI,LAI_TYPE,LAI -US-SP2,27384,GRP_LAI,LAI_TYPE,LAI -US-SP2,27385,GRP_LAI,LAI_TYPE,LAI -US-SP2,27386,GRP_LAI,LAI_TYPE,LAI -US-SP2,27630,GRP_LAI,LAI_TYPE,LAI -US-SP2,27631,GRP_LAI,LAI_TYPE,LAI -US-SP2,27632,GRP_LAI,LAI_TYPE,LAI -US-SP2,27633,GRP_LAI,LAI_TYPE,LAI -US-SP2,27634,GRP_LAI,LAI_TYPE,LAI -US-SP2,27635,GRP_LAI,LAI_TYPE,LAI -US-SP2,27734,GRP_LAI,LAI_TYPE,LAI -US-SP2,27735,GRP_LAI,LAI_TYPE,LAI -US-SP2,27993,GRP_LAI,LAI_TYPE,LAI -US-SP2,27994,GRP_LAI,LAI_TYPE,LAI -US-SP2,27995,GRP_LAI,LAI_TYPE,LAI -US-SP2,27996,GRP_LAI,LAI_TYPE,LAI -US-SP2,27997,GRP_LAI,LAI_TYPE,LAI -US-SP2,27998,GRP_LAI,LAI_TYPE,LAI -US-SP2,28342,GRP_LAI,LAI_TYPE,LAI -US-SP2,28343,GRP_LAI,LAI_TYPE,LAI -US-SP2,28344,GRP_LAI,LAI_TYPE,LAI -US-SP2,28345,GRP_LAI,LAI_TYPE,LAI -US-SP2,28607,GRP_LAI,LAI_TYPE,LAI -US-SP2,28608,GRP_LAI,LAI_TYPE,LAI -US-SP2,28609,GRP_LAI,LAI_TYPE,LAI -US-SP2,28610,GRP_LAI,LAI_TYPE,LAI -US-SP2,28611,GRP_LAI,LAI_TYPE,LAI -US-SP2,28612,GRP_LAI,LAI_TYPE,LAI -US-SP2,28837,GRP_LAI,LAI_TYPE,LAI -US-SP2,28847,GRP_LAI,LAI_TYPE,LAI -US-SP2,28848,GRP_LAI,LAI_TYPE,LAI -US-SP2,28849,GRP_LAI,LAI_TYPE,LAI -US-SP2,28850,GRP_LAI,LAI_TYPE,LAI -US-SP2,28851,GRP_LAI,LAI_TYPE,LAI -US-SP2,29187,GRP_LAI,LAI_TYPE,LAI -US-SP2,29201,GRP_LAI,LAI_TYPE,LAI -US-SP2,29214,GRP_LAI,LAI_TYPE,LAI -US-SP2,29215,GRP_LAI,LAI_TYPE,LAI -US-SP2,29216,GRP_LAI,LAI_TYPE,LAI -US-SP2,29217,GRP_LAI,LAI_TYPE,LAI -US-SP2,29218,GRP_LAI,LAI_TYPE,LAI -US-SP2,29219,GRP_LAI,LAI_TYPE,LAI -US-SP2,29320,GRP_LAI,LAI_TYPE,LAI -US-SP2,29321,GRP_LAI,LAI_TYPE,LAI -US-SP2,29322,GRP_LAI,LAI_TYPE,LAI -US-SP2,29323,GRP_LAI,LAI_TYPE,LAI -US-SP2,29324,GRP_LAI,LAI_TYPE,LAI -US-SP2,29325,GRP_LAI,LAI_TYPE,LAI -US-SP2,29326,GRP_LAI,LAI_TYPE,LAI -US-SP2,29327,GRP_LAI,LAI_TYPE,LAI -US-SP2,29532,GRP_LAI,LAI_TYPE,LAI -US-SP2,29537,GRP_LAI,LAI_TYPE,LAI -US-SP2,29538,GRP_LAI,LAI_TYPE,LAI -US-SP2,29539,GRP_LAI,LAI_TYPE,LAI -US-SP2,26781,GRP_LAI,LAI_METHOD,Litterfall -US-SP2,26788,GRP_LAI,LAI_METHOD,Litterfall -US-SP2,26789,GRP_LAI,LAI_METHOD,Litterfall -US-SP2,26790,GRP_LAI,LAI_METHOD,Litterfall -US-SP2,26791,GRP_LAI,LAI_METHOD,Litterfall -US-SP2,26792,GRP_LAI,LAI_METHOD,Litterfall -US-SP2,26793,GRP_LAI,LAI_METHOD,Litterfall -US-SP2,26794,GRP_LAI,LAI_METHOD,Litterfall -US-SP2,26795,GRP_LAI,LAI_METHOD,Litterfall -US-SP2,26796,GRP_LAI,LAI_METHOD,Litterfall -US-SP2,27074,GRP_LAI,LAI_METHOD,Litterfall -US-SP2,27082,GRP_LAI,LAI_METHOD,Litterfall -US-SP2,27083,GRP_LAI,LAI_METHOD,Litterfall -US-SP2,27084,GRP_LAI,LAI_METHOD,Litterfall -US-SP2,27085,GRP_LAI,LAI_METHOD,Litterfall -US-SP2,27086,GRP_LAI,LAI_METHOD,Litterfall -US-SP2,27087,GRP_LAI,LAI_METHOD,Litterfall -US-SP2,27383,GRP_LAI,LAI_METHOD,Litterfall -US-SP2,27384,GRP_LAI,LAI_METHOD,Litterfall -US-SP2,27385,GRP_LAI,LAI_METHOD,Litterfall -US-SP2,27386,GRP_LAI,LAI_METHOD,Litterfall -US-SP2,27630,GRP_LAI,LAI_METHOD,Litterfall -US-SP2,27631,GRP_LAI,LAI_METHOD,Litterfall -US-SP2,27632,GRP_LAI,LAI_METHOD,Litterfall -US-SP2,27633,GRP_LAI,LAI_METHOD,Litterfall -US-SP2,27634,GRP_LAI,LAI_METHOD,Litterfall -US-SP2,27635,GRP_LAI,LAI_METHOD,Litterfall -US-SP2,27734,GRP_LAI,LAI_METHOD,Litterfall -US-SP2,27735,GRP_LAI,LAI_METHOD,Litterfall -US-SP2,27993,GRP_LAI,LAI_METHOD,Litterfall -US-SP2,27994,GRP_LAI,LAI_METHOD,Litterfall -US-SP2,27995,GRP_LAI,LAI_METHOD,Litterfall -US-SP2,27996,GRP_LAI,LAI_METHOD,Litterfall -US-SP2,27997,GRP_LAI,LAI_METHOD,Litterfall -US-SP2,27998,GRP_LAI,LAI_METHOD,Litterfall -US-SP2,28342,GRP_LAI,LAI_METHOD,Litterfall -US-SP2,28343,GRP_LAI,LAI_METHOD,Litterfall -US-SP2,28344,GRP_LAI,LAI_METHOD,Litterfall -US-SP2,28345,GRP_LAI,LAI_METHOD,Litterfall -US-SP2,28607,GRP_LAI,LAI_METHOD,Litterfall -US-SP2,28608,GRP_LAI,LAI_METHOD,Litterfall -US-SP2,28609,GRP_LAI,LAI_METHOD,Litterfall -US-SP2,28610,GRP_LAI,LAI_METHOD,Litterfall -US-SP2,28611,GRP_LAI,LAI_METHOD,Litterfall -US-SP2,28612,GRP_LAI,LAI_METHOD,Litterfall -US-SP2,28837,GRP_LAI,LAI_METHOD,Litterfall -US-SP2,28847,GRP_LAI,LAI_METHOD,Litterfall -US-SP2,28848,GRP_LAI,LAI_METHOD,Litterfall -US-SP2,28849,GRP_LAI,LAI_METHOD,Litterfall -US-SP2,28850,GRP_LAI,LAI_METHOD,Litterfall -US-SP2,28851,GRP_LAI,LAI_METHOD,Litterfall -US-SP2,29187,GRP_LAI,LAI_METHOD,Litterfall -US-SP2,29201,GRP_LAI,LAI_METHOD,Litterfall -US-SP2,29214,GRP_LAI,LAI_METHOD,Litterfall -US-SP2,29215,GRP_LAI,LAI_METHOD,Litterfall -US-SP2,29216,GRP_LAI,LAI_METHOD,Litterfall -US-SP2,29217,GRP_LAI,LAI_METHOD,Litterfall -US-SP2,29218,GRP_LAI,LAI_METHOD,Litterfall -US-SP2,29219,GRP_LAI,LAI_METHOD,Litterfall -US-SP2,29320,GRP_LAI,LAI_METHOD,Litterfall -US-SP2,29321,GRP_LAI,LAI_METHOD,Litterfall -US-SP2,29322,GRP_LAI,LAI_METHOD,Litterfall -US-SP2,29323,GRP_LAI,LAI_METHOD,Litterfall -US-SP2,29324,GRP_LAI,LAI_METHOD,Litterfall -US-SP2,29325,GRP_LAI,LAI_METHOD,Litterfall -US-SP2,29326,GRP_LAI,LAI_METHOD,Litterfall -US-SP2,29327,GRP_LAI,LAI_METHOD,Litterfall -US-SP2,29532,GRP_LAI,LAI_METHOD,Litterfall -US-SP2,29537,GRP_LAI,LAI_METHOD,Litterfall -US-SP2,29538,GRP_LAI,LAI_METHOD,Litterfall -US-SP2,29539,GRP_LAI,LAI_METHOD,Litterfall -US-SP2,26781,GRP_LAI,LAI_DATE,20010301 -US-SP2,28837,GRP_LAI,LAI_DATE,20010401 -US-SP2,27074,GRP_LAI,LAI_DATE,20010501 -US-SP2,29187,GRP_LAI,LAI_DATE,20010601 -US-SP2,29201,GRP_LAI,LAI_DATE,20010701 -US-SP2,29532,GRP_LAI,LAI_DATE,20010801 -US-SP2,29214,GRP_LAI,LAI_DATE,20010901 -US-SP2,29320,GRP_LAI,LAI_DATE,20011001 -US-SP2,27082,GRP_LAI,LAI_DATE,20011101 -US-SP2,28607,GRP_LAI,LAI_DATE,20011201 -US-SP2,27993,GRP_LAI,LAI_DATE,2002 -US-SP2,28608,GRP_LAI,LAI_DATE,20020201 -US-SP2,27994,GRP_LAI,LAI_DATE,20020301 -US-SP2,27083,GRP_LAI,LAI_DATE,20020401 -US-SP2,29321,GRP_LAI,LAI_DATE,20020501 -US-SP2,29215,GRP_LAI,LAI_DATE,20020601 -US-SP2,29322,GRP_LAI,LAI_DATE,20020701 -US-SP2,26788,GRP_LAI,LAI_DATE,20020801 -US-SP2,28847,GRP_LAI,LAI_DATE,20020901 -US-SP2,26789,GRP_LAI,LAI_DATE,20021001 -US-SP2,27734,GRP_LAI,LAI_DATE,20021101 -US-SP2,29323,GRP_LAI,LAI_DATE,20021201 -US-SP2,27084,GRP_LAI,LAI_DATE,2003 -US-SP2,27630,GRP_LAI,LAI_DATE,20030201 -US-SP2,27085,GRP_LAI,LAI_DATE,20030301 -US-SP2,29324,GRP_LAI,LAI_DATE,20030401 -US-SP2,28609,GRP_LAI,LAI_DATE,20030501 -US-SP2,27383,GRP_LAI,LAI_DATE,20030601 -US-SP2,27384,GRP_LAI,LAI_DATE,20030701 -US-SP2,28610,GRP_LAI,LAI_DATE,20030801 -US-SP2,29537,GRP_LAI,LAI_DATE,20030901 -US-SP2,29216,GRP_LAI,LAI_DATE,20031001 -US-SP2,27631,GRP_LAI,LAI_DATE,20031101 -US-SP2,29217,GRP_LAI,LAI_DATE,20031201 -US-SP2,28848,GRP_LAI,LAI_DATE,2004 -US-SP2,28849,GRP_LAI,LAI_DATE,20040201 -US-SP2,26790,GRP_LAI,LAI_DATE,20040301 -US-SP2,26791,GRP_LAI,LAI_DATE,20040401 -US-SP2,28342,GRP_LAI,LAI_DATE,20040501 -US-SP2,27632,GRP_LAI,LAI_DATE,20040601 -US-SP2,29218,GRP_LAI,LAI_DATE,20040701 -US-SP2,27633,GRP_LAI,LAI_DATE,20040801 -US-SP2,28611,GRP_LAI,LAI_DATE,20040901 -US-SP2,27385,GRP_LAI,LAI_DATE,20041001 -US-SP2,27386,GRP_LAI,LAI_DATE,20041101 -US-SP2,28612,GRP_LAI,LAI_DATE,20041201 -US-SP2,29538,GRP_LAI,LAI_DATE,2005 -US-SP2,28343,GRP_LAI,LAI_DATE,20050201 -US-SP2,27634,GRP_LAI,LAI_DATE,20050301 -US-SP2,27086,GRP_LAI,LAI_DATE,20050401 -US-SP2,29539,GRP_LAI,LAI_DATE,20050501 -US-SP2,26792,GRP_LAI,LAI_DATE,20050601 -US-SP2,28850,GRP_LAI,LAI_DATE,20050701 -US-SP2,26793,GRP_LAI,LAI_DATE,20050801 -US-SP2,26794,GRP_LAI,LAI_DATE,20050901 -US-SP2,29325,GRP_LAI,LAI_DATE,20051001 -US-SP2,28344,GRP_LAI,LAI_DATE,20051101 -US-SP2,29326,GRP_LAI,LAI_DATE,20051201 -US-SP2,28345,GRP_LAI,LAI_DATE,2006 -US-SP2,27995,GRP_LAI,LAI_DATE,20060201 -US-SP2,27996,GRP_LAI,LAI_DATE,20060301 -US-SP2,27997,GRP_LAI,LAI_DATE,20060401 -US-SP2,27998,GRP_LAI,LAI_DATE,20060501 -US-SP2,29219,GRP_LAI,LAI_DATE,20060601 -US-SP2,27635,GRP_LAI,LAI_DATE,20060701 -US-SP2,27087,GRP_LAI,LAI_DATE,20060801 -US-SP2,29327,GRP_LAI,LAI_DATE,20060901 -US-SP2,28851,GRP_LAI,LAI_DATE,20061001 -US-SP2,27735,GRP_LAI,LAI_DATE,20061101 -US-SP2,26795,GRP_LAI,LAI_DATE,20061201 -US-SP2,26796,GRP_LAI,LAI_DATE,2007 -US-SP2,26781,GRP_LAI,LAI_TOT,0.29 -US-SP2,28837,GRP_LAI,LAI_TOT,0.34 -US-SP2,27074,GRP_LAI,LAI_TOT,0.47 -US-SP2,29187,GRP_LAI,LAI_TOT,0.69 -US-SP2,28608,GRP_LAI,LAI_TOT,0.83 -US-SP2,27993,GRP_LAI,LAI_TOT,0.86 -US-SP2,27994,GRP_LAI,LAI_TOT,0.89 -US-SP2,28607,GRP_LAI,LAI_TOT,0.89 -US-SP2,29201,GRP_LAI,LAI_TOT,0.91 -US-SP2,27082,GRP_LAI,LAI_TOT,0.95 -US-SP2,27083,GRP_LAI,LAI_TOT,0.99 -US-SP2,29320,GRP_LAI,LAI_TOT,1.03 -US-SP2,29532,GRP_LAI,LAI_TOT,1.03 -US-SP2,29214,GRP_LAI,LAI_TOT,1.05 -US-SP2,29321,GRP_LAI,LAI_TOT,1.30 -US-SP2,29215,GRP_LAI,LAI_TOT,1.85 -US-SP2,27630,GRP_LAI,LAI_TOT,1.94 -US-SP2,27084,GRP_LAI,LAI_TOT,2.03 -US-SP2,27085,GRP_LAI,LAI_TOT,2.04 -US-SP2,29324,GRP_LAI,LAI_TOT,2.19 -US-SP2,29323,GRP_LAI,LAI_TOT,2.21 -US-SP2,29322,GRP_LAI,LAI_TOT,2.30 -US-SP2,27734,GRP_LAI,LAI_TOT,2.38 -US-SP2,26789,GRP_LAI,LAI_TOT,2.41 -US-SP2,26788,GRP_LAI,LAI_TOT,2.54 -US-SP2,28847,GRP_LAI,LAI_TOT,2.58 -US-SP2,28609,GRP_LAI,LAI_TOT,2.64 -US-SP2,26796,GRP_LAI,LAI_TOT,2.81 -US-SP2,26795,GRP_LAI,LAI_TOT,3.02 -US-SP2,28849,GRP_LAI,LAI_TOT,3.15 -US-SP2,28848,GRP_LAI,LAI_TOT,3.17 -US-SP2,26790,GRP_LAI,LAI_TOT,3.28 -US-SP2,27735,GRP_LAI,LAI_TOT,3.30 -US-SP2,29217,GRP_LAI,LAI_TOT,3.38 -US-SP2,27383,GRP_LAI,LAI_TOT,3.39 -US-SP2,26791,GRP_LAI,LAI_TOT,3.49 -US-SP2,27631,GRP_LAI,LAI_TOT,3.85 -US-SP2,28343,GRP_LAI,LAI_TOT,3.87 -US-SP2,28851,GRP_LAI,LAI_TOT,3.90 -US-SP2,27995,GRP_LAI,LAI_TOT,4.03 -US-SP2,29216,GRP_LAI,LAI_TOT,4.04 -US-SP2,27996,GRP_LAI,LAI_TOT,4.16 -US-SP2,27384,GRP_LAI,LAI_TOT,4.17 -US-SP2,28342,GRP_LAI,LAI_TOT,4.18 -US-SP2,29537,GRP_LAI,LAI_TOT,4.22 -US-SP2,29538,GRP_LAI,LAI_TOT,4.26 -US-SP2,28345,GRP_LAI,LAI_TOT,4.40 -US-SP2,28610,GRP_LAI,LAI_TOT,4.47 -US-SP2,27997,GRP_LAI,LAI_TOT,4.57 -US-SP2,27634,GRP_LAI,LAI_TOT,4.62 -US-SP2,29326,GRP_LAI,LAI_TOT,4.72 -US-SP2,28612,GRP_LAI,LAI_TOT,4.73 -US-SP2,28344,GRP_LAI,LAI_TOT,5.00 -US-SP2,27998,GRP_LAI,LAI_TOT,5.11 -US-SP2,27086,GRP_LAI,LAI_TOT,5.19 -US-SP2,29327,GRP_LAI,LAI_TOT,5.21 -US-SP2,27632,GRP_LAI,LAI_TOT,5.29 -US-SP2,27386,GRP_LAI,LAI_TOT,5.39 -US-SP2,29219,GRP_LAI,LAI_TOT,5.41 -US-SP2,27087,GRP_LAI,LAI_TOT,5.54 -US-SP2,27385,GRP_LAI,LAI_TOT,5.55 -US-SP2,27635,GRP_LAI,LAI_TOT,5.56 -US-SP2,29539,GRP_LAI,LAI_TOT,6.22 -US-SP2,29218,GRP_LAI,LAI_TOT,6.26 -US-SP2,29325,GRP_LAI,LAI_TOT,6.28 -US-SP2,26794,GRP_LAI,LAI_TOT,6.65 -US-SP2,27633,GRP_LAI,LAI_TOT,6.79 -US-SP2,28611,GRP_LAI,LAI_TOT,6.85 -US-SP2,26792,GRP_LAI,LAI_TOT,7.07 -US-SP2,26793,GRP_LAI,LAI_TOT,7.07 -US-SP2,28850,GRP_LAI,LAI_TOT,7.29 -US-SP2,304,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -US-SP2,304,GRP_LAND_OWNERSHIP,LAND_OWNER,Private -US-SP2,27097,GRP_LMA,LMA,50 -US-SP2,27097,GRP_LMA,LMA_SPP,(All) -US-SP2,6822,GRP_LOCATION,LOCATION_LAT,29.7648 -US-SP2,6822,GRP_LOCATION,LOCATION_LONG,-82.2448 -US-SP2,6822,GRP_LOCATION,LOCATION_ELEV,50 -US-SP2,24155,GRP_N_DEP,N_DEP_WET,1.35 -US-SP2,28828,GRP_NEP,NEP,348170 -US-SP2,28828,GRP_NEP,NEP_APPROACH,Eddy covariance -US-SP2,28828,GRP_NEP,NEP_DATE_START,2006 -US-SP2,28828,GRP_NEP,NEP_DATE_END,2007 -US-SP2,28828,GRP_NEP,NEP_COMMENT,Agrading plantation. NEP range from 164.6 g C m-2 yr-1 (carbon source) in 2001 to -348 g C m-2 yr-1 (carbon sink) in 2006 -US-SP2,9820,GRP_NETWORK,NETWORK,AmeriFlux -US-SP2,1700005751,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Bracho, R., Starr, G., Gholz, H. L., Martin, T. A., Cropper, W. P., Loescher, H. W. (2012) Controls On Carbon Dynamics By Ecosystem Structure And Climate For Southeastern U.S. Slash Pine Plantations, Ecological Monographs, 82(1), 101-128" -US-SP2,1700005751,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1890/11-0587.1 -US-SP2,1700005751,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-SP2,1700005268,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Castro, M. S., Gholz, H. L., Clark, K. L., Steudler, P. A. (2000) Effects Of Forest Harvesting On Soil Methane Fluxes In Florida Slash Pine Plantations, Canadian Journal Of Forest Research, 30(10), 1534-1542" -US-SP2,1700005268,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1139/CJFR-30-10-1534 -US-SP2,1700005268,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-SP2,1700005619,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Baldocchi, D. D., Poindexter, C., Abraha, M., Desai, A. R., Bohrer, G., Arain, M. A., Griffis, T., Blanken, P. D., O'Halloran, T. L., Thomas, R. Q., Zhang, Q., Burns, S. P., Frank, J. M., Christian, D., Brown, S., Black, T. A., Gough, C. M., Law, B. E., Lee, X., Chen, J., Reed, D. E., Massman, W. J., Clark, K., Hatfield, J., Prueger, J., Bracho, R., Baker, J. M., Martin, T. A. (2018) Temporal Dynamics Of Aerodynamic Canopy Height Derived From Eddy Covariance Momentum Flux Data Across North American Flux Networks, Geophysical Research Letters, 45(1), 9275–9287" -US-SP2,1700005619,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018GL079306 -US-SP2,1700005619,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-SP2,1700000522,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Baldocchi, D. D., Poindexter, C., Abraha, M., Desai, A. R., Bohrer, G., Arain, M. A., Griffis, T., Blanken, P. D., O'Halloran, T. L., Thomas, R. Q., Zhang, Q., Burns, S. P., Frank, J. M., Christian, D., Brown, S., Black, T. A., Gough, C. M., Law, B. E., Lee, X., Chen, J., Reed, D. E., Massman, W. J., Clark, K., Hatfield, J., Prueger, J., Bracho, R., Baker, J. M., Martin, T. A. (2018) Temporal Dynamics Of Aerodynamic Canopy Height Derived From Eddy Covariance Momentum Flux Data Across North American Flux Networks, Geophysical Research Letters, 45(4), 9275–9287" -US-SP2,1700000522,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018GL079306 -US-SP2,1700000522,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-SP2,1700007824,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(1), 108350" -US-SP2,1700007824,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -US-SP2,1700007824,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-SP2,1700001140,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Clark, K. L., Gholz, H. L., Castro, M. S. (2004) Carbon Dynamics Along A Chronosequence Of Slash Pine Plantations In North Florida, Ecological Applications, 14(4), 1154-1171" -US-SP2,1700001140,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1890/02-5391 -US-SP2,1700001140,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-SP2,1700003015,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Clark, K. L., Gholz, H. L., Moncrieff, J. B., Cropley, F., Loescher, H. W. (1999) Environmental Controls Over Net Exchanges Of Carbon Dioxide From Contrasting Florida Ecosystems, Ecological Applications, 9(3), 936-948" -US-SP2,1700003015,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.2307/2641340 -US-SP2,1700003015,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-SP2,1700000375,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Dennis Baldocchi, Cove Sturtevant (2015) Does day and night sampling reduce spurious correlation between canopy photosynthesis and ecosystem respiration?, Agricultural and Forest Meteorology, 207(4), 117-126" -US-SP2,1700000375,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2015.03.010 -US-SP2,1700000375,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-SP2,1700005925,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Fang, C., Moncrieff, J. (1998) Simple And Fast Technique To Measure CO2 Profiles In Soil, Soil Biology And Biochemistry, 30(14), 2107-2112" -US-SP2,1700005925,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/S0038-0717(98)00088-1 -US-SP2,1700005925,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-SP2,1700008817,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Gholz, H. L., Clark, K. L. (2002) Energy Exchange Across A Chronosequence Of Slash Pine Forests In Florida, Agricultural And Forest Meteorology, 112(2), 87-102" -US-SP2,1700008817,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/S0168-1923(02)00059-X -US-SP2,1700008817,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-SP2,1700005319,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Gholz, H. L., Guerin, D. N., Cropper, W. P. (1999) Phenology And Productivity Of Saw Palmetto ( Serenoa Repens ) In A North Florida Slash Pine Plantation, Canadian Journal Of Forest Research, 29(8), 1248-1253" -US-SP2,1700005319,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1139/CJFR-29-8-1248 -US-SP2,1700005319,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-SP2,1700002823,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Moncrieff, J. B., Fang, C. (1999) A Model For Soil CO2 Production And Transport 2: Application To A Florida Pinus Elliotte Plantation, Agricultural And Forest Meteorology, 95(4), 237-256" -US-SP2,1700002823,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/S0168-1923(99)00035-0 -US-SP2,1700002823,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-SP2,1627,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"The research and science objectives of the Mize site are as follows: 1) Quantify the carbon dynamics of intensively managed pine plantations; 2) Investigate the energy partitioning and changes in carbon sequestration across a slash pine management cycle, or rotation, in north-central Florida; 3) Quantify ecosystem water and energy budgets and the determining environmental variables; 4) Determine the dominant environmental factors controlling the seasonal partitioning of net radiation into the main energy budget components of latent energy flux and sensible heat flux. (Powell et al., 2008, Powell et al., 2005, Gholz and Clark, 2002)" -US-SP2,26912,GRP_SA,SA_DATE,2008 -US-SP2,26912,GRP_SA,SA_MAX,9 -US-SP2,27608,GRP_SA,SA,9 -US-SP2,27608,GRP_SA,SA_DATE,2008 -US-SP2,27608,GRP_SA,SA_COMMENT,even aged plantation -US-SP2,5840,GRP_SITE_CHAR,TERRAIN,Flat -US-SP2,7966,GRP_SITE_DESC,SITE_DESC,Even aged slash pine (Pinus elliottii) plantation. Planted in Jan. 1999. -US-SP2,2470,GRP_SITE_FUNDING,SITE_FUNDING,DOE/NIGEC -US-SP2,26931,GRP_SNAG_MASS,SNAG_MASS,69.9 -US-SP2,26931,GRP_SNAG_MASS,SNAG_MASS_UNIT,gC m-2 -US-SP2,26931,GRP_SNAG_MASS,SNAG_MASS_DATE,2007 -US-SP2,28589,GRP_SOIL_CHEM,SOIL_CHEM_C_ORG,8 -US-SP2,27979,GRP_SOIL_CHEM,SOIL_CHEM_BD,1.21 -US-SP2,27979,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,10 -US-SP2,28589,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,10 -US-SP2,28589,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,100 -US-SP2,27979,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,150 -US-SP2,27979,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,1.5 measured at 0.5m -US-SP2,28430,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION,"Poorly drained ultic alaquods (sandy, silicecous, thermic) overlying a discontinuous spodic horizon spanning from 0.30 - 0.80 m deep transitioning to an argillic horizon at depths below 0.80 m" -US-SP2,28430,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION_TAXONOMY,Other -US-SP2,28328,GRP_SOIL_DEPTH,SOIL_DEPTH,300 -US-SP2,28590,GRP_SOIL_TEX,SOIL_TEX_SAND,99 -US-SP2,28590,GRP_SOIL_TEX,SOIL_TEX_SILT,0 -US-SP2,28590,GRP_SOIL_TEX,SOIL_TEX_CLAY,1 -US-SP2,27609,GRP_SPP_O,SPP_O,PIELE2 (NRCS plant code) -US-SP2,27609,GRP_SPP_O,SPP_O_PERC,100 -US-SP2,27609,GRP_SPP_O,SPP_APPROACH,Inventory -US-SP2,27609,GRP_SPP_O,SPP_DATE,2008 -US-SP2,28331,GRP_SPP_U,SPP_U,ILGL (NRCS plant code) -US-SP2,29520,GRP_SPP_U,SPP_U,MYCE (NRCS plant code) -US-SP2,29521,GRP_SPP_U,SPP_U,SERE2 (NRCS plant code) -US-SP2,28331,GRP_SPP_U,SPP_APPROACH,Clipping plots -US-SP2,29520,GRP_SPP_U,SPP_APPROACH,Clipping plots -US-SP2,29521,GRP_SPP_U,SPP_APPROACH,Clipping plots -US-SP2,28331,GRP_SPP_U,SPP_DATE,2008 -US-SP2,29520,GRP_SPP_U,SPP_DATE,2008 -US-SP2,29521,GRP_SPP_U,SPP_DATE,2008 -US-SP2,4914,GRP_STATE,STATE,FL -US-SP2,1531,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Tim Martin -US-SP2,1531,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-SP2,1531,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,tamartin@ufl.edu -US-SP2,1531,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Florida -US-SP2,1531,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"P.O. Box 110410, 326 Newins Ziegler Hall,Gainesville, FL USA 32611-0410" -US-SP2,91800,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Rosvel Bracho -US-SP2,91800,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,AncContact -US-SP2,91800,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,rbracho@ufl.edu -US-SP2,91800,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Florida -US-SP2,91800,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"School of Forest Resources and Conservation, 224B Newins-Ziegler Hall,Gainesville, FL USA 32611" -US-SP2,10131,GRP_URL,URL,http://carboncenter.ifas.ufl.edu/ameriflux.shtml -US-SP2,24000431,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-SP2 -US-SP2,1935,GRP_UTC_OFFSET,UTC_OFFSET,-5 -US-SP2,28838,GRP_WD_BIOMASS,WD_BIOMASS_CRS,2.94 -US-SP2,28838,GRP_WD_BIOMASS,WD_BIOMASS_UNIT,gC m-2 -US-SP2,28838,GRP_WD_BIOMASS,WD_BIOMASS_DATE,2006 -US-SP2,28838,GRP_WD_BIOMASS,WD_BIOMASS_COMMENT,Total woody debries masured in 2006; Jan-2006 to Dec-2006 -US-SP3,23634,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER,7 -US-SP3,23634,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_ORGAN,Total -US-SP3,23634,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_PHEN,Mixed/unknown -US-SP3,23634,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_UNIT,kgDM m-2 -US-SP3,23634,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_COMMENT,": -(December 2003)" -US-SP3,28329,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB,114.75 -US-SP3,28329,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_ORGAN,Wood -US-SP3,28329,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_PHEN,Mixed/unknown -US-SP3,28329,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_UNIT,gC m-2 -US-SP3,28329,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_APPROACH,10 1m2 plots were clipped -US-SP3,28329,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_DATE,2007 -US-SP3,26770,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB,133.5 -US-SP3,26770,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_ORGAN,Total -US-SP3,26770,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_PHEN,Mixed/unknown -US-SP3,26770,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_UNIT,gC m-2 -US-SP3,26770,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_DATE,2007 -US-SP3,29174,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB,18.75 -US-SP3,29174,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_ORGAN,Foliage -US-SP3,29174,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_PHEN,Mixed/unknown -US-SP3,29174,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_SHRUB_UNIT,gC m-2 -US-SP3,29174,GRP_AG_BIOMASS_SHRUB,AG_BIOMASS_DATE,2007 -US-SP3,27610,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,173 -US-SP3,27610,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Foliage -US-SP3,27610,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-SP3,27610,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-SP3,27610,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,literrfall -US-SP3,27610,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2007 -US-SP3,27980,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,4545 -US-SP3,27980,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Wood -US-SP3,27980,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-SP3,27980,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-SP3,27980,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,Allometric equations developed on site were applied to dbh and height measurements -US-SP3,27980,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2007 -US-SP3,28591,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,4718 -US-SP3,28591,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Total -US-SP3,28591,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-SP3,28591,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-SP3,28591,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,Inventory on 4 625 m2 plots -US-SP3,28591,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2007 -US-SP3,29189,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS,1600 -US-SP3,29189,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_UNIT,gC m-2 -US-SP3,29189,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_DATE,2007 -US-SP3,26915,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT,204.12 -US-SP3,26915,GRP_AG_LIT_PROD,AG_LIT_PROD_UNIT,gC m-2 -US-SP3,26915,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_START,2006 -US-SP3,26915,GRP_AG_LIT_PROD,AG_LIT_PROD_COMMENT,Value measured in 2006 -US-SP3,28858,GRP_AG_PROD_OTHER,AG_PROD_OTHER,3.2 -US-SP3,28858,GRP_AG_PROD_OTHER,AG_PROD_OTHER_ORGAN,Total -US-SP3,28858,GRP_AG_PROD_OTHER,AG_PROD_OTHER_UNIT,gC m-2 -US-SP3,28858,GRP_AG_PROD_OTHER,AG_PROD_APPROACH,10 1m2 Clipping plots -US-SP3,28858,GRP_AG_PROD_OTHER,AG_PROD_DATE_START,2007 -US-SP3,27644,GRP_AG_PROD_SHRUB,AG_PROD_SHRUB,0.53 -US-SP3,27644,GRP_AG_PROD_SHRUB,AG_PROD_SHRUB_ORGAN,Wood -US-SP3,27644,GRP_AG_PROD_SHRUB,AG_PROD_SHRUB_UNIT,gC m-2 -US-SP3,27644,GRP_AG_PROD_SHRUB,AG_PROD_APPROACH,Clipping plots -US-SP3,27644,GRP_AG_PROD_SHRUB,AG_PROD_DATE_START,2007 -US-SP3,27099,GRP_AG_PROD_SHRUB,AG_PROD_SHRUB,18.75 -US-SP3,27099,GRP_AG_PROD_SHRUB,AG_PROD_SHRUB_ORGAN,Foliage -US-SP3,27099,GRP_AG_PROD_SHRUB,AG_PROD_SHRUB_UNIT,gC m-2 -US-SP3,27099,GRP_AG_PROD_SHRUB,AG_PROD_APPROACH,10 1m2 Clipping plots -US-SP3,27099,GRP_AG_PROD_SHRUB,AG_PROD_DATE_START,2007 -US-SP3,27402,GRP_AG_PROD_SHRUB,AG_PROD_SHRUB,19.28 -US-SP3,27402,GRP_AG_PROD_SHRUB,AG_PROD_SHRUB_ORGAN,Total -US-SP3,27402,GRP_AG_PROD_SHRUB,AG_PROD_SHRUB_UNIT,gC m-2 -US-SP3,27402,GRP_AG_PROD_SHRUB,AG_PROD_APPROACH,Clipping plots -US-SP3,27402,GRP_AG_PROD_SHRUB,AG_PROD_DATE_START,2007 -US-SP3,28857,GRP_AG_PROD_TREE,AG_PROD_TREE,173 -US-SP3,28857,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Foliage -US-SP3,28857,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-SP3,28857,GRP_AG_PROD_TREE,AG_PROD_APPROACH,10 1m2 litterfall traps -US-SP3,28857,GRP_AG_PROD_TREE,AG_PROD_DATE_START,2007 -US-SP3,26932,GRP_AG_PROD_TREE,AG_PROD_TREE,229 -US-SP3,26932,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Wood -US-SP3,26932,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-SP3,26932,GRP_AG_PROD_TREE,AG_PROD_APPROACH,Increments in biomass from inventory. -US-SP3,26932,GRP_AG_PROD_TREE,AG_PROD_DATE_START,2007 -US-SP3,26782,GRP_AG_PROD_TREE,AG_PROD_TREE,402 -US-SP3,26782,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Total -US-SP3,26782,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-SP3,26782,GRP_AG_PROD_TREE,AG_PROD_APPROACH,Increments in biomass plus foliage production. -US-SP3,26782,GRP_AG_PROD_TREE,AG_PROD_DATE_START,2007 -US-SP3,27075,GRP_BIOMASS_CHEM,BIOMASS_N,0.095 -US-SP3,27075,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-SP3,27075,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-SP3,27075,GRP_BIOMASS_CHEM,BIOMASS_SPP,(All) -US-SP3,5975,GRP_CLIM_AVG,MAT,20.25 -US-SP3,5975,GRP_CLIM_AVG,MAP,1312.35 -US-SP3,5975,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Cfa -US-SP3,27000432,GRP_COUNTRY,COUNTRY,USA -US-SP3,305,GRP_DM_FERT_M,DM_FERT_M,Other -US-SP3,305,GRP_DM_FERT_M,DM_DATE,19930801 -US-SP3,305,GRP_DM_FERT_M,DM_COMMENT,50 Kg/ha N; 56 kg/ha P -US-SP3,5381,GRP_DM_FERT_M,DM_FERT_M,N -US-SP3,5381,GRP_DM_FERT_M,DM_DATE,20011201 -US-SP3,5381,GRP_DM_FERT_M,DM_COMMENT,151 Kg/ha N -US-SP3,8793,GRP_DM_PLANTING,DM_PLANTING,Planting live trees -US-SP3,8793,GRP_DM_PLANTING,DM_DATE,1990 -US-SP3,8793,GRP_DM_PLANTING,DM_COMMENT,Planted at 2032 trees/ha -US-SP3,15666,GRP_DOI,DOI,10.17190/AMF/1246102 -US-SP3,15666,GRP_DOI,DOI_CITATION,"Tim Martin (2016), AmeriFlux BASE US-SP3 Slashpine-Donaldson-mid-rot- 12yrs, Ver. 3-1, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1246102" -US-SP3,15666,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-SP3,32200,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-SP3,32200,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Tim Martin -US-SP3,32200,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-SP3,32200,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,tamartin@ufl.edu -US-SP3,32200,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of Florida -US-SP3,32202,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,University of Florida -US-SP3,32202,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-SP3,32201,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,DOE/NIGEC -US-SP3,32201,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-SP3,3364,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Forestry -US-SP3,91799,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-SP3,91799,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-SP3,91799,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,199901 -US-SP3,91799,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,201311 -US-SP3,91799,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-SP3,91803,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-SP3,91803,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-SP3,91803,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,199901 -US-SP3,91803,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,201311 -US-SP3,91803,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-SP3,91790,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-SP3,91790,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-SP3,91790,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,199901 -US-SP3,91790,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,201311 -US-SP3,91790,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-SP3,23000432,GRP_HEADER,SITE_NAME,Slashpine-Donaldson-mid-rot- 12yrs -US-SP3,28829,GRP_HEIGHTC,HEIGHTC,14 -US-SP3,28829,GRP_HEIGHTC,HEIGHTC_DATE,2008 -US-SP3,28829,GRP_HEIGHTC,HEIGHTC_COMMENT,value obtained from inventory -US-SP3,2828,GRP_IGBP,IGBP,ENF -US-SP3,2828,GRP_IGBP,IGBP_COMMENT,Even aged high density slash pine (Pinus elliottii) plantation. -US-SP3,26797,GRP_LAI,LAI_TYPE,LAI -US-SP3,26798,GRP_LAI,LAI_TYPE,LAI -US-SP3,26799,GRP_LAI,LAI_TYPE,LAI -US-SP3,26800,GRP_LAI,LAI_TYPE,LAI -US-SP3,26801,GRP_LAI,LAI_TYPE,LAI -US-SP3,26802,GRP_LAI,LAI_TYPE,LAI -US-SP3,26803,GRP_LAI,LAI_TYPE,LAI -US-SP3,26804,GRP_LAI,LAI_TYPE,LAI -US-SP3,27088,GRP_LAI,LAI_TYPE,LAI -US-SP3,27089,GRP_LAI,LAI_TYPE,LAI -US-SP3,27090,GRP_LAI,LAI_TYPE,LAI -US-SP3,27091,GRP_LAI,LAI_TYPE,LAI -US-SP3,27092,GRP_LAI,LAI_TYPE,LAI -US-SP3,27093,GRP_LAI,LAI_TYPE,LAI -US-SP3,27094,GRP_LAI,LAI_TYPE,LAI -US-SP3,27095,GRP_LAI,LAI_TYPE,LAI -US-SP3,27096,GRP_LAI,LAI_TYPE,LAI -US-SP3,27387,GRP_LAI,LAI_TYPE,LAI -US-SP3,27388,GRP_LAI,LAI_TYPE,LAI -US-SP3,27389,GRP_LAI,LAI_TYPE,LAI -US-SP3,27390,GRP_LAI,LAI_TYPE,LAI -US-SP3,27391,GRP_LAI,LAI_TYPE,LAI -US-SP3,27392,GRP_LAI,LAI_TYPE,LAI -US-SP3,27393,GRP_LAI,LAI_TYPE,LAI -US-SP3,27394,GRP_LAI,LAI_TYPE,LAI -US-SP3,27395,GRP_LAI,LAI_TYPE,LAI -US-SP3,27396,GRP_LAI,LAI_TYPE,LAI -US-SP3,27636,GRP_LAI,LAI_TYPE,LAI -US-SP3,27637,GRP_LAI,LAI_TYPE,LAI -US-SP3,27638,GRP_LAI,LAI_TYPE,LAI -US-SP3,27639,GRP_LAI,LAI_TYPE,LAI -US-SP3,27640,GRP_LAI,LAI_TYPE,LAI -US-SP3,27641,GRP_LAI,LAI_TYPE,LAI -US-SP3,27642,GRP_LAI,LAI_TYPE,LAI -US-SP3,27736,GRP_LAI,LAI_TYPE,LAI -US-SP3,27737,GRP_LAI,LAI_TYPE,LAI -US-SP3,27738,GRP_LAI,LAI_TYPE,LAI -US-SP3,27739,GRP_LAI,LAI_TYPE,LAI -US-SP3,27740,GRP_LAI,LAI_TYPE,LAI -US-SP3,27741,GRP_LAI,LAI_TYPE,LAI -US-SP3,27742,GRP_LAI,LAI_TYPE,LAI -US-SP3,27743,GRP_LAI,LAI_TYPE,LAI -US-SP3,27999,GRP_LAI,LAI_TYPE,LAI -US-SP3,28000,GRP_LAI,LAI_TYPE,LAI -US-SP3,28001,GRP_LAI,LAI_TYPE,LAI -US-SP3,28002,GRP_LAI,LAI_TYPE,LAI -US-SP3,28003,GRP_LAI,LAI_TYPE,LAI -US-SP3,28004,GRP_LAI,LAI_TYPE,LAI -US-SP3,28005,GRP_LAI,LAI_TYPE,LAI -US-SP3,28006,GRP_LAI,LAI_TYPE,LAI -US-SP3,28346,GRP_LAI,LAI_TYPE,LAI -US-SP3,28347,GRP_LAI,LAI_TYPE,LAI -US-SP3,28348,GRP_LAI,LAI_TYPE,LAI -US-SP3,28349,GRP_LAI,LAI_TYPE,LAI -US-SP3,28350,GRP_LAI,LAI_TYPE,LAI -US-SP3,28351,GRP_LAI,LAI_TYPE,LAI -US-SP3,28352,GRP_LAI,LAI_TYPE,LAI -US-SP3,28613,GRP_LAI,LAI_TYPE,LAI -US-SP3,28614,GRP_LAI,LAI_TYPE,LAI -US-SP3,28615,GRP_LAI,LAI_TYPE,LAI -US-SP3,28616,GRP_LAI,LAI_TYPE,LAI -US-SP3,28617,GRP_LAI,LAI_TYPE,LAI -US-SP3,28618,GRP_LAI,LAI_TYPE,LAI -US-SP3,28619,GRP_LAI,LAI_TYPE,LAI -US-SP3,28620,GRP_LAI,LAI_TYPE,LAI -US-SP3,28852,GRP_LAI,LAI_TYPE,LAI -US-SP3,28853,GRP_LAI,LAI_TYPE,LAI -US-SP3,28854,GRP_LAI,LAI_TYPE,LAI -US-SP3,28855,GRP_LAI,LAI_TYPE,LAI -US-SP3,28856,GRP_LAI,LAI_TYPE,LAI -US-SP3,29220,GRP_LAI,LAI_TYPE,LAI -US-SP3,29221,GRP_LAI,LAI_TYPE,LAI -US-SP3,29222,GRP_LAI,LAI_TYPE,LAI -US-SP3,29223,GRP_LAI,LAI_TYPE,LAI -US-SP3,29224,GRP_LAI,LAI_TYPE,LAI -US-SP3,29225,GRP_LAI,LAI_TYPE,LAI -US-SP3,29226,GRP_LAI,LAI_TYPE,LAI -US-SP3,29227,GRP_LAI,LAI_TYPE,LAI -US-SP3,29228,GRP_LAI,LAI_TYPE,LAI -US-SP3,29328,GRP_LAI,LAI_TYPE,LAI -US-SP3,29329,GRP_LAI,LAI_TYPE,LAI -US-SP3,29330,GRP_LAI,LAI_TYPE,LAI -US-SP3,29331,GRP_LAI,LAI_TYPE,LAI -US-SP3,29332,GRP_LAI,LAI_TYPE,LAI -US-SP3,29333,GRP_LAI,LAI_TYPE,LAI -US-SP3,29540,GRP_LAI,LAI_TYPE,LAI -US-SP3,29541,GRP_LAI,LAI_TYPE,LAI -US-SP3,29542,GRP_LAI,LAI_TYPE,LAI -US-SP3,29543,GRP_LAI,LAI_TYPE,LAI -US-SP3,29544,GRP_LAI,LAI_TYPE,LAI -US-SP3,29545,GRP_LAI,LAI_TYPE,LAI -US-SP3,29546,GRP_LAI,LAI_TYPE,LAI -US-SP3,29547,GRP_LAI,LAI_TYPE,LAI -US-SP3,29548,GRP_LAI,LAI_TYPE,LAI -US-SP3,29549,GRP_LAI,LAI_TYPE,LAI -US-SP3,29550,GRP_LAI,LAI_TYPE,LAI -US-SP3,26797,GRP_LAI,LAI_METHOD,Litterfall -US-SP3,26798,GRP_LAI,LAI_METHOD,Litterfall -US-SP3,26799,GRP_LAI,LAI_METHOD,Litterfall -US-SP3,26800,GRP_LAI,LAI_METHOD,Litterfall -US-SP3,26801,GRP_LAI,LAI_METHOD,Litterfall -US-SP3,26802,GRP_LAI,LAI_METHOD,Litterfall -US-SP3,26803,GRP_LAI,LAI_METHOD,Litterfall -US-SP3,26804,GRP_LAI,LAI_METHOD,Litterfall -US-SP3,27088,GRP_LAI,LAI_METHOD,Litterfall -US-SP3,27089,GRP_LAI,LAI_METHOD,Litterfall -US-SP3,27090,GRP_LAI,LAI_METHOD,Litterfall -US-SP3,27091,GRP_LAI,LAI_METHOD,Litterfall -US-SP3,27092,GRP_LAI,LAI_METHOD,Litterfall -US-SP3,27093,GRP_LAI,LAI_METHOD,Litterfall -US-SP3,27094,GRP_LAI,LAI_METHOD,Litterfall -US-SP3,27095,GRP_LAI,LAI_METHOD,Litterfall -US-SP3,27096,GRP_LAI,LAI_METHOD,Litterfall -US-SP3,27387,GRP_LAI,LAI_METHOD,Litterfall -US-SP3,27388,GRP_LAI,LAI_METHOD,Litterfall -US-SP3,27389,GRP_LAI,LAI_METHOD,Litterfall -US-SP3,27390,GRP_LAI,LAI_METHOD,Litterfall -US-SP3,27391,GRP_LAI,LAI_METHOD,Litterfall -US-SP3,27392,GRP_LAI,LAI_METHOD,Litterfall -US-SP3,27393,GRP_LAI,LAI_METHOD,Litterfall -US-SP3,27394,GRP_LAI,LAI_METHOD,Litterfall -US-SP3,27395,GRP_LAI,LAI_METHOD,Litterfall -US-SP3,27396,GRP_LAI,LAI_METHOD,Litterfall -US-SP3,27636,GRP_LAI,LAI_METHOD,Litterfall -US-SP3,27637,GRP_LAI,LAI_METHOD,Litterfall -US-SP3,27638,GRP_LAI,LAI_METHOD,Litterfall -US-SP3,27639,GRP_LAI,LAI_METHOD,Litterfall -US-SP3,27640,GRP_LAI,LAI_METHOD,Litterfall -US-SP3,27641,GRP_LAI,LAI_METHOD,Litterfall -US-SP3,27642,GRP_LAI,LAI_METHOD,Litterfall -US-SP3,27736,GRP_LAI,LAI_METHOD,Litterfall -US-SP3,27737,GRP_LAI,LAI_METHOD,Litterfall -US-SP3,27738,GRP_LAI,LAI_METHOD,Litterfall -US-SP3,27739,GRP_LAI,LAI_METHOD,Litterfall -US-SP3,27740,GRP_LAI,LAI_METHOD,Litterfall -US-SP3,27741,GRP_LAI,LAI_METHOD,Litterfall -US-SP3,27742,GRP_LAI,LAI_METHOD,Litterfall -US-SP3,27743,GRP_LAI,LAI_METHOD,Litterfall -US-SP3,27999,GRP_LAI,LAI_METHOD,Litterfall -US-SP3,28000,GRP_LAI,LAI_METHOD,Litterfall -US-SP3,28001,GRP_LAI,LAI_METHOD,Litterfall -US-SP3,28002,GRP_LAI,LAI_METHOD,Litterfall -US-SP3,28003,GRP_LAI,LAI_METHOD,Litterfall -US-SP3,28004,GRP_LAI,LAI_METHOD,Litterfall -US-SP3,28005,GRP_LAI,LAI_METHOD,Litterfall -US-SP3,28006,GRP_LAI,LAI_METHOD,Litterfall -US-SP3,28346,GRP_LAI,LAI_METHOD,Litterfall -US-SP3,28347,GRP_LAI,LAI_METHOD,Litterfall -US-SP3,28348,GRP_LAI,LAI_METHOD,Litterfall -US-SP3,28349,GRP_LAI,LAI_METHOD,Litterfall -US-SP3,28350,GRP_LAI,LAI_METHOD,Litterfall -US-SP3,28351,GRP_LAI,LAI_METHOD,Litterfall -US-SP3,28352,GRP_LAI,LAI_METHOD,Litterfall -US-SP3,28613,GRP_LAI,LAI_METHOD,Litterfall -US-SP3,28614,GRP_LAI,LAI_METHOD,Litterfall -US-SP3,28615,GRP_LAI,LAI_METHOD,Litterfall -US-SP3,28616,GRP_LAI,LAI_METHOD,Litterfall -US-SP3,28617,GRP_LAI,LAI_METHOD,Litterfall -US-SP3,28618,GRP_LAI,LAI_METHOD,Litterfall -US-SP3,28619,GRP_LAI,LAI_METHOD,Litterfall -US-SP3,28620,GRP_LAI,LAI_METHOD,Litterfall -US-SP3,28852,GRP_LAI,LAI_METHOD,Litterfall -US-SP3,28853,GRP_LAI,LAI_METHOD,Litterfall -US-SP3,28854,GRP_LAI,LAI_METHOD,Litterfall -US-SP3,28855,GRP_LAI,LAI_METHOD,Litterfall -US-SP3,28856,GRP_LAI,LAI_METHOD,Litterfall -US-SP3,29220,GRP_LAI,LAI_METHOD,Litterfall -US-SP3,29221,GRP_LAI,LAI_METHOD,Litterfall -US-SP3,29222,GRP_LAI,LAI_METHOD,Litterfall -US-SP3,29223,GRP_LAI,LAI_METHOD,Litterfall -US-SP3,29224,GRP_LAI,LAI_METHOD,Litterfall -US-SP3,29225,GRP_LAI,LAI_METHOD,Litterfall -US-SP3,29226,GRP_LAI,LAI_METHOD,Litterfall -US-SP3,29227,GRP_LAI,LAI_METHOD,Litterfall -US-SP3,29228,GRP_LAI,LAI_METHOD,Litterfall -US-SP3,29328,GRP_LAI,LAI_METHOD,Litterfall -US-SP3,29329,GRP_LAI,LAI_METHOD,Litterfall -US-SP3,29330,GRP_LAI,LAI_METHOD,Litterfall -US-SP3,29331,GRP_LAI,LAI_METHOD,Litterfall -US-SP3,29332,GRP_LAI,LAI_METHOD,Litterfall -US-SP3,29333,GRP_LAI,LAI_METHOD,Litterfall -US-SP3,29540,GRP_LAI,LAI_METHOD,Litterfall -US-SP3,29541,GRP_LAI,LAI_METHOD,Litterfall -US-SP3,29542,GRP_LAI,LAI_METHOD,Litterfall -US-SP3,29543,GRP_LAI,LAI_METHOD,Litterfall -US-SP3,29544,GRP_LAI,LAI_METHOD,Litterfall -US-SP3,29545,GRP_LAI,LAI_METHOD,Litterfall -US-SP3,29546,GRP_LAI,LAI_METHOD,Litterfall -US-SP3,29547,GRP_LAI,LAI_METHOD,Litterfall -US-SP3,29548,GRP_LAI,LAI_METHOD,Litterfall -US-SP3,29549,GRP_LAI,LAI_METHOD,Litterfall -US-SP3,29550,GRP_LAI,LAI_METHOD,Litterfall -US-SP3,28852,GRP_LAI,LAI_DATE,19990301 -US-SP3,29220,GRP_LAI,LAI_DATE,19990401 -US-SP3,29540,GRP_LAI,LAI_DATE,19990501 -US-SP3,29221,GRP_LAI,LAI_DATE,19990601 -US-SP3,29541,GRP_LAI,LAI_DATE,19990701 -US-SP3,28613,GRP_LAI,LAI_DATE,19990801 -US-SP3,27387,GRP_LAI,LAI_DATE,19990901 -US-SP3,28614,GRP_LAI,LAI_DATE,19991001 -US-SP3,27999,GRP_LAI,LAI_DATE,19991101 -US-SP3,28000,GRP_LAI,LAI_DATE,19991201 -US-SP3,27088,GRP_LAI,LAI_DATE,2000 -US-SP3,29542,GRP_LAI,LAI_DATE,20000201 -US-SP3,27089,GRP_LAI,LAI_DATE,20000301 -US-SP3,29328,GRP_LAI,LAI_DATE,20000401 -US-SP3,26797,GRP_LAI,LAI_DATE,20000501 -US-SP3,28853,GRP_LAI,LAI_DATE,20000601 -US-SP3,26798,GRP_LAI,LAI_DATE,20000701 -US-SP3,28854,GRP_LAI,LAI_DATE,20000801 -US-SP3,29329,GRP_LAI,LAI_DATE,20000901 -US-SP3,28346,GRP_LAI,LAI_DATE,20001001 -US-SP3,27636,GRP_LAI,LAI_DATE,20001101 -US-SP3,29222,GRP_LAI,LAI_DATE,20001201 -US-SP3,28001,GRP_LAI,LAI_DATE,2001 -US-SP3,28002,GRP_LAI,LAI_DATE,20010201 -US-SP3,28615,GRP_LAI,LAI_DATE,20010301 -US-SP3,28616,GRP_LAI,LAI_DATE,20010401 -US-SP3,29223,GRP_LAI,LAI_DATE,20010501 -US-SP3,29330,GRP_LAI,LAI_DATE,20010601 -US-SP3,27090,GRP_LAI,LAI_DATE,20010701 -US-SP3,29331,GRP_LAI,LAI_DATE,20010801 -US-SP3,29224,GRP_LAI,LAI_DATE,20010901 -US-SP3,27736,GRP_LAI,LAI_DATE,20011001 -US-SP3,27737,GRP_LAI,LAI_DATE,20011101 -US-SP3,28855,GRP_LAI,LAI_DATE,20011201 -US-SP3,27738,GRP_LAI,LAI_DATE,2002 -US-SP3,27091,GRP_LAI,LAI_DATE,20020201 -US-SP3,27637,GRP_LAI,LAI_DATE,20020301 -US-SP3,29225,GRP_LAI,LAI_DATE,20020401 -US-SP3,27638,GRP_LAI,LAI_DATE,20020501 -US-SP3,27388,GRP_LAI,LAI_DATE,20020601 -US-SP3,28617,GRP_LAI,LAI_DATE,20020701 -US-SP3,27389,GRP_LAI,LAI_DATE,20020801 -US-SP3,28618,GRP_LAI,LAI_DATE,20020901 -US-SP3,29543,GRP_LAI,LAI_DATE,20021001 -US-SP3,27092,GRP_LAI,LAI_DATE,20021101 -US-SP3,29332,GRP_LAI,LAI_DATE,20021201 -US-SP3,27093,GRP_LAI,LAI_DATE,2003 -US-SP3,26799,GRP_LAI,LAI_DATE,20030201 -US-SP3,27739,GRP_LAI,LAI_DATE,20030301 -US-SP3,27740,GRP_LAI,LAI_DATE,20030401 -US-SP3,26800,GRP_LAI,LAI_DATE,20030501 -US-SP3,29226,GRP_LAI,LAI_DATE,20030601 -US-SP3,29544,GRP_LAI,LAI_DATE,20030701 -US-SP3,28347,GRP_LAI,LAI_DATE,20030801 -US-SP3,27639,GRP_LAI,LAI_DATE,20030901 -US-SP3,27094,GRP_LAI,LAI_DATE,20031001 -US-SP3,28619,GRP_LAI,LAI_DATE,20031101 -US-SP3,27390,GRP_LAI,LAI_DATE,20031201 -US-SP3,27391,GRP_LAI,LAI_DATE,2004 -US-SP3,27392,GRP_LAI,LAI_DATE,20040201 -US-SP3,27095,GRP_LAI,LAI_DATE,20040301 -US-SP3,27640,GRP_LAI,LAI_DATE,20040401 -US-SP3,28348,GRP_LAI,LAI_DATE,20040501 -US-SP3,29545,GRP_LAI,LAI_DATE,20040601 -US-SP3,27741,GRP_LAI,LAI_DATE,20040701 -US-SP3,26801,GRP_LAI,LAI_DATE,20040801 -US-SP3,28856,GRP_LAI,LAI_DATE,20040901 -US-SP3,26802,GRP_LAI,LAI_DATE,20041001 -US-SP3,29546,GRP_LAI,LAI_DATE,20041101 -US-SP3,29227,GRP_LAI,LAI_DATE,20041201 -US-SP3,29333,GRP_LAI,LAI_DATE,2005 -US-SP3,28349,GRP_LAI,LAI_DATE,20050201 -US-SP3,28003,GRP_LAI,LAI_DATE,20050301 -US-SP3,28004,GRP_LAI,LAI_DATE,20050401 -US-SP3,28005,GRP_LAI,LAI_DATE,20050501 -US-SP3,27393,GRP_LAI,LAI_DATE,20050601 -US-SP3,28006,GRP_LAI,LAI_DATE,20050701 -US-SP3,27641,GRP_LAI,LAI_DATE,20050801 -US-SP3,28350,GRP_LAI,LAI_DATE,20050901 -US-SP3,27642,GRP_LAI,LAI_DATE,20051001 -US-SP3,28351,GRP_LAI,LAI_DATE,20051101 -US-SP3,26803,GRP_LAI,LAI_DATE,20051201 -US-SP3,26804,GRP_LAI,LAI_DATE,2006 -US-SP3,27742,GRP_LAI,LAI_DATE,20060201 -US-SP3,27743,GRP_LAI,LAI_DATE,20060301 -US-SP3,29228,GRP_LAI,LAI_DATE,20060401 -US-SP3,29547,GRP_LAI,LAI_DATE,20060501 -US-SP3,28352,GRP_LAI,LAI_DATE,20060601 -US-SP3,29548,GRP_LAI,LAI_DATE,20060701 -US-SP3,27394,GRP_LAI,LAI_DATE,20060801 -US-SP3,27395,GRP_LAI,LAI_DATE,20060901 -US-SP3,27396,GRP_LAI,LAI_DATE,20061001 -US-SP3,28620,GRP_LAI,LAI_DATE,20061101 -US-SP3,29549,GRP_LAI,LAI_DATE,20061201 -US-SP3,27096,GRP_LAI,LAI_DATE,2007 -US-SP3,29550,GRP_LAI,LAI_DATE,20070201 -US-SP3,26797,GRP_LAI,LAI_COMMENT,LAI is calculated from monthly litter fall -US-SP3,26798,GRP_LAI,LAI_COMMENT,LAI is calculated from monthly litter fall -US-SP3,26799,GRP_LAI,LAI_COMMENT,LAI is calculated from monthly litter fall -US-SP3,26800,GRP_LAI,LAI_COMMENT,LAI is calculated from monthly litter fall -US-SP3,26801,GRP_LAI,LAI_COMMENT,LAI is calculated from monthly litter fall -US-SP3,26802,GRP_LAI,LAI_COMMENT,LAI is calculated from monthly litter fall -US-SP3,26803,GRP_LAI,LAI_COMMENT,LAI is calculated from monthly litter fall -US-SP3,26804,GRP_LAI,LAI_COMMENT,LAI is calculated from monthly litter fall -US-SP3,27088,GRP_LAI,LAI_COMMENT,LAI is calculated from monthly litter fall -US-SP3,27089,GRP_LAI,LAI_COMMENT,LAI is calculated from monthly litter fall -US-SP3,27090,GRP_LAI,LAI_COMMENT,LAI is calculated from monthly litter fall -US-SP3,27091,GRP_LAI,LAI_COMMENT,LAI is calculated from monthly litter fall -US-SP3,27092,GRP_LAI,LAI_COMMENT,LAI is calculated from monthly litter fall -US-SP3,27093,GRP_LAI,LAI_COMMENT,LAI is calculated from monthly litter fall -US-SP3,27094,GRP_LAI,LAI_COMMENT,LAI is calculated from monthly litter fall -US-SP3,27095,GRP_LAI,LAI_COMMENT,LAI is calculated from monthly litter fall -US-SP3,27096,GRP_LAI,LAI_COMMENT,LAI is calculated from monthly litter fall -US-SP3,27387,GRP_LAI,LAI_COMMENT,LAI is calculated from monthly litter fall -US-SP3,27388,GRP_LAI,LAI_COMMENT,LAI is calculated from monthly litter fall -US-SP3,27389,GRP_LAI,LAI_COMMENT,LAI is calculated from monthly litter fall -US-SP3,27390,GRP_LAI,LAI_COMMENT,LAI is calculated from monthly litter fall -US-SP3,27391,GRP_LAI,LAI_COMMENT,LAI is calculated from monthly litter fall -US-SP3,27392,GRP_LAI,LAI_COMMENT,LAI is calculated from monthly litter fall -US-SP3,27393,GRP_LAI,LAI_COMMENT,LAI is calculated from monthly litter fall -US-SP3,27394,GRP_LAI,LAI_COMMENT,LAI is calculated from monthly litter fall -US-SP3,27395,GRP_LAI,LAI_COMMENT,LAI is calculated from monthly litter fall -US-SP3,27396,GRP_LAI,LAI_COMMENT,LAI is calculated from monthly litter fall -US-SP3,27636,GRP_LAI,LAI_COMMENT,LAI is calculated from monthly litter fall -US-SP3,27637,GRP_LAI,LAI_COMMENT,LAI is calculated from monthly litter fall -US-SP3,27638,GRP_LAI,LAI_COMMENT,LAI is calculated from monthly litter fall -US-SP3,27639,GRP_LAI,LAI_COMMENT,LAI is calculated from monthly litter fall -US-SP3,27640,GRP_LAI,LAI_COMMENT,LAI is calculated from monthly litter fall -US-SP3,27641,GRP_LAI,LAI_COMMENT,LAI is calculated from monthly litter fall -US-SP3,27642,GRP_LAI,LAI_COMMENT,LAI is calculated from monthly litter fall -US-SP3,27736,GRP_LAI,LAI_COMMENT,LAI is calculated from monthly litter fall -US-SP3,27737,GRP_LAI,LAI_COMMENT,LAI is calculated from monthly litter fall -US-SP3,27738,GRP_LAI,LAI_COMMENT,LAI is calculated from monthly litter fall -US-SP3,27739,GRP_LAI,LAI_COMMENT,LAI is calculated from monthly litter fall -US-SP3,27740,GRP_LAI,LAI_COMMENT,LAI is calculated from monthly litter fall -US-SP3,27741,GRP_LAI,LAI_COMMENT,LAI is calculated from monthly litter fall -US-SP3,27742,GRP_LAI,LAI_COMMENT,LAI is calculated from monthly litter fall -US-SP3,27743,GRP_LAI,LAI_COMMENT,LAI is calculated from monthly litter fall -US-SP3,27999,GRP_LAI,LAI_COMMENT,LAI is calculated from monthly litter fall -US-SP3,28000,GRP_LAI,LAI_COMMENT,LAI is calculated from monthly litter fall -US-SP3,28001,GRP_LAI,LAI_COMMENT,LAI is calculated from monthly litter fall -US-SP3,28002,GRP_LAI,LAI_COMMENT,LAI is calculated from monthly litter fall -US-SP3,28003,GRP_LAI,LAI_COMMENT,LAI is calculated from monthly litter fall -US-SP3,28004,GRP_LAI,LAI_COMMENT,LAI is calculated from monthly litter fall -US-SP3,28005,GRP_LAI,LAI_COMMENT,LAI is calculated from monthly litter fall -US-SP3,28006,GRP_LAI,LAI_COMMENT,LAI is calculated from monthly litter fall -US-SP3,28346,GRP_LAI,LAI_COMMENT,LAI is calculated from monthly litter fall -US-SP3,28347,GRP_LAI,LAI_COMMENT,LAI is calculated from monthly litter fall -US-SP3,28348,GRP_LAI,LAI_COMMENT,LAI is calculated from monthly litter fall -US-SP3,28349,GRP_LAI,LAI_COMMENT,LAI is calculated from monthly litter fall -US-SP3,28350,GRP_LAI,LAI_COMMENT,LAI is calculated from monthly litter fall -US-SP3,28351,GRP_LAI,LAI_COMMENT,LAI is calculated from monthly litter fall -US-SP3,28352,GRP_LAI,LAI_COMMENT,LAI is calculated from monthly litter fall -US-SP3,28613,GRP_LAI,LAI_COMMENT,LAI is calculated from monthly litter fall -US-SP3,28614,GRP_LAI,LAI_COMMENT,LAI is calculated from monthly litter fall -US-SP3,28615,GRP_LAI,LAI_COMMENT,LAI is calculated from monthly litter fall -US-SP3,28616,GRP_LAI,LAI_COMMENT,LAI is calculated from monthly litter fall -US-SP3,28617,GRP_LAI,LAI_COMMENT,LAI is calculated from monthly litter fall -US-SP3,28618,GRP_LAI,LAI_COMMENT,LAI is calculated from monthly litter fall -US-SP3,28619,GRP_LAI,LAI_COMMENT,LAI is calculated from monthly litter fall -US-SP3,28620,GRP_LAI,LAI_COMMENT,LAI is calculated from monthly litter fall -US-SP3,28852,GRP_LAI,LAI_COMMENT,LAI is calculated from monthly litter fall -US-SP3,28853,GRP_LAI,LAI_COMMENT,LAI is calculated from monthly litter fall -US-SP3,28854,GRP_LAI,LAI_COMMENT,LAI is calculated from monthly litter fall -US-SP3,28855,GRP_LAI,LAI_COMMENT,LAI is calculated from monthly litter fall -US-SP3,28856,GRP_LAI,LAI_COMMENT,LAI is calculated from monthly litter fall -US-SP3,29220,GRP_LAI,LAI_COMMENT,LAI is calculated from monthly litter fall -US-SP3,29221,GRP_LAI,LAI_COMMENT,LAI is calculated from monthly litter fall -US-SP3,29222,GRP_LAI,LAI_COMMENT,LAI is calculated from monthly litter fall -US-SP3,29223,GRP_LAI,LAI_COMMENT,LAI is calculated from monthly litter fall -US-SP3,29224,GRP_LAI,LAI_COMMENT,LAI is calculated from monthly litter fall -US-SP3,29225,GRP_LAI,LAI_COMMENT,LAI is calculated from monthly litter fall -US-SP3,29226,GRP_LAI,LAI_COMMENT,LAI is calculated from monthly litter fall -US-SP3,29227,GRP_LAI,LAI_COMMENT,LAI is calculated from monthly litter fall -US-SP3,29228,GRP_LAI,LAI_COMMENT,LAI is calculated from monthly litter fall -US-SP3,29328,GRP_LAI,LAI_COMMENT,LAI is calculated from monthly litter fall -US-SP3,29329,GRP_LAI,LAI_COMMENT,LAI is calculated from monthly litter fall -US-SP3,29330,GRP_LAI,LAI_COMMENT,LAI is calculated from monthly litter fall -US-SP3,29331,GRP_LAI,LAI_COMMENT,LAI is calculated from monthly litter fall -US-SP3,29332,GRP_LAI,LAI_COMMENT,LAI is calculated from monthly litter fall -US-SP3,29333,GRP_LAI,LAI_COMMENT,LAI is calculated from monthly litter fall -US-SP3,29540,GRP_LAI,LAI_COMMENT,LAI is calculated from monthly litter fall -US-SP3,29541,GRP_LAI,LAI_COMMENT,LAI is calculated from monthly litter fall -US-SP3,29542,GRP_LAI,LAI_COMMENT,LAI is calculated from monthly litter fall -US-SP3,29543,GRP_LAI,LAI_COMMENT,LAI is calculated from monthly litter fall -US-SP3,29544,GRP_LAI,LAI_COMMENT,LAI is calculated from monthly litter fall -US-SP3,29545,GRP_LAI,LAI_COMMENT,LAI is calculated from monthly litter fall -US-SP3,29546,GRP_LAI,LAI_COMMENT,LAI is calculated from monthly litter fall -US-SP3,29547,GRP_LAI,LAI_COMMENT,LAI is calculated from monthly litter fall -US-SP3,29548,GRP_LAI,LAI_COMMENT,LAI is calculated from monthly litter fall -US-SP3,29549,GRP_LAI,LAI_COMMENT,LAI is calculated from monthly litter fall -US-SP3,29550,GRP_LAI,LAI_COMMENT,LAI is calculated from monthly litter fall -US-SP3,29550,GRP_LAI,LAI_TOT,2.38 -US-SP3,27096,GRP_LAI,LAI_TOT,2.44 -US-SP3,29549,GRP_LAI,LAI_TOT,2.57 -US-SP3,28620,GRP_LAI,LAI_TOT,2.87 -US-SP3,28349,GRP_LAI,LAI_TOT,3.35 -US-SP3,29333,GRP_LAI,LAI_TOT,3.52 -US-SP3,28852,GRP_LAI,LAI_TOT,3.53 -US-SP3,27743,GRP_LAI,LAI_TOT,3.60 -US-SP3,27396,GRP_LAI,LAI_TOT,3.62 -US-SP3,29228,GRP_LAI,LAI_TOT,3.76 -US-SP3,29227,GRP_LAI,LAI_TOT,3.82 -US-SP3,27091,GRP_LAI,LAI_TOT,3.84 -US-SP3,27392,GRP_LAI,LAI_TOT,3.85 -US-SP3,29220,GRP_LAI,LAI_TOT,3.85 -US-SP3,27637,GRP_LAI,LAI_TOT,3.92 -US-SP3,27095,GRP_LAI,LAI_TOT,3.93 -US-SP3,29542,GRP_LAI,LAI_TOT,4.01 -US-SP3,27391,GRP_LAI,LAI_TOT,4.05 -US-SP3,27089,GRP_LAI,LAI_TOT,4.07 -US-SP3,27738,GRP_LAI,LAI_TOT,4.09 -US-SP3,29547,GRP_LAI,LAI_TOT,4.11 -US-SP3,27088,GRP_LAI,LAI_TOT,4.21 -US-SP3,27640,GRP_LAI,LAI_TOT,4.25 -US-SP3,28002,GRP_LAI,LAI_TOT,4.28 -US-SP3,29225,GRP_LAI,LAI_TOT,4.31 -US-SP3,29546,GRP_LAI,LAI_TOT,4.31 -US-SP3,27395,GRP_LAI,LAI_TOT,4.33 -US-SP3,28615,GRP_LAI,LAI_TOT,4.35 -US-SP3,27390,GRP_LAI,LAI_TOT,4.36 -US-SP3,29328,GRP_LAI,LAI_TOT,4.36 -US-SP3,28001,GRP_LAI,LAI_TOT,4.37 -US-SP3,26799,GRP_LAI,LAI_TOT,4.39 -US-SP3,27742,GRP_LAI,LAI_TOT,4.40 -US-SP3,28855,GRP_LAI,LAI_TOT,4.41 -US-SP3,29540,GRP_LAI,LAI_TOT,4.42 -US-SP3,28003,GRP_LAI,LAI_TOT,4.43 -US-SP3,28000,GRP_LAI,LAI_TOT,4.46 -US-SP3,28352,GRP_LAI,LAI_TOT,4.47 -US-SP3,27739,GRP_LAI,LAI_TOT,4.48 -US-SP3,27093,GRP_LAI,LAI_TOT,4.49 -US-SP3,26804,GRP_LAI,LAI_TOT,4.51 -US-SP3,29222,GRP_LAI,LAI_TOT,4.55 -US-SP3,28616,GRP_LAI,LAI_TOT,4.59 -US-SP3,27394,GRP_LAI,LAI_TOT,4.60 -US-SP3,29548,GRP_LAI,LAI_TOT,4.65 -US-SP3,26802,GRP_LAI,LAI_TOT,4.76 -US-SP3,27740,GRP_LAI,LAI_TOT,4.78 -US-SP3,28004,GRP_LAI,LAI_TOT,4.78 -US-SP3,29332,GRP_LAI,LAI_TOT,4.82 -US-SP3,26797,GRP_LAI,LAI_TOT,4.85 -US-SP3,26803,GRP_LAI,LAI_TOT,4.89 -US-SP3,28348,GRP_LAI,LAI_TOT,4.89 -US-SP3,27638,GRP_LAI,LAI_TOT,4.93 -US-SP3,27999,GRP_LAI,LAI_TOT,4.94 -US-SP3,27737,GRP_LAI,LAI_TOT,4.98 -US-SP3,28619,GRP_LAI,LAI_TOT,5.00 -US-SP3,29223,GRP_LAI,LAI_TOT,5.05 -US-SP3,27636,GRP_LAI,LAI_TOT,5.24 -US-SP3,29221,GRP_LAI,LAI_TOT,5.29 -US-SP3,27092,GRP_LAI,LAI_TOT,5.35 -US-SP3,28005,GRP_LAI,LAI_TOT,5.36 -US-SP3,28853,GRP_LAI,LAI_TOT,5.36 -US-SP3,28614,GRP_LAI,LAI_TOT,5.39 -US-SP3,26800,GRP_LAI,LAI_TOT,5.43 -US-SP3,28351,GRP_LAI,LAI_TOT,5.44 -US-SP3,29330,GRP_LAI,LAI_TOT,5.55 -US-SP3,27094,GRP_LAI,LAI_TOT,5.66 -US-SP3,27388,GRP_LAI,LAI_TOT,5.70 -US-SP3,27387,GRP_LAI,LAI_TOT,5.73 -US-SP3,27736,GRP_LAI,LAI_TOT,5.73 -US-SP3,28856,GRP_LAI,LAI_TOT,5.73 -US-SP3,29545,GRP_LAI,LAI_TOT,5.75 -US-SP3,27642,GRP_LAI,LAI_TOT,5.81 -US-SP3,26798,GRP_LAI,LAI_TOT,5.89 -US-SP3,28346,GRP_LAI,LAI_TOT,5.90 -US-SP3,29541,GRP_LAI,LAI_TOT,5.94 -US-SP3,27090,GRP_LAI,LAI_TOT,6.00 -US-SP3,28613,GRP_LAI,LAI_TOT,6.00 -US-SP3,29329,GRP_LAI,LAI_TOT,6.06 -US-SP3,29543,GRP_LAI,LAI_TOT,6.07 -US-SP3,27639,GRP_LAI,LAI_TOT,6.10 -US-SP3,28854,GRP_LAI,LAI_TOT,6.13 -US-SP3,27393,GRP_LAI,LAI_TOT,6.14 -US-SP3,28350,GRP_LAI,LAI_TOT,6.14 -US-SP3,29224,GRP_LAI,LAI_TOT,6.21 -US-SP3,29226,GRP_LAI,LAI_TOT,6.21 -US-SP3,29331,GRP_LAI,LAI_TOT,6.28 -US-SP3,28617,GRP_LAI,LAI_TOT,6.37 -US-SP3,27741,GRP_LAI,LAI_TOT,6.38 -US-SP3,28618,GRP_LAI,LAI_TOT,6.46 -US-SP3,28347,GRP_LAI,LAI_TOT,6.49 -US-SP3,27641,GRP_LAI,LAI_TOT,6.50 -US-SP3,26801,GRP_LAI,LAI_TOT,6.54 -US-SP3,28006,GRP_LAI,LAI_TOT,6.59 -US-SP3,27389,GRP_LAI,LAI_TOT,6.60 -US-SP3,29544,GRP_LAI,LAI_TOT,6.63 -US-SP3,8792,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -US-SP3,8792,GRP_LAND_OWNERSHIP,LAND_OWNER,Private -US-SP3,28592,GRP_LMA,LMA,50 -US-SP3,28592,GRP_LMA,LMA_SPP,(All) -US-SP3,2402,GRP_LOCATION,LOCATION_LAT,29.7548 -US-SP3,2402,GRP_LOCATION,LOCATION_LONG,-82.1633 -US-SP3,2402,GRP_LOCATION,LOCATION_ELEV,50 -US-SP3,24539,GRP_N_DEP,N_DEP_WET,1.35 -US-SP3,29064,GRP_NEP,NEP,614200 -US-SP3,29064,GRP_NEP,NEP_APPROACH,Eddy covariance -US-SP3,29064,GRP_NEP,NEP_DATE_START,2006 -US-SP3,29064,GRP_NEP,NEP_DATE_END,2007 -US-SP3,29064,GRP_NEP,NEP_COMMENT,622 ± (83) gCm-2 yr-1 (9 years of measurements) -US-SP3,3817,GRP_NETWORK,NETWORK,AmeriFlux -US-SP3,1700004155,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Bracho, R., Starr, G., Gholz, H. L., Martin, T. A., Cropper, W. P., Loescher, H. W. (2012) Controls On Carbon Dynamics By Ecosystem Structure And Climate For Southeastern U.S. Slash Pine Plantations, Ecological Monographs, 82(1), 101-128" -US-SP3,1700004155,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1890/11-0587.1 -US-SP3,1700004155,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-SP3,1700003300,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Castro, M. S., Gholz, H. L., Clark, K. L., Steudler, P. A. (2000) Effects Of Forest Harvesting On Soil Methane Fluxes In Florida Slash Pine Plantations, Canadian Journal Of Forest Research, 30(10), 1534-1542" -US-SP3,1700003300,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1139/CJFR-30-10-1534 -US-SP3,1700003300,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-SP3,1700007416,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Baldocchi, D. D., Poindexter, C., Abraha, M., Desai, A. R., Bohrer, G., Arain, M. A., Griffis, T., Blanken, P. D., O'Halloran, T. L., Thomas, R. Q., Zhang, Q., Burns, S. P., Frank, J. M., Christian, D., Brown, S., Black, T. A., Gough, C. M., Law, B. E., Lee, X., Chen, J., Reed, D. E., Massman, W. J., Clark, K., Hatfield, J., Prueger, J., Bracho, R., Baker, J. M., Martin, T. A. (2018) Temporal Dynamics Of Aerodynamic Canopy Height Derived From Eddy Covariance Momentum Flux Data Across North American Flux Networks, Geophysical Research Letters, 45(1), 9275–9287" -US-SP3,1700007416,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018GL079306 -US-SP3,1700007416,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-SP3,1700008814,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Baldocchi, D. D., Poindexter, C., Abraha, M., Desai, A. R., Bohrer, G., Arain, M. A., Griffis, T., Blanken, P. D., O'Halloran, T. L., Thomas, R. Q., Zhang, Q., Burns, S. P., Frank, J. M., Christian, D., Brown, S., Black, T. A., Gough, C. M., Law, B. E., Lee, X., Chen, J., Reed, D. E., Massman, W. J., Clark, K., Hatfield, J., Prueger, J., Bracho, R., Baker, J. M., Martin, T. A. (2018) Temporal Dynamics Of Aerodynamic Canopy Height Derived From Eddy Covariance Momentum Flux Data Across North American Flux Networks, Geophysical Research Letters, 45(4), 9275–9287" -US-SP3,1700008814,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018GL079306 -US-SP3,1700008814,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-SP3,1700004410,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(1), 108350" -US-SP3,1700004410,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -US-SP3,1700004410,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-SP3,1700006582,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Clark, K. L., Gholz, H. L., Castro, M. S. (2004) Carbon Dynamics Along A Chronosequence Of Slash Pine Plantations In North Florida, Ecological Applications, 14(4), 1154-1171" -US-SP3,1700006582,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1890/02-5391 -US-SP3,1700006582,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-SP3,1700000858,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Clark, K. L., Gholz, H. L., Moncrieff, J. B., Cropley, F., Loescher, H. W. (1999) Environmental Controls Over Net Exchanges Of Carbon Dioxide From Contrasting Florida Ecosystems, Ecological Applications, 9(3), 936-948" -US-SP3,1700000858,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.2307/2641340 -US-SP3,1700000858,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-SP3,1700000333,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Dennis Baldocchi, Cove Sturtevant (2015) Does day and night sampling reduce spurious correlation between canopy photosynthesis and ecosystem respiration?, Agricultural and Forest Meteorology, 207(4), 117-126" -US-SP3,1700000333,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2015.03.010 -US-SP3,1700000333,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-SP3,1700003492,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Gholz, H. L., Clark, K. L. (2002) Energy Exchange Across A Chronosequence Of Slash Pine Forests In Florida, Agricultural And Forest Meteorology, 112(2), 87-102" -US-SP3,1700003492,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/S0168-1923(02)00059-X -US-SP3,1700003492,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-SP3,1700000921,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Gholz, H. L., Guerin, D. N., Cropper, W. P. (1999) Phenology And Productivity Of Saw Palmetto ( Serenoa Repens ) In A North Florida Slash Pine Plantation, Canadian Journal Of Forest Research, 29(8), 1248-1253" -US-SP3,1700000921,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1139/CJFR-29-8-1248 -US-SP3,1700000921,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-SP3,1700005859,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Moncrieff, J. B., Fang, C. (1999) A Model For Soil CO2 Production And Transport 2: Application To A Florida Pinus Elliotte Plantation, Agricultural And Forest Meteorology, 95(4), 237-256" -US-SP3,1700005859,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/S0168-1923(99)00035-0 -US-SP3,1700005859,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-SP3,1700005793,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"POWELL, T. L., GHOLZ, H. L., CLARK, K. L., STARR, G., CROPPER, W. P., MARTIN, T. A. (2008) Carbon Exchange Of A Mature, Naturally Regenerated Pine Forest In North Florida, Global Change Biology, 45(1), 9275–9287" -US-SP3,1700005793,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/J.1365-2486.2008.01675.X -US-SP3,1700005793,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-SP3,1700008577,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"POWELL, T. L., GHOLZ, H. L., CLARK, K. L., STARR, G., CROPPER, W. P., MARTIN, T. A. (2008) Carbon Exchange Of A Mature, Naturally Regenerated Pine Forest In North Florida, Global Change Biology, 45(4), 9275–9287" -US-SP3,1700008577,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/J.1365-2486.2008.01675.X -US-SP3,1700008577,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-SP3,10161,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"The research and science objectives of the Donaldson site are as follows: 1) Quantify the carbon dynamics of intensively managed pine plantations; 2) Investigate the energy partitioning and changes in carbon sequestration across a slash pine management cycle, or rotation, in north-central Florida; 3) Quantify ecosystem water and energy budgets and the determining environmental variables; 4) Determine the dominant environmental factors controlling the seasonal partitioning of net radiation into the main energy budget components of latent energy flux and sensible heat flux. (Powell et al., 2008, Powell et al., 2005, Gholz and Clark, 2002)" -US-SP3,26914,GRP_SA,SA,18 -US-SP3,26914,GRP_SA,SA_DATE,2008 -US-SP3,26914,GRP_SA,SA_COMMENT,even-aged plantation -US-SP3,27068,GRP_SA,SA_DATE,2008 -US-SP3,27068,GRP_SA,SA_MAX,18 -US-SP3,1585,GRP_SITE_CHAR,TERRAIN,Flat -US-SP3,9651,GRP_SITE_DESC,SITE_DESC,"Slash pine planted end of 1989 early 1990. Gholz and Clark, 2002. Agric. Forest Meteo. 112, 87 - 102; Ckark et al., 2004. Ecological Applications, 14, 1154 - 1171." -US-SP3,3313,GRP_SITE_FUNDING,SITE_FUNDING,DOE/NIGEC -US-SP3,29063,GRP_SNAG_MASS,SNAG_MASS,78.25 -US-SP3,29063,GRP_SNAG_MASS,SNAG_MASS_UNIT,gC m-2 -US-SP3,29063,GRP_SNAG_MASS,SNAG_MASS_DATE,2007 -US-SP3,28330,GRP_SOIL_CHEM,SOIL_CHEM_C_ORG,8 -US-SP3,27611,GRP_SOIL_CHEM,SOIL_CHEM_BD,1.21 -US-SP3,27611,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,10 -US-SP3,28330,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,10 -US-SP3,28330,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,100 -US-SP3,27611,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,150 -US-SP3,27611,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,1.5 measured at 0.5m -US-SP3,28087,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION,"Poorly drained ultic alaquods (sandy, silicecous, thermic) overlying a discontinuous spodic horizon spanning from 0.30 - 0.80 m deep transitioning to an argillic horizon at depths below 0.80 m" -US-SP3,28087,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION_TAXONOMY,Other -US-SP3,29175,GRP_SOIL_DEPTH,SOIL_DEPTH,300 -US-SP3,27357,GRP_SOIL_TEX,SOIL_TEX_SAND,99 -US-SP3,27357,GRP_SOIL_TEX,SOIL_TEX_SILT,0 -US-SP3,27357,GRP_SOIL_TEX,SOIL_TEX_CLAY,1 -US-SP3,26769,GRP_SPP_O,SPP_O,PIELE2 (NRCS plant code) -US-SP3,26769,GRP_SPP_O,SPP_O_PERC,100 -US-SP3,26769,GRP_SPP_O,SPP_APPROACH,Inventory -US-SP3,26769,GRP_SPP_O,SPP_DATE,2008 -US-SP3,29176,GRP_SPP_U,SPP_U,ILGL (NRCS plant code) -US-SP3,27062,GRP_SPP_U,SPP_U,MYCE (NRCS plant code) -US-SP3,29052,GRP_SPP_U,SPP_U,SERE2 (NRCS plant code) -US-SP3,27062,GRP_SPP_U,SPP_APPROACH,Clipping plots -US-SP3,29052,GRP_SPP_U,SPP_APPROACH,Clipping plots -US-SP3,29176,GRP_SPP_U,SPP_APPROACH,Clipping plots -US-SP3,27062,GRP_SPP_U,SPP_DATE,2008 -US-SP3,29052,GRP_SPP_U,SPP_DATE,2008 -US-SP3,29176,GRP_SPP_U,SPP_DATE,2008 -US-SP3,9176,GRP_STATE,STATE,FL -US-SP3,4028,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Tim Martin -US-SP3,4028,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-SP3,4028,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,tamartin@ufl.edu -US-SP3,4028,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Florida -US-SP3,4028,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"P.O. Box 110410, 326 Newins Ziegler Hall,Gainesville, FL USA 32611-0410" -US-SP3,91807,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Rosvel Bracho -US-SP3,91807,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,AncContact -US-SP3,91807,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,rbracho@ufl.edu -US-SP3,91807,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Florida -US-SP3,91807,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"School of Forest Resources and Conservation, 224B Newins-Ziegler Hall,Gainesville, FL USA 32611" -US-SP3,5849,GRP_URL,URL,http://carboncenter.ifas.ufl.edu/ameriflux.shtml -US-SP3,24000432,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-SP3 -US-SP3,251,GRP_UTC_OFFSET,UTC_OFFSET,-5 -US-SP4,37,GRP_CLIM_AVG,MAT,20 -US-SP4,37,GRP_CLIM_AVG,MAP,1319.63 -US-SP4,37,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Cfa -US-SP4,27000433,GRP_COUNTRY,COUNTRY,USA -US-SP4,15677,GRP_DOI,DOI,10.17190/AMF/1246103 -US-SP4,15677,GRP_DOI,DOI_CITATION,"Tim Martin (2019), AmeriFlux BASE US-SP4 Slashpine-Rayonier-mid-rot- 12yrs, Ver. 3-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1246103" -US-SP4,15677,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-SP4,32203,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-SP4,32203,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Tim Martin -US-SP4,32203,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-SP4,32203,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,tamartin@ufl.edu -US-SP4,32203,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of Florida -US-SP4,32205,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,University of Florida -US-SP4,32205,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-SP4,32204,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,DOE/TCP -US-SP4,32204,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-SP4,412,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-SP4,412,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-SP4,412,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,1998 -US-SP4,412,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,1998 -US-SP4,412,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-SP4,23000433,GRP_HEADER,SITE_NAME,Slashpine-Rayonier-mid-rot- 12yrs -US-SP4,8572,GRP_IGBP,IGBP,ENF -US-SP4,4063,GRP_LOCATION,LOCATION_LAT,29.8028 -US-SP4,4063,GRP_LOCATION,LOCATION_LONG,-82.2031 -US-SP4,4063,GRP_LOCATION,LOCATION_ELEV,47 -US-SP4,9821,GRP_NETWORK,NETWORK,AmeriFlux -US-SP4,1700006021,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Castro, M. S., Gholz, H. L., Clark, K. L., Steudler, P. A. (2000) Effects Of Forest Harvesting On Soil Methane Fluxes In Florida Slash Pine Plantations, Canadian Journal Of Forest Research, 30(10), 1534-1542" -US-SP4,1700006021,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1139/CJFR-30-10-1534 -US-SP4,1700006021,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-SP4,1700001257,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Clark, K. L., Gholz, H. L., Castro, M. S. (2004) Carbon Dynamics Along A Chronosequence Of Slash Pine Plantations In North Florida, Ecological Applications, 14(4), 1154-1171" -US-SP4,1700001257,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1890/02-5391 -US-SP4,1700001257,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-SP4,1700000228,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Clark, K. L., Gholz, H. L., Moncrieff, J. B., Cropley, F., Loescher, H. W. (1999) Environmental Controls Over Net Exchanges Of Carbon Dioxide From Contrasting Florida Ecosystems, Ecological Applications, 9(3), 936-948" -US-SP4,1700000228,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.2307/2641340 -US-SP4,1700000228,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-SP4,1700008664,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Gholz, H. L., Clark, K. L. (2002) Energy Exchange Across A Chronosequence Of Slash Pine Forests In Florida, Agricultural And Forest Meteorology, 112(2), 87-102" -US-SP4,1700008664,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/S0168-1923(02)00059-X -US-SP4,1700008664,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-SP4,1700005073,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Gholz, H. L., Guerin, D. N., Cropper, W. P. (1999) Phenology And Productivity Of Saw Palmetto ( Serenoa Repens ) In A North Florida Slash Pine Plantation, Canadian Journal Of Forest Research, 29(8), 1248-1253" -US-SP4,1700005073,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1139/CJFR-29-8-1248 -US-SP4,1700005073,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-SP4,1700003681,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Moncrieff, J. B., Fang, C. (1999) A Model For Soil CO2 Production And Transport 2: Application To A Florida Pinus Elliotte Plantation, Agricultural And Forest Meteorology, 95(4), 237-256" -US-SP4,1700003681,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/S0168-1923(99)00035-0 -US-SP4,1700003681,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-SP4,4130,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"The research and science objectives of the Rayonier site were as follows: 1) Quantify the carbon dynamics of intensively managed pine plantations; 2) Investigate the energy partitioning and changes in carbon sequestration across a slash pine management cycle, or rotation, in north-central Florida; 3) Quantify ecosystem water and energy budgets and the determining environmental variables; 4) Determine the dominant environmental factors controlling the seasonal partitioning of net radiation into the main energy budget components of latent energy flux and sensible heat flux. (Powell et al., 2008, Powell et al., 2005, Gholz and Clark, 2002)" -US-SP4,8399,GRP_SITE_CHAR,TERRAIN,Flat -US-SP4,4117,GRP_SITE_DESC,SITE_DESC,"Only active for one year, the Rayonier tract site was shutdown due to a stand replacing wild fire in 1998. The tower was relocated to the Donaldson tract. The characteristics between the two mid-rotation pine plantations are nearly indistinguishable, enabling the integration of measurements made at both towers. The site information provided below follows the convention that the two sites are nearly identical." -US-SP4,5877,GRP_SITE_FUNDING,SITE_FUNDING,DOE/TCP -US-SP4,28782,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION,"Poorly drained ultic alaquods (sandy, silicecous, thermic) overlying a discontinuous spodic horizon spanning from 0.30 - 0.80 m deep transitioning to an argillic horizon at depths below 0.80 m" -US-SP4,28782,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION_TAXONOMY,Other -US-SP4,8300,GRP_STATE,STATE,FL -US-SP4,1532,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Tim Martin -US-SP4,1532,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-SP4,1532,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,tamartin@ufl.edu -US-SP4,1532,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Florida -US-SP4,1532,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"P.O. Box 110410, 326 Newins Ziegler Hall,Gainesville, FL USA 32611-0410" -US-SP4,91795,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Rosvel Bracho -US-SP4,91795,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,AncContact -US-SP4,91795,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,rbracho@ufl.edu -US-SP4,91795,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Florida -US-SP4,91795,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"School of Forest Resources and Conservation, 224B Newins-Ziegler Hall,Gainesville, FL USA 32611" -US-SP4,9362,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Henry L. Gholz -US-SP4,9362,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Affiliate -US-SP4,9362,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,hgholz@nsf.edu -US-SP4,9362,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,National Science Foundation -US-SP4,9362,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Long-Term Ecological Research, 4201 Wilson Boulevard,Arlington, VA USA 22230" -US-SP4,742,GRP_URL,URL,http://carboncenter.ifas.ufl.edu/ameriflux.shtml -US-SP4,24000433,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-SP4 -US-SP4,4462,GRP_UTC_OFFSET,UTC_OFFSET,-5 -US-SRC,86654,GRP_CLIM_AVG,MAT,22 -US-SRC,86654,GRP_CLIM_AVG,MAP,330 -US-SRC,86654,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Bwh -US-SRC,27000487,GRP_COUNTRY,COUNTRY,USA -US-SRC,15719,GRP_DOI,DOI,10.17190/AMF/1246127 -US-SRC,15719,GRP_DOI,DOI_CITATION,"Shirley Kurc (2019), AmeriFlux BASE US-SRC Santa Rita Creosote, Ver. 6-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1246127" -US-SRC,15719,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-SRC,32277,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-SRC,32277,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Shirley Kurc -US-SRC,32277,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-SRC,32277,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,kurc@ag.arizona.edu -US-SRC,32277,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of Arizona -US-SRC,32279,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,University of Arizona -US-SRC,32279,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-SRC,32278,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,USDA CSREES -US-SRC,32278,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-SRC,86652,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-SRC,86652,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-SRC,86652,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,200804241200 -US-SRC,86652,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,201803110730 -US-SRC,86652,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-SRC,86648,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-SRC,86648,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-SRC,86648,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,200804241200 -US-SRC,86648,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,201803110730 -US-SRC,86648,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-SRC,23000487,GRP_HEADER,SITE_NAME,Santa Rita Creosote -US-SRC,88363,GRP_HEIGHTC,HEIGHTC,1.7 -US-SRC,88363,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-SRC,88363,GRP_HEIGHTC,HEIGHTC_DATE,20081108 -US-SRC,95116,GRP_IGBP,IGBP,OSH -US-SRC,86651,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-SRC,86651,GRP_LAND_OWNERSHIP,LAND_OWNER,University of Arizona -US-SRC,86655,GRP_LOCATION,LOCATION_LAT,31.9083 -US-SRC,86655,GRP_LOCATION,LOCATION_LONG,-110.8395 -US-SRC,86655,GRP_LOCATION,LOCATION_ELEV,950 -US-SRC,86655,GRP_LOCATION,LOCATION_DATE_START,20180925 -US-SRC,4705,GRP_NETWORK,NETWORK,AmeriFlux -US-SRC,1700008724,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(21), 108350" -US-SRC,1700008724,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -US-SRC,1700008724,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-SRC,1700002415,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Wolf, S., Keenan, T.F., Fisher, J.B., Baldocchi, D.D., Desai, A.R., Richardson, A.D., Scott, R.L., Law, B.E., Litvak, M.E., Brunsell, N.A., Peters, W., van der Laan-Luijkx, I.T. (2016) Warm spring reduced carbon cycle impact of the 2012 US summer drought, Proceedings of the National Academy of Sciences, 113(21), 5880-5885" -US-SRC,1700002415,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1073/PNAS.1519620113 -US-SRC,1700002415,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-SRC,757,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"1) Feedbacks between climate, phenology, and ecosystem scale fluxes of water, energy and carbon. 2) Spatial and temporal nature of soil moisture control on ecosystem scale fluxes of water, energy and carbon. 3) Understanding the role of widespread creosotebush on land-atmosphere interactions." -US-SRC,86650,GRP_SITE_CHAR,TERRAIN,Flat -US-SRC,86650,GRP_SITE_CHAR,ASPECT,FLAT -US-SRC,86650,GRP_SITE_CHAR,WIND_DIRECTION,SE -US-SRC,86650,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,500 -US-SRC,10140,GRP_SITE_DESC,SITE_DESC,Part of the Santa Rita Experimental Range since 1901; Site vegetation has been dominated by Creosote bush since at least 1934 -US-SRC,2471,GRP_SITE_FUNDING,SITE_FUNDING,USDA CSREES -US-SRC,28940,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION,Sandy Loam -US-SRC,28940,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION_TAXONOMY,Other -US-SRC,10014,GRP_STATE,STATE,AZ -US-SRC,95118,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Shirley (Kurc) Papuga -US-SRC,95118,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-SRC,95118,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,shirley.papuga@gmail.com -US-SRC,95118,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Wayne State University/University of Arizona -US-SRC,95118,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Department of Environmental Science and Geology, Wayne State University, Detroit, MI" -US-SRC,86647,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-SRC,86649,GRP_TOWER_TYPE,TOWER_TYPE,tripod -US-SRC,95117,GRP_URL,URL,https://studylib.net/doc/10668630/fluxletter-highlight-fluxnet-site--the-newsletter-of-fluxnet -US-SRC,24000487,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-SRC -US-SRC,33655,GRP_UTC_OFFSET,UTC_OFFSET,-7 -US-SRC,33655,GRP_UTC_OFFSET,UTC_OFFSET_COMMENT,Added by AMF data processing team for data QAQC checks. -US-SRG,11844,GRP_CLIM_AVG,MAT,17 -US-SRG,11844,GRP_CLIM_AVG,MAP,420 -US-SRG,11844,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Bsk -US-SRG,27000528,GRP_COUNTRY,COUNTRY,USA -US-SRG,15626,GRP_DOI,DOI,10.17190/AMF/1246154 -US-SRG,15626,GRP_DOI,DOI_CITATION,"Russell Scott (2022), AmeriFlux BASE US-SRG Santa Rita Grassland, Ver. 12-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1246154" -US-SRG,15626,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-SRG,32393,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-SRG,32393,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Russell Scott -US-SRG,32393,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-SRG,32393,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,russ.scott@ars.usda.gov -US-SRG,32393,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,United States Department of Agriculture -US-SRG,32395,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,United States Department of Agriculture -US-SRG,32395,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-SRG,32394,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,"USDA-ARS, DOE, University of Arizona" -US-SRG,32394,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-SRG,11845,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Grazing -US-SRG,11846,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-SRG,11846,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-SRG,11846,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20080308 -US-SRG,11846,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-SRG,11858,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-SRG,11858,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-SRG,11858,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20080308 -US-SRG,11858,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-SRG,23000528,GRP_HEADER,SITE_NAME,Santa Rita Grassland -US-SRG,88345,GRP_HEIGHTC,HEIGHTC,0.5 -US-SRG,88345,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-SRG,88345,GRP_HEIGHTC,HEIGHTC_DATE,20000101 -US-SRG,11847,GRP_IGBP,IGBP,GRA -US-SRG,11848,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-SRG,11848,GRP_LAND_OWNERSHIP,LAND_OWNER,University of Arizona College of Agriculture -US-SRG,11849,GRP_LOCATION,LOCATION_LAT,31.7894 -US-SRG,11849,GRP_LOCATION,LOCATION_LONG,-110.8277 -US-SRG,11849,GRP_LOCATION,LOCATION_ELEV,1291 -US-SRG,11850,GRP_NETWORK,NETWORK,AmeriFlux -US-SRG,1700006942,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Baldocchi, D., Penuelas, J. (2018) The Physics And Ecology Of Mining Carbon Dioxide From The Atmosphere By Ecosystems, Global Change Biology, 45(2), 748-757" -US-SRG,1700006942,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/GCB.14559 -US-SRG,1700006942,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-SRG,1700004350,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Biederman, J. A., Scott, R. L., Bell, T. W., Bowling, D. R., Dore, S., Garatuza-Payan, J., Kolb, T. E., Krishnan, P., Krofcheck, D. J., Litvak, M. E., Maurer, G. E., Meyers, T. P., Oechel, W. C., Papuga, S. A., Ponce-Campos, G. E., Rodriguez, J. C., Smith, W. K., Vargas, R., Watts, C. J., Yepez, E. A., Goulden, M. L. (2017) Co2 Exchange And Evapotranspiration Across Dryland Ecosystems Of Southwestern North America, Global Change Biology, 23(10), 4204-4221" -US-SRG,1700004350,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/GCB.13686 -US-SRG,1700004350,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-SRG,1700008190,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Biederman, J. A., Scott, R. L., Goulden, M. L., Vargas, R., Litvak, M. E., Kolb, T. E., Yepez, E. A., Oechel, W. C., Blanken, P. D., Bell, T. W., Garatuza-Payan, J., Maurer, G. E., Dore, S., Burns, S. P. (2016) Terrestrial Carbon Balance In A Drier World: The Effects Of Water Availability In Southwestern North America, Global Change Biology, 22(5), 1867-1879" -US-SRG,1700008190,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/GCB.13222 -US-SRG,1700008190,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-SRG,1700002859,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(6), 108350" -US-SRG,1700002859,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -US-SRG,1700002859,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-SRG,1700006873,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Novick, K. A., Ficklin, D. L., Stoy, P. C., Williams, C. A., Bohrer, G., Oishi, A., Papuga, S. A., Blanken, P. D., Noormets, A., Sulman, B. N., Scott, R. L., Wang, L., Phillips, R. P. (2016) The Increasing Importance Of Atmospheric Demand For Ecosystem Water And Carbon Fluxes, Nature Climate Change, 6(11), 1023-1027" -US-SRG,1700006873,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1038/NCLIMATE3114 -US-SRG,1700006873,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-SRG,1700001044,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Novick, K. A., Konings, A. G., Gentine, P. (2019) Beyond Soil Water Potential: An Expanded View On Isohydricity Including Land–Atmosphere Interactions And Phenology, Plant, Cell & Environment, 42(6), 1802-1815" -US-SRG,1700001044,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/PCE.13517 -US-SRG,1700001044,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-SRG,1700007029,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Scott, R. L., Biederman, J. A., Hamerlynck, E. P., Barron-Gafford, G. A. (2015) The Carbon Balance Pivot Point Of Southwestern U.S. Semiarid Ecosystems: Insights From The 21st Century Drought, Journal Of Geophysical Research: Biogeosciences, 120(12), 2612-2624" -US-SRG,1700007029,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/2015JG003181 -US-SRG,1700007029,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-SRG,1700003222,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Scott, R.L., Biederman, J.A., Hamerlynck, E.P., Barron-Gafford, G. (2015) The carbon balance pivot point of southwestern U.S. semiarid ecosystems: Insights from the 21st century drought, Journal of Geophysical Research: Biogeosciences, 120(), 2612-2624" -US-SRG,1700003222,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/2015JG003181 -US-SRG,1700003222,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Primary_Citation -US-SRG,1700001866,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Scott, R.L., Biederman, J.A., Hamerlynck, E.P., Barron-Gafford, G. (2015) The carbon balance pivot point of southwestern U.S. semiarid ecosystems: Insights from the 21st century drought, Journal of Geophysical Research: Biogeosciences, 120(6), 2612-2624" -US-SRG,1700001866,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/2015JG003181 -US-SRG,1700001866,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Primary_Citation -US-SRG,1700001992,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Smith, W. K., Biederman, J. A., Scott, R. L., Moore, D. J., He, M., Kimball, J. S., Yan, D., Hudson, A., Barnes, M. L., MacBean, N., Fox, A. M., Litvak, M. E. (2018) Chlorophyll Fluorescence Better Captures Seasonal And Interannual Gross Primary Productivity Dynamics Across Dryland Ecosystems Of Southwestern North America, Geophysical Research Letters, 45(2), 748-757" -US-SRG,1700001992,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/2017GL075922 -US-SRG,1700001992,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-SRG,1700003447,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Sullivan, R. C., Cook, D. R., Ghate, V. P., Kotamarthi, V. R., Feng, Y. (2019) Improved Spatiotemporal Representativeness And Bias Reduction Of Satellite-Based Evapotranspiration Retrievals Via Use Of In Situ Meteorology And Constrained Canopy Surface Resistance, Journal Of Geophysical Research: Biogeosciences, 124(2), 342-352" -US-SRG,1700003447,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018JG004744 -US-SRG,1700003447,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-SRG,1700003522,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Sullivan, R. C., Kotamarthi, V. R., Feng, Y. (2019) Recovering Evapotranspiration Trends From Biased CMIP5 Simulations And Sensitivity To Changing Climate Over North America, Journal Of Hydrometeorology, 20(8), 1619-1633" -US-SRG,1700003522,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1175/JHM-D-18-0259.1 -US-SRG,1700003522,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-SRG,1700007263,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Zhang, Q., Ficklin, D. L., Manzoni, S., Wang, L., Way, D., Phillips, R. P., Novick, K. A. (2019) Response Of Ecosystem Intrinsic Water Use Efficiency And Gross Primary Productivity To Rising Vapor Pressure Deficit, Environmental Research Letters, 14(7), 074023" -US-SRG,1700007263,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1088/1748-9326/AB2603 -US-SRG,1700007263,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-SRG,29700,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"Long-term water, carbon and energy flux measurements (eddy covariance) and role of semiarid systems in global C cycle. -Determining how woody plant encroachment affects water and carbon cycling. -Comparing how mesquite function in upland versus riparian environments." -US-SRG,11852,GRP_SITE_CHAR,TERRAIN,Gentle slope (<2 %) -US-SRG,11852,GRP_SITE_CHAR,ASPECT,W -US-SRG,11852,GRP_SITE_CHAR,WIND_DIRECTION,W -US-SRG,11852,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,1000 -US-SRG,11852,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,5 -US-SRG,11853,GRP_SITE_DESC,SITE_DESC,"Semidesert C4 grassland, lies in Pasture 1 on the Santa Rita Experimental Range. This is the companion site for US-SRM, but has much less mesquite encroachment." -US-SRG,11854,GRP_SITE_FUNDING,SITE_FUNDING,"USDA-ARS, DOE, University of Arizona" -US-SRG,11855,GRP_STATE,STATE,AZ -US-SRG,11856,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Russell Scott -US-SRG,11856,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-SRG,11856,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,russ.scott@ars.usda.gov -US-SRG,11856,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,United States Department of Agriculture -US-SRG,11856,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"USDA-ARS Southwest Watershed Research Center, 2000 East Allen Rd.,Tucson, AZ USA 85719" -US-SRG,81555,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Ross Bryant -US-SRG,81555,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Technician -US-SRG,81555,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,ross.bryant@ars.usda.gov -US-SRG,81555,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,USDA-ARS-SWRC -US-SRG,81555,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"2000 East Allen Rd -Tucson AZ 85719" -US-SRG,29866,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-SRG,29699,GRP_TOWER_TYPE,TOWER_TYPE,tripod -US-SRG,24000528,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-SRG -US-SRG,11857,GRP_UTC_OFFSET,UTC_OFFSET,-7 -US-SRM,27354,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER,200 -US-SRM,27354,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_ORGAN,Total -US-SRM,27354,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_PHEN,Mixed/unknown -US-SRM,27354,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_UNIT,gC m-2 -US-SRM,27354,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_COMMENT,"*aboveground tree biomass = (EXP(1.6*LN(35)-0.58)/100)/1000*.47 estimated using equation given in Browning et al. 2008EcolApp,18,933 (be careful…numbers not verified), biomass of herbage production given in Follet, SRER100 issue" -US-SRM,27974,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,780 -US-SRM,27974,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Total -US-SRM,27974,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-SRM,27974,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-SRM,27974,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,"*aboveground tree biomass = (EXP(1.6*LN(35)-0.58)/100)/1000*.47 estimated using equation given in Browning et al. 2008EcolApp,18,933 (be careful…numbers not verified), biomass of herbage production given in Follet, SRER100 issue" -US-SRM,26910,GRP_AG_PROD_OTHER,AG_PROD_OTHER,100 -US-SRM,26910,GRP_AG_PROD_OTHER,AG_PROD_OTHER_ORGAN,Total -US-SRM,26910,GRP_AG_PROD_OTHER,AG_PROD_OTHER_UNIT,gC m-2 -US-SRM,26910,GRP_AG_PROD_OTHER,AG_PROD_COMMENT,"Bad year, Rough estimate from: http://ag.arizona.edu/SRER/proceedings/Ffolliott.pdf" -US-SRM,29054,GRP_AG_PROD_OTHER,AG_PROD_OTHER,200 -US-SRM,29054,GRP_AG_PROD_OTHER,AG_PROD_OTHER_ORGAN,Total -US-SRM,29054,GRP_AG_PROD_OTHER,AG_PROD_OTHER_UNIT,gC m-2 -US-SRM,29054,GRP_AG_PROD_OTHER,AG_PROD_COMMENT,"good year, Rough estimate from: http://ag.arizona.edu/SRER/proceedings/Ffolliott.pdf" -US-SRM,11656,GRP_CLIM_AVG,MAT,17.92 -US-SRM,11656,GRP_CLIM_AVG,MAP,380 -US-SRM,11656,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Bsk -US-SRM,27000435,GRP_COUNTRY,COUNTRY,USA -US-SRM,7075,GRP_DM_GRAZE,DM_GRAZE,Other -US-SRM,7075,GRP_DM_GRAZE,DM_DATE,2004 -US-SRM,7075,GRP_DM_GRAZE,DM_COMMENT,~0.028 animals ha-1 y-1 -US-SRM,6240,GRP_DM_GRAZE,DM_GRAZE,Other -US-SRM,6240,GRP_DM_GRAZE,DM_DATE,2005 -US-SRM,6240,GRP_DM_GRAZE,DM_COMMENT,~0.028 animals ha-1 y-1 -US-SRM,306,GRP_DM_GRAZE,DM_GRAZE,Other -US-SRM,306,GRP_DM_GRAZE,DM_DATE,2006 -US-SRM,306,GRP_DM_GRAZE,DM_COMMENT,grazing for less than 9 days -US-SRM,4512,GRP_DM_GRAZE,DM_GRAZE,Other -US-SRM,4512,GRP_DM_GRAZE,DM_DATE,2007 -US-SRM,4512,GRP_DM_GRAZE,DM_COMMENT,no animals in Pasture in this year -US-SRM,15756,GRP_DOI,DOI,10.17190/AMF/1246104 -US-SRM,15756,GRP_DOI,DOI_CITATION,"Russell Scott (2022), AmeriFlux BASE US-SRM Santa Rita Mesquite, Ver. 23-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1246104" -US-SRM,15756,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-SRM,32206,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-SRM,32206,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Russell Scott -US-SRM,32206,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-SRM,32206,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,russ.scott@ars.usda.gov -US-SRM,32206,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,United States Department of Agriculture -US-SRM,32208,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,United States Department of Agriculture -US-SRM,32208,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-SRM,32207,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,"USDA-ARS, DOE, University of Arizona" -US-SRM,32207,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-SRM,11176,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Grazing -US-SRM,22199,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Land cover change -US-SRM,11658,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-SRM,11658,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-SRM,11658,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20040101 -US-SRM,11658,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-SRM,11671,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-SRM,11671,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-SRM,11671,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20040101 -US-SRM,11671,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-SRM,11177,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-SRM,11177,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-SRM,11177,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,2004 -US-SRM,11177,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-SRM,23000435,GRP_HEADER,SITE_NAME,Santa Rita Mesquite -US-SRM,88648,GRP_HEIGHTC,HEIGHTC,2.5 -US-SRM,88648,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-SRM,88648,GRP_HEIGHTC,HEIGHTC_DATE,20060801 -US-SRM,88648,GRP_HEIGHTC,HEIGHTC_COMMENT,"Potts et al. 2008 Ecology, range from 0.25 to 5 m" -US-SRM,11178,GRP_IGBP,IGBP,WSA -US-SRM,11178,GRP_IGBP,IGBP_COMMENT,"MODIS website lists this as Open Shrublands (OSO), but site is a Desert Grassland that has been fully encroached by Mesquite (now about 35% canopy cover, mean canopy height > 2 m)" -US-SRM,26761,GRP_LAI,LAI_TYPE,LAI -US-SRM,28324,GRP_LAI,LAI_TYPE,LAI -US-SRM,28824,GRP_LAI,LAI_TYPE,LAI -US-SRM,28825,GRP_LAI,LAI_TYPE,LAI -US-SRM,28324,GRP_LAI,LAI_METHOD,LAI_2000 -US-SRM,26761,GRP_LAI,LAI_METHOD,Other -US-SRM,28824,GRP_LAI,LAI_METHOD,Other -US-SRM,28825,GRP_LAI,LAI_METHOD,Other -US-SRM,26761,GRP_LAI,LAI_APPROACH,LI-2001 -US-SRM,28824,GRP_LAI,LAI_APPROACH,LI-2002 -US-SRM,28825,GRP_LAI,LAI_APPROACH,LI-2003 -US-SRM,28324,GRP_LAI,LAI_DATE,20040201 -US-SRM,26761,GRP_LAI,LAI_DATE,20040801 -US-SRM,28825,GRP_LAI,LAI_DATE,20040801 -US-SRM,28824,GRP_LAI,LAI_DATE,20070201 -US-SRM,26761,GRP_LAI,LAI_COMMENT,overstory LAI with leaves -US-SRM,28324,GRP_LAI,LAI_COMMENT,overstory LAI without leaves -US-SRM,28824,GRP_LAI,LAI_COMMENT,"understory, dormant season" -US-SRM,28825,GRP_LAI,LAI_COMMENT,"understory, growing season" -US-SRM,28824,GRP_LAI,LAI_TOT,0.15 -US-SRM,28324,GRP_LAI,LAI_TOT,0.22 -US-SRM,28825,GRP_LAI,LAI_TOT,0.4 -US-SRM,26761,GRP_LAI,LAI_TOT,0.5 -US-SRM,11179,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-SRM,11179,GRP_LAND_OWNERSHIP,LAND_OWNER,University of Arizona College of Agriculture -US-SRM,11180,GRP_LOCATION,LOCATION_LAT,31.8214 -US-SRM,11180,GRP_LOCATION,LOCATION_LONG,-110.8661 -US-SRM,11180,GRP_LOCATION,LOCATION_ELEV,1120 -US-SRM,11181,GRP_NETWORK,NETWORK,AmeriFlux -US-SRM,87009,GRP_NETWORK,NETWORK,Phenocam -US-SRM,26763,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,BudBreak -US-SRM,26763,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,PRVE (NRCS plant code) -US-SRM,26763,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20040409 -US-SRM,26763,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,Prosopis leaf out every year around this time -US-SRM,27066,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,Flowering -US-SRM,27066,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,(All) -US-SRM,27066,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,rain dependent -US-SRM,29172,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,Leaf senescence -US-SRM,29172,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,(All) -US-SRM,29172,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,maximum LAI during mid-monsoon (~213 - 243)for all species -US-SRM,29056,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,Total leaf-off -US-SRM,29056,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,(All) -US-SRM,29056,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,(~ day 250) understory (~ day 300) overstory -US-SRM,1700004794,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Barron-Gafford, G. A., Scott, R. L., Jenerette, G. D., Hamerlynck, E. P., Huxman, T. E. (2013) Landscape And Environmental Controls Over Leaf And Ecosystem Carbon Dioxide Fluxes Under Woody Plant Expansion, Journal Of Ecology, 101(6), 1471-1483" -US-SRM,1700004794,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/1365-2745.12161 -US-SRM,1700004794,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-SRM,1700002070,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Barron-Gafford, G.A., Scott, R.L., Jenerette, G.D., Huxman, T.E. (2011) The Relative Controls Of Temperature, Soil Moisture, And Plant Functional Group On Soil CO2 Efflux At Diel, Seasonal, And Annual Scales, Journal Of Geophysical Research, 116(G1), n/a-n/a" -US-SRM,1700002070,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2010JG001442 -US-SRM,1700002070,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-SRM,1700006669,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Biederman, J. A., Scott, R. L., Bell, T. W., Bowling, D. R., Dore, S., Garatuza-Payan, J., Kolb, T. E., Krishnan, P., Krofcheck, D. J., Litvak, M. E., Maurer, G. E., Meyers, T. P., Oechel, W. C., Papuga, S. A., Ponce-Campos, G. E., Rodriguez, J. C., Smith, W. K., Vargas, R., Watts, C. J., Yepez, E. A., Goulden, M. L. (2017) Co2 Exchange And Evapotranspiration Across Dryland Ecosystems Of Southwestern North America, Global Change Biology, 23(10), 4204-4221" -US-SRM,1700006669,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/GCB.13686 -US-SRM,1700006669,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-SRM,1700001731,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Baldocchi, D. D., Poindexter, C., Abraha, M., Desai, A. R., Bohrer, G., Arain, M. A., Griffis, T., Blanken, P. D., O'Halloran, T. L., Thomas, R. Q., Zhang, Q., Burns, S. P., Frank, J. M., Christian, D., Brown, S., Black, T. A., Gough, C. M., Law, B. E., Lee, X., Chen, J., Reed, D. E., Massman, W. J., Clark, K., Hatfield, J., Prueger, J., Bracho, R., Baker, J. M., Martin, T. A. (2018) Temporal Dynamics Of Aerodynamic Canopy Height Derived From Eddy Covariance Momentum Flux Data Across North American Flux Networks, Geophysical Research Letters, 45(2), 9275–9287" -US-SRM,1700001731,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018GL079306 -US-SRM,1700001731,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-SRM,1700003660,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(6), 108350" -US-SRM,1700003660,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -US-SRM,1700003660,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-SRM,1700005571,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Dennis Baldocchi, Cove Sturtevant (2015) Does day and night sampling reduce spurious correlation between canopy photosynthesis and ecosystem respiration?, Agricultural and Forest Meteorology, 207(1), 117-126" -US-SRM,1700005571,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2015.03.010 -US-SRM,1700005571,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-SRM,1700005241,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Hamerlynck, E. P., Scott, R. L., Barron-Gafford, G. A., Cavanaugh, M. L., Susan Moran, M., Huxman, T. E. (2012) Cool-Season Whole-Plant Gas Exchange Of Exotic And Native Semiarid Bunchgrasses, Plant Ecology, 213(8), 1229-1239" -US-SRM,1700005241,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1007/S11258-012-0081-X -US-SRM,1700005241,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-SRM,1700008370,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Novick, K. A., Ficklin, D. L., Stoy, P. C., Williams, C. A., Bohrer, G., Oishi, A., Papuga, S. A., Blanken, P. D., Noormets, A., Sulman, B. N., Scott, R. L., Wang, L., Phillips, R. P. (2016) The Increasing Importance Of Atmospheric Demand For Ecosystem Water And Carbon Fluxes, Nature Climate Change, 6(11), 1023-1027" -US-SRM,1700008370,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1038/NCLIMATE3114 -US-SRM,1700008370,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-SRM,1700000774,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Novick, K. A., Konings, A. G., Gentine, P. (2019) Beyond Soil Water Potential: An Expanded View On Isohydricity Including Land–Atmosphere Interactions And Phenology, Plant, Cell & Environment, 42(6), 1802-1815" -US-SRM,1700000774,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/PCE.13517 -US-SRM,1700000774,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-SRM,1700002379,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Potts, D. L., Scott, R. L., Bayram, S., Carbonara, J. (2009) Woody Plants Modulate The Temporal Dynamics Of Soil Moisture In A Semi-Arid Mesquite Savanna, Ecohydrology, 3(1), 20-27" -US-SRM,1700002379,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/ECO.91 -US-SRM,1700002379,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-SRM,1700003768,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Scott, R. L. (2010) Using Watershed Water Balance To Evaluate The Accuracy Of Eddy Covariance Evaporation Measurements For Three Semiarid Ecosystems, Agricultural And Forest Meteorology, 150(2), 219-225" -US-SRM,1700003768,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2009.11.002 -US-SRM,1700003768,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-SRM,1700006141,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Scott, R. L., Cable, W. L., Hultine, K. R. (2008) The Ecohydrologic Significance Of Hydraulic Redistribution In A Semiarid Savanna, Water Resources Research, 44(W02440), n/a-n/a" -US-SRM,1700006141,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2007WR006149 -US-SRM,1700006141,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-SRM,1700008256,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Scott, R.L., Biederman, J.A., Hamerlynck, E.P., Barron-Gafford, G. (2015) The carbon balance pivot point of southwestern U.S. semiarid ecosystems: Insights from the 21st century drought, Journal of Geophysical Research: Biogeosciences, 120(21), 2612-2624" -US-SRM,1700008256,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/2015JG003181 -US-SRM,1700008256,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-SRM,1700000453,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Scott, R.L., Jenerette, G.D., Potts, D.L., Huxman, T.E. (2009) Effects Of Seasonal Drought On Net Carbon Dioxide Exchange From A Woody-Plant-Encroached Semiarid Grassland, Journal Of Geophysical Research: Biogeosciences, 114(G4), n/a-n/a" -US-SRM,1700000453,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2008JG000900 -US-SRM,1700000453,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Primary_Citation -US-SRM,1700006879,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Smith, W. K., Biederman, J. A., Scott, R. L., Moore, D. J., He, M., Kimball, J. S., Yan, D., Hudson, A., Barnes, M. L., MacBean, N., Fox, A. M., Litvak, M. E. (2018) Chlorophyll Fluorescence Better Captures Seasonal And Interannual Gross Primary Productivity Dynamics Across Dryland Ecosystems Of Southwestern North America, Geophysical Research Letters, 45(2), 748-757" -US-SRM,1700006879,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/2017GL075922 -US-SRM,1700006879,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-SRM,1700008610,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Sullivan, R. C., Cook, D. R., Ghate, V. P., Kotamarthi, V. R., Feng, Y. (2019) Improved Spatiotemporal Representativeness And Bias Reduction Of Satellite-Based Evapotranspiration Retrievals Via Use Of In Situ Meteorology And Constrained Canopy Surface Resistance, Journal Of Geophysical Research: Biogeosciences, 124(2), 342-352" -US-SRM,1700008610,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018JG004744 -US-SRM,1700008610,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-SRM,1700008571,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Sullivan, R. C., Kotamarthi, V. R., Feng, Y. (2019) Recovering Evapotranspiration Trends From Biased CMIP5 Simulations And Sensitivity To Changing Climate Over North America, Journal Of Hydrometeorology, 20(8), 1619-1633" -US-SRM,1700008571,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1175/JHM-D-18-0259.1 -US-SRM,1700008571,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-SRM,1700002364,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Wolf, S., Keenan, T.F., Fisher, J.B., Baldocchi, D.D., Desai, A.R., Richardson, A.D., Scott, R.L., Law, B.E., Litvak, M.E., Brunsell, N.A., Peters, W., van der Laan-Luijkx, I.T. (2016) Warm spring reduced carbon cycle impact of the 2012 US summer drought, Proceedings of the National Academy of Sciences, 113(21), 5880-5885" -US-SRM,1700002364,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1073/PNAS.1519620113 -US-SRM,1700002364,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-SRM,1700001809,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Zhang, Q., Ficklin, D. L., Manzoni, S., Wang, L., Way, D., Phillips, R. P., Novick, K. A. (2019) Response Of Ecosystem Intrinsic Water Use Efficiency And Gross Primary Productivity To Rising Vapor Pressure Deficit, Environmental Research Letters, 14(7), 074023" -US-SRM,1700001809,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1088/1748-9326/AB2603 -US-SRM,1700001809,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-SRM,1700006795,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Zhang, Q., Phillips, R. P., Manzoni, S., Scott, R. L., Oishi, A. C., Finzi, A., Daly, E., Vargas, R., Novick, K. A. (2018) Changes In Photosynthesis And Soil Moisture Drive The Seasonal Soil Respiration-Temperature Hysteresis Relationship, Agricultural And Forest Meteorology, 259(1), 184-195" -US-SRM,1700006795,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2018.05.005 -US-SRM,1700006795,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-SRM,1700000441,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Zhang, Q., Phillips, R. P., Manzoni, S., Scott, R. L., Oishi, A. C., Finzi, A., Daly, E., Vargas, R., Novick, K. A. (2018) Changes In Photosynthesis And Soil Moisture Drive The Seasonal Soil Respiration-Temperature Hysteresis Relationship, Agricultural And Forest Meteorology, 259(21), 184-195" -US-SRM,1700000441,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2018.05.005 -US-SRM,1700000441,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-SRM,11183,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"Long-term water, carbon and energy flux measurements (eddy covariance). Determining how woody plant encroachment affects water and carbon cycling. Comparing how mesquite function in upland versus riparian environments. Determining the role of mesquite hydraulic redistribution in the terrestrial water balance" -US-SRM,27972,GRP_SA,SA,60 -US-SRM,27972,GRP_SA,SA_DATE,2008 -US-SRM,27972,GRP_SA,SA_COMMENT,"guesstimate, based on when majority of encroachment happened, mesquite tree encroachment over the last 100 years (M. McClaren, personal communication)" -US-SRM,27972,GRP_SA,SA_MAX,200 -US-SRM,11665,GRP_SITE_CHAR,TERRAIN,"Medium Slope (>2 %, <5%)" -US-SRM,11665,GRP_SITE_CHAR,ASPECT,W -US-SRM,11665,GRP_SITE_CHAR,WIND_DIRECTION,W -US-SRM,11665,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,5000 -US-SRM,11665,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,2 -US-SRM,11184,GRP_SITE_DESC,SITE_DESC,"Semidesert grassland encroached by mesquite (Prosopis velutina) trees. Please see Scott et al. 2009 JGR-Biogeo, 114, G04004" -US-SRM,11185,GRP_SITE_FUNDING,SITE_FUNDING,"USDA-ARS, DOE, University of Arizona" -US-SRM,28325,GRP_SOIL_CHEM,SOIL_CHEM_C_ORG,10.4783 -US-SRM,27604,GRP_SOIL_CHEM,SOIL_CHEM_N_TOT,0.98628 -US-SRM,28322,GRP_SOIL_CHEM,SOIL_CHEM_PH_SALT,8.1 -US-SRM,29167,GRP_SOIL_CHEM,SOIL_CHEM_PH_SALT,8.2 -US-SRM,27057,GRP_SOIL_CHEM,SOIL_CHEM_PH_SALT,8.4 -US-SRM,29171,GRP_SOIL_CHEM,SOIL_CHEM_PH_SALT,8.4 -US-SRM,27064,GRP_SOIL_CHEM,SOIL_CHEM_PH_SALT,8.6 -US-SRM,26762,GRP_SOIL_CHEM,SOIL_CHEM_BD,1.5 -US-SRM,26762,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,0 -US-SRM,27064,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,0 -US-SRM,27604,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,0 -US-SRM,28325,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,0 -US-SRM,28322,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,110 -US-SRM,29171,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,2 -US-SRM,27057,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,59 -US-SRM,29167,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,9 -US-SRM,27057,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,110 -US-SRM,28322,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,140 -US-SRM,27064,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,2 -US-SRM,26762,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,20 -US-SRM,27604,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,20 -US-SRM,28325,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,20 -US-SRM,29167,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,59 -US-SRM,29171,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,9 -US-SRM,27604,GRP_SOIL_CHEM,SOIL_CHEM_DATE,1981 -US-SRM,28325,GRP_SOIL_CHEM,SOIL_CHEM_DATE,1981 -US-SRM,26762,GRP_SOIL_CHEM,SOIL_CHEM_DATE,1993 -US-SRM,27604,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,"from Tiedemann&Klemmendson, Soil Sci. Soc. Am. J. 50: 472-475, also agrees well within the range in Table 2 of Wheeler et al. 2007 Ecol. Applications, 17, 1911-1928" -US-SRM,28325,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,"Organic C only, not total C, = ((0.06*8*1380+0.08*3.8*1540+0.06*3.1*1580)/1000 )*0.35+((0.06*3*1580+0.08*2.4*1620+0.06*2.6*1600)/1000 )*(1-0.35) Tiedemann&Klemmendson, Soil Sci. Soc. Am. J. 50: 472-475, also agrees well within the range in Table 2 of Wheeler et al. 2007 Ecol. Applications, 17, 1911-1928" -US-SRM,27057,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,PH varies considerably between the two soils described on WS6 -US-SRM,27064,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,PH varies considerably between the two soils described on WS6 -US-SRM,28322,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,PH varies considerably between the two soils described on WS6 -US-SRM,29167,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,PH varies considerably between the two soils described on WS6 -US-SRM,29171,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,PH varies considerably between the two soils described on WS6 -US-SRM,26762,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,"Tiedemann&Klemmendson, Soil Sci. Soc. Am. J. 50: 472-475" -US-SRM,29307,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION,Sandy loams -US-SRM,29307,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION_TAXONOMY,Other -US-SRM,27601,GRP_SOIL_TEX,SOIL_TEX_SAND,72 -US-SRM,27063,GRP_SOIL_TEX,SOIL_TEX_SAND,74 -US-SRM,27605,GRP_SOIL_TEX,SOIL_TEX_SAND,80 -US-SRM,29169,GRP_SOIL_TEX,SOIL_TEX_SAND,84 -US-SRM,27065,GRP_SOIL_TEX,SOIL_TEX_SAND,87 -US-SRM,27061,GRP_SOIL_TEX,SOIL_TEX_SILT,10 -US-SRM,28323,GRP_SOIL_TEX,SOIL_TEX_SILT,12 -US-SRM,29170,GRP_SOIL_TEX,SOIL_TEX_SILT,17 -US-SRM,28585,GRP_SOIL_TEX,SOIL_TEX_SILT,7 -US-SRM,29055,GRP_SOIL_TEX,SOIL_TEX_SILT,9 -US-SRM,27606,GRP_SOIL_TEX,SOIL_TEX_CLAY,11 -US-SRM,26911,GRP_SOIL_TEX,SOIL_TEX_CLAY,15 -US-SRM,27600,GRP_SOIL_TEX,SOIL_TEX_CLAY,6 -US-SRM,28586,GRP_SOIL_TEX,SOIL_TEX_CLAY,6 -US-SRM,27973,GRP_SOIL_TEX,SOIL_TEX_CLAY,9 -US-SRM,27975,GRP_SOIL_TEX,SOIL_TEX_WATER_HOLD_CAP,0.11 -US-SRM,27975,GRP_SOIL_TEX,SOIL_TEX_COMMENT,"(range 0.15 - 0.07) vol. water content ~ 0.15 at field capacity (1/3 bar) and ~0.07 at ""wilting point"" (15 bar)" -US-SRM,26911,GRP_SOIL_TEX,SOIL_TEX_COMMENT,"loamy sand, sampled on WS#6 from spreadsheet (source: P. Heilman), same soil type" -US-SRM,27061,GRP_SOIL_TEX,SOIL_TEX_COMMENT,"loamy sand, sampled on WS#6 from spreadsheet (source: P. Heilman), same soil type" -US-SRM,27063,GRP_SOIL_TEX,SOIL_TEX_COMMENT,"loamy sand, sampled on WS#6 from spreadsheet (source: P. Heilman), same soil type" -US-SRM,27065,GRP_SOIL_TEX,SOIL_TEX_COMMENT,"loamy sand, sampled on WS#6 from spreadsheet (source: P. Heilman), same soil type" -US-SRM,27600,GRP_SOIL_TEX,SOIL_TEX_COMMENT,"loamy sand, sampled on WS#6 from spreadsheet (source: P. Heilman), same soil type" -US-SRM,27601,GRP_SOIL_TEX,SOIL_TEX_COMMENT,"loamy sand, sampled on WS#6 from spreadsheet (source: P. Heilman), same soil type" -US-SRM,27605,GRP_SOIL_TEX,SOIL_TEX_COMMENT,"loamy sand, sampled on WS#6 from spreadsheet (source: P. Heilman), same soil type" -US-SRM,27606,GRP_SOIL_TEX,SOIL_TEX_COMMENT,"loamy sand, sampled on WS#6 from spreadsheet (source: P. Heilman), same soil type" -US-SRM,27973,GRP_SOIL_TEX,SOIL_TEX_COMMENT,"loamy sand, sampled on WS#6 from spreadsheet (source: P. Heilman), same soil type" -US-SRM,28323,GRP_SOIL_TEX,SOIL_TEX_COMMENT,"loamy sand, sampled on WS#6 from spreadsheet (source: P. Heilman), same soil type" -US-SRM,28585,GRP_SOIL_TEX,SOIL_TEX_COMMENT,"loamy sand, sampled on WS#6 from spreadsheet (source: P. Heilman), same soil type" -US-SRM,28586,GRP_SOIL_TEX,SOIL_TEX_COMMENT,"loamy sand, sampled on WS#6 from spreadsheet (source: P. Heilman), same soil type" -US-SRM,29055,GRP_SOIL_TEX,SOIL_TEX_COMMENT,"loamy sand, sampled on WS#6 from spreadsheet (source: P. Heilman), same soil type" -US-SRM,29169,GRP_SOIL_TEX,SOIL_TEX_COMMENT,"loamy sand, sampled on WS#6 from spreadsheet (source: P. Heilman), same soil type" -US-SRM,29170,GRP_SOIL_TEX,SOIL_TEX_COMMENT,"loamy sand, sampled on WS#6 from spreadsheet (source: P. Heilman), same soil type" -US-SRM,27353,GRP_SPP_O,SPP_O,PRVE (NRCS plant code) -US-SRM,27353,GRP_SPP_O,SPP_O_PERC,35 -US-SRM,27353,GRP_SPP_O,SPP_COMMENT,"Mesquite canopy cover estimated within the flux footprint via aerial photos, total understory grass species ~= 25% (E. Hamerlynck, personal communication)" -US-SRM,28823,GRP_SPP_U,SPP_U,BOER4 (NRCS plant code) -US-SRM,28821,GRP_SPP_U,SPP_U,DICA8 (NRCS plant code) -US-SRM,29053,GRP_SPP_U,SPP_U,ERLE (NRCS plant code) -US-SRM,27602,GRP_SPP_U,SPP_U,ISTE2 (NRCS plant code) -US-SRM,29523,GRP_SPP_U,SPP_U,ISTE2 (NRCS plant code) -US-SRM,28822,GRP_SPP_U,SPP_U,MUPO2 (NRCS plant code) -US-SRM,27602,GRP_SPP_U,SPP_COMMENT,"Mesquite canopy cover estimated within the flux footprint via aerial photos, total understory grass species ~= 25% (E. Hamerlynck, personal communication)" -US-SRM,28821,GRP_SPP_U,SPP_COMMENT,"Mesquite canopy cover estimated within the flux footprint via aerial photos, total understory grass species ~= 25% (E. Hamerlynck, personal communication)" -US-SRM,28822,GRP_SPP_U,SPP_COMMENT,"Mesquite canopy cover estimated within the flux footprint via aerial photos, total understory grass species ~= 25% (E. Hamerlynck, personal communication)" -US-SRM,28823,GRP_SPP_U,SPP_COMMENT,"Mesquite canopy cover estimated within the flux footprint via aerial photos, total understory grass species ~= 25% (E. Hamerlynck, personal communication)" -US-SRM,29053,GRP_SPP_U,SPP_COMMENT,"Mesquite canopy cover estimated within the flux footprint via aerial photos, total understory grass species ~= 25% (E. Hamerlynck, personal communication)" -US-SRM,29523,GRP_SPP_U,SPP_COMMENT,"Mesquite canopy cover estimated within the flux footprint via aerial photos, total understory grass species ~= 25% (E. Hamerlynck, personal communication)" -US-SRM,11186,GRP_STATE,STATE,AZ -US-SRM,11187,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Russell Scott -US-SRM,11187,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-SRM,11187,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,russ.scott@ars.usda.gov -US-SRM,11187,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,United States Department of Agriculture -US-SRM,11187,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"USDA-ARS Southwest Watershed Research Center, 2000 East Allen Rd.,Tucson, AZ USA 85719" -US-SRM,81552,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Ross Bryant -US-SRM,81552,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Technician -US-SRM,81552,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,ross.bryant@ars.usda.gov -US-SRM,81552,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,USDA-ARS-SWRC -US-SRM,81552,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"2000 East Allen RD -Tucson AZ 85719" -US-SRM,79397,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-SRM,79396,GRP_TOWER_TYPE,TOWER_TYPE,walk-up -US-SRM,138,GRP_URL,URL,http://ag.arizona.edu/SRER/ -US-SRM,24000435,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-SRM -US-SRM,11188,GRP_UTC_OFFSET,UTC_OFFSET,-7 -US-Srr,30944,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,USGS Land Carbon Program -US-Srr,30945,GRP_CLIM_AVG,MAT,15.1 -US-Srr,30945,GRP_CLIM_AVG,MAP,326 -US-Srr,30945,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Csa -US-Srr,27000712,GRP_COUNTRY,COUNTRY,USA -US-Srr,79340,GRP_DOI,DOI,10.17190/AMF/1418685 -US-Srr,79340,GRP_DOI,DOI_CITATION,"Brian Bergamaschi, Lisamarie Windham-Myers (2018), AmeriFlux BASE US-Srr Suisun marsh - Rush Ranch, Ver. 1-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1418685" -US-Srr,79340,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-Srr,79218,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Srr,79218,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Brian Bergamaschi -US-Srr,79218,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Srr,79218,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,bbergama@usgs.gov -US-Srr,79218,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,USGS -US-Srr,79217,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Srr,79217,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Lisamarie Windham-Myers -US-Srr,79217,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Srr,79217,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,lwindham-myers@usgs.gov -US-Srr,79217,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,USGS -US-Srr,93966,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,United States Geological Survey -US-Srr,93966,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-Srr,79220,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,USGS -US-Srr,79220,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-Srr,79219,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,USGS -US-Srr,79219,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-Srr,30948,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Drought -US-Srr,30947,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Storm or wind -US-Srr,30946,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Temperature extreme -US-Srr,30950,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Srr,30950,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-Srr,30950,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20140406 -US-Srr,30950,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Srr,30952,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Srr,30952,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CH4 -US-Srr,30952,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20140406 -US-Srr,30952,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Srr,30949,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Srr,30949,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-Srr,30949,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20140406 -US-Srr,30949,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Srr,30951,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Srr,30951,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-Srr,30951,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20140406 -US-Srr,30951,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Srr,23000712,GRP_HEADER,SITE_NAME,Suisun marsh - Rush Ranch -US-Srr,30953,GRP_IGBP,IGBP,WET -US-Srr,30953,GRP_IGBP,IGBP_COMMENT,"Schoenoplectus and Typha species, Juncus balticus, Distichlis spicata, and Sarcocornia pacifica, although it is increasingly influenced by an invasive perennial forb (Lepidium latifolium L.)" -US-Srr,30954,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-Srr,30954,GRP_LAND_OWNERSHIP,LAND_OWNER,Solano Land Trust -US-Srr,30955,GRP_LOCATION,LOCATION_LAT,38.2006 -US-Srr,30955,GRP_LOCATION,LOCATION_LONG,-122.0264 -US-Srr,30955,GRP_LOCATION,LOCATION_ELEV,8 -US-Srr,30955,GRP_LOCATION,LOCATION_DATE_START,20140406 -US-Srr,30956,GRP_NETWORK,NETWORK,AmeriFlux -US-Srr,1700008841,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Baldocchi, D. D., Poindexter, C., Abraha, M., Desai, A. R., Bohrer, G., Arain, M. A., Griffis, T., Blanken, P. D., O'Halloran, T. L., Thomas, R. Q., Zhang, Q., Burns, S. P., Frank, J. M., Christian, D., Brown, S., Black, T. A., Gough, C. M., Law, B. E., Lee, X., Chen, J., Reed, D. E., Massman, W. J., Clark, K., Hatfield, J., Prueger, J., Bracho, R., Baker, J. M., Martin, T. A. (2018) Temporal Dynamics Of Aerodynamic Canopy Height Derived From Eddy Covariance Momentum Flux Data Across North American Flux Networks, Geophysical Research Letters, 45(), 9275–9287" -US-Srr,1700008841,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018GL079306 -US-Srr,1700008841,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Srr,1700005259,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(2), 108350" -US-Srr,1700005259,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -US-Srr,1700005259,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Srr,1700004914,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Feagin, R. A., Forbrich, I., Huff, T. P., Barr, J. G., Ruiz‐Plancarte, J., Fuentes, J. D., Najjar, R. G., Vargas, R., Vázquez‐Lule, A., Windham‐Myers, L., Kroeger, K. D., Ward, E. J., Moore, G. W., Leclerc, M., Krauss, K. W., Stagg, C. L., Alber, M., Knox, S. H., Schäfer, K. V., Bianchi, T. S., Hutchings, J. A., Nahrawi, H., Noormets, A., Mitra, B., Jaimes, A., Hinson, A. L., Bergamaschi, B., King, J. S., Miao, G. (2020) Tidal Wetland Gross Primary Production Across The Continental United States, 2000–2019, Global Biogeochemical Cycles, 34(2), 108350" -US-Srr,1700004914,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2019GB006349 -US-Srr,1700004914,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Srr,1700004527,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Feagin, R. A., Forbrich, I., Huff, T. P., Barr, J. G., Ruiz‐Plancarte, J., Fuentes, J. D., Najjar, R. G., Vargas, R., Vázquez‐Lule, A., Windham‐Myers, L., Kroeger, K. D., Ward, E. J., Moore, G. W., Leclerc, M., Krauss, K. W., Stagg, C. L., Alber, M., Knox, S. H., Schäfer, K. V., Bianchi, T. S., Hutchings, J. A., Nahrawi, H., Noormets, A., Mitra, B., Jaimes, A., Hinson, A. L., Bergamaschi, B., King, J. S., Miao, G. (2020) Tidal Wetland Gross Primary Production Across The Continental United States, 2000–2019, Global Biogeochemical Cycles, 34(2), 9275–9287" -US-Srr,1700004527,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2019GB006349 -US-Srr,1700004527,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Srr,30957,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"Our research focuses on assessing the components of the Net Ecoystem Carbon Balance using the eddy covariance approach to measure atmospheric fluxes of heat, energy, carbon dioxide and methane and testing equipment and techniques to measure the tidal exchange of dissolved organic (DOC) and inorganic carbon (DIC)." -US-Srr,30958,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"6000 J Street, Placer Hall, Sacramento, CA, 95819" -US-Srr,30959,GRP_SITE_CHAR,TERRAIN,Flat -US-Srr,30959,GRP_SITE_CHAR,ASPECT,FLAT -US-Srr,30959,GRP_SITE_CHAR,WIND_DIRECTION,W -US-Srr,30959,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,1400 -US-Srr,30959,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,0 -US-Srr,30960,GRP_SITE_DESC,SITE_DESC,"This site is a 4.57 km2 brackish tidal marsh located in the San Francisco Bay National Estuarine Research Reserve (SFBNERR, http://www.nerrs.noaa.gov/reserves/san-francisco-bay.html) in Suisun Bay, CA, USA. Suisun Bay is the most extensive contiguous brackish marsh complex in California. This site is classified as a high marsh, which according to the National Wetland Inventory, is representative of over 58% of estuarine wetlands." -US-Srr,30961,GRP_SITE_FUNDING,SITE_FUNDING,USGS -US-Srr,30962,GRP_STATE,STATE,CA -US-Srr,30963,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Brian Bergamaschi -US-Srr,30963,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Srr,30963,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,bbergama@usgs.gov -US-Srr,30963,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,USGS -US-Srr,30965,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Lisamarie Windham-Myers -US-Srr,30965,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Srr,30965,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,lwindham-myers@usgs.gov -US-Srr,30965,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,USGS -US-Srr,30965,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"345 Middlefield Road, Menlo Park, CA, 94025" -US-Srr,89416,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Ellen Stuart-Haëntjens -US-Srr,89416,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,AncContact -US-Srr,89416,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,egoodrich-stuart@usgs.gov -US-Srr,89416,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,USGS -US-Srr,90739,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Sara Knox -US-Srr,90739,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,AncContact -US-Srr,90739,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,sara.knox@ubc.ca -US-Srr,90739,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,UBC Geography -US-Srr,90737,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Frank Anderson -US-Srr,90737,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Affiliate -US-Srr,90737,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,fanders@usgs.gov -US-Srr,30969,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-Srr,30967,GRP_TOWER_TYPE,TOWER_TYPE,other -US-Srr,24000712,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-Srr -US-Srr,30968,GRP_UTC_OFFSET,UTC_OFFSET,-8 -US-SRS,92005,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,Funding for the operation and maintenance of the Santa Rita Experimental Range Mesquite Savanna site was provide by the US Army Research Office (grant 56059‐EV‐PCS) and USDA-NIFA (grant 2022-13610-012-06S). -US-SRS,92009,GRP_CLIM_AVG,MAT,19.4 -US-SRS,92009,GRP_CLIM_AVG,MAP,388 -US-SRS,92009,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Bsk -US-SRS,27001138,GRP_COUNTRY,COUNTRY,USA -US-SRS,93751,GRP_DOI,DOI,10.17190/AMF/1660351 -US-SRS,93751,GRP_DOI,DOI_CITATION,"Enrique R. Vivoni (2022), AmeriFlux BASE US-SRS Santa Rita Savanna, Ver. 3-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1660351" -US-SRS,93751,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-SRS,93707,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-SRS,93707,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Enrique R. Vivoni -US-SRS,93707,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-SRS,93707,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,vivoni@asu.edu -US-SRS,93707,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Arizona State University -US-SRS,93740,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Arizona State University -US-SRS,93740,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-SRS,93720,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,"US Army Research Office, USDA-NIFA" -US-SRS,93720,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-SRS,91992,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Fire -US-SRS,91987,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Forestry -US-SRS,92002,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Grazing -US-SRS,92000,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Land cover change -US-SRS,91993,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-SRS,91993,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-SRS,91993,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201105250830 -US-SRS,91993,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,201912312330 -US-SRS,91993,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-SRS,91989,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-SRS,91989,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-SRS,91989,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201105250830 -US-SRS,91989,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,201912312330 -US-SRS,91989,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-SRS,91998,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-SRS,91998,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-SRS,91998,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201105250830 -US-SRS,91998,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,201912312330 -US-SRS,91998,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-SRS,23001138,GRP_HEADER,SITE_NAME,Santa Rita Savanna -US-SRS,91994,GRP_IGBP,IGBP,WSA -US-SRS,92006,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-SRS,92006,GRP_LAND_OWNERSHIP,LAND_OWNER,AZ State land administered by University of Arizona College of Agriculture -US-SRS,92007,GRP_LOCATION,LOCATION_LAT,31.8173 -US-SRS,92007,GRP_LOCATION,LOCATION_LONG,-110.8508 -US-SRS,92007,GRP_LOCATION,LOCATION_ELEV,1169 -US-SRS,92007,GRP_LOCATION,LOCATION_DATE_START,201105240000 -US-SRS,92004,GRP_NETWORK,NETWORK,AmeriFlux -US-SRS,1700001191,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Anderson, C. A., Vivoni, E. R. (2016) Impact Of Land Surface States Within The Flux Footprint On Daytime Land-Atmosphere Coupling In Two Semiarid Ecosystems Of The Southwestern U.S., Water Resources Research, 52(6), 4785-4800" -US-SRS,1700001191,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/2015WR018016 -US-SRS,1700001191,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Primary_Citation -US-SRS,1700004428,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Mascaro, G., Vivoni, E. R. (2016) On The Observed Hysteresis In Field-Scale Soil Moisture Variability And Its Physical Controls, Environmental Research Letters, 11(8), 084008" -US-SRS,1700004428,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1088/1748-9326/11/8/084008 -US-SRS,1700004428,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-SRS,1700004641,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Pierini, N. A., Vivoni, E. R., Robles-Morua, A., Scott, R. L., Nearing, M. A. (2014) Using Observations And A Distributed Hydrologic Model To Explore Runoff Thresholds Linked With Mesquite Encroachment In The Sonoran Desert, Water Resources Research, 50(10), 8191-8215" -US-SRS,1700004641,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/2014WR015781 -US-SRS,1700004641,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Primary_Citation -US-SRS,91997,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,Watershed hydrology and ecohydrology -US-SRS,91999,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"ISTB4 Room 795, 781 E Terrace Rd, Tempe, AZ 85287" -US-SRS,92003,GRP_SITE_CHAR,TERRAIN,"Medium Slope (>2 %, <5%)" -US-SRS,92003,GRP_SITE_CHAR,ASPECT,W -US-SRS,92003,GRP_SITE_CHAR,WIND_DIRECTION,E -US-SRS,92003,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,700 -US-SRS,92003,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,0 -US-SRS,92012,GRP_SITE_DESC,SITE_DESC,"The study site is located in the Santa Rita Experimental Range, approximately 45 km south of Tucson, Arizona, within the Sonoran Desert. The rangeland has undergone a shift from a semiarid grassland to a savanna due to the encroachment of the woody leguminous tree Prosopis velutina Woot., or velvet mesquite. A pair of adjacent watersheds of similar size ( 1.08 ha and 1.10 ha) was established to investigate the effects of mesquite removal on hydrologic processes. In 1974, diesel oil was applied basally to all trees in one watershed, with reapplication as needed and dead tree removal for wood, whereas the other watershed, where the flux tower is located, has continued in the woody plant encroachment process. In 2016, an herbicide process was applied to the area around the EC flux tower." -US-SRS,91996,GRP_SITE_FUNDING,SITE_FUNDING,"US Army Research Office, USDA-NIFA" -US-SRS,91988,GRP_STATE,STATE,AZ -US-SRS,91995,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Enrique R. Vivoni -US-SRS,91995,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-SRS,91995,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,vivoni@asu.edu -US-SRS,91995,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Arizona State University -US-SRS,91995,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"ISTB4 Room 769, 781 E Terrace Rd, Tempe, AZ 85287" -US-SRS,91991,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Eli R. Perez-Ruiz -US-SRS,91991,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-SRS,91991,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,eli.perez@asu.edu -US-SRS,91991,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"Arizona State University -and -Universidad Autonoma de Ciudad Juarez" -US-SRS,91991,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"ISTB4 Room 768, 781 E Terrace Rd, Tempe, AZ 85287 -and -Edificio E, Av. del Charro # 450 Nte. Col. Partido Romero , Cd Juárez, Chihuahua, México, CP 32310" -US-SRS,92008,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-SRS,92011,GRP_TOWER_TYPE,TOWER_TYPE,triangle -US-SRS,92871,GRP_URL,URL,http://hydrology.asu.edu/wiki/index.php -US-SRS,24001138,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-SRS -US-SRS,92010,GRP_UTC_OFFSET,UTC_OFFSET,-7 -US-SSH,98269,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,"Logistical support and/or data were provided by the NSF-supported Shale Hills Susquehanna Critical Zone Observatory. Financial Support was provided by National Science Foundation Grant EAR – 0725019 (C. Duffy), EAR – 1239285 (S. Brantley), and EAR – 1331726 (S. Brantley) for the Susquehanna Shale Hills Critical Zone Observatory.  Logistical support and/or data were provided by the NSF-supported Susquehanna Shale Hills Critical Zone Observatory.  Additional financial support was provided by The Pennsylvania State University’s Colleges of Earth and Mineral Sciences, Agricultural Sciences and Engineering, and the Institutes of Energy and the Environment. This research was conducted in Penn State's Stone Valley Forest, which is funded by the Penn State College of Agriculture Sciences, Department of Ecosystem Science and Management and managed by the staff of the Forestlands Management Office." -US-SSH,98269,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT_COMMENT,"The user of Susquehanna Shale Hills CZO data agrees to provide proper acknowledgment with each usage of the data. Citation of the name(s) of the investigator(s) responsible for the data set, in addition to the generic statement above, constitutes proper acknowledgment. Author(s) (including Susquehanna Shale Hills CZO investigators) of published material that makes use of previously unpublished Susquehanna Shale Hills CZO data agree to provide the Susquehanna Shale Hills CZO data manager with four (4) copies (preferably reprints) of that material for binding as soon as it becomes available. The user of Susquehanna Shale Hills CZO data agrees not to resell or redistribute shared data. The user of these data should be aware that, while efforts have been taken to ensure that these data are of the highest quality, there is no guarantee of perfection for the data contained herein and the possibility of errors exists." -US-SSH,30679,GRP_CLIM_AVG,MAT,9.5 -US-SSH,30679,GRP_CLIM_AVG,MAP,1050 -US-SSH,30679,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfb -US-SSH,27000701,GRP_COUNTRY,COUNTRY,USA -US-SSH,30680,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Forestry -US-SSH,98264,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-SSH,98264,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-SSH,98264,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,200905010000 -US-SSH,98264,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-SSH,98265,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-SSH,98265,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-SSH,98265,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,200905010000 -US-SSH,98265,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-SSH,98274,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-SSH,98274,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-SSH,98274,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,200905010000 -US-SSH,98274,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-SSH,98263,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-SSH,98263,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,Other -US-SSH,98263,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,200905010000 -US-SSH,98263,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-SSH,98263,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,latent heat -US-SSH,23000701,GRP_HEADER,SITE_NAME,Susquehanna Shale Hills Critical Zone Observatory -US-SSH,30684,GRP_IGBP,IGBP,DBF -US-SSH,30685,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-SSH,30685,GRP_LAND_OWNERSHIP,LAND_OWNER,The Pennsylvania State University -US-SSH,98272,GRP_LOCATION,LOCATION_LAT,40.6658 -US-SSH,98272,GRP_LOCATION,LOCATION_LONG,-77.9041 -US-SSH,98272,GRP_LOCATION,LOCATION_ELEV,310 -US-SSH,98272,GRP_LOCATION,LOCATION_DATE_START,200905010000 -US-SSH,30687,GRP_NETWORK,NETWORK,AmeriFlux -US-SSH,87010,GRP_NETWORK,NETWORK,Phenocam -US-SSH,1700000696,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Brantley, S. L., White, T., West, N., Williams, J. Z., Forsythe, B., Shapich, D., Kaye, J., Lin, H., Shi, Y., Kaye, M., Herndon, E., Davis, K. J., He, Y., Eissenstat, D., Weitzman, J., DiBiase, R., Li, L., Reed, W., Brubaker, K., Gu, X. (2018) Susquehanna Shale Hills Critical Zone Observatory: Shale Hills In The Context Of Shaver'S Creek Watershed, Vadose Zone Journal, 17(1), 1-19" -US-SSH,1700000696,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.2136/VZJ2018.04.0092 -US-SSH,1700000696,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-SSH,1700000570,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Shi, Y., Davis, K. J., Duffy, C. J., Yu, X. (2013) Development Of A Coupled Land Surface Hydrologic Model And Evaluation At A Critical Zone Observatory, Journal Of Hydrometeorology, 14(5), 1401-1420" -US-SSH,1700000570,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1175/JHM-D-12-0145.1 -US-SSH,1700000570,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-SSH,30690,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,Understanding of pathways and fluxes of water and carbon in the watershed -US-SSH,30691,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"512 Walker Building, University Park, PA, 16802" -US-SSH,30692,GRP_SITE_CHAR,TERRAIN,Hilltop -US-SSH,30692,GRP_SITE_CHAR,WIND_DIRECTION,NW -US-SSH,30693,GRP_SITE_DESC,SITE_DESC,"The Susquehanna Shale Hills Critical Zone Observatory is comprised of one first-order catchment in the Susquehanna River basin. This catchment, known as Shale Hills, is about 8 hectares in total area. The stream that defines the Shale Hills catchment flows into Shavers Creek in the Juniata River sub-basin. The vegetation cover at Shale Hills is dominated by deciduous broadleaf forest, with some evergreen needleleaf -trees along the stream." -US-SSH,30694,GRP_SITE_FUNDING,SITE_FUNDING,NSF -US-SSH,30695,GRP_STATE,STATE,PA -US-SSH,30697,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Kenneth J. Davis -US-SSH,30697,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-SSH,30697,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,kjd10@psu.edu -US-SSH,30697,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"Department of Meteorology, Earth and Environmental Systems Institute, the Pennsylvania University" -US-SSH,30697,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"512 Walker Building, University Park, PA, 16802" -US-SSH,30696,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Yuning Shi -US-SSH,30696,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-SSH,30696,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,yshi@psu.edu -US-SSH,30696,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"Department of Ecosystem Science and Management, Earth and Environmental Systems Institute, The Pennsylvania State University" -US-SSH,92867,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Yuting He Smeglin -US-SSH,92867,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-SSH,92867,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,heyuting.iap@gmail.com -US-SSH,92867,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Penn State University -US-SSH,98267,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Brandon Forsythe -US-SSH,98267,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,DataManager -US-SSH,98267,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,brf11@psu.edu -US-SSH,98267,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"Penn State University, Earth and Environmental Systems Institute" -US-SSH,98267,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"2217 Earth and Engineering Science Building, University Park, PA 16802" -US-SSH,101436,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Jason Horne -US-SSH,101436,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Affiliate -US-SSH,101436,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,jph6488@psu.edu -US-SSH,101436,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Penn State University -US-SSH,101436,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Department of Meteorology, Walker Building, University Park, PA" -US-SSH,30701,GRP_TOWER_POWER,TOWER_POWER,Direct power -US-SSH,30698,GRP_TOWER_TYPE,TOWER_TYPE,other -US-SSH,98273,GRP_URL,URL,http://www.czo.psu.edu/data_surfflux.html -US-SSH,24000701,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-SSH -US-SSH,30700,GRP_UTC_OFFSET,UTC_OFFSET,-5 -US-StJ,95530,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,"Funding was provided by the National Science Foundation (#1652594) and we acknowledge onsite support from the Delaware National Estuarine Research Reserve (DNERR)," -US-StJ,83408,GRP_CLIM_AVG,MAT,13.5 -US-StJ,83408,GRP_CLIM_AVG,MAP,1121 -US-StJ,83408,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Cfa -US-StJ,27000551,GRP_COUNTRY,COUNTRY,USA -US-StJ,85254,GRP_DOI,DOI,10.17190/AMF/1480316 -US-StJ,85254,GRP_DOI,DOI_CITATION,"Rodrigo Vargas (2020), AmeriFlux BASE US-StJ St Jones Reserve, Ver. 2-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1480316" -US-StJ,85254,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-StJ,84783,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-StJ,84783,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Rodrigo Vargas -US-StJ,84783,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-StJ,84783,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,rvargas@udel.edu -US-StJ,84783,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of Delaware -US-StJ,84792,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,University of Delaware -US-StJ,84792,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-StJ,84791,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,University of Delaware -US-StJ,84791,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-StJ,95532,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Undisturbed -US-StJ,83407,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-StJ,83407,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-StJ,83407,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20150121 -US-StJ,83407,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-StJ,83413,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-StJ,83413,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CH4 -US-StJ,83413,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20150121 -US-StJ,83413,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-StJ,83411,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-StJ,83411,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-StJ,83411,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20150121 -US-StJ,83411,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-StJ,83409,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-StJ,83409,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-StJ,83409,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20150121 -US-StJ,83409,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-StJ,23000551,GRP_HEADER,SITE_NAME,St Jones Reserve -US-StJ,95526,GRP_IGBP,IGBP,WET -US-StJ,95526,GRP_IGBP,IGBP_DATE_START,19000101 -US-StJ,95526,GRP_IGBP,IGBP_COMMENT,"The most dominant plant species is Spartina alterniflora covering ~66% of the salt marsh area, followed by Spartina -cynosuroides (i.e., ~29%) and Phragmatis australis (i.e., <5%)." -US-StJ,13289,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-StJ,13289,GRP_LAND_OWNERSHIP,LAND_OWNER,State of Delaware -US-StJ,13290,GRP_LOCATION,LOCATION_LAT,39.0882 -US-StJ,13290,GRP_LOCATION,LOCATION_LONG,-75.4372 -US-StJ,13290,GRP_LOCATION,LOCATION_ELEV,6.7 -US-StJ,13290,GRP_LOCATION,LOCATION_DATE_START,20140808 -US-StJ,13291,GRP_NETWORK,NETWORK,AmeriFlux -US-StJ,83412,GRP_NETWORK,NETWORK,Phenocam -US-StJ,1700004545,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Capooci, M., Barba, J., Seyfferth, A. L., Vargas, R. (2019) Experimental Influence Of Storm-Surge Salinity On Soil Greenhouse Gas Emissions From A Tidal Salt Marsh, Science Of The Total Environment, 686(2), 1164-1172" -US-StJ,1700004545,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.SCITOTENV.2019.06.032 -US-StJ,1700004545,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-StJ,1700001878,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(8), 108350" -US-StJ,1700001878,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -US-StJ,1700001878,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-StJ,1700001401,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Feagin, R. A., Forbrich, I., Huff, T. P., Barr, J. G., Ruiz‐Plancarte, J., Fuentes, J. D., Najjar, R. G., Vargas, R., Vázquez‐Lule, A., Windham‐Myers, L., Kroeger, K. D., Ward, E. J., Moore, G. W., Leclerc, M., Krauss, K. W., Stagg, C. L., Alber, M., Knox, S. H., Schäfer, K. V., Bianchi, T. S., Hutchings, J. A., Nahrawi, H., Noormets, A., Mitra, B., Jaimes, A., Hinson, A. L., Bergamaschi, B., King, J. S., Miao, G. (2020) Tidal Wetland Gross Primary Production Across The Continental United States, 2000–2019, Global Biogeochemical Cycles, 34(2), " -US-StJ,1700001401,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2019GB006349 -US-StJ,1700001401,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-StJ,1700008832,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Feagin, R. A., Forbrich, I., Huff, T. P., Barr, J. G., Ruiz‐Plancarte, J., Fuentes, J. D., Najjar, R. G., Vargas, R., Vázquez‐Lule, A., Windham‐Myers, L., Kroeger, K. D., Ward, E. J., Moore, G. W., Leclerc, M., Krauss, K. W., Stagg, C. L., Alber, M., Knox, S. H., Schäfer, K. V., Bianchi, T. S., Hutchings, J. A., Nahrawi, H., Noormets, A., Mitra, B., Jaimes, A., Hinson, A. L., Bergamaschi, B., King, J. S., Miao, G. (2020) Tidal Wetland Gross Primary Production Across The Continental United States, 2000–2019, Global Biogeochemical Cycles, 34(2), 108481" -US-StJ,1700008832,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2019GB006349 -US-StJ,1700008832,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-StJ,1700008727,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Hill, A. C., Vázquez-Lule, A., Vargas, R. (2021) Linking Vegetation Spectral Reflectance With Ecosystem Carbon Phenology In A Temperate Salt Marsh, Agricultural And Forest Meteorology, 307(8), 108481" -US-StJ,1700008727,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108481 -US-StJ,1700008727,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-StJ,1700005511,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Trifunovic, B., Vázquez‐Lule, A., Capooci, M., Seyfferth, A. L., Moffat, C., Vargas, R. (2020) Carbon Dioxide And Methane Emissions From A Temperate Salt Marsh Tidal Creek, Journal Of Geophysical Research: Biogeosciences, 125(8), 1164-1172" -US-StJ,1700005511,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2019JG005558 -US-StJ,1700005511,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-StJ,1700006066,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Vázquez-Lule, A., Vargas, R. (2021) Biophysical Drivers Of Net Ecosystem And Methane Exchange Across Phenological Phases In A Tidal Salt Marsh, Agricultural And Forest Meteorology, 300(8), 108309" -US-StJ,1700006066,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2020.108309 -US-StJ,1700006066,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Primary_Citation -US-StJ,13292,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,Understanding carbon dynamics in a temperate tidal marsh -US-StJ,13293,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"St Jones Reserve -818 Kitts Hummock Road -Dover, DE 19901" -US-StJ,13294,GRP_SITE_CHAR,TERRAIN,Gentle slope (<2 %) -US-StJ,13294,GRP_SITE_CHAR,ASPECT,FLAT -US-StJ,13294,GRP_SITE_CHAR,WIND_DIRECTION,SE -US-StJ,13294,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,970 -US-StJ,13294,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,18 -US-StJ,13295,GRP_SITE_DESC,SITE_DESC,"This tower is located in St Jones, near Dover Delaware. This area is part of the National Estuarine Research Reserve. It was established in 1993, and estuarine ecosystems from the Mid-Atlantic region are represented here. This region has been influenced by agricultural fields along the watershed. The EC tower is located in a tidal marsh near the Dover headquarters, there is a board walk that goes along the marsh. Restoring natural vegetation is on the long term management plan." -US-StJ,13296,GRP_SITE_FUNDING,SITE_FUNDING,University of Delaware -US-StJ,13297,GRP_STATE,STATE,DE -US-StJ,83406,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Rodrigo Vargas -US-StJ,83406,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-StJ,83406,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,rvargas@udel.edu -US-StJ,83406,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Delaware -US-StJ,83406,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,531 South College Avenue 152 Townsend Hall Newark Delaware 19716 -US-StJ,83410,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Alma Vázquez-Lule -US-StJ,83410,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Affiliate -US-StJ,83410,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,avlule@udel.edu -US-StJ,83410,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Delaware -US-StJ,83410,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,532 South College Avenue 152 Townsend Hall Newark Delaware 19716 -US-StJ,95538,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Andrew Hill -US-StJ,95538,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Affiliate -US-StJ,95538,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,hill@udel.edu -US-StJ,95538,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Delaware -US-StJ,95538,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,532 South College Avenue 152 Townsend Hall Newark Delaware 19716 -US-StJ,29885,GRP_TOWER_POWER,TOWER_POWER,Direct power -US-StJ,13299,GRP_TOWER_TYPE,TOWER_TYPE,triangle -US-StJ,24000551,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-StJ -US-StJ,13300,GRP_UTC_OFFSET,UTC_OFFSET,-5 -US-StS,30093,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,Site access to the Hobcaw Barony was provided by The Bell Baruch Foundation. -US-StS,30094,GRP_CLIM_AVG,MAT,18.1 -US-StS,30094,GRP_CLIM_AVG,MAP,1300 -US-StS,30094,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Cfa -US-StS,27000685,GRP_COUNTRY,COUNTRY,USA -US-StS,30095,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Hydrologic event -US-StS,30096,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Land cover change -US-StS,30097,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Storm or wind -US-StS,30099,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-StS,30099,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-StS,30099,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20150521 -US-StS,30099,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20160210 -US-StS,30099,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Intermittent -US-StS,30099,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,Data is collected in intermittent periods of time. -US-StS,30098,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-StS,30098,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-StS,30098,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20150521 -US-StS,30098,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20160210 -US-StS,30098,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Intermittent -US-StS,30098,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,Data is collected in intermittent periods of time. -US-StS,30101,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-StS,30101,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-StS,30101,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20150521 -US-StS,30101,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20160210 -US-StS,30101,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Intermittent -US-StS,30101,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,Data is collected in intermittent periods of time. -US-StS,30100,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Gradients -US-StS,30100,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-StS,30100,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20150521 -US-StS,30100,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20160210 -US-StS,30100,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Intermittent -US-StS,30100,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,Data is collected in intermittent periods of time. -US-StS,30102,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Gradients -US-StS,30102,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-StS,30102,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20150521 -US-StS,30102,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20160210 -US-StS,30102,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Intermittent -US-StS,30102,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,Data is collected in intermittent periods of time. -US-StS,23000685,GRP_HEADER,SITE_NAME,Strawberry Swamp -US-StS,30103,GRP_IGBP,IGBP,WET -US-StS,30103,GRP_IGBP,IGBP_DATE_START,201505211930 -US-StS,30103,GRP_IGBP,IGBP_COMMENT,Continuously flooded deciduous forest transitioning to flooded shrubland -US-StS,30104,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -US-StS,30104,GRP_LAND_OWNERSHIP,LAND_OWNER,Hobcaw Barony: The Belle Baruch Foundation -US-StS,30105,GRP_LOCATION,LOCATION_LAT,33.3302 -US-StS,30105,GRP_LOCATION,LOCATION_LONG,-79.2492 -US-StS,30105,GRP_LOCATION,LOCATION_ELEV,0 -US-StS,30105,GRP_LOCATION,LOCATION_DATE_START,201505211930 -US-StS,30105,GRP_LOCATION,LOCATION_COMMENT,"Tower is located over water, site is accessed through small boardwalk. Gasoline generator was used to power site 05212015 to 10052015, which was located 250m to east of station" -US-StS,30106,GRP_NETWORK,NETWORK,AmeriFlux -US-StS,30110,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"carbon fluxes, energy fluxes, water fluxes of a transitioning coastal swamp" -US-StS,30111,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"Callcott Building, 709 Bull St, Columbia, SC 29208" -US-StS,30112,GRP_SITE_CHAR,TERRAIN,Flat -US-StS,30112,GRP_SITE_CHAR,WIND_DIRECTION,W -US-StS,30112,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,100 -US-StS,30112,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,0 -US-StS,30113,GRP_SITE_DESC,SITE_DESC,"Located in a degraded coastal swamp on the Hobcaw Barony Property near Georgetown, SC. Swamp was previously used for rice cultivation in the 19th century, but has not been used for these purposes since. The coastal swamp was formally a freshwater bald cypress/tupelo forest that was continuously flooded. However, in recent years a salinity gradient has developed over the gradient of the ecosystem causing the forest to transition to a wax myrtle shrub forest to the west of the tower where salinity is higher." -US-StS,30114,GRP_SITE_FUNDING,SITE_FUNDING,"Consortium of Universities for the Advancement of Hydrologic Sciences, Inc (CUAHSI)." -US-StS,30115,GRP_STATE,STATE,SC -US-StS,30116,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Alexandria G McCombs -US-StS,30116,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-StS,30116,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,amccombs@email.sc.edu -US-StS,30116,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of South Carolina -US-StS,30116,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Callcott Building, 709 Bull St, Columbia, SC 29208" -US-StS,30117,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,April Hiscox -US-StS,30117,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-StS,30117,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,hiscox@sc.edu -US-StS,30117,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of South Carolina -US-StS,30117,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Callcott Building, 709 Bull St, Columbia, SC 29208" -US-StS,30118,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Scott Allen -US-StS,30118,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-StS,30118,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,scottallen1@gmail.com -US-StS,30118,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Louisiana State University -US-StS,30118,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"227 Renewable Natural Resource Bldg. Baton Rouge LA, 70803" -US-StS,30121,GRP_TOWER_POWER,TOWER_POWER,Gasoline generator -US-StS,30119,GRP_TOWER_TYPE,TOWER_TYPE,triangle -US-StS,24000685,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-StS -US-StS,30120,GRP_UTC_OFFSET,UTC_OFFSET,-5 -US-StS,30120,GRP_UTC_OFFSET,UTC_OFFSET_DATE_START,201505211930 -US-SuM,13059,GRP_CLIM_AVG,MAT,24.1 -US-SuM,13059,GRP_CLIM_AVG,MAP,287 -US-SuM,13059,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Aw -US-SuM,27000544,GRP_COUNTRY,COUNTRY,USA -US-SuM,15701,GRP_DOI,DOI,10.17190/AMF/1246158 -US-SuM,15701,GRP_DOI,DOI_CITATION,"Dong Wang, Ray Anderson (2019), AmeriFlux BASE US-SuM Maui Sugarcane Middle, Ver. 2-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1246158" -US-SuM,15701,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-SuM,32416,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-SuM,32416,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Dong Wang -US-SuM,32416,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-SuM,32416,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,dong.wang@ars.usda.gov -US-SuM,32416,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"USDA - Agricultural Research Service, San Joaquin Valley Agricultural Sciences Center, Water Management Research Unit" -US-SuM,32415,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-SuM,32415,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Ray Anderson -US-SuM,32415,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-SuM,32415,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,ray.anderson@ars.usda.gov -US-SuM,32415,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"USDA-Agricultural Research Service, United States Salinity Laboratory, Contaminant Fate and Transport Unit" -US-SuM,32418,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,"USDA - Agricultural Research Service, San Joaquin Valley Agricultural Sciences Center, Water Management Research Unit" -US-SuM,32418,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-SuM,32419,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,"USDA-Agricultural Research Service, United States Salinity Laboratory, Contaminant Fate and Transport Unit" -US-SuM,32419,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-SuM,32417,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,US Navy - Office of Naval Research -US-SuM,32417,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-SuM,13060,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Agriculture -US-SuM,13061,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-SuM,13061,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-SuM,13061,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20130425 -US-SuM,13061,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20131209 -US-SuM,13061,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Periodic operation -US-SuM,13061,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,Observations during part of 2 year sugarcane growth cycle -US-SuM,13077,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-SuM,13077,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-SuM,13077,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20130425 -US-SuM,13077,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20131209 -US-SuM,13077,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Periodic operation -US-SuM,13077,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,Observations during part of 2 year sugarcane growth cycle -US-SuM,13075,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-SuM,13075,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-SuM,13075,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20130425 -US-SuM,13075,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20131209 -US-SuM,13075,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Periodic operation -US-SuM,13075,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,Observations during part of 2 year sugarcane growth cycle -US-SuM,23000544,GRP_HEADER,SITE_NAME,Maui Sugarcane Middle -US-SuM,13062,GRP_IGBP,IGBP,CRO -US-SuM,13062,GRP_IGBP,IGBP_DATE_START,19000101 -US-SuM,13062,GRP_IGBP,IGBP_COMMENT,This field has been in sugarcane cultivation for >100 years. Exact date of initial conversion is unknown. -US-SuM,13063,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -US-SuM,13064,GRP_LOCATION,LOCATION_LAT,20.7981 -US-SuM,13064,GRP_LOCATION,LOCATION_LONG,-156.4540 -US-SuM,13064,GRP_LOCATION,LOCATION_ELEV,21 -US-SuM,13064,GRP_LOCATION,LOCATION_DATE_START,20130425 -US-SuM,13064,GRP_LOCATION,LOCATION_COMMENT,Tower location was unchanged for entire period -US-SuM,13065,GRP_NETWORK,NETWORK,AmeriFlux -US-SuM,1700001518,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Anderson, R. G., Tirado-Corbalá, R., Wang, D., Ayars, J. E. (2015) Long-Rotation Sugarcane In Hawaii Sustains High Carbon Accumulation And Radiation Use Efficiency In 2nd Year Of Growth, Agriculture, Ecosystems & Environment, 199(), 216-224" -US-SuM,1700001518,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGEE.2014.09.012 -US-SuM,1700001518,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Primary_Citation -US-SuM,13067,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"biofuels, crop water use, soil carbon sequestration" -US-SuM,13068,GRP_SITE_CHAR,TERRAIN,Gentle slope (<2 %) -US-SuM,13068,GRP_SITE_CHAR,ASPECT,WSW -US-SuM,13068,GRP_SITE_CHAR,WIND_DIRECTION,NNE -US-SuM,13068,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,350 -US-SuM,13068,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,0 -US-SuM,13069,GRP_SITE_DESC,SITE_DESC,"Continuous, irrigated, sugarcane cultivation for >100 years. Practice is to grow plant sugarcane for 2 years, drydown, burn leaves, harvest cane, and then till and replant very shortly after harvest. Site differs from Sugarcane Windy and Sugarcane Lee/sheltered in soil and meteorology." -US-SuM,13070,GRP_SITE_FUNDING,SITE_FUNDING,US Navy - Office of Naval Research -US-SuM,13071,GRP_STATE,STATE,HI -US-SuM,13076,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Dong Wang -US-SuM,13076,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-SuM,13076,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,dong.wang@ars.usda.gov -US-SuM,13076,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"USDA - Agricultural Research Service, San Joaquin Valley Agricultural Sciences Center, Water Management Research Unit" -US-SuM,13076,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"9611 S. Riverbend Ave., Parlier, CA, 93648-9757 USA" -US-SuM,13072,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Ray Anderson -US-SuM,13072,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-SuM,13072,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,ray.anderson@ars.usda.gov -US-SuM,13072,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"USDA-Agricultural Research Service, United States Salinity Laboratory, Contaminant Fate and Transport Unit" -US-SuM,13072,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"450 W. Big Springs Rd., Riverside, CA, 92507-4617, USA" -US-SuM,29878,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-SuM,13073,GRP_TOWER_TYPE,TOWER_TYPE,triangle -US-SuM,24000544,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-SuM -US-SuM,13074,GRP_UTC_OFFSET,UTC_OFFSET,-10 -US-SuM,13074,GRP_UTC_OFFSET,UTC_OFFSET_COMMENT,"Data are reported in Hawaiian Standard Time, which is always GMT-10 hours" -US-SuS,13078,GRP_CLIM_AVG,MAT,24.4 -US-SuS,13078,GRP_CLIM_AVG,MAP,334 -US-SuS,13078,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Aw -US-SuS,27000545,GRP_COUNTRY,COUNTRY,USA -US-SuS,15659,GRP_DOI,DOI,10.17190/AMF/1246159 -US-SuS,15659,GRP_DOI,DOI_CITATION,"Dong Wang, Ray Anderson (2019), AmeriFlux BASE US-SuS Maui Sugarcane Lee/Sheltered, Ver. 2-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1246159" -US-SuS,15659,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-SuS,32420,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-SuS,32420,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Dong Wang -US-SuS,32420,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-SuS,32420,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,dong.wang@ars.usda.gov -US-SuS,32420,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"USDA - Agricultural Research Service, San Joaquin Valley Agricultural Sciences Center, Water Management Research Unit" -US-SuS,32421,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-SuS,32421,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Ray Anderson -US-SuS,32421,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-SuS,32421,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,ray.anderson@ars.usda.gov -US-SuS,32421,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"USDA-Agricultural Research Service, United States Salinity Laboratory, Contaminant Fate and Transport Unit" -US-SuS,32424,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,"USDA - Agricultural Research Service, San Joaquin Valley Agricultural Sciences Center, Water Management Research Unit" -US-SuS,32424,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-SuS,32423,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,"USDA-Agricultural Research Service, United States Salinity Laboratory, Contaminant Fate and Transport Unit" -US-SuS,32423,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-SuS,32422,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,US Navy - Office of Naval Research -US-SuS,32422,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-SuS,13079,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Agriculture -US-SuS,13080,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-SuS,13080,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-SuS,13080,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20110721 -US-SuS,13080,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20131209 -US-SuS,13080,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-SuS,13080,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,"Observations during part of two separate, two year sugarcane growth cycle" -US-SuS,13097,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-SuS,13097,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-SuS,13097,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20110721 -US-SuS,13097,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20131209 -US-SuS,13097,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-SuS,13097,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,"Observations during part of two separate, two year sugarcane growth cycle" -US-SuS,13094,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-SuS,13094,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-SuS,13094,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20110721 -US-SuS,13094,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20131209 -US-SuS,13094,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-SuS,13094,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,"Observations during part of two separate, two year sugarcane growth cycle" -US-SuS,23000545,GRP_HEADER,SITE_NAME,Maui Sugarcane Lee/Sheltered -US-SuS,13081,GRP_IGBP,IGBP,CRO -US-SuS,13081,GRP_IGBP,IGBP_DATE_START,19200101 -US-SuS,13081,GRP_IGBP,IGBP_COMMENT,This field has been in sugarcane cultivation for >80 years. Exact date of initial conversion is unknown. -US-SuS,13082,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -US-SuS,13083,GRP_LOCATION,LOCATION_LAT,20.7847 -US-SuS,13083,GRP_LOCATION,LOCATION_LONG,-156.4039 -US-SuS,13083,GRP_LOCATION,LOCATION_ELEV,203 -US-SuS,13083,GRP_LOCATION,LOCATION_DATE_START,20110721 -US-SuS,13083,GRP_LOCATION,LOCATION_COMMENT,Tower location was unchanged for entire period -US-SuS,13084,GRP_NETWORK,NETWORK,AmeriFlux -US-SuS,1700008715,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Anderson, R. G., Tirado-Corbalá, R., Wang, D., Ayars, J. E. (2015) Long-Rotation Sugarcane In Hawaii Sustains High Carbon Accumulation And Radiation Use Efficiency In 2nd Year Of Growth, Agriculture, Ecosystems & Environment, 199(), 216-224" -US-SuS,1700008715,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGEE.2014.09.012 -US-SuS,1700008715,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Primary_Citation -US-SuS,1700008916,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Anderson, R. G., Wang, D. (2014) Energy Budget Closure Observed In Paired Eddy Covariance Towers With Increased And Continuous Daily Turbulence, Agricultural And Forest Meteorology, 184(), 204-209" -US-SuS,1700008916,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2013.09.012 -US-SuS,1700008916,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-SuS,1700001620,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Anderson, R. G., Wang, D., Tirado-Corbalá, R., Zhang, H., Ayars, J. E. (2015) Divergence Of Actual And Reference Evapotranspiration Observations For Irrigated Sugarcane With Windy Tropical Conditions, Hydrology And Earth System Sciences, 19(1), 583-599" -US-SuS,1700001620,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.5194/HESS-19-583-2015 -US-SuS,1700001620,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-SuS,1700002868,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Baldocchi, D. D., Poindexter, C., Abraha, M., Desai, A. R., Bohrer, G., Arain, M. A., Griffis, T., Blanken, P. D., O'Halloran, T. L., Thomas, R. Q., Zhang, Q., Burns, S. P., Frank, J. M., Christian, D., Brown, S., Black, T. A., Gough, C. M., Law, B. E., Lee, X., Chen, J., Reed, D. E., Massman, W. J., Clark, K., Hatfield, J., Prueger, J., Bracho, R., Baker, J. M., Martin, T. A. (2018) Temporal Dynamics Of Aerodynamic Canopy Height Derived From Eddy Covariance Momentum Flux Data Across North American Flux Networks, Geophysical Research Letters, 45(1), 9275–9287" -US-SuS,1700002868,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018GL079306 -US-SuS,1700002868,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-SuS,13086,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"biofuels, crop water use, soil carbon sequestration" -US-SuS,13087,GRP_SITE_CHAR,TERRAIN,"Medium Slope (>2 %, <5%)" -US-SuS,13087,GRP_SITE_CHAR,ASPECT,W -US-SuS,13087,GRP_SITE_CHAR,WIND_DIRECTION,NNE -US-SuS,13087,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,500 -US-SuS,13087,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,0 -US-SuS,13088,GRP_SITE_DESC,SITE_DESC,"Continuous, irrigated, sugarcane cultivation for >100 years. Practice is to grow plant sugarcane for 2 years, drydown, burn leaves, harvest cane, and then till and replant very shortly after harvest. First cycle of observations were from July 2011 to November 2012. Second cycle was from April 2013 to December 2013. Site differs from Sugarcane Windy and Sugarcane Middle in soil type and meteorology." -US-SuS,13089,GRP_SITE_FUNDING,SITE_FUNDING,US Navy - Office of Naval Research -US-SuS,13090,GRP_STATE,STATE,HI -US-SuS,13096,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Dong Wang -US-SuS,13096,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-SuS,13096,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,dong.wang@ars.usda.gov -US-SuS,13096,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"USDA - Agricultural Research Service, San Joaquin Valley Agricultural Sciences Center, Water Management Research Unit" -US-SuS,13096,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"9611 S. Riverbend Ave., Parlier, CA, 93648-9757 USA" -US-SuS,13091,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Ray Anderson -US-SuS,13091,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-SuS,13091,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,ray.anderson@ars.usda.gov -US-SuS,13091,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"USDA-Agricultural Research Service, United States Salinity Laboratory, Contaminant Fate and Transport Unit" -US-SuS,13091,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"450 W. Big Springs Rd., Riverside, CA, 92507-4617, USA" -US-SuS,29879,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-SuS,13092,GRP_TOWER_TYPE,TOWER_TYPE,triangle -US-SuS,24000545,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-SuS -US-SuS,13093,GRP_UTC_OFFSET,UTC_OFFSET,-10 -US-SuS,13093,GRP_UTC_OFFSET,UTC_OFFSET_DATE_START,20110721 -US-SuS,13093,GRP_UTC_OFFSET,UTC_OFFSET_COMMENT,"Data are reported in Hawaiian Standard Time, which is always GMT-10 hours" -US-SuW,13099,GRP_CLIM_AVG,MAT,24.4 -US-SuW,13099,GRP_CLIM_AVG,MAP,366 -US-SuW,13099,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Aw -US-SuW,27000543,GRP_COUNTRY,COUNTRY,USA -US-SuW,15720,GRP_DOI,DOI,10.17190/AMF/1246157 -US-SuW,15720,GRP_DOI,DOI_CITATION,"Dong Wang, Ray Anderson (2019), AmeriFlux BASE US-SuW Maui Sugarcane Windy, Ver. 2-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1246157" -US-SuW,15720,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-SuW,32411,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-SuW,32411,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Dong Wang -US-SuW,32411,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-SuW,32411,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,dong.wang@ars.usda.gov -US-SuW,32411,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"USDA - Agricultural Research Service, San Joaquin Valley Agricultural Sciences Center, Water Management Research Unit" -US-SuW,32410,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-SuW,32410,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Ray Anderson -US-SuW,32410,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-SuW,32410,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,ray.anderson@ars.usda.gov -US-SuW,32410,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"USDA-Agricultural Research Service, United States Salinity Laboratory, Contaminant Fate and Transport Unit" -US-SuW,32413,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,"USDA - Agricultural Research Service, San Joaquin Valley Agricultural Sciences Center, Water Management Research Unit" -US-SuW,32413,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-SuW,32414,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,"USDA-Agricultural Research Service, United States Salinity Laboratory, Contaminant Fate and Transport Unit" -US-SuW,32414,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-SuW,32412,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,US Navy - Office of Naval Research -US-SuW,32412,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-SuW,13100,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Agriculture -US-SuW,13101,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-SuW,13101,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-SuW,13101,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20110723 -US-SuW,13101,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20130419 -US-SuW,13101,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-SuW,13101,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,Observations during 2 year sugarcane growth cycle -US-SuW,13118,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-SuW,13118,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-SuW,13118,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20110723 -US-SuW,13118,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20130419 -US-SuW,13118,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-SuW,13118,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,Observations during 2 year sugarcane growth cycle -US-SuW,13115,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-SuW,13115,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-SuW,13115,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20110723 -US-SuW,13115,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20130419 -US-SuW,13115,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-SuW,13115,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,Observations during 2 year sugarcane growth cycle -US-SuW,23000543,GRP_HEADER,SITE_NAME,Maui Sugarcane Windy -US-SuW,13102,GRP_IGBP,IGBP,CRO -US-SuW,13102,GRP_IGBP,IGBP_DATE_START,19000101 -US-SuW,13102,GRP_IGBP,IGBP_COMMENT,This field has been in sugarcane cultivation for >100 years. Exact date of initial conversion is unknown. -US-SuW,13103,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -US-SuW,13104,GRP_LOCATION,LOCATION_LAT,20.8246 -US-SuW,13104,GRP_LOCATION,LOCATION_LONG,-156.4913 -US-SuW,13104,GRP_LOCATION,LOCATION_ELEV,44 -US-SuW,13104,GRP_LOCATION,LOCATION_DATE_START,20110723 -US-SuW,13104,GRP_LOCATION,LOCATION_COMMENT,Tower location was unchanged for entire period -US-SuW,13105,GRP_NETWORK,NETWORK,AmeriFlux -US-SuW,1700003939,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Anderson, R. G., Tirado-Corbalá, R., Wang, D., Ayars, J. E. (2015) Long-Rotation Sugarcane In Hawaii Sustains High Carbon Accumulation And Radiation Use Efficiency In 2nd Year Of Growth, Agriculture, Ecosystems & Environment, 199(), 216-224" -US-SuW,1700003939,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGEE.2014.09.012 -US-SuW,1700003939,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Primary_Citation -US-SuW,1700002325,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Anderson, R. G., Wang, D. (2014) Energy Budget Closure Observed In Paired Eddy Covariance Towers With Increased And Continuous Daily Turbulence, Agricultural And Forest Meteorology, 184(), 204-209" -US-SuW,1700002325,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2013.09.012 -US-SuW,1700002325,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-SuW,1700008748,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Anderson, R. G., Wang, D., Tirado-Corbalá, R., Zhang, H., Ayars, J. E. (2015) Divergence Of Actual And Reference Evapotranspiration Observations For Irrigated Sugarcane With Windy Tropical Conditions, Hydrology And Earth System Sciences, 19(1), 583-599" -US-SuW,1700008748,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.5194/HESS-19-583-2015 -US-SuW,1700008748,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-SuW,13107,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"biofuels, crop water use, soil carbon sequestration" -US-SuW,13108,GRP_SITE_CHAR,TERRAIN,Gentle slope (<2 %) -US-SuW,13108,GRP_SITE_CHAR,ASPECT,ENE -US-SuW,13108,GRP_SITE_CHAR,WIND_DIRECTION,NE -US-SuW,13108,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,350 -US-SuW,13108,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,0 -US-SuW,13109,GRP_SITE_DESC,SITE_DESC,"Continuous, irrigated, sugarcane cultivation for >100 years. Practice is to grow plant sugarcane for 2 years, drydown, burn leaves, harvest cane, and then till and replant very shortly after harvest. Site differs from Sugarcane Lee/Sheltered and Sugarcane Middle in soil type and site meteorology." -US-SuW,13110,GRP_SITE_FUNDING,SITE_FUNDING,US Navy - Office of Naval Research -US-SuW,13111,GRP_STATE,STATE,HI -US-SuW,13117,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Dong Wang -US-SuW,13117,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-SuW,13117,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,dong.wang@ars.usda.gov -US-SuW,13117,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"USDA - Agricultural Research Service, San Joaquin Valley Agricultural Sciences Center, Water Management Research Unit" -US-SuW,13117,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"9611 S. Riverbend Ave., Parlier, CA, 93648-9757 USA" -US-SuW,13112,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Ray Anderson -US-SuW,13112,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-SuW,13112,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,ray.anderson@ars.usda.gov -US-SuW,13112,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"USDA-Agricultural Research Service, United States Salinity Laboratory, Contaminant Fate and Transport Unit" -US-SuW,13112,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"450 W. Big Springs Rd., Riverside, CA, 92507-4617, USA" -US-SuW,29877,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-SuW,13113,GRP_TOWER_TYPE,TOWER_TYPE,triangle -US-SuW,24000543,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-SuW -US-SuW,13114,GRP_UTC_OFFSET,UTC_OFFSET,-10 -US-SuW,13114,GRP_UTC_OFFSET,UTC_OFFSET_COMMENT,"Data are reported in Hawaiian Standard Time, which is always GMT-10 hours" -US-Syv,23635,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER,25.4 -US-Syv,23635,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_ORGAN,Total -US-Syv,23635,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_PHEN,Mixed/unknown -US-Syv,23635,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_UNIT,kgDM m-2 -US-Syv,27938,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,12700 -US-Syv,27938,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Total -US-Syv,27938,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-Syv,27938,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-Syv,27938,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,2007 Fluxnet File (total above-ground biomass) -US-Syv,27018,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,150.5 -US-Syv,27018,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Foliage -US-Syv,27018,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-Syv,27018,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-Syv,27018,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,2007 Fluxnet File (total above-ground biomass) -US-Syv,27937,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,24.07 -US-Syv,27937,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Foliage -US-Syv,27937,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-Syv,27937,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-Syv,27937,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,"AG_TF, Sugar Maple, Tang et al 2008" -US-Syv,28297,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,33.1 -US-Syv,28297,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Wood -US-Syv,28297,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-Syv,28297,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-Syv,28297,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,Live Aboveground Woody BioMass; www.cheas.psu.edu/data/cheas/biometry -US-Syv,28297,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,"(33.1 m2 ha-1); Basal Area, Tang 2008" -US-Syv,27320,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,33.33 -US-Syv,27320,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Foliage -US-Syv,27320,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-Syv,27320,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-Syv,27320,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,"AG_TF, Sugar Maple, Tang et al 2008" -US-Syv,28203,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,93.09 -US-Syv,28203,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Foliage -US-Syv,28203,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-Syv,28203,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-Syv,28203,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,"AG_TF, Sugar Maple, Tang et al 2008" -US-Syv,26867,GRP_AG_PROD_TREE,AG_PROD_TREE,106 -US-Syv,26867,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Total -US-Syv,26867,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-Syv,26867,GRP_AG_PROD_TREE,AG_PROD_COMMENT,2007 Fluxnet File (above-ground NPP) -US-Syv,26727,GRP_BIOMASS_CHEM,BIOMASS_N,0.1793 -US-Syv,29485,GRP_BIOMASS_CHEM,BIOMASS_N,0.192 -US-Syv,28296,GRP_BIOMASS_CHEM,BIOMASS_N,0.204 -US-Syv,28201,GRP_BIOMASS_CHEM,BIOMASS_N,0.2083 -US-Syv,29484,GRP_BIOMASS_CHEM,BIOMASS_N,0.2083 -US-Syv,29025,GRP_BIOMASS_CHEM,BIOMASS_N,0.2519 -US-Syv,26727,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-Syv,28201,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-Syv,28296,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-Syv,29025,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-Syv,29484,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-Syv,29485,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-Syv,26727,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-Syv,28201,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-Syv,28296,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-Syv,29025,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-Syv,29484,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-Syv,29485,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-Syv,28201,GRP_BIOMASS_CHEM,BIOMASS_SPP,(All) -US-Syv,28296,GRP_BIOMASS_CHEM,BIOMASS_SPP,(All) -US-Syv,29485,GRP_BIOMASS_CHEM,BIOMASS_SPP,(All) -US-Syv,26727,GRP_BIOMASS_CHEM,BIOMASS_SPP,ACSA3 (NRCS plant code) -US-Syv,29025,GRP_BIOMASS_CHEM,BIOMASS_SPP,BEAL2 (NRCS plant code) -US-Syv,29484,GRP_BIOMASS_CHEM,BIOMASS_SPP,TSCA (NRCS plant code) -US-Syv,26727,GRP_BIOMASS_CHEM,BIOMASS_COMMENT,"ACSA3,Maple" -US-Syv,29025,GRP_BIOMASS_CHEM,BIOMASS_COMMENT,"BEAL2, Birch" -US-Syv,28201,GRP_BIOMASS_CHEM,BIOMASS_COMMENT,Lower Canopy -US-Syv,29485,GRP_BIOMASS_CHEM,BIOMASS_COMMENT,Mid-canopy -US-Syv,29484,GRP_BIOMASS_CHEM,BIOMASS_COMMENT,"TSCA, Hemlock" -US-Syv,28296,GRP_BIOMASS_CHEM,BIOMASS_COMMENT,Upper Canopy -US-Syv,15313,GRP_CLIM_AVG,MAT,3.81 -US-Syv,15313,GRP_CLIM_AVG,MAP,826 -US-Syv,15313,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfb -US-Syv,27000437,GRP_COUNTRY,COUNTRY,USA -US-Syv,3674,GRP_DM_GENERAL,DM_GENERAL,Other -US-Syv,3674,GRP_DM_GENERAL,DM_COMMENT,"undisturbed, old growth forest appoximately 350 years old" -US-Syv,15741,GRP_DOI,DOI,10.17190/AMF/1246106 -US-Syv,15741,GRP_DOI,DOI_CITATION,"Ankur Desai (2022), AmeriFlux BASE US-Syv Sylvania Wilderness Area, Ver. 20-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1246106" -US-Syv,15741,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-Syv,32212,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Syv,32212,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Ankur Desai -US-Syv,32212,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Syv,32212,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,desai@aos.wisc.edu -US-Syv,32212,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of Wisconsin -US-Syv,32214,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,University of Wisconsin -US-Syv,32214,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-Syv,32213,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,DOE Ameriflux Network Management Project -US-Syv,32213,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-Syv,22192,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Undisturbed -US-Syv,91747,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Syv,91747,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-Syv,91747,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20010601 -US-Syv,91747,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Syv,91747,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,"No flux data from mid 2007 to late 2011, also first half of 2019, confirmed 4/1/2020" -US-Syv,91748,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Syv,91748,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-Syv,91748,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20010601 -US-Syv,91748,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Syv,91748,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,confirmed 4/1/20 -US-Syv,91745,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Syv,91745,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-Syv,91745,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20010601 -US-Syv,91745,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Syv,91745,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,confirmed 4/1/2020 -US-Syv,23000437,GRP_HEADER,SITE_NAME,Sylvania Wilderness Area -US-Syv,88195,GRP_HEIGHTC,HEIGHTC,27.5 -US-Syv,88195,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Syv,88195,GRP_HEIGHTC,HEIGHTC_DATE,20050404 -US-Syv,88195,GRP_HEIGHTC,HEIGHTC_COMMENT,27-28; From Ameriflux Site Info Page -US-Syv,15315,GRP_IGBP,IGBP,MF -US-Syv,15315,GRP_IGBP,IGBP_COMMENT,"sugar maple (Acer saccharum), eastern hemlock (Tsuga canadensis), , and yellow birch (Betula alleghaniensis)." -US-Syv,26726,GRP_LAI,LAI_TYPE,LAI -US-Syv,27017,GRP_LAI,LAI_TYPE,LAI -US-Syv,27573,GRP_LAI,LAI_TYPE,LAI -US-Syv,28538,GRP_LAI,LAI_TYPE,LAI -US-Syv,29026,GRP_LAI,LAI_TYPE,LAI -US-Syv,29027,GRP_LAI,LAI_TYPE,LAI -US-Syv,29138,GRP_LAI,LAI_TYPE,LAI -US-Syv,27017,GRP_LAI,LAI_METHOD,LAI_2000 -US-Syv,27017,GRP_LAI,LAI_DATE,20020901 -US-Syv,26726,GRP_LAI,LAI_COMMENT,"ACSA3, sugar maple patches, Ameriflux page" -US-Syv,29138,GRP_LAI,LAI_COMMENT,"ACSA3, sugar maple. Tang et al., 2008, Table 2." -US-Syv,29026,GRP_LAI,LAI_COMMENT,"BEAL2, yellow birch. Tang et al., 2008, Table 2." -US-Syv,27017,GRP_LAI,LAI_COMMENT,"LAI-2000 (LI-COR, Inc., Lincoln, NE); Tang et al-2008" -US-Syv,29027,GRP_LAI,LAI_COMMENT,"Total. Tang et al., 2008, Table 2." -US-Syv,28538,GRP_LAI,LAI_COMMENT,"TSCA, hemlock patches, Ameriflux page" -US-Syv,27573,GRP_LAI,LAI_COMMENT,"TSCA,Hemlock. Tang et al., 2008, Table 2." -US-Syv,29026,GRP_LAI,LAI_TOT,1.78 -US-Syv,29138,GRP_LAI,LAI_TOT,2.65 -US-Syv,28538,GRP_LAI,LAI_TOT,3.79 -US-Syv,26726,GRP_LAI,LAI_TOT,4.06 -US-Syv,27017,GRP_LAI,LAI_TOT,4.1 -US-Syv,27573,GRP_LAI,LAI_TOT,4.26 -US-Syv,29027,GRP_LAI,LAI_TOT,7.53 -US-Syv,15316,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-Syv,15316,GRP_LAND_OWNERSHIP,LAND_OWNER,USDA Forest Service. Ottawa National Forest. -US-Syv,27318,GRP_LMA,LMA,147 -US-Syv,27318,GRP_LMA,LMA_SPP,TSCA (NRCS plant code) -US-Syv,27318,GRP_LMA,LMA_COMMENT,"TSCA, Hemlock; http://www.cheas.psu.edu/data/cheas/publish-on-cheas/Sylvania_tower/Site%20Characterization/Leaf%20Characterization/Leaf%20Area/Raw%20Data%20Files/SLA_2002.xls" -US-Syv,27316,GRP_LMA,LMA,54.36 -US-Syv,27316,GRP_LMA,LMA_SPP,ACSA3 (NRCS plant code) -US-Syv,27316,GRP_LMA,LMA_COMMENT,"ACSA3, Maple; http://www.cheas.psu.edu/data/cheas/publish-on-cheas/Sylvania_tower/Site%20Characterization/Leaf%20Characterization/Leaf%20Area/Raw%20Data%20Files/SLA_2002.xls" -US-Syv,27317,GRP_LMA,LMA,60.09 -US-Syv,27317,GRP_LMA,LMA_SPP,BEAL2 (NRCS plant code) -US-Syv,27317,GRP_LMA,LMA_COMMENT,"BEAL2, Birch; http://www.cheas.psu.edu/data/cheas/publish-on-cheas/Sylvania_tower/Site%20Characterization/Leaf%20Characterization/Leaf%20Area/Raw%20Data%20Files/SLA_2002.xls" -US-Syv,15317,GRP_LOCATION,LOCATION_LAT,46.2420 -US-Syv,15317,GRP_LOCATION,LOCATION_LONG,-89.3477 -US-Syv,15317,GRP_LOCATION,LOCATION_ELEV,540.00 -US-Syv,24926,GRP_NEP,NEP,212 -US-Syv,15318,GRP_NETWORK,NETWORK,AmeriFlux -US-Syv,87012,GRP_NETWORK,NETWORK,Phenocam -US-Syv,27936,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,Leaf senescence -US-Syv,27936,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,(All) -US-Syv,27936,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20030530 -US-Syv,27936,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,"Inferred from PAR data, Brett Raczka" -US-Syv,29137,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,Leaf senescence -US-Syv,29137,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,(All) -US-Syv,29137,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20020602 -US-Syv,29137,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,"Inferred from PAR data, Brett Raczka" -US-Syv,27319,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,Maximum leaf expansion -US-Syv,27319,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,(All) -US-Syv,27319,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20031017 -US-Syv,27319,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,"Inferred from PAR data, Brett Raczka" -US-Syv,28202,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,Maximum leaf expansion -US-Syv,28202,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,(All) -US-Syv,28202,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20011015 -US-Syv,28202,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,"Inferred from PAR data, Brett Raczka" -US-Syv,29487,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,Maximum leaf expansion -US-Syv,29487,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,(All) -US-Syv,29487,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20051014 -US-Syv,29487,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,"Inferred from PAR data, Brett Raczka" -US-Syv,1700001506,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Barr, A., Richardson, A., Hollinger, D., Papale, D., Arain, M., Black, T., Bohrer, G., Dragoni, D., Fischer, M., Gu, L., Law, B., Margolis, H., McCaughey, J., Munger, J., Oechel, W., Schaeffer, K. (2013) Use Of Change-Point Detection For Friction–Velocity Threshold Evaluation In Eddy-Covariance Studies, Agricultural And Forest Meteorology, 171-172(7), 31-45" -US-Syv,1700001506,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2012.11.023 -US-Syv,1700001506,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Syv,1700002397,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Besnard, S., Carvalhais, N., Arain, M. A., Black, A., de Bruin, S., Buchmann, N., Cescatti, A., Chen, J., Clevers, J. G., Desai, A. R., Gough, C. M., Havrankova, K., Herold, M., Hörtnagl, L., Jung, M., Knohl, A., Kruijt, B., Krupkova, L., Law, B. E., Lindroth, A., Noormets, A., Roupsard, O., Steinbrecher, R., Varlagin, A., Vincke, C., Reichstein, M. (2018) Quantifying The Effect Of Forest Age In Annual Net Forest Carbon Balance, Environmental Research Letters, 13(12), 124018" -US-Syv,1700002397,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1088/1748-9326/AAEAEB -US-Syv,1700002397,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Syv,1700006216,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Baldocchi, D. D., Poindexter, C., Abraha, M., Desai, A. R., Bohrer, G., Arain, M. A., Griffis, T., Blanken, P. D., O'Halloran, T. L., Thomas, R. Q., Zhang, Q., Burns, S. P., Frank, J. M., Christian, D., Brown, S., Black, T. A., Gough, C. M., Law, B. E., Lee, X., Chen, J., Reed, D. E., Massman, W. J., Clark, K., Hatfield, J., Prueger, J., Bracho, R., Baker, J. M., Martin, T. A. (2018) Temporal Dynamics Of Aerodynamic Canopy Height Derived From Eddy Covariance Momentum Flux Data Across North American Flux Networks, Geophysical Research Letters, 45(2), 9275–9287" -US-Syv,1700006216,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018GL079306 -US-Syv,1700006216,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Syv,1700001425,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Baldocchi, D. D., Poindexter, C., Abraha, M., Desai, A. R., Bohrer, G., Arain, M. A., Griffis, T., Blanken, P. D., O'Halloran, T. L., Thomas, R. Q., Zhang, Q., Burns, S. P., Frank, J. M., Christian, D., Brown, S., Black, T. A., Gough, C. M., Law, B. E., Lee, X., Chen, J., Reed, D. E., Massman, W. J., Clark, K., Hatfield, J., Prueger, J., Bracho, R., Baker, J. M., Martin, T. A. (2018) Temporal Dynamics Of Aerodynamic Canopy Height Derived From Eddy Covariance Momentum Flux Data Across North American Flux Networks, Geophysical Research Letters, 45(G2), 9275–9287" -US-Syv,1700001425,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018GL079306 -US-Syv,1700001425,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Syv,1700007143,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(7), 108350" -US-Syv,1700007143,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -US-Syv,1700007143,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Syv,1700002892,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Desai, A. R., Bolstad, P. V., Cook, B. D., Davis, K. J., Carey, E. V. (2005) Comparing Net Ecosystem Exchange Of Carbon Dioxide Between An Old-Growth And Mature Forest In The Upper Midwest, Usa, Agricultural And Forest Meteorology, 128(1-2), 33-55" -US-Syv,1700002892,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2004.09.005 -US-Syv,1700002892,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Primary_Citation -US-Syv,1700004290,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Desai, A. R., Noormets, A., Bolstad, P. V., Chen, J., Cook, B. D., Davis, K. J., Euskirchen, E. S., Gough, C., Martin, J. G., Ricciuto, D. M., Schmid, H. P., Tang, J., Wang, W. (2008) Influence Of Vegetation And Seasonal Forcing On Carbon Dioxide Fluxes Across The Upper Midwest, Usa: Implications For Regional Scaling, Agricultural And Forest Meteorology, 148(2), 288-308" -US-Syv,1700004290,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2007.08.001 -US-Syv,1700004290,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Syv,1700004314,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Desai, A.R. (2010) Climatic And Phenological Controls On Coherent Regional Interannual Variability Of Carbon Dioxide Flux In A Heterogeneous Landscape, Journal Of Geophysical Research, 115(G00J02), n/a-n/a" -US-Syv,1700004314,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2010JG001423 -US-Syv,1700004314,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Syv,1700008856,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Matheny, A. M., Bohrer, G., Stoy, P. C., Baker, I. T., Black, A. T., Desai, A. R., Dietze, M. C., Gough, C. M., Ivanov, V. Y., Jassal, R. S., Novick, K. A., Schäfer, K. V., Verbeeck, H. (2014) Characterizing The Diurnal Patterns of Errors in The Prediction of Evapotranspiration by Several Land-Surface Models: An Nacp Analysis, Journal Of Geophysical Research: Biogeosciences, 119(7), 1458-1473" -US-Syv,1700008856,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/2014JG002623 -US-Syv,1700008856,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Syv,1700000600,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Novick, K. A., Ficklin, D. L., Stoy, P. C., Williams, C. A., Bohrer, G., Oishi, A., Papuga, S. A., Blanken, P. D., Noormets, A., Sulman, B. N., Scott, R. L., Wang, L., Phillips, R. P. (2016) The Increasing Importance Of Atmospheric Demand For Ecosystem Water And Carbon Fluxes, Nature Climate Change, 6(11), 1023-1027" -US-Syv,1700000600,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1038/NCLIMATE3114 -US-Syv,1700000600,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Syv,1700004185,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Sullivan, R. C., Cook, D. R., Ghate, V. P., Kotamarthi, V. R., Feng, Y. (2019) Improved Spatiotemporal Representativeness And Bias Reduction Of Satellite-Based Evapotranspiration Retrievals Via Use Of In Situ Meteorology And Constrained Canopy Surface Resistance, Journal Of Geophysical Research: Biogeosciences, 124(2), 342-352" -US-Syv,1700004185,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018JG004744 -US-Syv,1700004185,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Syv,1700007938,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Sullivan, R. C., Kotamarthi, V. R., Feng, Y. (2019) Recovering Evapotranspiration Trends From Biased CMIP5 Simulations And Sensitivity To Changing Climate Over North America, Journal Of Hydrometeorology, 20(8), 1619-1633" -US-Syv,1700007938,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1175/JHM-D-18-0259.1 -US-Syv,1700007938,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Syv,1700004872,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Tang, J., Bolstad, P. V., Desai, A. R., Martin, J. G., Cook, B. D., Davis, K. J., Carey, E. V. (2008) Ecosystem Respiration And Its Components In An Old-Growth Forest In The Great Lakes Region Of The United States, Agricultural And Forest Meteorology, 148(2), 171-185" -US-Syv,1700004872,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2007.08.008 -US-Syv,1700004872,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Syv,1700001779,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Tang, J., Bolstad, P. V., Ewers, B. E., Desai, A. R., Davis, K. J., Carey, E. V. (2006) Sap Flux-Upscaled Canopy Transpiration, Stomatal Conductance, And Water Use Efficiency In An Old Growth Forest In The Great Lakes Region Of The United States, Journal Of Geophysical Research: Biogeosciences, 111(G2), n/a-n/a" -US-Syv,1700001779,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2005JG000083 -US-Syv,1700001779,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Syv,1700000057,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Xu, B., Arain, M. A., Black, T. A., Law, B. E., Pastorello, G. Z., Chu, H. (2020) Seasonal Variability Of Forest Sensitivity To Heat And Drought Stresses: A Synthesis Based On Carbon Fluxes From North American Forest Ecosystems, Global Change Biology, 26(2), 901-918" -US-Syv,1700000057,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/GCB.14843 -US-Syv,1700000057,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Syv,1700001764,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Zhang, Q., Ficklin, D. L., Manzoni, S., Wang, L., Way, D., Phillips, R. P., Novick, K. A. (2019) Response Of Ecosystem Intrinsic Water Use Efficiency And Gross Primary Productivity To Rising Vapor Pressure Deficit, Environmental Research Letters, 14(7), 074023" -US-Syv,1700001764,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1088/1748-9326/AB2603 -US-Syv,1700001764,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Syv,15320,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"The research and science objectives of the Sylvania Wilderness site are as follows: 1) Better quantify stand age effects in models of forest carbon exchange and improve regional-scale estimates of NEE in old-growth forests; 2) Evaluate the carbon sink strength of old-growth forests; 3) Quantify the differential impact of environmental drivers, radiation, and vapor pressure deficit in old-growth forests; 4) Compare respiration from the old-growth forest with mature second-growth forests under similar climate, and derive the successional pattern of respiration; 5) Upscale sap flux to canopy transpiration, estimate canopy stomatal conductance, and examine transpiration and stomatal responses to environmental conditions; 6) Calculate water use efficiency and its responses to environmental conditions by combining sap flux measurements and eddy covariance measurements. (Deasi et al. (2005), Tang et al. (2006), Ewers et al. (2008), Tang et al. (2008))" -US-Syv,22193,GRP_SITE_CHAR,TERRAIN,Gentle slope (<2 %) -US-Syv,22193,GRP_SITE_CHAR,ASPECT,N -US-Syv,22193,GRP_SITE_CHAR,WIND_DIRECTION,W -US-Syv,22193,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,1000 -US-Syv,22193,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,120 -US-Syv,94997,GRP_SITE_DESC,SITE_DESC,"Old growth forest consisting primarily of sugar maple and eastern hemlock. Note that a small lake to the north and data analyses suggest that wind direction screening is appropriate (see Desai, A.R., Bolstad, P.V., Cook, B.D., Davis, K.J., and Carey, E.V., 2005. Comparing net ecosystem exchange of carbon dioxide between an old-growth and mature forest in the upper midwest, USA. Ag. For. Met. 128(1-2): 33-55 (doi: 10.1016/j.agrformet.2004). Site was chosen to represent an end member representative of the upland forests in the WLEF tall tower flux footprint. (Note, however, that old growth forests are not found within the WLEF tall tower flux footprint.) -Virtual Site Visit: https://fen.aos.wisc.edu/owncloud/index.php/s/Il31u921iYXbSEO" -US-Syv,15323,GRP_SITE_FUNDING,SITE_FUNDING,DOE Ameriflux Network Management Project -US-Syv,29486,GRP_SOIL_CHEM,SOIL_CHEM_C_ORG,104.67 -US-Syv,29486,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,0 -US-Syv,29486,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,60 -US-Syv,29486,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,(top 60 cm); 2007 Fluxnet File -US-Syv,27187,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION,"Upland soils that are moderately well-drained, coarse or sandy loam spodosols. The thickness of the overlying organic horizon is approximately 0.1 m." -US-Syv,27187,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION_TAXONOMY,Other -US-Syv,24933,GRP_SOIL_DEPTH,SOIL_DEPTH,10 -US-Syv,28539,GRP_SOIL_TEX,SOIL_TEX_SAND,57 -US-Syv,28539,GRP_SOIL_TEX,SOIL_TEX_SILT,36 -US-Syv,28539,GRP_SOIL_TEX,SOIL_TEX_CLAY,6 -US-Syv,28539,GRP_SOIL_TEX,SOIL_TEX_COMMENT,http://www.cheas.psu.edu/data/cheas/publish-on-cheas/Sylvania_tower/Site%20Characterization/Soil%20Characterization/Soil%20Texture/Soil%20Texture.doc -US-Syv,28298,GRP_SPP_O,SPP_O,ACSA3 (NRCS plant code) -US-Syv,28540,GRP_SPP_O,SPP_O,BEAL2 (NRCS plant code) -US-Syv,28541,GRP_SPP_O,SPP_O,EUSID (NRCS plant code) -US-Syv,26729,GRP_SPP_O,SPP_O,TIAM (NRCS plant code) -US-Syv,26728,GRP_SPP_O,SPP_O,TSCA (NRCS plant code) -US-Syv,26728,GRP_SPP_O,SPP_O_PERC,14 -US-Syv,28540,GRP_SPP_O,SPP_O_PERC,7 -US-Syv,28298,GRP_SPP_O,SPP_O_PERC,71 -US-Syv,26729,GRP_SPP_O,SPP_O_PERC,8 -US-Syv,28541,GRP_SPP_O,SPP_O_PERC,8 -US-Syv,26728,GRP_SPP_O,SPP_DATE,2002 -US-Syv,26729,GRP_SPP_O,SPP_DATE,2002 -US-Syv,28298,GRP_SPP_O,SPP_DATE,2002 -US-Syv,28540,GRP_SPP_O,SPP_DATE,2002 -US-Syv,28541,GRP_SPP_O,SPP_DATE,2002 -US-Syv,26728,GRP_SPP_O,SPP_COMMENT,(hemlock); Tang et al-2008 -US-Syv,28298,GRP_SPP_O,SPP_COMMENT,(sugar maple); Tang et al-2008 -US-Syv,28540,GRP_SPP_O,SPP_COMMENT,(yellow birch); Tang et al-2008 -US-Syv,26729,GRP_SPP_O,SPP_COMMENT,"split between TIAM, (basswood) & EUSID (ironwood), Tang et al-2008" -US-Syv,28541,GRP_SPP_O,SPP_COMMENT,"split between TIAM, (basswood) & EUSID (ironwood), Tang et al-2008" -US-Syv,15324,GRP_STATE,STATE,MI -US-Syv,15325,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Ankur Desai -US-Syv,15325,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Syv,15325,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,desai@aos.wisc.edu -US-Syv,15325,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Wisconsin -US-Syv,15325,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Department of Atmospheric and Oceanic Sciences, 1225 W Dayton St, Madison, WI 53706" -US-Syv,15331,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Jonathan Thom -US-Syv,15331,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-Syv,15331,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,jthom@ssec.wisc.edu -US-Syv,15331,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Wisconsin -US-Syv,15331,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Space Sciences and Engineering, 1225 W Dayton St,Madison, WI 53706" -US-Syv,29841,GRP_TOWER_POWER,TOWER_POWER,Direct power -US-Syv,15326,GRP_TOWER_TYPE,TOWER_TYPE,triangle -US-Syv,15327,GRP_URL,URL,http://flux.aos.wisc.edu/twiki/bin/view/Main/ChEASData -US-Syv,24000437,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-Syv -US-Syv,15328,GRP_UTC_OFFSET,UTC_OFFSET,-6 -US-TCS,90684,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,USGS Priority Ecosystem Science Everglades Program -US-TCS,90684,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT_COMMENT,Tower construction funded by South Florida Water Management District -US-TCS,90699,GRP_CLIM_AVG,MAT,23.6 -US-TCS,90699,GRP_CLIM_AVG,MAP,1312 -US-TCS,90699,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Cfa -US-TCS,27001117,GRP_COUNTRY,COUNTRY,USA -US-TCS,90700,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Hydrologic event -US-TCS,90696,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Storm or wind -US-TCS,90683,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-TCS,90683,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-TCS,90683,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20121212 -US-TCS,90683,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,202001130000 -US-TCS,90683,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-TCS,90682,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-TCS,90682,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-TCS,90682,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20121212 -US-TCS,90682,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,202001130000 -US-TCS,90682,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-TCS,90695,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-TCS,90695,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,Other -US-TCS,90695,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20121212 -US-TCS,90695,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,202001130000 -US-TCS,90695,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-TCS,90695,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,Measured for LE -US-TCS,23001117,GRP_HEADER,SITE_NAME,Tall Cypress Swamp -US-TCS,90703,GRP_IGBP,IGBP,WET -US-TCS,90691,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-TCS,90691,GRP_LAND_OWNERSHIP,LAND_OWNER,National Preserve -US-TCS,90690,GRP_LOCATION,LOCATION_LAT,25.8221 -US-TCS,90690,GRP_LOCATION,LOCATION_LONG,-81.1017 -US-TCS,90690,GRP_LOCATION,LOCATION_ELEV,1.2 -US-TCS,90690,GRP_LOCATION,LOCATION_DATE_START,20121212 -US-TCS,90690,GRP_LOCATION,LOCATION_COMMENT,Located in Big Cypress National Preserve -US-TCS,90687,GRP_NETWORK,NETWORK,AmeriFlux -US-TCS,90689,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,Carbon and water fuxes -US-TCS,90693,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"3321 College Ave, Davie FL 33314" -US-TCS,90692,GRP_SITE_CHAR,TERRAIN,Flat -US-TCS,90692,GRP_SITE_CHAR,ASPECT,S -US-TCS,90692,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,0 -US-TCS,90701,GRP_SITE_DESC,SITE_DESC,Tall Cypress Swamp -US-TCS,90688,GRP_SITE_FUNDING,SITE_FUNDING,USGS Priority Ecosystem Science Everglades Program -US-TCS,90686,GRP_STATE,STATE,FL -US-TCS,90755,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Andre Daniels -US-TCS,90755,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-TCS,90755,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,andre_daniels@usgs.gov -US-TCS,90755,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,USGS -US-TCS,90698,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,W. Barclay Shoemaker -US-TCS,90698,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-TCS,90698,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,bshoemak@usgs.gov -US-TCS,90698,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,USGS -US-TCS,90698,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"3321 College Ave, Davie FL 33314" -US-TCS,93484,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Rosvel Bracho-Garrillo -US-TCS,93484,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,DataManager -US-TCS,93484,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,rbracho@ufl.edu -US-TCS,93484,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Florida -US-TCS,90697,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-TCS,90694,GRP_TOWER_TYPE,TOWER_TYPE,triangle -US-TCS,90685,GRP_URL,URL,https://sites.google.com/site/floridaetwiki/home -US-TCS,24001117,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-TCS -US-TCS,90704,GRP_UTC_OFFSET,UTC_OFFSET,-5 -US-TCS,90704,GRP_UTC_OFFSET,UTC_OFFSET_DATE_START,20200113 -US-TCS,90704,GRP_UTC_OFFSET,UTC_OFFSET_COMMENT,Eatern Standard Time Zone -US-Ton,9339,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,"This research was supported by the US Department of Energy Terrestrial Carbon Program, grant No. DE-FG03-00ER63013 and DE-SC0005130" -US-Ton,9339,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT_COMMENT,multi-site synthesis or exclusive use of data -US-Ton,553,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,"This research was supported in part by the Office of Science (BER), U.S. Department of Energy, Grant No. DE-FG02-03ER63638" -US-Ton,23838,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER,500 -US-Ton,23838,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_ORGAN,Total -US-Ton,23838,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_PHEN,Mixed/unknown -US-Ton,23838,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_UNIT,gC m-2 -US-Ton,23838,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_DATE,2003 -US-Ton,23838,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_COMMENT,2001-2003 by John Battles -US-Ton,23983,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER,500 -US-Ton,23983,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_ORGAN,Total -US-Ton,23983,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_PHEN,Mixed/unknown -US-Ton,23983,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_UNIT,gC m-2 -US-Ton,23983,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_DATE,2001 -US-Ton,23983,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_COMMENT,2001-2003 by John Battles -US-Ton,24244,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER,500 -US-Ton,24244,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_ORGAN,Total -US-Ton,24244,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_PHEN,Mixed/unknown -US-Ton,24244,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_UNIT,gC m-2 -US-Ton,24244,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_DATE,2002 -US-Ton,24244,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_COMMENT,2001-2003 by John Battles -US-Ton,24495,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,4200 -US-Ton,24495,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Foliage -US-Ton,24495,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-Ton,24495,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-Ton,24495,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2001 -US-Ton,24495,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,2001-2003 by John Battles -US-Ton,24732,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,4200 -US-Ton,24732,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Foliage -US-Ton,24732,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-Ton,24732,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-Ton,24732,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2003 -US-Ton,24732,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,2001-2003 by John Battles -US-Ton,25002,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,4200 -US-Ton,25002,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Foliage -US-Ton,25002,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-Ton,25002,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-Ton,25002,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2002 -US-Ton,25002,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,2001-2003 by John Battles -US-Ton,24630,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,4243 -US-Ton,24630,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Total -US-Ton,24630,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-Ton,24630,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-Ton,24630,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2002 -US-Ton,24630,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,2001-2003 by John Battles -US-Ton,24733,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,4243 -US-Ton,24733,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Total -US-Ton,24733,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-Ton,24733,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-Ton,24733,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2003 -US-Ton,24733,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,2001-2003 by John Battles -US-Ton,25134,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,4243 -US-Ton,25134,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Total -US-Ton,25134,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-Ton,25134,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-Ton,25134,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2001 -US-Ton,25134,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,2001-2003 by John Battles -US-Ton,23837,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,43 -US-Ton,23837,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Wood -US-Ton,23837,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-Ton,23837,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-Ton,23837,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2003 -US-Ton,23837,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,2001-2003 by John Battles -US-Ton,24243,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,43 -US-Ton,24243,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Wood -US-Ton,24243,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-Ton,24243,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-Ton,24243,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2002 -US-Ton,24243,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,2001-2003 by John Battles -US-Ton,24885,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,43 -US-Ton,24885,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Wood -US-Ton,24885,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-Ton,24885,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-Ton,24885,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,2001 -US-Ton,24885,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,2001-2003 by John Battles -US-Ton,24599,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT,650 -US-Ton,24599,GRP_AG_LIT_PROD,AG_LIT_PROD_UNIT,gC m-2 -US-Ton,24599,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_START,2007 -US-Ton,786,GRP_CLIM_AVG,MAT,15.8 -US-Ton,786,GRP_CLIM_AVG,MAP,559 -US-Ton,786,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Csa -US-Ton,27000438,GRP_COUNTRY,COUNTRY,USA -US-Ton,4335,GRP_DM_GRAZE,DM_GRAZE,Other -US-Ton,4335,GRP_DM_GRAZE,DM_COMMENT,grazing intensity: ~100 cows per 900 acres. -US-Ton,15607,GRP_DOI,DOI,10.17190/AMF/1245971 -US-Ton,15607,GRP_DOI,DOI_CITATION,"Siyan Ma, Liukang Xu, Joseph Verfaillie, Dennis Baldocchi (2022), AmeriFlux BASE US-Ton Tonzi Ranch, Ver. 16-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1245971" -US-Ton,15607,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-Ton,94053,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Ton,94053,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Siyan Ma -US-Ton,94053,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Ton,94053,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,1 -US-Ton,94053,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0002-6145-196X -US-Ton,94053,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,syma@berkeley.edu -US-Ton,94053,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"University of California, Berkeley" -US-Ton,94053,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,2005 -US-Ton,94137,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Ton,94137,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Liukang Xu -US-Ton,94137,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Ton,94137,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,2 -US-Ton,94137,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0002-1910-8383 -US-Ton,94137,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,liukang.xu@licor.com -US-Ton,94137,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"University of California, Berkeley" -US-Ton,94137,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,200102 -US-Ton,94137,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_END,200403 -US-Ton,94115,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Ton,94115,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Joseph Verfaillie -US-Ton,94115,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Ton,94115,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,8 -US-Ton,94115,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0002-7009-8942 -US-Ton,94115,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,jverfail@berkeley.edu -US-Ton,94115,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"University of California, Berkeley" -US-Ton,94115,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,200809 -US-Ton,94050,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Ton,94050,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Dennis Baldocchi -US-Ton,94050,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Ton,94050,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,9 -US-Ton,94050,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0003-3496-4919 -US-Ton,94050,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,Baldocchi@berkeley.edu -US-Ton,94050,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"University of California, Berkeley" -US-Ton,94050,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,2001 -US-Ton,31829,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,"University of California, Berkeley" -US-Ton,31829,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-Ton,31828,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,DOE/TCP -US-Ton,31828,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-Ton,8463,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Grazing -US-Ton,91435,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Ton,91435,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-Ton,91435,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20010105 -US-Ton,91435,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Ton,91435,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,Two towers: one above canopy and one below canopy -US-Ton,91305,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Ton,91305,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-Ton,91305,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20010105 -US-Ton,91305,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Ton,91305,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,Two towers: one above canopy and one below canopy -US-Ton,23000438,GRP_HEADER,SITE_NAME,Tonzi Ranch -US-Ton,89141,GRP_HEIGHTC,HEIGHTC,4.449 -US-Ton,89141,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Ton,89141,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Ton,89141,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,21061 -US-Ton,89141,GRP_HEIGHTC,HEIGHTC_APPROACH,Morphological analysis of airborne LiDAR data determine individual tree heights -US-Ton,89141,GRP_HEIGHTC,HEIGHTC_DATE,20030824 -US-Ton,89141,GRP_HEIGHTC,HEIGHTC_DATE_UNC,0 -US-Ton,89141,GRP_HEIGHTC,HEIGHTC_COMMENT,Based on LiDAR data for an area of 1723m x 1732m centered on the tower. Claimed vertical accuracy from the data provider is 18 cm with 95% confidence. Trees make up about 40% of the surface the rest is grass. -US-Ton,89142,GRP_HEIGHTC,HEIGHTC,9.16 -US-Ton,89142,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ton,89142,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Ton,89142,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,21061 -US-Ton,89142,GRP_HEIGHTC,HEIGHTC_APPROACH,Morphological analysis of airborne LiDAR data determine individual tree heights -US-Ton,89142,GRP_HEIGHTC,HEIGHTC_DATE,20030824 -US-Ton,89142,GRP_HEIGHTC,HEIGHTC_DATE_UNC,0 -US-Ton,89142,GRP_HEIGHTC,HEIGHTC_COMMENT,Based on LiDAR data for an area of 1723m x 1732m centered on the tower. Claimed vertical accuracy from the data provider is 18 cm with 95% confidence. Trees make up about 40% of the surface the rest is grass. -US-Ton,89140,GRP_HEIGHTC,HEIGHTC,4.61 -US-Ton,89140,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Ton,89140,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Ton,89140,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,8022 -US-Ton,89140,GRP_HEIGHTC,HEIGHTC_APPROACH,Morphological analysis of airborne LiDAR data determine individual -US-Ton,89140,GRP_HEIGHTC,HEIGHTC_DATE,20090420 -US-Ton,89143,GRP_HEIGHTC,HEIGHTC,10.64 -US-Ton,89143,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Ton,89143,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Ton,89143,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,8022 -US-Ton,89143,GRP_HEIGHTC,HEIGHTC_APPROACH,Morphological analysis of airborne LiDAR data determine individual tree heights -US-Ton,89143,GRP_HEIGHTC,HEIGHTC_DATE,20090420 -US-Ton,89143,GRP_HEIGHTC,HEIGHTC_DATE_UNC,0 -US-Ton,89143,GRP_HEIGHTC,HEIGHTC_COMMENT,"Based on LiDAR data for an area of 1065m x 1065m centered on the tower The vertical accuracy was -0.01 ± 0.05 m, based on the comparison of 819 test points. Trees make up about 40% of the surface the rest is grass." -US-Ton,8615,GRP_IGBP,IGBP,WSA -US-Ton,19463,GRP_LAI,LAI_TYPE,LAI -US-Ton,19464,GRP_LAI,LAI_TYPE,LAI -US-Ton,19465,GRP_LAI,LAI_TYPE,LAI -US-Ton,19466,GRP_LAI,LAI_TYPE,LAI -US-Ton,19467,GRP_LAI,LAI_TYPE,LAI -US-Ton,19468,GRP_LAI,LAI_TYPE,LAI -US-Ton,19469,GRP_LAI,LAI_TYPE,LAI -US-Ton,19470,GRP_LAI,LAI_TYPE,LAI -US-Ton,19471,GRP_LAI,LAI_TYPE,LAI -US-Ton,19472,GRP_LAI,LAI_TYPE,LAI -US-Ton,19473,GRP_LAI,LAI_TYPE,LAI -US-Ton,19474,GRP_LAI,LAI_TYPE,LAI -US-Ton,19475,GRP_LAI,LAI_TYPE,LAI -US-Ton,19476,GRP_LAI,LAI_TYPE,LAI -US-Ton,19477,GRP_LAI,LAI_TYPE,LAI -US-Ton,19478,GRP_LAI,LAI_TYPE,LAI -US-Ton,19479,GRP_LAI,LAI_TYPE,LAI -US-Ton,19480,GRP_LAI,LAI_TYPE,LAI -US-Ton,19481,GRP_LAI,LAI_TYPE,LAI -US-Ton,19482,GRP_LAI,LAI_TYPE,LAI -US-Ton,19483,GRP_LAI,LAI_TYPE,LAI -US-Ton,19484,GRP_LAI,LAI_TYPE,LAI -US-Ton,19485,GRP_LAI,LAI_TYPE,LAI -US-Ton,19486,GRP_LAI,LAI_TYPE,LAI -US-Ton,19487,GRP_LAI,LAI_TYPE,LAI -US-Ton,19488,GRP_LAI,LAI_TYPE,LAI -US-Ton,19489,GRP_LAI,LAI_TYPE,LAI -US-Ton,19490,GRP_LAI,LAI_TYPE,LAI -US-Ton,19491,GRP_LAI,LAI_TYPE,LAI -US-Ton,19492,GRP_LAI,LAI_TYPE,LAI -US-Ton,19493,GRP_LAI,LAI_TYPE,LAI -US-Ton,19494,GRP_LAI,LAI_TYPE,LAI -US-Ton,19495,GRP_LAI,LAI_TYPE,LAI -US-Ton,19496,GRP_LAI,LAI_TYPE,LAI -US-Ton,19497,GRP_LAI,LAI_TYPE,LAI -US-Ton,19498,GRP_LAI,LAI_TYPE,LAI -US-Ton,19499,GRP_LAI,LAI_TYPE,LAI -US-Ton,19500,GRP_LAI,LAI_TYPE,LAI -US-Ton,19501,GRP_LAI,LAI_TYPE,LAI -US-Ton,19502,GRP_LAI,LAI_TYPE,LAI -US-Ton,19503,GRP_LAI,LAI_TYPE,LAI -US-Ton,19504,GRP_LAI,LAI_TYPE,LAI -US-Ton,19505,GRP_LAI,LAI_TYPE,LAI -US-Ton,19506,GRP_LAI,LAI_TYPE,LAI -US-Ton,19507,GRP_LAI,LAI_TYPE,LAI -US-Ton,19508,GRP_LAI,LAI_TYPE,LAI -US-Ton,19509,GRP_LAI,LAI_TYPE,LAI -US-Ton,19510,GRP_LAI,LAI_TYPE,LAI -US-Ton,19511,GRP_LAI,LAI_TYPE,LAI -US-Ton,19512,GRP_LAI,LAI_TYPE,LAI -US-Ton,19513,GRP_LAI,LAI_TYPE,LAI -US-Ton,19514,GRP_LAI,LAI_TYPE,LAI -US-Ton,19515,GRP_LAI,LAI_TYPE,LAI -US-Ton,19516,GRP_LAI,LAI_TYPE,LAI -US-Ton,19517,GRP_LAI,LAI_TYPE,LAI -US-Ton,19518,GRP_LAI,LAI_TYPE,LAI -US-Ton,19519,GRP_LAI,LAI_TYPE,LAI -US-Ton,19520,GRP_LAI,LAI_TYPE,LAI -US-Ton,19521,GRP_LAI,LAI_TYPE,LAI -US-Ton,19522,GRP_LAI,LAI_TYPE,LAI -US-Ton,19523,GRP_LAI,LAI_TYPE,LAI -US-Ton,19524,GRP_LAI,LAI_TYPE,LAI -US-Ton,19525,GRP_LAI,LAI_TYPE,LAI -US-Ton,19526,GRP_LAI,LAI_TYPE,LAI -US-Ton,19527,GRP_LAI,LAI_TYPE,LAI -US-Ton,19528,GRP_LAI,LAI_TYPE,LAI -US-Ton,19529,GRP_LAI,LAI_TYPE,LAI -US-Ton,19530,GRP_LAI,LAI_TYPE,LAI -US-Ton,19531,GRP_LAI,LAI_TYPE,LAI -US-Ton,19532,GRP_LAI,LAI_TYPE,LAI -US-Ton,19533,GRP_LAI,LAI_TYPE,LAI -US-Ton,19534,GRP_LAI,LAI_TYPE,LAI -US-Ton,19535,GRP_LAI,LAI_TYPE,LAI -US-Ton,19536,GRP_LAI,LAI_TYPE,LAI -US-Ton,19537,GRP_LAI,LAI_TYPE,LAI -US-Ton,19538,GRP_LAI,LAI_TYPE,LAI -US-Ton,19539,GRP_LAI,LAI_TYPE,LAI -US-Ton,19540,GRP_LAI,LAI_TYPE,LAI -US-Ton,19541,GRP_LAI,LAI_TYPE,LAI -US-Ton,19542,GRP_LAI,LAI_TYPE,LAI -US-Ton,19543,GRP_LAI,LAI_TYPE,LAI -US-Ton,19544,GRP_LAI,LAI_TYPE,LAI -US-Ton,19545,GRP_LAI,LAI_TYPE,LAI -US-Ton,19546,GRP_LAI,LAI_TYPE,LAI -US-Ton,19547,GRP_LAI,LAI_TYPE,LAI -US-Ton,19548,GRP_LAI,LAI_TYPE,LAI -US-Ton,19549,GRP_LAI,LAI_TYPE,LAI -US-Ton,19550,GRP_LAI,LAI_TYPE,LAI -US-Ton,19551,GRP_LAI,LAI_TYPE,LAI -US-Ton,19552,GRP_LAI,LAI_TYPE,LAI -US-Ton,19553,GRP_LAI,LAI_TYPE,LAI -US-Ton,19554,GRP_LAI,LAI_TYPE,LAI -US-Ton,19555,GRP_LAI,LAI_TYPE,LAI -US-Ton,19556,GRP_LAI,LAI_TYPE,LAI -US-Ton,19557,GRP_LAI,LAI_TYPE,LAI -US-Ton,19558,GRP_LAI,LAI_TYPE,LAI -US-Ton,19559,GRP_LAI,LAI_TYPE,LAI -US-Ton,19560,GRP_LAI,LAI_TYPE,LAI -US-Ton,19561,GRP_LAI,LAI_TYPE,LAI -US-Ton,19562,GRP_LAI,LAI_TYPE,LAI -US-Ton,19563,GRP_LAI,LAI_TYPE,LAI -US-Ton,19564,GRP_LAI,LAI_TYPE,LAI -US-Ton,19565,GRP_LAI,LAI_TYPE,LAI -US-Ton,19566,GRP_LAI,LAI_TYPE,LAI -US-Ton,19567,GRP_LAI,LAI_TYPE,LAI -US-Ton,19568,GRP_LAI,LAI_TYPE,LAI -US-Ton,19569,GRP_LAI,LAI_TYPE,LAI -US-Ton,19570,GRP_LAI,LAI_TYPE,LAI -US-Ton,19571,GRP_LAI,LAI_TYPE,LAI -US-Ton,19572,GRP_LAI,LAI_TYPE,LAI -US-Ton,19573,GRP_LAI,LAI_TYPE,LAI -US-Ton,19574,GRP_LAI,LAI_TYPE,LAI -US-Ton,19575,GRP_LAI,LAI_TYPE,LAI -US-Ton,19576,GRP_LAI,LAI_TYPE,LAI -US-Ton,19577,GRP_LAI,LAI_TYPE,LAI -US-Ton,19578,GRP_LAI,LAI_TYPE,LAI -US-Ton,19579,GRP_LAI,LAI_TYPE,LAI -US-Ton,19580,GRP_LAI,LAI_TYPE,LAI -US-Ton,19581,GRP_LAI,LAI_TYPE,LAI -US-Ton,19582,GRP_LAI,LAI_TYPE,LAI -US-Ton,19583,GRP_LAI,LAI_TYPE,LAI -US-Ton,19584,GRP_LAI,LAI_TYPE,LAI -US-Ton,19585,GRP_LAI,LAI_TYPE,LAI -US-Ton,19586,GRP_LAI,LAI_TYPE,LAI -US-Ton,19587,GRP_LAI,LAI_TYPE,LAI -US-Ton,19588,GRP_LAI,LAI_TYPE,LAI -US-Ton,19463,GRP_LAI,LAI_METHOD,Direct -US-Ton,19464,GRP_LAI,LAI_METHOD,Direct -US-Ton,19465,GRP_LAI,LAI_METHOD,Direct -US-Ton,19466,GRP_LAI,LAI_METHOD,Direct -US-Ton,19467,GRP_LAI,LAI_METHOD,Direct -US-Ton,19468,GRP_LAI,LAI_METHOD,Direct -US-Ton,19469,GRP_LAI,LAI_METHOD,Direct -US-Ton,19470,GRP_LAI,LAI_METHOD,Direct -US-Ton,19471,GRP_LAI,LAI_METHOD,Direct -US-Ton,19472,GRP_LAI,LAI_METHOD,Direct -US-Ton,19473,GRP_LAI,LAI_METHOD,Direct -US-Ton,19474,GRP_LAI,LAI_METHOD,Direct -US-Ton,19475,GRP_LAI,LAI_METHOD,Direct -US-Ton,19476,GRP_LAI,LAI_METHOD,Direct -US-Ton,19477,GRP_LAI,LAI_METHOD,Direct -US-Ton,19478,GRP_LAI,LAI_METHOD,Direct -US-Ton,19479,GRP_LAI,LAI_METHOD,Direct -US-Ton,19480,GRP_LAI,LAI_METHOD,Direct -US-Ton,19481,GRP_LAI,LAI_METHOD,Direct -US-Ton,19482,GRP_LAI,LAI_METHOD,Direct -US-Ton,19483,GRP_LAI,LAI_METHOD,Direct -US-Ton,19484,GRP_LAI,LAI_METHOD,Direct -US-Ton,19485,GRP_LAI,LAI_METHOD,Direct -US-Ton,19486,GRP_LAI,LAI_METHOD,Direct -US-Ton,19487,GRP_LAI,LAI_METHOD,Direct -US-Ton,19488,GRP_LAI,LAI_METHOD,Direct -US-Ton,19489,GRP_LAI,LAI_METHOD,Direct -US-Ton,19490,GRP_LAI,LAI_METHOD,Direct -US-Ton,19491,GRP_LAI,LAI_METHOD,Direct -US-Ton,19492,GRP_LAI,LAI_METHOD,Direct -US-Ton,19493,GRP_LAI,LAI_METHOD,Direct -US-Ton,19494,GRP_LAI,LAI_METHOD,Direct -US-Ton,19495,GRP_LAI,LAI_METHOD,Direct -US-Ton,19496,GRP_LAI,LAI_METHOD,Direct -US-Ton,19497,GRP_LAI,LAI_METHOD,Direct -US-Ton,19498,GRP_LAI,LAI_METHOD,Direct -US-Ton,19499,GRP_LAI,LAI_METHOD,Direct -US-Ton,19500,GRP_LAI,LAI_METHOD,Direct -US-Ton,19501,GRP_LAI,LAI_METHOD,Direct -US-Ton,19502,GRP_LAI,LAI_METHOD,Direct -US-Ton,19503,GRP_LAI,LAI_METHOD,Direct -US-Ton,19504,GRP_LAI,LAI_METHOD,Direct -US-Ton,19505,GRP_LAI,LAI_METHOD,Direct -US-Ton,19506,GRP_LAI,LAI_METHOD,Direct -US-Ton,19507,GRP_LAI,LAI_METHOD,Direct -US-Ton,19508,GRP_LAI,LAI_METHOD,Direct -US-Ton,19509,GRP_LAI,LAI_METHOD,Direct -US-Ton,19510,GRP_LAI,LAI_METHOD,Direct -US-Ton,19511,GRP_LAI,LAI_METHOD,Direct -US-Ton,19512,GRP_LAI,LAI_METHOD,Direct -US-Ton,19513,GRP_LAI,LAI_METHOD,Direct -US-Ton,19514,GRP_LAI,LAI_METHOD,Direct -US-Ton,19515,GRP_LAI,LAI_METHOD,Direct -US-Ton,19516,GRP_LAI,LAI_METHOD,Direct -US-Ton,19517,GRP_LAI,LAI_METHOD,Direct -US-Ton,19518,GRP_LAI,LAI_METHOD,Direct -US-Ton,19519,GRP_LAI,LAI_METHOD,Direct -US-Ton,19520,GRP_LAI,LAI_METHOD,Direct -US-Ton,19521,GRP_LAI,LAI_METHOD,Direct -US-Ton,19522,GRP_LAI,LAI_METHOD,Direct -US-Ton,19523,GRP_LAI,LAI_METHOD,Direct -US-Ton,19524,GRP_LAI,LAI_METHOD,Direct -US-Ton,19525,GRP_LAI,LAI_METHOD,Direct -US-Ton,19526,GRP_LAI,LAI_METHOD,Direct -US-Ton,19527,GRP_LAI,LAI_METHOD,Direct -US-Ton,19528,GRP_LAI,LAI_METHOD,Direct -US-Ton,19529,GRP_LAI,LAI_METHOD,Direct -US-Ton,19530,GRP_LAI,LAI_METHOD,Direct -US-Ton,19531,GRP_LAI,LAI_METHOD,Direct -US-Ton,19532,GRP_LAI,LAI_METHOD,Direct -US-Ton,19533,GRP_LAI,LAI_METHOD,Direct -US-Ton,19534,GRP_LAI,LAI_METHOD,Direct -US-Ton,19535,GRP_LAI,LAI_METHOD,Direct -US-Ton,19536,GRP_LAI,LAI_METHOD,Direct -US-Ton,19537,GRP_LAI,LAI_METHOD,Direct -US-Ton,19538,GRP_LAI,LAI_METHOD,Direct -US-Ton,19539,GRP_LAI,LAI_METHOD,Direct -US-Ton,19540,GRP_LAI,LAI_METHOD,Direct -US-Ton,19541,GRP_LAI,LAI_METHOD,Direct -US-Ton,19542,GRP_LAI,LAI_METHOD,Direct -US-Ton,19543,GRP_LAI,LAI_METHOD,Direct -US-Ton,19544,GRP_LAI,LAI_METHOD,Direct -US-Ton,19545,GRP_LAI,LAI_METHOD,Direct -US-Ton,19546,GRP_LAI,LAI_METHOD,Direct -US-Ton,19547,GRP_LAI,LAI_METHOD,Direct -US-Ton,19548,GRP_LAI,LAI_METHOD,Direct -US-Ton,19549,GRP_LAI,LAI_METHOD,Direct -US-Ton,19550,GRP_LAI,LAI_METHOD,Direct -US-Ton,19551,GRP_LAI,LAI_METHOD,Direct -US-Ton,19552,GRP_LAI,LAI_METHOD,Direct -US-Ton,19553,GRP_LAI,LAI_METHOD,Direct -US-Ton,19554,GRP_LAI,LAI_METHOD,Direct -US-Ton,19555,GRP_LAI,LAI_METHOD,Direct -US-Ton,19556,GRP_LAI,LAI_METHOD,Direct -US-Ton,19557,GRP_LAI,LAI_METHOD,Direct -US-Ton,19558,GRP_LAI,LAI_METHOD,Direct -US-Ton,19559,GRP_LAI,LAI_METHOD,Direct -US-Ton,19560,GRP_LAI,LAI_METHOD,Direct -US-Ton,19561,GRP_LAI,LAI_METHOD,Direct -US-Ton,19562,GRP_LAI,LAI_METHOD,Direct -US-Ton,19563,GRP_LAI,LAI_METHOD,Direct -US-Ton,19564,GRP_LAI,LAI_METHOD,Direct -US-Ton,19565,GRP_LAI,LAI_METHOD,Direct -US-Ton,19566,GRP_LAI,LAI_METHOD,Direct -US-Ton,19567,GRP_LAI,LAI_METHOD,Direct -US-Ton,19568,GRP_LAI,LAI_METHOD,Direct -US-Ton,19569,GRP_LAI,LAI_METHOD,Direct -US-Ton,19570,GRP_LAI,LAI_METHOD,Direct -US-Ton,19571,GRP_LAI,LAI_METHOD,Direct -US-Ton,19572,GRP_LAI,LAI_METHOD,Direct -US-Ton,19573,GRP_LAI,LAI_METHOD,Direct -US-Ton,19574,GRP_LAI,LAI_METHOD,Direct -US-Ton,19575,GRP_LAI,LAI_METHOD,Direct -US-Ton,19576,GRP_LAI,LAI_METHOD,Direct -US-Ton,19577,GRP_LAI,LAI_METHOD,Direct -US-Ton,19578,GRP_LAI,LAI_METHOD,Direct -US-Ton,19579,GRP_LAI,LAI_METHOD,Direct -US-Ton,19580,GRP_LAI,LAI_METHOD,Direct -US-Ton,19581,GRP_LAI,LAI_METHOD,Direct -US-Ton,19582,GRP_LAI,LAI_METHOD,Direct -US-Ton,19583,GRP_LAI,LAI_METHOD,Direct -US-Ton,19584,GRP_LAI,LAI_METHOD,Direct -US-Ton,19585,GRP_LAI,LAI_METHOD,Direct -US-Ton,19586,GRP_LAI,LAI_METHOD,Direct -US-Ton,19587,GRP_LAI,LAI_METHOD,Direct -US-Ton,19588,GRP_LAI,LAI_METHOD,Direct -US-Ton,19463,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 replicants; measured throught Li-cor area meter -US-Ton,19464,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 replicants; measured throught Li-cor area meter -US-Ton,19465,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 replicants; measured throught Li-cor area meter -US-Ton,19466,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 replicants; measured throught Li-cor area meter -US-Ton,19467,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 replicants; measured throught Li-cor area meter -US-Ton,19468,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 replicants; measured throught Li-cor area meter -US-Ton,19469,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 replicants; measured throught Li-cor area meter -US-Ton,19470,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 replicants; measured throught Li-cor area meter -US-Ton,19471,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 replicants; measured throught Li-cor area meter -US-Ton,19472,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 replicants; measured throught Li-cor area meter -US-Ton,19473,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 replicants; measured throught Li-cor area meter -US-Ton,19474,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 replicants; measured throught Li-cor area meter -US-Ton,19475,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 replicants; measured throught Li-cor area meter -US-Ton,19476,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 replicants; measured throught Li-cor area meter -US-Ton,19477,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 replicants; measured throught Li-cor area meter -US-Ton,19478,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 replicants; measured throught Li-cor area meter -US-Ton,19479,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 replicants; measured throught Li-cor area meter -US-Ton,19480,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 replicants; measured throught Li-cor area meter -US-Ton,19481,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 replicants; measured throught Li-cor area meter -US-Ton,19482,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 replicants; measured throught Li-cor area meter -US-Ton,19483,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 replicants; measured throught Li-cor area meter -US-Ton,19484,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 replicants; measured throught Li-cor area meter -US-Ton,19485,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 replicants; measured throught Li-cor area meter -US-Ton,19486,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 replicants; measured throught Li-cor area meter -US-Ton,19487,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 replicants; measured throught Li-cor area meter -US-Ton,19488,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 replicants; measured throught Li-cor area meter -US-Ton,19489,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 replicants; measured throught Li-cor area meter -US-Ton,19490,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 replicants; measured throught Li-cor area meter -US-Ton,19491,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 replicants; measured throught Li-cor area meter -US-Ton,19492,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 replicants; measured throught Li-cor area meter -US-Ton,19493,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 replicants; measured throught Li-cor area meter -US-Ton,19494,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 replicants; measured throught Li-cor area meter -US-Ton,19495,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 replicants; measured throught Li-cor area meter -US-Ton,19496,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 replicants; measured throught Li-cor area meter -US-Ton,19497,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 replicants; measured throught Li-cor area meter -US-Ton,19498,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 replicants; measured throught Li-cor area meter -US-Ton,19499,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 replicants; measured throught Li-cor area meter -US-Ton,19500,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 replicants; measured throught Li-cor area meter -US-Ton,19501,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 replicants; measured throught Li-cor area meter -US-Ton,19502,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 replicants; measured throught Li-cor area meter -US-Ton,19503,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 replicants; measured throught Li-cor area meter -US-Ton,19504,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 replicants; measured throught Li-cor area meter -US-Ton,19505,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 replicants; measured throught Li-cor area meter -US-Ton,19506,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 replicants; measured throught Li-cor area meter -US-Ton,19507,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 replicants; measured throught Li-cor area meter -US-Ton,19508,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 replicants; measured throught Li-cor area meter -US-Ton,19509,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 replicants; measured throught Li-cor area meter -US-Ton,19510,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 replicants; measured throught Li-cor area meter -US-Ton,19511,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 replicants; measured throught Li-cor area meter -US-Ton,19512,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 replicants; measured throught Li-cor area meter -US-Ton,19513,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 replicants; measured throught Li-cor area meter -US-Ton,19514,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 replicants; measured throught Li-cor area meter -US-Ton,19515,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 replicants; measured throught Li-cor area meter -US-Ton,19516,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 replicants; measured throught Li-cor area meter -US-Ton,19517,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 replicants; measured throught Li-cor area meter -US-Ton,19518,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 replicants; measured throught Li-cor area meter -US-Ton,19519,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 replicants; measured throught Li-cor area meter -US-Ton,19520,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 replicants; measured throught Li-cor area meter -US-Ton,19521,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 replicants; measured throught Li-cor area meter -US-Ton,19522,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 replicants; measured throught Li-cor area meter -US-Ton,19523,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 replicants; measured throught Li-cor area meter -US-Ton,19524,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 replicants; measured throught Li-cor area meter -US-Ton,19525,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 replicants; measured throught Li-cor area meter -US-Ton,19526,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 replicants; measured throught Li-cor area meter -US-Ton,19527,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 replicants; measured throught Li-cor area meter -US-Ton,19528,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 replicants; measured throught Li-cor area meter -US-Ton,19529,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 replicants; measured throught Li-cor area meter -US-Ton,19530,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 replicants; measured throught Li-cor area meter -US-Ton,19531,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 replicants; measured throught Li-cor area meter -US-Ton,19532,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 replicants; measured throught Li-cor area meter -US-Ton,19533,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 replicants; measured throught Li-cor area meter -US-Ton,19534,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 replicants; measured throught Li-cor area meter -US-Ton,19535,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 replicants; measured throught Li-cor area meter -US-Ton,19536,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 replicants; measured throught Li-cor area meter -US-Ton,19537,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 replicants; measured throught Li-cor area meter -US-Ton,19538,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 replicants; measured throught Li-cor area meter -US-Ton,19539,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 replicants; measured throught Li-cor area meter -US-Ton,19540,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 replicants; measured throught Li-cor area meter -US-Ton,19541,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 replicants; measured throught Li-cor area meter -US-Ton,19542,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 replicants; measured throught Li-cor area meter -US-Ton,19543,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 replicants; measured throught Li-cor area meter -US-Ton,19544,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 replicants; measured throught Li-cor area meter -US-Ton,19545,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 replicants; measured throught Li-cor area meter -US-Ton,19546,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 replicants; measured throught Li-cor area meter -US-Ton,19547,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 replicants; measured throught Li-cor area meter -US-Ton,19548,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 replicants; measured throught Li-cor area meter -US-Ton,19549,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 replicants; measured throught Li-cor area meter -US-Ton,19550,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 replicants; measured throught Li-cor area meter -US-Ton,19551,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 replicants; measured throught Li-cor area meter -US-Ton,19552,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 replicants; measured throught Li-cor area meter -US-Ton,19553,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 replicants; measured throught Li-cor area meter -US-Ton,19554,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 replicants; measured throught Li-cor area meter -US-Ton,19555,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 replicants; measured throught Li-cor area meter -US-Ton,19556,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 replicants; measured throught Li-cor area meter -US-Ton,19557,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 replicants; measured throught Li-cor area meter -US-Ton,19558,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 replicants; measured throught Li-cor area meter -US-Ton,19559,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 replicants; measured throught Li-cor area meter -US-Ton,19560,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 replicants; measured throught Li-cor area meter -US-Ton,19561,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 replicants; measured throught Li-cor area meter -US-Ton,19562,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 replicants; measured throught Li-cor area meter -US-Ton,19563,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 replicants; measured throught Li-cor area meter -US-Ton,19564,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 replicants; measured throught Li-cor area meter -US-Ton,19565,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 replicants; measured throught Li-cor area meter -US-Ton,19566,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 replicants; measured throught Li-cor area meter -US-Ton,19567,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 replicants; measured throught Li-cor area meter -US-Ton,19568,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 replicants; measured throught Li-cor area meter -US-Ton,19569,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 replicants; measured throught Li-cor area meter -US-Ton,19570,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 replicants; measured throught Li-cor area meter -US-Ton,19571,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 replicants; measured throught Li-cor area meter -US-Ton,19572,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 replicants; measured throught Li-cor area meter -US-Ton,19573,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 replicants; measured throught Li-cor area meter -US-Ton,19574,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 replicants; measured throught Li-cor area meter -US-Ton,19575,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 replicants; measured throught Li-cor area meter -US-Ton,19576,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 replicants; measured throught Li-cor area meter -US-Ton,19577,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 replicants; measured throught Li-cor area meter -US-Ton,19578,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 replicants; measured throught Li-cor area meter -US-Ton,19579,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 replicants; measured throught Li-cor area meter -US-Ton,19580,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 replicants; measured throught Li-cor area meter -US-Ton,19581,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 replicants; measured throught Li-cor area meter -US-Ton,19582,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 replicants; measured throught Li-cor area meter -US-Ton,19583,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 replicants; measured throught Li-cor area meter -US-Ton,19584,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 replicants; measured throught Li-cor area meter -US-Ton,19585,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 replicants; measured throught Li-cor area meter -US-Ton,19586,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 replicants; measured throught Li-cor area meter -US-Ton,19587,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 replicants; measured throught Li-cor area meter -US-Ton,19588,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 replicants; measured throught Li-cor area meter -US-Ton,19463,GRP_LAI,LAI_DATE,20010106 -US-Ton,19464,GRP_LAI,LAI_DATE,20010223 -US-Ton,19465,GRP_LAI,LAI_DATE,20010308 -US-Ton,19466,GRP_LAI,LAI_DATE,20010322 -US-Ton,19467,GRP_LAI,LAI_DATE,20010408 -US-Ton,19468,GRP_LAI,LAI_DATE,20010418 -US-Ton,19469,GRP_LAI,LAI_DATE,20010503 -US-Ton,19470,GRP_LAI,LAI_DATE,20010513 -US-Ton,19471,GRP_LAI,LAI_DATE,20011219 -US-Ton,19472,GRP_LAI,LAI_DATE,20020208 -US-Ton,19473,GRP_LAI,LAI_DATE,20020320 -US-Ton,19474,GRP_LAI,LAI_DATE,20020404 -US-Ton,19475,GRP_LAI,LAI_DATE,20020418 -US-Ton,19476,GRP_LAI,LAI_DATE,20020502 -US-Ton,19477,GRP_LAI,LAI_DATE,20020516 -US-Ton,19478,GRP_LAI,LAI_DATE,20020523 -US-Ton,19479,GRP_LAI,LAI_DATE,20021114 -US-Ton,19480,GRP_LAI,LAI_DATE,20021223 -US-Ton,19481,GRP_LAI,LAI_DATE,20030129 -US-Ton,19482,GRP_LAI,LAI_DATE,20030221 -US-Ton,19483,GRP_LAI,LAI_DATE,20030317 -US-Ton,19484,GRP_LAI,LAI_DATE,20030405 -US-Ton,19485,GRP_LAI,LAI_DATE,20030416 -US-Ton,19486,GRP_LAI,LAI_DATE,20030430 -US-Ton,19487,GRP_LAI,LAI_DATE,20030521 -US-Ton,19488,GRP_LAI,LAI_DATE,20030613 -US-Ton,19489,GRP_LAI,LAI_DATE,20031231 -US-Ton,19490,GRP_LAI,LAI_DATE,20040130 -US-Ton,19491,GRP_LAI,LAI_DATE,20040305 -US-Ton,19492,GRP_LAI,LAI_DATE,20040325 -US-Ton,19493,GRP_LAI,LAI_DATE,20040409 -US-Ton,19494,GRP_LAI,LAI_DATE,20040423 -US-Ton,19495,GRP_LAI,LAI_DATE,20040506 -US-Ton,19496,GRP_LAI,LAI_DATE,20041120 -US-Ton,19555,GRP_LAI,LAI_DATE,20041226 -US-Ton,19556,GRP_LAI,LAI_DATE,20050117 -US-Ton,19557,GRP_LAI,LAI_DATE,20050127 -US-Ton,19558,GRP_LAI,LAI_DATE,20050226 -US-Ton,19559,GRP_LAI,LAI_DATE,20050324 -US-Ton,19560,GRP_LAI,LAI_DATE,20050424 -US-Ton,19561,GRP_LAI,LAI_DATE,20050517 -US-Ton,19562,GRP_LAI,LAI_DATE,20050601 -US-Ton,19563,GRP_LAI,LAI_DATE,20050610 -US-Ton,19564,GRP_LAI,LAI_DATE,20050623 -US-Ton,19565,GRP_LAI,LAI_DATE,20051229 -US-Ton,19566,GRP_LAI,LAI_DATE,20060110 -US-Ton,19567,GRP_LAI,LAI_DATE,20060124 -US-Ton,19568,GRP_LAI,LAI_DATE,20060209 -US-Ton,19569,GRP_LAI,LAI_DATE,20060223 -US-Ton,19570,GRP_LAI,LAI_DATE,20060308 -US-Ton,19571,GRP_LAI,LAI_DATE,20060330 -US-Ton,19497,GRP_LAI,LAI_DATE,20060418 -US-Ton,19498,GRP_LAI,LAI_DATE,20060504 -US-Ton,19499,GRP_LAI,LAI_DATE,20060512 -US-Ton,19500,GRP_LAI,LAI_DATE,20060518 -US-Ton,19501,GRP_LAI,LAI_DATE,20060528 -US-Ton,19502,GRP_LAI,LAI_DATE,20061206 -US-Ton,19503,GRP_LAI,LAI_DATE,20070110 -US-Ton,19504,GRP_LAI,LAI_DATE,20070204 -US-Ton,19505,GRP_LAI,LAI_DATE,20070302 -US-Ton,19506,GRP_LAI,LAI_DATE,20070314 -US-Ton,19507,GRP_LAI,LAI_DATE,20070328 -US-Ton,19508,GRP_LAI,LAI_DATE,20070405 -US-Ton,19509,GRP_LAI,LAI_DATE,20070413 -US-Ton,19510,GRP_LAI,LAI_DATE,20070501 -US-Ton,19511,GRP_LAI,LAI_DATE,20070510 -US-Ton,19512,GRP_LAI,LAI_DATE,20070525 -US-Ton,19513,GRP_LAI,LAI_DATE,20071129 -US-Ton,19538,GRP_LAI,LAI_DATE,20071227 -US-Ton,19539,GRP_LAI,LAI_DATE,20080130 -US-Ton,19540,GRP_LAI,LAI_DATE,20080306 -US-Ton,19541,GRP_LAI,LAI_DATE,20080405 -US-Ton,19542,GRP_LAI,LAI_DATE,20080420 -US-Ton,19543,GRP_LAI,LAI_DATE,20080506 -US-Ton,19544,GRP_LAI,LAI_DATE,20080513 -US-Ton,19545,GRP_LAI,LAI_DATE,20081211 -US-Ton,19546,GRP_LAI,LAI_DATE,20090108 -US-Ton,19547,GRP_LAI,LAI_DATE,20090119 -US-Ton,19548,GRP_LAI,LAI_DATE,20090210 -US-Ton,19549,GRP_LAI,LAI_DATE,20090228 -US-Ton,19550,GRP_LAI,LAI_DATE,20090312 -US-Ton,19551,GRP_LAI,LAI_DATE,20090327 -US-Ton,19552,GRP_LAI,LAI_DATE,20090417 -US-Ton,19553,GRP_LAI,LAI_DATE,20090507 -US-Ton,19554,GRP_LAI,LAI_DATE,20090527 -US-Ton,19514,GRP_LAI,LAI_DATE,20091105 -US-Ton,19515,GRP_LAI,LAI_DATE,20091222 -US-Ton,19516,GRP_LAI,LAI_DATE,20100210 -US-Ton,19517,GRP_LAI,LAI_DATE,20100305 -US-Ton,19518,GRP_LAI,LAI_DATE,20100321 -US-Ton,19519,GRP_LAI,LAI_DATE,20100413 -US-Ton,19520,GRP_LAI,LAI_DATE,20100430 -US-Ton,19521,GRP_LAI,LAI_DATE,20100513 -US-Ton,19522,GRP_LAI,LAI_DATE,20100528 -US-Ton,19523,GRP_LAI,LAI_DATE,20100610 -US-Ton,19524,GRP_LAI,LAI_DATE,20101112 -US-Ton,19525,GRP_LAI,LAI_DATE,20101202 -US-Ton,19526,GRP_LAI,LAI_DATE,20110105 -US-Ton,19527,GRP_LAI,LAI_DATE,20110222 -US-Ton,19528,GRP_LAI,LAI_DATE,20110330 -US-Ton,19529,GRP_LAI,LAI_DATE,20110422 -US-Ton,19530,GRP_LAI,LAI_DATE,20110510 -US-Ton,19572,GRP_LAI,LAI_DATE,20110527 -US-Ton,19573,GRP_LAI,LAI_DATE,20111026 -US-Ton,19574,GRP_LAI,LAI_DATE,20111201 -US-Ton,19575,GRP_LAI,LAI_DATE,20120104 -US-Ton,19576,GRP_LAI,LAI_DATE,20120201 -US-Ton,19577,GRP_LAI,LAI_DATE,20120302 -US-Ton,19578,GRP_LAI,LAI_DATE,20120405 -US-Ton,19579,GRP_LAI,LAI_DATE,20120504 -US-Ton,19580,GRP_LAI,LAI_DATE,20120518 -US-Ton,19581,GRP_LAI,LAI_DATE,20120530 -US-Ton,19582,GRP_LAI,LAI_DATE,20121107 -US-Ton,19583,GRP_LAI,LAI_DATE,20121211 -US-Ton,19584,GRP_LAI,LAI_DATE,20130116 -US-Ton,19585,GRP_LAI,LAI_DATE,20130227 -US-Ton,19586,GRP_LAI,LAI_DATE,20130327 -US-Ton,19587,GRP_LAI,LAI_DATE,20130410 -US-Ton,19588,GRP_LAI,LAI_DATE,20130424 -US-Ton,19531,GRP_LAI,LAI_DATE,20130508 -US-Ton,19532,GRP_LAI,LAI_DATE,20140210 -US-Ton,19533,GRP_LAI,LAI_DATE,20140304 -US-Ton,19534,GRP_LAI,LAI_DATE,20140327 -US-Ton,19535,GRP_LAI,LAI_DATE,20140422 -US-Ton,19536,GRP_LAI,LAI_DATE,20140508 -US-Ton,19537,GRP_LAI,LAI_DATE,20150522 -US-Ton,19537,GRP_LAI,LAI_COMMENT,estimated by Siyan Ma -US-Ton,19544,GRP_LAI,LAI_COMMENT,estimated by Siyan Ma -US-Ton,19564,GRP_LAI,LAI_COMMENT,estimated by Siyan Ma -US-Ton,19581,GRP_LAI,LAI_COMMENT,estimated by Siyan Ma -US-Ton,19463,GRP_LAI,LAI_COMMENT,operated by Liukang Xu -US-Ton,19464,GRP_LAI,LAI_COMMENT,operated by Liukang Xu -US-Ton,19465,GRP_LAI,LAI_COMMENT,operated by Liukang Xu -US-Ton,19466,GRP_LAI,LAI_COMMENT,operated by Liukang Xu -US-Ton,19467,GRP_LAI,LAI_COMMENT,operated by Liukang Xu -US-Ton,19468,GRP_LAI,LAI_COMMENT,operated by Liukang Xu -US-Ton,19469,GRP_LAI,LAI_COMMENT,operated by Liukang Xu -US-Ton,19470,GRP_LAI,LAI_COMMENT,operated by Liukang Xu -US-Ton,19471,GRP_LAI,LAI_COMMENT,operated by Liukang Xu -US-Ton,19472,GRP_LAI,LAI_COMMENT,operated by Liukang Xu -US-Ton,19473,GRP_LAI,LAI_COMMENT,operated by Liukang Xu -US-Ton,19474,GRP_LAI,LAI_COMMENT,operated by Liukang Xu -US-Ton,19475,GRP_LAI,LAI_COMMENT,operated by Liukang Xu -US-Ton,19476,GRP_LAI,LAI_COMMENT,operated by Liukang Xu -US-Ton,19477,GRP_LAI,LAI_COMMENT,operated by Liukang Xu -US-Ton,19478,GRP_LAI,LAI_COMMENT,operated by Liukang Xu -US-Ton,19479,GRP_LAI,LAI_COMMENT,operated by Liukang Xu -US-Ton,19480,GRP_LAI,LAI_COMMENT,operated by Liukang Xu -US-Ton,19481,GRP_LAI,LAI_COMMENT,operated by Liukang Xu -US-Ton,19482,GRP_LAI,LAI_COMMENT,operated by Liukang Xu -US-Ton,19483,GRP_LAI,LAI_COMMENT,operated by Liukang Xu -US-Ton,19484,GRP_LAI,LAI_COMMENT,operated by Liukang Xu -US-Ton,19485,GRP_LAI,LAI_COMMENT,operated by Liukang Xu -US-Ton,19486,GRP_LAI,LAI_COMMENT,operated by Liukang Xu -US-Ton,19487,GRP_LAI,LAI_COMMENT,operated by Liukang Xu -US-Ton,19488,GRP_LAI,LAI_COMMENT,operated by Liukang Xu -US-Ton,19489,GRP_LAI,LAI_COMMENT,operated by Liukang Xu -US-Ton,19490,GRP_LAI,LAI_COMMENT,operated by Liukang Xu -US-Ton,19491,GRP_LAI,LAI_COMMENT,operated by Liukang Xu -US-Ton,19492,GRP_LAI,LAI_COMMENT,operated by Liukang Xu -US-Ton,19493,GRP_LAI,LAI_COMMENT,operated by Liukang Xu -US-Ton,19494,GRP_LAI,LAI_COMMENT,operated by Siyan Ma -US-Ton,19495,GRP_LAI,LAI_COMMENT,operated by Siyan Ma -US-Ton,19496,GRP_LAI,LAI_COMMENT,operated by Siyan Ma -US-Ton,19497,GRP_LAI,LAI_COMMENT,operated by Siyan Ma -US-Ton,19498,GRP_LAI,LAI_COMMENT,operated by Siyan Ma -US-Ton,19499,GRP_LAI,LAI_COMMENT,operated by Siyan Ma -US-Ton,19500,GRP_LAI,LAI_COMMENT,operated by Siyan Ma -US-Ton,19501,GRP_LAI,LAI_COMMENT,operated by Siyan Ma -US-Ton,19502,GRP_LAI,LAI_COMMENT,operated by Siyan Ma -US-Ton,19503,GRP_LAI,LAI_COMMENT,operated by Siyan Ma -US-Ton,19504,GRP_LAI,LAI_COMMENT,operated by Siyan Ma -US-Ton,19505,GRP_LAI,LAI_COMMENT,operated by Siyan Ma -US-Ton,19506,GRP_LAI,LAI_COMMENT,operated by Siyan Ma -US-Ton,19507,GRP_LAI,LAI_COMMENT,operated by Siyan Ma -US-Ton,19508,GRP_LAI,LAI_COMMENT,operated by Siyan Ma -US-Ton,19509,GRP_LAI,LAI_COMMENT,operated by Siyan Ma -US-Ton,19510,GRP_LAI,LAI_COMMENT,operated by Siyan Ma -US-Ton,19511,GRP_LAI,LAI_COMMENT,operated by Siyan Ma -US-Ton,19512,GRP_LAI,LAI_COMMENT,operated by Siyan Ma -US-Ton,19513,GRP_LAI,LAI_COMMENT,operated by Siyan Ma -US-Ton,19514,GRP_LAI,LAI_COMMENT,operated by Siyan Ma -US-Ton,19515,GRP_LAI,LAI_COMMENT,operated by Siyan Ma -US-Ton,19516,GRP_LAI,LAI_COMMENT,operated by Siyan Ma -US-Ton,19517,GRP_LAI,LAI_COMMENT,operated by Siyan Ma -US-Ton,19518,GRP_LAI,LAI_COMMENT,operated by Siyan 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-US-Ton,19717,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_STATUS,Peak -US-Ton,19717,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,blue oak -US-Ton,19717,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20031103 -US-Ton,19717,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_UNC,3 -US-Ton,19717,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_APPROACH,direct -US-Ton,19718,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,Total leaf-off -US-Ton,19718,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_STATUS,Peak -US-Ton,19718,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,blue oak -US-Ton,19718,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20041017 -US-Ton,19718,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_UNC,3 -US-Ton,19718,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_APPROACH,direct -US-Ton,19719,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,Total leaf-off -US-Ton,19719,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_STATUS,Peak -US-Ton,19719,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,blue oak -US-Ton,19719,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20051103 -US-Ton,19719,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_UNC,7 -US-Ton,19719,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_APPROACH,direct -US-Ton,19720,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,Total leaf-off -US-Ton,19720,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_STATUS,Peak -US-Ton,19720,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,blue oak -US-Ton,19720,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20061027 -US-Ton,19720,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_UNC,7 -US-Ton,19720,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_APPROACH,direct -US-Ton,19721,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,Total leaf-off -US-Ton,19721,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_STATUS,Peak -US-Ton,19721,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,blue oak -US-Ton,19721,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20070920 -US-Ton,19721,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_UNC,7 -US-Ton,19721,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_APPROACH,direct -US-Ton,19722,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,Total leaf-off -US-Ton,19722,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_STATUS,Peak -US-Ton,19722,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,blue oak -US-Ton,19722,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20080911 -US-Ton,19722,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_UNC,7 -US-Ton,19722,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_APPROACH,direct -US-Ton,1700002862,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Baldocchi, D. D., Ma, S., Rambal, S., Misson, L., Ourcival, J., Limousin, J., Pereira, J., Papale, D. (2010) On The Differential Advantages Of Evergreenness And Deciduousness In Mediterranean Oak Woodlands: A Flux Perspective, Ecological Applications, 20(6), 1583-1597" -US-Ton,1700002862,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1890/08-2047.1 -US-Ton,1700002862,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ton,1700003561,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Baldocchi, D. D., Ryu, Y., Dechant, B., Eichelmann, E., Hemes, K., Ma, S., Sanchez, C. R., Shortt, R., Szutu, D., Valach, A., Verfaillie, J., Badgley, G., Zeng, Y., Berry, J. A. (2020) Outgoing Near‐Infrared Radiation From Vegetation Scales With Canopy Photosynthesis Across A Spectrum Of Function, Structure, Physiological Capacity, And Weather, Journal Of Geophysical Research: Biogeosciences, 125(7), 108204" -US-Ton,1700003561,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2019JG005534 -US-Ton,1700003561,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ton,1700000120,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Baldocchi, D. D., Xu, L. (2007) What Limits Evaporation From Mediterranean Oak Woodlands – The Supply Of Moisture In The Soil, Physiological Control By Plants Or The Demand By The Atmosphere?, Advances In Water Resources, 30(10), 2113-2122" -US-Ton,1700000120,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.ADVWATRES.2006.06.013 -US-Ton,1700000120,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ton,1700006345,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Baldocchi, D. D., Xu, L., Kiang, N. (2004) How Plant Functional-Type, Weather, Seasonal Drought, And Soil Physical Properties Alter Water And Energy Fluxes Of An Oak–Grass Savanna And An Annual Grassland, Agricultural And Forest Meteorology, 123(1-2), 13-39" -US-Ton,1700006345,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2003.11.006 -US-Ton,1700006345,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ton,1700002940,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Baldocchi, D., Chen, Q., Chen, X., Ma, S., Miller, G., Ryu, Y., Xiao, J., Wenk, R., Battles, J. (2010) The Dynamics Of Energy, Water, And Carbon Fluxes In A Blue Oak (Quercus Douglasii) Savanna In California, Ecosystem Function In Savannas, 132(3), 135-151" -US-Ton,1700002940,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1201/B10275-10 -US-Ton,1700002940,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Primary_Citation -US-Ton,1700002376,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Baldocchi, D., Ma, S., Verfaillie, J. (2021) On The Inter‐ And Intra‐Annual Variability Of Ecosystem Evapotranspiration And Water Use Efficiency Of An Oak Savanna And Annual Grassland Subjected To Booms And Busts In Rainfall, Global Change Biology, 27(2), 359-375" -US-Ton,1700002376,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/GCB.15414 -US-Ton,1700002376,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ton,1700003462,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Baldocchi, D., Penuelas, J. (2018) The Physics And Ecology Of Mining Carbon Dioxide From The Atmosphere By Ecosystems, Global Change Biology, 45(3), 9275–9287" -US-Ton,1700003462,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/GCB.14559 -US-Ton,1700003462,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ton,1700004116,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Barr, A., Richardson, A., Hollinger, D., Papale, D., Arain, M., Black, T., Bohrer, G., Dragoni, D., Fischer, M., Gu, L., Law, B., Margolis, H., McCaughey, J., Munger, J., Oechel, W., Schaeffer, K. (2013) Use Of Change-Point Detection For Friction–Velocity Threshold Evaluation In Eddy-Covariance Studies, Agricultural And Forest Meteorology, 171-172(7), 31-45" -US-Ton,1700004116,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2012.11.023 -US-Ton,1700004116,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ton,1700002151,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Braghiere, R. K., Quaife, T., Black, E., Ryu, Y., Chen, Q., De Kauwe, M. G., Baldocchi, D. (2020) Influence Of Sun Zenith Angle On Canopy Clumping And The Resulting Impacts On Photosynthesis, Agricultural And Forest Meteorology, 291(6), 108065" -US-Ton,1700002151,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2020.108065 -US-Ton,1700002151,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ton,1700003039,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chen, Q., Baldocchi, D., Gong, P., Dawson, T. (2008) Modeling Radiation And Photosynthesis Of A Heterogeneous Savanna Woodland Landscape With A Hierarchy Of Model Complexities, Agricultural And Forest Meteorology, 148(6-7), 1005-1020" -US-Ton,1700003039,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2008.01.020 -US-Ton,1700003039,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ton,1700004626,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chen, Q., Gong, P., Baldocchi, D., Tian, Y. Q. (2007) Estimating Basal Area And Stem Volume For Individual Trees From Lidar Data, Photogrammetric Engineering & Remote Sensing, 73(12), 1355-1365" -US-Ton,1700004626,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.14358/PERS.73.12.1355 -US-Ton,1700004626,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ton,1700006075,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chen, Q., Gong, P., Baldocchi, D., Xie, G. (2007) Filtering Airborne Laser Scanning Data With Morphological Methods, Photogrammetric Engineering & Remote Sensing, 73(2), 175-185" -US-Ton,1700006075,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.14358/PERS.73.2.175 -US-Ton,1700006075,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ton,1700003546,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chen, X., Rubin, Y., Ma, S., Baldocchi, D. (2008) Observations And Stochastic Modeling Of Soil Moisture Control On Evapotranspiration In A Californian Oak Savanna, Water Resources Research, 44(8), n/a-n/a" -US-Ton,1700003546,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2007WR006646 -US-Ton,1700003546,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ton,1700003837,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Baldocchi, D. D., Poindexter, C., Abraha, M., Desai, A. R., Bohrer, G., Arain, M. A., Griffis, T., Blanken, P. D., O'Halloran, T. L., Thomas, R. Q., Zhang, Q., Burns, S. P., Frank, J. M., Christian, D., Brown, S., Black, T. A., Gough, C. M., Law, B. E., Lee, X., Chen, J., Reed, D. E., Massman, W. J., Clark, K., Hatfield, J., Prueger, J., Bracho, R., Baker, J. M., Martin, T. A. (2018) Temporal Dynamics Of Aerodynamic Canopy Height Derived From Eddy Covariance Momentum Flux Data Across North American Flux Networks, Geophysical Research Letters, 45(3), 9275–9287" -US-Ton,1700003837,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018GL079306 -US-Ton,1700003837,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ton,1700000273,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(6), 108350" -US-Ton,1700000273,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -US-Ton,1700000273,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ton,1700009021,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Curiel Yuste, J., Ma, S., Baldocchi, D. D. (2010) Plant-Soil Interactions And Acclimation To Temperature Of Microbial-Mediated Soil Respiration May Affect Predictions Of Soil CO2 Efflux, Biogeochemistry, 98(1-3), 127-138" -US-Ton,1700009021,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1007/S10533-009-9381-1 -US-Ton,1700009021,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ton,1700008718,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Dennis Baldocchi, Cove Sturtevant (2015) Does day and night sampling reduce spurious correlation between canopy photosynthesis and ecosystem respiration?, Agricultural and Forest Meteorology, 207(6), 117-126" -US-Ton,1700008718,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2015.03.010 -US-Ton,1700008718,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ton,1700004881,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Filippa, G, Cremonesea, E, Migliavacca M., Galvagno, M., Sonnentag, O., Humphrey, E., Hufkens,K., Ryu, Y. Verfaillie, J., Morra di Cella, U., Richardson, A. (2017) NDVI derived from near-infrared-enabled digital cameras: Applicability across different plant functional types, Agricultural and Forest Meteorology, 132(3), 135-151" -US-Ton,1700004881,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2017.11.003 -US-Ton,1700004881,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ton,1700003354,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Fisher, J. B., Baldocchi, D. D., Misson, L., Dawson, T. E., Goldstein, A. H. (2007) What The Towers Don'T See At Night: Nocturnal Sap Flow In Trees And Shrubs At Two Ameriflux Sites In California, Tree Physiology, 27(4), 597-610" -US-Ton,1700003354,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1093/TREEPHYS/27.4.597 -US-Ton,1700003354,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ton,1700001611,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Gu, L., Falge, E. M., Boden, T., Baldocchi, D. D., Black, T., Saleska, S. R., Suni, T., Verma, S. B., Vesala, T., Wofsy, S. C., Xu, L. (2005) Objective Threshold Determination For Nighttime Eddy Flux Filtering, Agricultural And Forest Meteorology, 128(3-4), 179-197" -US-Ton,1700001611,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2004.11.006 -US-Ton,1700001611,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ton,1700008301,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Hibbard, K. A., Law, B. E., Reichstein, M., Sulzman, J. (2005) An Analysis Of Soil Respiration Across Northern Hemisphere Temperate Ecosystems, Biogeochemistry, 73(1), 29-70" -US-Ton,1700008301,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1007/S10533-004-2946-0 -US-Ton,1700008301,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ton,1700000486,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Kim, J., Guo, Q., Baldocchi, D., Leclerc, M., Xu, L., Schmid, H. (2006) Upscaling Fluxes From Tower To Landscape: Overlaying Flux Footprints On High-Resolution (IKONOS) Images Of Vegetation Cover, Agricultural And Forest Meteorology, 136(3-4), 132-146" -US-Ton,1700000486,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2004.11.015 -US-Ton,1700000486,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ton,1700008700,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Kobayashi, H., Baldocchi, D. D., Ryu, Y., Chen, Q., Ma, S., Osuna, J. L., Ustin, S. L. (2012) Modeling Energy And Carbon Fluxes In A Heterogeneous Oak Woodland: A Three-Dimensional Approach, Agricultural And Forest Meteorology, 152(1-2), 83-100" -US-Ton,1700008700,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2011.09.008 -US-Ton,1700008700,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ton,1700002079,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Liu, Y., Hill, M. J., Zhang, X., Wang, Z., Richardson, A. D., Hufkens, K., Filippa, G., Baldocchi, D. D., Ma, S., Verfaillie, J., Schaaf, C. B. (2017) Using Data From Landsat, Modis, Viirs And Phenocams To Monitor The Phenology Of California Oak/Grass Savanna And Open Grassland Across Spatial Scales, Agricultural And Forest Meteorology, 237-238(3), 311-325" -US-Ton,1700002079,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2017.02.026 -US-Ton,1700002079,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ton,1700004476,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Ma, S, Baldocchi, D.D., Wolf, S., Verfaillie, J. (2016) Slow ecosystem responses conditionally regulate annual carbon balance over 15 years in Californian oak-grass savanna, Agricultural and Forest Meteorology, 228-229(GB4002), 252-264" -US-Ton,1700004476,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2016.07.016 -US-Ton,1700004476,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Primary_Citation -US-Ton,1700000156,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Ma, S., Baldocchi, D. D., Mambelli, S., Dawson, T. E. (2011) Are Temporal Variations Of Leaf Traits Responsible For Seasonal And Inter-Annual Variability In Ecosystem CO2 Exchange?, Functional Ecology, 25(1), 258-270" -US-Ton,1700000156,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/J.1365-2435.2010.01779.X -US-Ton,1700000156,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ton,1700005148,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Ma, S., Baldocchi, D. D., Xu, L., Hehn, T. (2007) Inter-Annual Variability In Carbon Dioxide Exchange Of An Oak/Grass Savanna And Open Grassland In California, Agricultural And Forest Meteorology, 147(3-4), 157-171" -US-Ton,1700005148,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2007.07.008 -US-Ton,1700005148,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ton,1700000510,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Ma, S., Eichelmann, E., Wolf, S., Rey-Sanchez, C., Baldocchi, D. D. (2020) Transpiration And Evaporation In A Californian Oak-Grass Savanna: Field Measurements And Partitioning Model Results, Agricultural And Forest Meteorology, 295(2), 108204" -US-Ton,1700000510,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2020.108204 -US-Ton,1700000510,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ton,1700006750,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Ma, S., Osuna, J. L., Verfaillie, J., Baldocchi, D. D. (2017) Photosynthetic Responses To Temperature Across Leaf–Canopy–Ecosystem Scales: A 15-Year Study In A Californian Oak-Grass Savanna, Photosynthesis Research, 132(3), 277-291" -US-Ton,1700006750,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1007/S11120-017-0388-5 -US-Ton,1700006750,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ton,1700007191,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Matheny, A. M., Bohrer, G., Stoy, P. C., Baker, I. T., Black, A. T., Desai, A. R., Dietze, M. C., Gough, C. M., Ivanov, V. Y., Jassal, R. S., Novick, K. A., Schäfer, K. V., Verbeeck, H. (2014) Characterizing The Diurnal Patterns of Errors in The Prediction of Evapotranspiration by Several Land-Surface Models: An Nacp Analysis, Journal Of Geophysical Research: Biogeosciences, 119(7), 1458-1473" -US-Ton,1700007191,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/2014JG002623 -US-Ton,1700007191,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ton,1700007551,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Miller, G. R., Chen, X., Rubin, Y., Ma, S., Baldocchi, D. D. (2010) Groundwater Uptake By Woody Vegetation In A Semiarid Oak Savanna, Water Resources Research, 46(10), n/a-n/a" -US-Ton,1700007551,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2009WR008902 -US-Ton,1700007551,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ton,1700005631,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Novick, K. A., Ficklin, D. L., Stoy, P. C., Williams, C. A., Bohrer, G., Oishi, A., Papuga, S. A., Blanken, P. D., Noormets, A., Sulman, B. N., Scott, R. L., Wang, L., Phillips, R. P. (2016) The Increasing Importance Of Atmospheric Demand For Ecosystem Water And Carbon Fluxes, Nature Climate Change, 6(11), 1023-1027" -US-Ton,1700005631,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1038/NCLIMATE3114 -US-Ton,1700005631,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ton,1700008739,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Novick, K. A., Konings, A. G., Gentine, P. (2019) Beyond Soil Water Potential: An Expanded View On Isohydricity Including Land–Atmosphere Interactions And Phenology, Plant, Cell & Environment, 42(6), 1802-1815" -US-Ton,1700008739,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/PCE.13517 -US-Ton,1700008739,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ton,1700005994,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Raz-Yaseef, N., Koteen, L., Baldocchi, D. D. (2013) Coarse Root Distribution Of A Semi-Arid Oak Savanna Estimated With Ground Penetrating Radar, Journal Of Geophysical Research: Biogeosciences, 118(1), 135-147" -US-Ton,1700005994,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2012JG002160 -US-Ton,1700005994,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ton,1700006573,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Ryu, Y., Nilson, T., Kobayashi, H., Sonnentag, O., Law, B. E., Baldocchi, D. D. (2010) On The Correct Estimation Of Effective Leaf Area Index: Does It Reveal Information On Clumping Effects?, Agricultural And Forest Meteorology, 150(3), 463-472" -US-Ton,1700006573,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2010.01.009 -US-Ton,1700006573,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ton,1700005520,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Ryu, Y., Sonnentag, O., Nilson, T., Vargas, R., Kobayashi, H., Wenk, R., Baldocchi, D. D. (2010) How To Quantify Tree Leaf Area Index In An Open Savanna Ecosystem: A Multi-Instrument And Multi-Model Approach, Agricultural And Forest Meteorology, 150(1), 63-76" -US-Ton,1700005520,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2009.08.007 -US-Ton,1700005520,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ton,1700000759,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Sadeghi, M., Tuller, M., Warrick, A. W., Babaeian, E., Parajuli, K., Gohardoust, M. R., Jones, S. B. (2019) An Analytical Model For Estimation of Land Surface Net Water Flux From Near-Surface Soil Moisture Observations, Journal of Hydrology, 570(6), 26-37" -US-Ton,1700000759,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.JHYDROL.2018.12.038 -US-Ton,1700000759,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ton,1700002745,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Sims, D. A., Rahman, A. F., Cordova, V. D., Baldocchi, D. D., Flanagan, L. B., Goldstein, A. H., Hollinger, D. Y., Misson, L., Monson, R. K., Schmid, H. P., Wofsy, S. C., Xu, L. (2005) Midday Values Of Gross CO2 Flux And Light Use Efficiency During Satellite Overpasses Can Be Used To Directly Estimate Eight-Day Mean Flux, Agricultural And Forest Meteorology, 131(1-2), 1-12" -US-Ton,1700002745,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2005.04.006 -US-Ton,1700002745,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ton,1700004695,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Sullivan, R. C., Cook, D. R., Ghate, V. P., Kotamarthi, V. R., Feng, Y. (2019) Improved Spatiotemporal Representativeness And Bias Reduction Of Satellite-Based Evapotranspiration Retrievals Via Use Of In Situ Meteorology And Constrained Canopy Surface Resistance, Journal Of Geophysical Research: Biogeosciences, 124(2), 342-352" -US-Ton,1700004695,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018JG004744 -US-Ton,1700004695,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ton,1700007200,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Sullivan, R. C., Kotamarthi, V. R., Feng, Y. (2019) Recovering Evapotranspiration Trends From Biased CMIP5 Simulations And Sensitivity To Changing Climate Over North America, Journal Of Hydrometeorology, 20(8), 1619-1633" -US-Ton,1700007200,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1175/JHM-D-18-0259.1 -US-Ton,1700007200,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ton,1700001050,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Tang, J., Baldocchi, D. D. (2005) Spatial–Temporal Variation In Soil Respiration In An Oak–Grass Savanna Ecosystem In California And Its Partitioning Into Autotrophic And Heterotrophic Components, Biogeochemistry, 73(1), 183-207" -US-Ton,1700001050,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1007/S10533-004-5889-6 -US-Ton,1700001050,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ton,1700006342,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Tang, J., Baldocchi, D. D., Qi, Y., Xu, L. (2003) Assessing Soil CO2 Efflux Using Continuous Measurements Of CO2 Profiles In Soils With Small Solid-State Sensors, Agricultural And Forest Meteorology, 118(3-4), 207-220" -US-Ton,1700006342,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/S0168-1923(03)00112-6 -US-Ton,1700006342,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ton,1700003264,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Wang, J., X. M. Xiao, P. Wagle, S. Y. Ma, D. Baldocchi, A. Carrara, Y. Zhang, J. W. Dong, and Y. W. Qin. (2016) Canopy and climate controls of gross primary production of Mediterranean-type deciduous and evergreen oak savannas., Agricultural and Forest Meteorology, 226(GB4002), 132-147" -US-Ton,1700003264,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2016.05.020 -US-Ton,1700003264,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ton,1700004542,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Wharton, S., Ma, S., Baldocchi, D.D., Falk, M., Newman, J.F., Osuna, J.L, Bible, K. (2017) Influence of regional nighttime atmospheric regimes on canopy turbulence and gradients at a closed and open forest in mountain-valley terrain, Agricultural and Forest Meteorology, 237–238(6), 18-29" -US-Ton,1700004542,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2017.01.020 -US-Ton,1700004542,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ton,1700002841,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Wolf, S., Keenan, T.F., Fisher, J.B., Baldocchi, D.D., Desai, A.R., Richardson, A.D., Scott, R.L., Law, B.E., Litvak, M.E., Brunsell, N.A., Peters, W., van der Laan-Luijkx, I.T. (2016) Warm spring reduced carbon cycle impact of the 2012 US summer drought, Proceedings of the National Academy of Sciences, 113(21), 5880-5885" -US-Ton,1700002841,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1073/PNAS.1519620113 -US-Ton,1700002841,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ton,1700003339,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Xu, L., Baldocchi, D. D. (2003) Seasonal Trends In Photosynthetic Parameters And Stomatal Conductance Of Blue Oak (Quercus Douglasii) Under Prolonged Summer Drought And High Temperature, Tree Physiology, 23(13), 865-877" -US-Ton,1700003339,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1093/TREEPHYS/23.13.865 -US-Ton,1700003339,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ton,1700001260,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Xu, L., Baldocchi, D. D., Tang, J. (2004) How Soil Moisture, Rain Pulses, And Growth Alter The Response Of Ecosystem Respiration To Temperature, Global Biogeochemical Cycles, 18(4), n/a-n/a" -US-Ton,1700001260,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2004GB002281 -US-Ton,1700001260,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ton,1700008313,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Xu, L., Baldocchi, D.D., Tang, J. (2004) How soil moisture, rain pulses, and growth alter the response of ecosystem respiration to temperature, Global Biogeochemical Cycles, 18(GB4002), 0-0" -US-Ton,1700008313,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2004GB002281 -US-Ton,1700008313,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ton,1700003807,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Zhang, Q., Ficklin, D. L., Manzoni, S., Wang, L., Way, D., Phillips, R. P., Novick, K. A. (2019) Response Of Ecosystem Intrinsic Water Use Efficiency And Gross Primary Productivity To Rising Vapor Pressure Deficit, Environmental Research Letters, 14(7), 074023" -US-Ton,1700003807,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1088/1748-9326/AB2603 -US-Ton,1700003807,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Ton,7599,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"The research approach of the University of California, Berkeley Biometeorology Laboratory involves the coordinated use of experimental measurements and theoretical models to understand the physical, biological, and chemical processes that control trace gas fluxes between the biosphere and atmosphere and to quantify their temporal and spatial variations. The research objectives of the Tonzi Ranch site include the following: 1) Comparing radiative, convective and latent energy flux densities of an oak savanna and nearby annual grassland over the course of two growing seasons; 2) Quantifying the roles of soil water content and soil physical properties on evaporation rates and canopy conductance; 3) Quantifying the effects of canopy structure and phenology on the partitioning of energy exchange associated with understory and overstory vegetation. Three-fold study assessments include: 1) The relative contributions of vegetation and the soil on CO2 and water vapor exchange; 2) Spatial variability of understory fluxes; 3) The impact of sloping terrain on the interpretation of flux covariances." -US-Ton,23849,GRP_ROOT_BIOMASS,ROOT_BIOMASS_TOT,130 -US-Ton,23849,GRP_ROOT_BIOMASS,ROOT_BIOMASS_UNIT,gC m-2 -US-Ton,91726,GRP_SITE_CHAR,TERRAIN,Flat -US-Ton,91726,GRP_SITE_CHAR,ASPECT,FLAT -US-Ton,91726,GRP_SITE_CHAR,WIND_DIRECTION,WNW -US-Ton,91726,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,1000 -US-Ton,91726,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,0 -US-Ton,5903,GRP_SITE_DESC,SITE_DESC,"Located in the lower foothills of the Sierra Nevada Mountains, the Tonzi Ranch site is classified as an oak savanna woodland on privately owned land. Managed by local rancher, Russell Tonzi, brush has been periodically removed for cattle grazing. The overstory is dominated by blue oak trees (40% of total vegetation) with intermittent grey pine trees (3 trees/ha). Understory species include a variety of grasses and herbs, including purple false brome, smooth cat's ear, and rose clover. These two distinctive layers operate in and out from one another. Growing season of the understory is confined to the wet season only, typically from October to early May. In contrast, the deciduous blue oak trees are dormant during the rainy winter months and reach maximum LAI in April. The blue oak ecosystem rings the Great Central Valley of California, inhabiting the lower reaches of the Sierra Nevada foothills." -US-Ton,5066,GRP_SITE_FUNDING,SITE_FUNDING,DOE/TCP -US-Ton,22046,GRP_SOIL_CHEM,SOIL_CHEM_BD,1.3085325233 -US-Ton,22041,GRP_SOIL_CHEM,SOIL_CHEM_BD,1.4210887234 -US-Ton,22045,GRP_SOIL_CHEM,SOIL_CHEM_BD,1.4446378263 -US-Ton,22043,GRP_SOIL_CHEM,SOIL_CHEM_BD,1.5217769331 -US-Ton,22042,GRP_SOIL_CHEM,SOIL_CHEM_BD,1.5748308674 -US-Ton,22040,GRP_SOIL_CHEM,SOIL_CHEM_BD,1.5805109047 -US-Ton,22044,GRP_SOIL_CHEM,SOIL_CHEM_BD,1.5838081838 -US-Ton,22039,GRP_SOIL_CHEM,SOIL_CHEM_BD,1.6441975309 -US-Ton,22039,GRP_SOIL_CHEM,SOIL_CHEM_BD_SPATIAL_VARIABILITY,0.10796027519 -US-Ton,22041,GRP_SOIL_CHEM,SOIL_CHEM_BD_SPATIAL_VARIABILITY,0.24261582016 -US-Ton,22043,GRP_SOIL_CHEM,SOIL_CHEM_BD_SPATIAL_VARIABILITY,0.27539306697 -US-Ton,22042,GRP_SOIL_CHEM,SOIL_CHEM_BD_SPATIAL_VARIABILITY,0.28707411562 -US-Ton,22045,GRP_SOIL_CHEM,SOIL_CHEM_BD_SPATIAL_VARIABILITY,0.29768789259 -US-Ton,22046,GRP_SOIL_CHEM,SOIL_CHEM_BD_SPATIAL_VARIABILITY,0.42681480863 -US-Ton,22044,GRP_SOIL_CHEM,SOIL_CHEM_BD_SPATIAL_VARIABILITY,0.42850606276 -US-Ton,22040,GRP_SOIL_CHEM,SOIL_CHEM_BD_SPATIAL_VARIABILITY,0.4661854149 -US-Ton,22041,GRP_SOIL_CHEM,SOIL_CHEM_BD_SPATIAL_REP_NUMBER,12 -US-Ton,22042,GRP_SOIL_CHEM,SOIL_CHEM_BD_SPATIAL_REP_NUMBER,12 -US-Ton,22043,GRP_SOIL_CHEM,SOIL_CHEM_BD_SPATIAL_REP_NUMBER,12 -US-Ton,22044,GRP_SOIL_CHEM,SOIL_CHEM_BD_SPATIAL_REP_NUMBER,12 -US-Ton,22045,GRP_SOIL_CHEM,SOIL_CHEM_BD_SPATIAL_REP_NUMBER,12 -US-Ton,22039,GRP_SOIL_CHEM,SOIL_CHEM_BD_SPATIAL_REP_NUMBER,27 -US-Ton,22046,GRP_SOIL_CHEM,SOIL_CHEM_BD_SPATIAL_REP_NUMBER,6 -US-Ton,22040,GRP_SOIL_CHEM,SOIL_CHEM_BD_SPATIAL_REP_NUMBER,69 -US-Ton,22039,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_ZERO_REF,Top of mineral soil -US-Ton,22039,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,0 -US-Ton,22040,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,0 -US-Ton,22041,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,0 -US-Ton,22042,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,10 -US-Ton,22043,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,20 -US-Ton,22044,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,30 -US-Ton,22045,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,40 -US-Ton,22046,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,50 -US-Ton,22041,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,10 -US-Ton,22042,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,20 -US-Ton,22039,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,30 -US-Ton,22043,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,30 -US-Ton,22044,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,40 -US-Ton,22045,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,50 -US-Ton,22040,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,60 -US-Ton,22046,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,60 -US-Ton,22039,GRP_SOIL_CHEM,SOIL_CHEM_DATE,20010425 -US-Ton,22040,GRP_SOIL_CHEM,SOIL_CHEM_DATE,20110502 -US-Ton,22041,GRP_SOIL_CHEM,SOIL_CHEM_DATE,20110502 -US-Ton,22042,GRP_SOIL_CHEM,SOIL_CHEM_DATE,20110502 -US-Ton,22043,GRP_SOIL_CHEM,SOIL_CHEM_DATE,20110502 -US-Ton,22044,GRP_SOIL_CHEM,SOIL_CHEM_DATE,20110502 -US-Ton,22045,GRP_SOIL_CHEM,SOIL_CHEM_DATE,20110502 -US-Ton,22046,GRP_SOIL_CHEM,SOIL_CHEM_DATE,20110502 -US-Ton,22039,GRP_SOIL_CHEM,SOIL_CHEM_DATE_UNC,0 -US-Ton,23841,GRP_SPP_O,SPP_O,QUDO (NRCS plant code) -US-Ton,28455,GRP_SPP_U,SPP_U,AETR (NRCS plant code) -US-Ton,28248,GRP_SPP_U,SPP_U,AICA (NRCS plant code) -US-Ton,27228,GRP_SPP_U,SPP_U,AVBA (NRCS plant code) -US-Ton,28113,GRP_SPP_U,SPP_U,B (NRCS plant code) -US-Ton,27857,GRP_SPP_U,SPP_U,BRDI (NRCS plant code) -US-Ton,26957,GRP_SPP_U,SPP_U,BRDI2 (NRCS plant code) -US-Ton,25918,GRP_SPP_U,SPP_U,BREL (NRCS plant code) -US-Ton,28479,GRP_SPP_U,SPP_U,BRHO (NRCS plant code) -US-Ton,27505,GRP_SPP_U,SPP_U,BRMA (NRCS plant code) -US-Ton,27220,GRP_SPP_U,SPP_U,BRMI (NRCS plant code) -US-Ton,28226,GRP_SPP_U,SPP_U,CALOCHOR (NRCS plant code) -US-Ton,25280,GRP_SPP_U,SPP_U,CEME (NRCS plant code) -US-Ton,27864,GRP_SPP_U,SPP_U,CHPO (NRCS plant code) -US-Ton,27881,GRP_SPP_U,SPP_U,CYEC (NRCS plant code) -US-Ton,28456,GRP_SPP_U,SPP_U,DIVO (NRCS plant code) -US-Ton,27229,GRP_SPP_U,SPP_U,ERBO (NRCS plant code) -US-Ton,27506,GRP_SPP_U,SPP_U,GAVE (NRCS plant code) -US-Ton,26817,GRP_SPP_U,SPP_U,HYGL (NRCS plant code) -US-Ton,26935,GRP_SPP_U,SPP_U,JUBU (NRCS plant code) -US-Ton,26685,GRP_SPP_U,SPP_U,L (NRCS plant code) -US-Ton,28963,GRP_SPP_U,SPP_U,LICI (NRCS plant code) -US-Ton,26044,GRP_SPP_U,SPP_U,MASU (NRCS plant code) -US-Ton,26947,GRP_SPP_U,SPP_U,MICA (NRCS plant code) -US-Ton,26037,GRP_SPP_U,SPP_U,NAPU2 (NRCS plant code) -US-Ton,27523,GRP_SPP_U,SPP_U,OL (NRCS plant code) -US-Ton,26045,GRP_SPP_U,SPP_U,PLER (NRCS plant code) -US-Ton,25284,GRP_SPP_U,SPP_U,QUDO (NRCS plant code) -US-Ton,26946,GRP_SPP_U,SPP_U,SABI (NRCS plant code) -US-Ton,28123,GRP_SPP_U,SPP_U,SHAR (NRCS plant code) -US-Ton,27219,GRP_SPP_U,SPP_U,TRDU (NRCS plant code) -US-Ton,25544,GRP_SPP_U,SPP_U,TRHI (NRCS plant code) -US-Ton,25919,GRP_SPP_U,SPP_U,UKF1 (NRCS plant code) -US-Ton,28449,GRP_SPP_U,SPP_U,VUMY (NRCS plant code) -US-Ton,9348,GRP_STATE,STATE,CA -US-Ton,20789,GRP_SWC,SWC,10.019444444 -US-Ton,20789,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.1920579579 -US-Ton,20789,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20789,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20789,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20789,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20789,GRP_SWC,SWC_DATE,20120518 -US-Ton,20946,GRP_SWC,SWC,10.033333333 -US-Ton,20946,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.8047009808 -US-Ton,20946,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20946,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20946,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20946,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20946,GRP_SWC,SWC_DATE,20140709 -US-Ton,20415,GRP_SWC,SWC,10.058333333 -US-Ton,20415,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.5398275082 -US-Ton,20415,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20415,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20415,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20415,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20415,GRP_SWC,SWC_DATE,20070623 -US-Ton,19876,GRP_SWC,SWC,10.06 -US-Ton,19876,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.1654931681 -US-Ton,19876,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19876,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19876,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,19876,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,19876,GRP_SWC,SWC_DATE,20021105 -US-Ton,20652,GRP_SWC,SWC,10.095833333 -US-Ton,20652,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.3254772902 -US-Ton,20652,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20652,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20652,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20652,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20652,GRP_SWC,SWC_DATE,20100814 -US-Ton,20870,GRP_SWC,SWC,10.118181818 -US-Ton,20870,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.6869645149 -US-Ton,20870,GRP_SWC,SWC_SPATIAL_REP_NUMBER,11 -US-Ton,20870,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20870,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20870,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20870,GRP_SWC,SWC_DATE,20130619 -US-Ton,20108,GRP_SWC,SWC,10.183333333 -US-Ton,20108,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.6221540553 -US-Ton,20108,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20108,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20108,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20108,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20108,GRP_SWC,SWC_DATE,20040607 -US-Ton,19941,GRP_SWC,SWC,10.196296296 -US-Ton,19941,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.3585481505 -US-Ton,19941,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,19941,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19941,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,19941,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,19941,GRP_SWC,SWC_DATE,20030530 -US-Ton,20286,GRP_SWC,SWC,10.2 -US-Ton,20286,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.8422951895 -US-Ton,20286,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20286,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20286,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20286,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20286,GRP_SWC,SWC_DATE,20060623 -US-Ton,20127,GRP_SWC,SWC,10.207407407 -US-Ton,20127,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.8421694454 -US-Ton,20127,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20127,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20127,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20127,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20127,GRP_SWC,SWC_DATE,20040908 -US-Ton,19992,GRP_SWC,SWC,10.208333333 -US-Ton,19992,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.437992389 -US-Ton,19992,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,19992,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19992,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,19992,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,19992,GRP_SWC,SWC_DATE,20030806 -US-Ton,20729,GRP_SWC,SWC,10.213888889 -US-Ton,20729,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.0170459605 -US-Ton,20729,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20729,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20729,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20729,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20729,GRP_SWC,SWC_DATE,20110916 -US-Ton,19996,GRP_SWC,SWC,10.233333333 -US-Ton,19996,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.256318644 -US-Ton,19996,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,19996,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19996,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,19996,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,19996,GRP_SWC,SWC_DATE,20030816 -US-Ton,20603,GRP_SWC,SWC,10.266666667 -US-Ton,20603,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.5847736722 -US-Ton,20603,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20603,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20603,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20603,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20603,GRP_SWC,SWC_DATE,20091105 -US-Ton,20110,GRP_SWC,SWC,10.27037037 -US-Ton,20110,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.6590619792 -US-Ton,20110,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20110,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20110,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20110,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20110,GRP_SWC,SWC_DATE,20040708 -US-Ton,20725,GRP_SWC,SWC,10.286111111 -US-Ton,20725,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.1946685337 -US-Ton,20725,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20725,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20725,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20725,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20725,GRP_SWC,SWC_DATE,20110831 -US-Ton,20306,GRP_SWC,SWC,10.291666667 -US-Ton,20306,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.5680129624 -US-Ton,20306,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20306,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20306,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20306,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20306,GRP_SWC,SWC_DATE,20061104 -US-Ton,20802,GRP_SWC,SWC,10.309722222 -US-Ton,20802,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.4843749963 -US-Ton,20802,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20802,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20802,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20802,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20802,GRP_SWC,SWC_DATE,20120725 -US-Ton,20906,GRP_SWC,SWC,10.320833333 -US-Ton,20906,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.9431981888 -US-Ton,20906,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20906,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20906,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20906,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20906,GRP_SWC,SWC_DATE,20140107 -US-Ton,20015,GRP_SWC,SWC,10.355555556 -US-Ton,20015,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.277395454 -US-Ton,20015,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20015,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20015,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20015,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20015,GRP_SWC,SWC_DATE,20031007 -US-Ton,20905,GRP_SWC,SWC,10.359090909 -US-Ton,20905,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.2191349268 -US-Ton,20905,GRP_SWC,SWC_SPATIAL_REP_NUMBER,11 -US-Ton,20905,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20905,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20905,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20905,GRP_SWC,SWC_DATE,20140107 -US-Ton,20019,GRP_SWC,SWC,10.359259259 -US-Ton,20019,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.8413375613 -US-Ton,20019,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20019,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20019,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20019,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20019,GRP_SWC,SWC_DATE,20031024 -US-Ton,19884,GRP_SWC,SWC,10.3625 -US-Ton,19884,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.0758179138 -US-Ton,19884,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Ton,19884,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19884,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,19884,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,19884,GRP_SWC,SWC_DATE,20021206 -US-Ton,19874,GRP_SWC,SWC,10.4 -US-Ton,19874,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.49497474683 -US-Ton,19874,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19874,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19874,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,19874,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,19874,GRP_SWC,SWC_DATE,20021105 -US-Ton,19998,GRP_SWC,SWC,10.405555556 -US-Ton,19998,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.1199548272 -US-Ton,19998,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,19998,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19998,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,19998,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,19998,GRP_SWC,SWC_DATE,20030821 -US-Ton,20419,GRP_SWC,SWC,10.422222222 -US-Ton,20419,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.2683772062 -US-Ton,20419,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20419,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20419,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20419,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20419,GRP_SWC,SWC_DATE,20070626 -US-Ton,19986,GRP_SWC,SWC,10.438888889 -US-Ton,19986,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.96884569 -US-Ton,19986,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,19986,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19986,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,19986,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,19986,GRP_SWC,SWC_DATE,20030731 -US-Ton,19994,GRP_SWC,SWC,10.514814815 -US-Ton,19994,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.2131444812 -US-Ton,19994,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,19994,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19994,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,19994,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,19994,GRP_SWC,SWC_DATE,20030816 -US-Ton,19872,GRP_SWC,SWC,10.52 -US-Ton,19872,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.8535553979 -US-Ton,19872,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19872,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19872,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,19872,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,19872,GRP_SWC,SWC_DATE,20021024 -US-Ton,20495,GRP_SWC,SWC,10.530555556 -US-Ton,20495,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.12278878 -US-Ton,20495,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20495,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20495,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20495,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20495,GRP_SWC,SWC_DATE,20080420 -US-Ton,20402,GRP_SWC,SWC,10.539393939 -US-Ton,20402,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.1989490002 -US-Ton,20402,GRP_SWC,SWC_SPATIAL_REP_NUMBER,11 -US-Ton,20402,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20402,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20402,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20402,GRP_SWC,SWC_DATE,20070515 -US-Ton,20704,GRP_SWC,SWC,10.568181818 -US-Ton,20704,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.3400422998 -US-Ton,20704,GRP_SWC,SWC_SPATIAL_REP_NUMBER,11 -US-Ton,20704,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20704,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20704,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20704,GRP_SWC,SWC_DATE,20110510 -US-Ton,19988,GRP_SWC,SWC,10.583333333 -US-Ton,19988,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.4769778544 -US-Ton,19988,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,19988,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19988,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,19988,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,19988,GRP_SWC,SWC_DATE,20030731 -US-Ton,20308,GRP_SWC,SWC,10.595833333 -US-Ton,20308,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.1630002876 -US-Ton,20308,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20308,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20308,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20308,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20308,GRP_SWC,SWC_DATE,20061104 -US-Ton,19870,GRP_SWC,SWC,10.6 -US-Ton,19870,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.48476798574 -US-Ton,19870,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19870,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19870,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,19870,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,19870,GRP_SWC,SWC_DATE,20021024 -US-Ton,20822,GRP_SWC,SWC,10.608333333 -US-Ton,20822,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.4681617805 -US-Ton,20822,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20822,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20822,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20822,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20822,GRP_SWC,SWC_DATE,20121107 -US-Ton,20216,GRP_SWC,SWC,10.645833333 -US-Ton,20216,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.1300123309 -US-Ton,20216,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20216,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20216,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20216,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20216,GRP_SWC,SWC_DATE,20050925 -US-Ton,20131,GRP_SWC,SWC,10.65 -US-Ton,20131,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.1032761301 -US-Ton,20131,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20131,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20131,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20131,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20131,GRP_SWC,SWC_DATE,20040921 -US-Ton,19871,GRP_SWC,SWC,10.68 -US-Ton,19871,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.4370034933 -US-Ton,19871,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19871,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19871,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,19871,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,19871,GRP_SWC,SWC_DATE,20021024 -US-Ton,20123,GRP_SWC,SWC,10.685185185 -US-Ton,20123,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.0346883141 -US-Ton,20123,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20123,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20123,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20123,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20123,GRP_SWC,SWC_DATE,20040817 -US-Ton,19982,GRP_SWC,SWC,10.688888889 -US-Ton,19982,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.0171161574 -US-Ton,19982,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,19982,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19982,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,19982,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,19982,GRP_SWC,SWC_DATE,20030725 -US-Ton,20316,GRP_SWC,SWC,10.6975 -US-Ton,20316,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.814927782 -US-Ton,20316,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20316,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20316,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20316,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20316,GRP_SWC,SWC_DATE,20061114 -US-Ton,19866,GRP_SWC,SWC,10.713333333 -US-Ton,19866,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.71242933373 -US-Ton,19866,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19866,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19866,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,19866,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,19866,GRP_SWC,SWC_DATE,20021002 -US-Ton,20324,GRP_SWC,SWC,10.713888889 -US-Ton,20324,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.7906360332 -US-Ton,20324,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20324,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20324,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20324,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20324,GRP_SWC,SWC_DATE,20061219 -US-Ton,20206,GRP_SWC,SWC,10.725 -US-Ton,20206,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.7315302735 -US-Ton,20206,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20206,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20206,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20206,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20206,GRP_SWC,SWC_DATE,20050706 -US-Ton,20442,GRP_SWC,SWC,10.727777778 -US-Ton,20442,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.2460438838 -US-Ton,20442,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20442,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20442,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20442,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20442,GRP_SWC,SWC_DATE,20071024 -US-Ton,20584,GRP_SWC,SWC,10.75 -US-Ton,20584,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.7705798927 -US-Ton,20584,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20584,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20584,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20584,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20584,GRP_SWC,SWC_DATE,20090705 -US-Ton,20119,GRP_SWC,SWC,10.751851852 -US-Ton,20119,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.2475420466 -US-Ton,20119,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20119,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20119,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20119,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20119,GRP_SWC,SWC_DATE,20040805 -US-Ton,20007,GRP_SWC,SWC,10.761111111 -US-Ton,20007,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.2643125013 -US-Ton,20007,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20007,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20007,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20007,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20007,GRP_SWC,SWC_DATE,20030918 -US-Ton,20011,GRP_SWC,SWC,10.764814815 -US-Ton,20011,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.1041952002 -US-Ton,20011,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20011,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20011,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20011,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20011,GRP_SWC,SWC_DATE,20031002 -US-Ton,20300,GRP_SWC,SWC,10.794166667 -US-Ton,20300,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.6577741501 -US-Ton,20300,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20300,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20300,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20300,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20300,GRP_SWC,SWC_DATE,20060808 -US-Ton,20910,GRP_SWC,SWC,10.8 -US-Ton,20910,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.9704124577 -US-Ton,20910,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20910,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20910,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20910,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20910,GRP_SWC,SWC_DATE,20140124 -US-Ton,20437,GRP_SWC,SWC,10.816666667 -US-Ton,20437,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.96597514 -US-Ton,20437,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20437,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20437,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20437,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20437,GRP_SWC,SWC_DATE,20070908 -US-Ton,20538,GRP_SWC,SWC,10.816666667 -US-Ton,20538,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.5769040278 -US-Ton,20538,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20538,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20538,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20538,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20538,GRP_SWC,SWC_DATE,20081126 -US-Ton,20546,GRP_SWC,SWC,10.816666667 -US-Ton,20546,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.5769040278 -US-Ton,20546,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20546,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20546,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20546,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20546,GRP_SWC,SWC_DATE,20090108 -US-Ton,20320,GRP_SWC,SWC,10.820833333 -US-Ton,20320,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.8087731536 -US-Ton,20320,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20320,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20320,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20320,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20320,GRP_SWC,SWC_DATE,20061119 -US-Ton,20282,GRP_SWC,SWC,10.836111111 -US-Ton,20282,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.9240377662 -US-Ton,20282,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20282,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20282,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20282,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20282,GRP_SWC,SWC_DATE,20060608 -US-Ton,20003,GRP_SWC,SWC,10.848148148 -US-Ton,20003,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.9030634163 -US-Ton,20003,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20003,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20003,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20003,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20003,GRP_SWC,SWC_DATE,20030905 -US-Ton,20115,GRP_SWC,SWC,10.872222222 -US-Ton,20115,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.3229521362 -US-Ton,20115,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20115,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20115,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20115,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20115,GRP_SWC,SWC_DATE,20040721 -US-Ton,20433,GRP_SWC,SWC,10.880555556 -US-Ton,20433,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.0626071922 -US-Ton,20433,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20433,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20433,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20433,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20433,GRP_SWC,SWC_DATE,20070822 -US-Ton,19984,GRP_SWC,SWC,10.894444444 -US-Ton,19984,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.5418529363 -US-Ton,19984,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,19984,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19984,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,19984,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,19984,GRP_SWC,SWC_DATE,20030725 -US-Ton,19980,GRP_SWC,SWC,10.9 -US-Ton,19980,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.5974528026 -US-Ton,19980,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,19980,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19980,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,19980,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,19980,GRP_SWC,SWC_DATE,20030717 -US-Ton,20942,GRP_SWC,SWC,10.904166667 -US-Ton,20942,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.5604307523 -US-Ton,20942,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20942,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20942,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20942,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20942,GRP_SWC,SWC_DATE,20140625 -US-Ton,20866,GRP_SWC,SWC,10.904545455 -US-Ton,20866,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.1457480957 -US-Ton,20866,GRP_SWC,SWC_SPATIAL_REP_NUMBER,11 -US-Ton,20866,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20866,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20866,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20866,GRP_SWC,SWC_DATE,20130530 -US-Ton,20212,GRP_SWC,SWC,10.933333333 -US-Ton,20212,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.4338724403 -US-Ton,20212,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20212,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20212,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20212,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20212,GRP_SWC,SWC_DATE,20050910 -US-Ton,19875,GRP_SWC,SWC,10.966666667 -US-Ton,19875,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.5088185198 -US-Ton,19875,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19875,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19875,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,19875,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,19875,GRP_SWC,SWC_DATE,20021105 -US-Ton,19854,GRP_SWC,SWC,10.986666667 -US-Ton,19854,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.59469880332 -US-Ton,19854,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19854,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19854,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,19854,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,19854,GRP_SWC,SWC_DATE,20020905 -US-Ton,19976,GRP_SWC,SWC,10.988888889 -US-Ton,19976,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.7070128735 -US-Ton,19976,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,19976,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19976,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,19976,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,19976,GRP_SWC,SWC_DATE,20030711 -US-Ton,20530,GRP_SWC,SWC,11.018055556 -US-Ton,20530,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.6471260714 -US-Ton,20530,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20530,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20530,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20530,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20530,GRP_SWC,SWC_DATE,20081030 -US-Ton,20288,GRP_SWC,SWC,11.022222222 -US-Ton,20288,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.8944818114 -US-Ton,20288,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20288,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20288,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20288,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20288,GRP_SWC,SWC_DATE,20060623 -US-Ton,19858,GRP_SWC,SWC,11.025 -US-Ton,19858,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.66520673478 -US-Ton,19858,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Ton,19858,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19858,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,19858,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,19858,GRP_SWC,SWC_DATE,20020912 -US-Ton,20411,GRP_SWC,SWC,11.025 -US-Ton,20411,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.4309089705 -US-Ton,20411,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20411,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20411,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20411,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20411,GRP_SWC,SWC_DATE,20070616 -US-Ton,20224,GRP_SWC,SWC,11.059722222 -US-Ton,20224,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.1059455259 -US-Ton,20224,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20224,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20224,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20224,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20224,GRP_SWC,SWC_DATE,20051213 -US-Ton,20106,GRP_SWC,SWC,11.061111111 -US-Ton,20106,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.4230064561 -US-Ton,20106,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20106,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20106,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20106,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20106,GRP_SWC,SWC_DATE,20040607 -US-Ton,20938,GRP_SWC,SWC,11.0625 -US-Ton,20938,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.9703861989 -US-Ton,20938,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20938,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20938,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20938,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20938,GRP_SWC,SWC_DATE,20140611 -US-Ton,20425,GRP_SWC,SWC,11.066666667 -US-Ton,20425,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.7939777036 -US-Ton,20425,GRP_SWC,SWC_SPATIAL_REP_NUMBER,11 -US-Ton,20425,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20425,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20425,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20425,GRP_SWC,SWC_DATE,20070717 -US-Ton,20292,GRP_SWC,SWC,11.077777778 -US-Ton,20292,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.8272493526 -US-Ton,20292,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20292,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20292,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20292,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20292,GRP_SWC,SWC_DATE,20060713 -US-Ton,20429,GRP_SWC,SWC,11.119444444 -US-Ton,20429,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.0838317358 -US-Ton,20429,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20429,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20429,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20429,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20429,GRP_SWC,SWC_DATE,20070809 -US-Ton,19862,GRP_SWC,SWC,11.126666667 -US-Ton,19862,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.61391276977 -US-Ton,19862,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19862,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19862,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,19862,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,19862,GRP_SWC,SWC_DATE,20020920 -US-Ton,19974,GRP_SWC,SWC,11.133333333 -US-Ton,19974,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.1548499104 -US-Ton,19974,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,19974,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19974,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,19974,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,19974,GRP_SWC,SWC_DATE,20030711 -US-Ton,20862,GRP_SWC,SWC,11.1375 -US-Ton,20862,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.3376326283 -US-Ton,20862,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20862,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20862,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20862,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20862,GRP_SWC,SWC_DATE,20130508 -US-Ton,19991,GRP_SWC,SWC,11.144444444 -US-Ton,19991,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.0477167556 -US-Ton,19991,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,19991,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19991,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,19991,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,19991,GRP_SWC,SWC_DATE,20030806 -US-Ton,19999,GRP_SWC,SWC,11.144444444 -US-Ton,19999,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.0984951484 -US-Ton,19999,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,19999,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19999,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,19999,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,19999,GRP_SWC,SWC_DATE,20030821 -US-Ton,20107,GRP_SWC,SWC,11.172222222 -US-Ton,20107,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.0204650626 -US-Ton,20107,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20107,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20107,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20107,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20107,GRP_SWC,SWC_DATE,20040607 -US-Ton,19966,GRP_SWC,SWC,11.18 -US-Ton,19966,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.3290414643 -US-Ton,19966,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,19966,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19966,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,19966,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,19966,GRP_SWC,SWC_DATE,20030702 -US-Ton,20312,GRP_SWC,SWC,11.183333333 -US-Ton,20312,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.4174927758 -US-Ton,20312,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20312,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20312,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20312,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20312,GRP_SWC,SWC_DATE,20061108 -US-Ton,20452,GRP_SWC,SWC,11.188888889 -US-Ton,20452,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.7469146457 -US-Ton,20452,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20452,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20452,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20452,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20452,GRP_SWC,SWC_DATE,20071111 -US-Ton,20900,GRP_SWC,SWC,11.205 -US-Ton,20900,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.0675113881 -US-Ton,20900,GRP_SWC,SWC_SPATIAL_REP_NUMBER,10 -US-Ton,20900,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20900,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20900,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20900,GRP_SWC,SWC_DATE,20131127 -US-Ton,20328,GRP_SWC,SWC,11.216666667 -US-Ton,20328,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.113190165 -US-Ton,20328,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20328,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20328,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20328,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20328,GRP_SWC,SWC_DATE,20061226 -US-Ton,19842,GRP_SWC,SWC,11.22 -US-Ton,19842,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.40865633483 -US-Ton,19842,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19842,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19842,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,19842,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,19842,GRP_SWC,SWC_DATE,20020815 -US-Ton,19846,GRP_SWC,SWC,11.22 -US-Ton,19846,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.45497252664 -US-Ton,19846,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19846,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19846,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,19846,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,19846,GRP_SWC,SWC_DATE,20020823 -US-Ton,19868,GRP_SWC,SWC,11.22 -US-Ton,19868,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.1670752527 -US-Ton,19868,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19868,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19868,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,19868,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,19868,GRP_SWC,SWC_DATE,20021002 -US-Ton,19958,GRP_SWC,SWC,11.232222222 -US-Ton,19958,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.8033472126 -US-Ton,19958,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,19958,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19958,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,19958,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,19958,GRP_SWC,SWC_DATE,20030625 -US-Ton,19978,GRP_SWC,SWC,11.244444444 -US-Ton,19978,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.329902488 -US-Ton,19978,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,19978,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19978,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,19978,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,19978,GRP_SWC,SWC_DATE,20030717 -US-Ton,19880,GRP_SWC,SWC,11.253333333 -US-Ton,19880,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.7714276696 -US-Ton,19880,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19880,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19880,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,19880,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,19880,GRP_SWC,SWC_DATE,20021114 -US-Ton,20102,GRP_SWC,SWC,11.255555556 -US-Ton,20102,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.0687409327 -US-Ton,20102,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20102,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20102,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20102,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20102,GRP_SWC,SWC_DATE,20040522 -US-Ton,20598,GRP_SWC,SWC,11.255555556 -US-Ton,20598,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.0064066699 -US-Ton,20598,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20598,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20598,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20598,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20598,GRP_SWC,SWC_DATE,20091002 -US-Ton,19995,GRP_SWC,SWC,11.274074074 -US-Ton,19995,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.9200772854 -US-Ton,19995,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,19995,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19995,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,19995,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,19995,GRP_SWC,SWC_DATE,20030816 -US-Ton,20111,GRP_SWC,SWC,11.281481481 -US-Ton,20111,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.9246858645 -US-Ton,20111,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20111,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20111,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20111,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20111,GRP_SWC,SWC_DATE,20040708 -US-Ton,20969,GRP_SWC,SWC,11.304166667 -US-Ton,20969,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.5327338328 -US-Ton,20969,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20969,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20969,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20969,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20969,GRP_SWC,SWC_DATE,20141113 -US-Ton,20534,GRP_SWC,SWC,11.344444444 -US-Ton,20534,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.1924796388 -US-Ton,20534,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20534,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20534,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20534,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20534,GRP_SWC,SWC_DATE,20081113 -US-Ton,20104,GRP_SWC,SWC,11.35 -US-Ton,20104,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.9841090598 -US-Ton,20104,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20104,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20104,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20104,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20104,GRP_SWC,SWC_DATE,20040522 -US-Ton,20542,GRP_SWC,SWC,11.3625 -US-Ton,20542,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.5759810175 -US-Ton,20542,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20542,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20542,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20542,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20542,GRP_SWC,SWC_DATE,20081211 -US-Ton,19879,GRP_SWC,SWC,11.366666667 -US-Ton,19879,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.1745924618 -US-Ton,19879,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19879,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19879,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,19879,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,19879,GRP_SWC,SWC_DATE,20021114 -US-Ton,20304,GRP_SWC,SWC,11.391666667 -US-Ton,20304,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.6255033445 -US-Ton,20304,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20304,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20304,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20304,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20304,GRP_SWC,SWC_DATE,20060923 -US-Ton,19968,GRP_SWC,SWC,11.402222222 -US-Ton,19968,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.7652084198 -US-Ton,19968,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,19968,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19968,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,19968,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,19968,GRP_SWC,SWC_DATE,20030702 -US-Ton,20456,GRP_SWC,SWC,11.405555556 -US-Ton,20456,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.6928450446 -US-Ton,20456,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20456,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20456,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20456,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20456,GRP_SWC,SWC_DATE,20071125 -US-Ton,19954,GRP_SWC,SWC,11.407407407 -US-Ton,19954,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.4012554326 -US-Ton,19954,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,19954,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19954,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,19954,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,19954,GRP_SWC,SWC_DATE,20030620 -US-Ton,19793,GRP_SWC,SWC,11.43 -US-Ton,19793,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.3500408877 -US-Ton,19793,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19793,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19793,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,19793,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,19793,GRP_SWC,SWC_DATE,20020509 -US-Ton,19850,GRP_SWC,SWC,11.44 -US-Ton,19850,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.27018512172 -US-Ton,19850,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19850,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19850,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,19850,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,19850,GRP_SWC,SWC_DATE,20020829 -US-Ton,19962,GRP_SWC,SWC,11.440740741 -US-Ton,19962,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.5232356222 -US-Ton,19962,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,19962,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19962,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,19962,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,19962,GRP_SWC,SWC_DATE,20030627 -US-Ton,20444,GRP_SWC,SWC,11.452777778 -US-Ton,20444,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.9986959579 -US-Ton,20444,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20444,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20444,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20444,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20444,GRP_SWC,SWC_DATE,20071024 -US-Ton,19883,GRP_SWC,SWC,11.4625 -US-Ton,19883,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.2851244634 -US-Ton,19883,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Ton,19883,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19883,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,19883,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,19883,GRP_SWC,SWC_DATE,20021206 -US-Ton,19859,GRP_SWC,SWC,11.4875 -US-Ton,19859,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.2007010745 -US-Ton,19859,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Ton,19859,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19859,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,19859,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,19859,GRP_SWC,SWC_DATE,20020912 -US-Ton,19987,GRP_SWC,SWC,11.505555556 -US-Ton,19987,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.8088099128 -US-Ton,19987,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,19987,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19987,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,19987,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,19987,GRP_SWC,SWC_DATE,20030731 -US-Ton,20407,GRP_SWC,SWC,11.508333333 -US-Ton,20407,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.3344278506 -US-Ton,20407,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20407,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20407,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20407,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20407,GRP_SWC,SWC_DATE,20070604 -US-Ton,19964,GRP_SWC,SWC,11.52962963 -US-Ton,19964,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.0807626073 -US-Ton,19964,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,19964,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19964,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,19964,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,19964,GRP_SWC,SWC_DATE,20030627 -US-Ton,19972,GRP_SWC,SWC,11.535714286 -US-Ton,19972,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.3702320958 -US-Ton,19972,GRP_SWC,SWC_SPATIAL_REP_NUMBER,7 -US-Ton,19972,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19972,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,19972,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,19972,GRP_SWC,SWC_DATE,20030703 -US-Ton,20798,GRP_SWC,SWC,11.5375 -US-Ton,20798,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.4094487905 -US-Ton,20798,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20798,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20798,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20798,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20798,GRP_SWC,SWC_DATE,20120704 -US-Ton,20968,GRP_SWC,SWC,11.55 -US-Ton,20968,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.5788159556 -US-Ton,20968,GRP_SWC,SWC_SPATIAL_REP_NUMBER,10 -US-Ton,20968,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20968,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20968,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20968,GRP_SWC,SWC_DATE,20141024 -US-Ton,20035,GRP_SWC,SWC,11.562962963 -US-Ton,20035,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.5787352066 -US-Ton,20035,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20035,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20035,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20035,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20035,GRP_SWC,SWC_DATE,20031119 -US-Ton,20911,GRP_SWC,SWC,11.579166667 -US-Ton,20911,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.5597151529 -US-Ton,20911,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20911,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20911,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20911,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20911,GRP_SWC,SWC_DATE,20140124 -US-Ton,20794,GRP_SWC,SWC,11.595454545 -US-Ton,20794,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.3474037881 -US-Ton,20794,GRP_SWC,SWC_SPATIAL_REP_NUMBER,11 -US-Ton,20794,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20794,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20794,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20794,GRP_SWC,SWC_DATE,20120530 -US-Ton,20896,GRP_SWC,SWC,11.61 -US-Ton,20896,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.0772805494 -US-Ton,20896,GRP_SWC,SWC_SPATIAL_REP_NUMBER,10 -US-Ton,20896,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20896,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20896,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20896,GRP_SWC,SWC_DATE,20131107 -US-Ton,19867,GRP_SWC,SWC,11.613333333 -US-Ton,19867,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.5339215305 -US-Ton,19867,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19867,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19867,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,19867,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,19867,GRP_SWC,SWC_DATE,20021002 -US-Ton,20448,GRP_SWC,SWC,11.633333333 -US-Ton,20448,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.4923841278 -US-Ton,20448,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20448,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20448,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20448,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20448,GRP_SWC,SWC_DATE,20071107 -US-Ton,20904,GRP_SWC,SWC,11.640909091 -US-Ton,20904,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.454760223 -US-Ton,20904,GRP_SWC,SWC_SPATIAL_REP_NUMBER,11 -US-Ton,20904,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20904,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20904,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20904,GRP_SWC,SWC_DATE,20131217 -US-Ton,20912,GRP_SWC,SWC,11.65 -US-Ton,20912,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.1114251111 -US-Ton,20912,GRP_SWC,SWC_SPATIAL_REP_NUMBER,10 -US-Ton,20912,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20912,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20912,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20912,GRP_SWC,SWC_DATE,20140124 -US-Ton,19950,GRP_SWC,SWC,11.655555556 -US-Ton,19950,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.5828787653 -US-Ton,19950,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,19950,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19950,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,19950,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,19950,GRP_SWC,SWC_DATE,20030613 -US-Ton,20098,GRP_SWC,SWC,11.666666667 -US-Ton,20098,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.2811359474 -US-Ton,20098,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20098,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20098,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20098,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20098,GRP_SWC,SWC_DATE,20040506 -US-Ton,20460,GRP_SWC,SWC,11.675 -US-Ton,20460,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.8960533477 -US-Ton,20460,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20460,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20460,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20460,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20460,GRP_SWC,SWC_DATE,20071129 -US-Ton,20580,GRP_SWC,SWC,11.675 -US-Ton,20580,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.8052893809 -US-Ton,20580,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20580,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20580,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20580,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20580,GRP_SWC,SWC_DATE,20090621 -US-Ton,19960,GRP_SWC,SWC,11.694444444 -US-Ton,19960,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.790607178 -US-Ton,19960,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,19960,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19960,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,19960,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,19960,GRP_SWC,SWC_DATE,20030625 -US-Ton,19888,GRP_SWC,SWC,11.7 -US-Ton,19888,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.8677081441 -US-Ton,19888,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19888,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19888,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,19888,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,19888,GRP_SWC,SWC_DATE,20021214 -US-Ton,20311,GRP_SWC,SWC,11.708333333 -US-Ton,20311,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.2088139172 -US-Ton,20311,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20311,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20311,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20311,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20311,GRP_SWC,SWC_DATE,20061108 -US-Ton,20606,GRP_SWC,SWC,11.725 -US-Ton,20606,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.9448758478 -US-Ton,20606,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20606,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20606,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20606,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20606,GRP_SWC,SWC_DATE,20091105 -US-Ton,20897,GRP_SWC,SWC,11.725757576 -US-Ton,20897,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.5197014049 -US-Ton,20897,GRP_SWC,SWC_SPATIAL_REP_NUMBER,11 -US-Ton,20897,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20897,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20897,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20897,GRP_SWC,SWC_DATE,20131127 -US-Ton,19970,GRP_SWC,SWC,11.757142857 -US-Ton,19970,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.3285321387 -US-Ton,19970,GRP_SWC,SWC_SPATIAL_REP_NUMBER,7 -US-Ton,19970,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19970,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,19970,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,19970,GRP_SWC,SWC_DATE,20030703 -US-Ton,19946,GRP_SWC,SWC,11.758333333 -US-Ton,19946,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.6033717801 -US-Ton,19946,GRP_SWC,SWC_SPATIAL_REP_NUMBER,8 -US-Ton,19946,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19946,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,19946,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,19946,GRP_SWC,SWC_DATE,20030606 -US-Ton,19863,GRP_SWC,SWC,11.76 -US-Ton,19863,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.512414973 -US-Ton,19863,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19863,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19863,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,19863,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,19863,GRP_SWC,SWC_DATE,20020920 -US-Ton,20970,GRP_SWC,SWC,11.770833333 -US-Ton,20970,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.305162937 -US-Ton,20970,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20970,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20970,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20970,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20970,GRP_SWC,SWC_DATE,20141113 -US-Ton,20500,GRP_SWC,SWC,11.8125 -US-Ton,20500,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.9916645564 -US-Ton,20500,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20500,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20500,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20500,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20500,GRP_SWC,SWC_DATE,20080506 -US-Ton,20295,GRP_SWC,SWC,11.816666667 -US-Ton,20295,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.8062144115 -US-Ton,20295,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20295,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20295,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20295,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20295,GRP_SWC,SWC_DATE,20060801 -US-Ton,20027,GRP_SWC,SWC,11.837037037 -US-Ton,20027,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.9574540934 -US-Ton,20027,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20027,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20027,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20027,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20027,GRP_SWC,SWC_DATE,20031110 -US-Ton,20208,GRP_SWC,SWC,11.854166667 -US-Ton,20208,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.8048356931 -US-Ton,20208,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20208,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20208,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20208,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20208,GRP_SWC,SWC_DATE,20050706 -US-Ton,20892,GRP_SWC,SWC,11.854545455 -US-Ton,20892,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.2410139546 -US-Ton,20892,GRP_SWC,SWC_SPATIAL_REP_NUMBER,11 -US-Ton,20892,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20892,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20892,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20892,GRP_SWC,SWC_DATE,20130925 -US-Ton,19983,GRP_SWC,SWC,11.883333333 -US-Ton,19983,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.0923553817 -US-Ton,19983,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,19983,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19983,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,19983,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,19983,GRP_SWC,SWC_DATE,20030725 -US-Ton,20902,GRP_SWC,SWC,11.883333333 -US-Ton,20902,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.9423188031 -US-Ton,20902,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20902,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20902,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20902,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20902,GRP_SWC,SWC_DATE,20131217 -US-Ton,20748,GRP_SWC,SWC,11.886363636 -US-Ton,20748,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.4635307786 -US-Ton,20748,GRP_SWC,SWC_SPATIAL_REP_NUMBER,11 -US-Ton,20748,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20748,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20748,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20748,GRP_SWC,SWC_DATE,20111201 -US-Ton,20861,GRP_SWC,SWC,11.904166667 -US-Ton,20861,GRP_SWC,SWC_SPATIAL_VARIABILITY,10.334286674 -US-Ton,20861,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20861,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20861,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20861,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20861,GRP_SWC,SWC_DATE,20130508 -US-Ton,20043,GRP_SWC,SWC,11.922222222 -US-Ton,20043,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.1071668391 -US-Ton,20043,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20043,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20043,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20043,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20043,GRP_SWC,SWC_DATE,20031206 -US-Ton,19979,GRP_SWC,SWC,11.940740741 -US-Ton,19979,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.2048529112 -US-Ton,19979,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,19979,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19979,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,19979,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,19979,GRP_SWC,SWC_DATE,20030717 -US-Ton,19967,GRP_SWC,SWC,11.988888889 -US-Ton,19967,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.6226871094 -US-Ton,19967,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,19967,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19967,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,19967,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,19967,GRP_SWC,SWC_DATE,20030702 -US-Ton,19975,GRP_SWC,SWC,11.988888889 -US-Ton,19975,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.0456526943 -US-Ton,19975,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,19975,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19975,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,19975,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,19975,GRP_SWC,SWC_DATE,20030711 -US-Ton,20031,GRP_SWC,SWC,12 -US-Ton,20031,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.9748427642 -US-Ton,20031,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20031,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20031,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20031,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20031,GRP_SWC,SWC_DATE,20031112 -US-Ton,20039,GRP_SWC,SWC,12 -US-Ton,20039,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.9999218742 -US-Ton,20039,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20039,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20039,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20039,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20039,GRP_SWC,SWC_DATE,20031127 -US-Ton,20972,GRP_SWC,SWC,12 -US-Ton,20972,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.2954514107 -US-Ton,20972,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20972,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20972,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20972,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20972,GRP_SWC,SWC_DATE,20141113 -US-Ton,19834,GRP_SWC,SWC,12.01 -US-Ton,19834,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.47486840282 -US-Ton,19834,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19834,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19834,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,19834,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,19834,GRP_SWC,SWC_DATE,20020725 -US-Ton,20572,GRP_SWC,SWC,12.016666667 -US-Ton,20572,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.5900958036 -US-Ton,20572,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20572,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20572,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20572,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20572,GRP_SWC,SWC_DATE,20090527 -US-Ton,19838,GRP_SWC,SWC,12.026666667 -US-Ton,19838,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.5018853344 -US-Ton,19838,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19838,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19838,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,19838,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,19838,GRP_SWC,SWC_DATE,20020801 -US-Ton,20440,GRP_SWC,SWC,12.033333333 -US-Ton,20440,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.5551391778 -US-Ton,20440,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20440,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20440,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20440,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20440,GRP_SWC,SWC_DATE,20070920 -US-Ton,19801,GRP_SWC,SWC,12.046666667 -US-Ton,19801,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.9876848337 -US-Ton,19801,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19801,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19801,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,19801,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,19801,GRP_SWC,SWC_DATE,20020530 -US-Ton,20309,GRP_SWC,SWC,12.066666667 -US-Ton,20309,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.567982062 -US-Ton,20309,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20309,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20309,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20309,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20309,GRP_SWC,SWC_DATE,20061108 -US-Ton,20967,GRP_SWC,SWC,12.075 -US-Ton,20967,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.1925694981 -US-Ton,20967,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20967,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20967,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20967,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20967,GRP_SWC,SWC_DATE,20141024 -US-Ton,19963,GRP_SWC,SWC,12.081481481 -US-Ton,19963,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.9132788077 -US-Ton,19963,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,19963,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19963,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,19963,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,19963,GRP_SWC,SWC_DATE,20030627 -US-Ton,20436,GRP_SWC,SWC,12.083333333 -US-Ton,20436,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.8604672012 -US-Ton,20436,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20436,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20436,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20436,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20436,GRP_SWC,SWC_DATE,20070908 -US-Ton,20721,GRP_SWC,SWC,12.091666667 -US-Ton,20721,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.1216933161 -US-Ton,20721,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20721,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20721,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20721,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20721,GRP_SWC,SWC_DATE,20110720 -US-Ton,20576,GRP_SWC,SWC,12.095833333 -US-Ton,20576,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.6806399297 -US-Ton,20576,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20576,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20576,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20576,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20576,GRP_SWC,SWC_DATE,20090609 -US-Ton,19864,GRP_SWC,SWC,12.113333333 -US-Ton,19864,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.3491743911 -US-Ton,19864,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19864,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19864,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,19864,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,19864,GRP_SWC,SWC_DATE,20020920 -US-Ton,20717,GRP_SWC,SWC,12.116666667 -US-Ton,20717,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.1483154056 -US-Ton,20717,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20717,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20717,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20717,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20717,GRP_SWC,SWC_DATE,20110706 -US-Ton,20522,GRP_SWC,SWC,12.118055556 -US-Ton,20522,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.5773457216 -US-Ton,20522,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20522,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20522,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20522,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20522,GRP_SWC,SWC_DATE,20080904 -US-Ton,20305,GRP_SWC,SWC,12.129166667 -US-Ton,20305,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.0764813482 -US-Ton,20305,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20305,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20305,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20305,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20305,GRP_SWC,SWC_DATE,20061104 -US-Ton,20299,GRP_SWC,SWC,12.135833333 -US-Ton,20299,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.7587956046 -US-Ton,20299,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20299,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20299,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20299,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20299,GRP_SWC,SWC_DATE,20060808 -US-Ton,20901,GRP_SWC,SWC,12.184722222 -US-Ton,20901,GRP_SWC,SWC_SPATIAL_VARIABILITY,8.1794132385 -US-Ton,20901,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20901,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20901,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20901,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20901,GRP_SWC,SWC_DATE,20131217 -US-Ton,20454,GRP_SWC,SWC,12.194444444 -US-Ton,20454,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.8991996803 -US-Ton,20454,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20454,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20454,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20454,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20454,GRP_SWC,SWC_DATE,20071125 -US-Ton,20908,GRP_SWC,SWC,12.277272727 -US-Ton,20908,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.4669170305 -US-Ton,20908,GRP_SWC,SWC_SPATIAL_REP_NUMBER,11 -US-Ton,20908,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20908,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20908,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20908,GRP_SWC,SWC_DATE,20140107 -US-Ton,20648,GRP_SWC,SWC,12.3 -US-Ton,20648,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.592879865 -US-Ton,20648,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20648,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20648,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20648,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20648,GRP_SWC,SWC_DATE,20100624 -US-Ton,20303,GRP_SWC,SWC,12.325 -US-Ton,20303,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.3725099941 -US-Ton,20303,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20303,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20303,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20303,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20303,GRP_SWC,SWC_DATE,20060923 -US-Ton,20907,GRP_SWC,SWC,12.325 -US-Ton,20907,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.4027061423 -US-Ton,20907,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20907,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20907,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20907,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20907,GRP_SWC,SWC_DATE,20140107 -US-Ton,19959,GRP_SWC,SWC,12.331111111 -US-Ton,19959,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.2502201012 -US-Ton,19959,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,19959,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19959,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,19959,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,19959,GRP_SWC,SWC_DATE,20030625 -US-Ton,20103,GRP_SWC,SWC,12.333333333 -US-Ton,20103,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.4029109689 -US-Ton,20103,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20103,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20103,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20103,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20103,GRP_SWC,SWC_DATE,20040522 -US-Ton,19855,GRP_SWC,SWC,12.346666667 -US-Ton,19855,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.6736614245 -US-Ton,19855,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19855,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19855,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,19855,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,19855,GRP_SWC,SWC_DATE,20020905 -US-Ton,20899,GRP_SWC,SWC,12.35 -US-Ton,20899,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.5354053387 -US-Ton,20899,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20899,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20899,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20899,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20899,GRP_SWC,SWC_DATE,20131127 -US-Ton,20315,GRP_SWC,SWC,12.383333333 -US-Ton,20315,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.7942832118 -US-Ton,20315,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20315,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20315,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20315,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20315,GRP_SWC,SWC_DATE,20061114 -US-Ton,20417,GRP_SWC,SWC,12.404166667 -US-Ton,20417,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.1671364645 -US-Ton,20417,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20417,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20417,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20417,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20417,GRP_SWC,SWC_DATE,20070623 -US-Ton,20610,GRP_SWC,SWC,12.405555556 -US-Ton,20610,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.5578007431 -US-Ton,20610,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20610,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20610,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20610,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20610,GRP_SWC,SWC_DATE,20091129 -US-Ton,20964,GRP_SWC,SWC,12.418181818 -US-Ton,20964,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.6559726973 -US-Ton,20964,GRP_SWC,SWC_SPATIAL_REP_NUMBER,11 -US-Ton,20964,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20964,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20964,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20964,GRP_SWC,SWC_DATE,20140930 -US-Ton,20432,GRP_SWC,SWC,12.430555556 -US-Ton,20432,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.7157046526 -US-Ton,20432,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20432,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20432,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20432,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20432,GRP_SWC,SWC_DATE,20070822 -US-Ton,19830,GRP_SWC,SWC,12.433333333 -US-Ton,19830,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.86890735985 -US-Ton,19830,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19830,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19830,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,19830,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,19830,GRP_SWC,SWC_DATE,20020719 -US-Ton,19856,GRP_SWC,SWC,12.433333333 -US-Ton,19856,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.0492423768 -US-Ton,19856,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19856,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19856,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,19856,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,19856,GRP_SWC,SWC_DATE,20020905 -US-Ton,20518,GRP_SWC,SWC,12.447222222 -US-Ton,20518,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.0490014681 -US-Ton,20518,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20518,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20518,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20518,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20518,GRP_SWC,SWC_DATE,20080820 -US-Ton,19847,GRP_SWC,SWC,12.45 -US-Ton,19847,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.4408614029 -US-Ton,19847,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19847,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19847,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,19847,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,19847,GRP_SWC,SWC_DATE,20020823 -US-Ton,19860,GRP_SWC,SWC,12.45 -US-Ton,19860,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.149525727 -US-Ton,19860,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Ton,19860,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19860,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,19860,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,19860,GRP_SWC,SWC_DATE,20020912 -US-Ton,19956,GRP_SWC,SWC,12.455555556 -US-Ton,19956,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.1482928216 -US-Ton,19956,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,19956,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19956,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,19956,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,19956,GRP_SWC,SWC_DATE,20030620 -US-Ton,20287,GRP_SWC,SWC,12.458333333 -US-Ton,20287,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.9952730181 -US-Ton,20287,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20287,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20287,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20287,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20287,GRP_SWC,SWC_DATE,20060623 -US-Ton,19851,GRP_SWC,SWC,12.466666667 -US-Ton,19851,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.5629546958 -US-Ton,19851,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19851,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19851,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,19851,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,19851,GRP_SWC,SWC_DATE,20020829 -US-Ton,19852,GRP_SWC,SWC,12.466666667 -US-Ton,19852,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.6959537295 -US-Ton,19852,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19852,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19852,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,19852,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,19852,GRP_SWC,SWC_DATE,20020829 -US-Ton,20745,GRP_SWC,SWC,12.467777778 -US-Ton,20745,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.5793535945 -US-Ton,20745,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20745,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20745,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20745,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20745,GRP_SWC,SWC_DATE,20111109 -US-Ton,20593,GRP_SWC,SWC,12.475 -US-Ton,20593,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.0919266411 -US-Ton,20593,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20593,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20593,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20593,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20593,GRP_SWC,SWC_DATE,20090907 -US-Ton,20421,GRP_SWC,SWC,12.480555556 -US-Ton,20421,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.1606995519 -US-Ton,20421,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20421,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20421,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20421,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20421,GRP_SWC,SWC_DATE,20070626 -US-Ton,20291,GRP_SWC,SWC,12.502777778 -US-Ton,20291,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.7888645738 -US-Ton,20291,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20291,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20291,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20291,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20291,GRP_SWC,SWC_DATE,20060713 -US-Ton,19826,GRP_SWC,SWC,12.506666667 -US-Ton,19826,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.48154842839 -US-Ton,19826,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19826,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19826,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,19826,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,19826,GRP_SWC,SWC_DATE,20020711 -US-Ton,20428,GRP_SWC,SWC,12.525 -US-Ton,20428,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.3136411534 -US-Ton,20428,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20428,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20428,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20428,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20428,GRP_SWC,SWC_DATE,20070809 -US-Ton,20601,GRP_SWC,SWC,12.533333333 -US-Ton,20601,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.8153794023 -US-Ton,20601,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20601,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20601,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20601,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20601,GRP_SWC,SWC_DATE,20091022 -US-Ton,19822,GRP_SWC,SWC,12.54 -US-Ton,19822,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.32480763538 -US-Ton,19822,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19822,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19822,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,19822,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,19822,GRP_SWC,SWC_DATE,20020705 -US-Ton,20963,GRP_SWC,SWC,12.5625 -US-Ton,20963,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.1723532977 -US-Ton,20963,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20963,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20963,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20963,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20963,GRP_SWC,SWC_DATE,20140930 -US-Ton,20976,GRP_SWC,SWC,12.570833333 -US-Ton,20976,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.1484814762 -US-Ton,20976,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20976,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20976,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20976,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20976,GRP_SWC,SWC_DATE,20141126 -US-Ton,20219,GRP_SWC,SWC,12.604166667 -US-Ton,20219,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.3518782953 -US-Ton,20219,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20219,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20219,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20219,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20219,GRP_SWC,SWC_DATE,20051029 -US-Ton,20458,GRP_SWC,SWC,12.619444444 -US-Ton,20458,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.0438040455 -US-Ton,20458,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20458,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20458,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20458,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20458,GRP_SWC,SWC_DATE,20071129 -US-Ton,20413,GRP_SWC,SWC,12.630555556 -US-Ton,20413,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.0352787397 -US-Ton,20413,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20413,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20413,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20413,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20413,GRP_SWC,SWC_DATE,20070616 -US-Ton,20700,GRP_SWC,SWC,12.636363636 -US-Ton,20700,GRP_SWC,SWC_SPATIAL_VARIABILITY,9.0212829162 -US-Ton,20700,GRP_SWC,SWC_SPATIAL_REP_NUMBER,11 -US-Ton,20700,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20700,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20700,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20700,GRP_SWC,SWC_DATE,20110503 -US-Ton,20529,GRP_SWC,SWC,12.641666667 -US-Ton,20529,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.1333974824 -US-Ton,20529,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20529,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20529,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20529,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20529,GRP_SWC,SWC_DATE,20081030 -US-Ton,20307,GRP_SWC,SWC,12.65 -US-Ton,20307,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.8056398911 -US-Ton,20307,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20307,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20307,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20307,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20307,GRP_SWC,SWC_DATE,20061104 -US-Ton,20960,GRP_SWC,SWC,12.675 -US-Ton,20960,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.1562035294 -US-Ton,20960,GRP_SWC,SWC_SPATIAL_REP_NUMBER,10 -US-Ton,20960,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20960,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20960,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20960,GRP_SWC,SWC_DATE,20140911 -US-Ton,20514,GRP_SWC,SWC,12.691666667 -US-Ton,20514,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.9405480619 -US-Ton,20514,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20514,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20514,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20514,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20514,GRP_SWC,SWC_DATE,20080806 -US-Ton,20526,GRP_SWC,SWC,12.691666667 -US-Ton,20526,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.9405480619 -US-Ton,20526,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20526,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20526,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20526,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20526,GRP_SWC,SWC_DATE,20080919 -US-Ton,20416,GRP_SWC,SWC,12.704166667 -US-Ton,20416,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.369650409 -US-Ton,20416,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20416,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20416,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20416,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20416,GRP_SWC,SWC_DATE,20070623 -US-Ton,20202,GRP_SWC,SWC,12.75 -US-Ton,20202,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.0453115399 -US-Ton,20202,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20202,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20202,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20202,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20202,GRP_SWC,SWC_DATE,20050623 -US-Ton,20605,GRP_SWC,SWC,12.766666667 -US-Ton,20605,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.5969027781 -US-Ton,20605,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20605,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20605,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20605,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20605,GRP_SWC,SWC_DATE,20091105 -US-Ton,20747,GRP_SWC,SWC,12.777272727 -US-Ton,20747,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.1257859708 -US-Ton,20747,GRP_SWC,SWC_SPATIAL_REP_NUMBER,11 -US-Ton,20747,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20747,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20747,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20747,GRP_SWC,SWC_DATE,20111109 -US-Ton,20974,GRP_SWC,SWC,12.790909091 -US-Ton,20974,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.0478655699 -US-Ton,20974,GRP_SWC,SWC_SPATIAL_REP_NUMBER,11 -US-Ton,20974,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20974,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20974,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20974,GRP_SWC,SWC_DATE,20141126 -US-Ton,20971,GRP_SWC,SWC,12.8 -US-Ton,20971,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.4717293787 -US-Ton,20971,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20971,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20971,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20971,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20971,GRP_SWC,SWC_DATE,20141113 -US-Ton,20898,GRP_SWC,SWC,12.806944444 -US-Ton,20898,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.2090948938 -US-Ton,20898,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20898,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20898,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20898,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20898,GRP_SWC,SWC_DATE,20131127 -US-Ton,20602,GRP_SWC,SWC,12.816666667 -US-Ton,20602,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.4836740887 -US-Ton,20602,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20602,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20602,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20602,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20602,GRP_SWC,SWC_DATE,20091022 -US-Ton,19843,GRP_SWC,SWC,12.84 -US-Ton,19843,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.6895510328 -US-Ton,19843,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19843,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19843,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,19843,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,19843,GRP_SWC,SWC_DATE,20020815 -US-Ton,20319,GRP_SWC,SWC,12.854166667 -US-Ton,20319,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.6442431787 -US-Ton,20319,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20319,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20319,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20319,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20319,GRP_SWC,SWC_DATE,20061119 -US-Ton,20763,GRP_SWC,SWC,12.863636364 -US-Ton,20763,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.5420309834 -US-Ton,20763,GRP_SWC,SWC_SPATIAL_REP_NUMBER,11 -US-Ton,20763,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20763,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20763,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20763,GRP_SWC,SWC_DATE,20120118 -US-Ton,19848,GRP_SWC,SWC,12.89 -US-Ton,19848,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.8782863149 -US-Ton,19848,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19848,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19848,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,19848,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,19848,GRP_SWC,SWC_DATE,20020823 -US-Ton,20934,GRP_SWC,SWC,12.891666667 -US-Ton,20934,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.2287031093 -US-Ton,20934,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20934,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20934,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20934,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20934,GRP_SWC,SWC_DATE,20140522 -US-Ton,20662,GRP_SWC,SWC,12.908333333 -US-Ton,20662,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.151250216 -US-Ton,20662,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20662,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20662,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20662,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20662,GRP_SWC,SWC_DATE,20101007 -US-Ton,20215,GRP_SWC,SWC,12.933333333 -US-Ton,20215,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.7365110935 -US-Ton,20215,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20215,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20215,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20215,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20215,GRP_SWC,SWC_DATE,20050925 -US-Ton,20594,GRP_SWC,SWC,12.941666667 -US-Ton,20594,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.4059661206 -US-Ton,20594,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20594,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20594,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20594,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20594,GRP_SWC,SWC_DATE,20090907 -US-Ton,20880,GRP_SWC,SWC,12.95 -US-Ton,20880,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.8876565797 -US-Ton,20880,GRP_SWC,SWC_SPATIAL_REP_NUMBER,11 -US-Ton,20880,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20880,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20880,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20880,GRP_SWC,SWC_DATE,20130728 -US-Ton,20296,GRP_SWC,SWC,12.9625 -US-Ton,20296,GRP_SWC,SWC_SPATIAL_VARIABILITY,9.7083873064 -US-Ton,20296,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20296,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20296,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20296,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20296,GRP_SWC,SWC_DATE,20060801 -US-Ton,20509,GRP_SWC,SWC,12.966666667 -US-Ton,20509,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.7808929521 -US-Ton,20509,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20509,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20509,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20509,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20509,GRP_SWC,SWC_DATE,20080731 -US-Ton,20510,GRP_SWC,SWC,12.975 -US-Ton,20510,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.2393832045 -US-Ton,20510,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20510,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20510,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20510,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20510,GRP_SWC,SWC_DATE,20080731 -US-Ton,19955,GRP_SWC,SWC,12.981481481 -US-Ton,19955,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.3763399134 -US-Ton,19955,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,19955,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19955,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,19955,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,19955,GRP_SWC,SWC_DATE,20030620 -US-Ton,20521,GRP_SWC,SWC,13.031944444 -US-Ton,20521,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.6171062317 -US-Ton,20521,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20521,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20521,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20521,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20521,GRP_SWC,SWC_DATE,20080904 -US-Ton,20459,GRP_SWC,SWC,13.041666667 -US-Ton,20459,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.6974773 -US-Ton,20459,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20459,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20459,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20459,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20459,GRP_SWC,SWC_DATE,20071129 -US-Ton,20757,GRP_SWC,SWC,13.075 -US-Ton,20757,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.6100761622 -US-Ton,20757,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20757,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20757,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20757,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20757,GRP_SWC,SWC_DATE,20120104 -US-Ton,20959,GRP_SWC,SWC,13.104166667 -US-Ton,20959,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.37173038 -US-Ton,20959,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20959,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20959,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20959,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20959,GRP_SWC,SWC_DATE,20140911 -US-Ton,20094,GRP_SWC,SWC,13.116666667 -US-Ton,20094,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.2613818181 -US-Ton,20094,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20094,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20094,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20094,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20094,GRP_SWC,SWC_DATE,20040428 -US-Ton,20820,GRP_SWC,SWC,13.127272727 -US-Ton,20820,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.0169394872 -US-Ton,20820,GRP_SWC,SWC_SPATIAL_REP_NUMBER,11 -US-Ton,20820,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20820,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20820,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20820,GRP_SWC,SWC_DATE,20121009 -US-Ton,20818,GRP_SWC,SWC,13.133333333 -US-Ton,20818,GRP_SWC,SWC_SPATIAL_VARIABILITY,15.371421732 -US-Ton,20818,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20818,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20818,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20818,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20818,GRP_SWC,SWC_DATE,20121009 -US-Ton,20517,GRP_SWC,SWC,13.15 -US-Ton,20517,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.5841824223 -US-Ton,20517,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20517,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20517,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20517,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20517,GRP_SWC,SWC_DATE,20080820 -US-Ton,20948,GRP_SWC,SWC,13.175 -US-Ton,20948,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.2484011171 -US-Ton,20948,GRP_SWC,SWC_SPATIAL_REP_NUMBER,8 -US-Ton,20948,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20948,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20948,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20948,GRP_SWC,SWC_DATE,20140709 -US-Ton,20952,GRP_SWC,SWC,13.175 -US-Ton,20952,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.472215172 -US-Ton,20952,GRP_SWC,SWC_SPATIAL_REP_NUMBER,10 -US-Ton,20952,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20952,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20952,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20952,GRP_SWC,SWC_DATE,20140805 -US-Ton,20975,GRP_SWC,SWC,13.2 -US-Ton,20975,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.7556664766 -US-Ton,20975,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20975,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20975,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20975,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20975,GRP_SWC,SWC_DATE,20141126 -US-Ton,19814,GRP_SWC,SWC,13.24 -US-Ton,19814,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.87920418561 -US-Ton,19814,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19814,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19814,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,19814,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,19814,GRP_SWC,SWC_DATE,20020620 -US-Ton,20278,GRP_SWC,SWC,13.248484848 -US-Ton,20278,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.5809839709 -US-Ton,20278,GRP_SWC,SWC_SPATIAL_REP_NUMBER,11 -US-Ton,20278,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20278,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20278,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20278,GRP_SWC,SWC_DATE,20060526 -US-Ton,20211,GRP_SWC,SWC,13.261111111 -US-Ton,20211,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.7423412251 -US-Ton,20211,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20211,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20211,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20211,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20211,GRP_SWC,SWC_DATE,20050910 -US-Ton,20888,GRP_SWC,SWC,13.263636364 -US-Ton,20888,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.4371224514 -US-Ton,20888,GRP_SWC,SWC_SPATIAL_REP_NUMBER,11 -US-Ton,20888,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20888,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20888,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20888,GRP_SWC,SWC_DATE,20130904 -US-Ton,19818,GRP_SWC,SWC,13.293333333 -US-Ton,19818,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.80117968577 -US-Ton,19818,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19818,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19818,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,19818,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,19818,GRP_SWC,SWC_DATE,20020628 -US-Ton,20657,GRP_SWC,SWC,13.329166667 -US-Ton,20657,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.6517404526 -US-Ton,20657,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20657,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20657,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20657,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20657,GRP_SWC,SWC_DATE,20100902 -US-Ton,19839,GRP_SWC,SWC,13.346666667 -US-Ton,19839,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.5369838243 -US-Ton,19839,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19839,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19839,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,19839,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,19839,GRP_SWC,SWC_DATE,20020801 -US-Ton,20398,GRP_SWC,SWC,13.354545455 -US-Ton,20398,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.1143051341 -US-Ton,20398,GRP_SWC,SWC_SPATIAL_REP_NUMBER,11 -US-Ton,20398,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20398,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20398,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20398,GRP_SWC,SWC_DATE,20070508 -US-Ton,20085,GRP_SWC,SWC,13.377777778 -US-Ton,20085,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.849658849 -US-Ton,20085,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20085,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20085,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20085,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20085,GRP_SWC,SWC_DATE,20040409 -US-Ton,20420,GRP_SWC,SWC,13.386111111 -US-Ton,20420,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.2551563096 -US-Ton,20420,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20420,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20420,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20420,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20420,GRP_SWC,SWC_DATE,20070626 -US-Ton,20403,GRP_SWC,SWC,13.412121212 -US-Ton,20403,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.4696228654 -US-Ton,20403,GRP_SWC,SWC_SPATIAL_REP_NUMBER,11 -US-Ton,20403,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20403,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20403,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20403,GRP_SWC,SWC_DATE,20070515 -US-Ton,19951,GRP_SWC,SWC,13.414814815 -US-Ton,19951,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.9935266738 -US-Ton,19951,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,19951,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19951,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,19951,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,19951,GRP_SWC,SWC_DATE,20030613 -US-Ton,20589,GRP_SWC,SWC,13.416666667 -US-Ton,20589,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.0318805297 -US-Ton,20589,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20589,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20589,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20589,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20589,GRP_SWC,SWC_DATE,20090802 -US-Ton,20455,GRP_SWC,SWC,13.438888889 -US-Ton,20455,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.1277291757 -US-Ton,20455,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20455,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20455,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20455,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20455,GRP_SWC,SWC_DATE,20071125 -US-Ton,20761,GRP_SWC,SWC,13.45 -US-Ton,20761,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.1158140765 -US-Ton,20761,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20761,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20761,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20761,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20761,GRP_SWC,SWC_DATE,20120118 -US-Ton,20895,GRP_SWC,SWC,13.468181818 -US-Ton,20895,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.0020330576 -US-Ton,20895,GRP_SWC,SWC_SPATIAL_REP_NUMBER,11 -US-Ton,20895,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20895,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20895,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20895,GRP_SWC,SWC_DATE,20131107 -US-Ton,20021,GRP_SWC,SWC,13.488888889 -US-Ton,20021,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.5854935349 -US-Ton,20021,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20021,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20021,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20021,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20021,GRP_SWC,SWC_DATE,20031107 -US-Ton,20823,GRP_SWC,SWC,13.488888889 -US-Ton,20823,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.9301061219 -US-Ton,20823,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20823,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20823,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20823,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20823,GRP_SWC,SWC_DATE,20121107 -US-Ton,20755,GRP_SWC,SWC,13.531818182 -US-Ton,20755,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.493083733 -US-Ton,20755,GRP_SWC,SWC_SPATIAL_REP_NUMBER,11 -US-Ton,20755,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20755,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20755,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20755,GRP_SWC,SWC_DATE,20111218 -US-Ton,20513,GRP_SWC,SWC,13.5375 -US-Ton,20513,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.3664875815 -US-Ton,20513,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20513,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20513,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20513,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20513,GRP_SWC,SWC_DATE,20080806 -US-Ton,20525,GRP_SWC,SWC,13.5375 -US-Ton,20525,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.3664875815 -US-Ton,20525,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20525,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20525,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20525,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20525,GRP_SWC,SWC_DATE,20080919 -US-Ton,19835,GRP_SWC,SWC,13.54 -US-Ton,19835,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.5644550606 -US-Ton,19835,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19835,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19835,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,19835,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,19835,GRP_SWC,SWC_DATE,20020725 -US-Ton,20284,GRP_SWC,SWC,13.541666667 -US-Ton,20284,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.2025267741 -US-Ton,20284,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20284,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20284,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20284,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20284,GRP_SWC,SWC_DATE,20060608 -US-Ton,20597,GRP_SWC,SWC,13.573611111 -US-Ton,20597,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.3905903325 -US-Ton,20597,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20597,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20597,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20597,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20597,GRP_SWC,SWC_DATE,20091002 -US-Ton,20496,GRP_SWC,SWC,13.580555556 -US-Ton,20496,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.4520513103 -US-Ton,20496,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20496,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20496,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20496,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20496,GRP_SWC,SWC_DATE,20080420 -US-Ton,20653,GRP_SWC,SWC,13.595833333 -US-Ton,20653,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.4934652199 -US-Ton,20653,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20653,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20653,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20653,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20653,GRP_SWC,SWC_DATE,20100814 -US-Ton,20198,GRP_SWC,SWC,13.616666667 -US-Ton,20198,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.7240358965 -US-Ton,20198,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20198,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20198,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20198,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20198,GRP_SWC,SWC_DATE,20050610 -US-Ton,20887,GRP_SWC,SWC,13.633333333 -US-Ton,20887,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.3075690958 -US-Ton,20887,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20887,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20887,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20887,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20887,GRP_SWC,SWC_DATE,20130904 -US-Ton,20644,GRP_SWC,SWC,13.675 -US-Ton,20644,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.4706217215 -US-Ton,20644,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20644,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20644,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20644,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20644,GRP_SWC,SWC_DATE,20100610 -US-Ton,20815,GRP_SWC,SWC,13.695833333 -US-Ton,20815,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.942823191 -US-Ton,20815,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20815,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20815,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20815,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20815,GRP_SWC,SWC_DATE,20120919 -US-Ton,20734,GRP_SWC,SWC,13.716666667 -US-Ton,20734,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.4457239535 -US-Ton,20734,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20734,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20734,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20734,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20734,GRP_SWC,SWC_DATE,20110929 -US-Ton,20541,GRP_SWC,SWC,13.720833333 -US-Ton,20541,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.6636084009 -US-Ton,20541,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20541,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20541,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20541,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20541,GRP_SWC,SWC_DATE,20081211 -US-Ton,19844,GRP_SWC,SWC,13.733333333 -US-Ton,19844,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.8824125814 -US-Ton,19844,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19844,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19844,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,19844,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,19844,GRP_SWC,SWC_DATE,20020815 -US-Ton,20197,GRP_SWC,SWC,13.745833333 -US-Ton,20197,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.4169959107 -US-Ton,20197,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20197,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20197,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20197,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20197,GRP_SWC,SWC_DATE,20050610 -US-Ton,19831,GRP_SWC,SWC,13.76 -US-Ton,19831,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.1488552638 -US-Ton,19831,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19831,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19831,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,19831,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,19831,GRP_SWC,SWC_DATE,20020719 -US-Ton,20708,GRP_SWC,SWC,13.767361111 -US-Ton,20708,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.4178166179 -US-Ton,20708,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20708,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20708,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20708,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20708,GRP_SWC,SWC_DATE,20110527 -US-Ton,20883,GRP_SWC,SWC,13.783333333 -US-Ton,20883,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.8552076809 -US-Ton,20883,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20883,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20883,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20883,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20883,GRP_SWC,SWC_DATE,20130813 -US-Ton,20424,GRP_SWC,SWC,13.796969697 -US-Ton,20424,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.8650702033 -US-Ton,20424,GRP_SWC,SWC_SPATIAL_REP_NUMBER,11 -US-Ton,20424,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20424,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20424,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20424,GRP_SWC,SWC_DATE,20070717 -US-Ton,19810,GRP_SWC,SWC,13.82 -US-Ton,19810,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.1966620241 -US-Ton,19810,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19810,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19810,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,19810,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,19810,GRP_SWC,SWC_DATE,20020613 -US-Ton,20533,GRP_SWC,SWC,13.830555556 -US-Ton,20533,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.1498620723 -US-Ton,20533,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20533,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20533,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20533,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20533,GRP_SWC,SWC_DATE,20081113 -US-Ton,20884,GRP_SWC,SWC,13.831818182 -US-Ton,20884,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.1426082704 -US-Ton,20884,GRP_SWC,SWC_SPATIAL_REP_NUMBER,11 -US-Ton,20884,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20884,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20884,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20884,GRP_SWC,SWC_DATE,20130813 -US-Ton,19952,GRP_SWC,SWC,13.833333333 -US-Ton,19952,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.9468003127 -US-Ton,19952,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,19952,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19952,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,19952,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,19952,GRP_SWC,SWC_DATE,20030613 -US-Ton,20891,GRP_SWC,SWC,13.855555556 -US-Ton,20891,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.7387633917 -US-Ton,20891,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20891,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20891,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20891,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20891,GRP_SWC,SWC_DATE,20130925 -US-Ton,20903,GRP_SWC,SWC,13.863888889 -US-Ton,20903,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.072282754 -US-Ton,20903,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20903,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20903,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20903,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20903,GRP_SWC,SWC_DATE,20131217 -US-Ton,20409,GRP_SWC,SWC,13.875 -US-Ton,20409,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.1410435014 -US-Ton,20409,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20409,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20409,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20409,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20409,GRP_SWC,SWC_DATE,20070604 -US-Ton,20951,GRP_SWC,SWC,13.881818182 -US-Ton,20951,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.7223020195 -US-Ton,20951,GRP_SWC,SWC_SPATIAL_REP_NUMBER,11 -US-Ton,20951,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20951,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20951,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20951,GRP_SWC,SWC_DATE,20140805 -US-Ton,20735,GRP_SWC,SWC,13.904545455 -US-Ton,20735,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.4162038401 -US-Ton,20735,GRP_SWC,SWC_SPATIAL_REP_NUMBER,11 -US-Ton,20735,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20735,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20735,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20735,GRP_SWC,SWC_DATE,20110929 -US-Ton,20956,GRP_SWC,SWC,13.91 -US-Ton,20956,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.5398115477 -US-Ton,20956,GRP_SWC,SWC_SPATIAL_REP_NUMBER,10 -US-Ton,20956,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20956,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20956,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20956,GRP_SWC,SWC_DATE,20140821 -US-Ton,20705,GRP_SWC,SWC,13.925 -US-Ton,20705,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.246059127 -US-Ton,20705,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20705,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20705,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20705,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20705,GRP_SWC,SWC_DATE,20110510 -US-Ton,20273,GRP_SWC,SWC,13.930555556 -US-Ton,20273,GRP_SWC,SWC_SPATIAL_VARIABILITY,8.5652393379 -US-Ton,20273,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20273,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20273,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20273,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20273,GRP_SWC,SWC_DATE,20060512 -US-Ton,20590,GRP_SWC,SWC,13.933333333 -US-Ton,20590,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.7529965841 -US-Ton,20590,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20590,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20590,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20590,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20590,GRP_SWC,SWC_DATE,20090802 -US-Ton,20283,GRP_SWC,SWC,13.947222222 -US-Ton,20283,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.7787716255 -US-Ton,20283,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20283,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20283,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20283,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20283,GRP_SWC,SWC_DATE,20060608 -US-Ton,20539,GRP_SWC,SWC,13.9625 -US-Ton,20539,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.0856168334 -US-Ton,20539,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20539,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20539,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20539,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20539,GRP_SWC,SWC_DATE,20081211 -US-Ton,19971,GRP_SWC,SWC,14.007142857 -US-Ton,19971,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.3269641531 -US-Ton,19971,GRP_SWC,SWC_SPATIAL_REP_NUMBER,7 -US-Ton,19971,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19971,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,19971,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,19971,GRP_SWC,SWC_DATE,20030703 -US-Ton,19827,GRP_SWC,SWC,14.013333333 -US-Ton,19827,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.5793376523 -US-Ton,19827,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19827,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19827,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,19827,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,19827,GRP_SWC,SWC_DATE,20020711 -US-Ton,19840,GRP_SWC,SWC,14.013333333 -US-Ton,19840,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.7647684737 -US-Ton,19840,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19840,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19840,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,19840,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,19840,GRP_SWC,SWC_DATE,20020801 -US-Ton,20739,GRP_SWC,SWC,14.018181818 -US-Ton,20739,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.4325062273 -US-Ton,20739,GRP_SWC,SWC_SPATIAL_REP_NUMBER,11 -US-Ton,20739,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20739,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20739,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20739,GRP_SWC,SWC_DATE,20111013 -US-Ton,20491,GRP_SWC,SWC,14.030555556 -US-Ton,20491,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.6451116552 -US-Ton,20491,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20491,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20491,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20491,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20491,GRP_SWC,SWC_DATE,20080408 -US-Ton,20973,GRP_SWC,SWC,14.031818182 -US-Ton,20973,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.2080299906 -US-Ton,20973,GRP_SWC,SWC_SPATIAL_REP_NUMBER,11 -US-Ton,20973,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20973,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20973,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20973,GRP_SWC,SWC_DATE,20141126 -US-Ton,19789,GRP_SWC,SWC,14.054 -US-Ton,19789,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.2704392606 -US-Ton,19789,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19789,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19789,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,19789,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,19789,GRP_SWC,SWC_DATE,20020502 -US-Ton,19823,GRP_SWC,SWC,14.09 -US-Ton,19823,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.4060186109 -US-Ton,19823,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19823,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19823,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,19823,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,19823,GRP_SWC,SWC_DATE,20020705 -US-Ton,20314,GRP_SWC,SWC,14.1 -US-Ton,20314,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.4571054599 -US-Ton,20314,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20314,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20314,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20314,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20314,GRP_SWC,SWC_DATE,20061114 -US-Ton,20661,GRP_SWC,SWC,14.116666667 -US-Ton,20661,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.4800415441 -US-Ton,20661,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20661,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20661,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20661,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20661,GRP_SWC,SWC_DATE,20101007 -US-Ton,20821,GRP_SWC,SWC,14.116666667 -US-Ton,20821,GRP_SWC,SWC_SPATIAL_VARIABILITY,10.497755893 -US-Ton,20821,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20821,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20821,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20821,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20821,GRP_SWC,SWC_DATE,20121107 -US-Ton,20204,GRP_SWC,SWC,14.135416667 -US-Ton,20204,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.6865561432 -US-Ton,20204,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20204,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20204,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20204,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20204,GRP_SWC,SWC_DATE,20050623 -US-Ton,20955,GRP_SWC,SWC,14.140909091 -US-Ton,20955,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.0009013797 -US-Ton,20955,GRP_SWC,SWC_SPATIAL_REP_NUMBER,11 -US-Ton,20955,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20955,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20955,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20955,GRP_SWC,SWC_DATE,20140821 -US-Ton,20585,GRP_SWC,SWC,14.141666667 -US-Ton,20585,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.6021353095 -US-Ton,20585,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20585,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20585,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20585,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20585,GRP_SWC,SWC_DATE,20090705 -US-Ton,19819,GRP_SWC,SWC,14.146666667 -US-Ton,19819,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.34092924 -US-Ton,19819,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19819,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19819,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,19819,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,19819,GRP_SWC,SWC_DATE,20020628 -US-Ton,20317,GRP_SWC,SWC,14.15 -US-Ton,20317,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.142734067 -US-Ton,20317,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20317,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20317,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20317,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20317,GRP_SWC,SWC_DATE,20061119 -US-Ton,19942,GRP_SWC,SWC,14.151851852 -US-Ton,19942,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.0650521307 -US-Ton,19942,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,19942,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19942,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,19942,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,19942,GRP_SWC,SWC_DATE,20030530 -US-Ton,20811,GRP_SWC,SWC,14.1625 -US-Ton,20811,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.2290672028 -US-Ton,20811,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20811,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20811,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20811,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20811,GRP_SWC,SWC_DATE,20120905 -US-Ton,20670,GRP_SWC,SWC,14.170833333 -US-Ton,20670,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.3260277853 -US-Ton,20670,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20670,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20670,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20670,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20670,GRP_SWC,SWC_DATE,20101112 -US-Ton,20277,GRP_SWC,SWC,14.175757576 -US-Ton,20277,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.6053563849 -US-Ton,20277,GRP_SWC,SWC_SPATIAL_REP_NUMBER,11 -US-Ton,20277,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20277,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20277,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20277,GRP_SWC,SWC_DATE,20060526 -US-Ton,20713,GRP_SWC,SWC,14.183333333 -US-Ton,20713,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.788991643 -US-Ton,20713,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20713,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20713,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20713,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20713,GRP_SWC,SWC_DATE,20110615 -US-Ton,20751,GRP_SWC,SWC,14.190909091 -US-Ton,20751,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.8551181962 -US-Ton,20751,GRP_SWC,SWC_SPATIAL_REP_NUMBER,11 -US-Ton,20751,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20751,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20751,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20751,GRP_SWC,SWC_DATE,20111201 -US-Ton,19937,GRP_SWC,SWC,14.196296296 -US-Ton,19937,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.3349592429 -US-Ton,19937,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,19937,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19937,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,19937,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,19937,GRP_SWC,SWC_DATE,20030521 -US-Ton,20876,GRP_SWC,SWC,14.204545455 -US-Ton,20876,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.5591712337 -US-Ton,20876,GRP_SWC,SWC_SPATIAL_REP_NUMBER,11 -US-Ton,20876,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20876,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20876,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20876,GRP_SWC,SWC_DATE,20130711 -US-Ton,20666,GRP_SWC,SWC,14.208333333 -US-Ton,20666,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.265124603 -US-Ton,20666,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20666,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20666,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20666,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20666,GRP_SWC,SWC_DATE,20101028 -US-Ton,20812,GRP_SWC,SWC,14.213636364 -US-Ton,20812,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.9694258899 -US-Ton,20812,GRP_SWC,SWC_SPATIAL_REP_NUMBER,11 -US-Ton,20812,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20812,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20812,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20812,GRP_SWC,SWC_DATE,20120905 -US-Ton,20451,GRP_SWC,SWC,14.241666667 -US-Ton,20451,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.3584529756 -US-Ton,20451,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20451,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20451,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20451,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20451,GRP_SWC,SWC_DATE,20071111 -US-Ton,20207,GRP_SWC,SWC,14.283333333 -US-Ton,20207,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.0909730635 -US-Ton,20207,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20207,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20207,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20207,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20207,GRP_SWC,SWC_DATE,20050706 -US-Ton,19806,GRP_SWC,SWC,14.3 -US-Ton,19806,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.7906004579 -US-Ton,19806,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19806,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19806,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,19806,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,19806,GRP_SWC,SWC_DATE,20020606 -US-Ton,20819,GRP_SWC,SWC,14.320833333 -US-Ton,20819,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.1399521083 -US-Ton,20819,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20819,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20819,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20819,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20819,GRP_SWC,SWC_DATE,20121009 -US-Ton,20738,GRP_SWC,SWC,14.404166667 -US-Ton,20738,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.3563006105 -US-Ton,20738,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20738,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20738,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20738,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20738,GRP_SWC,SWC_DATE,20111013 -US-Ton,19836,GRP_SWC,SWC,14.43 -US-Ton,19836,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.7919772099 -US-Ton,19836,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19836,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19836,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,19836,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,19836,GRP_SWC,SWC_DATE,20020725 -US-Ton,20412,GRP_SWC,SWC,14.436111111 -US-Ton,20412,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.2717171419 -US-Ton,20412,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20412,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20412,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20412,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20412,GRP_SWC,SWC_DATE,20070616 -US-Ton,19815,GRP_SWC,SWC,14.44 -US-Ton,19815,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.1299986548 -US-Ton,19815,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19815,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19815,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,19815,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,19815,GRP_SWC,SWC_DATE,20020620 -US-Ton,20599,GRP_SWC,SWC,14.45 -US-Ton,20599,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.6164395809 -US-Ton,20599,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20599,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20599,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20599,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20599,GRP_SWC,SWC_DATE,20091022 -US-Ton,19798,GRP_SWC,SWC,14.46 -US-Ton,19798,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.4205632686 -US-Ton,19798,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19798,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19798,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,19798,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,19798,GRP_SWC,SWC_DATE,20020516 -US-Ton,19832,GRP_SWC,SWC,14.466666667 -US-Ton,19832,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.5501251237 -US-Ton,19832,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19832,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19832,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,19832,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,19832,GRP_SWC,SWC_DATE,20020719 -US-Ton,20753,GRP_SWC,SWC,14.466666667 -US-Ton,20753,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.2052885558 -US-Ton,20753,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20753,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20753,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20753,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20753,GRP_SWC,SWC_DATE,20111218 -US-Ton,20731,GRP_SWC,SWC,14.478787879 -US-Ton,20731,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.0335593462 -US-Ton,20731,GRP_SWC,SWC_SPATIAL_REP_NUMBER,11 -US-Ton,20731,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20731,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20731,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20731,GRP_SWC,SWC_DATE,20110916 -US-Ton,20758,GRP_SWC,SWC,14.523611111 -US-Ton,20758,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.092467701 -US-Ton,20758,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20758,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20758,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20758,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20758,GRP_SWC,SWC_DATE,20120104 -US-Ton,20537,GRP_SWC,SWC,14.525 -US-Ton,20537,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.1447286341 -US-Ton,20537,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20537,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20537,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20537,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20537,GRP_SWC,SWC_DATE,20081126 -US-Ton,20545,GRP_SWC,SWC,14.525 -US-Ton,20545,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.1447286341 -US-Ton,20545,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20545,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20545,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20545,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20545,GRP_SWC,SWC_DATE,20090108 -US-Ton,20816,GRP_SWC,SWC,14.525757576 -US-Ton,20816,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.2345514123 -US-Ton,20816,GRP_SWC,SWC_SPATIAL_REP_NUMBER,11 -US-Ton,20816,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20816,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20816,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20816,GRP_SWC,SWC_DATE,20120919 -US-Ton,20750,GRP_SWC,SWC,14.570833333 -US-Ton,20750,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.2073394761 -US-Ton,20750,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20750,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20750,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20750,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20750,GRP_SWC,SWC_DATE,20111201 -US-Ton,20762,GRP_SWC,SWC,14.6 -US-Ton,20762,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.9604207318 -US-Ton,20762,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20762,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20762,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20762,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20762,GRP_SWC,SWC_DATE,20120118 -US-Ton,19735,GRP_SWC,SWC,14.62 -US-Ton,19735,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.0831360497 -US-Ton,19735,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19735,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19735,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,19735,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,19735,GRP_SWC,SWC_DATE,20011110 -US-Ton,19828,GRP_SWC,SWC,14.693333333 -US-Ton,19828,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.4350406316 -US-Ton,19828,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19828,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19828,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,19828,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,19828,GRP_SWC,SWC_DATE,20020711 -US-Ton,20803,GRP_SWC,SWC,14.731944444 -US-Ton,20803,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.1030244153 -US-Ton,20803,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20803,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20803,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20803,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20803,GRP_SWC,SWC_DATE,20120725 -US-Ton,20099,GRP_SWC,SWC,14.733333333 -US-Ton,20099,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.4922235037 -US-Ton,20099,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20099,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20099,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20099,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20099,GRP_SWC,SWC_DATE,20040506 -US-Ton,20807,GRP_SWC,SWC,14.806944444 -US-Ton,20807,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.2622686716 -US-Ton,20807,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20807,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20807,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20807,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20807,GRP_SWC,SWC_DATE,20120822 -US-Ton,20408,GRP_SWC,SWC,14.811111111 -US-Ton,20408,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.1168373988 -US-Ton,20408,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20408,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20408,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20408,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20408,GRP_SWC,SWC_DATE,20070604 -US-Ton,20318,GRP_SWC,SWC,14.85 -US-Ton,20318,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.2231129694 -US-Ton,20318,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20318,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20318,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20318,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20318,GRP_SWC,SWC_DATE,20061119 -US-Ton,20582,GRP_SWC,SWC,14.858333333 -US-Ton,20582,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.2366641591 -US-Ton,20582,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20582,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20582,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20582,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20582,GRP_SWC,SWC_DATE,20090621 -US-Ton,19824,GRP_SWC,SWC,14.87 -US-Ton,19824,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.2531657122 -US-Ton,19824,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19824,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19824,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,19824,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,19824,GRP_SWC,SWC_DATE,20020705 -US-Ton,20505,GRP_SWC,SWC,14.891666667 -US-Ton,20505,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.9956131247 -US-Ton,20505,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20505,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20505,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20505,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20505,GRP_SWC,SWC_DATE,20080531 -US-Ton,20609,GRP_SWC,SWC,14.895833333 -US-Ton,20609,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.4265022457 -US-Ton,20609,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20609,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20609,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20609,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20609,GRP_SWC,SWC_DATE,20091129 -US-Ton,20581,GRP_SWC,SWC,14.908333333 -US-Ton,20581,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.145634798 -US-Ton,20581,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20581,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20581,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20581,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20581,GRP_SWC,SWC_DATE,20090621 -US-Ton,20746,GRP_SWC,SWC,14.911111111 -US-Ton,20746,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.9496219012 -US-Ton,20746,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20746,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20746,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20746,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20746,GRP_SWC,SWC_DATE,20111109 -US-Ton,20871,GRP_SWC,SWC,14.95 -US-Ton,20871,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.0590485086 -US-Ton,20871,GRP_SWC,SWC_SPATIAL_REP_NUMBER,10 -US-Ton,20871,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20871,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20871,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20871,GRP_SWC,SWC_DATE,20130619 -US-Ton,20600,GRP_SWC,SWC,15.008333333 -US-Ton,20600,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.8855111594 -US-Ton,20600,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20600,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20600,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20600,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20600,GRP_SWC,SWC_DATE,20091022 -US-Ton,19820,GRP_SWC,SWC,15.013333333 -US-Ton,19820,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.6689637204 -US-Ton,19820,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19820,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19820,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,19820,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,19820,GRP_SWC,SWC_DATE,20020628 -US-Ton,19811,GRP_SWC,SWC,15.026666667 -US-Ton,19811,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.920487498 -US-Ton,19811,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19811,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19811,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,19811,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,19811,GRP_SWC,SWC_DATE,20020613 -US-Ton,20726,GRP_SWC,SWC,15.068055556 -US-Ton,20726,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.4710082424 -US-Ton,20726,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20726,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20726,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20726,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20726,GRP_SWC,SWC_DATE,20110831 -US-Ton,20540,GRP_SWC,SWC,15.091666667 -US-Ton,20540,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.2055608929 -US-Ton,20540,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20540,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20540,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20540,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20540,GRP_SWC,SWC_DATE,20081211 -US-Ton,20749,GRP_SWC,SWC,15.095833333 -US-Ton,20749,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.1213656503 -US-Ton,20749,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20749,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20749,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20749,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20749,GRP_SWC,SWC_DATE,20111201 -US-Ton,20730,GRP_SWC,SWC,15.105555556 -US-Ton,20730,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.3980982926 -US-Ton,20730,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20730,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20730,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20730,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20730,GRP_SWC,SWC_DATE,20110916 -US-Ton,20100,GRP_SWC,SWC,15.138888889 -US-Ton,20100,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.9089515204 -US-Ton,20100,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20100,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20100,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20100,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20100,GRP_SWC,SWC_DATE,20040506 -US-Ton,20578,GRP_SWC,SWC,15.141666667 -US-Ton,20578,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.6986861478 -US-Ton,20578,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20578,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20578,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20578,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20578,GRP_SWC,SWC_DATE,20090609 -US-Ton,20722,GRP_SWC,SWC,15.146969697 -US-Ton,20722,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.8736428505 -US-Ton,20722,GRP_SWC,SWC_SPATIAL_REP_NUMBER,11 -US-Ton,20722,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20722,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20722,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20722,GRP_SWC,SWC_DATE,20110720 -US-Ton,20608,GRP_SWC,SWC,15.181944444 -US-Ton,20608,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.5851971214 -US-Ton,20608,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20608,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20608,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20608,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20608,GRP_SWC,SWC_DATE,20091129 -US-Ton,20857,GRP_SWC,SWC,15.191666667 -US-Ton,20857,GRP_SWC,SWC_SPATIAL_VARIABILITY,12.022173327 -US-Ton,20857,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20857,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20857,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20857,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20857,GRP_SWC,SWC_DATE,20130424 -US-Ton,20727,GRP_SWC,SWC,15.204545455 -US-Ton,20727,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.5815233415 -US-Ton,20727,GRP_SWC,SWC_SPATIAL_REP_NUMBER,11 -US-Ton,20727,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20727,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20727,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20727,GRP_SWC,SWC_DATE,20110831 -US-Ton,20808,GRP_SWC,SWC,15.204545455 -US-Ton,20808,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.6195715324 -US-Ton,20808,GRP_SWC,SWC_SPATIAL_REP_NUMBER,11 -US-Ton,20808,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20808,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20808,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20808,GRP_SWC,SWC_DATE,20120822 -US-Ton,20867,GRP_SWC,SWC,15.215277778 -US-Ton,20867,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.3914439159 -US-Ton,20867,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20867,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20867,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20867,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20867,GRP_SWC,SWC_DATE,20130530 -US-Ton,20944,GRP_SWC,SWC,15.272727273 -US-Ton,20944,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.9579917122 -US-Ton,20944,GRP_SWC,SWC_SPATIAL_REP_NUMBER,11 -US-Ton,20944,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20944,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20944,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20944,GRP_SWC,SWC_DATE,20140625 -US-Ton,20879,GRP_SWC,SWC,15.295454545 -US-Ton,20879,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.8276523562 -US-Ton,20879,GRP_SWC,SWC_SPATIAL_REP_NUMBER,11 -US-Ton,20879,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20879,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20879,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20879,GRP_SWC,SWC_DATE,20130728 -US-Ton,20875,GRP_SWC,SWC,15.3125 -US-Ton,20875,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.4020204555 -US-Ton,20875,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20875,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20875,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20875,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20875,GRP_SWC,SWC_DATE,20130711 -US-Ton,20947,GRP_SWC,SWC,15.3375 -US-Ton,20947,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.0653513295 -US-Ton,20947,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20947,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20947,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20947,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20947,GRP_SWC,SWC_DATE,20140709 -US-Ton,19816,GRP_SWC,SWC,15.34 -US-Ton,19816,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.2639574732 -US-Ton,19816,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19816,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19816,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,19816,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,19816,GRP_SWC,SWC_DATE,20020620 -US-Ton,20943,GRP_SWC,SWC,15.383333333 -US-Ton,20943,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.5239415847 -US-Ton,20943,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20943,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20943,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20943,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20943,GRP_SWC,SWC_DATE,20140625 -US-Ton,20577,GRP_SWC,SWC,15.3875 -US-Ton,20577,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.4943824618 -US-Ton,20577,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20577,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20577,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20577,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20577,GRP_SWC,SWC_DATE,20090609 -US-Ton,20824,GRP_SWC,SWC,15.390909091 -US-Ton,20824,GRP_SWC,SWC_SPATIAL_VARIABILITY,10.03117187 -US-Ton,20824,GRP_SWC,SWC_SPATIAL_REP_NUMBER,11 -US-Ton,20824,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20824,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20824,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20824,GRP_SWC,SWC_DATE,20121107 -US-Ton,20709,GRP_SWC,SWC,15.455555556 -US-Ton,20709,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.1843780598 -US-Ton,20709,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20709,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20709,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20709,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20709,GRP_SWC,SWC_DATE,20110527 -US-Ton,20465,GRP_SWC,SWC,15.484259259 -US-Ton,20465,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.5984809433 -US-Ton,20465,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20465,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20465,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20465,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20465,GRP_SWC,SWC_DATE,20071221 -US-Ton,20487,GRP_SWC,SWC,15.495833333 -US-Ton,20487,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.6321239156 -US-Ton,20487,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20487,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20487,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20487,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20487,GRP_SWC,SWC_DATE,20080404 -US-Ton,20718,GRP_SWC,SWC,15.525 -US-Ton,20718,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.5538295665 -US-Ton,20718,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20718,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20718,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20718,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20718,GRP_SWC,SWC_DATE,20110706 -US-Ton,20090,GRP_SWC,SWC,15.55 -US-Ton,20090,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.5414755311 -US-Ton,20090,GRP_SWC,SWC_SPATIAL_REP_NUMBER,8 -US-Ton,20090,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20090,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20090,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20090,GRP_SWC,SWC_DATE,20040423 -US-Ton,20858,GRP_SWC,SWC,15.558333333 -US-Ton,20858,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.4551893618 -US-Ton,20858,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20858,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20858,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20858,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20858,GRP_SWC,SWC_DATE,20130424 -US-Ton,20203,GRP_SWC,SWC,15.559722222 -US-Ton,20203,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.1052778196 -US-Ton,20203,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20203,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20203,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20203,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20203,GRP_SWC,SWC_DATE,20050623 -US-Ton,20586,GRP_SWC,SWC,15.566666667 -US-Ton,20586,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.7483780318 -US-Ton,20586,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20586,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20586,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20586,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20586,GRP_SWC,SWC_DATE,20090705 -US-Ton,20799,GRP_SWC,SWC,15.606944444 -US-Ton,20799,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.7987502472 -US-Ton,20799,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20799,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20799,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20799,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20799,GRP_SWC,SWC_DATE,20120704 -US-Ton,19785,GRP_SWC,SWC,15.62 -US-Ton,19785,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.9238416589 -US-Ton,19785,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19785,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19785,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,19785,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,19785,GRP_SWC,SWC_DATE,20020426 -US-Ton,20754,GRP_SWC,SWC,15.658333333 -US-Ton,20754,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.1182980451 -US-Ton,20754,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20754,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20754,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20754,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20754,GRP_SWC,SWC_DATE,20111218 -US-Ton,19881,GRP_SWC,SWC,15.6625 -US-Ton,19881,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.5083703292 -US-Ton,19881,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Ton,19881,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19881,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,19881,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,19881,GRP_SWC,SWC_DATE,20021206 -US-Ton,20742,GRP_SWC,SWC,15.7 -US-Ton,20742,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.5630823111 -US-Ton,20742,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20742,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20742,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20742,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20742,GRP_SWC,SWC_DATE,20111026 -US-Ton,19947,GRP_SWC,SWC,15.8 -US-Ton,19947,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.8078031829 -US-Ton,19947,GRP_SWC,SWC_SPATIAL_REP_NUMBER,8 -US-Ton,19947,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19947,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,19947,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,19947,GRP_SWC,SWC_DATE,20030606 -US-Ton,20037,GRP_SWC,SWC,15.8 -US-Ton,20037,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.7684931853 -US-Ton,20037,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20037,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20037,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20037,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20037,GRP_SWC,SWC_DATE,20031127 -US-Ton,19887,GRP_SWC,SWC,15.88 -US-Ton,19887,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.7803765542 -US-Ton,19887,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19887,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19887,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,19887,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,19887,GRP_SWC,SWC_DATE,20021214 -US-Ton,20980,GRP_SWC,SWC,15.918181818 -US-Ton,20980,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.1292451468 -US-Ton,20980,GRP_SWC,SWC_SPATIAL_REP_NUMBER,11 -US-Ton,20980,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20980,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20980,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20980,GRP_SWC,SWC_DATE,20141209 -US-Ton,20649,GRP_SWC,SWC,15.941666667 -US-Ton,20649,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.0369786932 -US-Ton,20649,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20649,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20649,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20649,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20649,GRP_SWC,SWC_DATE,20100624 -US-Ton,20506,GRP_SWC,SWC,15.954166667 -US-Ton,20506,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.481682652 -US-Ton,20506,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20506,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20506,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20506,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20506,GRP_SWC,SWC_DATE,20080531 -US-Ton,19807,GRP_SWC,SWC,15.96 -US-Ton,19807,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.6044070247 -US-Ton,19807,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19807,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19807,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,19807,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,19807,GRP_SWC,SWC_DATE,20020606 -US-Ton,20741,GRP_SWC,SWC,15.983333333 -US-Ton,20741,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.6550428969 -US-Ton,20741,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20741,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20741,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20741,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20741,GRP_SWC,SWC_DATE,20111026 -US-Ton,19948,GRP_SWC,SWC,16.0875 -US-Ton,19948,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.9477171653 -US-Ton,19948,GRP_SWC,SWC_SPATIAL_REP_NUMBER,8 -US-Ton,19948,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19948,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,19948,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,19948,GRP_SWC,SWC_DATE,20030606 -US-Ton,19812,GRP_SWC,SWC,16.126666667 -US-Ton,19812,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.583248061 -US-Ton,19812,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19812,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19812,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,19812,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,19812,GRP_SWC,SWC_DATE,20020613 -US-Ton,20221,GRP_SWC,SWC,16.168055556 -US-Ton,20221,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.1392196697 -US-Ton,20221,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20221,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20221,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20221,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20221,GRP_SWC,SWC_DATE,20051213 -US-Ton,19802,GRP_SWC,SWC,16.2 -US-Ton,19802,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.1863211109 -US-Ton,19802,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19802,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19802,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,19802,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,19802,GRP_SWC,SWC_DATE,20020530 -US-Ton,20939,GRP_SWC,SWC,16.313636364 -US-Ton,20939,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.1736129977 -US-Ton,20939,GRP_SWC,SWC_SPATIAL_REP_NUMBER,11 -US-Ton,20939,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20939,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20939,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20939,GRP_SWC,SWC_DATE,20140611 -US-Ton,20323,GRP_SWC,SWC,16.313888889 -US-Ton,20323,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.3211279254 -US-Ton,20323,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20323,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20323,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20323,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20323,GRP_SWC,SWC_DATE,20061219 -US-Ton,20701,GRP_SWC,SWC,16.354166667 -US-Ton,20701,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.1077245552 -US-Ton,20701,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20701,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20701,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20701,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20701,GRP_SWC,SWC_DATE,20110503 -US-Ton,19794,GRP_SWC,SWC,16.39 -US-Ton,19794,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.0126697389 -US-Ton,19794,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19794,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19794,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,19794,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,19794,GRP_SWC,SWC_DATE,20020509 -US-Ton,20736,GRP_SWC,SWC,16.431818182 -US-Ton,20736,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.364128877 -US-Ton,20736,GRP_SWC,SWC_SPATIAL_REP_NUMBER,11 -US-Ton,20736,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20736,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20736,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20736,GRP_SWC,SWC_DATE,20111013 -US-Ton,20573,GRP_SWC,SWC,16.466666667 -US-Ton,20573,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.6349136176 -US-Ton,20573,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20573,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20573,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20573,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20573,GRP_SWC,SWC_DATE,20090527 -US-Ton,20849,GRP_SWC,SWC,16.4875 -US-Ton,20849,GRP_SWC,SWC_SPATIAL_VARIABILITY,9.1912538713 -US-Ton,20849,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20849,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20849,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20849,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20849,GRP_SWC,SWC_DATE,20130327 -US-Ton,20872,GRP_SWC,SWC,16.5 -US-Ton,20872,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.2202262199 -US-Ton,20872,GRP_SWC,SWC_SPATIAL_REP_NUMBER,10 -US-Ton,20872,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20872,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20872,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20872,GRP_SWC,SWC_DATE,20130619 -US-Ton,20029,GRP_SWC,SWC,16.516666667 -US-Ton,20029,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.37941679 -US-Ton,20029,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20029,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20029,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20029,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20029,GRP_SWC,SWC_DATE,20031112 -US-Ton,20536,GRP_SWC,SWC,16.608333333 -US-Ton,20536,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.0402846841 -US-Ton,20536,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20536,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20536,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20536,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20536,GRP_SWC,SWC_DATE,20081126 -US-Ton,20544,GRP_SWC,SWC,16.608333333 -US-Ton,20544,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.0402846841 -US-Ton,20544,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20544,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20544,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20544,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20544,GRP_SWC,SWC_DATE,20090108 -US-Ton,20077,GRP_SWC,SWC,16.727777778 -US-Ton,20077,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.9774561218 -US-Ton,20077,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20077,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20077,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20077,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20077,GRP_SWC,SWC_DATE,20040325 -US-Ton,20535,GRP_SWC,SWC,16.733333333 -US-Ton,20535,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.6149691707 -US-Ton,20535,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20535,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20535,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20535,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20535,GRP_SWC,SWC_DATE,20081126 -US-Ton,20543,GRP_SWC,SWC,16.733333333 -US-Ton,20543,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.6149691707 -US-Ton,20543,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20543,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20543,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20543,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20543,GRP_SWC,SWC_DATE,20090108 -US-Ton,20804,GRP_SWC,SWC,16.756666667 -US-Ton,20804,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.0522967102 -US-Ton,20804,GRP_SWC,SWC_SPATIAL_REP_NUMBER,10 -US-Ton,20804,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20804,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20804,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20804,GRP_SWC,SWC_DATE,20120725 -US-Ton,20743,GRP_SWC,SWC,16.793939394 -US-Ton,20743,GRP_SWC,SWC_SPATIAL_VARIABILITY,9.6306780445 -US-Ton,20743,GRP_SWC,SWC_SPATIAL_REP_NUMBER,11 -US-Ton,20743,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20743,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20743,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20743,GRP_SWC,SWC_DATE,20111026 -US-Ton,20665,GRP_SWC,SWC,16.879166667 -US-Ton,20665,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.6819867619 -US-Ton,20665,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20665,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20665,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20665,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20665,GRP_SWC,SWC_DATE,20101028 -US-Ton,20607,GRP_SWC,SWC,16.9125 -US-Ton,20607,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.2420528544 -US-Ton,20607,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20607,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20607,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20607,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20607,GRP_SWC,SWC_DATE,20091129 -US-Ton,20940,GRP_SWC,SWC,16.965 -US-Ton,20940,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.973813043 -US-Ton,20940,GRP_SWC,SWC_SPATIAL_REP_NUMBER,10 -US-Ton,20940,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20940,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20940,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20940,GRP_SWC,SWC_DATE,20140611 -US-Ton,20200,GRP_SWC,SWC,17.05 -US-Ton,20200,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.8854259788 -US-Ton,20200,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20200,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20200,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20200,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20200,GRP_SWC,SWC_DATE,20050610 -US-Ton,20723,GRP_SWC,SWC,17.05 -US-Ton,20723,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.6113017008 -US-Ton,20723,GRP_SWC,SWC_SPATIAL_REP_NUMBER,10 -US-Ton,20723,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20723,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20723,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20723,GRP_SWC,SWC_DATE,20110720 -US-Ton,20279,GRP_SWC,SWC,17.057575758 -US-Ton,20279,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.6453821971 -US-Ton,20279,GRP_SWC,SWC_SPATIAL_REP_NUMBER,11 -US-Ton,20279,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20279,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20279,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20279,GRP_SWC,SWC_DATE,20060526 -US-Ton,20559,GRP_SWC,SWC,17.1 -US-Ton,20559,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.866546142 -US-Ton,20559,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20559,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20559,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20559,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20559,GRP_SWC,SWC_DATE,20090403 -US-Ton,20790,GRP_SWC,SWC,17.119444444 -US-Ton,20790,GRP_SWC,SWC_SPATIAL_VARIABILITY,10.62260272 -US-Ton,20790,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20790,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20790,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20790,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20790,GRP_SWC,SWC_DATE,20120518 -US-Ton,20390,GRP_SWC,SWC,17.127777778 -US-Ton,20390,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.6427809129 -US-Ton,20390,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20390,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20390,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20390,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20390,GRP_SWC,SWC_DATE,20070418 -US-Ton,20199,GRP_SWC,SWC,17.154166667 -US-Ton,20199,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.3153772791 -US-Ton,20199,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20199,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20199,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20199,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20199,GRP_SWC,SWC_DATE,20050610 -US-Ton,20800,GRP_SWC,SWC,17.175757576 -US-Ton,20800,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.0434341515 -US-Ton,20800,GRP_SWC,SWC_SPATIAL_REP_NUMBER,11 -US-Ton,20800,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20800,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20800,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20800,GRP_SWC,SWC_DATE,20120704 -US-Ton,20033,GRP_SWC,SWC,17.211111111 -US-Ton,20033,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.6179375507 -US-Ton,20033,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20033,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20033,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20033,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20033,GRP_SWC,SWC_DATE,20031119 -US-Ton,20313,GRP_SWC,SWC,17.358333333 -US-Ton,20313,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.6571162653 -US-Ton,20313,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20313,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20313,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20313,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20313,GRP_SWC,SWC_DATE,20061114 -US-Ton,20501,GRP_SWC,SWC,17.379166667 -US-Ton,20501,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.9805469207 -US-Ton,20501,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20501,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20501,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20501,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20501,GRP_SWC,SWC_DATE,20080506 -US-Ton,19803,GRP_SWC,SWC,17.433333333 -US-Ton,19803,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.1031830463 -US-Ton,19803,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19803,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19803,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,19803,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,19803,GRP_SWC,SWC_DATE,20020530 -US-Ton,20041,GRP_SWC,SWC,17.438888889 -US-Ton,20041,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.4993162033 -US-Ton,20041,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20041,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20041,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20041,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20041,GRP_SWC,SWC_DATE,20031206 -US-Ton,20042,GRP_SWC,SWC,17.522222222 -US-Ton,20042,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.3483889013 -US-Ton,20042,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20042,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20042,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20042,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20042,GRP_SWC,SWC_DATE,20031206 -US-Ton,20639,GRP_SWC,SWC,17.525 -US-Ton,20639,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.9476402618 -US-Ton,20639,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20639,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20639,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20639,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20639,GRP_SWC,SWC_DATE,20100528 -US-Ton,20863,GRP_SWC,SWC,17.670833333 -US-Ton,20863,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.2668094496 -US-Ton,20863,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20863,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20863,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20863,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20863,GRP_SWC,SWC_DATE,20130508 -US-Ton,20640,GRP_SWC,SWC,17.7 -US-Ton,20640,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.4636043983 -US-Ton,20640,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20640,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20640,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20640,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20640,GRP_SWC,SWC_DATE,20100528 -US-Ton,20714,GRP_SWC,SWC,17.718181818 -US-Ton,20714,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.5658597708 -US-Ton,20714,GRP_SWC,SWC_SPATIAL_REP_NUMBER,11 -US-Ton,20714,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20714,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20714,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20714,GRP_SWC,SWC_DATE,20110615 -US-Ton,20531,GRP_SWC,SWC,17.768055556 -US-Ton,20531,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.7801718429 -US-Ton,20531,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20531,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20531,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20531,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20531,GRP_SWC,SWC_DATE,20081113 -US-Ton,20399,GRP_SWC,SWC,17.815151515 -US-Ton,20399,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.1044939598 -US-Ton,20399,GRP_SWC,SWC_SPATIAL_REP_NUMBER,11 -US-Ton,20399,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20399,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20399,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20399,GRP_SWC,SWC_DATE,20070508 -US-Ton,20038,GRP_SWC,SWC,17.838888889 -US-Ton,20038,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.1966041374 -US-Ton,20038,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20038,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20038,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20038,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20038,GRP_SWC,SWC_DATE,20031127 -US-Ton,20081,GRP_SWC,SWC,17.872222222 -US-Ton,20081,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.7353974948 -US-Ton,20081,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20081,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20081,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20081,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20081,GRP_SWC,SWC_DATE,20040402 -US-Ton,19943,GRP_SWC,SWC,17.892592593 -US-Ton,19943,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.0489977422 -US-Ton,19943,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,19943,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19943,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,19943,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,19943,GRP_SWC,SWC_DATE,20030530 -US-Ton,19808,GRP_SWC,SWC,17.9 -US-Ton,19808,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.4590461113 -US-Ton,19808,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19808,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19808,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,19808,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,19808,GRP_SWC,SWC_DATE,20020606 -US-Ton,20574,GRP_SWC,SWC,17.941666667 -US-Ton,20574,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.3842292153 -US-Ton,20574,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20574,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20574,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20574,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20574,GRP_SWC,SWC_DATE,20090527 -US-Ton,20658,GRP_SWC,SWC,17.945833333 -US-Ton,20658,GRP_SWC,SWC_SPATIAL_VARIABILITY,8.7213285668 -US-Ton,20658,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20658,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20658,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20658,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20658,GRP_SWC,SWC_DATE,20100902 -US-Ton,20223,GRP_SWC,SWC,17.968055556 -US-Ton,20223,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.7370731376 -US-Ton,20223,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20223,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20223,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20223,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20223,GRP_SWC,SWC_DATE,20051213 -US-Ton,20654,GRP_SWC,SWC,17.991666667 -US-Ton,20654,GRP_SWC,SWC_SPATIAL_VARIABILITY,8.9652823647 -US-Ton,20654,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20654,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20654,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20654,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20654,GRP_SWC,SWC_DATE,20100814 -US-Ton,20095,GRP_SWC,SWC,18.122222222 -US-Ton,20095,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.3235978853 -US-Ton,20095,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20095,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20095,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20095,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20095,GRP_SWC,SWC_DATE,20040428 -US-Ton,20935,GRP_SWC,SWC,18.129166667 -US-Ton,20935,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.3980087609 -US-Ton,20935,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20935,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20935,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20935,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20935,GRP_SWC,SWC_DATE,20140522 -US-Ton,20394,GRP_SWC,SWC,18.215151515 -US-Ton,20394,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.1700596726 -US-Ton,20394,GRP_SWC,SWC_SPATIAL_REP_NUMBER,11 -US-Ton,20394,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20394,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20394,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20394,GRP_SWC,SWC_DATE,20070428 -US-Ton,20025,GRP_SWC,SWC,18.238888889 -US-Ton,20025,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.9710703023 -US-Ton,20025,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20025,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20025,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20025,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20025,GRP_SWC,SWC_DATE,20031110 -US-Ton,20719,GRP_SWC,SWC,18.5 -US-Ton,20719,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.9644813159 -US-Ton,20719,GRP_SWC,SWC_SPATIAL_REP_NUMBER,11 -US-Ton,20719,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20719,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20719,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20719,GRP_SWC,SWC_DATE,20110706 -US-Ton,20795,GRP_SWC,SWC,18.563636364 -US-Ton,20795,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.6366255587 -US-Ton,20795,GRP_SWC,SWC_SPATIAL_REP_NUMBER,11 -US-Ton,20795,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20795,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20795,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20795,GRP_SWC,SWC_DATE,20120530 -US-Ton,20269,GRP_SWC,SWC,18.676388889 -US-Ton,20269,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.4071237907 -US-Ton,20269,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20269,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20269,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20269,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20269,GRP_SWC,SWC_DATE,20060504 -US-Ton,20532,GRP_SWC,SWC,18.686111111 -US-Ton,20532,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.207734309 -US-Ton,20532,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20532,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20532,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20532,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20532,GRP_SWC,SWC_DATE,20081113 -US-Ton,19740,GRP_SWC,SWC,18.75 -US-Ton,19740,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.4763162765 -US-Ton,19740,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Ton,19740,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19740,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,19740,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,19740,GRP_SWC,SWC_DATE,20011113 -US-Ton,20030,GRP_SWC,SWC,18.766666667 -US-Ton,20030,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.8233514493 -US-Ton,20030,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20030,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20030,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20030,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20030,GRP_SWC,SWC_DATE,20031112 -US-Ton,20386,GRP_SWC,SWC,18.820833333 -US-Ton,20386,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.2401725768 -US-Ton,20386,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20386,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20386,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20386,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20386,GRP_SWC,SWC_DATE,20070405 -US-Ton,20645,GRP_SWC,SWC,18.9 -US-Ton,20645,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.6219806711 -US-Ton,20645,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20645,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20645,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20645,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20645,GRP_SWC,SWC_DATE,20100610 -US-Ton,20492,GRP_SWC,SWC,19.072222222 -US-Ton,20492,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.493583154 -US-Ton,20492,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20492,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20492,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20492,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20492,GRP_SWC,SWC_DATE,20080408 -US-Ton,19938,GRP_SWC,SWC,19.17037037 -US-Ton,19938,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.8389126757 -US-Ton,19938,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,19938,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19938,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,19938,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,19938,GRP_SWC,SWC_DATE,20030521 -US-Ton,20663,GRP_SWC,SWC,19.208333333 -US-Ton,20663,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.4987524215 -US-Ton,20663,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20663,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20663,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20663,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20663,GRP_SWC,SWC_DATE,20101028 -US-Ton,19799,GRP_SWC,SWC,19.24 -US-Ton,19799,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.8295923775 -US-Ton,19799,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19799,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19799,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,19799,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,19799,GRP_SWC,SWC_DATE,20020516 -US-Ton,19736,GRP_SWC,SWC,19.26 -US-Ton,19736,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.6446743696 -US-Ton,19736,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19736,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19736,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,19736,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,19736,GRP_SWC,SWC_DATE,20011110 -US-Ton,19882,GRP_SWC,SWC,19.325 -US-Ton,19882,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.6043233286 -US-Ton,19882,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Ton,19882,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19882,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,19882,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,19882,GRP_SWC,SWC_DATE,20021206 -US-Ton,20563,GRP_SWC,SWC,19.325 -US-Ton,20563,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.0048654515 -US-Ton,20563,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20563,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20563,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20563,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20563,GRP_SWC,SWC_DATE,20090417 -US-Ton,19790,GRP_SWC,SWC,19.326 -US-Ton,19790,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.74758277134 -US-Ton,19790,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19790,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19790,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,19790,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,19790,GRP_SWC,SWC_DATE,20020502 -US-Ton,20853,GRP_SWC,SWC,19.355555556 -US-Ton,20853,GRP_SWC,SWC_SPATIAL_VARIABILITY,10.499115724 -US-Ton,20853,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20853,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20853,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20853,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20853,GRP_SWC,SWC_DATE,20130410 -US-Ton,20404,GRP_SWC,SWC,19.454545455 -US-Ton,20404,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.669522304 -US-Ton,20404,GRP_SWC,SWC_SPATIAL_REP_NUMBER,11 -US-Ton,20404,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20404,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20404,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20404,GRP_SWC,SWC_DATE,20070515 -US-Ton,20034,GRP_SWC,SWC,19.475925926 -US-Ton,20034,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.7346762084 -US-Ton,20034,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20034,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20034,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20034,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20034,GRP_SWC,SWC_DATE,20031119 -US-Ton,20929,GRP_SWC,SWC,19.518181818 -US-Ton,20929,GRP_SWC,SWC_SPATIAL_VARIABILITY,11.366513818 -US-Ton,20929,GRP_SWC,SWC_SPATIAL_REP_NUMBER,11 -US-Ton,20929,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20929,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20929,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20929,GRP_SWC,SWC_DATE,20140422 -US-Ton,20274,GRP_SWC,SWC,19.722222222 -US-Ton,20274,GRP_SWC,SWC_SPATIAL_VARIABILITY,9.7156058294 -US-Ton,20274,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20274,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20274,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20274,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20274,GRP_SWC,SWC_DATE,20060512 -US-Ton,20189,GRP_SWC,SWC,19.7875 -US-Ton,20189,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.5810376703 -US-Ton,20189,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20189,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20189,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20189,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20189,GRP_SWC,SWC_DATE,20050425 -US-Ton,20845,GRP_SWC,SWC,19.854166667 -US-Ton,20845,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.4610338771 -US-Ton,20845,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20845,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20845,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20845,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20845,GRP_SWC,SWC_DATE,20130313 -US-Ton,20864,GRP_SWC,SWC,19.854166667 -US-Ton,20864,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.7686932515 -US-Ton,20864,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20864,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20864,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20864,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20864,GRP_SWC,SWC_DATE,20130508 -US-Ton,20350,GRP_SWC,SWC,19.8875 -US-Ton,20350,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.9105833884 -US-Ton,20350,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20350,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20350,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20350,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20350,GRP_SWC,SWC_DATE,20070204 -US-Ton,20715,GRP_SWC,SWC,19.990909091 -US-Ton,20715,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.0024902889 -US-Ton,20715,GRP_SWC,SWC_SPATIAL_REP_NUMBER,11 -US-Ton,20715,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20715,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20715,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20715,GRP_SWC,SWC_DATE,20110615 -US-Ton,20817,GRP_SWC,SWC,2.99 -US-Ton,20817,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.8188518967 -US-Ton,20817,GRP_SWC,SWC_SPATIAL_REP_NUMBER,10 -US-Ton,20817,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20817,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20817,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20817,GRP_SWC,SWC_DATE,20121009 -US-Ton,20391,GRP_SWC,SWC,20.008333333 -US-Ton,20391,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.1767765213 -US-Ton,20391,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20391,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20391,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20391,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20391,GRP_SWC,SWC_DATE,20070418 -US-Ton,20321,GRP_SWC,SWC,20.030555556 -US-Ton,20321,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.3462621339 -US-Ton,20321,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20321,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20321,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20321,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20321,GRP_SWC,SWC_DATE,20061219 -US-Ton,20026,GRP_SWC,SWC,20.066666667 -US-Ton,20026,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.594529281 -US-Ton,20026,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20026,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20026,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20026,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20026,GRP_SWC,SWC_DATE,20031110 -US-Ton,20737,GRP_SWC,SWC,20.283333333 -US-Ton,20737,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.9679569633 -US-Ton,20737,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20737,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20737,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20737,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20737,GRP_SWC,SWC_DATE,20111013 -US-Ton,20710,GRP_SWC,SWC,20.341666667 -US-Ton,20710,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.8155811538 -US-Ton,20710,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20710,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20710,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20710,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20710,GRP_SWC,SWC_DATE,20110527 -US-Ton,20650,GRP_SWC,SWC,20.383333333 -US-Ton,20650,GRP_SWC,SWC_SPATIAL_VARIABILITY,8.3346847389 -US-Ton,20650,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20650,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20650,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20650,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20650,GRP_SWC,SWC_DATE,20100624 -US-Ton,20483,GRP_SWC,SWC,20.557719167 -US-Ton,20483,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.7662481761 -US-Ton,20483,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20483,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20483,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20483,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20483,GRP_SWC,SWC_DATE,20080322 -US-Ton,20086,GRP_SWC,SWC,20.603703704 -US-Ton,20086,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.0430502886 -US-Ton,20086,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20086,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20086,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20086,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20086,GRP_SWC,SWC_DATE,20040409 -US-Ton,20450,GRP_SWC,SWC,20.625 -US-Ton,20450,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.9231679844 -US-Ton,20450,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20450,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20450,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20450,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20450,GRP_SWC,SWC_DATE,20071111 -US-Ton,20327,GRP_SWC,SWC,20.641666667 -US-Ton,20327,GRP_SWC,SWC_SPATIAL_VARIABILITY,8.1169528915 -US-Ton,20327,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20327,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20327,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20327,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20327,GRP_SWC,SWC_DATE,20061226 -US-Ton,20096,GRP_SWC,SWC,20.727777778 -US-Ton,20096,GRP_SWC,SWC_SPATIAL_VARIABILITY,10.156528415 -US-Ton,20096,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20096,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20096,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20096,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20096,GRP_SWC,SWC_DATE,20040428 -US-Ton,20193,GRP_SWC,SWC,20.729166667 -US-Ton,20193,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.6616654472 -US-Ton,20193,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20193,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20193,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20193,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20193,GRP_SWC,SWC_DATE,20050517 -US-Ton,20706,GRP_SWC,SWC,20.963636364 -US-Ton,20706,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.5228359969 -US-Ton,20706,GRP_SWC,SWC_SPATIAL_REP_NUMBER,11 -US-Ton,20706,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20706,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20706,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20706,GRP_SWC,SWC_DATE,20110510 -US-Ton,20222,GRP_SWC,SWC,20.9875 -US-Ton,20222,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.2241510922 -US-Ton,20222,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20222,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20222,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20222,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20222,GRP_SWC,SWC_DATE,20051213 -US-Ton,20382,GRP_SWC,SWC,21.05 -US-Ton,20382,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.1592912487 -US-Ton,20382,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20382,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20382,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20382,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20382,GRP_SWC,SWC_DATE,20070402 -US-Ton,20488,GRP_SWC,SWC,21.195833333 -US-Ton,20488,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.3721697975 -US-Ton,20488,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20488,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20488,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20488,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20488,GRP_SWC,SWC_DATE,20080404 -US-Ton,20325,GRP_SWC,SWC,21.304166667 -US-Ton,20325,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.1310606865 -US-Ton,20325,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20325,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20325,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20325,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20325,GRP_SWC,SWC_DATE,20061226 -US-Ton,20930,GRP_SWC,SWC,21.316666667 -US-Ton,20930,GRP_SWC,SWC_SPATIAL_VARIABILITY,8.2754932106 -US-Ton,20930,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20930,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20930,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20930,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20930,GRP_SWC,SWC_DATE,20140422 -US-Ton,20502,GRP_SWC,SWC,21.5375 -US-Ton,20502,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.3945349906 -US-Ton,20502,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20502,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20502,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20502,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20502,GRP_SWC,SWC_DATE,20080506 -US-Ton,19744,GRP_SWC,SWC,21.686666667 -US-Ton,19744,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.1365981729 -US-Ton,19744,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19744,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19744,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,19744,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,19744,GRP_SWC,SWC_DATE,20011125 -US-Ton,20497,GRP_SWC,SWC,21.7 -US-Ton,20497,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.5258353835 -US-Ton,20497,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20497,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20497,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20497,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20497,GRP_SWC,SWC_DATE,20080420 -US-Ton,20280,GRP_SWC,SWC,21.709090909 -US-Ton,20280,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.4268744871 -US-Ton,20280,GRP_SWC,SWC_SPATIAL_REP_NUMBER,11 -US-Ton,20280,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20280,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20280,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20280,GRP_SWC,SWC_DATE,20060526 -US-Ton,20374,GRP_SWC,SWC,21.736111111 -US-Ton,20374,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.4690476456 -US-Ton,20374,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20374,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20374,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20374,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20374,GRP_SWC,SWC_DATE,20070319 -US-Ton,20405,GRP_SWC,SWC,21.806060606 -US-Ton,20405,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.3328911712 -US-Ton,20405,GRP_SWC,SWC_SPATIAL_REP_NUMBER,11 -US-Ton,20405,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20405,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20405,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20405,GRP_SWC,SWC_DATE,20070515 -US-Ton,20091,GRP_SWC,SWC,21.81875 -US-Ton,20091,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.0866543335 -US-Ton,20091,GRP_SWC,SWC_SPATIAL_REP_NUMBER,8 -US-Ton,20091,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20091,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20091,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20091,GRP_SWC,SWC_DATE,20040423 -US-Ton,19804,GRP_SWC,SWC,21.84 -US-Ton,19804,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.5664641687 -US-Ton,19804,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19804,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19804,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,19804,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,19804,GRP_SWC,SWC_DATE,20020530 -US-Ton,20646,GRP_SWC,SWC,21.905555556 -US-Ton,20646,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.0857481024 -US-Ton,20646,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20646,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20646,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20646,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20646,GRP_SWC,SWC_DATE,20100610 -US-Ton,19786,GRP_SWC,SWC,22.1 -US-Ton,19786,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.3600847442 -US-Ton,19786,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19786,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19786,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,19786,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,19786,GRP_SWC,SWC_DATE,20020426 -US-Ton,20137,GRP_SWC,SWC,22.188888889 -US-Ton,20137,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.5057559984 -US-Ton,20137,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20137,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20137,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20137,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20137,GRP_SWC,SWC_DATE,20041103 -US-Ton,20977,GRP_SWC,SWC,22.3625 -US-Ton,20977,GRP_SWC,SWC_SPATIAL_VARIABILITY,8.3520853411 -US-Ton,20977,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20977,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20977,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20977,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20977,GRP_SWC,SWC_DATE,20141209 -US-Ton,20784,GRP_SWC,SWC,22.425 -US-Ton,20784,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.151293286 -US-Ton,20784,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20784,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20784,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20784,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20784,GRP_SWC,SWC_DATE,20120504 -US-Ton,20615,GRP_SWC,SWC,22.445454545 -US-Ton,20615,GRP_SWC,SWC_SPATIAL_VARIABILITY,8.8763014411 -US-Ton,20615,GRP_SWC,SWC_SPATIAL_REP_NUMBER,11 -US-Ton,20615,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20615,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20615,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20615,GRP_SWC,SWC_DATE,20100108 -US-Ton,20322,GRP_SWC,SWC,22.566666667 -US-Ton,20322,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.4151360355 -US-Ton,20322,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20322,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20322,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20322,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20322,GRP_SWC,SWC_DATE,20061219 -US-Ton,20049,GRP_SWC,SWC,22.572222222 -US-Ton,20049,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.0906747939 -US-Ton,20049,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20049,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20049,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20049,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20049,GRP_SWC,SWC_DATE,20031219 -US-Ton,20346,GRP_SWC,SWC,22.575 -US-Ton,20346,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.5211100218 -US-Ton,20346,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20346,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20346,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20346,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20346,GRP_SWC,SWC_DATE,20070127 -US-Ton,20854,GRP_SWC,SWC,22.683333333 -US-Ton,20854,GRP_SWC,SWC_SPATIAL_VARIABILITY,8.6229960342 -US-Ton,20854,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20854,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20854,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20854,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20854,GRP_SWC,SWC_DATE,20130410 -US-Ton,20979,GRP_SWC,SWC,22.7375 -US-Ton,20979,GRP_SWC,SWC_SPATIAL_VARIABILITY,9.5515616286 -US-Ton,20979,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20979,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20979,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20979,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20979,GRP_SWC,SWC_DATE,20141209 -US-Ton,20342,GRP_SWC,SWC,22.779166667 -US-Ton,20342,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.1091956562 -US-Ton,20342,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20342,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20342,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20342,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20342,GRP_SWC,SWC_DATE,20070119 -US-Ton,20764,GRP_SWC,SWC,22.8625 -US-Ton,20764,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.0249905696 -US-Ton,20764,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20764,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20764,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20764,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20764,GRP_SWC,SWC_DATE,20120201 -US-Ton,19877,GRP_SWC,SWC,22.866666667 -US-Ton,19877,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.5568454475 -US-Ton,19877,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19877,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19877,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,19877,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,19877,GRP_SWC,SWC_DATE,20021114 -US-Ton,20796,GRP_SWC,SWC,22.895454545 -US-Ton,20796,GRP_SWC,SWC_SPATIAL_VARIABILITY,8.7576953174 -US-Ton,20796,GRP_SWC,SWC_SPATIAL_REP_NUMBER,11 -US-Ton,20796,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20796,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20796,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20796,GRP_SWC,SWC_DATE,20120530 -US-Ton,20667,GRP_SWC,SWC,22.929166667 -US-Ton,20667,GRP_SWC,SWC_SPATIAL_VARIABILITY,8.1048935368 -US-Ton,20667,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20667,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20667,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20667,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20667,GRP_SWC,SWC_DATE,20101112 -US-Ton,20400,GRP_SWC,SWC,23.36969697 -US-Ton,20400,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.6845717116 -US-Ton,20400,GRP_SWC,SWC_SPATIAL_REP_NUMBER,11 -US-Ton,20400,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20400,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20400,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20400,GRP_SWC,SWC_DATE,20070508 -US-Ton,20791,GRP_SWC,SWC,23.430555556 -US-Ton,20791,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.1302825577 -US-Ton,20791,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20791,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20791,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20791,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20791,GRP_SWC,SWC_DATE,20120518 -US-Ton,20850,GRP_SWC,SWC,23.6375 -US-Ton,20850,GRP_SWC,SWC_SPATIAL_VARIABILITY,10.772083554 -US-Ton,20850,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20850,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20850,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20850,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20850,GRP_SWC,SWC_DATE,20130327 -US-Ton,20768,GRP_SWC,SWC,23.658333333 -US-Ton,20768,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.7102646382 -US-Ton,20768,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20768,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20768,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20768,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20768,GRP_SWC,SWC_DATE,20120216 -US-Ton,20564,GRP_SWC,SWC,23.666666667 -US-Ton,20564,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.3252969756 -US-Ton,20564,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20564,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20564,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20564,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20564,GRP_SWC,SWC_DATE,20090417 -US-Ton,20618,GRP_SWC,SWC,23.681818182 -US-Ton,20618,GRP_SWC,SWC_SPATIAL_VARIABILITY,13.830315845 -US-Ton,20618,GRP_SWC,SWC_SPATIAL_REP_NUMBER,11 -US-Ton,20618,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20618,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20618,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20618,GRP_SWC,SWC_DATE,20100108 -US-Ton,20338,GRP_SWC,SWC,23.697222222 -US-Ton,20338,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.8438093499 -US-Ton,20338,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20338,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20338,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20338,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20338,GRP_SWC,SWC_DATE,20070115 -US-Ton,20614,GRP_SWC,SWC,23.745833333 -US-Ton,20614,GRP_SWC,SWC_SPATIAL_VARIABILITY,13.26810013 -US-Ton,20614,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20614,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20614,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20614,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20614,GRP_SWC,SWC_DATE,20091222 -US-Ton,19739,GRP_SWC,SWC,23.75 -US-Ton,19739,GRP_SWC,SWC_SPATIAL_VARIABILITY,8.7403068003 -US-Ton,19739,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Ton,19739,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19739,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,19739,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,19739,GRP_SWC,SWC_DATE,20011113 -US-Ton,19781,GRP_SWC,SWC,23.806666667 -US-Ton,19781,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.9270773653 -US-Ton,19781,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19781,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19781,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,19781,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,19781,GRP_SWC,SWC_DATE,20020418 -US-Ton,20868,GRP_SWC,SWC,23.836363636 -US-Ton,20868,GRP_SWC,SWC_SPATIAL_VARIABILITY,21.791111616 -US-Ton,20868,GRP_SWC,SWC_SPATIAL_REP_NUMBER,11 -US-Ton,20868,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20868,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20868,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20868,GRP_SWC,SWC_DATE,20130530 -US-Ton,20936,GRP_SWC,SWC,23.891666667 -US-Ton,20936,GRP_SWC,SWC_SPATIAL_VARIABILITY,11.439799612 -US-Ton,20936,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20936,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20936,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20936,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20936,GRP_SWC,SWC_DATE,20140522 -US-Ton,20841,GRP_SWC,SWC,23.966666667 -US-Ton,20841,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.1321720947 -US-Ton,20841,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20841,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20841,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20841,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20841,GRP_SWC,SWC_DATE,20130227 -US-Ton,20616,GRP_SWC,SWC,24.054545455 -US-Ton,20616,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.2320724701 -US-Ton,20616,GRP_SWC,SWC_SPATIAL_REP_NUMBER,11 -US-Ton,20616,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20616,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20616,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20616,GRP_SWC,SWC_DATE,20100108 -US-Ton,20641,GRP_SWC,SWC,24.15 -US-Ton,20641,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.6648589572 -US-Ton,20641,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20641,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20641,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20641,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20641,GRP_SWC,SWC_DATE,20100528 -US-Ton,20351,GRP_SWC,SWC,24.1625 -US-Ton,20351,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.9777609394 -US-Ton,20351,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20351,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20351,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20351,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20351,GRP_SWC,SWC_DATE,20070204 -US-Ton,20664,GRP_SWC,SWC,24.179166667 -US-Ton,20664,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.3880377672 -US-Ton,20664,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20664,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20664,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20664,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20664,GRP_SWC,SWC_DATE,20101028 -US-Ton,20395,GRP_SWC,SWC,24.190909091 -US-Ton,20395,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.7968962019 -US-Ton,20395,GRP_SWC,SWC_SPATIAL_REP_NUMBER,11 -US-Ton,20395,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20395,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20395,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20395,GRP_SWC,SWC_DATE,20070428 -US-Ton,20387,GRP_SWC,SWC,24.3125 -US-Ton,20387,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.2352416662 -US-Ton,20387,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20387,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20387,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20387,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20387,GRP_SWC,SWC_DATE,20070405 -US-Ton,20190,GRP_SWC,SWC,24.354166667 -US-Ton,20190,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.2129845898 -US-Ton,20190,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20190,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20190,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20190,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20190,GRP_SWC,SWC_DATE,20050425 -US-Ton,20759,GRP_SWC,SWC,24.38 -US-Ton,20759,GRP_SWC,SWC_SPATIAL_VARIABILITY,37.522602078 -US-Ton,20759,GRP_SWC,SWC_SPATIAL_REP_NUMBER,10 -US-Ton,20759,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20759,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20759,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20759,GRP_SWC,SWC_DATE,20120104 -US-Ton,20846,GRP_SWC,SWC,24.408333333 -US-Ton,20846,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.8614480758 -US-Ton,20846,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20846,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20846,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20846,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20846,GRP_SWC,SWC_DATE,20130313 -US-Ton,19795,GRP_SWC,SWC,24.448333333 -US-Ton,19795,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.2606577387 -US-Ton,19795,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19795,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19795,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,19795,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,19795,GRP_SWC,SWC_DATE,20020509 -US-Ton,20567,GRP_SWC,SWC,24.458333333 -US-Ton,20567,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.412944248 -US-Ton,20567,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20567,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20567,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20567,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20567,GRP_SWC,SWC_DATE,20090507 -US-Ton,20560,GRP_SWC,SWC,24.491666667 -US-Ton,20560,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.1855341995 -US-Ton,20560,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20560,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20560,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20560,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20560,GRP_SWC,SWC_DATE,20090403 -US-Ton,20859,GRP_SWC,SWC,24.686111111 -US-Ton,20859,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.1857070144 -US-Ton,20859,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20859,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20859,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20859,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20859,GRP_SWC,SWC_DATE,20130424 -US-Ton,20078,GRP_SWC,SWC,24.7 -US-Ton,20078,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.1128962039 -US-Ton,20078,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20078,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20078,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20078,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20078,GRP_SWC,SWC_DATE,20040325 -US-Ton,20695,GRP_SWC,SWC,24.766666667 -US-Ton,20695,GRP_SWC,SWC_SPATIAL_VARIABILITY,8.8878193801 -US-Ton,20695,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20695,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20695,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20695,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20695,GRP_SWC,SWC_DATE,20110415 -US-Ton,20334,GRP_SWC,SWC,24.830555556 -US-Ton,20334,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.2478029809 -US-Ton,20334,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20334,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20334,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20334,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20334,GRP_SWC,SWC_DATE,20070110 -US-Ton,20270,GRP_SWC,SWC,25.008333333 -US-Ton,20270,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.2021562722 -US-Ton,20270,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20270,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20270,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20270,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20270,GRP_SWC,SWC_DATE,20060504 -US-Ton,20048,GRP_SWC,SWC,25.02037037 -US-Ton,20048,GRP_SWC,SWC_SPATIAL_VARIABILITY,14.095499621 -US-Ton,20048,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20048,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20048,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20048,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20048,GRP_SWC,SWC_DATE,20031215 -US-Ton,20326,GRP_SWC,SWC,25.120833333 -US-Ton,20326,GRP_SWC,SWC_SPATIAL_VARIABILITY,8.3399492677 -US-Ton,20326,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20326,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20326,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20326,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20326,GRP_SWC,SWC_DATE,20061226 -US-Ton,20702,GRP_SWC,SWC,25.15 -US-Ton,20702,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.0282252778 -US-Ton,20702,GRP_SWC,SWC_SPATIAL_REP_NUMBER,11 -US-Ton,20702,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20702,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20702,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20702,GRP_SWC,SWC_DATE,20110503 -US-Ton,19944,GRP_SWC,SWC,25.162962963 -US-Ton,19944,GRP_SWC,SWC_SPATIAL_VARIABILITY,10.624388145 -US-Ton,19944,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,19944,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19944,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,19944,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,19944,GRP_SWC,SWC_DATE,20030530 -US-Ton,20569,GRP_SWC,SWC,25.175 -US-Ton,20569,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.6002926932 -US-Ton,20569,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20569,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20569,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20569,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20569,GRP_SWC,SWC_DATE,20090507 -US-Ton,20671,GRP_SWC,SWC,25.208333333 -US-Ton,20671,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.677766997 -US-Ton,20671,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20671,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20671,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20671,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20671,GRP_SWC,SWC_DATE,20101202 -US-Ton,19878,GRP_SWC,SWC,25.24 -US-Ton,19878,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.992868643 -US-Ton,19878,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19878,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19878,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,19878,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,19878,GRP_SWC,SWC_DATE,20021114 -US-Ton,20194,GRP_SWC,SWC,25.2625 -US-Ton,20194,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.6271180148 -US-Ton,20194,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20194,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20194,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20194,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20194,GRP_SWC,SWC_DATE,20050517 -US-Ton,20052,GRP_SWC,SWC,25.272222222 -US-Ton,20052,GRP_SWC,SWC_SPATIAL_VARIABILITY,15.074401131 -US-Ton,20052,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20052,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20052,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20052,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20052,GRP_SWC,SWC_DATE,20031219 -US-Ton,20462,GRP_SWC,SWC,25.299074074 -US-Ton,20462,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.4450443091 -US-Ton,20462,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20462,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20462,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20462,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20462,GRP_SWC,SWC_DATE,20071221 -US-Ton,20669,GRP_SWC,SWC,25.3 -US-Ton,20669,GRP_SWC,SWC_SPATIAL_VARIABILITY,8.2379112534 -US-Ton,20669,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20669,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20669,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20669,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20669,GRP_SWC,SWC_DATE,20101112 -US-Ton,20347,GRP_SWC,SWC,25.308333333 -US-Ton,20347,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.1287598621 -US-Ton,20347,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20347,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20347,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20347,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20347,GRP_SWC,SWC_DATE,20070127 -US-Ton,20370,GRP_SWC,SWC,25.475 -US-Ton,20370,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.4762678646 -US-Ton,20370,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20370,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20370,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20370,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20370,GRP_SWC,SWC_DATE,20070316 -US-Ton,20785,GRP_SWC,SWC,25.591666667 -US-Ton,20785,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.4085280508 -US-Ton,20785,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20785,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20785,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20785,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20785,GRP_SWC,SWC_DATE,20120504 -US-Ton,20082,GRP_SWC,SWC,25.666666667 -US-Ton,20082,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.3456875175 -US-Ton,20082,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20082,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20082,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20082,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20082,GRP_SWC,SWC_DATE,20040402 -US-Ton,20484,GRP_SWC,SWC,25.694418056 -US-Ton,20484,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.4351413109 -US-Ton,20484,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20484,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20484,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20484,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20484,GRP_SWC,SWC_DATE,20080322 -US-Ton,20631,GRP_SWC,SWC,25.808333333 -US-Ton,20631,GRP_SWC,SWC_SPATIAL_VARIABILITY,8.0689594162 -US-Ton,20631,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20631,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20631,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20631,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20631,GRP_SWC,SWC_DATE,20100402 -US-Ton,20765,GRP_SWC,SWC,25.9125 -US-Ton,20765,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.7724491577 -US-Ton,20765,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20765,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20765,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20765,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20765,GRP_SWC,SWC_DATE,20120201 -US-Ton,20045,GRP_SWC,SWC,25.924074074 -US-Ton,20045,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.8075209326 -US-Ton,20045,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20045,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20045,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20045,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20045,GRP_SWC,SWC_DATE,20031215 -US-Ton,20769,GRP_SWC,SWC,25.933333333 -US-Ton,20769,GRP_SWC,SWC_SPATIAL_VARIABILITY,8.2971334955 -US-Ton,20769,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20769,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20769,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20769,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20769,GRP_SWC,SWC_DATE,20120216 -US-Ton,20978,GRP_SWC,SWC,26 -US-Ton,20978,GRP_SWC,SWC_SPATIAL_VARIABILITY,8.4217791254 -US-Ton,20978,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20978,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20978,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20978,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20978,GRP_SWC,SWC_DATE,20141209 -US-Ton,20555,GRP_SWC,SWC,26.040277778 -US-Ton,20555,GRP_SWC,SWC_SPATIAL_VARIABILITY,9.474115343 -US-Ton,20555,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20555,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20555,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20555,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20555,GRP_SWC,SWC_DATE,20090327 -US-Ton,20383,GRP_SWC,SWC,26.05 -US-Ton,20383,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.7322756445 -US-Ton,20383,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20383,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20383,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20383,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20383,GRP_SWC,SWC_DATE,20070402 -US-Ton,20711,GRP_SWC,SWC,26.069444444 -US-Ton,20711,GRP_SWC,SWC_SPATIAL_VARIABILITY,11.102674701 -US-Ton,20711,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20711,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20711,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20711,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20711,GRP_SWC,SWC_DATE,20110527 -US-Ton,20343,GRP_SWC,SWC,26.1625 -US-Ton,20343,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.8221272675 -US-Ton,20343,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20343,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20343,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20343,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20343,GRP_SWC,SWC_DATE,20070119 -US-Ton,20772,GRP_SWC,SWC,26.170833333 -US-Ton,20772,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.4294584225 -US-Ton,20772,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20772,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20772,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20772,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20772,GRP_SWC,SWC_DATE,20120302 -US-Ton,20604,GRP_SWC,SWC,26.266666667 -US-Ton,20604,GRP_SWC,SWC_SPATIAL_VARIABILITY,48.17759444 -US-Ton,20604,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20604,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20604,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20604,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20604,GRP_SWC,SWC_DATE,20091105 -US-Ton,20138,GRP_SWC,SWC,26.35 -US-Ton,20138,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.021039809 -US-Ton,20138,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20138,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20138,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20138,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20138,GRP_SWC,SWC_DATE,20041103 -US-Ton,20061,GRP_SWC,SWC,26.416666667 -US-Ton,20061,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.4588873165 -US-Ton,20061,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20061,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20061,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20061,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20061,GRP_SWC,SWC_DATE,20040123 -US-Ton,20140,GRP_SWC,SWC,26.427777778 -US-Ton,20140,GRP_SWC,SWC_SPATIAL_VARIABILITY,15.703962699 -US-Ton,20140,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20140,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20140,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20140,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20140,GRP_SWC,SWC_DATE,20041103 -US-Ton,20568,GRP_SWC,SWC,26.633333333 -US-Ton,20568,GRP_SWC,SWC_SPATIAL_VARIABILITY,8.9722129968 -US-Ton,20568,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20568,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20568,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20568,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20568,GRP_SWC,SWC_DATE,20090507 -US-Ton,20612,GRP_SWC,SWC,26.7 -US-Ton,20612,GRP_SWC,SWC_SPATIAL_VARIABILITY,8.4112478806 -US-Ton,20612,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20612,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20612,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20612,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20612,GRP_SWC,SWC_DATE,20091222 -US-Ton,20092,GRP_SWC,SWC,26.78125 -US-Ton,20092,GRP_SWC,SWC_SPATIAL_VARIABILITY,10.216196437 -US-Ton,20092,GRP_SWC,SWC_SPATIAL_REP_NUMBER,8 -US-Ton,20092,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20092,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20092,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20092,GRP_SWC,SWC_DATE,20040423 -US-Ton,20339,GRP_SWC,SWC,26.825 -US-Ton,20339,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.2043074237 -US-Ton,20339,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20339,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20339,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20339,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20339,GRP_SWC,SWC_DATE,20070115 -US-Ton,20375,GRP_SWC,SWC,26.825 -US-Ton,20375,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.7783840183 -US-Ton,20375,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20375,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20375,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20375,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20375,GRP_SWC,SWC_DATE,20070319 -US-Ton,20051,GRP_SWC,SWC,26.877777778 -US-Ton,20051,GRP_SWC,SWC_SPATIAL_VARIABILITY,9.5883428936 -US-Ton,20051,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20051,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20051,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20051,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20051,GRP_SWC,SWC_DATE,20031219 -US-Ton,20668,GRP_SWC,SWC,26.883333333 -US-Ton,20668,GRP_SWC,SWC_SPATIAL_VARIABILITY,8.0902953461 -US-Ton,20668,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20668,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20668,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20668,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20668,GRP_SWC,SWC_DATE,20101112 -US-Ton,19886,GRP_SWC,SWC,26.91 -US-Ton,19886,GRP_SWC,SWC_SPATIAL_VARIABILITY,9.973239193 -US-Ton,19886,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19886,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19886,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,19886,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,19886,GRP_SWC,SWC_DATE,20021214 -US-Ton,20548,GRP_SWC,SWC,26.95 -US-Ton,20548,GRP_SWC,SWC_SPATIAL_VARIABILITY,9.3892104422 -US-Ton,20548,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20548,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20548,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20548,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20548,GRP_SWC,SWC_DATE,20090210 -US-Ton,20047,GRP_SWC,SWC,27.011111111 -US-Ton,20047,GRP_SWC,SWC_SPATIAL_VARIABILITY,10.267644028 -US-Ton,20047,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20047,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20047,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20047,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20047,GRP_SWC,SWC_DATE,20031215 -US-Ton,20627,GRP_SWC,SWC,27.079166667 -US-Ton,20627,GRP_SWC,SWC_SPATIAL_VARIABILITY,8.5950688382 -US-Ton,20627,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20627,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20627,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20627,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20627,GRP_SWC,SWC_DATE,20100321 -US-Ton,20611,GRP_SWC,SWC,27.2625 -US-Ton,20611,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.5577511386 -US-Ton,20611,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20611,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20611,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20611,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20611,GRP_SWC,SWC_DATE,20091222 -US-Ton,20837,GRP_SWC,SWC,27.275 -US-Ton,20837,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.6901501345 -US-Ton,20837,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20837,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20837,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20837,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20837,GRP_SWC,SWC_DATE,20130206 -US-Ton,20547,GRP_SWC,SWC,27.283333333 -US-Ton,20547,GRP_SWC,SWC_SPATIAL_VARIABILITY,9.4858107751 -US-Ton,20547,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20547,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20547,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20547,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20547,GRP_SWC,SWC_DATE,20090210 -US-Ton,20493,GRP_SWC,SWC,27.322222222 -US-Ton,20493,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.277383292 -US-Ton,20493,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20493,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20493,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20493,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20493,GRP_SWC,SWC_DATE,20080408 -US-Ton,20378,GRP_SWC,SWC,27.329166667 -US-Ton,20378,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.1273773988 -US-Ton,20378,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20378,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20378,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20378,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20378,GRP_SWC,SWC_DATE,20070328 -US-Ton,20050,GRP_SWC,SWC,27.35 -US-Ton,20050,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.8593097661 -US-Ton,20050,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20050,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20050,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20050,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20050,GRP_SWC,SWC_DATE,20031219 -US-Ton,20275,GRP_SWC,SWC,27.438888889 -US-Ton,20275,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.6610994637 -US-Ton,20275,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20275,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20275,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20275,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20275,GRP_SWC,SWC_DATE,20060512 -US-Ton,20354,GRP_SWC,SWC,27.541666667 -US-Ton,20354,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.7788757597 -US-Ton,20354,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20354,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20354,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20354,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20354,GRP_SWC,SWC_DATE,20070219 -US-Ton,20825,GRP_SWC,SWC,27.55 -US-Ton,20825,GRP_SWC,SWC_SPATIAL_VARIABILITY,8.001931585 -US-Ton,20825,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20825,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20825,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20825,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20825,GRP_SWC,SWC_DATE,20121211 -US-Ton,20696,GRP_SWC,SWC,27.558333333 -US-Ton,20696,GRP_SWC,SWC_SPATIAL_VARIABILITY,8.1239498156 -US-Ton,20696,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20696,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20696,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20696,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20696,GRP_SWC,SWC_DATE,20110415 -US-Ton,20087,GRP_SWC,SWC,27.585185185 -US-Ton,20087,GRP_SWC,SWC_SPATIAL_VARIABILITY,8.2100566907 -US-Ton,20087,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20087,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20087,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20087,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20087,GRP_SWC,SWC_DATE,20040409 -US-Ton,20392,GRP_SWC,SWC,27.655555556 -US-Ton,20392,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.449983687 -US-Ton,20392,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20392,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20392,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20392,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20392,GRP_SWC,SWC_DATE,20070418 -US-Ton,20401,GRP_SWC,SWC,27.666666667 -US-Ton,20401,GRP_SWC,SWC_SPATIAL_VARIABILITY,8.8575517059 -US-Ton,20401,GRP_SWC,SWC_SPATIAL_REP_NUMBER,11 -US-Ton,20401,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20401,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20401,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20401,GRP_SWC,SWC_DATE,20070508 -US-Ton,20053,GRP_SWC,SWC,27.694444444 -US-Ton,20053,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.3347476491 -US-Ton,20053,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20053,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20053,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20053,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20053,GRP_SWC,SWC_DATE,20031231 -US-Ton,20707,GRP_SWC,SWC,27.727272727 -US-Ton,20707,GRP_SWC,SWC_SPATIAL_VARIABILITY,8.2017487049 -US-Ton,20707,GRP_SWC,SWC_SPATIAL_REP_NUMBER,11 -US-Ton,20707,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20707,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20707,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20707,GRP_SWC,SWC_DATE,20110510 -US-Ton,20464,GRP_SWC,SWC,27.787037037 -US-Ton,20464,GRP_SWC,SWC_SPATIAL_VARIABILITY,9.9952747908 -US-Ton,20464,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20464,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20464,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20464,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20464,GRP_SWC,SWC_DATE,20071221 -US-Ton,20329,GRP_SWC,SWC,27.861111111 -US-Ton,20329,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.2177403936 -US-Ton,20329,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20329,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20329,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20329,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20329,GRP_SWC,SWC_DATE,20070106 -US-Ton,19800,GRP_SWC,SWC,27.993333333 -US-Ton,19800,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.9413148987 -US-Ton,19800,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19800,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19800,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,19800,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,19800,GRP_SWC,SWC_DATE,20020516 -US-Ton,20332,GRP_SWC,SWC,28.058333333 -US-Ton,20332,GRP_SWC,SWC_SPATIAL_VARIABILITY,10.604250387 -US-Ton,20332,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20332,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20332,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20332,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20332,GRP_SWC,SWC_DATE,20070106 -US-Ton,20366,GRP_SWC,SWC,28.116666667 -US-Ton,20366,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.1013229668 -US-Ton,20366,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20366,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20366,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20366,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20366,GRP_SWC,SWC_DATE,20070310 -US-Ton,20921,GRP_SWC,SWC,28.1375 -US-Ton,20921,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.3581162671 -US-Ton,20921,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20921,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20921,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20921,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20921,GRP_SWC,SWC_DATE,20140318 -US-Ton,19782,GRP_SWC,SWC,28.223333333 -US-Ton,19782,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.1497707148 -US-Ton,19782,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19782,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19782,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,19782,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,19782,GRP_SWC,SWC_DATE,20020418 -US-Ton,20335,GRP_SWC,SWC,28.244444444 -US-Ton,20335,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.2564472668 -US-Ton,20335,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20335,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20335,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20335,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20335,GRP_SWC,SWC_DATE,20070110 -US-Ton,20842,GRP_SWC,SWC,28.258333333 -US-Ton,20842,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.9928898328 -US-Ton,20842,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20842,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20842,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20842,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20842,GRP_SWC,SWC_DATE,20130227 -US-Ton,20333,GRP_SWC,SWC,28.344444444 -US-Ton,20333,GRP_SWC,SWC_SPATIAL_VARIABILITY,12.311810322 -US-Ton,20333,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20333,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20333,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20333,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20333,GRP_SWC,SWC_DATE,20070106 -US-Ton,20632,GRP_SWC,SWC,28.483333333 -US-Ton,20632,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.690115655 -US-Ton,20632,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20632,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20632,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20632,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20632,GRP_SWC,SWC_DATE,20100402 -US-Ton,20833,GRP_SWC,SWC,28.531944444 -US-Ton,20833,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.9729327277 -US-Ton,20833,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20833,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20833,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20833,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20833,GRP_SWC,SWC_DATE,20130116 -US-Ton,20925,GRP_SWC,SWC,28.579166667 -US-Ton,20925,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.1320120654 -US-Ton,20925,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20925,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20925,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20925,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20925,GRP_SWC,SWC_DATE,20140408 -US-Ton,20773,GRP_SWC,SWC,28.591666667 -US-Ton,20773,GRP_SWC,SWC_SPATIAL_VARIABILITY,8.6013168477 -US-Ton,20773,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20773,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20773,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20773,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20773,GRP_SWC,SWC_DATE,20120302 -US-Ton,20352,GRP_SWC,SWC,28.7 -US-Ton,20352,GRP_SWC,SWC_SPATIAL_VARIABILITY,8.8897796271 -US-Ton,20352,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20352,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20352,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20352,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20352,GRP_SWC,SWC_DATE,20070204 -US-Ton,20463,GRP_SWC,SWC,28.703518519 -US-Ton,20463,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.8909481255 -US-Ton,20463,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20463,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20463,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20463,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20463,GRP_SWC,SWC_DATE,20071221 -US-Ton,20672,GRP_SWC,SWC,28.708333333 -US-Ton,20672,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.173747383 -US-Ton,20672,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20672,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20672,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20672,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20672,GRP_SWC,SWC_DATE,20101202 -US-Ton,20046,GRP_SWC,SWC,28.811111111 -US-Ton,20046,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.6719773273 -US-Ton,20046,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20046,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20046,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20046,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20046,GRP_SWC,SWC_DATE,20031215 -US-Ton,20073,GRP_SWC,SWC,28.901851852 -US-Ton,20073,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.6941240407 -US-Ton,20073,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20073,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20073,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20073,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20073,GRP_SWC,SWC_DATE,20040321 -US-Ton,20139,GRP_SWC,SWC,28.977777778 -US-Ton,20139,GRP_SWC,SWC_SPATIAL_VARIABILITY,8.7514324224 -US-Ton,20139,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20139,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20139,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20139,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20139,GRP_SWC,SWC_DATE,20041103 -US-Ton,20776,GRP_SWC,SWC,29.029166667 -US-Ton,20776,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.8153828015 -US-Ton,20776,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20776,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20776,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20776,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20776,GRP_SWC,SWC_DATE,20120321 -US-Ton,20479,GRP_SWC,SWC,29.133333333 -US-Ton,20479,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.6692116354 -US-Ton,20479,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20479,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20479,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20479,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20479,GRP_SWC,SWC_DATE,20080306 -US-Ton,20379,GRP_SWC,SWC,29.15 -US-Ton,20379,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.8957826374 -US-Ton,20379,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20379,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20379,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20379,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20379,GRP_SWC,SWC_DATE,20070328 -US-Ton,19743,GRP_SWC,SWC,29.24 -US-Ton,19743,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.9526166204 -US-Ton,19743,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19743,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19743,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,19743,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,19743,GRP_SWC,SWC_DATE,20011125 -US-Ton,20570,GRP_SWC,SWC,29.241666667 -US-Ton,20570,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.0035651095 -US-Ton,20570,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20570,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20570,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20570,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20570,GRP_SWC,SWC_DATE,20090507 -US-Ton,20057,GRP_SWC,SWC,29.307407407 -US-Ton,20057,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.1305026932 -US-Ton,20057,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20057,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20057,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20057,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20057,GRP_SWC,SWC_DATE,20040108 -US-Ton,20362,GRP_SWC,SWC,29.320833333 -US-Ton,20362,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.5304869781 -US-Ton,20362,GRP_SWC,SWC_SPATIAL_REP_NUMBER,8 -US-Ton,20362,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20362,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20362,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20362,GRP_SWC,SWC_DATE,20070304 -US-Ton,20922,GRP_SWC,SWC,29.3375 -US-Ton,20922,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.8271417342 -US-Ton,20922,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20922,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20922,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20922,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20922,GRP_SWC,SWC_DATE,20140318 -US-Ton,19939,GRP_SWC,SWC,29.344444444 -US-Ton,19939,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.2065942025 -US-Ton,19939,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,19939,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19939,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,19939,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,19939,GRP_SWC,SWC_DATE,20030521 -US-Ton,20348,GRP_SWC,SWC,29.347222222 -US-Ton,20348,GRP_SWC,SWC_SPATIAL_VARIABILITY,8.7747279256 -US-Ton,20348,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20348,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20348,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20348,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20348,GRP_SWC,SWC_DATE,20070127 -US-Ton,20855,GRP_SWC,SWC,29.366666667 -US-Ton,20855,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.1522476799 -US-Ton,20855,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20855,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20855,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20855,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20855,GRP_SWC,SWC_DATE,20130410 -US-Ton,19933,GRP_SWC,SWC,29.396296296 -US-Ton,19933,GRP_SWC,SWC_SPATIAL_VARIABILITY,8.2474650052 -US-Ton,19933,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,19933,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19933,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,19933,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,19933,GRP_SWC,SWC_DATE,20030509 -US-Ton,20565,GRP_SWC,SWC,29.466666667 -US-Ton,20565,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.55768646 -US-Ton,20565,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20565,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20565,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20565,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20565,GRP_SWC,SWC_DATE,20090417 -US-Ton,20144,GRP_SWC,SWC,29.496296296 -US-Ton,20144,GRP_SWC,SWC_SPATIAL_VARIABILITY,10.073913568 -US-Ton,20144,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20144,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20144,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20144,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20144,GRP_SWC,SWC_DATE,20041118 -US-Ton,20489,GRP_SWC,SWC,29.545833333 -US-Ton,20489,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.2409009523 -US-Ton,20489,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20489,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20489,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20489,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20489,GRP_SWC,SWC_DATE,20080404 -US-Ton,20344,GRP_SWC,SWC,29.55 -US-Ton,20344,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.8479296633 -US-Ton,20344,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20344,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20344,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20344,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20344,GRP_SWC,SWC_DATE,20070119 -US-Ton,20466,GRP_SWC,SWC,29.552777778 -US-Ton,20466,GRP_SWC,SWC_SPATIAL_VARIABILITY,8.4070852554 -US-Ton,20466,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20466,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20466,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20466,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20466,GRP_SWC,SWC_DATE,20080117 -US-Ton,20148,GRP_SWC,SWC,29.605555556 -US-Ton,20148,GRP_SWC,SWC_SPATIAL_VARIABILITY,9.2740378357 -US-Ton,20148,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20148,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20148,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20148,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20148,GRP_SWC,SWC_DATE,20041120 -US-Ton,20145,GRP_SWC,SWC,29.644444444 -US-Ton,20145,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.3894538213 -US-Ton,20145,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20145,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20145,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20145,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20145,GRP_SWC,SWC_DATE,20041120 -US-Ton,20241,GRP_SWC,SWC,29.691666667 -US-Ton,20241,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.6395154931 -US-Ton,20241,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20241,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20241,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20241,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20241,GRP_SWC,SWC_DATE,20060223 -US-Ton,20340,GRP_SWC,SWC,29.75 -US-Ton,20340,GRP_SWC,SWC_SPATIAL_VARIABILITY,8.7725294372 -US-Ton,20340,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20340,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20340,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20340,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20340,GRP_SWC,SWC_DATE,20070115 -US-Ton,19777,GRP_SWC,SWC,29.82 -US-Ton,19777,GRP_SWC,SWC_SPATIAL_VARIABILITY,9.3633624065 -US-Ton,19777,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19777,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19777,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,19777,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,19777,GRP_SWC,SWC_DATE,20020411 -US-Ton,20152,GRP_SWC,SWC,29.888888889 -US-Ton,20152,GRP_SWC,SWC_SPATIAL_VARIABILITY,8.2948318917 -US-Ton,20152,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20152,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20152,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20152,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20152,GRP_SWC,SWC_DATE,20041128 -US-Ton,20679,GRP_SWC,SWC,29.920833333 -US-Ton,20679,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.5163170493 -US-Ton,20679,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20679,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20679,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20679,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20679,GRP_SWC,SWC_DATE,20110119 -US-Ton,20805,GRP_SWC,SWC,3.0090909091 -US-Ton,20805,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.9261124295 -US-Ton,20805,GRP_SWC,SWC_SPATIAL_REP_NUMBER,11 -US-Ton,20805,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20805,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20805,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20805,GRP_SWC,SWC_DATE,20120822 -US-Ton,20595,GRP_SWC,SWC,3.2972222222 -US-Ton,20595,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.9240350242 -US-Ton,20595,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20595,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20595,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20595,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20595,GRP_SWC,SWC_DATE,20091002 -US-Ton,20809,GRP_SWC,SWC,3.3181818182 -US-Ton,20809,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.4619555693 -US-Ton,20809,GRP_SWC,SWC_SPATIAL_REP_NUMBER,11 -US-Ton,20809,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20809,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20809,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20809,GRP_SWC,SWC_DATE,20120905 -US-Ton,20005,GRP_SWC,SWC,3.4333333333 -US-Ton,20005,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.9527224585 -US-Ton,20005,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20005,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20005,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20005,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20005,GRP_SWC,SWC_DATE,20030918 -US-Ton,20013,GRP_SWC,SWC,3.7277777778 -US-Ton,20013,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.1873372955 -US-Ton,20013,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20013,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20013,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20013,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20013,GRP_SWC,SWC_DATE,20031007 -US-Ton,20009,GRP_SWC,SWC,3.7648148148 -US-Ton,20009,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.6669259058 -US-Ton,20009,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20009,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20009,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20009,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20009,GRP_SWC,SWC_DATE,20031002 -US-Ton,20945,GRP_SWC,SWC,3.8090909091 -US-Ton,20945,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.351105652 -US-Ton,20945,GRP_SWC,SWC_SPATIAL_REP_NUMBER,11 -US-Ton,20945,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20945,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20945,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20945,GRP_SWC,SWC_DATE,20140709 -US-Ton,20724,GRP_SWC,SWC,3.8151515152 -US-Ton,20724,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.3160485332 -US-Ton,20724,GRP_SWC,SWC_SPATIAL_REP_NUMBER,11 -US-Ton,20724,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20724,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20724,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20724,GRP_SWC,SWC_DATE,20110831 -US-Ton,19849,GRP_SWC,SWC,3.8933333333 -US-Ton,19849,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.9609238186 -US-Ton,19849,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19849,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19849,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,19849,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,19849,GRP_SWC,SWC_DATE,20020829 -US-Ton,20017,GRP_SWC,SWC,3.9 -US-Ton,20017,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.4676236882 -US-Ton,20017,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20017,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20017,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20017,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20017,GRP_SWC,SWC_DATE,20031024 -US-Ton,20893,GRP_SWC,SWC,3.9318181818 -US-Ton,20893,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.2265750299 -US-Ton,20893,GRP_SWC,SWC_SPATIAL_REP_NUMBER,11 -US-Ton,20893,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20893,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20893,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20893,GRP_SWC,SWC_DATE,20131107 -US-Ton,20617,GRP_SWC,SWC,30 -US-Ton,20617,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.9195375568 -US-Ton,20617,GRP_SWC,SWC_SPATIAL_REP_NUMBER,11 -US-Ton,20617,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20617,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20617,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20617,GRP_SWC,SWC_DATE,20100108 -US-Ton,20141,GRP_SWC,SWC,30.037037037 -US-Ton,20141,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.0831263586 -US-Ton,20141,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20141,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20141,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20141,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20141,GRP_SWC,SWC_DATE,20041118 -US-Ton,20396,GRP_SWC,SWC,30.048484848 -US-Ton,20396,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.0233317402 -US-Ton,20396,GRP_SWC,SWC_SPATIAL_REP_NUMBER,11 -US-Ton,20396,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20396,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20396,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20396,GRP_SWC,SWC_DATE,20070428 -US-Ton,20195,GRP_SWC,SWC,30.208333333 -US-Ton,20195,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.6611046679 -US-Ton,20195,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20195,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20195,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20195,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20195,GRP_SWC,SWC_DATE,20050517 -US-Ton,19921,GRP_SWC,SWC,30.211111111 -US-Ton,19921,GRP_SWC,SWC_SPATIAL_VARIABILITY,8.9306121477 -US-Ton,19921,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,19921,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19921,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,19921,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,19921,GRP_SWC,SWC_DATE,20030416 -US-Ton,20371,GRP_SWC,SWC,30.225 -US-Ton,20371,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.468098821 -US-Ton,20371,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20371,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20371,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20371,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20371,GRP_SWC,SWC_DATE,20070316 -US-Ton,19934,GRP_SWC,SWC,30.233333333 -US-Ton,19934,GRP_SWC,SWC_SPATIAL_VARIABILITY,8.7504444332 -US-Ton,19934,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,19934,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19934,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,19934,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,19934,GRP_SWC,SWC_DATE,20030509 -US-Ton,20829,GRP_SWC,SWC,30.319444444 -US-Ton,20829,GRP_SWC,SWC_SPATIAL_VARIABILITY,8.0885342011 -US-Ton,20829,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20829,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20829,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20829,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20829,GRP_SWC,SWC_DATE,20130101 -US-Ton,20229,GRP_SWC,SWC,30.358333333 -US-Ton,20229,GRP_SWC,SWC_SPATIAL_VARIABILITY,8.161601707 -US-Ton,20229,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20229,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20229,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20229,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20229,GRP_SWC,SWC_DATE,20060110 -US-Ton,19922,GRP_SWC,SWC,30.418518519 -US-Ton,19922,GRP_SWC,SWC_SPATIAL_VARIABILITY,9.9902745918 -US-Ton,19922,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,19922,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19922,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,19922,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,19922,GRP_SWC,SWC_DATE,20030416 -US-Ton,20062,GRP_SWC,SWC,30.444444444 -US-Ton,20062,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.9571290537 -US-Ton,20062,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20062,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20062,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20062,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20062,GRP_SWC,SWC_DATE,20040123 -US-Ton,19791,GRP_SWC,SWC,30.446 -US-Ton,19791,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.9004622231 -US-Ton,19791,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19791,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19791,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,19791,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,19791,GRP_SWC,SWC_DATE,20020502 -US-Ton,20336,GRP_SWC,SWC,30.472222222 -US-Ton,20336,GRP_SWC,SWC_SPATIAL_VARIABILITY,8.4814930234 -US-Ton,20336,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20336,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20336,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20336,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20336,GRP_SWC,SWC_DATE,20070110 -US-Ton,20156,GRP_SWC,SWC,30.540740741 -US-Ton,20156,GRP_SWC,SWC_SPATIAL_VARIABILITY,8.4622327264 -US-Ton,20156,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20156,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20156,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20156,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20156,GRP_SWC,SWC_DATE,20041212 -US-Ton,20498,GRP_SWC,SWC,30.555555556 -US-Ton,20498,GRP_SWC,SWC_SPATIAL_VARIABILITY,8.6891472229 -US-Ton,20498,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20498,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20498,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20498,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20498,GRP_SWC,SWC_DATE,20080420 -US-Ton,20054,GRP_SWC,SWC,30.6 -US-Ton,20054,GRP_SWC,SWC_SPATIAL_VARIABILITY,8.0142841227 -US-Ton,20054,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20054,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20054,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20054,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20054,GRP_SWC,SWC_DATE,20031231 -US-Ton,20233,GRP_SWC,SWC,30.725 -US-Ton,20233,GRP_SWC,SWC_SPATIAL_VARIABILITY,8.042684423 -US-Ton,20233,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20233,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20233,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20233,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20233,GRP_SWC,SWC_DATE,20060124 -US-Ton,20355,GRP_SWC,SWC,30.866666667 -US-Ton,20355,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.4737250188 -US-Ton,20355,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20355,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20355,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20355,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20355,GRP_SWC,SWC_DATE,20070219 -US-Ton,20079,GRP_SWC,SWC,30.872222222 -US-Ton,20079,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.8996879962 -US-Ton,20079,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20079,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20079,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20079,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20079,GRP_SWC,SWC_DATE,20040325 -US-Ton,19737,GRP_SWC,SWC,30.933333333 -US-Ton,19737,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.3233265058 -US-Ton,19737,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Ton,19737,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19737,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,19737,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,19737,GRP_SWC,SWC_DATE,20011113 -US-Ton,20153,GRP_SWC,SWC,30.985185185 -US-Ton,20153,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.518011607 -US-Ton,20153,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20153,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20153,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20153,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20153,GRP_SWC,SWC_DATE,20041212 -US-Ton,19885,GRP_SWC,SWC,31.01 -US-Ton,19885,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.1528855019 -US-Ton,19885,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19885,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19885,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,19885,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,19885,GRP_SWC,SWC_DATE,20021214 -US-Ton,20780,GRP_SWC,SWC,31.025 -US-Ton,20780,GRP_SWC,SWC_SPATIAL_VARIABILITY,8.0859445954 -US-Ton,20780,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20780,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20780,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20780,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20780,GRP_SWC,SWC_DATE,20120405 -US-Ton,20083,GRP_SWC,SWC,31.027777778 -US-Ton,20083,GRP_SWC,SWC_SPATIAL_VARIABILITY,8.4369392818 -US-Ton,20083,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20083,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20083,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20083,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20083,GRP_SWC,SWC_DATE,20040402 -US-Ton,20635,GRP_SWC,SWC,31.108333333 -US-Ton,20635,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.9802549895 -US-Ton,20635,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20635,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20635,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20635,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20635,GRP_SWC,SWC_DATE,20100430 -US-Ton,20475,GRP_SWC,SWC,31.116666667 -US-Ton,20475,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.999132934 -US-Ton,20475,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20475,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20475,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20475,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20475,GRP_SWC,SWC_DATE,20080302 -US-Ton,20191,GRP_SWC,SWC,31.125 -US-Ton,20191,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.851048857 -US-Ton,20191,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20191,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20191,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20191,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20191,GRP_SWC,SWC_DATE,20050425 -US-Ton,20981,GRP_SWC,SWC,31.129166667 -US-Ton,20981,GRP_SWC,SWC_SPATIAL_VARIABILITY,8.0136377602 -US-Ton,20981,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20981,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20981,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20981,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20981,GRP_SWC,SWC_DATE,20141223 -US-Ton,20237,GRP_SWC,SWC,31.183333333 -US-Ton,20237,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.8446662057 -US-Ton,20237,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20237,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20237,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20237,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20237,GRP_SWC,SWC_DATE,20060210 -US-Ton,20642,GRP_SWC,SWC,31.225 -US-Ton,20642,GRP_SWC,SWC_SPATIAL_VARIABILITY,10.812293088 -US-Ton,20642,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20642,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20642,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20642,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20642,GRP_SWC,SWC_DATE,20100528 -US-Ton,20628,GRP_SWC,SWC,31.266666667 -US-Ton,20628,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.8873181657 -US-Ton,20628,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20628,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20628,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20628,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20628,GRP_SWC,SWC_DATE,20100321 -US-Ton,19741,GRP_SWC,SWC,31.273333333 -US-Ton,19741,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.6541709762 -US-Ton,19741,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19741,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19741,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,19741,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,19741,GRP_SWC,SWC_DATE,20011125 -US-Ton,20367,GRP_SWC,SWC,31.375 -US-Ton,20367,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.6167429212 -US-Ton,20367,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20367,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20367,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20367,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20367,GRP_SWC,SWC_DATE,20070310 -US-Ton,20349,GRP_SWC,SWC,31.430555556 -US-Ton,20349,GRP_SWC,SWC_SPATIAL_VARIABILITY,14.403425928 -US-Ton,20349,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20349,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20349,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20349,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20349,GRP_SWC,SWC_DATE,20070127 -US-Ton,20146,GRP_SWC,SWC,31.461111111 -US-Ton,20146,GRP_SWC,SWC_SPATIAL_VARIABILITY,9.7330229688 -US-Ton,20146,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20146,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20146,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20146,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20146,GRP_SWC,SWC_DATE,20041120 -US-Ton,20353,GRP_SWC,SWC,31.5375 -US-Ton,20353,GRP_SWC,SWC_SPATIAL_VARIABILITY,14.02361847 -US-Ton,20353,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20353,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20353,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20353,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20353,GRP_SWC,SWC_DATE,20070204 -US-Ton,20363,GRP_SWC,SWC,31.5375 -US-Ton,20363,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.3165053133 -US-Ton,20363,GRP_SWC,SWC_SPATIAL_REP_NUMBER,8 -US-Ton,20363,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20363,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20363,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20363,GRP_SWC,SWC_DATE,20070304 -US-Ton,20913,GRP_SWC,SWC,31.566666667 -US-Ton,20913,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.66756253 -US-Ton,20913,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20913,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20913,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20913,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20913,GRP_SWC,SWC_DATE,20140210 -US-Ton,20917,GRP_SWC,SWC,31.566666667 -US-Ton,20917,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.66756253 -US-Ton,20917,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20917,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20917,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20917,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20917,GRP_SWC,SWC_DATE,20140304 -US-Ton,20149,GRP_SWC,SWC,31.572222222 -US-Ton,20149,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.1282191087 -US-Ton,20149,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20149,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20149,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20149,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20149,GRP_SWC,SWC_DATE,20041128 -US-Ton,20225,GRP_SWC,SWC,31.647222222 -US-Ton,20225,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.424916533 -US-Ton,20225,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20225,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20225,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20225,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20225,GRP_SWC,SWC_DATE,20051229 -US-Ton,20766,GRP_SWC,SWC,31.666666667 -US-Ton,20766,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.0269973428 -US-Ton,20766,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20766,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20766,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20766,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20766,GRP_SWC,SWC_DATE,20120201 -US-Ton,19926,GRP_SWC,SWC,31.711111111 -US-Ton,19926,GRP_SWC,SWC_SPATIAL_VARIABILITY,9.0301962572 -US-Ton,19926,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,19926,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19926,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,19926,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,19926,GRP_SWC,SWC_DATE,20030425 -US-Ton,20142,GRP_SWC,SWC,31.72962963 -US-Ton,20142,GRP_SWC,SWC_SPATIAL_VARIABILITY,9.8163758367 -US-Ton,20142,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20142,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20142,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20142,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20142,GRP_SWC,SWC_DATE,20041118 -US-Ton,20341,GRP_SWC,SWC,31.736111111 -US-Ton,20341,GRP_SWC,SWC_SPATIAL_VARIABILITY,14.55471362 -US-Ton,20341,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20341,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20341,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20341,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20341,GRP_SWC,SWC_DATE,20070115 -US-Ton,20242,GRP_SWC,SWC,31.754166667 -US-Ton,20242,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.6463139763 -US-Ton,20242,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20242,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20242,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20242,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20242,GRP_SWC,SWC_DATE,20060223 -US-Ton,19742,GRP_SWC,SWC,31.76 -US-Ton,19742,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.7825917041 -US-Ton,19742,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19742,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19742,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,19742,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,19742,GRP_SWC,SWC_DATE,20011125 -US-Ton,19897,GRP_SWC,SWC,31.806666667 -US-Ton,19897,GRP_SWC,SWC_SPATIAL_VARIABILITY,8.2141273967 -US-Ton,19897,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19897,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19897,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,19897,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,19897,GRP_SWC,SWC_DATE,20030129 -US-Ton,20556,GRP_SWC,SWC,31.808333333 -US-Ton,20556,GRP_SWC,SWC_SPATIAL_VARIABILITY,10.123820545 -US-Ton,20556,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20556,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20556,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20556,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20556,GRP_SWC,SWC_DATE,20090327 -US-Ton,20337,GRP_SWC,SWC,31.855555556 -US-Ton,20337,GRP_SWC,SWC_SPATIAL_VARIABILITY,14.11259437 -US-Ton,20337,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20337,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20337,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20337,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20337,GRP_SWC,SWC_DATE,20070110 -US-Ton,20234,GRP_SWC,SWC,31.883333333 -US-Ton,20234,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.8021286585 -US-Ton,20234,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20234,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20234,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20234,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20234,GRP_SWC,SWC_DATE,20060124 -US-Ton,19902,GRP_SWC,SWC,31.9 -US-Ton,19902,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.4566236993 -US-Ton,19902,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19902,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19902,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,19902,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,19902,GRP_SWC,SWC_DATE,20030213 -US-Ton,20162,GRP_SWC,SWC,31.907407407 -US-Ton,20162,GRP_SWC,SWC_SPATIAL_VARIABILITY,9.7380094044 -US-Ton,20162,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20162,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20162,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20162,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20162,GRP_SWC,SWC_DATE,20041226 -US-Ton,20330,GRP_SWC,SWC,31.911111111 -US-Ton,20330,GRP_SWC,SWC_SPATIAL_VARIABILITY,9.396446065 -US-Ton,20330,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20330,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20330,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20330,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20330,GRP_SWC,SWC_DATE,20070106 -US-Ton,20331,GRP_SWC,SWC,31.930555556 -US-Ton,20331,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.0960005571 -US-Ton,20331,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20331,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20331,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20331,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20331,GRP_SWC,SWC_DATE,20070106 -US-Ton,20173,GRP_SWC,SWC,31.977777778 -US-Ton,20173,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.6464288784 -US-Ton,20173,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20173,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20173,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20173,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20173,GRP_SWC,SWC_DATE,20050208 -US-Ton,20471,GRP_SWC,SWC,31.994444444 -US-Ton,20471,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.8951696438 -US-Ton,20471,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20471,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20471,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20471,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20471,GRP_SWC,SWC_DATE,20080210 -US-Ton,20181,GRP_SWC,SWC,32.016666667 -US-Ton,20181,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.7144123595 -US-Ton,20181,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20181,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20181,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20181,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20181,GRP_SWC,SWC_DATE,20050309 -US-Ton,20636,GRP_SWC,SWC,32.016666667 -US-Ton,20636,GRP_SWC,SWC_SPATIAL_VARIABILITY,8.176110804 -US-Ton,20636,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20636,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20636,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20636,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20636,GRP_SWC,SWC_DATE,20100430 -US-Ton,20065,GRP_SWC,SWC,32.05 -US-Ton,20065,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.8844073618 -US-Ton,20065,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20065,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20065,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20065,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20065,GRP_SWC,SWC_DATE,20040130 -US-Ton,20770,GRP_SWC,SWC,32.056944444 -US-Ton,20770,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.334071789 -US-Ton,20770,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20770,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20770,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20770,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20770,GRP_SWC,SWC_DATE,20120216 -US-Ton,20613,GRP_SWC,SWC,32.0625 -US-Ton,20613,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.7929783372 -US-Ton,20613,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20613,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20613,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20613,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20613,GRP_SWC,SWC_DATE,20091222 -US-Ton,20683,GRP_SWC,SWC,32.083333333 -US-Ton,20683,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.3907890017 -US-Ton,20683,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20683,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20683,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20683,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20683,GRP_SWC,SWC_DATE,20110222 -US-Ton,20345,GRP_SWC,SWC,32.0875 -US-Ton,20345,GRP_SWC,SWC_SPATIAL_VARIABILITY,14.284990931 -US-Ton,20345,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20345,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20345,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20345,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20345,GRP_SWC,SWC_DATE,20070119 -US-Ton,20549,GRP_SWC,SWC,32.095833333 -US-Ton,20549,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.6692121088 -US-Ton,20549,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20549,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20549,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20549,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20549,GRP_SWC,SWC_DATE,20090210 -US-Ton,20254,GRP_SWC,SWC,32.115277778 -US-Ton,20254,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.1325737996 -US-Ton,20254,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20254,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20254,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20254,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20254,GRP_SWC,SWC_DATE,20060318 -US-Ton,20561,GRP_SWC,SWC,32.141666667 -US-Ton,20561,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.7425997594 -US-Ton,20561,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20561,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20561,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20561,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20561,GRP_SWC,SWC_DATE,20090403 -US-Ton,20767,GRP_SWC,SWC,32.268181818 -US-Ton,20767,GRP_SWC,SWC_SPATIAL_VARIABILITY,15.581580034 -US-Ton,20767,GRP_SWC,SWC_SPATIAL_REP_NUMBER,11 -US-Ton,20767,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20767,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20767,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20767,GRP_SWC,SWC_DATE,20120201 -US-Ton,20066,GRP_SWC,SWC,32.272222222 -US-Ton,20066,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.9715945359 -US-Ton,20066,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20066,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20066,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20066,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20066,GRP_SWC,SWC_DATE,20040130 -US-Ton,20154,GRP_SWC,SWC,32.288888889 -US-Ton,20154,GRP_SWC,SWC_SPATIAL_VARIABILITY,8.4927747069 -US-Ton,20154,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20154,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20154,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20154,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20154,GRP_SWC,SWC_DATE,20041212 -US-Ton,20774,GRP_SWC,SWC,32.3625 -US-Ton,20774,GRP_SWC,SWC_SPATIAL_VARIABILITY,8.0053426762 -US-Ton,20774,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20774,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20774,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20774,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20774,GRP_SWC,SWC_DATE,20120302 -US-Ton,19925,GRP_SWC,SWC,32.407407407 -US-Ton,19925,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.49126858 -US-Ton,19925,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,19925,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19925,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,19925,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,19925,GRP_SWC,SWC_DATE,20030425 -US-Ton,20177,GRP_SWC,SWC,32.463888889 -US-Ton,20177,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.2745672044 -US-Ton,20177,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20177,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20177,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20177,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20177,GRP_SWC,SWC_DATE,20050226 -US-Ton,20480,GRP_SWC,SWC,32.469444444 -US-Ton,20480,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.4454576802 -US-Ton,20480,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20480,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20480,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20480,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20480,GRP_SWC,SWC_DATE,20080306 -US-Ton,20074,GRP_SWC,SWC,32.481481481 -US-Ton,20074,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.9395084705 -US-Ton,20074,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20074,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20074,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20074,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20074,GRP_SWC,SWC_DATE,20040321 -US-Ton,20147,GRP_SWC,SWC,32.511111111 -US-Ton,20147,GRP_SWC,SWC_SPATIAL_VARIABILITY,9.3082549982 -US-Ton,20147,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20147,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20147,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20147,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20147,GRP_SWC,SWC_DATE,20041120 -US-Ton,20838,GRP_SWC,SWC,32.608333333 -US-Ton,20838,GRP_SWC,SWC_SPATIAL_VARIABILITY,10.716211876 -US-Ton,20838,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20838,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20838,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20838,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20838,GRP_SWC,SWC_DATE,20130206 -US-Ton,20931,GRP_SWC,SWC,32.658333333 -US-Ton,20931,GRP_SWC,SWC_SPATIAL_VARIABILITY,8.3287790585 -US-Ton,20931,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20931,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20931,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20931,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20931,GRP_SWC,SWC_DATE,20140422 -US-Ton,19930,GRP_SWC,SWC,32.662962963 -US-Ton,19930,GRP_SWC,SWC_SPATIAL_VARIABILITY,8.5271371457 -US-Ton,19930,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,19930,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19930,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,19930,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,19930,GRP_SWC,SWC_DATE,20030430 -US-Ton,20551,GRP_SWC,SWC,32.730555556 -US-Ton,20551,GRP_SWC,SWC_SPATIAL_VARIABILITY,8.1964818559 -US-Ton,20551,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20551,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20551,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20551,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20551,GRP_SWC,SWC_DATE,20090227 -US-Ton,20851,GRP_SWC,SWC,32.7375 -US-Ton,20851,GRP_SWC,SWC_SPATIAL_VARIABILITY,9.2847167921 -US-Ton,20851,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20851,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20851,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20851,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20851,GRP_SWC,SWC_DATE,20130327 -US-Ton,19909,GRP_SWC,SWC,32.743333333 -US-Ton,19909,GRP_SWC,SWC_SPATIAL_VARIABILITY,9.3662336792 -US-Ton,19909,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19909,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19909,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,19909,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,19909,GRP_SWC,SWC_DATE,20030227 -US-Ton,20088,GRP_SWC,SWC,32.766666667 -US-Ton,20088,GRP_SWC,SWC_SPATIAL_VARIABILITY,11.821390687 -US-Ton,20088,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20088,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20088,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20088,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20088,GRP_SWC,SWC_DATE,20040409 -US-Ton,20164,GRP_SWC,SWC,32.774074074 -US-Ton,20164,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.4929294402 -US-Ton,20164,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20164,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20164,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20164,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20164,GRP_SWC,SWC_DATE,20041226 -US-Ton,20178,GRP_SWC,SWC,32.811111111 -US-Ton,20178,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.5504157218 -US-Ton,20178,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20178,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20178,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20178,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20178,GRP_SWC,SWC_DATE,20050226 -US-Ton,20358,GRP_SWC,SWC,32.829166667 -US-Ton,20358,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.3104813539 -US-Ton,20358,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20358,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20358,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20358,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20358,GRP_SWC,SWC_DATE,20070302 -US-Ton,20182,GRP_SWC,SWC,32.866666667 -US-Ton,20182,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.3372754876 -US-Ton,20182,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20182,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20182,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20182,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20182,GRP_SWC,SWC_DATE,20050309 -US-Ton,20230,GRP_SWC,SWC,32.866666667 -US-Ton,20230,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.9632036675 -US-Ton,20230,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20230,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20230,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20230,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20230,GRP_SWC,SWC_DATE,20060110 -US-Ton,20388,GRP_SWC,SWC,32.895833333 -US-Ton,20388,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.8454520217 -US-Ton,20388,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20388,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20388,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20388,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20388,GRP_SWC,SWC_DATE,20070405 -US-Ton,20058,GRP_SWC,SWC,32.922222222 -US-Ton,20058,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.2336609469 -US-Ton,20058,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20058,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20058,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20058,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20058,GRP_SWC,SWC_DATE,20040108 -US-Ton,20680,GRP_SWC,SWC,32.925 -US-Ton,20680,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.3518241398 -US-Ton,20680,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20680,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20680,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20680,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20680,GRP_SWC,SWC_DATE,20110119 -US-Ton,20069,GRP_SWC,SWC,32.964814815 -US-Ton,20069,GRP_SWC,SWC_SPATIAL_VARIABILITY,8.0269184469 -US-Ton,20069,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20069,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20069,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20069,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20069,GRP_SWC,SWC_DATE,20040305 -US-Ton,20238,GRP_SWC,SWC,33.05 -US-Ton,20238,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.7245141764 -US-Ton,20238,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20238,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20238,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20238,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20238,GRP_SWC,SWC_DATE,20060210 -US-Ton,20151,GRP_SWC,SWC,33.083333333 -US-Ton,20151,GRP_SWC,SWC_SPATIAL_VARIABILITY,9.1612976701 -US-Ton,20151,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20151,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20151,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20151,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20151,GRP_SWC,SWC_DATE,20041128 -US-Ton,20174,GRP_SWC,SWC,33.083333333 -US-Ton,20174,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.504660334 -US-Ton,20174,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20174,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20174,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20174,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20174,GRP_SWC,SWC_DATE,20050208 -US-Ton,20771,GRP_SWC,SWC,33.111111111 -US-Ton,20771,GRP_SWC,SWC_SPATIAL_VARIABILITY,11.888272664 -US-Ton,20771,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20771,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20771,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20771,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20771,GRP_SWC,SWC_DATE,20120216 -US-Ton,20150,GRP_SWC,SWC,33.177777778 -US-Ton,20150,GRP_SWC,SWC_SPATIAL_VARIABILITY,8.4046903241 -US-Ton,20150,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20150,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20150,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20150,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20150,GRP_SWC,SWC_DATE,20041128 -US-Ton,20271,GRP_SWC,SWC,33.1875 -US-Ton,20271,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.6044793684 -US-Ton,20271,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20271,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20271,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20271,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20271,GRP_SWC,SWC_DATE,20060504 -US-Ton,20169,GRP_SWC,SWC,33.227777778 -US-Ton,20169,GRP_SWC,SWC_SPATIAL_VARIABILITY,8.4184841522 -US-Ton,20169,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20169,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20169,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20169,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20169,GRP_SWC,SWC_DATE,20050127 -US-Ton,20781,GRP_SWC,SWC,33.229166667 -US-Ton,20781,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.9030045591 -US-Ton,20781,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20781,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20781,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20781,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20781,GRP_SWC,SWC_DATE,20120405 -US-Ton,20675,GRP_SWC,SWC,33.233333333 -US-Ton,20675,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.8882344301 -US-Ton,20675,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20675,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20675,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20675,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20675,GRP_SWC,SWC_DATE,20101230 -US-Ton,20397,GRP_SWC,SWC,33.390909091 -US-Ton,20397,GRP_SWC,SWC_SPATIAL_VARIABILITY,9.4827573452 -US-Ton,20397,GRP_SWC,SWC_SPATIAL_REP_NUMBER,11 -US-Ton,20397,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20397,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20397,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20397,GRP_SWC,SWC_DATE,20070428 -US-Ton,20860,GRP_SWC,SWC,33.436111111 -US-Ton,20860,GRP_SWC,SWC_SPATIAL_VARIABILITY,12.720683931 -US-Ton,20860,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20860,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20860,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20860,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20860,GRP_SWC,SWC_DATE,20130424 -US-Ton,20775,GRP_SWC,SWC,33.445833333 -US-Ton,20775,GRP_SWC,SWC_SPATIAL_VARIABILITY,16.425153359 -US-Ton,20775,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20775,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20775,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20775,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20775,GRP_SWC,SWC_DATE,20120302 -US-Ton,20186,GRP_SWC,SWC,33.525 -US-Ton,20186,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.5492365967 -US-Ton,20186,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20186,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20186,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20186,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20186,GRP_SWC,SWC_DATE,20050324 -US-Ton,20161,GRP_SWC,SWC,33.544444444 -US-Ton,20161,GRP_SWC,SWC_SPATIAL_VARIABILITY,8.424748595 -US-Ton,20161,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20161,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20161,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20161,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20161,GRP_SWC,SWC_DATE,20041226 -US-Ton,19905,GRP_SWC,SWC,33.56 -US-Ton,19905,GRP_SWC,SWC_SPATIAL_VARIABILITY,8.0408581632 -US-Ton,19905,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19905,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19905,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,19905,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,19905,GRP_SWC,SWC_DATE,20030221 -US-Ton,19901,GRP_SWC,SWC,33.58 -US-Ton,19901,GRP_SWC,SWC_SPATIAL_VARIABILITY,8.5165720804 -US-Ton,19901,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19901,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19901,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,19901,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,19901,GRP_SWC,SWC_DATE,20030213 -US-Ton,20166,GRP_SWC,SWC,33.611111111 -US-Ton,20166,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.890340492 -US-Ton,20166,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20166,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20166,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20166,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20166,GRP_SWC,SWC_DATE,20050117 -US-Ton,20384,GRP_SWC,SWC,33.644444444 -US-Ton,20384,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.6996507271 -US-Ton,20384,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20384,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20384,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20384,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20384,GRP_SWC,SWC_DATE,20070402 -US-Ton,20070,GRP_SWC,SWC,33.698148148 -US-Ton,20070,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.1725222449 -US-Ton,20070,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20070,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20070,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20070,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20070,GRP_SWC,SWC_DATE,20040305 -US-Ton,20792,GRP_SWC,SWC,33.702777778 -US-Ton,20792,GRP_SWC,SWC_SPATIAL_VARIABILITY,14.212945503 -US-Ton,20792,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20792,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20792,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20792,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20792,GRP_SWC,SWC_DATE,20120518 -US-Ton,20847,GRP_SWC,SWC,33.775 -US-Ton,20847,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.6277824346 -US-Ton,20847,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20847,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20847,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20847,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20847,GRP_SWC,SWC_DATE,20130313 -US-Ton,19929,GRP_SWC,SWC,33.798148148 -US-Ton,19929,GRP_SWC,SWC_SPATIAL_VARIABILITY,8.0008265391 -US-Ton,19929,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,19929,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19929,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,19929,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,19929,GRP_SWC,SWC_DATE,20030430 -US-Ton,20160,GRP_SWC,SWC,33.807407407 -US-Ton,20160,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.6476898796 -US-Ton,20160,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20160,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20160,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20160,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20160,GRP_SWC,SWC_DATE,20041215 -US-Ton,19787,GRP_SWC,SWC,33.834 -US-Ton,19787,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.5119624454 -US-Ton,19787,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19787,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19787,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,19787,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,19787,GRP_SWC,SWC_DATE,20020426 -US-Ton,20476,GRP_SWC,SWC,33.858333333 -US-Ton,20476,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.379730977 -US-Ton,20476,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20476,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20476,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20476,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20476,GRP_SWC,SWC_DATE,20080302 -US-Ton,20485,GRP_SWC,SWC,33.952917778 -US-Ton,20485,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.5036663089 -US-Ton,20485,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20485,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20485,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20485,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20485,GRP_SWC,SWC_DATE,20080322 -US-Ton,20777,GRP_SWC,SWC,33.966666667 -US-Ton,20777,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.3466855029 -US-Ton,20777,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20777,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20777,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20777,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20777,GRP_SWC,SWC_DATE,20120321 -US-Ton,20155,GRP_SWC,SWC,34.018518519 -US-Ton,20155,GRP_SWC,SWC_SPATIAL_VARIABILITY,9.1916796783 -US-Ton,20155,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20155,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20155,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20155,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20155,GRP_SWC,SWC_DATE,20041212 -US-Ton,19738,GRP_SWC,SWC,34.025 -US-Ton,19738,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.52519837522 -US-Ton,19738,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Ton,19738,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19738,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,19738,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,19738,GRP_SWC,SWC_DATE,20011113 -US-Ton,19778,GRP_SWC,SWC,34.066666667 -US-Ton,19778,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.2389127119 -US-Ton,19778,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19778,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19778,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,19778,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,19778,GRP_SWC,SWC_DATE,20020411 -US-Ton,20143,GRP_SWC,SWC,34.074074074 -US-Ton,20143,GRP_SWC,SWC_SPATIAL_VARIABILITY,9.4498203654 -US-Ton,20143,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20143,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20143,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20143,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20143,GRP_SWC,SWC_DATE,20041118 -US-Ton,20926,GRP_SWC,SWC,34.116666667 -US-Ton,20926,GRP_SWC,SWC_SPATIAL_VARIABILITY,9.3357653758 -US-Ton,20926,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20926,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20926,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20926,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20926,GRP_SWC,SWC_DATE,20140408 -US-Ton,20914,GRP_SWC,SWC,34.129166667 -US-Ton,20914,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.8709023601 -US-Ton,20914,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20914,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20914,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20914,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20914,GRP_SWC,SWC_DATE,20140210 -US-Ton,20918,GRP_SWC,SWC,34.129166667 -US-Ton,20918,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.8709023601 -US-Ton,20918,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20918,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20918,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20918,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20918,GRP_SWC,SWC_DATE,20140304 -US-Ton,20619,GRP_SWC,SWC,34.133333333 -US-Ton,20619,GRP_SWC,SWC_SPATIAL_VARIABILITY,8.9347918303 -US-Ton,20619,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20619,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20619,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20619,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20619,GRP_SWC,SWC_DATE,20100210 -US-Ton,20158,GRP_SWC,SWC,34.151851852 -US-Ton,20158,GRP_SWC,SWC_SPATIAL_VARIABILITY,9.5574013075 -US-Ton,20158,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20158,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20158,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20158,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20158,GRP_SWC,SWC_DATE,20041215 -US-Ton,20472,GRP_SWC,SWC,34.161111111 -US-Ton,20472,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.2114223836 -US-Ton,20472,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20472,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20472,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20472,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20472,GRP_SWC,SWC_DATE,20080210 -US-Ton,20253,GRP_SWC,SWC,34.163888889 -US-Ton,20253,GRP_SWC,SWC_SPATIAL_VARIABILITY,8.4975154816 -US-Ton,20253,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20253,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20253,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20253,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20253,GRP_SWC,SWC_DATE,20060318 -US-Ton,20170,GRP_SWC,SWC,34.225 -US-Ton,20170,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.7365587298 -US-Ton,20170,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20170,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20170,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20170,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20170,GRP_SWC,SWC_DATE,20050127 -US-Ton,20055,GRP_SWC,SWC,34.305555556 -US-Ton,20055,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.0111716409 -US-Ton,20055,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20055,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20055,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20055,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20055,GRP_SWC,SWC_DATE,20031231 -US-Ton,20163,GRP_SWC,SWC,34.318518519 -US-Ton,20163,GRP_SWC,SWC_SPATIAL_VARIABILITY,9.4476718342 -US-Ton,20163,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20163,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20163,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20163,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20163,GRP_SWC,SWC_DATE,20041226 -US-Ton,20623,GRP_SWC,SWC,34.433333333 -US-Ton,20623,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.927590862 -US-Ton,20623,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20623,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20623,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20623,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20623,GRP_SWC,SWC_DATE,20100305 -US-Ton,20834,GRP_SWC,SWC,34.45 -US-Ton,20834,GRP_SWC,SWC_SPATIAL_VARIABILITY,8.9863785809 -US-Ton,20834,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20834,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20834,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20834,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20834,GRP_SWC,SWC_DATE,20130116 -US-Ton,20380,GRP_SWC,SWC,34.491666667 -US-Ton,20380,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.6207800046 -US-Ton,20380,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20380,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20380,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20380,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20380,GRP_SWC,SWC_DATE,20070328 -US-Ton,20826,GRP_SWC,SWC,34.5 -US-Ton,20826,GRP_SWC,SWC_SPATIAL_VARIABILITY,10.461183663 -US-Ton,20826,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20826,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20826,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20826,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20826,GRP_SWC,SWC_DATE,20121211 -US-Ton,19910,GRP_SWC,SWC,34.603333333 -US-Ton,19910,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.2069022782 -US-Ton,19910,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19910,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19910,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,19910,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,19910,GRP_SWC,SWC_DATE,20030227 -US-Ton,20063,GRP_SWC,SWC,34.666666667 -US-Ton,20063,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.7632547942 -US-Ton,20063,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20063,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20063,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20063,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20063,GRP_SWC,SWC_DATE,20040123 -US-Ton,20923,GRP_SWC,SWC,34.7375 -US-Ton,20923,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.9308946512 -US-Ton,20923,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20923,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20923,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20923,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20923,GRP_SWC,SWC_DATE,20140318 -US-Ton,20359,GRP_SWC,SWC,34.751388889 -US-Ton,20359,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.9240886004 -US-Ton,20359,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20359,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20359,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20359,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20359,GRP_SWC,SWC_DATE,20070302 -US-Ton,19913,GRP_SWC,SWC,34.786666667 -US-Ton,19913,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.1992203811 -US-Ton,19913,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19913,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19913,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,19913,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,19913,GRP_SWC,SWC_DATE,20030317 -US-Ton,20687,GRP_SWC,SWC,34.827777778 -US-Ton,20687,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.1153694989 -US-Ton,20687,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20687,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20687,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20687,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20687,GRP_SWC,SWC_DATE,20110308 -US-Ton,20157,GRP_SWC,SWC,34.840740741 -US-Ton,20157,GRP_SWC,SWC_SPATIAL_VARIABILITY,9.0450535558 -US-Ton,20157,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20157,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20157,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20157,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20157,GRP_SWC,SWC_DATE,20041215 -US-Ton,19889,GRP_SWC,SWC,34.86 -US-Ton,19889,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.7345329529 -US-Ton,19889,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19889,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19889,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,19889,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,19889,GRP_SWC,SWC_DATE,20021223 -US-Ton,20376,GRP_SWC,SWC,34.863888889 -US-Ton,20376,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.6461876113 -US-Ton,20376,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20376,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20376,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20376,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20376,GRP_SWC,SWC_DATE,20070319 -US-Ton,20226,GRP_SWC,SWC,34.927777778 -US-Ton,20226,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.4754511839 -US-Ton,20226,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20226,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20226,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20226,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20226,GRP_SWC,SWC_DATE,20051229 -US-Ton,20467,GRP_SWC,SWC,34.951543333 -US-Ton,20467,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.4560550525 -US-Ton,20467,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20467,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20467,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20467,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20467,GRP_SWC,SWC_DATE,20080130 -US-Ton,20932,GRP_SWC,SWC,35.036363636 -US-Ton,20932,GRP_SWC,SWC_SPATIAL_VARIABILITY,14.196797014 -US-Ton,20932,GRP_SWC,SWC_SPATIAL_REP_NUMBER,11 -US-Ton,20932,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20932,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20932,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20932,GRP_SWC,SWC_DATE,20140422 -US-Ton,20165,GRP_SWC,SWC,35.044444444 -US-Ton,20165,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.010547609 -US-Ton,20165,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20165,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20165,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20165,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20165,GRP_SWC,SWC_DATE,20050117 -US-Ton,20697,GRP_SWC,SWC,35.073611111 -US-Ton,20697,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.3992086724 -US-Ton,20697,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20697,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20697,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20697,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20697,GRP_SWC,SWC_DATE,20110415 -US-Ton,19906,GRP_SWC,SWC,35.1 -US-Ton,19906,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.4439619473 -US-Ton,19906,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19906,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19906,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,19906,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,19906,GRP_SWC,SWC_DATE,20030221 -US-Ton,20691,GRP_SWC,SWC,35.108333333 -US-Ton,20691,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.5800525704 -US-Ton,20691,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20691,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20691,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20691,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20691,GRP_SWC,SWC_DATE,20110330 -US-Ton,20266,GRP_SWC,SWC,35.25 -US-Ton,20266,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.063697376 -US-Ton,20266,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20266,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20266,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20266,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20266,GRP_SWC,SWC_DATE,20060418 -US-Ton,20830,GRP_SWC,SWC,35.25 -US-Ton,20830,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.78947425 -US-Ton,20830,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20830,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20830,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20830,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20830,GRP_SWC,SWC_DATE,20130101 -US-Ton,20056,GRP_SWC,SWC,35.455555556 -US-Ton,20056,GRP_SWC,SWC_SPATIAL_VARIABILITY,12.447877441 -US-Ton,20056,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20056,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20056,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20056,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20056,GRP_SWC,SWC_DATE,20031231 -US-Ton,20633,GRP_SWC,SWC,35.508333333 -US-Ton,20633,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.1283926906 -US-Ton,20633,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20633,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20633,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20633,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20633,GRP_SWC,SWC_DATE,20100402 -US-Ton,19796,GRP_SWC,SWC,35.536666667 -US-Ton,19796,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.591816392 -US-Ton,19796,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19796,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19796,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,19796,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,19796,GRP_SWC,SWC_DATE,20020509 -US-Ton,20557,GRP_SWC,SWC,35.584722222 -US-Ton,20557,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.2636137025 -US-Ton,20557,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20557,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20557,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20557,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20557,GRP_SWC,SWC_DATE,20090327 -US-Ton,20692,GRP_SWC,SWC,35.629166667 -US-Ton,20692,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.7922903599 -US-Ton,20692,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20692,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20692,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20692,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20692,GRP_SWC,SWC_DATE,20110330 -US-Ton,20243,GRP_SWC,SWC,35.675 -US-Ton,20243,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.4220718952 -US-Ton,20243,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20243,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20243,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20243,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20243,GRP_SWC,SWC_DATE,20060223 -US-Ton,20247,GRP_SWC,SWC,35.702777778 -US-Ton,20247,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.4092598932 -US-Ton,20247,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20247,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20247,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20247,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20247,GRP_SWC,SWC_DATE,20060304 -US-Ton,20550,GRP_SWC,SWC,35.720833333 -US-Ton,20550,GRP_SWC,SWC_SPATIAL_VARIABILITY,14.927209115 -US-Ton,20550,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20550,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20550,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20550,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20550,GRP_SWC,SWC_DATE,20090210 -US-Ton,19773,GRP_SWC,SWC,35.73 -US-Ton,19773,GRP_SWC,SWC_SPATIAL_VARIABILITY,10.033356866 -US-Ton,19773,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19773,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19773,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,19773,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,19773,GRP_SWC,SWC_DATE,20020404 -US-Ton,19893,GRP_SWC,SWC,35.806666667 -US-Ton,19893,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.4161760137 -US-Ton,19893,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19893,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19893,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,19893,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,19893,GRP_SWC,SWC_DATE,20030104 -US-Ton,20185,GRP_SWC,SWC,35.866666667 -US-Ton,20185,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.8945410993 -US-Ton,20185,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20185,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20185,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20185,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20185,GRP_SWC,SWC_DATE,20050324 -US-Ton,20673,GRP_SWC,SWC,35.983333333 -US-Ton,20673,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.7386779176 -US-Ton,20673,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20673,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20673,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20673,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20673,GRP_SWC,SWC_DATE,20101202 -US-Ton,19745,GRP_SWC,SWC,36 -US-Ton,19745,GRP_SWC,SWC_SPATIAL_VARIABILITY,9.3776329636 -US-Ton,19745,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19745,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19745,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,19745,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,19745,GRP_SWC,SWC_DATE,20011219 -US-Ton,20249,GRP_SWC,SWC,36.029166667 -US-Ton,20249,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.1970782687 -US-Ton,20249,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20249,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20249,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20249,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20249,GRP_SWC,SWC_DATE,20060308 -US-Ton,19890,GRP_SWC,SWC,36.04 -US-Ton,19890,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.95289033997 -US-Ton,19890,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19890,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19890,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,19890,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,19890,GRP_SWC,SWC_DATE,20021223 -US-Ton,20982,GRP_SWC,SWC,36.05 -US-Ton,20982,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.1194356263 -US-Ton,20982,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20982,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20982,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20982,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20982,GRP_SWC,SWC_DATE,20141223 -US-Ton,20356,GRP_SWC,SWC,36.069444444 -US-Ton,20356,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.9796851617 -US-Ton,20356,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20356,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20356,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20356,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20356,GRP_SWC,SWC_DATE,20070219 -US-Ton,20552,GRP_SWC,SWC,36.069444444 -US-Ton,20552,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.6953721836 -US-Ton,20552,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20552,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20552,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20552,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20552,GRP_SWC,SWC_DATE,20090227 -US-Ton,20075,GRP_SWC,SWC,36.07037037 -US-Ton,20075,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.8712503804 -US-Ton,20075,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20075,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20075,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20075,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20075,GRP_SWC,SWC_DATE,20040321 -US-Ton,20235,GRP_SWC,SWC,36.1125 -US-Ton,20235,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.1935082406 -US-Ton,20235,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20235,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20235,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20235,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20235,GRP_SWC,SWC_DATE,20060124 -US-Ton,20227,GRP_SWC,SWC,36.125 -US-Ton,20227,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.8603429219 -US-Ton,20227,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20227,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20227,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20227,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20227,GRP_SWC,SWC_DATE,20051229 -US-Ton,20171,GRP_SWC,SWC,36.130555556 -US-Ton,20171,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.6242544217 -US-Ton,20171,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20171,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20171,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20171,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20171,GRP_SWC,SWC_DATE,20050127 -US-Ton,20175,GRP_SWC,SWC,36.218055556 -US-Ton,20175,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.3895275875 -US-Ton,20175,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20175,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20175,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20175,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20175,GRP_SWC,SWC_DATE,20050208 -US-Ton,19914,GRP_SWC,SWC,36.28 -US-Ton,19914,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.5856299134 -US-Ton,19914,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19914,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19914,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,19914,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,19914,GRP_SWC,SWC_DATE,20030317 -US-Ton,19746,GRP_SWC,SWC,36.36 -US-Ton,19746,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.6094167335 -US-Ton,19746,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19746,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19746,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,19746,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,19746,GRP_SWC,SWC_DATE,20011219 -US-Ton,20159,GRP_SWC,SWC,36.366666667 -US-Ton,20159,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.9581686607 -US-Ton,20159,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20159,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20159,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20159,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20159,GRP_SWC,SWC_DATE,20041215 -US-Ton,20843,GRP_SWC,SWC,36.383333333 -US-Ton,20843,GRP_SWC,SWC_SPATIAL_VARIABILITY,10.597755623 -US-Ton,20843,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20843,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20843,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20843,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20843,GRP_SWC,SWC_DATE,20130227 -US-Ton,20231,GRP_SWC,SWC,36.476388889 -US-Ton,20231,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.5575390025 -US-Ton,20231,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20231,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20231,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20231,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20231,GRP_SWC,SWC_DATE,20060110 -US-Ton,20703,GRP_SWC,SWC,36.481818182 -US-Ton,20703,GRP_SWC,SWC_SPATIAL_VARIABILITY,10.80852147 -US-Ton,20703,GRP_SWC,SWC_SPATIAL_REP_NUMBER,11 -US-Ton,20703,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20703,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20703,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20703,GRP_SWC,SWC_DATE,20110503 -US-Ton,20067,GRP_SWC,SWC,36.544444444 -US-Ton,20067,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.2694918277 -US-Ton,20067,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20067,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20067,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20067,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20067,GRP_SWC,SWC_DATE,20040130 -US-Ton,20786,GRP_SWC,SWC,36.566666667 -US-Ton,20786,GRP_SWC,SWC_SPATIAL_VARIABILITY,10.872846356 -US-Ton,20786,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20786,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20786,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20786,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20786,GRP_SWC,SWC_DATE,20120504 -US-Ton,20620,GRP_SWC,SWC,36.569444444 -US-Ton,20620,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.1093314672 -US-Ton,20620,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20620,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20620,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20620,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20620,GRP_SWC,SWC_DATE,20100210 -US-Ton,20787,GRP_SWC,SWC,36.575 -US-Ton,20787,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.0148493311 -US-Ton,20787,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20787,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20787,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20787,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20787,GRP_SWC,SWC_DATE,20120504 -US-Ton,20059,GRP_SWC,SWC,36.598148148 -US-Ton,20059,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.1813447046 -US-Ton,20059,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20059,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20059,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20059,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20059,GRP_SWC,SWC_DATE,20040108 -US-Ton,20393,GRP_SWC,SWC,36.6 -US-Ton,20393,GRP_SWC,SWC_SPATIAL_VARIABILITY,9.4334243491 -US-Ton,20393,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20393,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20393,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20393,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20393,GRP_SWC,SWC_DATE,20070418 -US-Ton,20468,GRP_SWC,SWC,36.6 -US-Ton,20468,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.9892611951 -US-Ton,20468,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20468,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20468,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20468,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20468,GRP_SWC,SWC_DATE,20080130 -US-Ton,19898,GRP_SWC,SWC,36.7 -US-Ton,19898,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.7748239349 -US-Ton,19898,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19898,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19898,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,19898,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,19898,GRP_SWC,SWC_DATE,20030129 -US-Ton,20255,GRP_SWC,SWC,36.719444444 -US-Ton,20255,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.5166908941 -US-Ton,20255,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20255,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20255,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20255,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20255,GRP_SWC,SWC_DATE,20060318 -US-Ton,19940,GRP_SWC,SWC,36.748148148 -US-Ton,19940,GRP_SWC,SWC_SPATIAL_VARIABILITY,11.72278303 -US-Ton,19940,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,19940,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19940,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,19940,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,19940,GRP_SWC,SWC_DATE,20030521 -US-Ton,19935,GRP_SWC,SWC,36.774074074 -US-Ton,19935,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.1580520409 -US-Ton,19935,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,19935,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19935,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,19935,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,19935,GRP_SWC,SWC_DATE,20030509 -US-Ton,20179,GRP_SWC,SWC,36.905555556 -US-Ton,20179,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.5705874196 -US-Ton,20179,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20179,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20179,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20179,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20179,GRP_SWC,SWC_DATE,20050226 -US-Ton,19917,GRP_SWC,SWC,36.92 -US-Ton,19917,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.148242748 -US-Ton,19917,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19917,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19917,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,19917,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,19917,GRP_SWC,SWC_DATE,20030405 -US-Ton,20372,GRP_SWC,SWC,36.945833333 -US-Ton,20372,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.1457471745 -US-Ton,20372,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20372,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20372,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20372,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20372,GRP_SWC,SWC_DATE,20070316 -US-Ton,20258,GRP_SWC,SWC,36.962962963 -US-Ton,20258,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.9497069126 -US-Ton,20258,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20258,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20258,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20258,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20258,GRP_SWC,SWC_DATE,20060330 -US-Ton,20239,GRP_SWC,SWC,36.983333333 -US-Ton,20239,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.6571432799 -US-Ton,20239,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20239,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20239,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20239,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20239,GRP_SWC,SWC_DATE,20060210 -US-Ton,20071,GRP_SWC,SWC,37.107407407 -US-Ton,20071,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.508315123 -US-Ton,20071,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20071,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20071,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20071,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20071,GRP_SWC,SWC_DATE,20040305 -US-Ton,20183,GRP_SWC,SWC,37.141666667 -US-Ton,20183,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.3991090735 -US-Ton,20183,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20183,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20183,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20183,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20183,GRP_SWC,SWC_DATE,20050309 -US-Ton,20250,GRP_SWC,SWC,37.145833333 -US-Ton,20250,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.2333918401 -US-Ton,20250,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20250,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20250,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20250,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20250,GRP_SWC,SWC_DATE,20060308 -US-Ton,20187,GRP_SWC,SWC,37.175 -US-Ton,20187,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.3990443177 -US-Ton,20187,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20187,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20187,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20187,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20187,GRP_SWC,SWC_DATE,20050324 -US-Ton,20684,GRP_SWC,SWC,37.241666667 -US-Ton,20684,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.9063486384 -US-Ton,20684,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20684,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20684,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20684,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20684,GRP_SWC,SWC_DATE,20110222 -US-Ton,20368,GRP_SWC,SWC,37.25 -US-Ton,20368,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.1157108493 -US-Ton,20368,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20368,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20368,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20368,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20368,GRP_SWC,SWC_DATE,20070310 -US-Ton,19923,GRP_SWC,SWC,37.259259259 -US-Ton,19923,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.0569239025 -US-Ton,19923,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,19923,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19923,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,19923,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,19923,GRP_SWC,SWC_DATE,20030416 -US-Ton,20364,GRP_SWC,SWC,37.304166667 -US-Ton,20364,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.0275254256 -US-Ton,20364,GRP_SWC,SWC_SPATIAL_REP_NUMBER,8 -US-Ton,20364,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20364,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20364,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20364,GRP_SWC,SWC_DATE,20070304 -US-Ton,20915,GRP_SWC,SWC,37.345454545 -US-Ton,20915,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.8063404042 -US-Ton,20915,GRP_SWC,SWC_SPATIAL_REP_NUMBER,11 -US-Ton,20915,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20915,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20915,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20915,GRP_SWC,SWC_DATE,20140210 -US-Ton,20919,GRP_SWC,SWC,37.345454545 -US-Ton,20919,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.8063404042 -US-Ton,20919,GRP_SWC,SWC_SPATIAL_REP_NUMBER,11 -US-Ton,20919,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20919,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20919,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20919,GRP_SWC,SWC_DATE,20140304 -US-Ton,19927,GRP_SWC,SWC,37.355555556 -US-Ton,19927,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.3405159967 -US-Ton,19927,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,19927,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19927,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,19927,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,19927,GRP_SWC,SWC_DATE,20030425 -US-Ton,19894,GRP_SWC,SWC,37.36 -US-Ton,19894,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.61617097194 -US-Ton,19894,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19894,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19894,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,19894,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,19894,GRP_SWC,SWC_DATE,20030104 -US-Ton,20257,GRP_SWC,SWC,37.362962963 -US-Ton,20257,GRP_SWC,SWC_SPATIAL_VARIABILITY,8.2225375315 -US-Ton,20257,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20257,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20257,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20257,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20257,GRP_SWC,SWC_DATE,20060330 -US-Ton,20196,GRP_SWC,SWC,37.379166667 -US-Ton,20196,GRP_SWC,SWC_SPATIAL_VARIABILITY,10.44834607 -US-Ton,20196,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20196,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20196,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20196,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20196,GRP_SWC,SWC_DATE,20050517 -US-Ton,20265,GRP_SWC,SWC,37.383333333 -US-Ton,20265,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.4071456321 -US-Ton,20265,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20265,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20265,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20265,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20265,GRP_SWC,SWC_DATE,20060418 -US-Ton,19774,GRP_SWC,SWC,37.44 -US-Ton,19774,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.4472944245 -US-Ton,19774,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19774,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19774,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,19774,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,19774,GRP_SWC,SWC_DATE,20020404 -US-Ton,20839,GRP_SWC,SWC,37.483333333 -US-Ton,20839,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.5356420886 -US-Ton,20839,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20839,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20839,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20839,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20839,GRP_SWC,SWC_DATE,20130206 -US-Ton,19783,GRP_SWC,SWC,37.531666667 -US-Ton,19783,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.8163364939 -US-Ton,19783,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19783,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19783,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,19783,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,19783,GRP_SWC,SWC_DATE,20020418 -US-Ton,20262,GRP_SWC,SWC,37.536363636 -US-Ton,20262,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.7847781249 -US-Ton,20262,GRP_SWC,SWC_SPATIAL_REP_NUMBER,11 -US-Ton,20262,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20262,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20262,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20262,GRP_SWC,SWC_DATE,20060408 -US-Ton,19770,GRP_SWC,SWC,37.54 -US-Ton,19770,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.64609940756 -US-Ton,19770,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19770,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19770,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,19770,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,19770,GRP_SWC,SWC_DATE,20020320 -US-Ton,19758,GRP_SWC,SWC,37.6875 -US-Ton,19758,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.97328909717 -US-Ton,19758,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Ton,19758,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19758,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,19758,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,19758,GRP_SWC,SWC_DATE,20020208 -US-Ton,20629,GRP_SWC,SWC,37.7625 -US-Ton,20629,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.1319465118 -US-Ton,20629,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20629,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20629,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20629,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20629,GRP_SWC,SWC_DATE,20100321 -US-Ton,20481,GRP_SWC,SWC,37.816666667 -US-Ton,20481,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.3111565443 -US-Ton,20481,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20481,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20481,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20481,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20481,GRP_SWC,SWC_DATE,20080306 -US-Ton,19918,GRP_SWC,SWC,37.853333333 -US-Ton,19918,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.9411623093 -US-Ton,19918,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19918,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19918,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,19918,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,19918,GRP_SWC,SWC_DATE,20030405 -US-Ton,20267,GRP_SWC,SWC,37.870833333 -US-Ton,20267,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.8512960235 -US-Ton,20267,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20267,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20267,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20267,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20267,GRP_SWC,SWC_DATE,20060418 -US-Ton,19762,GRP_SWC,SWC,37.92 -US-Ton,19762,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.54599552298 -US-Ton,19762,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19762,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19762,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,19762,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,19762,GRP_SWC,SWC_DATE,20020228 -US-Ton,20167,GRP_SWC,SWC,37.977777778 -US-Ton,20167,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.5289641385 -US-Ton,20167,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20167,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20167,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20167,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20167,GRP_SWC,SWC_DATE,20050117 -US-Ton,20251,GRP_SWC,SWC,38.016666667 -US-Ton,20251,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.2422835475 -US-Ton,20251,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20251,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20251,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20251,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20251,GRP_SWC,SWC_DATE,20060308 -US-Ton,19931,GRP_SWC,SWC,38.059259259 -US-Ton,19931,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.6070584925 -US-Ton,19931,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,19931,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19931,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,19931,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,19931,GRP_SWC,SWC_DATE,20030430 -US-Ton,20916,GRP_SWC,SWC,38.0625 -US-Ton,20916,GRP_SWC,SWC_SPATIAL_VARIABILITY,13.410106857 -US-Ton,20916,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20916,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20916,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20916,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20916,GRP_SWC,SWC_DATE,20140210 -US-Ton,20920,GRP_SWC,SWC,38.0625 -US-Ton,20920,GRP_SWC,SWC_SPATIAL_VARIABILITY,13.410106857 -US-Ton,20920,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20920,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20920,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20920,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20920,GRP_SWC,SWC_DATE,20140304 -US-Ton,19754,GRP_SWC,SWC,38.113333333 -US-Ton,19754,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.92183392093 -US-Ton,19754,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19754,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19754,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,19754,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,19754,GRP_SWC,SWC_DATE,20020123 -US-Ton,20245,GRP_SWC,SWC,38.116666667 -US-Ton,20245,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.0341034164 -US-Ton,20245,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20245,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20245,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20245,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20245,GRP_SWC,SWC_DATE,20060304 -US-Ton,19750,GRP_SWC,SWC,38.173333333 -US-Ton,19750,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.1528708128 -US-Ton,19750,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19750,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19750,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,19750,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,19750,GRP_SWC,SWC_DATE,20020115 -US-Ton,19753,GRP_SWC,SWC,38.406666667 -US-Ton,19753,GRP_SWC,SWC_SPATIAL_VARIABILITY,8.5627552679 -US-Ton,19753,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19753,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19753,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,19753,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,19753,GRP_SWC,SWC_DATE,20020123 -US-Ton,20927,GRP_SWC,SWC,38.429166667 -US-Ton,20927,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.0038774434 -US-Ton,20927,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20927,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20927,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20927,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20927,GRP_SWC,SWC_DATE,20140408 -US-Ton,19766,GRP_SWC,SWC,38.525 -US-Ton,19766,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.1183755581 -US-Ton,19766,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19766,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19766,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,19766,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,19766,GRP_SWC,SWC_DATE,20020308 -US-Ton,20477,GRP_SWC,SWC,38.541666667 -US-Ton,20477,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.8279306272 -US-Ton,20477,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20477,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20477,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20477,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20477,GRP_SWC,SWC_DATE,20080302 -US-Ton,20624,GRP_SWC,SWC,38.558333333 -US-Ton,20624,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.1003490671 -US-Ton,20624,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20624,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20624,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20624,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20624,GRP_SWC,SWC_DATE,20100305 -US-Ton,20473,GRP_SWC,SWC,38.566666667 -US-Ton,20473,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.9906709393 -US-Ton,20473,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20473,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20473,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20473,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20473,GRP_SWC,SWC_DATE,20080210 -US-Ton,19903,GRP_SWC,SWC,38.66 -US-Ton,19903,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.199166584 -US-Ton,19903,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19903,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19903,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,19903,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,19903,GRP_SWC,SWC_DATE,20030213 -US-Ton,20263,GRP_SWC,SWC,38.675757576 -US-Ton,20263,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.71271362 -US-Ton,20263,GRP_SWC,SWC_SPATIAL_REP_NUMBER,11 -US-Ton,20263,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20263,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20263,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20263,GRP_SWC,SWC_DATE,20060408 -US-Ton,20259,GRP_SWC,SWC,38.759259259 -US-Ton,20259,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.542049763 -US-Ton,20259,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20259,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20259,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20259,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20259,GRP_SWC,SWC_DATE,20060330 -US-Ton,20674,GRP_SWC,SWC,38.85 -US-Ton,20674,GRP_SWC,SWC_SPATIAL_VARIABILITY,13.516353731 -US-Ton,20674,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20674,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20674,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20674,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20674,GRP_SWC,SWC_DATE,20101202 -US-Ton,20469,GRP_SWC,SWC,38.883333333 -US-Ton,20469,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.625875025 -US-Ton,20469,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20469,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20469,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20469,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20469,GRP_SWC,SWC_DATE,20080130 -US-Ton,20856,GRP_SWC,SWC,38.891666667 -US-Ton,20856,GRP_SWC,SWC_SPATIAL_VARIABILITY,12.297982712 -US-Ton,20856,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20856,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20856,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20856,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20856,GRP_SWC,SWC_DATE,20130410 -US-Ton,20360,GRP_SWC,SWC,38.915277778 -US-Ton,20360,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.9964050629 -US-Ton,20360,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20360,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20360,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20360,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20360,GRP_SWC,SWC_DATE,20070302 -US-Ton,20782,GRP_SWC,SWC,38.95 -US-Ton,20782,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.1553590828 -US-Ton,20782,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20782,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20782,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20782,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20782,GRP_SWC,SWC_DATE,20120405 -US-Ton,20276,GRP_SWC,SWC,39.008333333 -US-Ton,20276,GRP_SWC,SWC_SPATIAL_VARIABILITY,11.339883357 -US-Ton,20276,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20276,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20276,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20276,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20276,GRP_SWC,SWC_DATE,20060512 -US-Ton,20064,GRP_SWC,SWC,39.055555556 -US-Ton,20064,GRP_SWC,SWC_SPATIAL_VARIABILITY,8.3974863964 -US-Ton,20064,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20064,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20064,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20064,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20064,GRP_SWC,SWC_DATE,20040123 -US-Ton,20621,GRP_SWC,SWC,39.080555556 -US-Ton,20621,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.6437426184 -US-Ton,20621,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20621,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20621,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20621,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20621,GRP_SWC,SWC_DATE,20100210 -US-Ton,19757,GRP_SWC,SWC,39.175 -US-Ton,19757,GRP_SWC,SWC_SPATIAL_VARIABILITY,9.8723097601 -US-Ton,19757,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Ton,19757,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19757,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,19757,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,19757,GRP_SWC,SWC_DATE,20020208 -US-Ton,20844,GRP_SWC,SWC,39.183333333 -US-Ton,20844,GRP_SWC,SWC_SPATIAL_VARIABILITY,12.253447258 -US-Ton,20844,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20844,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20844,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20844,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20844,GRP_SWC,SWC_DATE,20130227 -US-Ton,20688,GRP_SWC,SWC,39.2 -US-Ton,20688,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.6278035456 -US-Ton,20688,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20688,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20688,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20688,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20688,GRP_SWC,SWC_DATE,20110308 -US-Ton,19749,GRP_SWC,SWC,39.22 -US-Ton,19749,GRP_SWC,SWC_SPATIAL_VARIABILITY,8.6327412924 -US-Ton,19749,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19749,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19749,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,19749,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,19749,GRP_SWC,SWC_DATE,20020115 -US-Ton,19747,GRP_SWC,SWC,39.24 -US-Ton,19747,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.0143769407 -US-Ton,19747,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19747,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19747,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,19747,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,19747,GRP_SWC,SWC_DATE,20011219 -US-Ton,19761,GRP_SWC,SWC,39.246666667 -US-Ton,19761,GRP_SWC,SWC_SPATIAL_VARIABILITY,8.1081097948 -US-Ton,19761,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19761,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19761,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,19761,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,19761,GRP_SWC,SWC_DATE,20020228 -US-Ton,20261,GRP_SWC,SWC,39.321212121 -US-Ton,20261,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.6184636137 -US-Ton,20261,GRP_SWC,SWC_SPATIAL_REP_NUMBER,11 -US-Ton,20261,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20261,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20261,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20261,GRP_SWC,SWC_DATE,20060408 -US-Ton,20553,GRP_SWC,SWC,39.352777778 -US-Ton,20553,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.5564574742 -US-Ton,20553,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20553,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20553,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20553,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20553,GRP_SWC,SWC_DATE,20090227 -US-Ton,20637,GRP_SWC,SWC,39.408333333 -US-Ton,20637,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.7550702284 -US-Ton,20637,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20637,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20637,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20637,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20637,GRP_SWC,SWC_DATE,20100430 -US-Ton,19911,GRP_SWC,SWC,39.47 -US-Ton,19911,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.5066678994 -US-Ton,19911,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19911,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19911,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,19911,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,19911,GRP_SWC,SWC_DATE,20030227 -US-Ton,20246,GRP_SWC,SWC,39.494444444 -US-Ton,20246,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.2653841191 -US-Ton,20246,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20246,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20246,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20246,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20246,GRP_SWC,SWC_DATE,20060304 -US-Ton,19915,GRP_SWC,SWC,39.593333333 -US-Ton,19915,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.9538588746 -US-Ton,19915,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19915,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19915,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,19915,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,19915,GRP_SWC,SWC_DATE,20030317 -US-Ton,20924,GRP_SWC,SWC,39.645833333 -US-Ton,20924,GRP_SWC,SWC_SPATIAL_VARIABILITY,10.681472029 -US-Ton,20924,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20924,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20924,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20924,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20924,GRP_SWC,SWC_DATE,20140318 -US-Ton,19769,GRP_SWC,SWC,39.666666667 -US-Ton,19769,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.604823031 -US-Ton,19769,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19769,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19769,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,19769,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,19769,GRP_SWC,SWC_DATE,20020320 -US-Ton,20494,GRP_SWC,SWC,39.741666667 -US-Ton,20494,GRP_SWC,SWC_SPATIAL_VARIABILITY,11.104891315 -US-Ton,20494,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20494,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20494,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20494,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20494,GRP_SWC,SWC_DATE,20080408 -US-Ton,19891,GRP_SWC,SWC,39.746666667 -US-Ton,19891,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.892576706 -US-Ton,19891,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19891,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19891,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,19891,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,19891,GRP_SWC,SWC_DATE,20021223 -US-Ton,19907,GRP_SWC,SWC,39.766 -US-Ton,19907,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.9332848867 -US-Ton,19907,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19907,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19907,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,19907,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,19907,GRP_SWC,SWC_DATE,20030221 -US-Ton,19748,GRP_SWC,SWC,39.933333333 -US-Ton,19748,GRP_SWC,SWC_SPATIAL_VARIABILITY,10.398744582 -US-Ton,19748,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19748,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19748,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,19748,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,19748,GRP_SWC,SWC_DATE,20011219 -US-Ton,20681,GRP_SWC,SWC,39.970833333 -US-Ton,20681,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.7032071652 -US-Ton,20681,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20681,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20681,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20681,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20681,GRP_SWC,SWC_DATE,20110119 -US-Ton,20957,GRP_SWC,SWC,4.0272727273 -US-Ton,20957,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.381816349 -US-Ton,20957,GRP_SWC,SWC_SPATIAL_REP_NUMBER,11 -US-Ton,20957,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20957,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20957,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20957,GRP_SWC,SWC_DATE,20140911 -US-Ton,20117,GRP_SWC,SWC,4.0518518519 -US-Ton,20117,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.7421339972 -US-Ton,20117,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20117,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20117,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20117,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20117,GRP_SWC,SWC_DATE,20040805 -US-Ton,20511,GRP_SWC,SWC,4.0666666667 -US-Ton,20511,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.1011239409 -US-Ton,20511,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20511,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20511,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20511,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20511,GRP_SWC,SWC_DATE,20080806 -US-Ton,20523,GRP_SWC,SWC,4.0666666667 -US-Ton,20523,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.1011239409 -US-Ton,20523,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20523,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20523,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20523,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20523,GRP_SWC,SWC_DATE,20080919 -US-Ton,20801,GRP_SWC,SWC,4.1272727273 -US-Ton,20801,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.9692897835 -US-Ton,20801,GRP_SWC,SWC_SPATIAL_REP_NUMBER,11 -US-Ton,20801,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20801,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20801,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20801,GRP_SWC,SWC_DATE,20120725 -US-Ton,20813,GRP_SWC,SWC,4.2196969697 -US-Ton,20813,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.7482797401 -US-Ton,20813,GRP_SWC,SWC_SPATIAL_REP_NUMBER,11 -US-Ton,20813,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20813,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20813,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20813,GRP_SWC,SWC_DATE,20120919 -US-Ton,19861,GRP_SWC,SWC,4.2533333333 -US-Ton,19861,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.1130020771 -US-Ton,19861,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19861,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19861,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,19861,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,19861,GRP_SWC,SWC_DATE,20020920 -US-Ton,20113,GRP_SWC,SWC,4.2685185185 -US-Ton,20113,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.7811798611 -US-Ton,20113,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20113,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20113,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20113,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20113,GRP_SWC,SWC_DATE,20040721 -US-Ton,20121,GRP_SWC,SWC,4.2833333333 -US-Ton,20121,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.5802669974 -US-Ton,20121,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20121,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20121,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20121,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20121,GRP_SWC,SWC_DATE,20040817 -US-Ton,19873,GRP_SWC,SWC,4.2866666667 -US-Ton,19873,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.166615384 -US-Ton,19873,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19873,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19873,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,19873,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,19873,GRP_SWC,SWC_DATE,20021105 -US-Ton,20591,GRP_SWC,SWC,4.3666666667 -US-Ton,20591,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.9901271468 -US-Ton,20591,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20591,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20591,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20591,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20591,GRP_SWC,SWC_DATE,20090907 -US-Ton,20655,GRP_SWC,SWC,4.3833333333 -US-Ton,20655,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.6002039547 -US-Ton,20655,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20655,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20655,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20655,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20655,GRP_SWC,SWC_DATE,20100902 -US-Ton,20125,GRP_SWC,SWC,4.3925925926 -US-Ton,20125,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.9643190634 -US-Ton,20125,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20125,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20125,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20125,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20125,GRP_SWC,SWC_DATE,20040908 -US-Ton,19865,GRP_SWC,SWC,4.42 -US-Ton,19865,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.3149994 -US-Ton,19865,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19865,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19865,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,19865,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,19865,GRP_SWC,SWC_DATE,20021002 -US-Ton,19985,GRP_SWC,SWC,4.4833333333 -US-Ton,19985,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.33425577 -US-Ton,19985,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,19985,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19985,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,19985,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,19985,GRP_SWC,SWC_DATE,20030731 -US-Ton,20213,GRP_SWC,SWC,4.5166666667 -US-Ton,20213,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.2109575603 -US-Ton,20213,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20213,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20213,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20213,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20213,GRP_SWC,SWC_DATE,20050925 -US-Ton,19869,GRP_SWC,SWC,4.54 -US-Ton,19869,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.8063775906 -US-Ton,19869,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19869,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19869,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,19869,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,19869,GRP_SWC,SWC_DATE,20021024 -US-Ton,19853,GRP_SWC,SWC,4.5466666667 -US-Ton,19853,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.4076959941 -US-Ton,19853,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19853,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19853,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,19853,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,19853,GRP_SWC,SWC_DATE,20020905 -US-Ton,20953,GRP_SWC,SWC,4.5636363636 -US-Ton,20953,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.3565675108 -US-Ton,20953,GRP_SWC,SWC_SPATIAL_REP_NUMBER,11 -US-Ton,20953,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20953,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20953,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20953,GRP_SWC,SWC_DATE,20140821 -US-Ton,20297,GRP_SWC,SWC,4.565 -US-Ton,20297,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.4547116105 -US-Ton,20297,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20297,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20297,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20297,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20297,GRP_SWC,SWC_DATE,20060808 -US-Ton,20209,GRP_SWC,SWC,4.6111111111 -US-Ton,20209,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.7115571334 -US-Ton,20209,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20209,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20209,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20209,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20209,GRP_SWC,SWC_DATE,20050910 -US-Ton,20659,GRP_SWC,SWC,4.6625 -US-Ton,20659,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.025196399 -US-Ton,20659,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20659,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20659,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20659,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20659,GRP_SWC,SWC_DATE,20101007 -US-Ton,20438,GRP_SWC,SWC,4.675 -US-Ton,20438,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.6176990822 -US-Ton,20438,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20438,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20438,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20438,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20438,GRP_SWC,SWC_DATE,20070920 -US-Ton,20133,GRP_SWC,SWC,4.6888888889 -US-Ton,20133,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.7002057535 -US-Ton,20133,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20133,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20133,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20133,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20133,GRP_SWC,SWC_DATE,20041013 -US-Ton,19981,GRP_SWC,SWC,4.6925925926 -US-Ton,19981,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.5064238456 -US-Ton,19981,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,19981,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19981,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,19981,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,19981,GRP_SWC,SWC_DATE,20030725 -US-Ton,20129,GRP_SWC,SWC,4.7 -US-Ton,20129,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.1953074955 -US-Ton,20129,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20129,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20129,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20129,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20129,GRP_SWC,SWC_DATE,20040921 -US-Ton,20109,GRP_SWC,SWC,4.7888888889 -US-Ton,20109,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.4563410006 -US-Ton,20109,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20109,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20109,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20109,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20109,GRP_SWC,SWC_DATE,20040708 -US-Ton,20515,GRP_SWC,SWC,4.8111111111 -US-Ton,20515,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.6594726193 -US-Ton,20515,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20515,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20515,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20515,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20515,GRP_SWC,SWC_DATE,20080820 -US-Ton,20434,GRP_SWC,SWC,4.8472222222 -US-Ton,20434,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.5375347272 -US-Ton,20434,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20434,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20434,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20434,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20434,GRP_SWC,SWC_DATE,20070908 -US-Ton,20949,GRP_SWC,SWC,4.8818181818 -US-Ton,20949,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.3257526933 -US-Ton,20949,GRP_SWC,SWC_SPATIAL_REP_NUMBER,11 -US-Ton,20949,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20949,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20949,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20949,GRP_SWC,SWC_DATE,20140805 -US-Ton,19997,GRP_SWC,SWC,4.8822222222 -US-Ton,19997,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.8730374944 -US-Ton,19997,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,19997,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19997,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,19997,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,19997,GRP_SWC,SWC_DATE,20030821 -US-Ton,20507,GRP_SWC,SWC,4.8833333333 -US-Ton,20507,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.3832114824 -US-Ton,20507,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20507,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20507,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20507,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20507,GRP_SWC,SWC_DATE,20080731 -US-Ton,20651,GRP_SWC,SWC,4.9166666667 -US-Ton,20651,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.8239505962 -US-Ton,20651,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20651,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20651,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20651,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20651,GRP_SWC,SWC_DATE,20100814 -US-Ton,20289,GRP_SWC,SWC,4.9416666667 -US-Ton,20289,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.4505256084 -US-Ton,20289,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20289,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20289,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20289,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20289,GRP_SWC,SWC_DATE,20060713 -US-Ton,20519,GRP_SWC,SWC,4.9708333333 -US-Ton,20519,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.8451974929 -US-Ton,20519,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20519,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20519,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20519,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20519,GRP_SWC,SWC_DATE,20080904 -US-Ton,19895,GRP_SWC,SWC,40.086666667 -US-Ton,19895,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.6572333147 -US-Ton,19895,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19895,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19895,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,19895,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,19895,GRP_SWC,SWC_DATE,20030104 -US-Ton,20693,GRP_SWC,SWC,40.104166667 -US-Ton,20693,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.285782963 -US-Ton,20693,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20693,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20693,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20693,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20693,GRP_SWC,SWC_DATE,20110330 -US-Ton,20248,GRP_SWC,SWC,40.202777778 -US-Ton,20248,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.6779424108 -US-Ton,20248,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20248,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20248,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20248,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20248,GRP_SWC,SWC_DATE,20060304 -US-Ton,19779,GRP_SWC,SWC,40.233333333 -US-Ton,19779,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.7671828555 -US-Ton,19779,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19779,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19779,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,19779,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,19779,GRP_SWC,SWC_DATE,20020411 -US-Ton,19899,GRP_SWC,SWC,40.273333333 -US-Ton,19899,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.8614681546 -US-Ton,19899,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19899,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19899,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,19899,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,19899,GRP_SWC,SWC_DATE,20030129 -US-Ton,20852,GRP_SWC,SWC,40.370833333 -US-Ton,20852,GRP_SWC,SWC_SPATIAL_VARIABILITY,9.8490299092 -US-Ton,20852,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20852,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20852,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20852,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20852,GRP_SWC,SWC_DATE,20130327 -US-Ton,20068,GRP_SWC,SWC,40.377777778 -US-Ton,20068,GRP_SWC,SWC_SPATIAL_VARIABILITY,8.4299359099 -US-Ton,20068,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20068,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20068,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20068,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20068,GRP_SWC,SWC_DATE,20040130 -US-Ton,20983,GRP_SWC,SWC,40.595833333 -US-Ton,20983,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.9079475875 -US-Ton,20983,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20983,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20983,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20983,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20983,GRP_SWC,SWC_DATE,20141223 -US-Ton,19892,GRP_SWC,SWC,40.66 -US-Ton,19892,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.85254382 -US-Ton,19892,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19892,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19892,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,19892,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,19892,GRP_SWC,SWC_DATE,20021223 -US-Ton,19924,GRP_SWC,SWC,40.688888889 -US-Ton,19924,GRP_SWC,SWC_SPATIAL_VARIABILITY,12.851740046 -US-Ton,19924,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,19924,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19924,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,19924,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,19924,GRP_SWC,SWC_DATE,20030416 -US-Ton,20566,GRP_SWC,SWC,40.791666667 -US-Ton,20566,GRP_SWC,SWC_SPATIAL_VARIABILITY,10.754995316 -US-Ton,20566,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20566,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20566,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20566,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20566,GRP_SWC,SWC_DATE,20090417 -US-Ton,20778,GRP_SWC,SWC,40.85 -US-Ton,20778,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.6116976227 -US-Ton,20778,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20778,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20778,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20778,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20778,GRP_SWC,SWC_DATE,20120321 -US-Ton,20256,GRP_SWC,SWC,40.905555556 -US-Ton,20256,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.3044610361 -US-Ton,20256,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20256,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20256,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20256,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20256,GRP_SWC,SWC_DATE,20060318 -US-Ton,20685,GRP_SWC,SWC,40.925 -US-Ton,20685,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.5925478012 -US-Ton,20685,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20685,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20685,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20685,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20685,GRP_SWC,SWC_DATE,20110222 -US-Ton,20060,GRP_SWC,SWC,40.927777778 -US-Ton,20060,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.5808936094 -US-Ton,20060,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20060,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20060,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20060,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20060,GRP_SWC,SWC_DATE,20040108 -US-Ton,19919,GRP_SWC,SWC,40.953333333 -US-Ton,19919,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.4940107486 -US-Ton,19919,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19919,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19919,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,19919,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,19919,GRP_SWC,SWC_DATE,20030405 -US-Ton,20080,GRP_SWC,SWC,41.016666667 -US-Ton,20080,GRP_SWC,SWC_SPATIAL_VARIABILITY,11.414875164 -US-Ton,20080,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20080,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20080,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20080,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20080,GRP_SWC,SWC_DATE,20040325 -US-Ton,20084,GRP_SWC,SWC,41.15 -US-Ton,20084,GRP_SWC,SWC_SPATIAL_VARIABILITY,8.6495664631 -US-Ton,20084,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20084,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20084,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20084,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20084,GRP_SWC,SWC_DATE,20040402 -US-Ton,20558,GRP_SWC,SWC,41.154166667 -US-Ton,20558,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.0350246602 -US-Ton,20558,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20558,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20558,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20558,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20558,GRP_SWC,SWC_DATE,20090327 -US-Ton,20490,GRP_SWC,SWC,41.175 -US-Ton,20490,GRP_SWC,SWC_SPATIAL_VARIABILITY,11.000340904 -US-Ton,20490,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20490,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20490,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20490,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20490,GRP_SWC,SWC_DATE,20080404 -US-Ton,20676,GRP_SWC,SWC,41.208333333 -US-Ton,20676,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.5118811066 -US-Ton,20676,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20676,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20676,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20676,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20676,GRP_SWC,SWC_DATE,20101230 -US-Ton,19751,GRP_SWC,SWC,41.32 -US-Ton,19751,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.327444951 -US-Ton,19751,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19751,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19751,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,19751,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,19751,GRP_SWC,SWC_DATE,20020115 -US-Ton,19755,GRP_SWC,SWC,41.433333333 -US-Ton,19755,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.7689749407 -US-Ton,19755,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19755,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19755,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,19755,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,19755,GRP_SWC,SWC_DATE,20020123 -US-Ton,19775,GRP_SWC,SWC,41.63 -US-Ton,19775,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.7483176672 -US-Ton,19775,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19775,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19775,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,19775,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,19775,GRP_SWC,SWC_DATE,20020404 -US-Ton,20389,GRP_SWC,SWC,41.633333333 -US-Ton,20389,GRP_SWC,SWC_SPATIAL_VARIABILITY,9.821875708 -US-Ton,20389,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20389,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20389,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20389,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20389,GRP_SWC,SWC_DATE,20070405 -US-Ton,20677,GRP_SWC,SWC,41.783333333 -US-Ton,20677,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.1828095809 -US-Ton,20677,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20677,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20677,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20677,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20677,GRP_SWC,SWC_DATE,20101230 -US-Ton,19759,GRP_SWC,SWC,41.7875 -US-Ton,19759,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.6920794317 -US-Ton,19759,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Ton,19759,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19759,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,19759,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,19759,GRP_SWC,SWC_DATE,20020208 -US-Ton,20835,GRP_SWC,SWC,41.820833333 -US-Ton,20835,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.8095063962 -US-Ton,20835,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20835,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20835,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20835,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20835,GRP_SWC,SWC_DATE,20130116 -US-Ton,19936,GRP_SWC,SWC,41.866666667 -US-Ton,19936,GRP_SWC,SWC_SPATIAL_VARIABILITY,10.47491713 -US-Ton,19936,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,19936,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19936,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,19936,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,19936,GRP_SWC,SWC_DATE,20030509 -US-Ton,20192,GRP_SWC,SWC,41.891666667 -US-Ton,20192,GRP_SWC,SWC_SPATIAL_VARIABILITY,10.515720555 -US-Ton,20192,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20192,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20192,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20192,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20192,GRP_SWC,SWC_DATE,20050425 -US-Ton,20236,GRP_SWC,SWC,41.9125 -US-Ton,20236,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.7504199451 -US-Ton,20236,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20236,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20236,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20236,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20236,GRP_SWC,SWC_DATE,20060124 -US-Ton,19767,GRP_SWC,SWC,42.073333333 -US-Ton,19767,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.5222785114 -US-Ton,19767,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19767,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19767,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,19767,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,19767,GRP_SWC,SWC_DATE,20020308 -US-Ton,20486,GRP_SWC,SWC,42.088101667 -US-Ton,20486,GRP_SWC,SWC_SPATIAL_VARIABILITY,12.995572287 -US-Ton,20486,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20486,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20486,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20486,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20486,GRP_SWC,SWC_DATE,20080322 -US-Ton,20831,GRP_SWC,SWC,42.181944444 -US-Ton,20831,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.2770242352 -US-Ton,20831,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20831,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20831,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20831,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20831,GRP_SWC,SWC_DATE,20130101 -US-Ton,20228,GRP_SWC,SWC,42.219444444 -US-Ton,20228,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.1868025676 -US-Ton,20228,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20228,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20228,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20228,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20228,GRP_SWC,SWC_DATE,20051229 -US-Ton,20168,GRP_SWC,SWC,42.222222222 -US-Ton,20168,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.0231363681 -US-Ton,20168,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20168,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20168,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20168,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20168,GRP_SWC,SWC_DATE,20050117 -US-Ton,20827,GRP_SWC,SWC,42.241666667 -US-Ton,20827,GRP_SWC,SWC_SPATIAL_VARIABILITY,9.2993360793 -US-Ton,20827,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20827,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20827,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20827,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20827,GRP_SWC,SWC_DATE,20121211 -US-Ton,19763,GRP_SWC,SWC,42.3 -US-Ton,19763,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.6894857005 -US-Ton,19763,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19763,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19763,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,19763,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,19763,GRP_SWC,SWC_DATE,20020228 -US-Ton,19765,GRP_SWC,SWC,42.321666667 -US-Ton,19765,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.920289212 -US-Ton,19765,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19765,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19765,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,19765,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,19765,GRP_SWC,SWC_DATE,20020308 -US-Ton,20689,GRP_SWC,SWC,42.366666667 -US-Ton,20689,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.509294259 -US-Ton,20689,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20689,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20689,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20689,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20689,GRP_SWC,SWC_DATE,20110308 -US-Ton,20176,GRP_SWC,SWC,42.469444444 -US-Ton,20176,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.0773855004 -US-Ton,20176,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20176,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20176,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20176,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20176,GRP_SWC,SWC_DATE,20050208 -US-Ton,20244,GRP_SWC,SWC,42.470833333 -US-Ton,20244,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.6679219163 -US-Ton,20244,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20244,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20244,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20244,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20244,GRP_SWC,SWC_DATE,20060223 -US-Ton,20357,GRP_SWC,SWC,42.497222222 -US-Ton,20357,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.7391104118 -US-Ton,20357,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20357,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20357,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20357,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20357,GRP_SWC,SWC_DATE,20070219 -US-Ton,20385,GRP_SWC,SWC,42.619444444 -US-Ton,20385,GRP_SWC,SWC_SPATIAL_VARIABILITY,9.8095856885 -US-Ton,20385,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20385,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20385,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20385,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20385,GRP_SWC,SWC_DATE,20070402 -US-Ton,20848,GRP_SWC,SWC,42.658333333 -US-Ton,20848,GRP_SWC,SWC_SPATIAL_VARIABILITY,10.78510828 -US-Ton,20848,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20848,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20848,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20848,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20848,GRP_SWC,SWC_DATE,20130313 -US-Ton,19792,GRP_SWC,SWC,42.738 -US-Ton,19792,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.7432020685 -US-Ton,19792,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19792,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19792,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,19792,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,19792,GRP_SWC,SWC_DATE,20020502 -US-Ton,20381,GRP_SWC,SWC,42.8375 -US-Ton,20381,GRP_SWC,SWC_SPATIAL_VARIABILITY,9.7771562374 -US-Ton,20381,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20381,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20381,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20381,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20381,GRP_SWC,SWC_DATE,20070328 -US-Ton,20562,GRP_SWC,SWC,42.85 -US-Ton,20562,GRP_SWC,SWC_SPATIAL_VARIABILITY,11.111787353 -US-Ton,20562,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20562,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20562,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20562,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20562,GRP_SWC,SWC_DATE,20090403 -US-Ton,20072,GRP_SWC,SWC,42.862962963 -US-Ton,20072,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.3384583312 -US-Ton,20072,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20072,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20072,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20072,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20072,GRP_SWC,SWC_DATE,20040305 -US-Ton,20180,GRP_SWC,SWC,42.863888889 -US-Ton,20180,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.3101072735 -US-Ton,20180,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20180,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20180,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20180,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20180,GRP_SWC,SWC_DATE,20050226 -US-Ton,20788,GRP_SWC,SWC,42.866666667 -US-Ton,20788,GRP_SWC,SWC_SPATIAL_VARIABILITY,15.212215984 -US-Ton,20788,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20788,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20788,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20788,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20788,GRP_SWC,SWC_DATE,20120504 -US-Ton,19928,GRP_SWC,SWC,42.881481481 -US-Ton,19928,GRP_SWC,SWC_SPATIAL_VARIABILITY,9.4097778801 -US-Ton,19928,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,19928,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19928,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,19928,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,19928,GRP_SWC,SWC_DATE,20030425 -US-Ton,19771,GRP_SWC,SWC,42.92 -US-Ton,19771,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.4417207047 -US-Ton,19771,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19771,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19771,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,19771,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,19771,GRP_SWC,SWC_DATE,20020320 -US-Ton,20240,GRP_SWC,SWC,42.979166667 -US-Ton,20240,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.2824963981 -US-Ton,20240,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20240,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20240,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20240,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20240,GRP_SWC,SWC_DATE,20060210 -US-Ton,20172,GRP_SWC,SWC,42.986111111 -US-Ton,20172,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.6638185753 -US-Ton,20172,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20172,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20172,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20172,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20172,GRP_SWC,SWC_DATE,20050127 -US-Ton,20232,GRP_SWC,SWC,42.988888889 -US-Ton,20232,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.8287572238 -US-Ton,20232,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20232,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20232,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20232,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20232,GRP_SWC,SWC_DATE,20060110 -US-Ton,20076,GRP_SWC,SWC,43.016666667 -US-Ton,20076,GRP_SWC,SWC_SPATIAL_VARIABILITY,9.6948941316 -US-Ton,20076,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20076,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20076,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20076,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20076,GRP_SWC,SWC_DATE,20040321 -US-Ton,20272,GRP_SWC,SWC,43.329166667 -US-Ton,20272,GRP_SWC,SWC_SPATIAL_VARIABILITY,10.591751901 -US-Ton,20272,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20272,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20272,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20272,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20272,GRP_SWC,SWC_DATE,20060504 -US-Ton,20365,GRP_SWC,SWC,43.383333333 -US-Ton,20365,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.4348258816 -US-Ton,20365,GRP_SWC,SWC_SPATIAL_REP_NUMBER,8 -US-Ton,20365,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20365,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20365,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20365,GRP_SWC,SWC_DATE,20070304 -US-Ton,20634,GRP_SWC,SWC,43.425 -US-Ton,20634,GRP_SWC,SWC_SPATIAL_VARIABILITY,9.4962313099 -US-Ton,20634,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20634,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20634,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20634,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20634,GRP_SWC,SWC_DATE,20100402 -US-Ton,20625,GRP_SWC,SWC,43.483333333 -US-Ton,20625,GRP_SWC,SWC_SPATIAL_VARIABILITY,15.260992064 -US-Ton,20625,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20625,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20625,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20625,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20625,GRP_SWC,SWC_DATE,20100305 -US-Ton,20260,GRP_SWC,SWC,43.62962963 -US-Ton,20260,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.5357931907 -US-Ton,20260,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20260,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20260,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20260,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20260,GRP_SWC,SWC_DATE,20060330 -US-Ton,20840,GRP_SWC,SWC,43.866666667 -US-Ton,20840,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.97545477 -US-Ton,20840,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20840,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20840,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20840,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20840,GRP_SWC,SWC_DATE,20130206 -US-Ton,20252,GRP_SWC,SWC,44.025 -US-Ton,20252,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.4616877896 -US-Ton,20252,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20252,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20252,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20252,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20252,GRP_SWC,SWC_DATE,20060308 -US-Ton,20188,GRP_SWC,SWC,44.104166667 -US-Ton,20188,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.9047499396 -US-Ton,20188,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20188,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20188,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20188,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20188,GRP_SWC,SWC_DATE,20050324 -US-Ton,20678,GRP_SWC,SWC,44.183333333 -US-Ton,20678,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.5744454773 -US-Ton,20678,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20678,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20678,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20678,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20678,GRP_SWC,SWC_DATE,20101230 -US-Ton,20184,GRP_SWC,SWC,44.3 -US-Ton,20184,GRP_SWC,SWC_SPATIAL_VARIABILITY,8.951282285 -US-Ton,20184,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20184,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20184,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20184,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20184,GRP_SWC,SWC_DATE,20050309 -US-Ton,20682,GRP_SWC,SWC,44.341666667 -US-Ton,20682,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.3963391846 -US-Ton,20682,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20682,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20682,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20682,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20682,GRP_SWC,SWC_DATE,20110119 -US-Ton,20377,GRP_SWC,SWC,44.4 -US-Ton,20377,GRP_SWC,SWC_SPATIAL_VARIABILITY,10.118150508 -US-Ton,20377,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20377,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20377,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20377,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20377,GRP_SWC,SWC_DATE,20070319 -US-Ton,20264,GRP_SWC,SWC,44.421212121 -US-Ton,20264,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.7638134005 -US-Ton,20264,GRP_SWC,SWC_SPATIAL_REP_NUMBER,11 -US-Ton,20264,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20264,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20264,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20264,GRP_SWC,SWC_DATE,20060408 -US-Ton,19760,GRP_SWC,SWC,44.45 -US-Ton,19760,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.950949253 -US-Ton,19760,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Ton,19760,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19760,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,19760,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,19760,GRP_SWC,SWC_DATE,20020208 -US-Ton,19932,GRP_SWC,SWC,44.487037037 -US-Ton,19932,GRP_SWC,SWC_SPATIAL_VARIABILITY,8.3734773814 -US-Ton,19932,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,19932,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19932,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,19932,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,19932,GRP_SWC,SWC_DATE,20030430 -US-Ton,20698,GRP_SWC,SWC,44.498611111 -US-Ton,20698,GRP_SWC,SWC_SPATIAL_VARIABILITY,10.639179685 -US-Ton,20698,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20698,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20698,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20698,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20698,GRP_SWC,SWC_DATE,20110415 -US-Ton,20482,GRP_SWC,SWC,44.536111111 -US-Ton,20482,GRP_SWC,SWC_SPATIAL_VARIABILITY,8.2085870083 -US-Ton,20482,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20482,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20482,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20482,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20482,GRP_SWC,SWC_DATE,20080306 -US-Ton,20369,GRP_SWC,SWC,44.602777778 -US-Ton,20369,GRP_SWC,SWC_SPATIAL_VARIABILITY,8.6855442231 -US-Ton,20369,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20369,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20369,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20369,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20369,GRP_SWC,SWC_DATE,20070310 -US-Ton,20699,GRP_SWC,SWC,44.680555556 -US-Ton,20699,GRP_SWC,SWC_SPATIAL_VARIABILITY,8.5042171159 -US-Ton,20699,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20699,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20699,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20699,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20699,GRP_SWC,SWC_DATE,20110415 -US-Ton,20630,GRP_SWC,SWC,44.829166667 -US-Ton,20630,GRP_SWC,SWC_SPATIAL_VARIABILITY,9.0695910085 -US-Ton,20630,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20630,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20630,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20630,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20630,GRP_SWC,SWC_DATE,20100321 -US-Ton,19904,GRP_SWC,SWC,44.9 -US-Ton,19904,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.7407805265 -US-Ton,19904,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19904,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19904,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,19904,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,19904,GRP_SWC,SWC_DATE,20030213 -US-Ton,20373,GRP_SWC,SWC,44.904166667 -US-Ton,20373,GRP_SWC,SWC_SPATIAL_VARIABILITY,10.288132138 -US-Ton,20373,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20373,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20373,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20373,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20373,GRP_SWC,SWC_DATE,20070316 -US-Ton,20268,GRP_SWC,SWC,44.975 -US-Ton,20268,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.3087061056 -US-Ton,20268,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20268,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20268,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20268,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20268,GRP_SWC,SWC_DATE,20060418 -US-Ton,20554,GRP_SWC,SWC,45.072222222 -US-Ton,20554,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.665215058 -US-Ton,20554,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20554,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20554,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20554,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20554,GRP_SWC,SWC_DATE,20090227 -US-Ton,20928,GRP_SWC,SWC,45.179166667 -US-Ton,20928,GRP_SWC,SWC_SPATIAL_VARIABILITY,8.5401314215 -US-Ton,20928,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20928,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20928,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20928,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20928,GRP_SWC,SWC_DATE,20140408 -US-Ton,20474,GRP_SWC,SWC,45.475 -US-Ton,20474,GRP_SWC,SWC_SPATIAL_VARIABILITY,8.7773252984 -US-Ton,20474,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20474,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20474,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20474,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20474,GRP_SWC,SWC_DATE,20080210 -US-Ton,20686,GRP_SWC,SWC,45.5375 -US-Ton,20686,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.4330511989 -US-Ton,20686,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20686,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20686,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20686,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20686,GRP_SWC,SWC_DATE,20110222 -US-Ton,20622,GRP_SWC,SWC,45.541666667 -US-Ton,20622,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.3756646679 -US-Ton,20622,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20622,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20622,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20622,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20622,GRP_SWC,SWC_DATE,20100210 -US-Ton,20470,GRP_SWC,SWC,45.666666667 -US-Ton,20470,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.7479738822 -US-Ton,20470,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20470,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20470,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20470,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20470,GRP_SWC,SWC_DATE,20080130 -US-Ton,20690,GRP_SWC,SWC,45.769444444 -US-Ton,20690,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.7135386465 -US-Ton,20690,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20690,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20690,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20690,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20690,GRP_SWC,SWC_DATE,20110308 -US-Ton,20779,GRP_SWC,SWC,45.829166667 -US-Ton,20779,GRP_SWC,SWC_SPATIAL_VARIABILITY,9.3529883006 -US-Ton,20779,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20779,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20779,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20779,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20779,GRP_SWC,SWC_DATE,20120321 -US-Ton,19916,GRP_SWC,SWC,45.9 -US-Ton,19916,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.2093932255 -US-Ton,19916,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19916,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19916,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,19916,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,19916,GRP_SWC,SWC_DATE,20030317 -US-Ton,20361,GRP_SWC,SWC,45.906944444 -US-Ton,20361,GRP_SWC,SWC_SPATIAL_VARIABILITY,8.2130730304 -US-Ton,20361,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20361,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20361,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20361,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20361,GRP_SWC,SWC_DATE,20070302 -US-Ton,19752,GRP_SWC,SWC,46.193333333 -US-Ton,19752,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.1880418057 -US-Ton,19752,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19752,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19752,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,19752,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,19752,GRP_SWC,SWC_DATE,20020115 -US-Ton,20984,GRP_SWC,SWC,46.216666667 -US-Ton,20984,GRP_SWC,SWC_SPATIAL_VARIABILITY,8.1614207022 -US-Ton,20984,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20984,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20984,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20984,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20984,GRP_SWC,SWC_DATE,20141223 -US-Ton,20783,GRP_SWC,SWC,46.791666667 -US-Ton,20783,GRP_SWC,SWC_SPATIAL_VARIABILITY,9.2892370108 -US-Ton,20783,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20783,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20783,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20783,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20783,GRP_SWC,SWC_DATE,20120405 -US-Ton,19908,GRP_SWC,SWC,46.818 -US-Ton,19908,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.0940766323 -US-Ton,19908,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19908,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19908,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,19908,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,19908,GRP_SWC,SWC_DATE,20030221 -US-Ton,19920,GRP_SWC,SWC,46.853333333 -US-Ton,19920,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.5707868983 -US-Ton,19920,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19920,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19920,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,19920,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,19920,GRP_SWC,SWC_DATE,20030405 -US-Ton,20836,GRP_SWC,SWC,46.859722222 -US-Ton,20836,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.8825419499 -US-Ton,20836,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20836,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20836,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20836,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20836,GRP_SWC,SWC_DATE,20130116 -US-Ton,20832,GRP_SWC,SWC,46.913888889 -US-Ton,20832,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.1860584486 -US-Ton,20832,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20832,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20832,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20832,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20832,GRP_SWC,SWC_DATE,20130101 -US-Ton,20478,GRP_SWC,SWC,46.925 -US-Ton,20478,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.4604969775 -US-Ton,20478,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20478,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20478,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20478,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20478,GRP_SWC,SWC_DATE,20080302 -US-Ton,19912,GRP_SWC,SWC,47.003333333 -US-Ton,19912,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.596060122 -US-Ton,19912,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19912,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19912,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,19912,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,19912,GRP_SWC,SWC_DATE,20030227 -US-Ton,19788,GRP_SWC,SWC,47.226 -US-Ton,19788,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.658611493 -US-Ton,19788,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19788,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19788,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,19788,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,19788,GRP_SWC,SWC_DATE,20020426 -US-Ton,19900,GRP_SWC,SWC,47.266666667 -US-Ton,19900,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.3068305123 -US-Ton,19900,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19900,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19900,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,19900,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,19900,GRP_SWC,SWC_DATE,20030129 -US-Ton,20828,GRP_SWC,SWC,47.2875 -US-Ton,20828,GRP_SWC,SWC_SPATIAL_VARIABILITY,8.5623415712 -US-Ton,20828,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20828,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20828,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20828,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20828,GRP_SWC,SWC_DATE,20121211 -US-Ton,19896,GRP_SWC,SWC,47.393333333 -US-Ton,19896,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.6986060674 -US-Ton,19896,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19896,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19896,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,19896,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,19896,GRP_SWC,SWC_DATE,20030104 -US-Ton,20638,GRP_SWC,SWC,47.458333333 -US-Ton,20638,GRP_SWC,SWC_SPATIAL_VARIABILITY,9.4084544507 -US-Ton,20638,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20638,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20638,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20638,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20638,GRP_SWC,SWC_DATE,20100430 -US-Ton,20626,GRP_SWC,SWC,47.608333333 -US-Ton,20626,GRP_SWC,SWC_SPATIAL_VARIABILITY,11.734832248 -US-Ton,20626,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20626,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20626,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20626,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20626,GRP_SWC,SWC_DATE,20100305 -US-Ton,20694,GRP_SWC,SWC,47.645833333 -US-Ton,20694,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.4684931647 -US-Ton,20694,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20694,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20694,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20694,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20694,GRP_SWC,SWC_DATE,20110330 -US-Ton,19756,GRP_SWC,SWC,47.66 -US-Ton,19756,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.9655262224 -US-Ton,19756,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19756,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19756,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,19756,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,19756,GRP_SWC,SWC_DATE,20020123 -US-Ton,19764,GRP_SWC,SWC,47.806666667 -US-Ton,19764,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.3591769683 -US-Ton,19764,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19764,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19764,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,19764,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,19764,GRP_SWC,SWC_DATE,20020228 -US-Ton,19772,GRP_SWC,SWC,47.973333333 -US-Ton,19772,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.1154124413 -US-Ton,19772,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19772,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19772,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,19772,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,19772,GRP_SWC,SWC_DATE,20020320 -US-Ton,19784,GRP_SWC,SWC,48.243333333 -US-Ton,19784,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.8766472774 -US-Ton,19784,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19784,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19784,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,19784,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,19784,GRP_SWC,SWC_DATE,20020418 -US-Ton,19768,GRP_SWC,SWC,48.528333333 -US-Ton,19768,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.0394409693 -US-Ton,19768,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19768,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19768,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,19768,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,19768,GRP_SWC,SWC_DATE,20020308 -US-Ton,19780,GRP_SWC,SWC,48.94 -US-Ton,19780,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.0318876871 -US-Ton,19780,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19780,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19780,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,19780,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,19780,GRP_SWC,SWC_DATE,20020411 -US-Ton,20797,GRP_SWC,SWC,5.0166666667 -US-Ton,20797,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.0191058279 -US-Ton,20797,GRP_SWC,SWC_SPATIAL_REP_NUMBER,10 -US-Ton,20797,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20797,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20797,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20797,GRP_SWC,SWC_DATE,20120704 -US-Ton,20426,GRP_SWC,SWC,5.0527777778 -US-Ton,20426,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.0841549547 -US-Ton,20426,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20426,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20426,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20426,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20426,GRP_SWC,SWC_DATE,20070809 -US-Ton,20728,GRP_SWC,SWC,5.0636363636 -US-Ton,20728,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.4911940524 -US-Ton,20728,GRP_SWC,SWC_SPATIAL_REP_NUMBER,11 -US-Ton,20728,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20728,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20728,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20728,GRP_SWC,SWC_DATE,20110916 -US-Ton,20587,GRP_SWC,SWC,5.0916666667 -US-Ton,20587,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.2111901881 -US-Ton,20587,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20587,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20587,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20587,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20587,GRP_SWC,SWC_DATE,20090802 -US-Ton,20422,GRP_SWC,SWC,5.1424242424 -US-Ton,20422,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.9217228901 -US-Ton,20422,GRP_SWC,SWC_SPATIAL_REP_NUMBER,11 -US-Ton,20422,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20422,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20422,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20422,GRP_SWC,SWC_DATE,20070717 -US-Ton,20732,GRP_SWC,SWC,5.1638888889 -US-Ton,20732,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.9637441626 -US-Ton,20732,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20732,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20732,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20732,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20732,GRP_SWC,SWC_DATE,20110929 -US-Ton,20301,GRP_SWC,SWC,5.2 -US-Ton,20301,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.3276988246 -US-Ton,20301,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20301,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20301,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20301,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20301,GRP_SWC,SWC_DATE,20060923 -US-Ton,20001,GRP_SWC,SWC,5.2185185185 -US-Ton,20001,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.56190636 -US-Ton,20001,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20001,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20001,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20001,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20001,GRP_SWC,SWC_DATE,20030905 -US-Ton,19829,GRP_SWC,SWC,5.22 -US-Ton,19829,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.2448212005 -US-Ton,19829,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19829,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19829,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,19829,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,19829,GRP_SWC,SWC_DATE,20020719 -US-Ton,19841,GRP_SWC,SWC,5.2533333333 -US-Ton,19841,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.8148021442 -US-Ton,19841,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19841,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19841,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,19841,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,19841,GRP_SWC,SWC_DATE,20020815 -US-Ton,19845,GRP_SWC,SWC,5.28 -US-Ton,19845,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.8010265975 -US-Ton,19845,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19845,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19845,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,19845,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,19845,GRP_SWC,SWC_DATE,20020823 -US-Ton,20205,GRP_SWC,SWC,5.3041666667 -US-Ton,20205,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.700964334 -US-Ton,20205,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20205,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20205,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20205,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20205,GRP_SWC,SWC_DATE,20050706 -US-Ton,19837,GRP_SWC,SWC,5.3466666667 -US-Ton,19837,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.7259656801 -US-Ton,19837,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19837,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19837,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,19837,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,19837,GRP_SWC,SWC_DATE,20020801 -US-Ton,19977,GRP_SWC,SWC,5.3555555556 -US-Ton,19977,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.9066972475 -US-Ton,19977,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,19977,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19977,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,19977,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,19977,GRP_SWC,SWC_DATE,20030717 -US-Ton,20418,GRP_SWC,SWC,5.3583333333 -US-Ton,20418,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.7020054281 -US-Ton,20418,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20418,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20418,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20418,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20418,GRP_SWC,SWC_DATE,20070626 -US-Ton,19993,GRP_SWC,SWC,5.4555555556 -US-Ton,19993,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.7620443314 -US-Ton,19993,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,19993,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19993,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,19993,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,19993,GRP_SWC,SWC_DATE,20030816 -US-Ton,20865,GRP_SWC,SWC,5.5 -US-Ton,20865,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.7245805133 -US-Ton,20865,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20865,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20865,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20865,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20865,GRP_SWC,SWC_DATE,20130530 -US-Ton,20583,GRP_SWC,SWC,5.5333333333 -US-Ton,20583,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.8665257189 -US-Ton,20583,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20583,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20583,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20583,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20583,GRP_SWC,SWC_DATE,20090705 -US-Ton,20101,GRP_SWC,SWC,5.5722222222 -US-Ton,20101,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.8153719904 -US-Ton,20101,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20101,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20101,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20101,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20101,GRP_SWC,SWC_DATE,20040522 -US-Ton,19969,GRP_SWC,SWC,5.6142857143 -US-Ton,19969,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.3487204379 -US-Ton,19969,GRP_SWC,SWC_SPATIAL_REP_NUMBER,7 -US-Ton,19969,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19969,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,19969,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,19969,GRP_SWC,SWC_DATE,20030703 -US-Ton,20430,GRP_SWC,SWC,5.6151515152 -US-Ton,20430,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.7378565678 -US-Ton,20430,GRP_SWC,SWC_SPATIAL_REP_NUMBER,11 -US-Ton,20430,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20430,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20430,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20430,GRP_SWC,SWC_DATE,20070822 -US-Ton,20105,GRP_SWC,SWC,5.6333333333 -US-Ton,20105,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.6547913757 -US-Ton,20105,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20105,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20105,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20105,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20105,GRP_SWC,SWC_DATE,20040607 -US-Ton,20885,GRP_SWC,SWC,5.685 -US-Ton,20885,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.9391822285 -US-Ton,20885,GRP_SWC,SWC_SPATIAL_REP_NUMBER,10 -US-Ton,20885,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20885,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20885,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20885,GRP_SWC,SWC_DATE,20130904 -US-Ton,19973,GRP_SWC,SWC,5.6962962963 -US-Ton,19973,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.5783524264 -US-Ton,19973,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,19973,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19973,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,19973,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,19973,GRP_SWC,SWC_DATE,20030711 -US-Ton,19833,GRP_SWC,SWC,5.75 -US-Ton,19833,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.9671113899 -US-Ton,19833,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19833,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19833,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,19833,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,19833,GRP_SWC,SWC_DATE,20020725 -US-Ton,19825,GRP_SWC,SWC,5.7733333333 -US-Ton,19825,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.7607768633 -US-Ton,19825,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19825,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19825,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,19825,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,19825,GRP_SWC,SWC_DATE,20020711 -US-Ton,19857,GRP_SWC,SWC,5.8 -US-Ton,19857,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.8055470085 -US-Ton,19857,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Ton,19857,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19857,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,19857,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,19857,GRP_SWC,SWC_DATE,20020912 -US-Ton,19965,GRP_SWC,SWC,5.8422222222 -US-Ton,19965,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.3653846293 -US-Ton,19965,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,19965,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19965,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,19965,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,19965,GRP_SWC,SWC_DATE,20030702 -US-Ton,20869,GRP_SWC,SWC,5.9444444444 -US-Ton,20869,GRP_SWC,SWC_SPATIAL_VARIABILITY,8.4013185142 -US-Ton,20869,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20869,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20869,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20869,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20869,GRP_SWC,SWC_DATE,20130619 -US-Ton,20527,GRP_SWC,SWC,5.9555555556 -US-Ton,20527,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.6144927597 -US-Ton,20527,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20527,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20527,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20527,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20527,GRP_SWC,SWC_DATE,20081030 -US-Ton,19776,GRP_SWC,SWC,50.08 -US-Ton,19776,GRP_SWC,SWC_SPATIAL_VARIABILITY,8.4881976886 -US-Ton,19776,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19776,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19776,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,19776,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,19776,GRP_SWC,SWC_DATE,20020404 -US-Ton,20410,GRP_SWC,SWC,6.0305555556 -US-Ton,20410,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.1696623257 -US-Ton,20410,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20410,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20410,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20410,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20410,GRP_SWC,SWC_DATE,20070616 -US-Ton,20217,GRP_SWC,SWC,6.2083333333 -US-Ton,20217,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.39416835 -US-Ton,20217,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20217,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20217,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20217,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20217,GRP_SWC,SWC_DATE,20051029 -US-Ton,20097,GRP_SWC,SWC,6.2555555556 -US-Ton,20097,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.6452131819 -US-Ton,20097,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20097,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20097,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20097,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20097,GRP_SWC,SWC_DATE,20040506 -US-Ton,20503,GRP_SWC,SWC,6.335 -US-Ton,20503,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.0243655626 -US-Ton,20503,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20503,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20503,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20503,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20503,GRP_SWC,SWC_DATE,20080531 -US-Ton,20579,GRP_SWC,SWC,6.35 -US-Ton,20579,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.3573868429 -US-Ton,20579,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20579,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20579,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20579,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20579,GRP_SWC,SWC_DATE,20090621 -US-Ton,19821,GRP_SWC,SWC,6.39 -US-Ton,19821,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.6474988196 -US-Ton,19821,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19821,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19821,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,19821,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,19821,GRP_SWC,SWC_DATE,20020705 -US-Ton,20937,GRP_SWC,SWC,6.4227272727 -US-Ton,20937,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.2491849072 -US-Ton,20937,GRP_SWC,SWC_SPATIAL_REP_NUMBER,11 -US-Ton,20937,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20937,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20937,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20937,GRP_SWC,SWC_DATE,20140611 -US-Ton,19961,GRP_SWC,SWC,6.4481481481 -US-Ton,19961,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.8885363033 -US-Ton,19961,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,19961,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19961,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,19961,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,19961,GRP_SWC,SWC_DATE,20030627 -US-Ton,20881,GRP_SWC,SWC,6.4944444444 -US-Ton,20881,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.2714931613 -US-Ton,20881,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20881,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20881,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20881,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20881,GRP_SWC,SWC_DATE,20130813 -US-Ton,20285,GRP_SWC,SWC,6.5083333333 -US-Ton,20285,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.2245311303 -US-Ton,20285,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20285,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20285,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20285,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20285,GRP_SWC,SWC_DATE,20060623 -US-Ton,20873,GRP_SWC,SWC,6.6045454545 -US-Ton,20873,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.3559994068 -US-Ton,20873,GRP_SWC,SWC_SPATIAL_REP_NUMBER,11 -US-Ton,20873,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20873,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20873,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20873,GRP_SWC,SWC_DATE,20130711 -US-Ton,20941,GRP_SWC,SWC,6.6045454545 -US-Ton,20941,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.8763702464 -US-Ton,20941,GRP_SWC,SWC_SPATIAL_REP_NUMBER,11 -US-Ton,20941,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20941,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20941,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20941,GRP_SWC,SWC_DATE,20140625 -US-Ton,19957,GRP_SWC,SWC,6.6855555556 -US-Ton,19957,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.9171137753 -US-Ton,19957,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,19957,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19957,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,19957,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,19957,GRP_SWC,SWC_DATE,20030625 -US-Ton,19734,GRP_SWC,SWC,6.74 -US-Ton,19734,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.1282730166 -US-Ton,19734,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19734,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19734,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,19734,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,19734,GRP_SWC,SWC_DATE,20011110 -US-Ton,19817,GRP_SWC,SWC,6.78 -US-Ton,19817,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.8669185936 -US-Ton,19817,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19817,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19817,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,19817,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,19817,GRP_SWC,SWC_DATE,20020628 -US-Ton,20647,GRP_SWC,SWC,7.0166666667 -US-Ton,20647,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.8755500133 -US-Ton,20647,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20647,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20647,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20647,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20647,GRP_SWC,SWC_DATE,20100624 -US-Ton,19953,GRP_SWC,SWC,7.1 -US-Ton,19953,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.0297139579 -US-Ton,19953,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,19953,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19953,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,19953,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,19953,GRP_SWC,SWC_DATE,20030620 -US-Ton,20293,GRP_SWC,SWC,7.1333333333 -US-Ton,20293,GRP_SWC,SWC_SPATIAL_VARIABILITY,9.7255131515 -US-Ton,20293,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20293,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20293,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20293,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20293,GRP_SWC,SWC_DATE,20060801 -US-Ton,20414,GRP_SWC,SWC,7.2833333333 -US-Ton,20414,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.6355150525 -US-Ton,20414,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20414,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20414,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20414,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20414,GRP_SWC,SWC_DATE,20070623 -US-Ton,19945,GRP_SWC,SWC,7.4041666667 -US-Ton,19945,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.2583196322 -US-Ton,19945,GRP_SWC,SWC_SPATIAL_REP_NUMBER,8 -US-Ton,19945,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19945,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,19945,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,19945,GRP_SWC,SWC_DATE,20030606 -US-Ton,19813,GRP_SWC,SWC,7.4133333333 -US-Ton,19813,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.2808874138 -US-Ton,19813,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19813,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19813,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,19813,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,19813,GRP_SWC,SWC_DATE,20020620 -US-Ton,20966,GRP_SWC,SWC,7.5416666667 -US-Ton,20966,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.2890364108 -US-Ton,20966,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20966,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20966,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20966,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20966,GRP_SWC,SWC_DATE,20141024 -US-Ton,19733,GRP_SWC,SWC,7.58 -US-Ton,19733,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.0776218559 -US-Ton,19733,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19733,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19733,GRP_SWC,SWC_PROFILE_ZERO_REF,Top of mineral soil -US-Ton,19733,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,19733,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,19733,GRP_SWC,SWC_APPROACH,"TDR probes from Environmental Sensors Inc. (ESI), Canada, Moisture Points, 1-800-799-6324" -US-Ton,19733,GRP_SWC,SWC_DATE,20011110 -US-Ton,20886,GRP_SWC,SWC,7.6181818182 -US-Ton,20886,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.4400052854 -US-Ton,20886,GRP_SWC,SWC_SPATIAL_REP_NUMBER,11 -US-Ton,20886,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20886,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20886,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20886,GRP_SWC,SWC_DATE,20130904 -US-Ton,20136,GRP_SWC,SWC,7.7111111111 -US-Ton,20136,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.6063986345 -US-Ton,20136,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20136,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20136,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20136,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20136,GRP_SWC,SWC_DATE,20041013 -US-Ton,20281,GRP_SWC,SWC,7.7444444444 -US-Ton,20281,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.4469524919 -US-Ton,20281,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20281,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20281,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20281,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20281,GRP_SWC,SWC_DATE,20060608 -US-Ton,20406,GRP_SWC,SWC,7.7555555556 -US-Ton,20406,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.1242405688 -US-Ton,20406,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20406,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20406,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20406,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20406,GRP_SWC,SWC_DATE,20070604 -US-Ton,20889,GRP_SWC,SWC,7.7681818182 -US-Ton,20889,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.8539766947 -US-Ton,20889,GRP_SWC,SWC_SPATIAL_REP_NUMBER,11 -US-Ton,20889,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20889,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20889,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20889,GRP_SWC,SWC_DATE,20130925 -US-Ton,20958,GRP_SWC,SWC,7.7833333333 -US-Ton,20958,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.6943650785 -US-Ton,20958,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20958,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20958,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20958,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20958,GRP_SWC,SWC_DATE,20140911 -US-Ton,19949,GRP_SWC,SWC,7.7925925926 -US-Ton,19949,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.0354286617 -US-Ton,19949,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,19949,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19949,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,19949,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,19949,GRP_SWC,SWC_DATE,20030613 -US-Ton,20093,GRP_SWC,SWC,7.7944444444 -US-Ton,20093,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.4304194755 -US-Ton,20093,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20093,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20093,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20093,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20093,GRP_SWC,SWC_DATE,20040428 -US-Ton,20965,GRP_SWC,SWC,7.8590909091 -US-Ton,20965,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.4864149692 -US-Ton,20965,GRP_SWC,SWC_SPATIAL_REP_NUMBER,11 -US-Ton,20965,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20965,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20965,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20965,GRP_SWC,SWC_DATE,20141024 -US-Ton,20132,GRP_SWC,SWC,7.8944444444 -US-Ton,20132,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.5880395452 -US-Ton,20132,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20132,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20132,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20132,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20132,GRP_SWC,SWC_DATE,20040921 -US-Ton,20720,GRP_SWC,SWC,7.9575757576 -US-Ton,20720,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.0118318866 -US-Ton,20720,GRP_SWC,SWC_SPATIAL_REP_NUMBER,11 -US-Ton,20720,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20720,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20720,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20720,GRP_SWC,SWC_DATE,20110720 -US-Ton,20760,GRP_SWC,SWC,8.1636363636 -US-Ton,20760,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.0686048536 -US-Ton,20760,GRP_SWC,SWC_SPATIAL_REP_NUMBER,11 -US-Ton,20760,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20760,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20760,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20760,GRP_SWC,SWC_DATE,20120118 -US-Ton,19809,GRP_SWC,SWC,8.26 -US-Ton,19809,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.7819307238 -US-Ton,19809,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19809,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19809,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,19809,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,19809,GRP_SWC,SWC_DATE,20020613 -US-Ton,20878,GRP_SWC,SWC,8.3125 -US-Ton,20878,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.2750930346 -US-Ton,20878,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20878,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20878,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20878,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20878,GRP_SWC,SWC_DATE,20130728 -US-Ton,20909,GRP_SWC,SWC,8.3166666667 -US-Ton,20909,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.7214853852 -US-Ton,20909,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20909,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20909,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20909,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20909,GRP_SWC,SWC_DATE,20140124 -US-Ton,20575,GRP_SWC,SWC,8.325 -US-Ton,20575,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.495549118 -US-Ton,20575,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20575,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20575,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20575,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20575,GRP_SWC,SWC_DATE,20090609 -US-Ton,20499,GRP_SWC,SWC,8.375 -US-Ton,20499,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.8497607555 -US-Ton,20499,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20499,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20499,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20499,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20499,GRP_SWC,SWC_DATE,20080506 -US-Ton,20894,GRP_SWC,SWC,8.3954545455 -US-Ton,20894,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.1847591335 -US-Ton,20894,GRP_SWC,SWC_SPATIAL_REP_NUMBER,11 -US-Ton,20894,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20894,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20894,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20894,GRP_SWC,SWC_DATE,20131107 -US-Ton,20882,GRP_SWC,SWC,8.4291666667 -US-Ton,20882,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.2190831799 -US-Ton,20882,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20882,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20882,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20882,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20882,GRP_SWC,SWC_DATE,20130813 -US-Ton,20793,GRP_SWC,SWC,8.4318181818 -US-Ton,20793,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.0526441594 -US-Ton,20793,GRP_SWC,SWC_SPATIAL_REP_NUMBER,11 -US-Ton,20793,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20793,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20793,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20793,GRP_SWC,SWC_DATE,20120530 -US-Ton,20128,GRP_SWC,SWC,8.4481481481 -US-Ton,20128,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.6412418177 -US-Ton,20128,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20128,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20128,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20128,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20128,GRP_SWC,SWC_DATE,20040908 -US-Ton,20024,GRP_SWC,SWC,8.45 -US-Ton,20024,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.1357083134 -US-Ton,20024,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20024,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20024,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20024,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20024,GRP_SWC,SWC_DATE,20031107 -US-Ton,20643,GRP_SWC,SWC,8.4944444444 -US-Ton,20643,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.0157778142 -US-Ton,20643,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20643,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20643,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20643,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20643,GRP_SWC,SWC_DATE,20100610 -US-Ton,20020,GRP_SWC,SWC,8.4962962963 -US-Ton,20020,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.6718410447 -US-Ton,20020,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20020,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20020,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20020,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20020,GRP_SWC,SWC_DATE,20031024 -US-Ton,20201,GRP_SWC,SWC,8.5430555556 -US-Ton,20201,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.0493948814 -US-Ton,20201,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20201,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20201,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20201,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20201,GRP_SWC,SWC_DATE,20050623 -US-Ton,20877,GRP_SWC,SWC,8.5722222222 -US-Ton,20877,GRP_SWC,SWC_SPATIAL_VARIABILITY,10.420985771 -US-Ton,20877,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20877,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20877,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20877,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20877,GRP_SWC,SWC_DATE,20130728 -US-Ton,20022,GRP_SWC,SWC,8.6 -US-Ton,20022,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.6326643115 -US-Ton,20022,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20022,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20022,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20022,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20022,GRP_SWC,SWC_DATE,20031107 -US-Ton,20089,GRP_SWC,SWC,8.6 -US-Ton,20089,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.138926707 -US-Ton,20089,GRP_SWC,SWC_SPATIAL_REP_NUMBER,8 -US-Ton,20089,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20089,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20089,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20089,GRP_SWC,SWC_DATE,20040423 -US-Ton,20954,GRP_SWC,SWC,8.65 -US-Ton,20954,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.9564102186 -US-Ton,20954,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20954,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20954,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20954,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20954,GRP_SWC,SWC_DATE,20140821 -US-Ton,20130,GRP_SWC,SWC,8.7222222222 -US-Ton,20130,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.3662953591 -US-Ton,20130,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20130,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20130,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20130,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20130,GRP_SWC,SWC_DATE,20040921 -US-Ton,20040,GRP_SWC,SWC,8.7388888889 -US-Ton,20040,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.3876999625 -US-Ton,20040,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20040,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20040,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20040,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20040,GRP_SWC,SWC_DATE,20031127 -US-Ton,20016,GRP_SWC,SWC,8.8 -US-Ton,20016,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.630114066 -US-Ton,20016,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20016,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20016,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20016,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20016,GRP_SWC,SWC_DATE,20031007 -US-Ton,20134,GRP_SWC,SWC,8.8166666667 -US-Ton,20134,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.505174746 -US-Ton,20134,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20134,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20134,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20134,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20134,GRP_SWC,SWC_DATE,20041013 -US-Ton,19989,GRP_SWC,SWC,8.8222222222 -US-Ton,19989,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.0284060813 -US-Ton,19989,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,19989,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19989,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,19989,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,19989,GRP_SWC,SWC_DATE,20030806 -US-Ton,20124,GRP_SWC,SWC,8.8222222222 -US-Ton,20124,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.6759730382 -US-Ton,20124,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20124,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20124,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20124,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20124,GRP_SWC,SWC_DATE,20040817 -US-Ton,20520,GRP_SWC,SWC,8.8375 -US-Ton,20520,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.378886651 -US-Ton,20520,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20520,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20520,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20520,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20520,GRP_SWC,SWC_DATE,20080904 -US-Ton,20032,GRP_SWC,SWC,8.8388888889 -US-Ton,20032,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.6699459004 -US-Ton,20032,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20032,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20032,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20032,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20032,GRP_SWC,SWC_DATE,20031112 -US-Ton,20571,GRP_SWC,SWC,8.8416666667 -US-Ton,20571,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.8317948164 -US-Ton,20571,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20571,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20571,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20571,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20571,GRP_SWC,SWC_DATE,20090527 -US-Ton,20874,GRP_SWC,SWC,8.8958333333 -US-Ton,20874,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.8843191947 -US-Ton,20874,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20874,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20874,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20874,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20874,GRP_SWC,SWC_DATE,20130711 -US-Ton,20294,GRP_SWC,SWC,8.9 -US-Ton,20294,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.3955039012 -US-Ton,20294,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20294,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20294,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20294,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20294,GRP_SWC,SWC_DATE,20060801 -US-Ton,20012,GRP_SWC,SWC,8.9185185185 -US-Ton,20012,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.7942456302 -US-Ton,20012,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20012,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20012,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20012,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20012,GRP_SWC,SWC_DATE,20031002 -US-Ton,20814,GRP_SWC,SWC,8.9513888889 -US-Ton,20814,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.5188687371 -US-Ton,20814,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20814,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20814,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20814,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20814,GRP_SWC,SWC_DATE,20120919 -US-Ton,20890,GRP_SWC,SWC,8.9555555556 -US-Ton,20890,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.4563275484 -US-Ton,20890,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20890,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20890,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20890,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20890,GRP_SWC,SWC_DATE,20130925 -US-Ton,20528,GRP_SWC,SWC,8.9708333333 -US-Ton,20528,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.1577795949 -US-Ton,20528,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20528,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20528,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20528,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20528,GRP_SWC,SWC_DATE,20081030 -US-Ton,20449,GRP_SWC,SWC,8.9875 -US-Ton,20449,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.0283723873 -US-Ton,20449,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20449,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20449,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20449,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20449,GRP_SWC,SWC_DATE,20071107 -US-Ton,20126,GRP_SWC,SWC,9.0111111111 -US-Ton,20126,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.2559774091 -US-Ton,20126,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20126,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20126,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20126,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20126,GRP_SWC,SWC_DATE,20040908 -US-Ton,20044,GRP_SWC,SWC,9.0222222222 -US-Ton,20044,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.286251177 -US-Ton,20044,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20044,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20044,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20044,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20044,GRP_SWC,SWC_DATE,20031206 -US-Ton,20446,GRP_SWC,SWC,9.025 -US-Ton,20446,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.0701219279 -US-Ton,20446,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20446,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20446,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20446,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20446,GRP_SWC,SWC_DATE,20071107 -US-Ton,20752,GRP_SWC,SWC,9.0318181818 -US-Ton,20752,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.9491551161 -US-Ton,20752,GRP_SWC,SWC_SPATIAL_REP_NUMBER,11 -US-Ton,20752,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20752,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20752,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20752,GRP_SWC,SWC_DATE,20111218 -US-Ton,20961,GRP_SWC,SWC,9.0458333333 -US-Ton,20961,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.2105591984 -US-Ton,20961,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20961,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20961,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20961,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20961,GRP_SWC,SWC_DATE,20140930 -US-Ton,20756,GRP_SWC,SWC,9.05 -US-Ton,20756,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.4583955818 -US-Ton,20756,GRP_SWC,SWC_SPATIAL_REP_NUMBER,11 -US-Ton,20756,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20756,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20756,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20756,GRP_SWC,SWC_DATE,20120104 -US-Ton,20596,GRP_SWC,SWC,9.0555555556 -US-Ton,20596,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.2714045213 -US-Ton,20596,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20596,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20596,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20596,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20596,GRP_SWC,SWC_DATE,20091002 -US-Ton,20036,GRP_SWC,SWC,9.0722222222 -US-Ton,20036,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.3214877892 -US-Ton,20036,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20036,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20036,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20036,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20036,GRP_SWC,SWC_DATE,20031119 -US-Ton,20218,GRP_SWC,SWC,9.1041666667 -US-Ton,20218,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.2108097487 -US-Ton,20218,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20218,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20218,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20218,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20218,GRP_SWC,SWC_DATE,20051029 -US-Ton,20516,GRP_SWC,SWC,9.1083333333 -US-Ton,20516,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.0814572507 -US-Ton,20516,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20516,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20516,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20516,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20516,GRP_SWC,SWC_DATE,20080820 -US-Ton,20453,GRP_SWC,SWC,9.1111111111 -US-Ton,20453,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.8978972143 -US-Ton,20453,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20453,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20453,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20453,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20453,GRP_SWC,SWC_DATE,20071111 -US-Ton,20028,GRP_SWC,SWC,9.1203703704 -US-Ton,20028,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.7881791372 -US-Ton,20028,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20028,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20028,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20028,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20028,GRP_SWC,SWC_DATE,20031110 -US-Ton,20120,GRP_SWC,SWC,9.137037037 -US-Ton,20120,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.6792377096 -US-Ton,20120,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20120,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20120,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20120,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20120,GRP_SWC,SWC_DATE,20040805 -US-Ton,20439,GRP_SWC,SWC,9.1583333333 -US-Ton,20439,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.9082649553 -US-Ton,20439,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20439,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20439,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20439,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20439,GRP_SWC,SWC_DATE,20070920 -US-Ton,20018,GRP_SWC,SWC,9.2 -US-Ton,20018,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.7298719072 -US-Ton,20018,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20018,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20018,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20018,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20018,GRP_SWC,SWC_DATE,20031024 -US-Ton,20435,GRP_SWC,SWC,9.2027777778 -US-Ton,20435,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.0827135604 -US-Ton,20435,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20435,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20435,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20435,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20435,GRP_SWC,SWC_DATE,20070908 -US-Ton,20443,GRP_SWC,SWC,9.2166666667 -US-Ton,20443,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.306910426 -US-Ton,20443,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20443,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20443,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20443,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20443,GRP_SWC,SWC_DATE,20071024 -US-Ton,20806,GRP_SWC,SWC,9.2263888889 -US-Ton,20806,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.2711710263 -US-Ton,20806,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20806,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20806,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20806,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20806,GRP_SWC,SWC_DATE,20120822 -US-Ton,20431,GRP_SWC,SWC,9.2333333333 -US-Ton,20431,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.9590470757 -US-Ton,20431,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20431,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20431,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20431,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20431,GRP_SWC,SWC_DATE,20070822 -US-Ton,20116,GRP_SWC,SWC,9.2351851852 -US-Ton,20116,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.7267468354 -US-Ton,20116,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20116,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20116,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20116,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20116,GRP_SWC,SWC_DATE,20040721 -US-Ton,20660,GRP_SWC,SWC,9.2458333333 -US-Ton,20660,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.8285683494 -US-Ton,20660,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20660,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20660,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20660,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20660,GRP_SWC,SWC_DATE,20101007 -US-Ton,20512,GRP_SWC,SWC,9.2625 -US-Ton,20512,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.1262906426 -US-Ton,20512,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20512,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20512,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20512,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20512,GRP_SWC,SWC_DATE,20080806 -US-Ton,20524,GRP_SWC,SWC,9.2625 -US-Ton,20524,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.1262906426 -US-Ton,20524,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20524,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20524,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20524,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20524,GRP_SWC,SWC_DATE,20080919 -US-Ton,20298,GRP_SWC,SWC,9.2666666667 -US-Ton,20298,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.4447148802 -US-Ton,20298,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20298,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20298,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20298,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20298,GRP_SWC,SWC_DATE,20060808 -US-Ton,20508,GRP_SWC,SWC,9.4 -US-Ton,20508,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.3975927307 -US-Ton,20508,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20508,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20508,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20508,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20508,GRP_SWC,SWC_DATE,20080731 -US-Ton,20008,GRP_SWC,SWC,9.4444444444 -US-Ton,20008,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.035358756 -US-Ton,20008,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20008,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20008,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20008,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20008,GRP_SWC,SWC_DATE,20030918 -US-Ton,20592,GRP_SWC,SWC,9.4833333333 -US-Ton,20592,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.3560889937 -US-Ton,20592,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20592,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20592,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20592,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20592,GRP_SWC,SWC_DATE,20090907 -US-Ton,20427,GRP_SWC,SWC,9.4861111111 -US-Ton,20427,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.988173941 -US-Ton,20427,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20427,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20427,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20427,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20427,GRP_SWC,SWC_DATE,20070809 -US-Ton,20210,GRP_SWC,SWC,9.5 -US-Ton,20210,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.1638584039 -US-Ton,20210,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20210,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20210,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20210,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20210,GRP_SWC,SWC_DATE,20050910 -US-Ton,20122,GRP_SWC,SWC,9.5037037037 -US-Ton,20122,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.4351307772 -US-Ton,20122,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20122,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20122,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20122,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20122,GRP_SWC,SWC_DATE,20040817 -US-Ton,20310,GRP_SWC,SWC,9.5083333333 -US-Ton,20310,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.6889166513 -US-Ton,20310,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20310,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20310,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20310,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20310,GRP_SWC,SWC_DATE,20061108 -US-Ton,20656,GRP_SWC,SWC,9.5166666667 -US-Ton,20656,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.9507383276 -US-Ton,20656,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20656,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20656,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20656,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20656,GRP_SWC,SWC_DATE,20100902 -US-Ton,20740,GRP_SWC,SWC,9.5227272727 -US-Ton,20740,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.1251335325 -US-Ton,20740,GRP_SWC,SWC_SPATIAL_REP_NUMBER,11 -US-Ton,20740,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20740,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20740,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20740,GRP_SWC,SWC_DATE,20111026 -US-Ton,20447,GRP_SWC,SWC,9.525 -US-Ton,20447,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.1858707958 -US-Ton,20447,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20447,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20447,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20447,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20447,GRP_SWC,SWC_DATE,20071107 -US-Ton,20810,GRP_SWC,SWC,9.5333333333 -US-Ton,20810,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.0408482932 -US-Ton,20810,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20810,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20810,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20810,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20810,GRP_SWC,SWC_DATE,20120905 -US-Ton,20445,GRP_SWC,SWC,9.5416666667 -US-Ton,20445,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.5074153269 -US-Ton,20445,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20445,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20445,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20445,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20445,GRP_SWC,SWC_DATE,20071024 -US-Ton,19797,GRP_SWC,SWC,9.5666666667 -US-Ton,19797,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.3504150504 -US-Ton,19797,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19797,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19797,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,19797,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,19797,GRP_SWC,SWC_DATE,20020516 -US-Ton,19805,GRP_SWC,SWC,9.57 -US-Ton,19805,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.1670733135 -US-Ton,19805,GRP_SWC,SWC_SPATIAL_REP_NUMBER,5 -US-Ton,19805,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19805,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,19805,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,19805,GRP_SWC,SWC_DATE,20020606 -US-Ton,20023,GRP_SWC,SWC,9.5740740741 -US-Ton,20023,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.6071661505 -US-Ton,20023,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20023,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20023,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20023,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20023,GRP_SWC,SWC_DATE,20031107 -US-Ton,20733,GRP_SWC,SWC,9.5805555556 -US-Ton,20733,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.0569981522 -US-Ton,20733,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20733,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20733,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20733,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20733,GRP_SWC,SWC_DATE,20110929 -US-Ton,20744,GRP_SWC,SWC,9.5819444444 -US-Ton,20744,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.9161733617 -US-Ton,20744,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20744,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20744,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20744,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20744,GRP_SWC,SWC_DATE,20111109 -US-Ton,20006,GRP_SWC,SWC,9.6111111111 -US-Ton,20006,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.786058123 -US-Ton,20006,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20006,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20006,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20006,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20006,GRP_SWC,SWC_DATE,20030918 -US-Ton,20461,GRP_SWC,SWC,9.625 -US-Ton,20461,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.1135677208 -US-Ton,20461,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20461,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20461,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20461,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20461,GRP_SWC,SWC_DATE,20071129 -US-Ton,20118,GRP_SWC,SWC,9.6259259259 -US-Ton,20118,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.4048485762 -US-Ton,20118,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20118,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20118,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20118,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20118,GRP_SWC,SWC_DATE,20040805 -US-Ton,20716,GRP_SWC,SWC,9.63 -US-Ton,20716,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.6899412823 -US-Ton,20716,GRP_SWC,SWC_SPATIAL_REP_NUMBER,10 -US-Ton,20716,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20716,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20716,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20716,GRP_SWC,SWC_DATE,20110706 -US-Ton,20010,GRP_SWC,SWC,9.637037037 -US-Ton,20010,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.9698672118 -US-Ton,20010,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20010,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20010,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20010,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20010,GRP_SWC,SWC_DATE,20031002 -US-Ton,20220,GRP_SWC,SWC,9.6375 -US-Ton,20220,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.6966683066 -US-Ton,20220,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20220,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20220,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20220,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20220,GRP_SWC,SWC_DATE,20051029 -US-Ton,20214,GRP_SWC,SWC,9.6458333333 -US-Ton,20214,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.4035715421 -US-Ton,20214,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20214,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20214,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20214,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20214,GRP_SWC,SWC_DATE,20050925 -US-Ton,19990,GRP_SWC,SWC,9.6981481481 -US-Ton,19990,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.8647484865 -US-Ton,19990,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,19990,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,19990,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,19990,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,19990,GRP_SWC,SWC_DATE,20030806 -US-Ton,20014,GRP_SWC,SWC,9.7055555556 -US-Ton,20014,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.8297718963 -US-Ton,20014,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20014,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20014,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20014,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20014,GRP_SWC,SWC_DATE,20031007 -US-Ton,20457,GRP_SWC,SWC,9.7138888889 -US-Ton,20457,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.2445558317 -US-Ton,20457,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20457,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20457,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20457,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20457,GRP_SWC,SWC_DATE,20071125 -US-Ton,20114,GRP_SWC,SWC,9.7240740741 -US-Ton,20114,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.77135688 -US-Ton,20114,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20114,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20114,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20114,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20114,GRP_SWC,SWC_DATE,20040721 -US-Ton,20933,GRP_SWC,SWC,9.7375 -US-Ton,20933,GRP_SWC,SWC_SPATIAL_VARIABILITY,10.019801418 -US-Ton,20933,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20933,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20933,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20933,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20933,GRP_SWC,SWC_DATE,20140522 -US-Ton,20112,GRP_SWC,SWC,9.7407407407 -US-Ton,20112,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.7529535694 -US-Ton,20112,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20112,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20112,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20112,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20112,GRP_SWC,SWC_DATE,20040708 -US-Ton,20135,GRP_SWC,SWC,9.75 -US-Ton,20135,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.9549217955 -US-Ton,20135,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20135,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20135,GRP_SWC,SWC_PROFILE_MIN,30 -US-Ton,20135,GRP_SWC,SWC_PROFILE_MAX,45 -US-Ton,20135,GRP_SWC,SWC_DATE,20041013 -US-Ton,20004,GRP_SWC,SWC,9.7833333333 -US-Ton,20004,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.9981475762 -US-Ton,20004,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20004,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20004,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20004,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20004,GRP_SWC,SWC_DATE,20030905 -US-Ton,20504,GRP_SWC,SWC,9.8125 -US-Ton,20504,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.0177599308 -US-Ton,20504,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20504,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20504,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20504,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20504,GRP_SWC,SWC_DATE,20080531 -US-Ton,20962,GRP_SWC,SWC,9.9 -US-Ton,20962,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.1502427127 -US-Ton,20962,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20962,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20962,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20962,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20962,GRP_SWC,SWC_DATE,20140930 -US-Ton,20588,GRP_SWC,SWC,9.9583333333 -US-Ton,20588,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.2701010085 -US-Ton,20588,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20588,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20588,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20588,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20588,GRP_SWC,SWC_DATE,20090802 -US-Ton,20002,GRP_SWC,SWC,9.9625925926 -US-Ton,20002,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.8771889079 -US-Ton,20002,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20002,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20002,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20002,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20002,GRP_SWC,SWC_DATE,20030905 -US-Ton,20441,GRP_SWC,SWC,9.9638888889 -US-Ton,20441,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.4958220411 -US-Ton,20441,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20441,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20441,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20441,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20441,GRP_SWC,SWC_DATE,20070920 -US-Ton,20423,GRP_SWC,SWC,9.9757575758 -US-Ton,20423,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.0375096126 -US-Ton,20423,GRP_SWC,SWC_SPATIAL_REP_NUMBER,11 -US-Ton,20423,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20423,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20423,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20423,GRP_SWC,SWC_DATE,20070717 -US-Ton,20712,GRP_SWC,SWC,9.9818181818 -US-Ton,20712,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.5864331353 -US-Ton,20712,GRP_SWC,SWC_SPATIAL_REP_NUMBER,11 -US-Ton,20712,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20712,GRP_SWC,SWC_PROFILE_MIN,0 -US-Ton,20712,GRP_SWC,SWC_PROFILE_MAX,15 -US-Ton,20712,GRP_SWC,SWC_DATE,20110615 -US-Ton,20000,GRP_SWC,SWC,9.9833333333 -US-Ton,20000,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.3169074452 -US-Ton,20000,GRP_SWC,SWC_SPATIAL_REP_NUMBER,9 -US-Ton,20000,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20000,GRP_SWC,SWC_PROFILE_MIN,45 -US-Ton,20000,GRP_SWC,SWC_PROFILE_MAX,60 -US-Ton,20000,GRP_SWC,SWC_DATE,20030821 -US-Ton,20302,GRP_SWC,SWC,9.9916666667 -US-Ton,20302,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.4642218944 -US-Ton,20302,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20302,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20302,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20302,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20302,GRP_SWC,SWC_DATE,20060923 -US-Ton,20950,GRP_SWC,SWC,9.9916666667 -US-Ton,20950,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.1611155492 -US-Ton,20950,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20950,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20950,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20950,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20950,GRP_SWC,SWC_DATE,20140805 -US-Ton,20290,GRP_SWC,SWC,9.9972222222 -US-Ton,20290,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.678258765 -US-Ton,20290,GRP_SWC,SWC_SPATIAL_REP_NUMBER,12 -US-Ton,20290,GRP_SWC,SWC_UNIT,Volumetric -US-Ton,20290,GRP_SWC,SWC_PROFILE_MIN,15 -US-Ton,20290,GRP_SWC,SWC_PROFILE_MAX,30 -US-Ton,20290,GRP_SWC,SWC_DATE,20060713 -US-Ton,9346,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Dennis Baldocchi -US-Ton,9346,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Ton,9346,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,Baldocchi@berkeley.edu -US-Ton,9346,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"University of California, Berkeley" -US-Ton,9346,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Department of Environmental Science, Policy and Management, 137 Mulford Hall, 345 Hilgard Hall,Berkeley, CA USA 94720-3110" -US-Ton,5065,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Siyan Ma -US-Ton,5065,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-Ton,5065,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,syma@berkeley.edu -US-Ton,5065,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"University of California, Berkeley" -US-Ton,81426,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Daphne Szutu -US-Ton,81426,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Technician -US-Ton,81426,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,daphneszutu@berkeley.edu -US-Ton,81426,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,UC Berkeley -US-Ton,6739,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Joe Verfaillie -US-Ton,6739,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Technician -US-Ton,6739,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,jverfail@berkeley.edu -US-Ton,6739,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"University of California, Berkeley" -US-Ton,33665,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-Ton,33664,GRP_TOWER_TYPE,TOWER_TYPE,walk-up -US-Ton,6737,GRP_URL,URL,http://nature.berkeley.edu/biometlab/sites.php?tab=US-Ton -US-Ton,24000438,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-Ton -US-Ton,4160,GRP_UTC_OFFSET,UTC_OFFSET,-8 -US-TrB,91015,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,"We acknowledge support from Ameriflux, NSF DEG #1552976, NSF NTL LTER #DEB-1440297, and UW2020" -US-TrB,91010,GRP_CLIM_AVG,MAT,3.8 -US-TrB,91010,GRP_CLIM_AVG,MAP,787 -US-TrB,91010,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfb -US-TrB,27001120,GRP_COUNTRY,COUNTRY,USA -US-TrB,96779,GRP_DOI,DOI,10.17190/AMF/1804493 -US-TrB,96779,GRP_DOI,DOI_CITATION,"Paul Stoy (2021), AmeriFlux BASE US-TrB Trout Bog, Ver. 1-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1804493" -US-TrB,96779,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-TrB,96767,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-TrB,96767,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Paul Stoy -US-TrB,96767,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-TrB,96767,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,pcstoy@wisc.edu -US-TrB,96767,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of Wisconsin -US-TrB,96775,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,University of Wisconsin -US-TrB,96775,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-TrB,96774,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,"Ameriflux, NSF" -US-TrB,96774,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-TrB,91020,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-TrB,91020,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-TrB,91020,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20200317 -US-TrB,91020,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Periodic operation -US-TrB,91027,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-TrB,91027,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CH4 -US-TrB,91027,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20200317 -US-TrB,91027,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Periodic operation -US-TrB,91027,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,Flux measurements are made on a small buoy that will settle into the bog after ice melt -US-TrB,91023,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-TrB,91023,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-TrB,91023,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20200317 -US-TrB,91023,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Periodic operation -US-TrB,91019,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-TrB,91019,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-TrB,91019,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20200317 -US-TrB,91019,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Periodic operation -US-TrB,23001120,GRP_HEADER,SITE_NAME,Trout Bog -US-TrB,91028,GRP_IGBP,IGBP,WAT -US-TrB,91028,GRP_IGBP,IGBP_COMMENT,Bog lake -US-TrB,91017,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-TrB,91017,GRP_LAND_OWNERSHIP,LAND_OWNER,Wisconsin Department of Natural Resources -US-TrB,91008,GRP_LOCATION,LOCATION_LAT,46.0412 -US-TrB,91008,GRP_LOCATION,LOCATION_LONG,-89.6862 -US-TrB,91008,GRP_LOCATION,LOCATION_ELEV,499 -US-TrB,91008,GRP_LOCATION,LOCATION_DATE_START,20200317 -US-TrB,91008,GRP_LOCATION,LOCATION_COMMENT,The buoy is anchored and will move over a limited area in response to wind -US-TrB,91011,GRP_NETWORK,NETWORK,AmeriFlux -US-TrB,91006,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"Bog lake melt, methane efflux" -US-TrB,91013,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"540 Elm Drive, University of Wisconsin – Madison, Madison, WI 53706" -US-TrB,91022,GRP_SITE_CHAR,TERRAIN,Flat -US-TrB,91022,GRP_SITE_CHAR,ASPECT,FLAT -US-TrB,91022,GRP_SITE_CHAR,WIND_DIRECTION,SW -US-TrB,91022,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,60 -US-TrB,91012,GRP_SITE_DESC,SITE_DESC,Trout Bog is part of the North Temperate Lakes Long Term Ecological Research Network described here: https://lter.limnology.wisc.edu/researchsite/trout-bog -US-TrB,91007,GRP_SITE_FUNDING,SITE_FUNDING,"Ameriflux, NSF" -US-TrB,91026,GRP_STATE,STATE,WI -US-TrB,91018,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Paul Stoy -US-TrB,91018,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-TrB,91018,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,pcstoy@wisc.edu -US-TrB,91018,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Wisconsin -US-TrB,91018,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"460 Henry Mall, University of Wisconsin – Madison, Madison, WI 53706" -US-TrB,91156,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Ankur Desai -US-TrB,91156,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,AncContact -US-TrB,91156,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,desai@aos.wisc.edu -US-TrB,91156,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Wisconsin -US-TrB,91155,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Hilary Dugan -US-TrB,91155,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,AncContact -US-TrB,91155,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,hdugan@wisc.edu -US-TrB,91155,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Wisconsin -US-TrB,91158,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Paul Schramm -US-TrB,91158,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Technician -US-TrB,91158,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,pschramm@wisc.edu -US-TrB,91158,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Wisconsin -US-TrB,91016,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-TrB,91014,GRP_TOWER_TYPE,TOWER_TYPE,other -US-TrB,24001120,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-TrB -US-TrB,91021,GRP_UTC_OFFSET,UTC_OFFSET,-6 -US-TrB,91021,GRP_UTC_OFFSET,UTC_OFFSET_DATE_START,20200317 -US-TrS,91037,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,"We acknowledge support from Ameriflux, NSF DEG #1552976, NSF NTL LTER #DEB-1440297, NSF-DEB 1856224, and UW2020" -US-TrS,91050,GRP_CLIM_AVG,MAT,3.8 -US-TrS,91050,GRP_CLIM_AVG,MAP,787 -US-TrS,91050,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfb -US-TrS,27001121,GRP_COUNTRY,COUNTRY,USA -US-TrS,98493,GRP_DOI,DOI,10.17190/AMF/1825939 -US-TrS,98493,GRP_DOI,DOI_CITATION,"Paul Stoy (2021), AmeriFlux BASE US-TrS Trout Lake Area South Sparkling Bog, Ver. 1-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1825939" -US-TrS,98493,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-TrS,98476,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-TrS,98476,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Paul Stoy -US-TrS,98476,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-TrS,98476,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,pcstoy@wisc.edu -US-TrS,98476,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of Wisconsin -US-TrS,98487,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,University of Wisconsin -US-TrS,98487,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-TrS,98484,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,"Ameriflux, NSF" -US-TrS,98484,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-TrS,91048,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-TrS,91048,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-TrS,91048,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20200317 -US-TrS,91048,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Periodic operation -US-TrS,91038,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-TrS,91038,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CH4 -US-TrS,91038,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20200317 -US-TrS,91038,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Periodic operation -US-TrS,91038,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,Flux measurements are made on a small buoy that will settle into the bog after ice melt -US-TrS,91043,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-TrS,91043,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-TrS,91043,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20200317 -US-TrS,91043,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Periodic operation -US-TrS,91041,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-TrS,91041,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-TrS,91041,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20200317 -US-TrS,91041,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Periodic operation -US-TrS,23001121,GRP_HEADER,SITE_NAME,Trout Lake Area South Sparkling Bog -US-TrS,91046,GRP_IGBP,IGBP,WAT -US-TrS,91046,GRP_IGBP,IGBP_COMMENT,Bog lake -US-TrS,91035,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-TrS,91035,GRP_LAND_OWNERSHIP,LAND_OWNER,Wisconsin Department of Natural Resources -US-TrS,91029,GRP_LOCATION,LOCATION_LAT,46.0034 -US-TrS,91029,GRP_LOCATION,LOCATION_LONG,-89.7053 -US-TrS,91029,GRP_LOCATION,LOCATION_ELEV,495 -US-TrS,91029,GRP_LOCATION,LOCATION_DATE_START,20200317 -US-TrS,91029,GRP_LOCATION,LOCATION_COMMENT,The buoy is anchored and will move over a limited area in response to wind -US-TrS,91036,GRP_NETWORK,NETWORK,AmeriFlux -US-TrS,91045,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"Bog lake melt, methane efflux" -US-TrS,91033,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"540 Elm Drive, University of Wisconsin – Madison, Madison, WI 53706" -US-TrS,91039,GRP_SITE_CHAR,TERRAIN,Flat -US-TrS,91039,GRP_SITE_CHAR,ASPECT,FLAT -US-TrS,91039,GRP_SITE_CHAR,WIND_DIRECTION,SW -US-TrS,91039,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,60 -US-TrS,91030,GRP_SITE_DESC,SITE_DESC,South Sparkling Bog was plowed after snow events during the winter of 2019/20 as an experimental treatment with Trout Bog (US-TrB) as a control -US-TrS,91034,GRP_SITE_FUNDING,SITE_FUNDING,"Ameriflux, NSF" -US-TrS,91042,GRP_STATE,STATE,WI -US-TrS,91047,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Paul Stoy -US-TrS,91047,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-TrS,91047,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,pcstoy@wisc.edu -US-TrS,91047,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Wisconsin -US-TrS,91047,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"460 Henry Mall, University of Wisconsin – Madison, Madison, WI 53706" -US-TrS,91157,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Ankur Desai -US-TrS,91157,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,AncContact -US-TrS,91157,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,desai@aos.wisc.edu -US-TrS,91157,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Wisconsin -US-TrS,91153,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Hilary Dugan -US-TrS,91153,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,AncContact -US-TrS,91153,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,hdugan@wisc.edu -US-TrS,91153,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Wisconsin -US-TrS,91154,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Paul Schramm -US-TrS,91154,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Technician -US-TrS,91154,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,pschramm@wisc.edu -US-TrS,91154,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Wisconsin -US-TrS,91031,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-TrS,91044,GRP_TOWER_TYPE,TOWER_TYPE,other -US-TrS,24001121,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-TrS -US-TrS,91049,GRP_UTC_OFFSET,UTC_OFFSET,-6 -US-Tur,85309,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,"Support comes from NSF OIA-1632810, DEB-1552976, USDA-NIFA 228396, USDA-Multistate W3188, and the Graduate School at Montana State University." -US-Tur,85307,GRP_CLIM_AVG,MAT,6.67 -US-Tur,85307,GRP_CLIM_AVG,MAP,670 -US-Tur,85307,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfb -US-Tur,27001017,GRP_COUNTRY,COUNTRY,USA -US-Tur,98492,GRP_DOI,DOI,10.17190/AMF/1825940 -US-Tur,98492,GRP_DOI,DOI_CITATION,"Paul Stoy (2021), AmeriFlux BASE US-Tur Turner Ranch, Ver. 1-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1825940" -US-Tur,98492,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-Tur,98475,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Tur,98475,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Paul Stoy -US-Tur,98475,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Tur,98475,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,paul.stoy@montana.edu -US-Tur,98475,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Montana State University -US-Tur,98488,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Montana State University -US-Tur,98488,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-Tur,98482,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,"NSF, USDA" -US-Tur,98482,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-Tur,85320,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Grazing -US-Tur,85314,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Tur,85314,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-Tur,85314,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201711141800 -US-Tur,85314,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,201802141230 -US-Tur,85314,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Periodic operation -US-Tur,85314,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,"Measurements were made during daytime hours. It was unsafe to access the tower when animals were present, resulting in a large data gap due to overwriting." -US-Tur,85316,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Tur,85316,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CH4 -US-Tur,85316,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201711141800 -US-Tur,85316,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,201802141230 -US-Tur,85316,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Periodic operation -US-Tur,85316,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,"Measurements were made during daytime hours. It was unsafe to access the tower when animals were present, resulting in a large data gap due to overwriting." -US-Tur,85310,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Tur,85310,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-Tur,85310,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201711141800 -US-Tur,85310,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,201802141230 -US-Tur,85310,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Periodic operation -US-Tur,85310,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,"Measurements were made during daytime hours. It was unsafe to access the tower when animals were present, resulting in a large data gap due to overwriting." -US-Tur,85311,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Tur,85311,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-Tur,85311,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201711141800 -US-Tur,85311,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,201802141230 -US-Tur,85311,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Periodic operation -US-Tur,85311,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,"Measurements were made during daytime hours. It was unsafe to access the tower when animals were present, resulting in a large data gap due to overwriting." -US-Tur,23001017,GRP_HEADER,SITE_NAME,Turner Ranch -US-Tur,85306,GRP_IGBP,IGBP,GRA -US-Tur,85306,GRP_IGBP,IGBP_COMMENT,"Snow cover was present throughout the measurement period. Climate is for nearby Bozeman, MT because the GHCN website is down for the government shutdown." -US-Tur,85304,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -US-Tur,85304,GRP_LAND_OWNERSHIP,LAND_OWNER,"Turner Enterprises, Inc." -US-Tur,85318,GRP_LOCATION,LOCATION_LAT,45.5571 -US-Tur,85318,GRP_LOCATION,LOCATION_LONG,-111.2286 -US-Tur,85318,GRP_LOCATION,LOCATION_ELEV,1530 -US-Tur,85318,GRP_LOCATION,LOCATION_DATE_START,201711141800 -US-Tur,85315,GRP_NETWORK,NETWORK,AmeriFlux -US-Tur,85308,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,Methane measurements from American Bison herd -US-Tur,85317,GRP_SITE_CHAR,TERRAIN,Flat -US-Tur,85317,GRP_SITE_CHAR,ASPECT,E -US-Tur,85317,GRP_SITE_CHAR,WIND_DIRECTION,SW -US-Tur,85317,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,80 -US-Tur,85301,GRP_SITE_DESC,SITE_DESC,Pasture -US-Tur,85302,GRP_SITE_FUNDING,SITE_FUNDING,"NSF, USDA" -US-Tur,85305,GRP_STATE,STATE,MT -US-Tur,85313,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Paul Stoy -US-Tur,85313,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Tur,85313,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,paul.stoy@montana.edu -US-Tur,85313,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Montana State University -US-Tur,85312,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-Tur,85319,GRP_TOWER_TYPE,TOWER_TYPE,tripod -US-Tur,24001017,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-Tur -US-Tur,85303,GRP_UTC_OFFSET,UTC_OFFSET,-7 -US-Tur,85303,GRP_UTC_OFFSET,UTC_OFFSET_COMMENT,Mountain Standard Time -US-Tw1,12560,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,"Biometeorology Lab, University of California, Berkeley, PI: Dennis Baldocchi" -US-Tw1,12561,GRP_CLIM_AVG,MAT,15.5 -US-Tw1,12561,GRP_CLIM_AVG,MAP,421 -US-Tw1,12561,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Csa -US-Tw1,27000518,GRP_COUNTRY,COUNTRY,USA -US-Tw1,15723,GRP_DOI,DOI,10.17190/AMF/1246147 -US-Tw1,15723,GRP_DOI,DOI_CITATION,"Alex Valach, Robert Shortt, Daphne Szutu, Elke Eichelmann, Sara Knox, Kyle Hemes, Joseph Verfaillie, Dennis Baldocchi (2021), AmeriFlux BASE US-Tw1 Twitchell Wetland West Pond, Ver. 9-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1246147" -US-Tw1,15723,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-Tw1,98284,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Tw1,98284,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Alex Valach -US-Tw1,98284,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Tw1,98284,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,1 -US-Tw1,98284,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0003-4782-5766 -US-Tw1,98284,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,valach@berkeley.edu -US-Tw1,98284,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"University of California, Berkeley" -US-Tw1,98284,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,20180212 -US-Tw1,98284,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_END,20200922 -US-Tw1,98291,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Tw1,98291,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Robert Shortt -US-Tw1,98291,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Tw1,98291,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,1 -US-Tw1,98291,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0001-5690-4656 -US-Tw1,98291,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,robert_shortt@berkeley.edu -US-Tw1,98291,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"University of California, Berkeley" -US-Tw1,98291,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,20210304 -US-Tw1,94144,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Tw1,94144,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Daphne Szutu -US-Tw1,94144,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Tw1,94144,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,2 -US-Tw1,94144,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0001-7698-0461 -US-Tw1,94144,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,daphneszutu@berkeley.edu -US-Tw1,94144,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"University of California, Berkeley" -US-Tw1,94144,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,201612 -US-Tw1,98278,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Tw1,98278,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Elke Eichelmann -US-Tw1,98278,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Tw1,98278,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,3 -US-Tw1,98278,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0001-9516-7951 -US-Tw1,98278,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,elke.eichelmann@ucd.ie -US-Tw1,98278,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"University of California, Berkeley" -US-Tw1,98278,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,20160801 -US-Tw1,98278,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_END,20180211 -US-Tw1,98282,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Tw1,98282,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Sara Knox -US-Tw1,98282,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Tw1,98282,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,4 -US-Tw1,98282,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,sknox01@mail.ubc.ca -US-Tw1,98282,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"University of California, Berkeley" -US-Tw1,98282,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,20130807 -US-Tw1,98282,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_END,20160427 -US-Tw1,98290,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Tw1,98290,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Kyle Hemes -US-Tw1,98290,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Tw1,98290,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,7 -US-Tw1,98290,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0001-5090-1083 -US-Tw1,98290,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,hemesphere@gmail.com -US-Tw1,98290,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"University of California, Berkeley" -US-Tw1,98290,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,20160429 -US-Tw1,98290,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_END,20160801 -US-Tw1,94149,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Tw1,94149,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Joseph Verfaillie -US-Tw1,94149,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Tw1,94149,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,8 -US-Tw1,94149,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0002-7009-8942 -US-Tw1,94149,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,jverfail@berkeley.edu -US-Tw1,94149,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"University of California, Berkeley" -US-Tw1,94149,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,20120424 -US-Tw1,94131,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Tw1,94131,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Dennis Baldocchi -US-Tw1,94131,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Tw1,94131,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,9 -US-Tw1,94131,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0003-3496-4919 -US-Tw1,94131,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,baldocchi@berkeley.edu -US-Tw1,94131,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"University of California, Berkeley" -US-Tw1,94131,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,20120424 -US-Tw1,32372,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,"University of California, Berkeley" -US-Tw1,32372,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-Tw1,32371,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,California Department of Water Resources -US-Tw1,32371,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-Tw1,22205,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Hydrologic event -US-Tw1,22206,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Land cover change -US-Tw1,12562,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Tw1,12562,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-Tw1,12562,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20120712 -US-Tw1,12562,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Tw1,12576,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Tw1,12576,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CH4 -US-Tw1,12576,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20120712 -US-Tw1,12576,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Tw1,91367,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Tw1,91367,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-Tw1,91367,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20120712 -US-Tw1,91367,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Tw1,23000518,GRP_HEADER,SITE_NAME,Twitchell Wetland West Pond -US-Tw1,88378,GRP_HEIGHTC,HEIGHTC,29 -US-Tw1,88378,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Aerenchymatous Plants -US-Tw1,88378,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Tw1,88378,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw1,88378,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,41 -US-Tw1,88378,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw1,88378,GRP_HEIGHTC,HEIGHTC_DATE,20140801 -US-Tw1,88378,GRP_HEIGHTC,HEIGHTC_COMMENT,Average: Green plants from 30cm x 30cm plots 7m to 10m apart along a transect upwind from the tower. From Sophie -US-Tw1,88380,GRP_HEIGHTC,HEIGHTC,3.43 -US-Tw1,88380,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Aerenchymatous Plants -US-Tw1,88380,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Tw1,88380,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw1,88380,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Tw1,88380,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw1,88380,GRP_HEIGHTC,HEIGHTC_DATE,20150811 -US-Tw1,88380,GRP_HEIGHTC,HEIGHTC_COMMENT,Green plants from 30cm x 30cm plots 7m to 10m apart along a transect upwind from the tower. From Sophie -US-Tw1,88381,GRP_HEIGHTC,HEIGHTC,0.23 -US-Tw1,88381,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Aerenchymatous Plants -US-Tw1,88381,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Tw1,88381,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw1,88381,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Tw1,88381,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw1,88381,GRP_HEIGHTC,HEIGHTC_DATE,20150811 -US-Tw1,88381,GRP_HEIGHTC,HEIGHTC_COMMENT,Green plants from 30cm x 30cm plots 7m to 10m apart along a transect upwind from the tower. From Sophie -US-Tw1,88377,GRP_HEIGHTC,HEIGHTC,0.291 -US-Tw1,88377,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Aerenchymatous Plants -US-Tw1,88377,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Tw1,88377,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw1,88377,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,22 -US-Tw1,88377,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw1,88377,GRP_HEIGHTC,HEIGHTC_DATE,20160808 -US-Tw1,88377,GRP_HEIGHTC,HEIGHTC_COMMENT,Green plants from 30cm x 30cm plots 7m to 10m apart along a transect upwind from the tower. From Sophie -US-Tw1,88379,GRP_HEIGHTC,HEIGHTC,3.355 -US-Tw1,88379,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Aerenchymatous Plants -US-Tw1,88379,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Tw1,88379,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw1,88379,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,22 -US-Tw1,88379,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw1,88379,GRP_HEIGHTC,HEIGHTC_DATE,20160808 -US-Tw1,88379,GRP_HEIGHTC,HEIGHTC_COMMENT,Green plants from 30cm x 30cm plots 7m to 10m apart along a transect upwind from the tower. From Sophie -US-Tw1,88382,GRP_HEIGHTC,HEIGHTC,3.064 -US-Tw1,88382,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Aerenchymatous Plants -US-Tw1,88382,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Tw1,88382,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw1,88382,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,14 -US-Tw1,88382,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw1,88382,GRP_HEIGHTC,HEIGHTC_DATE,20170719 -US-Tw1,88382,GRP_HEIGHTC,HEIGHTC_COMMENT,Green plants from 30cm x 30cm plots 7m to 10m apart along a transect upwind from the tower. From Sophie -US-Tw1,88383,GRP_HEIGHTC,HEIGHTC,0.575 -US-Tw1,88383,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Aerenchymatous Plants -US-Tw1,88383,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Tw1,88383,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw1,88383,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,14 -US-Tw1,88383,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw1,88383,GRP_HEIGHTC,HEIGHTC_DATE,20170719 -US-Tw1,88383,GRP_HEIGHTC,HEIGHTC_COMMENT,Green plants from 30cm x 30cm plots 7m to 10m apart along a transect upwind from the tower. From Sophie -US-Tw1,12563,GRP_IGBP,IGBP,WET -US-Tw1,12563,GRP_IGBP,IGBP_COMMENT,Schoenoplectus acutus and Typha spp. dominate the site -US-Tw1,12564,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-Tw1,12564,GRP_LAND_OWNERSHIP,LAND_OWNER,California Department of Water Resources -US-Tw1,91002,GRP_LOCATION,LOCATION_LAT,38.1074 -US-Tw1,91002,GRP_LOCATION,LOCATION_LONG,-121.6469 -US-Tw1,91002,GRP_LOCATION,LOCATION_ELEV,-5 -US-Tw1,91002,GRP_LOCATION,LOCATION_DATE_START,20120416 -US-Tw1,12566,GRP_NETWORK,NETWORK,AmeriFlux -US-Tw1,87014,GRP_NETWORK,NETWORK,Phenocam -US-Tw1,1700000285,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Arias‐Ortiz, A., Oikawa, P. Y., Carlin, J., Masqué, P., Shahan, J., Kanneg, S., Paytan, A., Baldocchi, D. D. (2021) Tidal And Nontidal Marsh Restoration: A Trade‐Off Between Carbon Sequestration, Methane Emissions, And Soil Accretion, Journal Of Geophysical Research: Biogeosciences, 126(12), e0248398" -US-Tw1,1700000285,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2021JG006573 -US-Tw1,1700000285,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Tw1,1700005433,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Baldocchi, D. D., Ryu, Y., Dechant, B., Eichelmann, E., Hemes, K., Ma, S., Sanchez, C. R., Shortt, R., Szutu, D., Valach, A., Verfaillie, J., Badgley, G., Zeng, Y., Berry, J. A. (2020) Outgoing Near‐Infrared Radiation From Vegetation Scales With Canopy Photosynthesis Across A Spectrum Of Function, Structure, Physiological Capacity, And Weather, Journal Of Geophysical Research: Biogeosciences, 125(7), e0248398" -US-Tw1,1700005433,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2019JG005534 -US-Tw1,1700005433,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Tw1,1700007743,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Baldocchi, D., Penuelas, J. (2018) The Physics And Ecology Of Mining Carbon Dioxide From The Atmosphere By Ecosystems, Global Change Biology, 256-257(1), 179-195" -US-Tw1,1700007743,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/GCB.14559 -US-Tw1,1700007743,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Tw1,1700002310,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Baldocchi, D., Penuelas, J. (2018) The Physics And Ecology Of Mining Carbon Dioxide From The Atmosphere By Ecosystems, Global Change Biology, 256-257(12), 179-195" -US-Tw1,1700002310,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/GCB.14559 -US-Tw1,1700002310,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Tw1,1700000243,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chamberlain, S. D., Hemes, K. S., Eichelmann, E., Szutu, D. J., Verfaillie, J. G., Baldocchi, D. D. (2019) Effect Of Drought-Induced Salinization On Wetland Methane Emissions, Gross Ecosystem Productivity, And Their Interactions, Ecosystems, 20(8), 1619-1633" -US-Tw1,1700000243,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1007/S10021-019-00430-5 -US-Tw1,1700000243,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Tw1,1700000033,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chamberlain, S. D., Verfaillie, J., Eichelmann, E., Hemes, K. S., Baldocchi, D. D. (2017) Evaluation Of Density Corrections To Methane Fluxes Measured By Open-Path Eddy Covariance Over Contrasting Landscapes, Boundary-Layer Meteorology, 237–238(1), 233-245" -US-Tw1,1700000033,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1007/S10546-017-0275-9 -US-Tw1,1700000033,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Tw1,1700007134,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chamberlain, S. D., Verfaillie, J., Eichelmann, E., Hemes, K. S., Baldocchi, D. D. (2017) Evaluation Of Density Corrections To Methane Fluxes Measured By Open-Path Eddy Covariance Over Contrasting Landscapes, Boundary-Layer Meteorology, 43(12), 6276-6284" -US-Tw1,1700007134,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1007/S10546-017-0275-9 -US-Tw1,1700007134,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Tw1,1700007782,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(8), 108350" -US-Tw1,1700007782,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -US-Tw1,1700007782,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Tw1,1700003018,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Eichelmann, E., Hemes, K. S., Knox, S. H., Oikawa, P. Y., Chamberlain, S. D., Sturtevant, C., Verfaillie, J., Baldocchi, D. D. (2018) The Effect Of Land Cover Type And Structure On Evapotranspiration From Agricultural And Wetland Sites In The Sacramento–San Joaquin River Delta, California, Agricultural And Forest Meteorology, 256-257(1), 179-195" -US-Tw1,1700003018,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2018.03.007 -US-Tw1,1700003018,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Tw1,1700003282,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Eichelmann, E., Hemes, K. S., Knox, S. H., Oikawa, P. Y., Chamberlain, S. D., Sturtevant, C., Verfaillie, J., Baldocchi, D. D. (2018) The Effect Of Land Cover Type And Structure On Evapotranspiration From Agricultural And Wetland Sites In The Sacramento–San Joaquin River Delta, California, Agricultural And Forest Meteorology, 256-257(12), 179-195" -US-Tw1,1700003282,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2018.03.007 -US-Tw1,1700003282,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Tw1,1700005514,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Hemes, K. S., Chamberlain, S. D., Eichelmann, E., Anthony, T., Valach, A., Kasak, K., Szutu, D., Verfaillie, J., Silver, W. L., Baldocchi, D. D. (2019) Assessing The Carbon And Climate Benefit Of Restoring Degraded Agricultural Peat Soils To Managed Wetlands, Agricultural And Forest Meteorology, 268(1), 202-214" -US-Tw1,1700005514,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2019.01.017 -US-Tw1,1700005514,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Tw1,1700007869,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Hemes, K. S., Chamberlain, S. D., Eichelmann, E., Anthony, T., Valach, A., Kasak, K., Szutu, D., Verfaillie, J., Silver, W. L., Baldocchi, D. D. (2019) Assessing The Carbon And Climate Benefit Of Restoring Degraded Agricultural Peat Soils To Managed Wetlands, Agricultural And Forest Meteorology, 268(12), 202-214" -US-Tw1,1700007869,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2019.01.017 -US-Tw1,1700007869,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Tw1,1700006807,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Hemes, K. S., Chamberlain, S. D., Eichelmann, E., Knox, S. H., Baldocchi, D. D. (2018) A Biogeochemical Compromise: The High Methane Cost Of Sequestering Carbon In Restored Wetlands, Geophysical Research Letters, 256-257(1), 179-195" -US-Tw1,1700006807,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018GL077747 -US-Tw1,1700006807,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Tw1,1700007995,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Hemes, K. S., Chamberlain, S. D., Eichelmann, E., Knox, S. H., Baldocchi, D. D. (2018) A Biogeochemical Compromise: The High Methane Cost Of Sequestering Carbon In Restored Wetlands, Geophysical Research Letters, 256-257(12), 179-195" -US-Tw1,1700007995,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018GL077747 -US-Tw1,1700007995,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Tw1,1700007227,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Hemes, K. S., Eichelmann, E., Chamberlain, S., Knox, S. H., Oikawa, P. Y., Sturtevant, C., Verfaillie, J., Szutu, D., Baldocchi, D. D. (2018) A Unique Combination Of Aerodynamic And Surface Properties Contribute To Surface Cooling In Restored Wetlands Of The Sacramento-San Joaquin Delta, California, Journal Of Geophysical Research: Biogeosciences, 256-257(1), 179-195" -US-Tw1,1700007227,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018JG004494 -US-Tw1,1700007227,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Tw1,1700002706,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Hemes, K. S., Eichelmann, E., Chamberlain, S., Knox, S. H., Oikawa, P. Y., Sturtevant, C., Verfaillie, J., Szutu, D., Baldocchi, D. D. (2018) A Unique Combination Of Aerodynamic And Surface Properties Contribute To Surface Cooling In Restored Wetlands Of The Sacramento-San Joaquin Delta, California, Journal Of Geophysical Research: Biogeosciences, 256-257(12), 179-195" -US-Tw1,1700002706,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018JG004494 -US-Tw1,1700002706,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Tw1,1700001698,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Hemes, K. S., Verfaillie, J., Baldocchi, D. D. (2020) Wildfire‐Smoke Aerosols Lead To Increased Light Use Efficiency Among Agricultural And Restored Wetland Land Uses In California'S Central Valley, Journal Of Geophysical Research: Biogeosciences, 20(8), 1619-1633" -US-Tw1,1700001698,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2019JG005380 -US-Tw1,1700001698,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Tw1,1700002475,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Knox, S. H.,, Sturtevant, C., Matthes, J.H., Koteen, L., Verfaillie,J., Baldocchi. D. (2014) Agricultural peatland restoration: effects of land-use change on greenhouse gas (CO2 and CH4) fluxes in the Sacramento-San Joaquin Delta, Global Change Biology, 21(), 750-765" -US-Tw1,1700002475,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/GCB.12745 -US-Tw1,1700002475,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Tw1,1700002697,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Knox, Sara Helen Dronova, Iryna Sturtevant, Cove Oikawa, Patricia Y. Matthes, Jaclyn Hatala Verfaillie, Joseph Baldocchi, Dennis (2017) Using digital camera and Landsat imagery with eddy covariance data to model gross primary production in restored wetlands, Agricultural and Forest Meteorology, 237–238(1), 233-245" -US-Tw1,1700002697,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2017.02.020 -US-Tw1,1700002697,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Tw1,1700000528,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Miller, R. L., Fram, M., Fuji, R., Wheeler, G. (2008) Subsidence Reversal In A Re-Established Wetland In The Sacramento-San Joaquin Delta, California, USA, San Francisco Estuary And Watershed Science, 6(3), n/a-n/a" -US-Tw1,1700000528,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.15447/SFEWS.2008V6ISS3ART1 -US-Tw1,1700000528,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Tw1,1700003651,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Miller, R. L., Fujii, R. (2010) Plant Community, Primary Productivity, And Environmental Conditions Following Wetland Re-Establishment In The Sacramento-San Joaquin Delta, California, Wetlands Ecology And Management, 18(1), 1-16" -US-Tw1,1700003651,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1007/S11273-009-9143-9 -US-Tw1,1700003651,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Tw1,1700002619,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Oikawa, P. Y.; Jenerette, G. D.; Knox, S. H.; Sturtevant, C.; Verfaillie, J.; Dronova, I.; Poindexter, C. M. ; Eichelmann, E.; Baldocchi, D. D. (2017) Evaluation of a hierarchy of models reveals importance of substrate limitation for predicting carbon dioxide and methane exchange in restored wetlands, Journal of Geophysical Research: Biogeosciences, 122(1), 145-167" -US-Tw1,1700002619,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/2016JG003438 -US-Tw1,1700002619,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Tw1,1700004143,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Poindexter, C. M., D. D. Baldocchi, J. H. Matthes, S. H. Knox, and E. A. Variano. (2016) The contribution of an overlooked transport process to a wetland's methane emissions., Geophysical Research Letters, 43(12), 6276-6284" -US-Tw1,1700004143,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/2016GL068782 -US-Tw1,1700004143,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Tw1,1700001407,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Poindexter, C. M., D. D. Baldocchi, J. H. Matthes, S. H. Knox, and E. A. Variano. (2016) The contribution of an overlooked transport process to a wetland's methane emissions., Geophysical Research Letters, 43(3), 6276-6284" -US-Tw1,1700001407,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/2016GL068782 -US-Tw1,1700001407,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Tw1,1700002463,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Rey‐Sanchez, C., Wharton, S., Vilà‐Guerau de Arellano, J., Paw U, K. T., Hemes, K. S., Fuentes, J. D., Osuna, J., Szutu, D., Ribeiro, J. V., Verfaillie, J., Baldocchi, D. (2021) Evaluation Of Atmospheric Boundary Layer Height From Wind Profiling Radar And Slab Models And Its Responses To Seasonality Of Land Cover, Subsidence, And Advection, Journal Of Geophysical Research: Atmospheres, 126(7), e0248398" -US-Tw1,1700002463,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2020JD033775 -US-Tw1,1700002463,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Tw1,1700003765,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Sullivan, R. C., Cook, D. R., Ghate, V. P., Kotamarthi, V. R., Feng, Y. (2019) Improved Spatiotemporal Representativeness And Bias Reduction Of Satellite-Based Evapotranspiration Retrievals Via Use Of In Situ Meteorology And Constrained Canopy Surface Resistance, Journal Of Geophysical Research: Biogeosciences, 124(2), 342-352" -US-Tw1,1700003765,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018JG004744 -US-Tw1,1700003765,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Tw1,1700007881,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Sullivan, R. C., Kotamarthi, V. R., Feng, Y. (2019) Recovering Evapotranspiration Trends From Biased CMIP5 Simulations And Sensitivity To Changing Climate Over North America, Journal Of Hydrometeorology, 20(8), 1619-1633" -US-Tw1,1700007881,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1175/JHM-D-18-0259.1 -US-Tw1,1700007881,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Tw1,1700004008,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Valach, A. C., Kasak, K., Hemes, K. S., Anthony, T. L., Dronova, I., Taddeo, S., Silver, W. L., Szutu, D., Verfaillie, J., Baldocchi, D. D. (2021) Productive Wetlands Restored For Carbon Sequestration Quickly Become Net Co2 Sinks With Site-Level Factors Driving Uptake Variability, Plos One, 16(3), e0248398" -US-Tw1,1700004008,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1371/JOURNAL.PONE.0248398 -US-Tw1,1700004008,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Tw1,1700001026,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Valach, Alex C. Kasak, Kuno Hemes, Kyle S. Szutu, Daphne Verfaillie, Joe Baldocchi, Dennis D. (2021) Carbon Flux Trajectories and Site Conditions from Restored Impounded Marshes in the Sacramento-San Joaquin Delta, Wetland Carbon and Environmental Management, 125(7), e0248398" -US-Tw1,1700001026,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/9781119639305.CH13 -US-Tw1,1700001026,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Tw1,12568,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"The research approach of the University of California, Berkeley Biometeorology Laboratory involves the coordinated use of experimental measurements and theoretical models to understand the physical, biological, and chemical processes that control trace gas fluxes between the biosphere and atmosphere and to quantify their temporal and spatial variations. The research objectives of the Mayberry Wetland, Twitchell Wetland, Sherman Island, Twitchell Island, Twitchell Alfalfa, and Twitchell Corn sites are as follows: 1) Describe differences in the fluxes of CO2, CH4, H2O, and energy between different land uses; 2) Understand the mechanisms controlling these fluxes; 3) Use ecosystem modeling to understand controls on these mechanisms under different environmental scenarios. These six sites were selected to capture a wide range of inundated conditions within the Sacramento-San Joaquin River Delta. The research focuses on the eddy covariance technique to measure CH4, CO2, H2O, and energy fluxes and works to combine measurements of both net fluxes and partitioned fluxes in order to achieve a mechanistic understanding of the ecological controls on current and future carbon flux in the Delta." -US-Tw1,12569,GRP_SITE_CHAR,TERRAIN,Flat -US-Tw1,12569,GRP_SITE_CHAR,ASPECT,FLAT -US-Tw1,12569,GRP_SITE_CHAR,WIND_DIRECTION,W -US-Tw1,12569,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,310 -US-Tw1,12569,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,0 -US-Tw1,12570,GRP_SITE_DESC,SITE_DESC,"The Twitchell Wetland site is a 7.4-acre restored wetland on Twitchell Island, that is managed by the California Department of Water Resources (DWR) and the U.S. Geological Survey (USGS). In the fall of 1997, the site was permanently flooded to a depth of approximately 25 cm. The wetland was almost completely covered by cattails and -tules by the third growing season. A flux tower equipped to analyze energy, H2O, CO2, and CH4 fluxes was installed on May 17, 2012." -US-Tw1,12571,GRP_SITE_FUNDING,SITE_FUNDING,California Department of Water Resources -US-Tw1,12572,GRP_STATE,STATE,CA -US-Tw1,12582,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Dennis Baldocchi -US-Tw1,12582,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Tw1,12582,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,baldocchi@berkeley.edu -US-Tw1,12582,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"University of California, Berkeley" -US-Tw1,12582,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Department of Environmental Science, Policy and Management, 130 Mulford Hall,Berkeley, CA USA 94720-3110" -US-Tw1,12583,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Joe Verfaillie -US-Tw1,12583,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,AncContact -US-Tw1,12583,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,jverfail@berkeley.edu -US-Tw1,12583,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"University of California, Berkeley" -US-Tw1,95204,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Robert Shortt -US-Tw1,95204,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-Tw1,95204,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,robert_shortt@berkeley.edu -US-Tw1,95204,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"University of California, Berkeley" -US-Tw1,30340,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Daphne Szutu -US-Tw1,30340,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Technician -US-Tw1,30340,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,daphneszutu@berkeley.edu -US-Tw1,30340,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,UC Berkeley -US-Tw1,12574,GRP_URL,URL,http://nature.berkeley.edu/biometlab/sites.php?tab=US-Tw1 -US-Tw1,24000518,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-Tw1 -US-Tw1,12575,GRP_UTC_OFFSET,UTC_OFFSET,-8 -US-Tw2,11264,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,"Biometeorology Lab, University of California, Berkeley, PI: Dennis Baldocchi" -US-Tw2,11265,GRP_CLIM_AVG,MAT,15.5 -US-Tw2,11265,GRP_CLIM_AVG,MAP,421 -US-Tw2,11265,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Csa -US-Tw2,27000519,GRP_COUNTRY,COUNTRY,USA -US-Tw2,15617,GRP_DOI,DOI,10.17190/AMF/1246148 -US-Tw2,15617,GRP_DOI,DOI_CITATION,"Cove Sturtevant, Joseph Verfaillie, Dennis Baldocchi (2019), AmeriFlux BASE US-Tw2 Twitchell Corn, Ver. 2-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1246148" -US-Tw2,15617,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-Tw2,94030,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Tw2,94030,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Cove Sturtevant -US-Tw2,94030,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Tw2,94030,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,1 -US-Tw2,94030,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0002-0341-3228 -US-Tw2,94030,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,csturtevant@battelleecology.org -US-Tw2,94030,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"University of California, Berkeley" -US-Tw2,94030,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,20120521 -US-Tw2,94030,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_END,20131125 -US-Tw2,94113,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Tw2,94113,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Joseph Verfaillie -US-Tw2,94113,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Tw2,94113,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,2 -US-Tw2,94113,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0002-7009-8942 -US-Tw2,94113,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,jverfail@berkeley.edu -US-Tw2,94113,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"University of California, Berkeley" -US-Tw2,94113,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,20120521 -US-Tw2,94113,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_END,20131125 -US-Tw2,94111,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Tw2,94111,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Dennis Baldocchi -US-Tw2,94111,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Tw2,94111,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,3 -US-Tw2,94111,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0003-3496-4919 -US-Tw2,94111,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,baldocchi@berkeley.edu -US-Tw2,94111,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"University of California, Berkeley" -US-Tw2,94111,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,20120521 -US-Tw2,94111,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_END,20131125 -US-Tw2,32375,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,"University of California, Berkeley" -US-Tw2,32375,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-Tw2,32374,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,California Department of Water Resources -US-Tw2,32374,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-Tw2,29996,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Agriculture -US-Tw2,11266,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Tw2,11266,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-Tw2,11266,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20120522 -US-Tw2,11266,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20130525 -US-Tw2,11266,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Tw2,91328,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Tw2,91328,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-Tw2,91328,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20120522 -US-Tw2,91328,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20130525 -US-Tw2,91328,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Tw2,23000519,GRP_HEADER,SITE_NAME,Twitchell Corn -US-Tw2,88391,GRP_HEIGHTC,HEIGHTC,0.25 -US-Tw2,88391,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Tw2,88391,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Tw2,88391,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw2,88391,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,5 -US-Tw2,88391,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw2,88391,GRP_HEIGHTC,HEIGHTC_DATE,20120621 -US-Tw2,88391,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured from clip plot sampled for biomass and LAI/PAI. -US-Tw2,88399,GRP_HEIGHTC,HEIGHTC,0.22 -US-Tw2,88399,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Tw2,88399,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Tw2,88399,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw2,88399,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,5 -US-Tw2,88399,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw2,88399,GRP_HEIGHTC,HEIGHTC_DATE,20120629 -US-Tw2,88399,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured from clip plot sampled for biomass and LAI/PAI. -US-Tw2,88401,GRP_HEIGHTC,HEIGHTC,0.39 -US-Tw2,88401,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Tw2,88401,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Tw2,88401,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw2,88401,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,5 -US-Tw2,88401,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw2,88401,GRP_HEIGHTC,HEIGHTC_DATE,20120629 -US-Tw2,88401,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured from clip plot sampled for biomass and LAI/PAI. -US-Tw2,88384,GRP_HEIGHTC,HEIGHTC,0.23 -US-Tw2,88384,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Tw2,88384,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Tw2,88384,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw2,88384,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,5 -US-Tw2,88384,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw2,88384,GRP_HEIGHTC,HEIGHTC_DATE,20120705 -US-Tw2,88384,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured from clip plot sampled for biomass and LAI/PAI. -US-Tw2,88407,GRP_HEIGHTC,HEIGHTC,0.44 -US-Tw2,88407,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Tw2,88407,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Tw2,88407,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw2,88407,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,5 -US-Tw2,88407,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw2,88407,GRP_HEIGHTC,HEIGHTC_DATE,20120705 -US-Tw2,88407,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured from clip plot sampled for biomass and LAI/PAI. -US-Tw2,88395,GRP_HEIGHTC,HEIGHTC,0.87 -US-Tw2,88395,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Tw2,88395,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Tw2,88395,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw2,88395,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,5 -US-Tw2,88395,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw2,88395,GRP_HEIGHTC,HEIGHTC_DATE,20120712 -US-Tw2,88395,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured from clip plot sampled for biomass and LAI/PAI. -US-Tw2,88403,GRP_HEIGHTC,HEIGHTC,0.27 -US-Tw2,88403,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Tw2,88403,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Tw2,88403,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw2,88403,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,5 -US-Tw2,88403,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw2,88403,GRP_HEIGHTC,HEIGHTC_DATE,20120712 -US-Tw2,88403,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured from clip plot sampled for biomass and LAI/PAI. -US-Tw2,88397,GRP_HEIGHTC,HEIGHTC,1.08 -US-Tw2,88397,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Tw2,88397,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Tw2,88397,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw2,88397,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,5 -US-Tw2,88397,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw2,88397,GRP_HEIGHTC,HEIGHTC_DATE,20120719 -US-Tw2,88397,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured from clip plot sampled for biomass and LAI/PAI. -US-Tw2,88408,GRP_HEIGHTC,HEIGHTC,0.34 -US-Tw2,88408,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Tw2,88408,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Tw2,88408,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw2,88408,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,5 -US-Tw2,88408,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw2,88408,GRP_HEIGHTC,HEIGHTC_DATE,20120719 -US-Tw2,88408,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured from clip plot sampled for biomass and LAI/PAI. -US-Tw2,88392,GRP_HEIGHTC,HEIGHTC,0.41 -US-Tw2,88392,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Tw2,88392,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Tw2,88392,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw2,88392,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,5 -US-Tw2,88392,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw2,88392,GRP_HEIGHTC,HEIGHTC_DATE,20120726 -US-Tw2,88392,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured from clip plot sampled for biomass and LAI/PAI. -US-Tw2,88398,GRP_HEIGHTC,HEIGHTC,1.5 -US-Tw2,88398,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Tw2,88398,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Tw2,88398,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw2,88398,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,5 -US-Tw2,88398,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw2,88398,GRP_HEIGHTC,HEIGHTC_DATE,20120726 -US-Tw2,88398,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured from clip plot sampled for biomass and LAI/PAI. -US-Tw2,88394,GRP_HEIGHTC,HEIGHTC,0.51 -US-Tw2,88394,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Tw2,88394,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Tw2,88394,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw2,88394,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,5 -US-Tw2,88394,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw2,88394,GRP_HEIGHTC,HEIGHTC_DATE,20120802 -US-Tw2,88394,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured from clip plot sampled for biomass and LAI/PAI. -US-Tw2,88406,GRP_HEIGHTC,HEIGHTC,1.8 -US-Tw2,88406,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Tw2,88406,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Tw2,88406,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw2,88406,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,5 -US-Tw2,88406,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw2,88406,GRP_HEIGHTC,HEIGHTC_DATE,20120802 -US-Tw2,88406,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured from clip plot sampled for biomass and LAI/PAI. -US-Tw2,88387,GRP_HEIGHTC,HEIGHTC,0.22 -US-Tw2,88387,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Tw2,88387,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Tw2,88387,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw2,88387,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,5 -US-Tw2,88387,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw2,88387,GRP_HEIGHTC,HEIGHTC_DATE,20120809 -US-Tw2,88387,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured from clip plot sampled for biomass and LAI/PAI. -US-Tw2,88388,GRP_HEIGHTC,HEIGHTC,2.38 -US-Tw2,88388,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Tw2,88388,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Tw2,88388,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw2,88388,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,5 -US-Tw2,88388,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw2,88388,GRP_HEIGHTC,HEIGHTC_DATE,20120809 -US-Tw2,88388,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured from clip plot sampled for biomass and LAI/PAI. -US-Tw2,88393,GRP_HEIGHTC,HEIGHTC,0.39 -US-Tw2,88393,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Tw2,88393,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Tw2,88393,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw2,88393,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,5 -US-Tw2,88393,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw2,88393,GRP_HEIGHTC,HEIGHTC_DATE,20120816 -US-Tw2,88393,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured from clip plot sampled for biomass and LAI/PAI. -US-Tw2,88404,GRP_HEIGHTC,HEIGHTC,2.62 -US-Tw2,88404,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Tw2,88404,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Tw2,88404,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw2,88404,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,5 -US-Tw2,88404,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw2,88404,GRP_HEIGHTC,HEIGHTC_DATE,20120816 -US-Tw2,88404,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured from clip plot sampled for biomass and LAI/PAI. -US-Tw2,88389,GRP_HEIGHTC,HEIGHTC,0.08 -US-Tw2,88389,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Tw2,88389,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Tw2,88389,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw2,88389,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,5 -US-Tw2,88389,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw2,88389,GRP_HEIGHTC,HEIGHTC_DATE,20120823 -US-Tw2,88389,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured from clip plot sampled for biomass and LAI/PAI. -US-Tw2,88390,GRP_HEIGHTC,HEIGHTC,2.73 -US-Tw2,88390,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Tw2,88390,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Tw2,88390,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw2,88390,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,5 -US-Tw2,88390,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw2,88390,GRP_HEIGHTC,HEIGHTC_DATE,20120823 -US-Tw2,88390,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured from clip plot sampled for biomass and LAI/PAI. -US-Tw2,88386,GRP_HEIGHTC,HEIGHTC,2.57 -US-Tw2,88386,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Tw2,88386,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Tw2,88386,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw2,88386,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,5 -US-Tw2,88386,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw2,88386,GRP_HEIGHTC,HEIGHTC_DATE,20120830 -US-Tw2,88386,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured from clip plot sampled for biomass and LAI/PAI. -US-Tw2,88400,GRP_HEIGHTC,HEIGHTC,0.27 -US-Tw2,88400,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Tw2,88400,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Tw2,88400,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw2,88400,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,5 -US-Tw2,88400,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw2,88400,GRP_HEIGHTC,HEIGHTC_DATE,20120830 -US-Tw2,88400,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured from clip plot sampled for biomass and LAI/PAI. -US-Tw2,88385,GRP_HEIGHTC,HEIGHTC,2.76 -US-Tw2,88385,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Tw2,88385,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Tw2,88385,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw2,88385,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,5 -US-Tw2,88385,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw2,88385,GRP_HEIGHTC,HEIGHTC_DATE,20120913 -US-Tw2,88385,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured from clip plot sampled for biomass and LAI/PAI. -US-Tw2,88396,GRP_HEIGHTC,HEIGHTC,0.21 -US-Tw2,88396,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Tw2,88396,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Tw2,88396,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw2,88396,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,5 -US-Tw2,88396,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw2,88396,GRP_HEIGHTC,HEIGHTC_DATE,20120913 -US-Tw2,88396,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured from clip plot sampled for biomass and LAI/PAI. -US-Tw2,88402,GRP_HEIGHTC,HEIGHTC,2.53 -US-Tw2,88402,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Tw2,88402,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Tw2,88402,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw2,88402,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,5 -US-Tw2,88402,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw2,88402,GRP_HEIGHTC,HEIGHTC_DATE,20120927 -US-Tw2,88402,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured from clip plot sampled for biomass and LAI/PAI. -US-Tw2,88405,GRP_HEIGHTC,HEIGHTC,0.26 -US-Tw2,88405,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Tw2,88405,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Tw2,88405,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw2,88405,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,5 -US-Tw2,88405,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw2,88405,GRP_HEIGHTC,HEIGHTC_DATE,20120927 -US-Tw2,88405,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured from clip plot sampled for biomass and LAI/PAI. -US-Tw2,11267,GRP_IGBP,IGBP,CRO -US-Tw2,11268,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-Tw2,11268,GRP_LAND_OWNERSHIP,LAND_OWNER,California Department of Water Resources -US-Tw2,90997,GRP_LOCATION,LOCATION_LAT,38.1047 -US-Tw2,90997,GRP_LOCATION,LOCATION_LONG,-121.6433 -US-Tw2,90997,GRP_LOCATION,LOCATION_ELEV,-5 -US-Tw2,90997,GRP_LOCATION,LOCATION_DATE_START,20120521 -US-Tw2,101125,GRP_LOCATION,LOCATION_LAT,38.0969 -US-Tw2,101125,GRP_LOCATION,LOCATION_LONG,-121.6365 -US-Tw2,101125,GRP_LOCATION,LOCATION_ELEV,-5 -US-Tw2,101125,GRP_LOCATION,LOCATION_DATE_START,20130509 -US-Tw2,101125,GRP_LOCATION,LOCATION_COMMENT,The Tower was moved 540m ESE to avoid earth moving equipment as the corn fields were converted to wetland. -US-Tw2,11270,GRP_NETWORK,NETWORK,AmeriFlux -US-Tw2,1700007422,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Baldocchi, D., Penuelas, J. (2018) The Physics And Ecology Of Mining Carbon Dioxide From The Atmosphere By Ecosystems, Global Change Biology, 21(), 750-765" -US-Tw2,1700007422,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/GCB.14559 -US-Tw2,1700007422,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Tw2,1700004806,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Baldocchi, D., Penuelas, J. (2018) The Physics And Ecology Of Mining Carbon Dioxide From The Atmosphere By Ecosystems, Global Change Biology, 301-302(8), 108350" -US-Tw2,1700004806,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/GCB.14559 -US-Tw2,1700004806,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Tw2,1700000726,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(8), 108350" -US-Tw2,1700000726,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -US-Tw2,1700000726,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Tw2,1700008139,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Hemes, K. S., Chamberlain, S. D., Eichelmann, E., Anthony, T., Valach, A., Kasak, K., Szutu, D., Verfaillie, J., Silver, W. L., Baldocchi, D. D. (2019) Assessing The Carbon And Climate Benefit Of Restoring Degraded Agricultural Peat Soils To Managed Wetlands, Agricultural And Forest Meteorology, 268(), 202-214" -US-Tw2,1700008139,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2019.01.017 -US-Tw2,1700008139,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Tw2,1700001461,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Hemes, K. S., Chamberlain, S. D., Eichelmann, E., Anthony, T., Valach, A., Kasak, K., Szutu, D., Verfaillie, J., Silver, W. L., Baldocchi, D. D. (2019) Assessing The Carbon And Climate Benefit Of Restoring Degraded Agricultural Peat Soils To Managed Wetlands, Agricultural And Forest Meteorology, 268(8), 202-214" -US-Tw2,1700001461,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2019.01.017 -US-Tw2,1700001461,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Tw2,1700008829,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Knox, S. H.,, Sturtevant, C., Matthes, J.H., Koteen, L., Verfaillie,J., Baldocchi. D. (2014) Agricultural peatland restoration: effects of land-use change on greenhouse gas (CO2 and CH4) fluxes in the Sacramento-San Joaquin Delta, Global Change Biology, 21(), 750-765" -US-Tw2,1700008829,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/GCB.12745 -US-Tw2,1700008829,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Tw2,1700001422,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Sullivan, R. C., Cook, D. R., Ghate, V. P., Kotamarthi, V. R., Feng, Y. (2019) Improved Spatiotemporal Representativeness And Bias Reduction Of Satellite-Based Evapotranspiration Retrievals Via Use Of In Situ Meteorology And Constrained Canopy Surface Resistance, Journal Of Geophysical Research: Biogeosciences, 124(2), 342-352" -US-Tw2,1700001422,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018JG004744 -US-Tw2,1700001422,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Tw2,1700003597,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Sullivan, R. C., Kotamarthi, V. R., Feng, Y. (2019) Recovering Evapotranspiration Trends From Biased CMIP5 Simulations And Sensitivity To Changing Climate Over North America, Journal Of Hydrometeorology, 20(8), 1619-1633" -US-Tw2,1700003597,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1175/JHM-D-18-0259.1 -US-Tw2,1700003597,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Tw2,11271,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"The research approach of the University of California, Berkeley Biometeorology Laboratory involves the coordinated use of experimental measurements and theoretical models to understand the physical, biological, and chemical processes that control trace gas fluxes between the biosphere and atmosphere and to quantify their temporal and spatial variations. The research objectives of the Mayberry Wetland, Twitchell Wetland, Sherman Island, Twitchell Island, Twitchell Alfalfa, and Twitchell Corn sites are as follows: 1) Describe differences in the fluxes of CO2, CH4, H2O, and energy between different land uses; 2) Understand the mechanisms controlling these fluxes; 3) Use ecosystem modeling to understand controls on these mechanisms under different environmental scenarios. These six sites were selected to capture a wide range of inundated conditions within the Sacramento-San Joaquin River Delta. The research focuses on the eddy covariance technique to measure CH4, CO2, H2O, and energy fluxes and works to combine measurements of both net fluxes and partitioned fluxes in order to achieve a mechanistic understanding of the ecological controls on current and future carbon flux in the Delta." -US-Tw2,11272,GRP_SITE_CHAR,TERRAIN,Flat -US-Tw2,11272,GRP_SITE_CHAR,ASPECT,FLAT -US-Tw2,11272,GRP_SITE_CHAR,WIND_DIRECTION,W -US-Tw2,11272,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,630 -US-Tw2,11272,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,0 -US-Tw2,101124,GRP_SITE_DESC,SITE_DESC,"The Twitchell Corn site is a corn field on peat soil. The tower was installed on May 17, 2012 and was equipped to analyze energy, H2O and CO2 fluxes. The field was planted in early May 2012 and harvested in early November 2012. The field was fallow during the non-growing season. The variety of corn used was ES-7477 hybrid corn commercialized by Eureka seeds. Beginning 2013-05-09 this site was converted to wetland. The tower was moved 540m ESE to avoid earth moving in the construction. The site is near US-Tw1, US-Tw3 and US-Twt sites." -US-Tw2,11274,GRP_SITE_FUNDING,SITE_FUNDING,California Department of Water Resources -US-Tw2,11275,GRP_STATE,STATE,CA -US-Tw2,11276,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Dennis Baldocchi -US-Tw2,11276,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Tw2,11276,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,baldocchi@berkeley.edu -US-Tw2,11276,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"University of California, Berkeley" -US-Tw2,11276,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Department of Environmental Science, Policy and Management, 130 Mulford Hall,Berkeley, CA USA 94720-3110" -US-Tw2,11280,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Joe Verfaillie -US-Tw2,11280,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,AncContact -US-Tw2,11280,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,jverfail@berkeley.edu -US-Tw2,11280,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"University of California, Berkeley" -US-Tw2,11280,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Department of Environmental Science, Policy and Management, 130 Mulford Hall,Berkeley, CA USA 94720-3110" -US-Tw2,11282,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Cove Sturtevant -US-Tw2,11282,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Affiliate -US-Tw2,11282,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,csturtevant@berkeley.edu -US-Tw2,11282,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"University of California, Berkeley" -US-Tw2,11282,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Department of Environmental Science, Policy and Management, 130 Mulford Hall,Berkeley, CA USA 94720-3110" -US-Tw2,11281,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Laurie Koteen -US-Tw2,11281,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Affiliate -US-Tw2,11281,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,lkoteen@berkeley.edu -US-Tw2,11281,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"University of California, Berkeley" -US-Tw2,11281,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Department of Environmental Science, Policy and Management, 130 Mulford Hall,Berkeley, CA USA 94720-3110" -US-Tw2,11279,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Sara Knox -US-Tw2,11279,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Affiliate -US-Tw2,11279,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,saraknox@berkeley.edu -US-Tw2,11279,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"University of California, Berkeley" -US-Tw2,11279,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Department of Environmental Science, Policy and Management, 130 Mulford Hall,Berkeley, CA USA 94720-3110" -US-Tw2,29994,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-Tw2,29995,GRP_TOWER_TYPE,TOWER_TYPE,walk-up -US-Tw2,11277,GRP_URL,URL,http://nature.berkeley.edu/biometlab/sites.php?tab=US-Tw2 -US-Tw2,24000519,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-Tw2 -US-Tw2,11278,GRP_UTC_OFFSET,UTC_OFFSET,-8 -US-Tw3,15352,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,"California Department of Water Resources, DOE AmeriFlux; Biometeorology Lab, University of California, Berkeley, PI: Dennis Baldocchi" -US-Tw3,11284,GRP_CLIM_AVG,MAT,15.6 -US-Tw3,11284,GRP_CLIM_AVG,MAP,421 -US-Tw3,11284,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Csa -US-Tw3,27000520,GRP_COUNTRY,COUNTRY,USA -US-Tw3,15645,GRP_DOI,DOI,10.17190/AMF/1246149 -US-Tw3,15645,GRP_DOI,DOI_CITATION,"Samuel D Chamberlain, Patty Oikawa, Cove Sturtevant, Daphne Szutu, Joseph Verfaillie, Dennis Baldocchi (2018), AmeriFlux BASE US-Tw3 Twitchell Alfalfa, Ver. 5-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1246149" -US-Tw3,15645,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-Tw3,94073,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Tw3,94073,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Samuel D Chamberlain -US-Tw3,94073,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Tw3,94073,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,1 -US-Tw3,94073,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0002-5570-764X -US-Tw3,94073,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,sam.d.chamberlain@gmail.com -US-Tw3,94073,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"University of California, Berkeley" -US-Tw3,94073,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,20161031 -US-Tw3,94073,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_END,20180613 -US-Tw3,94095,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Tw3,94095,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Patty Oikawa -US-Tw3,94095,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Tw3,94095,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,2 -US-Tw3,94095,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0001-7852-4435 -US-Tw3,94095,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,patty.oikawa@csueastbay.edu -US-Tw3,94095,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"University of California, Berkeley" -US-Tw3,94095,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,20150818 -US-Tw3,94095,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_END,20161031 -US-Tw3,94048,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Tw3,94048,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Cove Sturtevant -US-Tw3,94048,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Tw3,94048,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,3 -US-Tw3,94048,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0002-0341-3228 -US-Tw3,94048,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,csturtevant@battelleecology.org -US-Tw3,94048,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"University of California, Berkeley" -US-Tw3,94048,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,20130524 -US-Tw3,94048,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_END,20150712 -US-Tw3,94107,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Tw3,94107,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Daphne Szutu -US-Tw3,94107,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Tw3,94107,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,4 -US-Tw3,94107,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0001-7698-0461 -US-Tw3,94107,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,daphneszutu@berkeley.edu -US-Tw3,94107,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"University of California, Berkeley" -US-Tw3,94107,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,201612 -US-Tw3,94107,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_END,20180613 -US-Tw3,94020,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Tw3,94020,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Joseph Verfaillie -US-Tw3,94020,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Tw3,94020,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,8 -US-Tw3,94020,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0002-7009-8942 -US-Tw3,94020,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,jverfail@berkeley.edu -US-Tw3,94020,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"University of California, Berkeley" -US-Tw3,94020,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,20130524 -US-Tw3,94020,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_END,20180613 -US-Tw3,94032,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Tw3,94032,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Dennis Baldocchi -US-Tw3,94032,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Tw3,94032,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,9 -US-Tw3,94032,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0003-3496-4919 -US-Tw3,94032,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,baldocchi@berkeley.edu -US-Tw3,94032,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"University of California, Berkeley" -US-Tw3,94032,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,20130524 -US-Tw3,94032,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_END,20180613 -US-Tw3,32378,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,"University of California, Berkeley" -US-Tw3,32378,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-Tw3,32377,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,California Department of Water Resources -US-Tw3,32377,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-Tw3,22207,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Agriculture -US-Tw3,91331,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Tw3,91331,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-Tw3,91331,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20130524 -US-Tw3,91331,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20180605 -US-Tw3,91331,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Tw3,91378,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Tw3,91378,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CH4 -US-Tw3,91378,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20130828 -US-Tw3,91378,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20180605 -US-Tw3,91378,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Tw3,91348,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Tw3,91348,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-Tw3,91348,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20131125 -US-Tw3,91348,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20180605 -US-Tw3,91348,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Tw3,23000520,GRP_HEADER,SITE_NAME,Twitchell Alfalfa -US-Tw3,88410,GRP_HEIGHTC,HEIGHTC,0.145 -US-Tw3,88410,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88410,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Tw3,88410,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88410,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,15 -US-Tw3,88410,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88410,GRP_HEIGHTC,HEIGHTC_DATE,20130911 -US-Tw3,88409,GRP_HEIGHTC,HEIGHTC,0.211 -US-Tw3,88409,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88409,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Tw3,88409,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88409,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Tw3,88409,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88409,GRP_HEIGHTC,HEIGHTC_DATE,20131016 -US-Tw3,88411,GRP_HEIGHTC,HEIGHTC,0.099 -US-Tw3,88411,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88411,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Tw3,88411,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88411,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Tw3,88411,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88411,GRP_HEIGHTC,HEIGHTC_DATE,20131016 -US-Tw3,88412,GRP_HEIGHTC,HEIGHTC,0.194 -US-Tw3,88412,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88412,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Tw3,88412,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88412,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Tw3,88412,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88412,GRP_HEIGHTC,HEIGHTC_DATE,20131106 -US-Tw3,88413,GRP_HEIGHTC,HEIGHTC,0.107 -US-Tw3,88413,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88413,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Tw3,88413,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88413,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Tw3,88413,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88413,GRP_HEIGHTC,HEIGHTC_DATE,20131106 -US-Tw3,88414,GRP_HEIGHTC,HEIGHTC,0.167 -US-Tw3,88414,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88414,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Tw3,88414,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88414,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Tw3,88414,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88414,GRP_HEIGHTC,HEIGHTC_DATE,20140313 -US-Tw3,88415,GRP_HEIGHTC,HEIGHTC,0.029 -US-Tw3,88415,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88415,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Tw3,88415,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88415,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Tw3,88415,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88415,GRP_HEIGHTC,HEIGHTC_DATE,20140313 -US-Tw3,88416,GRP_HEIGHTC,HEIGHTC,0.317 -US-Tw3,88416,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88416,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Tw3,88416,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88416,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Tw3,88416,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88416,GRP_HEIGHTC,HEIGHTC_DATE,20140327 -US-Tw3,88417,GRP_HEIGHTC,HEIGHTC,0.071 -US-Tw3,88417,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88417,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Tw3,88417,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88417,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Tw3,88417,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88417,GRP_HEIGHTC,HEIGHTC_DATE,20140327 -US-Tw3,88418,GRP_HEIGHTC,HEIGHTC,0.364 -US-Tw3,88418,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88418,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Tw3,88418,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88418,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Tw3,88418,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88418,GRP_HEIGHTC,HEIGHTC_DATE,20140403 -US-Tw3,88419,GRP_HEIGHTC,HEIGHTC,0.054 -US-Tw3,88419,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88419,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Tw3,88419,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88419,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Tw3,88419,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88419,GRP_HEIGHTC,HEIGHTC_DATE,20140403 -US-Tw3,88420,GRP_HEIGHTC,HEIGHTC,0.486 -US-Tw3,88420,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88420,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Tw3,88420,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88420,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Tw3,88420,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88420,GRP_HEIGHTC,HEIGHTC_DATE,20140417 -US-Tw3,88421,GRP_HEIGHTC,HEIGHTC,0.068 -US-Tw3,88421,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88421,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Tw3,88421,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88421,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Tw3,88421,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88421,GRP_HEIGHTC,HEIGHTC_DATE,20140417 -US-Tw3,88422,GRP_HEIGHTC,HEIGHTC,0.532 -US-Tw3,88422,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88422,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Tw3,88422,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88422,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Tw3,88422,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88422,GRP_HEIGHTC,HEIGHTC_DATE,20140501 -US-Tw3,88423,GRP_HEIGHTC,HEIGHTC,0.082 -US-Tw3,88423,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88423,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Tw3,88423,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88423,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Tw3,88423,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88423,GRP_HEIGHTC,HEIGHTC_DATE,20140501 -US-Tw3,88424,GRP_HEIGHTC,HEIGHTC,0.05 -US-Tw3,88424,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88424,GRP_HEIGHTC,HEIGHTC_STATISTIC,Expert estimate -US-Tw3,88424,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88424,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,1 -US-Tw3,88424,GRP_HEIGHTC,HEIGHTC_APPROACH,Visual estimate -US-Tw3,88424,GRP_HEIGHTC,HEIGHTC_DATE,20140514 -US-Tw3,88424,GRP_HEIGHTC,HEIGHTC_COMMENT,Too short to measure -- just clipped -US-Tw3,88425,GRP_HEIGHTC,HEIGHTC,0.268 -US-Tw3,88425,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88425,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Tw3,88425,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88425,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Tw3,88425,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88425,GRP_HEIGHTC,HEIGHTC_DATE,20140521 -US-Tw3,88426,GRP_HEIGHTC,HEIGHTC,0.058 -US-Tw3,88426,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88426,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Tw3,88426,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88426,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Tw3,88426,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88426,GRP_HEIGHTC,HEIGHTC_DATE,20140521 -US-Tw3,88427,GRP_HEIGHTC,HEIGHTC,0.403 -US-Tw3,88427,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88427,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Tw3,88427,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88427,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Tw3,88427,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88427,GRP_HEIGHTC,HEIGHTC_DATE,20140529 -US-Tw3,88428,GRP_HEIGHTC,HEIGHTC,0.078 -US-Tw3,88428,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88428,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Tw3,88428,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88428,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Tw3,88428,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88428,GRP_HEIGHTC,HEIGHTC_DATE,20140529 -US-Tw3,88429,GRP_HEIGHTC,HEIGHTC,0.524 -US-Tw3,88429,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88429,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Tw3,88429,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88429,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Tw3,88429,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88429,GRP_HEIGHTC,HEIGHTC_DATE,20140605 -US-Tw3,88430,GRP_HEIGHTC,HEIGHTC,0.119 -US-Tw3,88430,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88430,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Tw3,88430,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88430,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Tw3,88430,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88430,GRP_HEIGHTC,HEIGHTC_DATE,20140605 -US-Tw3,88431,GRP_HEIGHTC,HEIGHTC,0.597 -US-Tw3,88431,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88431,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Tw3,88431,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88431,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Tw3,88431,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88431,GRP_HEIGHTC,HEIGHTC_DATE,20140612 -US-Tw3,88432,GRP_HEIGHTC,HEIGHTC,0.103 -US-Tw3,88432,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88432,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Tw3,88432,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88432,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Tw3,88432,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88432,GRP_HEIGHTC,HEIGHTC_DATE,20140612 -US-Tw3,88433,GRP_HEIGHTC,HEIGHTC,0.053 -US-Tw3,88433,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88433,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Tw3,88433,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88433,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Tw3,88433,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88433,GRP_HEIGHTC,HEIGHTC_DATE,20140617 -US-Tw3,88433,GRP_HEIGHTC,HEIGHTC_COMMENT,Just cut -US-Tw3,88434,GRP_HEIGHTC,HEIGHTC,0.04 -US-Tw3,88434,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88434,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Tw3,88434,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88434,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Tw3,88434,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88434,GRP_HEIGHTC,HEIGHTC_DATE,20140617 -US-Tw3,88434,GRP_HEIGHTC,HEIGHTC_COMMENT,Just cut -US-Tw3,88435,GRP_HEIGHTC,HEIGHTC,0.194 -US-Tw3,88435,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88435,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Tw3,88435,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88435,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Tw3,88435,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88435,GRP_HEIGHTC,HEIGHTC_DATE,20140626 -US-Tw3,88435,GRP_HEIGHTC,HEIGHTC_COMMENT,Bailed since last week -US-Tw3,88436,GRP_HEIGHTC,HEIGHTC,0.047 -US-Tw3,88436,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88436,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Tw3,88436,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88436,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Tw3,88436,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88436,GRP_HEIGHTC,HEIGHTC_DATE,20140626 -US-Tw3,88436,GRP_HEIGHTC,HEIGHTC_COMMENT,Bailed since last week -US-Tw3,88437,GRP_HEIGHTC,HEIGHTC,0.295 -US-Tw3,88437,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88437,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Tw3,88437,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88437,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Tw3,88437,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88437,GRP_HEIGHTC,HEIGHTC_DATE,20140702 -US-Tw3,88438,GRP_HEIGHTC,HEIGHTC,0.079 -US-Tw3,88438,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88438,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Tw3,88438,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88438,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Tw3,88438,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88438,GRP_HEIGHTC,HEIGHTC_DATE,20140702 -US-Tw3,88439,GRP_HEIGHTC,HEIGHTC,0.483 -US-Tw3,88439,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88439,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Tw3,88439,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88439,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,18 -US-Tw3,88439,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88439,GRP_HEIGHTC,HEIGHTC_DATE,20140708 -US-Tw3,88440,GRP_HEIGHTC,HEIGHTC,0.082 -US-Tw3,88440,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88440,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Tw3,88440,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88440,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,18 -US-Tw3,88440,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88440,GRP_HEIGHTC,HEIGHTC_DATE,20140708 -US-Tw3,88441,GRP_HEIGHTC,HEIGHTC,0.551 -US-Tw3,88441,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88441,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Tw3,88441,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88441,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Tw3,88441,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88441,GRP_HEIGHTC,HEIGHTC_DATE,20140715 -US-Tw3,88441,GRP_HEIGHTC,HEIGHTC_COMMENT,Flowering -US-Tw3,88442,GRP_HEIGHTC,HEIGHTC,0.083 -US-Tw3,88442,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88442,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Tw3,88442,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88442,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Tw3,88442,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88442,GRP_HEIGHTC,HEIGHTC_DATE,20140715 -US-Tw3,88442,GRP_HEIGHTC,HEIGHTC_COMMENT,Flowering -US-Tw3,88443,GRP_HEIGHTC,HEIGHTC,0.05 -US-Tw3,88443,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88443,GRP_HEIGHTC,HEIGHTC_STATISTIC,Expert estimate -US-Tw3,88443,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88443,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,1 -US-Tw3,88443,GRP_HEIGHTC,HEIGHTC_APPROACH,Visual estimate -US-Tw3,88443,GRP_HEIGHTC,HEIGHTC_DATE,20140731 -US-Tw3,88443,GRP_HEIGHTC,HEIGHTC_COMMENT,Just cut -US-Tw3,88444,GRP_HEIGHTC,HEIGHTC,0.153 -US-Tw3,88444,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88444,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Tw3,88444,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88444,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Tw3,88444,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88444,GRP_HEIGHTC,HEIGHTC_DATE,20140807 -US-Tw3,88445,GRP_HEIGHTC,HEIGHTC,0.052 -US-Tw3,88445,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88445,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Tw3,88445,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88445,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Tw3,88445,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88445,GRP_HEIGHTC,HEIGHTC_DATE,20140807 -US-Tw3,88446,GRP_HEIGHTC,HEIGHTC,0.247 -US-Tw3,88446,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88446,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Tw3,88446,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88446,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Tw3,88446,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88446,GRP_HEIGHTC,HEIGHTC_DATE,20140813 -US-Tw3,88447,GRP_HEIGHTC,HEIGHTC,0.064 -US-Tw3,88447,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88447,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Tw3,88447,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88447,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Tw3,88447,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88447,GRP_HEIGHTC,HEIGHTC_DATE,20140813 -US-Tw3,88448,GRP_HEIGHTC,HEIGHTC,0.364 -US-Tw3,88448,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88448,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Tw3,88448,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88448,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Tw3,88448,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88448,GRP_HEIGHTC,HEIGHTC_DATE,20140819 -US-Tw3,88449,GRP_HEIGHTC,HEIGHTC,0.08 -US-Tw3,88449,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88449,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Tw3,88449,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88449,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Tw3,88449,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88449,GRP_HEIGHTC,HEIGHTC_DATE,20140819 -US-Tw3,88450,GRP_HEIGHTC,HEIGHTC,0.457 -US-Tw3,88450,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88450,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Tw3,88450,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88450,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Tw3,88450,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88450,GRP_HEIGHTC,HEIGHTC_DATE,20140827 -US-Tw3,88450,GRP_HEIGHTC,HEIGHTC_COMMENT,Flowering -US-Tw3,88451,GRP_HEIGHTC,HEIGHTC,0.105 -US-Tw3,88451,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88451,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Tw3,88451,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88451,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Tw3,88451,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88451,GRP_HEIGHTC,HEIGHTC_DATE,20140827 -US-Tw3,88451,GRP_HEIGHTC,HEIGHTC_COMMENT,Flowering -US-Tw3,88452,GRP_HEIGHTC,HEIGHTC,0.56 -US-Tw3,88452,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88452,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Tw3,88452,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88452,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Tw3,88452,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88452,GRP_HEIGHTC,HEIGHTC_DATE,20140904 -US-Tw3,88452,GRP_HEIGHTC,HEIGHTC_COMMENT,Flowering -US-Tw3,88453,GRP_HEIGHTC,HEIGHTC,0.078 -US-Tw3,88453,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88453,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Tw3,88453,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88453,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Tw3,88453,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88453,GRP_HEIGHTC,HEIGHTC_DATE,20140904 -US-Tw3,88453,GRP_HEIGHTC,HEIGHTC_COMMENT,Flowering -US-Tw3,88454,GRP_HEIGHTC,HEIGHTC,0.05 -US-Tw3,88454,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88454,GRP_HEIGHTC,HEIGHTC_STATISTIC,Expert estimate -US-Tw3,88454,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88454,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,1 -US-Tw3,88454,GRP_HEIGHTC,HEIGHTC_APPROACH,Visual estimate -US-Tw3,88454,GRP_HEIGHTC,HEIGHTC_DATE,20140908 -US-Tw3,88454,GRP_HEIGHTC,HEIGHTC_COMMENT,Too short to measure -- just clipped -US-Tw3,88455,GRP_HEIGHTC,HEIGHTC,0.176 -US-Tw3,88455,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88455,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Tw3,88455,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88455,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Tw3,88455,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88455,GRP_HEIGHTC,HEIGHTC_DATE,20140925 -US-Tw3,88456,GRP_HEIGHTC,HEIGHTC,0.065 -US-Tw3,88456,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88456,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Tw3,88456,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88456,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Tw3,88456,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88456,GRP_HEIGHTC,HEIGHTC_DATE,20140925 -US-Tw3,88457,GRP_HEIGHTC,HEIGHTC,0.267 -US-Tw3,88457,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88457,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Tw3,88457,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88457,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Tw3,88457,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88457,GRP_HEIGHTC,HEIGHTC_DATE,20141002 -US-Tw3,88458,GRP_HEIGHTC,HEIGHTC,0.081 -US-Tw3,88458,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88458,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Tw3,88458,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88458,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Tw3,88458,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88458,GRP_HEIGHTC,HEIGHTC_DATE,20141002 -US-Tw3,88459,GRP_HEIGHTC,HEIGHTC,0.42 -US-Tw3,88459,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88459,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Tw3,88459,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88459,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Tw3,88459,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88459,GRP_HEIGHTC,HEIGHTC_DATE,20141009 -US-Tw3,88460,GRP_HEIGHTC,HEIGHTC,0.081 -US-Tw3,88460,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88460,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Tw3,88460,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88460,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Tw3,88460,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88460,GRP_HEIGHTC,HEIGHTC_DATE,20141009 -US-Tw3,88461,GRP_HEIGHTC,HEIGHTC,0.397 -US-Tw3,88461,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88461,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Tw3,88461,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88461,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Tw3,88461,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88461,GRP_HEIGHTC,HEIGHTC_DATE,20141016 -US-Tw3,88461,GRP_HEIGHTC,HEIGHTC_COMMENT,Flowering -US-Tw3,88462,GRP_HEIGHTC,HEIGHTC,0.147 -US-Tw3,88462,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88462,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Tw3,88462,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88462,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Tw3,88462,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88462,GRP_HEIGHTC,HEIGHTC_DATE,20141016 -US-Tw3,88462,GRP_HEIGHTC,HEIGHTC_COMMENT,Flowering -US-Tw3,88463,GRP_HEIGHTC,HEIGHTC,0.151 -US-Tw3,88463,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88463,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Tw3,88463,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88463,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Tw3,88463,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88463,GRP_HEIGHTC,HEIGHTC_DATE,20141111 -US-Tw3,88464,GRP_HEIGHTC,HEIGHTC,0.05 -US-Tw3,88464,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88464,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Tw3,88464,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88464,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Tw3,88464,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88464,GRP_HEIGHTC,HEIGHTC_DATE,20141111 -US-Tw3,88465,GRP_HEIGHTC,HEIGHTC,0.24 -US-Tw3,88465,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88465,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Tw3,88465,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88465,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Tw3,88465,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88465,GRP_HEIGHTC,HEIGHTC_DATE,20141125 -US-Tw3,88466,GRP_HEIGHTC,HEIGHTC,0.093 -US-Tw3,88466,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88466,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Tw3,88466,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88466,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Tw3,88466,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88466,GRP_HEIGHTC,HEIGHTC_DATE,20141125 -US-Tw3,88467,GRP_HEIGHTC,HEIGHTC,0.076 -US-Tw3,88467,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88467,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Tw3,88467,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88467,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Tw3,88467,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88467,GRP_HEIGHTC,HEIGHTC_DATE,20150205 -US-Tw3,88468,GRP_HEIGHTC,HEIGHTC,0.05 -US-Tw3,88468,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88468,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Tw3,88468,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88468,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Tw3,88468,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88468,GRP_HEIGHTC,HEIGHTC_DATE,20150205 -US-Tw3,88469,GRP_HEIGHTC,HEIGHTC,0.186 -US-Tw3,88469,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88469,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Tw3,88469,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88469,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Tw3,88469,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88469,GRP_HEIGHTC,HEIGHTC_DATE,20150219 -US-Tw3,88470,GRP_HEIGHTC,HEIGHTC,0.072 -US-Tw3,88470,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88470,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Tw3,88470,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88470,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Tw3,88470,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88470,GRP_HEIGHTC,HEIGHTC_DATE,20150219 -US-Tw3,88471,GRP_HEIGHTC,HEIGHTC,0.163 -US-Tw3,88471,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88471,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Tw3,88471,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88471,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Tw3,88471,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88471,GRP_HEIGHTC,HEIGHTC_DATE,20150305 -US-Tw3,88472,GRP_HEIGHTC,HEIGHTC,0.086 -US-Tw3,88472,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88472,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Tw3,88472,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88472,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Tw3,88472,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88472,GRP_HEIGHTC,HEIGHTC_DATE,20150305 -US-Tw3,88473,GRP_HEIGHTC,HEIGHTC,0.095 -US-Tw3,88473,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88473,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Tw3,88473,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88473,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Tw3,88473,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88473,GRP_HEIGHTC,HEIGHTC_DATE,20150324 -US-Tw3,88473,GRP_HEIGHTC,HEIGHTC_COMMENT,Sheep grazed -US-Tw3,88474,GRP_HEIGHTC,HEIGHTC,0.058 -US-Tw3,88474,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88474,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Tw3,88474,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88474,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Tw3,88474,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88474,GRP_HEIGHTC,HEIGHTC_DATE,20150324 -US-Tw3,88474,GRP_HEIGHTC,HEIGHTC_COMMENT,Sheep grazed -US-Tw3,88475,GRP_HEIGHTC,HEIGHTC,0.204 -US-Tw3,88475,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88475,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Tw3,88475,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88475,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Tw3,88475,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88475,GRP_HEIGHTC,HEIGHTC_DATE,20150409 -US-Tw3,88476,GRP_HEIGHTC,HEIGHTC,0.104 -US-Tw3,88476,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88476,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Tw3,88476,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88476,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Tw3,88476,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88476,GRP_HEIGHTC,HEIGHTC_DATE,20150409 -US-Tw3,88477,GRP_HEIGHTC,HEIGHTC,0.253 -US-Tw3,88477,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88477,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Tw3,88477,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88477,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Tw3,88477,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88477,GRP_HEIGHTC,HEIGHTC_DATE,20150507 -US-Tw3,88478,GRP_HEIGHTC,HEIGHTC,0.07 -US-Tw3,88478,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88478,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Tw3,88478,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88478,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Tw3,88478,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88478,GRP_HEIGHTC,HEIGHTC_DATE,20150507 -US-Tw3,88479,GRP_HEIGHTC,HEIGHTC,0.434 -US-Tw3,88479,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88479,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Tw3,88479,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88479,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Tw3,88479,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88479,GRP_HEIGHTC,HEIGHTC_DATE,20150521 -US-Tw3,88480,GRP_HEIGHTC,HEIGHTC,0.086 -US-Tw3,88480,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88480,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Tw3,88480,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88480,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Tw3,88480,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88480,GRP_HEIGHTC,HEIGHTC_DATE,20150521 -US-Tw3,88481,GRP_HEIGHTC,HEIGHTC,0.51 -US-Tw3,88481,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88481,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Tw3,88481,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88481,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Tw3,88481,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88481,GRP_HEIGHTC,HEIGHTC_DATE,20150625 -US-Tw3,88482,GRP_HEIGHTC,HEIGHTC,0.104 -US-Tw3,88482,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88482,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Tw3,88482,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88482,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Tw3,88482,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88482,GRP_HEIGHTC,HEIGHTC_DATE,20150625 -US-Tw3,88483,GRP_HEIGHTC,HEIGHTC,0.574 -US-Tw3,88483,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88483,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Tw3,88483,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88483,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Tw3,88483,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88483,GRP_HEIGHTC,HEIGHTC_DATE,20150701 -US-Tw3,88484,GRP_HEIGHTC,HEIGHTC,0.067 -US-Tw3,88484,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88484,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Tw3,88484,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88484,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Tw3,88484,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88484,GRP_HEIGHTC,HEIGHTC_DATE,20150701 -US-Tw3,88485,GRP_HEIGHTC,HEIGHTC,0.573 -US-Tw3,88485,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88485,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Tw3,88485,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88485,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Tw3,88485,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88485,GRP_HEIGHTC,HEIGHTC_DATE,20150709 -US-Tw3,88486,GRP_HEIGHTC,HEIGHTC,0.075 -US-Tw3,88486,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88486,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Tw3,88486,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88486,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Tw3,88486,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88486,GRP_HEIGHTC,HEIGHTC_DATE,20150709 -US-Tw3,88487,GRP_HEIGHTC,HEIGHTC,0.274 -US-Tw3,88487,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88487,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Tw3,88487,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88487,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,19 -US-Tw3,88487,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88487,GRP_HEIGHTC,HEIGHTC_DATE,20150806 -US-Tw3,88488,GRP_HEIGHTC,HEIGHTC,0.053 -US-Tw3,88488,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88488,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Tw3,88488,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88488,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,19 -US-Tw3,88488,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88488,GRP_HEIGHTC,HEIGHTC_DATE,20150806 -US-Tw3,88489,GRP_HEIGHTC,HEIGHTC,0.315 -US-Tw3,88489,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88489,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Tw3,88489,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88489,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Tw3,88489,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88489,GRP_HEIGHTC,HEIGHTC_DATE,20150819 -US-Tw3,88490,GRP_HEIGHTC,HEIGHTC,0.095 -US-Tw3,88490,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88490,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Tw3,88490,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88490,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Tw3,88490,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88490,GRP_HEIGHTC,HEIGHTC_DATE,20150819 -US-Tw3,88491,GRP_HEIGHTC,HEIGHTC,0.411 -US-Tw3,88491,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88491,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Tw3,88491,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88491,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Tw3,88491,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88491,GRP_HEIGHTC,HEIGHTC_DATE,20150902 -US-Tw3,88492,GRP_HEIGHTC,HEIGHTC,0.075 -US-Tw3,88492,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88492,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Tw3,88492,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88492,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Tw3,88492,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88492,GRP_HEIGHTC,HEIGHTC_DATE,20150902 -US-Tw3,88493,GRP_HEIGHTC,HEIGHTC,0.05 -US-Tw3,88493,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88493,GRP_HEIGHTC,HEIGHTC_STATISTIC,Expert estimate -US-Tw3,88493,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88493,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,1 -US-Tw3,88493,GRP_HEIGHTC,HEIGHTC_APPROACH,Visual estimate -US-Tw3,88493,GRP_HEIGHTC,HEIGHTC_DATE,20150916 -US-Tw3,88493,GRP_HEIGHTC,HEIGHTC_COMMENT,Just cut -US-Tw3,88494,GRP_HEIGHTC,HEIGHTC,0.229 -US-Tw3,88494,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88494,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Tw3,88494,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88494,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Tw3,88494,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88494,GRP_HEIGHTC,HEIGHTC_DATE,20150930 -US-Tw3,88495,GRP_HEIGHTC,HEIGHTC,0.074 -US-Tw3,88495,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88495,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Tw3,88495,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88495,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Tw3,88495,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88495,GRP_HEIGHTC,HEIGHTC_DATE,20150930 -US-Tw3,88496,GRP_HEIGHTC,HEIGHTC,0.452 -US-Tw3,88496,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88496,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Tw3,88496,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88496,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Tw3,88496,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88496,GRP_HEIGHTC,HEIGHTC_DATE,20151029 -US-Tw3,88497,GRP_HEIGHTC,HEIGHTC,0.07 -US-Tw3,88497,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88497,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Tw3,88497,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88497,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Tw3,88497,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88497,GRP_HEIGHTC,HEIGHTC_DATE,20151029 -US-Tw3,88498,GRP_HEIGHTC,HEIGHTC,0.05 -US-Tw3,88498,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88498,GRP_HEIGHTC,HEIGHTC_STATISTIC,Expert estimate -US-Tw3,88498,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88498,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,1 -US-Tw3,88498,GRP_HEIGHTC,HEIGHTC_APPROACH,Visual estimate -US-Tw3,88498,GRP_HEIGHTC,HEIGHTC_DATE,20151112 -US-Tw3,88498,GRP_HEIGHTC,HEIGHTC_COMMENT,Just cut (Eastern half of field) -US-Tw3,88499,GRP_HEIGHTC,HEIGHTC,0.064 -US-Tw3,88499,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88499,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Tw3,88499,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88499,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,11 -US-Tw3,88499,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88499,GRP_HEIGHTC,HEIGHTC_DATE,20160128 -US-Tw3,88500,GRP_HEIGHTC,HEIGHTC,0.02 -US-Tw3,88500,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88500,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Tw3,88500,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88500,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,11 -US-Tw3,88500,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88500,GRP_HEIGHTC,HEIGHTC_DATE,20160128 -US-Tw3,88501,GRP_HEIGHTC,HEIGHTC,0.113 -US-Tw3,88501,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88501,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Tw3,88501,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88501,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Tw3,88501,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88501,GRP_HEIGHTC,HEIGHTC_DATE,20160211 -US-Tw3,88502,GRP_HEIGHTC,HEIGHTC,0.032 -US-Tw3,88502,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88502,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Tw3,88502,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88502,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Tw3,88502,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88502,GRP_HEIGHTC,HEIGHTC_DATE,20160211 -US-Tw3,88503,GRP_HEIGHTC,HEIGHTC,0.05 -US-Tw3,88503,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88503,GRP_HEIGHTC,HEIGHTC_STATISTIC,Expert estimate -US-Tw3,88503,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88503,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,1 -US-Tw3,88503,GRP_HEIGHTC,HEIGHTC_APPROACH,Visual estimate -US-Tw3,88503,GRP_HEIGHTC,HEIGHTC_DATE,20160225 -US-Tw3,88503,GRP_HEIGHTC,HEIGHTC_COMMENT,Just eaten (sheep in field) -US-Tw3,88504,GRP_HEIGHTC,HEIGHTC,0.201 -US-Tw3,88504,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88504,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Tw3,88504,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88504,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Tw3,88504,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88504,GRP_HEIGHTC,HEIGHTC_DATE,20160329 -US-Tw3,88505,GRP_HEIGHTC,HEIGHTC,0.067 -US-Tw3,88505,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88505,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Tw3,88505,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88505,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Tw3,88505,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88505,GRP_HEIGHTC,HEIGHTC_DATE,20160329 -US-Tw3,88506,GRP_HEIGHTC,HEIGHTC,0.451 -US-Tw3,88506,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88506,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Tw3,88506,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88506,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,10 -US-Tw3,88506,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88506,GRP_HEIGHTC,HEIGHTC_DATE,20160413 -US-Tw3,88507,GRP_HEIGHTC,HEIGHTC,0.103 -US-Tw3,88507,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88507,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Tw3,88507,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88507,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,10 -US-Tw3,88507,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88507,GRP_HEIGHTC,HEIGHTC_DATE,20160413 -US-Tw3,88508,GRP_HEIGHTC,HEIGHTC,0.153 -US-Tw3,88508,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88508,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Tw3,88508,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88508,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,19 -US-Tw3,88508,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88508,GRP_HEIGHTC,HEIGHTC_DATE,20160428 -US-Tw3,88508,GRP_HEIGHTC,HEIGHTC_COMMENT,Recently cut -US-Tw3,88509,GRP_HEIGHTC,HEIGHTC,0.046 -US-Tw3,88509,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88509,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Tw3,88509,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88509,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,19 -US-Tw3,88509,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88509,GRP_HEIGHTC,HEIGHTC_DATE,20160428 -US-Tw3,88509,GRP_HEIGHTC,HEIGHTC_COMMENT,Recently cut -US-Tw3,88510,GRP_HEIGHTC,HEIGHTC,0.443 -US-Tw3,88510,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88510,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Tw3,88510,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88510,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,10 -US-Tw3,88510,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88510,GRP_HEIGHTC,HEIGHTC_DATE,20160512 -US-Tw3,88511,GRP_HEIGHTC,HEIGHTC,0.056 -US-Tw3,88511,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88511,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Tw3,88511,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88511,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,10 -US-Tw3,88511,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88511,GRP_HEIGHTC,HEIGHTC_DATE,20160512 -US-Tw3,88512,GRP_HEIGHTC,HEIGHTC,0.562 -US-Tw3,88512,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88512,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Tw3,88512,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88512,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Tw3,88512,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88512,GRP_HEIGHTC,HEIGHTC_DATE,20160524 -US-Tw3,88512,GRP_HEIGHTC,HEIGHTC_COMMENT,Flowering -US-Tw3,88513,GRP_HEIGHTC,HEIGHTC,0.064 -US-Tw3,88513,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88513,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Tw3,88513,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88513,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Tw3,88513,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88513,GRP_HEIGHTC,HEIGHTC_DATE,20160524 -US-Tw3,88513,GRP_HEIGHTC,HEIGHTC_COMMENT,Flowering -US-Tw3,88514,GRP_HEIGHTC,HEIGHTC,0.166 -US-Tw3,88514,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88514,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Tw3,88514,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88514,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Tw3,88514,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88514,GRP_HEIGHTC,HEIGHTC_DATE,20160606 -US-Tw3,88514,GRP_HEIGHTC,HEIGHTC_COMMENT,Recently Cut -US-Tw3,88515,GRP_HEIGHTC,HEIGHTC,0.036 -US-Tw3,88515,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88515,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Tw3,88515,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88515,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Tw3,88515,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88515,GRP_HEIGHTC,HEIGHTC_DATE,20160606 -US-Tw3,88515,GRP_HEIGHTC,HEIGHTC_COMMENT,Recently Cut -US-Tw3,88516,GRP_HEIGHTC,HEIGHTC,0.348 -US-Tw3,88516,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88516,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Tw3,88516,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88516,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,25 -US-Tw3,88516,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88516,GRP_HEIGHTC,HEIGHTC_DATE,20160624 -US-Tw3,88517,GRP_HEIGHTC,HEIGHTC,0.074 -US-Tw3,88517,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88517,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Tw3,88517,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88517,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,25 -US-Tw3,88517,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88517,GRP_HEIGHTC,HEIGHTC_DATE,20160624 -US-Tw3,88518,GRP_HEIGHTC,HEIGHTC,0.223 -US-Tw3,88518,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88518,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Tw3,88518,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88518,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,4 -US-Tw3,88518,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88518,GRP_HEIGHTC,HEIGHTC_DATE,20160706 -US-Tw3,88518,GRP_HEIGHTC,HEIGHTC_COMMENT,Recently cut -US-Tw3,88519,GRP_HEIGHTC,HEIGHTC,0.017 -US-Tw3,88519,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88519,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Tw3,88519,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88519,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,4 -US-Tw3,88519,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88519,GRP_HEIGHTC,HEIGHTC_DATE,20160706 -US-Tw3,88519,GRP_HEIGHTC,HEIGHTC_COMMENT,Recently cut -US-Tw3,88520,GRP_HEIGHTC,HEIGHTC,0.204 -US-Tw3,88520,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88520,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Tw3,88520,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88520,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,16 -US-Tw3,88520,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88520,GRP_HEIGHTC,HEIGHTC_DATE,20160720 -US-Tw3,88521,GRP_HEIGHTC,HEIGHTC,0.04 -US-Tw3,88521,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88521,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Tw3,88521,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88521,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,16 -US-Tw3,88521,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88521,GRP_HEIGHTC,HEIGHTC_DATE,20160720 -US-Tw3,88522,GRP_HEIGHTC,HEIGHTC,0.37 -US-Tw3,88522,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88522,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Tw3,88522,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88522,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Tw3,88522,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88522,GRP_HEIGHTC,HEIGHTC_DATE,20160801 -US-Tw3,88523,GRP_HEIGHTC,HEIGHTC,0.076 -US-Tw3,88523,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88523,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Tw3,88523,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88523,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Tw3,88523,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88523,GRP_HEIGHTC,HEIGHTC_DATE,20160801 -US-Tw3,88524,GRP_HEIGHTC,HEIGHTC,0.05 -US-Tw3,88524,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88524,GRP_HEIGHTC,HEIGHTC_STATISTIC,Expert estimate -US-Tw3,88524,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88524,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,1 -US-Tw3,88524,GRP_HEIGHTC,HEIGHTC_APPROACH,Visual estimate -US-Tw3,88524,GRP_HEIGHTC,HEIGHTC_DATE,20160812 -US-Tw3,88524,GRP_HEIGHTC,HEIGHTC_COMMENT,"Alfalfa just cut and baled, bales being removed" -US-Tw3,88525,GRP_HEIGHTC,HEIGHTC,0.356 -US-Tw3,88525,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88525,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Tw3,88525,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88525,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,23 -US-Tw3,88525,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88525,GRP_HEIGHTC,HEIGHTC_DATE,20160913 -US-Tw3,88525,GRP_HEIGHTC,HEIGHTC_COMMENT,"Flowering, lots of butterflies, soon to be cut" -US-Tw3,88526,GRP_HEIGHTC,HEIGHTC,0.087 -US-Tw3,88526,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88526,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Tw3,88526,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88526,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,23 -US-Tw3,88526,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88526,GRP_HEIGHTC,HEIGHTC_DATE,20160913 -US-Tw3,88526,GRP_HEIGHTC,HEIGHTC_COMMENT,"Flowering, lots of butterflies, soon to be cut" -US-Tw3,88527,GRP_HEIGHTC,HEIGHTC,0.141 -US-Tw3,88527,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88527,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Tw3,88527,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88527,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Tw3,88527,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88527,GRP_HEIGHTC,HEIGHTC_DATE,20161011 -US-Tw3,88528,GRP_HEIGHTC,HEIGHTC,0.055 -US-Tw3,88528,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88528,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Tw3,88528,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88528,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Tw3,88528,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88528,GRP_HEIGHTC,HEIGHTC_DATE,20161011 -US-Tw3,88529,GRP_HEIGHTC,HEIGHTC,0.269 -US-Tw3,88529,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88529,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Tw3,88529,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88529,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Tw3,88529,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88529,GRP_HEIGHTC,HEIGHTC_DATE,20161026 -US-Tw3,88530,GRP_HEIGHTC,HEIGHTC,0.08 -US-Tw3,88530,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88530,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Tw3,88530,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88530,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Tw3,88530,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88530,GRP_HEIGHTC,HEIGHTC_DATE,20161026 -US-Tw3,88531,GRP_HEIGHTC,HEIGHTC,0.344 -US-Tw3,88531,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88531,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Tw3,88531,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88531,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Tw3,88531,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88531,GRP_HEIGHTC,HEIGHTC_DATE,20161108 -US-Tw3,88531,GRP_HEIGHTC,HEIGHTC_COMMENT,"not quite flowering, could be ready soon for final cut" -US-Tw3,88532,GRP_HEIGHTC,HEIGHTC,0.077 -US-Tw3,88532,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88532,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Tw3,88532,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88532,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Tw3,88532,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88532,GRP_HEIGHTC,HEIGHTC_DATE,20161108 -US-Tw3,88532,GRP_HEIGHTC,HEIGHTC_COMMENT,"not quite flowering, could be ready soon for final cut" -US-Tw3,88533,GRP_HEIGHTC,HEIGHTC,0.286 -US-Tw3,88533,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88533,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Tw3,88533,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88533,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Tw3,88533,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88533,GRP_HEIGHTC,HEIGHTC_DATE,20161122 -US-Tw3,88534,GRP_HEIGHTC,HEIGHTC,0.079 -US-Tw3,88534,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88534,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Tw3,88534,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88534,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Tw3,88534,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88534,GRP_HEIGHTC,HEIGHTC_DATE,20161122 -US-Tw3,88535,GRP_HEIGHTC,HEIGHTC,0.106 -US-Tw3,88535,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88535,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Tw3,88535,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88535,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Tw3,88535,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88535,GRP_HEIGHTC,HEIGHTC_DATE,20170315 -US-Tw3,88536,GRP_HEIGHTC,HEIGHTC,0.049 -US-Tw3,88536,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88536,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Tw3,88536,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88536,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Tw3,88536,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88536,GRP_HEIGHTC,HEIGHTC_DATE,20170315 -US-Tw3,88537,GRP_HEIGHTC,HEIGHTC,0.237 -US-Tw3,88537,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88537,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Tw3,88537,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88537,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Tw3,88537,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88537,GRP_HEIGHTC,HEIGHTC_DATE,20170329 -US-Tw3,88538,GRP_HEIGHTC,HEIGHTC,0.06 -US-Tw3,88538,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88538,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Tw3,88538,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88538,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Tw3,88538,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88538,GRP_HEIGHTC,HEIGHTC_DATE,20170329 -US-Tw3,88539,GRP_HEIGHTC,HEIGHTC,0.346 -US-Tw3,88539,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88539,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Tw3,88539,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88539,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Tw3,88539,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88539,GRP_HEIGHTC,HEIGHTC_DATE,20170411 -US-Tw3,88540,GRP_HEIGHTC,HEIGHTC,0.043 -US-Tw3,88540,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88540,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Tw3,88540,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88540,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Tw3,88540,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88540,GRP_HEIGHTC,HEIGHTC_DATE,20170411 -US-Tw3,88541,GRP_HEIGHTC,HEIGHTC,0.538 -US-Tw3,88541,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88541,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Tw3,88541,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88541,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Tw3,88541,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88541,GRP_HEIGHTC,HEIGHTC_DATE,20170427 -US-Tw3,88541,GRP_HEIGHTC,HEIGHTC_COMMENT,mix of alfalfa and grass -US-Tw3,88542,GRP_HEIGHTC,HEIGHTC,0.09 -US-Tw3,88542,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88542,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Tw3,88542,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88542,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Tw3,88542,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88542,GRP_HEIGHTC,HEIGHTC_DATE,20170427 -US-Tw3,88542,GRP_HEIGHTC,HEIGHTC_COMMENT,mix of alfalfa and grass -US-Tw3,88543,GRP_HEIGHTC,HEIGHTC,0.584 -US-Tw3,88543,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88543,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Tw3,88543,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88543,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Tw3,88543,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88543,GRP_HEIGHTC,HEIGHTC_DATE,20170510 -US-Tw3,88543,GRP_HEIGHTC,HEIGHTC_COMMENT,mix of flowering alfalfa and grass -US-Tw3,88544,GRP_HEIGHTC,HEIGHTC,0.148 -US-Tw3,88544,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88544,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Tw3,88544,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88544,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Tw3,88544,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88544,GRP_HEIGHTC,HEIGHTC_DATE,20170510 -US-Tw3,88544,GRP_HEIGHTC,HEIGHTC_COMMENT,mix of flowering alfalfa and grass -US-Tw3,88545,GRP_HEIGHTC,HEIGHTC,0.247 -US-Tw3,88545,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88545,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Tw3,88545,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88545,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Tw3,88545,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88545,GRP_HEIGHTC,HEIGHTC_DATE,20170726 -US-Tw3,88546,GRP_HEIGHTC,HEIGHTC,0.084 -US-Tw3,88546,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88546,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Tw3,88546,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88546,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Tw3,88546,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88546,GRP_HEIGHTC,HEIGHTC_DATE,20170726 -US-Tw3,88547,GRP_HEIGHTC,HEIGHTC,0.229 -US-Tw3,88547,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88547,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Tw3,88547,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88547,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Tw3,88547,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88547,GRP_HEIGHTC,HEIGHTC_DATE,20170809 -US-Tw3,88548,GRP_HEIGHTC,HEIGHTC,0.068 -US-Tw3,88548,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88548,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Tw3,88548,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88548,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Tw3,88548,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88548,GRP_HEIGHTC,HEIGHTC_DATE,20170809 -US-Tw3,88549,GRP_HEIGHTC,HEIGHTC,0.119 -US-Tw3,88549,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88549,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Tw3,88549,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88549,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Tw3,88549,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88549,GRP_HEIGHTC,HEIGHTC_DATE,20170906 -US-Tw3,88550,GRP_HEIGHTC,HEIGHTC,0.036 -US-Tw3,88550,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88550,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Tw3,88550,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88550,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Tw3,88550,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88550,GRP_HEIGHTC,HEIGHTC_DATE,20170906 -US-Tw3,88551,GRP_HEIGHTC,HEIGHTC,0.218 -US-Tw3,88551,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88551,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Tw3,88551,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88551,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Tw3,88551,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88551,GRP_HEIGHTC,HEIGHTC_DATE,20170919 -US-Tw3,88552,GRP_HEIGHTC,HEIGHTC,0.074 -US-Tw3,88552,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88552,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Tw3,88552,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88552,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Tw3,88552,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88552,GRP_HEIGHTC,HEIGHTC_DATE,20170919 -US-Tw3,88553,GRP_HEIGHTC,HEIGHTC,0.112 -US-Tw3,88553,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88553,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Tw3,88553,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88553,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Tw3,88553,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88553,GRP_HEIGHTC,HEIGHTC_DATE,20171026 -US-Tw3,88554,GRP_HEIGHTC,HEIGHTC,0.039 -US-Tw3,88554,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88554,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Tw3,88554,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88554,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Tw3,88554,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88554,GRP_HEIGHTC,HEIGHTC_DATE,20171026 -US-Tw3,88555,GRP_HEIGHTC,HEIGHTC,0.185 -US-Tw3,88555,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88555,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Tw3,88555,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88555,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Tw3,88555,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88555,GRP_HEIGHTC,HEIGHTC_DATE,20171110 -US-Tw3,88556,GRP_HEIGHTC,HEIGHTC,0.083 -US-Tw3,88556,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88556,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Tw3,88556,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88556,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Tw3,88556,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88556,GRP_HEIGHTC,HEIGHTC_DATE,20171110 -US-Tw3,88557,GRP_HEIGHTC,HEIGHTC,0.03 -US-Tw3,88557,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88557,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Tw3,88557,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88557,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,22 -US-Tw3,88557,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88557,GRP_HEIGHTC,HEIGHTC_DATE,20180104 -US-Tw3,88558,GRP_HEIGHTC,HEIGHTC,0.028 -US-Tw3,88558,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88558,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Tw3,88558,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88558,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,22 -US-Tw3,88558,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88558,GRP_HEIGHTC,HEIGHTC_DATE,20180104 -US-Tw3,88559,GRP_HEIGHTC,HEIGHTC,0.048 -US-Tw3,88559,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88559,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Tw3,88559,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88559,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Tw3,88559,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88559,GRP_HEIGHTC,HEIGHTC_DATE,20180116 -US-Tw3,88559,GRP_HEIGHTC,HEIGHTC_COMMENT,Lots of grass and gaps between alfalfa plants -US-Tw3,88560,GRP_HEIGHTC,HEIGHTC,0.029 -US-Tw3,88560,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88560,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Tw3,88560,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88560,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Tw3,88560,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88560,GRP_HEIGHTC,HEIGHTC_DATE,20180116 -US-Tw3,88560,GRP_HEIGHTC,HEIGHTC_COMMENT,Lots of grass and gaps between alfalfa plants -US-Tw3,88561,GRP_HEIGHTC,HEIGHTC,0.117 -US-Tw3,88561,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88561,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Tw3,88561,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88561,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Tw3,88561,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88561,GRP_HEIGHTC,HEIGHTC_DATE,20180228 -US-Tw3,88561,GRP_HEIGHTC,HEIGHTC_COMMENT,"1st set W transect, second N" -US-Tw3,88562,GRP_HEIGHTC,HEIGHTC,0.05 -US-Tw3,88562,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88562,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Tw3,88562,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88562,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Tw3,88562,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88562,GRP_HEIGHTC,HEIGHTC_DATE,20180228 -US-Tw3,88562,GRP_HEIGHTC,HEIGHTC_COMMENT,"1st set W transect, second N" -US-Tw3,88563,GRP_HEIGHTC,HEIGHTC,0.151 -US-Tw3,88563,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88563,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Tw3,88563,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88563,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Tw3,88563,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88563,GRP_HEIGHTC,HEIGHTC_DATE,20180319 -US-Tw3,88563,GRP_HEIGHTC,HEIGHTC_COMMENT,"Mostly weeds (grass, nettles)" -US-Tw3,88564,GRP_HEIGHTC,HEIGHTC,0.107 -US-Tw3,88564,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88564,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Tw3,88564,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88564,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Tw3,88564,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88564,GRP_HEIGHTC,HEIGHTC_DATE,20180319 -US-Tw3,88564,GRP_HEIGHTC,HEIGHTC_COMMENT,"Mostly weeds (grass, nettles)" -US-Tw3,88565,GRP_HEIGHTC,HEIGHTC,0.507 -US-Tw3,88565,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88565,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Tw3,88565,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88565,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,21 -US-Tw3,88565,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88565,GRP_HEIGHTC,HEIGHTC_DATE,20180405 -US-Tw3,88565,GRP_HEIGHTC,HEIGHTC_COMMENT,Mostly grass -US-Tw3,88566,GRP_HEIGHTC,HEIGHTC,0.134 -US-Tw3,88566,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88566,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Tw3,88566,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88566,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,21 -US-Tw3,88566,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88566,GRP_HEIGHTC,HEIGHTC_DATE,20180405 -US-Tw3,88566,GRP_HEIGHTC,HEIGHTC_COMMENT,Mostly grass -US-Tw3,88567,GRP_HEIGHTC,HEIGHTC,0.218 -US-Tw3,88567,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88567,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Tw3,88567,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88567,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,18 -US-Tw3,88567,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88567,GRP_HEIGHTC,HEIGHTC_DATE,20180503 -US-Tw3,88567,GRP_HEIGHTC,HEIGHTC_COMMENT,Grass and alfalfa -US-Tw3,88568,GRP_HEIGHTC,HEIGHTC,0.046 -US-Tw3,88568,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88568,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Tw3,88568,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88568,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,18 -US-Tw3,88568,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88568,GRP_HEIGHTC,HEIGHTC_DATE,20180503 -US-Tw3,88568,GRP_HEIGHTC,HEIGHTC_COMMENT,Grass and alfalfa -US-Tw3,88569,GRP_HEIGHTC,HEIGHTC,0.35 -US-Tw3,88569,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88569,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Tw3,88569,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88569,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Tw3,88569,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88569,GRP_HEIGHTC,HEIGHTC_DATE,20180516 -US-Tw3,88569,GRP_HEIGHTC,HEIGHTC_COMMENT,Mixed grass and alfalfa 50-50 -US-Tw3,88570,GRP_HEIGHTC,HEIGHTC,0.077 -US-Tw3,88570,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Herbaceous Crop -US-Tw3,88570,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Tw3,88570,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw3,88570,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Tw3,88570,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw3,88570,GRP_HEIGHTC,HEIGHTC_DATE,20180516 -US-Tw3,88570,GRP_HEIGHTC,HEIGHTC_COMMENT,Mixed grass and alfalfa 50-50 -US-Tw3,11286,GRP_IGBP,IGBP,CRO -US-Tw3,11286,GRP_IGBP,IGBP_COMMENT,alfalfa is a fast growing leguminous crop raised for animal feed of low stature. It is planted in rows and typically reaches 60-70 cm in height prior to harvest. -US-Tw3,15356,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-Tw3,15356,GRP_LAND_OWNERSHIP,LAND_OWNER,California Department of Water Resources -US-Tw3,94793,GRP_LOCATION,LOCATION_LAT,38.1151 -US-Tw3,94793,GRP_LOCATION,LOCATION_LONG,-121.6467 -US-Tw3,94793,GRP_LOCATION,LOCATION_ELEV,-4 -US-Tw3,94793,GRP_LOCATION,LOCATION_DATE_START,20130524 -US-Tw3,94793,GRP_LOCATION,LOCATION_COMMENT,Original location in a drainage ditch through the middle of the field -US-Tw3,94770,GRP_LOCATION,LOCATION_LAT,38.1152 -US-Tw3,94770,GRP_LOCATION,LOCATION_LONG,-121.6469 -US-Tw3,94770,GRP_LOCATION,LOCATION_ELEV,-4 -US-Tw3,94770,GRP_LOCATION,LOCATION_DATE_START,20161026 -US-Tw3,94770,GRP_LOCATION,LOCATION_COMMENT,Moved 14m to the northwest due to tractor work at the original location -US-Tw3,11289,GRP_NETWORK,NETWORK,AmeriFlux -US-Tw3,87086,GRP_NETWORK,NETWORK,Phenocam -US-Tw3,1700007908,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Baldocchi, D., Penuelas, J. (2018) The Physics And Ecology Of Mining Carbon Dioxide From The Atmosphere By Ecosystems, Global Change Biology, 45(), 9275–9287" -US-Tw3,1700007908,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/GCB.14559 -US-Tw3,1700007908,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Tw3,1700006396,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Baldocchi, D., Penuelas, J. (2018) The Physics And Ecology Of Mining Carbon Dioxide From The Atmosphere By Ecosystems, Global Change Biology, 45(8), 9275–9287" -US-Tw3,1700006396,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/GCB.14559 -US-Tw3,1700006396,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Tw3,1700003168,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chamberlain, S. D., Verfaillie, J., Eichelmann, E., Hemes, K. S., Baldocchi, D. D. (2017) Evaluation Of Density Corrections To Methane Fluxes Measured By Open-Path Eddy Covariance Over Contrasting Landscapes, Boundary-Layer Meteorology, 207(), 117-126" -US-Tw3,1700003168,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1007/S10546-017-0275-9 -US-Tw3,1700003168,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Tw3,1700000321,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chamberlain, S. D., Verfaillie, J., Eichelmann, E., Hemes, K. S., Baldocchi, D. D. (2017) Evaluation Of Density Corrections To Methane Fluxes Measured By Open-Path Eddy Covariance Over Contrasting Landscapes, Boundary-Layer Meteorology, 207(8), 117-126" -US-Tw3,1700000321,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1007/S10546-017-0275-9 -US-Tw3,1700000321,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Tw3,1700002139,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Baldocchi, D. D., Poindexter, C., Abraha, M., Desai, A. R., Bohrer, G., Arain, M. A., Griffis, T., Blanken, P. D., O'Halloran, T. L., Thomas, R. Q., Zhang, Q., Burns, S. P., Frank, J. M., Christian, D., Brown, S., Black, T. A., Gough, C. M., Law, B. E., Lee, X., Chen, J., Reed, D. E., Massman, W. J., Clark, K., Hatfield, J., Prueger, J., Bracho, R., Baker, J. M., Martin, T. A. (2018) Temporal Dynamics Of Aerodynamic Canopy Height Derived From Eddy Covariance Momentum Flux Data Across North American Flux Networks, Geophysical Research Letters, 45(), 9275–9287" -US-Tw3,1700002139,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018GL079306 -US-Tw3,1700002139,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Tw3,1700002718,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Baldocchi, D. D., Poindexter, C., Abraha, M., Desai, A. R., Bohrer, G., Arain, M. A., Griffis, T., Blanken, P. D., O'Halloran, T. L., Thomas, R. Q., Zhang, Q., Burns, S. P., Frank, J. M., Christian, D., Brown, S., Black, T. A., Gough, C. M., Law, B. E., Lee, X., Chen, J., Reed, D. E., Massman, W. J., Clark, K., Hatfield, J., Prueger, J., Bracho, R., Baker, J. M., Martin, T. A. (2018) Temporal Dynamics Of Aerodynamic Canopy Height Derived From Eddy Covariance Momentum Flux Data Across North American Flux Networks, Geophysical Research Letters, 45(8), 9275–9287" -US-Tw3,1700002718,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018GL079306 -US-Tw3,1700002718,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Tw3,1700006900,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(8), 108350" -US-Tw3,1700006900,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -US-Tw3,1700006900,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Tw3,1700001629,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Dennis Baldocchi, Cove Sturtevant (2015) Does day and night sampling reduce spurious correlation between canopy photosynthesis and ecosystem respiration?, Agricultural and Forest Meteorology, 207(), 117-126" -US-Tw3,1700001629,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2015.03.010 -US-Tw3,1700001629,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Primary_Citation -US-Tw3,1700006648,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Dennis Baldocchi, Cove Sturtevant (2015) Does day and night sampling reduce spurious correlation between canopy photosynthesis and ecosystem respiration?, Agricultural and Forest Meteorology, 207(8), 117-126" -US-Tw3,1700006648,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2015.03.010 -US-Tw3,1700006648,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Primary_Citation -US-Tw3,1700007500,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Eichelmann, E., Hemes, K. S., Knox, S. H., Oikawa, P. Y., Chamberlain, S. D., Sturtevant, C., Verfaillie, J., Baldocchi, D. D. (2018) The Effect Of Land Cover Type And Structure On Evapotranspiration From Agricultural And Wetland Sites In The Sacramento–San Joaquin River Delta, California, Agricultural And Forest Meteorology, 256-257(), 179-195" -US-Tw3,1700007500,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2018.03.007 -US-Tw3,1700007500,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Tw3,1700001404,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Eichelmann, E., Hemes, K. S., Knox, S. H., Oikawa, P. Y., Chamberlain, S. D., Sturtevant, C., Verfaillie, J., Baldocchi, D. D. (2018) The Effect Of Land Cover Type And Structure On Evapotranspiration From Agricultural And Wetland Sites In The Sacramento–San Joaquin River Delta, California, Agricultural And Forest Meteorology, 256-257(8), 179-195" -US-Tw3,1700001404,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2018.03.007 -US-Tw3,1700001404,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Tw3,1700005637,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Hemes, K. S., Chamberlain, S. D., Eichelmann, E., Anthony, T., Valach, A., Kasak, K., Szutu, D., Verfaillie, J., Silver, W. L., Baldocchi, D. D. (2019) Assessing The Carbon And Climate Benefit Of Restoring Degraded Agricultural Peat Soils To Managed Wetlands, Agricultural And Forest Meteorology, 268(), 202-214" -US-Tw3,1700005637,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2019.01.017 -US-Tw3,1700005637,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Tw3,1700007320,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Hemes, K. S., Chamberlain, S. D., Eichelmann, E., Anthony, T., Valach, A., Kasak, K., Szutu, D., Verfaillie, J., Silver, W. L., Baldocchi, D. D. (2019) Assessing The Carbon And Climate Benefit Of Restoring Degraded Agricultural Peat Soils To Managed Wetlands, Agricultural And Forest Meteorology, 268(8), 202-214" -US-Tw3,1700007320,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2019.01.017 -US-Tw3,1700007320,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Tw3,1700009048,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Hemes, K. S., Eichelmann, E., Chamberlain, S., Knox, S. H., Oikawa, P. Y., Sturtevant, C., Verfaillie, J., Szutu, D., Baldocchi, D. D. (2018) A Unique Combination Of Aerodynamic And Surface Properties Contribute To Surface Cooling In Restored Wetlands Of The Sacramento-San Joaquin Delta, California, Journal Of Geophysical Research: Biogeosciences, 256-257(), 179-195" -US-Tw3,1700009048,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018JG004494 -US-Tw3,1700009048,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Tw3,1700004386,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Hemes, K. S., Eichelmann, E., Chamberlain, S., Knox, S. H., Oikawa, P. Y., Sturtevant, C., Verfaillie, J., Szutu, D., Baldocchi, D. D. (2018) A Unique Combination Of Aerodynamic And Surface Properties Contribute To Surface Cooling In Restored Wetlands Of The Sacramento-San Joaquin Delta, California, Journal Of Geophysical Research: Biogeosciences, 256-257(8), 179-195" -US-Tw3,1700004386,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018JG004494 -US-Tw3,1700004386,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Tw3,1700001011,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Oikawa, P. Y., C. Sturtevant, S. H. Knox, J. Verfaillie, Y. W. Huang, and D. D. Baldocchi. (2017) Revisiting the partitioning of net ecosystem exchange of CO2 into photosynthesis and respiration with simultaneous flux measurements of 13CO2 and CO2, soil respiration and a biophysical model, CANVEG., Agricultural and Forest Meteorology, 234(), 149-163" -US-Tw3,1700001011,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2016.12.016 -US-Tw3,1700001011,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Tw3,1700003510,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Oikawa, P. Y., C. Sturtevant, S. H. Knox, J. Verfaillie, Y. W. Huang, and D. D. Baldocchi. (2017) Revisiting the partitioning of net ecosystem exchange of CO2 into photosynthesis and respiration with simultaneous flux measurements of 13CO2 and CO2, soil respiration and a biophysical model, CANVEG., Agricultural and Forest Meteorology, 234(8), 149-163" -US-Tw3,1700003510,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2016.12.016 -US-Tw3,1700003510,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Tw3,1700002901,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Sullivan, R. C., Cook, D. R., Ghate, V. P., Kotamarthi, V. R., Feng, Y. (2019) Improved Spatiotemporal Representativeness And Bias Reduction Of Satellite-Based Evapotranspiration Retrievals Via Use Of In Situ Meteorology And Constrained Canopy Surface Resistance, Journal Of Geophysical Research: Biogeosciences, 124(2), 342-352" -US-Tw3,1700002901,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018JG004744 -US-Tw3,1700002901,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Tw3,1700005220,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Sullivan, R. C., Kotamarthi, V. R., Feng, Y. (2019) Recovering Evapotranspiration Trends From Biased CMIP5 Simulations And Sensitivity To Changing Climate Over North America, Journal Of Hydrometeorology, 20(8), 1619-1633" -US-Tw3,1700005220,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1175/JHM-D-18-0259.1 -US-Tw3,1700005220,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Tw3,11290,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"The research approach of the University of California, Berkeley Biometeorology Laboratory involves the coordinated use of experimental measurements and theoretical models to understand the physical, biological, and chemical processes that control trace gas fluxes between the biosphere and atmosphere and to quantify their temporal and spatial variations. The research objectives of the Mayberry Wetland, Twitchell Wetland, Sherman Island, Twitchell Island, Twitchell Alfalfa, and Twitchell Corn sites are as follows: 1) Describe differences in the fluxes of CO2, CH4, H2O, and energy between different land uses; 2) Understand the mechanisms controlling these fluxes; 3) Use ecosystem modeling to understand controls on these mechanisms under different environmental scenarios. These six sites were selected to capture a wide range of inundated conditions within the Sacramento-San Joaquin River Delta. The research focuses on the eddy covariance technique to measure CH4, CO2, H2O, and energy fluxes and works to combine measurements of both net fluxes and partitioned fluxes in order to achieve a mechanistic understanding of the ecological controls on current and future carbon flux in the Delta." -US-Tw3,11291,GRP_SITE_CHAR,TERRAIN,Flat -US-Tw3,11291,GRP_SITE_CHAR,ASPECT,FLAT -US-Tw3,11291,GRP_SITE_CHAR,WIND_DIRECTION,W -US-Tw3,11291,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,370 -US-Tw3,11291,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,0 -US-Tw3,15361,GRP_SITE_DESC,SITE_DESC,"The Twitchell Alfalfa site is an alfalfa field owned by the state of California and leased to third parties for farming. The tower was installed on May 24, 2013. This site and the surrounding region are part of the San Joaquin - Sacramento River Delta drained beginning in the 1850's and subsequently used for agriculture. The field has been alfalfa for X years…., Crop rotation occurs every 5-6 years. The site is harvested by mowing and bailing several times per year. The field is fallow typically between November and February. The site is irrigated by periodically-flooded ditches surrounding the field. The site is irrigated by raising, and subsequently lowering the water table??" -US-Tw3,11293,GRP_SITE_FUNDING,SITE_FUNDING,California Department of Water Resources -US-Tw3,11294,GRP_STATE,STATE,CA -US-Tw3,15368,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Dennis Baldocchi -US-Tw3,15368,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Tw3,15368,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,baldocchi@berkeley.edu -US-Tw3,15368,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"University of California, Berkeley" -US-Tw3,15368,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Department of Environmental Science, Policy and Management, 137 Mulford Hall, 345 Hilgard Hall,Berkeley, CA USA 94720-3110" -US-Tw3,30341,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Sam Chamberlain -US-Tw3,30341,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-Tw3,30341,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,schamberlain@berkeley.edu -US-Tw3,30341,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,UC Berkeley -US-Tw3,30342,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Daphne Szutu -US-Tw3,30342,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Technician -US-Tw3,30342,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,daphneszutu@berkeley.edu -US-Tw3,30342,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,UC Berkeley -US-Tw3,15367,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Joe Verfaillie -US-Tw3,15367,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Technician -US-Tw3,15367,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,jverfail@berkeley.edu -US-Tw3,15367,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"University of California, Berkeley" -US-Tw3,85050,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Elke Eichelmann -US-Tw3,85050,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Affiliate -US-Tw3,85050,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,eeichelm@berkeley.edu -US-Tw3,85050,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,UC Berkeley -US-Tw3,15370,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Patty Oikawa -US-Tw3,15370,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Affiliate -US-Tw3,15370,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,pattyoikawa@berkeley.edu -US-Tw3,15370,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"University of California, Berkeley" -US-Tw3,11296,GRP_URL,URL,http://nature.berkeley.edu/biometlab/sites.php?tab=US-Tw3 -US-Tw3,24000520,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-Tw3 -US-Tw3,11297,GRP_UTC_OFFSET,UTC_OFFSET,-8 -US-Tw4,11303,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,"Biometeorology Lab, University of California, Berkeley, PI: Dennis Baldocchi" -US-Tw4,11304,GRP_CLIM_AVG,MAT,15.6 -US-Tw4,11304,GRP_CLIM_AVG,MAP,421 -US-Tw4,11304,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Csa -US-Tw4,27000523,GRP_COUNTRY,COUNTRY,USA -US-Tw4,15636,GRP_DOI,DOI,10.17190/AMF/1246151 -US-Tw4,15636,GRP_DOI,DOI_CITATION,"Elke Eichelmann, Robert Shortt, Sara Knox, Camilo Rey Sanchez, Alex Valach, Cove Sturtevant, Daphne Szutu, Joseph Verfaillie, Dennis Baldocchi (2021), AmeriFlux BASE US-Tw4 Twitchell East End Wetland, Ver. 12-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1246151" -US-Tw4,15636,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-Tw4,98280,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Tw4,98280,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Elke Eichelmann -US-Tw4,98280,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Tw4,98280,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,1 -US-Tw4,98280,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0001-9516-7951 -US-Tw4,98280,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,elke.eichelmann@ucd.ie -US-Tw4,98280,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"University of California, Berkeley" -US-Tw4,98280,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,20160112 -US-Tw4,98280,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_END,20181031 -US-Tw4,98276,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Tw4,98276,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Robert Shortt -US-Tw4,98276,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Tw4,98276,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,1 -US-Tw4,98276,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0001-5690-4656 -US-Tw4,98276,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,robert_shortt@berkeley.edu -US-Tw4,98276,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"University of California, Berkeley" -US-Tw4,98276,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,20210720 -US-Tw4,94138,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Tw4,94138,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Sara Knox -US-Tw4,94138,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Tw4,94138,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,2 -US-Tw4,94138,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0003-2255-5835 -US-Tw4,94138,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,sknox01@mail.ubc.ca -US-Tw4,94138,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"University of California, Berkeley" -US-Tw4,94138,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,20150709 -US-Tw4,94138,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_END,20160111 -US-Tw4,98285,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Tw4,98285,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Camilo Rey Sanchez -US-Tw4,98285,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Tw4,98285,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,3 -US-Tw4,98285,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0003-4762-9001 -US-Tw4,98285,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,rey.1@berkeley.edu -US-Tw4,98285,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"University of California, Berkeley" -US-Tw4,98285,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,20181101 -US-Tw4,98285,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_END,20210719 -US-Tw4,98292,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Tw4,98292,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Alex Valach -US-Tw4,98292,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Tw4,98292,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,4 -US-Tw4,98292,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0003-4782-5766 -US-Tw4,98292,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,valach@berkeley.edu -US-Tw4,98292,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"University of California, Berkelely" -US-Tw4,98292,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,20200101 -US-Tw4,98292,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_END,20200922 -US-Tw4,98287,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Tw4,98287,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Cove Sturtevant -US-Tw4,98287,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Tw4,98287,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,5 -US-Tw4,98287,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0002-0341-3228 -US-Tw4,98287,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,csturtevant@battelleecology.org -US-Tw4,98287,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"University of California, Berkelely" -US-Tw4,98287,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,20131125 -US-Tw4,98287,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_END,20150708 -US-Tw4,94104,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Tw4,94104,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Daphne Szutu -US-Tw4,94104,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Tw4,94104,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,7 -US-Tw4,94104,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0001-7698-0461 -US-Tw4,94104,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,daphneszutu@berkeley.edu -US-Tw4,94104,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"University of California, Berkeley" -US-Tw4,94104,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,201612 -US-Tw4,98294,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Tw4,98294,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Joseph Verfaillie -US-Tw4,98294,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Tw4,98294,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,8 -US-Tw4,98294,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0002-7009-8942 -US-Tw4,98294,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,jverfail@berkeley.edu -US-Tw4,98294,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"University of California, Berkeley" -US-Tw4,98294,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,20131125 -US-Tw4,94146,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Tw4,94146,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Dennis Baldocchi -US-Tw4,94146,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Tw4,94146,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,9 -US-Tw4,94146,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0003-3496-4919 -US-Tw4,94146,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,baldocchi@berkeley.edu -US-Tw4,94146,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"University of California, Berkeley" -US-Tw4,94146,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,20131125 -US-Tw4,32385,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,"University of California, Berkeley" -US-Tw4,32385,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-Tw4,32384,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,California Department of Water Resources -US-Tw4,32384,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-Tw4,22209,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Hydrologic event -US-Tw4,22208,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Land cover change -US-Tw4,11305,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Tw4,11305,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-Tw4,11305,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20131125 -US-Tw4,11305,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Tw4,11317,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Tw4,11317,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CH4 -US-Tw4,11317,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20131125 -US-Tw4,11317,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Tw4,91386,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Tw4,91386,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-Tw4,91386,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20131125 -US-Tw4,91386,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Tw4,23000523,GRP_HEADER,SITE_NAME,Twitchell East End Wetland -US-Tw4,88571,GRP_HEIGHTC,HEIGHTC,0.529 -US-Tw4,88571,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Aerenchymatous Plants -US-Tw4,88571,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Tw4,88571,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw4,88571,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,10 -US-Tw4,88571,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw4,88571,GRP_HEIGHTC,HEIGHTC_DATE,20150811 -US-Tw4,88571,GRP_HEIGHTC,HEIGHTC_COMMENT,Green plants from 30cm x 30cm plots 7m to 10m apart along a transect upwind from the tower. From Sophie -US-Tw4,88572,GRP_HEIGHTC,HEIGHTC,0.291 -US-Tw4,88572,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Aerenchymatous Plants -US-Tw4,88572,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Tw4,88572,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw4,88572,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,19 -US-Tw4,88572,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw4,88572,GRP_HEIGHTC,HEIGHTC_DATE,20160804 -US-Tw4,88572,GRP_HEIGHTC,HEIGHTC_COMMENT,Green plants from 30cm x 30cm plots 7m to 10m apart along a transect upwind from the tower. From Sophie -US-Tw4,88574,GRP_HEIGHTC,HEIGHTC,2.824 -US-Tw4,88574,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Aerenchymatous Plants -US-Tw4,88574,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Tw4,88574,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw4,88574,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,19 -US-Tw4,88574,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw4,88574,GRP_HEIGHTC,HEIGHTC_DATE,20160804 -US-Tw4,88574,GRP_HEIGHTC,HEIGHTC_COMMENT,Green plants from 30cm x 30cm plots 7m to 10m apart along a transect upwind from the tower. From Sophie -US-Tw4,88573,GRP_HEIGHTC,HEIGHTC,1.256 -US-Tw4,88573,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Aerenchymatous Plants -US-Tw4,88573,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Tw4,88573,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw4,88573,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Tw4,88573,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw4,88573,GRP_HEIGHTC,HEIGHTC_DATE,20170801 -US-Tw4,88573,GRP_HEIGHTC,HEIGHTC_COMMENT,Green plants from 30cm x 30cm plots 7m to 10m apart along a transect upwind from the tower. From Sophie -US-Tw4,88575,GRP_HEIGHTC,HEIGHTC,3.239 -US-Tw4,88575,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Aerenchymatous Plants -US-Tw4,88575,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Tw4,88575,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Tw4,88575,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Tw4,88575,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Tw4,88575,GRP_HEIGHTC,HEIGHTC_DATE,20170801 -US-Tw4,88575,GRP_HEIGHTC,HEIGHTC_COMMENT,Green plants from 30cm x 30cm plots 7m to 10m apart along a transect upwind from the tower. From Sophie -US-Tw4,11306,GRP_IGBP,IGBP,WET -US-Tw4,11306,GRP_IGBP,IGBP_DATE_START,201401 -US-Tw4,11306,GRP_IGBP,IGBP_COMMENT,cattail and tule vegetation -US-Tw4,11307,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-Tw4,11307,GRP_LAND_OWNERSHIP,LAND_OWNER,State of California -US-Tw4,91895,GRP_LOCATION,LOCATION_LAT,38.1027 -US-Tw4,91895,GRP_LOCATION,LOCATION_LONG,-121.6413 -US-Tw4,91895,GRP_LOCATION,LOCATION_ELEV,-5 -US-Tw4,91895,GRP_LOCATION,LOCATION_DATE_START,20131125 -US-Tw4,11309,GRP_NETWORK,NETWORK,AmeriFlux -US-Tw4,87015,GRP_NETWORK,NETWORK,Phenocam -US-Tw4,1700005814,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chamberlain, S. D., Verfaillie, J., Eichelmann, E., Hemes, K. S., Baldocchi, D. D. (2017) Evaluation Of Density Corrections To Methane Fluxes Measured By Open-Path Eddy Covariance Over Contrasting Landscapes, Boundary-Layer Meteorology, 122(1), 145-167" -US-Tw4,1700005814,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1007/S10546-017-0275-9 -US-Tw4,1700005814,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Tw4,1700006624,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chamberlain, S. D., Verfaillie, J., Eichelmann, E., Hemes, K. S., Baldocchi, D. D. (2017) Evaluation Of Density Corrections To Methane Fluxes Measured By Open-Path Eddy Covariance Over Contrasting Landscapes, Boundary-Layer Meteorology, 16(3), e0248398" -US-Tw4,1700006624,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1007/S10546-017-0275-9 -US-Tw4,1700006624,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Tw4,1700001545,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(8), 108350" -US-Tw4,1700001545,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -US-Tw4,1700001545,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Tw4,1700006411,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Eichelmann, E., Hemes, K. S., Knox, S. H., Oikawa, P. Y., Chamberlain, S. D., Sturtevant, C., Verfaillie, J., Baldocchi, D. D. (2018) The Effect Of Land Cover Type And Structure On Evapotranspiration From Agricultural And Wetland Sites In The Sacramento–San Joaquin River Delta, California, Agricultural And Forest Meteorology, 256-257(1), 179-195" -US-Tw4,1700006411,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2018.03.007 -US-Tw4,1700006411,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Tw4,1700008187,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Eichelmann, E., Hemes, K. S., Knox, S. H., Oikawa, P. Y., Chamberlain, S. D., Sturtevant, C., Verfaillie, J., Baldocchi, D. D. (2018) The Effect Of Land Cover Type And Structure On Evapotranspiration From Agricultural And Wetland Sites In The Sacramento–San Joaquin River Delta, California, Agricultural And Forest Meteorology, 256-257(3), 179-195" -US-Tw4,1700008187,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2018.03.007 -US-Tw4,1700008187,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Tw4,1700000744,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Hemes, K. S., Chamberlain, S. D., Eichelmann, E., Anthony, T., Valach, A., Kasak, K., Szutu, D., Verfaillie, J., Silver, W. L., Baldocchi, D. D. (2019) Assessing The Carbon And Climate Benefit Of Restoring Degraded Agricultural Peat Soils To Managed Wetlands, Agricultural And Forest Meteorology, 268(1), 202-214" -US-Tw4,1700000744,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2019.01.017 -US-Tw4,1700000744,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Tw4,1700003525,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Hemes, K. S., Chamberlain, S. D., Eichelmann, E., Anthony, T., Valach, A., Kasak, K., Szutu, D., Verfaillie, J., Silver, W. L., Baldocchi, D. D. (2019) Assessing The Carbon And Climate Benefit Of Restoring Degraded Agricultural Peat Soils To Managed Wetlands, Agricultural And Forest Meteorology, 268(3), 202-214" -US-Tw4,1700003525,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2019.01.017 -US-Tw4,1700003525,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Tw4,1700001974,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Hemes, K. S., Chamberlain, S. D., Eichelmann, E., Knox, S. H., Baldocchi, D. D. (2018) A Biogeochemical Compromise: The High Methane Cost Of Sequestering Carbon In Restored Wetlands, Geophysical Research Letters, 256-257(1), 179-195" -US-Tw4,1700001974,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018GL077747 -US-Tw4,1700001974,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Tw4,1700000735,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Hemes, K. S., Chamberlain, S. D., Eichelmann, E., Knox, S. H., Baldocchi, D. D. (2018) A Biogeochemical Compromise: The High Methane Cost Of Sequestering Carbon In Restored Wetlands, Geophysical Research Letters, 256-257(3), 179-195" -US-Tw4,1700000735,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018GL077747 -US-Tw4,1700000735,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Tw4,1700002211,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Hemes, K. S., Eichelmann, E., Chamberlain, S., Knox, S. H., Oikawa, P. Y., Sturtevant, C., Verfaillie, J., Szutu, D., Baldocchi, D. D. (2018) A Unique Combination Of Aerodynamic And Surface Properties Contribute To Surface Cooling In Restored Wetlands Of The Sacramento-San Joaquin Delta, California, Journal Of Geophysical Research: Biogeosciences, 256-257(1), 179-195" -US-Tw4,1700002211,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018JG004494 -US-Tw4,1700002211,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Tw4,1700003399,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Hemes, K. S., Eichelmann, E., Chamberlain, S., Knox, S. H., Oikawa, P. Y., Sturtevant, C., Verfaillie, J., Szutu, D., Baldocchi, D. D. (2018) A Unique Combination Of Aerodynamic And Surface Properties Contribute To Surface Cooling In Restored Wetlands Of The Sacramento-San Joaquin Delta, California, Journal Of Geophysical Research: Biogeosciences, 256-257(3), 179-195" -US-Tw4,1700003399,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018JG004494 -US-Tw4,1700003399,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Tw4,1700001557,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Hemes, K. S., Verfaillie, J., Baldocchi, D. D. (2020) Wildfire‐Smoke Aerosols Lead To Increased Light Use Efficiency Among Agricultural And Restored Wetland Land Uses In California'S Central Valley, Journal Of Geophysical Research: Biogeosciences, 20(8), 1619-1633" -US-Tw4,1700001557,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2019JG005380 -US-Tw4,1700001557,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Tw4,1700004233,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Oikawa, P. Y.; Jenerette, G. D.; Knox, S. H.; Sturtevant, C.; Verfaillie, J.; Dronova, I.; Poindexter, C. M. ; Eichelmann, E.; Baldocchi, D. D. (2017) Evaluation of a hierarchy of models reveals importance of substrate limitation for predicting carbon dioxide and methane exchange in restored wetlands, Journal of Geophysical Research: Biogeosciences, 122(1), 145-167" -US-Tw4,1700004233,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/2016JG003438 -US-Tw4,1700004233,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Tw4,1700001548,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Sullivan, R. C., Cook, D. R., Ghate, V. P., Kotamarthi, V. R., Feng, Y. (2019) Improved Spatiotemporal Representativeness And Bias Reduction Of Satellite-Based Evapotranspiration Retrievals Via Use Of In Situ Meteorology And Constrained Canopy Surface Resistance, Journal Of Geophysical Research: Biogeosciences, 124(2), 342-352" -US-Tw4,1700001548,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018JG004744 -US-Tw4,1700001548,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Tw4,1700008097,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Sullivan, R. C., Kotamarthi, V. R., Feng, Y. (2019) Recovering Evapotranspiration Trends From Biased CMIP5 Simulations And Sensitivity To Changing Climate Over North America, Journal Of Hydrometeorology, 20(8), 1619-1633" -US-Tw4,1700008097,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1175/JHM-D-18-0259.1 -US-Tw4,1700008097,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Tw4,1700000729,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Valach, A. C., Kasak, K., Hemes, K. S., Anthony, T. L., Dronova, I., Taddeo, S., Silver, W. L., Szutu, D., Verfaillie, J., Baldocchi, D. D. (2021) Productive Wetlands Restored For Carbon Sequestration Quickly Become Net Co2 Sinks With Site-Level Factors Driving Uptake Variability, Plos One, 16(3), e0248398" -US-Tw4,1700000729,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1371/JOURNAL.PONE.0248398 -US-Tw4,1700000729,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Tw4,1700002298,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Valach, Alex C. Kasak, Kuno Hemes, Kyle S. Szutu, Daphne Verfaillie, Joe Baldocchi, Dennis D. (2021) Carbon Flux Trajectories and Site Conditions from Restored Impounded Marshes in the Sacramento-San Joaquin Delta, Wetland Carbon and Environmental Management, 16(3), e0248398" -US-Tw4,1700002298,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/9781119639305.CH13 -US-Tw4,1700002298,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Tw4,11310,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"The research approach of the University of California, Berkeley Biometeorology Laboratory involves the coordinated use of experimental measurements and theoretical models to understand the physical, biological, and chemical processes that control trace gas fluxes between the biosphere and atmosphere and to quantify their temporal and spatial variations. The research objectives of the Mayberry Wetland, Twitchell Wetland, Sherman Island, Twitchell Island, Twitchell Alfalfa, and Twitchell Corn, and Twitchell East End Wetland sites are as follows: 1) Describe differences in the fluxes of CO2, CH4, H2O, and energy between different land uses; 2) Understand the mechanisms controlling these fluxes; 3) Use ecosystem modeling to understand controls on these mechanisms under different environmental scenarios. These six sites were selected to capture a wide range of inundated conditions within the Sacramento-San Joaquin River Delta. The research focuses on the eddy covariance technique to measure CH4, CO2, H2O, and energy fluxes and works to combine measurements of both net fluxes and partitioned fluxes in order to achieve a mechanistic understanding of the ecological controls on current and future carbon flux in the Delta." -US-Tw4,11311,GRP_SITE_CHAR,TERRAIN,Flat -US-Tw4,11311,GRP_SITE_CHAR,ASPECT,FLAT -US-Tw4,11311,GRP_SITE_CHAR,WIND_DIRECTION,W -US-Tw4,11311,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,800 -US-Tw4,11311,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,0 -US-Tw4,11312,GRP_SITE_DESC,SITE_DESC,"The Twitchell East End Wetland is a newly constructed restored wetland on Twitchell Island, CA. This site and the surrounding region are part of the San Joaquin - Sacramento River Delta drained beginning in the 1850's and subsequently used for agriculture. The site was previously a corn field. The wetland was designed to have a mix of vegetated and open water channels and ponds (due to surface elevation differences). Flooding of the wetland was done gradually beginning in January, 2014. Berms wind throughout the wetland to allow vehicle access. Tule and Cattail plant material from a nearby wetland were spread along the berms immediately prior to flooding to facilitate plant establishment and stabilization of the berms from wind/water erosion. The tower was installed on November 25, 2013." -US-Tw4,11313,GRP_SITE_FUNDING,SITE_FUNDING,California Department of Water Resources -US-Tw4,11314,GRP_STATE,STATE,CA -US-Tw4,11319,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Dennis Baldocchi -US-Tw4,11319,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Tw4,11319,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,baldocchi@berkeley.edu -US-Tw4,11319,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"University of California, Berkeley" -US-Tw4,11319,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Department of Environmental Science, Policy and Management, 137 Mulford Hall, 345 Hilgard Hall,Berkeley, CA USA 94720-3110" -US-Tw4,11318,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Joe Verfaillie -US-Tw4,11318,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,AncContact -US-Tw4,11318,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,jverfail@berkeley.edu -US-Tw4,11318,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"University of California, Berkeley" -US-Tw4,11318,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Department of Environmental Science, Policy and Management, 137 Mulford Hall, 345 Hilgard Hall,Berkeley, CA USA 94720-3110" -US-Tw4,98453,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Robert Shortt -US-Tw4,98453,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-Tw4,98453,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,robert_shortt@berkeley.edu -US-Tw4,98453,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"University of California, Berkeley" -US-Tw4,30346,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Daphne Szutu -US-Tw4,30346,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Technician -US-Tw4,30346,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,daphneszutu@berkeley.edu -US-Tw4,30346,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,UC Berkeley -US-Tw4,98432,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Camilo Rey -US-Tw4,98432,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Affiliate -US-Tw4,98432,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,rey.1@berkeley.edu -US-Tw4,98432,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,UC Berkeley -US-Tw4,86482,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Elke Eichelmann -US-Tw4,86482,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Affiliate -US-Tw4,86482,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,eeichelm@berkeley.edu -US-Tw4,86482,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,UC Berkeley -US-Tw4,24000523,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-Tw4 -US-Tw4,11316,GRP_UTC_OFFSET,UTC_OFFSET,-8 -US-Tw5,84618,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,"Biometeorology Lab, University of California, Berkeley, PI: Dennis Baldocchi" -US-Tw5,84626,GRP_CLIM_AVG,MAT,15.5 -US-Tw5,84626,GRP_CLIM_AVG,MAP,421 -US-Tw5,84626,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Csa -US-Tw5,27000988,GRP_COUNTRY,COUNTRY,USA -US-Tw5,87121,GRP_DOI,DOI,10.17190/AMF/1543380 -US-Tw5,87121,GRP_DOI,DOI_CITATION,"Alex Valach, Kuno Kasak, Daphne Szutu, Joseph Verfaillie, Dennis Baldocchi (2020), AmeriFlux BASE US-Tw5 East Pond Wetland, Ver. 3-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1543380" -US-Tw5,87121,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-Tw5,90788,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Tw5,90788,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Alex Valach -US-Tw5,90788,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Tw5,90788,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,1 -US-Tw5,90788,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0003-4782-5766 -US-Tw5,90788,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,valach@berkeley.edu -US-Tw5,90788,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"University of California, Berkeley" -US-Tw5,90788,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,20180524 -US-Tw5,90788,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_END,20200130 -US-Tw5,90766,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Tw5,90766,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Kuno Kasak -US-Tw5,90766,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Tw5,90766,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,2 -US-Tw5,90766,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0002-0810-2154 -US-Tw5,90766,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,kuno.kasak@ut.ee -US-Tw5,90766,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of Taartu -US-Tw5,90766,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,2019 -US-Tw5,90766,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_END,20200130 -US-Tw5,94056,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Tw5,94056,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Daphne Szutu -US-Tw5,94056,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Tw5,94056,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,7 -US-Tw5,94056,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0001-7698-0461 -US-Tw5,94056,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,daphneszutu@berkeley.edu -US-Tw5,94056,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"University of California, Berkeley" -US-Tw5,94056,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,201612 -US-Tw5,94056,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_END,20200130 -US-Tw5,94022,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Tw5,94022,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Joseph Verfaillie -US-Tw5,94022,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Tw5,94022,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,8 -US-Tw5,94022,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0002-7009-8942 -US-Tw5,94022,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,jverfail@berkeley.edu -US-Tw5,94022,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"University of California, Berkeley" -US-Tw5,94022,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,20180417 -US-Tw5,94022,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_END,20200130 -US-Tw5,94098,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Tw5,94098,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Dennis Baldocchi -US-Tw5,94098,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Tw5,94098,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,9 -US-Tw5,94098,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0003-3496-4919 -US-Tw5,94098,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,baldocchi@berkeley.edu -US-Tw5,94098,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"University of California, Berkeley" -US-Tw5,94098,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,20180417 -US-Tw5,94098,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_END,20200130 -US-Tw5,86625,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,"University of California, Berkeley" -US-Tw5,86625,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-Tw5,86624,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,California Department of Water Resources -US-Tw5,86624,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-Tw5,84622,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Hydrologic event -US-Tw5,84624,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Land cover change -US-Tw5,90995,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Tw5,90995,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-Tw5,90995,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201804250000 -US-Tw5,90995,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20200130 -US-Tw5,90995,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Tw5,90996,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Tw5,90996,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CH4 -US-Tw5,90996,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201804250000 -US-Tw5,90996,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20200130 -US-Tw5,90996,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Tw5,91005,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Tw5,91005,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-Tw5,91005,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201804250000 -US-Tw5,91005,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20200130 -US-Tw5,91005,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Tw5,23000988,GRP_HEADER,SITE_NAME,East Pond Wetland -US-Tw5,84611,GRP_IGBP,IGBP,WET -US-Tw5,84611,GRP_IGBP,IGBP_DATE_START,201809040000 -US-Tw5,84611,GRP_IGBP,IGBP_COMMENT,Schoenoplectus acutus and Typha spp. dominate the site with Azolla covering much of the water surface -US-Tw5,84628,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-Tw5,84628,GRP_LAND_OWNERSHIP,LAND_OWNER,California Department of Water Resources -US-Tw5,94780,GRP_LOCATION,LOCATION_LAT,38.1072 -US-Tw5,94780,GRP_LOCATION,LOCATION_LONG,-121.6426 -US-Tw5,94780,GRP_LOCATION,LOCATION_ELEV,-5 -US-Tw5,94780,GRP_LOCATION,LOCATION_DATE_START,201804250000 -US-Tw5,84609,GRP_NETWORK,NETWORK,AmeriFlux -US-Tw5,87016,GRP_NETWORK,NETWORK,Phenocam -US-Tw5,1700001128,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(), 108350" -US-Tw5,1700001128,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -US-Tw5,1700001128,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Tw5,1700003726,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Hemes, K. S., Chamberlain, S. D., Eichelmann, E., Anthony, T., Valach, A., Kasak, K., Szutu, D., Verfaillie, J., Silver, W. L., Baldocchi, D. D. (2019) Assessing The Carbon And Climate Benefit Of Restoring Degraded Agricultural Peat Soils To Managed Wetlands, Agricultural And Forest Meteorology, 268(), 202-214" -US-Tw5,1700003726,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2019.01.017 -US-Tw5,1700003726,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Tw5,1700007548,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Kasak, K., Valach, A., Rey-Sanchez, C., Kill, K., Shortt, R., Liu, J., Dronova, I., Mander, Ü., Szutu, D., Verfaillie, J., Baldocchi, D. (2020) Experimental Harvesting Of Wetland Plants To Evaluate Trade-Offs Between Reducing Methane Emissions And Removing Nutrients Accumulated To The Biomass In Constructed Wetlands, Science Of The Total Environment, 715(), 136960" -US-Tw5,1700007548,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.SCITOTENV.2020.136960 -US-Tw5,1700007548,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Primary_Citation -US-Tw5,84627,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"The research approach of the University of California, Berkeley Biometeorology Laboratory involves the coordinated use of experimental measurements and theoretical models to understand the physical, biological, and chemical processes that control trace gas fluxes between the biosphere and atmosphere and to quantify their temporal and spatial variations. The research objectives of the Mayberry Wetland, Twitchell West Pond Wetland, Sherman Wetland, Twitchell East End Wetland, Twitchell East Pond Wetland, Bouldin Alfalfa, and Boudlin Corn sites are as follows: 1) Describe differences in the fluxes of CO2, CH4, H2O, and energy between different land uses; 2) Understand the mechanisms controlling these fluxes; 3) Use ecosystem modeling to understand controls on these mechanisms under different environmental scenarios. These seven sites were selected to capture a wide range of inundated conditions within the Sacramento-San Joaquin River Delta. The research focuses on the eddy covariance technique to measure CH4, CO2, H2O, and energy fluxes and works to combine measurements of both net fluxes and partitioned fluxes in order to achieve a mechanistic understanding of the ecological controls on current and future carbon flux in the Delta." -US-Tw5,84619,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"Department of Environmental Science, Policy and Management, 130 Mulford Hall,Berkeley, CA USA 94720-3110" -US-Tw5,84615,GRP_SITE_CHAR,TERRAIN,Flat -US-Tw5,84615,GRP_SITE_CHAR,ASPECT,FLAT -US-Tw5,84615,GRP_SITE_CHAR,WIND_DIRECTION,W -US-Tw5,84615,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,208 -US-Tw5,84615,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,0 -US-Tw5,84616,GRP_SITE_DESC,SITE_DESC,"The Twitchell Wetland site is a 6.5 acre restored wetland on Twitchell Island, that is managed by the California Department of Water Resources (DWR) and the U.S. Geological Survey (USGS). In the fall of 1997, the site was permanently flooded to a depth of approximately 55 cm. The wetland remained fairly unvegetated in patches increasing in size towards the east. The site underwent a major disturbance in 2013 when the vegetation was removed to seed a nearby restored wetland. A flux tower equipped to analyze energy, H2O, CO2, and CH4 fluxes was installed on April 17, 2018." -US-Tw5,84621,GRP_SITE_FUNDING,SITE_FUNDING,California Department of Water Resources -US-Tw5,84620,GRP_STATE,STATE,CA -US-Tw5,84613,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Dennis Baldocchi -US-Tw5,84613,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Tw5,84613,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,baldocchi@berkeley.edu -US-Tw5,84613,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"University of California, Berkeley" -US-Tw5,88060,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Daphne Szutu -US-Tw5,88060,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Technician -US-Tw5,88060,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,daphneszutu@berkeley.edu -US-Tw5,88060,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"University of California, Berkeley" -US-Tw5,88044,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Joe Verfaillie -US-Tw5,88044,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Technician -US-Tw5,88044,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,jverfail@berkeley.edu -US-Tw5,88044,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"University of California, Berkeley" -US-Tw5,95206,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,"Valach, Alex" -US-Tw5,95206,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Affiliate -US-Tw5,95206,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,a.c.valach@gmail.com -US-Tw5,95206,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"University of California, Berkeley" -US-Tw5,84623,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-Tw5,84610,GRP_TOWER_TYPE,TOWER_TYPE,walk-up -US-Tw5,84614,GRP_URL,URL,http://nature.berkeley.edu/biometlab/sites.php?tab=US-Tw5 -US-Tw5,24000988,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-Tw5 -US-Tw5,84617,GRP_UTC_OFFSET,UTC_OFFSET,-8 -US-Tw5,84617,GRP_UTC_OFFSET,UTC_OFFSET_DATE_START,201804250000 -US-Twt,11932,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,California Department of Water Resources; USDA/AFRI -US-Twt,11933,GRP_CLIM_AVG,MAT,15.6 -US-Twt,11933,GRP_CLIM_AVG,MAP,421 -US-Twt,11933,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Csa -US-Twt,27000506,GRP_COUNTRY,COUNTRY,USA -US-Twt,15633,GRP_DOI,DOI,10.17190/AMF/1246140 -US-Twt,15633,GRP_DOI,DOI_CITATION,"Sara Knox, Jaclyn Hatala Matthes, Joseph Verfaillie, Dennis Baldocchi (2018), AmeriFlux BASE US-Twt Twitchell Island, Ver. 6-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1246140" -US-Twt,15633,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-Twt,94025,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Twt,94025,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Sara Knox -US-Twt,94025,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Twt,94025,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,1 -US-Twt,94025,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0003-2255-5835 -US-Twt,94025,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,sknox01@mail.ubc.ca -US-Twt,94025,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"University of California, Berkeley" -US-Twt,94025,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,20090403 -US-Twt,94025,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_END,20170404 -US-Twt,94102,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Twt,94102,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Jaclyn Hatala Matthes -US-Twt,94102,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Twt,94102,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,2 -US-Twt,94102,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0001-7852-4435 -US-Twt,94102,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,jaclyn.hatala.matthes@gmail.com -US-Twt,94102,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"University of California, Berkeley" -US-Twt,94102,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,20090403 -US-Twt,94102,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_END,2013 -US-Twt,94156,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Twt,94156,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Joseph Verfaillie -US-Twt,94156,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Twt,94156,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,8 -US-Twt,94156,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0002-7009-8942 -US-Twt,94156,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,jverfail@berkeley.edu -US-Twt,94156,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"University of California, Berkeley" -US-Twt,94156,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,20090403 -US-Twt,94156,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_END,20170404 -US-Twt,94038,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Twt,94038,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Dennis Baldocchi -US-Twt,94038,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Twt,94038,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,9 -US-Twt,94038,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0003-3496-4919 -US-Twt,94038,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,baldocchi@berkeley.edu -US-Twt,94038,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"University of California, Berkeley" -US-Twt,94038,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,20090403 -US-Twt,94038,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_END,20170404 -US-Twt,32339,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,"University of California, Berkeley" -US-Twt,32339,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-Twt,90761,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,NSF/California Department of Water Resources/USDA-NIFA -US-Twt,90761,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-Twt,22204,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Agriculture -US-Twt,79398,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Twt,79398,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-Twt,79398,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20090425 -US-Twt,79398,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20170404 -US-Twt,79398,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Twt,79399,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Twt,79399,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CH4 -US-Twt,79399,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20090425 -US-Twt,79399,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20170404 -US-Twt,79399,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Twt,91394,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Twt,91394,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-Twt,91394,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20090617 -US-Twt,91394,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20170404 -US-Twt,91394,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Twt,23000506,GRP_HEADER,SITE_NAME,Twitchell Island -US-Twt,89158,GRP_HEIGHTC,HEIGHTC,0 -US-Twt,89158,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Twt,89158,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Twt,89158,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Twt,89158,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,3 -US-Twt,89158,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Twt,89158,GRP_HEIGHTC,HEIGHTC_DATE,20090804 -US-Twt,89158,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured from clip plot sampled for biomass and LAI/PAI. -US-Twt,89156,GRP_HEIGHTC,HEIGHTC,0.04 -US-Twt,89156,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Twt,89156,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Twt,89156,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Twt,89156,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,5 -US-Twt,89156,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Twt,89156,GRP_HEIGHTC,HEIGHTC_DATE,20120712 -US-Twt,89156,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured from clip plot sampled for biomass and LAI/PAI. -US-Twt,89197,GRP_HEIGHTC,HEIGHTC,0.34 -US-Twt,89197,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Twt,89197,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Twt,89197,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Twt,89197,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,5 -US-Twt,89197,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Twt,89197,GRP_HEIGHTC,HEIGHTC_DATE,20120712 -US-Twt,89197,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured from clip plot sampled for biomass and LAI/PAI. -US-Twt,89164,GRP_HEIGHTC,HEIGHTC,0.13 -US-Twt,89164,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Twt,89164,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Twt,89164,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Twt,89164,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,5 -US-Twt,89164,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Twt,89164,GRP_HEIGHTC,HEIGHTC_DATE,20120719 -US-Twt,89164,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured from clip plot sampled for biomass and LAI/PAI. -US-Twt,89166,GRP_HEIGHTC,HEIGHTC,0.48 -US-Twt,89166,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Twt,89166,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Twt,89166,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Twt,89166,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,5 -US-Twt,89166,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Twt,89166,GRP_HEIGHTC,HEIGHTC_DATE,20120719 -US-Twt,89166,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured from clip plot sampled for biomass and LAI/PAI. -US-Twt,89169,GRP_HEIGHTC,HEIGHTC,0.16 -US-Twt,89169,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Twt,89169,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Twt,89169,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Twt,89169,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,5 -US-Twt,89169,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Twt,89169,GRP_HEIGHTC,HEIGHTC_DATE,20120726 -US-Twt,89169,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured from clip plot sampled for biomass and LAI/PAI. -US-Twt,89186,GRP_HEIGHTC,HEIGHTC,0.44 -US-Twt,89186,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Twt,89186,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Twt,89186,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Twt,89186,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,5 -US-Twt,89186,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Twt,89186,GRP_HEIGHTC,HEIGHTC_DATE,20120726 -US-Twt,89186,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured from clip plot sampled for biomass and LAI/PAI. -US-Twt,89200,GRP_HEIGHTC,HEIGHTC,0.62 -US-Twt,89200,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Twt,89200,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Twt,89200,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Twt,89200,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,5 -US-Twt,89200,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Twt,89200,GRP_HEIGHTC,HEIGHTC_DATE,20120802 -US-Twt,89200,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured from clip plot sampled for biomass and LAI/PAI. -US-Twt,89206,GRP_HEIGHTC,HEIGHTC,0.08 -US-Twt,89206,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Twt,89206,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Twt,89206,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Twt,89206,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,5 -US-Twt,89206,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Twt,89206,GRP_HEIGHTC,HEIGHTC_DATE,20120802 -US-Twt,89206,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured from clip plot sampled for biomass and LAI/PAI. -US-Twt,89203,GRP_HEIGHTC,HEIGHTC,0.56 -US-Twt,89203,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Twt,89203,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Twt,89203,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Twt,89203,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,5 -US-Twt,89203,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Twt,89203,GRP_HEIGHTC,HEIGHTC_DATE,20120809 -US-Twt,89203,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured from clip plot sampled for biomass and LAI/PAI. -US-Twt,89210,GRP_HEIGHTC,HEIGHTC,0.07 -US-Twt,89210,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Twt,89210,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Twt,89210,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Twt,89210,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,5 -US-Twt,89210,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Twt,89210,GRP_HEIGHTC,HEIGHTC_DATE,20120809 -US-Twt,89210,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured from clip plot sampled for biomass and LAI/PAI. -US-Twt,89145,GRP_HEIGHTC,HEIGHTC,0.72 -US-Twt,89145,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Twt,89145,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Twt,89145,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Twt,89145,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,5 -US-Twt,89145,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Twt,89145,GRP_HEIGHTC,HEIGHTC_DATE,20120816 -US-Twt,89145,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured from clip plot sampled for biomass and LAI/PAI. -US-Twt,89212,GRP_HEIGHTC,HEIGHTC,0.06 -US-Twt,89212,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Twt,89212,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Twt,89212,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Twt,89212,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,5 -US-Twt,89212,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Twt,89212,GRP_HEIGHTC,HEIGHTC_DATE,20120816 -US-Twt,89212,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured from clip plot sampled for biomass and LAI/PAI. -US-Twt,89152,GRP_HEIGHTC,HEIGHTC,0.06 -US-Twt,89152,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Twt,89152,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Twt,89152,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Twt,89152,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,5 -US-Twt,89152,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Twt,89152,GRP_HEIGHTC,HEIGHTC_DATE,20120823 -US-Twt,89152,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured from clip plot sampled for biomass and LAI/PAI. -US-Twt,89167,GRP_HEIGHTC,HEIGHTC,0.78 -US-Twt,89167,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Twt,89167,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Twt,89167,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Twt,89167,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,5 -US-Twt,89167,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Twt,89167,GRP_HEIGHTC,HEIGHTC_DATE,20120823 -US-Twt,89167,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured from clip plot sampled for biomass and LAI/PAI. -US-Twt,89178,GRP_HEIGHTC,HEIGHTC,1.12 -US-Twt,89178,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Twt,89178,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Twt,89178,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Twt,89178,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,4 -US-Twt,89178,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Twt,89178,GRP_HEIGHTC,HEIGHTC_DATE,20120830 -US-Twt,89178,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured from clip plot sampled for biomass and LAI/PAI. -US-Twt,89194,GRP_HEIGHTC,HEIGHTC,0.06 -US-Twt,89194,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Twt,89194,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Twt,89194,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Twt,89194,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,4 -US-Twt,89194,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Twt,89194,GRP_HEIGHTC,HEIGHTC_DATE,20120830 -US-Twt,89194,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured from clip plot sampled for biomass and LAI/PAI. -US-Twt,89159,GRP_HEIGHTC,HEIGHTC,0.36 -US-Twt,89159,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Twt,89159,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Twt,89159,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Twt,89159,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,4 -US-Twt,89159,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Twt,89159,GRP_HEIGHTC,HEIGHTC_DATE,20120913 -US-Twt,89159,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured from clip plot sampled for biomass and LAI/PAI. -US-Twt,89217,GRP_HEIGHTC,HEIGHTC,1.18 -US-Twt,89217,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Twt,89217,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Twt,89217,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Twt,89217,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,4 -US-Twt,89217,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Twt,89217,GRP_HEIGHTC,HEIGHTC_DATE,20120913 -US-Twt,89217,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured from clip plot sampled for biomass and LAI/PAI. -US-Twt,89195,GRP_HEIGHTC,HEIGHTC,0.07 -US-Twt,89195,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Twt,89195,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Twt,89195,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Twt,89195,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,5 -US-Twt,89195,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Twt,89195,GRP_HEIGHTC,HEIGHTC_DATE,20120920 -US-Twt,89195,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured from clip plot sampled for biomass and LAI/PAI. -US-Twt,89202,GRP_HEIGHTC,HEIGHTC,0.89 -US-Twt,89202,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Twt,89202,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Twt,89202,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Twt,89202,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,5 -US-Twt,89202,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Twt,89202,GRP_HEIGHTC,HEIGHTC_DATE,20120920 -US-Twt,89202,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured from clip plot sampled for biomass and LAI/PAI. -US-Twt,89170,GRP_HEIGHTC,HEIGHTC,0.83 -US-Twt,89170,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Twt,89170,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Twt,89170,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Twt,89170,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,5 -US-Twt,89170,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Twt,89170,GRP_HEIGHTC,HEIGHTC_DATE,20120927 -US-Twt,89170,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured from clip plot sampled for biomass and LAI/PAI. -US-Twt,89171,GRP_HEIGHTC,HEIGHTC,0.04 -US-Twt,89171,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Twt,89171,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Twt,89171,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Twt,89171,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,5 -US-Twt,89171,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Twt,89171,GRP_HEIGHTC,HEIGHTC_DATE,20120927 -US-Twt,89171,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured from clip plot sampled for biomass and LAI/PAI. -US-Twt,89161,GRP_HEIGHTC,HEIGHTC,0.26 -US-Twt,89161,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Twt,89161,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Twt,89161,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Twt,89161,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,5 -US-Twt,89161,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Twt,89161,GRP_HEIGHTC,HEIGHTC_DATE,20121005 -US-Twt,89161,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured from clip plot sampled for biomass and LAI/PAI. -US-Twt,89172,GRP_HEIGHTC,HEIGHTC,0.93 -US-Twt,89172,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Twt,89172,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Twt,89172,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Twt,89172,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,5 -US-Twt,89172,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Twt,89172,GRP_HEIGHTC,HEIGHTC_DATE,20121005 -US-Twt,89172,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured from clip plot sampled for biomass and LAI/PAI. -US-Twt,89176,GRP_HEIGHTC,HEIGHTC,0 -US-Twt,89176,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Twt,89176,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Twt,89176,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Twt,89176,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,5 -US-Twt,89176,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Twt,89176,GRP_HEIGHTC,HEIGHTC_DATE,20121011 -US-Twt,89176,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured from clip plot sampled for biomass and LAI/PAI. -US-Twt,89198,GRP_HEIGHTC,HEIGHTC,0.8 -US-Twt,89198,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Twt,89198,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Twt,89198,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Twt,89198,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,5 -US-Twt,89198,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Twt,89198,GRP_HEIGHTC,HEIGHTC_DATE,20121011 -US-Twt,89198,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured from clip plot sampled for biomass and LAI/PAI. -US-Twt,89163,GRP_HEIGHTC,HEIGHTC,0.16 -US-Twt,89163,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Twt,89163,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Twt,89163,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Twt,89163,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,5 -US-Twt,89163,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Twt,89163,GRP_HEIGHTC,HEIGHTC_DATE,20121018 -US-Twt,89163,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured from clip plot sampled for biomass and LAI/PAI. -US-Twt,89175,GRP_HEIGHTC,HEIGHTC,0.89 -US-Twt,89175,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Twt,89175,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Twt,89175,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Twt,89175,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,5 -US-Twt,89175,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Twt,89175,GRP_HEIGHTC,HEIGHTC_DATE,20121018 -US-Twt,89175,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured from clip plot sampled for biomass and LAI/PAI. -US-Twt,89189,GRP_HEIGHTC,HEIGHTC,0.07 -US-Twt,89189,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Twt,89189,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Twt,89189,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Twt,89189,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,4 -US-Twt,89189,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Twt,89189,GRP_HEIGHTC,HEIGHTC_DATE,20121025 -US-Twt,89189,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured from clip plot sampled for biomass and LAI/PAI. -US-Twt,89213,GRP_HEIGHTC,HEIGHTC,0.84 -US-Twt,89213,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Twt,89213,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Twt,89213,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Twt,89213,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,4 -US-Twt,89213,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Twt,89213,GRP_HEIGHTC,HEIGHTC_DATE,20121025 -US-Twt,89213,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured from clip plot sampled for biomass and LAI/PAI. -US-Twt,89154,GRP_HEIGHTC,HEIGHTC,0.15 -US-Twt,89154,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Twt,89154,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Twt,89154,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Twt,89154,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,5 -US-Twt,89154,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Twt,89154,GRP_HEIGHTC,HEIGHTC_DATE,20130524 -US-Twt,89154,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured from clip plot sampled for biomass and LAI/PAI. -US-Twt,89155,GRP_HEIGHTC,HEIGHTC,0.02 -US-Twt,89155,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Twt,89155,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Twt,89155,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Twt,89155,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,5 -US-Twt,89155,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Twt,89155,GRP_HEIGHTC,HEIGHTC_DATE,20130524 -US-Twt,89155,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured from clip plot sampled for biomass and LAI/PAI. -US-Twt,89157,GRP_HEIGHTC,HEIGHTC,0.24 -US-Twt,89157,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Twt,89157,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Twt,89157,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Twt,89157,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,5 -US-Twt,89157,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Twt,89157,GRP_HEIGHTC,HEIGHTC_DATE,20130531 -US-Twt,89157,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured from clip plot sampled for biomass and LAI/PAI. -US-Twt,89168,GRP_HEIGHTC,HEIGHTC,0.04 -US-Twt,89168,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Twt,89168,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Twt,89168,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Twt,89168,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,5 -US-Twt,89168,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Twt,89168,GRP_HEIGHTC,HEIGHTC_DATE,20130531 -US-Twt,89168,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured from clip plot sampled for biomass and LAI/PAI. -US-Twt,89146,GRP_HEIGHTC,HEIGHTC,0.32 -US-Twt,89146,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Twt,89146,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Twt,89146,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Twt,89146,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,5 -US-Twt,89146,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Twt,89146,GRP_HEIGHTC,HEIGHTC_DATE,20130605 -US-Twt,89146,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured from clip plot sampled for biomass and LAI/PAI. -US-Twt,89214,GRP_HEIGHTC,HEIGHTC,0.02 -US-Twt,89214,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Twt,89214,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Twt,89214,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Twt,89214,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,5 -US-Twt,89214,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Twt,89214,GRP_HEIGHTC,HEIGHTC_DATE,20130605 -US-Twt,89214,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured from clip plot sampled for biomass and LAI/PAI. -US-Twt,89181,GRP_HEIGHTC,HEIGHTC,0.37 -US-Twt,89181,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Twt,89181,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Twt,89181,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Twt,89181,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,5 -US-Twt,89181,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Twt,89181,GRP_HEIGHTC,HEIGHTC_DATE,20130613 -US-Twt,89181,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured from clip plot sampled for biomass and LAI/PAI. -US-Twt,89191,GRP_HEIGHTC,HEIGHTC,0.03 -US-Twt,89191,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Twt,89191,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Twt,89191,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Twt,89191,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,5 -US-Twt,89191,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Twt,89191,GRP_HEIGHTC,HEIGHTC_DATE,20130613 -US-Twt,89191,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured from clip plot sampled for biomass and LAI/PAI. -US-Twt,89179,GRP_HEIGHTC,HEIGHTC,0.03 -US-Twt,89179,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Twt,89179,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Twt,89179,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Twt,89179,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,5 -US-Twt,89179,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Twt,89179,GRP_HEIGHTC,HEIGHTC_DATE,20130620 -US-Twt,89179,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured from clip plot sampled for biomass and LAI/PAI. -US-Twt,89196,GRP_HEIGHTC,HEIGHTC,0.3 -US-Twt,89196,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Twt,89196,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Twt,89196,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Twt,89196,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,5 -US-Twt,89196,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Twt,89196,GRP_HEIGHTC,HEIGHTC_DATE,20130620 -US-Twt,89196,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured from clip plot sampled for biomass and LAI/PAI. -US-Twt,89149,GRP_HEIGHTC,HEIGHTC,0.04 -US-Twt,89149,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Twt,89149,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Twt,89149,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Twt,89149,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,5 -US-Twt,89149,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Twt,89149,GRP_HEIGHTC,HEIGHTC_DATE,20130627 -US-Twt,89149,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured from clip plot sampled for biomass and LAI/PAI. -US-Twt,89204,GRP_HEIGHTC,HEIGHTC,0.44 -US-Twt,89204,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Twt,89204,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Twt,89204,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Twt,89204,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,5 -US-Twt,89204,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Twt,89204,GRP_HEIGHTC,HEIGHTC_DATE,20130627 -US-Twt,89204,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured from clip plot sampled for biomass and LAI/PAI. -US-Twt,89162,GRP_HEIGHTC,HEIGHTC,0 -US-Twt,89162,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Twt,89162,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Twt,89162,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Twt,89162,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,5 -US-Twt,89162,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Twt,89162,GRP_HEIGHTC,HEIGHTC_DATE,20130710 -US-Twt,89162,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured from clip plot sampled for biomass and LAI/PAI. -US-Twt,89207,GRP_HEIGHTC,HEIGHTC,0.6 -US-Twt,89207,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Twt,89207,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Twt,89207,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Twt,89207,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,5 -US-Twt,89207,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Twt,89207,GRP_HEIGHTC,HEIGHTC_DATE,20130710 -US-Twt,89207,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured from clip plot sampled for biomass and LAI/PAI. -US-Twt,89165,GRP_HEIGHTC,HEIGHTC,0.67 -US-Twt,89165,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Twt,89165,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Twt,89165,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Twt,89165,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,5 -US-Twt,89165,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Twt,89165,GRP_HEIGHTC,HEIGHTC_DATE,20130716 -US-Twt,89165,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured from clip plot sampled for biomass and LAI/PAI. -US-Twt,89208,GRP_HEIGHTC,HEIGHTC,0.02 -US-Twt,89208,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Twt,89208,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Twt,89208,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Twt,89208,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,5 -US-Twt,89208,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Twt,89208,GRP_HEIGHTC,HEIGHTC_DATE,20130716 -US-Twt,89208,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured from clip plot sampled for biomass and LAI/PAI. -US-Twt,89148,GRP_HEIGHTC,HEIGHTC,0.77 -US-Twt,89148,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Twt,89148,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Twt,89148,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Twt,89148,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,5 -US-Twt,89148,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Twt,89148,GRP_HEIGHTC,HEIGHTC_DATE,20130726 -US-Twt,89148,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured from clip plot sampled for biomass and LAI/PAI. -US-Twt,89199,GRP_HEIGHTC,HEIGHTC,0.07 -US-Twt,89199,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Twt,89199,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Twt,89199,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Twt,89199,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,5 -US-Twt,89199,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Twt,89199,GRP_HEIGHTC,HEIGHTC_DATE,20130726 -US-Twt,89199,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured from clip plot sampled for biomass and LAI/PAI. -US-Twt,89190,GRP_HEIGHTC,HEIGHTC,0.3 -US-Twt,89190,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Twt,89190,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Twt,89190,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Twt,89190,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,5 -US-Twt,89190,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Twt,89190,GRP_HEIGHTC,HEIGHTC_DATE,20130731 -US-Twt,89190,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured from clip plot sampled for biomass and LAI/PAI. -US-Twt,89211,GRP_HEIGHTC,HEIGHTC,0.64 -US-Twt,89211,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Twt,89211,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Twt,89211,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Twt,89211,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,5 -US-Twt,89211,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Twt,89211,GRP_HEIGHTC,HEIGHTC_DATE,20130731 -US-Twt,89211,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured from clip plot sampled for biomass and LAI/PAI. -US-Twt,89160,GRP_HEIGHTC,HEIGHTC,0.08 -US-Twt,89160,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Twt,89160,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Twt,89160,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Twt,89160,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,5 -US-Twt,89160,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Twt,89160,GRP_HEIGHTC,HEIGHTC_DATE,20130805 -US-Twt,89160,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured from clip plot sampled for biomass and LAI/PAI. -US-Twt,89187,GRP_HEIGHTC,HEIGHTC,0.82 -US-Twt,89187,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Twt,89187,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Twt,89187,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Twt,89187,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,5 -US-Twt,89187,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Twt,89187,GRP_HEIGHTC,HEIGHTC_DATE,20130805 -US-Twt,89187,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured from clip plot sampled for biomass and LAI/PAI. -US-Twt,89173,GRP_HEIGHTC,HEIGHTC,0.07 -US-Twt,89173,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Twt,89173,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Twt,89173,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Twt,89173,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,5 -US-Twt,89173,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Twt,89173,GRP_HEIGHTC,HEIGHTC_DATE,20130815 -US-Twt,89173,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured from clip plot sampled for biomass and LAI/PAI. -US-Twt,89201,GRP_HEIGHTC,HEIGHTC,0.74 -US-Twt,89201,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Twt,89201,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Twt,89201,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Twt,89201,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,5 -US-Twt,89201,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Twt,89201,GRP_HEIGHTC,HEIGHTC_DATE,20130815 -US-Twt,89201,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured from clip plot sampled for biomass and LAI/PAI. -US-Twt,89188,GRP_HEIGHTC,HEIGHTC,0.02 -US-Twt,89188,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Twt,89188,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Twt,89188,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Twt,89188,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,5 -US-Twt,89188,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Twt,89188,GRP_HEIGHTC,HEIGHTC_DATE,20130829 -US-Twt,89188,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured from clip plot sampled for biomass and LAI/PAI. -US-Twt,89209,GRP_HEIGHTC,HEIGHTC,0.69 -US-Twt,89209,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Twt,89209,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Twt,89209,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Twt,89209,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,5 -US-Twt,89209,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Twt,89209,GRP_HEIGHTC,HEIGHTC_DATE,20130829 -US-Twt,89209,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured from clip plot sampled for biomass and LAI/PAI. -US-Twt,89205,GRP_HEIGHTC,HEIGHTC,0.64 -US-Twt,89205,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Twt,89205,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Twt,89205,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Twt,89205,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,5 -US-Twt,89205,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Twt,89205,GRP_HEIGHTC,HEIGHTC_DATE,20130911 -US-Twt,89205,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured from clip plot sampled for biomass and LAI/PAI. -US-Twt,89216,GRP_HEIGHTC,HEIGHTC,0.02 -US-Twt,89216,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Twt,89216,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Twt,89216,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Twt,89216,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,5 -US-Twt,89216,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Twt,89216,GRP_HEIGHTC,HEIGHTC_DATE,20130911 -US-Twt,89216,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured from clip plot sampled for biomass and LAI/PAI. -US-Twt,89182,GRP_HEIGHTC,HEIGHTC,0.89 -US-Twt,89182,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Twt,89182,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Twt,89182,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Twt,89182,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,5 -US-Twt,89182,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Twt,89182,GRP_HEIGHTC,HEIGHTC_DATE,20130920 -US-Twt,89182,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured from clip plot sampled for biomass and LAI/PAI. -US-Twt,89184,GRP_HEIGHTC,HEIGHTC,0.02 -US-Twt,89184,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Twt,89184,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Twt,89184,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Twt,89184,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,5 -US-Twt,89184,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Twt,89184,GRP_HEIGHTC,HEIGHTC_DATE,20130920 -US-Twt,89184,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured from clip plot sampled for biomass and LAI/PAI. -US-Twt,89453,GRP_HEIGHTC,HEIGHTC,0.115 -US-Twt,89453,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Twt,89453,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Twt,89453,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Twt,89453,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Twt,89453,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Twt,89453,GRP_HEIGHTC,HEIGHTC_DATE,20140521 -US-Twt,89466,GRP_HEIGHTC,HEIGHTC,0.035 -US-Twt,89466,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Twt,89466,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Twt,89466,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Twt,89466,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Twt,89466,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Twt,89466,GRP_HEIGHTC,HEIGHTC_DATE,20140521 -US-Twt,89421,GRP_HEIGHTC,HEIGHTC,0.036 -US-Twt,89421,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Twt,89421,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Twt,89421,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Twt,89421,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Twt,89421,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Twt,89421,GRP_HEIGHTC,HEIGHTC_DATE,20140529 -US-Twt,89430,GRP_HEIGHTC,HEIGHTC,0.122 -US-Twt,89430,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Twt,89430,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Twt,89430,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Twt,89430,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Twt,89430,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Twt,89430,GRP_HEIGHTC,HEIGHTC_DATE,20140529 -US-Twt,89185,GRP_HEIGHTC,HEIGHTC,0.02 -US-Twt,89185,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Twt,89185,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Twt,89185,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Twt,89185,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,5 -US-Twt,89185,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Twt,89185,GRP_HEIGHTC,HEIGHTC_DATE,20140606 -US-Twt,89185,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured from clip plot sampled for biomass and LAI/PAI. -US-Twt,89215,GRP_HEIGHTC,HEIGHTC,0.18 -US-Twt,89215,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Twt,89215,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Twt,89215,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Twt,89215,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,5 -US-Twt,89215,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Twt,89215,GRP_HEIGHTC,HEIGHTC_DATE,20140606 -US-Twt,89215,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured from clip plot sampled for biomass and LAI/PAI. -US-Twt,89426,GRP_HEIGHTC,HEIGHTC,0.024 -US-Twt,89426,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Twt,89426,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Twt,89426,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Twt,89426,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Twt,89426,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Twt,89426,GRP_HEIGHTC,HEIGHTC_DATE,20140612 -US-Twt,89426,GRP_HEIGHTC,HEIGHTC_COMMENT,Was originally recorded as inches so converted to cm -US-Twt,89432,GRP_HEIGHTC,HEIGHTC,0.186 -US-Twt,89432,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Twt,89432,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Twt,89432,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Twt,89432,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Twt,89432,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Twt,89432,GRP_HEIGHTC,HEIGHTC_DATE,20140612 -US-Twt,89432,GRP_HEIGHTC,HEIGHTC_COMMENT,Was originally recorded as inches so converted to cm -US-Twt,89463,GRP_HEIGHTC,HEIGHTC,0.024 -US-Twt,89463,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Twt,89463,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Twt,89463,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Twt,89463,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Twt,89463,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Twt,89463,GRP_HEIGHTC,HEIGHTC_DATE,20140617 -US-Twt,89470,GRP_HEIGHTC,HEIGHTC,0.244 -US-Twt,89470,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Twt,89470,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Twt,89470,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Twt,89470,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Twt,89470,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Twt,89470,GRP_HEIGHTC,HEIGHTC_DATE,20140617 -US-Twt,89183,GRP_HEIGHTC,HEIGHTC,0.01 -US-Twt,89183,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Twt,89183,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Twt,89183,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Twt,89183,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,5 -US-Twt,89183,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Twt,89183,GRP_HEIGHTC,HEIGHTC_DATE,20140618 -US-Twt,89183,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured from clip plot sampled for biomass and LAI/PAI. -US-Twt,89192,GRP_HEIGHTC,HEIGHTC,0.25 -US-Twt,89192,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Twt,89192,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Twt,89192,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Twt,89192,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,5 -US-Twt,89192,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Twt,89192,GRP_HEIGHTC,HEIGHTC_DATE,20140618 -US-Twt,89192,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured from clip plot sampled for biomass and LAI/PAI. -US-Twt,89460,GRP_HEIGHTC,HEIGHTC,0.4 -US-Twt,89460,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Twt,89460,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Twt,89460,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Twt,89460,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Twt,89460,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Twt,89460,GRP_HEIGHTC,HEIGHTC_DATE,20140626 -US-Twt,89464,GRP_HEIGHTC,HEIGHTC,0.054 -US-Twt,89464,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Twt,89464,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Twt,89464,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Twt,89464,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Twt,89464,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Twt,89464,GRP_HEIGHTC,HEIGHTC_DATE,20140626 -US-Twt,89150,GRP_HEIGHTC,HEIGHTC,0.43 -US-Twt,89150,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Twt,89150,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Twt,89150,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Twt,89150,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,5 -US-Twt,89150,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Twt,89150,GRP_HEIGHTC,HEIGHTC_DATE,20140627 -US-Twt,89150,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured from clip plot sampled for biomass and LAI/PAI. -US-Twt,89193,GRP_HEIGHTC,HEIGHTC,0.06 -US-Twt,89193,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Twt,89193,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Twt,89193,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Twt,89193,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,5 -US-Twt,89193,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Twt,89193,GRP_HEIGHTC,HEIGHTC_DATE,20140627 -US-Twt,89193,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured from clip plot sampled for biomass and LAI/PAI. -US-Twt,89439,GRP_HEIGHTC,HEIGHTC,0.455 -US-Twt,89439,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Twt,89439,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Twt,89439,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Twt,89439,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,18 -US-Twt,89439,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Twt,89439,GRP_HEIGHTC,HEIGHTC_DATE,20140702 -US-Twt,89439,GRP_HEIGHTC,HEIGHTC_COMMENT,Katheleen noted a fair number of caterpillars in the field eating the leaves -US-Twt,89459,GRP_HEIGHTC,HEIGHTC,0.042 -US-Twt,89459,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Twt,89459,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Twt,89459,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Twt,89459,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,18 -US-Twt,89459,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Twt,89459,GRP_HEIGHTC,HEIGHTC_DATE,20140702 -US-Twt,89459,GRP_HEIGHTC,HEIGHTC_COMMENT,Katheleen noted a fair number of caterpillars in the field eating the leaves -US-Twt,89147,GRP_HEIGHTC,HEIGHTC,0.06 -US-Twt,89147,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Twt,89147,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Twt,89147,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Twt,89147,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,5 -US-Twt,89147,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Twt,89147,GRP_HEIGHTC,HEIGHTC_DATE,20140709 -US-Twt,89147,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured from clip plot sampled for biomass and LAI/PAI. -US-Twt,89153,GRP_HEIGHTC,HEIGHTC,0.47 -US-Twt,89153,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Twt,89153,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Twt,89153,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Twt,89153,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,5 -US-Twt,89153,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Twt,89153,GRP_HEIGHTC,HEIGHTC_DATE,20140709 -US-Twt,89153,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured from clip plot sampled for biomass and LAI/PAI. -US-Twt,89458,GRP_HEIGHTC,HEIGHTC,0.107 -US-Twt,89458,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Twt,89458,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Twt,89458,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Twt,89458,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Twt,89458,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Twt,89458,GRP_HEIGHTC,HEIGHTC_DATE,20140715 -US-Twt,89458,GRP_HEIGHTC,HEIGHTC_COMMENT,Katheleen noted a fair number of caterpillars in the field eating the leaves -US-Twt,89472,GRP_HEIGHTC,HEIGHTC,0.647 -US-Twt,89472,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Twt,89472,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Twt,89472,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Twt,89472,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Twt,89472,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Twt,89472,GRP_HEIGHTC,HEIGHTC_DATE,20140715 -US-Twt,89472,GRP_HEIGHTC,HEIGHTC_COMMENT,Katheleen noted a fair number of caterpillars in the field eating the leaves -US-Twt,89429,GRP_HEIGHTC,HEIGHTC,0.073 -US-Twt,89429,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Twt,89429,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Twt,89429,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Twt,89429,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Twt,89429,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Twt,89429,GRP_HEIGHTC,HEIGHTC_DATE,20140723 -US-Twt,89467,GRP_HEIGHTC,HEIGHTC,0.674 -US-Twt,89467,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Twt,89467,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Twt,89467,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Twt,89467,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Twt,89467,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Twt,89467,GRP_HEIGHTC,HEIGHTC_DATE,20140723 -US-Twt,89457,GRP_HEIGHTC,HEIGHTC,0.741 -US-Twt,89457,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Twt,89457,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Twt,89457,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Twt,89457,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Twt,89457,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Twt,89457,GRP_HEIGHTC,HEIGHTC_DATE,20140731 -US-Twt,89476,GRP_HEIGHTC,HEIGHTC,0.094 -US-Twt,89476,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Twt,89476,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Twt,89476,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Twt,89476,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Twt,89476,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Twt,89476,GRP_HEIGHTC,HEIGHTC_DATE,20140731 -US-Twt,89423,GRP_HEIGHTC,HEIGHTC,0.704 -US-Twt,89423,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Twt,89423,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Twt,89423,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Twt,89423,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Twt,89423,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Twt,89423,GRP_HEIGHTC,HEIGHTC_DATE,20140806 -US-Twt,89423,GRP_HEIGHTC,HEIGHTC_COMMENT,starting to seed -US-Twt,89437,GRP_HEIGHTC,HEIGHTC,0.082 -US-Twt,89437,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Twt,89437,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Twt,89437,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Twt,89437,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Twt,89437,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Twt,89437,GRP_HEIGHTC,HEIGHTC_DATE,20140806 -US-Twt,89437,GRP_HEIGHTC,HEIGHTC_COMMENT,starting to seed -US-Twt,89151,GRP_HEIGHTC,HEIGHTC,0.04 -US-Twt,89151,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Twt,89151,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Twt,89151,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Twt,89151,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,5 -US-Twt,89151,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Twt,89151,GRP_HEIGHTC,HEIGHTC_DATE,20140807 -US-Twt,89151,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured from clip plot sampled for biomass and LAI/PAI. -US-Twt,89174,GRP_HEIGHTC,HEIGHTC,0.7 -US-Twt,89174,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Twt,89174,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Twt,89174,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Twt,89174,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,5 -US-Twt,89174,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Twt,89174,GRP_HEIGHTC,HEIGHTC_DATE,20140807 -US-Twt,89174,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured from clip plot sampled for biomass and LAI/PAI. -US-Twt,89422,GRP_HEIGHTC,HEIGHTC,0.784 -US-Twt,89422,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Twt,89422,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Twt,89422,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Twt,89422,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Twt,89422,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Twt,89422,GRP_HEIGHTC,HEIGHTC_DATE,20140813 -US-Twt,89422,GRP_HEIGHTC,HEIGHTC_COMMENT,big and green -US-Twt,89465,GRP_HEIGHTC,HEIGHTC,0.06 -US-Twt,89465,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Twt,89465,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Twt,89465,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Twt,89465,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Twt,89465,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Twt,89465,GRP_HEIGHTC,HEIGHTC_DATE,20140813 -US-Twt,89465,GRP_HEIGHTC,HEIGHTC_COMMENT,big and green -US-Twt,89440,GRP_HEIGHTC,HEIGHTC,0.76 -US-Twt,89440,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Twt,89440,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Twt,89440,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Twt,89440,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Twt,89440,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Twt,89440,GRP_HEIGHTC,HEIGHTC_DATE,20140819 -US-Twt,89440,GRP_HEIGHTC,HEIGHTC_COMMENT,seeding heavily -US-Twt,89455,GRP_HEIGHTC,HEIGHTC,0.034 -US-Twt,89455,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Twt,89455,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Twt,89455,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Twt,89455,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Twt,89455,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Twt,89455,GRP_HEIGHTC,HEIGHTC_DATE,20140819 -US-Twt,89455,GRP_HEIGHTC,HEIGHTC_COMMENT,seeding heavily -US-Twt,89438,GRP_HEIGHTC,HEIGHTC,0.676 -US-Twt,89438,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Twt,89438,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Twt,89438,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Twt,89438,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Twt,89438,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Twt,89438,GRP_HEIGHTC,HEIGHTC_DATE,20140827 -US-Twt,89438,GRP_HEIGHTC,HEIGHTC_COMMENT,seeding heavily -US-Twt,89462,GRP_HEIGHTC,HEIGHTC,0.029 -US-Twt,89462,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Twt,89462,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Twt,89462,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Twt,89462,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Twt,89462,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Twt,89462,GRP_HEIGHTC,HEIGHTC_DATE,20140827 -US-Twt,89462,GRP_HEIGHTC,HEIGHTC_COMMENT,seeding heavily -US-Twt,89441,GRP_HEIGHTC,HEIGHTC,0.694 -US-Twt,89441,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Twt,89441,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Twt,89441,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Twt,89441,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Twt,89441,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Twt,89441,GRP_HEIGHTC,HEIGHTC_DATE,20140904 -US-Twt,89441,GRP_HEIGHTC,HEIGHTC_COMMENT,seeding heavily -US-Twt,89474,GRP_HEIGHTC,HEIGHTC,0.035 -US-Twt,89474,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Twt,89474,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Twt,89474,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Twt,89474,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Twt,89474,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Twt,89474,GRP_HEIGHTC,HEIGHTC_DATE,20140904 -US-Twt,89474,GRP_HEIGHTC,HEIGHTC_COMMENT,seeding heavily -US-Twt,89427,GRP_HEIGHTC,HEIGHTC,0.048 -US-Twt,89427,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Twt,89427,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Twt,89427,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Twt,89427,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Twt,89427,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Twt,89427,GRP_HEIGHTC,HEIGHTC_DATE,20140908 -US-Twt,89448,GRP_HEIGHTC,HEIGHTC,0.645 -US-Twt,89448,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Twt,89448,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Twt,89448,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Twt,89448,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Twt,89448,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Twt,89448,GRP_HEIGHTC,HEIGHTC_DATE,20140908 -US-Twt,89447,GRP_HEIGHTC,HEIGHTC,0.031 -US-Twt,89447,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Twt,89447,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Twt,89447,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Twt,89447,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Twt,89447,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Twt,89447,GRP_HEIGHTC,HEIGHTC_DATE,20140918 -US-Twt,89468,GRP_HEIGHTC,HEIGHTC,0.668 -US-Twt,89468,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Twt,89468,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Twt,89468,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Twt,89468,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Twt,89468,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Twt,89468,GRP_HEIGHTC,HEIGHTC_DATE,20140918 -US-Twt,89451,GRP_HEIGHTC,HEIGHTC,0.625 -US-Twt,89451,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Twt,89451,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Twt,89451,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Twt,89451,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Twt,89451,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Twt,89451,GRP_HEIGHTC,HEIGHTC_DATE,20140925 -US-Twt,89452,GRP_HEIGHTC,HEIGHTC,0.028 -US-Twt,89452,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Twt,89452,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Twt,89452,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Twt,89452,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Twt,89452,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Twt,89452,GRP_HEIGHTC,HEIGHTC_DATE,20140925 -US-Twt,89424,GRP_HEIGHTC,HEIGHTC,0.025 -US-Twt,89424,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Twt,89424,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Twt,89424,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Twt,89424,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Twt,89424,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Twt,89424,GRP_HEIGHTC,HEIGHTC_DATE,20150521 -US-Twt,89436,GRP_HEIGHTC,HEIGHTC,0.11 -US-Twt,89436,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Twt,89436,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Twt,89436,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Twt,89436,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Twt,89436,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Twt,89436,GRP_HEIGHTC,HEIGHTC_DATE,20150521 -US-Twt,89177,GRP_HEIGHTC,HEIGHTC,0.34 -US-Twt,89177,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Twt,89177,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Twt,89177,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Twt,89177,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,5 -US-Twt,89177,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Twt,89177,GRP_HEIGHTC,HEIGHTC_DATE,20150701 -US-Twt,89177,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured from clip plot sampled for biomass and LAI/PAI. -US-Twt,89180,GRP_HEIGHTC,HEIGHTC,0.04 -US-Twt,89180,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Twt,89180,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Twt,89180,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Twt,89180,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,5 -US-Twt,89180,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Twt,89180,GRP_HEIGHTC,HEIGHTC_DATE,20150701 -US-Twt,89180,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured from clip plot sampled for biomass and LAI/PAI. -US-Twt,89442,GRP_HEIGHTC,HEIGHTC,0.624 -US-Twt,89442,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Twt,89442,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Twt,89442,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Twt,89442,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Twt,89442,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Twt,89442,GRP_HEIGHTC,HEIGHTC_DATE,20150709 -US-Twt,89469,GRP_HEIGHTC,HEIGHTC,0.133 -US-Twt,89469,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Twt,89469,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Twt,89469,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Twt,89469,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Twt,89469,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Twt,89469,GRP_HEIGHTC,HEIGHTC_DATE,20150709 -US-Twt,89428,GRP_HEIGHTC,HEIGHTC,0.038 -US-Twt,89428,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Twt,89428,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Twt,89428,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Twt,89428,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Twt,89428,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Twt,89428,GRP_HEIGHTC,HEIGHTC_DATE,20150722 -US-Twt,89434,GRP_HEIGHTC,HEIGHTC,0.58 -US-Twt,89434,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Twt,89434,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Twt,89434,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Twt,89434,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Twt,89434,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Twt,89434,GRP_HEIGHTC,HEIGHTC_DATE,20150722 -US-Twt,89433,GRP_HEIGHTC,HEIGHTC,0.189 -US-Twt,89433,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Twt,89433,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Twt,89433,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Twt,89433,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Twt,89433,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Twt,89433,GRP_HEIGHTC,HEIGHTC_DATE,20150806 -US-Twt,89433,GRP_HEIGHTC,HEIGHTC_COMMENT,Lots of weeds; starting to seed -US-Twt,89443,GRP_HEIGHTC,HEIGHTC,0.853 -US-Twt,89443,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Twt,89443,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Twt,89443,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Twt,89443,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Twt,89443,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Twt,89443,GRP_HEIGHTC,HEIGHTC_DATE,20150806 -US-Twt,89443,GRP_HEIGHTC,HEIGHTC_COMMENT,Lots of weeds; starting to seed -US-Twt,89446,GRP_HEIGHTC,HEIGHTC,0.835 -US-Twt,89446,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Twt,89446,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Twt,89446,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Twt,89446,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Twt,89446,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Twt,89446,GRP_HEIGHTC,HEIGHTC_DATE,20150819 -US-Twt,89446,GRP_HEIGHTC,HEIGHTC_COMMENT,Lots of weeds; starting to seed -US-Twt,89449,GRP_HEIGHTC,HEIGHTC,0.164 -US-Twt,89449,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Twt,89449,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Twt,89449,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Twt,89449,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Twt,89449,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Twt,89449,GRP_HEIGHTC,HEIGHTC_DATE,20150819 -US-Twt,89449,GRP_HEIGHTC,HEIGHTC_COMMENT,Lots of weeds; starting to seed -US-Twt,89473,GRP_HEIGHTC,HEIGHTC,0.845 -US-Twt,89473,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Twt,89473,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Twt,89473,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Twt,89473,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Twt,89473,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Twt,89473,GRP_HEIGHTC,HEIGHTC_DATE,20150902 -US-Twt,89477,GRP_HEIGHTC,HEIGHTC,0.306 -US-Twt,89477,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Twt,89477,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Twt,89477,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Twt,89477,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Twt,89477,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Twt,89477,GRP_HEIGHTC,HEIGHTC_DATE,20150902 -US-Twt,89435,GRP_HEIGHTC,HEIGHTC,0.019 -US-Twt,89435,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Twt,89435,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Twt,89435,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Twt,89435,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Twt,89435,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Twt,89435,GRP_HEIGHTC,HEIGHTC_DATE,20160524 -US-Twt,89435,GRP_HEIGHTC,HEIGHTC_COMMENT,row spacing about 15 cm -US-Twt,89445,GRP_HEIGHTC,HEIGHTC,0.107 -US-Twt,89445,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Twt,89445,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Twt,89445,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Twt,89445,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Twt,89445,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Twt,89445,GRP_HEIGHTC,HEIGHTC_DATE,20160524 -US-Twt,89445,GRP_HEIGHTC,HEIGHTC_COMMENT,row spacing about 15 cm -US-Twt,89431,GRP_HEIGHTC,HEIGHTC,0.028 -US-Twt,89431,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Twt,89431,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Twt,89431,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Twt,89431,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Twt,89431,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Twt,89431,GRP_HEIGHTC,HEIGHTC_DATE,20160606 -US-Twt,89461,GRP_HEIGHTC,HEIGHTC,0.162 -US-Twt,89461,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Twt,89461,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Twt,89461,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Twt,89461,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Twt,89461,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Twt,89461,GRP_HEIGHTC,HEIGHTC_DATE,20160606 -US-Twt,89450,GRP_HEIGHTC,HEIGHTC,0.034 -US-Twt,89450,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Twt,89450,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Twt,89450,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Twt,89450,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Twt,89450,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Twt,89450,GRP_HEIGHTC,HEIGHTC_DATE,20160624 -US-Twt,89450,GRP_HEIGHTC,HEIGHTC_COMMENT,field flooded -US-Twt,89479,GRP_HEIGHTC,HEIGHTC,0.2 -US-Twt,89479,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Twt,89479,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Twt,89479,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Twt,89479,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Twt,89479,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Twt,89479,GRP_HEIGHTC,HEIGHTC_DATE,20160624 -US-Twt,89479,GRP_HEIGHTC,HEIGHTC_COMMENT,field flooded -US-Twt,89454,GRP_HEIGHTC,HEIGHTC,0.037 -US-Twt,89454,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Twt,89454,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Twt,89454,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Twt,89454,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Twt,89454,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Twt,89454,GRP_HEIGHTC,HEIGHTC_DATE,20160706 -US-Twt,89471,GRP_HEIGHTC,HEIGHTC,0.582 -US-Twt,89471,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Twt,89471,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Twt,89471,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Twt,89471,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Twt,89471,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Twt,89471,GRP_HEIGHTC,HEIGHTC_DATE,20160706 -US-Twt,89456,GRP_HEIGHTC,HEIGHTC,0.722 -US-Twt,89456,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Twt,89456,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Twt,89456,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Twt,89456,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Twt,89456,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Twt,89456,GRP_HEIGHTC,HEIGHTC_DATE,20160720 -US-Twt,89478,GRP_HEIGHTC,HEIGHTC,0.052 -US-Twt,89478,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Twt,89478,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Twt,89478,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Twt,89478,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Twt,89478,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Twt,89478,GRP_HEIGHTC,HEIGHTC_DATE,20160720 -US-Twt,89425,GRP_HEIGHTC,HEIGHTC,0.056 -US-Twt,89425,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Twt,89425,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Twt,89425,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Twt,89425,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Twt,89425,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Twt,89425,GRP_HEIGHTC,HEIGHTC_DATE,20160801 -US-Twt,89475,GRP_HEIGHTC,HEIGHTC,0.747 -US-Twt,89475,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Twt,89475,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Twt,89475,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Twt,89475,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Twt,89475,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Twt,89475,GRP_HEIGHTC,HEIGHTC_DATE,20160801 -US-Twt,89420,GRP_HEIGHTC,HEIGHTC,0.85 -US-Twt,89420,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Twt,89420,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Twt,89420,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Twt,89420,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Twt,89420,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Twt,89420,GRP_HEIGHTC,HEIGHTC_DATE,20160812 -US-Twt,89444,GRP_HEIGHTC,HEIGHTC,0.224 -US-Twt,89444,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Crop -US-Twt,89444,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Twt,89444,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Twt,89444,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Twt,89444,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Twt,89444,GRP_HEIGHTC,HEIGHTC_DATE,20160812 -US-Twt,11935,GRP_IGBP,IGBP,CRO -US-Twt,11935,GRP_IGBP,IGBP_COMMENT,rice -US-Twt,11936,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-Twt,11936,GRP_LAND_OWNERSHIP,LAND_OWNER,Department of Water Resources -US-Twt,86662,GRP_LOCATION,LOCATION_LAT,38.1087 -US-Twt,86662,GRP_LOCATION,LOCATION_LONG,-121.6531 -US-Twt,86662,GRP_LOCATION,LOCATION_ELEV,-7 -US-Twt,86662,GRP_LOCATION,LOCATION_DATE_START,20090403 -US-Twt,86660,GRP_LOCATION,LOCATION_LAT,38.1055 -US-Twt,86660,GRP_LOCATION,LOCATION_LONG,-121.6521 -US-Twt,86660,GRP_LOCATION,LOCATION_ELEV,-7 -US-Twt,86660,GRP_LOCATION,LOCATION_DATE_START,20090722 -US-Twt,86660,GRP_LOCATION,LOCATION_COMMENT,Secondary: The tower site was moved 360m to the south to make use of AC power from a generator for closed path CH4. The footprint is still within the same field and not significantly different from the previous location. -US-Twt,86659,GRP_LOCATION,LOCATION_LAT,38.1087 -US-Twt,86659,GRP_LOCATION,LOCATION_LONG,-121.6531 -US-Twt,86659,GRP_LOCATION,LOCATION_ELEV,-7 -US-Twt,86659,GRP_LOCATION,LOCATION_DATE_START,20101118 -US-Twt,11938,GRP_NETWORK,NETWORK,AmeriFlux -US-Twt,87017,GRP_NETWORK,NETWORK,Phenocam -US-Twt,1700001776,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Baldocchi, D., Penuelas, J. (2018) The Physics And Ecology Of Mining Carbon Dioxide From The Atmosphere By Ecosystems, Global Change Biology, 45(6), 9275–9287" -US-Twt,1700001776,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/GCB.14559 -US-Twt,1700001776,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Twt,1700001053,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Baldocchi, D., Penuelas, J. (2018) The Physics And Ecology Of Mining Carbon Dioxide From The Atmosphere By Ecosystems, Global Change Biology, 45(8), 9275–9287" -US-Twt,1700001053,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/GCB.14559 -US-Twt,1700001053,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Twt,1700005256,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Baldocchi, D., S. Knox, I. Dronova, J. Verfaillie, P. Oikawa, C. Sturtevant, J. H. Matthes, and M. Detto. (2016) The impact of expanding flooded land area on the annual evaporation of rice. Agricultural and Forest Meteorology, Agricultural and Forest Meteorology, 223(6), 181-193" -US-Twt,1700005256,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2016.04.001 -US-Twt,1700005256,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Twt,1700006987,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chamberlain, S. D., Verfaillie, J., Eichelmann, E., Hemes, K. S., Baldocchi, D. D. (2017) Evaluation Of Density Corrections To Methane Fluxes Measured By Open-Path Eddy Covariance Over Contrasting Landscapes, Boundary-Layer Meteorology, 223(6), 181-193" -US-Twt,1700006987,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1007/S10546-017-0275-9 -US-Twt,1700006987,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Twt,1700004122,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chamberlain, S. D., Verfaillie, J., Eichelmann, E., Hemes, K. S., Baldocchi, D. D. (2017) Evaluation Of Density Corrections To Methane Fluxes Measured By Open-Path Eddy Covariance Over Contrasting Landscapes, Boundary-Layer Meteorology, 301-302(8), 108350" -US-Twt,1700004122,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1007/S10546-017-0275-9 -US-Twt,1700004122,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Twt,1700007425,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Baldocchi, D. D., Poindexter, C., Abraha, M., Desai, A. R., Bohrer, G., Arain, M. A., Griffis, T., Blanken, P. D., O'Halloran, T. L., Thomas, R. Q., Zhang, Q., Burns, S. P., Frank, J. M., Christian, D., Brown, S., Black, T. A., Gough, C. M., Law, B. E., Lee, X., Chen, J., Reed, D. E., Massman, W. J., Clark, K., Hatfield, J., Prueger, J., Bracho, R., Baker, J. M., Martin, T. A. (2018) Temporal Dynamics Of Aerodynamic Canopy Height Derived From Eddy Covariance Momentum Flux Data Across North American Flux Networks, Geophysical Research Letters, 45(6), 9275–9287" -US-Twt,1700007425,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018GL079306 -US-Twt,1700007425,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Twt,1700002670,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Baldocchi, D. D., Poindexter, C., Abraha, M., Desai, A. R., Bohrer, G., Arain, M. A., Griffis, T., Blanken, P. D., O'Halloran, T. L., Thomas, R. Q., Zhang, Q., Burns, S. P., Frank, J. M., Christian, D., Brown, S., Black, T. A., Gough, C. M., Law, B. E., Lee, X., Chen, J., Reed, D. E., Massman, W. J., Clark, K., Hatfield, J., Prueger, J., Bracho, R., Baker, J. M., Martin, T. A. (2018) Temporal Dynamics Of Aerodynamic Canopy Height Derived From Eddy Covariance Momentum Flux Data Across North American Flux Networks, Geophysical Research Letters, 45(8), 9275–9287" -US-Twt,1700002670,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018GL079306 -US-Twt,1700002670,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Twt,1700001083,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(8), 108350" -US-Twt,1700001083,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -US-Twt,1700001083,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Twt,1700006564,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Eichelmann, E., Hemes, K. S., Knox, S. H., Oikawa, P. Y., Chamberlain, S. D., Sturtevant, C., Verfaillie, J., Baldocchi, D. D. (2018) The Effect Of Land Cover Type And Structure On Evapotranspiration From Agricultural And Wetland Sites In The Sacramento–San Joaquin River Delta, California, Agricultural And Forest Meteorology, 256-257(6), 179-195" -US-Twt,1700006564,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2018.03.007 -US-Twt,1700006564,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Twt,1700001080,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Eichelmann, E., Hemes, K. S., Knox, S. H., Oikawa, P. Y., Chamberlain, S. D., Sturtevant, C., Verfaillie, J., Baldocchi, D. D. (2018) The Effect Of Land Cover Type And Structure On Evapotranspiration From Agricultural And Wetland Sites In The Sacramento–San Joaquin River Delta, California, Agricultural And Forest Meteorology, 256-257(8), 179-195" -US-Twt,1700001080,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2018.03.007 -US-Twt,1700001080,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Twt,1700002970,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Hatala, J. A., Detto, M., Baldocchi, D. D. (2012) Gross Ecosystem Photosynthesis Causes A Diurnal Pattern In Methane Emission From Rice, Geophysical Research Letters, 39(6), n/a-n/a" -US-Twt,1700002970,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2012GL051303 -US-Twt,1700002970,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Twt,1700006810,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Hatala, J. A., Detto, M., Sonnentag, O., Deverel, S. J., Verfaillie, J., Baldocchi, D. D. (2012) Greenhouse Gas (CO2, CH4, H2O) Fluxes From Drained And Flooded Agricultural Peatlands In The Sacramento-San Joaquin Delta, Agriculture, Ecosystems & Environment, 150(6), 1-18" -US-Twt,1700006810,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGEE.2012.01.009 -US-Twt,1700006810,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Primary_Citation -US-Twt,1700004710,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Hemes, K. S., Chamberlain, S. D., Eichelmann, E., Anthony, T., Valach, A., Kasak, K., Szutu, D., Verfaillie, J., Silver, W. L., Baldocchi, D. D. (2019) Assessing The Carbon And Climate Benefit Of Restoring Degraded Agricultural Peat Soils To Managed Wetlands, Agricultural And Forest Meteorology, 268(6), 202-214" -US-Twt,1700004710,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2019.01.017 -US-Twt,1700004710,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Twt,1700000240,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Hemes, K. S., Chamberlain, S. D., Eichelmann, E., Anthony, T., Valach, A., Kasak, K., Szutu, D., Verfaillie, J., Silver, W. L., Baldocchi, D. D. (2019) Assessing The Carbon And Climate Benefit Of Restoring Degraded Agricultural Peat Soils To Managed Wetlands, Agricultural And Forest Meteorology, 268(8), 202-214" -US-Twt,1700000240,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2019.01.017 -US-Twt,1700000240,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Twt,1700006159,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Kim, Y., Johnson, M. S., Knox, S. H., Black, T. A., Dalmagro, H. J., Kang, M., Kim, J., Baldocchi, D. (2019) Gap‐Filling Approaches For Eddy Covariance Methane Fluxes: A Comparison Of Three Machine Learning Algorithms And A Traditional Method With Principal Component Analysis, Global Change Biology, 20(8), 1619-1633" -US-Twt,1700006159,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/GCB.14845 -US-Twt,1700006159,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Twt,1700000507,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Knox, S. H., J. H. Matthes, C. Sturtevant, P. Y. Oikawa, J. Verfaillie, and D. Baldocchi. (2016) Biophysical controls on interannual variability in ecosystem-scale CO2 and CH4 exchange in a California rice paddy., Journal of Geophysical Research-Biogeosciences, 121(6), 978-1001" -US-Twt,1700000507,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/2015JG003247 -US-Twt,1700000507,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Twt,1700001737,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Knox, S. H.,, Sturtevant, C., Matthes, J.H., Koteen, L., Verfaillie,J., Baldocchi. D. (2014) Agricultural peatland restoration: effects of land-use change on greenhouse gas (CO2 and CH4) fluxes in the Sacramento-San Joaquin Delta, Global Change Biology, 21(), 750-765" -US-Twt,1700001737,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/GCB.12745 -US-Twt,1700001737,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Twt,1700003900,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Sullivan, R. C., Cook, D. R., Ghate, V. P., Kotamarthi, V. R., Feng, Y. (2019) Improved Spatiotemporal Representativeness And Bias Reduction Of Satellite-Based Evapotranspiration Retrievals Via Use Of In Situ Meteorology And Constrained Canopy Surface Resistance, Journal Of Geophysical Research: Biogeosciences, 124(2), 342-352" -US-Twt,1700003900,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018JG004744 -US-Twt,1700003900,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Twt,1700001920,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Sullivan, R. C., Kotamarthi, V. R., Feng, Y. (2019) Recovering Evapotranspiration Trends From Biased CMIP5 Simulations And Sensitivity To Changing Climate Over North America, Journal Of Hydrometeorology, 20(8), 1619-1633" -US-Twt,1700001920,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1175/JHM-D-18-0259.1 -US-Twt,1700001920,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Twt,11940,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"The research approach of the University of California, Berkeley Biometeorology Laboratory involves the coordinated use of experimental measurements and theoretical models to understand the physical, biological, and chemical processes that control trace gas fluxes between the biosphere and atmosphere and to quantify their temporal and spatial variations. They are also responsible for making eddy covariance measurements of H2O, CO2, sensible heat, and CH4 exchange between a rice paddy and the atmosphere. The research objectives of the Mayberry Wetland, Sherman Island, and Twitchell Island sites are as follows: 1) Describe differences in the fluxes of CO2, CH4, H2O, and energy between different land uses; 2) Understand the mechanisms controlling these fluxes; 3) Use ecosystem modeling to understand controls on these mechanisms under different environmental scenarios. These three sites were selected to capture a wide range of inundated conditions within the Sacramento-San Joaquin River Delta. The research focuses on the eddy covariance technique to measure CH4, CO2, H2O, and energy fluxes and works to combine measurements of both net fluxes and partitioned fluxes in order to achieve a mechanistic understanding of the ecological controls on current and future carbon flux in the Delta." -US-Twt,11941,GRP_SITE_CHAR,TERRAIN,Flat -US-Twt,11941,GRP_SITE_CHAR,ASPECT,FLAT -US-Twt,11941,GRP_SITE_CHAR,WIND_DIRECTION,W -US-Twt,11941,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,455 -US-Twt,11941,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,0 -US-Twt,11942,GRP_SITE_DESC,SITE_DESC,"The Twitchell Island site is a rice paddy that is owned by the state and managed by the California Department of Water Resources. While Bare Peat field was leveled for rice planting, the tower was installed on April 3, 2009. The rice paddy was converted from corn in 2007. In Summer 2009, Bispyribac-sodium and Pendimethalin herbicides were applied to the fields prior to rice planting and flooding, then pesticide and fertilizer application took place. Each year after rice is planted in the spring by drilling, the field is flooded. Then, the field is drained in early fall, rice is harvested, and the field site is moved." -US-Twt,11943,GRP_SITE_FUNDING,SITE_FUNDING,NSF/California Department of Water Resources -US-Twt,28941,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION,Mixture of peat and mineral soil -US-Twt,28941,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION_TAXONOMY,Other -US-Twt,11944,GRP_STATE,STATE,CA -US-Twt,11945,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Dennis Baldocchi -US-Twt,11945,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Twt,11945,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,baldocchi@berkeley.edu -US-Twt,11945,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"University of California, Berkeley" -US-Twt,11945,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Department of Environmental Science, Policy and Management, 130 Mulford Hall,Berkeley, CA USA 94720-3110" -US-Twt,11953,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Joe Verfaillie -US-Twt,11953,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,AncContact -US-Twt,11953,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,jverfail@berkeley.edu -US-Twt,11953,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"University of California, Berkeley" -US-Twt,11953,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Department of Environmental Science, Policy and Management, 130 Mulford Hall,Berkeley, CA USA 94720-3110" -US-Twt,33578,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Elke Eichelmann -US-Twt,33578,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-Twt,33578,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,eeichelm@berkeley.edu -US-Twt,33578,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,UC Berkeley -US-Twt,30349,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Daphne Szutu -US-Twt,30349,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Technician -US-Twt,30349,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,daphneszutu@berkeley.edu -US-Twt,30349,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,UC Berkeley -US-Twt,86661,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Sara Knox -US-Twt,86661,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Affiliate -US-Twt,86661,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,saraknox.knox@gmail.com -US-Twt,86661,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"University of British Columbia, Vancouver" -US-Twt,11946,GRP_URL,URL,http://nature.berkeley.edu/biometlab/fielddescription.html -US-Twt,24000506,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-Twt -US-Twt,11947,GRP_UTC_OFFSET,UTC_OFFSET,-8 -US-Uaf,81368,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,"Supported by Arctic Challenge for Sustainability (ArCS) project by the Ministry of Education, Culture, Sports, Science and Technology, Japan." -US-Uaf,81368,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT_COMMENT,Acknowledge the ArCS Project -US-Uaf,81349,GRP_CLIM_AVG,MAT,-2.9 -US-Uaf,81349,GRP_CLIM_AVG,MAP,263 -US-Uaf,81349,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dwc -US-Uaf,27000967,GRP_COUNTRY,COUNTRY,USA -US-Uaf,85247,GRP_DOI,DOI,10.17190/AMF/1480322 -US-Uaf,85247,GRP_DOI,DOI_CITATION,"Masahito Ueyama, Hiroki Iwata, Yoshinobu Harazono (2022), AmeriFlux BASE US-Uaf University of Alaska, Fairbanks, Ver. 10-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1480322" -US-Uaf,85247,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-Uaf,88004,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Uaf,88004,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Masahito Ueyama -US-Uaf,88004,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Uaf,88004,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,1 -US-Uaf,88004,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0002-4000-4888 -US-Uaf,88004,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,miyabi-flux@muh.biglobe.ne.jp -US-Uaf,88004,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Osaka Prefecture University -US-Uaf,88003,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Uaf,88003,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Hiroki Iwata -US-Uaf,88003,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Uaf,88003,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,2 -US-Uaf,88003,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,hiwata@shinshu-u.ac.jp -US-Uaf,88003,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Shinshu University -US-Uaf,88005,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Uaf,88005,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Yoshinobu Harazono -US-Uaf,88005,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Uaf,88005,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,3 -US-Uaf,88005,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,harazono2009gl@gmail.com -US-Uaf,88005,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Osaka Prefecture University -US-Uaf,84796,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Osaka Prefecture University -US-Uaf,84796,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-Uaf,84797,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Shinshu University -US-Uaf,84797,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-Uaf,84795,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,"ArCS, KAKENHI" -US-Uaf,84795,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-Uaf,81351,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Undisturbed -US-Uaf,81526,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Uaf,81526,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-Uaf,81526,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20021001 -US-Uaf,81526,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Uaf,81519,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Uaf,81519,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-Uaf,81519,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20021001 -US-Uaf,81519,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Uaf,81518,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Uaf,81518,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-Uaf,81518,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20021001 -US-Uaf,81518,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Uaf,81525,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Uaf,81525,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CH4 -US-Uaf,81525,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20090401 -US-Uaf,81525,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Growing season operation only -US-Uaf,81521,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Chambers -US-Uaf,81521,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-Uaf,81521,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20160401 -US-Uaf,81521,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Growing season operation only -US-Uaf,81520,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Chambers -US-Uaf,81520,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CH4 -US-Uaf,81520,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20160401 -US-Uaf,81520,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Growing season operation only -US-Uaf,23000967,GRP_HEADER,SITE_NAME,"University of Alaska, Fairbanks" -US-Uaf,81364,GRP_IGBP,IGBP,ENF -US-Uaf,81364,GRP_IGBP,IGBP_COMMENT,"Open black spruce forest on dense understory, such as shrub, sedge, moss, and lichen." -US-Uaf,81372,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-Uaf,81372,GRP_LAND_OWNERSHIP,LAND_OWNER,"University of Alaska, Fairbanks" -US-Uaf,81352,GRP_LOCATION,LOCATION_LAT,64.8663 -US-Uaf,81352,GRP_LOCATION,LOCATION_LONG,-147.8555 -US-Uaf,81352,GRP_LOCATION,LOCATION_ELEV,155 -US-Uaf,81366,GRP_NETWORK,NETWORK,AmeriFlux -US-Uaf,1700001647,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(18), 108350" -US-Uaf,1700001647,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -US-Uaf,1700001647,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Uaf,1700006165,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Date, T., Ueyama. M., Harazono, Y., Ota, Y., Iwata, T. and Yamamoto, S. (2009) Satellite observations of decadal scale CO2 fluxes over black spruce forests in Alaska associated with climate variability., J. Agric. Meteorol., 65(107-115), 47-60" -US-Uaf,1700006165,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Uaf,1700008346,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Harazono, Y., Iwata, H., Sakabe, A., Ueyama, M., Takahashi, K., Nagano, H., Nakai, T., and Kosugi, Y. (2015) Effects of water vapor dilution on trace gas flux, and practical correction methods, J. Agric. Meteorol., 71(4), 65-76" -US-Uaf,1700008346,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Uaf,1700000411,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Iwata, H., Harazono, Y., and Ueyama, M. (2010) Influence of source/sink distributions on flux-gradient relationships in the roughtness sublayer over an open forest canopy under unstable conditions, Boundary Layer Meteorol., 136(107-115), 391-405" -US-Uaf,1700000411,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Uaf,1700003351,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Iwata, H., Harazono, Y., and Ueyama, M. (2012) Sensitivity and offset changes of a fast-response open-path infrared gas analyzer during long-term observations in an Arctic environment, J. Agric. Meteorol., 68(107-115), 175-181" -US-Uaf,1700003351,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Uaf,1700008946,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Iwata, H., Harazono, Y., and Ueyama, M. (2012) The role of permafrost on water exchange of a black spruce forest in Interior Alaska, Agric. Forest Meteorol., 161(107-115), 223-233" -US-Uaf,1700008946,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Uaf,1700004458,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Iwata, H., Harazono, Y., Ueyama, M., Sakabe, A., Nagano H., Kosugi, Y., Takahashi, K., and Kim, Y. (2015) Methane exchange in a poorly-drained black spruce forest over permafrost observed using the eddy covariance technique, Agric. Forest Meteorol., 214-215(4), 157-168" -US-Uaf,1700004458,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Uaf,1700000714,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Kim, Y., Ueyama, M., Nakagawa, F., Tsunogai, U., Harazono, Y. and Tanaka, N. (2007) Assessment of winter fluxes of CO2 and CH4 in boreal forest soils of central Alaska estimated by the profile method and the chamber method: A diagnosis of methane emission and implications for the regional carbon budget, Tellus, 59B(), 223-233" -US-Uaf,1700000714,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Uaf,1700007617,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Kim, Y., Ueyama, M., Nakagawa, F., Tsunogai, U., Harazono, Y. and Tanaka, N. (2007) Assessment of winter fluxes of CO2 and CH4 in boreal forest soils of central Alaska estimated by the profile method and the chamber method: A diagnosis of methane emission and implications for the regional carbon budget, Tellus, 59B(18), 223-233" -US-Uaf,1700007617,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Uaf,1700007212,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Kitamoto, T., Ueyama, M., Harazono, Y., Iwata, T. and Yamamoto, S. (2007) Applications of NOAA/AVHRR and observed fluxes to estimate regional carbon fluxes over black spruce forests in Alaska., J. Agric. Meteorol., 63(107-115), 171-183" -US-Uaf,1700007212,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Uaf,1700002574,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Masahito UEYAMA, Narumi TAHARA, Hirohiko NAGANO, Naoki MAKITA, Hiroki IWATA, Yoshinobu HARAZONO (2018) Leaf- and ecosystem-scale photosynthetic parameters for the overstory and understory of boreal forests in interior Alaska, journal of Agricultural Meteorology, 74(2), 79-86" -US-Uaf,1700002574,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Uaf,1700003498,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Ueyama, M., Harazaono, Y., Okada, R., Nojiri, A., Ohtaki, E. and Miyata, A. (2006) Micrometeorological measurements of methane flux at a boreal forest in central Alaska, Mem. Natl Inst. Polar Res., Spec. Issue, 59(), 156-167" -US-Uaf,1700003498,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Uaf,1700008535,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Ueyama, M., Harazaono, Y., Okada, R., Nojiri, A., Ohtaki, E. and Miyata, A. (2006) Micrometeorological measurements of methane flux at a boreal forest in central Alaska, Mem. Natl Inst. Polar Res., Spec. Issue, 59(18), 156-167" -US-Uaf,1700008535,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Uaf,1700002817,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Ueyama, M., Harazono, Y., and Ichii, K. (2010) Satellite-based modeling of the carbon fluxes in mature black spruce forests in Alaska: a synthesis of the eddy covariance data and satellite remote sensing data, 2010, 14(107-115), 1-27" -US-Uaf,1700002817,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Uaf,1700008208,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Ueyama, M., Harazono, Y., Kim, Y. and Tanaka, N. (2009) Response of the carbon cycle in sub-arctic black spruce forests to climate change: Reduction of a carbon sink related to the sensitivity of heterotrophic respiration., Agric. Forest Meteorol., 149(107-115), 582-602" -US-Uaf,1700008208,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Uaf,1700002340,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Ueyama, M., Harazono, Y., Okada, R., Nojiri, A., Ohataki, E. and Miyata, A. (2006) Controlling factors on the inter-annual CO2 budget at a sub-arctic black spruce forest in interior Alaska, Tellus, 58B(), 491-501" -US-Uaf,1700002340,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Uaf,1700008448,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Ueyama, M., Harazono, Y., Okada, R., Nojiri, A., Ohataki, E. and Miyata, A. (2006) Controlling factors on the inter-annual CO2 budget at a sub-arctic black spruce forest in interior Alaska, Tellus, 58B(18), 491-501" -US-Uaf,1700008448,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Uaf,1700000891,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Ueyama, M., Iwata, H., Harazono, Y. (2014) Autumn Warming Reduces The Co2sink Of A Black Spruce Forest In Interior Alaska Based On A Nine-Year Eddy Covariance Measurement, Global Change Biology, 20(4), 1161-1173" -US-Uaf,1700000891,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/GCB.12434 -US-Uaf,1700000891,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Primary_Citation -US-Uaf,1700007764,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Ueyama, M., Kudo, S., Iwama, C., Nagano, H., Kobayashi, H., Harazono, Y. and Yoshikawa, K. (2014) Does summer warming reduce black spruce productivity in interior Alaska?, J. Forest Res., 20(4), 52-59" -US-Uaf,1700007764,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Uaf,1700008553,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Ueyama, M., Tahara, N., Iwata, H., Euskirchen, E. S., Ikawa, H., Kobayashi, H., Nagano, H., Nakai, T., and Harazono, Y. (2016) Optimization of a biochemical model with eddy covariance measurements in black spruce forests of Alaska for estimating CO2 fertilization effects, Agric. Forest Meteorol., 222(4), 98-111" -US-Uaf,1700008553,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Uaf,1700004434,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Ueyama, M., Yamamori, T., Iwata, H., Harazono, Y. (2020) Cooling And Moistening Of The Planetary Boundary Layer In Interior Alaska Due To A Postfire Change In Surface Energy Exchange, Journal Of Geophysical Research: Atmospheres, 125(18), 79-86" -US-Uaf,1700004434,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2020JD032968 -US-Uaf,1700004434,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Uaf,81358,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,Long-term monitoring energy & greenhouse gas fluxes under high-latitude climate change -US-Uaf,81353,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"Syun-Ichi Akasofu Building -2160 Koyukuk Dr -Fairbanks, AK 99775" -US-Uaf,81360,GRP_SITE_CHAR,TERRAIN,Gentle slope (<2 %) -US-Uaf,81360,GRP_SITE_CHAR,ASPECT,N -US-Uaf,81360,GRP_SITE_CHAR,WIND_DIRECTION,NW -US-Uaf,81360,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,120 -US-Uaf,81360,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,195 -US-Uaf,81361,GRP_SITE_DESC,SITE_DESC,"This tower is located near Smith Lake, University of Alaska, Fairbanks. The open black spruce is dominated on discontinuous permafrost." -US-Uaf,81350,GRP_SITE_FUNDING,SITE_FUNDING,"ArCS, KAKENHI" -US-Uaf,81369,GRP_STATE,STATE,AK -US-Uaf,81523,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Hiroki Iwata -US-Uaf,81523,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Uaf,81523,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,hiwata@shinshu-u.ac.jp -US-Uaf,81523,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Shinshu University -US-Uaf,81524,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Masahito Ueyama -US-Uaf,81524,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Uaf,81524,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,miyabi-flux@muh.biglobe.ne.jp -US-Uaf,81524,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Osaka Prefecture University -US-Uaf,81522,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Yoshinobu Harazono -US-Uaf,81522,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Uaf,81522,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,harazono2009gl@gmail.com -US-Uaf,81522,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Osaka Prefecture University -US-Uaf,81357,GRP_TOWER_POWER,TOWER_POWER,Direct power -US-Uaf,81374,GRP_TOWER_TYPE,TOWER_TYPE,walk-up -US-Uaf,81367,GRP_URL,URL,http://atmenv.envi.osakafu-u.ac.jp/data/uaf_data/ -US-Uaf,24000967,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-Uaf -US-Uaf,81370,GRP_UTC_OFFSET,UTC_OFFSET,-9 -US-UC1,97441,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,This research was a contribution from the Long-Term Agroecosystem Research (LTAR) network. LTAR is supported by the United States Department of Agriculture. -US-UC1,97438,GRP_CLIM_AVG,MAT,10.1 -US-UC1,97438,GRP_CLIM_AVG,MAP,1006.35 -US-UC1,97438,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfb -US-UC1,27001198,GRP_COUNTRY,COUNTRY,USA -US-UC1,99515,GRP_DOI,DOI,10.17190/AMF/1865482 -US-UC1,99515,GRP_DOI,DOI_CITATION,"Sarah Goslee (2022), AmeriFlux BASE US-UC1 LTAR UCB (Upper Chesapeake Bay) EC1, Ver. 1-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1865482" -US-UC1,99515,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-UC1,99479,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-UC1,99479,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Sarah Goslee -US-UC1,99479,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-UC1,99479,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,sarah.goslee@usda.gov -US-UC1,99479,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,USDA ARS Pasture Sytems and Watershed Management Research Unit -US-UC1,99499,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,USDA ARS Pasture Sytems and Watershed Management Research Unit -US-UC1,99499,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-UC1,99494,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,USDA ARS -US-UC1,99494,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-UC1,97432,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Agriculture -US-UC1,97429,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-UC1,97429,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-UC1,97429,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201905151100 -US-UC1,97429,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-UC1,97434,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-UC1,97434,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-UC1,97434,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201905151100 -US-UC1,97434,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-UC1,23001198,GRP_HEADER,SITE_NAME,LTAR UCB (Upper Chesapeake Bay) EC1 -US-UC1,97424,GRP_IGBP,IGBP,CVM -US-UC1,97424,GRP_IGBP,IGBP_COMMENT,"Land has been privately owned, no records exist as to when crop land was cleared in landscape." -US-UC1,97425,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -US-UC1,97425,GRP_LAND_OWNERSHIP,LAND_OWNER,Evergreen Farms Inc -US-UC1,97427,GRP_LOCATION,LOCATION_LAT,40.7536 -US-UC1,97427,GRP_LOCATION,LOCATION_LONG,-78.0056 -US-UC1,97427,GRP_LOCATION,LOCATION_ELEV,390 -US-UC1,97427,GRP_LOCATION,LOCATION_DATE_START,201905150900 -US-UC1,97427,GRP_LOCATION,LOCATION_COMMENT,Site info started with Eddy Covariance systems and Phenocams -US-UC1,97428,GRP_NETWORK,NETWORK,AmeriFlux -US-UC1,97440,GRP_NETWORK,NETWORK,LTAR -US-UC1,97443,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,Dairy Grazing Farm crop rotation and manure management -US-UC1,97436,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"Curtin Rd, Building 3702, University Park, PA 16802" -US-UC1,97426,GRP_SITE_CHAR,TERRAIN,"Medium Slope (>2 %, <5%)" -US-UC1,97426,GRP_SITE_CHAR,ASPECT,NW -US-UC1,97426,GRP_SITE_CHAR,WIND_DIRECTION,SSW -US-UC1,97426,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,300 -US-UC1,97426,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,18 -US-UC1,97423,GRP_SITE_DESC,SITE_DESC,"Upper Chesapeake Bay farm is privately owned. The farming that took place was performed by the Farm Owner. The ground is rolling terrain, next to wooded areas, private resdiences and other large fields maintained by private land owners. At the time of this collection period, the site housed another Eddy Covariance System and a two Phenocams. Crop has been continuous corn with plans to rotate to alfalfa grass mixture." -US-UC1,97431,GRP_SITE_FUNDING,SITE_FUNDING,USDA ARS -US-UC1,97442,GRP_STATE,STATE,PA -US-UC1,97430,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Sarah Goslee -US-UC1,97430,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-UC1,97430,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,sarah.goslee@usda.gov -US-UC1,97430,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,USDA ARS Pasture Sytems and Watershed Management Research Unit -US-UC1,97437,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Dan Arthur -US-UC1,97437,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,DataManager -US-UC1,97437,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,dan.arthur@usda.gov -US-UC1,97437,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,USDA ARS Pasture Sytems and Watershed Management Research Unit -US-UC1,97433,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Jeffery Gonet -US-UC1,97433,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Technician -US-UC1,97433,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,jeffery.gonet@usda.gov -US-UC1,97433,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,USDA ARS Pasture Sytems and Watershed Management Research Unit -US-UC1,97433,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Curtin Rd, Building 3702, University Park, PA 16802" -US-UC1,97422,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-UC1,97439,GRP_TOWER_TYPE,TOWER_TYPE,triangle -US-UC1,24001198,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-UC1 -US-UC1,97435,GRP_UTC_OFFSET,UTC_OFFSET,-5 -US-UC2,97462,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,This research was a contribution from the Long-Term Agroecosystem Research (LTAR) network. LTAR is supported by the United States Department of Agriculture. -US-UC2,97455,GRP_CLIM_AVG,MAT,10.1 -US-UC2,97455,GRP_CLIM_AVG,MAP,1006.35 -US-UC2,97455,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfb -US-UC2,27001199,GRP_COUNTRY,COUNTRY,USA -US-UC2,99513,GRP_DOI,DOI,10.17190/AMF/1865483 -US-UC2,99513,GRP_DOI,DOI_CITATION,"Sarah Goslee (2022), AmeriFlux BASE US-UC2 LTAR UCB (Upper Chesapeake Bay) EC2, Ver. 1-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1865483" -US-UC2,99513,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-UC2,99480,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-UC2,99480,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Sarah Goslee -US-UC2,99480,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-UC2,99480,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,sarah.goslee@usda.gov -US-UC2,99480,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,USDA ARS Pasture Sytems and Watershed Management Research Unit -US-UC2,99503,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,USDA ARS Pasture Sytems and Watershed Management Research Unit -US-UC2,99503,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-UC2,99490,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,USDA ARS -US-UC2,99490,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-UC2,97464,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Agriculture -US-UC2,97459,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-UC2,97459,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-UC2,97459,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201905240930 -US-UC2,97459,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-UC2,97461,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-UC2,97461,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-UC2,97461,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201905240930 -US-UC2,97461,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-UC2,23001199,GRP_HEADER,SITE_NAME,LTAR UCB (Upper Chesapeake Bay) EC2 -US-UC2,97449,GRP_IGBP,IGBP,CVM -US-UC2,97449,GRP_IGBP,IGBP_COMMENT,"Land has been privately owned, no records exist as to when crop land was cleared in landscape." -US-UC2,97453,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -US-UC2,97453,GRP_LAND_OWNERSHIP,LAND_OWNER,Evergreen Farms Inc -US-UC2,97456,GRP_LOCATION,LOCATION_LAT,40.7559 -US-UC2,97456,GRP_LOCATION,LOCATION_LONG,-77.9998 -US-UC2,97456,GRP_LOCATION,LOCATION_ELEV,396 -US-UC2,97456,GRP_LOCATION,LOCATION_DATE_START,201905240930 -US-UC2,97456,GRP_LOCATION,LOCATION_COMMENT,Site info started with Eddy Covariance systems and Phenocams -US-UC2,97458,GRP_NETWORK,NETWORK,AmeriFlux -US-UC2,97446,GRP_NETWORK,NETWORK,LTAR -US-UC2,97445,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,Dairy Grazing Farm crop rotation and manure management -US-UC2,97450,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"Curtin Rd, Building 3702, University Park, PA 16802" -US-UC2,97444,GRP_SITE_CHAR,TERRAIN,"Medium Slope (>2 %, <5%)" -US-UC2,97444,GRP_SITE_CHAR,ASPECT,NW -US-UC2,97444,GRP_SITE_CHAR,WIND_DIRECTION,SSW -US-UC2,97444,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,300 -US-UC2,97444,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,18 -US-UC2,97454,GRP_SITE_DESC,SITE_DESC,"Upper Chesapeake Bay farm is privately owned. The farming that took place was performed by the Farm Owner. The ground is rolling terrain, next to wooded areas, private resdiences and other large fields maintained by private land owners. At the time of this collection period, the site housed another Eddy Covariance System and a two Phenocams. Crop has been continuous corn with plans to rotate to alfalfa grass mixture." -US-UC2,97451,GRP_SITE_FUNDING,SITE_FUNDING,USDA ARS -US-UC2,97447,GRP_STATE,STATE,PA -US-UC2,97460,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Sarah Goslee -US-UC2,97460,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-UC2,97460,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,sarah.goslee@usda.gov -US-UC2,97460,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,USDA ARS Pasture Sytems and Watershed Management Research Unit -US-UC2,97448,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Dan Arthur -US-UC2,97448,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,DataManager -US-UC2,97448,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,dan.arthur@usda.gov -US-UC2,97448,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,USDA ARS Pasture Sytems and Watershed Management Research Unit -US-UC2,97463,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Jeffery Gonet -US-UC2,97463,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Technician -US-UC2,97463,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,jeffery.gonet@usda.gov -US-UC2,97463,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,USDA ARS Pasture Sytems and Watershed Management Research Unit -US-UC2,97463,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Curtin Rd, Building 3702, University Park, PA 16802" -US-UC2,97465,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-UC2,97452,GRP_TOWER_TYPE,TOWER_TYPE,triangle -US-UC2,24001199,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-UC2 -US-UC2,97457,GRP_UTC_OFFSET,UTC_OFFSET,-5 -US-UiA,87892,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,"This work was funded by the DOE Center for Advanced Bioenergy and Bioproducts Innovation (U.S. Department of Energy, Office of Science, Office of Biological and Environmental Research under Award Number DE-SC0018420), the Energy Biosciences Institute at the University of Illinois Urbana-Champaign & the Global Change and Photosynthesis Research Unit of the United States Department of Agriculture/Agricultural Research Service." -US-UiA,87906,GRP_CLIM_AVG,MAT,10.9 -US-UiA,87906,GRP_CLIM_AVG,MAP,1051 -US-UiA,87906,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfa -US-UiA,27001107,GRP_COUNTRY,COUNTRY,USA -US-UiA,91704,GRP_DOI,DOI,10.17190/AMF/1617725 -US-UiA,91704,GRP_DOI,DOI_CITATION,"Carl J Bernacchi (2020), AmeriFlux BASE US-UiA University of Illinois Switchgrass, Ver. 1-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1617725" -US-UiA,91704,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-UiA,91601,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-UiA,91601,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Carl J Bernacchi -US-UiA,91601,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-UiA,91601,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,bernacch@illinois.edu -US-UiA,91601,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,USDA/ARS -US-UiA,91655,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,USDA/ARS -US-UiA,91655,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-UiA,91623,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Energy Biosciences Institute -US-UiA,91623,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-UiA,87894,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Agriculture -US-UiA,87899,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-UiA,87899,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-UiA,87899,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,200806131630 -US-UiA,87899,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,201606141500 -US-UiA,87899,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-UiA,87899,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,Open path LI7500 used with RM Young 81000 RE sonic anemometer -US-UiA,87905,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-UiA,87905,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-UiA,87905,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,200806131630 -US-UiA,87905,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,201606141500 -US-UiA,87905,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-UiA,87905,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,Open path LI7500 used with RM Young 81000 RE sonic anemometer -US-UiA,87904,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-UiA,87904,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-UiA,87904,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,200806131630 -US-UiA,87904,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,201606141500 -US-UiA,87904,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-UiA,87904,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,Open path LI7500 used with RM Young 81000 RE sonic anemometer -US-UiA,23001107,GRP_HEADER,SITE_NAME,University of Illinois Switchgrass -US-UiA,87900,GRP_IGBP,IGBP,CRO -US-UiA,87900,GRP_IGBP,IGBP_DATE_START,200806131630 -US-UiA,87900,GRP_IGBP,IGBP_COMMENT,Panicum virgatum perennial crop -US-UiA,87887,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-UiA,87887,GRP_LAND_OWNERSHIP,LAND_OWNER,University of Illinois -US-UiA,87889,GRP_LOCATION,LOCATION_LAT,40.0646 -US-UiA,87889,GRP_LOCATION,LOCATION_LONG,-88.1961 -US-UiA,87889,GRP_LOCATION,LOCATION_ELEV,224 -US-UiA,87889,GRP_LOCATION,LOCATION_DATE_START,200806131630 -US-UiA,87889,GRP_LOCATION,LOCATION_COMMENT,This was a 4 ha (200 m x 200 m) perennial C4 switchgrass field establishd at the University of Illinois Urbana-Champaign Energy Research Farm -US-UiA,87896,GRP_NETWORK,NETWORK,AmeriFlux -US-UiA,87886,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"196 ERML, 1201 W Gregory Dr, Urbana IL 61801" -US-UiA,87903,GRP_SITE_CHAR,TERRAIN,Gentle slope (<2 %) -US-UiA,87903,GRP_SITE_CHAR,ASPECT,FLAT -US-UiA,87903,GRP_SITE_CHAR,WIND_DIRECTION,S -US-UiA,87903,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,200 -US-UiA,87907,GRP_SITE_DESC,SITE_DESC,"Field was treated with Potash, lime and diammonium phosphate before planting. Herbicide application included 2,4-D for 2008, 2009. 56 kg/ha nitrogen applied in 2010, 2011, 2012, 2013, 2014, 2016." -US-UiA,87898,GRP_SITE_FUNDING,SITE_FUNDING,Energy Biosciences Institute -US-UiA,87897,GRP_STATE,STATE,IL -US-UiA,87888,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Carl J Bernacchi -US-UiA,87888,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-UiA,87888,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,bernacch@illinois.edu -US-UiA,87888,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,USDA/ARS -US-UiA,87888,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"196 ERML, 1201 W Gregory Dr, Urbana IL 61801" -US-UiA,92766,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Bethany J Blakely -US-UiA,92766,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-UiA,92766,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,blakely6@illinois.edu -US-UiA,92766,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Illinois Urbana-Champaign -US-UiA,92766,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"196 ERML, 1201 W Gregory Dr, Urbana IL 61801" -US-UiA,87891,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Caitlin E Moore -US-UiA,87891,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-UiA,87891,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,moore.e.caitlin@gmail.com -US-UiA,87891,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Uniersity of Illinois Urbana-Champaign -US-UiA,87891,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"196 ERML, 1201 W Gregory Dr, Urbana IL 61801" -US-UiA,87893,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Evan C Dracup -US-UiA,87893,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Technician -US-UiA,87893,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,edracup@illinois.edu -US-UiA,87893,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,USDA/ARS -US-UiA,87893,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"196 ERML, 1201 W Gregory Dr, Urbana IL 61801" -US-UiA,87890,GRP_TOWER_POWER,TOWER_POWER,Direct power -US-UiA,87895,GRP_TOWER_TYPE,TOWER_TYPE,other -US-UiA,87901,GRP_URL,URL,http://www.life.illinois.edu/bernacchi/ -US-UiA,24001107,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-UiA -US-UiA,87902,GRP_UTC_OFFSET,UTC_OFFSET,-6 -US-UiB,87918,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,"This work was funded by the DOE Center for Advanced Bioenergy and Bioproducts Innovation (U.S. Department of Energy, Office of Science, Office of Biological and Environmental Research under Award Number DE-SC0018420), the Energy Biosciences Institute at the University of Illinois Urbana-Champaign & the Global Change and Photosynthesis Research Unit of the United States Department of Agriculture/Agricultural Research Service." -US-UiB,87924,GRP_CLIM_AVG,MAT,10.9 -US-UiB,87924,GRP_CLIM_AVG,MAP,1051 -US-UiB,87924,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfa -US-UiB,27001108,GRP_COUNTRY,COUNTRY,USA -US-UiB,98952,GRP_DOI,DOI,10.17190/AMF/1846664 -US-UiB,98952,GRP_DOI,DOI_CITATION,"Carl J Bernacchi (2022), AmeriFlux BASE US-UiB University of Illinois Miscanthus, Ver. 1-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1846664" -US-UiB,98952,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-UiB,98934,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-UiB,98934,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Carl J Bernacchi -US-UiB,98934,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-UiB,98934,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,bernacch@illinois.edu -US-UiB,98934,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,USDA/ARS -US-UiB,98949,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,USDA/ARS -US-UiB,98949,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-UiB,98940,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Energy Biosciences Institute & Center for Advanced Bioenergy & Bioproducts Innovation -US-UiB,98940,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-UiB,87923,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Agriculture -US-UiB,87925,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-UiB,87925,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-UiB,87925,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,200807090930 -US-UiB,87925,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,201801010000 -US-UiB,87925,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-UiB,87925,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,Open path LI7500 used with RM Young 81000 RE sonic anemometer -US-UiB,87914,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-UiB,87914,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-UiB,87914,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,200807090930 -US-UiB,87914,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,201801010000 -US-UiB,87914,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-UiB,87913,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-UiB,87913,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-UiB,87913,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,200807090930 -US-UiB,87913,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,201801010000 -US-UiB,87913,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-UiB,87913,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,Open path LI7500 used with RM Young 81000 RE sonic anemometer -US-UiB,23001108,GRP_HEADER,SITE_NAME,University of Illinois Miscanthus -US-UiB,87916,GRP_IGBP,IGBP,CRO -US-UiB,87916,GRP_IGBP,IGBP_DATE_START,200807090930 -US-UiB,87916,GRP_IGBP,IGBP_COMMENT,Miscanthus x giganteus perennial C4 crop -US-UiB,87915,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-UiB,87915,GRP_LAND_OWNERSHIP,LAND_OWNER,University of Illinois -US-UiB,87922,GRP_LOCATION,LOCATION_LAT,40.0628 -US-UiB,87922,GRP_LOCATION,LOCATION_LONG,-88.1984 -US-UiB,87922,GRP_LOCATION,LOCATION_ELEV,224 -US-UiB,87922,GRP_LOCATION,LOCATION_DATE_START,200807090930 -US-UiB,87922,GRP_LOCATION,LOCATION_COMMENT,This was a 4 ha (200 m x 200 m) miscanthus x giganteus perennial C4 bioenergy field establishd at the University of Illinois Urbana-Champaign Energy Research Farm -US-UiB,87910,GRP_NETWORK,NETWORK,AmeriFlux -US-UiB,87927,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"196 ERML, 1201 W Gregory Dr, Urbana, IL, 61801" -US-UiB,87926,GRP_SITE_CHAR,TERRAIN,Gentle slope (<2 %) -US-UiB,87926,GRP_SITE_CHAR,ASPECT,FLAT -US-UiB,87926,GRP_SITE_CHAR,WIND_DIRECTION,S -US-UiB,87926,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,200 -US-UiB,87912,GRP_SITE_DESC,SITE_DESC,"Diammonium phosphate, potash & lime fertilizer applied before planting in 2008. Prowl & 2,4-D herbicide used. 2,4-D & accent herbicide applied in 2009. No fertilizer applied. Bicep herbicide applied in 2010 & 2011. 56 kg/ha nitrogen applied in 2014, 2015 & 2016. 45 kg/ha nitrogen applied in 2017." -US-UiB,87920,GRP_SITE_FUNDING,SITE_FUNDING,Energy Biosciences Institute & Center for Advanced Bioenergy & Bioproducts Innovation -US-UiB,87911,GRP_STATE,STATE,IL -US-UiB,87921,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Carl J Bernacchi -US-UiB,87921,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-UiB,87921,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,bernacch@illinois.edu -US-UiB,87921,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,USDA/ARS -US-UiB,87921,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"196 ERML, 1201 W Gregory Dr, Urbana, IL, 61801" -US-UiB,92770,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Bethany J Blakely -US-UiB,92770,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-UiB,92770,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,blakely6@illinois.edu -US-UiB,92770,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Illinois Urbana-Champaign -US-UiB,92770,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"196 ERML, 1201 W Gregory Dr, Urbana IL 61801" -US-UiB,87917,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Caitlin E Moore -US-UiB,87917,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-UiB,87917,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,moore.e.caitlin@gmail.com -US-UiB,87917,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Illinois Urbana-Champaign -US-UiB,87917,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"196 ERML, 1201 W Gregory Dr, Urbana, IL, 61801" -US-UiB,87928,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Evan C Dracup -US-UiB,87928,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Technician -US-UiB,87928,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,edracup@illinois.edu -US-UiB,87928,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,USDA/ARS -US-UiB,87928,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"196 ERML, 1201 W Gregory Dr, Urbana, IL, 61801" -US-UiB,87909,GRP_TOWER_POWER,TOWER_POWER,Direct power -US-UiB,87919,GRP_TOWER_TYPE,TOWER_TYPE,other -US-UiB,87929,GRP_URL,URL,http://www.life.illinois.edu/bernacchi/ -US-UiB,24001108,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-UiB -US-UiB,87908,GRP_UTC_OFFSET,UTC_OFFSET,-6 -US-UiC,87949,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,"This work was funded by the DOE Center for Advanced Bioenergy and Bioproducts Innovation (U.S. Department of Energy, Office of Science, Office of Biological and Environmental Research under Award Number DE-SC0018420), the Energy Biosciences Institute at the University of Illinois Urbana-Champaign & the Global Change and Photosynthesis Research Unit of the United States Department of Agriculture/Agricultural Research Service." -US-UiC,87938,GRP_CLIM_AVG,MAT,10.9 -US-UiC,87938,GRP_CLIM_AVG,MAP,1051 -US-UiC,87938,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfa -US-UiC,27001109,GRP_COUNTRY,COUNTRY,USA -US-UiC,98955,GRP_DOI,DOI,10.17190/AMF/1846665 -US-UiC,98955,GRP_DOI,DOI_CITATION,"Carl J Bernacchi (2022), AmeriFlux BASE US-UiC University of Illinois Maize-Soy, Ver. 1-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1846665" -US-UiC,98955,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-UiC,98935,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-UiC,98935,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Carl J Bernacchi -US-UiC,98935,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-UiC,98935,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,bernacch@illinois.edu -US-UiC,98935,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,USDA/ARS -US-UiC,98944,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,USDA/ARS -US-UiC,98944,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-UiC,98941,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Energy Biosciences Institute -US-UiC,98941,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-UiC,87936,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Agriculture -US-UiC,87951,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-UiC,87951,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-UiC,87951,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,200807231030 -US-UiC,87951,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,201603231100 -US-UiC,87951,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-UiC,87951,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,Open path LI7500 used with RM Young 81000 RE sonic anemometer -US-UiC,87932,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-UiC,87932,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-UiC,87932,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,200807231030 -US-UiC,87932,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,201603231100 -US-UiC,87932,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-UiC,87932,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,Open path LI7500 used with RM Young 81000 RE sonic anemometer -US-UiC,87948,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-UiC,87948,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-UiC,87948,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,200807231030 -US-UiC,87948,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,201603231100 -US-UiC,87948,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-UiC,87948,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,Open path LI7500 used with RM Young 81000 RE sonic anemometer -US-UiC,23001109,GRP_HEADER,SITE_NAME,University of Illinois Maize-Soy -US-UiC,87950,GRP_IGBP,IGBP,GRA -US-UiC,87950,GRP_IGBP,IGBP_DATE_START,200807231030 -US-UiC,87950,GRP_IGBP,IGBP_COMMENT,"Native Prairie Species: Andropogon gerardii (Big bluestem), Coreopsis tripteris (Tall tickseed), Elymus canadensis (Canada wild rye), Helianthus grosseserratus (Sawtooth sunflower), Heliopsis helianthoides (Early sunflower), Ratibida pinnata (Yellow coneflower), Rudbeckia subtomentosa (Sweet blackeyed Susan), Schizachyrium scoparium (Little bluestem), Solidago rigida (Stiff goldenrod)" -US-UiC,87942,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-UiC,87942,GRP_LAND_OWNERSHIP,LAND_OWNER,University of Illinois -US-UiC,87933,GRP_LOCATION,LOCATION_LAT,40.0647 -US-UiC,87933,GRP_LOCATION,LOCATION_LONG,-88.1983 -US-UiC,87933,GRP_LOCATION,LOCATION_ELEV,224 -US-UiC,87933,GRP_LOCATION,LOCATION_DATE_START,200807231030 -US-UiC,87933,GRP_LOCATION,LOCATION_COMMENT,This was a 4 ha (200 m x 200 m) native prairie field establishd at the University of Illinois Urbana-Champaign Energy Research Farm -US-UiC,87937,GRP_NETWORK,NETWORK,AmeriFlux -US-UiC,87943,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"196 ERML, 1201 W Gregory Dr, Urbana IL 61801" -US-UiC,87930,GRP_SITE_CHAR,TERRAIN,Gentle slope (<2 %) -US-UiC,87930,GRP_SITE_CHAR,ASPECT,FLAT -US-UiC,87930,GRP_SITE_CHAR,WIND_DIRECTION,S -US-UiC,87930,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,200 -US-UiC,87947,GRP_SITE_DESC,SITE_DESC,"Field treated with diammonium phosphate, potash & lime before planting in 2008. No herbicide applied. This site was harvested each year for biomass." -US-UiC,87945,GRP_SITE_FUNDING,SITE_FUNDING,Energy Biosciences Institute -US-UiC,87934,GRP_STATE,STATE,IL -US-UiC,87946,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Carl J Bernacchi -US-UiC,87946,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-UiC,87946,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,bernacch@illinois.edu -US-UiC,87946,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,USDA/ARS -US-UiC,87946,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"196 ERML, 1201 W Gregory Dr, Urbana IL 61801" -US-UiC,92758,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Bethany J Blakely -US-UiC,92758,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-UiC,92758,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,blakely6@illinois.edu -US-UiC,92758,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Illinois Urbana-Champaign -US-UiC,92758,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"196 ERML, 1201 W Gregory Dr, Urbana IL 61801" -US-UiC,87931,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Caitlin E Moore -US-UiC,87931,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-UiC,87931,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,moore.e.caitlin@gmail.com -US-UiC,87931,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Illinois Urbana-Champaign -US-UiC,87931,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"196 ERML, 1201 W Gregory Dr, Urbana IL 61801" -US-UiC,87944,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Evan C Dracup -US-UiC,87944,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Technician -US-UiC,87944,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,edracup@illinois.edu -US-UiC,87944,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,USDA/ARS -US-UiC,87944,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"196 ERML, 1201 W Gregory Dr, Urbana IL 61801" -US-UiC,87939,GRP_TOWER_POWER,TOWER_POWER,Direct power -US-UiC,87941,GRP_TOWER_TYPE,TOWER_TYPE,other -US-UiC,87940,GRP_URL,URL,http://www.life.illinois.edu/bernacchi/ -US-UiC,24001109,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-UiC -US-UiC,87935,GRP_UTC_OFFSET,UTC_OFFSET,-6 -US-UiD,90991,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,"This work was funded by the DOE Center for Advanced Bioenergy and Bioproducts Innovation (U.S. Department of Energy, Office of Science, Office of Biological and Environmental Research under Award Number DE-SC0018420), the Energy Biosciences Institute at the University of Illinois Urbana-Champaign & the Global Change and Photosynthesis Research Unit of the United States Department of Agriculture/Agricultural Research Service." -US-UiD,90977,GRP_CLIM_AVG,MAT,10.9 -US-UiD,90977,GRP_CLIM_AVG,MAP,1051 -US-UiD,27001119,GRP_COUNTRY,COUNTRY,USA -US-UiD,90988,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-UiD,90988,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-UiD,90988,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,200807231030 -US-UiD,90988,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,201603231100 -US-UiD,90988,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-UiD,90992,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-UiD,90992,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-UiD,90992,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,200807231030 -US-UiD,90992,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,201603231100 -US-UiD,90992,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-UiD,90993,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-UiD,90993,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-UiD,90993,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,200807231030 -US-UiD,90993,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,201603231100 -US-UiD,90993,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-UiD,23001119,GRP_HEADER,SITE_NAME,University of Illinois Restored Native Prairie -US-UiD,90985,GRP_IGBP,IGBP,GRA -US-UiD,90985,GRP_IGBP,IGBP_DATE_START,200805291200 -US-UiD,90985,GRP_IGBP,IGBP_COMMENT,"Restored native prarie grasses, see Zeri et al. 2011 Agric. Ecosyst. Environ. 144; 319–329" -US-UiD,90989,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -US-UiD,90989,GRP_LAND_OWNERSHIP,LAND_OWNER,"University of Illinois, Champaign-Urbana" -US-UiD,90990,GRP_LOCATION,LOCATION_LAT,40.0646 -US-UiD,90990,GRP_LOCATION,LOCATION_LONG,-88.1985 -US-UiD,90990,GRP_LOCATION,LOCATION_ELEV,224 -US-UiD,90990,GRP_LOCATION,LOCATION_DATE_START,200807231030 -US-UiD,90984,GRP_NETWORK,NETWORK,AmeriFlux -US-UiD,90994,GRP_SITE_CHAR,TERRAIN,Flat -US-UiD,90994,GRP_SITE_CHAR,ASPECT,FLAT -US-UiD,90994,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,110 -US-UiD,90987,GRP_SITE_DESC,SITE_DESC,"Site harvested annually with a mower during winters starting 2009. No fertilizer was applied, and not irrigated." -US-UiD,90983,GRP_STATE,STATE,IL -US-UiD,90982,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Carl J Bernacchi -US-UiD,90982,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-UiD,90982,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,bernacch@illinois.edu -US-UiD,90982,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,USDA/ARS -US-UiD,92768,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Bethany J Blakely -US-UiD,92768,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-UiD,92768,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,blakely6@illinois.edu -US-UiD,92768,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Illinois Urbana-Champaign -US-UiD,92768,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"196 ERML, 1201 W Gregory Dr, Urbana IL 61801" -US-UiD,90980,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Caitlin E Moore -US-UiD,90980,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-UiD,90980,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,moore.e.caitlin@gmail.com -US-UiD,90980,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Illinois Urbana-Champaign -US-UiD,90978,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Evan C Dracup -US-UiD,90978,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Technician -US-UiD,90978,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,edracup@illinois.edu -US-UiD,90978,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,USDA/ARS -US-UiD,90981,GRP_TOWER_POWER,TOWER_POWER,Direct power -US-UiD,90986,GRP_TOWER_TYPE,TOWER_TYPE,other -US-UiD,90979,GRP_URL,URL,http://www.life.illinois.edu/bernacchi/ -US-UiD,24001119,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-UiD -US-UiD,98546,GRP_UTC_OFFSET,UTC_OFFSET,-6 -US-UiE,99556,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,"This work was funded by the DOE Center for Advanced Bioenergy and Bioproducts Innovation (U.S. Department of Energy, Office of Science, Office of Biological and Environmental Research under Award Number DE-SC0018420), the Energy Biosciences Institute at the University of Illinois Urbana-Champaign & the Global Change and Photosynthesis Research Unit of the United States Department of Agriculture/Agricultural Research Service." -US-UiE,99549,GRP_CLIM_AVG,MAT,11.2 -US-UiE,99549,GRP_CLIM_AVG,MAP,1021 -US-UiE,99549,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfa -US-UiE,27001224,GRP_COUNTRY,COUNTRY,USA -US-UiE,99548,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Agriculture -US-UiE,99565,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Storm or wind -US-UiE,99547,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-UiE,99547,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-UiE,99547,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20180701 -US-UiE,99547,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-UiE,99561,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-UiE,99561,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-UiE,99561,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20180701 -US-UiE,99561,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-UiE,99546,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-UiE,99546,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-UiE,99546,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20180701 -US-UiE,99546,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-UiE,23001224,GRP_HEADER,SITE_NAME,University of Illinois Sorghum-Soy -US-UiE,99550,GRP_IGBP,IGBP,CRO -US-UiE,99550,GRP_IGBP,IGBP_COMMENT,This field was planted in sorghum-soy rotation starting in 2017. It was almost certainly cropland before this date but the specific crop type is unknown -US-UiE,99563,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-UiE,99563,GRP_LAND_OWNERSHIP,LAND_OWNER,University of Illinois at Urbana-Champaign -US-UiE,99564,GRP_LOCATION,LOCATION_LAT,40.0629 -US-UiE,99564,GRP_LOCATION,LOCATION_LONG,-88.2033 -US-UiE,99564,GRP_LOCATION,LOCATION_ELEV,217 -US-UiE,99564,GRP_LOCATION,LOCATION_COMMENT,This is a 4ha experimental field established at the University of Illinois at Urbana-Champaign Energy Farm -US-UiE,99559,GRP_NETWORK,NETWORK,AmeriFlux -US-UiE,99554,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"196 ERML, 1201 W Gregory Dr, Urbana IL 61801" -US-UiE,99558,GRP_SITE_CHAR,TERRAIN,Gentle slope (<2 %) -US-UiE,99558,GRP_SITE_CHAR,ASPECT,FLAT -US-UiE,99558,GRP_SITE_CHAR,WIND_DIRECTION,S -US-UiE,99558,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,100 -US-UiE,99553,GRP_SITE_DESC,SITE_DESC,"Agricultural field planted with photoperiod-sensitive (""energy"") sorghum bicolor in a three year rotation with soy (sorghum-sorghum-soy). The first soy rotation was in 2019. This field is typically planted in May and harvested for biomass (sorghum) or grain (soy) in October. This site is located at an experimental farm approximately 2 miles south of the University of Illinois at Urbana Champaign and is colocated with (500-1000m distance) all other Us-Ui sites." -US-UiE,99555,GRP_SITE_FUNDING,SITE_FUNDING,Center for Advance Bioenergy and Bioproducts Innovation (CABBI) -US-UiE,99552,GRP_STATE,STATE,IL -US-UiE,99560,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Carl Bernacchi -US-UiE,99560,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-UiE,99560,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,bernacch@illinois.edu -US-UiE,99560,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,USDA/ARS -US-UiE,99560,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"196 ERML, 1201 W Gregory Dr, Urbana IL 61801" -US-UiE,99551,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Bethany Blakely -US-UiE,99551,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-UiE,99551,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,blakely6@illinois.edu -US-UiE,99551,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Illinois Urbana-Champaign -US-UiE,99551,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"196 ERML, 1201 W Gregory Dr, Urbana IL 61801" -US-UiE,99562,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Taylor Pederson -US-UiE,99562,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Technician -US-UiE,99562,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,tpeders2@illinois.edu -US-UiE,99562,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Illinois Urbana-Champaign -US-UiE,99562,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"196 ERML, 1201 W Gregory Dr, Urbana IL 61801" -US-UiE,99567,GRP_TOWER_POWER,TOWER_POWER,Direct power -US-UiE,99557,GRP_TOWER_TYPE,TOWER_TYPE,other -US-UiE,24001224,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-UiE -US-UiE,99566,GRP_UTC_OFFSET,UTC_OFFSET,-6 -US-UiE,99566,GRP_UTC_OFFSET,UTC_OFFSET_COMMENT,"This site remains on CST (GMT-6) year-round, ignoring daylight savings time" -US-UM3,14772,GRP_CLIM_AVG,MAT,5.83 -US-UM3,14772,GRP_CLIM_AVG,MAP,803 -US-UM3,14772,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfb -US-UM3,27000548,GRP_COUNTRY,COUNTRY,USA -US-UM3,85250,GRP_DOI,DOI,10.17190/AMF/1480315 -US-UM3,85250,GRP_DOI,DOI_CITATION,"Gil Bohrer (2018), AmeriFlux BASE US-UM3 Douglas Lake, Ver. 1-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1480315" -US-UM3,85250,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-UM3,83446,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-UM3,83446,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Gil Bohrer -US-UM3,83446,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-UM3,83446,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,bohrer.17@osu.edu -US-UM3,83446,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,The Ohio State University -US-UM3,83453,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,The Ohio State University -US-UM3,83453,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-UM3,91814,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-UM3,91814,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-UM3,91814,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20130707 -US-UM3,91814,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20140827 -US-UM3,91814,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Growing season operation only -US-UM3,91813,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-UM3,91813,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-UM3,91813,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20130707 -US-UM3,91813,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20140827 -US-UM3,91813,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Growing season operation only -US-UM3,91820,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-UM3,91820,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-UM3,91820,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20130707 -US-UM3,91820,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20140827 -US-UM3,91820,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Growing season operation only -US-UM3,23000548,GRP_HEADER,SITE_NAME,Douglas Lake -US-UM3,14774,GRP_IGBP,IGBP,WAT -US-UM3,14775,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-UM3,14775,GRP_LAND_OWNERSHIP,LAND_OWNER,University of Michigan -US-UM3,14776,GRP_LOCATION,LOCATION_LAT,45.5686 -US-UM3,14776,GRP_LOCATION,LOCATION_LONG,-84.6707 -US-UM3,14776,GRP_LOCATION,LOCATION_ELEV,234 -US-UM3,14776,GRP_LOCATION,LOCATION_DATE_START,20130707 -US-UM3,14777,GRP_NETWORK,NETWORK,AmeriFlux -US-UM3,1700008379,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Kenny, W. T., Bohrer, G., Morin, T. H., Vogel, C. S., Matheny, A. M., Desai, A. R. (2017) A Numerical Case Study Of The Implications Of Secondary Circulations To The Interpretation Of Eddy-Covariance Measurements Over Small Lakes, Boundary-Layer Meteorology, 165(2), 311-332" -US-UM3,1700008379,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1007/S10546-017-0268-8 -US-UM3,1700008379,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-UM3,1700006315,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Morin, T., Rey-Sánchez, A., Vogel, C., Matheny, A., Kenny, W., Bohrer, G. (2018) Carbon Dioxide Emissions From An Oligotrophic Temperate Lake: An Eddy Covariance Approach, Ecological Engineering, 114(), 25-33" -US-UM3,1700006315,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.ECOLENG.2017.05.005 -US-UM3,1700006315,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-UM3,1700004629,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Morin, T., Rey-Sánchez, A., Vogel, C., Matheny, A., Kenny, W., Bohrer, G. (2018) Carbon Dioxide Emissions From An Oligotrophic Temperate Lake: An Eddy Covariance Approach, Ecological Engineering, 114(2), 25-33" -US-UM3,1700004629,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.ECOLENG.2017.05.005 -US-UM3,1700004629,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-UM3,14778,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,Lake/forest carbon interactions -US-UM3,14779,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"470 Hitchcock Hall, 2070 Neil Avenue, Columbus, OH 43210" -US-UM3,14780,GRP_SITE_CHAR,TERRAIN,Flat -US-UM3,14780,GRP_SITE_CHAR,ASPECT,W -US-UM3,14780,GRP_SITE_CHAR,WIND_DIRECTION,NW -US-UM3,14780,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,600 -US-UM3,14781,GRP_SITE_DESC,SITE_DESC,Douglas Lake is a small inland freshwater lake surrounded by an early successional forest. -US-UM3,14782,GRP_STATE,STATE,OH -US-UM3,14783,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Gil Bohrer -US-UM3,14783,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-UM3,14783,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,bohrer.17@osu.edu -US-UM3,14783,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,The Ohio State University -US-UM3,14783,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"470 Hitchcock Hall, 2070 Neil Avenue, Columbus, OH 43210" -US-UM3,14784,GRP_TOWER_TYPE,TOWER_TYPE,triangle -US-UM3,24000548,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-UM3 -US-UM3,81427,GRP_UTC_OFFSET,UTC_OFFSET,-5 -US-UMB,18548,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER,113.6 -US-UMB,18548,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_SPATIAL_VARIABILITY,23.9 -US-UMB,18548,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_SPATIAL_REP_NUMBER,13 -US-UMB,18548,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_ORGAN,Foliage -US-UMB,18548,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_PHEN,Senescent -US-UMB,18548,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_UNIT,gC m-2 -US-UMB,18548,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_APPROACH,Tree AG wood total biomass =a*D^b where D=DBH (diam. At 1.37m) and a and b are species specific coefficients. DBH determined from complete census and measurement of all trees in all plots. Resulting biomass multiplied by wood carbon fraction. AG_BIOMASS_OTHER_ORGAN is tree foliage captured by litter traps 1 m above forest floor -US-UMB,18548,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_DATE,20100721 -US-UMB,18548,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_DATE_UNC,28 -US-UMB,18548,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_COMMENT,Litter traps are .264 m^2 with one trap in each of 60 - 0.08 ha plots and 20 traps in a 1.13 ha plot with flux tower a plot center. Litter trap collection date is 20011020 ± 20 d -US-UMB,18443,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER,114 -US-UMB,18443,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_SPATIAL_VARIABILITY,28.7 -US-UMB,18443,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_SPATIAL_REP_NUMBER,50 -US-UMB,18443,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_ORGAN,Foliage -US-UMB,18443,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_PHEN,Senescent -US-UMB,18443,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_UNIT,gC m-2 -US-UMB,18443,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_APPROACH,Tree AG wood total biomass =a*D^b where D=DBH (diam. At 1.37m) and a and b are species specific coefficients. DBH determined from increment bands installed on 15% of trees with DBH>= 10 cm. Resulting biomass multiplied by wood carbon fraction. AG_BIOMASS_OTHER_ORGAN is tree foliage captured by litter traps 1 m above forest floor -US-UMB,18443,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_DATE,20061020 -US-UMB,18443,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_DATE_UNC,20 -US-UMB,18443,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_COMMENT,Increment bands are capable of detecting 0.13 mm diameter change. Increment bands are read each year after leaf abscission and after AG growth has ceased. Growth of all trees extrapolated from regressions developed from banded trees. Litter traps are .264 m^2 with one trap in each of 60 - 0.08 ha plots and 20 traps in a 1.13 ha plot with flux tower a plot center. -US-UMB,18532,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER,114.2 -US-UMB,18532,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_SPATIAL_VARIABILITY,23.9 -US-UMB,18532,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_SPATIAL_REP_NUMBER,15 -US-UMB,18532,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_ORGAN,Foliage -US-UMB,18532,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_PHEN,Senescent -US-UMB,18532,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_UNIT,gC m-2 -US-UMB,18532,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_APPROACH,Tree AG wood total biomass =a*D^b where D=DBH (diam. At 1.37m) and a and b are species specific coefficients. DBH determined from increment bands installed on 15% of trees with DBH>= 10 cm. Resulting biomass multiplied by wood carbon fraction. AG_BIOMASS_OTHER_ORGAN is tree foliage captured by litter traps 1 m above forest floor -US-UMB,18532,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_DATE,20081020 -US-UMB,18532,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_DATE_UNC,20 -US-UMB,18532,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_COMMENT,Increment bands are capable of detecting 0.13 mm diameter change. Increment bands are read each year after leaf abscission and after AG growth has ceased. Growth of all trees extrapolated from regressions developed from banded trees. Litter traps are .264 m^2 with one trap in each of 60 - 0.08 ha plots and 20 traps in a 1.13 ha plot with flux tower a plot center. -US-UMB,18475,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER,114.7 -US-UMB,18475,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_SPATIAL_VARIABILITY,23.8 -US-UMB,18475,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_SPATIAL_REP_NUMBER,16 -US-UMB,18475,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_ORGAN,Foliage -US-UMB,18475,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_PHEN,Senescent -US-UMB,18475,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_UNIT,gC m-2 -US-UMB,18475,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_APPROACH,Tree AG wood total biomass =a*D^b where D=DBH (diam. At 1.37m) and a and b are species specific coefficients. DBH determined from increment bands installed on 15% of trees with DBH>= 10 cm. Resulting biomass multiplied by wood carbon fraction. AG_BIOMASS_OTHER_ORGAN is tree foliage captured by litter traps 1 m above forest floor -US-UMB,18475,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_DATE,20131020 -US-UMB,18475,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_DATE_UNC,20 -US-UMB,18475,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_COMMENT,Increment bands are capable of detecting 0.13 mm diameter change. Increment bands are read each year after leaf abscission and after AG growth has ceased. Growth of all trees extrapolated from regressions developed from banded trees. Litter traps are .264 m^2 with one trap in each of 60 - 0.08 ha plots and 20 traps in a 1.13 ha plot with flux tower a plot center. -US-UMB,18521,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER,115.3 -US-UMB,18521,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_SPATIAL_VARIABILITY,24.6 -US-UMB,18521,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_SPATIAL_REP_NUMBER,50 -US-UMB,18521,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_ORGAN,Foliage -US-UMB,18521,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_PHEN,Senescent -US-UMB,18521,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_UNIT,gC m-2 -US-UMB,18521,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_APPROACH,Tree AG wood total biomass =a*D^b where D=DBH (diam. At 1.37m) and a and b are species specific coefficients. DBH determined from increment bands installed on 15% of trees with DBH>= 10 cm. Resulting biomass multiplied by wood carbon fraction. AG_BIOMASS_OTHER_ORGAN is tree foliage captured by litter traps 1 m above forest floor -US-UMB,18521,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_DATE,20041020 -US-UMB,18521,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_DATE_UNC,20 -US-UMB,18521,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_COMMENT,Increment bands are capable of detecting 0.13 mm diameter change. Increment bands are read each year after leaf abscission and after AG growth has ceased. Growth of all trees extrapolated from regressions developed from banded trees. Litter traps are .264 m^2 with one trap in each of 60 - 0.08 ha plots and 20 traps in a 1.13 ha plot with flux tower a plot center. -US-UMB,18461,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER,116.9 -US-UMB,18461,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_SPATIAL_VARIABILITY,23.68 -US-UMB,18461,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_SPATIAL_REP_NUMBER,16 -US-UMB,18461,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_ORGAN,Foliage -US-UMB,18461,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_PHEN,Senescent -US-UMB,18461,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_UNIT,gC m-2 -US-UMB,18461,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_APPROACH,Tree AG wood total biomass =a*D^b where D=DBH (diam. At 1.37m) and a and b are species specific coefficients. DBH determined from increment bands installed on 15% of trees with DBH>= 10 cm. Resulting biomass multiplied by wood carbon fraction. AG_BIOMASS_OTHER_ORGAN is tree foliage captured by litter traps 1 m above forest floor -US-UMB,18461,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_DATE,20111020 -US-UMB,18461,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_DATE_UNC,20 -US-UMB,18461,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_COMMENT,Increment bands are capable of detecting 0.13 mm diameter change. Increment bands are read each year after leaf abscission and after AG growth has ceased. Growth of all trees extrapolated from regressions developed from banded trees. Litter traps are .264 m^2 with one trap in each of 60 - 0.08 ha plots and 20 traps in a 1.13 ha plot with flux tower a plot center. -US-UMB,18468,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER,119.1 -US-UMB,18468,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_SPATIAL_VARIABILITY,22.3 -US-UMB,18468,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_SPATIAL_REP_NUMBER,16 -US-UMB,18468,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_ORGAN,Foliage -US-UMB,18468,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_PHEN,Senescent -US-UMB,18468,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_UNIT,gC m-2 -US-UMB,18468,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_APPROACH,Tree AG wood total biomass =a*D^b where D=DBH (diam. At 1.37m) and a and b are species specific coefficients. DBH determined from increment bands installed on 15% of trees with DBH>= 10 cm. Resulting biomass multiplied by wood carbon fraction. AG_BIOMASS_OTHER_ORGAN is tree foliage captured by litter traps 1 m above forest floor -US-UMB,18468,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_DATE,20121020 -US-UMB,18468,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_DATE_UNC,20 -US-UMB,18468,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_COMMENT,Increment bands are capable of detecting 0.13 mm diameter change. Increment bands are read each year after leaf abscission and after AG growth has ceased. Growth of all trees extrapolated from regressions developed from banded trees. Litter traps are .264 m^2 with one trap in each of 60 - 0.08 ha plots and 20 traps in a 1.13 ha plot with flux tower a plot center. -US-UMB,18451,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER,121.4 -US-UMB,18451,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_SPATIAL_VARIABILITY,26 -US-UMB,18451,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_SPATIAL_REP_NUMBER,50 -US-UMB,18451,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_ORGAN,Foliage -US-UMB,18451,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_PHEN,Senescent -US-UMB,18451,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_UNIT,gC m-2 -US-UMB,18451,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_APPROACH,Tree AG wood total biomass =a*D^b where D=DBH (diam. At 1.37m) and a and b are species specific coefficients. DBH determined from increment bands installed on 15% of trees with DBH>= 10 cm. Resulting biomass multiplied by wood carbon fraction. AG_BIOMASS_OTHER_ORGAN is tree foliage captured by litter traps 1 m above forest floor -US-UMB,18451,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_DATE,20071020 -US-UMB,18451,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_DATE_UNC,20 -US-UMB,18451,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_COMMENT,Increment bands are capable of detecting 0.13 mm diameter change. Increment bands are read each year after leaf abscission and after AG growth has ceased. Growth of all trees extrapolated from regressions developed from banded trees. Litter traps are .264 m^2 with one trap in each of 60 - 0.08 ha plots and 20 traps in a 1.13 ha plot with flux tower a plot center. -US-UMB,18529,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER,126.1 -US-UMB,18529,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_SPATIAL_VARIABILITY,26.8 -US-UMB,18529,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_SPATIAL_REP_NUMBER,51 -US-UMB,18529,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_ORGAN,Foliage -US-UMB,18529,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_PHEN,Senescent -US-UMB,18529,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_UNIT,gC m-2 -US-UMB,18529,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_APPROACH,Tree AG wood total biomass =a*D^b where D=DBH (diam. At 1.37m) and a and b are species specific coefficients. DBH determined from increment bands installed on 15% of trees with DBH>= 10 cm. Resulting biomass multiplied by wood carbon fraction. AG_BIOMASS_OTHER_ORGAN is tree foliage captured by litter traps 1 m above forest floor -US-UMB,18529,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_DATE,20051020 -US-UMB,18529,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_DATE_UNC,20 -US-UMB,18529,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_COMMENT,Increment bands are capable of detecting 0.13 mm diameter change. Increment bands are read each year after leaf abscission and after AG growth has ceased. Growth of all trees extrapolated from regressions developed from banded trees. Litter traps are .264 m^2 with one trap in each of 60 - 0.08 ha plots and 20 traps in a 1.13 ha plot with flux tower a plot center. -US-UMB,18540,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER,126.6 -US-UMB,18540,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_SPATIAL_VARIABILITY,17.4 -US-UMB,18540,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_SPATIAL_REP_NUMBER,15 -US-UMB,18540,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_ORGAN,Foliage -US-UMB,18540,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_PHEN,Senescent -US-UMB,18540,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_UNIT,gC m-2 -US-UMB,18540,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_APPROACH,Tree AG wood total biomass =a*D^b where D=DBH (diam. At 1.37m) and a and b are species specific coefficients. DBH determined from increment bands installed on 15% of trees with DBH>= 10 cm. Resulting biomass multiplied by wood carbon fraction. AG_BIOMASS_OTHER_ORGAN is tree foliage captured by litter traps 1 m above forest floor -US-UMB,18540,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_DATE,20091020 -US-UMB,18540,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_DATE_UNC,20 -US-UMB,18540,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_COMMENT,Increment bands are capable of detecting 0.13 mm diameter change. Increment bands are read each year after leaf abscission and after AG growth has ceased. Growth of all trees extrapolated from regressions developed from banded trees. Litter traps are .264 m^2 with one trap in each of 60 - 0.08 ha plots and 20 traps in a 1.13 ha plot with flux tower a plot center. -US-UMB,18401,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER,127.9 -US-UMB,18401,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_SPATIAL_VARIABILITY,25.7 -US-UMB,18401,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_SPATIAL_REP_NUMBER,61 -US-UMB,18401,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_ORGAN,Foliage -US-UMB,18401,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_PHEN,Senescent -US-UMB,18401,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_UNIT,gC m-2 -US-UMB,18401,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_APPROACH,Tree AG wood total biomass =a*D^b where D=DBH (diam. At 1.37m) and a and b are species specific coefficients. DBH determined from increment bands installed on 15% of trees with DBH>= 10 cm. Resulting biomass multiplied by wood carbon fraction. AG_BIOMASS_OTHER_ORGAN is tree foliage captured by litter traps 1 m above forest floor -US-UMB,18401,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_DATE,19991020 -US-UMB,18401,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_DATE_UNC,20 -US-UMB,18401,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_COMMENT,Increment bands are capable of detecting 0.13 mm diameter change. Increment bands are read each year after leaf abscission and after AG growth has ceased. Growth of all trees extrapolated from regressions developed from banded trees. Litter traps are .179 m^2 with one trap in each of 60 - 0.08 ha plots and 20 traps in a 1.13 ha plot with flux tower a plot center. -US-UMB,18422,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER,129.5 -US-UMB,18422,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_SPATIAL_VARIABILITY,30.4 -US-UMB,18422,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_SPATIAL_REP_NUMBER,60 -US-UMB,18422,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_ORGAN,Foliage -US-UMB,18422,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_PHEN,Senescent -US-UMB,18422,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_UNIT,gC m-2 -US-UMB,18422,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_APPROACH,Tree AG wood total biomass =a*D^b where D=DBH (diam. At 1.37m) and a and b are species specific coefficients. DBH determined from complete census and measurement of all trees in all plots. Resulting biomass multiplied by wood carbon fraction. AG_BIOMASS_OTHER_ORGAN is tree foliage captured by litter traps 1 m above forest floor -US-UMB,18422,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_DATE,20010721 -US-UMB,18422,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_DATE_UNC,28 -US-UMB,18422,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_COMMENT,Litter traps are .179 m^2 with one trap in each of 60 - 0.08 ha plots and 20 traps in a 1.13 ha plot with flux tower at plot center. Litter trap collection date is 20011020 ± 20 d -US-UMB,18390,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER,133.8 -US-UMB,18390,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_SPATIAL_VARIABILITY,28.2 -US-UMB,18390,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_SPATIAL_REP_NUMBER,61 -US-UMB,18390,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_ORGAN,Foliage -US-UMB,18390,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_PHEN,Senescent -US-UMB,18390,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_UNIT,gC m-2 -US-UMB,18390,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_APPROACH,Tree AG wood total biomass =a*D^b where D=DBH (diam. At 1.37m) and a and b are species specific coefficients. DBH determined from complete census and measurement of all trees in all plots. Resulting biomass multiplied by wood carbon fraction. AG_BIOMASS_OTHER_ORGAN is tree foliage captured by litter traps 1 m above forest floor -US-UMB,18390,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_DATE,19980721 -US-UMB,18390,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_DATE_UNC,28 -US-UMB,18390,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_COMMENT,Litter traps are .179 m^2 with one trap in each of 60 - 0.08 ha plots and 20 traps in a 1.13 ha plot with flux tower a plot center. Litter trap collection date is 20011020 ± 20 d -US-UMB,18513,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER,133.9 -US-UMB,18513,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_SPATIAL_VARIABILITY,28 -US-UMB,18513,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_SPATIAL_REP_NUMBER,31 -US-UMB,18513,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_ORGAN,Foliage -US-UMB,18513,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_PHEN,Senescent -US-UMB,18513,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_UNIT,gC m-2 -US-UMB,18513,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_APPROACH,Tree AG wood total biomass =a*D^b where D=DBH (diam. At 1.37m) and a and b are species specific coefficients. DBH determined from increment bands installed on 15% of trees with DBH>= 10 cm. Resulting biomass multiplied by wood carbon fraction. Twenty new 0.08 ha plots added to existing plots. AG_BIOMASS_OTHER_ORGAN is tree foliage captured by litter traps 1 m above forest floor -US-UMB,18513,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_DATE,20031020 -US-UMB,18513,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_DATE_UNC,20 -US-UMB,18513,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_COMMENT,Increment bands are capable of detecting 0.13 mm diameter change. Increment bands are read each year after leaf abscission and after AG growth has ceased. Growth of all trees extrapolated from regressions developed from banded trees. Litter traps are .264 m^2 with one trap in each of 60 - 0.08 ha plots and 20 traps in a 1.13 ha plot with flux tower a plot center. -US-UMB,18432,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER,137.5 -US-UMB,18432,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_SPATIAL_VARIABILITY,33.2 -US-UMB,18432,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_SPATIAL_REP_NUMBER,31 -US-UMB,18432,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_ORGAN,Foliage -US-UMB,18432,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_PHEN,Senescent -US-UMB,18432,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_UNIT,gC m-2 -US-UMB,18432,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_APPROACH,Tree AG wood total biomass =a*D^b where D=DBH (diam. At 1.37m) and a and b are species specific coefficients. DBH determined from increment bands installed on 15% of trees with DBH>= 10 cm. Resulting biomass multiplied by wood carbon fraction. AG_BIOMASS_OTHER_ORGAN is tree foliage captured by litter traps 1 m above forest floor -US-UMB,18432,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_DATE,20021020 -US-UMB,18432,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_DATE_UNC,20 -US-UMB,18432,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_COMMENT,Increment bands are capable of detecting 0.13 mm diameter change. Increment bands are read each year after leaf abscission and after AG growth has ceased. Growth of all trees extrapolated from regressions developed from banded trees. Litter traps are .264 m^2 with 1 trap in each of 30 - 0.08 ha plots and 20 traps in a 1.13 ha plot with flux tower a plot center. -US-UMB,18412,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER,146.5 -US-UMB,18412,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_SPATIAL_VARIABILITY,29.6 -US-UMB,18412,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_SPATIAL_REP_NUMBER,60 -US-UMB,18412,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_ORGAN,Foliage -US-UMB,18412,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_PHEN,Senescent -US-UMB,18412,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_UNIT,gC m-2 -US-UMB,18412,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_APPROACH,Tree AG wood total biomass =a*D^b where D=DBH (diam. At 1.37m) and a and b are species specific coefficients. DBH determined from increment bands installed on 15% of trees with DBH>= 10 cm. Resulting biomass multiplied by wood carbon fraction. AG_BIOMASS_OTHER_ORGAN is tree foliage captured by litter traps 1 m above forest floor -US-UMB,18412,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_DATE,20001020 -US-UMB,18412,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_DATE_UNC,20 -US-UMB,18412,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_COMMENT,Increment bands are capable of detecting 0.13 mm diameter change. Increment bands are read each year after leaf abscission and after AG growth has ceased. Growth of all trees extrapolated from regressions developed from banded trees. Litter traps are .179 m^2 with one trap in each of 59 - 0.08 ha plots and 20 traps in a 1.13 ha plot with flux tower a plot center. -US-UMB,18391,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,6476.7 -US-UMB,18391,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_SPATIAL_VARIABILITY,2218.2 -US-UMB,18391,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_SPATIAL_REP_NUMBER,61 -US-UMB,18391,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Wood -US-UMB,18391,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Green -US-UMB,18391,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-UMB,18391,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,Tree AG wood total biomass =a*D^b where D=DBH (diam. At 1.37m) and a and b are species specific coefficients. DBH determined from complete census and measurement of all trees in all plots. Resulting biomass multiplied by wood carbon fraction. AG_BIOMASS_OTHER_ORGAN is tree foliage captured by litter traps 1 m above forest floor -US-UMB,18391,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,19980721 -US-UMB,18391,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE_UNC,28 -US-UMB,18391,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,Litter traps are .179 m^2 with one trap in each of 60 - 0.08 ha plots and 20 traps in a 1.13 ha plot with flux tower a plot center. Litter trap collection date is 20011020 ± 20 d -US-UMB,18402,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,6670 -US-UMB,18402,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_SPATIAL_VARIABILITY,2270.5 -US-UMB,18402,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_SPATIAL_REP_NUMBER,61 -US-UMB,18402,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Wood -US-UMB,18402,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-UMB,18402,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-UMB,18402,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,Tree AG wood total biomass =a*D^b where D=DBH (diam. At 1.37m) and a and b are species specific coefficients. DBH determined from increment bands installed on 15% of trees with DBH>= 10 cm. Resulting biomass multiplied by wood carbon fraction. AG_BIOMASS_OTHER_ORGAN is tree foliage captured by litter traps 1 m above forest floor -US-UMB,18402,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,19991020 -US-UMB,18402,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE_UNC,20 -US-UMB,18402,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,Increment bands are capable of detecting 0.13 mm diameter change. Increment bands are read each year after leaf abscission and after AG growth has ceased. Growth of all trees extrapolated from regressions developed from banded trees. Litter traps are .179 m^2 with one trap in each of 60 - 0.08 ha plots and 20 traps in a 1.13 ha plot with flux tower a plot center. -US-UMB,18413,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,6860.6 -US-UMB,18413,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_SPATIAL_VARIABILITY,2318.1 -US-UMB,18413,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_SPATIAL_REP_NUMBER,61 -US-UMB,18413,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Wood -US-UMB,18413,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-UMB,18413,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-UMB,18413,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,Tree AG wood total biomass =a*D^b where D=DBH (diam. At 1.37m) and a and b are species specific coefficients. DBH determined from increment bands installed on 15% of trees with DBH>= 10 cm. Resulting biomass multiplied by wood carbon fraction. AG_BIOMASS_OTHER_ORGAN is tree foliage captured by litter traps 1 m above forest floor -US-UMB,18413,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,20001020 -US-UMB,18413,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE_UNC,20 -US-UMB,18413,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,Increment bands are capable of detecting 0.13 mm diameter change. Increment bands are read each year after leaf abscission and after AG growth has ceased. Growth of all trees extrapolated from regressions developed from banded trees. Litter traps are .179 m^2 with one trap in each of 59 - 0.08 ha plots and 20 traps in a 1.13 ha plot with flux tower a plot center. -US-UMB,18423,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,6866.1 -US-UMB,18423,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_SPATIAL_VARIABILITY,2212.7 -US-UMB,18423,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_SPATIAL_REP_NUMBER,61 -US-UMB,18423,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Wood -US-UMB,18423,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Green -US-UMB,18423,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-UMB,18423,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,Tree AG wood total biomass =a*D^b where D=DBH (diam. At 1.37m) and a and b are species specific coefficients. DBH determined from complete census and measurement of all trees in all plots. Resulting biomass multiplied by wood carbon fraction. AG_BIOMASS_OTHER_ORGAN is tree foliage captured by litter traps 1 m above forest floor -US-UMB,18423,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,20010721 -US-UMB,18423,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE_UNC,28 -US-UMB,18423,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,Litter traps are .179 m^2 with one trap in each of 60 - 0.08 ha plots and 20 traps in a 1.13 ha plot with flux tower at plot center. Litter trap collection date is 20011020 ± 20 d -US-UMB,18433,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,7011.9 -US-UMB,18433,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_SPATIAL_VARIABILITY,2254.1 -US-UMB,18433,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_SPATIAL_REP_NUMBER,61 -US-UMB,18433,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Wood -US-UMB,18433,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-UMB,18433,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-UMB,18433,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,Tree AG wood total biomass =a*D^b where D=DBH (diam. At 1.37m) and a and b are species specific coefficients. DBH determined from increment bands installed on 15% of trees with DBH>= 10 cm. Resulting biomass multiplied by wood carbon fraction. AG_BIOMASS_OTHER_ORGAN is tree foliage captured by litter traps 1 m above forest floor -US-UMB,18433,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,20021020 -US-UMB,18433,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE_UNC,20 -US-UMB,18433,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,Increment bands are capable of detecting 0.13 mm diameter change. Increment bands are read each year after leaf abscission and after AG growth has ceased. Growth of all trees extrapolated from regressions developed from banded trees. Litter traps are .264 m^2 with 1 trap in each of 30 - 0.08 ha plots and 20 traps in a 1.13 ha plot with flux tower a plot center. -US-UMB,18514,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,7181.6 -US-UMB,18514,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_SPATIAL_VARIABILITY,2288.7 -US-UMB,18514,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_SPATIAL_REP_NUMBER,81 -US-UMB,18514,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Wood -US-UMB,18514,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-UMB,18514,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-UMB,18514,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,Tree AG wood total biomass =a*D^b where D=DBH (diam. At 1.37m) and a and b are species specific coefficients. DBH determined from increment bands installed on 15% of trees with DBH>= 10 cm. Resulting biomass multiplied by wood carbon fraction. Twenty new 0.08 ha plots added to existing plots. AG_BIOMASS_OTHER_ORGAN is tree foliage captured by litter traps 1 m above forest floor -US-UMB,18514,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,20031020 -US-UMB,18514,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE_UNC,20 -US-UMB,18514,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,Increment bands are capable of detecting 0.13 mm diameter change. Increment bands are read each year after leaf abscission and after AG growth has ceased. Growth of all trees extrapolated from regressions developed from banded trees. Litter traps are .264 m^2 with one trap in each of 60 - 0.08 ha plots and 20 traps in a 1.13 ha plot with flux tower a plot center. -US-UMB,18522,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,7361.3 -US-UMB,18522,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_SPATIAL_VARIABILITY,2334.5 -US-UMB,18522,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_SPATIAL_REP_NUMBER,81 -US-UMB,18522,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Wood -US-UMB,18522,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-UMB,18522,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-UMB,18522,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,Tree AG wood total biomass =a*D^b where D=DBH (diam. At 1.37m) and a and b are species specific coefficients. DBH determined from increment bands installed on 15% of trees with DBH>= 10 cm. Resulting biomass multiplied by wood carbon fraction. AG_BIOMASS_OTHER_ORGAN is tree foliage captured by litter traps 1 m above forest floor -US-UMB,18522,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,20041020 -US-UMB,18522,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE_UNC,20 -US-UMB,18522,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,Increment bands are capable of detecting 0.13 mm diameter change. Increment bands are read each year after leaf abscission and after AG growth has ceased. Growth of all trees extrapolated from regressions developed from banded trees. Litter traps are .264 m^2 with one trap in each of 60 - 0.08 ha plots and 20 traps in a 1.13 ha plot with flux tower a plot center. -US-UMB,18530,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,7513.7 -US-UMB,18530,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_SPATIAL_VARIABILITY,2374.8 -US-UMB,18530,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_SPATIAL_REP_NUMBER,81 -US-UMB,18530,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Wood -US-UMB,18530,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-UMB,18530,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-UMB,18530,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,Tree AG wood total biomass =a*D^b where D=DBH (diam. At 1.37m) and a and b are species specific coefficients. DBH determined from increment bands installed on 15% of trees with DBH>= 10 cm. Resulting biomass multiplied by wood carbon fraction. AG_BIOMASS_OTHER_ORGAN is tree foliage captured by litter traps 1 m above forest floor -US-UMB,18530,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,20051020 -US-UMB,18530,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE_UNC,20 -US-UMB,18530,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,Increment bands are capable of detecting 0.13 mm diameter change. Increment bands are read each year after leaf abscission and after AG growth has ceased. Growth of all trees extrapolated from regressions developed from banded trees. Litter traps are .264 m^2 with one trap in each of 60 - 0.08 ha plots and 20 traps in a 1.13 ha plot with flux tower a plot center. -US-UMB,18549,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,7666.67 -US-UMB,18549,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_SPATIAL_VARIABILITY,2424.9 -US-UMB,18549,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_SPATIAL_REP_NUMBER,78 -US-UMB,18549,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Wood -US-UMB,18549,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Green -US-UMB,18549,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-UMB,18549,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,Tree AG wood total biomass =a*D^b where D=DBH (diam. At 1.37m) and a and b are species specific coefficients. DBH determined from complete census and measurement of all trees in all plots. Resulting biomass multiplied by wood carbon fraction. AG_BIOMASS_OTHER_ORGAN is tree foliage captured by litter traps 1 m above forest floor -US-UMB,18549,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,20100721 -US-UMB,18549,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE_UNC,28 -US-UMB,18549,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,Litter traps are .264 m^2 with one trap in each of 60 - 0.08 ha plots and 20 traps in a 1.13 ha plot with flux tower a plot center. Litter trap collection date is 20011020 ± 20 d -US-UMB,18444,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,7693.5 -US-UMB,18444,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_SPATIAL_VARIABILITY,2423.5 -US-UMB,18444,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_SPATIAL_REP_NUMBER,81 -US-UMB,18444,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Wood -US-UMB,18444,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-UMB,18444,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-UMB,18444,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,Tree AG wood total biomass =a*D^b where D=DBH (diam. At 1.37m) and a and b are species specific coefficients. DBH determined from increment bands installed on 15% of trees with DBH>= 10 cm. Resulting biomass multiplied by wood carbon fraction. AG_BIOMASS_OTHER_ORGAN is tree foliage captured by litter traps 1 m above forest floor -US-UMB,18444,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,20061020 -US-UMB,18444,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE_UNC,20 -US-UMB,18444,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,Increment bands are capable of detecting 0.13 mm diameter change. Increment bands are read each year after leaf abscission and after AG growth has ceased. Growth of all trees extrapolated from regressions developed from banded trees. Litter traps are .264 m^2 with one trap in each of 60 - 0.08 ha plots and 20 traps in a 1.13 ha plot with flux tower a plot center. -US-UMB,18462,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,7829.1 -US-UMB,18462,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_SPATIAL_VARIABILITY,2450.4 -US-UMB,18462,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_SPATIAL_REP_NUMBER,78 -US-UMB,18462,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Wood -US-UMB,18462,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-UMB,18462,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-UMB,18462,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,Tree AG wood total biomass =a*D^b where D=DBH (diam. At 1.37m) and a and b are species specific coefficients. DBH determined from increment bands installed on 15% of trees with DBH>= 10 cm. Resulting biomass multiplied by wood carbon fraction. AG_BIOMASS_OTHER_ORGAN is tree foliage captured by litter traps 1 m above forest floor -US-UMB,18462,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,20111020 -US-UMB,18462,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE_UNC,20 -US-UMB,18462,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,Increment bands are capable of detecting 0.13 mm diameter change. Increment bands are read each year after leaf abscission and after AG growth has ceased. Growth of all trees extrapolated from regressions developed from banded trees. Litter traps are .264 m^2 with one trap in each of 60 - 0.08 ha plots and 20 traps in a 1.13 ha plot with flux tower a plot center. -US-UMB,18452,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,7864.1 -US-UMB,18452,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_SPATIAL_VARIABILITY,2468 -US-UMB,18452,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_SPATIAL_REP_NUMBER,81 -US-UMB,18452,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Wood -US-UMB,18452,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-UMB,18452,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-UMB,18452,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,Tree AG wood total biomass =a*D^b where D=DBH (diam. At 1.37m) and a and b are species specific coefficients. DBH determined from increment bands installed on 15% of trees with DBH>= 10 cm. Resulting biomass multiplied by wood carbon fraction. AG_BIOMASS_OTHER_ORGAN is tree foliage captured by litter traps 1 m above forest floor -US-UMB,18452,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,20071020 -US-UMB,18452,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE_UNC,20 -US-UMB,18452,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,Increment bands are capable of detecting 0.13 mm diameter change. Increment bands are read each year after leaf abscission and after AG growth has ceased. Growth of all trees extrapolated from regressions developed from banded trees. Litter traps are .264 m^2 with one trap in each of 60 - 0.08 ha plots and 20 traps in a 1.13 ha plot with flux tower a plot center. -US-UMB,18533,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,7971.7 -US-UMB,18533,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_SPATIAL_VARIABILITY,2490.9 -US-UMB,18533,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_SPATIAL_REP_NUMBER,78 -US-UMB,18533,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Wood -US-UMB,18533,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-UMB,18533,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-UMB,18533,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,Tree AG wood total biomass =a*D^b where D=DBH (diam. At 1.37m) and a and b are species specific coefficients. DBH determined from increment bands installed on 15% of trees with DBH>= 10 cm. Resulting biomass multiplied by wood carbon fraction. AG_BIOMASS_OTHER_ORGAN is tree foliage captured by litter traps 1 m above forest floor -US-UMB,18533,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,20081020 -US-UMB,18533,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE_UNC,20 -US-UMB,18533,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,Increment bands are capable of detecting 0.13 mm diameter change. Increment bands are read each year after leaf abscission and after AG growth has ceased. Growth of all trees extrapolated from regressions developed from banded trees. Litter traps are .264 m^2 with one trap in each of 60 - 0.08 ha plots and 20 traps in a 1.13 ha plot with flux tower a plot center. -US-UMB,18469,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,7993.1 -US-UMB,18469,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_SPATIAL_VARIABILITY,2494.1 -US-UMB,18469,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_SPATIAL_REP_NUMBER,78 -US-UMB,18469,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Wood -US-UMB,18469,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-UMB,18469,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-UMB,18469,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,Tree AG wood total biomass =a*D^b where D=DBH (diam. At 1.37m) and a and b are species specific coefficients. DBH determined from increment bands installed on 15% of trees with DBH>= 10 cm. Resulting biomass multiplied by wood carbon fraction. AG_BIOMASS_OTHER_ORGAN is tree foliage captured by litter traps 1 m above forest floor -US-UMB,18469,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,20121020 -US-UMB,18469,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE_UNC,20 -US-UMB,18469,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,Increment bands are capable of detecting 0.13 mm diameter change. Increment bands are read each year after leaf abscission and after AG growth has ceased. Growth of all trees extrapolated from regressions developed from banded trees. Litter traps are .264 m^2 with one trap in each of 60 - 0.08 ha plots and 20 traps in a 1.13 ha plot with flux tower a plot center. -US-UMB,18541,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,8119.5 -US-UMB,18541,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_SPATIAL_VARIABILITY,2526.8 -US-UMB,18541,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_SPATIAL_REP_NUMBER,78 -US-UMB,18541,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Wood -US-UMB,18541,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-UMB,18541,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-UMB,18541,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,Tree AG wood total biomass =a*D^b where D=DBH (diam. At 1.37m) and a and b are species specific coefficients. DBH determined from increment bands installed on 15% of trees with DBH>= 10 cm. Resulting biomass multiplied by wood carbon fraction. AG_BIOMASS_OTHER_ORGAN is tree foliage captured by litter traps 1 m above forest floor -US-UMB,18541,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,20091020 -US-UMB,18541,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE_UNC,20 -US-UMB,18541,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,Increment bands are capable of detecting 0.13 mm diameter change. Increment bands are read each year after leaf abscission and after AG growth has ceased. Growth of all trees extrapolated from regressions developed from banded trees. Litter traps are .264 m^2 with one trap in each of 60 - 0.08 ha plots and 20 traps in a 1.13 ha plot with flux tower a plot center. -US-UMB,18476,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,8164.5 -US-UMB,18476,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_SPATIAL_VARIABILITY,2535.8 -US-UMB,18476,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_SPATIAL_REP_NUMBER,78 -US-UMB,18476,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Wood -US-UMB,18476,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-UMB,18476,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-UMB,18476,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,Tree AG wood total biomass =a*D^b where D=DBH (diam. At 1.37m) and a and b are species specific coefficients. DBH determined from increment bands installed on 15% of trees with DBH>= 10 cm. Resulting biomass multiplied by wood carbon fraction. AG_BIOMASS_OTHER_ORGAN is tree foliage captured by litter traps 1 m above forest floor -US-UMB,18476,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,20131020 -US-UMB,18476,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE_UNC,20 -US-UMB,18476,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,Increment bands are capable of detecting 0.13 mm diameter change. Increment bands are read each year after leaf abscission and after AG growth has ceased. Growth of all trees extrapolated from regressions developed from banded trees. Litter traps are .264 m^2 with one trap in each of 60 - 0.08 ha plots and 20 traps in a 1.13 ha plot with flux tower a plot center. -US-UMB,18392,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS,12.6 -US-UMB,18392,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_SPATIAL_VARIABILITY,18 -US-UMB,18392,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_SPATIAL_REP_NUMBER,61 -US-UMB,18392,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_UNIT,gC m-2 -US-UMB,18392,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_APPROACH,Litter debris collected from litter traps of .179 m^2 in area. One trap in each of 60 - 0.08 ha plots and 20 traps in a 1.13 ha plot with flux tower at plot center -US-UMB,18392,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_DATE,19980630 -US-UMB,18392,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_DATE_UNC,182 -US-UMB,18392,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_COMMENT,"Litter does NOT include identifiable leaves, but includes leaf fragments, seeds, flowers, lichens and fine woody debris collected from litter traps." -US-UMB,18523,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS,12.9 -US-UMB,18523,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_SPATIAL_VARIABILITY,9.9 -US-UMB,18523,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_SPATIAL_REP_NUMBER,50 -US-UMB,18523,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_UNIT,gC m-2 -US-UMB,18523,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_APPROACH,Litter debris collected from litter traps of .264 m^2 in area. One trap in each of 49 - 0.08 ha plots and 20 traps in a 1.13 ha plot with flux tower at plot center -US-UMB,18523,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_DATE,20040630 -US-UMB,18523,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_DATE_UNC,182 -US-UMB,18523,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_COMMENT,"Litter does NOT include identifiable leaves, but includes leaf fragments, seeds, flowers, lichens and fine woody debris collected from litter traps." -US-UMB,18515,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS,15.8 -US-UMB,18515,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_SPATIAL_VARIABILITY,13.5 -US-UMB,18515,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_SPATIAL_REP_NUMBER,31 -US-UMB,18515,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_UNIT,gC m-2 -US-UMB,18515,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_APPROACH,Litter debris collected from litter traps of .264 m^2 in area. One trap in each of 30 - 0.08 ha plots and 20 traps in a 1.13 ha plot with flux tower at plot center -US-UMB,18515,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_DATE,20030630 -US-UMB,18515,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_DATE_UNC,182 -US-UMB,18515,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_COMMENT,"Litter does NOT include identifiable leaves, but includes leaf fragments, seeds, flowers, lichens and fine woody debris collected from litter traps." -US-UMB,18453,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS,17.3 -US-UMB,18453,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_SPATIAL_VARIABILITY,19.7 -US-UMB,18453,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_SPATIAL_REP_NUMBER,50 -US-UMB,18453,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_UNIT,gC m-2 -US-UMB,18453,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_APPROACH,Litter debris collected from litter traps of .264 m^2 in area. One trap in each of 49 - 0.08 ha plots and 20 traps in a 1.13 ha plot with flux tower at plot center -US-UMB,18453,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_DATE,20070630 -US-UMB,18453,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_DATE_UNC,182 -US-UMB,18453,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_COMMENT,"Litter does NOT include identifiable leaves, but includes leaf fragments, seeds, flowers, lichens and fine woody debris collected from litter traps." -US-UMB,18434,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS,18.6 -US-UMB,18434,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_SPATIAL_VARIABILITY,20.8 -US-UMB,18434,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_SPATIAL_REP_NUMBER,31 -US-UMB,18434,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_UNIT,gC m-2 -US-UMB,18434,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_APPROACH,Litter debris collected from litter traps of .264 m^2 in area. One trap in each of 30 - 0.08 ha plots and 20 traps in a 1.13 ha plot with flux tower a plot center -US-UMB,18434,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_DATE,20020630 -US-UMB,18434,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_DATE_UNC,182 -US-UMB,18434,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_COMMENT,"Litter does NOT include identifiable leaves, but includes leaf fragments, seeds, flowers, lichens and fine woody debris collected from litter traps. New type of litter traps installed across all plots in 2002." -US-UMB,18534,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS,19.7 -US-UMB,18534,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_SPATIAL_VARIABILITY,14.9 -US-UMB,18534,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_SPATIAL_REP_NUMBER,15 -US-UMB,18534,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_UNIT,gC m-2 -US-UMB,18534,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_APPROACH,Litter debris collected from litter traps of .264 m^2 in area. Three traps in each of 14 - 0.08 ha plots and 20 traps in a 1.13 ha plot with flux tower at plot center -US-UMB,18534,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_DATE,20080630 -US-UMB,18534,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_DATE_UNC,182 -US-UMB,18534,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_COMMENT,"Litter does NOT include identifiable leaves, but includes leaf fragments, seeds, flowers, lichens and fine woody debris collected from litter traps." -US-UMB,18463,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS,24 -US-UMB,18463,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_SPATIAL_VARIABILITY,18.7 -US-UMB,18463,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_SPATIAL_REP_NUMBER,16 -US-UMB,18463,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_UNIT,gC m-2 -US-UMB,18463,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_APPROACH,Litter debris collected from litter traps of .264 m^2 in area. Three traps in each of 15 - 0.08 ha plots and 20 traps in a 1.13 ha plot with flux tower at plot center -US-UMB,18463,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_DATE,20110630 -US-UMB,18463,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_DATE_UNC,182 -US-UMB,18463,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_COMMENT,"Litter does NOT include identifiable leaves, but includes leaf fragments, seeds, flowers, lichens and fine woody debris collected from litter traps." -US-UMB,18470,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS,25 -US-UMB,18470,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_SPATIAL_VARIABILITY,14.3 -US-UMB,18470,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_SPATIAL_REP_NUMBER,16 -US-UMB,18470,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_UNIT,gC m-2 -US-UMB,18470,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_APPROACH,Litter debris collected from litter traps of .264 m^2 in area. Three traps in each of 15 - 0.08 ha plots and 20 traps in a 1.13 ha plot with flux tower at plot center -US-UMB,18470,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_DATE,20120630 -US-UMB,18470,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_DATE_UNC,182 -US-UMB,18470,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_COMMENT,"Litter does NOT include identifiable leaves, but includes leaf fragments, seeds, flowers, lichens and fine woody debris collected from litter traps." -US-UMB,18445,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS,35.8 -US-UMB,18445,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_SPATIAL_VARIABILITY,25 -US-UMB,18445,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_SPATIAL_REP_NUMBER,50 -US-UMB,18445,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_UNIT,gC m-2 -US-UMB,18445,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_APPROACH,Litter debris collected from litter traps of .264 m^2 in area. One trap in each of 49 - 0.08 ha plots and 20 traps in a 1.13 ha plot with flux tower at plot center -US-UMB,18445,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_DATE,20060630 -US-UMB,18445,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_DATE_UNC,182 -US-UMB,18445,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_COMMENT,"Litter does NOT include identifiable leaves, but includes leaf fragments, seeds, flowers, lichens and fine woody debris collected from litter traps." -US-UMB,18424,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS,36.9 -US-UMB,18424,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_SPATIAL_VARIABILITY,17.5 -US-UMB,18424,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_SPATIAL_REP_NUMBER,7 -US-UMB,18424,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_UNIT,gC m-2 -US-UMB,18424,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_APPROACH,Litter debris collected from litter traps of .179 m^2 in area. One trap in each of 60 - 0.08 ha plots and 20 traps in a 1.13 ha plot with flux tower at plot center -US-UMB,18424,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_DATE,20010630 -US-UMB,18424,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_DATE_UNC,182 -US-UMB,18424,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_COMMENT,"Litter does NOT include identifiable leaves, but includes leaf fragments, seeds, flowers, lichens and fine woody debris collected from litter traps. Five - 10 sample plots pooled for debris resulting in 7 replicates." -US-UMB,18550,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS,38.4 -US-UMB,18550,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_SPATIAL_VARIABILITY,27.4 -US-UMB,18550,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_SPATIAL_REP_NUMBER,13 -US-UMB,18550,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_UNIT,gC m-2 -US-UMB,18550,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_APPROACH,Litter debris collected from litter traps of .264 m^2 in area. Three traps in each of 12 - 0.08 ha plots and 20 traps in a 1.13 ha plot with flux tower at plot center -US-UMB,18550,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_DATE,20100630 -US-UMB,18550,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_DATE_UNC,182 -US-UMB,18550,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_COMMENT,"Litter does NOT include identifiable leaves, but includes leaf fragments, seeds, flowers, lichens and fine woody debris collected from litter traps." -US-UMB,18414,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS,39.9 -US-UMB,18414,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_SPATIAL_VARIABILITY,29.5 -US-UMB,18414,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_SPATIAL_REP_NUMBER,60 -US-UMB,18414,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_UNIT,gC m-2 -US-UMB,18414,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_APPROACH,Litter debris collected from litter traps of .179 m^2 in area. One trap in each of 59 - 0.08 ha plots and 20 traps in a 1.13 ha plot with flux tower at plot center -US-UMB,18414,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_DATE,20000630 -US-UMB,18414,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_DATE_UNC,182 -US-UMB,18414,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_COMMENT,"Litter does NOT include identifiable leaves, but includes leaf fragments, seeds, flowers, lichens and fine woody debris collected from litter traps." -US-UMB,18477,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS,47.5 -US-UMB,18477,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_SPATIAL_VARIABILITY,40.85 -US-UMB,18477,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_SPATIAL_REP_NUMBER,16 -US-UMB,18477,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_UNIT,gC m-2 -US-UMB,18477,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_APPROACH,Litter debris collected from litter traps of .264 m^2 in area. Three traps in each of 15 - 0.08 ha plots and 20 traps in a 1.13 ha plot with flux tower at plot center -US-UMB,18477,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_DATE,20130630 -US-UMB,18477,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_DATE_UNC,182 -US-UMB,18477,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_COMMENT,"Litter does NOT include identifiable leaves, but includes leaf fragments, seeds, flowers, lichens and fine woody debris collected from litter traps." -US-UMB,18542,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS,52.3 -US-UMB,18542,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_SPATIAL_VARIABILITY,24.5 -US-UMB,18542,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_SPATIAL_REP_NUMBER,15 -US-UMB,18542,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_UNIT,gC m-2 -US-UMB,18542,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_APPROACH,Litter debris collected from litter traps of .264 m^2 in area. Three traps in each of 14 - 0.08 ha plots and 20 traps in a 1.13 ha plot with flux tower at plot center -US-UMB,18542,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_DATE,20090630 -US-UMB,18542,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_DATE_UNC,182 -US-UMB,18542,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_COMMENT,"Litter does NOT include identifiable leaves, but includes leaf fragments, seeds, flowers, lichens and fine woody debris collected from litter traps." -US-UMB,18436,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS,57.6 -US-UMB,18436,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_SPATIAL_VARIABILITY,78 -US-UMB,18436,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_SPATIAL_REP_NUMBER,50 -US-UMB,18436,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_UNIT,gC m-2 -US-UMB,18436,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_APPROACH,Litter debris collected from litter traps of .264 m^2 in area. One trap in each of 49 - 0.08 ha plots and 20 traps in a 1.13 ha plot with flux tower at plot center -US-UMB,18436,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_DATE,20050630 -US-UMB,18436,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_DATE_UNC,182 -US-UMB,18436,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_COMMENT,"Litter does NOT include identifiable leaves, but includes leaf fragments, seeds, flowers, lichens and fine woody debris collected from litter traps. Includes 16.2 ± 50.3 of Quercus rubra acorns." -US-UMB,18403,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS,66.1 -US-UMB,18403,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_SPATIAL_VARIABILITY,163.9 -US-UMB,18403,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_SPATIAL_REP_NUMBER,61 -US-UMB,18403,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_UNIT,gC m-2 -US-UMB,18403,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_APPROACH,Litter debris collected from litter traps of .179 m^2 in area. One trap in each of 60 - 0.08 ha plots and 20 traps in a 1.13 ha plot with flux tower at plot center -US-UMB,18403,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_DATE,19990630 -US-UMB,18403,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_DATE_UNC,182 -US-UMB,18403,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_COMMENT,"Litter does NOT include identifiable leaves, but includes leaf fragments, seeds, flowers, lichens and fine woody debris collected from litter traps." -US-UMB,24235,GRP_AG_LIT_CHEM,AG_LIT_C,4.711 -US-UMB,24344,GRP_AG_LIT_CHEM,AG_LIT_C,4.746 -US-UMB,24877,GRP_AG_LIT_CHEM,AG_LIT_C,4.77 -US-UMB,24617,GRP_AG_LIT_CHEM,AG_LIT_C,4.801 -US-UMB,24876,GRP_AG_LIT_CHEM,AG_LIT_C,4.821 -US-UMB,24993,GRP_AG_LIT_CHEM,AG_LIT_C,4.903 -US-UMB,24616,GRP_AG_LIT_CHEM,AG_LIT_C,5.01 -US-UMB,24875,GRP_AG_LIT_CHEM,AG_LIT_C,5.036 -US-UMB,24877,GRP_AG_LIT_CHEM,AG_LIT_N,0.036 -US-UMB,24235,GRP_AG_LIT_CHEM,AG_LIT_N,0.047 -US-UMB,24344,GRP_AG_LIT_CHEM,AG_LIT_N,0.049 -US-UMB,24616,GRP_AG_LIT_CHEM,AG_LIT_N,0.054 -US-UMB,24993,GRP_AG_LIT_CHEM,AG_LIT_N,0.054 -US-UMB,24875,GRP_AG_LIT_CHEM,AG_LIT_N,0.056 -US-UMB,24876,GRP_AG_LIT_CHEM,AG_LIT_N,0.058 -US-UMB,24617,GRP_AG_LIT_CHEM,AG_LIT_N,0.062 -US-UMB,24875,GRP_AG_LIT_CHEM,AG_LIT_DATE,19981106 -US-UMB,24993,GRP_AG_LIT_CHEM,AG_LIT_DATE,19991106 -US-UMB,24616,GRP_AG_LIT_CHEM,AG_LIT_DATE,20001105 -US-UMB,24235,GRP_AG_LIT_CHEM,AG_LIT_DATE,20011106 -US-UMB,24617,GRP_AG_LIT_CHEM,AG_LIT_DATE,20021106 -US-UMB,24876,GRP_AG_LIT_CHEM,AG_LIT_DATE,20031106 -US-UMB,24344,GRP_AG_LIT_CHEM,AG_LIT_DATE,20041105 -US-UMB,24877,GRP_AG_LIT_CHEM,AG_LIT_DATE,20061106 -US-UMB,18524,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT,128.2 -US-UMB,18535,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT,133.9 -US-UMB,18425,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT,135.8 -US-UMB,18454,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT,138.7 -US-UMB,18464,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT,140.9 -US-UMB,18471,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT,144 -US-UMB,18393,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT,146.5 -US-UMB,18516,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT,149.7 -US-UMB,18446,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT,149.9 -US-UMB,18551,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT,152 -US-UMB,18435,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT,156.1 -US-UMB,18478,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT,162.2 -US-UMB,18543,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT,178.9 -US-UMB,18437,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT,183.7 -US-UMB,18415,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT,186.4 -US-UMB,18404,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT,194 -US-UMB,18404,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT_SPATIAL_VARIABILITY,172.7 -US-UMB,18543,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT_SPATIAL_VARIABILITY,25.2 -US-UMB,18524,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT_SPATIAL_VARIABILITY,28.3 -US-UMB,18535,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT_SPATIAL_VARIABILITY,30.1 -US-UMB,18516,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT_SPATIAL_VARIABILITY,31.6 -US-UMB,18471,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT_SPATIAL_VARIABILITY,32 -US-UMB,18454,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT_SPATIAL_VARIABILITY,33 -US-UMB,18425,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT_SPATIAL_VARIABILITY,36.1 -US-UMB,18464,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT_SPATIAL_VARIABILITY,36.7 -US-UMB,18435,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT_SPATIAL_VARIABILITY,37.1 -US-UMB,18393,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT_SPATIAL_VARIABILITY,37.4 -US-UMB,18446,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT_SPATIAL_VARIABILITY,41 -US-UMB,18415,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT_SPATIAL_VARIABILITY,42.8 -US-UMB,18551,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT_SPATIAL_VARIABILITY,47.3 -US-UMB,18478,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT_SPATIAL_VARIABILITY,60.3 -US-UMB,18437,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT_SPATIAL_VARIABILITY,76.6 -US-UMB,18551,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT_SPATIAL_REP_NUMBER,13 -US-UMB,18535,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT_SPATIAL_REP_NUMBER,15 -US-UMB,18543,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT_SPATIAL_REP_NUMBER,15 -US-UMB,18464,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT_SPATIAL_REP_NUMBER,16 -US-UMB,18471,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT_SPATIAL_REP_NUMBER,16 -US-UMB,18478,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT_SPATIAL_REP_NUMBER,16 -US-UMB,18435,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT_SPATIAL_REP_NUMBER,31 -US-UMB,18516,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT_SPATIAL_REP_NUMBER,31 -US-UMB,18446,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT_SPATIAL_REP_NUMBER,50 -US-UMB,18454,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT_SPATIAL_REP_NUMBER,50 -US-UMB,18524,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT_SPATIAL_REP_NUMBER,50 -US-UMB,18437,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT_SPATIAL_REP_NUMBER,51 -US-UMB,18393,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT_SPATIAL_REP_NUMBER,61 -US-UMB,18404,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT_SPATIAL_REP_NUMBER,61 -US-UMB,18415,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT_SPATIAL_REP_NUMBER,61 -US-UMB,18425,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT_SPATIAL_REP_NUMBER,61 -US-UMB,18393,GRP_AG_LIT_PROD,AG_LIT_PROD_UNIT,gC m-2 -US-UMB,18404,GRP_AG_LIT_PROD,AG_LIT_PROD_UNIT,gC m-2 -US-UMB,18415,GRP_AG_LIT_PROD,AG_LIT_PROD_UNIT,gC m-2 -US-UMB,18425,GRP_AG_LIT_PROD,AG_LIT_PROD_UNIT,gC m-2 -US-UMB,18435,GRP_AG_LIT_PROD,AG_LIT_PROD_UNIT,gC m-2 -US-UMB,18437,GRP_AG_LIT_PROD,AG_LIT_PROD_UNIT,gC m-2 -US-UMB,18446,GRP_AG_LIT_PROD,AG_LIT_PROD_UNIT,gC m-2 -US-UMB,18454,GRP_AG_LIT_PROD,AG_LIT_PROD_UNIT,gC m-2 -US-UMB,18464,GRP_AG_LIT_PROD,AG_LIT_PROD_UNIT,gC m-2 -US-UMB,18471,GRP_AG_LIT_PROD,AG_LIT_PROD_UNIT,gC m-2 -US-UMB,18478,GRP_AG_LIT_PROD,AG_LIT_PROD_UNIT,gC m-2 -US-UMB,18516,GRP_AG_LIT_PROD,AG_LIT_PROD_UNIT,gC m-2 -US-UMB,18524,GRP_AG_LIT_PROD,AG_LIT_PROD_UNIT,gC m-2 -US-UMB,18535,GRP_AG_LIT_PROD,AG_LIT_PROD_UNIT,gC m-2 -US-UMB,18543,GRP_AG_LIT_PROD,AG_LIT_PROD_UNIT,gC m-2 -US-UMB,18551,GRP_AG_LIT_PROD,AG_LIT_PROD_UNIT,gC m-2 -US-UMB,18415,GRP_AG_LIT_PROD,AG_LIT_PROD_APPROACH,"Litter collected from litter traps of .179 m^2 in area. One trap in each of 59 - 0.08 ha plots and 20 traps in a 1.13 ha plot with flux tower at plot center. Litter includes foliage, seeds, flowers, fine woody debris." -US-UMB,18393,GRP_AG_LIT_PROD,AG_LIT_PROD_APPROACH,"Litter collected from litter traps of .179 m^2 in area. One trap in each of 60 - 0.08 ha plots and 20 traps in a 1.13 ha plot with flux tower at plot center. Litter includes foliage, seeds, flowers, fine woody debris." -US-UMB,18404,GRP_AG_LIT_PROD,AG_LIT_PROD_APPROACH,"Litter collected from litter traps of .179 m^2 in area. One trap in each of 60 - 0.08 ha plots and 20 traps in a 1.13 ha plot with flux tower at plot center. Litter includes foliage, seeds, flowers, fine woody debris." -US-UMB,18425,GRP_AG_LIT_PROD,AG_LIT_PROD_APPROACH,"Litter collected from litter traps of .179 m^2 in area. One trap in each of 60 - 0.08 ha plots and 20 traps in a 1.13 ha plot with flux tower at plot center. Litter includes foliage, seeds, flowers, fine woody debris." -US-UMB,18435,GRP_AG_LIT_PROD,AG_LIT_PROD_APPROACH,"Litter collected from litter traps of .264 m^2 in area. One trap in each of 30 - 0.08 ha plots and 20 traps in a 1.13 ha plot with flux tower a plot center. Litter includes foliage, seeds, flowers, fine woody debris." -US-UMB,18516,GRP_AG_LIT_PROD,AG_LIT_PROD_APPROACH,"Litter collected from litter traps of .264 m^2 in area. One trap in each of 30 - 0.08 ha plots and 20 traps in a 1.13 ha plot with flux tower at plot center. Litter includes foliage, seeds, flowers, fine woody debris." -US-UMB,18446,GRP_AG_LIT_PROD,AG_LIT_PROD_APPROACH,"Litter collected from litter traps of .264 m^2 in area. One trap in each of 49 - 0.08 ha plots and 20 traps in a 1.13 ha plot with flux tower at plot center. Litter includes foliage, seeds, flowers, fine woody debris." -US-UMB,18454,GRP_AG_LIT_PROD,AG_LIT_PROD_APPROACH,"Litter collected from litter traps of .264 m^2 in area. One trap in each of 49 - 0.08 ha plots and 20 traps in a 1.13 ha plot with flux tower at plot center. Litter includes foliage, seeds, flowers, fine woody debris." -US-UMB,18524,GRP_AG_LIT_PROD,AG_LIT_PROD_APPROACH,"Litter collected from litter traps of .264 m^2 in area. One trap in each of 49 - 0.08 ha plots and 20 traps in a 1.13 ha plot with flux tower at plot center. Litter includes foliage, seeds, flowers, fine woody debris." -US-UMB,18437,GRP_AG_LIT_PROD,AG_LIT_PROD_APPROACH,"Litter collected from litter traps of .264 m^2 in area. One trap in each of 50 - 0.08 ha plots and 20 traps in a 1.13 ha plot with flux tower at plot center. Litter includes foliage, seeds, flowers, fine woody debris. Major red oak mast year." -US-UMB,18551,GRP_AG_LIT_PROD,AG_LIT_PROD_APPROACH,"Litter collected from litter traps of .264 m^2 in area. Three traps in each of 12 - 0.08 ha plots and 20 traps in a 1.13 ha plot with flux tower at plot center. Litter includes foliage, seeds, flowers, fine woody debris." -US-UMB,18535,GRP_AG_LIT_PROD,AG_LIT_PROD_APPROACH,"Litter collected from litter traps of .264 m^2 in area. Three traps in each of 14 - 0.08 ha plots and 20 traps in a 1.13 ha plot with flux tower at plot center. Litter includes foliage, seeds, flowers, fine woody debris." -US-UMB,18543,GRP_AG_LIT_PROD,AG_LIT_PROD_APPROACH,"Litter collected from litter traps of .264 m^2 in area. Three traps in each of 14 - 0.08 ha plots and 20 traps in a 1.13 ha plot with flux tower at plot center. Litter includes foliage, seeds, flowers, fine woody debris." -US-UMB,18464,GRP_AG_LIT_PROD,AG_LIT_PROD_APPROACH,"Litter collected from litter traps of .264 m^2 in area. Three traps in each of 15 - 0.08 ha plots and 20 traps in a 1.13 ha plot with flux tower at plot center. Litter includes foliage, seeds, flowers, fine woody debris." -US-UMB,18471,GRP_AG_LIT_PROD,AG_LIT_PROD_APPROACH,"Litter collected from litter traps of .264 m^2 in area. Three traps in each of 15 - 0.08 ha plots and 20 traps in a 1.13 ha plot with flux tower at plot center. Litter includes foliage, seeds, flowers, fine woody debris." -US-UMB,18478,GRP_AG_LIT_PROD,AG_LIT_PROD_APPROACH,"Litter collected from litter traps of .264 m^2 in area. Three traps in each of 15 - 0.08 ha plots and 20 traps in a 1.13 ha plot with flux tower at plot center. Litter includes foliage, seeds, flowers, fine woody debris." -US-UMB,18393,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_START,19971101 -US-UMB,18404,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_START,19981101 -US-UMB,18415,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_START,19991101 -US-UMB,18425,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_START,20001101 -US-UMB,18435,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_START,20011101 -US-UMB,18516,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_START,20021101 -US-UMB,18524,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_START,20031101 -US-UMB,18437,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_START,20041101 -US-UMB,18446,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_START,20051101 -US-UMB,18454,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_START,20061101 -US-UMB,18535,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_START,20071101 -US-UMB,18543,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_START,20081101 -US-UMB,18551,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_START,20091101 -US-UMB,18464,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_START,20101101 -US-UMB,18471,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_START,20111101 -US-UMB,18478,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_START,20121101 -US-UMB,18393,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_END,19981101 -US-UMB,18404,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_END,19991101 -US-UMB,18415,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_END,20001101 -US-UMB,18425,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_END,20011101 -US-UMB,18435,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_END,20021101 -US-UMB,18516,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_END,20031101 -US-UMB,18524,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_END,20041101 -US-UMB,18437,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_END,20051101 -US-UMB,18446,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_END,20061101 -US-UMB,18454,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_END,20071101 -US-UMB,18535,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_END,20081101 -US-UMB,18543,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_END,20091101 -US-UMB,18551,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_END,20101101 -US-UMB,18464,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_END,20111101 -US-UMB,18471,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_END,20121101 -US-UMB,18478,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_END,20131101 -US-UMB,18393,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_UNC,30 -US-UMB,18404,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_UNC,30 -US-UMB,18415,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_UNC,30 -US-UMB,18425,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_UNC,30 -US-UMB,18435,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_UNC,30 -US-UMB,18437,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_UNC,30 -US-UMB,18446,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_UNC,30 -US-UMB,18454,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_UNC,30 -US-UMB,18464,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_UNC,30 -US-UMB,18471,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_UNC,30 -US-UMB,18478,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_UNC,30 -US-UMB,18516,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_UNC,30 -US-UMB,18524,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_UNC,30 -US-UMB,18535,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_UNC,30 -US-UMB,18543,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_UNC,30 -US-UMB,18551,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_UNC,30 -US-UMB,18393,GRP_AG_LIT_PROD,AG_LIT_PROD_COMMENT,Litter includes all litter from 1 m above forest floor to the top of the canopy. Litter does not include herbaceous layer below 1 m. -US-UMB,18404,GRP_AG_LIT_PROD,AG_LIT_PROD_COMMENT,Litter includes all litter from 1 m above forest floor to the top of the canopy. Litter does not include herbaceous layer below 1 m. -US-UMB,18415,GRP_AG_LIT_PROD,AG_LIT_PROD_COMMENT,Litter includes all litter from 1 m above forest floor to the top of the canopy. Litter does not include herbaceous layer below 1 m. -US-UMB,18425,GRP_AG_LIT_PROD,AG_LIT_PROD_COMMENT,Litter includes all litter from 1 m above forest floor to the top of the canopy. Litter does not include herbaceous layer below 1 m. -US-UMB,18435,GRP_AG_LIT_PROD,AG_LIT_PROD_COMMENT,Litter includes all litter from 1 m above forest floor to the top of the canopy. Litter does not include herbaceous layer below 1 m. -US-UMB,18437,GRP_AG_LIT_PROD,AG_LIT_PROD_COMMENT,Litter includes all litter from 1 m above forest floor to the top of the canopy. Litter does not include herbaceous layer below 1 m. -US-UMB,18446,GRP_AG_LIT_PROD,AG_LIT_PROD_COMMENT,Litter includes all litter from 1 m above forest floor to the top of the canopy. Litter does not include herbaceous layer below 1 m. -US-UMB,18454,GRP_AG_LIT_PROD,AG_LIT_PROD_COMMENT,Litter includes all litter from 1 m above forest floor to the top of the canopy. Litter does not include herbaceous layer below 1 m. -US-UMB,18464,GRP_AG_LIT_PROD,AG_LIT_PROD_COMMENT,Litter includes all litter from 1 m above forest floor to the top of the canopy. Litter does not include herbaceous layer below 1 m. -US-UMB,18471,GRP_AG_LIT_PROD,AG_LIT_PROD_COMMENT,Litter includes all litter from 1 m above forest floor to the top of the canopy. Litter does not include herbaceous layer below 1 m. -US-UMB,18478,GRP_AG_LIT_PROD,AG_LIT_PROD_COMMENT,Litter includes all litter from 1 m above forest floor to the top of the canopy. Litter does not include herbaceous layer below 1 m. -US-UMB,18516,GRP_AG_LIT_PROD,AG_LIT_PROD_COMMENT,Litter includes all litter from 1 m above forest floor to the top of the canopy. Litter does not include herbaceous layer below 1 m. -US-UMB,18524,GRP_AG_LIT_PROD,AG_LIT_PROD_COMMENT,Litter includes all litter from 1 m above forest floor to the top of the canopy. Litter does not include herbaceous layer below 1 m. -US-UMB,18535,GRP_AG_LIT_PROD,AG_LIT_PROD_COMMENT,Litter includes all litter from 1 m above forest floor to the top of the canopy. Litter does not include herbaceous layer below 1 m. -US-UMB,18543,GRP_AG_LIT_PROD,AG_LIT_PROD_COMMENT,Litter includes all litter from 1 m above forest floor to the top of the canopy. Litter does not include herbaceous layer below 1 m. -US-UMB,18551,GRP_AG_LIT_PROD,AG_LIT_PROD_COMMENT,Litter includes all litter from 1 m above forest floor to the top of the canopy. Litter does not include herbaceous layer below 1 m. -US-UMB,18426,GRP_AG_PROD_TREE,AG_PROD_TREE,1242.3 -US-UMB,18426,GRP_AG_PROD_TREE,AG_PROD_TREE_SPATIAL_VARIABILITY,557.45 -US-UMB,18426,GRP_AG_PROD_TREE,AG_PROD_TREE_SPATIAL_REP_NUMBER,20 -US-UMB,18426,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Wood -US-UMB,18426,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-UMB,18426,GRP_AG_PROD_TREE,AG_PROD_DATE_START,20030715 -US-UMB,18426,GRP_AG_PROD_TREE,AG_PROD_DATE_END,20100715 -US-UMB,18426,GRP_AG_PROD_TREE,AG_PROD_DATE_UNC,28 -US-UMB,18426,GRP_AG_PROD_TREE,AG_PROD_COMMENT,Species specific allometric equations in the form a*D^b where D is diameter of tree stem at 1.37 m ht and a and b are species specific constants were used to determine AG woody biomass. Stem diameters were determined from manual measurments of trees in 20 - 0.08 ha plots. -US-UMB,18416,GRP_AG_PROD_TREE,AG_PROD_TREE,1453.7 -US-UMB,18416,GRP_AG_PROD_TREE,AG_PROD_TREE_SPATIAL_VARIABILITY,433.16 -US-UMB,18416,GRP_AG_PROD_TREE,AG_PROD_TREE_SPATIAL_REP_NUMBER,61 -US-UMB,18416,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Wood -US-UMB,18416,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-UMB,18416,GRP_AG_PROD_TREE,AG_PROD_DATE_START,20010715 -US-UMB,18416,GRP_AG_PROD_TREE,AG_PROD_DATE_END,20100715 -US-UMB,18416,GRP_AG_PROD_TREE,AG_PROD_DATE_UNC,28 -US-UMB,18416,GRP_AG_PROD_TREE,AG_PROD_COMMENT,Species specific allometric equations in the form a*D^b where D is diameter of tree stem at 1.37 m ht and a and b are species specific constants were used to determine AG woody biomass. Stem diameters were determined from manual measurments of trees in 60 - 0.08 ha plots and a single 1.13 ha plot. -US-UMB,18438,GRP_AG_PROD_TREE,AG_PROD_TREE,146.3 -US-UMB,18438,GRP_AG_PROD_TREE,AG_PROD_TREE_SPATIAL_VARIABILITY,42.3 -US-UMB,18438,GRP_AG_PROD_TREE,AG_PROD_TREE_SPATIAL_REP_NUMBER,61 -US-UMB,18438,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Wood -US-UMB,18438,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-UMB,18438,GRP_AG_PROD_TREE,AG_PROD_DATE_START,20011102 -US-UMB,18438,GRP_AG_PROD_TREE,AG_PROD_DATE_END,20021123 -US-UMB,18438,GRP_AG_PROD_TREE,AG_PROD_DATE_UNC,4 -US-UMB,18438,GRP_AG_PROD_TREE,AG_PROD_COMMENT,Species specific allometric equations in the form a*D^b where D is diameter of tree stem at 1.37 m ht and a and b are species specific constants were used to determine AG woody biomass. Stem diameters for all trees in all plots were estimated from band dendrometer readings taken from 10 -20% of total number of trees in year 2002. All trees manualy measured for Diameter in 2001. See STEM_INCR data in this file for more information. -US-UMB,18472,GRP_AG_PROD_TREE,AG_PROD_TREE,147.8 -US-UMB,18472,GRP_AG_PROD_TREE,AG_PROD_TREE_SPATIAL_VARIABILITY,41.6 -US-UMB,18472,GRP_AG_PROD_TREE,AG_PROD_TREE_SPATIAL_REP_NUMBER,78 -US-UMB,18472,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Wood -US-UMB,18472,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-UMB,18472,GRP_AG_PROD_TREE,AG_PROD_DATE_START,20081104 -US-UMB,18472,GRP_AG_PROD_TREE,AG_PROD_DATE_END,20091104 -US-UMB,18472,GRP_AG_PROD_TREE,AG_PROD_DATE_UNC,4 -US-UMB,18472,GRP_AG_PROD_TREE,AG_PROD_COMMENT,Species specific allometric equations in the form a*D^b where D is diameter of tree stem at 1.37 m ht and a and b are species specific constants were used to determine AG woody biomass. Stem diameters for all trees in all plots were estimated from band dendrometer readings taken from 10 -20% of total number of trees. See STEM_INCR data in this file for more information. -US-UMB,18536,GRP_AG_PROD_TREE,AG_PROD_TREE,152.4 -US-UMB,18536,GRP_AG_PROD_TREE,AG_PROD_TREE_SPATIAL_VARIABILITY,42.2 -US-UMB,18536,GRP_AG_PROD_TREE,AG_PROD_TREE_SPATIAL_REP_NUMBER,81 -US-UMB,18536,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Wood -US-UMB,18536,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-UMB,18536,GRP_AG_PROD_TREE,AG_PROD_DATE_START,20041106 -US-UMB,18536,GRP_AG_PROD_TREE,AG_PROD_DATE_END,20051101 -US-UMB,18536,GRP_AG_PROD_TREE,AG_PROD_DATE_UNC,4 -US-UMB,18536,GRP_AG_PROD_TREE,AG_PROD_COMMENT,Species specific allometric equations in the form a*D^b where D is diameter of tree stem at 1.37 m ht and a and b are species specific constants were used to determine AG woody biomass. Stem diameters for all trees in all plots were estimated from band dendrometer readings taken from 10 -20% of total number of trees. See STEM_INCR data in this file for more information. -US-UMB,18465,GRP_AG_PROD_TREE,AG_PROD_TREE,157.7 -US-UMB,18465,GRP_AG_PROD_TREE,AG_PROD_TREE_SPATIAL_VARIABILITY,47.4 -US-UMB,18465,GRP_AG_PROD_TREE,AG_PROD_TREE_SPATIAL_REP_NUMBER,78 -US-UMB,18465,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Wood -US-UMB,18465,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-UMB,18465,GRP_AG_PROD_TREE,AG_PROD_DATE_START,20071017 -US-UMB,18465,GRP_AG_PROD_TREE,AG_PROD_DATE_END,20081104 -US-UMB,18465,GRP_AG_PROD_TREE,AG_PROD_DATE_UNC,4 -US-UMB,18465,GRP_AG_PROD_TREE,AG_PROD_COMMENT,Species specific allometric equations in the form a*D^b where D is diameter of tree stem at 1.37 m ht and a and b are species specific constants were used to determine AG woody biomass. Stem diameters for all trees in all plots were estimated from band dendrometer readings taken from 10 -20% of total number of trees. See STEM_INCR data in this file for more information. -US-UMB,18447,GRP_AG_PROD_TREE,AG_PROD_TREE,162.1 -US-UMB,18447,GRP_AG_PROD_TREE,AG_PROD_TREE_SPATIAL_VARIABILITY,47.2 -US-UMB,18447,GRP_AG_PROD_TREE,AG_PROD_TREE_SPATIAL_REP_NUMBER,61 -US-UMB,18447,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Wood -US-UMB,18447,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-UMB,18447,GRP_AG_PROD_TREE,AG_PROD_DATE_START,20021123 -US-UMB,18447,GRP_AG_PROD_TREE,AG_PROD_DATE_END,20031108 -US-UMB,18447,GRP_AG_PROD_TREE,AG_PROD_DATE_UNC,4 -US-UMB,18447,GRP_AG_PROD_TREE,AG_PROD_COMMENT,Species specific allometric equations in the form a*D^b where D is diameter of tree stem at 1.37 m ht and a and b are species specific constants were used to determine AG woody biomass. Stem diameters for all trees in all plots were estimated from band dendrometer readings taken from 10 -20% of total number of trees. See STEM_INCR data in this file for more information. -US-UMB,18481,GRP_AG_PROD_TREE,AG_PROD_TREE,162.5 -US-UMB,18481,GRP_AG_PROD_TREE,AG_PROD_TREE_SPATIAL_VARIABILITY,86.8 -US-UMB,18481,GRP_AG_PROD_TREE,AG_PROD_TREE_SPATIAL_REP_NUMBER,78 -US-UMB,18481,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Wood -US-UMB,18481,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-UMB,18481,GRP_AG_PROD_TREE,AG_PROD_DATE_START,20101112 -US-UMB,18481,GRP_AG_PROD_TREE,AG_PROD_DATE_END,20111105 -US-UMB,18481,GRP_AG_PROD_TREE,AG_PROD_DATE_UNC,4 -US-UMB,18481,GRP_AG_PROD_TREE,AG_PROD_COMMENT,Species specific allometric equations in the form a*D^b where D is diameter of tree stem at 1.37 m ht and a and b are species specific constants were used to determine AG woody biomass. Stem diameters for all trees in all plots were estimated from band dendrometer readings taken from 10 -20% of total number of trees in year 2011. All trees manualy measured for Diameter in 2010. See STEM_INCR data in this file for more information. -US-UMB,18555,GRP_AG_PROD_TREE,AG_PROD_TREE,164 -US-UMB,18555,GRP_AG_PROD_TREE,AG_PROD_TREE_SPATIAL_VARIABILITY,49.3 -US-UMB,18555,GRP_AG_PROD_TREE,AG_PROD_TREE_SPATIAL_REP_NUMBER,78 -US-UMB,18555,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Wood -US-UMB,18555,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-UMB,18555,GRP_AG_PROD_TREE,AG_PROD_DATE_START,20111105 -US-UMB,18555,GRP_AG_PROD_TREE,AG_PROD_DATE_END,20121109 -US-UMB,18555,GRP_AG_PROD_TREE,AG_PROD_DATE_UNC,4 -US-UMB,18555,GRP_AG_PROD_TREE,AG_PROD_COMMENT,Species specific allometric equations in the form a*D^b where D is diameter of tree stem at 1.37 m ht and a and b are species specific constants were used to determine AG woody biomass. Stem diameters for all trees in all plots were estimated from band dendrometer readings taken from 10 -20% of total number of trees. See STEM_INCR data in this file for more information. -US-UMB,18552,GRP_AG_PROD_TREE,AG_PROD_TREE,170.6 -US-UMB,18552,GRP_AG_PROD_TREE,AG_PROD_TREE_SPATIAL_VARIABILITY,53.1 -US-UMB,18552,GRP_AG_PROD_TREE,AG_PROD_TREE_SPATIAL_REP_NUMBER,81 -US-UMB,18552,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Wood -US-UMB,18552,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-UMB,18552,GRP_AG_PROD_TREE,AG_PROD_DATE_START,20061115 -US-UMB,18552,GRP_AG_PROD_TREE,AG_PROD_DATE_END,20071017 -US-UMB,18552,GRP_AG_PROD_TREE,AG_PROD_DATE_UNC,4 -US-UMB,18552,GRP_AG_PROD_TREE,AG_PROD_COMMENT,Species specific allometric equations in the form a*D^b where D is diameter of tree stem at 1.37 m ht and a and b are species specific constants were used to determine AG woody biomass. Stem diameters for all trees in all plots were estimated from band dendrometer readings taken from 10 -20% of total number of trees. See STEM_INCR data in this file for more information. -US-UMB,18557,GRP_AG_PROD_TREE,AG_PROD_TREE,171.4 -US-UMB,18557,GRP_AG_PROD_TREE,AG_PROD_TREE_SPATIAL_VARIABILITY,49.8 -US-UMB,18557,GRP_AG_PROD_TREE,AG_PROD_TREE_SPATIAL_REP_NUMBER,78 -US-UMB,18557,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Wood -US-UMB,18557,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-UMB,18557,GRP_AG_PROD_TREE,AG_PROD_DATE_START,20121109 -US-UMB,18557,GRP_AG_PROD_TREE,AG_PROD_DATE_END,20131020 -US-UMB,18557,GRP_AG_PROD_TREE,AG_PROD_DATE_UNC,7 -US-UMB,18557,GRP_AG_PROD_TREE,AG_PROD_COMMENT,Species specific allometric equations in the form a*D^b where D is diameter of tree stem at 1.37 m ht and a and b are species specific constants were used to determine AG woody biomass. Stem diameters for all trees in all plots were estimated from band dendrometer readings taken from 10 -20% of total number of trees. See STEM_INCR data in this file for more information. -US-UMB,18455,GRP_AG_PROD_TREE,AG_PROD_TREE,179.7 -US-UMB,18455,GRP_AG_PROD_TREE,AG_PROD_TREE_SPATIAL_VARIABILITY,51.5 -US-UMB,18455,GRP_AG_PROD_TREE,AG_PROD_TREE_SPATIAL_REP_NUMBER,81 -US-UMB,18455,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Wood -US-UMB,18455,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-UMB,18455,GRP_AG_PROD_TREE,AG_PROD_DATE_START,20031108 -US-UMB,18455,GRP_AG_PROD_TREE,AG_PROD_DATE_END,20041106 -US-UMB,18455,GRP_AG_PROD_TREE,AG_PROD_DATE_UNC,4 -US-UMB,18455,GRP_AG_PROD_TREE,AG_PROD_COMMENT,Species specific allometric equations in the form a*D^b where D is diameter of tree stem at 1.37 m ht and a and b are species specific constants were used to determine AG woody biomass. Stem diameters for all trees in all plots were estimated from band dendrometer readings taken from 10 -20% of total number of trees. See STEM_INCR data in this file for more information. -US-UMB,18544,GRP_AG_PROD_TREE,AG_PROD_TREE,179.8 -US-UMB,18544,GRP_AG_PROD_TREE,AG_PROD_TREE_SPATIAL_VARIABILITY,55.9 -US-UMB,18544,GRP_AG_PROD_TREE,AG_PROD_TREE_SPATIAL_REP_NUMBER,81 -US-UMB,18544,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Wood -US-UMB,18544,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-UMB,18544,GRP_AG_PROD_TREE,AG_PROD_DATE_START,20051101 -US-UMB,18544,GRP_AG_PROD_TREE,AG_PROD_DATE_END,20061115 -US-UMB,18544,GRP_AG_PROD_TREE,AG_PROD_DATE_UNC,4 -US-UMB,18544,GRP_AG_PROD_TREE,AG_PROD_COMMENT,Species specific allometric equations in the form a*D^b where D is diameter of tree stem at 1.37 m ht and a and b are species specific constants were used to determine AG woody biomass. Stem diameters for all trees in all plots were estimated from band dendrometer readings taken from 10 -20% of total number of trees. See STEM_INCR data in this file for more information. -US-UMB,18517,GRP_AG_PROD_TREE,AG_PROD_TREE,190.7 -US-UMB,18517,GRP_AG_PROD_TREE,AG_PROD_TREE_SPATIAL_VARIABILITY,51.1 -US-UMB,18517,GRP_AG_PROD_TREE,AG_PROD_TREE_SPATIAL_REP_NUMBER,61 -US-UMB,18517,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Wood -US-UMB,18517,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-UMB,18517,GRP_AG_PROD_TREE,AG_PROD_DATE_START,19991101 -US-UMB,18517,GRP_AG_PROD_TREE,AG_PROD_DATE_END,20001116 -US-UMB,18517,GRP_AG_PROD_TREE,AG_PROD_DATE_UNC,4 -US-UMB,18517,GRP_AG_PROD_TREE,AG_PROD_COMMENT,Species specific allometric equations in the form a*D^b where D is diameter of tree stem at 1.37 m ht and a and b are species specific constants were used to determine AG woody biomass. Stem diameters for all trees in all plots were estimated from band dendrometer readings taken from 10 -20% of total number of trees. See STEM_INCR data in this file for more information. -US-UMB,18508,GRP_AG_PROD_TREE,AG_PROD_TREE,193.3 -US-UMB,18508,GRP_AG_PROD_TREE,AG_PROD_TREE_SPATIAL_VARIABILITY,55.1 -US-UMB,18508,GRP_AG_PROD_TREE,AG_PROD_TREE_SPATIAL_REP_NUMBER,61 -US-UMB,18508,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Wood -US-UMB,18508,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-UMB,18508,GRP_AG_PROD_TREE,AG_PROD_DATE_START,19981101 -US-UMB,18508,GRP_AG_PROD_TREE,AG_PROD_DATE_END,19991101 -US-UMB,18508,GRP_AG_PROD_TREE,AG_PROD_DATE_UNC,4 -US-UMB,18508,GRP_AG_PROD_TREE,AG_PROD_COMMENT,Species specific allometric equations in the form a*D^b where D is diameter of tree stem at 1.37 m ht and a and b are species specific constants were used to determine AG woody biomass. Stem diameters for all trees in all plots were estimated from band dendrometer readings taken from 10 -20% of total number of trees. See STEM_INCR data in this file for more information. -US-UMB,18525,GRP_AG_PROD_TREE,AG_PROD_TREE,268.9 -US-UMB,18525,GRP_AG_PROD_TREE,AG_PROD_TREE_SPATIAL_VARIABILITY,155.6 -US-UMB,18525,GRP_AG_PROD_TREE,AG_PROD_TREE_SPATIAL_REP_NUMBER,61 -US-UMB,18525,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Wood -US-UMB,18525,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-UMB,18525,GRP_AG_PROD_TREE,AG_PROD_DATE_START,20001116 -US-UMB,18525,GRP_AG_PROD_TREE,AG_PROD_DATE_END,20010701 -US-UMB,18525,GRP_AG_PROD_TREE,AG_PROD_DATE_UNC,28 -US-UMB,18525,GRP_AG_PROD_TREE,AG_PROD_COMMENT,Species specific allometric equations in the form a*D^b where D is diameter of tree stem at 1.37 m ht and a and b are species specific constants were used to determine AG woody biomass. Stem diameters for all trees in all plots were estimated from band dendrometer readings taken from 10 -20% of total number of trees in year 2000. All trees manualy measured for Diameter in 2001. See STEM_INCR data in this file for more information. -US-UMB,18479,GRP_AG_PROD_TREE,AG_PROD_TREE,315.8 -US-UMB,18479,GRP_AG_PROD_TREE,AG_PROD_TREE_SPATIAL_VARIABILITY,312.7 -US-UMB,18479,GRP_AG_PROD_TREE,AG_PROD_TREE_SPATIAL_REP_NUMBER,78 -US-UMB,18479,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Wood -US-UMB,18479,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-UMB,18479,GRP_AG_PROD_TREE,AG_PROD_DATE_START,20091104 -US-UMB,18479,GRP_AG_PROD_TREE,AG_PROD_DATE_END,20101112 -US-UMB,18479,GRP_AG_PROD_TREE,AG_PROD_DATE_UNC,4 -US-UMB,18479,GRP_AG_PROD_TREE,AG_PROD_COMMENT,Species specific allometric equations in the form a*D^b where D is diameter of tree stem at 1.37 m ht and a and b are species specific constants were used to determine AG woody biomass. Stem diameters for all trees in all plots were estimated from band dendrometer readings taken from 10 -20% of total number of trees in year 2009. All trees manualy measured for Diameter in 2010. See STEM_INCR data in this file for more information. -US-UMB,18405,GRP_AG_PROD_TREE,AG_PROD_TREE,733.1 -US-UMB,18405,GRP_AG_PROD_TREE,AG_PROD_TREE_SPATIAL_VARIABILITY,212.55 -US-UMB,18405,GRP_AG_PROD_TREE,AG_PROD_TREE_SPATIAL_REP_NUMBER,13 -US-UMB,18405,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Wood -US-UMB,18405,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-UMB,18405,GRP_AG_PROD_TREE,AG_PROD_DATE_START,19980715 -US-UMB,18405,GRP_AG_PROD_TREE,AG_PROD_DATE_END,20010715 -US-UMB,18405,GRP_AG_PROD_TREE,AG_PROD_DATE_UNC,28 -US-UMB,18405,GRP_AG_PROD_TREE,AG_PROD_COMMENT,Species specific allometric equations in the form a*D^b where D is diameter of tree stem at 1.37 m ht and a and b are species specific constants were used to determine AG woody biomass. Stem diameters were determined from manual measurments of trees in 13 - 0.08 ha plots. -US-UMB,18394,GRP_AG_PROD_TREE,AG_PROD_TREE,784.9 -US-UMB,18394,GRP_AG_PROD_TREE,AG_PROD_TREE_SPATIAL_VARIABILITY,240.94 -US-UMB,18394,GRP_AG_PROD_TREE,AG_PROD_TREE_SPATIAL_REP_NUMBER,48 -US-UMB,18394,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Wood -US-UMB,18394,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-UMB,18394,GRP_AG_PROD_TREE,AG_PROD_DATE_START,19970715 -US-UMB,18394,GRP_AG_PROD_TREE,AG_PROD_DATE_END,20010715 -US-UMB,18394,GRP_AG_PROD_TREE,AG_PROD_DATE_UNC,28 -US-UMB,18394,GRP_AG_PROD_TREE,AG_PROD_COMMENT,Species specific allometric equations in the form a*D^b where D is diameter of tree stem at 1.37 m ht and a and b are species specific constants were used to determine AG woody biomass. Stem diameters were determined from manual measurments of trees in 47 - 0.08 ha plots and a single 1.13 ha plot -US-UMB,18882,GRP_BASAL_AREA,BASAL_AREA,0.1 -US-UMB,18882,GRP_BASAL_AREA,BASAL_AREA_SPP,Other -US-UMB,18882,GRP_BASAL_AREA,BASAL_AREA_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 60 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm." -US-UMB,18882,GRP_BASAL_AREA,BASAL_AREA_DATE,19970714 -US-UMB,18882,GRP_BASAL_AREA,BASAL_AREA_DATE_UNC,28 -US-UMB,18882,GRP_BASAL_AREA,BASAL_AREA_COMMENT,Average and standard dev. based on 61 plots regardless of whether species existed in all plots. Number of Other trees = 54. Other trees represented by 6 species. -US-UMB,18882,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,61 -US-UMB,18882,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,0.22 -US-UMB,18904,GRP_BASAL_AREA,BASAL_AREA,0.11 -US-UMB,18904,GRP_BASAL_AREA,BASAL_AREA_SPP,Other -US-UMB,18904,GRP_BASAL_AREA,BASAL_AREA_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 60 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm." -US-UMB,18904,GRP_BASAL_AREA,BASAL_AREA_DATE,20010714 -US-UMB,18904,GRP_BASAL_AREA,BASAL_AREA_DATE_UNC,28 -US-UMB,18904,GRP_BASAL_AREA,BASAL_AREA_COMMENT,Average and standard dev. based on 61 plots regardless of whether species existed in all plots. Number of Other trees = 64. Other trees represented by 6 species. -US-UMB,18904,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,61 -US-UMB,18904,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,0.25 -US-UMB,19117,GRP_BASAL_AREA,BASAL_AREA,0.15 -US-UMB,19117,GRP_BASAL_AREA,BASAL_AREA_SPP,Populus tremuloides -US-UMB,19117,GRP_BASAL_AREA,BASAL_AREA_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 20 - 0.08 ha plots for trees with DBH >= 8 cm." -US-UMB,19117,GRP_BASAL_AREA,BASAL_AREA_DATE,20030714 -US-UMB,19117,GRP_BASAL_AREA,BASAL_AREA_DATE_UNC,28 -US-UMB,19117,GRP_BASAL_AREA,BASAL_AREA_COMMENT,Average and standard dev. based on 20 plots regardless of whether species existed in all plots. The plots represented here are different from those from 1997 and 2001. Number of P. tremuloides trees = 29. 2 of the 3 plots only had a single P. tremuloides tree. -US-UMB,19117,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,20 -US-UMB,19117,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,0.57 -US-UMB,19138,GRP_BASAL_AREA,BASAL_AREA,0.16 -US-UMB,19138,GRP_BASAL_AREA,BASAL_AREA_SPP,Other -US-UMB,19138,GRP_BASAL_AREA,BASAL_AREA_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 76 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm." -US-UMB,19138,GRP_BASAL_AREA,BASAL_AREA_DATE,20100714 -US-UMB,19138,GRP_BASAL_AREA,BASAL_AREA_DATE_UNC,28 -US-UMB,19138,GRP_BASAL_AREA,BASAL_AREA_COMMENT,Average and standard dev. based on 77 plots regardless of whether species existed in all plots. The plots represented here are a combination of plots measured in 2001 and 2003. Number of Other trees = 79. Other trees are represented by 11 species. -US-UMB,19138,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,77 -US-UMB,19138,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,0.36 -US-UMB,18857,GRP_BASAL_AREA,BASAL_AREA,0.28 -US-UMB,18857,GRP_BASAL_AREA,BASAL_AREA_SPP,Acer saccharum -US-UMB,18857,GRP_BASAL_AREA,BASAL_AREA_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 60 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm." -US-UMB,18857,GRP_BASAL_AREA,BASAL_AREA_DATE,19970714 -US-UMB,18857,GRP_BASAL_AREA,BASAL_AREA_DATE_UNC,28 -US-UMB,18857,GRP_BASAL_AREA,BASAL_AREA_COMMENT,Average and standard dev. based on 61 plots regardless of whether species existed in all plots. Number of A saccharum trees = 82 -US-UMB,18857,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,61 -US-UMB,18857,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,1.06 -US-UMB,19125,GRP_BASAL_AREA,BASAL_AREA,0.28 -US-UMB,19125,GRP_BASAL_AREA,BASAL_AREA_SPP,Other -US-UMB,19125,GRP_BASAL_AREA,BASAL_AREA_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 20 - 0.08 ha plots for trees with DBH >= 8 cm." -US-UMB,19125,GRP_BASAL_AREA,BASAL_AREA_DATE,20030714 -US-UMB,19125,GRP_BASAL_AREA,BASAL_AREA_DATE_UNC,28 -US-UMB,19125,GRP_BASAL_AREA,BASAL_AREA_COMMENT,Average and standard dev. based on 20 plots regardless of whether species existed in all plots. The plots represented here are different from those from 1997 and 2001. Number of Other trees = 22. Other trees represented by 8 species. -US-UMB,19125,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,20 -US-UMB,19125,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,0.52 -US-UMB,18892,GRP_BASAL_AREA,BASAL_AREA,0.33 -US-UMB,18892,GRP_BASAL_AREA,BASAL_AREA_SPP,Acer saccharum -US-UMB,18892,GRP_BASAL_AREA,BASAL_AREA_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 60 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm." -US-UMB,18892,GRP_BASAL_AREA,BASAL_AREA_DATE,20010714 -US-UMB,18892,GRP_BASAL_AREA,BASAL_AREA_DATE_UNC,28 -US-UMB,18892,GRP_BASAL_AREA,BASAL_AREA_COMMENT,Average and standard dev. based on 61 plots regardless of whether species existed in all plots. Number of A saccharum trees = 88 -US-UMB,18892,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,61 -US-UMB,18892,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,1.23 -US-UMB,19109,GRP_BASAL_AREA,BASAL_AREA,0.57 -US-UMB,19109,GRP_BASAL_AREA,BASAL_AREA_SPP,Pinus strobus -US-UMB,19109,GRP_BASAL_AREA,BASAL_AREA_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 20 - 0.08 ha plots for trees with DBH >= 8 cm." -US-UMB,19109,GRP_BASAL_AREA,BASAL_AREA_DATE,20030714 -US-UMB,19109,GRP_BASAL_AREA,BASAL_AREA_DATE_UNC,28 -US-UMB,19109,GRP_BASAL_AREA,BASAL_AREA_COMMENT,Average and standard dev. based on 20 plots regardless of whether species existed in all plots. The plots represented here are different from those from 1997 and 2001. Number of P. strobus trees = 51 -US-UMB,19109,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,20 -US-UMB,19109,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,0.85 -US-UMB,19063,GRP_BASAL_AREA,BASAL_AREA,0.67 -US-UMB,19063,GRP_BASAL_AREA,BASAL_AREA_SPP,Pinus strobus -US-UMB,19063,GRP_BASAL_AREA,BASAL_AREA_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 60 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm." -US-UMB,19063,GRP_BASAL_AREA,BASAL_AREA_DATE,19970714 -US-UMB,19063,GRP_BASAL_AREA,BASAL_AREA_DATE_UNC,28 -US-UMB,19063,GRP_BASAL_AREA,BASAL_AREA_COMMENT,Average and standard dev. based on 61 plots regardless of whether species existed in all plots. Number of P strobus trees = 481 -US-UMB,19063,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,61 -US-UMB,19063,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,1.82 -US-UMB,18925,GRP_BASAL_AREA,BASAL_AREA,0.72 -US-UMB,18925,GRP_BASAL_AREA,BASAL_AREA_SPP,Acer saccarum -US-UMB,18925,GRP_BASAL_AREA,BASAL_AREA_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 76 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm." -US-UMB,18925,GRP_BASAL_AREA,BASAL_AREA_DATE,20100714 -US-UMB,18925,GRP_BASAL_AREA,BASAL_AREA_DATE_UNC,28 -US-UMB,18925,GRP_BASAL_AREA,BASAL_AREA_COMMENT,Average and standard dev. based on 77 plots regardless of whether species existed in all plots. The plots represented here are a combination of plots measured in 2001 and 2003. Number of A saccharum trees = 174 -US-UMB,18925,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,77 -US-UMB,18925,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,2.66 -US-UMB,18871,GRP_BASAL_AREA,BASAL_AREA,0.8 -US-UMB,18871,GRP_BASAL_AREA,BASAL_AREA_SPP,Fagus grandifolia -US-UMB,18871,GRP_BASAL_AREA,BASAL_AREA_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 60 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm." -US-UMB,18871,GRP_BASAL_AREA,BASAL_AREA_DATE,19970714 -US-UMB,18871,GRP_BASAL_AREA,BASAL_AREA_DATE_UNC,28 -US-UMB,18871,GRP_BASAL_AREA,BASAL_AREA_COMMENT,Average and standard dev. based on 61 plots regardless of whether species existed in all plots. Number of F. grandifolia trees = 234 -US-UMB,18871,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,61 -US-UMB,18871,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,2.23 -US-UMB,19092,GRP_BASAL_AREA,BASAL_AREA,0.8 -US-UMB,19092,GRP_BASAL_AREA,BASAL_AREA_SPP,Pinus strobus -US-UMB,19092,GRP_BASAL_AREA,BASAL_AREA_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 60 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm." -US-UMB,19092,GRP_BASAL_AREA,BASAL_AREA_DATE,20010714 -US-UMB,19092,GRP_BASAL_AREA,BASAL_AREA_DATE_UNC,28 -US-UMB,19092,GRP_BASAL_AREA,BASAL_AREA_COMMENT,Average and standard dev. based on 61 plots regardless of whether species existed in all plots. Number of P strobus trees = 572 -US-UMB,19092,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,61 -US-UMB,19092,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,2.09 -US-UMB,19087,GRP_BASAL_AREA,BASAL_AREA,0.92 -US-UMB,19087,GRP_BASAL_AREA,BASAL_AREA_SPP,Fagus grandifolia -US-UMB,19087,GRP_BASAL_AREA,BASAL_AREA_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 60 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm." -US-UMB,19087,GRP_BASAL_AREA,BASAL_AREA_DATE,20010714 -US-UMB,19087,GRP_BASAL_AREA,BASAL_AREA_DATE_UNC,28 -US-UMB,19087,GRP_BASAL_AREA,BASAL_AREA_COMMENT,Average and standard dev. based on 61 plots regardless of whether species existed in all plots. Number of F. grandifolia trees = 255 -US-UMB,19087,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,61 -US-UMB,19087,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,2.47 -US-UMB,19105,GRP_BASAL_AREA,BASAL_AREA,0.98 -US-UMB,19105,GRP_BASAL_AREA,BASAL_AREA_SPP,Fagus grandifolia -US-UMB,19105,GRP_BASAL_AREA,BASAL_AREA_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 20 - 0.08 ha plots for trees with DBH >= 8 cm." -US-UMB,19105,GRP_BASAL_AREA,BASAL_AREA_DATE,20030714 -US-UMB,19105,GRP_BASAL_AREA,BASAL_AREA_DATE_UNC,28 -US-UMB,19105,GRP_BASAL_AREA,BASAL_AREA_COMMENT,Average and standard dev. based on 20 plots regardless of whether species existed in all plots. The plots represented here are different from those from 1997 and 2001. Number of F. grandifolia trees = 57 -US-UMB,19105,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,20 -US-UMB,19105,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,2.46 -US-UMB,18937,GRP_BASAL_AREA,BASAL_AREA,1.14 -US-UMB,18937,GRP_BASAL_AREA,BASAL_AREA_SPP,Pinus strobus -US-UMB,18937,GRP_BASAL_AREA,BASAL_AREA_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 76 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm." -US-UMB,18937,GRP_BASAL_AREA,BASAL_AREA_DATE,20100714 -US-UMB,18937,GRP_BASAL_AREA,BASAL_AREA_DATE_UNC,28 -US-UMB,18937,GRP_BASAL_AREA,BASAL_AREA_COMMENT,Average and standard dev. based on 77 plots regardless of whether species existed in all plots. The plots represented here are a combination of plots measured in 2001 and 2003. Number of P. strobus trees = 810. -US-UMB,18937,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,77 -US-UMB,18937,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,2.65 -US-UMB,18933,GRP_BASAL_AREA,BASAL_AREA,1.18 -US-UMB,18933,GRP_BASAL_AREA,BASAL_AREA_SPP,Fagus grandifolia -US-UMB,18933,GRP_BASAL_AREA,BASAL_AREA_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 76 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm." -US-UMB,18933,GRP_BASAL_AREA,BASAL_AREA_DATE,20100714 -US-UMB,18933,GRP_BASAL_AREA,BASAL_AREA_DATE_UNC,28 -US-UMB,18933,GRP_BASAL_AREA,BASAL_AREA_COMMENT,Average and standard dev. based on 77 plots regardless of whether species existed in all plots. The plots represented here are a combination of plots measured in 2001 and 2003. Number of F grandifolia trees = 343 -US-UMB,18933,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,77 -US-UMB,18933,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,2.9 -US-UMB,18916,GRP_BASAL_AREA,BASAL_AREA,1.31 -US-UMB,18916,GRP_BASAL_AREA,BASAL_AREA_SPP,Betula papyrifera -US-UMB,18916,GRP_BASAL_AREA,BASAL_AREA_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 20 - 0.08 ha plots for trees with DBH >= 8 cm." -US-UMB,18916,GRP_BASAL_AREA,BASAL_AREA_DATE,20030714 -US-UMB,18916,GRP_BASAL_AREA,BASAL_AREA_DATE_UNC,28 -US-UMB,18916,GRP_BASAL_AREA,BASAL_AREA_COMMENT,Average and standard dev. based on 20 plots regardless of whether species existed in all plots. The plots represented here are different from those from 1997 and 2001. Number of B. papyrifera trees = 68 -US-UMB,18916,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,20 -US-UMB,18916,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,2.46 -US-UMB,18912,GRP_BASAL_AREA,BASAL_AREA,1.56 -US-UMB,18912,GRP_BASAL_AREA,BASAL_AREA_SPP,Acer saccarum -US-UMB,18912,GRP_BASAL_AREA,BASAL_AREA_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 20 - 0.08 ha plots for trees with DBH >= 8 cm." -US-UMB,18912,GRP_BASAL_AREA,BASAL_AREA_DATE,20030714 -US-UMB,18912,GRP_BASAL_AREA,BASAL_AREA_DATE_UNC,28 -US-UMB,18912,GRP_BASAL_AREA,BASAL_AREA_COMMENT,Average and standard dev. based on 20 plots regardless of whether species existed in all plots. The plots represented here are different from those from 1997 and 2001. Number of A. saccharum trees = 114 -US-UMB,18912,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,20 -US-UMB,18912,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,3.89 -US-UMB,18929,GRP_BASAL_AREA,BASAL_AREA,1.76 -US-UMB,18929,GRP_BASAL_AREA,BASAL_AREA_SPP,Betula papyrifera -US-UMB,18929,GRP_BASAL_AREA,BASAL_AREA_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 76 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm." -US-UMB,18929,GRP_BASAL_AREA,BASAL_AREA_DATE,20100714 -US-UMB,18929,GRP_BASAL_AREA,BASAL_AREA_DATE_UNC,28 -US-UMB,18929,GRP_BASAL_AREA,BASAL_AREA_COMMENT,Average and standard dev. based on 77 plots regardless of whether species existed in all plots. The plots represented here are a combination of plots measured in 2001 and 2003. Number of B papyrifera trees = 371 -US-UMB,18929,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,77 -US-UMB,18929,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,2.35 -US-UMB,18941,GRP_BASAL_AREA,BASAL_AREA,10.45 -US-UMB,18941,GRP_BASAL_AREA,BASAL_AREA_SPP,Populus grandidentata -US-UMB,18941,GRP_BASAL_AREA,BASAL_AREA_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 76 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm." -US-UMB,18941,GRP_BASAL_AREA,BASAL_AREA_DATE,20100714 -US-UMB,18941,GRP_BASAL_AREA,BASAL_AREA_DATE_UNC,28 -US-UMB,18941,GRP_BASAL_AREA,BASAL_AREA_COMMENT,Average and standard dev. based on 77 plots regardless of whether species existed in all plots. The plots represented here are a combination of plots measured in 2001 and 2003. Number of P. grandidentata trees = 1299 -US-UMB,18941,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,77 -US-UMB,18941,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,9.86 -US-UMB,19113,GRP_BASAL_AREA,BASAL_AREA,12.05 -US-UMB,19113,GRP_BASAL_AREA,BASAL_AREA_SPP,Populus grandidentata -US-UMB,19113,GRP_BASAL_AREA,BASAL_AREA_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 20 - 0.08 ha plots for trees with DBH >= 8 cm." -US-UMB,19113,GRP_BASAL_AREA,BASAL_AREA_DATE,20030714 -US-UMB,19113,GRP_BASAL_AREA,BASAL_AREA_DATE_UNC,28 -US-UMB,19113,GRP_BASAL_AREA,BASAL_AREA_COMMENT,Average and standard dev. based on 20 plots regardless of whether species existed in all plots. The plots represented here are different from those from 1997 and 2001. Number of P. grandidentata trees = 394 -US-UMB,19113,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,20 -US-UMB,19113,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,10.59 -US-UMB,18876,GRP_BASAL_AREA,BASAL_AREA,2.06 -US-UMB,18876,GRP_BASAL_AREA,BASAL_AREA_SPP,Quercus rubra -US-UMB,18876,GRP_BASAL_AREA,BASAL_AREA_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 60 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm." -US-UMB,18876,GRP_BASAL_AREA,BASAL_AREA_DATE,19970714 -US-UMB,18876,GRP_BASAL_AREA,BASAL_AREA_DATE_UNC,28 -US-UMB,18876,GRP_BASAL_AREA,BASAL_AREA_COMMENT,Average and standard dev. based on 61 plots regardless of whether species existed in all plots. Number of Q. rubra trees = 273 -US-UMB,18876,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,61 -US-UMB,18876,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,3.33 -US-UMB,18899,GRP_BASAL_AREA,BASAL_AREA,2.32 -US-UMB,18899,GRP_BASAL_AREA,BASAL_AREA_SPP,Quercus rubra -US-UMB,18899,GRP_BASAL_AREA,BASAL_AREA_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 60 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm." -US-UMB,18899,GRP_BASAL_AREA,BASAL_AREA_DATE,20010714 -US-UMB,18899,GRP_BASAL_AREA,BASAL_AREA_DATE_UNC,28 -US-UMB,18899,GRP_BASAL_AREA,BASAL_AREA_COMMENT,Average and standard dev. based on 61 plots regardless of whether species existed in all plots. Number of Q. rubra trees = 305 -US-UMB,18899,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,61 -US-UMB,18899,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,3.58 -US-UMB,18864,GRP_BASAL_AREA,BASAL_AREA,2.35 -US-UMB,18864,GRP_BASAL_AREA,BASAL_AREA_SPP,Betula papyrifera -US-UMB,18864,GRP_BASAL_AREA,BASAL_AREA_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 60 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm." -US-UMB,18864,GRP_BASAL_AREA,BASAL_AREA_DATE,19970714 -US-UMB,18864,GRP_BASAL_AREA,BASAL_AREA_DATE_UNC,28 -US-UMB,18864,GRP_BASAL_AREA,BASAL_AREA_COMMENT,Average and standard dev. based on 61 plots regardless of whether species existed in all plots. Number of B. papyrifera trees = 441 -US-UMB,18864,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,61 -US-UMB,18864,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,2.85 -US-UMB,19082,GRP_BASAL_AREA,BASAL_AREA,2.39 -US-UMB,19082,GRP_BASAL_AREA,BASAL_AREA_SPP,Betula papyrifera -US-UMB,19082,GRP_BASAL_AREA,BASAL_AREA_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 60 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm." -US-UMB,19082,GRP_BASAL_AREA,BASAL_AREA_DATE,20010714 -US-UMB,19082,GRP_BASAL_AREA,BASAL_AREA_DATE_UNC,28 -US-UMB,19082,GRP_BASAL_AREA,BASAL_AREA_COMMENT,Average and standard dev. based on 61 plots regardless of whether species existed in all plots. Number of B. papyrifera trees = 425 -US-UMB,19082,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,61 -US-UMB,19082,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,2.86 -US-UMB,19130,GRP_BASAL_AREA,BASAL_AREA,2.98 -US-UMB,19130,GRP_BASAL_AREA,BASAL_AREA_SPP,Populus tremuloides -US-UMB,19130,GRP_BASAL_AREA,BASAL_AREA_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 76 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm." -US-UMB,19130,GRP_BASAL_AREA,BASAL_AREA_DATE,20100714 -US-UMB,19130,GRP_BASAL_AREA,BASAL_AREA_DATE_UNC,28 -US-UMB,19130,GRP_BASAL_AREA,BASAL_AREA_COMMENT,Average and standard dev. based on 77 plots regardless of whether species existed in all plots. The plots represented here are a combination of plots measured in 2001 and 2003. Number of P. tremuloides trees = 336 -US-UMB,19130,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,77 -US-UMB,19130,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,5.99 -US-UMB,19134,GRP_BASAL_AREA,BASAL_AREA,3.25 -US-UMB,19134,GRP_BASAL_AREA,BASAL_AREA_SPP,Quercus rubra -US-UMB,19134,GRP_BASAL_AREA,BASAL_AREA_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 76 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm." -US-UMB,19134,GRP_BASAL_AREA,BASAL_AREA_DATE,20100714 -US-UMB,19134,GRP_BASAL_AREA,BASAL_AREA_DATE_UNC,28 -US-UMB,19134,GRP_BASAL_AREA,BASAL_AREA_COMMENT,Average and standard dev. based on 77 plots regardless of whether species existed in all plots. The plots represented here are a combination of plots measured in 2001 and 2003. Number of Q. rubra trees = 484 -US-UMB,19134,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,77 -US-UMB,19134,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,4.49 -US-UMB,18908,GRP_BASAL_AREA,BASAL_AREA,3.98 -US-UMB,18908,GRP_BASAL_AREA,BASAL_AREA_SPP,Acer rubrum -US-UMB,18908,GRP_BASAL_AREA,BASAL_AREA_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 20 - 0.08 ha plots for trees with DBH >= 8 cm." -US-UMB,18908,GRP_BASAL_AREA,BASAL_AREA_DATE,20030714 -US-UMB,18908,GRP_BASAL_AREA,BASAL_AREA_DATE_UNC,28 -US-UMB,18908,GRP_BASAL_AREA,BASAL_AREA_COMMENT,Average and standard dev. based on 20 plots regardless of whether species existed in all plots. The plots represented here are different from those from 1997 and 2001. Number of A. rubrum trees = 327 -US-UMB,18908,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,20 -US-UMB,18908,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,4.07 -US-UMB,19077,GRP_BASAL_AREA,BASAL_AREA,3.99 -US-UMB,19077,GRP_BASAL_AREA,BASAL_AREA_SPP,Populus tremuloides -US-UMB,19077,GRP_BASAL_AREA,BASAL_AREA_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 60 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm." -US-UMB,19077,GRP_BASAL_AREA,BASAL_AREA_DATE,19970714 -US-UMB,19077,GRP_BASAL_AREA,BASAL_AREA_DATE_UNC,28 -US-UMB,19077,GRP_BASAL_AREA,BASAL_AREA_COMMENT,Average and standard dev. based on 61 plots regardless of whether species existed in all plots. Number of P. tremuloides trees = 458 -US-UMB,19077,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,61 -US-UMB,19077,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,6.8 -US-UMB,19056,GRP_BASAL_AREA,BASAL_AREA,4.13 -US-UMB,19056,GRP_BASAL_AREA,BASAL_AREA_SPP,Acer rubrum -US-UMB,19056,GRP_BASAL_AREA,BASAL_AREA_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 60 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm." -US-UMB,19056,GRP_BASAL_AREA,BASAL_AREA_DATE,19970714 -US-UMB,19056,GRP_BASAL_AREA,BASAL_AREA_DATE_UNC,28 -US-UMB,19056,GRP_BASAL_AREA,BASAL_AREA_COMMENT,Average and standard dev. based on 61 plots regardless of whether species existed in all plots. Number of A rubrum trees = 1189 -US-UMB,19056,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,61 -US-UMB,19056,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,3.79 -US-UMB,19102,GRP_BASAL_AREA,BASAL_AREA,4.15 -US-UMB,19102,GRP_BASAL_AREA,BASAL_AREA_SPP,Populus tremuloides -US-UMB,19102,GRP_BASAL_AREA,BASAL_AREA_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 60 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm." -US-UMB,19102,GRP_BASAL_AREA,BASAL_AREA_DATE,20010714 -US-UMB,19102,GRP_BASAL_AREA,BASAL_AREA_DATE_UNC,28 -US-UMB,19102,GRP_BASAL_AREA,BASAL_AREA_COMMENT,Average and standard dev. based on 61 plots regardless of whether species existed in all plots. Number of P. tremuloides trees = 425 -US-UMB,19102,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,61 -US-UMB,19102,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,7.03 -US-UMB,19121,GRP_BASAL_AREA,BASAL_AREA,4.27 -US-UMB,19121,GRP_BASAL_AREA,BASAL_AREA_SPP,Quercus rubra -US-UMB,19121,GRP_BASAL_AREA,BASAL_AREA_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 20 - 0.08 ha plots for trees with DBH >= 8 cm." -US-UMB,19121,GRP_BASAL_AREA,BASAL_AREA_DATE,20030714 -US-UMB,19121,GRP_BASAL_AREA,BASAL_AREA_DATE_UNC,28 -US-UMB,19121,GRP_BASAL_AREA,BASAL_AREA_COMMENT,Average and standard dev. based on 20 plots regardless of whether species existed in all plots. The plots represented here are different from those from 1997 and 2001. Number of Q. rubra trees = 130 -US-UMB,19121,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,20 -US-UMB,19121,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,5.44 -US-UMB,18887,GRP_BASAL_AREA,BASAL_AREA,4.47 -US-UMB,18887,GRP_BASAL_AREA,BASAL_AREA_SPP,Acer rubrum -US-UMB,18887,GRP_BASAL_AREA,BASAL_AREA_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 60 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm." -US-UMB,18887,GRP_BASAL_AREA,BASAL_AREA_DATE,20010714 -US-UMB,18887,GRP_BASAL_AREA,BASAL_AREA_DATE_UNC,28 -US-UMB,18887,GRP_BASAL_AREA,BASAL_AREA_COMMENT,Average and standard dev. based on 61 plots regardless of whether species existed in all plots. Number of A rubrum trees = 1234 -US-UMB,18887,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,61 -US-UMB,18887,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,3.86 -US-UMB,18921,GRP_BASAL_AREA,BASAL_AREA,5.11 -US-UMB,18921,GRP_BASAL_AREA,BASAL_AREA_SPP,Acer rubrum -US-UMB,18921,GRP_BASAL_AREA,BASAL_AREA_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 76 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm." -US-UMB,18921,GRP_BASAL_AREA,BASAL_AREA_DATE,20100714 -US-UMB,18921,GRP_BASAL_AREA,BASAL_AREA_DATE_UNC,28 -US-UMB,18921,GRP_BASAL_AREA,BASAL_AREA_COMMENT,Average and standard dev. based on 77 plots regardless of whether species existed in all plots. The plots represented here are a combination of plots measured in 2001 and 2003. Number of A rubrum trees = 1588 -US-UMB,18921,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,77 -US-UMB,18921,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,4.07 -US-UMB,19070,GRP_BASAL_AREA,BASAL_AREA,8.72 -US-UMB,19070,GRP_BASAL_AREA,BASAL_AREA_SPP,Populus grandidentata -US-UMB,19070,GRP_BASAL_AREA,BASAL_AREA_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 60 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm." -US-UMB,19070,GRP_BASAL_AREA,BASAL_AREA_DATE,19970714 -US-UMB,19070,GRP_BASAL_AREA,BASAL_AREA_DATE_UNC,28 -US-UMB,19070,GRP_BASAL_AREA,BASAL_AREA_COMMENT,Average and standard dev. based on 61 plots regardless of whether species existed in all plots. Number of P grandidentata trees = 1187 -US-UMB,19070,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,61 -US-UMB,19070,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,8.44 -US-UMB,19097,GRP_BASAL_AREA,BASAL_AREA,9.23 -US-UMB,19097,GRP_BASAL_AREA,BASAL_AREA_SPP,Populus grandidentata -US-UMB,19097,GRP_BASAL_AREA,BASAL_AREA_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 60 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm." -US-UMB,19097,GRP_BASAL_AREA,BASAL_AREA_DATE,20010714 -US-UMB,19097,GRP_BASAL_AREA,BASAL_AREA_DATE_UNC,28 -US-UMB,19097,GRP_BASAL_AREA,BASAL_AREA_COMMENT,Average and standard dev. based on 61 plots regardless of whether species existed in all plots. Number of P grandidentata trees = 1129 -US-UMB,19097,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,61 -US-UMB,19097,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,8.98 -US-UMB,18509,GRP_BG_LIT_PROD,BG_LIT_PROD,249 -US-UMB,18509,GRP_BG_LIT_PROD,BG_LIT_PROD_SPATIAL_VARIABILITY,98 -US-UMB,18509,GRP_BG_LIT_PROD,BG_LIT_PROD_SPATIAL_REP_NUMBER,6 -US-UMB,18509,GRP_BG_LIT_PROD,BG_LIT_PROD_UNIT,gC m-2 -US-UMB,18509,GRP_BG_LIT_PROD,BG_LIT_PROD_PROFILE_ZERO_REF,Top of surface -US-UMB,18509,GRP_BG_LIT_PROD,BG_LIT_PROD_PROFILE_MIN,0 -US-UMB,18509,GRP_BG_LIT_PROD,BG_LIT_PROD_PROFILE_MAX,80 -US-UMB,18509,GRP_BG_LIT_PROD,BG_LIT_PROD_APPROACH,"Three approaches were used to estimate FINE ROOT turnover/production. See Gough et al, 2008. Ag For Met. 148: 158-170 for details. Very briefly, the 3 methods are 1) minirhizotron based cohort analysis, 2) An empirical relationship between annual N mineralization and fine root turnover, and 3) a mass balance approach." -US-UMB,18509,GRP_BG_LIT_PROD,BG_LIT_PROD_DATE_START,20030101 -US-UMB,18509,GRP_BG_LIT_PROD,BG_LIT_PROD_DATE_END,20031231 -US-UMB,18509,GRP_BG_LIT_PROD,BG_LIT_PROD_DATE_UNC,0 -US-UMB,18509,GRP_BG_LIT_PROD,BG_LIT_PROD_COMMENT,BG_LIT_PROD is for fine roots only -US-UMB,18427,GRP_BG_LIT_PROD,BG_LIT_PROD,254 -US-UMB,18427,GRP_BG_LIT_PROD,BG_LIT_PROD_SPATIAL_VARIABILITY,110 -US-UMB,18427,GRP_BG_LIT_PROD,BG_LIT_PROD_SPATIAL_REP_NUMBER,6 -US-UMB,18427,GRP_BG_LIT_PROD,BG_LIT_PROD_UNIT,gC m-2 -US-UMB,18427,GRP_BG_LIT_PROD,BG_LIT_PROD_PROFILE_ZERO_REF,Top of surface -US-UMB,18427,GRP_BG_LIT_PROD,BG_LIT_PROD_PROFILE_MIN,0 -US-UMB,18427,GRP_BG_LIT_PROD,BG_LIT_PROD_PROFILE_MAX,80 -US-UMB,18427,GRP_BG_LIT_PROD,BG_LIT_PROD_APPROACH,"Three approaches were used to estimate FINE ROOT turnover/production. See Gough et al, 2008. Ag For Met. 148: 158-170 for details. Very briefly, the 3 methods are 1) minirhizotron based cohort analysis, 2) An empirical relationship between annual N mineralization and fine root turnover, and 3) a mass balance approach." -US-UMB,18427,GRP_BG_LIT_PROD,BG_LIT_PROD_DATE_START,20020101 -US-UMB,18427,GRP_BG_LIT_PROD,BG_LIT_PROD_DATE_END,20021231 -US-UMB,18427,GRP_BG_LIT_PROD,BG_LIT_PROD_DATE_UNC,0 -US-UMB,18427,GRP_BG_LIT_PROD,BG_LIT_PROD_COMMENT,BG_LIT_PROD is for fine roots only -US-UMB,18406,GRP_BG_LIT_PROD,BG_LIT_PROD,267 -US-UMB,18406,GRP_BG_LIT_PROD,BG_LIT_PROD_SPATIAL_VARIABILITY,100 -US-UMB,18406,GRP_BG_LIT_PROD,BG_LIT_PROD_SPATIAL_REP_NUMBER,6 -US-UMB,18406,GRP_BG_LIT_PROD,BG_LIT_PROD_UNIT,gC m-2 -US-UMB,18406,GRP_BG_LIT_PROD,BG_LIT_PROD_PROFILE_ZERO_REF,Top of surface -US-UMB,18406,GRP_BG_LIT_PROD,BG_LIT_PROD_PROFILE_MIN,0 -US-UMB,18406,GRP_BG_LIT_PROD,BG_LIT_PROD_PROFILE_MAX,80 -US-UMB,18406,GRP_BG_LIT_PROD,BG_LIT_PROD_APPROACH,"Three approaches were used to estimate FINE ROOT turnover/production. See Gough et al, 2008. Ag For Met. 148: 158-170 for details. Very briefly, the 3 methods are 1) minirhizotron based cohort analysis, 2) An empirical relationship between annual N mineralization and fine root turnover, and 3) a mass balance approach." -US-UMB,18406,GRP_BG_LIT_PROD,BG_LIT_PROD_DATE_START,20000101 -US-UMB,18406,GRP_BG_LIT_PROD,BG_LIT_PROD_DATE_END,20001231 -US-UMB,18406,GRP_BG_LIT_PROD,BG_LIT_PROD_DATE_UNC,0 -US-UMB,18406,GRP_BG_LIT_PROD,BG_LIT_PROD_COMMENT,BG_LIT_PROD is for fine roots only -US-UMB,18417,GRP_BG_LIT_PROD,BG_LIT_PROD,275 -US-UMB,18417,GRP_BG_LIT_PROD,BG_LIT_PROD_SPATIAL_VARIABILITY,108 -US-UMB,18417,GRP_BG_LIT_PROD,BG_LIT_PROD_SPATIAL_REP_NUMBER,6 -US-UMB,18417,GRP_BG_LIT_PROD,BG_LIT_PROD_UNIT,gC m-2 -US-UMB,18417,GRP_BG_LIT_PROD,BG_LIT_PROD_PROFILE_ZERO_REF,Top of surface -US-UMB,18417,GRP_BG_LIT_PROD,BG_LIT_PROD_PROFILE_MIN,0 -US-UMB,18417,GRP_BG_LIT_PROD,BG_LIT_PROD_PROFILE_MAX,80 -US-UMB,18417,GRP_BG_LIT_PROD,BG_LIT_PROD_APPROACH,"Three approaches were used to estimate FINE ROOT turnover/production. See Gough et al, 2008. Ag For Met. 148: 158-170 for details. Very briefly, the 3 methods are 1) minirhizotron based cohort analysis, 2) An empirical relationship between annual N mineralization and fine root turnover, and 3) a mass balance approach." -US-UMB,18417,GRP_BG_LIT_PROD,BG_LIT_PROD_DATE_START,20010101 -US-UMB,18417,GRP_BG_LIT_PROD,BG_LIT_PROD_DATE_END,20011231 -US-UMB,18417,GRP_BG_LIT_PROD,BG_LIT_PROD_DATE_UNC,0 -US-UMB,18417,GRP_BG_LIT_PROD,BG_LIT_PROD_COMMENT,BG_LIT_PROD is for fine roots only -US-UMB,18395,GRP_BG_LIT_PROD,BG_LIT_PROD,300 -US-UMB,18395,GRP_BG_LIT_PROD,BG_LIT_PROD_SPATIAL_VARIABILITY,142 -US-UMB,18395,GRP_BG_LIT_PROD,BG_LIT_PROD_SPATIAL_REP_NUMBER,6 -US-UMB,18395,GRP_BG_LIT_PROD,BG_LIT_PROD_UNIT,gC m-2 -US-UMB,18395,GRP_BG_LIT_PROD,BG_LIT_PROD_PROFILE_ZERO_REF,Top of surface -US-UMB,18395,GRP_BG_LIT_PROD,BG_LIT_PROD_PROFILE_MIN,0 -US-UMB,18395,GRP_BG_LIT_PROD,BG_LIT_PROD_PROFILE_MAX,80 -US-UMB,18395,GRP_BG_LIT_PROD,BG_LIT_PROD_APPROACH,"Three approaches were used to estimate FINE ROOT turnover/production. See Gough et al, 2008. Ag For Met. 148: 158-170 for details. Very briefly, the 3 methods are 1) minirhizotron based cohort analysis, 2) An empirical relationship between annual N mineralization and fine root turnover, and 3) a mass balance approach." -US-UMB,18395,GRP_BG_LIT_PROD,BG_LIT_PROD_DATE_START,19990101 -US-UMB,18395,GRP_BG_LIT_PROD,BG_LIT_PROD_DATE_END,19991231 -US-UMB,18395,GRP_BG_LIT_PROD,BG_LIT_PROD_DATE_UNC,0 -US-UMB,18395,GRP_BG_LIT_PROD,BG_LIT_PROD_COMMENT,BG_LIT_PROD is for fine roots only -US-UMB,24979,GRP_BIOMASS_CHEM,BIOMASS_C,4.489 -US-UMB,24219,GRP_BIOMASS_CHEM,BIOMASS_C,4.611 -US-UMB,24596,GRP_BIOMASS_CHEM,BIOMASS_C,4.629 -US-UMB,24980,GRP_BIOMASS_CHEM,BIOMASS_C,4.726 -US-UMB,24469,GRP_BIOMASS_CHEM,BIOMASS_C,4.8 -US-UMB,24466,GRP_BIOMASS_CHEM,BIOMASS_C,4.839 -US-UMB,24222,GRP_BIOMASS_CHEM,BIOMASS_C,4.848 -US-UMB,24218,GRP_BIOMASS_CHEM,BIOMASS_C,4.855 -US-UMB,24981,GRP_BIOMASS_CHEM,BIOMASS_C,4.861 -US-UMB,24068,GRP_BIOMASS_CHEM,BIOMASS_C,4.877 -US-UMB,24720,GRP_BIOMASS_CHEM,BIOMASS_C,4.879 -US-UMB,23961,GRP_BIOMASS_CHEM,BIOMASS_C,4.911 -US-UMB,23832,GRP_BIOMASS_CHEM,BIOMASS_C,4.914 -US-UMB,23831,GRP_BIOMASS_CHEM,BIOMASS_C,4.935 -US-UMB,24857,GRP_BIOMASS_CHEM,BIOMASS_C,4.942 -US-UMB,23830,GRP_BIOMASS_CHEM,BIOMASS_C,4.994 -US-UMB,24467,GRP_BIOMASS_CHEM,BIOMASS_C,5.053 -US-UMB,24333,GRP_BIOMASS_CHEM,BIOMASS_C,5.054 -US-UMB,24719,GRP_BIOMASS_CHEM,BIOMASS_C,5.057 -US-UMB,23962,GRP_BIOMASS_CHEM,BIOMASS_C,5.058 -US-UMB,23698,GRP_BIOMASS_CHEM,BIOMASS_C,5.068 -US-UMB,24333,GRP_BIOMASS_CHEM,BIOMASS_N,0.006 -US-UMB,24857,GRP_BIOMASS_CHEM,BIOMASS_N,0.006 -US-UMB,24222,GRP_BIOMASS_CHEM,BIOMASS_N,0.007 -US-UMB,24469,GRP_BIOMASS_CHEM,BIOMASS_N,0.007 -US-UMB,24981,GRP_BIOMASS_CHEM,BIOMASS_N,0.007 -US-UMB,23831,GRP_BIOMASS_CHEM,BIOMASS_N,0.015 -US-UMB,23832,GRP_BIOMASS_CHEM,BIOMASS_N,0.015 -US-UMB,24068,GRP_BIOMASS_CHEM,BIOMASS_N,0.021 -US-UMB,24596,GRP_BIOMASS_CHEM,BIOMASS_N,0.099 -US-UMB,23698,GRP_BIOMASS_CHEM,BIOMASS_N,0.126 -US-UMB,23962,GRP_BIOMASS_CHEM,BIOMASS_N,0.131 -US-UMB,23961,GRP_BIOMASS_CHEM,BIOMASS_N,0.15 -US-UMB,24219,GRP_BIOMASS_CHEM,BIOMASS_N,0.151 -US-UMB,23830,GRP_BIOMASS_CHEM,BIOMASS_N,0.167 -US-UMB,24979,GRP_BIOMASS_CHEM,BIOMASS_N,0.168 -US-UMB,24466,GRP_BIOMASS_CHEM,BIOMASS_N,0.185 -US-UMB,24218,GRP_BIOMASS_CHEM,BIOMASS_N,0.204 -US-UMB,24720,GRP_BIOMASS_CHEM,BIOMASS_N,0.208 -US-UMB,24980,GRP_BIOMASS_CHEM,BIOMASS_N,0.213 -US-UMB,24719,GRP_BIOMASS_CHEM,BIOMASS_N,0.24 -US-UMB,24467,GRP_BIOMASS_CHEM,BIOMASS_N,0.245 -US-UMB,23698,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-UMB,23830,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-UMB,23831,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-UMB,23832,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-UMB,23961,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-UMB,23962,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-UMB,24068,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-UMB,24218,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-UMB,24219,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-UMB,24222,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-UMB,24333,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-UMB,24466,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-UMB,24467,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-UMB,24469,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-UMB,24596,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-UMB,24719,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-UMB,24720,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-UMB,24857,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-UMB,24979,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-UMB,24980,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-UMB,24981,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-UMB,23698,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-UMB,23830,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-UMB,23831,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-UMB,23832,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-UMB,23961,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-UMB,23962,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-UMB,24068,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-UMB,24218,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-UMB,24219,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-UMB,24222,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-UMB,24333,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-UMB,24466,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-UMB,24467,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-UMB,24469,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-UMB,24596,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-UMB,24719,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-UMB,24720,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-UMB,24857,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-UMB,24979,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-UMB,24980,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-UMB,24981,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-UMB,23830,GRP_BIOMASS_CHEM,BIOMASS_SPP,ACRU (NRCS plant code) -US-UMB,23831,GRP_BIOMASS_CHEM,BIOMASS_SPP,ACRU (NRCS plant code) -US-UMB,23961,GRP_BIOMASS_CHEM,BIOMASS_SPP,ACRU (NRCS plant code) -US-UMB,24219,GRP_BIOMASS_CHEM,BIOMASS_SPP,ACRU (NRCS plant code) -US-UMB,24469,GRP_BIOMASS_CHEM,BIOMASS_SPP,ACRU (NRCS plant code) -US-UMB,24466,GRP_BIOMASS_CHEM,BIOMASS_SPP,BEPA (NRCS plant code) -US-UMB,24857,GRP_BIOMASS_CHEM,BIOMASS_SPP,BEPA (NRCS plant code) -US-UMB,24979,GRP_BIOMASS_CHEM,BIOMASS_SPP,BEPA (NRCS plant code) -US-UMB,23698,GRP_BIOMASS_CHEM,BIOMASS_SPP,PIST (NRCS plant code) -US-UMB,23962,GRP_BIOMASS_CHEM,BIOMASS_SPP,PIST (NRCS plant code) -US-UMB,24333,GRP_BIOMASS_CHEM,BIOMASS_SPP,PIST (NRCS plant code) -US-UMB,24596,GRP_BIOMASS_CHEM,BIOMASS_SPP,PIST (NRCS plant code) -US-UMB,23832,GRP_BIOMASS_CHEM,BIOMASS_SPP,POGR4 (NRCS plant code) -US-UMB,24222,GRP_BIOMASS_CHEM,BIOMASS_SPP,POGR4 (NRCS plant code) -US-UMB,24467,GRP_BIOMASS_CHEM,BIOMASS_SPP,POGR4 (NRCS plant code) -US-UMB,24719,GRP_BIOMASS_CHEM,BIOMASS_SPP,POGR4 (NRCS plant code) -US-UMB,24980,GRP_BIOMASS_CHEM,BIOMASS_SPP,POGR4 (NRCS plant code) -US-UMB,24068,GRP_BIOMASS_CHEM,BIOMASS_SPP,QURU (NRCS plant code) -US-UMB,24218,GRP_BIOMASS_CHEM,BIOMASS_SPP,QURU (NRCS plant code) -US-UMB,24720,GRP_BIOMASS_CHEM,BIOMASS_SPP,QURU (NRCS plant code) -US-UMB,24981,GRP_BIOMASS_CHEM,BIOMASS_SPP,QURU (NRCS plant code) -US-UMB,23698,GRP_BIOMASS_CHEM,BIOMASS_DATE,19980720 -US-UMB,23830,GRP_BIOMASS_CHEM,BIOMASS_DATE,19980720 -US-UMB,24719,GRP_BIOMASS_CHEM,BIOMASS_DATE,19980720 -US-UMB,24720,GRP_BIOMASS_CHEM,BIOMASS_DATE,19980720 -US-UMB,23961,GRP_BIOMASS_CHEM,BIOMASS_DATE,19990624 -US-UMB,23962,GRP_BIOMASS_CHEM,BIOMASS_DATE,19990624 -US-UMB,24218,GRP_BIOMASS_CHEM,BIOMASS_DATE,19990624 -US-UMB,24466,GRP_BIOMASS_CHEM,BIOMASS_DATE,19990624 -US-UMB,24467,GRP_BIOMASS_CHEM,BIOMASS_DATE,19990624 -US-UMB,23831,GRP_BIOMASS_CHEM,BIOMASS_DATE,19990925 -US-UMB,23832,GRP_BIOMASS_CHEM,BIOMASS_DATE,19990925 -US-UMB,24068,GRP_BIOMASS_CHEM,BIOMASS_DATE,19990925 -US-UMB,24222,GRP_BIOMASS_CHEM,BIOMASS_DATE,20001206 -US-UMB,24333,GRP_BIOMASS_CHEM,BIOMASS_DATE,20001206 -US-UMB,24469,GRP_BIOMASS_CHEM,BIOMASS_DATE,20001206 -US-UMB,24857,GRP_BIOMASS_CHEM,BIOMASS_DATE,20001206 -US-UMB,24981,GRP_BIOMASS_CHEM,BIOMASS_DATE,20001206 -US-UMB,24219,GRP_BIOMASS_CHEM,BIOMASS_DATE,20010625 -US-UMB,24596,GRP_BIOMASS_CHEM,BIOMASS_DATE,20010625 -US-UMB,24979,GRP_BIOMASS_CHEM,BIOMASS_DATE,20010625 -US-UMB,24980,GRP_BIOMASS_CHEM,BIOMASS_DATE,20010625 -US-UMB,24222,GRP_BIOMASS_CHEM,BIOMASS_COMMENT,"Includes bark, sapwood and heartwood" -US-UMB,24333,GRP_BIOMASS_CHEM,BIOMASS_COMMENT,"Includes bark, sapwood and heartwood" -US-UMB,24469,GRP_BIOMASS_CHEM,BIOMASS_COMMENT,"Includes bark, sapwood and heartwood" -US-UMB,24857,GRP_BIOMASS_CHEM,BIOMASS_COMMENT,"Includes bark, sapwood and heartwood" -US-UMB,24981,GRP_BIOMASS_CHEM,BIOMASS_COMMENT,"Includes bark, sapwood and heartwood" -US-UMB,23831,GRP_BIOMASS_CHEM,BIOMASS_COMMENT,sapwood only -US-UMB,23832,GRP_BIOMASS_CHEM,BIOMASS_COMMENT,sapwood only -US-UMB,24068,GRP_BIOMASS_CHEM,BIOMASS_COMMENT,sapwood only -US-UMB,12328,GRP_CLIM_AVG,MAT,5.83 -US-UMB,12328,GRP_CLIM_AVG,MAP,803 -US-UMB,12328,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfb -US-UMB,27000439,GRP_COUNTRY,COUNTRY,USA -US-UMB,18905,GRP_DBH,DBH,11.36 -US-UMB,18905,GRP_DBH,DBH_SPP,Other -US-UMB,18905,GRP_DBH,DBH_HEIGHT,1.37 -US-UMB,18905,GRP_DBH,DBH_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 60 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm." -US-UMB,18905,GRP_DBH,DBH_DATE,20010714 -US-UMB,18905,GRP_DBH,DBH_DATE_UNC,28 -US-UMB,18905,GRP_DBH,DBH_COMMENT,Average and standard dev. based soley on plots for which the species existed. Total N was 61 plots but not all species were represented in all plots. Number of Other trees = 64. Other trees represented by 6 species. -US-UMB,18905,GRP_DBH,DBH_SPATIAL_REP_NUMBER,19 -US-UMB,18905,GRP_DBH,DBH_SPATIAL_VARIABILITY,5.2 -US-UMB,18883,GRP_DBH,DBH,11.49 -US-UMB,18883,GRP_DBH,DBH_SPP,Other -US-UMB,18883,GRP_DBH,DBH_HEIGHT,1.37 -US-UMB,18883,GRP_DBH,DBH_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 60 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm." -US-UMB,18883,GRP_DBH,DBH_DATE,19970714 -US-UMB,18883,GRP_DBH,DBH_DATE_UNC,28 -US-UMB,18883,GRP_DBH,DBH_COMMENT,Average and standard dev. based soley on plots for which the species existed. Total N was 61 plots but not all species were represented in all plots. Number of Other trees = 54. Other trees represented by 6 species. -US-UMB,18883,GRP_DBH,DBH_SPATIAL_REP_NUMBER,18 -US-UMB,18883,GRP_DBH,DBH_SPATIAL_VARIABILITY,5.07 -US-UMB,19118,GRP_DBH,DBH,12.67 -US-UMB,19118,GRP_DBH,DBH_SPP,Populus tremuloides -US-UMB,19118,GRP_DBH,DBH_HEIGHT,1.37 -US-UMB,19118,GRP_DBH,DBH_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 20 - 0.08 ha plots for trees with DBH >= 8 cm." -US-UMB,19118,GRP_DBH,DBH_DATE,20030714 -US-UMB,19118,GRP_DBH,DBH_DATE_UNC,28 -US-UMB,19118,GRP_DBH,DBH_COMMENT,Average and standard dev. based soley on plots for which the species existed. Total N was 20 plots but not all species were represented in all plots. The plots represented here are different from those from 1997 and 2001. Number of P. tremuloides trees = 29. 2 of the 3 plots only had a single P. tremuloides tree. -US-UMB,19118,GRP_DBH,DBH_SPATIAL_REP_NUMBER,3 -US-UMB,19118,GRP_DBH,DBH_SPATIAL_VARIABILITY,2.36 -US-UMB,19088,GRP_DBH,DBH,12.79 -US-UMB,19088,GRP_DBH,DBH_SPP,Fagus grandifolia -US-UMB,19088,GRP_DBH,DBH_HEIGHT,1.37 -US-UMB,19088,GRP_DBH,DBH_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 60 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm." -US-UMB,19088,GRP_DBH,DBH_DATE,20010714 -US-UMB,19088,GRP_DBH,DBH_DATE_UNC,28 -US-UMB,19088,GRP_DBH,DBH_COMMENT,Average and standard dev. based soley on plots for which the species existed. Total N was 61 plots but not all species were represented in all plots. Number of F. grandifolia trees = 255 -US-UMB,19088,GRP_DBH,DBH_SPATIAL_REP_NUMBER,29 -US-UMB,19088,GRP_DBH,DBH_SPATIAL_VARIABILITY,3.52 -US-UMB,18872,GRP_DBH,DBH,12.84 -US-UMB,18872,GRP_DBH,DBH_SPP,Fagus grandifolia -US-UMB,18872,GRP_DBH,DBH_HEIGHT,1.37 -US-UMB,18872,GRP_DBH,DBH_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 60 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm." -US-UMB,18872,GRP_DBH,DBH_DATE,19970714 -US-UMB,18872,GRP_DBH,DBH_DATE_UNC,28 -US-UMB,18872,GRP_DBH,DBH_COMMENT,Average and standard dev. based soley on plots for which the species existed. Total N was 61 plots but not all species were represented in all plots. Number of F. grandifolia trees = 234 -US-UMB,18872,GRP_DBH,DBH_SPATIAL_REP_NUMBER,25 -US-UMB,18872,GRP_DBH,DBH_SPATIAL_VARIABILITY,3.18 -US-UMB,19110,GRP_DBH,DBH,13.71 -US-UMB,19110,GRP_DBH,DBH_SPP,Pinus strobus -US-UMB,19110,GRP_DBH,DBH_HEIGHT,1.37 -US-UMB,19110,GRP_DBH,DBH_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 20 - 0.08 ha plots for trees with DBH >= 8 cm." -US-UMB,19110,GRP_DBH,DBH_DATE,20030714 -US-UMB,19110,GRP_DBH,DBH_DATE_UNC,28 -US-UMB,19110,GRP_DBH,DBH_COMMENT,Average and standard dev. based soley on plots for which the species existed. Total N was 20 plots but not all species were represented in all plots. The plots represented here are different from those from 1997 and 2001. Number of P. strobus trees = 51 -US-UMB,19110,GRP_DBH,DBH_SPATIAL_REP_NUMBER,10 -US-UMB,19110,GRP_DBH,DBH_SPATIAL_VARIABILITY,4.34 -US-UMB,19139,GRP_DBH,DBH,13.79 -US-UMB,19139,GRP_DBH,DBH_SPP,Other -US-UMB,19139,GRP_DBH,DBH_HEIGHT,1.37 -US-UMB,19139,GRP_DBH,DBH_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 76 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm." -US-UMB,19139,GRP_DBH,DBH_DATE,20100714 -US-UMB,19139,GRP_DBH,DBH_DATE_UNC,28 -US-UMB,19139,GRP_DBH,DBH_COMMENT,Average and standard dev. based soley on plots for which the species existed. Total N was 77 plots but not all species were represented in all plots. The plots represented here are a combination of plots measured in 2001 and 2003. Number of Other trees = 79. Other trees are represented by 11 species. -US-UMB,19139,GRP_DBH,DBH_SPATIAL_REP_NUMBER,28 -US-UMB,19139,GRP_DBH,DBH_SPATIAL_VARIABILITY,7.39 -US-UMB,18934,GRP_DBH,DBH,14.01 -US-UMB,18934,GRP_DBH,DBH_SPP,Fagus grandifolia -US-UMB,18934,GRP_DBH,DBH_HEIGHT,1.37 -US-UMB,18934,GRP_DBH,DBH_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 76 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm." -US-UMB,18934,GRP_DBH,DBH_DATE,20100714 -US-UMB,18934,GRP_DBH,DBH_DATE_UNC,28 -US-UMB,18934,GRP_DBH,DBH_COMMENT,Average and standard dev. based soley on plots for which the species existed. Total N was 77 plots but not all species were represented in all plots. The plots represented here are a combination of plots measured in 2001 and 2003. Number of F grandifolia trees = 343 -US-UMB,18934,GRP_DBH,DBH_SPATIAL_REP_NUMBER,40 -US-UMB,18934,GRP_DBH,DBH_SPATIAL_VARIABILITY,3.73 -US-UMB,18858,GRP_DBH,DBH,14.45 -US-UMB,18858,GRP_DBH,DBH_SPP,Acer saccharum -US-UMB,18858,GRP_DBH,DBH_HEIGHT,1.37 -US-UMB,18858,GRP_DBH,DBH_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 60 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm." -US-UMB,18858,GRP_DBH,DBH_DATE,19970714 -US-UMB,18858,GRP_DBH,DBH_DATE_UNC,28 -US-UMB,18858,GRP_DBH,DBH_COMMENT,Average and standard dev. based soley on plots for which the species existed. Total N was 61 plots but not all species were represented in all plots. Number of A saccharum trees = 82 -US-UMB,18858,GRP_DBH,DBH_SPATIAL_REP_NUMBER,12 -US-UMB,18858,GRP_DBH,DBH_SPATIAL_VARIABILITY,3.63 -US-UMB,19093,GRP_DBH,DBH,14.5 -US-UMB,19093,GRP_DBH,DBH_SPP,Pinus strobus -US-UMB,19093,GRP_DBH,DBH_HEIGHT,1.37 -US-UMB,19093,GRP_DBH,DBH_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 60 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm." -US-UMB,19093,GRP_DBH,DBH_DATE,20010714 -US-UMB,19093,GRP_DBH,DBH_DATE_UNC,28 -US-UMB,19093,GRP_DBH,DBH_COMMENT,Average and standard dev. based soley on plots for which the species existed. Total N was 61 plots but not all species were represented in all plots. Number of P strobus trees = 572 -US-UMB,19093,GRP_DBH,DBH_SPATIAL_REP_NUMBER,25 -US-UMB,19093,GRP_DBH,DBH_SPATIAL_VARIABILITY,8.22 -US-UMB,19057,GRP_DBH,DBH,14.51 -US-UMB,19057,GRP_DBH,DBH_SPP,Acer rubrum -US-UMB,19057,GRP_DBH,DBH_HEIGHT,1.37 -US-UMB,19057,GRP_DBH,DBH_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 60 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm." -US-UMB,19057,GRP_DBH,DBH_DATE,19970714 -US-UMB,19057,GRP_DBH,DBH_DATE_UNC,28 -US-UMB,19057,GRP_DBH,DBH_COMMENT,Average and standard dev. based soley on plots for which the species existed. Total N was 61 plots but not all species were represented in all plots. Number of A rubrum trees = 1189 -US-UMB,19057,GRP_DBH,DBH_SPATIAL_REP_NUMBER,59 -US-UMB,19057,GRP_DBH,DBH_SPATIAL_VARIABILITY,3.09 -US-UMB,19106,GRP_DBH,DBH,14.51 -US-UMB,19106,GRP_DBH,DBH_SPP,Fagus grandifolia -US-UMB,19106,GRP_DBH,DBH_HEIGHT,1.37 -US-UMB,19106,GRP_DBH,DBH_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 20 - 0.08 ha plots for trees with DBH >= 8 cm." -US-UMB,19106,GRP_DBH,DBH_DATE,20030714 -US-UMB,19106,GRP_DBH,DBH_DATE_UNC,28 -US-UMB,19106,GRP_DBH,DBH_COMMENT,Average and standard dev. based soley on plots for which the species existed. Total N was 20 plots but not all species were represented in all plots. The plots represented here are different from those from 1997 and 2001. Number of F. grandifolia trees = 57 -US-UMB,19106,GRP_DBH,DBH_SPATIAL_REP_NUMBER,9 -US-UMB,19106,GRP_DBH,DBH_SPATIAL_VARIABILITY,3.52 -US-UMB,18893,GRP_DBH,DBH,14.66 -US-UMB,18893,GRP_DBH,DBH_SPP,Acer saccharum -US-UMB,18893,GRP_DBH,DBH_HEIGHT,1.37 -US-UMB,18893,GRP_DBH,DBH_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 60 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm." -US-UMB,18893,GRP_DBH,DBH_DATE,20010714 -US-UMB,18893,GRP_DBH,DBH_DATE_UNC,28 -US-UMB,18893,GRP_DBH,DBH_COMMENT,Average and standard dev. based soley on plots for which the species existed. Total N was 61 plots but not all species were represented in all plots. Number of A saccharum trees = 88 -US-UMB,18893,GRP_DBH,DBH_SPATIAL_REP_NUMBER,12 -US-UMB,18893,GRP_DBH,DBH_SPATIAL_VARIABILITY,3.79 -US-UMB,18938,GRP_DBH,DBH,14.82 -US-UMB,18938,GRP_DBH,DBH_SPP,Pinus strobus -US-UMB,18938,GRP_DBH,DBH_HEIGHT,1.37 -US-UMB,18938,GRP_DBH,DBH_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 76 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm." -US-UMB,18938,GRP_DBH,DBH_DATE,20100714 -US-UMB,18938,GRP_DBH,DBH_DATE_UNC,28 -US-UMB,18938,GRP_DBH,DBH_COMMENT,Average and standard dev. based soley on plots for which the species existed. Total N was 77 plots but not all species were represented in all plots. The plots represented here are a combination of plots measured in 2001 and 2003. Number of P. strobus trees = 810. -US-UMB,18938,GRP_DBH,DBH_SPATIAL_REP_NUMBER,37 -US-UMB,18938,GRP_DBH,DBH_SPATIAL_VARIABILITY,5.61 -US-UMB,18913,GRP_DBH,DBH,14.9 -US-UMB,18913,GRP_DBH,DBH_SPP,Acer saccarum -US-UMB,18913,GRP_DBH,DBH_HEIGHT,1.37 -US-UMB,18913,GRP_DBH,DBH_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 20 - 0.08 ha plots for trees with DBH >= 8 cm." -US-UMB,18913,GRP_DBH,DBH_DATE,20030714 -US-UMB,18913,GRP_DBH,DBH_DATE_UNC,28 -US-UMB,18913,GRP_DBH,DBH_COMMENT,Average and standard dev. based soley on plots for which the species existed. Total N was 20 plots but not all species were represented in all plots. The plots represented here are different from those from 1997 and 2001. Number of A. saccharum trees = 114 -US-UMB,18913,GRP_DBH,DBH_SPATIAL_REP_NUMBER,7 -US-UMB,18913,GRP_DBH,DBH_SPATIAL_VARIABILITY,2.13 -US-UMB,19064,GRP_DBH,DBH,14.91 -US-UMB,19064,GRP_DBH,DBH_SPP,Pinus strobus -US-UMB,19064,GRP_DBH,DBH_HEIGHT,1.37 -US-UMB,19064,GRP_DBH,DBH_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 60 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm." -US-UMB,19064,GRP_DBH,DBH_DATE,19970714 -US-UMB,19064,GRP_DBH,DBH_DATE_UNC,28 -US-UMB,19064,GRP_DBH,DBH_COMMENT,Average and standard dev. based soley on plots for which the species existed. Total N was 61 plots but not all species were represented in all plots. Number of P strobus trees = 481 -US-UMB,19064,GRP_DBH,DBH_SPATIAL_REP_NUMBER,21 -US-UMB,19064,GRP_DBH,DBH_SPATIAL_VARIABILITY,8.05 -US-UMB,18909,GRP_DBH,DBH,14.99 -US-UMB,18909,GRP_DBH,DBH_SPP,Acer rubrum -US-UMB,18909,GRP_DBH,DBH_HEIGHT,1.37 -US-UMB,18909,GRP_DBH,DBH_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 20 - 0.08 ha plots for trees with DBH >= 8 cm." -US-UMB,18909,GRP_DBH,DBH_DATE,20030714 -US-UMB,18909,GRP_DBH,DBH_DATE_UNC,28 -US-UMB,18909,GRP_DBH,DBH_COMMENT,Average and standard dev. based soley on plots for which the species existed. Total N was 20 plots but not all species were represented in all plots. The plots represented here are different from those from 1997 and 2001. Number of A. rubrum trees = 327 -US-UMB,18909,GRP_DBH,DBH_SPATIAL_REP_NUMBER,20 -US-UMB,18909,GRP_DBH,DBH_SPATIAL_VARIABILITY,4.7 -US-UMB,18888,GRP_DBH,DBH,15.02 -US-UMB,18888,GRP_DBH,DBH_SPP,Acer rubrum -US-UMB,18888,GRP_DBH,DBH_HEIGHT,1.37 -US-UMB,18888,GRP_DBH,DBH_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 60 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm." -US-UMB,18888,GRP_DBH,DBH_DATE,20010714 -US-UMB,18888,GRP_DBH,DBH_DATE_UNC,28 -US-UMB,18888,GRP_DBH,DBH_COMMENT,Average and standard dev. based soley on plots for which the species existed. Total N was 61 plots but not all species were represented in all plots. Number of A rubrum trees = 1234 -US-UMB,18888,GRP_DBH,DBH_SPATIAL_REP_NUMBER,59 -US-UMB,18888,GRP_DBH,DBH_SPATIAL_VARIABILITY,3.14 -US-UMB,18922,GRP_DBH,DBH,15.59 -US-UMB,18922,GRP_DBH,DBH_SPP,Acer rubrum -US-UMB,18922,GRP_DBH,DBH_HEIGHT,1.37 -US-UMB,18922,GRP_DBH,DBH_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 76 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm." -US-UMB,18922,GRP_DBH,DBH_DATE,20100714 -US-UMB,18922,GRP_DBH,DBH_DATE_UNC,28 -US-UMB,18922,GRP_DBH,DBH_COMMENT,Average and standard dev. based soley on plots for which the species existed. Total N was 77 plots but not all species were represented in all plots. The plots represented here are a combination of plots measured in 2001 and 2003. Number of A rubrum trees = 1588 -US-UMB,18922,GRP_DBH,DBH_SPATIAL_REP_NUMBER,77 -US-UMB,18922,GRP_DBH,DBH_SPATIAL_VARIABILITY,3.94 -US-UMB,19126,GRP_DBH,DBH,15.6 -US-UMB,19126,GRP_DBH,DBH_SPP,Other -US-UMB,19126,GRP_DBH,DBH_HEIGHT,1.37 -US-UMB,19126,GRP_DBH,DBH_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 20 - 0.08 ha plots for trees with DBH >= 8 cm." -US-UMB,19126,GRP_DBH,DBH_DATE,20030714 -US-UMB,19126,GRP_DBH,DBH_DATE_UNC,28 -US-UMB,19126,GRP_DBH,DBH_COMMENT,Average and standard dev. based soley on plots for which the species existed. Total N was 20 plots but not all species were represented in all plots. The plots represented here are different from those from 1997 and 2001. Number of Other trees = 22. Other trees represented by 8 species. -US-UMB,19126,GRP_DBH,DBH_SPATIAL_REP_NUMBER,10 -US-UMB,19126,GRP_DBH,DBH_SPATIAL_VARIABILITY,8.99 -US-UMB,18926,GRP_DBH,DBH,15.78 -US-UMB,18926,GRP_DBH,DBH_SPP,Acer saccarum -US-UMB,18926,GRP_DBH,DBH_HEIGHT,1.37 -US-UMB,18926,GRP_DBH,DBH_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 76 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm." -US-UMB,18926,GRP_DBH,DBH_DATE,20100714 -US-UMB,18926,GRP_DBH,DBH_DATE_UNC,28 -US-UMB,18926,GRP_DBH,DBH_COMMENT,Average and standard dev. based soley on plots for which the species existed. Total N was 77 plots but not all species were represented in all plots. The plots represented here are a combination of plots measured in 2001 and 2003. Number of A saccharum trees = 174 -US-UMB,18926,GRP_DBH,DBH_SPATIAL_REP_NUMBER,18 -US-UMB,18926,GRP_DBH,DBH_SPATIAL_VARIABILITY,3.45 -US-UMB,18917,GRP_DBH,DBH,16.67 -US-UMB,18917,GRP_DBH,DBH_SPP,Betula papyrifera -US-UMB,18917,GRP_DBH,DBH_HEIGHT,1.37 -US-UMB,18917,GRP_DBH,DBH_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 20 - 0.08 ha plots for trees with DBH >= 8 cm." -US-UMB,18917,GRP_DBH,DBH_DATE,20030714 -US-UMB,18917,GRP_DBH,DBH_DATE_UNC,28 -US-UMB,18917,GRP_DBH,DBH_COMMENT,Average and standard dev. based soley on plots for which the species existed. Total N was 20 plots but not all species were represented in all plots. The plots represented here are different from those from 1997 and 2001. Number of B. papyrifera trees = 68 -US-UMB,18917,GRP_DBH,DBH_SPATIAL_REP_NUMBER,12 -US-UMB,18917,GRP_DBH,DBH_SPATIAL_VARIABILITY,4.52 -US-UMB,18930,GRP_DBH,DBH,19.35 -US-UMB,18930,GRP_DBH,DBH_SPP,Betula papyrifera -US-UMB,18930,GRP_DBH,DBH_HEIGHT,1.37 -US-UMB,18930,GRP_DBH,DBH_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 76 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm." -US-UMB,18930,GRP_DBH,DBH_DATE,20100714 -US-UMB,18930,GRP_DBH,DBH_DATE_UNC,28 -US-UMB,18930,GRP_DBH,DBH_COMMENT,Average and standard dev. based soley on plots for which the species existed. Total N was 77 plots but not all species were represented in all plots. The plots represented here are a combination of plots measured in 2001 and 2003. Number of B papyrifera trees = 371 -US-UMB,18930,GRP_DBH,DBH_SPATIAL_REP_NUMBER,53 -US-UMB,18930,GRP_DBH,DBH_SPATIAL_VARIABILITY,5.74 -US-UMB,18865,GRP_DBH,DBH,19.51 -US-UMB,18865,GRP_DBH,DBH_SPP,Betula papyrifera -US-UMB,18865,GRP_DBH,DBH_HEIGHT,1.37 -US-UMB,18865,GRP_DBH,DBH_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 60 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm." -US-UMB,18865,GRP_DBH,DBH_DATE,19970714 -US-UMB,18865,GRP_DBH,DBH_DATE_UNC,28 -US-UMB,18865,GRP_DBH,DBH_COMMENT,Average and standard dev. based soley on plots for which the species existed. Total N was 61 plots but not all species were represented in all plots. Number of B. papyrifera trees = 441 -US-UMB,18865,GRP_DBH,DBH_SPATIAL_REP_NUMBER,44 -US-UMB,18865,GRP_DBH,DBH_SPATIAL_VARIABILITY,5.19 -US-UMB,19083,GRP_DBH,DBH,19.91 -US-UMB,19083,GRP_DBH,DBH_SPP,Betula papyrifera -US-UMB,19083,GRP_DBH,DBH_HEIGHT,1.37 -US-UMB,19083,GRP_DBH,DBH_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 60 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm." -US-UMB,19083,GRP_DBH,DBH_DATE,20010714 -US-UMB,19083,GRP_DBH,DBH_DATE_UNC,28 -US-UMB,19083,GRP_DBH,DBH_COMMENT,Average and standard dev. based soley on plots for which the species existed. Total N was 61 plots but not all species were represented in all plots. Number of B. papyrifera trees = 425 -US-UMB,19083,GRP_DBH,DBH_SPATIAL_REP_NUMBER,45 -US-UMB,19083,GRP_DBH,DBH_SPATIAL_VARIABILITY,5.62 -US-UMB,18900,GRP_DBH,DBH,20.28 -US-UMB,18900,GRP_DBH,DBH_SPP,Quercus rubra -US-UMB,18900,GRP_DBH,DBH_HEIGHT,1.37 -US-UMB,18900,GRP_DBH,DBH_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 60 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm." -US-UMB,18900,GRP_DBH,DBH_DATE,20010714 -US-UMB,18900,GRP_DBH,DBH_DATE_UNC,28 -US-UMB,18900,GRP_DBH,DBH_COMMENT,Average and standard dev. based soley on plots for which the species existed. Total N was 61 plots but not all species were represented in all plots. Number of Q. rubra trees = 305 -US-UMB,18900,GRP_DBH,DBH_SPATIAL_REP_NUMBER,49 -US-UMB,18900,GRP_DBH,DBH_SPATIAL_VARIABILITY,10.1 -US-UMB,19135,GRP_DBH,DBH,20.65 -US-UMB,19135,GRP_DBH,DBH_SPP,Quercus rubra -US-UMB,19135,GRP_DBH,DBH_HEIGHT,1.37 -US-UMB,19135,GRP_DBH,DBH_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 76 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm." -US-UMB,19135,GRP_DBH,DBH_DATE,20100714 -US-UMB,19135,GRP_DBH,DBH_DATE_UNC,28 -US-UMB,19135,GRP_DBH,DBH_COMMENT,Average and standard dev. based soley on plots for which the species existed. Total N was 77 plots but not all species were represented in all plots. The plots represented here are a combination of plots measured in 2001 and 2003. Number of Q. rubra trees = 484 -US-UMB,19135,GRP_DBH,DBH_SPATIAL_REP_NUMBER,64 -US-UMB,19135,GRP_DBH,DBH_SPATIAL_VARIABILITY,9.8 -US-UMB,19078,GRP_DBH,DBH,20.78 -US-UMB,19078,GRP_DBH,DBH_SPP,Populus tremuloides -US-UMB,19078,GRP_DBH,DBH_HEIGHT,1.37 -US-UMB,19078,GRP_DBH,DBH_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 60 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm." -US-UMB,19078,GRP_DBH,DBH_DATE,19970714 -US-UMB,19078,GRP_DBH,DBH_DATE_UNC,28 -US-UMB,19078,GRP_DBH,DBH_COMMENT,Average and standard dev. based soley on plots for which the species existed. Total N was 61 plots but not all species were represented in all plots. Number of P. tremuloides trees = 458 -US-UMB,19078,GRP_DBH,DBH_SPATIAL_REP_NUMBER,38 -US-UMB,19078,GRP_DBH,DBH_SPATIAL_VARIABILITY,7.06 -US-UMB,18877,GRP_DBH,DBH,21.36 -US-UMB,18877,GRP_DBH,DBH_SPP,Quercus rubra -US-UMB,18877,GRP_DBH,DBH_HEIGHT,1.37 -US-UMB,18877,GRP_DBH,DBH_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 60 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm." -US-UMB,18877,GRP_DBH,DBH_DATE,19970714 -US-UMB,18877,GRP_DBH,DBH_DATE_UNC,28 -US-UMB,18877,GRP_DBH,DBH_COMMENT,Average and standard dev. based soley on plots for which the species existed. Total N was 61 plots but not all species were represented in all plots. Number of Q. rubra trees = 273 -US-UMB,18877,GRP_DBH,DBH_SPATIAL_REP_NUMBER,41 -US-UMB,18877,GRP_DBH,DBH_SPATIAL_VARIABILITY,9.23 -US-UMB,19103,GRP_DBH,DBH,22.26 -US-UMB,19103,GRP_DBH,DBH_SPP,Populus tremuloides -US-UMB,19103,GRP_DBH,DBH_HEIGHT,1.37 -US-UMB,19103,GRP_DBH,DBH_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 60 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm." -US-UMB,19103,GRP_DBH,DBH_DATE,20010714 -US-UMB,19103,GRP_DBH,DBH_DATE_UNC,28 -US-UMB,19103,GRP_DBH,DBH_COMMENT,Average and standard dev. based soley on plots for which the species existed. Total N was 61 plots but not all species were represented in all plots. Number of P. tremuloides trees = 425 -US-UMB,19103,GRP_DBH,DBH_SPATIAL_REP_NUMBER,36 -US-UMB,19103,GRP_DBH,DBH_SPATIAL_VARIABILITY,7.21 -US-UMB,19131,GRP_DBH,DBH,24.56 -US-UMB,19131,GRP_DBH,DBH_SPP,Populus tremuloides -US-UMB,19131,GRP_DBH,DBH_HEIGHT,1.37 -US-UMB,19131,GRP_DBH,DBH_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 76 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm." -US-UMB,19131,GRP_DBH,DBH_DATE,20100714 -US-UMB,19131,GRP_DBH,DBH_DATE_UNC,28 -US-UMB,19131,GRP_DBH,DBH_COMMENT,Average and standard dev. based soley on plots for which the species existed. Total N was 77 plots but not all species were represented in all plots. The plots represented here are a combination of plots measured in 2001 and 2003. Number of P. tremuloides trees = 336 -US-UMB,19131,GRP_DBH,DBH_SPATIAL_REP_NUMBER,33 -US-UMB,19131,GRP_DBH,DBH_SPATIAL_VARIABILITY,8.27 -US-UMB,19114,GRP_DBH,DBH,24.57 -US-UMB,19114,GRP_DBH,DBH_SPP,Populus grandidentata -US-UMB,19114,GRP_DBH,DBH_HEIGHT,1.37 -US-UMB,19114,GRP_DBH,DBH_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 20 - 0.08 ha plots for trees with DBH >= 8 cm." -US-UMB,19114,GRP_DBH,DBH_DATE,20030714 -US-UMB,19114,GRP_DBH,DBH_DATE_UNC,28 -US-UMB,19114,GRP_DBH,DBH_COMMENT,Average and standard dev. based soley on plots for which the species existed. Total N was 20 plots but not all species were represented in all plots. The plots represented here are different from those from 1997 and 2001. Number of P. grandidentata trees = 394 -US-UMB,19114,GRP_DBH,DBH_SPATIAL_REP_NUMBER,19 -US-UMB,19114,GRP_DBH,DBH_SPATIAL_VARIABILITY,8.12 -US-UMB,19071,GRP_DBH,DBH,24.84 -US-UMB,19071,GRP_DBH,DBH_SPP,Populus grandidentata -US-UMB,19071,GRP_DBH,DBH_HEIGHT,1.37 -US-UMB,19071,GRP_DBH,DBH_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 60 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm." -US-UMB,19071,GRP_DBH,DBH_DATE,19970714 -US-UMB,19071,GRP_DBH,DBH_DATE_UNC,28 -US-UMB,19071,GRP_DBH,DBH_COMMENT,Average and standard dev. based soley on plots for which the species existed. Total N was 61 plots but not all species were represented in all plots. Number of P grandidentata trees = 1187 -US-UMB,19071,GRP_DBH,DBH_SPATIAL_REP_NUMBER,52 -US-UMB,19071,GRP_DBH,DBH_SPATIAL_VARIABILITY,7.84 -US-UMB,19098,GRP_DBH,DBH,26.53 -US-UMB,19098,GRP_DBH,DBH_SPP,Populus grandidentata -US-UMB,19098,GRP_DBH,DBH_HEIGHT,1.37 -US-UMB,19098,GRP_DBH,DBH_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 60 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm." -US-UMB,19098,GRP_DBH,DBH_DATE,20010714 -US-UMB,19098,GRP_DBH,DBH_DATE_UNC,28 -US-UMB,19098,GRP_DBH,DBH_COMMENT,Average and standard dev. based soley on plots for which the species existed. Total N was 61 plots but not all species were represented in all plots. Number of P grandidentata trees = 1129 -US-UMB,19098,GRP_DBH,DBH_SPATIAL_REP_NUMBER,52 -US-UMB,19098,GRP_DBH,DBH_SPATIAL_VARIABILITY,8.01 -US-UMB,19122,GRP_DBH,DBH,26.88 -US-UMB,19122,GRP_DBH,DBH_SPP,Quercus rubra -US-UMB,19122,GRP_DBH,DBH_HEIGHT,1.37 -US-UMB,19122,GRP_DBH,DBH_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 20 - 0.08 ha plots for trees with DBH >= 8 cm." -US-UMB,19122,GRP_DBH,DBH_DATE,20030714 -US-UMB,19122,GRP_DBH,DBH_DATE_UNC,28 -US-UMB,19122,GRP_DBH,DBH_COMMENT,Average and standard dev. based soley on plots for which the species existed. Total N was 20 plots but not all species were represented in all plots. The plots represented here are different from those from 1997 and 2001. Number of Q. rubra trees = 130 -US-UMB,19122,GRP_DBH,DBH_SPATIAL_REP_NUMBER,13 -US-UMB,19122,GRP_DBH,DBH_SPATIAL_VARIABILITY,8.25 -US-UMB,18942,GRP_DBH,DBH,28.22 -US-UMB,18942,GRP_DBH,DBH_SPP,Populus grandidentata -US-UMB,18942,GRP_DBH,DBH_HEIGHT,1.37 -US-UMB,18942,GRP_DBH,DBH_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 76 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm." -US-UMB,18942,GRP_DBH,DBH_DATE,20100714 -US-UMB,18942,GRP_DBH,DBH_DATE_UNC,28 -US-UMB,18942,GRP_DBH,DBH_COMMENT,Average and standard dev. based soley on plots for which the species existed. Total N was 77 plots but not all species were represented in all plots. The plots represented here are a combination of plots measured in 2001 and 2003. Number of P. grandidentata trees = 1299 -US-UMB,18942,GRP_DBH,DBH_SPATIAL_REP_NUMBER,69 -US-UMB,18942,GRP_DBH,DBH_SPATIAL_VARIABILITY,9.48 -US-UMB,8619,GRP_DM_FIRE,DM_FIRE,Nature induced burn -US-UMB,8619,GRP_DM_FIRE,DM_DATE,18800107 -US-UMB,8619,GRP_DM_FIRE,DM_COMMENT,medium; Patchy fires occurred yearly from 1880 - 1920 that essentially burned the entire region. Fires were from low - high intensity. -US-UMB,86663,GRP_DM_FIRE,DM_FIRE,Other -US-UMB,86663,GRP_DM_FIRE,DM_SURF,100 -US-UMB,86663,GRP_DM_FIRE,DM_DATE_START,19010701 -US-UMB,86663,GRP_DM_FIRE,DM_DATE_END,19230701 -US-UMB,86663,GRP_DM_FIRE,DM_DATE_UNC,60 -US-UMB,86663,GRP_DM_FIRE,DM_COMMENT,The first recorded fire was the summer of 1901 with unknown causes. Many fires were either human intentionally or unintentionally set as well as possible natural fires. The areas burned varied in in size and intensity depending on conditions and the amount of slash left behind from earlier logging. All of the flux footprint was burned at least once and some if not all of the footprint likely burned several times. The last intense fire was recorded in 1923. -US-UMB,86664,GRP_DM_FORESTRY,DM_FORESTRY,Clearcutting -US-UMB,86664,GRP_DM_FORESTRY,DM_SURF,100 -US-UMB,86664,GRP_DM_FORESTRY,DM_DATE_START,18791201 -US-UMB,86664,GRP_DM_FORESTRY,DM_DATE_END,19000101 -US-UMB,86664,GRP_DM_FORESTRY,DM_DATE_UNC,365 -US-UMB,86664,GRP_DM_FORESTRY,DM_COMMENT,Heavy logging of pine began in in winter of 1879 and completed in 1880. The flux footprint was mainly pine woodlands at the time of logging. Other tree species were progressively logged off through 1900 essentially creating a clearcut area. -US-UMB,8618,GRP_DM_FORESTRY,DM_FORESTRY,Clearcutting -US-UMB,8618,GRP_DM_FORESTRY,DM_DATE,1880 -US-UMB,8618,GRP_DM_FORESTRY,DM_COMMENT,The area was first logged for white pine the winter of 1879-1980. Other species logged in succesive years -US-UMB,86667,GRP_DM_INS_PATH,DM_INS_PATH,Insect -US-UMB,86667,GRP_DM_INS_PATH,DM_DATE_START,20010515 -US-UMB,86667,GRP_DM_INS_PATH,DM_DATE_END,20010621 -US-UMB,86667,GRP_DM_INS_PATH,DM_DATE_UNC,10 -US-UMB,86667,GRP_DM_INS_PATH,DM_COMMENT,"Locally patchy, moderate out-break of forest tent caterpillar (Malacosoma disstrium) removed .21 LAI units from mostly Quercus rubra trees within a 60m radius of the flux tower" -US-UMB,86665,GRP_DM_INS_PATH,DM_INS_PATH,Pathogen -US-UMB,86665,GRP_DM_INS_PATH,DM_DATE_START,20081010 -US-UMB,86665,GRP_DM_INS_PATH,DM_COMMENT,Beech bark disease first noticed in the fall of 2008 caused by infestation of Fagus grandifolia by the scale insect Cryptococcus fagisuga which leads to the introduction of pathogenic fungi Neonectria faginata and Neonectria ditissima. Some trees within the footprint were dead by 2016. This is an ongoing disease within the US-UMB footprint. -US-UMB,86666,GRP_DM_INS_PATH,DM_INS_PATH,Insect -US-UMB,86666,GRP_DM_INS_PATH,DM_DATE_START,20100515 -US-UMB,86666,GRP_DM_INS_PATH,DM_DATE_END,20100701 -US-UMB,86666,GRP_DM_INS_PATH,DM_DATE_UNC,10 -US-UMB,86666,GRP_DM_INS_PATH,DM_COMMENT,"Locally patchy, moderate out-break of forest tent caterpillar (Malacosoma disstrium). No attempt to quantify leaf area removed by herbivory." -US-UMB,15728,GRP_DOI,DOI,10.17190/AMF/1246107 -US-UMB,15728,GRP_DOI,DOI_CITATION,"Christopher Gough, Gil Bohrer, Peter Curtis (2022), AmeriFlux BASE US-UMB Univ. of Mich. Biological Station, Ver. 18-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1246107" -US-UMB,15728,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-UMB,32216,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-UMB,32216,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Christopher Gough -US-UMB,32216,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-UMB,32216,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,cmgough@vcu.edu -US-UMB,32216,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Virginia Commonwealth University -US-UMB,32215,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-UMB,32215,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Gil Bohrer -US-UMB,32215,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-UMB,32215,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,bohrer.17@osu.edu -US-UMB,32215,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Ohio State University -US-UMB,32217,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-UMB,32217,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Peter Curtis -US-UMB,32217,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-UMB,32217,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,curtis.7@osu.edu -US-UMB,32217,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Ohio State University -US-UMB,32219,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Ohio State University -US-UMB,32219,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-UMB,32220,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Virginia Commonwealth University -US-UMB,32220,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-UMB,32218,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,DOE/NICCR/NOAA/NSF/Ameriflux -US-UMB,32218,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-UMB,12345,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Fire -US-UMB,12329,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Forestry -US-UMB,91301,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-UMB,91301,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-UMB,91301,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,199906 -US-UMB,91301,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-UMB,91449,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-UMB,91449,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-UMB,91449,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,199906 -US-UMB,91449,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-UMB,91382,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-UMB,91382,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-UMB,91382,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,199906 -US-UMB,91382,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-UMB,23000439,GRP_HEADER,SITE_NAME,Univ. of Mich. Biological Station -US-UMB,88196,GRP_HEIGHTC,HEIGHTC,23 -US-UMB,88196,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-UMB,88196,GRP_HEIGHTC,HEIGHTC_DATE,20150101 -US-UMB,88196,GRP_HEIGHTC,HEIGHTC_COMMENT,Canopy ht estimated from flux tower. No replicates. -US-UMB,12331,GRP_IGBP,IGBP,DBF -US-UMB,92046,GRP_INST,INST_MODEL,RAD-Other -US-UMB,92046,GRP_INST,INST_SN,BF2-1 -US-UMB,92046,GRP_INST,INST_DATE,20030716 -US-UMB,92046,GRP_INST,INST_COMMENT,Bf2 Sunshine Sensor Diffuse/total PAR -US-UMB,92046,GRP_INST,INST_SAMPLING_INT,10 -US-UMB,92046,GRP_INST,INST_AVERAGING_INT,600 -US-UMB,92046,GRP_INST,INST_HEAT,Unheated -US-UMB,92046,GRP_INST,INST_SHIELDING,None -US-UMB,92046,GRP_INST,INST_ASPIRATION,None -US-UMB,92032,GRP_INST,INST_MODEL,RAD-Other -US-UMB,92032,GRP_INST,INST_SN,BF5-1 -US-UMB,92032,GRP_INST,INST_DATE,20120824 -US-UMB,92032,GRP_INST,INST_COMMENT,BF5 Sunshine Sensor Diffuse/total PAR -US-UMB,92032,GRP_INST,INST_SAMPLING_INT,10 -US-UMB,92032,GRP_INST,INST_AVERAGING_INT,600 -US-UMB,92032,GRP_INST,INST_HEAT,Unheated -US-UMB,92032,GRP_INST,INST_SHIELDING,None -US-UMB,92032,GRP_INST,INST_ASPIRATION,None -US-UMB,92057,GRP_INST,INST_MODEL,RAD-Pyrrad-SW+LW -US-UMB,92057,GRP_INST,INST_SN,CNR1-030712 -US-UMB,92057,GRP_INST,INST_DATE,20120509 -US-UMB,92057,GRP_INST,INST_COMMENT,Kipp and Zonen CNR1 -US-UMB,92057,GRP_INST,INST_SAMPLING_INT,10 -US-UMB,92057,GRP_INST,INST_AVERAGING_INT,600 -US-UMB,92057,GRP_INST,INST_HEAT,Unheated -US-UMB,92057,GRP_INST,INST_SHIELDING,None -US-UMB,92057,GRP_INST,INST_ASPIRATION,None -US-UMB,92071,GRP_INST,INST_MODEL,RAD-Pyrrad-SW+LW -US-UMB,92071,GRP_INST,INST_SN,CNR1-030712 -US-UMB,92071,GRP_INST,INST_DATE,20090424 -US-UMB,92071,GRP_INST,INST_COMMENT,Kipp and Zonen CNR1 -US-UMB,92071,GRP_INST,INST_SAMPLING_INT,10 -US-UMB,92071,GRP_INST,INST_AVERAGING_INT,600 -US-UMB,92071,GRP_INST,INST_HEAT,Unheated -US-UMB,92071,GRP_INST,INST_SHIELDING,None -US-UMB,92071,GRP_INST,INST_ASPIRATION,None -US-UMB,92084,GRP_INST,INST_MODEL,RAD-Pyrrad-SW+LW -US-UMB,92084,GRP_INST,INST_SN,CNR1-030712 -US-UMB,92084,GRP_INST,INST_DATE,20190524 -US-UMB,92084,GRP_INST,INST_COMMENT,Kipp and Zonen CNR1 -US-UMB,92084,GRP_INST,INST_SAMPLING_INT,10 -US-UMB,92084,GRP_INST,INST_AVERAGING_INT,600 -US-UMB,92084,GRP_INST,INST_HEAT,Unheated -US-UMB,92084,GRP_INST,INST_SHIELDING,None -US-UMB,92084,GRP_INST,INST_ASPIRATION,None -US-UMB,92128,GRP_INST,INST_MODEL,RAD-Pyrrad-SW+LW -US-UMB,92128,GRP_INST,INST_SN,CNR1-030712 -US-UMB,92128,GRP_INST,INST_DATE,20050418 -US-UMB,92128,GRP_INST,INST_COMMENT,Kipp and Zonen CNR1 -US-UMB,92128,GRP_INST,INST_SAMPLING_INT,10 -US-UMB,92128,GRP_INST,INST_AVERAGING_INT,600 -US-UMB,92128,GRP_INST,INST_HEAT,Unheated -US-UMB,92128,GRP_INST,INST_SHIELDING,None -US-UMB,92128,GRP_INST,INST_ASPIRATION,None -US-UMB,92144,GRP_INST,INST_MODEL,RAD-Pyrrad-SW+LW -US-UMB,92144,GRP_INST,INST_SN,CNR1-030712 -US-UMB,92144,GRP_INST,INST_DATE,20150521 -US-UMB,92144,GRP_INST,INST_COMMENT,Kipp and Zonen CNR1 -US-UMB,92144,GRP_INST,INST_SAMPLING_INT,10 -US-UMB,92144,GRP_INST,INST_AVERAGING_INT,600 -US-UMB,92144,GRP_INST,INST_HEAT,Unheated -US-UMB,92144,GRP_INST,INST_SHIELDING,None -US-UMB,92144,GRP_INST,INST_ASPIRATION,None -US-UMB,92125,GRP_INST,INST_MODEL,RAD-Pyrrad-SW+LW -US-UMB,92125,GRP_INST,INST_SN,CNR1-990210 -US-UMB,92125,GRP_INST,INST_DATE,20190419 -US-UMB,92125,GRP_INST,INST_COMMENT,Kipp and Zonen CNR1 -US-UMB,92125,GRP_INST,INST_SAMPLING_INT,10 -US-UMB,92125,GRP_INST,INST_AVERAGING_INT,600 -US-UMB,92125,GRP_INST,INST_HEAT,Unheated -US-UMB,92125,GRP_INST,INST_SHIELDING,None -US-UMB,92125,GRP_INST,INST_ASPIRATION,None -US-UMB,92126,GRP_INST,INST_MODEL,SA-Campbell CSAT-3 -US-UMB,92126,GRP_INST,INST_SN,CSAT3 (0149) -US-UMB,92126,GRP_INST,INST_DATE,20010908 -US-UMB,92126,GRP_INST,INST_COMMENT,Sonic Anemometer - Campbell CSAT-3 -US-UMB,92126,GRP_INST,INST_FIRMWARE,Instrument firmware version at installation -US-UMB,92126,GRP_INST,INST_SAMPLING_INT,0.1 -US-UMB,92126,GRP_INST,INST_AVERAGING_INT,0 -US-UMB,92126,GRP_INST,INST_HEAT,Unheated -US-UMB,92126,GRP_INST,INST_SHIELDING,None -US-UMB,92126,GRP_INST,INST_ASPIRATION,None -US-UMB,92126,GRP_INST,INST_SA_OFFSET_NORTH,300 -US-UMB,92126,GRP_INST,INST_SA_WIND_FORMAT,"U, V, W" -US-UMB,92129,GRP_INST,INST_MODEL,SA-Campbell CSAT-3 -US-UMB,92129,GRP_INST,INST_SN,CSAT3 (0244) -US-UMB,92129,GRP_INST,INST_DATE,20030507 -US-UMB,92129,GRP_INST,INST_COMMENT,Sonic Anemometer - Campbell CSAT-3 -US-UMB,92129,GRP_INST,INST_FIRMWARE,Instrument firmware version at installation -US-UMB,92129,GRP_INST,INST_SAMPLING_INT,0.1 -US-UMB,92129,GRP_INST,INST_AVERAGING_INT,0 -US-UMB,92129,GRP_INST,INST_HEAT,Unheated -US-UMB,92129,GRP_INST,INST_SHIELDING,None -US-UMB,92129,GRP_INST,INST_ASPIRATION,None -US-UMB,92129,GRP_INST,INST_SA_OFFSET_NORTH,300 -US-UMB,92129,GRP_INST,INST_SA_WIND_FORMAT,"U, V, W" -US-UMB,92139,GRP_INST,INST_MODEL,SA-Campbell CSAT-3 -US-UMB,92139,GRP_INST,INST_SN,CSAT3 (0244) -US-UMB,92139,GRP_INST,INST_DATE,19990101 -US-UMB,92139,GRP_INST,INST_COMMENT,Sonic Anemometer - Campbell CSAT-3 -US-UMB,92139,GRP_INST,INST_FIRMWARE,Instrument firmware version at installation -US-UMB,92139,GRP_INST,INST_SAMPLING_INT,0.1 -US-UMB,92139,GRP_INST,INST_AVERAGING_INT,0 -US-UMB,92139,GRP_INST,INST_HEAT,Unheated -US-UMB,92139,GRP_INST,INST_SHIELDING,None -US-UMB,92139,GRP_INST,INST_ASPIRATION,None -US-UMB,92139,GRP_INST,INST_SA_OFFSET_NORTH,300 -US-UMB,92139,GRP_INST,INST_SA_WIND_FORMAT,"U, V, W" -US-UMB,92053,GRP_INST,INST_MODEL,SA-Campbell CSAT-3 -US-UMB,92053,GRP_INST,INST_SN,CSAT3 (0249) -US-UMB,92053,GRP_INST,INST_DATE,19990101 -US-UMB,92053,GRP_INST,INST_COMMENT,Sonic Anemometer - Campbell CSAT-3 -US-UMB,92053,GRP_INST,INST_FIRMWARE,Instrument firmware version at installation -US-UMB,92053,GRP_INST,INST_SAMPLING_INT,0.1 -US-UMB,92053,GRP_INST,INST_AVERAGING_INT,0 -US-UMB,92053,GRP_INST,INST_HEAT,Unheated -US-UMB,92053,GRP_INST,INST_SHIELDING,None -US-UMB,92053,GRP_INST,INST_ASPIRATION,None -US-UMB,92053,GRP_INST,INST_SA_OFFSET_NORTH,300 -US-UMB,92053,GRP_INST,INST_SA_WIND_FORMAT,"U, V, W" -US-UMB,92062,GRP_INST,INST_MODEL,SA-Campbell CSAT-3 -US-UMB,92062,GRP_INST,INST_SN,CSAT3 (0249) -US-UMB,92062,GRP_INST,INST_DATE,20030507 -US-UMB,92062,GRP_INST,INST_COMMENT,Sonic Anemometer - Campbell CSAT-3 -US-UMB,92062,GRP_INST,INST_FIRMWARE,Instrument firmware version at installation -US-UMB,92062,GRP_INST,INST_SAMPLING_INT,0.1 -US-UMB,92062,GRP_INST,INST_AVERAGING_INT,0 -US-UMB,92062,GRP_INST,INST_HEAT,Unheated -US-UMB,92062,GRP_INST,INST_SHIELDING,None -US-UMB,92062,GRP_INST,INST_ASPIRATION,None -US-UMB,92062,GRP_INST,INST_SA_OFFSET_NORTH,300 -US-UMB,92062,GRP_INST,INST_SA_WIND_FORMAT,"U, V, W" -US-UMB,92098,GRP_INST,INST_MODEL,SA-Campbell CSAT-3 -US-UMB,92098,GRP_INST,INST_SN,CSAT3 (0249) -US-UMB,92098,GRP_INST,INST_DATE,20000622 -US-UMB,92098,GRP_INST,INST_COMMENT,Sonic Anemometer - Campbell CSAT-3 -US-UMB,92098,GRP_INST,INST_FIRMWARE,Instrument firmware version at installation -US-UMB,92098,GRP_INST,INST_SAMPLING_INT,0.1 -US-UMB,92098,GRP_INST,INST_AVERAGING_INT,0 -US-UMB,92098,GRP_INST,INST_HEAT,Unheated -US-UMB,92098,GRP_INST,INST_SHIELDING,None -US-UMB,92098,GRP_INST,INST_ASPIRATION,None -US-UMB,92098,GRP_INST,INST_SA_OFFSET_NORTH,240 -US-UMB,92098,GRP_INST,INST_SA_WIND_FORMAT,"U, V, W" -US-UMB,92105,GRP_INST,INST_MODEL,SA-Campbell CSAT-3 -US-UMB,92105,GRP_INST,INST_SN,CSAT3 (0249) -US-UMB,92105,GRP_INST,INST_DATE,20010509 -US-UMB,92105,GRP_INST,INST_COMMENT,Sonic Anemometer - Campbell CSAT-3 -US-UMB,92105,GRP_INST,INST_FIRMWARE,Instrument firmware version at installation -US-UMB,92105,GRP_INST,INST_SAMPLING_INT,0.1 -US-UMB,92105,GRP_INST,INST_AVERAGING_INT,0 -US-UMB,92105,GRP_INST,INST_HEAT,Unheated -US-UMB,92105,GRP_INST,INST_SHIELDING,None -US-UMB,92105,GRP_INST,INST_ASPIRATION,None -US-UMB,92105,GRP_INST,INST_SA_OFFSET_NORTH,300 -US-UMB,92105,GRP_INST,INST_SA_WIND_FORMAT,"U, V, W" -US-UMB,92137,GRP_INST,INST_MODEL,SA-Campbell CSAT-3 -US-UMB,92137,GRP_INST,INST_SN,CSAT3 1092 -US-UMB,92137,GRP_INST,INST_DATE,20060418 -US-UMB,92137,GRP_INST,INST_COMMENT,Sonic Anemometer - Campbell CSAT-3 CSAT3-0249 replaced w/ CSAT3 1092 -US-UMB,92137,GRP_INST,INST_FIRMWARE,Instrument firmware version at installation -US-UMB,92137,GRP_INST,INST_SAMPLING_INT,0.1 -US-UMB,92137,GRP_INST,INST_AVERAGING_INT,0 -US-UMB,92137,GRP_INST,INST_HEAT,Unheated -US-UMB,92137,GRP_INST,INST_SHIELDING,None -US-UMB,92137,GRP_INST,INST_ASPIRATION,None -US-UMB,92137,GRP_INST,INST_SA_OFFSET_NORTH,300 -US-UMB,92137,GRP_INST,INST_SA_WIND_FORMAT,"U, V, W" -US-UMB,92101,GRP_INST,INST_MODEL,SA-Campbell CSAT-3 -US-UMB,92101,GRP_INST,INST_SN,CSAT3-0244 -US-UMB,92101,GRP_INST,INST_DATE,20170515 -US-UMB,92101,GRP_INST,INST_COMMENT,Sonic Anemometer - Campbell CSAT-3 -US-UMB,92101,GRP_INST,INST_FIRMWARE,48 -US-UMB,92101,GRP_INST,INST_SAMPLING_INT,0.1 -US-UMB,92101,GRP_INST,INST_AVERAGING_INT,0 -US-UMB,92101,GRP_INST,INST_HEAT,Unheated -US-UMB,92101,GRP_INST,INST_SHIELDING,None -US-UMB,92101,GRP_INST,INST_ASPIRATION,None -US-UMB,92101,GRP_INST,INST_SA_OFFSET_NORTH,300 -US-UMB,92101,GRP_INST,INST_SA_WIND_FORMAT,"U, V, W" -US-UMB,92122,GRP_INST,INST_MODEL,SA-Campbell CSAT-3 -US-UMB,92122,GRP_INST,INST_SN,CSAT3-0244 replaced w/ CSAT3-1712 -US-UMB,92122,GRP_INST,INST_DATE,20131030 -US-UMB,92122,GRP_INST,INST_COMMENT,Sonic Anemometer - Campbell CSAT-3 -US-UMB,92122,GRP_INST,INST_FIRMWARE,Instrument firmware version at installation -US-UMB,92122,GRP_INST,INST_SAMPLING_INT,0.1 -US-UMB,92122,GRP_INST,INST_AVERAGING_INT,0 -US-UMB,92122,GRP_INST,INST_HEAT,Unheated -US-UMB,92122,GRP_INST,INST_SHIELDING,None -US-UMB,92122,GRP_INST,INST_ASPIRATION,None -US-UMB,92122,GRP_INST,INST_SA_OFFSET_NORTH,300 -US-UMB,92122,GRP_INST,INST_SA_WIND_FORMAT,"U, V, W" -US-UMB,92073,GRP_INST,INST_MODEL,SA-Campbell CSAT-3 -US-UMB,92073,GRP_INST,INST_SN,CSAT3-0735 -US-UMB,92073,GRP_INST,INST_DATE,20170515 -US-UMB,92073,GRP_INST,INST_COMMENT,Sonic Anemometer - Campbell CSAT-3 -US-UMB,92073,GRP_INST,INST_FIRMWARE,34 -US-UMB,92073,GRP_INST,INST_SAMPLING_INT,0.1 -US-UMB,92073,GRP_INST,INST_AVERAGING_INT,0 -US-UMB,92073,GRP_INST,INST_HEAT,Unheated -US-UMB,92073,GRP_INST,INST_SHIELDING,None -US-UMB,92073,GRP_INST,INST_ASPIRATION,None -US-UMB,92073,GRP_INST,INST_SA_OFFSET_NORTH,300 -US-UMB,92073,GRP_INST,INST_SA_WIND_FORMAT,"U, V, W" -US-UMB,92114,GRP_INST,INST_MODEL,SA-Campbell CSAT-3 -US-UMB,92114,GRP_INST,INST_SN,CSAT3-0735 -US-UMB,92114,GRP_INST,INST_DATE,20170424 -US-UMB,92114,GRP_INST,INST_COMMENT,Sonic Anemometer - Campbell CSAT-3 -US-UMB,92114,GRP_INST,INST_SAMPLING_INT,0.1 -US-UMB,92114,GRP_INST,INST_AVERAGING_INT,0 -US-UMB,92114,GRP_INST,INST_HEAT,Unheated -US-UMB,92114,GRP_INST,INST_SHIELDING,None -US-UMB,92114,GRP_INST,INST_ASPIRATION,None -US-UMB,92114,GRP_INST,INST_SA_OFFSET_NORTH,300 -US-UMB,92114,GRP_INST,INST_SA_WIND_FORMAT,"U, V, W" -US-UMB,92081,GRP_INST,INST_MODEL,SA-Campbell CSAT-3 -US-UMB,92081,GRP_INST,INST_SN,CSAT3-1092 -US-UMB,92081,GRP_INST,INST_DATE,20170608 -US-UMB,92081,GRP_INST,INST_COMMENT,Sonic Anemometer - Campbell CSAT-3 -US-UMB,92081,GRP_INST,INST_FIRMWARE,34 -US-UMB,92081,GRP_INST,INST_SAMPLING_INT,0.1 -US-UMB,92081,GRP_INST,INST_AVERAGING_INT,0 -US-UMB,92081,GRP_INST,INST_HEAT,Unheated -US-UMB,92081,GRP_INST,INST_SHIELDING,None -US-UMB,92081,GRP_INST,INST_ASPIRATION,None -US-UMB,92081,GRP_INST,INST_SA_OFFSET_NORTH,300 -US-UMB,92081,GRP_INST,INST_SA_WIND_FORMAT,"U, V, W" -US-UMB,92078,GRP_INST,INST_MODEL,SA-Campbell CSAT-3 -US-UMB,92078,GRP_INST,INST_SN,CSAT3-1092 replaced w/ factory cal CSAT3-0244 -US-UMB,92078,GRP_INST,INST_DATE,20140331 -US-UMB,92078,GRP_INST,INST_COMMENT,Sonic Anemometer - Campbell CSAT-3 -US-UMB,92078,GRP_INST,INST_FIRMWARE,4.0T programmed for rain resistance -US-UMB,92078,GRP_INST,INST_SAMPLING_INT,0.1 -US-UMB,92078,GRP_INST,INST_AVERAGING_INT,0 -US-UMB,92078,GRP_INST,INST_HEAT,Unheated -US-UMB,92078,GRP_INST,INST_SHIELDING,None -US-UMB,92078,GRP_INST,INST_ASPIRATION,None -US-UMB,92078,GRP_INST,INST_SA_OFFSET_NORTH,300 -US-UMB,92078,GRP_INST,INST_SA_WIND_FORMAT,"U, V, W" -US-UMB,92117,GRP_INST,INST_MODEL,SA-Campbell CSAT-3 -US-UMB,92117,GRP_INST,INST_SN,CSAT3-1712 replaced w/ factory cal CSAT3-0244 -US-UMB,92117,GRP_INST,INST_DATE,20140514 -US-UMB,92117,GRP_INST,INST_COMMENT,Sonic Anemometer - Campbell CSAT-3 -US-UMB,92117,GRP_INST,INST_FIRMWARE,4.0T programmed for rain resistance -US-UMB,92117,GRP_INST,INST_SAMPLING_INT,0.1 -US-UMB,92117,GRP_INST,INST_AVERAGING_INT,0 -US-UMB,92117,GRP_INST,INST_HEAT,Unheated -US-UMB,92117,GRP_INST,INST_SHIELDING,None -US-UMB,92117,GRP_INST,INST_ASPIRATION,None -US-UMB,92117,GRP_INST,INST_SA_OFFSET_NORTH,300 -US-UMB,92117,GRP_INST,INST_SA_WIND_FORMAT,"U, V, W" -US-UMB,92103,GRP_INST,INST_MODEL,GA_CP-LI-COR LI-6262 -US-UMB,92103,GRP_INST,INST_SN,IRG3-203 -US-UMB,92103,GRP_INST,INST_DATE,20101215 -US-UMB,92103,GRP_INST,INST_COMMENT,"Gas Analyzer, Closed Path, LI-COR LI-6262" -US-UMB,92103,GRP_INST,INST_FIRMWARE,Instrument firmware version at installation -US-UMB,92103,GRP_INST,INST_SAMPLING_INT,0.1 -US-UMB,92103,GRP_INST,INST_HEAT,Heated -US-UMB,92103,GRP_INST,INST_SHIELDING,None -US-UMB,92103,GRP_INST,INST_ASPIRATION,Ventilation -US-UMB,92103,GRP_INST,INST_GA_CP_TUBE_LENGTH,40.4 -US-UMB,92103,GRP_INST,INST_GA_CP_TUBE_IN_DIAM,4.7625 -US-UMB,92103,GRP_INST,INST_GA_CP_TUBE_MAT,Other -US-UMB,92103,GRP_INST,INST_GA_CP_TUBE_THERM,None -US-UMB,92103,GRP_INST,INST_GA_CP_FLOW_RATE,9 -US-UMB,92103,GRP_INST,INST_GA_CP_MFC,No -US-UMB,92142,GRP_INST,INST_MODEL,GA_CP-LI-COR LI-6262 -US-UMB,92142,GRP_INST,INST_SN,IRG3-203 -US-UMB,92142,GRP_INST,INST_DATE,20010818 -US-UMB,92142,GRP_INST,INST_COMMENT,"Gas Analyzer, Closed Path, LI-COR LI-6262" -US-UMB,92142,GRP_INST,INST_FIRMWARE,Instrument firmware version at installation -US-UMB,92142,GRP_INST,INST_SAMPLING_INT,0.1 -US-UMB,92142,GRP_INST,INST_HEAT,Heated -US-UMB,92142,GRP_INST,INST_SHIELDING,None -US-UMB,92142,GRP_INST,INST_ASPIRATION,Ventilation -US-UMB,92142,GRP_INST,INST_GA_CP_FILTERS,2 filters pore size 1 µm -US-UMB,92142,GRP_INST,INST_GA_CP_TUBE_LENGTH,40.4 -US-UMB,92142,GRP_INST,INST_GA_CP_TUBE_IN_DIAM,4.7625 -US-UMB,92142,GRP_INST,INST_GA_CP_TUBE_MAT,Other -US-UMB,92142,GRP_INST,INST_GA_CP_TUBE_THERM,None -US-UMB,92142,GRP_INST,INST_GA_CP_FLOW_RATE,9 -US-UMB,92142,GRP_INST,INST_GA_CP_MFC,No -US-UMB,92092,GRP_INST,INST_MODEL,GA_CP-LI-COR LI-6262 -US-UMB,92092,GRP_INST,INST_SN,IRG3-937 -US-UMB,92092,GRP_INST,INST_DATE,20030507 -US-UMB,92092,GRP_INST,INST_COMMENT,"Gas Analyzer, Closed Path, LI-COR LI-6262" -US-UMB,92092,GRP_INST,INST_FIRMWARE,Instrument firmware version at installation -US-UMB,92092,GRP_INST,INST_SAMPLING_INT,0.1 -US-UMB,92092,GRP_INST,INST_HEAT,Heated -US-UMB,92092,GRP_INST,INST_SHIELDING,None -US-UMB,92092,GRP_INST,INST_ASPIRATION,Ventilation -US-UMB,92092,GRP_INST,INST_GA_CP_FILTERS,2 filters pore size 1 µm -US-UMB,92092,GRP_INST,INST_GA_CP_TUBE_LENGTH,40.4 -US-UMB,92092,GRP_INST,INST_GA_CP_TUBE_IN_DIAM,4.7625 -US-UMB,92092,GRP_INST,INST_GA_CP_TUBE_MAT,Other -US-UMB,92092,GRP_INST,INST_GA_CP_TUBE_THERM,None -US-UMB,92092,GRP_INST,INST_GA_CP_FLOW_RATE,9 -US-UMB,92092,GRP_INST,INST_GA_CP_MFC,No -US-UMB,92143,GRP_INST,INST_MODEL,GA_CP-LI-COR LI-6262 -US-UMB,92143,GRP_INST,INST_SN,IRG3-937 -US-UMB,92143,GRP_INST,INST_DATE,20010908 -US-UMB,92143,GRP_INST,INST_COMMENT,"Gas Analyzer, Closed Path, LI-COR LI-6262" -US-UMB,92143,GRP_INST,INST_FIRMWARE,Instrument firmware version at installation -US-UMB,92143,GRP_INST,INST_SAMPLING_INT,0.1 -US-UMB,92143,GRP_INST,INST_HEAT,Heated -US-UMB,92143,GRP_INST,INST_SHIELDING,None -US-UMB,92143,GRP_INST,INST_ASPIRATION,Ventilation -US-UMB,92143,GRP_INST,INST_GA_CP_FILTERS,2 filters pore size 1 µm -US-UMB,92143,GRP_INST,INST_GA_CP_TUBE_LENGTH,40.4 -US-UMB,92143,GRP_INST,INST_GA_CP_TUBE_IN_DIAM,4.7625 -US-UMB,92143,GRP_INST,INST_GA_CP_TUBE_MAT,Other -US-UMB,92143,GRP_INST,INST_GA_CP_TUBE_THERM,None -US-UMB,92143,GRP_INST,INST_GA_CP_FLOW_RATE,9 -US-UMB,92143,GRP_INST,INST_GA_CP_MFC,No -US-UMB,92145,GRP_INST,INST_MODEL,GA_CP-LI-COR LI-6262 -US-UMB,92145,GRP_INST,INST_SN,IRG3-937 -US-UMB,92145,GRP_INST,INST_DATE,19990101 -US-UMB,92145,GRP_INST,INST_COMMENT,"Gas Analyzer, Closed Path, LI-COR LI-6262" -US-UMB,92145,GRP_INST,INST_FIRMWARE,Instrument firmware version at installation -US-UMB,92145,GRP_INST,INST_SAMPLING_INT,0.1 -US-UMB,92145,GRP_INST,INST_HEAT,Heated -US-UMB,92145,GRP_INST,INST_SHIELDING,None -US-UMB,92145,GRP_INST,INST_ASPIRATION,Ventilation -US-UMB,92145,GRP_INST,INST_GA_CP_FILTERS,2 filters pore size 1 µm -US-UMB,92145,GRP_INST,INST_GA_CP_TUBE_LENGTH,40.4 -US-UMB,92145,GRP_INST,INST_GA_CP_TUBE_IN_DIAM,4.7625 -US-UMB,92145,GRP_INST,INST_GA_CP_TUBE_MAT,Other -US-UMB,92145,GRP_INST,INST_GA_CP_TUBE_THERM,None -US-UMB,92145,GRP_INST,INST_GA_CP_FLOW_RATE,9 -US-UMB,92145,GRP_INST,INST_GA_CP_MFC,No -US-UMB,92066,GRP_INST,INST_MODEL,GA_CP-LI-COR LI-6262 -US-UMB,92066,GRP_INST,INST_SN,IRG3-938 -US-UMB,92066,GRP_INST,INST_DATE,20030507 -US-UMB,92066,GRP_INST,INST_COMMENT,"Gas Analyzer, Closed Path, LI-COR LI-6262" -US-UMB,92066,GRP_INST,INST_FIRMWARE,Instrument firmware version at installation -US-UMB,92066,GRP_INST,INST_SAMPLING_INT,0.1 -US-UMB,92066,GRP_INST,INST_HEAT,Heated -US-UMB,92066,GRP_INST,INST_SHIELDING,None -US-UMB,92066,GRP_INST,INST_ASPIRATION,Ventilation -US-UMB,92066,GRP_INST,INST_GA_CP_FILTERS,2 filters pore size 1 µm -US-UMB,92066,GRP_INST,INST_GA_CP_TUBE_LENGTH,52 -US-UMB,92066,GRP_INST,INST_GA_CP_TUBE_IN_DIAM,4.7625 -US-UMB,92066,GRP_INST,INST_GA_CP_TUBE_MAT,Other -US-UMB,92066,GRP_INST,INST_GA_CP_TUBE_THERM,None -US-UMB,92066,GRP_INST,INST_GA_CP_FLOW_RATE,9 -US-UMB,92066,GRP_INST,INST_GA_CP_MFC,No -US-UMB,92100,GRP_INST,INST_MODEL,GA_CP-LI-COR LI-6262 -US-UMB,92100,GRP_INST,INST_SN,IRG3-938 -US-UMB,92100,GRP_INST,INST_DATE,19990101 -US-UMB,92100,GRP_INST,INST_COMMENT,"Gas Analyzer, Closed Path, LI-COR LI-6262" -US-UMB,92100,GRP_INST,INST_FIRMWARE,Instrument firmware version at installation -US-UMB,92100,GRP_INST,INST_SAMPLING_INT,0.1 -US-UMB,92100,GRP_INST,INST_HEAT,Heated -US-UMB,92100,GRP_INST,INST_SHIELDING,None -US-UMB,92100,GRP_INST,INST_ASPIRATION,Ventilation -US-UMB,92100,GRP_INST,INST_GA_CP_FILTERS,2 filters pore size 1 µm -US-UMB,92100,GRP_INST,INST_GA_CP_TUBE_LENGTH,52 -US-UMB,92100,GRP_INST,INST_GA_CP_TUBE_IN_DIAM,4.7625 -US-UMB,92100,GRP_INST,INST_GA_CP_TUBE_MAT,Other -US-UMB,92100,GRP_INST,INST_GA_CP_TUBE_THERM,None -US-UMB,92100,GRP_INST,INST_GA_CP_FLOW_RATE,9 -US-UMB,92100,GRP_INST,INST_GA_CP_MFC,No -US-UMB,92017,GRP_INST,INST_MODEL,GA_CP-LI-COR LI-7000 -US-UMB,92017,GRP_INST,INST_SN,IRG4-0403 -US-UMB,92017,GRP_INST,INST_DATE,20110211 -US-UMB,92017,GRP_INST,INST_COMMENT,"Gas Analyzer, Closed Path, LI-COR LI-7000" -US-UMB,92017,GRP_INST,INST_FIRMWARE,Instrument firmware version at installation -US-UMB,92017,GRP_INST,INST_SAMPLING_INT,0.1 -US-UMB,92017,GRP_INST,INST_HEAT,Heated -US-UMB,92017,GRP_INST,INST_SHIELDING,None -US-UMB,92017,GRP_INST,INST_ASPIRATION,Ventilation -US-UMB,92017,GRP_INST,INST_GA_CP_TUBE_LENGTH,40.4 -US-UMB,92017,GRP_INST,INST_GA_CP_TUBE_IN_DIAM,4.7625 -US-UMB,92017,GRP_INST,INST_GA_CP_TUBE_MAT,Other -US-UMB,92017,GRP_INST,INST_GA_CP_TUBE_THERM,None -US-UMB,92017,GRP_INST,INST_GA_CP_FLOW_RATE,9 -US-UMB,92017,GRP_INST,INST_GA_CP_MFC,No -US-UMB,92043,GRP_INST,INST_MODEL,GA_CP-LI-COR LI-7000 -US-UMB,92043,GRP_INST,INST_SN,IRG4-0403 -US-UMB,92043,GRP_INST,INST_DATE,20081031 -US-UMB,92043,GRP_INST,INST_COMMENT,"Gas Analyzer, Closed Path, LI-COR LI-7000" -US-UMB,92043,GRP_INST,INST_FIRMWARE,Instrument firmware version at installation -US-UMB,92043,GRP_INST,INST_SAMPLING_INT,0.1 -US-UMB,92043,GRP_INST,INST_HEAT,Heated -US-UMB,92043,GRP_INST,INST_SHIELDING,None -US-UMB,92043,GRP_INST,INST_ASPIRATION,Ventilation -US-UMB,92043,GRP_INST,INST_GA_CP_TUBE_LENGTH,40.4 -US-UMB,92043,GRP_INST,INST_GA_CP_TUBE_IN_DIAM,4.7625 -US-UMB,92043,GRP_INST,INST_GA_CP_TUBE_MAT,Other -US-UMB,92043,GRP_INST,INST_GA_CP_TUBE_THERM,None -US-UMB,92043,GRP_INST,INST_GA_CP_FLOW_RATE,9 -US-UMB,92043,GRP_INST,INST_GA_CP_MFC,No -US-UMB,92096,GRP_INST,INST_MODEL,GA_CP-LI-COR LI-7000 -US-UMB,92096,GRP_INST,INST_SN,IRG4-0403 -US-UMB,92096,GRP_INST,INST_DATE,20050506 -US-UMB,92096,GRP_INST,INST_COMMENT,"Gas Analyzer, Closed Path, LI-COR LI-7000" -US-UMB,92096,GRP_INST,INST_FIRMWARE,Instrument firmware version at installation -US-UMB,92096,GRP_INST,INST_SAMPLING_INT,0.1 -US-UMB,92096,GRP_INST,INST_HEAT,Heated -US-UMB,92096,GRP_INST,INST_SHIELDING,None -US-UMB,92096,GRP_INST,INST_ASPIRATION,Ventilation -US-UMB,92096,GRP_INST,INST_GA_CP_TUBE_LENGTH,40.4 -US-UMB,92096,GRP_INST,INST_GA_CP_TUBE_IN_DIAM,4.7625 -US-UMB,92096,GRP_INST,INST_GA_CP_TUBE_MAT,Other -US-UMB,92096,GRP_INST,INST_GA_CP_TUBE_THERM,None -US-UMB,92096,GRP_INST,INST_GA_CP_FLOW_RATE,9 -US-UMB,92096,GRP_INST,INST_GA_CP_MFC,No -US-UMB,92124,GRP_INST,INST_MODEL,GA_CP-LI-COR LI-7000 -US-UMB,92124,GRP_INST,INST_SN,IRG4-0403 -US-UMB,92124,GRP_INST,INST_DATE,20060418 -US-UMB,92124,GRP_INST,INST_COMMENT,"Gas Analyzer, Closed Path, LI-COR LI-7000" -US-UMB,92124,GRP_INST,INST_FIRMWARE,Instrument firmware version at installation -US-UMB,92124,GRP_INST,INST_SAMPLING_INT,0.1 -US-UMB,92124,GRP_INST,INST_HEAT,Heated -US-UMB,92124,GRP_INST,INST_SHIELDING,None -US-UMB,92124,GRP_INST,INST_ASPIRATION,Ventilation -US-UMB,92124,GRP_INST,INST_GA_CP_TUBE_LENGTH,40.4 -US-UMB,92124,GRP_INST,INST_GA_CP_TUBE_IN_DIAM,4.7625 -US-UMB,92124,GRP_INST,INST_GA_CP_TUBE_MAT,Other -US-UMB,92124,GRP_INST,INST_GA_CP_TUBE_THERM,None -US-UMB,92124,GRP_INST,INST_GA_CP_FLOW_RATE,9 -US-UMB,92124,GRP_INST,INST_GA_CP_MFC,No -US-UMB,92149,GRP_INST,INST_MODEL,GA_CP-LI-COR LI-7000 -US-UMB,92149,GRP_INST,INST_SN,IRG4-0403 -US-UMB,92149,GRP_INST,INST_DATE,20050331 -US-UMB,92149,GRP_INST,INST_COMMENT,"Gas Analyzer, Closed Path, LI-COR LI-7000" -US-UMB,92149,GRP_INST,INST_FIRMWARE,Instrument firmware version at installation -US-UMB,92149,GRP_INST,INST_SAMPLING_INT,0.1 -US-UMB,92149,GRP_INST,INST_HEAT,Heated -US-UMB,92149,GRP_INST,INST_SHIELDING,None -US-UMB,92149,GRP_INST,INST_ASPIRATION,Ventilation -US-UMB,92149,GRP_INST,INST_GA_CP_FILTERS,2 filters pore size 1 µm -US-UMB,92149,GRP_INST,INST_GA_CP_TUBE_LENGTH,52 -US-UMB,92149,GRP_INST,INST_GA_CP_TUBE_IN_DIAM,4.7625 -US-UMB,92149,GRP_INST,INST_GA_CP_TUBE_MAT,Other -US-UMB,92149,GRP_INST,INST_GA_CP_TUBE_THERM,None -US-UMB,92149,GRP_INST,INST_GA_CP_FLOW_RATE,9 -US-UMB,92149,GRP_INST,INST_GA_CP_MFC,No -US-UMB,92019,GRP_INST,INST_MODEL,GA_CP-LI-COR LI-7000 -US-UMB,92019,GRP_INST,INST_SN,IRG4-0404 -US-UMB,92019,GRP_INST,INST_DATE,20050414 -US-UMB,92019,GRP_INST,INST_COMMENT,"Gas Analyzer, Closed Path, LI-COR LI-7000" -US-UMB,92019,GRP_INST,INST_FIRMWARE,Instrument firmware version at installation -US-UMB,92019,GRP_INST,INST_SAMPLING_INT,0.1 -US-UMB,92019,GRP_INST,INST_HEAT,Heated -US-UMB,92019,GRP_INST,INST_SHIELDING,None -US-UMB,92019,GRP_INST,INST_ASPIRATION,Ventilation -US-UMB,92019,GRP_INST,INST_GA_CP_FILTERS,2 filters pore size 1 µm -US-UMB,92019,GRP_INST,INST_GA_CP_TUBE_LENGTH,52 -US-UMB,92019,GRP_INST,INST_GA_CP_TUBE_IN_DIAM,4.7625 -US-UMB,92019,GRP_INST,INST_GA_CP_TUBE_MAT,Other -US-UMB,92019,GRP_INST,INST_GA_CP_TUBE_THERM,None -US-UMB,92019,GRP_INST,INST_GA_CP_FLOW_RATE,9 -US-UMB,92019,GRP_INST,INST_GA_CP_MFC,No -US-UMB,92024,GRP_INST,INST_MODEL,GA_CP-LI-COR LI-7000 -US-UMB,92024,GRP_INST,INST_SN,IRG4-0404 -US-UMB,92024,GRP_INST,INST_DATE,20061002 -US-UMB,92024,GRP_INST,INST_COMMENT,"Gas Analyzer, Closed Path, LI-COR LI-7000" -US-UMB,92024,GRP_INST,INST_FIRMWARE,Instrument firmware version at installation -US-UMB,92024,GRP_INST,INST_SAMPLING_INT,0.05 -US-UMB,92024,GRP_INST,INST_HEAT,Heated -US-UMB,92024,GRP_INST,INST_SHIELDING,None -US-UMB,92024,GRP_INST,INST_ASPIRATION,Ventilation -US-UMB,92024,GRP_INST,INST_SA_OFFSET_NORTH,300 -US-UMB,92024,GRP_INST,INST_GA_CP_FILTERS,2 filters pore size 1 µm -US-UMB,92024,GRP_INST,INST_GA_CP_TUBE_LENGTH,52 -US-UMB,92024,GRP_INST,INST_GA_CP_TUBE_IN_DIAM,4.7625 -US-UMB,92024,GRP_INST,INST_GA_CP_TUBE_MAT,Other -US-UMB,92024,GRP_INST,INST_GA_CP_TUBE_THERM,None -US-UMB,92024,GRP_INST,INST_GA_CP_FLOW_RATE,9 -US-UMB,92024,GRP_INST,INST_GA_CP_MFC,No -US-UMB,92035,GRP_INST,INST_MODEL,GA_CP-LI-COR LI-7000 -US-UMB,92035,GRP_INST,INST_SN,IRG4-0404 -US-UMB,92035,GRP_INST,INST_DATE,20050331 -US-UMB,92035,GRP_INST,INST_COMMENT,"Gas Analyzer, Closed Path, LI-COR LI-7000" -US-UMB,92035,GRP_INST,INST_FIRMWARE,Instrument firmware version at installation -US-UMB,92035,GRP_INST,INST_SAMPLING_INT,0.1 -US-UMB,92035,GRP_INST,INST_HEAT,Heated -US-UMB,92035,GRP_INST,INST_SHIELDING,None -US-UMB,92035,GRP_INST,INST_ASPIRATION,Ventilation -US-UMB,92035,GRP_INST,INST_SA_OFFSET_NORTH,300 -US-UMB,92035,GRP_INST,INST_GA_CP_FILTERS,2 filters pore size 1 µm -US-UMB,92035,GRP_INST,INST_GA_CP_TUBE_LENGTH,40.4 -US-UMB,92035,GRP_INST,INST_GA_CP_TUBE_IN_DIAM,4.7625 -US-UMB,92035,GRP_INST,INST_GA_CP_TUBE_MAT,Other -US-UMB,92035,GRP_INST,INST_GA_CP_TUBE_THERM,None -US-UMB,92035,GRP_INST,INST_GA_CP_FLOW_RATE,9 -US-UMB,92035,GRP_INST,INST_GA_CP_MFC,No -US-UMB,92037,GRP_INST,INST_MODEL,GA_CP-LI-COR LI-7000 -US-UMB,92037,GRP_INST,INST_SN,IRG4-0404 -US-UMB,92037,GRP_INST,INST_DATE,20131115 -US-UMB,92037,GRP_INST,INST_COMMENT,"Gas Analyzer, Closed Path, LI-COR LI-7000" -US-UMB,92037,GRP_INST,INST_FIRMWARE,Instrument firmware version at installation -US-UMB,92037,GRP_INST,INST_SAMPLING_INT,0.1 -US-UMB,92037,GRP_INST,INST_HEAT,Heated -US-UMB,92037,GRP_INST,INST_SHIELDING,None -US-UMB,92037,GRP_INST,INST_ASPIRATION,Ventilation -US-UMB,92037,GRP_INST,INST_SA_OFFSET_NORTH,300 -US-UMB,92037,GRP_INST,INST_GA_CP_FILTERS,2 filters pore size 1 µm -US-UMB,92037,GRP_INST,INST_GA_CP_TUBE_LENGTH,52 -US-UMB,92037,GRP_INST,INST_GA_CP_TUBE_IN_DIAM,4.7625 -US-UMB,92037,GRP_INST,INST_GA_CP_TUBE_MAT,Other -US-UMB,92037,GRP_INST,INST_GA_CP_TUBE_THERM,None -US-UMB,92037,GRP_INST,INST_GA_CP_FLOW_RATE,9 -US-UMB,92037,GRP_INST,INST_GA_CP_MFC,No -US-UMB,92072,GRP_INST,INST_MODEL,GA_CP-LI-COR LI-7000 -US-UMB,92072,GRP_INST,INST_SN,IRG4-0404 -US-UMB,92072,GRP_INST,INST_DATE,20150702 -US-UMB,92072,GRP_INST,INST_COMMENT,"Gas Analyzer, Closed Path, LI-COR LI-7000" -US-UMB,92072,GRP_INST,INST_FIRMWARE,Instrument firmware version at installation -US-UMB,92072,GRP_INST,INST_SAMPLING_INT,0.1 -US-UMB,92072,GRP_INST,INST_HEAT,Heated -US-UMB,92072,GRP_INST,INST_SHIELDING,None -US-UMB,92072,GRP_INST,INST_ASPIRATION,Ventilation -US-UMB,92072,GRP_INST,INST_GA_CP_TUBE_LENGTH,52 -US-UMB,92072,GRP_INST,INST_GA_CP_TUBE_IN_DIAM,4.7625 -US-UMB,92072,GRP_INST,INST_GA_CP_TUBE_MAT,Other -US-UMB,92072,GRP_INST,INST_GA_CP_TUBE_THERM,None -US-UMB,92072,GRP_INST,INST_GA_CP_FLOW_RATE,9 -US-UMB,92072,GRP_INST,INST_GA_CP_MFC,No -US-UMB,92089,GRP_INST,INST_MODEL,GA_CP-LI-COR LI-7000 -US-UMB,92089,GRP_INST,INST_SN,IRG4-0404 -US-UMB,92089,GRP_INST,INST_DATE,20101021 -US-UMB,92089,GRP_INST,INST_COMMENT,"Gas Analyzer, Closed Path, LI-COR LI-7000" -US-UMB,92089,GRP_INST,INST_FIRMWARE,Instrument firmware version at installation -US-UMB,92089,GRP_INST,INST_SAMPLING_INT,0.1 -US-UMB,92089,GRP_INST,INST_HEAT,Heated -US-UMB,92089,GRP_INST,INST_SHIELDING,None -US-UMB,92089,GRP_INST,INST_ASPIRATION,Ventilation -US-UMB,92089,GRP_INST,INST_SA_OFFSET_NORTH,300 -US-UMB,92089,GRP_INST,INST_GA_CP_FILTERS,2 filters pore size 1 µm -US-UMB,92089,GRP_INST,INST_GA_CP_TUBE_LENGTH,40.4 -US-UMB,92089,GRP_INST,INST_GA_CP_TUBE_IN_DIAM,4.7625 -US-UMB,92089,GRP_INST,INST_GA_CP_TUBE_MAT,Other -US-UMB,92089,GRP_INST,INST_GA_CP_TUBE_THERM,None -US-UMB,92089,GRP_INST,INST_GA_CP_FLOW_RATE,9 -US-UMB,92089,GRP_INST,INST_GA_CP_MFC,No -US-UMB,92112,GRP_INST,INST_MODEL,GA_CP-LI-COR LI-7000 -US-UMB,92112,GRP_INST,INST_SN,IRG4-0404 -US-UMB,92112,GRP_INST,INST_DATE,20110125 -US-UMB,92112,GRP_INST,INST_COMMENT,"Gas Analyzer, Closed Path, LI-COR LI-7000" -US-UMB,92112,GRP_INST,INST_FIRMWARE,Instrument firmware version at installation -US-UMB,92112,GRP_INST,INST_SAMPLING_INT,0.1 -US-UMB,92112,GRP_INST,INST_HEAT,Heated -US-UMB,92112,GRP_INST,INST_SHIELDING,None -US-UMB,92112,GRP_INST,INST_ASPIRATION,Ventilation -US-UMB,92112,GRP_INST,INST_SA_OFFSET_NORTH,300 -US-UMB,92112,GRP_INST,INST_GA_CP_FILTERS,2 filters pore size 1 µm -US-UMB,92112,GRP_INST,INST_GA_CP_TUBE_LENGTH,52 -US-UMB,92112,GRP_INST,INST_GA_CP_TUBE_IN_DIAM,4.7625 -US-UMB,92112,GRP_INST,INST_GA_CP_TUBE_MAT,Other -US-UMB,92112,GRP_INST,INST_GA_CP_TUBE_THERM,None -US-UMB,92112,GRP_INST,INST_GA_CP_FLOW_RATE,9 -US-UMB,92112,GRP_INST,INST_GA_CP_MFC,No -US-UMB,92034,GRP_INST,INST_MODEL,GA_CP-LI-COR LI-7000 -US-UMB,92034,GRP_INST,INST_SN,IRG4-1036 -US-UMB,92034,GRP_INST,INST_DATE,20150601 -US-UMB,92034,GRP_INST,INST_COMMENT,"Gas Analyzer, Closed Path, LI-COR LI-7000" -US-UMB,92034,GRP_INST,INST_FIRMWARE,Instrument firmware version at installation -US-UMB,92034,GRP_INST,INST_SAMPLING_INT,0.1 -US-UMB,92034,GRP_INST,INST_HEAT,Heated -US-UMB,92034,GRP_INST,INST_SHIELDING,None -US-UMB,92034,GRP_INST,INST_ASPIRATION,Ventilation -US-UMB,92034,GRP_INST,INST_GA_CP_TUBE_LENGTH,52 -US-UMB,92034,GRP_INST,INST_GA_CP_TUBE_IN_DIAM,4.7625 -US-UMB,92034,GRP_INST,INST_GA_CP_TUBE_MAT,Other -US-UMB,92034,GRP_INST,INST_GA_CP_TUBE_THERM,None -US-UMB,92034,GRP_INST,INST_GA_CP_FLOW_RATE,9 -US-UMB,92034,GRP_INST,INST_GA_CP_MFC,No -US-UMB,92086,GRP_INST,INST_MODEL,GA_CP-LI-COR LI-7000 -US-UMB,92086,GRP_INST,INST_SN,IRG4-1162 -US-UMB,92086,GRP_INST,INST_DATE,20150727 -US-UMB,92086,GRP_INST,INST_COMMENT,"Gas Analyzer, Closed Path, LI-COR LI-7000" -US-UMB,92086,GRP_INST,INST_FIRMWARE,Instrument firmware version at installation -US-UMB,92086,GRP_INST,INST_SAMPLING_INT,0.1 -US-UMB,92086,GRP_INST,INST_HEAT,Heated -US-UMB,92086,GRP_INST,INST_SHIELDING,None -US-UMB,92086,GRP_INST,INST_ASPIRATION,Ventilation -US-UMB,92086,GRP_INST,INST_GA_CP_TUBE_LENGTH,40.4 -US-UMB,92086,GRP_INST,INST_GA_CP_TUBE_IN_DIAM,4.7625 -US-UMB,92086,GRP_INST,INST_GA_CP_TUBE_MAT,Other -US-UMB,92086,GRP_INST,INST_GA_CP_TUBE_THERM,None -US-UMB,92086,GRP_INST,INST_GA_CP_FLOW_RATE,9 -US-UMB,92086,GRP_INST,INST_GA_CP_MFC,No -US-UMB,92087,GRP_INST,INST_MODEL,RAD-Other -US-UMB,92087,GRP_INST,INST_SN,NR-LITE-1 -US-UMB,92087,GRP_INST,INST_DATE,20150401 -US-UMB,92087,GRP_INST,INST_COMMENT,Kipp and Zonen NR-lite -US-UMB,92087,GRP_INST,INST_SAMPLING_INT,30 -US-UMB,92087,GRP_INST,INST_AVERAGING_INT,600 -US-UMB,92087,GRP_INST,INST_HEAT,Unheated -US-UMB,92087,GRP_INST,INST_SHIELDING,None -US-UMB,92087,GRP_INST,INST_ASPIRATION,None -US-UMB,92136,GRP_INST,INST_MODEL,RAD-Other -US-UMB,92136,GRP_INST,INST_SN,NR-LITE-1 -US-UMB,92136,GRP_INST,INST_DATE,20120316 -US-UMB,92136,GRP_INST,INST_COMMENT,Kipp and Zonen NR-lite -US-UMB,92136,GRP_INST,INST_SAMPLING_INT,30 -US-UMB,92136,GRP_INST,INST_AVERAGING_INT,600 -US-UMB,92136,GRP_INST,INST_HEAT,Unheated -US-UMB,92136,GRP_INST,INST_SHIELDING,None -US-UMB,92136,GRP_INST,INST_ASPIRATION,None -US-UMB,92141,GRP_INST,INST_MODEL,RAD-PAR Quantum -US-UMB,92141,GRP_INST,INST_SN,PAR1 -US-UMB,92141,GRP_INST,INST_DATE,19990101 -US-UMB,92141,GRP_INST,INST_COMMENT,LI-190 up facing sensor -US-UMB,92141,GRP_INST,INST_SAMPLING_INT,10 -US-UMB,92141,GRP_INST,INST_AVERAGING_INT,600 -US-UMB,92141,GRP_INST,INST_HEAT,Unheated -US-UMB,92141,GRP_INST,INST_SHIELDING,None -US-UMB,92141,GRP_INST,INST_ASPIRATION,None -US-UMB,92095,GRP_INST,INST_MODEL,RAD-PAR Quantum -US-UMB,92095,GRP_INST,INST_SN,PAR10 -US-UMB,92095,GRP_INST,INST_DATE,20010405 -US-UMB,92095,GRP_INST,INST_COMMENT,LI-190 up facing sensor -US-UMB,92095,GRP_INST,INST_SAMPLING_INT,1 -US-UMB,92095,GRP_INST,INST_AVERAGING_INT,1800 -US-UMB,92095,GRP_INST,INST_HEAT,Unheated -US-UMB,92095,GRP_INST,INST_SHIELDING,None -US-UMB,92095,GRP_INST,INST_ASPIRATION,None -US-UMB,92108,GRP_INST,INST_MODEL,RAD-PAR Quantum -US-UMB,92108,GRP_INST,INST_SN,PAR11 -US-UMB,92108,GRP_INST,INST_DATE,20180509 -US-UMB,92108,GRP_INST,INST_COMMENT,Apogee up facing sensor -US-UMB,92108,GRP_INST,INST_SAMPLING_INT,10 -US-UMB,92108,GRP_INST,INST_AVERAGING_INT,600 -US-UMB,92108,GRP_INST,INST_HEAT,Unheated -US-UMB,92108,GRP_INST,INST_SHIELDING,None -US-UMB,92108,GRP_INST,INST_ASPIRATION,None -US-UMB,92116,GRP_INST,INST_MODEL,RAD-PAR Quantum -US-UMB,92116,GRP_INST,INST_SN,PAR2 -US-UMB,92116,GRP_INST,INST_DATE,19990101 -US-UMB,92116,GRP_INST,INST_COMMENT,LI-190 up facing sensor -US-UMB,92116,GRP_INST,INST_SAMPLING_INT,10 -US-UMB,92116,GRP_INST,INST_AVERAGING_INT,600 -US-UMB,92116,GRP_INST,INST_HEAT,Unheated -US-UMB,92116,GRP_INST,INST_SHIELDING,None -US-UMB,92116,GRP_INST,INST_ASPIRATION,None -US-UMB,92102,GRP_INST,INST_MODEL,RAD-PAR Quantum -US-UMB,92102,GRP_INST,INST_SN,PAR3 -US-UMB,92102,GRP_INST,INST_DATE,20020625 -US-UMB,92102,GRP_INST,INST_COMMENT,LI-190 Down facing PAR -US-UMB,92102,GRP_INST,INST_SAMPLING_INT,10 -US-UMB,92102,GRP_INST,INST_AVERAGING_INT,600 -US-UMB,92102,GRP_INST,INST_HEAT,Unheated -US-UMB,92102,GRP_INST,INST_SHIELDING,None -US-UMB,92102,GRP_INST,INST_ASPIRATION,None -US-UMB,92076,GRP_INST,INST_MODEL,RAD-PAR Quantum -US-UMB,92076,GRP_INST,INST_SN,PAR4 -US-UMB,92076,GRP_INST,INST_DATE,20120509 -US-UMB,92076,GRP_INST,INST_COMMENT,down facing par Apogee SQ-110 -US-UMB,92076,GRP_INST,INST_SAMPLING_INT,10 -US-UMB,92076,GRP_INST,INST_AVERAGING_INT,600 -US-UMB,92076,GRP_INST,INST_HEAT,Unheated -US-UMB,92076,GRP_INST,INST_SHIELDING,None -US-UMB,92076,GRP_INST,INST_ASPIRATION,None -US-UMB,92050,GRP_INST,INST_MODEL,RAD-PAR Quantum -US-UMB,92050,GRP_INST,INST_SN,PAR5 -US-UMB,92050,GRP_INST,INST_DATE,19980901 -US-UMB,92050,GRP_INST,INST_COMMENT,LI-190 up facing sensor -US-UMB,92050,GRP_INST,INST_SAMPLING_INT,1 -US-UMB,92050,GRP_INST,INST_AVERAGING_INT,1800 -US-UMB,92050,GRP_INST,INST_HEAT,Unheated -US-UMB,92050,GRP_INST,INST_SHIELDING,None -US-UMB,92050,GRP_INST,INST_ASPIRATION,None -US-UMB,92140,GRP_INST,INST_MODEL,RAD-PAR Quantum -US-UMB,92140,GRP_INST,INST_SN,PAR6 -US-UMB,92140,GRP_INST,INST_DATE,20010405 -US-UMB,92140,GRP_INST,INST_COMMENT,LI-190 up facing sensor -US-UMB,92140,GRP_INST,INST_SAMPLING_INT,1 -US-UMB,92140,GRP_INST,INST_AVERAGING_INT,1800 -US-UMB,92140,GRP_INST,INST_HEAT,Unheated -US-UMB,92140,GRP_INST,INST_SHIELDING,None -US-UMB,92140,GRP_INST,INST_ASPIRATION,None -US-UMB,92029,GRP_INST,INST_MODEL,RAD-PAR Quantum -US-UMB,92029,GRP_INST,INST_SN,PAR7 -US-UMB,92029,GRP_INST,INST_DATE,20010405 -US-UMB,92029,GRP_INST,INST_COMMENT,LI-190 up facing sensor -US-UMB,92029,GRP_INST,INST_SAMPLING_INT,1 -US-UMB,92029,GRP_INST,INST_AVERAGING_INT,1800 -US-UMB,92029,GRP_INST,INST_HEAT,Unheated -US-UMB,92029,GRP_INST,INST_SHIELDING,None -US-UMB,92029,GRP_INST,INST_ASPIRATION,None -US-UMB,92097,GRP_INST,INST_MODEL,RAD-PAR Quantum -US-UMB,92097,GRP_INST,INST_SN,PAR8 -US-UMB,92097,GRP_INST,INST_DATE,20010405 -US-UMB,92097,GRP_INST,INST_COMMENT,LI-190 up facing sensor -US-UMB,92097,GRP_INST,INST_SAMPLING_INT,1 -US-UMB,92097,GRP_INST,INST_AVERAGING_INT,1800 -US-UMB,92097,GRP_INST,INST_HEAT,Unheated -US-UMB,92097,GRP_INST,INST_SHIELDING,None -US-UMB,92097,GRP_INST,INST_ASPIRATION,None -US-UMB,92014,GRP_INST,INST_MODEL,RAD-PAR Quantum -US-UMB,92014,GRP_INST,INST_SN,PAR9 -US-UMB,92014,GRP_INST,INST_DATE,20010405 -US-UMB,92014,GRP_INST,INST_COMMENT,LI-190 up facing sensor -US-UMB,92014,GRP_INST,INST_SAMPLING_INT,1 -US-UMB,92014,GRP_INST,INST_AVERAGING_INT,1800 -US-UMB,92014,GRP_INST,INST_HEAT,Unheated -US-UMB,92014,GRP_INST,INST_SHIELDING,None -US-UMB,92014,GRP_INST,INST_ASPIRATION,None -US-UMB,92121,GRP_INST,INST_MODEL,RAD-SW Pyran Class2 -US-UMB,92121,GRP_INST,INST_SN,PYRAN1 -US-UMB,92121,GRP_INST,INST_DATE,19990101 -US-UMB,92121,GRP_INST,INST_COMMENT,LI-200 -US-UMB,92121,GRP_INST,INST_SAMPLING_INT,10 -US-UMB,92121,GRP_INST,INST_AVERAGING_INT,600 -US-UMB,92121,GRP_INST,INST_HEAT,Unheated -US-UMB,92121,GRP_INST,INST_SHIELDING,None -US-UMB,92121,GRP_INST,INST_ASPIRATION,None -US-UMB,92015,GRP_INST,INST_MODEL,RAD-SW Pyran Class2 -US-UMB,92015,GRP_INST,INST_SN,PYRAN2 -US-UMB,92015,GRP_INST,INST_DATE,19990101 -US-UMB,92015,GRP_INST,INST_COMMENT,LI-200 -US-UMB,92015,GRP_INST,INST_SAMPLING_INT,10 -US-UMB,92015,GRP_INST,INST_AVERAGING_INT,600 -US-UMB,92015,GRP_INST,INST_HEAT,Unheated -US-UMB,92015,GRP_INST,INST_SHIELDING,None -US-UMB,92015,GRP_INST,INST_ASPIRATION,None -US-UMB,92082,GRP_INST,INST_MODEL,RAD-Other -US-UMB,92082,GRP_INST,INST_SN,Q98109 -US-UMB,92082,GRP_INST,INST_DATE,19990101 -US-UMB,92082,GRP_INST,INST_COMMENT,REBS/Q*7 net radiation -US-UMB,92082,GRP_INST,INST_SAMPLING_INT,30 -US-UMB,92082,GRP_INST,INST_AVERAGING_INT,600 -US-UMB,92082,GRP_INST,INST_HEAT,Unheated -US-UMB,92082,GRP_INST,INST_SHIELDING,None -US-UMB,92082,GRP_INST,INST_ASPIRATION,None -US-UMB,92085,GRP_INST,INST_MODEL,RAD-Other -US-UMB,92085,GRP_INST,INST_SN,Q98109 -US-UMB,92085,GRP_INST,INST_DATE,20021219 -US-UMB,92085,GRP_INST,INST_COMMENT,REBS/Q*7 net radiation -US-UMB,92085,GRP_INST,INST_SAMPLING_INT,30 -US-UMB,92085,GRP_INST,INST_AVERAGING_INT,600 -US-UMB,92085,GRP_INST,INST_HEAT,Unheated -US-UMB,92085,GRP_INST,INST_SHIELDING,None -US-UMB,92085,GRP_INST,INST_ASPIRATION,None -US-UMB,92044,GRP_INST,INST_MODEL,RAD-Other -US-UMB,92044,GRP_INST,INST_SN,Q98110 -US-UMB,92044,GRP_INST,INST_DATE,19990101 -US-UMB,92044,GRP_INST,INST_COMMENT,REBS/Q*7 net radiation -US-UMB,92044,GRP_INST,INST_SAMPLING_INT,30 -US-UMB,92044,GRP_INST,INST_AVERAGING_INT,600 -US-UMB,92044,GRP_INST,INST_HEAT,Unheated -US-UMB,92044,GRP_INST,INST_SHIELDING,None -US-UMB,92044,GRP_INST,INST_ASPIRATION,None -US-UMB,92119,GRP_INST,INST_MODEL,RAD-Other -US-UMB,92119,GRP_INST,INST_SN,Q98110 -US-UMB,92119,GRP_INST,INST_DATE,20030603 -US-UMB,92119,GRP_INST,INST_COMMENT,REBS/Q*7 net radiation -US-UMB,92119,GRP_INST,INST_SAMPLING_INT,30 -US-UMB,92119,GRP_INST,INST_AVERAGING_INT,600 -US-UMB,92119,GRP_INST,INST_HEAT,Unheated -US-UMB,92119,GRP_INST,INST_SHIELDING,None -US-UMB,92119,GRP_INST,INST_ASPIRATION,None -US-UMB,92146,GRP_INST,INST_MODEL,RH-Other -US-UMB,92146,GRP_INST,INST_SN,RH1 -US-UMB,92146,GRP_INST,INST_DATE,19990316 -US-UMB,92146,GRP_INST,INST_COMMENT,HPO-43 -US-UMB,92146,GRP_INST,INST_SAMPLING_INT,10 -US-UMB,92146,GRP_INST,INST_AVERAGING_INT,600 -US-UMB,92146,GRP_INST,INST_HEAT,Unheated -US-UMB,92146,GRP_INST,INST_SHIELDING,Radiation -US-UMB,92146,GRP_INST,INST_ASPIRATION,Ventilation -US-UMB,92083,GRP_INST,INST_MODEL,RH-Other -US-UMB,92083,GRP_INST,INST_SN,RH10 -US-UMB,92083,GRP_INST,INST_DATE,20030503 -US-UMB,92083,GRP_INST,INST_COMMENT,HPO-43 -US-UMB,92083,GRP_INST,INST_SAMPLING_INT,10 -US-UMB,92083,GRP_INST,INST_AVERAGING_INT,600 -US-UMB,92083,GRP_INST,INST_HEAT,Unheated -US-UMB,92083,GRP_INST,INST_SHIELDING,Radiation -US-UMB,92083,GRP_INST,INST_ASPIRATION,Ventilation -US-UMB,92067,GRP_INST,INST_MODEL,RH-Other -US-UMB,92067,GRP_INST,INST_SN,RH11 -US-UMB,92067,GRP_INST,INST_DATE,20030503 -US-UMB,92067,GRP_INST,INST_COMMENT,HPO-43 -US-UMB,92067,GRP_INST,INST_SAMPLING_INT,10 -US-UMB,92067,GRP_INST,INST_AVERAGING_INT,600 -US-UMB,92067,GRP_INST,INST_HEAT,Unheated -US-UMB,92067,GRP_INST,INST_SHIELDING,Radiation -US-UMB,92067,GRP_INST,INST_ASPIRATION,Ventilation -US-UMB,92135,GRP_INST,INST_MODEL,RH-Other -US-UMB,92135,GRP_INST,INST_SN,RH12 -US-UMB,92135,GRP_INST,INST_DATE,20161202 -US-UMB,92135,GRP_INST,INST_COMMENT,Rotronic HC2-S3 temperature/Relative Humidity sensor -US-UMB,92135,GRP_INST,INST_FIRMWARE,Instrument firmware version at installation -US-UMB,92135,GRP_INST,INST_SAMPLING_INT,0.1 -US-UMB,92135,GRP_INST,INST_AVERAGING_INT,600 -US-UMB,92135,GRP_INST,INST_HEAT,Unheated -US-UMB,92135,GRP_INST,INST_SHIELDING,Radiation -US-UMB,92135,GRP_INST,INST_ASPIRATION,Ventilation -US-UMB,92080,GRP_INST,INST_MODEL,RH-Other -US-UMB,92080,GRP_INST,INST_SN,RH13 -US-UMB,92080,GRP_INST,INST_DATE,20161205 -US-UMB,92080,GRP_INST,INST_COMMENT,Rotronic HC2-S3 temperature/Relative Humidity sensor -US-UMB,92080,GRP_INST,INST_FIRMWARE,Instrument firmware version at installation -US-UMB,92080,GRP_INST,INST_SAMPLING_INT,2 -US-UMB,92080,GRP_INST,INST_AVERAGING_INT,60 -US-UMB,92080,GRP_INST,INST_HEAT,Unheated -US-UMB,92080,GRP_INST,INST_SHIELDING,Radiation -US-UMB,92080,GRP_INST,INST_ASPIRATION,Ventilation -US-UMB,92061,GRP_INST,INST_MODEL,RH-Other -US-UMB,92061,GRP_INST,INST_SN,RH2 -US-UMB,92061,GRP_INST,INST_DATE,19990316 -US-UMB,92061,GRP_INST,INST_COMMENT,HPO-43 -US-UMB,92061,GRP_INST,INST_SAMPLING_INT,10 -US-UMB,92061,GRP_INST,INST_AVERAGING_INT,600 -US-UMB,92061,GRP_INST,INST_HEAT,Unheated -US-UMB,92061,GRP_INST,INST_SHIELDING,Radiation -US-UMB,92061,GRP_INST,INST_ASPIRATION,Ventilation -US-UMB,92013,GRP_INST,INST_MODEL,RH-Other -US-UMB,92013,GRP_INST,INST_SN,RH3 -US-UMB,92013,GRP_INST,INST_DATE,19990316 -US-UMB,92013,GRP_INST,INST_COMMENT,HPO-43 -US-UMB,92013,GRP_INST,INST_SAMPLING_INT,10 -US-UMB,92013,GRP_INST,INST_AVERAGING_INT,600 -US-UMB,92013,GRP_INST,INST_HEAT,Unheated -US-UMB,92013,GRP_INST,INST_SHIELDING,Radiation -US-UMB,92013,GRP_INST,INST_ASPIRATION,Ventilation -US-UMB,92033,GRP_INST,INST_MODEL,RH-Other -US-UMB,92033,GRP_INST,INST_SN,RH4 -US-UMB,92033,GRP_INST,INST_DATE,19990316 -US-UMB,92033,GRP_INST,INST_COMMENT,HPO-43 -US-UMB,92033,GRP_INST,INST_SAMPLING_INT,10 -US-UMB,92033,GRP_INST,INST_AVERAGING_INT,600 -US-UMB,92033,GRP_INST,INST_HEAT,Unheated -US-UMB,92033,GRP_INST,INST_SHIELDING,Radiation -US-UMB,92033,GRP_INST,INST_ASPIRATION,Ventilation -US-UMB,92077,GRP_INST,INST_MODEL,RH-Other -US-UMB,92077,GRP_INST,INST_SN,RH5 -US-UMB,92077,GRP_INST,INST_DATE,19990316 -US-UMB,92077,GRP_INST,INST_COMMENT,HPO-43 -US-UMB,92077,GRP_INST,INST_SAMPLING_INT,10 -US-UMB,92077,GRP_INST,INST_AVERAGING_INT,600 -US-UMB,92077,GRP_INST,INST_HEAT,Unheated -US-UMB,92077,GRP_INST,INST_SHIELDING,Radiation -US-UMB,92077,GRP_INST,INST_ASPIRATION,Ventilation -US-UMB,92027,GRP_INST,INST_MODEL,RH-Other -US-UMB,92027,GRP_INST,INST_SN,RH6 -US-UMB,92027,GRP_INST,INST_DATE,20021219 -US-UMB,92027,GRP_INST,INST_COMMENT,HPO-43 -US-UMB,92027,GRP_INST,INST_SAMPLING_INT,10 -US-UMB,92027,GRP_INST,INST_AVERAGING_INT,600 -US-UMB,92027,GRP_INST,INST_HEAT,Unheated -US-UMB,92027,GRP_INST,INST_SHIELDING,Radiation -US-UMB,92027,GRP_INST,INST_ASPIRATION,Ventilation -US-UMB,92113,GRP_INST,INST_MODEL,RH-Other -US-UMB,92113,GRP_INST,INST_SN,RH7 -US-UMB,92113,GRP_INST,INST_DATE,20030503 -US-UMB,92113,GRP_INST,INST_COMMENT,HPO-43 -US-UMB,92113,GRP_INST,INST_SAMPLING_INT,10 -US-UMB,92113,GRP_INST,INST_AVERAGING_INT,600 -US-UMB,92113,GRP_INST,INST_HEAT,Unheated -US-UMB,92113,GRP_INST,INST_SHIELDING,Radiation -US-UMB,92113,GRP_INST,INST_ASPIRATION,Ventilation -US-UMB,92036,GRP_INST,INST_MODEL,RH-Other -US-UMB,92036,GRP_INST,INST_SN,RH8 -US-UMB,92036,GRP_INST,INST_DATE,20030503 -US-UMB,92036,GRP_INST,INST_COMMENT,HPO-43 -US-UMB,92036,GRP_INST,INST_SAMPLING_INT,10 -US-UMB,92036,GRP_INST,INST_AVERAGING_INT,600 -US-UMB,92036,GRP_INST,INST_HEAT,Unheated -US-UMB,92036,GRP_INST,INST_SHIELDING,Radiation -US-UMB,92036,GRP_INST,INST_ASPIRATION,Ventilation -US-UMB,92138,GRP_INST,INST_MODEL,RH-Other -US-UMB,92138,GRP_INST,INST_SN,RH9 -US-UMB,92138,GRP_INST,INST_DATE,20030503 -US-UMB,92138,GRP_INST,INST_COMMENT,HPO-43 -US-UMB,92138,GRP_INST,INST_SAMPLING_INT,10 -US-UMB,92138,GRP_INST,INST_AVERAGING_INT,600 -US-UMB,92138,GRP_INST,INST_HEAT,Unheated -US-UMB,92138,GRP_INST,INST_SHIELDING,Radiation -US-UMB,92138,GRP_INST,INST_ASPIRATION,Ventilation -US-UMB,92028,GRP_INST,INST_MODEL,SWC-Other -US-UMB,92028,GRP_INST,INST_SN,SWC_AAS_1 -US-UMB,92028,GRP_INST,INST_DATE,20090323 -US-UMB,92028,GRP_INST,INST_COMMENT,Steven Hydra Probe. Coaxial impedance dielectric reflectometry -US-UMB,92028,GRP_INST,INST_FIRMWARE,Instrument firmware version at installation -US-UMB,92028,GRP_INST,INST_SAMPLING_INT,600 -US-UMB,92028,GRP_INST,INST_AVERAGING_INT,1800 -US-UMB,92028,GRP_INST,INST_HEAT,Unheated -US-UMB,92028,GRP_INST,INST_SHIELDING,None -US-UMB,92028,GRP_INST,INST_ASPIRATION,None -US-UMB,92107,GRP_INST,INST_MODEL,TEMP-Other -US-UMB,92107,GRP_INST,INST_SN,SWC_AAS_1 -US-UMB,92107,GRP_INST,INST_DATE,20090323 -US-UMB,92107,GRP_INST,INST_COMMENT,Steven Hydra Probe. Coaxial impedance dielectric reflectometry -US-UMB,92107,GRP_INST,INST_FIRMWARE,Instrument firmware version at installation -US-UMB,92107,GRP_INST,INST_SAMPLING_INT,600 -US-UMB,92107,GRP_INST,INST_AVERAGING_INT,1800 -US-UMB,92107,GRP_INST,INST_HEAT,Unheated -US-UMB,92107,GRP_INST,INST_SHIELDING,None -US-UMB,92107,GRP_INST,INST_ASPIRATION,None -US-UMB,92020,GRP_INST,INST_MODEL,SWC-Other -US-UMB,92020,GRP_INST,INST_SN,SWC_AAS_10 -US-UMB,92020,GRP_INST,INST_DATE,20090323 -US-UMB,92020,GRP_INST,INST_COMMENT,Steven Hydra Probe. Coaxial impedance dielectric reflectometry -US-UMB,92020,GRP_INST,INST_FIRMWARE,Instrument firmware version at installation -US-UMB,92020,GRP_INST,INST_SAMPLING_INT,600 -US-UMB,92020,GRP_INST,INST_AVERAGING_INT,1800 -US-UMB,92020,GRP_INST,INST_HEAT,Unheated -US-UMB,92020,GRP_INST,INST_SHIELDING,None -US-UMB,92020,GRP_INST,INST_ASPIRATION,None -US-UMB,92118,GRP_INST,INST_MODEL,TEMP-Other -US-UMB,92118,GRP_INST,INST_SN,SWC_AAS_10 -US-UMB,92118,GRP_INST,INST_DATE,20090323 -US-UMB,92118,GRP_INST,INST_COMMENT,Steven Hydra Probe. Coaxial impedance dielectric reflectometry -US-UMB,92118,GRP_INST,INST_FIRMWARE,Instrument firmware version at installation -US-UMB,92118,GRP_INST,INST_SAMPLING_INT,600 -US-UMB,92118,GRP_INST,INST_AVERAGING_INT,1800 -US-UMB,92118,GRP_INST,INST_HEAT,Unheated -US-UMB,92118,GRP_INST,INST_SHIELDING,None -US-UMB,92118,GRP_INST,INST_ASPIRATION,None -US-UMB,92016,GRP_INST,INST_MODEL,TEMP-Other -US-UMB,92016,GRP_INST,INST_SN,SWC_AAS_11 -US-UMB,92016,GRP_INST,INST_DATE,20090323 -US-UMB,92016,GRP_INST,INST_COMMENT,Steven Hydra Probe. Coaxial impedance dielectric reflectometry -US-UMB,92016,GRP_INST,INST_FIRMWARE,Instrument firmware version at installation -US-UMB,92016,GRP_INST,INST_SAMPLING_INT,600 -US-UMB,92016,GRP_INST,INST_AVERAGING_INT,1800 -US-UMB,92016,GRP_INST,INST_HEAT,Unheated -US-UMB,92016,GRP_INST,INST_SHIELDING,None -US-UMB,92016,GRP_INST,INST_ASPIRATION,None -US-UMB,92023,GRP_INST,INST_MODEL,SWC-Other -US-UMB,92023,GRP_INST,INST_SN,SWC_AAS_11 -US-UMB,92023,GRP_INST,INST_DATE,20090323 -US-UMB,92023,GRP_INST,INST_COMMENT,Steven Hydra Probe. Coaxial impedance dielectric reflectometry -US-UMB,92023,GRP_INST,INST_FIRMWARE,Instrument firmware version at installation -US-UMB,92023,GRP_INST,INST_SAMPLING_INT,600 -US-UMB,92023,GRP_INST,INST_AVERAGING_INT,1800 -US-UMB,92023,GRP_INST,INST_HEAT,Unheated -US-UMB,92023,GRP_INST,INST_SHIELDING,None -US-UMB,92023,GRP_INST,INST_ASPIRATION,None -US-UMB,92055,GRP_INST,INST_MODEL,TEMP-Other -US-UMB,92055,GRP_INST,INST_SN,SWC_AAS_2 -US-UMB,92055,GRP_INST,INST_DATE,20090323 -US-UMB,92055,GRP_INST,INST_COMMENT,Steven Hydra Probe. Coaxial impedance dielectric reflectometry -US-UMB,92055,GRP_INST,INST_FIRMWARE,Instrument firmware version at installation -US-UMB,92055,GRP_INST,INST_SAMPLING_INT,600 -US-UMB,92055,GRP_INST,INST_AVERAGING_INT,1800 -US-UMB,92055,GRP_INST,INST_HEAT,Unheated -US-UMB,92055,GRP_INST,INST_SHIELDING,None -US-UMB,92055,GRP_INST,INST_ASPIRATION,None -US-UMB,92094,GRP_INST,INST_MODEL,SWC-Other -US-UMB,92094,GRP_INST,INST_SN,SWC_AAS_2 -US-UMB,92094,GRP_INST,INST_DATE,20090323 -US-UMB,92094,GRP_INST,INST_COMMENT,Steven Hydra Probe. Coaxial impedance dielectric reflectometry -US-UMB,92094,GRP_INST,INST_FIRMWARE,Instrument firmware version at installation -US-UMB,92094,GRP_INST,INST_SAMPLING_INT,600 -US-UMB,92094,GRP_INST,INST_AVERAGING_INT,1800 -US-UMB,92094,GRP_INST,INST_HEAT,Unheated -US-UMB,92094,GRP_INST,INST_SHIELDING,None -US-UMB,92094,GRP_INST,INST_ASPIRATION,None -US-UMB,92070,GRP_INST,INST_MODEL,SWC-Other -US-UMB,92070,GRP_INST,INST_SN,SWC_AAS_3 -US-UMB,92070,GRP_INST,INST_DATE,20090323 -US-UMB,92070,GRP_INST,INST_COMMENT,Steven Hydra Probe. Coaxial impedance dielectric reflectometry -US-UMB,92070,GRP_INST,INST_FIRMWARE,Instrument firmware version at installation -US-UMB,92070,GRP_INST,INST_SAMPLING_INT,600 -US-UMB,92070,GRP_INST,INST_AVERAGING_INT,1800 -US-UMB,92070,GRP_INST,INST_HEAT,Unheated -US-UMB,92070,GRP_INST,INST_SHIELDING,None -US-UMB,92070,GRP_INST,INST_ASPIRATION,None -US-UMB,92133,GRP_INST,INST_MODEL,TEMP-Other -US-UMB,92133,GRP_INST,INST_SN,SWC_AAS_3 -US-UMB,92133,GRP_INST,INST_DATE,20090323 -US-UMB,92133,GRP_INST,INST_COMMENT,Steven Hydra Probe. Coaxial impedance dielectric reflectometry -US-UMB,92133,GRP_INST,INST_FIRMWARE,Instrument firmware version at installation -US-UMB,92133,GRP_INST,INST_SAMPLING_INT,600 -US-UMB,92133,GRP_INST,INST_AVERAGING_INT,1800 -US-UMB,92133,GRP_INST,INST_HEAT,Unheated -US-UMB,92133,GRP_INST,INST_SHIELDING,None -US-UMB,92133,GRP_INST,INST_ASPIRATION,None -US-UMB,92120,GRP_INST,INST_MODEL,TEMP-Other -US-UMB,92120,GRP_INST,INST_SN,SWC_AAS_4 -US-UMB,92120,GRP_INST,INST_DATE,20090323 -US-UMB,92120,GRP_INST,INST_COMMENT,Steven Hydra Probe. Coaxial impedance dielectric reflectometry -US-UMB,92120,GRP_INST,INST_FIRMWARE,Instrument firmware version at installation -US-UMB,92120,GRP_INST,INST_SAMPLING_INT,600 -US-UMB,92120,GRP_INST,INST_AVERAGING_INT,1800 -US-UMB,92120,GRP_INST,INST_HEAT,Unheated -US-UMB,92120,GRP_INST,INST_SHIELDING,None -US-UMB,92120,GRP_INST,INST_ASPIRATION,None -US-UMB,92123,GRP_INST,INST_MODEL,SWC-Other -US-UMB,92123,GRP_INST,INST_SN,SWC_AAS_4 -US-UMB,92123,GRP_INST,INST_DATE,20090323 -US-UMB,92123,GRP_INST,INST_COMMENT,Steven Hydra Probe. Coaxial impedance dielectric reflectometry -US-UMB,92123,GRP_INST,INST_FIRMWARE,Instrument firmware version at installation -US-UMB,92123,GRP_INST,INST_SAMPLING_INT,600 -US-UMB,92123,GRP_INST,INST_AVERAGING_INT,1800 -US-UMB,92123,GRP_INST,INST_HEAT,Unheated -US-UMB,92123,GRP_INST,INST_SHIELDING,None -US-UMB,92123,GRP_INST,INST_ASPIRATION,None -US-UMB,92026,GRP_INST,INST_MODEL,TEMP-Other -US-UMB,92026,GRP_INST,INST_SN,SWC_AAS_5 -US-UMB,92026,GRP_INST,INST_DATE,20090323 -US-UMB,92026,GRP_INST,INST_COMMENT,Steven Hydra Probe. Coaxial impedance dielectric reflectometry -US-UMB,92026,GRP_INST,INST_FIRMWARE,Instrument firmware version at installation -US-UMB,92026,GRP_INST,INST_SAMPLING_INT,600 -US-UMB,92026,GRP_INST,INST_AVERAGING_INT,1800 -US-UMB,92026,GRP_INST,INST_HEAT,Unheated -US-UMB,92026,GRP_INST,INST_SHIELDING,None -US-UMB,92026,GRP_INST,INST_ASPIRATION,None -US-UMB,92148,GRP_INST,INST_MODEL,SWC-Other -US-UMB,92148,GRP_INST,INST_SN,SWC_AAS_5 -US-UMB,92148,GRP_INST,INST_DATE,20090323 -US-UMB,92148,GRP_INST,INST_COMMENT,Steven Hydra Probe. Coaxial impedance dielectric reflectometry -US-UMB,92148,GRP_INST,INST_FIRMWARE,Instrument firmware version at installation -US-UMB,92148,GRP_INST,INST_SAMPLING_INT,600 -US-UMB,92148,GRP_INST,INST_AVERAGING_INT,1800 -US-UMB,92148,GRP_INST,INST_HEAT,Unheated -US-UMB,92148,GRP_INST,INST_SHIELDING,None -US-UMB,92148,GRP_INST,INST_ASPIRATION,None -US-UMB,92051,GRP_INST,INST_MODEL,TEMP-Other -US-UMB,92051,GRP_INST,INST_SN,SWC_AAS_6 -US-UMB,92051,GRP_INST,INST_DATE,20090323 -US-UMB,92051,GRP_INST,INST_COMMENT,Steven Hydra Probe. Coaxial impedance dielectric reflectometry -US-UMB,92051,GRP_INST,INST_FIRMWARE,Instrument firmware version at installation -US-UMB,92051,GRP_INST,INST_SAMPLING_INT,600 -US-UMB,92051,GRP_INST,INST_AVERAGING_INT,1800 -US-UMB,92051,GRP_INST,INST_HEAT,Unheated -US-UMB,92051,GRP_INST,INST_SHIELDING,None -US-UMB,92051,GRP_INST,INST_ASPIRATION,None -US-UMB,92151,GRP_INST,INST_MODEL,SWC-Other -US-UMB,92151,GRP_INST,INST_SN,SWC_AAS_6 -US-UMB,92151,GRP_INST,INST_DATE,20090323 -US-UMB,92151,GRP_INST,INST_COMMENT,Steven Hydra Probe. Coaxial impedance dielectric reflectometry -US-UMB,92151,GRP_INST,INST_FIRMWARE,Instrument firmware version at installation -US-UMB,92151,GRP_INST,INST_SAMPLING_INT,600 -US-UMB,92151,GRP_INST,INST_AVERAGING_INT,1800 -US-UMB,92151,GRP_INST,INST_HEAT,Unheated -US-UMB,92151,GRP_INST,INST_SHIELDING,None -US-UMB,92151,GRP_INST,INST_ASPIRATION,None -US-UMB,92060,GRP_INST,INST_MODEL,TEMP-Other -US-UMB,92060,GRP_INST,INST_SN,SWC_AAS_7 -US-UMB,92060,GRP_INST,INST_DATE,20090323 -US-UMB,92060,GRP_INST,INST_COMMENT,Steven Hydra Probe. Coaxial impedance dielectric reflectometry -US-UMB,92060,GRP_INST,INST_FIRMWARE,Instrument firmware version at installation -US-UMB,92060,GRP_INST,INST_SAMPLING_INT,600 -US-UMB,92060,GRP_INST,INST_AVERAGING_INT,1800 -US-UMB,92060,GRP_INST,INST_HEAT,Unheated -US-UMB,92060,GRP_INST,INST_SHIELDING,None -US-UMB,92060,GRP_INST,INST_ASPIRATION,None -US-UMB,92091,GRP_INST,INST_MODEL,SWC-Other -US-UMB,92091,GRP_INST,INST_SN,SWC_AAS_7 -US-UMB,92091,GRP_INST,INST_DATE,20090323 -US-UMB,92091,GRP_INST,INST_COMMENT,Steven Hydra Probe. Coaxial impedance dielectric reflectometry -US-UMB,92091,GRP_INST,INST_FIRMWARE,Instrument firmware version at installation -US-UMB,92091,GRP_INST,INST_SAMPLING_INT,600 -US-UMB,92091,GRP_INST,INST_AVERAGING_INT,1800 -US-UMB,92091,GRP_INST,INST_HEAT,Unheated -US-UMB,92091,GRP_INST,INST_SHIELDING,None -US-UMB,92091,GRP_INST,INST_ASPIRATION,None -US-UMB,92021,GRP_INST,INST_MODEL,TEMP-Other -US-UMB,92021,GRP_INST,INST_SN,SWC_AAS_8 -US-UMB,92021,GRP_INST,INST_DATE,20090323 -US-UMB,92021,GRP_INST,INST_COMMENT,Steven Hydra Probe. Coaxial impedance dielectric reflectometry -US-UMB,92021,GRP_INST,INST_FIRMWARE,Instrument firmware version at installation -US-UMB,92021,GRP_INST,INST_SAMPLING_INT,600 -US-UMB,92021,GRP_INST,INST_AVERAGING_INT,1800 -US-UMB,92021,GRP_INST,INST_HEAT,Unheated -US-UMB,92021,GRP_INST,INST_SHIELDING,None -US-UMB,92021,GRP_INST,INST_ASPIRATION,None -US-UMB,92022,GRP_INST,INST_MODEL,SWC-Other -US-UMB,92022,GRP_INST,INST_SN,SWC_AAS_8 -US-UMB,92022,GRP_INST,INST_DATE,20090323 -US-UMB,92022,GRP_INST,INST_COMMENT,Steven Hydra Probe. Coaxial impedance dielectric reflectometry -US-UMB,92022,GRP_INST,INST_FIRMWARE,Instrument firmware version at installation -US-UMB,92022,GRP_INST,INST_SAMPLING_INT,600 -US-UMB,92022,GRP_INST,INST_AVERAGING_INT,1800 -US-UMB,92022,GRP_INST,INST_HEAT,Unheated -US-UMB,92022,GRP_INST,INST_SHIELDING,None -US-UMB,92022,GRP_INST,INST_ASPIRATION,None -US-UMB,92047,GRP_INST,INST_MODEL,TEMP-Other -US-UMB,92047,GRP_INST,INST_SN,SWC_AAS_9 -US-UMB,92047,GRP_INST,INST_DATE,20090323 -US-UMB,92047,GRP_INST,INST_COMMENT,Steven Hydra Probe. Coaxial impedance dielectric reflectometry -US-UMB,92047,GRP_INST,INST_FIRMWARE,Instrument firmware version at installation -US-UMB,92047,GRP_INST,INST_SAMPLING_INT,600 -US-UMB,92047,GRP_INST,INST_AVERAGING_INT,1800 -US-UMB,92047,GRP_INST,INST_HEAT,Unheated -US-UMB,92047,GRP_INST,INST_SHIELDING,None -US-UMB,92047,GRP_INST,INST_ASPIRATION,None -US-UMB,92134,GRP_INST,INST_MODEL,SWC-Other -US-UMB,92134,GRP_INST,INST_SN,SWC_AAS_9 -US-UMB,92134,GRP_INST,INST_DATE,20090323 -US-UMB,92134,GRP_INST,INST_COMMENT,Steven Hydra Probe. Coaxial impedance dielectric reflectometry -US-UMB,92134,GRP_INST,INST_FIRMWARE,Instrument firmware version at installation -US-UMB,92134,GRP_INST,INST_SAMPLING_INT,600 -US-UMB,92134,GRP_INST,INST_AVERAGING_INT,1800 -US-UMB,92134,GRP_INST,INST_HEAT,Unheated -US-UMB,92134,GRP_INST,INST_SHIELDING,None -US-UMB,92134,GRP_INST,INST_ASPIRATION,None -US-UMB,92054,GRP_INST,INST_MODEL,TEMP-Other -US-UMB,92054,GRP_INST,INST_SN,SWC_AOS_1 -US-UMB,92054,GRP_INST,INST_DATE,20090323 -US-UMB,92054,GRP_INST,INST_COMMENT,Steven Hydra Probe. Coaxial impedance dielectric reflectometry -US-UMB,92054,GRP_INST,INST_FIRMWARE,Instrument firmware version at installation -US-UMB,92054,GRP_INST,INST_SAMPLING_INT,600 -US-UMB,92054,GRP_INST,INST_AVERAGING_INT,1800 -US-UMB,92054,GRP_INST,INST_HEAT,Unheated -US-UMB,92054,GRP_INST,INST_SHIELDING,None -US-UMB,92054,GRP_INST,INST_ASPIRATION,None -US-UMB,92132,GRP_INST,INST_MODEL,SWC-Other -US-UMB,92132,GRP_INST,INST_SN,SWC_AOS_1 -US-UMB,92132,GRP_INST,INST_DATE,20090323 -US-UMB,92132,GRP_INST,INST_COMMENT,Steven Hydra Probe. Coaxial impedance dielectric reflectometry -US-UMB,92132,GRP_INST,INST_FIRMWARE,Instrument firmware version at installation -US-UMB,92132,GRP_INST,INST_SAMPLING_INT,600 -US-UMB,92132,GRP_INST,INST_AVERAGING_INT,1800 -US-UMB,92132,GRP_INST,INST_HEAT,Unheated -US-UMB,92132,GRP_INST,INST_SHIELDING,None -US-UMB,92132,GRP_INST,INST_ASPIRATION,None -US-UMB,92106,GRP_INST,INST_MODEL,TEMP-Other -US-UMB,92106,GRP_INST,INST_SN,SWC_AOS_10 -US-UMB,92106,GRP_INST,INST_DATE,20090323 -US-UMB,92106,GRP_INST,INST_COMMENT,Steven Hydra Probe. Coaxial impedance dielectric reflectometry -US-UMB,92106,GRP_INST,INST_FIRMWARE,Instrument firmware version at installation -US-UMB,92106,GRP_INST,INST_SAMPLING_INT,600 -US-UMB,92106,GRP_INST,INST_AVERAGING_INT,1800 -US-UMB,92106,GRP_INST,INST_HEAT,Unheated -US-UMB,92106,GRP_INST,INST_SHIELDING,None -US-UMB,92106,GRP_INST,INST_ASPIRATION,None -US-UMB,92130,GRP_INST,INST_MODEL,SWC-Other -US-UMB,92130,GRP_INST,INST_SN,SWC_AOS_10 -US-UMB,92130,GRP_INST,INST_DATE,20090323 -US-UMB,92130,GRP_INST,INST_COMMENT,Steven Hydra Probe. Coaxial impedance dielectric reflectometry -US-UMB,92130,GRP_INST,INST_FIRMWARE,Instrument firmware version at installation -US-UMB,92130,GRP_INST,INST_SAMPLING_INT,600 -US-UMB,92130,GRP_INST,INST_AVERAGING_INT,1800 -US-UMB,92130,GRP_INST,INST_HEAT,Unheated -US-UMB,92130,GRP_INST,INST_SHIELDING,None -US-UMB,92130,GRP_INST,INST_ASPIRATION,None -US-UMB,92064,GRP_INST,INST_MODEL,TEMP-Other -US-UMB,92064,GRP_INST,INST_SN,SWC_AOS_11 -US-UMB,92064,GRP_INST,INST_DATE,20090323 -US-UMB,92064,GRP_INST,INST_COMMENT,Steven Hydra Probe. Coaxial impedance dielectric reflectometry -US-UMB,92064,GRP_INST,INST_FIRMWARE,Instrument firmware version at installation -US-UMB,92064,GRP_INST,INST_SAMPLING_INT,600 -US-UMB,92064,GRP_INST,INST_AVERAGING_INT,1800 -US-UMB,92064,GRP_INST,INST_HEAT,Unheated -US-UMB,92064,GRP_INST,INST_SHIELDING,None -US-UMB,92064,GRP_INST,INST_ASPIRATION,None -US-UMB,92150,GRP_INST,INST_MODEL,SWC-Other -US-UMB,92150,GRP_INST,INST_SN,SWC_AOS_11 -US-UMB,92150,GRP_INST,INST_DATE,20090323 -US-UMB,92150,GRP_INST,INST_COMMENT,Steven Hydra Probe. Coaxial impedance dielectric reflectometry -US-UMB,92150,GRP_INST,INST_FIRMWARE,Instrument firmware version at installation -US-UMB,92150,GRP_INST,INST_SAMPLING_INT,600 -US-UMB,92150,GRP_INST,INST_AVERAGING_INT,1800 -US-UMB,92150,GRP_INST,INST_HEAT,Unheated -US-UMB,92150,GRP_INST,INST_SHIELDING,None -US-UMB,92150,GRP_INST,INST_ASPIRATION,None -US-UMB,92030,GRP_INST,INST_MODEL,TEMP-Other -US-UMB,92030,GRP_INST,INST_SN,SWC_AOS_2 -US-UMB,92030,GRP_INST,INST_DATE,20090323 -US-UMB,92030,GRP_INST,INST_COMMENT,Steven Hydra Probe. Coaxial impedance dielectric reflectometry -US-UMB,92030,GRP_INST,INST_FIRMWARE,Instrument firmware version at installation -US-UMB,92030,GRP_INST,INST_SAMPLING_INT,600 -US-UMB,92030,GRP_INST,INST_AVERAGING_INT,1800 -US-UMB,92030,GRP_INST,INST_HEAT,Unheated -US-UMB,92030,GRP_INST,INST_SHIELDING,None -US-UMB,92030,GRP_INST,INST_ASPIRATION,None -US-UMB,92110,GRP_INST,INST_MODEL,SWC-Other -US-UMB,92110,GRP_INST,INST_SN,SWC_AOS_2 -US-UMB,92110,GRP_INST,INST_DATE,20090323 -US-UMB,92110,GRP_INST,INST_COMMENT,Steven Hydra Probe. Coaxial impedance dielectric reflectometry -US-UMB,92110,GRP_INST,INST_FIRMWARE,Instrument firmware version at installation -US-UMB,92110,GRP_INST,INST_SAMPLING_INT,600 -US-UMB,92110,GRP_INST,INST_AVERAGING_INT,1800 -US-UMB,92110,GRP_INST,INST_HEAT,Unheated -US-UMB,92110,GRP_INST,INST_SHIELDING,None -US-UMB,92110,GRP_INST,INST_ASPIRATION,None -US-UMB,92042,GRP_INST,INST_MODEL,SWC-Other -US-UMB,92042,GRP_INST,INST_SN,SWC_AOS_3 -US-UMB,92042,GRP_INST,INST_DATE,20090323 -US-UMB,92042,GRP_INST,INST_COMMENT,Steven Hydra Probe. Coaxial impedance dielectric reflectometry -US-UMB,92042,GRP_INST,INST_FIRMWARE,Instrument firmware version at installation -US-UMB,92042,GRP_INST,INST_SAMPLING_INT,600 -US-UMB,92042,GRP_INST,INST_AVERAGING_INT,1800 -US-UMB,92042,GRP_INST,INST_HEAT,Unheated -US-UMB,92042,GRP_INST,INST_SHIELDING,None -US-UMB,92042,GRP_INST,INST_ASPIRATION,None -US-UMB,92099,GRP_INST,INST_MODEL,TEMP-Other -US-UMB,92099,GRP_INST,INST_SN,SWC_AOS_3 -US-UMB,92099,GRP_INST,INST_DATE,20090323 -US-UMB,92099,GRP_INST,INST_COMMENT,Steven Hydra Probe. Coaxial impedance dielectric reflectometry -US-UMB,92099,GRP_INST,INST_FIRMWARE,Instrument firmware version at installation -US-UMB,92099,GRP_INST,INST_SAMPLING_INT,600 -US-UMB,92099,GRP_INST,INST_AVERAGING_INT,1800 -US-UMB,92099,GRP_INST,INST_HEAT,Unheated -US-UMB,92099,GRP_INST,INST_SHIELDING,None -US-UMB,92099,GRP_INST,INST_ASPIRATION,None -US-UMB,92039,GRP_INST,INST_MODEL,TEMP-Other -US-UMB,92039,GRP_INST,INST_SN,SWC_AOS_4 -US-UMB,92039,GRP_INST,INST_DATE,20090323 -US-UMB,92039,GRP_INST,INST_COMMENT,Steven Hydra Probe. Coaxial impedance dielectric reflectometry -US-UMB,92039,GRP_INST,INST_FIRMWARE,Instrument firmware version at installation -US-UMB,92039,GRP_INST,INST_SAMPLING_INT,600 -US-UMB,92039,GRP_INST,INST_AVERAGING_INT,1800 -US-UMB,92039,GRP_INST,INST_HEAT,Unheated -US-UMB,92039,GRP_INST,INST_SHIELDING,None -US-UMB,92039,GRP_INST,INST_ASPIRATION,None -US-UMB,92056,GRP_INST,INST_MODEL,SWC-Other -US-UMB,92056,GRP_INST,INST_SN,SWC_AOS_4 -US-UMB,92056,GRP_INST,INST_DATE,20090323 -US-UMB,92056,GRP_INST,INST_COMMENT,Steven Hydra Probe. Coaxial impedance dielectric reflectometry -US-UMB,92056,GRP_INST,INST_FIRMWARE,Instrument firmware version at installation -US-UMB,92056,GRP_INST,INST_SAMPLING_INT,600 -US-UMB,92056,GRP_INST,INST_AVERAGING_INT,1800 -US-UMB,92056,GRP_INST,INST_HEAT,Unheated -US-UMB,92056,GRP_INST,INST_SHIELDING,None -US-UMB,92056,GRP_INST,INST_ASPIRATION,None -US-UMB,92025,GRP_INST,INST_MODEL,TEMP-Other -US-UMB,92025,GRP_INST,INST_SN,SWC_AOS_5 -US-UMB,92025,GRP_INST,INST_DATE,20090323 -US-UMB,92025,GRP_INST,INST_COMMENT,Steven Hydra Probe. Coaxial impedance dielectric reflectometry -US-UMB,92025,GRP_INST,INST_FIRMWARE,Instrument firmware version at installation -US-UMB,92025,GRP_INST,INST_SAMPLING_INT,600 -US-UMB,92025,GRP_INST,INST_AVERAGING_INT,1800 -US-UMB,92025,GRP_INST,INST_HEAT,Unheated -US-UMB,92025,GRP_INST,INST_SHIELDING,None -US-UMB,92025,GRP_INST,INST_ASPIRATION,None -US-UMB,92048,GRP_INST,INST_MODEL,SWC-Other -US-UMB,92048,GRP_INST,INST_SN,SWC_AOS_5 -US-UMB,92048,GRP_INST,INST_DATE,20090323 -US-UMB,92048,GRP_INST,INST_COMMENT,Steven Hydra Probe. Coaxial impedance dielectric reflectometry -US-UMB,92048,GRP_INST,INST_FIRMWARE,Instrument firmware version at installation -US-UMB,92048,GRP_INST,INST_SAMPLING_INT,600 -US-UMB,92048,GRP_INST,INST_AVERAGING_INT,1800 -US-UMB,92048,GRP_INST,INST_HEAT,Unheated -US-UMB,92048,GRP_INST,INST_SHIELDING,None -US-UMB,92048,GRP_INST,INST_ASPIRATION,None -US-UMB,92104,GRP_INST,INST_MODEL,SWC-Other -US-UMB,92104,GRP_INST,INST_SN,SWC_AOS_6 -US-UMB,92104,GRP_INST,INST_DATE,20090323 -US-UMB,92104,GRP_INST,INST_COMMENT,Steven Hydra Probe. Coaxial impedance dielectric reflectometry -US-UMB,92104,GRP_INST,INST_FIRMWARE,Instrument firmware version at installation -US-UMB,92104,GRP_INST,INST_SAMPLING_INT,600 -US-UMB,92104,GRP_INST,INST_AVERAGING_INT,1800 -US-UMB,92104,GRP_INST,INST_HEAT,Unheated -US-UMB,92104,GRP_INST,INST_SHIELDING,None -US-UMB,92104,GRP_INST,INST_ASPIRATION,None -US-UMB,92111,GRP_INST,INST_MODEL,TEMP-Other -US-UMB,92111,GRP_INST,INST_SN,SWC_AOS_6 -US-UMB,92111,GRP_INST,INST_DATE,20090323 -US-UMB,92111,GRP_INST,INST_COMMENT,Steven Hydra Probe. Coaxial impedance dielectric reflectometry -US-UMB,92111,GRP_INST,INST_FIRMWARE,Instrument firmware version at installation -US-UMB,92111,GRP_INST,INST_SAMPLING_INT,600 -US-UMB,92111,GRP_INST,INST_AVERAGING_INT,1800 -US-UMB,92111,GRP_INST,INST_HEAT,Unheated -US-UMB,92111,GRP_INST,INST_SHIELDING,None -US-UMB,92111,GRP_INST,INST_ASPIRATION,None -US-UMB,92038,GRP_INST,INST_MODEL,TEMP-Other -US-UMB,92038,GRP_INST,INST_SN,SWC_AOS_7 -US-UMB,92038,GRP_INST,INST_DATE,20090323 -US-UMB,92038,GRP_INST,INST_COMMENT,Steven Hydra Probe. Coaxial impedance dielectric reflectometry -US-UMB,92038,GRP_INST,INST_FIRMWARE,Instrument firmware version at installation -US-UMB,92038,GRP_INST,INST_SAMPLING_INT,600 -US-UMB,92038,GRP_INST,INST_AVERAGING_INT,1800 -US-UMB,92038,GRP_INST,INST_HEAT,Unheated -US-UMB,92038,GRP_INST,INST_SHIELDING,None -US-UMB,92038,GRP_INST,INST_ASPIRATION,None -US-UMB,92052,GRP_INST,INST_MODEL,SWC-Other -US-UMB,92052,GRP_INST,INST_SN,SWC_AOS_7 -US-UMB,92052,GRP_INST,INST_DATE,20090323 -US-UMB,92052,GRP_INST,INST_COMMENT,Steven Hydra Probe. Coaxial impedance dielectric reflectometry -US-UMB,92052,GRP_INST,INST_FIRMWARE,Instrument firmware version at installation -US-UMB,92052,GRP_INST,INST_SAMPLING_INT,600 -US-UMB,92052,GRP_INST,INST_AVERAGING_INT,1800 -US-UMB,92052,GRP_INST,INST_HEAT,Unheated -US-UMB,92052,GRP_INST,INST_SHIELDING,None -US-UMB,92052,GRP_INST,INST_ASPIRATION,None -US-UMB,92045,GRP_INST,INST_MODEL,SWC-Other -US-UMB,92045,GRP_INST,INST_SN,SWC_AOS_8 -US-UMB,92045,GRP_INST,INST_DATE,20090323 -US-UMB,92045,GRP_INST,INST_COMMENT,Steven Hydra Probe. Coaxial impedance dielectric reflectometry -US-UMB,92045,GRP_INST,INST_FIRMWARE,Instrument firmware version at installation -US-UMB,92045,GRP_INST,INST_SAMPLING_INT,600 -US-UMB,92045,GRP_INST,INST_AVERAGING_INT,1800 -US-UMB,92045,GRP_INST,INST_HEAT,Unheated -US-UMB,92045,GRP_INST,INST_SHIELDING,None -US-UMB,92045,GRP_INST,INST_ASPIRATION,None -US-UMB,92109,GRP_INST,INST_MODEL,TEMP-Other -US-UMB,92109,GRP_INST,INST_SN,SWC_AOS_8 -US-UMB,92109,GRP_INST,INST_DATE,20090323 -US-UMB,92109,GRP_INST,INST_COMMENT,Steven Hydra Probe. Coaxial impedance dielectric reflectometry -US-UMB,92109,GRP_INST,INST_FIRMWARE,Instrument firmware version at installation -US-UMB,92109,GRP_INST,INST_SAMPLING_INT,600 -US-UMB,92109,GRP_INST,INST_AVERAGING_INT,1800 -US-UMB,92109,GRP_INST,INST_HEAT,Unheated -US-UMB,92109,GRP_INST,INST_SHIELDING,None -US-UMB,92109,GRP_INST,INST_ASPIRATION,None -US-UMB,92018,GRP_INST,INST_MODEL,SWC-Other -US-UMB,92018,GRP_INST,INST_SN,SWC_AOS_9 -US-UMB,92018,GRP_INST,INST_DATE,20090323 -US-UMB,92018,GRP_INST,INST_COMMENT,Steven Hydra Probe. Coaxial impedance dielectric reflectometry -US-UMB,92018,GRP_INST,INST_FIRMWARE,Instrument firmware version at installation -US-UMB,92018,GRP_INST,INST_SAMPLING_INT,600 -US-UMB,92018,GRP_INST,INST_AVERAGING_INT,1800 -US-UMB,92018,GRP_INST,INST_HEAT,Unheated -US-UMB,92018,GRP_INST,INST_SHIELDING,None -US-UMB,92018,GRP_INST,INST_ASPIRATION,None -US-UMB,92063,GRP_INST,INST_MODEL,TEMP-Other -US-UMB,92063,GRP_INST,INST_SN,SWC_AOS_9 -US-UMB,92063,GRP_INST,INST_DATE,20090323 -US-UMB,92063,GRP_INST,INST_COMMENT,Steven Hydra Probe. Coaxial impedance dielectric reflectometry -US-UMB,92063,GRP_INST,INST_FIRMWARE,Instrument firmware version at installation -US-UMB,92063,GRP_INST,INST_SAMPLING_INT,600 -US-UMB,92063,GRP_INST,INST_AVERAGING_INT,1800 -US-UMB,92063,GRP_INST,INST_HEAT,Unheated -US-UMB,92063,GRP_INST,INST_SHIELDING,None -US-UMB,92063,GRP_INST,INST_ASPIRATION,None -US-UMB,92041,GRP_INST,INST_MODEL,TEMP-ElectResis -US-UMB,92041,GRP_INST,INST_SN,TEMP1 -US-UMB,92041,GRP_INST,INST_DATE,19990316 -US-UMB,92041,GRP_INST,INST_COMMENT,HPO-43 -US-UMB,92041,GRP_INST,INST_SAMPLING_INT,10 -US-UMB,92041,GRP_INST,INST_AVERAGING_INT,600 -US-UMB,92041,GRP_INST,INST_HEAT,Unheated -US-UMB,92041,GRP_INST,INST_SHIELDING,Radiation -US-UMB,92041,GRP_INST,INST_ASPIRATION,Ventilation -US-UMB,92088,GRP_INST,INST_MODEL,TEMP-ElectResis -US-UMB,92088,GRP_INST,INST_SN,TEMP10 -US-UMB,92088,GRP_INST,INST_DATE,20030503 -US-UMB,92088,GRP_INST,INST_COMMENT,HPO-43 -US-UMB,92088,GRP_INST,INST_SAMPLING_INT,10 -US-UMB,92088,GRP_INST,INST_AVERAGING_INT,600 -US-UMB,92088,GRP_INST,INST_HEAT,Unheated -US-UMB,92088,GRP_INST,INST_SHIELDING,Radiation -US-UMB,92088,GRP_INST,INST_ASPIRATION,Ventilation -US-UMB,92069,GRP_INST,INST_MODEL,TEMP-ElectResis -US-UMB,92069,GRP_INST,INST_SN,TEMP11 -US-UMB,92069,GRP_INST,INST_DATE,20030503 -US-UMB,92069,GRP_INST,INST_COMMENT,HPO-43 -US-UMB,92069,GRP_INST,INST_SAMPLING_INT,10 -US-UMB,92069,GRP_INST,INST_AVERAGING_INT,600 -US-UMB,92069,GRP_INST,INST_HEAT,Unheated -US-UMB,92069,GRP_INST,INST_SHIELDING,Radiation -US-UMB,92069,GRP_INST,INST_ASPIRATION,Ventilation -US-UMB,92115,GRP_INST,INST_MODEL,TEMP-Other -US-UMB,92115,GRP_INST,INST_SN,TEMP12 -US-UMB,92115,GRP_INST,INST_DATE,20161202 -US-UMB,92115,GRP_INST,INST_COMMENT,Rotronic HC2-S3 temperature/Relative Humidity sensor -US-UMB,92115,GRP_INST,INST_FIRMWARE,Instrument firmware version at installation -US-UMB,92115,GRP_INST,INST_SAMPLING_INT,0.1 -US-UMB,92115,GRP_INST,INST_AVERAGING_INT,600 -US-UMB,92115,GRP_INST,INST_HEAT,Unheated -US-UMB,92115,GRP_INST,INST_SHIELDING,Radiation -US-UMB,92115,GRP_INST,INST_ASPIRATION,Ventilation -US-UMB,92093,GRP_INST,INST_MODEL,TEMP-Other -US-UMB,92093,GRP_INST,INST_SN,TEMP13 -US-UMB,92093,GRP_INST,INST_DATE,20161205 -US-UMB,92093,GRP_INST,INST_COMMENT,Rotronic HC2-S3 temperature/Relative Humidity sensor -US-UMB,92093,GRP_INST,INST_FIRMWARE,Instrument firmware version at installation -US-UMB,92093,GRP_INST,INST_SAMPLING_INT,2 -US-UMB,92093,GRP_INST,INST_AVERAGING_INT,60 -US-UMB,92093,GRP_INST,INST_HEAT,Unheated -US-UMB,92093,GRP_INST,INST_SHIELDING,Radiation -US-UMB,92093,GRP_INST,INST_ASPIRATION,Ventilation -US-UMB,92068,GRP_INST,INST_MODEL,TEMP-ElectResis -US-UMB,92068,GRP_INST,INST_SN,TEMP2 -US-UMB,92068,GRP_INST,INST_DATE,19990316 -US-UMB,92068,GRP_INST,INST_COMMENT,HPO-43 -US-UMB,92068,GRP_INST,INST_SAMPLING_INT,10 -US-UMB,92068,GRP_INST,INST_AVERAGING_INT,600 -US-UMB,92068,GRP_INST,INST_HEAT,Unheated -US-UMB,92068,GRP_INST,INST_SHIELDING,Radiation -US-UMB,92068,GRP_INST,INST_ASPIRATION,Ventilation -US-UMB,92049,GRP_INST,INST_MODEL,TEMP-ElectResis -US-UMB,92049,GRP_INST,INST_SN,TEMP3 -US-UMB,92049,GRP_INST,INST_DATE,19990316 -US-UMB,92049,GRP_INST,INST_COMMENT,HPO-43 -US-UMB,92049,GRP_INST,INST_SAMPLING_INT,10 -US-UMB,92049,GRP_INST,INST_AVERAGING_INT,600 -US-UMB,92049,GRP_INST,INST_HEAT,Unheated -US-UMB,92049,GRP_INST,INST_SHIELDING,Radiation -US-UMB,92049,GRP_INST,INST_ASPIRATION,Ventilation -US-UMB,92090,GRP_INST,INST_MODEL,TEMP-ElectResis -US-UMB,92090,GRP_INST,INST_SN,TEMP4 -US-UMB,92090,GRP_INST,INST_DATE,19990316 -US-UMB,92090,GRP_INST,INST_COMMENT,HPO-43 -US-UMB,92090,GRP_INST,INST_SAMPLING_INT,10 -US-UMB,92090,GRP_INST,INST_AVERAGING_INT,600 -US-UMB,92090,GRP_INST,INST_HEAT,Unheated -US-UMB,92090,GRP_INST,INST_SHIELDING,Radiation -US-UMB,92090,GRP_INST,INST_ASPIRATION,Ventilation -US-UMB,92131,GRP_INST,INST_MODEL,TEMP-ElectResis -US-UMB,92131,GRP_INST,INST_SN,TEMP5 -US-UMB,92131,GRP_INST,INST_DATE,19990316 -US-UMB,92131,GRP_INST,INST_COMMENT,HPO-43 -US-UMB,92131,GRP_INST,INST_SAMPLING_INT,10 -US-UMB,92131,GRP_INST,INST_AVERAGING_INT,600 -US-UMB,92131,GRP_INST,INST_HEAT,Unheated -US-UMB,92131,GRP_INST,INST_SHIELDING,Radiation -US-UMB,92131,GRP_INST,INST_ASPIRATION,Ventilation -US-UMB,92075,GRP_INST,INST_MODEL,TEMP-ElectResis -US-UMB,92075,GRP_INST,INST_SN,TEMP6 -US-UMB,92075,GRP_INST,INST_DATE,20021219 -US-UMB,92075,GRP_INST,INST_COMMENT,HPO-43 -US-UMB,92075,GRP_INST,INST_SAMPLING_INT,10 -US-UMB,92075,GRP_INST,INST_AVERAGING_INT,600 -US-UMB,92075,GRP_INST,INST_HEAT,Unheated -US-UMB,92075,GRP_INST,INST_SHIELDING,Radiation -US-UMB,92075,GRP_INST,INST_ASPIRATION,Ventilation -US-UMB,92079,GRP_INST,INST_MODEL,TEMP-ElectResis -US-UMB,92079,GRP_INST,INST_SN,TEMP7 -US-UMB,92079,GRP_INST,INST_DATE,20030503 -US-UMB,92079,GRP_INST,INST_COMMENT,HPO-43 -US-UMB,92079,GRP_INST,INST_SAMPLING_INT,10 -US-UMB,92079,GRP_INST,INST_AVERAGING_INT,600 -US-UMB,92079,GRP_INST,INST_HEAT,Unheated -US-UMB,92079,GRP_INST,INST_SHIELDING,Radiation -US-UMB,92079,GRP_INST,INST_ASPIRATION,Ventilation -US-UMB,92127,GRP_INST,INST_MODEL,TEMP-ElectResis -US-UMB,92127,GRP_INST,INST_SN,TEMP8 -US-UMB,92127,GRP_INST,INST_DATE,20030503 -US-UMB,92127,GRP_INST,INST_COMMENT,HPO-43 -US-UMB,92127,GRP_INST,INST_SAMPLING_INT,10 -US-UMB,92127,GRP_INST,INST_AVERAGING_INT,600 -US-UMB,92127,GRP_INST,INST_HEAT,Unheated -US-UMB,92127,GRP_INST,INST_SHIELDING,Radiation -US-UMB,92127,GRP_INST,INST_ASPIRATION,Ventilation -US-UMB,92074,GRP_INST,INST_MODEL,TEMP-ElectResis -US-UMB,92074,GRP_INST,INST_SN,TEMP9 -US-UMB,92074,GRP_INST,INST_DATE,20030503 -US-UMB,92074,GRP_INST,INST_COMMENT,HPO-43 -US-UMB,92074,GRP_INST,INST_SAMPLING_INT,10 -US-UMB,92074,GRP_INST,INST_AVERAGING_INT,600 -US-UMB,92074,GRP_INST,INST_HEAT,Unheated -US-UMB,92074,GRP_INST,INST_SHIELDING,Radiation -US-UMB,92074,GRP_INST,INST_ASPIRATION,Ventilation -US-UMB,92058,GRP_INST,INST_MODEL,PREC-OpticGauge -US-UMB,92058,GRP_INST,INST_SN,THIES1 -US-UMB,92058,GRP_INST,INST_DATE,20100627 -US-UMB,92058,GRP_INST,INST_COMMENT,Thies CLIMA 5.4103.20.041 -US-UMB,92058,GRP_INST,INST_SAMPLING_INT,0.1 -US-UMB,92058,GRP_INST,INST_AVERAGING_INT,10 -US-UMB,92058,GRP_INST,INST_HEAT,Unheated -US-UMB,92058,GRP_INST,INST_SHIELDING,None -US-UMB,92058,GRP_INST,INST_ASPIRATION,None -US-UMB,92031,GRP_INST,INST_MODEL,PREC-TipBucGauge -US-UMB,92031,GRP_INST,INST_SN,TIP1 -US-UMB,92031,GRP_INST,INST_DATE,19990101 -US-UMB,92031,GRP_INST,INST_COMMENT,Texas Electronics TE25MM -US-UMB,92031,GRP_INST,INST_AVERAGING_INT,600 -US-UMB,92031,GRP_INST,INST_HEAT,Unheated -US-UMB,92031,GRP_INST,INST_SHIELDING,None -US-UMB,92031,GRP_INST,INST_ASPIRATION,None -US-UMB,92059,GRP_INST,INST_MODEL,WIND-CupAn -US-UMB,92059,GRP_INST,INST_SN,WIND1 -US-UMB,92059,GRP_INST,INST_DATE,20000308 -US-UMB,92059,GRP_INST,INST_COMMENT,Met One 034A Windset -US-UMB,92059,GRP_INST,INST_SAMPLING_INT,10 -US-UMB,92059,GRP_INST,INST_AVERAGING_INT,600 -US-UMB,92059,GRP_INST,INST_HEAT,Unheated -US-UMB,92059,GRP_INST,INST_SHIELDING,None -US-UMB,92059,GRP_INST,INST_ASPIRATION,None -US-UMB,92065,GRP_INST,INST_MODEL,WIND-CupAn -US-UMB,92065,GRP_INST,INST_SN,WIND2 -US-UMB,92065,GRP_INST,INST_DATE,20000308 -US-UMB,92065,GRP_INST,INST_COMMENT,Met One 034A Windset -US-UMB,92065,GRP_INST,INST_SAMPLING_INT,10 -US-UMB,92065,GRP_INST,INST_AVERAGING_INT,600 -US-UMB,92065,GRP_INST,INST_HEAT,Unheated -US-UMB,92065,GRP_INST,INST_SHIELDING,None -US-UMB,92065,GRP_INST,INST_ASPIRATION,None -US-UMB,92147,GRP_INST,INST_MODEL,WIND-CupAn -US-UMB,92147,GRP_INST,INST_SN,WIND3 -US-UMB,92147,GRP_INST,INST_DATE,20000308 -US-UMB,92147,GRP_INST,INST_COMMENT,Met One 034A Windset -US-UMB,92147,GRP_INST,INST_SAMPLING_INT,10 -US-UMB,92147,GRP_INST,INST_AVERAGING_INT,600 -US-UMB,92147,GRP_INST,INST_HEAT,Unheated -US-UMB,92147,GRP_INST,INST_SHIELDING,None -US-UMB,92147,GRP_INST,INST_ASPIRATION,None -US-UMB,92040,GRP_INST,INST_MODEL,WIND-CupAn -US-UMB,92040,GRP_INST,INST_SN,WIND4 -US-UMB,92040,GRP_INST,INST_DATE,20001102 -US-UMB,92040,GRP_INST,INST_COMMENT,Met One 034A Windset -US-UMB,92040,GRP_INST,INST_SAMPLING_INT,10 -US-UMB,92040,GRP_INST,INST_AVERAGING_INT,600 -US-UMB,92040,GRP_INST,INST_HEAT,Unheated -US-UMB,92040,GRP_INST,INST_SHIELDING,None -US-UMB,92040,GRP_INST,INST_ASPIRATION,None -US-UMB,18779,GRP_LAI,LAI_TYPE,LAI -US-UMB,18780,GRP_LAI,LAI_TYPE,LAI -US-UMB,18781,GRP_LAI,LAI_TYPE,LAI -US-UMB,18782,GRP_LAI,LAI_TYPE,LAI -US-UMB,18783,GRP_LAI,LAI_TYPE,LAI -US-UMB,18784,GRP_LAI,LAI_TYPE,LAI -US-UMB,18785,GRP_LAI,LAI_TYPE,LAI -US-UMB,18786,GRP_LAI,LAI_TYPE,LAI -US-UMB,18787,GRP_LAI,LAI_TYPE,LAI -US-UMB,18788,GRP_LAI,LAI_TYPE,LAI -US-UMB,18789,GRP_LAI,LAI_TYPE,LAI -US-UMB,18790,GRP_LAI,LAI_TYPE,LAI -US-UMB,18791,GRP_LAI,LAI_TYPE,LAI -US-UMB,18792,GRP_LAI,LAI_TYPE,LAI -US-UMB,18793,GRP_LAI,LAI_TYPE,LAI -US-UMB,18794,GRP_LAI,LAI_TYPE,LAI -US-UMB,18795,GRP_LAI,LAI_TYPE,LAI -US-UMB,18796,GRP_LAI,LAI_TYPE,LAI -US-UMB,18797,GRP_LAI,LAI_TYPE,LAI -US-UMB,18798,GRP_LAI,LAI_TYPE,LAI -US-UMB,18799,GRP_LAI,LAI_TYPE,LAI -US-UMB,18800,GRP_LAI,LAI_TYPE,LAI -US-UMB,18801,GRP_LAI,LAI_TYPE,LAI -US-UMB,18802,GRP_LAI,LAI_TYPE,LAI -US-UMB,18803,GRP_LAI,LAI_TYPE,LAI -US-UMB,18804,GRP_LAI,LAI_TYPE,LAI -US-UMB,18805,GRP_LAI,LAI_TYPE,LAI -US-UMB,18806,GRP_LAI,LAI_TYPE,LAI -US-UMB,18807,GRP_LAI,LAI_TYPE,LAI -US-UMB,18808,GRP_LAI,LAI_TYPE,LAI -US-UMB,18809,GRP_LAI,LAI_TYPE,LAI -US-UMB,18810,GRP_LAI,LAI_TYPE,LAI -US-UMB,18811,GRP_LAI,LAI_TYPE,LAI -US-UMB,18812,GRP_LAI,LAI_TYPE,LAI -US-UMB,18813,GRP_LAI,LAI_TYPE,LAI -US-UMB,18814,GRP_LAI,LAI_TYPE,LAI -US-UMB,18815,GRP_LAI,LAI_TYPE,LAI -US-UMB,18816,GRP_LAI,LAI_TYPE,LAI -US-UMB,18817,GRP_LAI,LAI_TYPE,LAI -US-UMB,18818,GRP_LAI,LAI_TYPE,LAI -US-UMB,18819,GRP_LAI,LAI_TYPE,LAI -US-UMB,18820,GRP_LAI,LAI_TYPE,LAI -US-UMB,18821,GRP_LAI,LAI_TYPE,LAI -US-UMB,18822,GRP_LAI,LAI_TYPE,LAI -US-UMB,18823,GRP_LAI,LAI_TYPE,LAI -US-UMB,18824,GRP_LAI,LAI_TYPE,LAI -US-UMB,18825,GRP_LAI,LAI_TYPE,LAI -US-UMB,18826,GRP_LAI,LAI_TYPE,LAI -US-UMB,18827,GRP_LAI,LAI_TYPE,LAI -US-UMB,18828,GRP_LAI,LAI_TYPE,LAI -US-UMB,18829,GRP_LAI,LAI_TYPE,LAI -US-UMB,18830,GRP_LAI,LAI_TYPE,LAI -US-UMB,18831,GRP_LAI,LAI_TYPE,LAI -US-UMB,18832,GRP_LAI,LAI_TYPE,LAI -US-UMB,18833,GRP_LAI,LAI_TYPE,LAI -US-UMB,18834,GRP_LAI,LAI_TYPE,LAI -US-UMB,18835,GRP_LAI,LAI_TYPE,LAI -US-UMB,18836,GRP_LAI,LAI_TYPE,LAI -US-UMB,18837,GRP_LAI,LAI_TYPE,LAI -US-UMB,18838,GRP_LAI,LAI_TYPE,LAI -US-UMB,18839,GRP_LAI,LAI_TYPE,LAI -US-UMB,18840,GRP_LAI,LAI_TYPE,LAI -US-UMB,18841,GRP_LAI,LAI_TYPE,LAI -US-UMB,18842,GRP_LAI,LAI_TYPE,LAI -US-UMB,18843,GRP_LAI,LAI_TYPE,LAI -US-UMB,18844,GRP_LAI,LAI_TYPE,LAI -US-UMB,18845,GRP_LAI,LAI_TYPE,LAI -US-UMB,18846,GRP_LAI,LAI_TYPE,LAI -US-UMB,18847,GRP_LAI,LAI_TYPE,LAI -US-UMB,18848,GRP_LAI,LAI_TYPE,LAI -US-UMB,18849,GRP_LAI,LAI_TYPE,LAI -US-UMB,18850,GRP_LAI,LAI_TYPE,LAI -US-UMB,18851,GRP_LAI,LAI_TYPE,LAI -US-UMB,18859,GRP_LAI,LAI_TYPE,LAI -US-UMB,18866,GRP_LAI,LAI_TYPE,LAI -US-UMB,18873,GRP_LAI,LAI_TYPE,LAI -US-UMB,18878,GRP_LAI,LAI_TYPE,LAI -US-UMB,18884,GRP_LAI,LAI_TYPE,LAI -US-UMB,18889,GRP_LAI,LAI_TYPE,LAI -US-UMB,18894,GRP_LAI,LAI_TYPE,LAI -US-UMB,18901,GRP_LAI,LAI_TYPE,LAI -US-UMB,18961,GRP_LAI,LAI_TYPE,LAI -US-UMB,18962,GRP_LAI,LAI_TYPE,LAI -US-UMB,18963,GRP_LAI,LAI_TYPE,LAI -US-UMB,18964,GRP_LAI,LAI_TYPE,LAI -US-UMB,18965,GRP_LAI,LAI_TYPE,LAI -US-UMB,18966,GRP_LAI,LAI_TYPE,LAI -US-UMB,18967,GRP_LAI,LAI_TYPE,LAI -US-UMB,18968,GRP_LAI,LAI_TYPE,LAI -US-UMB,18969,GRP_LAI,LAI_TYPE,LAI -US-UMB,18970,GRP_LAI,LAI_TYPE,LAI -US-UMB,18971,GRP_LAI,LAI_TYPE,LAI -US-UMB,18972,GRP_LAI,LAI_TYPE,LAI -US-UMB,18973,GRP_LAI,LAI_TYPE,LAI -US-UMB,18974,GRP_LAI,LAI_TYPE,LAI -US-UMB,18975,GRP_LAI,LAI_TYPE,LAI -US-UMB,18976,GRP_LAI,LAI_TYPE,LAI -US-UMB,18977,GRP_LAI,LAI_TYPE,LAI -US-UMB,18978,GRP_LAI,LAI_TYPE,LAI -US-UMB,18979,GRP_LAI,LAI_TYPE,LAI -US-UMB,18980,GRP_LAI,LAI_TYPE,LAI -US-UMB,18981,GRP_LAI,LAI_TYPE,LAI -US-UMB,18982,GRP_LAI,LAI_TYPE,LAI -US-UMB,18983,GRP_LAI,LAI_TYPE,LAI -US-UMB,18984,GRP_LAI,LAI_TYPE,LAI -US-UMB,18985,GRP_LAI,LAI_TYPE,LAI -US-UMB,18986,GRP_LAI,LAI_TYPE,LAI -US-UMB,18987,GRP_LAI,LAI_TYPE,LAI -US-UMB,18988,GRP_LAI,LAI_TYPE,LAI -US-UMB,18989,GRP_LAI,LAI_TYPE,LAI -US-UMB,18990,GRP_LAI,LAI_TYPE,LAI -US-UMB,18991,GRP_LAI,LAI_TYPE,LAI -US-UMB,18992,GRP_LAI,LAI_TYPE,LAI -US-UMB,18993,GRP_LAI,LAI_TYPE,LAI -US-UMB,18994,GRP_LAI,LAI_TYPE,LAI -US-UMB,18995,GRP_LAI,LAI_TYPE,LAI -US-UMB,18996,GRP_LAI,LAI_TYPE,LAI -US-UMB,18997,GRP_LAI,LAI_TYPE,LAI -US-UMB,18998,GRP_LAI,LAI_TYPE,LAI -US-UMB,18999,GRP_LAI,LAI_TYPE,LAI -US-UMB,19000,GRP_LAI,LAI_TYPE,LAI -US-UMB,19001,GRP_LAI,LAI_TYPE,LAI -US-UMB,19002,GRP_LAI,LAI_TYPE,LAI -US-UMB,19003,GRP_LAI,LAI_TYPE,LAI -US-UMB,19004,GRP_LAI,LAI_TYPE,LAI -US-UMB,19005,GRP_LAI,LAI_TYPE,LAI -US-UMB,19006,GRP_LAI,LAI_TYPE,LAI -US-UMB,19007,GRP_LAI,LAI_TYPE,LAI -US-UMB,19008,GRP_LAI,LAI_TYPE,LAI -US-UMB,19009,GRP_LAI,LAI_TYPE,LAI -US-UMB,19010,GRP_LAI,LAI_TYPE,LAI -US-UMB,19011,GRP_LAI,LAI_TYPE,LAI -US-UMB,19012,GRP_LAI,LAI_TYPE,LAI -US-UMB,19013,GRP_LAI,LAI_TYPE,LAI -US-UMB,19014,GRP_LAI,LAI_TYPE,LAI -US-UMB,19015,GRP_LAI,LAI_TYPE,LAI -US-UMB,19016,GRP_LAI,LAI_TYPE,LAI -US-UMB,19017,GRP_LAI,LAI_TYPE,LAI -US-UMB,19018,GRP_LAI,LAI_TYPE,LAI -US-UMB,19019,GRP_LAI,LAI_TYPE,LAI -US-UMB,19020,GRP_LAI,LAI_TYPE,LAI -US-UMB,19021,GRP_LAI,LAI_TYPE,LAI -US-UMB,19022,GRP_LAI,LAI_TYPE,LAI -US-UMB,19023,GRP_LAI,LAI_TYPE,LAI -US-UMB,19024,GRP_LAI,LAI_TYPE,LAI -US-UMB,19025,GRP_LAI,LAI_TYPE,LAI -US-UMB,19026,GRP_LAI,LAI_TYPE,LAI -US-UMB,19027,GRP_LAI,LAI_TYPE,LAI -US-UMB,19028,GRP_LAI,LAI_TYPE,LAI -US-UMB,19029,GRP_LAI,LAI_TYPE,LAI -US-UMB,19030,GRP_LAI,LAI_TYPE,LAI -US-UMB,19031,GRP_LAI,LAI_TYPE,LAI -US-UMB,19032,GRP_LAI,LAI_TYPE,LAI -US-UMB,19033,GRP_LAI,LAI_TYPE,LAI -US-UMB,19034,GRP_LAI,LAI_TYPE,LAI -US-UMB,19035,GRP_LAI,LAI_TYPE,LAI -US-UMB,19036,GRP_LAI,LAI_TYPE,LAI -US-UMB,19037,GRP_LAI,LAI_TYPE,LAI -US-UMB,19038,GRP_LAI,LAI_TYPE,LAI -US-UMB,19039,GRP_LAI,LAI_TYPE,LAI -US-UMB,19040,GRP_LAI,LAI_TYPE,LAI -US-UMB,19041,GRP_LAI,LAI_TYPE,LAI -US-UMB,19042,GRP_LAI,LAI_TYPE,LAI -US-UMB,19043,GRP_LAI,LAI_TYPE,LAI -US-UMB,19044,GRP_LAI,LAI_TYPE,LAI -US-UMB,19045,GRP_LAI,LAI_TYPE,LAI -US-UMB,19046,GRP_LAI,LAI_TYPE,LAI -US-UMB,19047,GRP_LAI,LAI_TYPE,LAI -US-UMB,19048,GRP_LAI,LAI_TYPE,LAI -US-UMB,19049,GRP_LAI,LAI_TYPE,LAI -US-UMB,19050,GRP_LAI,LAI_TYPE,LAI -US-UMB,19051,GRP_LAI,LAI_TYPE,LAI -US-UMB,19052,GRP_LAI,LAI_TYPE,LAI -US-UMB,19053,GRP_LAI,LAI_TYPE,LAI -US-UMB,19054,GRP_LAI,LAI_TYPE,LAI -US-UMB,19055,GRP_LAI,LAI_TYPE,LAI -US-UMB,19065,GRP_LAI,LAI_TYPE,LAI -US-UMB,19072,GRP_LAI,LAI_TYPE,LAI -US-UMB,19079,GRP_LAI,LAI_TYPE,LAI -US-UMB,19084,GRP_LAI,LAI_TYPE,LAI -US-UMB,19089,GRP_LAI,LAI_TYPE,LAI -US-UMB,19094,GRP_LAI,LAI_TYPE,LAI -US-UMB,19099,GRP_LAI,LAI_TYPE,LAI -US-UMB,19104,GRP_LAI,LAI_TYPE,LAI -US-UMB,18961,GRP_LAI,LAI_METHOD,36 - 1m^2 sublots within 60m of flux tower were sampled for bracken fern (Pteridium aquilinum) and the fronds measured with a LI-COR LI-3100 leaf area meter. Bracken fern is by far the most dominant plant by leaf area below 1m in ht at UMB. -US-UMB,18962,GRP_LAI,LAI_METHOD,36 - 1m^2 sublots within 60m of flux tower were sampled for bracken fern (Pteridium aquilinum) and the fronds measured with a LI-COR LI-3100 leaf area meter. Bracken fern is by far the most dominant plant by leaf area below 1m in ht at UMB. -US-UMB,18894,GRP_LAI,LAI_METHOD,"Litter traps, 1 each in 30 - 0.08 ha plots and 20 in a single 1.13 ha plot, at 1 m ht above forest floor and with an effective area of .264 m^2 were used to collect autumnal litter fall." -US-UMB,19084,GRP_LAI,LAI_METHOD,"Litter traps, 1 each in 30 - 0.08 ha plots and 20 in a single 1.13 ha plot, at 1 m ht above forest floor and with an effective area of .264 m^2 were used to collect autumnal litter fall." -US-UMB,18878,GRP_LAI,LAI_METHOD,"Litter traps, 1 each in 49 - 0.08 ha plots and 20 in a single 1.13 ha plot, at 1 m ht above forest floor and with an effective area of .264 m^2 were used to collect autumnal litter fall." -US-UMB,18889,GRP_LAI,LAI_METHOD,"Litter traps, 1 each in 49 - 0.08 ha plots and 20 in a single 1.13 ha plot, at 1 m ht above forest floor and with an effective area of .264 m^2 were used to collect autumnal litter fall." -US-UMB,19079,GRP_LAI,LAI_METHOD,"Litter traps, 1 each in 49 - 0.08 ha plots and 20 in a single 1.13 ha plot, at 1 m ht above forest floor and with an effective area of .264 m^2 were used to collect autumnal litter fall." -US-UMB,18884,GRP_LAI,LAI_METHOD,"Litter traps, 1 each in 50 - 0.08 ha plots and 20 in a single 1.13 ha plot, at 1 m ht above forest floor and with an effective area of .264 m^2 were used to collect autumnal litter fall." -US-UMB,19089,GRP_LAI,LAI_METHOD,"Litter traps, 1 each in 59 - 0.08 ha plots and 20 in a single 1.13 ha plot, at 30 cm ht above forest floor and with an effective area of .179 m^2 were used to collect autumnal litter fall." -US-UMB,19094,GRP_LAI,LAI_METHOD,"Litter traps, 1 each in 59 - 0.08 ha plots and 20 in a single 1.13 ha plot, at 30 cm ht above forest floor and with an effective area of .179 m^2 were used to collect autumnal litter fall." -US-UMB,18901,GRP_LAI,LAI_METHOD,"Litter traps, 1 each in 60 - 0.08 ha plots and 20 in a single 1.13 ha plot, at 30 cm ht above forest floor and with an effective area of .179 m^2 were used to collect autumnal litter fall." -US-UMB,19099,GRP_LAI,LAI_METHOD,"Litter traps, 1 each in 60 - 0.08 ha plots and 20 in a single 1.13 ha plot, at 30 cm ht above forest floor and with an effective area of .179 m^2 were used to collect autumnal litter fall." -US-UMB,19104,GRP_LAI,LAI_METHOD,"Litter traps, 1 each in 60 - 0.08 ha plots and 20 in a single 1.13 ha plot, at 30 cm ht above forest floor and with an effective area of .179 m^2 were used to collect autumnal litter fall." -US-UMB,18873,GRP_LAI,LAI_METHOD,"Litter traps, 3 each in 12 - 0.08 ha plots and 20 in a single 1.13 ha plot, at 1 m ht above forest floor and with an effective area of .264 m^2 were used to collect autumnal litter fall." -US-UMB,19065,GRP_LAI,LAI_METHOD,"Litter traps, 3 each in 14 - 0.08 ha plots and 20 in a single 1.13 ha plot, at 1 m ht above forest floor and with an effective area of .264 m^2 were used to collect autumnal litter fall." -US-UMB,19072,GRP_LAI,LAI_METHOD,"Litter traps, 3 each in 14 - 0.08 ha plots and 20 in a single 1.13 ha plot, at 1 m ht above forest floor and with an effective area of .264 m^2 were used to collect autumnal litter fall." -US-UMB,18851,GRP_LAI,LAI_METHOD,"Litter traps, 3 each in 15 - 0.08 ha plots and 20 in a single 1.13 ha plot, at 1 m ht above forest floor and with an effective area of .264 m^2 were used to collect autumnal litter fall." -US-UMB,18859,GRP_LAI,LAI_METHOD,"Litter traps, 3 each in 15 - 0.08 ha plots and 20 in a single 1.13 ha plot, at 1 m ht above forest floor and with an effective area of .264 m^2 were used to collect autumnal litter fall." -US-UMB,18866,GRP_LAI,LAI_METHOD,"Litter traps, 3 each in 15 - 0.08 ha plots and 20 in a single 1.13 ha plot, at 1 m ht above forest floor and with an effective area of .264 m^2 were used to collect autumnal litter fall." -US-UMB,18961,GRP_LAI,LAI_APPROACH,Direct -US-UMB,18962,GRP_LAI,LAI_APPROACH,Direct -US-UMB,18779,GRP_LAI,LAI_APPROACH,LAI_2000 -US-UMB,18780,GRP_LAI,LAI_APPROACH,LAI_2000 -US-UMB,18782,GRP_LAI,LAI_APPROACH,LAI_2000 -US-UMB,18783,GRP_LAI,LAI_APPROACH,LAI_2000 -US-UMB,18784,GRP_LAI,LAI_APPROACH,LAI_2000 -US-UMB,18785,GRP_LAI,LAI_APPROACH,LAI_2000 -US-UMB,18786,GRP_LAI,LAI_APPROACH,LAI_2000 -US-UMB,18787,GRP_LAI,LAI_APPROACH,LAI_2000 -US-UMB,18789,GRP_LAI,LAI_APPROACH,LAI_2000 -US-UMB,18790,GRP_LAI,LAI_APPROACH,LAI_2000 -US-UMB,18791,GRP_LAI,LAI_APPROACH,LAI_2000 -US-UMB,18792,GRP_LAI,LAI_APPROACH,LAI_2000 -US-UMB,18793,GRP_LAI,LAI_APPROACH,LAI_2000 -US-UMB,18794,GRP_LAI,LAI_APPROACH,LAI_2000 -US-UMB,18796,GRP_LAI,LAI_APPROACH,LAI_2000 -US-UMB,18797,GRP_LAI,LAI_APPROACH,LAI_2000 -US-UMB,18798,GRP_LAI,LAI_APPROACH,LAI_2000 -US-UMB,18799,GRP_LAI,LAI_APPROACH,LAI_2000 -US-UMB,18800,GRP_LAI,LAI_APPROACH,LAI_2000 -US-UMB,18801,GRP_LAI,LAI_APPROACH,LAI_2000 -US-UMB,18802,GRP_LAI,LAI_APPROACH,LAI_2000 -US-UMB,18803,GRP_LAI,LAI_APPROACH,LAI_2000 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-US-UMB,19020,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,150 -US-UMB,19013,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,152 -US-UMB,19014,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,152 -US-UMB,18802,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,153 -US-UMB,18811,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,155 -US-UMB,18781,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,16 -US-UMB,18788,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,16 -US-UMB,18795,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,16 -US-UMB,18806,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,16 -US-UMB,18822,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,16 -US-UMB,18828,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,16 -US-UMB,18840,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,16 -US-UMB,18851,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,16 -US-UMB,18859,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,16 -US-UMB,18866,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,16 -US-UMB,18969,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,16 -US-UMB,18976,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,16 -US-UMB,18982,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,16 -US-UMB,18997,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,16 -US-UMB,19011,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,16 -US-UMB,19025,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,16 -US-UMB,19039,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,16 -US-UMB,19053,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,16 -US-UMB,19054,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,16 -US-UMB,19055,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,16 -US-UMB,19017,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,160 -US-UMB,19015,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,161 -US-UMB,18894,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,31 -US-UMB,19084,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,31 -US-UMB,18878,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,50 -US-UMB,18889,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,50 -US-UMB,19079,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,50 -US-UMB,18884,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,51 -US-UMB,19089,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,60 -US-UMB,19094,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,60 -US-UMB,18901,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,61 -US-UMB,19099,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,61 -US-UMB,19104,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,61 -US-UMB,18791,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,82 -US-UMB,18975,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.23 -US-UMB,18981,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.36 -US-UMB,19013,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.37 -US-UMB,18787,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.4 -US-UMB,18793,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.42 -US-UMB,18821,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.43 -US-UMB,18968,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.434511 -US-UMB,18967,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.436348 -US-UMB,18807,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.44 -US-UMB,18808,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.44 -US-UMB,18966,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.448999 -US-UMB,18780,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.45 -US-UMB,18800,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.45 -US-UMB,18986,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.45 -US-UMB,19021,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.45 -US-UMB,19024,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.45 -US-UMB,19026,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.45 -US-UMB,18794,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.46 -US-UMB,18803,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.46 -US-UMB,18804,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.46 -US-UMB,18819,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.46 -US-UMB,18820,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.46 -US-UMB,18974,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.46 -US-UMB,19023,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.46 -US-UMB,18779,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.47 -US-UMB,18801,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.47 -US-UMB,18980,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.47 -US-UMB,18810,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.48 -US-UMB,18979,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.48 -US-UMB,19022,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.48 -US-UMB,19027,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.48 -US-UMB,18802,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.49 -US-UMB,18805,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.49 -US-UMB,18809,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.49 -US-UMB,19014,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.49 -US-UMB,19020,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.49 -US-UMB,18811,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.5 -US-UMB,19015,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.51 -US-UMB,18792,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.52 -US-UMB,18785,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.53 -US-UMB,19033,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.53 -US-UMB,18783,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.54 -US-UMB,18786,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.54 -US-UMB,18789,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.54 -US-UMB,18791,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.54 -US-UMB,18796,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.54 -US-UMB,19034,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.54 -US-UMB,18784,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.55 -US-UMB,18797,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.55 -US-UMB,18799,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.55 -US-UMB,18985,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.55 -US-UMB,18970,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.56 -US-UMB,18984,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.56 -US-UMB,18965,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.561249 -US-UMB,18790,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.57 -US-UMB,18812,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.57 -US-UMB,18973,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.57 -US-UMB,19028,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.57 -US-UMB,19032,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.57 -US-UMB,18963,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.574456 -US-UMB,18964,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.576628 -US-UMB,18815,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.58 -US-UMB,18817,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.58 -US-UMB,18818,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.58 -US-UMB,18978,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.58 -US-UMB,19031,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.58 -US-UMB,18977,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.59 -US-UMB,19019,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.59 -US-UMB,19029,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.59 -US-UMB,18798,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.6 -US-UMB,18814,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.6 -US-UMB,18816,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.6 -US-UMB,19018,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.6 -US-UMB,19017,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.63 -US-UMB,18782,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.65 -US-UMB,19030,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.65 -US-UMB,18971,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.67 -US-UMB,18983,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.71 -US-UMB,18901,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.91 -US-UMB,19055,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.91 -US-UMB,18781,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.92 -US-UMB,18873,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.92 -US-UMB,18788,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.93 -US-UMB,19065,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.93 -US-UMB,19054,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.97 -US-UMB,19104,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.97 -US-UMB,18859,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.98 -US-UMB,18976,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.98 -US-UMB,18795,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,1.02 -US-UMB,19072,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,1.02 -US-UMB,19053,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,1.03 -US-UMB,19099,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,1.03 -US-UMB,18866,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,1.07 -US-UMB,18894,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,1.08 -US-UMB,18997,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,1.08 -US-UMB,18982,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,1.09 -US-UMB,18878,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,1.16 -US-UMB,19025,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,1.16 -US-UMB,18828,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,1.18 -US-UMB,19084,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,1.18 -US-UMB,18969,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,1.189 -US-UMB,18840,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,1.2 -US-UMB,19089,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,1.2 -US-UMB,18851,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,1.22 -US-UMB,19039,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,1.26 -US-UMB,19094,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,1.26 -US-UMB,19011,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,1.34 -US-UMB,19079,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,1.34 -US-UMB,18822,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,1.39 -US-UMB,18889,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,1.39 -US-UMB,18806,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,1.68 -US-UMB,18884,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,1.68 -US-UMB,18962,GRP_LAI,LAI_U,0.44 -US-UMB,19053,GRP_LAI,LAI_U,0.44 -US-UMB,18961,GRP_LAI,LAI_U,0.51 -US-UMB,19039,GRP_LAI,LAI_U,0.51 -US-UMB,18961,GRP_LAI,LAI_U_SPATIAL_REP_NUMBER,36 -US-UMB,18962,GRP_LAI,LAI_U_SPATIAL_REP_NUMBER,36 -US-UMB,19039,GRP_LAI,LAI_U_SPATIAL_REP_NUMBER,36 -US-UMB,19053,GRP_LAI,LAI_U_SPATIAL_REP_NUMBER,36 -US-UMB,18961,GRP_LAI,LAI_U_SPATIAL_VARIABILITY,0.415 -US-UMB,19039,GRP_LAI,LAI_U_SPATIAL_VARIABILITY,0.415 -US-UMB,18962,GRP_LAI,LAI_U_SPATIAL_VARIABILITY,0.427 -US-UMB,19053,GRP_LAI,LAI_U_SPATIAL_VARIABILITY,0.427 -US-UMB,12332,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -US-UMB,12332,GRP_LAND_OWNERSHIP,LAND_OWNER,University of Michigan -US-UMB,25122,GRP_LMA,LMA,24.1 -US-UMB,25122,GRP_LMA,LMA_SPP,ACRU (NRCS plant code) -US-UMB,25122,GRP_LMA,LMA_DATE,19990624 -US-UMB,24471,GRP_LMA,LMA,26.9 -US-UMB,24471,GRP_LMA,LMA_SPP,BEPA (NRCS plant code) -US-UMB,24471,GRP_LMA,LMA_DATE,19990624 -US-UMB,23706,GRP_LMA,LMA,31.1 -US-UMB,23706,GRP_LMA,LMA_SPP,POGR4 (NRCS plant code) -US-UMB,23706,GRP_LMA,LMA_DATE,19990624 -US-UMB,24725,GRP_LMA,LMA,33.88 -US-UMB,24725,GRP_LMA,LMA_SPP,ACRU (NRCS plant code) -US-UMB,24725,GRP_LMA,LMA_DATE,19980720 -US-UMB,25121,GRP_LMA,LMA,35.1 -US-UMB,25121,GRP_LMA,LMA_SPP,QURU (NRCS plant code) -US-UMB,25121,GRP_LMA,LMA_DATE,19980720 -US-UMB,23834,GRP_LMA,LMA,36.2 -US-UMB,23834,GRP_LMA,LMA_SPP,QURU (NRCS plant code) -US-UMB,23834,GRP_LMA,LMA_DATE,19990624 -US-UMB,23967,GRP_LMA,LMA,40.04 -US-UMB,23967,GRP_LMA,LMA_SPP,POGR4 (NRCS plant code) -US-UMB,23967,GRP_LMA,LMA_DATE,19980720 -US-UMB,23705,GRP_LMA,LMA,59.07 -US-UMB,23705,GRP_LMA,LMA_SPP,PIST (NRCS plant code) -US-UMB,23705,GRP_LMA,LMA_DATE,19980720 -US-UMB,24861,GRP_LMA,LMA,73.8 -US-UMB,24861,GRP_LMA,LMA_SPP,PIST (NRCS plant code) -US-UMB,24861,GRP_LMA,LMA_DATE,19990624 -US-UMB,12333,GRP_LOCATION,LOCATION_LAT,45.5598 -US-UMB,12333,GRP_LOCATION,LOCATION_LONG,-84.7138 -US-UMB,12333,GRP_LOCATION,LOCATION_ELEV,234 -US-UMB,12333,GRP_LOCATION,LOCATION_COMMENT,uyssaert -US-UMB,23778,GRP_N_DEP,N_DEP_WET,0.47 -US-UMB,23778,GRP_N_DEP,N_DEP_DRY,0.15 -US-UMB,24858,GRP_NEP,NEP,96000 -US-UMB,24858,GRP_NEP,NEP_APPROACH,"See Gough et al., Agric Forest Meteorol. (2008), 148:158-170" -US-UMB,24858,GRP_NEP,NEP_DATE_START,1999 -US-UMB,23699,GRP_NEP,NEP,179000 -US-UMB,23699,GRP_NEP,NEP_APPROACH,"See Gough et al., Agric Forest Meteorol. (2008), 148:158-170" -US-UMB,23699,GRP_NEP,NEP_DATE_START,2000 -US-UMB,24721,GRP_NEP,NEP,198000 -US-UMB,24721,GRP_NEP,NEP_APPROACH,"See Gough et al., Agric Forest Meteorol. (2008), 148:158-170" -US-UMB,24721,GRP_NEP,NEP_DATE_START,2001 -US-UMB,24722,GRP_NEP,NEP,134000 -US-UMB,24722,GRP_NEP,NEP_APPROACH,"See Gough et al., Agric Forest Meteorol. (2008), 148:158-170" -US-UMB,24722,GRP_NEP,NEP_DATE_START,2002 -US-UMB,24723,GRP_NEP,NEP,156000 -US-UMB,24723,GRP_NEP,NEP_APPROACH,"See Gough et al., Agric Forest Meteorol. (2008), 148:158-170" -US-UMB,24723,GRP_NEP,NEP_DATE_START,2003 -US-UMB,12334,GRP_NETWORK,NETWORK,AmeriFlux -US-UMB,87025,GRP_NETWORK,NETWORK,Phenocam -US-UMB,18852,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,BudBreak -US-UMB,18852,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_STATUS,Start -US-UMB,18852,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,Acer rubrum -US-UMB,18852,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,19990504 -US-UMB,18852,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_UNC,4 -US-UMB,18852,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_APPROACH,opening of bud scales -US-UMB,18852,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,Replicates are individual trees within 60 m of flux tower. Standard deviation is days instead of YYYYMMDD. -US-UMB,18852,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_REP_NUMBER,5 -US-UMB,18852,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_VARIABILITY,1.8 -US-UMB,18860,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,BudBreak -US-UMB,18860,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_STATUS,Start -US-UMB,18860,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,Betula papyrifera -US-UMB,18860,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,19990501 -US-UMB,18860,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_UNC,4 -US-UMB,18860,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_APPROACH,opening of bud scales -US-UMB,18860,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,Replicates are individual trees within 60 m of flux tower. Standard deviation is days instead of YYYYMMDD. -US-UMB,18860,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_REP_NUMBER,5 -US-UMB,18867,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,BudBreak -US-UMB,18867,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_STATUS,Start -US-UMB,18867,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,Fagus grandifolia -US-UMB,18867,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,19990506 -US-UMB,18867,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_UNC,3 -US-UMB,18867,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_APPROACH,opening of bud scales -US-UMB,18867,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,Replicates are individual trees within 60 m of flux tower. Standard deviation is days instead of YYYYMMDD. -US-UMB,18867,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_REP_NUMBER,5 -US-UMB,18867,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_VARIABILITY,1.3 -US-UMB,18879,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,BudBreak -US-UMB,18879,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_STATUS,Start -US-UMB,18879,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,Betula papyrifera -US-UMB,18879,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20000504 -US-UMB,18879,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_UNC,6 -US-UMB,18879,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_APPROACH,opening of bud scales -US-UMB,18879,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,Replicates are individual trees within 60 m of flux tower. Standard deviation is days instead of YYYYMMDD. -US-UMB,18879,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_REP_NUMBER,5 -US-UMB,18885,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,BudBreak -US-UMB,18885,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_STATUS,Start -US-UMB,18885,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,Fagus grandifolia -US-UMB,18885,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20000508 -US-UMB,18885,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_UNC,4 -US-UMB,18885,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_APPROACH,opening of bud scales -US-UMB,18885,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,Replicates are individual trees within 60 m of flux tower. Standard deviation is days instead of YYYYMMDD. -US-UMB,18885,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_REP_NUMBER,5 -US-UMB,18890,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,BudBreak -US-UMB,18890,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_STATUS,Start -US-UMB,18890,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,Populus grandidentata -US-UMB,18890,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20000508 -US-UMB,18890,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_UNC,4 -US-UMB,18890,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_APPROACH,opening of bud scales -US-UMB,18890,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,Replicates are individual trees within 60 m of flux tower. Standard deviation is days instead of YYYYMMDD. -US-UMB,18890,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_REP_NUMBER,5 -US-UMB,18895,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,BudBreak -US-UMB,18895,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_STATUS,Start -US-UMB,18895,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,Populus tremuloides -US-UMB,18895,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20000504 -US-UMB,18895,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_UNC,6 -US-UMB,18895,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_APPROACH,opening of bud scales -US-UMB,18895,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,Replicates are individual trees within 60 m of flux tower. Standard deviation is days instead of YYYYMMDD. -US-UMB,18895,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_REP_NUMBER,5 -US-UMB,18897,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,BudBreak -US-UMB,18897,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_STATUS,Start -US-UMB,18897,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,Populus grandidentata -US-UMB,18897,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20010505 -US-UMB,18897,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_UNC,4 -US-UMB,18897,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_APPROACH,opening of bud scales -US-UMB,18897,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,Replicates are individual trees within 60 m of flux tower. Standard deviation is days instead of YYYYMMDD. -US-UMB,18897,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_REP_NUMBER,5 -US-UMB,18897,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_VARIABILITY,2.7 -US-UMB,18902,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,BudBreak -US-UMB,18902,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_STATUS,Start -US-UMB,18902,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,Populus tremuloides -US-UMB,18902,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20010503 -US-UMB,18902,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_UNC,5 -US-UMB,18902,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_APPROACH,opening of bud scales -US-UMB,18902,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,Replicates are individual trees within 60 m of flux tower. Standard deviation is days instead of YYYYMMDD. -US-UMB,18902,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_REP_NUMBER,5 -US-UMB,18906,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,BudBreak -US-UMB,18906,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_STATUS,Start -US-UMB,18906,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,Quercus rubra -US-UMB,18906,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20010503 -US-UMB,18906,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_UNC,5 -US-UMB,18906,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_APPROACH,opening of bud scales -US-UMB,18906,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,Replicates are individual trees within 60 m of flux tower. Standard deviation is days instead of YYYYMMDD. -US-UMB,18906,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_REP_NUMBER,5 -US-UMB,18910,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,BudBreak -US-UMB,18910,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_STATUS,Start -US-UMB,18910,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,Acer rubrum -US-UMB,18910,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20020518 -US-UMB,18910,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_UNC,7 -US-UMB,18910,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_APPROACH,opening of bud scales -US-UMB,18910,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,Replicates are individual trees within 60 m of flux tower. Standard deviation is days instead of YYYYMMDD. -US-UMB,18910,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_REP_NUMBER,5 -US-UMB,18910,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_VARIABILITY,4.9 -US-UMB,18914,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,BudBreak -US-UMB,18914,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_STATUS,Start -US-UMB,18914,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,Betula papyrifera -US-UMB,18914,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20020518 -US-UMB,18914,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_UNC,7 -US-UMB,18914,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_APPROACH,opening of bud scales -US-UMB,18914,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,Replicates are individual trees within 60 m of flux tower. Standard deviation is days instead of YYYYMMDD. -US-UMB,18914,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_REP_NUMBER,5 -US-UMB,18914,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_VARIABILITY,4.9 -US-UMB,18918,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,BudBreak -US-UMB,18918,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_STATUS,Start -US-UMB,18918,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,Fagus grandifolia -US-UMB,18918,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20020523 -US-UMB,18918,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_UNC,5 -US-UMB,18918,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_APPROACH,opening of bud scales -US-UMB,18918,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,Replicates are individual trees within 60 m of flux tower. Standard deviation is days instead of YYYYMMDD. -US-UMB,18918,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_REP_NUMBER,5 -US-UMB,18918,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_VARIABILITY,2.7 -US-UMB,18923,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,BudBreak -US-UMB,18923,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_STATUS,Start -US-UMB,18923,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,Quercus rubra -US-UMB,18923,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20030524 -US-UMB,18923,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_UNC,7 -US-UMB,18923,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_APPROACH,opening of bud scales -US-UMB,18923,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,Replicates are individual trees within 60 m of flux tower. Standard deviation is days instead of YYYYMMDD. -US-UMB,18923,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_REP_NUMBER,5 -US-UMB,18927,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,BudBreak -US-UMB,18927,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_STATUS,Start -US-UMB,18927,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,Acer rubrum -US-UMB,18927,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20060505 -US-UMB,18927,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_UNC,5 -US-UMB,18927,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_APPROACH,opening of bud scales -US-UMB,18927,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,Replicates are individual trees within 60 m of flux tower. Standard deviation is days instead of YYYYMMDD. -US-UMB,18927,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_REP_NUMBER,5 -US-UMB,18927,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_VARIABILITY,2.7 -US-UMB,18931,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,BudBreak -US-UMB,18931,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_STATUS,Start -US-UMB,18931,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,Betula papyrifera -US-UMB,18931,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20060429 -US-UMB,18931,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_UNC,5 -US-UMB,18931,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_APPROACH,opening of bud scales -US-UMB,18931,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,Replicates are individual trees within 60 m of flux tower. Standard deviation is days instead of YYYYMMDD. -US-UMB,18931,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_REP_NUMBER,5 -US-UMB,18931,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_VARIABILITY,2.7 -US-UMB,18935,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,BudBreak -US-UMB,18935,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_STATUS,Start -US-UMB,18935,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,Fagus grandifolia -US-UMB,18935,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20060505 -US-UMB,18935,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_UNC,5 -US-UMB,18935,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_APPROACH,opening of bud scales -US-UMB,18935,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,Replicates are individual trees within 60 m of flux tower. Standard deviation is days instead of YYYYMMDD. -US-UMB,18935,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_REP_NUMBER,5 -US-UMB,18935,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_VARIABILITY,2.7 -US-UMB,18939,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,BudBreak -US-UMB,18939,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_STATUS,Start -US-UMB,18939,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,Populus grandidentata -US-UMB,18939,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20060510 -US-UMB,18939,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_UNC,5 -US-UMB,18939,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_APPROACH,opening of bud scales -US-UMB,18939,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,Replicates are individual trees within 60 m of flux tower. Standard deviation is days instead of YYYYMMDD. -US-UMB,18939,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_REP_NUMBER,3 -US-UMB,18943,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,BudBreak -US-UMB,18943,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_STATUS,Start -US-UMB,18943,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,Fagus grandifolia -US-UMB,18943,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20110512 -US-UMB,18943,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_UNC,1 -US-UMB,18943,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_APPROACH,opening of bud scales -US-UMB,18943,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,Replicates are individual trees within 60 m of flux tower. Standard deviation is days instead of YYYYMMDD. -US-UMB,18943,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_REP_NUMBER,5 -US-UMB,18943,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_VARIABILITY,0.8 -US-UMB,18944,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,BudBreak -US-UMB,18944,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_STATUS,Start -US-UMB,18944,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,Populus grandidentata -US-UMB,18944,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20110517 -US-UMB,18944,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_UNC,1 -US-UMB,18944,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_APPROACH,opening of bud scales -US-UMB,18944,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,Replicates are individual trees within 60 m of flux tower. Standard deviation is days instead of YYYYMMDD. -US-UMB,18944,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_REP_NUMBER,5 -US-UMB,18944,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_VARIABILITY,1.1 -US-UMB,18945,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,BudBreak -US-UMB,18945,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_STATUS,Start -US-UMB,18945,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,Quercus rubra -US-UMB,18945,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20110512 -US-UMB,18945,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_UNC,1 -US-UMB,18945,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_APPROACH,opening of bud scales -US-UMB,18945,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,Replicates are individual trees within 60 m of flux tower. Standard deviation is days instead of YYYYMMDD. -US-UMB,18945,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_REP_NUMBER,5 -US-UMB,18945,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_VARIABILITY,0.5 -US-UMB,18946,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,BudBreak -US-UMB,18946,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_STATUS,Start -US-UMB,18946,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,Acer rubrum -US-UMB,18946,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20120421 -US-UMB,18946,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_UNC,3 -US-UMB,18946,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_APPROACH,opening of bud scales -US-UMB,18946,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,Replicates are individual trees within 60 m of flux tower. Standard deviation is days instead of YYYYMMDD. -US-UMB,18946,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_REP_NUMBER,5 -US-UMB,18946,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_VARIABILITY,5.4 -US-UMB,18947,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,BudBreak -US-UMB,18947,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_STATUS,Start -US-UMB,18947,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,Betula papyrifera -US-UMB,18947,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20120425 -US-UMB,18947,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_UNC,2 -US-UMB,18947,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_APPROACH,opening of bud scales -US-UMB,18947,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,Replicates are individual trees within 60 m of flux tower. Standard deviation is days instead of YYYYMMDD. -US-UMB,18947,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_REP_NUMBER,2 -US-UMB,18947,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_VARIABILITY,8.5 -US-UMB,18948,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,BudBreak -US-UMB,18948,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_STATUS,Start -US-UMB,18948,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,Fagus grandifolia -US-UMB,18948,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20120506 -US-UMB,18948,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_UNC,2 -US-UMB,18948,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_APPROACH,opening of bud scales -US-UMB,18948,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,Replicates are individual trees within 60 m of flux tower. Standard deviation is days instead of YYYYMMDD. -US-UMB,18948,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_REP_NUMBER,4 -US-UMB,18948,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_VARIABILITY,1.8 -US-UMB,18949,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,BudBreak -US-UMB,18949,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_STATUS,Start -US-UMB,18949,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,Populus grandidentata -US-UMB,18949,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20120509 -US-UMB,18949,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_UNC,1 -US-UMB,18949,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_APPROACH,opening of bud scales -US-UMB,18949,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,Replicates are individual trees within 60 m of flux tower. Standard deviation is days instead of YYYYMMDD. -US-UMB,18949,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_REP_NUMBER,5 -US-UMB,18949,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_VARIABILITY,1.4 -US-UMB,18950,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,BudBreak -US-UMB,18950,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_STATUS,Start -US-UMB,18950,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,Quercus rubra -US-UMB,18950,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20120503 -US-UMB,18950,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_UNC,2 -US-UMB,18950,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_APPROACH,opening of bud scales -US-UMB,18950,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,Replicates are individual trees within 60 m of flux tower. Standard deviation is days instead of YYYYMMDD. -US-UMB,18950,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_REP_NUMBER,3 -US-UMB,18950,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_VARIABILITY,1.5 -US-UMB,18951,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,BudBreak -US-UMB,18951,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_STATUS,Start -US-UMB,18951,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,Acer rubrum -US-UMB,18951,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20130506 -US-UMB,18951,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_UNC,1 -US-UMB,18951,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_APPROACH,opening of bud scales -US-UMB,18951,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,Replicates are individual trees within 60 m of flux tower. Standard deviation is days instead of YYYYMMDD. -US-UMB,18951,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_REP_NUMBER,5 -US-UMB,18951,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_VARIABILITY,1.3 -US-UMB,18952,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,BudBreak -US-UMB,18952,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_STATUS,Start -US-UMB,18952,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,Betula papyrifera -US-UMB,18952,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20130505 -US-UMB,18952,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_UNC,1 -US-UMB,18952,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_APPROACH,opening of bud scales -US-UMB,18952,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,Replicates are individual trees within 60 m of flux tower. Standard deviation is days instead of YYYYMMDD. -US-UMB,18952,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_REP_NUMBER,5 -US-UMB,18952,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_VARIABILITY,8 -US-UMB,18953,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,BudBreak -US-UMB,18953,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_STATUS,Start -US-UMB,18953,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,Fagus grandifolia -US-UMB,18953,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20130507 -US-UMB,18953,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_UNC,1 -US-UMB,18953,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_APPROACH,opening of bud scales -US-UMB,18953,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,Replicates are individual trees within 60 m of flux tower. Standard deviation is days instead of YYYYMMDD. -US-UMB,18953,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_REP_NUMBER,5 -US-UMB,18953,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_VARIABILITY,0.7 -US-UMB,18954,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,BudBreak -US-UMB,18954,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_STATUS,Start -US-UMB,18954,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,Populus grandidentata -US-UMB,18954,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20130509 -US-UMB,18954,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_UNC,1 -US-UMB,18954,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_APPROACH,opening of bud scales -US-UMB,18954,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,Replicates are individual trees within 60 m of flux tower. Standard deviation is days instead of YYYYMMDD. -US-UMB,18954,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_REP_NUMBER,5 -US-UMB,18954,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_VARIABILITY,2.1 -US-UMB,18955,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,BudBreak -US-UMB,18955,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_STATUS,Start -US-UMB,18955,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,Quercus rubra -US-UMB,18955,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20130506 -US-UMB,18955,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_UNC,1 -US-UMB,18955,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_APPROACH,opening of bud scales -US-UMB,18955,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,Replicates are individual trees within 60 m of flux tower. Standard deviation is days instead of YYYYMMDD. -US-UMB,18955,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_REP_NUMBER,5 -US-UMB,18955,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_VARIABILITY,0.4 -US-UMB,18956,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,BudBreak -US-UMB,18956,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_STATUS,Start -US-UMB,18956,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,Acer rubrum -US-UMB,18956,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20140522 -US-UMB,18956,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_UNC,2 -US-UMB,18956,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_APPROACH,opening of bud scales -US-UMB,18956,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,Replicates are individual trees within 60 m of flux tower. Standard deviation is days instead of YYYYMMDD. -US-UMB,18956,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_REP_NUMBER,5 -US-UMB,18956,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_VARIABILITY,2 -US-UMB,18957,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,BudBreak -US-UMB,18957,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_STATUS,Start -US-UMB,18957,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,Betula papyrifera -US-UMB,18957,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20140516 -US-UMB,18957,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_UNC,2 -US-UMB,18957,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_APPROACH,opening of bud scales -US-UMB,18957,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,Replicates are individual trees within 60 m of flux tower. Standard deviation is days instead of YYYYMMDD. -US-UMB,18957,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_REP_NUMBER,5 -US-UMB,18957,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_VARIABILITY,1.6 -US-UMB,18958,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,BudBreak -US-UMB,18958,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_STATUS,Start -US-UMB,18958,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,Fagus grandifolia -US-UMB,18958,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20140525 -US-UMB,18958,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_UNC,1 -US-UMB,18958,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_APPROACH,opening of bud scales -US-UMB,18958,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,Replicates are individual trees within 60 m of flux tower. Standard deviation is days instead of YYYYMMDD. -US-UMB,18958,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_REP_NUMBER,5 -US-UMB,18958,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_VARIABILITY,0.9 -US-UMB,18959,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,BudBreak -US-UMB,18959,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_STATUS,Start -US-UMB,18959,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,Populus grandidentata -US-UMB,18959,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20140526 -US-UMB,18959,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_UNC,2 -US-UMB,18959,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_APPROACH,opening of bud scales -US-UMB,18959,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,Replicates are individual trees within 60 m of flux tower. Standard deviation is days instead of YYYYMMDD. -US-UMB,18959,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_REP_NUMBER,5 -US-UMB,18959,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_VARIABILITY,1.1 -US-UMB,18960,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,BudBreak -US-UMB,18960,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_STATUS,Start -US-UMB,18960,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,Quercus rubra -US-UMB,18960,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20140525 -US-UMB,18960,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_UNC,2 -US-UMB,18960,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_APPROACH,opening of bud scales -US-UMB,18960,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,Replicates are individual trees within 60 m of flux tower. Standard deviation is days instead of YYYYMMDD. -US-UMB,18960,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_REP_NUMBER,5 -US-UMB,18960,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_VARIABILITY,0.9 -US-UMB,19059,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,BudBreak -US-UMB,19059,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_STATUS,Start -US-UMB,19059,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,Populus grandidentata -US-UMB,19059,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,19990506 -US-UMB,19059,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_UNC,3 -US-UMB,19059,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_APPROACH,opening of bud scales -US-UMB,19059,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,Replicates are individual trees within 60 m of flux tower. Standard deviation is days instead of YYYYMMDD. -US-UMB,19059,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_REP_NUMBER,5 -US-UMB,19059,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_VARIABILITY,1.6 -US-UMB,19066,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,BudBreak -US-UMB,19066,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_STATUS,Start -US-UMB,19066,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,Populus tremuloides -US-UMB,19066,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,19990502 -US-UMB,19066,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_UNC,4 -US-UMB,19066,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_APPROACH,opening of bud scales -US-UMB,19066,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,Replicates are individual trees within 60 m of flux tower. Standard deviation is days instead of YYYYMMDD. -US-UMB,19066,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_REP_NUMBER,5 -US-UMB,19066,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_VARIABILITY,1.8 -US-UMB,19073,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,BudBreak -US-UMB,19073,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_STATUS,Start -US-UMB,19073,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,Quercus rubra -US-UMB,19073,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,19990504 -US-UMB,19073,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_UNC,3 -US-UMB,19073,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_APPROACH,opening of bud scales -US-UMB,19073,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,Replicates are individual trees within 60 m of flux tower. Standard deviation is days instead of YYYYMMDD. -US-UMB,19073,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_REP_NUMBER,5 -US-UMB,19073,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_VARIABILITY,1.8 -US-UMB,19080,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,BudBreak -US-UMB,19080,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_STATUS,Start -US-UMB,19080,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,Acer rubrum -US-UMB,19080,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20000504 -US-UMB,19080,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_UNC,4 -US-UMB,19080,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_APPROACH,opening of bud scales -US-UMB,19080,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,Replicates are individual trees within 60 m of flux tower. Standard deviation is days instead of YYYYMMDD. -US-UMB,19080,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_REP_NUMBER,5 -US-UMB,19085,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,BudBreak -US-UMB,19085,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_STATUS,Start -US-UMB,19085,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,Quercus rubra -US-UMB,19085,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20000507 -US-UMB,19085,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_UNC,4 -US-UMB,19085,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_APPROACH,opening of bud scales -US-UMB,19085,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,Replicates are individual trees within 60 m of flux tower. Standard deviation is days instead of YYYYMMDD. -US-UMB,19085,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_REP_NUMBER,5 -US-UMB,19085,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_VARIABILITY,1.8 -US-UMB,19090,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,BudBreak -US-UMB,19090,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_STATUS,Start -US-UMB,19090,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,Acer rubrum -US-UMB,19090,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20010503 -US-UMB,19090,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_UNC,5 -US-UMB,19090,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_APPROACH,opening of bud scales -US-UMB,19090,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,Replicates are individual trees within 60 m of flux tower. Standard deviation is days instead of YYYYMMDD. -US-UMB,19090,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_REP_NUMBER,5 -US-UMB,19095,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,BudBreak -US-UMB,19095,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_STATUS,Start -US-UMB,19095,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,Betula papyrifera -US-UMB,19095,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20010503 -US-UMB,19095,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_UNC,5 -US-UMB,19095,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_APPROACH,opening of bud scales -US-UMB,19095,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,Replicates are individual trees within 60 m of flux tower. Standard deviation is days instead of YYYYMMDD. -US-UMB,19095,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_REP_NUMBER,5 -US-UMB,19100,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,BudBreak -US-UMB,19100,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_STATUS,Start -US-UMB,19100,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,Fagus grandifolia -US-UMB,19100,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20010507 -US-UMB,19100,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_UNC,4 -US-UMB,19100,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_APPROACH,opening of bud scales -US-UMB,19100,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,Replicates are individual trees within 60 m of flux tower. Standard deviation is days instead of YYYYMMDD. -US-UMB,19100,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_REP_NUMBER,5 -US-UMB,19100,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_VARIABILITY,2.2 -US-UMB,19107,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,BudBreak -US-UMB,19107,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_STATUS,Start -US-UMB,19107,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,Populus grandidentata -US-UMB,19107,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20020530 -US-UMB,19107,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_UNC,7 -US-UMB,19107,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_APPROACH,opening of bud scales -US-UMB,19107,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,Replicates are individual trees within 60 m of flux tower. Standard deviation is days instead of YYYYMMDD. -US-UMB,19107,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_REP_NUMBER,5 -US-UMB,19107,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_VARIABILITY,4 -US-UMB,19111,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,BudBreak -US-UMB,19111,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_STATUS,Start -US-UMB,19111,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,Quercus rubra -US-UMB,19111,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20020518 -US-UMB,19111,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_UNC,7 -US-UMB,19111,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_APPROACH,opening of bud scales -US-UMB,19111,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,Replicates are individual trees within 60 m of flux tower. Standard deviation is days instead of YYYYMMDD. -US-UMB,19111,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_REP_NUMBER,5 -US-UMB,19111,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_VARIABILITY,4.9 -US-UMB,19115,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,BudBreak -US-UMB,19115,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_STATUS,Start -US-UMB,19115,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,Acer rubrum -US-UMB,19115,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20030514 -US-UMB,19115,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_UNC,3 -US-UMB,19115,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_APPROACH,opening of bud scales -US-UMB,19115,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,Replicates are individual trees within 60 m of flux tower. Standard deviation is days instead of YYYYMMDD. -US-UMB,19115,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_REP_NUMBER,5 -US-UMB,19115,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_VARIABILITY,2.2 -US-UMB,19119,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,BudBreak -US-UMB,19119,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_STATUS,Start -US-UMB,19119,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,Betula papyrifera -US-UMB,19119,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20030513 -US-UMB,19119,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_UNC,3 -US-UMB,19119,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_APPROACH,opening of bud scales -US-UMB,19119,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,Replicates are individual trees within 60 m of flux tower. Standard deviation is days instead of YYYYMMDD. -US-UMB,19119,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_REP_NUMBER,5 -US-UMB,19119,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_VARIABILITY,1.8 -US-UMB,19123,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,BudBreak -US-UMB,19123,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_STATUS,Start -US-UMB,19123,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,Fagus grandifolia -US-UMB,19123,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20030524 -US-UMB,19123,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_UNC,7 -US-UMB,19123,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_APPROACH,opening of bud scales -US-UMB,19123,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,Replicates are individual trees within 60 m of flux tower. Standard deviation is days instead of YYYYMMDD. -US-UMB,19123,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_REP_NUMBER,5 -US-UMB,19127,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,BudBreak -US-UMB,19127,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_STATUS,Start -US-UMB,19127,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,Populus grandidentata -US-UMB,19127,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20030525 -US-UMB,19127,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_UNC,7 -US-UMB,19127,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_APPROACH,opening of bud scales -US-UMB,19127,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,Replicates are individual trees within 60 m of flux tower. Standard deviation is days instead of YYYYMMDD. -US-UMB,19127,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_REP_NUMBER,5 -US-UMB,19127,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_VARIABILITY,2.7 -US-UMB,19128,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,BudBreak -US-UMB,19128,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_STATUS,Start -US-UMB,19128,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,Quercus rubra -US-UMB,19128,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20060504 -US-UMB,19128,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_UNC,5 -US-UMB,19128,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_APPROACH,opening of bud scales -US-UMB,19128,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,Replicates are individual trees within 60 m of flux tower. Standard deviation is days instead of YYYYMMDD. -US-UMB,19128,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_REP_NUMBER,5 -US-UMB,19132,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,BudBreak -US-UMB,19132,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_STATUS,Start -US-UMB,19132,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,Acer rubrum -US-UMB,19132,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20090507 -US-UMB,19132,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_UNC,1 -US-UMB,19132,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_APPROACH,opening of bud scales -US-UMB,19132,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,Replicates are individual trees within 60 m of flux tower. Standard deviation is days instead of YYYYMMDD. -US-UMB,19132,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_REP_NUMBER,5 -US-UMB,19132,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_VARIABILITY,1.3 -US-UMB,19136,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,BudBreak -US-UMB,19136,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_STATUS,Start -US-UMB,19136,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,Betula papyrifera -US-UMB,19136,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20090505 -US-UMB,19136,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_UNC,2 -US-UMB,19136,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_APPROACH,opening of bud scales -US-UMB,19136,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,Replicates are individual trees within 60 m of flux tower. Standard deviation is days instead of YYYYMMDD. -US-UMB,19136,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_REP_NUMBER,5 -US-UMB,19136,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_VARIABILITY,1.1 -US-UMB,19140,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,BudBreak -US-UMB,19140,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_STATUS,Start -US-UMB,19140,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,Fagus grandifolia -US-UMB,19140,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20090512 -US-UMB,19140,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_UNC,1 -US-UMB,19140,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_APPROACH,opening of bud scales -US-UMB,19140,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,Replicates are individual trees within 60 m of flux tower. Standard deviation is days instead of YYYYMMDD. -US-UMB,19140,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_REP_NUMBER,5 -US-UMB,19140,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_VARIABILITY,1.4 -US-UMB,19142,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,BudBreak -US-UMB,19142,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_STATUS,Start -US-UMB,19142,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,Populus grandidentata -US-UMB,19142,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20090516 -US-UMB,19142,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_UNC,3 -US-UMB,19142,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_APPROACH,opening of bud scales -US-UMB,19142,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,Replicates are individual trees within 60 m of flux tower. Standard deviation is days instead of YYYYMMDD. -US-UMB,19142,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_REP_NUMBER,5 -US-UMB,19142,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_VARIABILITY,1.5 -US-UMB,19143,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,BudBreak -US-UMB,19143,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_STATUS,Start -US-UMB,19143,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,Quercus rubra -US-UMB,19143,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20090509 -US-UMB,19143,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_UNC,0 -US-UMB,19143,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_APPROACH,opening of bud scales -US-UMB,19143,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,Replicates are individual trees within 60 m of flux tower. Standard deviation is days instead of YYYYMMDD. -US-UMB,19143,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_REP_NUMBER,5 -US-UMB,19143,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_VARIABILITY,1.4 -US-UMB,19144,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,BudBreak -US-UMB,19144,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_STATUS,Start -US-UMB,19144,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,Acer rubrum -US-UMB,19144,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20100420 -US-UMB,19144,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_UNC,1 -US-UMB,19144,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_APPROACH,opening of bud scales -US-UMB,19144,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,Replicates are individual trees within 60 m of flux tower. Standard deviation is days instead of YYYYMMDD. -US-UMB,19144,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_REP_NUMBER,5 -US-UMB,19144,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_VARIABILITY,4.2 -US-UMB,19145,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,BudBreak -US-UMB,19145,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_STATUS,Start -US-UMB,19145,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,Betula papyrifera -US-UMB,19145,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20100418 -US-UMB,19145,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_UNC,1 -US-UMB,19145,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_APPROACH,opening of bud scales -US-UMB,19145,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,Replicates are individual trees within 60 m of flux tower. Standard deviation is days instead of YYYYMMDD. -US-UMB,19145,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_REP_NUMBER,5 -US-UMB,19145,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_VARIABILITY,5.1 -US-UMB,19146,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,BudBreak -US-UMB,19146,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_STATUS,Start -US-UMB,19146,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,Fagus grandifolia -US-UMB,19146,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20100501 -US-UMB,19146,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_UNC,2 -US-UMB,19146,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_APPROACH,opening of bud scales -US-UMB,19146,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,Replicates are individual trees within 60 m of flux tower. Standard deviation is days instead of YYYYMMDD. -US-UMB,19146,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_REP_NUMBER,4 -US-UMB,19146,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_VARIABILITY,1.5 -US-UMB,19147,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,BudBreak -US-UMB,19147,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_STATUS,Start -US-UMB,19147,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,Populus grandidentata -US-UMB,19147,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20100504 -US-UMB,19147,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_UNC,1 -US-UMB,19147,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_APPROACH,opening of bud scales -US-UMB,19147,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,Replicates are individual trees within 60 m of flux tower. Standard deviation is days instead of YYYYMMDD. -US-UMB,19147,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_REP_NUMBER,4 -US-UMB,19147,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_VARIABILITY,1 -US-UMB,19148,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,BudBreak -US-UMB,19148,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_STATUS,Start -US-UMB,19148,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,Quercus rubra -US-UMB,19148,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20100424 -US-UMB,19148,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_UNC,1 -US-UMB,19148,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_APPROACH,opening of bud scales -US-UMB,19148,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,Replicates are individual trees within 60 m of flux tower. Standard deviation is days instead of YYYYMMDD. -US-UMB,19148,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_REP_NUMBER,5 -US-UMB,19148,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_VARIABILITY,2.2 -US-UMB,19149,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,BudBreak -US-UMB,19149,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_STATUS,Start -US-UMB,19149,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,Acer rubrum -US-UMB,19149,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20110510 -US-UMB,19149,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_UNC,2 -US-UMB,19149,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_APPROACH,opening of bud scales -US-UMB,19149,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,Replicates are individual trees within 60 m of flux tower. Standard deviation is days instead of YYYYMMDD. -US-UMB,19149,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_REP_NUMBER,5 -US-UMB,19149,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_VARIABILITY,1.6 -US-UMB,19150,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,BudBreak -US-UMB,19150,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_STATUS,Start -US-UMB,19150,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,Betula papyrifera -US-UMB,19150,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20110508 -US-UMB,19150,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_UNC,2 -US-UMB,19150,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_APPROACH,opening of bud scales -US-UMB,19150,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,Replicates are individual trees within 60 m of flux tower. Standard deviation is days instead of YYYYMMDD. -US-UMB,19150,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_REP_NUMBER,6 -US-UMB,19150,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_VARIABILITY,1.1 -US-UMB,1700005121,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Aron, P. G., Poulsen, C. J., Fiorella, R. P., Matheny, A. M. (2019) Stable Water Isotopes Reveal Effects Of Intermediate Disturbance And Canopy Structure On Forest Water Cycling, Journal Of Geophysical Research: Biogeosciences, 124(10), 2958-2975" -US-UMB,1700005121,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2019JG005118 -US-UMB,1700005121,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-UMB,1700006822,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Atkins, J. W., Bohrer, G., Fahey, R. T., Hardiman, B. S., Morin, T. H., Stovall, A. E., Zimmerman, N., Gough, C. M. (2018) Quantifying Vegetation And Canopy Structural Complexity From Terrestrial Lidar Data Using The Forestr R Package, Methods In Ecology And Evolution, 9(10), 2057-2066" -US-UMB,1700006822,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/2041-210X.13061 -US-UMB,1700006822,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-UMB,1700002559,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Atkins, J. W., Fahey, R. T., Hardiman, B. H., Gough, C. M. (2018) Forest Canopy Structural Complexity And Light Absorption Relationships At The Subcontinental Scale, Journal Of Geophysical Research: Biogeosciences, 123(4), 1387-1405" -US-UMB,1700002559,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/2017JG004256 -US-UMB,1700002559,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-UMB,1700001512,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Barr, A., Richardson, A., Hollinger, D., Papale, D., Arain, M., Black, T., Bohrer, G., Dragoni, D., Fischer, M., Gu, L., Law, B., Margolis, H., McCaughey, J., Munger, J., Oechel, W., Schaeffer, K. (2013) Use Of Change-Point Detection For Friction–Velocity Threshold Evaluation In Eddy-Covariance Studies, Agricultural And Forest Meteorology, 171-172(8), 31-45" -US-UMB,1700001512,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2012.11.023 -US-UMB,1700001512,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-UMB,1700003936,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Besnard, S., Carvalhais, N., Arain, M. A., Black, A., de Bruin, S., Buchmann, N., Cescatti, A., Chen, J., Clevers, J. G., Desai, A. R., Gough, C. M., Havrankova, K., Herold, M., Hörtnagl, L., Jung, M., Knohl, A., Kruijt, B., Krupkova, L., Law, B. E., Lindroth, A., Noormets, A., Roupsard, O., Steinbrecher, R., Varlagin, A., Vincke, C., Reichstein, M. (2018) Quantifying The Effect Of Forest Age In Annual Net Forest Carbon Balance, Environmental Research Letters, 13(12), 124018" -US-UMB,1700003936,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1088/1748-9326/AAEAEB -US-UMB,1700003936,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-UMB,1700001329,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Bond-Lamberty, B. Fisk, J. Holm, J.A. Bailey, V. Bohrer, G. Gough, C.M. (2015) Moderate forest disturbance as a stringent test for gap and big-leaf models, Biogeosciences, 12(), 513-526" -US-UMB,1700001329,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.5194/BG-12-513-2015 -US-UMB,1700001329,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-UMB,1700000324,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Bond-Lamberty, B., Bailey, V. L., Chen, M., Gough, C. M., Vargas, R. (2018) Globally Rising Soil Heterotrophic Respiration Over Recent Decades, Nature, 560(7716), 80-83" -US-UMB,1700000324,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1038/S41586-018-0358-X -US-UMB,1700000324,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-UMB,1700002562,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Braghiere,R.K., Wang,Y., Doughty,R., Sousa,D., Magney,T., Widlowski,J.-L., Longo,M., Bloom,A.A., Worden,J., Gentine,P., Frankenberg,C. (2021) Accounting for canopy structure improves hyperspectral radiative transfer and sun-induced chlorophyll fluorescence representations in a new generation Earth System model, Remote Sensing of Environment, 261(7), 108350" -US-UMB,1700002562,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.RSE.2021.112497 -US-UMB,1700002562,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-UMB,1700005784,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Bryan, A. M., Cheng, S. J., Ashworth, K., Guenther, A. B., Hardiman, B. S., Bohrer, G., Steiner, A. L. (2015) Forest-Atmosphere Bvoc Exchange In Diverse And Structurally Complex Canopies: 1-D Modeling Of A Mid-Successional Forest In Northern Michigan, Atmospheric Environment, 120(9), 217-226" -US-UMB,1700005784,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.ATMOSENV.2015.08.094 -US-UMB,1700005784,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-UMB,1700004299,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Castillo, B. T., Nave, L. E., Le Moine, J. M., James, T. Y., Nadelhoffer, K. J. (2018) Impacts Of Experimentally Accelerated Forest Succession On Belowground Plant And Fungal Communities, Soil Biology And Biochemistry, 125(7716), 44-53" -US-UMB,1700004299,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.SOILBIO.2018.06.022 -US-UMB,1700004299,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-UMB,1700002280,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Cheng, S. J., Bohrer, G., Steiner, A. L., Hollinger, D. Y., Suyker, A., Phillips, R. P., Nadelhoffer, K. J. (2015) Variations In The Influence Of Diffuse Light On Gross Primary Productivity In Temperate Ecosystems, Agricultural And Forest Meteorology, 201(1), 98-110" -US-UMB,1700002280,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2014.11.002 -US-UMB,1700002280,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-UMB,1700005313,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Cheng, S. J., Steiner, A. L., Hollinger, D. Y., Bohrer, G., Nadelhoffer, K. J. (2016) Using Satellite-Derived Optical Thickness To Assess The Influence Of Clouds On Terrestrial Carbon Uptake, Journal Of Geophysical Research: Biogeosciences, 121(7), 1747-1761" -US-UMB,1700005313,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/2016JG003365 -US-UMB,1700005313,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-UMB,1700004170,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Baldocchi, D. D., Poindexter, C., Abraha, M., Desai, A. R., Bohrer, G., Arain, M. A., Griffis, T., Blanken, P. D., O'Halloran, T. L., Thomas, R. Q., Zhang, Q., Burns, S. P., Frank, J. M., Christian, D., Brown, S., Black, T. A., Gough, C. M., Law, B. E., Lee, X., Chen, J., Reed, D. E., Massman, W. J., Clark, K., Hatfield, J., Prueger, J., Bracho, R., Baker, J. M., Martin, T. A. (2018) Temporal Dynamics Of Aerodynamic Canopy Height Derived From Eddy Covariance Momentum Flux Data Across North American Flux Networks, Geophysical Research Letters, 45(15), 9275–9287" -US-UMB,1700004170,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018GL079306 -US-UMB,1700004170,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-UMB,1700006306,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Baldocchi, D. D., Poindexter, C., Abraha, M., Desai, A. R., Bohrer, G., Arain, M. A., Griffis, T., Blanken, P. D., O'Halloran, T. L., Thomas, R. Q., Zhang, Q., Burns, S. P., Frank, J. M., Christian, D., Brown, S., Black, T. A., Gough, C. M., Law, B. E., Lee, X., Chen, J., Reed, D. E., Massman, W. J., Clark, K., Hatfield, J., Prueger, J., Bracho, R., Baker, J. M., Martin, T. A. (2018) Temporal Dynamics Of Aerodynamic Canopy Height Derived From Eddy Covariance Momentum Flux Data Across North American Flux Networks, Geophysical Research Letters, 45(3), 9275–9287" -US-UMB,1700006306,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018GL079306 -US-UMB,1700006306,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-UMB,1700007026,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(7), 108350" -US-UMB,1700007026,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -US-UMB,1700007026,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-UMB,1700003627,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Curtis, P. S., Gough, C. M. (2018) Forest Aging, Disturbance And The Carbon Cycle, New Phytologist, 219(4), 1188-1193" -US-UMB,1700003627,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/NPH.15227 -US-UMB,1700003627,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-UMB,1700004812,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Curtis, P. S., Hanson, P. J., Bolstad, P., Barford, C., Randolph, J., Schmid, H., Wilson, K. B. (2002) Biometric And Eddy-Covariance Based Estimates Of Annual Carbon Storage In Five Eastern North American Deciduous Forests, Agricultural And Forest Meteorology, 113(1-4), 3-19" -US-UMB,1700004812,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/S0168-1923(02)00099-0 -US-UMB,1700004812,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-UMB,1700006303,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Curtis, P. S., Vogel, C. S., Gough, C. M., Schmid, H. P., Su, H. B., Bovard, B. D. (2005) Respiratory Carbon Losses And The Carbon-Use Efficiency Of A Northern Hardwood Forest, 1999-2003, New Phytologist, 167(2), 437-456" -US-UMB,1700006303,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/J.1469-8137.2005.01438.X -US-UMB,1700006303,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-UMB,1700003048,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Davidson, E., Savage, K., Bolstad, P., Clark, D., Curtis, P., Ellsworth, D., Hanson, P., Law, B., Luo, Y., Pregitzer, K., Randolph, J., Zak, D. 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A., Law, B. E., Pastorello, G. Z., Chu, H. (2020) Seasonal Variability Of Forest Sensitivity To Heat And Drought Stresses: A Synthesis Based On Carbon Fluxes From North American Forest Ecosystems, Global Change Biology, 26(2), 901-918" -US-UMB,1700008031,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/GCB.14843 -US-UMB,1700008031,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-UMB,1700007812,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Yan, H., Wang, S., Billesbach, D., Oechel, W., Bohrer, G., Meyers, T., Martin, T. A., Matamala, R., Phillips, R. P., Rahman, F., Yu, Q., Shugart, H. H. (2015) Improved Global Simulations Of Gross Primary Product Based On A New Definition Of Water Stress Factor And A Separate Treatment Of C3 And C4 Plants, Ecological Modelling, 297(1), 42-59" -US-UMB,1700007812,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.ECOLMODEL.2014.11.002 -US-UMB,1700007812,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-UMB,1700005331,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Yan, H., Wang, S., Billesbach, D., Oechel, W., Zhang, J., Meyers, T., Martin, T., Matamala, R., Baldocchi, D., Bohrer, G., Dragoni, D., Scott, R. (2012) Global Estimation Of Evapotranspiration Using A Leaf Area Index-Based Surface Energy And Water Balance Model, Remote Sensing Of Environment, 124(12), 581-595" -US-UMB,1700005331,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.RSE.2012.06.004 -US-UMB,1700005331,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-UMB,1700008850,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Yan, H., Wang, S., Yu, K., Wang, B., Yu, Q., Bohrer, G., Billesbach, D., Bracho, R., Rahman, F., Shugart, H. H. (2017) A Novel Diffuse Fraction-Based Two-Leaf Light Use Efficiency Model: An Application Quantifying Photosynthetic Seasonality Across 20 Ameriflux Flux Tower Sites, Journal of Advances In Modeling Earth Systems, 9(6), 2317-2332" -US-UMB,1700008850,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/2016MS000886 -US-UMB,1700008850,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-UMB,1700005004,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Yuan, W., Luo, Y., Li, X., Liu, S., Yu, G., Zhou, T., Bahn, M., Black, A., Desai, A. R., Cescatti, A., Marcolla, B., Jacobs, C., Chen, J., Aurela, M., Bernhofer, C., Gielen, B., Bohrer, G., Cook, D. R., Dragoni, D., Dunn, A. L., Gianelle, D., Grünwald, T., Ibrom, A., Leclerc, M. Y., Lindroth, A., Liu, H., Marchesini, L. B., Montagnani, L., Pita, G., Rodeghiero, M., Rodrigues, A., Starr, G., Stoy, P. C. (2011) Redefinition And Global Estimation Of Basal Ecosystem Respiration Rate, Global Biogeochemical Cycles, 25(4), n/a-n/a" -US-UMB,1700005004,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2011GB004150 -US-UMB,1700005004,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-UMB,1700000381,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Yue, X., Unger, N., Keenan, T. F., Zhang, X., Vogel, C. S. (2015) Probing The Past 30-Year Phenology Trend Of Us Deciduous Forests, Biogeosciences, 12(15), 4693-4709" -US-UMB,1700000381,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.5194/BG-12-4693-2015 -US-UMB,1700000381,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-UMB,1700007944,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Zhang, Q., Ficklin, D. L., Manzoni, S., Wang, L., Way, D., Phillips, R. P., Novick, K. A. (2019) Response Of Ecosystem Intrinsic Water Use Efficiency And Gross Primary Productivity To Rising Vapor Pressure Deficit, Environmental Research Letters, 14(7), 074023" -US-UMB,1700007944,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1088/1748-9326/AB2603 -US-UMB,1700007944,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-UMB,1700001755,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Zscheischler, J., Fatichi, S., Wolf, S., Blanken, P., Bohrer, G., Clark, K., Desai, A., Hollinger, D., Keenan, T., Novick, K.A., Seneviratne, S.I. (2016) Short-term favorable weather conditions are an important control of interannual variability in carbon and water fluxes, Journal of Geophysical Research - Biogeosciences, 121(8), 2186-2198" -US-UMB,1700001755,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/2016JG003503 -US-UMB,1700001755,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-UMB,12336,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"The research objectives of the University of Michigan Biological Station (UMBS) site are to address questions of ecosystem/atmosphere linkages that are general in nature and which will contribute to large-scale carbon cycle modeling efforts, and to test hypotheses specific to the upper Great Lakes forest ecosystems that will further our understanding of productivity controls over these regionally important communities." -US-UMB,18553,GRP_ROOT_BIOMASS,ROOT_BIOMASS_FINE,117.5 -US-UMB,18537,GRP_ROOT_BIOMASS,ROOT_BIOMASS_FINE,122.2 -US-UMB,18439,GRP_ROOT_BIOMASS,ROOT_BIOMASS_FINE,126.9 -US-UMB,18448,GRP_ROOT_BIOMASS,ROOT_BIOMASS_FINE,136.3 -US-UMB,18456,GRP_ROOT_BIOMASS,ROOT_BIOMASS_FINE,145.7 -US-UMB,18518,GRP_ROOT_BIOMASS,ROOT_BIOMASS_FINE,155.1 -US-UMB,18526,GRP_ROOT_BIOMASS,ROOT_BIOMASS_FINE,169.2 -US-UMB,18510,GRP_ROOT_BIOMASS,ROOT_BIOMASS_FINE,588.2 -US-UMB,18545,GRP_ROOT_BIOMASS,ROOT_BIOMASS_FINE,98.7 -US-UMB,18545,GRP_ROOT_BIOMASS,ROOT_BIOMASS_FINE_SPATIAL_VARIABILITY,13.03 -US-UMB,18510,GRP_ROOT_BIOMASS,ROOT_BIOMASS_FINE_SPATIAL_VARIABILITY,200.4 -US-UMB,18439,GRP_ROOT_BIOMASS,ROOT_BIOMASS_FINE_SPATIAL_VARIABILITY,22.79 -US-UMB,18537,GRP_ROOT_BIOMASS,ROOT_BIOMASS_FINE_SPATIAL_VARIABILITY,25.23 -US-UMB,18553,GRP_ROOT_BIOMASS,ROOT_BIOMASS_FINE_SPATIAL_VARIABILITY,27.68 -US-UMB,18518,GRP_ROOT_BIOMASS,ROOT_BIOMASS_FINE_SPATIAL_VARIABILITY,30.12 -US-UMB,18456,GRP_ROOT_BIOMASS,ROOT_BIOMASS_FINE_SPATIAL_VARIABILITY,31.75 -US-UMB,18526,GRP_ROOT_BIOMASS,ROOT_BIOMASS_FINE_SPATIAL_VARIABILITY,46.4 -US-UMB,18448,GRP_ROOT_BIOMASS,ROOT_BIOMASS_FINE_SPATIAL_VARIABILITY,61.87 -US-UMB,18439,GRP_ROOT_BIOMASS,ROOT_BIOMASS_FINE_SPATIAL_REP_NUMBER,3 -US-UMB,18448,GRP_ROOT_BIOMASS,ROOT_BIOMASS_FINE_SPATIAL_REP_NUMBER,3 -US-UMB,18456,GRP_ROOT_BIOMASS,ROOT_BIOMASS_FINE_SPATIAL_REP_NUMBER,3 -US-UMB,18518,GRP_ROOT_BIOMASS,ROOT_BIOMASS_FINE_SPATIAL_REP_NUMBER,3 -US-UMB,18526,GRP_ROOT_BIOMASS,ROOT_BIOMASS_FINE_SPATIAL_REP_NUMBER,3 -US-UMB,18537,GRP_ROOT_BIOMASS,ROOT_BIOMASS_FINE_SPATIAL_REP_NUMBER,3 -US-UMB,18545,GRP_ROOT_BIOMASS,ROOT_BIOMASS_FINE_SPATIAL_REP_NUMBER,3 -US-UMB,18553,GRP_ROOT_BIOMASS,ROOT_BIOMASS_FINE_SPATIAL_REP_NUMBER,3 -US-UMB,18510,GRP_ROOT_BIOMASS,ROOT_BIOMASS_FINE_SPATIAL_REP_NUMBER,9 -US-UMB,18428,GRP_ROOT_BIOMASS,ROOT_BIOMASS_TOT,116.6 -US-UMB,18418,GRP_ROOT_BIOMASS,ROOT_BIOMASS_TOT,323.9 -US-UMB,18407,GRP_ROOT_BIOMASS,ROOT_BIOMASS_TOT,555.1 -US-UMB,18396,GRP_ROOT_BIOMASS,ROOT_BIOMASS_TOT,612 -US-UMB,18428,GRP_ROOT_BIOMASS,ROOT_BIOMASS_TOT_SPATIAL_VARIABILITY,188.73349663 -US-UMB,18396,GRP_ROOT_BIOMASS,ROOT_BIOMASS_TOT_SPATIAL_VARIABILITY,245.41263718 -US-UMB,18418,GRP_ROOT_BIOMASS,ROOT_BIOMASS_TOT_SPATIAL_VARIABILITY,260.92635998 -US-UMB,18407,GRP_ROOT_BIOMASS,ROOT_BIOMASS_TOT_SPATIAL_VARIABILITY,310.63132106 -US-UMB,18396,GRP_ROOT_BIOMASS,ROOT_BIOMASS_TOT_SPATIAL_REP_NUMBER,18 -US-UMB,18407,GRP_ROOT_BIOMASS,ROOT_BIOMASS_TOT_SPATIAL_REP_NUMBER,18 -US-UMB,18418,GRP_ROOT_BIOMASS,ROOT_BIOMASS_TOT_SPATIAL_REP_NUMBER,18 -US-UMB,18428,GRP_ROOT_BIOMASS,ROOT_BIOMASS_TOT_SPATIAL_REP_NUMBER,18 -US-UMB,18396,GRP_ROOT_BIOMASS,ROOT_BIOMASS_UNIT,gC m-2 -US-UMB,18407,GRP_ROOT_BIOMASS,ROOT_BIOMASS_UNIT,gC m-2 -US-UMB,18418,GRP_ROOT_BIOMASS,ROOT_BIOMASS_UNIT,gC m-2 -US-UMB,18428,GRP_ROOT_BIOMASS,ROOT_BIOMASS_UNIT,gC m-2 -US-UMB,18439,GRP_ROOT_BIOMASS,ROOT_BIOMASS_UNIT,gC m-2 -US-UMB,18448,GRP_ROOT_BIOMASS,ROOT_BIOMASS_UNIT,gC m-2 -US-UMB,18456,GRP_ROOT_BIOMASS,ROOT_BIOMASS_UNIT,gC m-2 -US-UMB,18510,GRP_ROOT_BIOMASS,ROOT_BIOMASS_UNIT,gC m-2 -US-UMB,18518,GRP_ROOT_BIOMASS,ROOT_BIOMASS_UNIT,gC m-2 -US-UMB,18526,GRP_ROOT_BIOMASS,ROOT_BIOMASS_UNIT,gC m-2 -US-UMB,18537,GRP_ROOT_BIOMASS,ROOT_BIOMASS_UNIT,gC m-2 -US-UMB,18545,GRP_ROOT_BIOMASS,ROOT_BIOMASS_UNIT,gC m-2 -US-UMB,18553,GRP_ROOT_BIOMASS,ROOT_BIOMASS_UNIT,gC m-2 -US-UMB,18439,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_ZERO_REF,Top of mineral soil -US-UMB,18448,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_ZERO_REF,Top of mineral soil -US-UMB,18526,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_ZERO_REF,Top of mineral soil -US-UMB,18537,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_ZERO_REF,Top of mineral soil -US-UMB,18545,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_ZERO_REF,Top of mineral soil -US-UMB,18553,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_ZERO_REF,Top of mineral soil -US-UMB,18396,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_ZERO_REF,Top of surface -US-UMB,18407,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_ZERO_REF,Top of surface -US-UMB,18418,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_ZERO_REF,Top of surface -US-UMB,18428,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_ZERO_REF,Top of surface -US-UMB,18456,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_ZERO_REF,Top of surface -US-UMB,18510,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_ZERO_REF,Top of surface -US-UMB,18518,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_ZERO_REF,Top of surface -US-UMB,18396,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MIN,0 -US-UMB,18456,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MIN,0 -US-UMB,18510,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MIN,0 -US-UMB,18518,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MIN,0 -US-UMB,18526,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MIN,0 -US-UMB,18537,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MIN,0 -US-UMB,18439,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MIN,10 -US-UMB,18448,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MIN,10 -US-UMB,18545,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MIN,10 -US-UMB,18553,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MIN,10 -US-UMB,18407,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MIN,15 -US-UMB,18418,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MIN,30 -US-UMB,18428,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MIN,45 -US-UMB,18526,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MAX,10 -US-UMB,18537,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MAX,10 -US-UMB,18396,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MAX,15 -US-UMB,18439,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MAX,20 -US-UMB,18545,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MAX,20 -US-UMB,18407,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MAX,30 -US-UMB,18448,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MAX,40 -US-UMB,18553,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MAX,40 -US-UMB,18418,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MAX,45 -US-UMB,18456,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MAX,5 -US-UMB,18518,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MAX,5 -US-UMB,18428,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MAX,60 -US-UMB,18510,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MAX,80 -US-UMB,18456,GRP_ROOT_BIOMASS,ROOT_BIOMASS_APPROACH,"225 cm^2 ""brownie"" of organic layer removed for fine root enumeration. Thickness of organic layer varied from site-to-site." -US-UMB,18518,GRP_ROOT_BIOMASS,ROOT_BIOMASS_APPROACH,"225 cm^2 ""brownie"" of organic layer removed for fine root enumeration. Thickness of organic layer varied from site-to-site." -US-UMB,18439,GRP_ROOT_BIOMASS,ROOT_BIOMASS_APPROACH,5.2 cm diameter soil core -US-UMB,18448,GRP_ROOT_BIOMASS,ROOT_BIOMASS_APPROACH,5.2 cm diameter soil core -US-UMB,18526,GRP_ROOT_BIOMASS,ROOT_BIOMASS_APPROACH,5.2 cm diameter soil core -US-UMB,18537,GRP_ROOT_BIOMASS,ROOT_BIOMASS_APPROACH,5.2 cm diameter soil core -US-UMB,18545,GRP_ROOT_BIOMASS,ROOT_BIOMASS_APPROACH,5.2 cm diameter soil core -US-UMB,18553,GRP_ROOT_BIOMASS,ROOT_BIOMASS_APPROACH,5.2 cm diameter soil core -US-UMB,18510,GRP_ROOT_BIOMASS,ROOT_BIOMASS_APPROACH,Fine root biomass collected using 5.2 cm diameter coring tubes; 3 samples per replicate. Includes live and dead fine roots of 2mm or less. -US-UMB,18396,GRP_ROOT_BIOMASS,ROOT_BIOMASS_APPROACH,Total root biomass collected using 5.2 cm diameter coring tubes; 5 samples per replicate. Includes live coarse roots and dead and live fine roots. -US-UMB,18407,GRP_ROOT_BIOMASS,ROOT_BIOMASS_APPROACH,Total root biomass collected using 5.2 cm diameter coring tubes; 5 samples per replicate. Includes live coarse roots and dead and live fine roots. -US-UMB,18418,GRP_ROOT_BIOMASS,ROOT_BIOMASS_APPROACH,Total root biomass collected using 5.2 cm diameter coring tubes; 5 samples per replicate. Includes live coarse roots and dead and live fine roots. -US-UMB,18428,GRP_ROOT_BIOMASS,ROOT_BIOMASS_APPROACH,Total root biomass collected using 5.2 cm diameter coring tubes; 5 samples per replicate. Includes live coarse roots and dead and live fine roots. -US-UMB,18396,GRP_ROOT_BIOMASS,ROOT_BIOMASS_DATE,19980714 -US-UMB,18407,GRP_ROOT_BIOMASS,ROOT_BIOMASS_DATE,19980714 -US-UMB,18418,GRP_ROOT_BIOMASS,ROOT_BIOMASS_DATE,19980714 -US-UMB,18428,GRP_ROOT_BIOMASS,ROOT_BIOMASS_DATE,19980714 -US-UMB,18510,GRP_ROOT_BIOMASS,ROOT_BIOMASS_DATE,20030701 -US-UMB,18439,GRP_ROOT_BIOMASS,ROOT_BIOMASS_DATE,20080714 -US-UMB,18448,GRP_ROOT_BIOMASS,ROOT_BIOMASS_DATE,20080714 -US-UMB,18518,GRP_ROOT_BIOMASS,ROOT_BIOMASS_DATE,20080714 -US-UMB,18526,GRP_ROOT_BIOMASS,ROOT_BIOMASS_DATE,20080714 -US-UMB,18456,GRP_ROOT_BIOMASS,ROOT_BIOMASS_DATE,20090714 -US-UMB,18537,GRP_ROOT_BIOMASS,ROOT_BIOMASS_DATE,20090714 -US-UMB,18545,GRP_ROOT_BIOMASS,ROOT_BIOMASS_DATE,20090714 -US-UMB,18553,GRP_ROOT_BIOMASS,ROOT_BIOMASS_DATE,20090714 -US-UMB,18396,GRP_ROOT_BIOMASS,ROOT_BIOMASS_DATE_UNC,1 -US-UMB,18407,GRP_ROOT_BIOMASS,ROOT_BIOMASS_DATE_UNC,1 -US-UMB,18418,GRP_ROOT_BIOMASS,ROOT_BIOMASS_DATE_UNC,1 -US-UMB,18428,GRP_ROOT_BIOMASS,ROOT_BIOMASS_DATE_UNC,1 -US-UMB,18439,GRP_ROOT_BIOMASS,ROOT_BIOMASS_DATE_UNC,28 -US-UMB,18448,GRP_ROOT_BIOMASS,ROOT_BIOMASS_DATE_UNC,28 -US-UMB,18456,GRP_ROOT_BIOMASS,ROOT_BIOMASS_DATE_UNC,28 -US-UMB,18510,GRP_ROOT_BIOMASS,ROOT_BIOMASS_DATE_UNC,28 -US-UMB,18518,GRP_ROOT_BIOMASS,ROOT_BIOMASS_DATE_UNC,28 -US-UMB,18526,GRP_ROOT_BIOMASS,ROOT_BIOMASS_DATE_UNC,28 -US-UMB,18537,GRP_ROOT_BIOMASS,ROOT_BIOMASS_DATE_UNC,28 -US-UMB,18545,GRP_ROOT_BIOMASS,ROOT_BIOMASS_DATE_UNC,28 -US-UMB,18553,GRP_ROOT_BIOMASS,ROOT_BIOMASS_DATE_UNC,28 -US-UMB,23844,GRP_ROOT_CHEM,ROOT_C,4.67 -US-UMB,24878,GRP_ROOT_CHEM,ROOT_C,4.69 -US-UMB,24878,GRP_ROOT_CHEM,ROOT_N,0.024 -US-UMB,23844,GRP_ROOT_CHEM,ROOT_N,0.063 -US-UMB,23844,GRP_ROOT_CHEM,ROOT_SPP,(Unknown) -US-UMB,24878,GRP_ROOT_CHEM,ROOT_SPP,(Unknown) -US-UMB,23844,GRP_ROOT_CHEM,ROOT_DATE,19980715 -US-UMB,24878,GRP_ROOT_CHEM,ROOT_DATE,19980715 -US-UMB,24878,GRP_ROOT_CHEM,ROOT_COMMENT,coarse roots -US-UMB,23844,GRP_ROOT_CHEM,ROOT_COMMENT,fine roots -US-UMB,18853,GRP_SA,SA,92 -US-UMB,18853,GRP_SA,SA_DATE,20150101 -US-UMB,18853,GRP_SA,SA_DATE_UNC,365 -US-UMB,18853,GRP_SA,SA_COMMENT,"After heavy logging, fire swept through the area in 1923 creating an even aged forest" -US-UMB,12337,GRP_SITE_CHAR,TERRAIN,Flat -US-UMB,12337,GRP_SITE_CHAR,ASPECT,FLAT -US-UMB,12337,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,3000 -US-UMB,12338,GRP_SITE_DESC,SITE_DESC,"The UMBS site is located within a protected forest owned by the University of Michigan. Arboreal composition of the forest consists of mid-aged northern hardwoods, conifer understory, aspen, and old growth hemlock. Logging of local white pines began in 1879. In successive years, several other species were harvested. Logging was discontinued in 1980 when the land became protected under the private ownership of the University of Michigan. Patchy low- to high-intensity wildfires occurred yearly from 1880 - 1920, essentially burning the entire region." -US-UMB,12339,GRP_SITE_FUNDING,SITE_FUNDING,DOE/NICCR/NOAA/NSF/Ameriflux -US-UMB,18397,GRP_SNAG_MASS,SNAG_MASS,239.9 -US-UMB,18397,GRP_SNAG_MASS,SNAG_MASS_SPATIAL_VARIABILITY,337.3 -US-UMB,18397,GRP_SNAG_MASS,SNAG_MASS_SPATIAL_REP_NUMBER,61 -US-UMB,18397,GRP_SNAG_MASS,SNAG_MASS_UNIT,gC m-2 -US-UMB,18397,GRP_SNAG_MASS,SNAG_MASS_APPROACH,Manual census -US-UMB,18397,GRP_SNAG_MASS,SNAG_MASS_DATE,20010721 -US-UMB,18397,GRP_SNAG_MASS,SNAG_MASS_DATE_UNC,28 -US-UMB,18397,GRP_SNAG_MASS,SNAG_MASS_COMMENT,Snags represent trees that were living at time of first census (1998) and had died by the time of next census (2001). -US-UMB,18408,GRP_SNAG_MASS,SNAG_MASS,608.4 -US-UMB,18408,GRP_SNAG_MASS,SNAG_MASS_SPATIAL_VARIABILITY,876.1 -US-UMB,18408,GRP_SNAG_MASS,SNAG_MASS_SPATIAL_REP_NUMBER,81 -US-UMB,18408,GRP_SNAG_MASS,SNAG_MASS_UNIT,gC m-2 -US-UMB,18408,GRP_SNAG_MASS,SNAG_MASS_APPROACH,Manual census -US-UMB,18408,GRP_SNAG_MASS,SNAG_MASS_DATE,20100721 -US-UMB,18408,GRP_SNAG_MASS,SNAG_MASS_DATE_UNC,28 -US-UMB,18408,GRP_SNAG_MASS,SNAG_MASS_COMMENT,Snags represent trees that were living at time of 2nd census (2001) and had died by the time of next census (2010). Does not include snags from 2001 census. -US-UMB,24852,GRP_SOIL_CHEM,SOIL_CHEM_C_ORG,21.62 -US-UMB,25113,GRP_SOIL_CHEM,SOIL_CHEM_C_ORG,27.53 -US-UMB,23957,GRP_SOIL_CHEM,SOIL_CHEM_C_ORG,31.25 -US-UMB,24880,GRP_SOIL_CHEM,SOIL_CHEM_N_TOT,0.57 -US-UMB,24345,GRP_SOIL_CHEM,SOIL_CHEM_PH_SALT,4.99 -US-UMB,24065,GRP_SOIL_CHEM,SOIL_CHEM_BD,0.88 -US-UMB,25112,GRP_SOIL_CHEM,SOIL_CHEM_BD,1.45 -US-UMB,24851,GRP_SOIL_CHEM,SOIL_CHEM_BD,1.5 -US-UMB,24065,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,0 -US-UMB,24345,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,0 -US-UMB,24852,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,0 -US-UMB,24880,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,0 -US-UMB,25112,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,10 -US-UMB,25113,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,20 -US-UMB,23957,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,40 -US-UMB,24851,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,50 -US-UMB,24851,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,100 -US-UMB,24345,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,15 -US-UMB,24880,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,15 -US-UMB,24852,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,20 -US-UMB,25113,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,40 -US-UMB,25112,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,50 -US-UMB,24065,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,7 -US-UMB,23957,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,80 -US-UMB,23957,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,Total -US-UMB,24065,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,Total -US-UMB,24345,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,Total -US-UMB,24851,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,Total -US-UMB,24852,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,Total -US-UMB,24880,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,Total -US-UMB,25112,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,Total -US-UMB,25113,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,Total -US-UMB,24851,GRP_SOIL_CHEM,SOIL_CHEM_DATE,19870701 -US-UMB,25112,GRP_SOIL_CHEM,SOIL_CHEM_DATE,19870701 -US-UMB,24345,GRP_SOIL_CHEM,SOIL_CHEM_DATE,19980721 -US-UMB,24880,GRP_SOIL_CHEM,SOIL_CHEM_DATE,19980721 -US-UMB,24065,GRP_SOIL_CHEM,SOIL_CHEM_DATE,20000501 -US-UMB,23957,GRP_SOIL_CHEM,SOIL_CHEM_DATE,20031001 -US-UMB,24852,GRP_SOIL_CHEM,SOIL_CHEM_DATE,20031001 -US-UMB,25113,GRP_SOIL_CHEM,SOIL_CHEM_DATE,20031001 -US-UMB,24065,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,Includes O layer (.018 m depth) -US-UMB,24880,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,litter layer removed -US-UMB,24851,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,"USDA, Soil Conservation Service, Soil Survey of Cheboygan County, Michigan" -US-UMB,25112,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,"USDA, Soil Conservation Service, Soil Survey of Cheboygan County, Michigan" -US-UMB,28786,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION,"Entic Haplorthod, glacial till, sandy, thin Wisconsin sandy lake deposits" -US-UMB,28786,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION_TAXONOMY,Other -US-UMB,23718,GRP_SOIL_DEPTH,SOIL_DEPTH,12100 -US-UMB,23718,GRP_SOIL_DEPTH,SOIL_DEPTH_COMMENT,From well drilling report -US-UMB,24587,GRP_SOIL_TEX,SOIL_TEX_SAND,92.6 -US-UMB,24587,GRP_SOIL_TEX,SOIL_TEX_SILT,6.8 -US-UMB,24587,GRP_SOIL_TEX,SOIL_TEX_CLAY,0.6 -US-UMB,24854,GRP_SOIL_TEX,SOIL_TEX_WATER_HOLD_CAP,0.031 -US-UMB,24854,GRP_SOIL_TEX,SOIL_TEX_PROFILE_MIN,0 -US-UMB,24854,GRP_SOIL_TEX,SOIL_TEX_PROFILE_MAX,15 -US-UMB,24587,GRP_SOIL_TEX,SOIL_TEX_HORIZON,Total -US-UMB,24854,GRP_SOIL_TEX,SOIL_TEX_HORIZON,Total -US-UMB,18854,GRP_SPP_O,SPP_O,Acer rubra -US-UMB,18861,GRP_SPP_O,SPP_O,Acer saccharum -US-UMB,24609,GRP_SPP_O,SPP_O,ACRU (NRCS plant code) -US-UMB,24232,GRP_SPP_O,SPP_O,BEPA (NRCS plant code) -US-UMB,18868,GRP_SPP_O,SPP_O,Betula papyrifera -US-UMB,19060,GRP_SPP_O,SPP_O,Fagus grandifolia -US-UMB,19067,GRP_SPP_O,SPP_O,Pinus strobus -US-UMB,23972,GRP_SPP_O,SPP_O,PIST (NRCS plant code) -US-UMB,24480,GRP_SPP_O,SPP_O,POGR4 (NRCS plant code) -US-UMB,19074,GRP_SPP_O,SPP_O,Populus grandidentata -US-UMB,19081,GRP_SPP_O,SPP_O,Populus tremuloides -US-UMB,24869,GRP_SPP_O,SPP_O,POTR5 (NRCS plant code) -US-UMB,18880,GRP_SPP_O,SPP_O,Quercus rubra -US-UMB,24339,GRP_SPP_O,SPP_O,QURU (NRCS plant code) -US-UMB,19081,GRP_SPP_O,SPP_O_PERC,12.5 -US-UMB,18854,GRP_SPP_O,SPP_O_PERC,14 -US-UMB,18880,GRP_SPP_O,SPP_O_PERC,16.2 -US-UMB,19067,GRP_SPP_O,SPP_O_PERC,2.2 -US-UMB,18861,GRP_SPP_O,SPP_O_PERC,2.3 -US-UMB,19074,GRP_SPP_O,SPP_O_PERC,37.9 -US-UMB,19060,GRP_SPP_O,SPP_O_PERC,4.2 -US-UMB,18868,GRP_SPP_O,SPP_O_PERC,7.5 -US-UMB,18854,GRP_SPP_O,SPP_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 77 - 0.08 ha plots for DBH of trees >= 8 cm. Counts of saplings < 8 cm DBH into 2 cm increment classes. Only saplings and seedlings that were >= 1.37m in height were included in sapling counts and thus biomass. Biomass estimated from species specific equations relating DBH to above ground woody biomass" -US-UMB,18861,GRP_SPP_O,SPP_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 77 - 0.08 ha plots for DBH of trees >= 8 cm. Counts of saplings < 8 cm DBH into 2 cm increment classes. Only saplings and seedlings that were >= 1.37m in height were included in sapling counts and thus biomass. Biomass estimated from species specific equations relating DBH to above ground woody biomass" -US-UMB,18868,GRP_SPP_O,SPP_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 77 - 0.08 ha plots for DBH of trees >= 8 cm. Counts of saplings < 8 cm DBH into 2 cm increment classes. Only saplings and seedlings that were >= 1.37m in height were included in sapling counts and thus biomass. Biomass estimated from species specific equations relating DBH to above ground woody biomass" -US-UMB,18880,GRP_SPP_O,SPP_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 77 - 0.08 ha plots for DBH of trees >= 8 cm. Counts of saplings < 8 cm DBH into 2 cm increment classes. Only saplings and seedlings that were >= 1.37m in height were included in sapling counts and thus biomass. Biomass estimated from species specific equations relating DBH to above ground woody biomass" -US-UMB,19060,GRP_SPP_O,SPP_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 77 - 0.08 ha plots for DBH of trees >= 8 cm. Counts of saplings < 8 cm DBH into 2 cm increment classes. Only saplings and seedlings that were >= 1.37m in height were included in sapling counts and thus biomass. Biomass estimated from species specific equations relating DBH to above ground woody biomass" -US-UMB,19067,GRP_SPP_O,SPP_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 77 - 0.08 ha plots for DBH of trees >= 8 cm. Counts of saplings < 8 cm DBH into 2 cm increment classes. Only saplings and seedlings that were >= 1.37m in height were included in sapling counts and thus biomass. Biomass estimated from species specific equations relating DBH to above ground woody biomass" -US-UMB,19074,GRP_SPP_O,SPP_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 77 - 0.08 ha plots for DBH of trees >= 8 cm. Counts of saplings < 8 cm DBH into 2 cm increment classes. Only saplings and seedlings that were >= 1.37m in height were included in sapling counts and thus biomass. Biomass estimated from species specific equations relating DBH to above ground woody biomass" -US-UMB,19081,GRP_SPP_O,SPP_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 77 - 0.08 ha plots for DBH of trees >= 8 cm. Counts of saplings < 8 cm DBH into 2 cm increment classes. Only saplings and seedlings that were >= 1.37m in height were included in sapling counts and thus biomass. Biomass estimated from species specific equations relating DBH to above ground woody biomass" -US-UMB,23972,GRP_SPP_O,SPP_APPROACH,Overstory trees defined as trees >=10cm DBH. Direct measurement of trees within a 60 m radius (1.13 ha plot) of flux tower and 60 - 0.08 ha plots within 1 km of flux tower. -US-UMB,24232,GRP_SPP_O,SPP_APPROACH,Overstory trees defined as trees >=10cm DBH. Direct measurement of trees within a 60 m radius (1.13 ha plot) of flux tower and 60 - 0.08 ha plots within 1 km of flux tower. -US-UMB,24339,GRP_SPP_O,SPP_APPROACH,Overstory trees defined as trees >=10cm DBH. Direct measurement of trees within a 60 m radius (1.13 ha plot) of flux tower and 60 - 0.08 ha plots within 1 km of flux tower. -US-UMB,24480,GRP_SPP_O,SPP_APPROACH,Overstory trees defined as trees >=10cm DBH. Direct measurement of trees within a 60 m radius (1.13 ha plot) of flux tower and 60 - 0.08 ha plots within 1 km of flux tower. -US-UMB,24609,GRP_SPP_O,SPP_APPROACH,Overstory trees defined as trees >=10cm DBH. Direct measurement of trees within a 60 m radius (1.13 ha plot) of flux tower and 60 - 0.08 ha plots within 1 km of flux tower. -US-UMB,24869,GRP_SPP_O,SPP_APPROACH,Overstory trees defined as trees >=10cm DBH. Direct measurement of trees within a 60 m radius (1.13 ha plot) of flux tower and 60 - 0.08 ha plots within 1 km of flux tower. -US-UMB,18854,GRP_SPP_O,SPP_DATE,20100714 -US-UMB,18861,GRP_SPP_O,SPP_DATE,20100714 -US-UMB,18868,GRP_SPP_O,SPP_DATE,20100714 -US-UMB,18880,GRP_SPP_O,SPP_DATE,20100714 -US-UMB,19060,GRP_SPP_O,SPP_DATE,20100714 -US-UMB,19067,GRP_SPP_O,SPP_DATE,20100714 -US-UMB,19074,GRP_SPP_O,SPP_DATE,20100714 -US-UMB,19081,GRP_SPP_O,SPP_DATE,20100714 -US-UMB,18854,GRP_SPP_O,SPP_DATE_UNC,28 -US-UMB,18861,GRP_SPP_O,SPP_DATE_UNC,28 -US-UMB,18868,GRP_SPP_O,SPP_DATE_UNC,28 -US-UMB,18880,GRP_SPP_O,SPP_DATE_UNC,28 -US-UMB,19060,GRP_SPP_O,SPP_DATE_UNC,28 -US-UMB,19067,GRP_SPP_O,SPP_DATE_UNC,28 -US-UMB,19074,GRP_SPP_O,SPP_DATE_UNC,28 -US-UMB,19081,GRP_SPP_O,SPP_DATE_UNC,28 -US-UMB,18854,GRP_SPP_O,SPP_COMMENT,Only species with biomass > 0.1% of total biomass included in results -US-UMB,18861,GRP_SPP_O,SPP_COMMENT,Only species with biomass > 0.1% of total biomass included in results -US-UMB,18868,GRP_SPP_O,SPP_COMMENT,Only species with biomass > 0.1% of total biomass included in results -US-UMB,18880,GRP_SPP_O,SPP_COMMENT,Only species with biomass > 0.1% of total biomass included in results -US-UMB,19060,GRP_SPP_O,SPP_COMMENT,Only species with biomass > 0.1% of total biomass included in results -US-UMB,19067,GRP_SPP_O,SPP_COMMENT,Only species with biomass > 0.1% of total biomass included in results -US-UMB,19074,GRP_SPP_O,SPP_COMMENT,Only species with biomass > 0.1% of total biomass included in results -US-UMB,19081,GRP_SPP_O,SPP_COMMENT,Only species with biomass > 0.1% of total biomass included in results -US-UMB,18855,GRP_SPP_U,SPP_U,Acer pensylvanicum -US-UMB,18862,GRP_SPP_U,SPP_U,Acer rubra -US-UMB,18869,GRP_SPP_U,SPP_U,Acer saccharum -US-UMB,24481,GRP_SPP_U,SPP_U,ACRU (NRCS plant code) -US-UMB,23974,GRP_SPP_U,SPP_U,AMELA (NRCS plant code) -US-UMB,24482,GRP_SPP_U,SPP_U,FAGR (NRCS plant code) -US-UMB,19061,GRP_SPP_U,SPP_U,Fagus grandifolia -US-UMB,19068,GRP_SPP_U,SPP_U,Pinus strobus -US-UMB,24871,GRP_SPP_U,SPP_U,PIST (NRCS plant code) -US-UMB,19075,GRP_SPP_U,SPP_U,Populus grandidentata -US-UMB,18874,GRP_SPP_U,SPP_U,Quercus rubra -US-UMB,24233,GRP_SPP_U,SPP_U,QURU (NRCS plant code) -US-UMB,18869,GRP_SPP_U,SPP_U_PERC,0.11 -US-UMB,19075,GRP_SPP_U,SPP_U_PERC,0.14 -US-UMB,18855,GRP_SPP_U,SPP_U_PERC,0.21 -US-UMB,19068,GRP_SPP_U,SPP_U_PERC,0.42 -US-UMB,18874,GRP_SPP_U,SPP_U_PERC,0.46 -US-UMB,18862,GRP_SPP_U,SPP_U_PERC,0.65 -US-UMB,19061,GRP_SPP_U,SPP_U_PERC,0.65 -US-UMB,18855,GRP_SPP_U,SPP_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 77 - 0.08 ha plots for DBH of trees >= 8 cm. Counts of saplings < 8 cm DBH into 2 cm increment classes. Only saplings and seedlings that were >= 1.37m in height were included in sapling counts and thus biomass. Biomass estimated from species specific equations relating DBH to above ground woody biomass" -US-UMB,18862,GRP_SPP_U,SPP_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 77 - 0.08 ha plots for DBH of trees >= 8 cm. Counts of saplings < 8 cm DBH into 2 cm increment classes. Only saplings and seedlings that were >= 1.37m in height were included in sapling counts and thus biomass. Biomass estimated from species specific equations relating DBH to above ground woody biomass" -US-UMB,18869,GRP_SPP_U,SPP_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 77 - 0.08 ha plots for DBH of trees >= 8 cm. Counts of saplings < 8 cm DBH into 2 cm increment classes. Only saplings and seedlings that were >= 1.37m in height were included in sapling counts and thus biomass. Biomass estimated from species specific equations relating DBH to above ground woody biomass" -US-UMB,18874,GRP_SPP_U,SPP_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 77 - 0.08 ha plots for DBH of trees >= 8 cm. Counts of saplings < 8 cm DBH into 2 cm increment classes. Only saplings and seedlings that were >= 1.37m in height were included in sapling counts and thus biomass. Biomass estimated from species specific equations relating DBH to above ground woody biomass" -US-UMB,19061,GRP_SPP_U,SPP_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 77 - 0.08 ha plots for DBH of trees >= 8 cm. Counts of saplings < 8 cm DBH into 2 cm increment classes. Only saplings and seedlings that were >= 1.37m in height were included in sapling counts and thus biomass. Biomass estimated from species specific equations relating DBH to above ground woody biomass" -US-UMB,19068,GRP_SPP_U,SPP_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 77 - 0.08 ha plots for DBH of trees >= 8 cm. Counts of saplings < 8 cm DBH into 2 cm increment classes. Only saplings and seedlings that were >= 1.37m in height were included in sapling counts and thus biomass. Biomass estimated from species specific equations relating DBH to above ground woody biomass" -US-UMB,19075,GRP_SPP_U,SPP_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 77 - 0.08 ha plots for DBH of trees >= 8 cm. Counts of saplings < 8 cm DBH into 2 cm increment classes. Only saplings and seedlings that were >= 1.37m in height were included in sapling counts and thus biomass. Biomass estimated from species specific equations relating DBH to above ground woody biomass" -US-UMB,23974,GRP_SPP_U,SPP_APPROACH,Understory trees defined as trees < 10cm DBH. Direct measurement of trees within a 60 m radius (1.13 ha plot) of flux tower and 60 - 0.08 ha plots within 1 km of flux tower. -US-UMB,24233,GRP_SPP_U,SPP_APPROACH,Understory trees defined as trees < 10cm DBH. Direct measurement of trees within a 60 m radius (1.13 ha plot) of flux tower and 60 - 0.08 ha plots within 1 km of flux tower. -US-UMB,24481,GRP_SPP_U,SPP_APPROACH,Understory trees defined as trees < 10cm DBH. Direct measurement of trees within a 60 m radius (1.13 ha plot) of flux tower and 60 - 0.08 ha plots within 1 km of flux tower. -US-UMB,24482,GRP_SPP_U,SPP_APPROACH,Understory trees defined as trees < 10cm DBH. Direct measurement of trees within a 60 m radius (1.13 ha plot) of flux tower and 60 - 0.08 ha plots within 1 km of flux tower. -US-UMB,24871,GRP_SPP_U,SPP_APPROACH,Understory trees defined as trees < 10cm DBH. Direct measurement of trees within a 60 m radius (1.13 ha plot) of flux tower and 60 - 0.08 ha plots within 1 km of flux tower. -US-UMB,18855,GRP_SPP_U,SPP_DATE,20100714 -US-UMB,18862,GRP_SPP_U,SPP_DATE,20100714 -US-UMB,18869,GRP_SPP_U,SPP_DATE,20100714 -US-UMB,18874,GRP_SPP_U,SPP_DATE,20100714 -US-UMB,19061,GRP_SPP_U,SPP_DATE,20100714 -US-UMB,19068,GRP_SPP_U,SPP_DATE,20100714 -US-UMB,19075,GRP_SPP_U,SPP_DATE,20100714 -US-UMB,18855,GRP_SPP_U,SPP_DATE_UNC,28 -US-UMB,18862,GRP_SPP_U,SPP_DATE_UNC,28 -US-UMB,18869,GRP_SPP_U,SPP_DATE_UNC,28 -US-UMB,18874,GRP_SPP_U,SPP_DATE_UNC,28 -US-UMB,19061,GRP_SPP_U,SPP_DATE_UNC,28 -US-UMB,19068,GRP_SPP_U,SPP_DATE_UNC,28 -US-UMB,19075,GRP_SPP_U,SPP_DATE_UNC,28 -US-UMB,18855,GRP_SPP_U,SPP_COMMENT,Only species with biomass > 0.1% of total biomass included in results -US-UMB,18862,GRP_SPP_U,SPP_COMMENT,Only species with biomass > 0.1% of total biomass included in results -US-UMB,18869,GRP_SPP_U,SPP_COMMENT,Only species with biomass > 0.1% of total biomass included in results -US-UMB,18874,GRP_SPP_U,SPP_COMMENT,Only species with biomass > 0.1% of total biomass included in results -US-UMB,19061,GRP_SPP_U,SPP_COMMENT,Only species with biomass > 0.1% of total biomass included in results -US-UMB,19068,GRP_SPP_U,SPP_COMMENT,Only species with biomass > 0.1% of total biomass included in results -US-UMB,19075,GRP_SPP_U,SPP_COMMENT,Only species with biomass > 0.1% of total biomass included in results -US-UMB,12340,GRP_STATE,STATE,MI -US-UMB,18567,GRP_STEM_INCR,STEM_INCR,-0.004 -US-UMB,18567,GRP_STEM_INCR,STEM_INCR_SPATIAL_VARIABILITY,0.0077 -US-UMB,18567,GRP_STEM_INCR,STEM_INCR_SPATIAL_REP_NUMBER,154 -US-UMB,18567,GRP_STEM_INCR,STEM_INCR_DIAM,18.86 -US-UMB,18567,GRP_STEM_INCR,STEM_INCR_NUM,154 -US-UMB,18567,GRP_STEM_INCR,STEM_INCR_APPROACH,Band Dendrometers -US-UMB,18567,GRP_STEM_INCR,STEM_INCR_DATE_START,20020805 -US-UMB,18567,GRP_STEM_INCR,STEM_INCR_DATE_END,20020812 -US-UMB,18567,GRP_STEM_INCR,STEM_INCR_DATE_UNC,0 -US-UMB,18567,GRP_STEM_INCR,STEM_INCR_COMMENT,"Within year data from a single, circular 1.13 ha plot with flux tower at the center of the plot. Standard deviation and means determined from number of stems measured in the plot. The same trees are measured repeatedly for within year data." -US-UMB,18491,GRP_STEM_INCR,STEM_INCR,-0.005 -US-UMB,18491,GRP_STEM_INCR,STEM_INCR_SPATIAL_VARIABILITY,0.0086 -US-UMB,18491,GRP_STEM_INCR,STEM_INCR_SPATIAL_REP_NUMBER,176 -US-UMB,18491,GRP_STEM_INCR,STEM_INCR_DIAM,20.18 -US-UMB,18491,GRP_STEM_INCR,STEM_INCR_NUM,176 -US-UMB,18491,GRP_STEM_INCR,STEM_INCR_APPROACH,Band Dendrometers -US-UMB,18491,GRP_STEM_INCR,STEM_INCR_DATE_START,20050707 -US-UMB,18491,GRP_STEM_INCR,STEM_INCR_DATE_END,20050712 -US-UMB,18491,GRP_STEM_INCR,STEM_INCR_DATE_UNC,0 -US-UMB,18491,GRP_STEM_INCR,STEM_INCR_COMMENT,"Within year data from a single, circular 1.13 ha plot with flux tower at the center of the plot. Standard deviation and means determined from number of stems measured in the plot. The same trees are measured repeatedly for within year data." -US-UMB,18497,GRP_STEM_INCR,STEM_INCR,-0.005 -US-UMB,18497,GRP_STEM_INCR,STEM_INCR_SPATIAL_VARIABILITY,0.0112 -US-UMB,18497,GRP_STEM_INCR,STEM_INCR_SPATIAL_REP_NUMBER,189 -US-UMB,18497,GRP_STEM_INCR,STEM_INCR_DIAM,20.24 -US-UMB,18497,GRP_STEM_INCR,STEM_INCR_NUM,189 -US-UMB,18497,GRP_STEM_INCR,STEM_INCR_APPROACH,Band Dendrometers -US-UMB,18497,GRP_STEM_INCR,STEM_INCR_DATE_START,20051101 -US-UMB,18497,GRP_STEM_INCR,STEM_INCR_DATE_END,20060419 -US-UMB,18497,GRP_STEM_INCR,STEM_INCR_DATE_UNC,0 -US-UMB,18497,GRP_STEM_INCR,STEM_INCR_COMMENT,"Within year data from a single, circular 1.13 ha plot with flux tower at the center of the plot. Standard deviation and means determined from number of stems measured in the plot. The same trees are measured repeatedly for within year data." -US-UMB,18483,GRP_STEM_INCR,STEM_INCR,0 -US-UMB,18483,GRP_STEM_INCR,STEM_INCR_SPATIAL_VARIABILITY,0.0082 -US-UMB,18483,GRP_STEM_INCR,STEM_INCR_SPATIAL_REP_NUMBER,180 -US-UMB,18483,GRP_STEM_INCR,STEM_INCR_DIAM,19.87 -US-UMB,18483,GRP_STEM_INCR,STEM_INCR_NUM,180 -US-UMB,18483,GRP_STEM_INCR,STEM_INCR_APPROACH,Band Dendrometers -US-UMB,18483,GRP_STEM_INCR,STEM_INCR_DATE_START,20030808 -US-UMB,18483,GRP_STEM_INCR,STEM_INCR_DATE_END,20030815 -US-UMB,18483,GRP_STEM_INCR,STEM_INCR_DATE_UNC,0 -US-UMB,18483,GRP_STEM_INCR,STEM_INCR_COMMENT,"Within year data from a single, circular 1.13 ha plot with flux tower at the center of the plot. Standard deviation and means determined from number of stems measured in the plot. The same trees are measured repeatedly for within year data." -US-UMB,18494,GRP_STEM_INCR,STEM_INCR,0 -US-UMB,18494,GRP_STEM_INCR,STEM_INCR_SPATIAL_VARIABILITY,0.0081 -US-UMB,18494,GRP_STEM_INCR,STEM_INCR_SPATIAL_REP_NUMBER,176 -US-UMB,18494,GRP_STEM_INCR,STEM_INCR_DIAM,20.21 -US-UMB,18494,GRP_STEM_INCR,STEM_INCR_NUM,176 -US-UMB,18494,GRP_STEM_INCR,STEM_INCR_APPROACH,Band Dendrometers -US-UMB,18494,GRP_STEM_INCR,STEM_INCR_DATE_START,20050728 -US-UMB,18494,GRP_STEM_INCR,STEM_INCR_DATE_END,20050804 -US-UMB,18494,GRP_STEM_INCR,STEM_INCR_DATE_UNC,0 -US-UMB,18494,GRP_STEM_INCR,STEM_INCR_COMMENT,"Within year data from a single, circular 1.13 ha plot with flux tower at the center of the plot. Standard deviation and means determined from number of stems measured in the plot. The same trees are measured repeatedly for within year data." -US-UMB,18584,GRP_STEM_INCR,STEM_INCR,0 -US-UMB,18584,GRP_STEM_INCR,STEM_INCR_SPATIAL_VARIABILITY,0.0057 -US-UMB,18584,GRP_STEM_INCR,STEM_INCR_SPATIAL_REP_NUMBER,189 -US-UMB,18584,GRP_STEM_INCR,STEM_INCR_DIAM,20.42 -US-UMB,18584,GRP_STEM_INCR,STEM_INCR_NUM,189 -US-UMB,18584,GRP_STEM_INCR,STEM_INCR_APPROACH,Band Dendrometers -US-UMB,18584,GRP_STEM_INCR,STEM_INCR_DATE_START,20060813 -US-UMB,18584,GRP_STEM_INCR,STEM_INCR_DATE_END,20060914 -US-UMB,18584,GRP_STEM_INCR,STEM_INCR_DATE_UNC,0 -US-UMB,18584,GRP_STEM_INCR,STEM_INCR_COMMENT,"Within year data from a single, circular 1.13 ha plot with flux tower at the center of the plot. Standard deviation and means determined from number of stems measured in the plot. The same trees are measured repeatedly for within year data." -US-UMB,18581,GRP_STEM_INCR,STEM_INCR,0.001 -US-UMB,18581,GRP_STEM_INCR,STEM_INCR_SPATIAL_VARIABILITY,0.0076 -US-UMB,18581,GRP_STEM_INCR,STEM_INCR_SPATIAL_REP_NUMBER,189 -US-UMB,18581,GRP_STEM_INCR,STEM_INCR_DIAM,20.41 -US-UMB,18581,GRP_STEM_INCR,STEM_INCR_NUM,189 -US-UMB,18581,GRP_STEM_INCR,STEM_INCR_APPROACH,Band Dendrometers -US-UMB,18581,GRP_STEM_INCR,STEM_INCR_DATE_START,20060726 -US-UMB,18581,GRP_STEM_INCR,STEM_INCR_DATE_END,20060801 -US-UMB,18581,GRP_STEM_INCR,STEM_INCR_DATE_UNC,0 -US-UMB,18581,GRP_STEM_INCR,STEM_INCR_COMMENT,"Within year data from a single, circular 1.13 ha plot with flux tower at the center of the plot. Standard deviation and means determined from number of stems measured in the plot. The same trees are measured repeatedly for within year data." -US-UMB,18538,GRP_STEM_INCR,STEM_INCR,0.002 -US-UMB,18538,GRP_STEM_INCR,STEM_INCR_SPATIAL_VARIABILITY,0.0121 -US-UMB,18538,GRP_STEM_INCR,STEM_INCR_SPATIAL_REP_NUMBER,160 -US-UMB,18538,GRP_STEM_INCR,STEM_INCR_DIAM,19.79 -US-UMB,18538,GRP_STEM_INCR,STEM_INCR_NUM,160 -US-UMB,18538,GRP_STEM_INCR,STEM_INCR_APPROACH,Band Dendrometers -US-UMB,18538,GRP_STEM_INCR,STEM_INCR_DATE_START,20010705 -US-UMB,18538,GRP_STEM_INCR,STEM_INCR_DATE_END,20010714 -US-UMB,18538,GRP_STEM_INCR,STEM_INCR_DATE_UNC,0 -US-UMB,18538,GRP_STEM_INCR,STEM_INCR_COMMENT,"Within year data from a single, circular 1.13 ha plot with flux tower at the center of the plot. Standard deviation and means determined from number of stems measured in the plot. The same trees are measured repeatedly for within year data." -US-UMB,18459,GRP_STEM_INCR,STEM_INCR,0.003 -US-UMB,18459,GRP_STEM_INCR,STEM_INCR_SPATIAL_VARIABILITY,0.0074 -US-UMB,18459,GRP_STEM_INCR,STEM_INCR_SPATIAL_REP_NUMBER,160 -US-UMB,18459,GRP_STEM_INCR,STEM_INCR_DIAM,19.82 -US-UMB,18459,GRP_STEM_INCR,STEM_INCR_NUM,160 -US-UMB,18459,GRP_STEM_INCR,STEM_INCR_APPROACH,Band Dendrometers -US-UMB,18459,GRP_STEM_INCR,STEM_INCR_DATE_START,20010730 -US-UMB,18459,GRP_STEM_INCR,STEM_INCR_DATE_END,20010803 -US-UMB,18459,GRP_STEM_INCR,STEM_INCR_DATE_UNC,0 -US-UMB,18459,GRP_STEM_INCR,STEM_INCR_COMMENT,"Within year data from a single, circular 1.13 ha plot with flux tower at the center of the plot. Standard deviation and means determined from number of stems measured in the plot. The same trees are measured repeatedly for within year data." -US-UMB,18466,GRP_STEM_INCR,STEM_INCR,0.003 -US-UMB,18466,GRP_STEM_INCR,STEM_INCR_SPATIAL_VARIABILITY,0.0081 -US-UMB,18466,GRP_STEM_INCR,STEM_INCR_SPATIAL_REP_NUMBER,160 -US-UMB,18466,GRP_STEM_INCR,STEM_INCR_DIAM,19.82 -US-UMB,18466,GRP_STEM_INCR,STEM_INCR_NUM,160 -US-UMB,18466,GRP_STEM_INCR,STEM_INCR_APPROACH,Band Dendrometers -US-UMB,18466,GRP_STEM_INCR,STEM_INCR_DATE_START,20010803 -US-UMB,18466,GRP_STEM_INCR,STEM_INCR_DATE_END,20010811 -US-UMB,18466,GRP_STEM_INCR,STEM_INCR_DATE_UNC,0 -US-UMB,18466,GRP_STEM_INCR,STEM_INCR_COMMENT,"Within year data from a single, circular 1.13 ha plot with flux tower at the center of the plot. Standard deviation and means determined from number of stems measured in the plot. The same trees are measured repeatedly for within year data." -US-UMB,18578,GRP_STEM_INCR,STEM_INCR,0.003 -US-UMB,18578,GRP_STEM_INCR,STEM_INCR_SPATIAL_VARIABILITY,0.0085 -US-UMB,18578,GRP_STEM_INCR,STEM_INCR_SPATIAL_REP_NUMBER,189 -US-UMB,18578,GRP_STEM_INCR,STEM_INCR_DIAM,20.38 -US-UMB,18578,GRP_STEM_INCR,STEM_INCR_NUM,189 -US-UMB,18578,GRP_STEM_INCR,STEM_INCR_APPROACH,Band Dendrometers -US-UMB,18578,GRP_STEM_INCR,STEM_INCR_DATE_START,20060705 -US-UMB,18578,GRP_STEM_INCR,STEM_INCR_DATE_END,20060712 -US-UMB,18578,GRP_STEM_INCR,STEM_INCR_DATE_UNC,0 -US-UMB,18578,GRP_STEM_INCR,STEM_INCR_COMMENT,"Within year data from a single, circular 1.13 ha plot with flux tower at the center of the plot. Standard deviation and means determined from number of stems measured in the plot. The same trees are measured repeatedly for within year data." -US-UMB,18480,GRP_STEM_INCR,STEM_INCR,0.004 -US-UMB,18480,GRP_STEM_INCR,STEM_INCR_SPATIAL_VARIABILITY,0.0078 -US-UMB,18480,GRP_STEM_INCR,STEM_INCR_SPATIAL_REP_NUMBER,160 -US-UMB,18480,GRP_STEM_INCR,STEM_INCR_DIAM,19.84 -US-UMB,18480,GRP_STEM_INCR,STEM_INCR_NUM,160 -US-UMB,18480,GRP_STEM_INCR,STEM_INCR_APPROACH,Band Dendrometers -US-UMB,18480,GRP_STEM_INCR,STEM_INCR_DATE_START,20010817 -US-UMB,18480,GRP_STEM_INCR,STEM_INCR_DATE_END,20010828 -US-UMB,18480,GRP_STEM_INCR,STEM_INCR_DATE_UNC,0 -US-UMB,18480,GRP_STEM_INCR,STEM_INCR_COMMENT,"Within year data from a single, circular 1.13 ha plot with flux tower at the center of the plot. Standard deviation and means determined from number of stems measured in the plot. The same trees are measured repeatedly for within year data." -US-UMB,18482,GRP_STEM_INCR,STEM_INCR,0.004 -US-UMB,18482,GRP_STEM_INCR,STEM_INCR_SPATIAL_VARIABILITY,0.007 -US-UMB,18482,GRP_STEM_INCR,STEM_INCR_SPATIAL_REP_NUMBER,180 -US-UMB,18482,GRP_STEM_INCR,STEM_INCR_DIAM,19.87 -US-UMB,18482,GRP_STEM_INCR,STEM_INCR_NUM,180 -US-UMB,18482,GRP_STEM_INCR,STEM_INCR_APPROACH,Band Dendrometers -US-UMB,18482,GRP_STEM_INCR,STEM_INCR_DATE_START,20030801 -US-UMB,18482,GRP_STEM_INCR,STEM_INCR_DATE_END,20030808 -US-UMB,18482,GRP_STEM_INCR,STEM_INCR_DATE_UNC,0 -US-UMB,18482,GRP_STEM_INCR,STEM_INCR_COMMENT,"Within year data from a single, circular 1.13 ha plot with flux tower at the center of the plot. Standard deviation and means determined from number of stems measured in the plot. The same trees are measured repeatedly for within year data." -US-UMB,18498,GRP_STEM_INCR,STEM_INCR,0.004 -US-UMB,18498,GRP_STEM_INCR,STEM_INCR_SPATIAL_VARIABILITY,0.0091 -US-UMB,18498,GRP_STEM_INCR,STEM_INCR_SPATIAL_REP_NUMBER,189 -US-UMB,18498,GRP_STEM_INCR,STEM_INCR_DIAM,20.24 -US-UMB,18498,GRP_STEM_INCR,STEM_INCR_NUM,189 -US-UMB,18498,GRP_STEM_INCR,STEM_INCR_APPROACH,Band Dendrometers -US-UMB,18498,GRP_STEM_INCR,STEM_INCR_DATE_START,20060419 -US-UMB,18498,GRP_STEM_INCR,STEM_INCR_DATE_END,20060428 -US-UMB,18498,GRP_STEM_INCR,STEM_INCR_DATE_UNC,0 -US-UMB,18498,GRP_STEM_INCR,STEM_INCR_COMMENT,"Within year data from a single, circular 1.13 ha plot with flux tower at the center of the plot. Standard deviation and means determined from number of stems measured in the plot. The same trees are measured repeatedly for within year data." -US-UMB,18566,GRP_STEM_INCR,STEM_INCR,0.005 -US-UMB,18566,GRP_STEM_INCR,STEM_INCR_SPATIAL_VARIABILITY,0.0088 -US-UMB,18566,GRP_STEM_INCR,STEM_INCR_SPATIAL_REP_NUMBER,154 -US-UMB,18566,GRP_STEM_INCR,STEM_INCR_DIAM,18.87 -US-UMB,18566,GRP_STEM_INCR,STEM_INCR_NUM,154 -US-UMB,18566,GRP_STEM_INCR,STEM_INCR_APPROACH,Band Dendrometers -US-UMB,18566,GRP_STEM_INCR,STEM_INCR_DATE_START,20020730 -US-UMB,18566,GRP_STEM_INCR,STEM_INCR_DATE_END,20020805 -US-UMB,18566,GRP_STEM_INCR,STEM_INCR_DATE_UNC,0 -US-UMB,18566,GRP_STEM_INCR,STEM_INCR_COMMENT,"Within year data from a single, circular 1.13 ha plot with flux tower at the center of the plot. Standard deviation and means determined from number of stems measured in the plot. The same trees are measured repeatedly for within year data." -US-UMB,18575,GRP_STEM_INCR,STEM_INCR,0.005 -US-UMB,18575,GRP_STEM_INCR,STEM_INCR_SPATIAL_VARIABILITY,0.0135 -US-UMB,18575,GRP_STEM_INCR,STEM_INCR_SPATIAL_REP_NUMBER,180 -US-UMB,18575,GRP_STEM_INCR,STEM_INCR_DIAM,19.85 -US-UMB,18575,GRP_STEM_INCR,STEM_INCR_NUM,180 -US-UMB,18575,GRP_STEM_INCR,STEM_INCR_APPROACH,Band Dendrometers -US-UMB,18575,GRP_STEM_INCR,STEM_INCR_DATE_START,20030718 -US-UMB,18575,GRP_STEM_INCR,STEM_INCR_DATE_END,20030725 -US-UMB,18575,GRP_STEM_INCR,STEM_INCR_DATE_UNC,0 -US-UMB,18575,GRP_STEM_INCR,STEM_INCR_COMMENT,"Within year data from a single, circular 1.13 ha plot with flux tower at the center of the plot. Standard deviation and means determined from number of stems measured in the plot. The same trees are measured repeatedly for within year data." -US-UMB,18577,GRP_STEM_INCR,STEM_INCR,0.005 -US-UMB,18577,GRP_STEM_INCR,STEM_INCR_SPATIAL_VARIABILITY,0.0109 -US-UMB,18577,GRP_STEM_INCR,STEM_INCR_SPATIAL_REP_NUMBER,189 -US-UMB,18577,GRP_STEM_INCR,STEM_INCR_DIAM,20.37 -US-UMB,18577,GRP_STEM_INCR,STEM_INCR_NUM,189 -US-UMB,18577,GRP_STEM_INCR,STEM_INCR_APPROACH,Band Dendrometers -US-UMB,18577,GRP_STEM_INCR,STEM_INCR_DATE_START,20060629 -US-UMB,18577,GRP_STEM_INCR,STEM_INCR_DATE_END,20060705 -US-UMB,18577,GRP_STEM_INCR,STEM_INCR_DATE_UNC,0 -US-UMB,18577,GRP_STEM_INCR,STEM_INCR_COMMENT,"Within year data from a single, circular 1.13 ha plot with flux tower at the center of the plot. Standard deviation and means determined from number of stems measured in the plot. The same trees are measured repeatedly for within year data." -US-UMB,18583,GRP_STEM_INCR,STEM_INCR,0.005 -US-UMB,18583,GRP_STEM_INCR,STEM_INCR_SPATIAL_VARIABILITY,0.0128 -US-UMB,18583,GRP_STEM_INCR,STEM_INCR_SPATIAL_REP_NUMBER,189 -US-UMB,18583,GRP_STEM_INCR,STEM_INCR_DIAM,20.42 -US-UMB,18583,GRP_STEM_INCR,STEM_INCR_NUM,189 -US-UMB,18583,GRP_STEM_INCR,STEM_INCR_APPROACH,Band Dendrometers -US-UMB,18583,GRP_STEM_INCR,STEM_INCR_DATE_START,20060809 -US-UMB,18583,GRP_STEM_INCR,STEM_INCR_DATE_END,20060813 -US-UMB,18583,GRP_STEM_INCR,STEM_INCR_DATE_UNC,0 -US-UMB,18583,GRP_STEM_INCR,STEM_INCR_COMMENT,"Within year data from a single, circular 1.13 ha plot with flux tower at the center of the plot. Standard deviation and means determined from number of stems measured in the plot. The same trees are measured repeatedly for within year data." -US-UMB,18565,GRP_STEM_INCR,STEM_INCR,0.006 -US-UMB,18565,GRP_STEM_INCR,STEM_INCR_SPATIAL_VARIABILITY,0.0076 -US-UMB,18565,GRP_STEM_INCR,STEM_INCR_SPATIAL_REP_NUMBER,154 -US-UMB,18565,GRP_STEM_INCR,STEM_INCR_DIAM,18.86 -US-UMB,18565,GRP_STEM_INCR,STEM_INCR_NUM,154 -US-UMB,18565,GRP_STEM_INCR,STEM_INCR_APPROACH,Band Dendrometers -US-UMB,18565,GRP_STEM_INCR,STEM_INCR_DATE_START,20020723 -US-UMB,18565,GRP_STEM_INCR,STEM_INCR_DATE_END,20020730 -US-UMB,18565,GRP_STEM_INCR,STEM_INCR_DATE_UNC,0 -US-UMB,18565,GRP_STEM_INCR,STEM_INCR_COMMENT,"Within year data from a single, circular 1.13 ha plot with flux tower at the center of the plot. Standard deviation and means determined from number of stems measured in the plot. The same trees are measured repeatedly for within year data." -US-UMB,18495,GRP_STEM_INCR,STEM_INCR,0.007 -US-UMB,18495,GRP_STEM_INCR,STEM_INCR_SPATIAL_VARIABILITY,0.0103 -US-UMB,18495,GRP_STEM_INCR,STEM_INCR_SPATIAL_REP_NUMBER,176 -US-UMB,18495,GRP_STEM_INCR,STEM_INCR_DIAM,20.21 -US-UMB,18495,GRP_STEM_INCR,STEM_INCR_NUM,176 -US-UMB,18495,GRP_STEM_INCR,STEM_INCR_APPROACH,Band Dendrometers -US-UMB,18495,GRP_STEM_INCR,STEM_INCR_DATE_START,20050804 -US-UMB,18495,GRP_STEM_INCR,STEM_INCR_DATE_END,20050812 -US-UMB,18495,GRP_STEM_INCR,STEM_INCR_DATE_UNC,0 -US-UMB,18495,GRP_STEM_INCR,STEM_INCR_COMMENT,"Within year data from a single, circular 1.13 ha plot with flux tower at the center of the plot. Standard deviation and means determined from number of stems measured in the plot. The same trees are measured repeatedly for within year data." -US-UMB,18429,GRP_STEM_INCR,STEM_INCR,0.008 -US-UMB,18429,GRP_STEM_INCR,STEM_INCR_SPATIAL_VARIABILITY,0.0178 -US-UMB,18429,GRP_STEM_INCR,STEM_INCR_SPATIAL_REP_NUMBER,160 -US-UMB,18429,GRP_STEM_INCR,STEM_INCR_DIAM,19.63 -US-UMB,18429,GRP_STEM_INCR,STEM_INCR_NUM,160 -US-UMB,18429,GRP_STEM_INCR,STEM_INCR_APPROACH,Band Dendrometers -US-UMB,18429,GRP_STEM_INCR,STEM_INCR_DATE_START,20001116 -US-UMB,18429,GRP_STEM_INCR,STEM_INCR_DATE_END,20010507 -US-UMB,18429,GRP_STEM_INCR,STEM_INCR_DATE_UNC,4 -US-UMB,18429,GRP_STEM_INCR,STEM_INCR_COMMENT,"Within year data from a single, circular 1.13 ha plot with flux tower at the center of the plot. Standard deviation and means determined from number of stems measured in the plot. The same trees are measured repeatedly for within year data." -US-UMB,18492,GRP_STEM_INCR,STEM_INCR,0.009 -US-UMB,18492,GRP_STEM_INCR,STEM_INCR_SPATIAL_VARIABILITY,0.011 -US-UMB,18492,GRP_STEM_INCR,STEM_INCR_SPATIAL_REP_NUMBER,176 -US-UMB,18492,GRP_STEM_INCR,STEM_INCR_DIAM,20.19 -US-UMB,18492,GRP_STEM_INCR,STEM_INCR_NUM,176 -US-UMB,18492,GRP_STEM_INCR,STEM_INCR_APPROACH,Band Dendrometers -US-UMB,18492,GRP_STEM_INCR,STEM_INCR_DATE_START,20050712 -US-UMB,18492,GRP_STEM_INCR,STEM_INCR_DATE_END,20050721 -US-UMB,18492,GRP_STEM_INCR,STEM_INCR_DATE_UNC,0 -US-UMB,18492,GRP_STEM_INCR,STEM_INCR_COMMENT,"Within year data from a single, circular 1.13 ha plot with flux tower at the center of the plot. Standard deviation and means determined from number of stems measured in the plot. The same trees are measured repeatedly for within year data." -US-UMB,18449,GRP_STEM_INCR,STEM_INCR,0.01 -US-UMB,18449,GRP_STEM_INCR,STEM_INCR_SPATIAL_VARIABILITY,0.0144 -US-UMB,18449,GRP_STEM_INCR,STEM_INCR_SPATIAL_REP_NUMBER,160 -US-UMB,18449,GRP_STEM_INCR,STEM_INCR_DIAM,19.76 -US-UMB,18449,GRP_STEM_INCR,STEM_INCR_NUM,160 -US-UMB,18449,GRP_STEM_INCR,STEM_INCR_APPROACH,Band Dendrometers -US-UMB,18449,GRP_STEM_INCR,STEM_INCR_DATE_START,20010620 -US-UMB,18449,GRP_STEM_INCR,STEM_INCR_DATE_END,20010627 -US-UMB,18449,GRP_STEM_INCR,STEM_INCR_DATE_UNC,0 -US-UMB,18449,GRP_STEM_INCR,STEM_INCR_COMMENT,"Within year data from a single, circular 1.13 ha plot with flux tower at the center of the plot. Standard deviation and means determined from number of stems measured in the plot. The same trees are measured repeatedly for within year data." -US-UMB,18499,GRP_STEM_INCR,STEM_INCR,0.01 -US-UMB,18499,GRP_STEM_INCR,STEM_INCR_SPATIAL_VARIABILITY,0.019 -US-UMB,18499,GRP_STEM_INCR,STEM_INCR_SPATIAL_REP_NUMBER,189 -US-UMB,18499,GRP_STEM_INCR,STEM_INCR_DIAM,20.25 -US-UMB,18499,GRP_STEM_INCR,STEM_INCR_NUM,189 -US-UMB,18499,GRP_STEM_INCR,STEM_INCR_APPROACH,Band Dendrometers -US-UMB,18499,GRP_STEM_INCR,STEM_INCR_DATE_START,20060428 -US-UMB,18499,GRP_STEM_INCR,STEM_INCR_DATE_END,20050509 -US-UMB,18499,GRP_STEM_INCR,STEM_INCR_DATE_UNC,0 -US-UMB,18499,GRP_STEM_INCR,STEM_INCR_COMMENT,"Within year data from a single, circular 1.13 ha plot with flux tower at the center of the plot. Standard deviation and means determined from number of stems measured in the plot. The same trees are measured repeatedly for within year data." -US-UMB,18582,GRP_STEM_INCR,STEM_INCR,0.01 -US-UMB,18582,GRP_STEM_INCR,STEM_INCR_SPATIAL_VARIABILITY,0.0118 -US-UMB,18582,GRP_STEM_INCR,STEM_INCR_SPATIAL_REP_NUMBER,189 -US-UMB,18582,GRP_STEM_INCR,STEM_INCR_DIAM,20.42 -US-UMB,18582,GRP_STEM_INCR,STEM_INCR_NUM,189 -US-UMB,18582,GRP_STEM_INCR,STEM_INCR_APPROACH,Band Dendrometers -US-UMB,18582,GRP_STEM_INCR,STEM_INCR_DATE_START,20060801 -US-UMB,18582,GRP_STEM_INCR,STEM_INCR_DATE_END,20060809 -US-UMB,18582,GRP_STEM_INCR,STEM_INCR_DATE_UNC,0 -US-UMB,18582,GRP_STEM_INCR,STEM_INCR_COMMENT,"Within year data from a single, circular 1.13 ha plot with flux tower at the center of the plot. Standard deviation and means determined from number of stems measured in the plot. The same trees are measured repeatedly for within year data." -US-UMB,18485,GRP_STEM_INCR,STEM_INCR,0.011 -US-UMB,18485,GRP_STEM_INCR,STEM_INCR_SPATIAL_VARIABILITY,0.0322 -US-UMB,18485,GRP_STEM_INCR,STEM_INCR_SPATIAL_REP_NUMBER,176 -US-UMB,18485,GRP_STEM_INCR,STEM_INCR_DIAM,20.06 -US-UMB,18485,GRP_STEM_INCR,STEM_INCR_NUM,176 -US-UMB,18485,GRP_STEM_INCR,STEM_INCR_APPROACH,Band Dendrometers -US-UMB,18485,GRP_STEM_INCR,STEM_INCR_DATE_START,20040406 -US-UMB,18485,GRP_STEM_INCR,STEM_INCR_DATE_END,20050521 -US-UMB,18485,GRP_STEM_INCR,STEM_INCR_DATE_UNC,0 -US-UMB,18485,GRP_STEM_INCR,STEM_INCR_COMMENT,"Within year data from a single, circular 1.13 ha plot with flux tower at the center of the plot. Standard deviation and means determined from number of stems measured in the plot. The same trees are measured repeatedly for within year data." -US-UMB,18527,GRP_STEM_INCR,STEM_INCR,0.011 -US-UMB,18527,GRP_STEM_INCR,STEM_INCR_SPATIAL_VARIABILITY,0.0087 -US-UMB,18527,GRP_STEM_INCR,STEM_INCR_SPATIAL_REP_NUMBER,160 -US-UMB,18527,GRP_STEM_INCR,STEM_INCR_DIAM,19.7 -US-UMB,18527,GRP_STEM_INCR,STEM_INCR_NUM,160 -US-UMB,18527,GRP_STEM_INCR,STEM_INCR_APPROACH,Band Dendrometers -US-UMB,18527,GRP_STEM_INCR,STEM_INCR_DATE_START,20010601 -US-UMB,18527,GRP_STEM_INCR,STEM_INCR_DATE_END,20010607 -US-UMB,18527,GRP_STEM_INCR,STEM_INCR_DATE_UNC,0 -US-UMB,18527,GRP_STEM_INCR,STEM_INCR_COMMENT,"Within year data from a single, circular 1.13 ha plot with flux tower at the center of the plot. Standard deviation and means determined from number of stems measured in the plot. The same trees are measured repeatedly for within year data." -US-UMB,18554,GRP_STEM_INCR,STEM_INCR,0.011 -US-UMB,18554,GRP_STEM_INCR,STEM_INCR_SPATIAL_VARIABILITY,0.0084 -US-UMB,18554,GRP_STEM_INCR,STEM_INCR_SPATIAL_REP_NUMBER,160 -US-UMB,18554,GRP_STEM_INCR,STEM_INCR_DIAM,19.85 -US-UMB,18554,GRP_STEM_INCR,STEM_INCR_NUM,160 -US-UMB,18554,GRP_STEM_INCR,STEM_INCR_APPROACH,Band Dendrometers -US-UMB,18554,GRP_STEM_INCR,STEM_INCR_DATE_START,20010817 -US-UMB,18554,GRP_STEM_INCR,STEM_INCR_DATE_END,20011102 -US-UMB,18554,GRP_STEM_INCR,STEM_INCR_DATE_UNC,0 -US-UMB,18554,GRP_STEM_INCR,STEM_INCR_COMMENT,"Within year data from a single, circular 1.13 ha plot with flux tower at the center of the plot. Standard deviation and means determined from number of stems measured in the plot. The same trees are measured repeatedly for within year data." -US-UMB,18579,GRP_STEM_INCR,STEM_INCR,0.011 -US-UMB,18579,GRP_STEM_INCR,STEM_INCR_SPATIAL_VARIABILITY,0.0114 -US-UMB,18579,GRP_STEM_INCR,STEM_INCR_SPATIAL_REP_NUMBER,189 -US-UMB,18579,GRP_STEM_INCR,STEM_INCR_DIAM,20.39 -US-UMB,18579,GRP_STEM_INCR,STEM_INCR_NUM,189 -US-UMB,18579,GRP_STEM_INCR,STEM_INCR_APPROACH,Band Dendrometers -US-UMB,18579,GRP_STEM_INCR,STEM_INCR_DATE_START,20060712 -US-UMB,18579,GRP_STEM_INCR,STEM_INCR_DATE_END,20060719 -US-UMB,18579,GRP_STEM_INCR,STEM_INCR_DATE_UNC,0 -US-UMB,18579,GRP_STEM_INCR,STEM_INCR_COMMENT,"Within year data from a single, circular 1.13 ha plot with flux tower at the center of the plot. Standard deviation and means determined from number of stems measured in the plot. The same trees are measured repeatedly for within year data." -US-UMB,18484,GRP_STEM_INCR,STEM_INCR,0.012 -US-UMB,18484,GRP_STEM_INCR,STEM_INCR_SPATIAL_VARIABILITY,0.0159 -US-UMB,18484,GRP_STEM_INCR,STEM_INCR_SPATIAL_REP_NUMBER,180 -US-UMB,18484,GRP_STEM_INCR,STEM_INCR_DIAM,19.88 -US-UMB,18484,GRP_STEM_INCR,STEM_INCR_NUM,180 -US-UMB,18484,GRP_STEM_INCR,STEM_INCR_APPROACH,Band Dendrometers -US-UMB,18484,GRP_STEM_INCR,STEM_INCR_DATE_START,20030815 -US-UMB,18484,GRP_STEM_INCR,STEM_INCR_DATE_END,20040406 -US-UMB,18484,GRP_STEM_INCR,STEM_INCR_DATE_UNC,0 -US-UMB,18484,GRP_STEM_INCR,STEM_INCR_COMMENT,"Within year data from a single, circular 1.13 ha plot with flux tower at the center of the plot. Standard deviation and means determined from number of stems measured in the plot. The same trees are measured repeatedly for within year data." -US-UMB,18561,GRP_STEM_INCR,STEM_INCR,0.012 -US-UMB,18561,GRP_STEM_INCR,STEM_INCR_SPATIAL_VARIABILITY,0.0122 -US-UMB,18561,GRP_STEM_INCR,STEM_INCR_SPATIAL_REP_NUMBER,154 -US-UMB,18561,GRP_STEM_INCR,STEM_INCR_DIAM,18.8 -US-UMB,18561,GRP_STEM_INCR,STEM_INCR_NUM,154 -US-UMB,18561,GRP_STEM_INCR,STEM_INCR_APPROACH,Band Dendrometers -US-UMB,18561,GRP_STEM_INCR,STEM_INCR_DATE_START,20020624 -US-UMB,18561,GRP_STEM_INCR,STEM_INCR_DATE_END,20020701 -US-UMB,18561,GRP_STEM_INCR,STEM_INCR_DATE_UNC,0 -US-UMB,18561,GRP_STEM_INCR,STEM_INCR_COMMENT,"Within year data from a single, circular 1.13 ha plot with flux tower at the center of the plot. Standard deviation and means determined from number of stems measured in the plot. The same trees are measured repeatedly for within year data." -US-UMB,18490,GRP_STEM_INCR,STEM_INCR,0.013 -US-UMB,18490,GRP_STEM_INCR,STEM_INCR_SPATIAL_VARIABILITY,0.013 -US-UMB,18490,GRP_STEM_INCR,STEM_INCR_SPATIAL_REP_NUMBER,176 -US-UMB,18490,GRP_STEM_INCR,STEM_INCR_DIAM,20.18 -US-UMB,18490,GRP_STEM_INCR,STEM_INCR_NUM,176 -US-UMB,18490,GRP_STEM_INCR,STEM_INCR_APPROACH,Band Dendrometers -US-UMB,18490,GRP_STEM_INCR,STEM_INCR_DATE_START,20050629 -US-UMB,18490,GRP_STEM_INCR,STEM_INCR_DATE_END,20050707 -US-UMB,18490,GRP_STEM_INCR,STEM_INCR_DATE_UNC,0 -US-UMB,18490,GRP_STEM_INCR,STEM_INCR_COMMENT,"Within year data from a single, circular 1.13 ha plot with flux tower at the center of the plot. Standard deviation and means determined from number of stems measured in the plot. The same trees are measured repeatedly for within year data." -US-UMB,18562,GRP_STEM_INCR,STEM_INCR,0.013 -US-UMB,18562,GRP_STEM_INCR,STEM_INCR_SPATIAL_VARIABILITY,0.0133 -US-UMB,18562,GRP_STEM_INCR,STEM_INCR_SPATIAL_REP_NUMBER,154 -US-UMB,18562,GRP_STEM_INCR,STEM_INCR_DIAM,18.82 -US-UMB,18562,GRP_STEM_INCR,STEM_INCR_NUM,154 -US-UMB,18562,GRP_STEM_INCR,STEM_INCR_APPROACH,Band Dendrometers -US-UMB,18562,GRP_STEM_INCR,STEM_INCR_DATE_START,20020701 -US-UMB,18562,GRP_STEM_INCR,STEM_INCR_DATE_END,20020707 -US-UMB,18562,GRP_STEM_INCR,STEM_INCR_DATE_UNC,0 -US-UMB,18562,GRP_STEM_INCR,STEM_INCR_COMMENT,"Within year data from a single, circular 1.13 ha plot with flux tower at the center of the plot. Standard deviation and means determined from number of stems measured in the plot. The same trees are measured repeatedly for within year data." -US-UMB,18563,GRP_STEM_INCR,STEM_INCR,0.013 -US-UMB,18563,GRP_STEM_INCR,STEM_INCR_SPATIAL_VARIABILITY,0.008 -US-UMB,18563,GRP_STEM_INCR,STEM_INCR_SPATIAL_REP_NUMBER,154 -US-UMB,18563,GRP_STEM_INCR,STEM_INCR_DIAM,18.83 -US-UMB,18563,GRP_STEM_INCR,STEM_INCR_NUM,154 -US-UMB,18563,GRP_STEM_INCR,STEM_INCR_APPROACH,Band Dendrometers -US-UMB,18563,GRP_STEM_INCR,STEM_INCR_DATE_START,20020707 -US-UMB,18563,GRP_STEM_INCR,STEM_INCR_DATE_END,20020715 -US-UMB,18563,GRP_STEM_INCR,STEM_INCR_DATE_UNC,0 -US-UMB,18563,GRP_STEM_INCR,STEM_INCR_COMMENT,"Within year data from a single, circular 1.13 ha plot with flux tower at the center of the plot. Standard deviation and means determined from number of stems measured in the plot. The same trees are measured repeatedly for within year data." -US-UMB,18473,GRP_STEM_INCR,STEM_INCR,0.015 -US-UMB,18473,GRP_STEM_INCR,STEM_INCR_SPATIAL_VARIABILITY,0.0128 -US-UMB,18473,GRP_STEM_INCR,STEM_INCR_SPATIAL_REP_NUMBER,160 -US-UMB,18473,GRP_STEM_INCR,STEM_INCR_DIAM,19.84 -US-UMB,18473,GRP_STEM_INCR,STEM_INCR_NUM,160 -US-UMB,18473,GRP_STEM_INCR,STEM_INCR_APPROACH,Band Dendrometers -US-UMB,18473,GRP_STEM_INCR,STEM_INCR_DATE_START,20010811 -US-UMB,18473,GRP_STEM_INCR,STEM_INCR_DATE_END,20010817 -US-UMB,18473,GRP_STEM_INCR,STEM_INCR_DATE_UNC,0 -US-UMB,18473,GRP_STEM_INCR,STEM_INCR_COMMENT,"Within year data from a single, circular 1.13 ha plot with flux tower at the center of the plot. Standard deviation and means determined from number of stems measured in the plot. The same trees are measured repeatedly for within year data." -US-UMB,18489,GRP_STEM_INCR,STEM_INCR,0.015 -US-UMB,18489,GRP_STEM_INCR,STEM_INCR_SPATIAL_VARIABILITY,0.0167 -US-UMB,18489,GRP_STEM_INCR,STEM_INCR_SPATIAL_REP_NUMBER,176 -US-UMB,18489,GRP_STEM_INCR,STEM_INCR_DIAM,20.17 -US-UMB,18489,GRP_STEM_INCR,STEM_INCR_NUM,176 -US-UMB,18489,GRP_STEM_INCR,STEM_INCR_APPROACH,Band Dendrometers -US-UMB,18489,GRP_STEM_INCR,STEM_INCR_DATE_START,20050622 -US-UMB,18489,GRP_STEM_INCR,STEM_INCR_DATE_END,20050629 -US-UMB,18489,GRP_STEM_INCR,STEM_INCR_DATE_UNC,0 -US-UMB,18489,GRP_STEM_INCR,STEM_INCR_COMMENT,"Within year data from a single, circular 1.13 ha plot with flux tower at the center of the plot. Standard deviation and means determined from number of stems measured in the plot. The same trees are measured repeatedly for within year data." -US-UMB,18558,GRP_STEM_INCR,STEM_INCR,0.015 -US-UMB,18558,GRP_STEM_INCR,STEM_INCR_SPATIAL_VARIABILITY,0.0171 -US-UMB,18558,GRP_STEM_INCR,STEM_INCR_SPATIAL_REP_NUMBER,154 -US-UMB,18558,GRP_STEM_INCR,STEM_INCR_DIAM,18.74 -US-UMB,18558,GRP_STEM_INCR,STEM_INCR_NUM,154 -US-UMB,18558,GRP_STEM_INCR,STEM_INCR_APPROACH,Band Dendrometers -US-UMB,18558,GRP_STEM_INCR,STEM_INCR_DATE_START,20020531 -US-UMB,18558,GRP_STEM_INCR,STEM_INCR_DATE_END,20020610 -US-UMB,18558,GRP_STEM_INCR,STEM_INCR_DATE_UNC,0 -US-UMB,18558,GRP_STEM_INCR,STEM_INCR_COMMENT,"Within year data from a single, circular 1.13 ha plot with flux tower at the center of the plot. Standard deviation and means determined from number of stems measured in the plot. The same trees are measured repeatedly for within year data." -US-UMB,18493,GRP_STEM_INCR,STEM_INCR,0.016 -US-UMB,18493,GRP_STEM_INCR,STEM_INCR_SPATIAL_VARIABILITY,0.0112 -US-UMB,18493,GRP_STEM_INCR,STEM_INCR_SPATIAL_REP_NUMBER,176 -US-UMB,18493,GRP_STEM_INCR,STEM_INCR_DIAM,20.2 -US-UMB,18493,GRP_STEM_INCR,STEM_INCR_NUM,176 -US-UMB,18493,GRP_STEM_INCR,STEM_INCR_APPROACH,Band Dendrometers -US-UMB,18493,GRP_STEM_INCR,STEM_INCR_DATE_START,20050721 -US-UMB,18493,GRP_STEM_INCR,STEM_INCR_DATE_END,20050728 -US-UMB,18493,GRP_STEM_INCR,STEM_INCR_DATE_UNC,0 -US-UMB,18493,GRP_STEM_INCR,STEM_INCR_COMMENT,"Within year data from a single, circular 1.13 ha plot with flux tower at the center of the plot. Standard deviation and means determined from number of stems measured in the plot. The same trees are measured repeatedly for within year data." -US-UMB,18496,GRP_STEM_INCR,STEM_INCR,0.016 -US-UMB,18496,GRP_STEM_INCR,STEM_INCR_SPATIAL_VARIABILITY,0.0127 -US-UMB,18496,GRP_STEM_INCR,STEM_INCR_SPATIAL_REP_NUMBER,176 -US-UMB,18496,GRP_STEM_INCR,STEM_INCR_DIAM,20.23 -US-UMB,18496,GRP_STEM_INCR,STEM_INCR_NUM,176 -US-UMB,18496,GRP_STEM_INCR,STEM_INCR_APPROACH,Band Dendrometers -US-UMB,18496,GRP_STEM_INCR,STEM_INCR_DATE_START,20050812 -US-UMB,18496,GRP_STEM_INCR,STEM_INCR_DATE_END,20051101 -US-UMB,18496,GRP_STEM_INCR,STEM_INCR_DATE_UNC,0 -US-UMB,18496,GRP_STEM_INCR,STEM_INCR_COMMENT,"Within year data from a single, circular 1.13 ha plot with flux tower at the center of the plot. Standard deviation and means determined from number of stems measured in the plot. The same trees are measured repeatedly for within year data." -US-UMB,18569,GRP_STEM_INCR,STEM_INCR,0.016 -US-UMB,18569,GRP_STEM_INCR,STEM_INCR_SPATIAL_VARIABILITY,0.0315 -US-UMB,18569,GRP_STEM_INCR,STEM_INCR_SPATIAL_REP_NUMBER,180 -US-UMB,18569,GRP_STEM_INCR,STEM_INCR_DIAM,19.7 -US-UMB,18569,GRP_STEM_INCR,STEM_INCR_NUM,180 -US-UMB,18569,GRP_STEM_INCR,STEM_INCR_APPROACH,Band Dendrometers -US-UMB,18569,GRP_STEM_INCR,STEM_INCR_DATE_START,20021123 -US-UMB,18569,GRP_STEM_INCR,STEM_INCR_DATE_END,20030527 -US-UMB,18569,GRP_STEM_INCR,STEM_INCR_DATE_UNC,4 -US-UMB,18569,GRP_STEM_INCR,STEM_INCR_COMMENT,"Within year data from a single, circular 1.13 ha plot with flux tower at the center of the plot. Standard deviation and means determined from number of stems measured in the plot. The same trees are measured repeatedly for within year data." -US-UMB,18504,GRP_STEM_INCR,STEM_INCR,0.017 -US-UMB,18504,GRP_STEM_INCR,STEM_INCR_SPATIAL_VARIABILITY,0.0154 -US-UMB,18504,GRP_STEM_INCR,STEM_INCR_SPATIAL_REP_NUMBER,189 -US-UMB,18504,GRP_STEM_INCR,STEM_INCR_DIAM,20.37 -US-UMB,18504,GRP_STEM_INCR,STEM_INCR_NUM,189 -US-UMB,18504,GRP_STEM_INCR,STEM_INCR_APPROACH,Band Dendrometers -US-UMB,18504,GRP_STEM_INCR,STEM_INCR_DATE_START,20060621 -US-UMB,18504,GRP_STEM_INCR,STEM_INCR_DATE_END,20060629 -US-UMB,18504,GRP_STEM_INCR,STEM_INCR_DATE_UNC,0 -US-UMB,18504,GRP_STEM_INCR,STEM_INCR_COMMENT,"Within year data from a single, circular 1.13 ha plot with flux tower at the center of the plot. Standard deviation and means determined from number of stems measured in the plot. The same trees are measured repeatedly for within year data." -US-UMB,18580,GRP_STEM_INCR,STEM_INCR,0.017 -US-UMB,18580,GRP_STEM_INCR,STEM_INCR_SPATIAL_VARIABILITY,0.0129 -US-UMB,18580,GRP_STEM_INCR,STEM_INCR_SPATIAL_REP_NUMBER,189 -US-UMB,18580,GRP_STEM_INCR,STEM_INCR_DIAM,20.41 -US-UMB,18580,GRP_STEM_INCR,STEM_INCR_NUM,189 -US-UMB,18580,GRP_STEM_INCR,STEM_INCR_APPROACH,Band Dendrometers -US-UMB,18580,GRP_STEM_INCR,STEM_INCR_DATE_START,20060719 -US-UMB,18580,GRP_STEM_INCR,STEM_INCR_DATE_END,20060726 -US-UMB,18580,GRP_STEM_INCR,STEM_INCR_DATE_UNC,0 -US-UMB,18580,GRP_STEM_INCR,STEM_INCR_COMMENT,"Within year data from a single, circular 1.13 ha plot with flux tower at the center of the plot. Standard deviation and means determined from number of stems measured in the plot. The same trees are measured repeatedly for within year data." -US-UMB,18576,GRP_STEM_INCR,STEM_INCR,0.018 -US-UMB,18576,GRP_STEM_INCR,STEM_INCR_SPATIAL_VARIABILITY,0.018 -US-UMB,18576,GRP_STEM_INCR,STEM_INCR_SPATIAL_REP_NUMBER,180 -US-UMB,18576,GRP_STEM_INCR,STEM_INCR_DIAM,19.86 -US-UMB,18576,GRP_STEM_INCR,STEM_INCR_NUM,180 -US-UMB,18576,GRP_STEM_INCR,STEM_INCR_APPROACH,Band Dendrometers -US-UMB,18576,GRP_STEM_INCR,STEM_INCR_DATE_START,20030725 -US-UMB,18576,GRP_STEM_INCR,STEM_INCR_DATE_END,20030801 -US-UMB,18576,GRP_STEM_INCR,STEM_INCR_DATE_UNC,0 -US-UMB,18576,GRP_STEM_INCR,STEM_INCR_COMMENT,"Within year data from a single, circular 1.13 ha plot with flux tower at the center of the plot. Standard deviation and means determined from number of stems measured in the plot. The same trees are measured repeatedly for within year data." -US-UMB,18486,GRP_STEM_INCR,STEM_INCR,0.02 -US-UMB,18486,GRP_STEM_INCR,STEM_INCR_SPATIAL_VARIABILITY,0.0223 -US-UMB,18486,GRP_STEM_INCR,STEM_INCR_SPATIAL_REP_NUMBER,176 -US-UMB,18486,GRP_STEM_INCR,STEM_INCR_DIAM,20.08 -US-UMB,18486,GRP_STEM_INCR,STEM_INCR_NUM,176 -US-UMB,18486,GRP_STEM_INCR,STEM_INCR_APPROACH,Band Dendrometers -US-UMB,18486,GRP_STEM_INCR,STEM_INCR_DATE_START,20050521 -US-UMB,18486,GRP_STEM_INCR,STEM_INCR_DATE_END,20050602 -US-UMB,18486,GRP_STEM_INCR,STEM_INCR_DATE_UNC,0 -US-UMB,18486,GRP_STEM_INCR,STEM_INCR_COMMENT,"Within year data from a single, circular 1.13 ha plot with flux tower at the center of the plot. Standard deviation and means determined from number of stems measured in the plot. The same trees are measured repeatedly for within year data." -US-UMB,18556,GRP_STEM_INCR,STEM_INCR,0.02 -US-UMB,18556,GRP_STEM_INCR,STEM_INCR_SPATIAL_VARIABILITY,0.0412 -US-UMB,18556,GRP_STEM_INCR,STEM_INCR_SPATIAL_REP_NUMBER,154 -US-UMB,18556,GRP_STEM_INCR,STEM_INCR_DIAM,18.73 -US-UMB,18556,GRP_STEM_INCR,STEM_INCR_NUM,154 -US-UMB,18556,GRP_STEM_INCR,STEM_INCR_APPROACH,Band Dendrometers -US-UMB,18556,GRP_STEM_INCR,STEM_INCR_DATE_START,20011102 -US-UMB,18556,GRP_STEM_INCR,STEM_INCR_DATE_END,20020531 -US-UMB,18556,GRP_STEM_INCR,STEM_INCR_DATE_UNC,0 -US-UMB,18556,GRP_STEM_INCR,STEM_INCR_COMMENT,"Within year data from a single, circular 1.13 ha plot with flux tower at the center of the plot. Standard deviation and means determined from number of stems measured in the plot. The same trees are measured repeatedly for within year data." -US-UMB,18560,GRP_STEM_INCR,STEM_INCR,0.02 -US-UMB,18560,GRP_STEM_INCR,STEM_INCR_SPATIAL_VARIABILITY,0.0146 -US-UMB,18560,GRP_STEM_INCR,STEM_INCR_SPATIAL_REP_NUMBER,154 -US-UMB,18560,GRP_STEM_INCR,STEM_INCR_DIAM,18.79 -US-UMB,18560,GRP_STEM_INCR,STEM_INCR_NUM,154 -US-UMB,18560,GRP_STEM_INCR,STEM_INCR_APPROACH,Band Dendrometers -US-UMB,18560,GRP_STEM_INCR,STEM_INCR_DATE_START,20020617 -US-UMB,18560,GRP_STEM_INCR,STEM_INCR_DATE_END,20020624 -US-UMB,18560,GRP_STEM_INCR,STEM_INCR_DATE_UNC,0 -US-UMB,18560,GRP_STEM_INCR,STEM_INCR_COMMENT,"Within year data from a single, circular 1.13 ha plot with flux tower at the center of the plot. Standard deviation and means determined from number of stems measured in the plot. The same trees are measured repeatedly for within year data." -US-UMB,18568,GRP_STEM_INCR,STEM_INCR,0.02 -US-UMB,18568,GRP_STEM_INCR,STEM_INCR_SPATIAL_VARIABILITY,0.02 -US-UMB,18568,GRP_STEM_INCR,STEM_INCR_SPATIAL_REP_NUMBER,154 -US-UMB,18568,GRP_STEM_INCR,STEM_INCR_DIAM,18.88 -US-UMB,18568,GRP_STEM_INCR,STEM_INCR_NUM,154 -US-UMB,18568,GRP_STEM_INCR,STEM_INCR_APPROACH,Band Dendrometers -US-UMB,18568,GRP_STEM_INCR,STEM_INCR_DATE_START,20020812 -US-UMB,18568,GRP_STEM_INCR,STEM_INCR_DATE_END,20021123 -US-UMB,18568,GRP_STEM_INCR,STEM_INCR_DATE_UNC,4 -US-UMB,18568,GRP_STEM_INCR,STEM_INCR_COMMENT,"Within year data from a single, circular 1.13 ha plot with flux tower at the center of the plot. Standard deviation and means determined from number of stems measured in the plot. The same trees are measured repeatedly for within year data." -US-UMB,18585,GRP_STEM_INCR,STEM_INCR,0.02 -US-UMB,18585,GRP_STEM_INCR,STEM_INCR_SPATIAL_VARIABILITY,0.0136 -US-UMB,18585,GRP_STEM_INCR,STEM_INCR_SPATIAL_REP_NUMBER,189 -US-UMB,18585,GRP_STEM_INCR,STEM_INCR_DIAM,20.44 -US-UMB,18585,GRP_STEM_INCR,STEM_INCR_NUM,189 -US-UMB,18585,GRP_STEM_INCR,STEM_INCR_APPROACH,Band Dendrometers -US-UMB,18585,GRP_STEM_INCR,STEM_INCR_DATE_START,20060914 -US-UMB,18585,GRP_STEM_INCR,STEM_INCR_DATE_END,20061115 -US-UMB,18585,GRP_STEM_INCR,STEM_INCR_DATE_UNC,0 -US-UMB,18585,GRP_STEM_INCR,STEM_INCR_COMMENT,"Within year data from a single, circular 1.13 ha plot with flux tower at the center of the plot. Standard deviation and means determined from number of stems measured in the plot. The same trees are measured repeatedly for within year data." -US-UMB,18488,GRP_STEM_INCR,STEM_INCR,0.022 -US-UMB,18488,GRP_STEM_INCR,STEM_INCR_SPATIAL_VARIABILITY,0.017 -US-UMB,18488,GRP_STEM_INCR,STEM_INCR_SPATIAL_REP_NUMBER,176 -US-UMB,18488,GRP_STEM_INCR,STEM_INCR_DIAM,20.16 -US-UMB,18488,GRP_STEM_INCR,STEM_INCR_NUM,176 -US-UMB,18488,GRP_STEM_INCR,STEM_INCR_APPROACH,Band Dendrometers -US-UMB,18488,GRP_STEM_INCR,STEM_INCR_DATE_START,20050613 -US-UMB,18488,GRP_STEM_INCR,STEM_INCR_DATE_END,20050622 -US-UMB,18488,GRP_STEM_INCR,STEM_INCR_DATE_UNC,0 -US-UMB,18488,GRP_STEM_INCR,STEM_INCR_COMMENT,"Within year data from a single, circular 1.13 ha plot with flux tower at the center of the plot. Standard deviation and means determined from number of stems measured in the plot. The same trees are measured repeatedly for within year data." -US-UMB,18501,GRP_STEM_INCR,STEM_INCR,0.022 -US-UMB,18501,GRP_STEM_INCR,STEM_INCR_SPATIAL_VARIABILITY,0.0205 -US-UMB,18501,GRP_STEM_INCR,STEM_INCR_SPATIAL_REP_NUMBER,189 -US-UMB,18501,GRP_STEM_INCR,STEM_INCR_DIAM,20.3 -US-UMB,18501,GRP_STEM_INCR,STEM_INCR_NUM,189 -US-UMB,18501,GRP_STEM_INCR,STEM_INCR_APPROACH,Band Dendrometers -US-UMB,18501,GRP_STEM_INCR,STEM_INCR_DATE_START,20060520 -US-UMB,18501,GRP_STEM_INCR,STEM_INCR_DATE_END,20060601 -US-UMB,18501,GRP_STEM_INCR,STEM_INCR_DATE_UNC,0 -US-UMB,18501,GRP_STEM_INCR,STEM_INCR_COMMENT,"Within year data from a single, circular 1.13 ha plot with flux tower at the center of the plot. Standard deviation and means determined from number of stems measured in the plot. The same trees are measured repeatedly for within year data." -US-UMB,18570,GRP_STEM_INCR,STEM_INCR,0.022 -US-UMB,18570,GRP_STEM_INCR,STEM_INCR_SPATIAL_VARIABILITY,0.0184 -US-UMB,18570,GRP_STEM_INCR,STEM_INCR_SPATIAL_REP_NUMBER,180 -US-UMB,18570,GRP_STEM_INCR,STEM_INCR_DIAM,19.72 -US-UMB,18570,GRP_STEM_INCR,STEM_INCR_NUM,180 -US-UMB,18570,GRP_STEM_INCR,STEM_INCR_APPROACH,Band Dendrometers -US-UMB,18570,GRP_STEM_INCR,STEM_INCR_DATE_START,20030527 -US-UMB,18570,GRP_STEM_INCR,STEM_INCR_DATE_END,20030604 -US-UMB,18570,GRP_STEM_INCR,STEM_INCR_DATE_UNC,0 -US-UMB,18570,GRP_STEM_INCR,STEM_INCR_COMMENT,"Within year data from a single, circular 1.13 ha plot with flux tower at the center of the plot. Standard deviation and means determined from number of stems measured in the plot. The same trees are measured repeatedly for within year data." -US-UMB,18519,GRP_STEM_INCR,STEM_INCR,0.023 -US-UMB,18519,GRP_STEM_INCR,STEM_INCR_SPATIAL_VARIABILITY,0.0183 -US-UMB,18519,GRP_STEM_INCR,STEM_INCR_SPATIAL_REP_NUMBER,160 -US-UMB,18519,GRP_STEM_INCR,STEM_INCR_DIAM,19.69 -US-UMB,18519,GRP_STEM_INCR,STEM_INCR_NUM,160 -US-UMB,18519,GRP_STEM_INCR,STEM_INCR_APPROACH,Band Dendrometers -US-UMB,18519,GRP_STEM_INCR,STEM_INCR_DATE_START,20010524 -US-UMB,18519,GRP_STEM_INCR,STEM_INCR_DATE_END,20010601 -US-UMB,18519,GRP_STEM_INCR,STEM_INCR_DATE_UNC,0 -US-UMB,18519,GRP_STEM_INCR,STEM_INCR_COMMENT,"Within year data from a single, circular 1.13 ha plot with flux tower at the center of the plot. Standard deviation and means determined from number of stems measured in the plot. The same trees are measured repeatedly for within year data." -US-UMB,18572,GRP_STEM_INCR,STEM_INCR,0.023 -US-UMB,18572,GRP_STEM_INCR,STEM_INCR_SPATIAL_VARIABILITY,0.0231 -US-UMB,18572,GRP_STEM_INCR,STEM_INCR_SPATIAL_REP_NUMBER,180 -US-UMB,18572,GRP_STEM_INCR,STEM_INCR_DIAM,19.78 -US-UMB,18572,GRP_STEM_INCR,STEM_INCR_NUM,180 -US-UMB,18572,GRP_STEM_INCR,STEM_INCR_APPROACH,Band Dendrometers -US-UMB,18572,GRP_STEM_INCR,STEM_INCR_DATE_START,20030618 -US-UMB,18572,GRP_STEM_INCR,STEM_INCR_DATE_END,20030627 -US-UMB,18572,GRP_STEM_INCR,STEM_INCR_DATE_UNC,0 -US-UMB,18572,GRP_STEM_INCR,STEM_INCR_COMMENT,"Within year data from a single, circular 1.13 ha plot with flux tower at the center of the plot. Standard deviation and means determined from number of stems measured in the plot. The same trees are measured repeatedly for within year data." -US-UMB,18457,GRP_STEM_INCR,STEM_INCR,0.024 -US-UMB,18457,GRP_STEM_INCR,STEM_INCR_SPATIAL_VARIABILITY,0.0218 -US-UMB,18457,GRP_STEM_INCR,STEM_INCR_SPATIAL_REP_NUMBER,160 -US-UMB,18457,GRP_STEM_INCR,STEM_INCR_DIAM,19.79 -US-UMB,18457,GRP_STEM_INCR,STEM_INCR_NUM,160 -US-UMB,18457,GRP_STEM_INCR,STEM_INCR_APPROACH,Band Dendrometers -US-UMB,18457,GRP_STEM_INCR,STEM_INCR_DATE_START,20010627 -US-UMB,18457,GRP_STEM_INCR,STEM_INCR_DATE_END,20010705 -US-UMB,18457,GRP_STEM_INCR,STEM_INCR_DATE_UNC,0 -US-UMB,18457,GRP_STEM_INCR,STEM_INCR_COMMENT,"Within year data from a single, circular 1.13 ha plot with flux tower at the center of the plot. Standard deviation and means determined from number of stems measured in the plot. The same trees are measured repeatedly for within year data." -US-UMB,18500,GRP_STEM_INCR,STEM_INCR,0.026 -US-UMB,18500,GRP_STEM_INCR,STEM_INCR_SPATIAL_VARIABILITY,0.0266 -US-UMB,18500,GRP_STEM_INCR,STEM_INCR_SPATIAL_REP_NUMBER,189 -US-UMB,18500,GRP_STEM_INCR,STEM_INCR_DIAM,20.27 -US-UMB,18500,GRP_STEM_INCR,STEM_INCR_NUM,189 -US-UMB,18500,GRP_STEM_INCR,STEM_INCR_APPROACH,Band Dendrometers -US-UMB,18500,GRP_STEM_INCR,STEM_INCR_DATE_START,20050509 -US-UMB,18500,GRP_STEM_INCR,STEM_INCR_DATE_END,20060520 -US-UMB,18500,GRP_STEM_INCR,STEM_INCR_DATE_UNC,0 -US-UMB,18500,GRP_STEM_INCR,STEM_INCR_COMMENT,"Within year data from a single, circular 1.13 ha plot with flux tower at the center of the plot. Standard deviation and means determined from number of stems measured in the plot. The same trees are measured repeatedly for within year data." -US-UMB,18503,GRP_STEM_INCR,STEM_INCR,0.026 -US-UMB,18503,GRP_STEM_INCR,STEM_INCR_SPATIAL_VARIABILITY,0.0177 -US-UMB,18503,GRP_STEM_INCR,STEM_INCR_SPATIAL_REP_NUMBER,189 -US-UMB,18503,GRP_STEM_INCR,STEM_INCR_DIAM,20.35 -US-UMB,18503,GRP_STEM_INCR,STEM_INCR_NUM,189 -US-UMB,18503,GRP_STEM_INCR,STEM_INCR_APPROACH,Band Dendrometers -US-UMB,18503,GRP_STEM_INCR,STEM_INCR_DATE_START,20060613 -US-UMB,18503,GRP_STEM_INCR,STEM_INCR_DATE_END,20060621 -US-UMB,18503,GRP_STEM_INCR,STEM_INCR_DATE_UNC,0 -US-UMB,18503,GRP_STEM_INCR,STEM_INCR_COMMENT,"Within year data from a single, circular 1.13 ha plot with flux tower at the center of the plot. Standard deviation and means determined from number of stems measured in the plot. The same trees are measured repeatedly for within year data." -US-UMB,18546,GRP_STEM_INCR,STEM_INCR,0.026 -US-UMB,18546,GRP_STEM_INCR,STEM_INCR_SPATIAL_VARIABILITY,0.022 -US-UMB,18546,GRP_STEM_INCR,STEM_INCR_SPATIAL_REP_NUMBER,160 -US-UMB,18546,GRP_STEM_INCR,STEM_INCR_DIAM,19.82 -US-UMB,18546,GRP_STEM_INCR,STEM_INCR_NUM,160 -US-UMB,18546,GRP_STEM_INCR,STEM_INCR_APPROACH,Band Dendrometers -US-UMB,18546,GRP_STEM_INCR,STEM_INCR_DATE_START,20010714 -US-UMB,18546,GRP_STEM_INCR,STEM_INCR_DATE_END,20010730 -US-UMB,18546,GRP_STEM_INCR,STEM_INCR_DATE_UNC,0 -US-UMB,18546,GRP_STEM_INCR,STEM_INCR_COMMENT,"Within year data from a single, circular 1.13 ha plot with flux tower at the center of the plot. Standard deviation and means determined from number of stems measured in the plot. The same trees are measured repeatedly for within year data." -US-UMB,18564,GRP_STEM_INCR,STEM_INCR,0.026 -US-UMB,18564,GRP_STEM_INCR,STEM_INCR_SPATIAL_VARIABILITY,0.0198 -US-UMB,18564,GRP_STEM_INCR,STEM_INCR_SPATIAL_REP_NUMBER,154 -US-UMB,18564,GRP_STEM_INCR,STEM_INCR_DIAM,18.85 -US-UMB,18564,GRP_STEM_INCR,STEM_INCR_NUM,154 -US-UMB,18564,GRP_STEM_INCR,STEM_INCR_APPROACH,Band Dendrometers -US-UMB,18564,GRP_STEM_INCR,STEM_INCR_DATE_START,20020715 -US-UMB,18564,GRP_STEM_INCR,STEM_INCR_DATE_END,20020723 -US-UMB,18564,GRP_STEM_INCR,STEM_INCR_DATE_UNC,0 -US-UMB,18564,GRP_STEM_INCR,STEM_INCR_COMMENT,"Within year data from a single, circular 1.13 ha plot with flux tower at the center of the plot. Standard deviation and means determined from number of stems measured in the plot. The same trees are measured repeatedly for within year data." -US-UMB,18574,GRP_STEM_INCR,STEM_INCR,0.028 -US-UMB,18574,GRP_STEM_INCR,STEM_INCR_SPATIAL_VARIABILITY,0.0159 -US-UMB,18574,GRP_STEM_INCR,STEM_INCR_SPATIAL_REP_NUMBER,180 -US-UMB,18574,GRP_STEM_INCR,STEM_INCR_DIAM,19.84 -US-UMB,18574,GRP_STEM_INCR,STEM_INCR_NUM,180 -US-UMB,18574,GRP_STEM_INCR,STEM_INCR_APPROACH,Band Dendrometers -US-UMB,18574,GRP_STEM_INCR,STEM_INCR_DATE_START,20030709 -US-UMB,18574,GRP_STEM_INCR,STEM_INCR_DATE_END,20030718 -US-UMB,18574,GRP_STEM_INCR,STEM_INCR_DATE_UNC,0 -US-UMB,18574,GRP_STEM_INCR,STEM_INCR_COMMENT,"Within year data from a single, circular 1.13 ha plot with flux tower at the center of the plot. Standard deviation and means determined from number of stems measured in the plot. The same trees are measured repeatedly for within year data." -US-UMB,18559,GRP_STEM_INCR,STEM_INCR,0.029 -US-UMB,18559,GRP_STEM_INCR,STEM_INCR_SPATIAL_VARIABILITY,0.0186 -US-UMB,18559,GRP_STEM_INCR,STEM_INCR_SPATIAL_REP_NUMBER,154 -US-UMB,18559,GRP_STEM_INCR,STEM_INCR_DIAM,18.77 -US-UMB,18559,GRP_STEM_INCR,STEM_INCR_NUM,154 -US-UMB,18559,GRP_STEM_INCR,STEM_INCR_APPROACH,Band Dendrometers -US-UMB,18559,GRP_STEM_INCR,STEM_INCR_DATE_START,20020610 -US-UMB,18559,GRP_STEM_INCR,STEM_INCR_DATE_END,20020617 -US-UMB,18559,GRP_STEM_INCR,STEM_INCR_DATE_UNC,0 -US-UMB,18559,GRP_STEM_INCR,STEM_INCR_COMMENT,"Within year data from a single, circular 1.13 ha plot with flux tower at the center of the plot. Standard deviation and means determined from number of stems measured in the plot. The same trees are measured repeatedly for within year data." -US-UMB,18502,GRP_STEM_INCR,STEM_INCR,0.03 -US-UMB,18502,GRP_STEM_INCR,STEM_INCR_SPATIAL_VARIABILITY,0.0243 -US-UMB,18502,GRP_STEM_INCR,STEM_INCR_SPATIAL_REP_NUMBER,189 -US-UMB,18502,GRP_STEM_INCR,STEM_INCR_DIAM,20.33 -US-UMB,18502,GRP_STEM_INCR,STEM_INCR_NUM,189 -US-UMB,18502,GRP_STEM_INCR,STEM_INCR_APPROACH,Band Dendrometers -US-UMB,18502,GRP_STEM_INCR,STEM_INCR_DATE_START,20060601 -US-UMB,18502,GRP_STEM_INCR,STEM_INCR_DATE_END,20060613 -US-UMB,18502,GRP_STEM_INCR,STEM_INCR_DATE_UNC,0 -US-UMB,18502,GRP_STEM_INCR,STEM_INCR_COMMENT,"Within year data from a single, circular 1.13 ha plot with flux tower at the center of the plot. Standard deviation and means determined from number of stems measured in the plot. The same trees are measured repeatedly for within year data." -US-UMB,18573,GRP_STEM_INCR,STEM_INCR,0.033 -US-UMB,18573,GRP_STEM_INCR,STEM_INCR_SPATIAL_VARIABILITY,0.0222 -US-UMB,18573,GRP_STEM_INCR,STEM_INCR_SPATIAL_REP_NUMBER,180 -US-UMB,18573,GRP_STEM_INCR,STEM_INCR_DIAM,19.81 -US-UMB,18573,GRP_STEM_INCR,STEM_INCR_NUM,180 -US-UMB,18573,GRP_STEM_INCR,STEM_INCR_APPROACH,Band Dendrometers -US-UMB,18573,GRP_STEM_INCR,STEM_INCR_DATE_START,20030627 -US-UMB,18573,GRP_STEM_INCR,STEM_INCR_DATE_END,20030709 -US-UMB,18573,GRP_STEM_INCR,STEM_INCR_DATE_UNC,0 -US-UMB,18573,GRP_STEM_INCR,STEM_INCR_COMMENT,"Within year data from a single, circular 1.13 ha plot with flux tower at the center of the plot. Standard deviation and means determined from number of stems measured in the plot. The same trees are measured repeatedly for within year data." -US-UMB,18511,GRP_STEM_INCR,STEM_INCR,0.034 -US-UMB,18511,GRP_STEM_INCR,STEM_INCR_SPATIAL_VARIABILITY,0.0359 -US-UMB,18511,GRP_STEM_INCR,STEM_INCR_SPATIAL_REP_NUMBER,160 -US-UMB,18511,GRP_STEM_INCR,STEM_INCR_DIAM,19.66 -US-UMB,18511,GRP_STEM_INCR,STEM_INCR_NUM,160 -US-UMB,18511,GRP_STEM_INCR,STEM_INCR_APPROACH,Band Dendrometers -US-UMB,18511,GRP_STEM_INCR,STEM_INCR_DATE_START,20010507 -US-UMB,18511,GRP_STEM_INCR,STEM_INCR_DATE_END,20010524 -US-UMB,18511,GRP_STEM_INCR,STEM_INCR_DATE_UNC,0 -US-UMB,18511,GRP_STEM_INCR,STEM_INCR_COMMENT,"Within year data from a single, circular 1.13 ha plot with flux tower at the center of the plot. Standard deviation and means determined from number of stems measured in the plot. The same trees are measured repeatedly for within year data." -US-UMB,18571,GRP_STEM_INCR,STEM_INCR,0.034 -US-UMB,18571,GRP_STEM_INCR,STEM_INCR_SPATIAL_VARIABILITY,0.0236 -US-UMB,18571,GRP_STEM_INCR,STEM_INCR_SPATIAL_REP_NUMBER,180 -US-UMB,18571,GRP_STEM_INCR,STEM_INCR_DIAM,19.76 -US-UMB,18571,GRP_STEM_INCR,STEM_INCR_NUM,180 -US-UMB,18571,GRP_STEM_INCR,STEM_INCR_APPROACH,Band Dendrometers -US-UMB,18571,GRP_STEM_INCR,STEM_INCR_DATE_START,20030604 -US-UMB,18571,GRP_STEM_INCR,STEM_INCR_DATE_END,20030618 -US-UMB,18571,GRP_STEM_INCR,STEM_INCR_DATE_UNC,0 -US-UMB,18571,GRP_STEM_INCR,STEM_INCR_COMMENT,"Within year data from a single, circular 1.13 ha plot with flux tower at the center of the plot. Standard deviation and means determined from number of stems measured in the plot. The same trees are measured repeatedly for within year data." -US-UMB,18440,GRP_STEM_INCR,STEM_INCR,0.054 -US-UMB,18440,GRP_STEM_INCR,STEM_INCR_SPATIAL_VARIABILITY,0.0276 -US-UMB,18440,GRP_STEM_INCR,STEM_INCR_SPATIAL_REP_NUMBER,160 -US-UMB,18440,GRP_STEM_INCR,STEM_INCR_DIAM,19.75 -US-UMB,18440,GRP_STEM_INCR,STEM_INCR_NUM,160 -US-UMB,18440,GRP_STEM_INCR,STEM_INCR_APPROACH,Band Dendrometers -US-UMB,18440,GRP_STEM_INCR,STEM_INCR_DATE_START,20010607 -US-UMB,18440,GRP_STEM_INCR,STEM_INCR_DATE_END,20010620 -US-UMB,18440,GRP_STEM_INCR,STEM_INCR_DATE_UNC,0 -US-UMB,18440,GRP_STEM_INCR,STEM_INCR_COMMENT,"Within year data from a single, circular 1.13 ha plot with flux tower at the center of the plot. Standard deviation and means determined from number of stems measured in the plot. The same trees are measured repeatedly for within year data." -US-UMB,18487,GRP_STEM_INCR,STEM_INCR,0.055 -US-UMB,18487,GRP_STEM_INCR,STEM_INCR_SPATIAL_VARIABILITY,0.0281 -US-UMB,18487,GRP_STEM_INCR,STEM_INCR_SPATIAL_REP_NUMBER,176 -US-UMB,18487,GRP_STEM_INCR,STEM_INCR_DIAM,20.14 -US-UMB,18487,GRP_STEM_INCR,STEM_INCR_NUM,176 -US-UMB,18487,GRP_STEM_INCR,STEM_INCR_APPROACH,Band Dendrometers -US-UMB,18487,GRP_STEM_INCR,STEM_INCR_DATE_START,20050602 -US-UMB,18487,GRP_STEM_INCR,STEM_INCR_DATE_END,20050613 -US-UMB,18487,GRP_STEM_INCR,STEM_INCR_DATE_UNC,0 -US-UMB,18487,GRP_STEM_INCR,STEM_INCR_COMMENT,"Within year data from a single, circular 1.13 ha plot with flux tower at the center of the plot. Standard deviation and means determined from number of stems measured in the plot. The same trees are measured repeatedly for within year data." -US-UMB,18594,GRP_STEM_INCR,STEM_INCR,0.15 -US-UMB,18594,GRP_STEM_INCR,STEM_INCR_SPATIAL_VARIABILITY,0.0498 -US-UMB,18594,GRP_STEM_INCR,STEM_INCR_SPATIAL_REP_NUMBER,51 -US-UMB,18594,GRP_STEM_INCR,STEM_INCR_DIAM,22.86 -US-UMB,18594,GRP_STEM_INCR,STEM_INCR_NUM,982 -US-UMB,18594,GRP_STEM_INCR,STEM_INCR_APPROACH,Band Dendrometers -US-UMB,18594,GRP_STEM_INCR,STEM_INCR_DATE_START,20091104 -US-UMB,18594,GRP_STEM_INCR,STEM_INCR_DATE_END,20101112 -US-UMB,18594,GRP_STEM_INCR,STEM_INCR_DATE_UNC,4 -US-UMB,18594,GRP_STEM_INCR,STEM_INCR_COMMENT,"Annual increment determined from a subset (10 -20%) of trees with DBH >=10 cm within .08 ha plots and one 1.13 ha plot. Variability determined across plots. Band dendrometers were read after autumnal leaf-off. Year-to-year variability in number of trees due to trees out growing bands, damaged bands, or additional trees outfitted with bands." -US-UMB,18596,GRP_STEM_INCR,STEM_INCR,0.164 -US-UMB,18596,GRP_STEM_INCR,STEM_INCR_SPATIAL_VARIABILITY,0.0658 -US-UMB,18596,GRP_STEM_INCR,STEM_INCR_SPATIAL_REP_NUMBER,51 -US-UMB,18596,GRP_STEM_INCR,STEM_INCR_DIAM,23.17 -US-UMB,18596,GRP_STEM_INCR,STEM_INCR_NUM,774 -US-UMB,18596,GRP_STEM_INCR,STEM_INCR_APPROACH,Band Dendrometers -US-UMB,18596,GRP_STEM_INCR,STEM_INCR_DATE_START,20111105 -US-UMB,18596,GRP_STEM_INCR,STEM_INCR_DATE_END,20121109 -US-UMB,18596,GRP_STEM_INCR,STEM_INCR_DATE_UNC,4 -US-UMB,18596,GRP_STEM_INCR,STEM_INCR_COMMENT,"Annual increment determined from a subset (10 -20%) of trees with DBH >=10 cm within .08 ha plots and one 1.13 ha plot. Variability determined across plots. Band dendrometers were read after autumnal leaf-off. Year-to-year variability in number of trees due to trees out growing bands, damaged bands, or additional trees outfitted with bands." -US-UMB,18593,GRP_STEM_INCR,STEM_INCR,0.168 -US-UMB,18593,GRP_STEM_INCR,STEM_INCR_SPATIAL_VARIABILITY,0.0615 -US-UMB,18593,GRP_STEM_INCR,STEM_INCR_SPATIAL_REP_NUMBER,51 -US-UMB,18593,GRP_STEM_INCR,STEM_INCR_DIAM,22.77 -US-UMB,18593,GRP_STEM_INCR,STEM_INCR_NUM,960 -US-UMB,18593,GRP_STEM_INCR,STEM_INCR_APPROACH,Band Dendrometers -US-UMB,18593,GRP_STEM_INCR,STEM_INCR_DATE_START,20081104 -US-UMB,18593,GRP_STEM_INCR,STEM_INCR_DATE_END,20091104 -US-UMB,18593,GRP_STEM_INCR,STEM_INCR_DATE_UNC,4 -US-UMB,18593,GRP_STEM_INCR,STEM_INCR_COMMENT,"Annual increment determined from a subset (10 -20%) of trees with DBH >=10 cm within .08 ha plots and one 1.13 ha plot. Variability determined across plots. Band dendrometers were read after autumnal leaf-off. Year-to-year variability in number of trees due to trees out growing bands, damaged bands, or additional trees outfitted with bands." -US-UMB,18592,GRP_STEM_INCR,STEM_INCR,0.184 -US-UMB,18592,GRP_STEM_INCR,STEM_INCR_SPATIAL_VARIABILITY,0.0741 -US-UMB,18592,GRP_STEM_INCR,STEM_INCR_SPATIAL_REP_NUMBER,51 -US-UMB,18592,GRP_STEM_INCR,STEM_INCR_DIAM,22.56 -US-UMB,18592,GRP_STEM_INCR,STEM_INCR_NUM,829 -US-UMB,18592,GRP_STEM_INCR,STEM_INCR_APPROACH,Band Dendrometers -US-UMB,18592,GRP_STEM_INCR,STEM_INCR_DATE_START,20071017 -US-UMB,18592,GRP_STEM_INCR,STEM_INCR_DATE_END,20081104 -US-UMB,18592,GRP_STEM_INCR,STEM_INCR_DATE_UNC,4 -US-UMB,18592,GRP_STEM_INCR,STEM_INCR_COMMENT,"Annual increment determined from a subset (10 -20%) of trees with DBH >=10 cm within .08 ha plots and one 1.13 ha plot. Variability determined across plots. Band dendrometers were read after autumnal leaf-off. Year-to-year variability in number of trees due to trees out growing bands, damaged bands, or additional trees outfitted with bands." -US-UMB,18597,GRP_STEM_INCR,STEM_INCR,0.184 -US-UMB,18597,GRP_STEM_INCR,STEM_INCR_SPATIAL_VARIABILITY,0.061 -US-UMB,18597,GRP_STEM_INCR,STEM_INCR_SPATIAL_REP_NUMBER,51 -US-UMB,18597,GRP_STEM_INCR,STEM_INCR_DIAM,23.43 -US-UMB,18597,GRP_STEM_INCR,STEM_INCR_NUM,1078 -US-UMB,18597,GRP_STEM_INCR,STEM_INCR_APPROACH,Band Dendrometers -US-UMB,18597,GRP_STEM_INCR,STEM_INCR_DATE_START,20121109 -US-UMB,18597,GRP_STEM_INCR,STEM_INCR_DATE_END,20131020 -US-UMB,18597,GRP_STEM_INCR,STEM_INCR_DATE_UNC,7 -US-UMB,18597,GRP_STEM_INCR,STEM_INCR_COMMENT,"Annual increment determined from a subset (10 -20%) of trees with DBH >=10 cm within .08 ha plots and one 1.13 ha plot. Variability determined across plots. Band dendrometers were read after autumnal leaf-off. Year-to-year variability in number of trees due to trees out growing bands, damaged bands, or additional trees outfitted with bands." -US-UMB,18595,GRP_STEM_INCR,STEM_INCR,0.19 -US-UMB,18595,GRP_STEM_INCR,STEM_INCR_SPATIAL_VARIABILITY,0.0657 -US-UMB,18595,GRP_STEM_INCR,STEM_INCR_SPATIAL_REP_NUMBER,51 -US-UMB,18595,GRP_STEM_INCR,STEM_INCR_DIAM,23.02 -US-UMB,18595,GRP_STEM_INCR,STEM_INCR_NUM,965 -US-UMB,18595,GRP_STEM_INCR,STEM_INCR_APPROACH,Band Dendrometers -US-UMB,18595,GRP_STEM_INCR,STEM_INCR_DATE_START,20101112 -US-UMB,18595,GRP_STEM_INCR,STEM_INCR_DATE_END,20111105 -US-UMB,18595,GRP_STEM_INCR,STEM_INCR_DATE_UNC,4 -US-UMB,18595,GRP_STEM_INCR,STEM_INCR_COMMENT,"Annual increment determined from a subset (10 -20%) of trees with DBH >=10 cm within .08 ha plots and one 1.13 ha plot. Variability determined across plots. Band dendrometers were read after autumnal leaf-off. Year-to-year variability in number of trees due to trees out growing bands, damaged bands, or additional trees outfitted with bands." -US-UMB,18586,GRP_STEM_INCR,STEM_INCR,0.195 -US-UMB,18586,GRP_STEM_INCR,STEM_INCR_SPATIAL_VARIABILITY,0.0352 -US-UMB,18586,GRP_STEM_INCR,STEM_INCR_SPATIAL_REP_NUMBER,31 -US-UMB,18586,GRP_STEM_INCR,STEM_INCR_DIAM,22.56 -US-UMB,18586,GRP_STEM_INCR,STEM_INCR_NUM,514 -US-UMB,18586,GRP_STEM_INCR,STEM_INCR_APPROACH,Band Dendrometers -US-UMB,18586,GRP_STEM_INCR,STEM_INCR_DATE_START,20011102 -US-UMB,18586,GRP_STEM_INCR,STEM_INCR_DATE_END,20021123 -US-UMB,18586,GRP_STEM_INCR,STEM_INCR_DATE_UNC,4 -US-UMB,18586,GRP_STEM_INCR,STEM_INCR_COMMENT,"Annual increment determined from a subset (10 -20%) of trees with DBH >=10 cm within .08 ha plots and one 1.13 ha plot. Variability determined across plots. Band dendrometers were read after autumnal leaf-off. Year-to-year variability in number of trees due to trees out growing bands, damaged bands, or additional trees outfitted with bands." -US-UMB,18591,GRP_STEM_INCR,STEM_INCR,0.204 -US-UMB,18591,GRP_STEM_INCR,STEM_INCR_SPATIAL_VARIABILITY,0.0869 -US-UMB,18591,GRP_STEM_INCR,STEM_INCR_SPATIAL_REP_NUMBER,51 -US-UMB,18591,GRP_STEM_INCR,STEM_INCR_DIAM,22.32 -US-UMB,18591,GRP_STEM_INCR,STEM_INCR_NUM,957 -US-UMB,18591,GRP_STEM_INCR,STEM_INCR_APPROACH,Band Dendrometers -US-UMB,18591,GRP_STEM_INCR,STEM_INCR_DATE_START,20061115 -US-UMB,18591,GRP_STEM_INCR,STEM_INCR_DATE_END,20071017 -US-UMB,18591,GRP_STEM_INCR,STEM_INCR_DATE_UNC,4 -US-UMB,18591,GRP_STEM_INCR,STEM_INCR_COMMENT,"Annual increment determined from a subset (10 -20%) of trees with DBH >=10 cm within .08 ha plots and one 1.13 ha plot. Variability determined across plots. Band dendrometers were read after autumnal leaf-off. Year-to-year variability in number of trees due to trees out growing bands, damaged bands, or additional trees outfitted with bands." -US-UMB,18598,GRP_STEM_INCR,STEM_INCR,0.215 -US-UMB,18598,GRP_STEM_INCR,STEM_INCR_SPATIAL_VARIABILITY,0.0776 -US-UMB,18598,GRP_STEM_INCR,STEM_INCR_SPATIAL_REP_NUMBER,51 -US-UMB,18598,GRP_STEM_INCR,STEM_INCR_DIAM,23.64 -US-UMB,18598,GRP_STEM_INCR,STEM_INCR_NUM,1108 -US-UMB,18598,GRP_STEM_INCR,STEM_INCR_APPROACH,Band Dendrometers -US-UMB,18598,GRP_STEM_INCR,STEM_INCR_DATE_START,20131020 -US-UMB,18598,GRP_STEM_INCR,STEM_INCR_DATE_END,20141101 -US-UMB,18598,GRP_STEM_INCR,STEM_INCR_DATE_UNC,7 -US-UMB,18598,GRP_STEM_INCR,STEM_INCR_COMMENT,"Annual increment determined from a subset (10 -20%) of trees with DBH >=10 cm within .08 ha plots and one 1.13 ha plot. Variability determined across plots. Band dendrometers were read after autumnal leaf-off. Year-to-year variability in number of trees due to trees out growing bands, damaged bands, or additional trees outfitted with bands." -US-UMB,18590,GRP_STEM_INCR,STEM_INCR,0.224 -US-UMB,18590,GRP_STEM_INCR,STEM_INCR_SPATIAL_VARIABILITY,0.0896 -US-UMB,18590,GRP_STEM_INCR,STEM_INCR_SPATIAL_REP_NUMBER,51 -US-UMB,18590,GRP_STEM_INCR,STEM_INCR_DIAM,22.22 -US-UMB,18590,GRP_STEM_INCR,STEM_INCR_NUM,986 -US-UMB,18590,GRP_STEM_INCR,STEM_INCR_APPROACH,Band Dendrometers -US-UMB,18590,GRP_STEM_INCR,STEM_INCR_DATE_START,20051101 -US-UMB,18590,GRP_STEM_INCR,STEM_INCR_DATE_END,20061115 -US-UMB,18590,GRP_STEM_INCR,STEM_INCR_DATE_UNC,4 -US-UMB,18590,GRP_STEM_INCR,STEM_INCR_COMMENT,"Annual increment determined from a subset (10 -20%) of trees with DBH >=10 cm within .08 ha plots and one 1.13 ha plot. Variability determined across plots. Band dendrometers were read after autumnal leaf-off. Year-to-year variability in number of trees due to trees out growing bands, damaged bands, or additional trees outfitted with bands." -US-UMB,18588,GRP_STEM_INCR,STEM_INCR,0.226 -US-UMB,18588,GRP_STEM_INCR,STEM_INCR_SPATIAL_VARIABILITY,0.0925 -US-UMB,18588,GRP_STEM_INCR,STEM_INCR_SPATIAL_REP_NUMBER,51 -US-UMB,18588,GRP_STEM_INCR,STEM_INCR_DIAM,21.83 -US-UMB,18588,GRP_STEM_INCR,STEM_INCR_NUM,906 -US-UMB,18588,GRP_STEM_INCR,STEM_INCR_APPROACH,Band Dendrometers -US-UMB,18588,GRP_STEM_INCR,STEM_INCR_DATE_START,20031108 -US-UMB,18588,GRP_STEM_INCR,STEM_INCR_DATE_END,20041106 -US-UMB,18588,GRP_STEM_INCR,STEM_INCR_DATE_UNC,4 -US-UMB,18588,GRP_STEM_INCR,STEM_INCR_COMMENT,"Annual increment determined from a subset (10 -20%) of trees with DBH >=10 cm within .08 ha plots and one 1.13 ha plot. Variability determined across plots. Band dendrometers were read after autumnal leaf-off. Year-to-year variability in number of trees due to trees out growing bands, damaged bands, or additional trees outfitted with bands." -US-UMB,18589,GRP_STEM_INCR,STEM_INCR,0.226 -US-UMB,18589,GRP_STEM_INCR,STEM_INCR_SPATIAL_VARIABILITY,0.057 -US-UMB,18589,GRP_STEM_INCR,STEM_INCR_SPATIAL_REP_NUMBER,51 -US-UMB,18589,GRP_STEM_INCR,STEM_INCR_DIAM,22.09 -US-UMB,18589,GRP_STEM_INCR,STEM_INCR_NUM,922 -US-UMB,18589,GRP_STEM_INCR,STEM_INCR_APPROACH,Band Dendrometers -US-UMB,18589,GRP_STEM_INCR,STEM_INCR_DATE_START,20041106 -US-UMB,18589,GRP_STEM_INCR,STEM_INCR_DATE_END,20051101 -US-UMB,18589,GRP_STEM_INCR,STEM_INCR_DATE_UNC,4 -US-UMB,18589,GRP_STEM_INCR,STEM_INCR_COMMENT,"Annual increment determined from a subset (10 -20%) of trees with DBH >=10 cm within .08 ha plots and one 1.13 ha plot. Variability determined across plots. Band dendrometers were read after autumnal leaf-off. Year-to-year variability in number of trees due to trees out growing bands, damaged bands, or additional trees outfitted with bands." -US-UMB,18587,GRP_STEM_INCR,STEM_INCR,0.243 -US-UMB,18587,GRP_STEM_INCR,STEM_INCR_SPATIAL_VARIABILITY,0.0985 -US-UMB,18587,GRP_STEM_INCR,STEM_INCR_SPATIAL_REP_NUMBER,31 -US-UMB,18587,GRP_STEM_INCR,STEM_INCR_DIAM,22.89 -US-UMB,18587,GRP_STEM_INCR,STEM_INCR_NUM,593 -US-UMB,18587,GRP_STEM_INCR,STEM_INCR_APPROACH,Band Dendrometers -US-UMB,18587,GRP_STEM_INCR,STEM_INCR_DATE_START,20021123 -US-UMB,18587,GRP_STEM_INCR,STEM_INCR_DATE_END,20031108 -US-UMB,18587,GRP_STEM_INCR,STEM_INCR_DATE_UNC,4 -US-UMB,18587,GRP_STEM_INCR,STEM_INCR_COMMENT,"Annual increment determined from a subset (10 -20%) of trees with DBH >=10 cm within .08 ha plots and one 1.13 ha plot. Variability determined across plots. Band dendrometers were read after autumnal leaf-off. Year-to-year variability in number of trees due to trees out growing bands, damaged bands, or additional trees outfitted with bands." -US-UMB,18419,GRP_STEM_INCR,STEM_INCR,0.268 -US-UMB,18419,GRP_STEM_INCR,STEM_INCR_SPATIAL_VARIABILITY,0.078 -US-UMB,18419,GRP_STEM_INCR,STEM_INCR_SPATIAL_REP_NUMBER,31 -US-UMB,18419,GRP_STEM_INCR,STEM_INCR_DIAM,22.33 -US-UMB,18419,GRP_STEM_INCR,STEM_INCR_NUM,556 -US-UMB,18419,GRP_STEM_INCR,STEM_INCR_APPROACH,Band Dendrometers -US-UMB,18419,GRP_STEM_INCR,STEM_INCR_DATE_START,20001116 -US-UMB,18419,GRP_STEM_INCR,STEM_INCR_DATE_END,20011102 -US-UMB,18419,GRP_STEM_INCR,STEM_INCR_DATE_UNC,4 -US-UMB,18419,GRP_STEM_INCR,STEM_INCR_COMMENT,"Annual increment determined from a subset (10 -20%) of trees with DBH >=10 cm within .08 ha plots and one 1.13 ha plot. Variability determined across plots. Band dendrometers were read after autumnal leaf-off. Year-to-year variability in number of trees due to trees out growing bands, damaged bands, or additional trees outfitted with bands." -US-UMB,18409,GRP_STEM_INCR,STEM_INCR,0.281 -US-UMB,18409,GRP_STEM_INCR,STEM_INCR_SPATIAL_VARIABILITY,0.091 -US-UMB,18409,GRP_STEM_INCR,STEM_INCR_SPATIAL_REP_NUMBER,31 -US-UMB,18409,GRP_STEM_INCR,STEM_INCR_DIAM,22.07 -US-UMB,18409,GRP_STEM_INCR,STEM_INCR_NUM,569 -US-UMB,18409,GRP_STEM_INCR,STEM_INCR_APPROACH,Band Dendrometers -US-UMB,18409,GRP_STEM_INCR,STEM_INCR_DATE_START,19991101 -US-UMB,18409,GRP_STEM_INCR,STEM_INCR_DATE_END,20001116 -US-UMB,18409,GRP_STEM_INCR,STEM_INCR_DATE_UNC,4 -US-UMB,18409,GRP_STEM_INCR,STEM_INCR_COMMENT,"Annual increment determined from a subset (10 -20%) of trees with DBH >=10 cm within .08 ha plots and one 1.13 ha plot. Variability determined across plots. Band dendrometers were read after autumnal leaf-off. Year-to-year variability in number of trees due to trees out growing bands, damaged bands, or additional trees outfitted with bands." -US-UMB,18398,GRP_STEM_INCR,STEM_INCR,0.288 -US-UMB,18398,GRP_STEM_INCR,STEM_INCR_SPATIAL_VARIABILITY,0.0924 -US-UMB,18398,GRP_STEM_INCR,STEM_INCR_SPATIAL_REP_NUMBER,31 -US-UMB,18398,GRP_STEM_INCR,STEM_INCR_DIAM,21.94 -US-UMB,18398,GRP_STEM_INCR,STEM_INCR_NUM,551 -US-UMB,18398,GRP_STEM_INCR,STEM_INCR_APPROACH,Band Dendrometers -US-UMB,18398,GRP_STEM_INCR,STEM_INCR_DATE_START,19981101 -US-UMB,18398,GRP_STEM_INCR,STEM_INCR_DATE_END,19991101 -US-UMB,18398,GRP_STEM_INCR,STEM_INCR_DATE_UNC,4 -US-UMB,18398,GRP_STEM_INCR,STEM_INCR_COMMENT,"Annual increment determined from a subset (10 -20%) of trees with DBH >=10 cm within .08 ha plots and one 1.13 ha plot. Variability determined across plots. Band dendrometers were read after autumnal leaf-off. Year-to-year variability in number of trees due to trees out growing bands, damaged bands, or additional trees outfitted with bands." -US-UMB,18505,GRP_STEM_INCR,STEM_INCR,0.838 -US-UMB,18505,GRP_STEM_INCR,STEM_INCR_SPATIAL_VARIABILITY,0.1803 -US-UMB,18505,GRP_STEM_INCR,STEM_INCR_SPATIAL_REP_NUMBER,13 -US-UMB,18505,GRP_STEM_INCR,STEM_INCR_DIAM,20.33 -US-UMB,18505,GRP_STEM_INCR,STEM_INCR_NUM,715 -US-UMB,18505,GRP_STEM_INCR,STEM_INCR_APPROACH,manual measurement - census -US-UMB,18505,GRP_STEM_INCR,STEM_INCR_DATE_START,19980715 -US-UMB,18505,GRP_STEM_INCR,STEM_INCR_DATE_END,20010715 -US-UMB,18505,GRP_STEM_INCR,STEM_INCR_DATE_UNC,28 -US-UMB,18505,GRP_STEM_INCR,STEM_INCR_COMMENT,"Three year increment of trees with DBH >= 8 cm and only included trees that were live and had DBH >= 8 cm both census years, i.e., trees measured in 1997, but were dead in 2001 were not included and trees <8 cm in 1997 but >=8 cm in 2001 were not included. Measurements made during June -August. stem diameter represents diameter in 2001. Plot size = 0.08 ha and are different plots than measured in 1997 - 2001." -US-UMB,18599,GRP_STEM_INCR,STEM_INCR,1.041 -US-UMB,18599,GRP_STEM_INCR,STEM_INCR_SPATIAL_VARIABILITY,0.2973 -US-UMB,18599,GRP_STEM_INCR,STEM_INCR_SPATIAL_REP_NUMBER,48 -US-UMB,18599,GRP_STEM_INCR,STEM_INCR_DIAM,19.95 -US-UMB,18599,GRP_STEM_INCR,STEM_INCR_NUM,3487 -US-UMB,18599,GRP_STEM_INCR,STEM_INCR_APPROACH,manual measurement - census -US-UMB,18599,GRP_STEM_INCR,STEM_INCR_DATE_START,19970715 -US-UMB,18599,GRP_STEM_INCR,STEM_INCR_DATE_END,20010715 -US-UMB,18599,GRP_STEM_INCR,STEM_INCR_DATE_UNC,28 -US-UMB,18599,GRP_STEM_INCR,STEM_INCR_COMMENT,"Four year increment of trees with DBH >= 8 cm and only included trees that were live and had DBH >= 8 cm both census years, i.e., trees measured in 1997, but were dead in 2001 were not included and trees <8 cm in 1997 but >=8 cm in 2001 were not included. Measurements made during June -August. Stem diameter represents diameter in 2001. Plot size = 0.08 ha for 47 plots and 1.13 ha for one plot." -US-UMB,18507,GRP_STEM_INCR,STEM_INCR,1.388 -US-UMB,18507,GRP_STEM_INCR,STEM_INCR_SPATIAL_VARIABILITY,0.3713 -US-UMB,18507,GRP_STEM_INCR,STEM_INCR_SPATIAL_REP_NUMBER,20 -US-UMB,18507,GRP_STEM_INCR,STEM_INCR_DIAM,20.77 -US-UMB,18507,GRP_STEM_INCR,STEM_INCR_NUM,1072 -US-UMB,18507,GRP_STEM_INCR,STEM_INCR_APPROACH,manual measurement - census -US-UMB,18507,GRP_STEM_INCR,STEM_INCR_DATE_START,20030715 -US-UMB,18507,GRP_STEM_INCR,STEM_INCR_DATE_END,20100715 -US-UMB,18507,GRP_STEM_INCR,STEM_INCR_DATE_UNC,28 -US-UMB,18507,GRP_STEM_INCR,STEM_INCR_COMMENT,"Seven year increment of trees with DBH >= 8 cm and only included trees that were live and had DBH >= 8 cm both census years, i.e., trees measured in 2003, but were dead in 2010 were not included and trees <8 cm in 2003 but >=8 cm in 2010 were not included. Measurements made during June -August. Stem diameter represents diameter in 2010. Plot size = 0.08 ha." -US-UMB,18506,GRP_STEM_INCR,STEM_INCR,1.929 -US-UMB,18506,GRP_STEM_INCR,STEM_INCR_SPATIAL_VARIABILITY,0.5823 -US-UMB,18506,GRP_STEM_INCR,STEM_INCR_SPATIAL_REP_NUMBER,61 -US-UMB,18506,GRP_STEM_INCR,STEM_INCR_DIAM,20.94 -US-UMB,18506,GRP_STEM_INCR,STEM_INCR_NUM,4113 -US-UMB,18506,GRP_STEM_INCR,STEM_INCR_APPROACH,manual measurement - census -US-UMB,18506,GRP_STEM_INCR,STEM_INCR_DATE_START,20010715 -US-UMB,18506,GRP_STEM_INCR,STEM_INCR_DATE_END,20100715 -US-UMB,18506,GRP_STEM_INCR,STEM_INCR_DATE_UNC,28 -US-UMB,18506,GRP_STEM_INCR,STEM_INCR_COMMENT,"Ten year increment of trees with DBH >= 8 cm and only included trees that were live and had DBH >= 8 cm both census years, i.e., trees measured in 2001, but were dead in 2010 were not included and trees <8 cm in 2001 but >=8 cm in 2010 were not included. Measurements made during June -August. Stem diameter represents diameter in 2010. Plot size = 0.08 ha for 60 plots and 1.13 for one plot." -US-UMB,12341,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Christopher Gough -US-UMB,12341,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-UMB,12341,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,cmgough@vcu.edu -US-UMB,12341,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Virginia Commonwealth University -US-UMB,12341,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Department of Biology, 1000 West Cary Street, PO Box 842012,Richmond, VA USA 23284-2012" -US-UMB,29723,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Gil Bohrer -US-UMB,29723,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-UMB,29723,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,bohrer.17@osu.edu -US-UMB,29723,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Ohio State University -US-UMB,29723,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Department of Civil, Environmental & Geodetic Engineering, 417E Hitchcock Hall, 2070 Neil Avenue,Columbus, Ohio USA 43210" -US-UMB,98547,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Luke Nave -US-UMB,98547,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-UMB,98547,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,lukenave@umich.edu -US-UMB,98547,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Michigan -US-UMB,95889,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Justine Missik -US-UMB,95889,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,DataManager -US-UMB,95889,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,missik.2@osu.edu -US-UMB,95889,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Ohio State University -US-UMB,95889,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"2070 Neil Ave., Columbus, OH, 43210" -US-UMB,29724,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Chris Vogel -US-UMB,29724,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Affiliate -US-UMB,29724,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,csvogel@umich.edu -US-UMB,29724,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Michigan -US-UMB,29724,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"University of Michigan Biological Station, 9008 Biological Road,Pellston, MI USA 49769" -US-UMB,98545,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Peter Curtis -US-UMB,98545,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Affiliate -US-UMB,98545,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,curtis.7@osu.edu -US-UMB,98545,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Ohio State University -US-UMB,98545,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Department of Evolution, Ecology, and Organismal Biology, 318 W 12th Avenue,Columbus, OH USA 43210-1293" -US-UMB,29842,GRP_TOWER_POWER,TOWER_POWER,Direct power -US-UMB,12342,GRP_TOWER_TYPE,TOWER_TYPE,triangle -US-UMB,19141,GRP_TREES_NUM,TREES_NUM,11.8 -US-UMB,19141,GRP_TREES_NUM,TREES_NUM_SPP,Other -US-UMB,19141,GRP_TREES_NUM,TREES_NUM_APPROACH,Census and identification of trees in 76 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm. -US-UMB,19141,GRP_TREES_NUM,TREES_NUM_DATE,20100714 -US-UMB,19141,GRP_TREES_NUM,TREES_NUM_DATE_UNC,28 -US-UMB,19141,GRP_TREES_NUM,TREES_NUM_COMMENT,The plots represented here are a combination of plots measured in 2001 and 2003. -US-UMB,19141,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,77 -US-UMB,19141,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,25.59 -US-UMB,18907,GRP_TREES_NUM,TREES_NUM,11.99 -US-UMB,18907,GRP_TREES_NUM,TREES_NUM_SPP,Other -US-UMB,18907,GRP_TREES_NUM,TREES_NUM_APPROACH,Census and identification of trees in 60 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm. -US-UMB,18907,GRP_TREES_NUM,TREES_NUM_DATE,20010714 -US-UMB,18907,GRP_TREES_NUM,TREES_NUM_DATE_UNC,28 -US-UMB,18907,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,61 -US-UMB,18907,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,25.99 -US-UMB,18920,GRP_TREES_NUM,TREES_NUM,13.68 -US-UMB,18920,GRP_TREES_NUM,TREES_NUM_SPP,Other -US-UMB,18920,GRP_TREES_NUM,TREES_NUM_APPROACH,Census and identification of trees in 20 - 0.08 ha plots for trees with DBH >= 8 cm. -US-UMB,18920,GRP_TREES_NUM,TREES_NUM_DATE,20030714 -US-UMB,18920,GRP_TREES_NUM,TREES_NUM_DATE_UNC,28 -US-UMB,18920,GRP_TREES_NUM,TREES_NUM_COMMENT,The plots represented here are different from those from 1997 and 2001. -US-UMB,18920,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,20 -US-UMB,18920,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,25.49 -US-UMB,18863,GRP_TREES_NUM,TREES_NUM,16.72 -US-UMB,18863,GRP_TREES_NUM,TREES_NUM_SPP,Acer saccharum -US-UMB,18863,GRP_TREES_NUM,TREES_NUM_APPROACH,Census and identification of trees in 60 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm. -US-UMB,18863,GRP_TREES_NUM,TREES_NUM_DATE,19970714 -US-UMB,18863,GRP_TREES_NUM,TREES_NUM_DATE_UNC,28 -US-UMB,18863,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,61 -US-UMB,18863,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,58.77 -US-UMB,18896,GRP_TREES_NUM,TREES_NUM,17.94 -US-UMB,18896,GRP_TREES_NUM,TREES_NUM_SPP,Acer saccharum -US-UMB,18896,GRP_TREES_NUM,TREES_NUM_APPROACH,Census and identification of trees in 60 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm. -US-UMB,18896,GRP_TREES_NUM,TREES_NUM_DATE,20010714 -US-UMB,18896,GRP_TREES_NUM,TREES_NUM_DATE_UNC,28 -US-UMB,18896,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,61 -US-UMB,18896,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,62.38 -US-UMB,19129,GRP_TREES_NUM,TREES_NUM,171.72 -US-UMB,19129,GRP_TREES_NUM,TREES_NUM_SPP,Populus grandidentata -US-UMB,19129,GRP_TREES_NUM,TREES_NUM_APPROACH,Census and identification of trees in 76 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm. -US-UMB,19129,GRP_TREES_NUM,TREES_NUM_DATE,20100714 -US-UMB,19129,GRP_TREES_NUM,TREES_NUM_DATE_UNC,28 -US-UMB,19129,GRP_TREES_NUM,TREES_NUM_COMMENT,The plots represented here are a combination of plots measured in 2001 and 2003. -US-UMB,19129,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,77 -US-UMB,19129,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,208.25 -US-UMB,19101,GRP_TREES_NUM,TREES_NUM,173.57 -US-UMB,19101,GRP_TREES_NUM,TREES_NUM_SPP,Populus grandidentata -US-UMB,19101,GRP_TREES_NUM,TREES_NUM_APPROACH,Census and identification of trees in 60 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm. -US-UMB,19101,GRP_TREES_NUM,TREES_NUM_DATE,20010714 -US-UMB,19101,GRP_TREES_NUM,TREES_NUM_DATE_UNC,28 -US-UMB,19101,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,61 -US-UMB,19101,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,222.9 -US-UMB,19120,GRP_TREES_NUM,TREES_NUM,18.03 -US-UMB,19120,GRP_TREES_NUM,TREES_NUM_SPP,Populus tremuloides -US-UMB,19120,GRP_TREES_NUM,TREES_NUM_APPROACH,Census and identification of trees in 20 - 0.08 ha plots for trees with DBH >= 8 cm. -US-UMB,19120,GRP_TREES_NUM,TREES_NUM_DATE,20030714 -US-UMB,19120,GRP_TREES_NUM,TREES_NUM_DATE_UNC,28 -US-UMB,19120,GRP_TREES_NUM,TREES_NUM_COMMENT,The plots represented here are different from those from 1997 and 2001. -US-UMB,19120,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,20 -US-UMB,19120,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,74.9 -US-UMB,19076,GRP_TREES_NUM,TREES_NUM,180.29 -US-UMB,19076,GRP_TREES_NUM,TREES_NUM_SPP,Populus grandidentata -US-UMB,19076,GRP_TREES_NUM,TREES_NUM_APPROACH,Census and identification of trees in 60 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm. -US-UMB,19076,GRP_TREES_NUM,TREES_NUM_DATE,19970714 -US-UMB,19076,GRP_TREES_NUM,TREES_NUM_DATE_UNC,28 -US-UMB,19076,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,61 -US-UMB,19076,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,223.69 -US-UMB,18856,GRP_TREES_NUM,TREES_NUM,202.66 -US-UMB,18856,GRP_TREES_NUM,TREES_NUM_SPP,Acer rubrum -US-UMB,18856,GRP_TREES_NUM,TREES_NUM_APPROACH,Census and identification of trees in 60 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm. -US-UMB,18856,GRP_TREES_NUM,TREES_NUM_DATE,19970714 -US-UMB,18856,GRP_TREES_NUM,TREES_NUM_DATE_UNC,28 -US-UMB,18856,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,61 -US-UMB,18856,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,151.52 -US-UMB,18911,GRP_TREES_NUM,TREES_NUM,203.36 -US-UMB,18911,GRP_TREES_NUM,TREES_NUM_SPP,Acer rubrum -US-UMB,18911,GRP_TREES_NUM,TREES_NUM_APPROACH,Census and identification of trees in 20 - 0.08 ha plots for trees with DBH >= 8 cm. -US-UMB,18911,GRP_TREES_NUM,TREES_NUM_DATE,20030714 -US-UMB,18911,GRP_TREES_NUM,TREES_NUM_DATE_UNC,28 -US-UMB,18911,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,20 -US-UMB,18911,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,124.2 -US-UMB,18891,GRP_TREES_NUM,TREES_NUM,210.32 -US-UMB,18891,GRP_TREES_NUM,TREES_NUM_SPP,Acer rubrum -US-UMB,18891,GRP_TREES_NUM,TREES_NUM_APPROACH,Census and identification of trees in 60 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm. -US-UMB,18891,GRP_TREES_NUM,TREES_NUM_DATE,20010714 -US-UMB,18891,GRP_TREES_NUM,TREES_NUM_DATE_UNC,28 -US-UMB,18891,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,61 -US-UMB,18891,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,144.8 -US-UMB,18924,GRP_TREES_NUM,TREES_NUM,224.25 -US-UMB,18924,GRP_TREES_NUM,TREES_NUM_SPP,Acer rubrum -US-UMB,18924,GRP_TREES_NUM,TREES_NUM_APPROACH,Census and identification of trees in 76 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm. -US-UMB,18924,GRP_TREES_NUM,TREES_NUM_DATE,20100714 -US-UMB,18924,GRP_TREES_NUM,TREES_NUM_DATE_UNC,28 -US-UMB,18924,GRP_TREES_NUM,TREES_NUM_COMMENT,The plots represented here are a combination of plots measured in 2001 and 2003. -US-UMB,18924,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,77 -US-UMB,18924,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,112.97 -US-UMB,19116,GRP_TREES_NUM,TREES_NUM,245.02 -US-UMB,19116,GRP_TREES_NUM,TREES_NUM_SPP,Populus grandidentata -US-UMB,19116,GRP_TREES_NUM,TREES_NUM_APPROACH,Census and identification of trees in 20 - 0.08 ha plots for trees with DBH >= 8 cm. -US-UMB,19116,GRP_TREES_NUM,TREES_NUM_DATE,20030714 -US-UMB,19116,GRP_TREES_NUM,TREES_NUM_DATE_UNC,28 -US-UMB,19116,GRP_TREES_NUM,TREES_NUM_COMMENT,The plots represented here are different from those from 1997 and 2001. -US-UMB,19116,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,20 -US-UMB,19116,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,225.41 -US-UMB,18928,GRP_TREES_NUM,TREES_NUM,28.11 -US-UMB,18928,GRP_TREES_NUM,TREES_NUM_SPP,Acer saccarum -US-UMB,18928,GRP_TREES_NUM,TREES_NUM_APPROACH,Census and identification of trees in 76 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm. -US-UMB,18928,GRP_TREES_NUM,TREES_NUM_DATE,20100714 -US-UMB,18928,GRP_TREES_NUM,TREES_NUM_DATE_UNC,28 -US-UMB,18928,GRP_TREES_NUM,TREES_NUM_COMMENT,The plots represented here are a combination of plots measured in 2001 and 2003. -US-UMB,18928,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,77 -US-UMB,18928,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,97.67 -US-UMB,19112,GRP_TREES_NUM,TREES_NUM,31.72 -US-UMB,19112,GRP_TREES_NUM,TREES_NUM_SPP,Pinus strobus -US-UMB,19112,GRP_TREES_NUM,TREES_NUM_APPROACH,Census and identification of trees in 20 - 0.08 ha plots for trees with DBH >= 8 cm. -US-UMB,19112,GRP_TREES_NUM,TREES_NUM_DATE,20030714 -US-UMB,19112,GRP_TREES_NUM,TREES_NUM_DATE_UNC,28 -US-UMB,19112,GRP_TREES_NUM,TREES_NUM_COMMENT,The plots represented here are different from those from 1997 and 2001. -US-UMB,19112,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,20 -US-UMB,19112,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,42.22 -US-UMB,19108,GRP_TREES_NUM,TREES_NUM,35.45 -US-UMB,19108,GRP_TREES_NUM,TREES_NUM_SPP,Fagus grandifolia -US-UMB,19108,GRP_TREES_NUM,TREES_NUM_APPROACH,Census and identification of trees in 20 - 0.08 ha plots for trees with DBH >= 8 cm. -US-UMB,19108,GRP_TREES_NUM,TREES_NUM_DATE,20030714 -US-UMB,19108,GRP_TREES_NUM,TREES_NUM_DATE_UNC,28 -US-UMB,19108,GRP_TREES_NUM,TREES_NUM_COMMENT,The plots represented here are different from those from 1997 and 2001. -US-UMB,19108,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,20 -US-UMB,19108,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,67.32 -US-UMB,19069,GRP_TREES_NUM,TREES_NUM,41.07 -US-UMB,19069,GRP_TREES_NUM,TREES_NUM_SPP,Pinus strobus -US-UMB,19069,GRP_TREES_NUM,TREES_NUM_APPROACH,Census and identification of trees in 60 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm. -US-UMB,19069,GRP_TREES_NUM,TREES_NUM_DATE,19970714 -US-UMB,19069,GRP_TREES_NUM,TREES_NUM_DATE_UNC,28 -US-UMB,19069,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,61 -US-UMB,19069,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,106.26 -US-UMB,18919,GRP_TREES_NUM,TREES_NUM,42.29 -US-UMB,18919,GRP_TREES_NUM,TREES_NUM_SPP,Betula papyrifera -US-UMB,18919,GRP_TREES_NUM,TREES_NUM_APPROACH,Census and identification of trees in 20 - 0.08 ha plots for trees with DBH >= 8 cm. -US-UMB,18919,GRP_TREES_NUM,TREES_NUM_DATE,20030714 -US-UMB,18919,GRP_TREES_NUM,TREES_NUM_DATE_UNC,28 -US-UMB,18919,GRP_TREES_NUM,TREES_NUM_COMMENT,The plots represented here are different from those from 1997 and 2001. -US-UMB,18919,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,20 -US-UMB,18919,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,62.96 -US-UMB,18881,GRP_TREES_NUM,TREES_NUM,43.16 -US-UMB,18881,GRP_TREES_NUM,TREES_NUM_SPP,Quercus rubra -US-UMB,18881,GRP_TREES_NUM,TREES_NUM_APPROACH,Census and identification of trees in 60 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm. -US-UMB,18881,GRP_TREES_NUM,TREES_NUM_DATE,19970714 -US-UMB,18881,GRP_TREES_NUM,TREES_NUM_DATE_UNC,28 -US-UMB,18881,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,61 -US-UMB,18881,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,61.78 -US-UMB,19062,GRP_TREES_NUM,TREES_NUM,43.92 -US-UMB,19062,GRP_TREES_NUM,TREES_NUM_SPP,Fagus grandifolia -US-UMB,19062,GRP_TREES_NUM,TREES_NUM_APPROACH,Census and identification of trees in 60 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm. -US-UMB,19062,GRP_TREES_NUM,TREES_NUM_DATE,19970714 -US-UMB,19062,GRP_TREES_NUM,TREES_NUM_DATE_UNC,28 -US-UMB,19062,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,61 -US-UMB,19062,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,120.58 -US-UMB,19091,GRP_TREES_NUM,TREES_NUM,48.02 -US-UMB,19091,GRP_TREES_NUM,TREES_NUM_SPP,Fagus grandifolia -US-UMB,19091,GRP_TREES_NUM,TREES_NUM_APPROACH,Census and identification of trees in 60 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm. -US-UMB,19091,GRP_TREES_NUM,TREES_NUM_DATE,20010714 -US-UMB,19091,GRP_TREES_NUM,TREES_NUM_DATE_UNC,28 -US-UMB,19091,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,61 -US-UMB,19091,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,124.22 -US-UMB,18932,GRP_TREES_NUM,TREES_NUM,48.67 -US-UMB,18932,GRP_TREES_NUM,TREES_NUM_SPP,Betula papyrifera -US-UMB,18932,GRP_TREES_NUM,TREES_NUM_APPROACH,Census and identification of trees in 76 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm. -US-UMB,18932,GRP_TREES_NUM,TREES_NUM_DATE,20100714 -US-UMB,18932,GRP_TREES_NUM,TREES_NUM_DATE_UNC,28 -US-UMB,18932,GRP_TREES_NUM,TREES_NUM_COMMENT,The plots represented here are a combination of plots measured in 2001 and 2003. -US-UMB,18932,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,77 -US-UMB,18932,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,61.15 -US-UMB,19096,GRP_TREES_NUM,TREES_NUM,48.83 -US-UMB,19096,GRP_TREES_NUM,TREES_NUM_SPP,Pinus strobus -US-UMB,19096,GRP_TREES_NUM,TREES_NUM_APPROACH,Census and identification of trees in 60 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm. -US-UMB,19096,GRP_TREES_NUM,TREES_NUM_DATE,20010714 -US-UMB,19096,GRP_TREES_NUM,TREES_NUM_DATE_UNC,28 -US-UMB,19096,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,61 -US-UMB,19096,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,118.24 -US-UMB,18903,GRP_TREES_NUM,TREES_NUM,49.5 -US-UMB,18903,GRP_TREES_NUM,TREES_NUM_SPP,Quercus rubra -US-UMB,18903,GRP_TREES_NUM,TREES_NUM_APPROACH,Census and identification of trees in 60 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm. -US-UMB,18903,GRP_TREES_NUM,TREES_NUM_DATE,20010714 -US-UMB,18903,GRP_TREES_NUM,TREES_NUM_DATE_UNC,28 -US-UMB,18903,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,61 -US-UMB,18903,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,64.76 -US-UMB,18936,GRP_TREES_NUM,TREES_NUM,51.5 -US-UMB,18936,GRP_TREES_NUM,TREES_NUM_SPP,Fagus grandifolia -US-UMB,18936,GRP_TREES_NUM,TREES_NUM_APPROACH,Census and identification of trees in 76 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm. -US-UMB,18936,GRP_TREES_NUM,TREES_NUM_DATE,20100714 -US-UMB,18936,GRP_TREES_NUM,TREES_NUM_DATE_UNC,28 -US-UMB,18936,GRP_TREES_NUM,TREES_NUM_COMMENT,The plots represented here are a combination of plots measured in 2001 and 2003. -US-UMB,18936,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,77 -US-UMB,18936,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,117.98 -US-UMB,19133,GRP_TREES_NUM,TREES_NUM,54.12 -US-UMB,19133,GRP_TREES_NUM,TREES_NUM_SPP,Populus tremuloides -US-UMB,19133,GRP_TREES_NUM,TREES_NUM_APPROACH,Census and identification of trees in 76 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm. -US-UMB,19133,GRP_TREES_NUM,TREES_NUM_DATE,20100714 -US-UMB,19133,GRP_TREES_NUM,TREES_NUM_DATE_UNC,28 -US-UMB,19133,GRP_TREES_NUM,TREES_NUM_COMMENT,The plots represented here are a combination of plots measured in 2001 and 2003. -US-UMB,19133,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,77 -US-UMB,19133,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,111.4 -US-UMB,18940,GRP_TREES_NUM,TREES_NUM,63.77 -US-UMB,18940,GRP_TREES_NUM,TREES_NUM_SPP,Pinus strobus -US-UMB,18940,GRP_TREES_NUM,TREES_NUM_APPROACH,Census and identification of trees in 76 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm. -US-UMB,18940,GRP_TREES_NUM,TREES_NUM_DATE,20100714 -US-UMB,18940,GRP_TREES_NUM,TREES_NUM_DATE_UNC,28 -US-UMB,18940,GRP_TREES_NUM,TREES_NUM_COMMENT,The plots represented here are a combination of plots measured in 2001 and 2003. -US-UMB,18940,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,77 -US-UMB,18940,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,133.23 -US-UMB,19137,GRP_TREES_NUM,TREES_NUM,64.53 -US-UMB,19137,GRP_TREES_NUM,TREES_NUM_SPP,Quercus rubra -US-UMB,19137,GRP_TREES_NUM,TREES_NUM_APPROACH,Census and identification of trees in 76 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm. -US-UMB,19137,GRP_TREES_NUM,TREES_NUM_DATE,20100714 -US-UMB,19137,GRP_TREES_NUM,TREES_NUM_DATE_UNC,28 -US-UMB,19137,GRP_TREES_NUM,TREES_NUM_COMMENT,The plots represented here are a combination of plots measured in 2001 and 2003. -US-UMB,19137,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,77 -US-UMB,19137,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,87.26 -US-UMB,19086,GRP_TREES_NUM,TREES_NUM,69.42 -US-UMB,19086,GRP_TREES_NUM,TREES_NUM_SPP,Betula papyrifera -US-UMB,19086,GRP_TREES_NUM,TREES_NUM_APPROACH,Census and identification of trees in 60 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm. -US-UMB,19086,GRP_TREES_NUM,TREES_NUM_DATE,20010714 -US-UMB,19086,GRP_TREES_NUM,TREES_NUM_DATE_UNC,28 -US-UMB,19086,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,61 -US-UMB,19086,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,79.83 -US-UMB,18915,GRP_TREES_NUM,TREES_NUM,70.9 -US-UMB,18915,GRP_TREES_NUM,TREES_NUM_SPP,Acer saccarum -US-UMB,18915,GRP_TREES_NUM,TREES_NUM_APPROACH,Census and identification of trees in 20 - 0.08 ha plots for trees with DBH >= 8 cm. -US-UMB,18915,GRP_TREES_NUM,TREES_NUM_DATE,20030714 -US-UMB,18915,GRP_TREES_NUM,TREES_NUM_DATE_UNC,28 -US-UMB,18915,GRP_TREES_NUM,TREES_NUM_COMMENT,The plots represented here are different from those from 1997 and 2001. -US-UMB,18915,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,20 -US-UMB,18915,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,173.81 -US-UMB,18870,GRP_TREES_NUM,TREES_NUM,71.93 -US-UMB,18870,GRP_TREES_NUM,TREES_NUM_SPP,Betula papyrifera -US-UMB,18870,GRP_TREES_NUM,TREES_NUM_APPROACH,Census and identification of trees in 60 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm. -US-UMB,18870,GRP_TREES_NUM,TREES_NUM_DATE,19970714 -US-UMB,18870,GRP_TREES_NUM,TREES_NUM_DATE_UNC,28 -US-UMB,18870,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,61 -US-UMB,18870,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,83.34 -US-UMB,19124,GRP_TREES_NUM,TREES_NUM,80.85 -US-UMB,19124,GRP_TREES_NUM,TREES_NUM_SPP,Quercus rubra -US-UMB,19124,GRP_TREES_NUM,TREES_NUM_APPROACH,Census and identification of trees in 20 - 0.08 ha plots for trees with DBH >= 8 cm. -US-UMB,19124,GRP_TREES_NUM,TREES_NUM_DATE,20030714 -US-UMB,19124,GRP_TREES_NUM,TREES_NUM_DATE_UNC,28 -US-UMB,19124,GRP_TREES_NUM,TREES_NUM_COMMENT,The plots represented here are different from those from 1997 and 2001. -US-UMB,19124,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,20 -US-UMB,19124,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,119.88 -US-UMB,18898,GRP_TREES_NUM,TREES_NUM,85.71 -US-UMB,18898,GRP_TREES_NUM,TREES_NUM_SPP,Populus tremuloides -US-UMB,18898,GRP_TREES_NUM,TREES_NUM_APPROACH,Census and identification of trees in 60 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm. -US-UMB,18898,GRP_TREES_NUM,TREES_NUM_DATE,20010714 -US-UMB,18898,GRP_TREES_NUM,TREES_NUM_DATE_UNC,28 -US-UMB,18898,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,61 -US-UMB,18898,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,140.16 -US-UMB,18886,GRP_TREES_NUM,TREES_NUM,9.87 -US-UMB,18886,GRP_TREES_NUM,TREES_NUM_SPP,Other -US-UMB,18886,GRP_TREES_NUM,TREES_NUM_APPROACH,Census and identification of trees in 60 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm. -US-UMB,18886,GRP_TREES_NUM,TREES_NUM_DATE,19970714 -US-UMB,18886,GRP_TREES_NUM,TREES_NUM_DATE_UNC,28 -US-UMB,18886,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,61 -US-UMB,18886,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,22.12 -US-UMB,18875,GRP_TREES_NUM,TREES_NUM,92.44 -US-UMB,18875,GRP_TREES_NUM,TREES_NUM_SPP,Populus tremuloides -US-UMB,18875,GRP_TREES_NUM,TREES_NUM_APPROACH,Census and identification of trees in 60 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm. -US-UMB,18875,GRP_TREES_NUM,TREES_NUM_DATE,19970714 -US-UMB,18875,GRP_TREES_NUM,TREES_NUM_DATE_UNC,28 -US-UMB,18875,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,61 -US-UMB,18875,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,150.61 -US-UMB,12343,GRP_URL,URL,http://flux.org.ohio-state.edu/ -US-UMB,24000439,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-UMB -US-UMB,12344,GRP_UTC_OFFSET,UTC_OFFSET,-5 -US-UMB,18430,GRP_WD_BIOMASS,WD_BIOMASS_CRS,206 -US-UMB,18458,GRP_WD_BIOMASS,WD_BIOMASS_CRS,206.9 -US-UMB,18410,GRP_WD_BIOMASS,WD_BIOMASS_CRS,259.9 -US-UMB,18420,GRP_WD_BIOMASS,WD_BIOMASS_CRS,272.2 -US-UMB,18441,GRP_WD_BIOMASS,WD_BIOMASS_CRS,272.2 -US-UMB,18399,GRP_WD_BIOMASS,WD_BIOMASS_CRS,289.7 -US-UMB,18430,GRP_WD_BIOMASS,WD_BIOMASS_CRS_SPATIAL_VARIABILITY,133 -US-UMB,18458,GRP_WD_BIOMASS,WD_BIOMASS_CRS_SPATIAL_VARIABILITY,133 -US-UMB,18399,GRP_WD_BIOMASS,WD_BIOMASS_CRS_SPATIAL_VARIABILITY,150.6 -US-UMB,18420,GRP_WD_BIOMASS,WD_BIOMASS_CRS_SPATIAL_VARIABILITY,205.4 -US-UMB,18441,GRP_WD_BIOMASS,WD_BIOMASS_CRS_SPATIAL_VARIABILITY,205.4 -US-UMB,18410,GRP_WD_BIOMASS,WD_BIOMASS_CRS_SPATIAL_VARIABILITY,231.9 -US-UMB,18410,GRP_WD_BIOMASS,WD_BIOMASS_CRS_SPATIAL_REP_NUMBER,12 -US-UMB,18420,GRP_WD_BIOMASS,WD_BIOMASS_CRS_SPATIAL_REP_NUMBER,12 -US-UMB,18441,GRP_WD_BIOMASS,WD_BIOMASS_CRS_SPATIAL_REP_NUMBER,12 -US-UMB,18399,GRP_WD_BIOMASS,WD_BIOMASS_CRS_SPATIAL_REP_NUMBER,4 -US-UMB,18430,GRP_WD_BIOMASS,WD_BIOMASS_CRS_SPATIAL_REP_NUMBER,8 -US-UMB,18458,GRP_WD_BIOMASS,WD_BIOMASS_CRS_SPATIAL_REP_NUMBER,8 -US-UMB,18399,GRP_WD_BIOMASS,WD_BIOMASS_UNIT,gC m-2 -US-UMB,18410,GRP_WD_BIOMASS,WD_BIOMASS_UNIT,gC m-2 -US-UMB,18420,GRP_WD_BIOMASS,WD_BIOMASS_UNIT,gC m-2 -US-UMB,18430,GRP_WD_BIOMASS,WD_BIOMASS_UNIT,gC m-2 -US-UMB,18441,GRP_WD_BIOMASS,WD_BIOMASS_UNIT,gC m-2 -US-UMB,18458,GRP_WD_BIOMASS,WD_BIOMASS_UNIT,gC m-2 -US-UMB,18399,GRP_WD_BIOMASS,WD_BIOMASS_APPROACH,Coarse woody debris plots were .08 ha in size and debris with diameter of 10 cm or greater were included. Species specific density and decay classes (5 classes each) were used to determine mass of debris. -US-UMB,18410,GRP_WD_BIOMASS,WD_BIOMASS_APPROACH,Coarse woody debris plots were .08 ha in size and debris with diameter of 10 cm or greater were included. Species specific density and decay classes (5 classes each) were used to determine mass of debris. -US-UMB,18420,GRP_WD_BIOMASS,WD_BIOMASS_APPROACH,Coarse woody debris plots were .08 ha in size and debris with diameter of 10 cm or greater were included. Species specific density and decay classes (5 classes each) were used to determine mass of debris. -US-UMB,18430,GRP_WD_BIOMASS,WD_BIOMASS_APPROACH,Coarse woody debris plots were .08 ha in size and debris with diameter of 10 cm or greater were included. Species specific density and decay classes (5 classes each) were used to determine mass of debris. -US-UMB,18441,GRP_WD_BIOMASS,WD_BIOMASS_DATE,19600401 -US-UMB,18458,GRP_WD_BIOMASS,WD_BIOMASS_DATE,19600401 -US-UMB,18399,GRP_WD_BIOMASS,WD_BIOMASS_DATE,20000714 -US-UMB,18410,GRP_WD_BIOMASS,WD_BIOMASS_DATE,20031114 -US-UMB,18420,GRP_WD_BIOMASS,WD_BIOMASS_DATE,20090714 -US-UMB,18430,GRP_WD_BIOMASS,WD_BIOMASS_DATE,20110714 -US-UMB,18399,GRP_WD_BIOMASS,WD_BIOMASS_DATE_UNC,28 -US-UMB,18410,GRP_WD_BIOMASS,WD_BIOMASS_DATE_UNC,28 -US-UMB,18420,GRP_WD_BIOMASS,WD_BIOMASS_DATE_UNC,28 -US-UMB,18430,GRP_WD_BIOMASS,WD_BIOMASS_DATE_UNC,28 -US-UMB,18450,GRP_WD_PROD,WD_PROD_CRS,-1.4 -US-UMB,18539,GRP_WD_PROD,WD_PROD_CRS,-122.6 -US-UMB,18531,GRP_WD_PROD,WD_PROD_CRS,12.3 -US-UMB,18531,GRP_WD_PROD,WD_PROD_CRS_SPATIAL_VARIABILITY,189.4 -US-UMB,18450,GRP_WD_PROD,WD_PROD_CRS_SPATIAL_VARIABILITY,207.2 -US-UMB,18539,GRP_WD_PROD,WD_PROD_CRS_SPATIAL_VARIABILITY,211.8 -US-UMB,18531,GRP_WD_PROD,WD_PROD_CRS_SPATIAL_REP_NUMBER,12 -US-UMB,18450,GRP_WD_PROD,WD_PROD_CRS_SPATIAL_REP_NUMBER,4 -US-UMB,18539,GRP_WD_PROD,WD_PROD_CRS_SPATIAL_REP_NUMBER,8 -US-UMB,18411,GRP_WD_PROD,WD_PROD_FINE,11.3 -US-UMB,18421,GRP_WD_PROD,WD_PROD_FINE,12.8 -US-UMB,18547,GRP_WD_PROD,WD_PROD_FINE,128.8 -US-UMB,18467,GRP_WD_PROD,WD_PROD_FINE,141.7 -US-UMB,18520,GRP_WD_PROD,WD_PROD_FINE,15.4 -US-UMB,18528,GRP_WD_PROD,WD_PROD_FINE,16.4 -US-UMB,18400,GRP_WD_PROD,WD_PROD_FINE,18.3 -US-UMB,18512,GRP_WD_PROD,WD_PROD_FINE,20.6 -US-UMB,18431,GRP_WD_PROD,WD_PROD_FINE,21.9 -US-UMB,18474,GRP_WD_PROD,WD_PROD_FINE,240.6 -US-UMB,18442,GRP_WD_PROD,WD_PROD_FINE,32.7 -US-UMB,18460,GRP_WD_PROD,WD_PROD_FINE,375.3 -US-UMB,18421,GRP_WD_PROD,WD_PROD_FINE_SPATIAL_VARIABILITY,10.3 -US-UMB,18528,GRP_WD_PROD,WD_PROD_FINE_SPATIAL_VARIABILITY,13.4 -US-UMB,18547,GRP_WD_PROD,WD_PROD_FINE_SPATIAL_VARIABILITY,138.23 -US-UMB,18520,GRP_WD_PROD,WD_PROD_FINE_SPATIAL_VARIABILITY,16.6 -US-UMB,18467,GRP_WD_PROD,WD_PROD_FINE_SPATIAL_VARIABILITY,178.03 -US-UMB,18431,GRP_WD_PROD,WD_PROD_FINE_SPATIAL_VARIABILITY,18.1 -US-UMB,18411,GRP_WD_PROD,WD_PROD_FINE_SPATIAL_VARIABILITY,19.9 -US-UMB,18400,GRP_WD_PROD,WD_PROD_FINE_SPATIAL_VARIABILITY,21 -US-UMB,18512,GRP_WD_PROD,WD_PROD_FINE_SPATIAL_VARIABILITY,21.3 -US-UMB,18460,GRP_WD_PROD,WD_PROD_FINE_SPATIAL_VARIABILITY,372.58 -US-UMB,18442,GRP_WD_PROD,WD_PROD_FINE_SPATIAL_VARIABILITY,39.8 -US-UMB,18474,GRP_WD_PROD,WD_PROD_FINE_SPATIAL_VARIABILITY,430.28 -US-UMB,18460,GRP_WD_PROD,WD_PROD_FINE_SPATIAL_REP_NUMBER,10 -US-UMB,18467,GRP_WD_PROD,WD_PROD_FINE_SPATIAL_REP_NUMBER,10 -US-UMB,18474,GRP_WD_PROD,WD_PROD_FINE_SPATIAL_REP_NUMBER,10 -US-UMB,18547,GRP_WD_PROD,WD_PROD_FINE_SPATIAL_REP_NUMBER,10 -US-UMB,18512,GRP_WD_PROD,WD_PROD_FINE_SPATIAL_REP_NUMBER,13 -US-UMB,18421,GRP_WD_PROD,WD_PROD_FINE_SPATIAL_REP_NUMBER,15 -US-UMB,18431,GRP_WD_PROD,WD_PROD_FINE_SPATIAL_REP_NUMBER,15 -US-UMB,18442,GRP_WD_PROD,WD_PROD_FINE_SPATIAL_REP_NUMBER,16 -US-UMB,18520,GRP_WD_PROD,WD_PROD_FINE_SPATIAL_REP_NUMBER,16 -US-UMB,18528,GRP_WD_PROD,WD_PROD_FINE_SPATIAL_REP_NUMBER,16 -US-UMB,18400,GRP_WD_PROD,WD_PROD_FINE_SPATIAL_REP_NUMBER,50 -US-UMB,18411,GRP_WD_PROD,WD_PROD_FINE_SPATIAL_REP_NUMBER,50 -US-UMB,18400,GRP_WD_PROD,WD_PROD_UNIT,gC m-2 -US-UMB,18411,GRP_WD_PROD,WD_PROD_UNIT,gC m-2 -US-UMB,18421,GRP_WD_PROD,WD_PROD_UNIT,gC m-2 -US-UMB,18431,GRP_WD_PROD,WD_PROD_UNIT,gC m-2 -US-UMB,18442,GRP_WD_PROD,WD_PROD_UNIT,gC m-2 -US-UMB,18450,GRP_WD_PROD,WD_PROD_UNIT,gC m-2 -US-UMB,18460,GRP_WD_PROD,WD_PROD_UNIT,gC m-2 -US-UMB,18467,GRP_WD_PROD,WD_PROD_UNIT,gC m-2 -US-UMB,18474,GRP_WD_PROD,WD_PROD_UNIT,gC m-2 -US-UMB,18512,GRP_WD_PROD,WD_PROD_UNIT,gC m-2 -US-UMB,18520,GRP_WD_PROD,WD_PROD_UNIT,gC m-2 -US-UMB,18528,GRP_WD_PROD,WD_PROD_UNIT,gC m-2 -US-UMB,18531,GRP_WD_PROD,WD_PROD_UNIT,gC m-2 -US-UMB,18539,GRP_WD_PROD,WD_PROD_UNIT,gC m-2 -US-UMB,18547,GRP_WD_PROD,WD_PROD_UNIT,gC m-2 -US-UMB,18450,GRP_WD_PROD,WD_PROD_APPROACH,Coarse woody debris plots were .08 ha in size and debris with diameter of 10 cm or greater were included. Species specific density and decay classes (5 classes each) were used to determine mass of debris. -US-UMB,18531,GRP_WD_PROD,WD_PROD_APPROACH,Coarse woody debris plots were .08 ha in size and debris with diameter of 10 cm or greater were included. Species specific density and decay classes (5 classes each) were used to determine mass of debris. -US-UMB,18539,GRP_WD_PROD,WD_PROD_APPROACH,Coarse woody debris plots were .08 ha in size and debris with diameter of 10 cm or greater were included. Species specific density and decay classes (5 classes each) were used to determine mass of debris. -US-UMB,18400,GRP_WD_PROD,WD_PROD_APPROACH,fine woody debris (<=1 cm diameter) collected from litter traps of .264 m^2 in area. One trap in each of 49 - 0.08 ha plots and 20 traps in a 1.13 ha plot with flux tower at plot center -US-UMB,18411,GRP_WD_PROD,WD_PROD_APPROACH,fine woody debris (<=1 cm diameter) collected from litter traps of .264 m^2 in area. One trap in each of 49 - 0.08 ha plots and 20 traps in a 1.13 ha plot with flux tower at plot center -US-UMB,18512,GRP_WD_PROD,WD_PROD_APPROACH,fine woody debris (<=1 cm diameter) collected from litter traps of .264 m^2 in area. Three traps in each of 12 - 0.08 ha plots and 20 traps in a 1.13 ha plot with flux tower at plot center -US-UMB,18421,GRP_WD_PROD,WD_PROD_APPROACH,fine woody debris (<=1 cm diameter) collected from litter traps of .264 m^2 in area. Three traps in each of 14 - 0.08 ha plots and 20 traps in a 1.13 ha plot with flux tower at plot center -US-UMB,18431,GRP_WD_PROD,WD_PROD_APPROACH,fine woody debris (<=1 cm diameter) collected from litter traps of .264 m^2 in area. Three traps in each of 14 - 0.08 ha plots and 20 traps in a 1.13 ha plot with flux tower at plot center -US-UMB,18442,GRP_WD_PROD,WD_PROD_APPROACH,fine woody debris (<=1 cm diameter) collected from litter traps of .264 m^2 in area. Three traps in each of 15 - 0.08 ha plots and 20 traps in a 1.13 ha plot with flux tower at plot center -US-UMB,18520,GRP_WD_PROD,WD_PROD_APPROACH,fine woody debris (<=1 cm diameter) collected from litter traps of .264 m^2 in area. Three traps in each of 15 - 0.08 ha plots and 20 traps in a 1.13 ha plot with flux tower at plot center -US-UMB,18528,GRP_WD_PROD,WD_PROD_APPROACH,fine woody debris (<=1 cm diameter) collected from litter traps of .264 m^2 in area. Three traps in each of 15 - 0.08 ha plots and 20 traps in a 1.13 ha plot with flux tower at plot center -US-UMB,18460,GRP_WD_PROD,WD_PROD_APPROACH,Woody debris with diameter > 1 cm and <10 cm collected from10 - 4 m^2 sub-plots within 60m of the flux tower. -US-UMB,18467,GRP_WD_PROD,WD_PROD_APPROACH,Woody debris with diameter > 1 cm and <10 cm collected from10 - 4 m^2 sub-plots within 60m of the flux tower. -US-UMB,18474,GRP_WD_PROD,WD_PROD_APPROACH,Woody debris with diameter > 1 cm and <10 cm collected from10 - 4 m^2 sub-plots within 60m of the flux tower. -US-UMB,18547,GRP_WD_PROD,WD_PROD_APPROACH,Woody debris with diameter > 1 cm and <10 cm collected from10 - 4 m^2 sub-plots within 60m of the flux tower. -US-UMB,18450,GRP_WD_PROD,WD_PROD_DATE_START,20000714 -US-UMB,18531,GRP_WD_PROD,WD_PROD_DATE_START,20030714 -US-UMB,18400,GRP_WD_PROD,WD_PROD_DATE_START,20051101 -US-UMB,18411,GRP_WD_PROD,WD_PROD_DATE_START,20061101 -US-UMB,18421,GRP_WD_PROD,WD_PROD_DATE_START,20071101 -US-UMB,18431,GRP_WD_PROD,WD_PROD_DATE_START,20081101 -US-UMB,18539,GRP_WD_PROD,WD_PROD_DATE_START,20090714 -US-UMB,18512,GRP_WD_PROD,WD_PROD_DATE_START,20091101 -US-UMB,18547,GRP_WD_PROD,WD_PROD_DATE_START,20100815 -US-UMB,18520,GRP_WD_PROD,WD_PROD_DATE_START,20101101 -US-UMB,18460,GRP_WD_PROD,WD_PROD_DATE_START,20110815 -US-UMB,18528,GRP_WD_PROD,WD_PROD_DATE_START,20111101 -US-UMB,18467,GRP_WD_PROD,WD_PROD_DATE_START,20120815 -US-UMB,18442,GRP_WD_PROD,WD_PROD_DATE_START,20121101 -US-UMB,18474,GRP_WD_PROD,WD_PROD_DATE_START,20130815 -US-UMB,18450,GRP_WD_PROD,WD_PROD_DATE_END,20030714 -US-UMB,18400,GRP_WD_PROD,WD_PROD_DATE_END,20061101 -US-UMB,18411,GRP_WD_PROD,WD_PROD_DATE_END,20071101 -US-UMB,18421,GRP_WD_PROD,WD_PROD_DATE_END,20081101 -US-UMB,18531,GRP_WD_PROD,WD_PROD_DATE_END,20090714 -US-UMB,18431,GRP_WD_PROD,WD_PROD_DATE_END,20091101 -US-UMB,18512,GRP_WD_PROD,WD_PROD_DATE_END,20101101 -US-UMB,18539,GRP_WD_PROD,WD_PROD_DATE_END,20110714 -US-UMB,18547,GRP_WD_PROD,WD_PROD_DATE_END,20110815 -US-UMB,18520,GRP_WD_PROD,WD_PROD_DATE_END,20111101 -US-UMB,18460,GRP_WD_PROD,WD_PROD_DATE_END,20120815 -US-UMB,18528,GRP_WD_PROD,WD_PROD_DATE_END,20121101 -US-UMB,18467,GRP_WD_PROD,WD_PROD_DATE_END,20130815 -US-UMB,18442,GRP_WD_PROD,WD_PROD_DATE_END,20131101 -US-UMB,18474,GRP_WD_PROD,WD_PROD_DATE_END,20140815 -US-UMB,18450,GRP_WD_PROD,WD_PROD_DATE_UNC,28 -US-UMB,18531,GRP_WD_PROD,WD_PROD_DATE_UNC,28 -US-UMB,18539,GRP_WD_PROD,WD_PROD_DATE_UNC,28 -US-UMB,18400,GRP_WD_PROD,WD_PROD_DATE_UNC,30 -US-UMB,18411,GRP_WD_PROD,WD_PROD_DATE_UNC,30 -US-UMB,18421,GRP_WD_PROD,WD_PROD_DATE_UNC,30 -US-UMB,18431,GRP_WD_PROD,WD_PROD_DATE_UNC,30 -US-UMB,18442,GRP_WD_PROD,WD_PROD_DATE_UNC,30 -US-UMB,18512,GRP_WD_PROD,WD_PROD_DATE_UNC,30 -US-UMB,18520,GRP_WD_PROD,WD_PROD_DATE_UNC,30 -US-UMB,18528,GRP_WD_PROD,WD_PROD_DATE_UNC,30 -US-UMB,18460,GRP_WD_PROD,WD_PROD_DATE_UNC,7 -US-UMB,18467,GRP_WD_PROD,WD_PROD_DATE_UNC,7 -US-UMB,18474,GRP_WD_PROD,WD_PROD_DATE_UNC,7 -US-UMB,18547,GRP_WD_PROD,WD_PROD_DATE_UNC,7 -US-UMd,18602,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER,106.54 -US-UMd,18602,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_SPATIAL_VARIABILITY,17.1 -US-UMd,18602,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_SPATIAL_REP_NUMBER,12 -US-UMd,18602,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_ORGAN,Foliage -US-UMd,18602,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_PHEN,Senescent -US-UMd,18602,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_UNIT,gC m-2 -US-UMd,18602,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_APPROACH,Tree AG wood total biomass =a*D^b where D=DBH (diam. At 1.37m) and a and b are species specific coefficients. DBH determined from increment bands installed on ~25% of trees with DBH>= 10 cm. Resulting biomass multiplied by wood carbon fraction. AG_BIOMASS_OTHER_ORGAN is tree foliage captured by litter traps 1 m above forest floor -US-UMd,18602,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_DATE,20111020 -US-UMd,18602,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_DATE_UNC,20 -US-UMd,18602,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_COMMENT,Increment bands are capable of detecting 0.13 mm diameter change. Increment bands are read each year after leaf abscission and after AG growth has ceased. Growth of all trees extrapolated from regressions developed from banded trees. Litter traps are .264 m^2 with 3 traps in each of 11 - 0.08 ha plots and 20 traps in a 1.13 ha plot with flux tower a plot center. -US-UMd,18644,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER,106.7 -US-UMd,18644,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_SPATIAL_VARIABILITY,21 -US-UMd,18644,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_SPATIAL_REP_NUMBER,22 -US-UMd,18644,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_ORGAN,Foliage -US-UMd,18644,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_PHEN,Senescent -US-UMd,18644,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_UNIT,gC m-2 -US-UMd,18644,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_APPROACH,Tree AG wood total biomass =a*D^b where D=DBH (diam. At 1.37m) and a and b are species specific coefficients. DBH determined from complete census and measurement of all trees in all plots. Resulting biomass multiplied by wood carbon fraction. AG_BIOMASS_OTHER_ORGAN is tree foliage captured by litter traps 1 m above forest floor -US-UMd,18644,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_DATE,20060714 -US-UMd,18644,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_DATE_UNC,28 -US-UMd,18644,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_COMMENT,Litter traps are .264 m^2 with one - 3 traps in each of 21 - 0.08 ha plots and 20 traps in a 1.13 ha plot with flux tower a plot center. Litter trap collection date is 20011020 ± 20 d -US-UMd,18611,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER,113.7 -US-UMd,18611,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_SPATIAL_VARIABILITY,13.5 -US-UMd,18611,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_SPATIAL_REP_NUMBER,12 -US-UMd,18611,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_ORGAN,Foliage -US-UMd,18611,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_PHEN,Senescent -US-UMd,18611,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_UNIT,gC m-2 -US-UMd,18611,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_APPROACH,Tree AG wood total biomass =a*D^b where D=DBH (diam. At 1.37m) and a and b are species specific coefficients. DBH determined from increment bands installed on 15% of trees with DBH>= 10 cm. Resulting biomass multiplied by wood carbon fraction. AG_BIOMASS_OTHER_ORGAN is tree foliage captured by litter traps 1 m above forest floor -US-UMd,18611,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_DATE,20121020 -US-UMd,18611,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_DATE_UNC,20 -US-UMd,18611,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_COMMENT,Increment bands are capable of detecting 0.13 mm diameter change. Increment bands are read each year after leaf abscission and after AG growth has ceased. Growth of all trees extrapolated from regressions developed from banded trees. Litter traps are .264 m^2 with 3 traps in each of 11 - 0.08 ha plots and 20 traps in a 1.13 ha plot with flux tower a plot center. -US-UMd,18678,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER,118 -US-UMd,18678,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_SPATIAL_VARIABILITY,21.3 -US-UMd,18678,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_SPATIAL_REP_NUMBER,12 -US-UMd,18678,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_ORGAN,Foliage -US-UMd,18678,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_PHEN,Senescent -US-UMd,18678,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_UNIT,gC m-2 -US-UMd,18678,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_APPROACH,AG_BIOMASS_OTHER_ORGAN is tree foliage captured by litter traps 1 m above forest floor -US-UMd,18678,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_DATE,20081020 -US-UMd,18678,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_DATE_UNC,20 -US-UMd,18678,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_COMMENT,Litter traps are .264 m^2 with 3 traps in each of 11 - 0.08 ha plots and 20 traps in a 1.13 ha plot with flux tower a plot center. -US-UMd,18670,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER,118.7 -US-UMd,18670,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_SPATIAL_VARIABILITY,25.7 -US-UMd,18670,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_SPATIAL_REP_NUMBER,23 -US-UMd,18670,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_ORGAN,Foliage -US-UMd,18670,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_PHEN,Senescent -US-UMd,18670,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_UNIT,gC m-2 -US-UMd,18670,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_APPROACH,AG_BIOMASS_OTHER_ORGAN is tree foliage captured by litter traps 1 m above forest floor -US-UMd,18670,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_DATE,20071020 -US-UMd,18670,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_DATE_UNC,20 -US-UMd,18670,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_COMMENT,Litter traps are .264 m^2 with 1 - 3 traps in each of 22 - 0.08 ha plots and 20 traps in a 1.13 ha plot with flux tower a plot center. -US-UMd,18623,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER,123.9 -US-UMd,18623,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_SPATIAL_VARIABILITY,26.7 -US-UMd,18623,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_SPATIAL_REP_NUMBER,12 -US-UMd,18623,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_ORGAN,Foliage -US-UMd,18623,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_PHEN,Senescent -US-UMd,18623,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_UNIT,gC m-2 -US-UMd,18623,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_APPROACH,AG_BIOMASS_OTHER_ORGAN is tree foliage captured by litter traps 1 m above forest floor -US-UMd,18623,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_DATE,20091020 -US-UMd,18623,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_DATE_UNC,20 -US-UMd,18623,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_COMMENT,Litter traps are .264 m^2 with 3 traps in each of 11 - 0.08 ha plots and 20 traps in a 1.13 ha plot with flux tower a plot center. -US-UMd,18655,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER,90 -US-UMd,18655,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_SPATIAL_VARIABILITY,13.6 -US-UMd,18655,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_SPATIAL_REP_NUMBER,12 -US-UMd,18655,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_ORGAN,Foliage -US-UMd,18655,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_PHEN,Senescent -US-UMd,18655,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_UNIT,gC m-2 -US-UMd,18655,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_APPROACH,Tree AG wood total biomass =a*D^b where D=DBH (diam. At 1.37m) and a and b are species specific coefficients. DBH determined from complete census and measurement of all trees in all plots. Resulting biomass multiplied by wood carbon fraction. AG_BIOMASS_OTHER_ORGAN is tree foliage captured by litter traps 1 m above forest floor -US-UMd,18655,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_DATE,20100714 -US-UMd,18655,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_DATE_UNC,28 -US-UMd,18655,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_COMMENT,Many of the Populus and all of the Betula trees girdled in 2008 had died by the 2010 census. Litter traps are .264 m^2 with one trap in each of 21 - 0.08 ha plots and 20 traps in a 1.13 ha plot with flux tower a plot center. Litter trap collection date is 20101020 ± 20 d -US-UMd,18620,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER,98 -US-UMd,18620,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_SPATIAL_VARIABILITY,13.5 -US-UMd,18620,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_SPATIAL_REP_NUMBER,12 -US-UMd,18620,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_ORGAN,Foliage -US-UMd,18620,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_PHEN,Senescent -US-UMd,18620,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_UNIT,gC m-2 -US-UMd,18620,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_APPROACH,Tree AG wood total biomass =a*D^b where D=DBH (diam. At 1.37m) and a and b are species specific coefficients. DBH determined from increment bands installed on 15% of trees with DBH>= 10 cm. Resulting biomass multiplied by wood carbon fraction. AG_BIOMASS_OTHER_ORGAN is tree foliage captured by litter traps 1 m above forest floor -US-UMd,18620,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_DATE,20131020 -US-UMd,18620,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_DATE_UNC,20 -US-UMd,18620,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_COMMENT,Increment bands are capable of detecting 0.13 mm diameter change. Increment bands are read each year after leaf abscission and after AG growth has ceased. Growth of all trees extrapolated from regressions developed from banded trees. Litter traps are .264 m^2 with 3 traps in each of 11 - 0.08 ha plots and 20 traps in a 1.13 ha plot with flux tower a plot center. -US-UMd,18656,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,5653.7 -US-UMd,18656,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_SPATIAL_VARIABILITY,2534.3 -US-UMd,18656,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_SPATIAL_REP_NUMBER,23 -US-UMd,18656,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Wood -US-UMd,18656,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Green -US-UMd,18656,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-UMd,18656,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,Tree AG wood total biomass =a*D^b where D=DBH (diam. At 1.37m) and a and b are species specific coefficients. DBH determined from complete census and measurement of all trees in all plots. Resulting biomass multiplied by wood carbon fraction. AG_BIOMASS_OTHER_ORGAN is tree foliage captured by litter traps 1 m above forest floor -US-UMd,18656,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,20100714 -US-UMd,18656,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE_UNC,28 -US-UMd,18656,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,Many of the Populus and all of the Betula trees girdled in 2008 had died by the 2010 census. Litter traps are .264 m^2 with one trap in each of 21 - 0.08 ha plots and 20 traps in a 1.13 ha plot with flux tower a plot center. Litter trap collection date is 20101020 ± 20 d -US-UMd,18603,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,5778.2 -US-UMd,18603,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_SPATIAL_VARIABILITY,2586.7 -US-UMd,18603,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_SPATIAL_REP_NUMBER,23 -US-UMd,18603,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Wood -US-UMd,18603,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Green -US-UMd,18603,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-UMd,18603,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,Tree AG wood total biomass =a*D^b where D=DBH (diam. At 1.37m) and a and b are species specific coefficients. DBH determined from increment bands installed on ~25% of trees with DBH>= 10 cm. Resulting biomass multiplied by wood carbon fraction. AG_BIOMASS_OTHER_ORGAN is tree foliage captured by litter traps 1 m above forest floor -US-UMd,18603,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,20111020 -US-UMd,18603,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE_UNC,20 -US-UMd,18603,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,Increment bands are capable of detecting 0.13 mm diameter change. Increment bands are read each year after leaf abscission and after AG growth has ceased. Growth of all trees extrapolated from regressions developed from banded trees. Litter traps are .264 m^2 with 3 traps in each of 11 - 0.08 ha plots and 20 traps in a 1.13 ha plot with flux tower a plot center. -US-UMd,18612,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,5929.4 -US-UMd,18612,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_SPATIAL_VARIABILITY,2651.2 -US-UMd,18612,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_SPATIAL_REP_NUMBER,23 -US-UMd,18612,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Wood -US-UMd,18612,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Green -US-UMd,18612,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-UMd,18612,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,Tree AG wood total biomass =a*D^b where D=DBH (diam. At 1.37m) and a and b are species specific coefficients. DBH determined from increment bands installed on 15% of trees with DBH>= 10 cm. Resulting biomass multiplied by wood carbon fraction. AG_BIOMASS_OTHER_ORGAN is tree foliage captured by litter traps 1 m above forest floor -US-UMd,18612,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,20121020 -US-UMd,18612,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE_UNC,20 -US-UMd,18612,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,Increment bands are capable of detecting 0.13 mm diameter change. Increment bands are read each year after leaf abscission and after AG growth has ceased. Growth of all trees extrapolated from regressions developed from banded trees. Litter traps are .264 m^2 with 3 traps in each of 11 - 0.08 ha plots and 20 traps in a 1.13 ha plot with flux tower a plot center. -US-UMd,18621,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,6074.3 -US-UMd,18621,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_SPATIAL_VARIABILITY,2704.6 -US-UMd,18621,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_SPATIAL_REP_NUMBER,23 -US-UMd,18621,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Wood -US-UMd,18621,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Green -US-UMd,18621,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-UMd,18621,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,Tree AG wood total biomass =a*D^b where D=DBH (diam. At 1.37m) and a and b are species specific coefficients. DBH determined from increment bands installed on 15% of trees with DBH>= 10 cm. Resulting biomass multiplied by wood carbon fraction. AG_BIOMASS_OTHER_ORGAN is tree foliage captured by litter traps 1 m above forest floor -US-UMd,18621,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,20131020 -US-UMd,18621,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE_UNC,20 -US-UMd,18621,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,Increment bands are capable of detecting 0.13 mm diameter change. Increment bands are read each year after leaf abscission and after AG growth has ceased. Growth of all trees extrapolated from regressions developed from banded trees. Litter traps are .264 m^2 with 3 traps in each of 11 - 0.08 ha plots and 20 traps in a 1.13 ha plot with flux tower a plot center. -US-UMd,18645,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,7888.8 -US-UMd,18645,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_SPATIAL_VARIABILITY,2508.1 -US-UMd,18645,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_SPATIAL_REP_NUMBER,23 -US-UMd,18645,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Wood -US-UMd,18645,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Green -US-UMd,18645,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-UMd,18645,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,Tree AG wood total biomass =a*D^b where D=DBH (diam. At 1.37m) and a and b are species specific coefficients. DBH determined from complete census and measurement of all trees in all plots. Resulting biomass multiplied by wood carbon fraction. AG_BIOMASS_OTHER_ORGAN is tree foliage captured by litter traps 1 m above forest floor -US-UMd,18645,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE,20060714 -US-UMd,18645,GRP_AG_BIOMASS_TREE,AG_BIOMASS_DATE_UNC,28 -US-UMd,18645,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,Litter traps are .264 m^2 with one - 3 traps in each of 21 - 0.08 ha plots and 20 traps in a 1.13 ha plot with flux tower a plot center. Litter trap collection date is 20011020 ± 20 d -US-UMd,18657,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS,10.8 -US-UMd,18657,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_SPATIAL_VARIABILITY,9.3 -US-UMd,18657,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_SPATIAL_REP_NUMBER,21 -US-UMd,18657,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_UNIT,gC m-2 -US-UMd,18657,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_APPROACH,Litter debris collected from litter traps of .264 m^2 in area. One - 3 traps in 20 - 0.08 ha plots and 20 traps in a 1.13 ha plot with flux tower at plot center -US-UMd,18657,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_DATE,20070630 -US-UMd,18657,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_DATE_UNC,182 -US-UMd,18657,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_COMMENT,"Litter does NOT include identifiable leaves, but includes leaf fragments, seeds, flowers, lichens, etc collected from litter traps." -US-UMd,18646,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS,13.9 -US-UMd,18646,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_SPATIAL_VARIABILITY,9.5 -US-UMd,18646,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_SPATIAL_REP_NUMBER,8 -US-UMd,18646,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_UNIT,gC m-2 -US-UMd,18646,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_APPROACH,Litter debris collected from litter traps of .264 m^2 in area. Three - 9 traps along 300m long transects and 20 traps in a 1.13 ha plot with flux tower at plot center -US-UMd,18646,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_DATE,20060630 -US-UMd,18646,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_DATE_UNC,182 -US-UMd,18646,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_COMMENT,"Litter does NOT include identifiable leaves, but includes leaf fragments, seeds, flowers, lichens, etc collected from litter traps." -US-UMd,18679,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS,15.3 -US-UMd,18679,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_SPATIAL_VARIABILITY,5.7 -US-UMd,18679,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_SPATIAL_REP_NUMBER,12 -US-UMd,18679,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_UNIT,gC m-2 -US-UMd,18679,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_APPROACH,Litter debris collected from litter traps of .264 m^2 in area. Three traps in 11 - 0.08 ha plots and 20 traps in a 1.13 ha plot with flux tower at plot center -US-UMd,18679,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_DATE,20120630 -US-UMd,18679,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_DATE_UNC,182 -US-UMd,18679,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_COMMENT,"Litter does NOT include identifiable leaves, but includes leaf fragments, seeds, flowers, lichens, etc collected from litter traps." -US-UMd,18671,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS,15.6 -US-UMd,18671,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_SPATIAL_VARIABILITY,6.8 -US-UMd,18671,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_SPATIAL_REP_NUMBER,12 -US-UMd,18671,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_UNIT,gC m-2 -US-UMd,18671,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_APPROACH,Litter debris collected from litter traps of .264 m^2 in area. Three traps in 11 - 0.08 ha plots and 20 traps in a 1.13 ha plot with flux tower at plot center -US-UMd,18671,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_DATE,20110630 -US-UMd,18671,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_DATE_UNC,182 -US-UMd,18671,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_COMMENT,"Litter does NOT include identifiable leaves, but includes leaf fragments, seeds, flowers, lichens, etc collected from litter traps." -US-UMd,18624,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS,17 -US-UMd,18624,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_SPATIAL_VARIABILITY,7.9 -US-UMd,18624,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_SPATIAL_REP_NUMBER,12 -US-UMd,18624,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_UNIT,gC m-2 -US-UMd,18624,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_APPROACH,Litter debris collected from litter traps of .264 m^2 in area. Three traps in 11 - 0.08 ha plots and 20 traps in a 1.13 ha plot with flux tower at plot center -US-UMd,18624,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_DATE,20130630 -US-UMd,18624,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_DATE_UNC,182 -US-UMd,18624,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_COMMENT,"Litter does NOT include identifiable leaves, but includes leaf fragments, seeds, flowers, lichens, etc collected from litter traps." -US-UMd,18663,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS,24.5 -US-UMd,18663,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_SPATIAL_VARIABILITY,16.4 -US-UMd,18663,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_SPATIAL_REP_NUMBER,12 -US-UMd,18663,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_UNIT,gC m-2 -US-UMd,18663,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_APPROACH,Litter debris collected from litter traps of .264 m^2 in area. Three traps in 11 - 0.08 ha plots and 20 traps in a 1.13 ha plot with flux tower at plot center -US-UMd,18663,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_DATE,20100630 -US-UMd,18663,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_DATE_UNC,182 -US-UMd,18663,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_COMMENT,"Litter does NOT include identifiable leaves, but includes leaf fragments, seeds, flowers, lichens, etc collected from litter traps." -US-UMd,18604,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS,25.4 -US-UMd,18604,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_SPATIAL_VARIABILITY,12.1 -US-UMd,18604,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_SPATIAL_REP_NUMBER,12 -US-UMd,18604,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_UNIT,gC m-2 -US-UMd,18604,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_APPROACH,Litter debris collected from litter traps of .264 m^2 in area. Three traps in each of 11 - 0.08 ha plots and 20 traps in a 1.13 ha plot with flux tower at plot center -US-UMd,18604,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_DATE,20080630 -US-UMd,18604,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_DATE_UNC,182 -US-UMd,18604,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_COMMENT,"Litter does NOT include identifiable leaves, but includes leaf fragments, seeds, flowers, lichens, etc collected from litter traps. 2008 was a significant mast year for Quercus rubra with 19% of debris mass." -US-UMd,18613,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS,37 -US-UMd,18613,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_SPATIAL_VARIABILITY,18.4 -US-UMd,18613,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_SPATIAL_REP_NUMBER,12 -US-UMd,18613,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_UNIT,gC m-2 -US-UMd,18613,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_APPROACH,Litter debris collected from litter traps of .264 m^2 in area. Three traps in 11 - 0.08 ha plots and 20 traps in a 1.13 ha plot with flux tower at plot center -US-UMd,18613,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_DATE,20090630 -US-UMd,18613,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_DATE_UNC,182 -US-UMd,18613,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_COMMENT,"Litter does NOT include identifiable leaves, but includes leaf fragments, seeds, flowers, lichens, etc collected from litter traps. 2009 was a heavy mast year for Quercus rubra with 47.2% of debris mass." -US-UMd,18647,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT,114.1 -US-UMd,18664,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT,135.5 -US-UMd,18625,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT,137.7 -US-UMd,18658,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT,139.3 -US-UMd,18672,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT,150.7 -US-UMd,18605,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT,158.8 -US-UMd,18680,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT,159.5 -US-UMd,18614,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT,184.1 -US-UMd,18625,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT_SPATIAL_VARIABILITY,20.3 -US-UMd,18647,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT_SPATIAL_VARIABILITY,21.03 -US-UMd,18658,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT_SPATIAL_VARIABILITY,25.9 -US-UMd,18605,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT_SPATIAL_VARIABILITY,28.3 -US-UMd,18680,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT_SPATIAL_VARIABILITY,28.8 -US-UMd,18664,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT_SPATIAL_VARIABILITY,29.7 -US-UMd,18672,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT_SPATIAL_VARIABILITY,34.4 -US-UMd,18614,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT_SPATIAL_VARIABILITY,46.2 -US-UMd,18605,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT_SPATIAL_REP_NUMBER,12 -US-UMd,18614,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT_SPATIAL_REP_NUMBER,12 -US-UMd,18625,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT_SPATIAL_REP_NUMBER,12 -US-UMd,18664,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT_SPATIAL_REP_NUMBER,12 -US-UMd,18672,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT_SPATIAL_REP_NUMBER,12 -US-UMd,18680,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT_SPATIAL_REP_NUMBER,12 -US-UMd,18647,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT_SPATIAL_REP_NUMBER,22 -US-UMd,18658,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT_SPATIAL_REP_NUMBER,23 -US-UMd,18605,GRP_AG_LIT_PROD,AG_LIT_PROD_UNIT,gC m-2 -US-UMd,18614,GRP_AG_LIT_PROD,AG_LIT_PROD_UNIT,gC m-2 -US-UMd,18625,GRP_AG_LIT_PROD,AG_LIT_PROD_UNIT,gC m-2 -US-UMd,18647,GRP_AG_LIT_PROD,AG_LIT_PROD_UNIT,gC m-2 -US-UMd,18658,GRP_AG_LIT_PROD,AG_LIT_PROD_UNIT,gC m-2 -US-UMd,18664,GRP_AG_LIT_PROD,AG_LIT_PROD_UNIT,gC m-2 -US-UMd,18672,GRP_AG_LIT_PROD,AG_LIT_PROD_UNIT,gC m-2 -US-UMd,18680,GRP_AG_LIT_PROD,AG_LIT_PROD_UNIT,gC m-2 -US-UMd,18647,GRP_AG_LIT_PROD,AG_LIT_PROD_APPROACH,"Litter collected from litter traps of .264 m^2 in area. One - 3 traps in each of 21 - 0.08 ha plots and 20 traps in a single 1.13 ha plot with flux tower at plot center. Litter includes foliage, seeds, flowers, fine woody debris." -US-UMd,18658,GRP_AG_LIT_PROD,AG_LIT_PROD_APPROACH,"Litter collected from litter traps of .264 m^2 in area. One - 3 traps in each of 21 - 0.08 ha plots and 20 traps in a single 1.13 ha plot with flux tower at plot center. Litter includes foliage, seeds, flowers, fine woody debris." -US-UMd,18605,GRP_AG_LIT_PROD,AG_LIT_PROD_APPROACH,"Litter collected from litter traps of .264 m^2 in area. Three traps in each of 11 - 0.08 ha plots and 20 traps in a single 1.13 ha plot with flux tower at plot center. Litter includes foliage, seeds, flowers, fine woody debris." -US-UMd,18614,GRP_AG_LIT_PROD,AG_LIT_PROD_APPROACH,"Litter collected from litter traps of .264 m^2 in area. Three traps in each of 11 - 0.08 ha plots and 20 traps in a single 1.13 ha plot with flux tower at plot center. Litter includes foliage, seeds, flowers, fine woody debris." -US-UMd,18625,GRP_AG_LIT_PROD,AG_LIT_PROD_APPROACH,"Litter collected from litter traps of .264 m^2 in area. Three traps in each of 11 - 0.08 ha plots and 20 traps in a single 1.13 ha plot with flux tower at plot center. Litter includes foliage, seeds, flowers, fine woody debris." -US-UMd,18664,GRP_AG_LIT_PROD,AG_LIT_PROD_APPROACH,"Litter collected from litter traps of .264 m^2 in area. Three traps in each of 11 - 0.08 ha plots and 20 traps in a single 1.13 ha plot with flux tower at plot center. Litter includes foliage, seeds, flowers, fine woody debris." -US-UMd,18672,GRP_AG_LIT_PROD,AG_LIT_PROD_APPROACH,"Litter collected from litter traps of .264 m^2 in area. Three traps in each of 11 - 0.08 ha plots and 20 traps in a single 1.13 ha plot with flux tower at plot center. Litter includes foliage, seeds, flowers, fine woody debris." -US-UMd,18680,GRP_AG_LIT_PROD,AG_LIT_PROD_APPROACH,"Litter collected from litter traps of .264 m^2 in area. Three traps in each of 11 - 0.08 ha plots and 20 traps in a single 1.13 ha plot with flux tower at plot center. Litter includes foliage, seeds, flowers, fine woody debris." -US-UMd,18647,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_START,20060807 -US-UMd,18658,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_START,20061101 -US-UMd,18605,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_START,20071101 -US-UMd,18614,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_START,20081101 -US-UMd,18664,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_START,20091101 -US-UMd,18672,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_START,20101101 -US-UMd,18680,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_START,20111101 -US-UMd,18625,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_START,20121101 -US-UMd,18647,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_END,20061101 -US-UMd,18658,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_END,20071101 -US-UMd,18605,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_END,20081101 -US-UMd,18614,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_END,20091101 -US-UMd,18664,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_END,20101101 -US-UMd,18672,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_END,20111101 -US-UMd,18680,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_END,20121101 -US-UMd,18625,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_END,20131101 -US-UMd,18605,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_UNC,30 -US-UMd,18614,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_UNC,30 -US-UMd,18625,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_UNC,30 -US-UMd,18647,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_UNC,30 -US-UMd,18658,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_UNC,30 -US-UMd,18664,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_UNC,30 -US-UMd,18672,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_UNC,30 -US-UMd,18680,GRP_AG_LIT_PROD,AG_LIT_PROD_DATE_UNC,30 -US-UMd,18605,GRP_AG_LIT_PROD,AG_LIT_PROD_COMMENT,Litter includes all litter from 1 m above forest floor to the top of the canopy. Litter does not include herbaceous layer below 1 m. -US-UMd,18614,GRP_AG_LIT_PROD,AG_LIT_PROD_COMMENT,Litter includes all litter from 1 m above forest floor to the top of the canopy. Litter does not include herbaceous layer below 1 m. -US-UMd,18625,GRP_AG_LIT_PROD,AG_LIT_PROD_COMMENT,Litter includes all litter from 1 m above forest floor to the top of the canopy. Litter does not include herbaceous layer below 1 m. -US-UMd,18647,GRP_AG_LIT_PROD,AG_LIT_PROD_COMMENT,Litter includes all litter from 1 m above forest floor to the top of the canopy. Litter does not include herbaceous layer below 1 m. -US-UMd,18658,GRP_AG_LIT_PROD,AG_LIT_PROD_COMMENT,Litter includes all litter from 1 m above forest floor to the top of the canopy. Litter does not include herbaceous layer below 1 m. -US-UMd,18664,GRP_AG_LIT_PROD,AG_LIT_PROD_COMMENT,Litter includes all litter from 1 m above forest floor to the top of the canopy. Litter does not include herbaceous layer below 1 m. -US-UMd,18672,GRP_AG_LIT_PROD,AG_LIT_PROD_COMMENT,Litter includes all litter from 1 m above forest floor to the top of the canopy. Litter does not include herbaceous layer below 1 m. -US-UMd,18680,GRP_AG_LIT_PROD,AG_LIT_PROD_COMMENT,Litter includes all litter from 1 m above forest floor to the top of the canopy. Litter does not include herbaceous layer below 1 m. -US-UMd,18665,GRP_AG_PROD_TREE,AG_PROD_TREE,113.9 -US-UMd,18665,GRP_AG_PROD_TREE,AG_PROD_TREE_SPATIAL_VARIABILITY,53.37 -US-UMd,18665,GRP_AG_PROD_TREE,AG_PROD_TREE_SPATIAL_REP_NUMBER,23 -US-UMd,18665,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Wood -US-UMd,18665,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-UMd,18665,GRP_AG_PROD_TREE,AG_PROD_APPROACH,Band Dendrometers -US-UMd,18665,GRP_AG_PROD_TREE,AG_PROD_DATE_START,20091106 -US-UMd,18665,GRP_AG_PROD_TREE,AG_PROD_DATE_END,20101116 -US-UMd,18665,GRP_AG_PROD_TREE,AG_PROD_DATE_UNC,4 -US-UMd,18665,GRP_AG_PROD_TREE,AG_PROD_COMMENT,Species specific allometric equations in the form a*D^b where D is diameter of tree stem at 1.37 m ht and a and b are species specific constants were used to determine AG woody biomass. Stem diameters for all trees in all plots were estimated from band dendrometer readings taken from ~25% of total number of trees. See STEM_INCR data in this file for more information. -US-UMd,18673,GRP_AG_PROD_TREE,AG_PROD_TREE,137 -US-UMd,18673,GRP_AG_PROD_TREE,AG_PROD_TREE_SPATIAL_VARIABILITY,63.55 -US-UMd,18673,GRP_AG_PROD_TREE,AG_PROD_TREE_SPATIAL_REP_NUMBER,23 -US-UMd,18673,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Wood -US-UMd,18673,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-UMd,18673,GRP_AG_PROD_TREE,AG_PROD_APPROACH,Band Dendrometers -US-UMd,18673,GRP_AG_PROD_TREE,AG_PROD_DATE_START,20101116 -US-UMd,18673,GRP_AG_PROD_TREE,AG_PROD_DATE_END,20111103 -US-UMd,18673,GRP_AG_PROD_TREE,AG_PROD_DATE_UNC,4 -US-UMd,18673,GRP_AG_PROD_TREE,AG_PROD_COMMENT,Species specific allometric equations in the form a*D^b where D is diameter of tree stem at 1.37 m ht and a and b are species specific constants were used to determine AG woody biomass. Stem diameters for all trees in all plots were estimated from band dendrometer readings taken from ~25% of total number of trees. See STEM_INCR data in this file for more information. -US-UMd,18626,GRP_AG_PROD_TREE,AG_PROD_TREE,144.9 -US-UMd,18626,GRP_AG_PROD_TREE,AG_PROD_TREE_SPATIAL_VARIABILITY,61.29 -US-UMd,18626,GRP_AG_PROD_TREE,AG_PROD_TREE_SPATIAL_REP_NUMBER,23 -US-UMd,18626,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Wood -US-UMd,18626,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-UMd,18626,GRP_AG_PROD_TREE,AG_PROD_APPROACH,Band Dendrometers -US-UMd,18626,GRP_AG_PROD_TREE,AG_PROD_DATE_START,20121108 -US-UMd,18626,GRP_AG_PROD_TREE,AG_PROD_DATE_END,20131001 -US-UMd,18626,GRP_AG_PROD_TREE,AG_PROD_DATE_UNC,4 -US-UMd,18626,GRP_AG_PROD_TREE,AG_PROD_COMMENT,Species specific allometric equations in the form a*D^b where D is diameter of tree stem at 1.37 m ht and a and b are species specific constants were used to determine AG woody biomass. Stem diameters for all trees in all plots were estimated from band dendrometer readings taken from ~25% of total number of trees. See STEM_INCR data in this file for more information. -US-UMd,18615,GRP_AG_PROD_TREE,AG_PROD_TREE,148.1 -US-UMd,18615,GRP_AG_PROD_TREE,AG_PROD_TREE_SPATIAL_VARIABILITY,54.66 -US-UMd,18615,GRP_AG_PROD_TREE,AG_PROD_TREE_SPATIAL_REP_NUMBER,23 -US-UMd,18615,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Wood -US-UMd,18615,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-UMd,18615,GRP_AG_PROD_TREE,AG_PROD_APPROACH,Band Dendrometers -US-UMd,18615,GRP_AG_PROD_TREE,AG_PROD_DATE_START,20081106 -US-UMd,18615,GRP_AG_PROD_TREE,AG_PROD_DATE_END,20091106 -US-UMd,18615,GRP_AG_PROD_TREE,AG_PROD_DATE_UNC,4 -US-UMd,18615,GRP_AG_PROD_TREE,AG_PROD_COMMENT,Species specific allometric equations in the form a*D^b where D is diameter of tree stem at 1.37 m ht and a and b are species specific constants were used to determine AG woody biomass. Stem diameters for all trees in all plots were estimated from band dendrometer readings taken from ~25% of total number of trees. See STEM_INCR data in this file for more information. -US-UMd,18606,GRP_AG_PROD_TREE,AG_PROD_TREE,154.9 -US-UMd,18606,GRP_AG_PROD_TREE,AG_PROD_TREE_SPATIAL_VARIABILITY,50.8 -US-UMd,18606,GRP_AG_PROD_TREE,AG_PROD_TREE_SPATIAL_REP_NUMBER,23 -US-UMd,18606,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Wood -US-UMd,18606,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-UMd,18606,GRP_AG_PROD_TREE,AG_PROD_APPROACH,Band Dendrometers -US-UMd,18606,GRP_AG_PROD_TREE,AG_PROD_DATE_START,20071022 -US-UMd,18606,GRP_AG_PROD_TREE,AG_PROD_DATE_END,20081106 -US-UMd,18606,GRP_AG_PROD_TREE,AG_PROD_DATE_UNC,4 -US-UMd,18606,GRP_AG_PROD_TREE,AG_PROD_COMMENT,Species specific allometric equations in the form a*D^b where D is diameter of tree stem at 1.37 m ht and a and b are species specific constants were used to determine AG woody biomass. Stem diameters for all trees in all plots were estimated from band dendrometer readings taken from ~25% of total number of trees. See STEM_INCR data in this file for more information. -US-UMd,18681,GRP_AG_PROD_TREE,AG_PROD_TREE,155.4 -US-UMd,18681,GRP_AG_PROD_TREE,AG_PROD_TREE_SPATIAL_VARIABILITY,76.36 -US-UMd,18681,GRP_AG_PROD_TREE,AG_PROD_TREE_SPATIAL_REP_NUMBER,23 -US-UMd,18681,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Wood -US-UMd,18681,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-UMd,18681,GRP_AG_PROD_TREE,AG_PROD_APPROACH,Band Dendrometers -US-UMd,18681,GRP_AG_PROD_TREE,AG_PROD_DATE_START,20111103 -US-UMd,18681,GRP_AG_PROD_TREE,AG_PROD_DATE_END,20121108 -US-UMd,18681,GRP_AG_PROD_TREE,AG_PROD_DATE_UNC,4 -US-UMd,18681,GRP_AG_PROD_TREE,AG_PROD_COMMENT,Species specific allometric equations in the form a*D^b where D is diameter of tree stem at 1.37 m ht and a and b are species specific constants were used to determine AG woody biomass. Stem diameters for all trees in all plots were estimated from band dendrometer readings taken from ~25% of total number of trees. See STEM_INCR data in this file for more information. -US-UMd,18659,GRP_AG_PROD_TREE,AG_PROD_TREE,155.9 -US-UMd,18659,GRP_AG_PROD_TREE,AG_PROD_TREE_SPATIAL_VARIABILITY,50.5 -US-UMd,18659,GRP_AG_PROD_TREE,AG_PROD_TREE_SPATIAL_REP_NUMBER,23 -US-UMd,18659,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Wood -US-UMd,18659,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-UMd,18659,GRP_AG_PROD_TREE,AG_PROD_APPROACH,Band Dendrometers -US-UMd,18659,GRP_AG_PROD_TREE,AG_PROD_DATE_START,20070430 -US-UMd,18659,GRP_AG_PROD_TREE,AG_PROD_DATE_END,20071022 -US-UMd,18659,GRP_AG_PROD_TREE,AG_PROD_DATE_UNC,4 -US-UMd,18659,GRP_AG_PROD_TREE,AG_PROD_COMMENT,Species specific allometric equations in the form a*D^b where D is diameter of tree stem at 1.37 m ht and a and b are species specific constants were used to determine AG woody biomass. Stem diameters for all trees in all plots were estimated from band dendrometer readings taken from ~25% of total number of trees. See STEM_INCR data in this file for more information. -US-UMd,18648,GRP_AG_PROD_TREE,AG_PROD_TREE,712 -US-UMd,18648,GRP_AG_PROD_TREE,AG_PROD_TREE_SPATIAL_VARIABILITY,279.3 -US-UMd,18648,GRP_AG_PROD_TREE,AG_PROD_TREE_SPATIAL_REP_NUMBER,23 -US-UMd,18648,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Wood -US-UMd,18648,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-UMd,18648,GRP_AG_PROD_TREE,AG_PROD_APPROACH,Manual census -US-UMd,18648,GRP_AG_PROD_TREE,AG_PROD_DATE_START,20060714 -US-UMd,18648,GRP_AG_PROD_TREE,AG_PROD_DATE_END,20100714 -US-UMd,18648,GRP_AG_PROD_TREE,AG_PROD_DATE_UNC,28 -US-UMd,18648,GRP_AG_PROD_TREE,AG_PROD_COMMENT,Species specific allometric equations in the form a*D^b where D is diameter of tree stem at 1.37 m ht and a and b are species specific constants were used to determine AG woody biomass. Stem diameters were determined from manual measurments of trees in 22 - 0.08 ha plots and a single 1.13 ha plot -US-UMd,19239,GRP_BASAL_AREA,BASAL_AREA,0.24 -US-UMd,19239,GRP_BASAL_AREA,BASAL_AREA_SPP,Betula papyrifera -US-UMd,19239,GRP_BASAL_AREA,BASAL_AREA_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 22 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm." -US-UMd,19239,GRP_BASAL_AREA,BASAL_AREA_DATE,20100714 -US-UMd,19239,GRP_BASAL_AREA,BASAL_AREA_DATE_UNC,28 -US-UMd,19239,GRP_BASAL_AREA,BASAL_AREA_COMMENT,Average and standard dev. based on 22 plots regardless of whether species existed in all plots. See DBH replicas for number of plots a tree species occurred. -US-UMd,19239,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,23 -US-UMd,19239,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,0.74 -US-UMd,19260,GRP_BASAL_AREA,BASAL_AREA,0.26 -US-UMd,19260,GRP_BASAL_AREA,BASAL_AREA_SPP,other (6 species) -US-UMd,19260,GRP_BASAL_AREA,BASAL_AREA_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 22 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm." -US-UMd,19260,GRP_BASAL_AREA,BASAL_AREA_DATE,20100714 -US-UMd,19260,GRP_BASAL_AREA,BASAL_AREA_DATE_UNC,28 -US-UMd,19260,GRP_BASAL_AREA,BASAL_AREA_COMMENT,Average and standard dev. based on 22 plots regardless of whether species existed in all plots. See DBH replicas for number of plots a tree species occurred. -US-UMd,19260,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,23 -US-UMd,19260,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,0.82 -US-UMd,19289,GRP_BASAL_AREA,BASAL_AREA,0.26 -US-UMd,19289,GRP_BASAL_AREA,BASAL_AREA_SPP,other (5 species) -US-UMd,19289,GRP_BASAL_AREA,BASAL_AREA_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 22 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm." -US-UMd,19289,GRP_BASAL_AREA,BASAL_AREA_DATE,20060714 -US-UMd,19289,GRP_BASAL_AREA,BASAL_AREA_DATE_UNC,28 -US-UMd,19289,GRP_BASAL_AREA,BASAL_AREA_COMMENT,Average and standard dev. based on 22 plots regardless of whether species existed in all plots. See DBH replicas for number of plots a tree species occurred. -US-UMd,19289,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,23 -US-UMd,19289,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,0.81 -US-UMd,19249,GRP_BASAL_AREA,BASAL_AREA,0.44 -US-UMd,19249,GRP_BASAL_AREA,BASAL_AREA_SPP,Populus tremuloides -US-UMd,19249,GRP_BASAL_AREA,BASAL_AREA_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 22 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm." -US-UMd,19249,GRP_BASAL_AREA,BASAL_AREA_DATE,20100714 -US-UMd,19249,GRP_BASAL_AREA,BASAL_AREA_DATE_UNC,28 -US-UMd,19249,GRP_BASAL_AREA,BASAL_AREA_COMMENT,Average and standard dev. based on 22 plots regardless of whether species existed in all plots. See DBH replicas for number of plots a tree species occurred. -US-UMd,19249,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,23 -US-UMd,19249,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,2.12 -US-UMd,19201,GRP_BASAL_AREA,BASAL_AREA,0.58 -US-UMd,19201,GRP_BASAL_AREA,BASAL_AREA_SPP,Fagus grandifolia -US-UMd,19201,GRP_BASAL_AREA,BASAL_AREA_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 22 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm." -US-UMd,19201,GRP_BASAL_AREA,BASAL_AREA_DATE,20060714 -US-UMd,19201,GRP_BASAL_AREA,BASAL_AREA_DATE_UNC,28 -US-UMd,19201,GRP_BASAL_AREA,BASAL_AREA_COMMENT,Average and standard dev. based on 22 plots regardless of whether species existed in all plots. See DBH replicas for number of plots a tree species occurred. -US-UMd,19201,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,23 -US-UMd,19201,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,1.74 -US-UMd,19291,GRP_BASAL_AREA,BASAL_AREA,0.62 -US-UMd,19291,GRP_BASAL_AREA,BASAL_AREA_SPP,Fagus grandifolia -US-UMd,19291,GRP_BASAL_AREA,BASAL_AREA_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 22 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm." -US-UMd,19291,GRP_BASAL_AREA,BASAL_AREA_DATE,20100714 -US-UMd,19291,GRP_BASAL_AREA,BASAL_AREA_DATE_UNC,28 -US-UMd,19291,GRP_BASAL_AREA,BASAL_AREA_COMMENT,Average and standard dev. based on 22 plots regardless of whether species existed in all plots. See DBH replicas for number of plots a tree species occurred. -US-UMd,19291,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,23 -US-UMd,19291,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,1.82 -US-UMd,19208,GRP_BASAL_AREA,BASAL_AREA,1.17 -US-UMd,19208,GRP_BASAL_AREA,BASAL_AREA_SPP,Pinus resinosa -US-UMd,19208,GRP_BASAL_AREA,BASAL_AREA_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 22 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm." -US-UMd,19208,GRP_BASAL_AREA,BASAL_AREA_DATE,20060714 -US-UMd,19208,GRP_BASAL_AREA,BASAL_AREA_DATE_UNC,28 -US-UMd,19208,GRP_BASAL_AREA,BASAL_AREA_COMMENT,Average and standard dev. based on 22 plots regardless of whether species existed in all plots. See DBH replicas for number of plots a tree species occurred. -US-UMd,19208,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,23 -US-UMd,19208,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,2.31 -US-UMd,19298,GRP_BASAL_AREA,BASAL_AREA,1.26 -US-UMd,19298,GRP_BASAL_AREA,BASAL_AREA_SPP,Pinus resinosa -US-UMd,19298,GRP_BASAL_AREA,BASAL_AREA_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 22 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm." -US-UMd,19298,GRP_BASAL_AREA,BASAL_AREA_DATE,20100714 -US-UMd,19298,GRP_BASAL_AREA,BASAL_AREA_DATE_UNC,28 -US-UMd,19298,GRP_BASAL_AREA,BASAL_AREA_COMMENT,Average and standard dev. based on 22 plots regardless of whether species existed in all plots. See DBH replicas for number of plots a tree species occurred. -US-UMd,19298,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,23 -US-UMd,19298,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,2.57 -US-UMd,19275,GRP_BASAL_AREA,BASAL_AREA,1.28 -US-UMd,19275,GRP_BASAL_AREA,BASAL_AREA_SPP,Populus tremuloides -US-UMd,19275,GRP_BASAL_AREA,BASAL_AREA_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 22 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm." -US-UMd,19275,GRP_BASAL_AREA,BASAL_AREA_DATE,20060714 -US-UMd,19275,GRP_BASAL_AREA,BASAL_AREA_DATE_UNC,28 -US-UMd,19275,GRP_BASAL_AREA,BASAL_AREA_COMMENT,Average and standard dev. based on 22 plots regardless of whether species existed in all plots. See DBH replicas for number of plots a tree species occurred. -US-UMd,19275,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,23 -US-UMd,19275,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,6.02 -US-UMd,19330,GRP_BASAL_AREA,BASAL_AREA,1.28 -US-UMd,19330,GRP_BASAL_AREA,BASAL_AREA_SPP,Acer saccharum -US-UMd,19330,GRP_BASAL_AREA,BASAL_AREA_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 22 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm." -US-UMd,19330,GRP_BASAL_AREA,BASAL_AREA_DATE,20060714 -US-UMd,19330,GRP_BASAL_AREA,BASAL_AREA_DATE_UNC,28 -US-UMd,19330,GRP_BASAL_AREA,BASAL_AREA_COMMENT,Average and standard dev. based on 22 plots regardless of whether species existed in all plots. See DBH replicas for number of plots a tree species occurred. -US-UMd,19330,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,23 -US-UMd,19330,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,2.8 -US-UMd,19233,GRP_BASAL_AREA,BASAL_AREA,1.37 -US-UMd,19233,GRP_BASAL_AREA,BASAL_AREA_SPP,Acer saccharum -US-UMd,19233,GRP_BASAL_AREA,BASAL_AREA_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 22 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm." -US-UMd,19233,GRP_BASAL_AREA,BASAL_AREA_DATE,20100714 -US-UMd,19233,GRP_BASAL_AREA,BASAL_AREA_DATE_UNC,28 -US-UMd,19233,GRP_BASAL_AREA,BASAL_AREA_COMMENT,Average and standard dev. based on 22 plots regardless of whether species existed in all plots. See DBH replicas for number of plots a tree species occurred. -US-UMd,19233,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,23 -US-UMd,19233,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,2.97 -US-UMd,19337,GRP_BASAL_AREA,BASAL_AREA,1.93 -US-UMd,19337,GRP_BASAL_AREA,BASAL_AREA_SPP,Betula papyrifera -US-UMd,19337,GRP_BASAL_AREA,BASAL_AREA_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 22 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm." -US-UMd,19337,GRP_BASAL_AREA,BASAL_AREA_DATE,20060714 -US-UMd,19337,GRP_BASAL_AREA,BASAL_AREA_DATE_UNC,28 -US-UMd,19337,GRP_BASAL_AREA,BASAL_AREA_COMMENT,Average and standard dev. based on 22 plots regardless of whether species existed in all plots. See DBH replicas for number of plots a tree species occurred. -US-UMd,19337,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,23 -US-UMd,19337,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,2.71 -US-UMd,19321,GRP_BASAL_AREA,BASAL_AREA,3.4 -US-UMd,19321,GRP_BASAL_AREA,BASAL_AREA_SPP,Acer rubrum -US-UMd,19321,GRP_BASAL_AREA,BASAL_AREA_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 22 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm." -US-UMd,19321,GRP_BASAL_AREA,BASAL_AREA_DATE,20060714 -US-UMd,19321,GRP_BASAL_AREA,BASAL_AREA_DATE_UNC,28 -US-UMd,19321,GRP_BASAL_AREA,BASAL_AREA_COMMENT,Average and standard dev. based on 22 plots regardless of whether species existed in all plots. See DBH replicas for number of plots a tree species occurred. -US-UMd,19321,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,23 -US-UMd,19321,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,1.95 -US-UMd,19215,GRP_BASAL_AREA,BASAL_AREA,3.45 -US-UMd,19215,GRP_BASAL_AREA,BASAL_AREA_SPP,Pinus strobus -US-UMd,19215,GRP_BASAL_AREA,BASAL_AREA_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 22 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm." -US-UMd,19215,GRP_BASAL_AREA,BASAL_AREA_DATE,20060714 -US-UMd,19215,GRP_BASAL_AREA,BASAL_AREA_DATE_UNC,28 -US-UMd,19215,GRP_BASAL_AREA,BASAL_AREA_COMMENT,Average and standard dev. based on 22 plots regardless of whether species existed in all plots. See DBH replicas for number of plots a tree species occurred. -US-UMd,19215,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,23 -US-UMd,19215,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,4.18 -US-UMd,19227,GRP_BASAL_AREA,BASAL_AREA,3.56 -US-UMd,19227,GRP_BASAL_AREA,BASAL_AREA_SPP,Acer rubrum -US-UMd,19227,GRP_BASAL_AREA,BASAL_AREA_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 22 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm." -US-UMd,19227,GRP_BASAL_AREA,BASAL_AREA_DATE,20100714 -US-UMd,19227,GRP_BASAL_AREA,BASAL_AREA_DATE_UNC,28 -US-UMd,19227,GRP_BASAL_AREA,BASAL_AREA_COMMENT,Average and standard dev. based on 22 plots regardless of whether species existed in all plots. See DBH replicas for number of plots a tree species occurred. -US-UMd,19227,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,23 -US-UMd,19227,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,1.98 -US-UMd,19305,GRP_BASAL_AREA,BASAL_AREA,3.81 -US-UMd,19305,GRP_BASAL_AREA,BASAL_AREA_SPP,Pinus strobus -US-UMd,19305,GRP_BASAL_AREA,BASAL_AREA_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 22 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm." -US-UMd,19305,GRP_BASAL_AREA,BASAL_AREA_DATE,20100714 -US-UMd,19305,GRP_BASAL_AREA,BASAL_AREA_DATE_UNC,28 -US-UMd,19305,GRP_BASAL_AREA,BASAL_AREA_COMMENT,Average and standard dev. based on 22 plots regardless of whether species existed in all plots. See DBH replicas for number of plots a tree species occurred. -US-UMd,19305,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,23 -US-UMd,19305,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,4.54 -US-UMd,19282,GRP_BASAL_AREA,BASAL_AREA,6.67 -US-UMd,19282,GRP_BASAL_AREA,BASAL_AREA_SPP,Quercus rubra -US-UMd,19282,GRP_BASAL_AREA,BASAL_AREA_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 22 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm." -US-UMd,19282,GRP_BASAL_AREA,BASAL_AREA_DATE,20060714 -US-UMd,19282,GRP_BASAL_AREA,BASAL_AREA_DATE_UNC,28 -US-UMd,19282,GRP_BASAL_AREA,BASAL_AREA_COMMENT,Average and standard dev. based on 22 plots regardless of whether species existed in all plots. See DBH replicas for number of plots a tree species occurred. -US-UMd,19282,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,23 -US-UMd,19282,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,5.45 -US-UMd,19312,GRP_BASAL_AREA,BASAL_AREA,6.94 -US-UMd,19312,GRP_BASAL_AREA,BASAL_AREA_SPP,Populus grandidentata -US-UMd,19312,GRP_BASAL_AREA,BASAL_AREA_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 22 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm." -US-UMd,19312,GRP_BASAL_AREA,BASAL_AREA_DATE,20100714 -US-UMd,19312,GRP_BASAL_AREA,BASAL_AREA_DATE_UNC,28 -US-UMd,19312,GRP_BASAL_AREA,BASAL_AREA_COMMENT,Average and standard dev. based on 22 plots regardless of whether species existed in all plots. See DBH replicas for number of plots a tree species occurred. -US-UMd,19312,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,23 -US-UMd,19312,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,7.33 -US-UMd,19255,GRP_BASAL_AREA,BASAL_AREA,7.06 -US-UMd,19255,GRP_BASAL_AREA,BASAL_AREA_SPP,Quercus rubra -US-UMd,19255,GRP_BASAL_AREA,BASAL_AREA_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 22 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm." -US-UMd,19255,GRP_BASAL_AREA,BASAL_AREA_DATE,20100714 -US-UMd,19255,GRP_BASAL_AREA,BASAL_AREA_DATE_UNC,28 -US-UMd,19255,GRP_BASAL_AREA,BASAL_AREA_COMMENT,Average and standard dev. based on 22 plots regardless of whether species existed in all plots. See DBH replicas for number of plots a tree species occurred. -US-UMd,19255,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,23 -US-UMd,19255,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,5.66 -US-UMd,19268,GRP_BASAL_AREA,BASAL_AREA,8.2 -US-UMd,19268,GRP_BASAL_AREA,BASAL_AREA_SPP,Populus grandidentata -US-UMd,19268,GRP_BASAL_AREA,BASAL_AREA_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 22 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm." -US-UMd,19268,GRP_BASAL_AREA,BASAL_AREA_DATE,20060714 -US-UMd,19268,GRP_BASAL_AREA,BASAL_AREA_DATE_UNC,28 -US-UMd,19268,GRP_BASAL_AREA,BASAL_AREA_COMMENT,Average and standard dev. based on 22 plots regardless of whether species existed in all plots. See DBH replicas for number of plots a tree species occurred. -US-UMd,19268,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_REP_NUMBER,23 -US-UMd,19268,GRP_BASAL_AREA,BASAL_AREA_SPATIAL_VARIABILITY,7.06 -US-UMd,18649,GRP_BG_LIT_PROD,BG_LIT_PROD,41.1 -US-UMd,18649,GRP_BG_LIT_PROD,BG_LIT_PROD_SPATIAL_VARIABILITY,15.2 -US-UMd,18649,GRP_BG_LIT_PROD,BG_LIT_PROD_SPATIAL_REP_NUMBER,4 -US-UMd,18649,GRP_BG_LIT_PROD,BG_LIT_PROD_UNIT,gC m-2 -US-UMd,18649,GRP_BG_LIT_PROD,BG_LIT_PROD_PROFILE_ZERO_REF,Top of surface -US-UMd,18649,GRP_BG_LIT_PROD,BG_LIT_PROD_PROFILE_MIN,0 -US-UMd,18649,GRP_BG_LIT_PROD,BG_LIT_PROD_PROFILE_MAX,40 -US-UMd,18649,GRP_BG_LIT_PROD,BG_LIT_PROD_APPROACH,minirhizotron images -US-UMd,18649,GRP_BG_LIT_PROD,BG_LIT_PROD_DATE_START,20090602 -US-UMd,18649,GRP_BG_LIT_PROD,BG_LIT_PROD_DATE_END,20090918 -US-UMd,18649,GRP_BG_LIT_PROD,BG_LIT_PROD_DATE_UNC,1 -US-UMd,18649,GRP_BG_LIT_PROD,BG_LIT_PROD_COMMENT,"Fine roots only. Fine root turnover determined by multiplying %turnover (minirhizotron analysis) by fine root biomass. All Populus and Betula had been stem girdled in the spring of 2008. See Nave, et al. 2011. JGR vol 116. doi: 10.1029/2011JG1758." -US-UMd,12361,GRP_CLIM_AVG,MAT,5.83 -US-UMd,12361,GRP_CLIM_AVG,MAP,803 -US-UMd,12361,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfb -US-UMd,27000500,GRP_COUNTRY,COUNTRY,USA -US-UMd,19202,GRP_DBH,DBH,10.75 -US-UMd,19202,GRP_DBH,DBH_SPP,Fagus grandifolia -US-UMd,19202,GRP_DBH,DBH_HEIGHT,1.37 -US-UMd,19202,GRP_DBH,DBH_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 22 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm." -US-UMd,19202,GRP_DBH,DBH_DATE,20060714 -US-UMd,19202,GRP_DBH,DBH_DATE_UNC,28 -US-UMd,19202,GRP_DBH,DBH_COMMENT,Average and standard dev. based soley on plots for which the species existed. Total N was 22 plots but not all species were represented in all plots. -US-UMd,19202,GRP_DBH,DBH_SPATIAL_REP_NUMBER,12 -US-UMd,19202,GRP_DBH,DBH_SPATIAL_VARIABILITY,2.34 -US-UMd,19292,GRP_DBH,DBH,11.385164497 -US-UMd,19292,GRP_DBH,DBH_SPP,Fagus grandifolia -US-UMd,19292,GRP_DBH,DBH_HEIGHT,1.37 -US-UMd,19292,GRP_DBH,DBH_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 22 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm." -US-UMd,19292,GRP_DBH,DBH_DATE,20100714 -US-UMd,19292,GRP_DBH,DBH_DATE_UNC,28 -US-UMd,19292,GRP_DBH,DBH_COMMENT,Average and standard dev. based soley on plots for which the species existed. Total N was 23 plots but not all species were represented in all plots. -US-UMd,19292,GRP_DBH,DBH_SPATIAL_REP_NUMBER,12 -US-UMd,19292,GRP_DBH,DBH_SPATIAL_VARIABILITY,2.2509130011 -US-UMd,19290,GRP_DBH,DBH,12.64 -US-UMd,19290,GRP_DBH,DBH_SPP,other (6 species) -US-UMd,19290,GRP_DBH,DBH_HEIGHT,1.37 -US-UMd,19290,GRP_DBH,DBH_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 22 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm." -US-UMd,19290,GRP_DBH,DBH_DATE,20060714 -US-UMd,19290,GRP_DBH,DBH_DATE_UNC,28 -US-UMd,19290,GRP_DBH,DBH_COMMENT,Average and standard dev. based soley on plots for which the species existed. Total N was 23 plots but not all species were represented in all plots. -US-UMd,19290,GRP_DBH,DBH_SPATIAL_REP_NUMBER,8 -US-UMd,19290,GRP_DBH,DBH_SPATIAL_VARIABILITY,4.77 -US-UMd,19261,GRP_DBH,DBH,12.73 -US-UMd,19261,GRP_DBH,DBH_SPP,other (6 species) -US-UMd,19261,GRP_DBH,DBH_HEIGHT,1.37 -US-UMd,19261,GRP_DBH,DBH_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 22 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm." -US-UMd,19261,GRP_DBH,DBH_DATE,20100714 -US-UMd,19261,GRP_DBH,DBH_DATE_UNC,28 -US-UMd,19261,GRP_DBH,DBH_COMMENT,Average and standard dev. based soley on plots for which the species existed. Total N was 23 plots but not all species were represented in all plots. -US-UMd,19261,GRP_DBH,DBH_SPATIAL_REP_NUMBER,8 -US-UMd,19261,GRP_DBH,DBH_SPATIAL_VARIABILITY,4.78 -US-UMd,19331,GRP_DBH,DBH,13.23 -US-UMd,19331,GRP_DBH,DBH_SPP,Acer saccharum -US-UMd,19331,GRP_DBH,DBH_HEIGHT,1.37 -US-UMd,19331,GRP_DBH,DBH_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 22 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm." -US-UMd,19331,GRP_DBH,DBH_DATE,20060714 -US-UMd,19331,GRP_DBH,DBH_DATE_UNC,28 -US-UMd,19331,GRP_DBH,DBH_COMMENT,Average and standard dev. based soley on plots for which the species existed. Total N was 22 plots but not all species were represented in all plots. -US-UMd,19331,GRP_DBH,DBH_SPATIAL_REP_NUMBER,7 -US-UMd,19331,GRP_DBH,DBH_SPATIAL_VARIABILITY,3.1 -US-UMd,19234,GRP_DBH,DBH,13.804146633 -US-UMd,19234,GRP_DBH,DBH_SPP,Acer saccharum -US-UMd,19234,GRP_DBH,DBH_HEIGHT,1.37 -US-UMd,19234,GRP_DBH,DBH_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 22 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm." -US-UMd,19234,GRP_DBH,DBH_DATE,20100714 -US-UMd,19234,GRP_DBH,DBH_DATE_UNC,28 -US-UMd,19234,GRP_DBH,DBH_COMMENT,Average and standard dev. based soley on plots for which the species existed. Total N was 23 plots but not all species were represented in all plots. -US-UMd,19234,GRP_DBH,DBH_SPATIAL_REP_NUMBER,7 -US-UMd,19234,GRP_DBH,DBH_SPATIAL_VARIABILITY,3.3258785704 -US-UMd,19322,GRP_DBH,DBH,14.69 -US-UMd,19322,GRP_DBH,DBH_SPP,Acer rubrum -US-UMd,19322,GRP_DBH,DBH_HEIGHT,1.37 -US-UMd,19322,GRP_DBH,DBH_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 22 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm." -US-UMd,19322,GRP_DBH,DBH_DATE,20060714 -US-UMd,19322,GRP_DBH,DBH_DATE_UNC,28 -US-UMd,19322,GRP_DBH,DBH_COMMENT,Average and standard dev. based soley on plots for which the species existed. Total N was 22 plots but not all species were represented in all plots. -US-UMd,19322,GRP_DBH,DBH_SPATIAL_REP_NUMBER,23 -US-UMd,19322,GRP_DBH,DBH_SPATIAL_VARIABILITY,3.74 -US-UMd,19228,GRP_DBH,DBH,14.732994077 -US-UMd,19228,GRP_DBH,DBH_SPP,Acer rubrum -US-UMd,19228,GRP_DBH,DBH_HEIGHT,1.37 -US-UMd,19228,GRP_DBH,DBH_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 22 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm." -US-UMd,19228,GRP_DBH,DBH_DATE,20100714 -US-UMd,19228,GRP_DBH,DBH_DATE_UNC,28 -US-UMd,19228,GRP_DBH,DBH_COMMENT,Average and standard dev. based soley on plots for which the species existed. Total N was 23 plots but not all species were represented in all plots. -US-UMd,19228,GRP_DBH,DBH_SPATIAL_REP_NUMBER,23 -US-UMd,19228,GRP_DBH,DBH_SPATIAL_VARIABILITY,3.5870747201 -US-UMd,19216,GRP_DBH,DBH,16.46 -US-UMd,19216,GRP_DBH,DBH_SPP,Pinus strobus -US-UMd,19216,GRP_DBH,DBH_HEIGHT,1.37 -US-UMd,19216,GRP_DBH,DBH_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 22 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm." -US-UMd,19216,GRP_DBH,DBH_DATE,20060714 -US-UMd,19216,GRP_DBH,DBH_DATE_UNC,28 -US-UMd,19216,GRP_DBH,DBH_COMMENT,Average and standard dev. based soley on plots for which the species existed. Total N was 22 plots but not all species were represented in all plots. -US-UMd,19216,GRP_DBH,DBH_SPATIAL_REP_NUMBER,17 -US-UMd,19216,GRP_DBH,DBH_SPATIAL_VARIABILITY,5.01 -US-UMd,19306,GRP_DBH,DBH,17.211006285 -US-UMd,19306,GRP_DBH,DBH_SPP,Pinus strobus -US-UMd,19306,GRP_DBH,DBH_HEIGHT,1.37 -US-UMd,19306,GRP_DBH,DBH_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 22 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm." -US-UMd,19306,GRP_DBH,DBH_DATE,20100714 -US-UMd,19306,GRP_DBH,DBH_DATE_UNC,28 -US-UMd,19306,GRP_DBH,DBH_COMMENT,Average and standard dev. based soley on plots for which the species existed. Total N was 23 plots but not all species were represented in all plots. -US-UMd,19306,GRP_DBH,DBH_SPATIAL_REP_NUMBER,17 -US-UMd,19306,GRP_DBH,DBH_SPATIAL_VARIABILITY,5.4910669398 -US-UMd,19338,GRP_DBH,DBH,20.62 -US-UMd,19338,GRP_DBH,DBH_SPP,Betula papyrifera -US-UMd,19338,GRP_DBH,DBH_HEIGHT,1.37 -US-UMd,19338,GRP_DBH,DBH_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 22 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm." -US-UMd,19338,GRP_DBH,DBH_DATE,20060714 -US-UMd,19338,GRP_DBH,DBH_DATE_UNC,28 -US-UMd,19338,GRP_DBH,DBH_COMMENT,Average and standard dev. based soley on plots for which the species existed. Total N was 22 plots but not all species were represented in all plots. -US-UMd,19338,GRP_DBH,DBH_SPATIAL_REP_NUMBER,15 -US-UMd,19338,GRP_DBH,DBH_SPATIAL_VARIABILITY,5.49 -US-UMd,19240,GRP_DBH,DBH,21.746428571 -US-UMd,19240,GRP_DBH,DBH_SPP,Betula papyrifera -US-UMd,19240,GRP_DBH,DBH_HEIGHT,1.37 -US-UMd,19240,GRP_DBH,DBH_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 22 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm." -US-UMd,19240,GRP_DBH,DBH_DATE,20100714 -US-UMd,19240,GRP_DBH,DBH_DATE_UNC,28 -US-UMd,19240,GRP_DBH,DBH_COMMENT,Average and standard dev. based soley on plots for which the species existed. Total N was 23 plots but not all species were represented in all plots. -US-UMd,19240,GRP_DBH,DBH_SPATIAL_REP_NUMBER,7 -US-UMd,19240,GRP_DBH,DBH_SPATIAL_VARIABILITY,4.9761185629 -US-UMd,19209,GRP_DBH,DBH,23.63 -US-UMd,19209,GRP_DBH,DBH_SPP,Pinus resinosa -US-UMd,19209,GRP_DBH,DBH_HEIGHT,1.37 -US-UMd,19209,GRP_DBH,DBH_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 22 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm." -US-UMd,19209,GRP_DBH,DBH_DATE,20060714 -US-UMd,19209,GRP_DBH,DBH_DATE_UNC,28 -US-UMd,19209,GRP_DBH,DBH_COMMENT,Average and standard dev. based soley on plots for which the species existed. Total N was 22 plots but not all species were represented in all plots. -US-UMd,19209,GRP_DBH,DBH_SPATIAL_REP_NUMBER,10 -US-UMd,19209,GRP_DBH,DBH_SPATIAL_VARIABILITY,8.52 -US-UMd,19299,GRP_DBH,DBH,23.641125296 -US-UMd,19299,GRP_DBH,DBH_SPP,Pinus resinosa -US-UMd,19299,GRP_DBH,DBH_HEIGHT,1.37 -US-UMd,19299,GRP_DBH,DBH_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 22 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm." -US-UMd,19299,GRP_DBH,DBH_DATE,20100714 -US-UMd,19299,GRP_DBH,DBH_DATE_UNC,28 -US-UMd,19299,GRP_DBH,DBH_COMMENT,Average and standard dev. based soley on plots for which the species existed. Total N was 23 plots but not all species were represented in all plots. -US-UMd,19299,GRP_DBH,DBH_SPATIAL_REP_NUMBER,10 -US-UMd,19299,GRP_DBH,DBH_SPATIAL_VARIABILITY,8.3972717492 -US-UMd,19283,GRP_DBH,DBH,23.97 -US-UMd,19283,GRP_DBH,DBH_SPP,Quercus rubra -US-UMd,19283,GRP_DBH,DBH_HEIGHT,1.37 -US-UMd,19283,GRP_DBH,DBH_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 22 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm." -US-UMd,19283,GRP_DBH,DBH_DATE,20060714 -US-UMd,19283,GRP_DBH,DBH_DATE_UNC,28 -US-UMd,19283,GRP_DBH,DBH_COMMENT,Average and standard dev. based soley on plots for which the species existed. Total N was 22 plots but not all species were represented in all plots. -US-UMd,19283,GRP_DBH,DBH_SPATIAL_REP_NUMBER,22 -US-UMd,19283,GRP_DBH,DBH_SPATIAL_VARIABILITY,7.97 -US-UMd,19256,GRP_DBH,DBH,24.085912379 -US-UMd,19256,GRP_DBH,DBH_SPP,Quercus rubra -US-UMd,19256,GRP_DBH,DBH_HEIGHT,1.37 -US-UMd,19256,GRP_DBH,DBH_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 22 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm." -US-UMd,19256,GRP_DBH,DBH_DATE,20100714 -US-UMd,19256,GRP_DBH,DBH_DATE_UNC,28 -US-UMd,19256,GRP_DBH,DBH_COMMENT,Average and standard dev. based soley on plots for which the species existed. Total N was 23 plots but not all species were represented in all plots. -US-UMd,19256,GRP_DBH,DBH_SPATIAL_REP_NUMBER,22 -US-UMd,19256,GRP_DBH,DBH_SPATIAL_VARIABILITY,8.4027514294 -US-UMd,19269,GRP_DBH,DBH,27.05 -US-UMd,19269,GRP_DBH,DBH_SPP,Populus grandidentata -US-UMd,19269,GRP_DBH,DBH_HEIGHT,1.37 -US-UMd,19269,GRP_DBH,DBH_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 22 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm." -US-UMd,19269,GRP_DBH,DBH_DATE,20060714 -US-UMd,19269,GRP_DBH,DBH_DATE_UNC,28 -US-UMd,19269,GRP_DBH,DBH_COMMENT,Average and standard dev. based soley on plots for which the species existed. Total N was 22 plots but not all species were represented in all plots. -US-UMd,19269,GRP_DBH,DBH_SPATIAL_REP_NUMBER,20 -US-UMd,19269,GRP_DBH,DBH_SPATIAL_VARIABILITY,5.16 -US-UMd,19276,GRP_DBH,DBH,28.85 -US-UMd,19276,GRP_DBH,DBH_SPP,Populus tremuloides -US-UMd,19276,GRP_DBH,DBH_HEIGHT,1.37 -US-UMd,19276,GRP_DBH,DBH_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 22 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm." -US-UMd,19276,GRP_DBH,DBH_DATE,19600401 -US-UMd,19276,GRP_DBH,DBH_COMMENT,Average and standard dev. based soley on plots for which the species existed. Total N was 22 plots but not all species were represented in all plots. -US-UMd,19276,GRP_DBH,DBH_SPATIAL_REP_NUMBER,2 -US-UMd,19276,GRP_DBH,DBH_SPATIAL_VARIABILITY,9.27 -US-UMd,19313,GRP_DBH,DBH,30.644639543 -US-UMd,19313,GRP_DBH,DBH_SPP,Populus grandidentata -US-UMd,19313,GRP_DBH,DBH_HEIGHT,1.37 -US-UMd,19313,GRP_DBH,DBH_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 22 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm." -US-UMd,19313,GRP_DBH,DBH_DATE,20100714 -US-UMd,19313,GRP_DBH,DBH_DATE_UNC,28 -US-UMd,19313,GRP_DBH,DBH_COMMENT,Average and standard dev. based soley on plots for which the species existed. Total N was 23 plots but not all species were represented in all plots. -US-UMd,19313,GRP_DBH,DBH_SPATIAL_REP_NUMBER,20 -US-UMd,19313,GRP_DBH,DBH_SPATIAL_VARIABILITY,5.8124725904 -US-UMd,19250,GRP_DBH,DBH,45.1 -US-UMd,19250,GRP_DBH,DBH_SPP,Populus tremuloides -US-UMd,19250,GRP_DBH,DBH_HEIGHT,1.37 -US-UMd,19250,GRP_DBH,DBH_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 22 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm." -US-UMd,19250,GRP_DBH,DBH_DATE,20100714 -US-UMd,19250,GRP_DBH,DBH_DATE_UNC,28 -US-UMd,19250,GRP_DBH,DBH_COMMENT,Average and standard dev. based soley on plots for which the species existed. Total N was 23 plots but not all species were represented in all plots. -US-UMd,19250,GRP_DBH,DBH_SPATIAL_REP_NUMBER,1 -US-UMd,86670,GRP_DM_FIRE,DM_FIRE,Other -US-UMd,86670,GRP_DM_FIRE,DM_SURF,100 -US-UMd,86670,GRP_DM_FIRE,DM_DATE_START,19010701 -US-UMd,86670,GRP_DM_FIRE,DM_DATE_END,19230701 -US-UMd,86670,GRP_DM_FIRE,DM_DATE_UNC,60 -US-UMd,86670,GRP_DM_FIRE,DM_COMMENT,The first recorded fire was the summer of 1901 with unknown causes. Many fires were either human intentionally or unintentionally set as well as possible natural fires. The areas burned varied in in size and intensity depending on conditions and the amount of slash left behind from earlier logging. All of the flux footprint was burned at least once and some if not all of the footprint likely burned several times. The last intense fire was recorded in 1923. -US-UMd,86669,GRP_DM_FORESTRY,DM_FORESTRY,Clearcutting -US-UMd,86669,GRP_DM_FORESTRY,DM_SURF,100 -US-UMd,86669,GRP_DM_FORESTRY,DM_DATE_START,18791201 -US-UMd,86669,GRP_DM_FORESTRY,DM_DATE_END,19000101 -US-UMd,86669,GRP_DM_FORESTRY,DM_DATE_UNC,365 -US-UMd,86669,GRP_DM_FORESTRY,DM_COMMENT,Heavy logging of pine began in in winter of 1879 and completed in 1880. The flux footprint was mainly pine woodlands at the time of logging. Other tree species were progressively logged off through 1900 essentially creating a clearcut area. -US-UMd,86672,GRP_DM_FORESTRY,DM_FORESTRY,Other -US-UMd,86672,GRP_DM_FORESTRY,DM_DATE_START,20080421 -US-UMd,86672,GRP_DM_FORESTRY,DM_DATE_END,20080502 -US-UMd,86672,GRP_DM_FORESTRY,DM_DATE_UNC,0 -US-UMd,86672,GRP_DM_FORESTRY,DM_COMMENT,"All aspen (Populus grandidentata, P. tremuloides) and birch (Betula papyrifera) stem girdled in 33 ha area surrounding flux tower (5614 trees in total). Three separate 2 ha areas had 1109 aspen and birch stem girdled. Birch were essentially all dead by summer 2009. 77% of aspen dead by July 2011." -US-UMd,86668,GRP_DM_INS_PATH,DM_INS_PATH,Insect -US-UMd,86668,GRP_DM_INS_PATH,DM_DATE_START,20100515 -US-UMd,86668,GRP_DM_INS_PATH,DM_DATE_END,20100701 -US-UMd,86668,GRP_DM_INS_PATH,DM_DATE_UNC,10 -US-UMd,86668,GRP_DM_INS_PATH,DM_COMMENT,"Locally patchy, moderate out-break of forest tent caterpillar (Malacosoma disstrium). No attempt to quantify leaf area removed by herbivory." -US-UMd,86671,GRP_DM_INS_PATH,DM_INS_PATH,Pathogen -US-UMd,86671,GRP_DM_INS_PATH,DM_DATE_START,20101010 -US-UMd,86671,GRP_DM_INS_PATH,DM_COMMENT,Beech bark disease first noticed in the fall of 2010 caused by infestation of Fagus grandifolia by the scale insect Cryptococcus fagisuga which leads to the introduction of pathogenic fungi Neonectria faginata and Neonectria ditissima. Some trees within the footprint were dead by 2018. This is an ongoing disease within the US-UMd footprint. -US-UMd,15735,GRP_DOI,DOI,10.17190/AMF/1246134 -US-UMd,15735,GRP_DOI,DOI_CITATION,"Christopher Gough, Gil Bohrer, Peter Curtis (2022), AmeriFlux BASE US-UMd UMBS Disturbance, Ver. 12-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1246134" -US-UMd,15735,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-UMd,32307,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-UMd,32307,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Christopher Gough -US-UMd,32307,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-UMd,32307,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,cmgough@vcu.edu -US-UMd,32307,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Virginia Commonwealth University -US-UMd,32309,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-UMd,32309,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Gil Bohrer -US-UMd,32309,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-UMd,32309,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,bohrer.17@osu.edu -US-UMd,32309,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Ohio State University -US-UMd,32308,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-UMd,32308,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Peter Curtis -US-UMd,32308,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-UMd,32308,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,curtis.7@osu.edu -US-UMd,32308,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Ohio State University -US-UMd,32312,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Ohio State University -US-UMd,32312,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-UMd,32311,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Virginia Commonwealth University -US-UMd,32311,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-UMd,32310,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,DOE/NSF -US-UMd,32310,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-UMd,12362,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Forestry -US-UMd,91418,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-UMd,91418,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-UMd,91418,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,200701 -US-UMd,91418,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-UMd,91354,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-UMd,91354,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-UMd,91354,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,200701 -US-UMd,91354,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-UMd,12363,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-UMd,12363,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-UMd,12363,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,2007 -US-UMd,12363,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-UMd,23000500,GRP_HEADER,SITE_NAME,UMBS Disturbance -US-UMd,88197,GRP_HEIGHTC,HEIGHTC,23 -US-UMd,88197,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-UMd,88197,GRP_HEIGHTC,HEIGHTC_DATE,20150101 -US-UMd,88197,GRP_HEIGHTC,HEIGHTC_COMMENT,Canopy ht estimated from flux tower. No replicates. -US-UMd,12364,GRP_IGBP,IGBP,DBF -US-UMd,92219,GRP_INST,INST_MODEL,RAD-PAR Quantum -US-UMd,92219,GRP_INST,INST_SN,11277 -US-UMd,92219,GRP_INST,INST_DATE,20150814 -US-UMd,92219,GRP_INST,INST_SAMPLING_INT,10 -US-UMd,92219,GRP_INST,INST_AVERAGING_INT,600 -US-UMd,92160,GRP_INST,INST_MODEL,RH-Other -US-UMd,92160,GRP_INST,INST_SN,200220040 -US-UMd,92160,GRP_INST,INST_DATE,20150814 -US-UMd,92160,GRP_INST,INST_SAMPLING_INT,10 -US-UMd,92160,GRP_INST,INST_AVERAGING_INT,600 -US-UMd,92160,GRP_INST,INST_HEAT,Unheated -US-UMd,92160,GRP_INST,INST_SHIELDING,Radiation -US-UMd,92160,GRP_INST,INST_ASPIRATION,Ventilation -US-UMd,92208,GRP_INST,INST_MODEL,TEMP-ElectResis -US-UMd,92208,GRP_INST,INST_SN,200220041 -US-UMd,92208,GRP_INST,INST_DATE,20150814 -US-UMd,92208,GRP_INST,INST_SAMPLING_INT,10 -US-UMd,92208,GRP_INST,INST_AVERAGING_INT,600 -US-UMd,92208,GRP_INST,INST_HEAT,Unheated -US-UMd,92208,GRP_INST,INST_SHIELDING,Radiation -US-UMd,92208,GRP_INST,INST_ASPIRATION,Ventilation -US-UMd,92161,GRP_INST,INST_MODEL,RAD-Pyrrad-SW+LW -US-UMd,92161,GRP_INST,INST_SN,CNR1-061240 -US-UMd,92161,GRP_INST,INST_DATE,20170419 -US-UMd,92161,GRP_INST,INST_SAMPLING_INT,10 -US-UMd,92161,GRP_INST,INST_AVERAGING_INT,600 -US-UMd,92161,GRP_INST,INST_HEAT,Unheated -US-UMd,92161,GRP_INST,INST_SHIELDING,None -US-UMd,92161,GRP_INST,INST_ASPIRATION,None -US-UMd,92167,GRP_INST,INST_MODEL,SA-Campbell CSAT-3 -US-UMd,92167,GRP_INST,INST_SN,CSAT3-0249 -US-UMd,92167,GRP_INST,INST_DATE,20170710 -US-UMd,92167,GRP_INST,INST_SAMPLING_INT,0.1 -US-UMd,92167,GRP_INST,INST_HEAT,Unheated -US-UMd,92167,GRP_INST,INST_SHIELDING,None -US-UMd,92167,GRP_INST,INST_ASPIRATION,None -US-UMd,92167,GRP_INST,INST_SA_OFFSET_NORTH,270 -US-UMd,92167,GRP_INST,INST_SA_WIND_FORMAT,"U, V, W" -US-UMd,92168,GRP_INST,INST_MODEL,SA-Campbell CSAT-3 -US-UMd,92168,GRP_INST,INST_SN,CSAT3-0249 -US-UMd,92168,GRP_INST,INST_DATE,20070521 -US-UMd,92168,GRP_INST,INST_SAMPLING_INT,0.1 -US-UMd,92168,GRP_INST,INST_HEAT,Unheated -US-UMd,92168,GRP_INST,INST_SHIELDING,None -US-UMd,92168,GRP_INST,INST_ASPIRATION,None -US-UMd,92168,GRP_INST,INST_SA_OFFSET_NORTH,270 -US-UMd,92168,GRP_INST,INST_SA_WIND_FORMAT,"U, V, W" -US-UMd,92188,GRP_INST,INST_MODEL,SA-Campbell CSAT-3 -US-UMd,92188,GRP_INST,INST_SN,CSAT3-0249 -US-UMd,92188,GRP_INST,INST_DATE,20141124 -US-UMd,92188,GRP_INST,INST_SAMPLING_INT,0.1 -US-UMd,92188,GRP_INST,INST_HEAT,Unheated -US-UMd,92188,GRP_INST,INST_SHIELDING,None -US-UMd,92188,GRP_INST,INST_ASPIRATION,None -US-UMd,92188,GRP_INST,INST_SA_OFFSET_NORTH,270 -US-UMd,92188,GRP_INST,INST_SA_WIND_FORMAT,"U, V, W" -US-UMd,92181,GRP_INST,INST_MODEL,SA-Campbell CSAT-3 -US-UMd,92181,GRP_INST,INST_SN,CSAT3-0735 -US-UMd,92181,GRP_INST,INST_DATE,20170608 -US-UMd,92181,GRP_INST,INST_SAMPLING_INT,0.1 -US-UMd,92181,GRP_INST,INST_HEAT,Unheated -US-UMd,92181,GRP_INST,INST_SHIELDING,None -US-UMd,92181,GRP_INST,INST_ASPIRATION,None -US-UMd,92181,GRP_INST,INST_SA_OFFSET_NORTH,270 -US-UMd,92181,GRP_INST,INST_SA_WIND_FORMAT,"U, V, W" -US-UMd,92157,GRP_INST,INST_MODEL,SA-Campbell CSAT-3 -US-UMd,92157,GRP_INST,INST_SN,CSAT3-1712 -US-UMd,92157,GRP_INST,INST_DATE,20141015 -US-UMd,92157,GRP_INST,INST_SAMPLING_INT,0.1 -US-UMd,92157,GRP_INST,INST_HEAT,Unheated -US-UMd,92157,GRP_INST,INST_SHIELDING,None -US-UMd,92157,GRP_INST,INST_ASPIRATION,None -US-UMd,92157,GRP_INST,INST_SA_OFFSET_NORTH,270 -US-UMd,92157,GRP_INST,INST_SA_WIND_FORMAT,"U, V, W" -US-UMd,92223,GRP_INST,INST_MODEL,GA_CP-LI-COR LI-6262 -US-UMd,92223,GRP_INST,INST_SN,IRG3-937 -US-UMd,92223,GRP_INST,INST_DATE,20070521 -US-UMd,92223,GRP_INST,INST_SAMPLING_INT,0.1 -US-UMd,92223,GRP_INST,INST_HEAT,Heated -US-UMd,92223,GRP_INST,INST_SHIELDING,None -US-UMd,92223,GRP_INST,INST_ASPIRATION,Ventilation -US-UMd,92223,GRP_INST,INST_GA_CP_FILTERS,2 filters pore size 1 µm -US-UMd,92223,GRP_INST,INST_GA_CP_TUBE_LENGTH,41.5 -US-UMd,92223,GRP_INST,INST_GA_CP_TUBE_IN_DIAM,4.7625 -US-UMd,92223,GRP_INST,INST_GA_CP_TUBE_MAT,Other -US-UMd,92223,GRP_INST,INST_GA_CP_TUBE_THERM,None -US-UMd,92223,GRP_INST,INST_GA_CP_FLOW_RATE,9 -US-UMd,92223,GRP_INST,INST_GA_CP_MFC,No -US-UMd,92152,GRP_INST,INST_MODEL,GA_CP-LI-COR LI-7000 -US-UMd,92152,GRP_INST,INST_SN,IRG4-1036 -US-UMd,92152,GRP_INST,INST_DATE,20120406 -US-UMd,92152,GRP_INST,INST_SAMPLING_INT,0.1 -US-UMd,92152,GRP_INST,INST_HEAT,Heated -US-UMd,92152,GRP_INST,INST_SHIELDING,None -US-UMd,92152,GRP_INST,INST_ASPIRATION,Ventilation -US-UMd,92152,GRP_INST,INST_GA_CP_FILTERS,2 filters pore size 1 µm -US-UMd,92152,GRP_INST,INST_GA_CP_TUBE_LENGTH,41.5 -US-UMd,92152,GRP_INST,INST_GA_CP_TUBE_IN_DIAM,4.7625 -US-UMd,92152,GRP_INST,INST_GA_CP_TUBE_MAT,Other -US-UMd,92152,GRP_INST,INST_GA_CP_TUBE_THERM,None -US-UMd,92152,GRP_INST,INST_GA_CP_FLOW_RATE,9 -US-UMd,92152,GRP_INST,INST_GA_CP_MFC,No -US-UMd,92193,GRP_INST,INST_MODEL,GA_CP-LI-COR LI-7000 -US-UMd,92193,GRP_INST,INST_SN,IRG4-1036 -US-UMd,92193,GRP_INST,INST_DATE,20181228 -US-UMd,92193,GRP_INST,INST_SAMPLING_INT,0.1 -US-UMd,92193,GRP_INST,INST_HEAT,Heated -US-UMd,92193,GRP_INST,INST_SHIELDING,None -US-UMd,92193,GRP_INST,INST_ASPIRATION,Ventilation -US-UMd,92193,GRP_INST,INST_GA_CP_FILTERS,2 filters pore size 1 µm -US-UMd,92193,GRP_INST,INST_GA_CP_TUBE_LENGTH,41.5 -US-UMd,92193,GRP_INST,INST_GA_CP_TUBE_IN_DIAM,4.7625 -US-UMd,92193,GRP_INST,INST_GA_CP_TUBE_MAT,Other -US-UMd,92193,GRP_INST,INST_GA_CP_TUBE_THERM,None -US-UMd,92193,GRP_INST,INST_GA_CP_FLOW_RATE,9 -US-UMd,92193,GRP_INST,INST_GA_CP_MFC,No -US-UMd,92199,GRP_INST,INST_MODEL,GA_CP-LI-COR LI-7000 -US-UMd,92199,GRP_INST,INST_SN,IRG4-403 -US-UMd,92199,GRP_INST,INST_DATE,20150420 -US-UMd,92199,GRP_INST,INST_SAMPLING_INT,0.1 -US-UMd,92199,GRP_INST,INST_HEAT,Heated -US-UMd,92199,GRP_INST,INST_SHIELDING,None -US-UMd,92199,GRP_INST,INST_ASPIRATION,Ventilation -US-UMd,92199,GRP_INST,INST_GA_CP_FILTERS,2 filters pore size 1 µm -US-UMd,92199,GRP_INST,INST_GA_CP_TUBE_LENGTH,41.5 -US-UMd,92199,GRP_INST,INST_GA_CP_TUBE_IN_DIAM,4.7625 -US-UMd,92199,GRP_INST,INST_GA_CP_TUBE_MAT,Other -US-UMd,92199,GRP_INST,INST_GA_CP_TUBE_THERM,None -US-UMd,92199,GRP_INST,INST_GA_CP_FLOW_RATE,9 -US-UMd,92199,GRP_INST,INST_GA_CP_MFC,No -US-UMd,92225,GRP_INST,INST_MODEL,RAD-Other -US-UMd,92225,GRP_INST,INST_SN,NR-LITE-1 -US-UMd,92225,GRP_INST,INST_DATE,20070521 -US-UMd,92225,GRP_INST,INST_SAMPLING_INT,10 -US-UMd,92225,GRP_INST,INST_AVERAGING_INT,600 -US-UMd,92225,GRP_INST,INST_HEAT,Unheated -US-UMd,92225,GRP_INST,INST_SHIELDING,None -US-UMd,92225,GRP_INST,INST_ASPIRATION,None -US-UMd,92226,GRP_INST,INST_MODEL,RAD-Pyrrad-SW+LW -US-UMd,92226,GRP_INST,INST_SN,NR01-1 -US-UMd,92226,GRP_INST,INST_DATE,20100630 -US-UMd,92226,GRP_INST,INST_SAMPLING_INT,10 -US-UMd,92226,GRP_INST,INST_AVERAGING_INT,600 -US-UMd,92226,GRP_INST,INST_HEAT,Unheated -US-UMd,92226,GRP_INST,INST_SHIELDING,None -US-UMd,92226,GRP_INST,INST_ASPIRATION,None -US-UMd,92159,GRP_INST,INST_MODEL,RAD-Pyrrad-SW+LW -US-UMd,92159,GRP_INST,INST_SN,NR01-1592 -US-UMd,92159,GRP_INST,INST_DATE,20120726 -US-UMd,92159,GRP_INST,INST_SAMPLING_INT,10 -US-UMd,92159,GRP_INST,INST_AVERAGING_INT,600 -US-UMd,92159,GRP_INST,INST_HEAT,Unheated -US-UMd,92159,GRP_INST,INST_SHIELDING,None -US-UMd,92159,GRP_INST,INST_ASPIRATION,None -US-UMd,92174,GRP_INST,INST_MODEL,RAD-Pyrrad-SW+LW -US-UMd,92174,GRP_INST,INST_SN,NR01-1592 -US-UMd,92174,GRP_INST,INST_DATE,20170606 -US-UMd,92174,GRP_INST,INST_SAMPLING_INT,10 -US-UMd,92174,GRP_INST,INST_AVERAGING_INT,600 -US-UMd,92174,GRP_INST,INST_HEAT,Unheated -US-UMd,92174,GRP_INST,INST_SHIELDING,None -US-UMd,92174,GRP_INST,INST_ASPIRATION,None -US-UMd,92171,GRP_INST,INST_MODEL,RAD-PAR Quantum -US-UMd,92171,GRP_INST,INST_SN,PAR 4 -US-UMd,92171,GRP_INST,INST_DATE,20180508 -US-UMd,92171,GRP_INST,INST_SAMPLING_INT,10 -US-UMd,92171,GRP_INST,INST_AVERAGING_INT,600 -US-UMd,92171,GRP_INST,INST_HEAT,Unheated -US-UMd,92171,GRP_INST,INST_SHIELDING,None -US-UMd,92171,GRP_INST,INST_ASPIRATION,None -US-UMd,92172,GRP_INST,INST_MODEL,RAD-PAR Quantum -US-UMd,92172,GRP_INST,INST_SN,PAR1 -US-UMd,92172,GRP_INST,INST_DATE,20070521 -US-UMd,92172,GRP_INST,INST_SAMPLING_INT,10 -US-UMd,92172,GRP_INST,INST_AVERAGING_INT,600 -US-UMd,92172,GRP_INST,INST_HEAT,Unheated -US-UMd,92172,GRP_INST,INST_SHIELDING,None -US-UMd,92172,GRP_INST,INST_ASPIRATION,None -US-UMd,92220,GRP_INST,INST_MODEL,RAD-PAR Quantum -US-UMd,92220,GRP_INST,INST_SN,PAR2 -US-UMd,92220,GRP_INST,INST_DATE,20100730 -US-UMd,92220,GRP_INST,INST_SAMPLING_INT,10 -US-UMd,92220,GRP_INST,INST_AVERAGING_INT,600 -US-UMd,92220,GRP_INST,INST_HEAT,Unheated -US-UMd,92220,GRP_INST,INST_SHIELDING,None -US-UMd,92220,GRP_INST,INST_ASPIRATION,None -US-UMd,92180,GRP_INST,INST_MODEL,RAD-PAR Quantum -US-UMd,92180,GRP_INST,INST_SN,PAR3 -US-UMd,92180,GRP_INST,INST_DATE,20120525 -US-UMd,92180,GRP_INST,INST_SAMPLING_INT,10 -US-UMd,92180,GRP_INST,INST_AVERAGING_INT,600 -US-UMd,92180,GRP_INST,INST_HEAT,Unheated -US-UMd,92180,GRP_INST,INST_SHIELDING,None -US-UMd,92180,GRP_INST,INST_ASPIRATION,None -US-UMd,92191,GRP_INST,INST_MODEL,RAD-SW Pyran Class2 -US-UMd,92191,GRP_INST,INST_SN,PYRAN1 -US-UMd,92191,GRP_INST,INST_DATE,20070521 -US-UMd,92191,GRP_INST,INST_SAMPLING_INT,10 -US-UMd,92191,GRP_INST,INST_AVERAGING_INT,600 -US-UMd,92191,GRP_INST,INST_HEAT,Unheated -US-UMd,92191,GRP_INST,INST_SHIELDING,None -US-UMd,92191,GRP_INST,INST_ASPIRATION,None -US-UMd,92194,GRP_INST,INST_MODEL,RH-Other -US-UMd,92194,GRP_INST,INST_SN,RH1 -US-UMd,92194,GRP_INST,INST_DATE,20070521 -US-UMd,92194,GRP_INST,INST_SAMPLING_INT,10 -US-UMd,92194,GRP_INST,INST_AVERAGING_INT,600 -US-UMd,92194,GRP_INST,INST_HEAT,Unheated -US-UMd,92194,GRP_INST,INST_SHIELDING,Radiation -US-UMd,92194,GRP_INST,INST_ASPIRATION,Ventilation -US-UMd,92216,GRP_INST,INST_MODEL,RH-Other -US-UMd,92216,GRP_INST,INST_SN,RH8 -US-UMd,92216,GRP_INST,INST_DATE,20161130 -US-UMd,92216,GRP_INST,INST_SAMPLING_INT,5 -US-UMd,92216,GRP_INST,INST_AVERAGING_INT,600 -US-UMd,92216,GRP_INST,INST_HEAT,Unheated -US-UMd,92216,GRP_INST,INST_SHIELDING,Radiation -US-UMd,92216,GRP_INST,INST_ASPIRATION,Ventilation -US-UMd,92224,GRP_INST,INST_MODEL,RH-Other -US-UMd,92224,GRP_INST,INST_SN,RH9 -US-UMd,92224,GRP_INST,INST_DATE,20161130 -US-UMd,92224,GRP_INST,INST_SAMPLING_INT,5 -US-UMd,92224,GRP_INST,INST_AVERAGING_INT,60 -US-UMd,92224,GRP_INST,INST_HEAT,Unheated -US-UMd,92224,GRP_INST,INST_SHIELDING,Radiation -US-UMd,92224,GRP_INST,INST_ASPIRATION,Ventilation -US-UMd,92207,GRP_INST,INST_MODEL,TEMP-Other -US-UMd,92207,GRP_INST,INST_SN,SWC_FAS_1 -US-UMd,92207,GRP_INST,INST_DATE,20090415 -US-UMd,92207,GRP_INST,INST_SAMPLING_INT,600 -US-UMd,92207,GRP_INST,INST_AVERAGING_INT,1800 -US-UMd,92207,GRP_INST,INST_HEAT,Unheated -US-UMd,92207,GRP_INST,INST_SHIELDING,None -US-UMd,92207,GRP_INST,INST_ASPIRATION,None -US-UMd,92212,GRP_INST,INST_MODEL,SWC-Other -US-UMd,92212,GRP_INST,INST_SN,SWC_FAS_1 -US-UMd,92212,GRP_INST,INST_DATE,20090415 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-US-UMd,92158,GRP_INST,INST_SHIELDING,None -US-UMd,92158,GRP_INST,INST_ASPIRATION,None -US-UMd,92211,GRP_INST,INST_MODEL,SWC-Other -US-UMd,92211,GRP_INST,INST_SN,SWC_FOS_5 -US-UMd,92211,GRP_INST,INST_DATE,20090415 -US-UMd,92211,GRP_INST,INST_SAMPLING_INT,600 -US-UMd,92211,GRP_INST,INST_AVERAGING_INT,1800 -US-UMd,92211,GRP_INST,INST_HEAT,Unheated -US-UMd,92211,GRP_INST,INST_SHIELDING,None -US-UMd,92211,GRP_INST,INST_ASPIRATION,None -US-UMd,92175,GRP_INST,INST_MODEL,TEMP-Other -US-UMd,92175,GRP_INST,INST_SN,SWC_FOS_6 -US-UMd,92175,GRP_INST,INST_DATE,20090415 -US-UMd,92175,GRP_INST,INST_SAMPLING_INT,600 -US-UMd,92175,GRP_INST,INST_AVERAGING_INT,1800 -US-UMd,92175,GRP_INST,INST_HEAT,Unheated -US-UMd,92175,GRP_INST,INST_SHIELDING,None -US-UMd,92175,GRP_INST,INST_ASPIRATION,None -US-UMd,92187,GRP_INST,INST_MODEL,SWC-Other -US-UMd,92187,GRP_INST,INST_SN,SWC_FOS_6 -US-UMd,92187,GRP_INST,INST_DATE,20090415 -US-UMd,92187,GRP_INST,INST_SAMPLING_INT,600 -US-UMd,92187,GRP_INST,INST_AVERAGING_INT,1800 -US-UMd,92187,GRP_INST,INST_HEAT,Unheated -US-UMd,92187,GRP_INST,INST_SHIELDING,None -US-UMd,92187,GRP_INST,INST_ASPIRATION,None -US-UMd,92176,GRP_INST,INST_MODEL,TEMP-Other -US-UMd,92176,GRP_INST,INST_SN,SWC_FOS_7 -US-UMd,92176,GRP_INST,INST_DATE,20090415 -US-UMd,92176,GRP_INST,INST_SAMPLING_INT,600 -US-UMd,92176,GRP_INST,INST_AVERAGING_INT,1800 -US-UMd,92176,GRP_INST,INST_HEAT,Unheated -US-UMd,92176,GRP_INST,INST_SHIELDING,None -US-UMd,92176,GRP_INST,INST_ASPIRATION,None -US-UMd,92213,GRP_INST,INST_MODEL,SWC-Other -US-UMd,92213,GRP_INST,INST_SN,SWC_FOS_7 -US-UMd,92213,GRP_INST,INST_DATE,20090415 -US-UMd,92213,GRP_INST,INST_SAMPLING_INT,600 -US-UMd,92213,GRP_INST,INST_AVERAGING_INT,1800 -US-UMd,92213,GRP_INST,INST_HEAT,Unheated -US-UMd,92213,GRP_INST,INST_SHIELDING,None -US-UMd,92213,GRP_INST,INST_ASPIRATION,None -US-UMd,92177,GRP_INST,INST_MODEL,SWC-Other -US-UMd,92177,GRP_INST,INST_SN,SWC_FOS_8 -US-UMd,92177,GRP_INST,INST_DATE,20090415 -US-UMd,92177,GRP_INST,INST_SAMPLING_INT,600 -US-UMd,92177,GRP_INST,INST_AVERAGING_INT,1800 -US-UMd,92177,GRP_INST,INST_HEAT,Unheated -US-UMd,92177,GRP_INST,INST_SHIELDING,None -US-UMd,92177,GRP_INST,INST_ASPIRATION,None -US-UMd,92222,GRP_INST,INST_MODEL,TEMP-Other -US-UMd,92222,GRP_INST,INST_SN,SWC_FOS_8 -US-UMd,92222,GRP_INST,INST_DATE,20090415 -US-UMd,92222,GRP_INST,INST_SAMPLING_INT,600 -US-UMd,92222,GRP_INST,INST_AVERAGING_INT,1800 -US-UMd,92222,GRP_INST,INST_HEAT,Unheated -US-UMd,92222,GRP_INST,INST_SHIELDING,None -US-UMd,92222,GRP_INST,INST_ASPIRATION,None -US-UMd,92202,GRP_INST,INST_MODEL,TEMP-Other -US-UMd,92202,GRP_INST,INST_SN,SWC_FOS_9 -US-UMd,92202,GRP_INST,INST_DATE,20090415 -US-UMd,92202,GRP_INST,INST_SAMPLING_INT,600 -US-UMd,92202,GRP_INST,INST_AVERAGING_INT,1800 -US-UMd,92202,GRP_INST,INST_HEAT,Unheated -US-UMd,92202,GRP_INST,INST_SHIELDING,None -US-UMd,92202,GRP_INST,INST_ASPIRATION,None -US-UMd,92217,GRP_INST,INST_MODEL,SWC-Other -US-UMd,92217,GRP_INST,INST_SN,SWC_FOS_9 -US-UMd,92217,GRP_INST,INST_DATE,20090415 -US-UMd,92217,GRP_INST,INST_SAMPLING_INT,600 -US-UMd,92217,GRP_INST,INST_AVERAGING_INT,1800 -US-UMd,92217,GRP_INST,INST_HEAT,Unheated -US-UMd,92217,GRP_INST,INST_SHIELDING,None -US-UMd,92217,GRP_INST,INST_ASPIRATION,None -US-UMd,92196,GRP_INST,INST_MODEL,TEMP-ElectResis -US-UMd,92196,GRP_INST,INST_SN,TEMP1 -US-UMd,92196,GRP_INST,INST_DATE,20070521 -US-UMd,92196,GRP_INST,INST_SAMPLING_INT,10 -US-UMd,92196,GRP_INST,INST_AVERAGING_INT,600 -US-UMd,92196,GRP_INST,INST_HEAT,Unheated -US-UMd,92196,GRP_INST,INST_SHIELDING,Radiation -US-UMd,92196,GRP_INST,INST_ASPIRATION,Ventilation -US-UMd,92201,GRP_INST,INST_MODEL,TEMP-TCouple -US-UMd,92201,GRP_INST,INST_SN,TEMP7 -US-UMd,92201,GRP_INST,INST_DATE,20121004 -US-UMd,92201,GRP_INST,INST_SAMPLING_INT,60 -US-UMd,92201,GRP_INST,INST_AVERAGING_INT,1800 -US-UMd,92201,GRP_INST,INST_HEAT,Unheated -US-UMd,92201,GRP_INST,INST_SHIELDING,None -US-UMd,92201,GRP_INST,INST_ASPIRATION,None -US-UMd,92215,GRP_INST,INST_MODEL,TEMP-Other -US-UMd,92215,GRP_INST,INST_SN,TEMP8 -US-UMd,92215,GRP_INST,INST_DATE,20161130 -US-UMd,92215,GRP_INST,INST_SAMPLING_INT,5 -US-UMd,92215,GRP_INST,INST_AVERAGING_INT,600 -US-UMd,92215,GRP_INST,INST_HEAT,Unheated -US-UMd,92215,GRP_INST,INST_SHIELDING,Radiation -US-UMd,92215,GRP_INST,INST_ASPIRATION,Ventilation -US-UMd,92179,GRP_INST,INST_MODEL,TEMP-Other -US-UMd,92179,GRP_INST,INST_SN,TEMP9 -US-UMd,92179,GRP_INST,INST_DATE,20161130 -US-UMd,92179,GRP_INST,INST_SAMPLING_INT,5 -US-UMd,92179,GRP_INST,INST_AVERAGING_INT,60 -US-UMd,92179,GRP_INST,INST_HEAT,Unheated -US-UMd,92179,GRP_INST,INST_SHIELDING,Radiation -US-UMd,92179,GRP_INST,INST_ASPIRATION,Ventilation -US-UMd,92182,GRP_INST,INST_MODEL,PREC-OpticGauge -US-UMd,92182,GRP_INST,INST_SN,THIES1 -US-UMd,92182,GRP_INST,INST_DATE,20100722 -US-UMd,92182,GRP_INST,INST_AVERAGING_INT,600 -US-UMd,92182,GRP_INST,INST_HEAT,Unheated -US-UMd,92182,GRP_INST,INST_SHIELDING,None -US-UMd,92182,GRP_INST,INST_ASPIRATION,None -US-UMd,92218,GRP_INST,INST_MODEL,PREC-TipBucGauge -US-UMd,92218,GRP_INST,INST_SN,TIP1 -US-UMd,92218,GRP_INST,INST_DATE,20100722 -US-UMd,92218,GRP_INST,INST_AVERAGING_INT,600 -US-UMd,92218,GRP_INST,INST_HEAT,Unheated -US-UMd,92218,GRP_INST,INST_SHIELDING,None -US-UMd,92218,GRP_INST,INST_ASPIRATION,None -US-UMd,92156,GRP_INST,INST_MODEL,WIND-CupAn -US-UMd,92156,GRP_INST,INST_SN,WIND1 -US-UMd,92156,GRP_INST,INST_DATE,20090729 -US-UMd,92156,GRP_INST,INST_SAMPLING_INT,0.1 -US-UMd,92156,GRP_INST,INST_AVERAGING_INT,600 -US-UMd,92156,GRP_INST,INST_HEAT,Unheated -US-UMd,92156,GRP_INST,INST_SHIELDING,None -US-UMd,92156,GRP_INST,INST_ASPIRATION,None -US-UMd,19151,GRP_LAI,LAI_TYPE,LAI -US-UMd,19152,GRP_LAI,LAI_TYPE,LAI -US-UMd,19153,GRP_LAI,LAI_TYPE,LAI -US-UMd,19154,GRP_LAI,LAI_TYPE,LAI -US-UMd,19155,GRP_LAI,LAI_TYPE,LAI -US-UMd,19156,GRP_LAI,LAI_TYPE,LAI -US-UMd,19157,GRP_LAI,LAI_TYPE,LAI -US-UMd,19158,GRP_LAI,LAI_TYPE,LAI -US-UMd,19159,GRP_LAI,LAI_TYPE,LAI -US-UMd,19160,GRP_LAI,LAI_TYPE,LAI -US-UMd,19161,GRP_LAI,LAI_TYPE,LAI -US-UMd,19162,GRP_LAI,LAI_TYPE,LAI -US-UMd,19163,GRP_LAI,LAI_TYPE,LAI -US-UMd,19164,GRP_LAI,LAI_TYPE,LAI -US-UMd,19165,GRP_LAI,LAI_TYPE,LAI -US-UMd,19166,GRP_LAI,LAI_TYPE,LAI -US-UMd,19167,GRP_LAI,LAI_TYPE,LAI -US-UMd,19168,GRP_LAI,LAI_TYPE,LAI -US-UMd,19169,GRP_LAI,LAI_TYPE,LAI -US-UMd,19170,GRP_LAI,LAI_TYPE,LAI -US-UMd,19171,GRP_LAI,LAI_TYPE,LAI -US-UMd,19172,GRP_LAI,LAI_TYPE,LAI -US-UMd,19173,GRP_LAI,LAI_TYPE,LAI -US-UMd,19174,GRP_LAI,LAI_TYPE,LAI -US-UMd,19175,GRP_LAI,LAI_TYPE,LAI -US-UMd,19176,GRP_LAI,LAI_TYPE,LAI -US-UMd,19177,GRP_LAI,LAI_TYPE,LAI -US-UMd,19178,GRP_LAI,LAI_TYPE,LAI -US-UMd,19179,GRP_LAI,LAI_TYPE,LAI -US-UMd,19180,GRP_LAI,LAI_TYPE,LAI -US-UMd,19181,GRP_LAI,LAI_TYPE,LAI -US-UMd,19182,GRP_LAI,LAI_TYPE,LAI -US-UMd,19183,GRP_LAI,LAI_TYPE,LAI -US-UMd,19184,GRP_LAI,LAI_TYPE,LAI -US-UMd,19185,GRP_LAI,LAI_TYPE,LAI -US-UMd,19186,GRP_LAI,LAI_TYPE,LAI -US-UMd,19187,GRP_LAI,LAI_TYPE,LAI -US-UMd,19188,GRP_LAI,LAI_TYPE,LAI -US-UMd,19189,GRP_LAI,LAI_TYPE,LAI -US-UMd,19190,GRP_LAI,LAI_TYPE,LAI -US-UMd,19191,GRP_LAI,LAI_TYPE,LAI -US-UMd,19192,GRP_LAI,LAI_TYPE,LAI -US-UMd,19193,GRP_LAI,LAI_TYPE,LAI -US-UMd,19194,GRP_LAI,LAI_TYPE,LAI -US-UMd,19195,GRP_LAI,LAI_TYPE,LAI -US-UMd,19196,GRP_LAI,LAI_TYPE,LAI -US-UMd,19197,GRP_LAI,LAI_TYPE,LAI -US-UMd,19198,GRP_LAI,LAI_TYPE,LAI -US-UMd,19203,GRP_LAI,LAI_TYPE,LAI -US-UMd,19210,GRP_LAI,LAI_TYPE,LAI -US-UMd,19217,GRP_LAI,LAI_TYPE,LAI -US-UMd,19222,GRP_LAI,LAI_TYPE,LAI -US-UMd,19229,GRP_LAI,LAI_TYPE,LAI -US-UMd,19235,GRP_LAI,LAI_TYPE,LAI -US-UMd,19241,GRP_LAI,LAI_TYPE,LAI -US-UMd,19270,GRP_LAI,LAI_TYPE,LAI -US-UMd,19277,GRP_LAI,LAI_TYPE,LAI -US-UMd,19284,GRP_LAI,LAI_TYPE,LAI -US-UMd,19293,GRP_LAI,LAI_TYPE,LAI -US-UMd,19300,GRP_LAI,LAI_TYPE,LAI -US-UMd,19307,GRP_LAI,LAI_TYPE,LAI -US-UMd,19319,GRP_LAI,LAI_TYPE,LAI -US-UMd,19320,GRP_LAI,LAI_TYPE,LAI -US-UMd,19324,GRP_LAI,LAI_TYPE,LAI -US-UMd,19332,GRP_LAI,LAI_TYPE,LAI -US-UMd,19339,GRP_LAI,LAI_TYPE,LAI -US-UMd,19222,GRP_LAI,LAI_METHOD,Litterfall -US-UMd,19229,GRP_LAI,LAI_METHOD,Litterfall -US-UMd,19235,GRP_LAI,LAI_METHOD,Litterfall -US-UMd,19241,GRP_LAI,LAI_METHOD,Litterfall -US-UMd,19284,GRP_LAI,LAI_METHOD,Litterfall -US-UMd,19293,GRP_LAI,LAI_METHOD,Litterfall -US-UMd,19300,GRP_LAI,LAI_METHOD,Litterfall -US-UMd,19307,GRP_LAI,LAI_METHOD,Litterfall -US-UMd,19151,GRP_LAI,LAI_APPROACH,LAI_2000 -US-UMd,19152,GRP_LAI,LAI_APPROACH,LAI_2000 -US-UMd,19153,GRP_LAI,LAI_APPROACH,LAI_2000 -US-UMd,19155,GRP_LAI,LAI_APPROACH,LAI_2000 -US-UMd,19156,GRP_LAI,LAI_APPROACH,LAI_2000 -US-UMd,19157,GRP_LAI,LAI_APPROACH,LAI_2000 -US-UMd,19158,GRP_LAI,LAI_APPROACH,LAI_2000 -US-UMd,19159,GRP_LAI,LAI_APPROACH,LAI_2000 -US-UMd,19160,GRP_LAI,LAI_APPROACH,LAI_2000 -US-UMd,19161,GRP_LAI,LAI_APPROACH,LAI_2000 -US-UMd,19162,GRP_LAI,LAI_APPROACH,LAI_2000 -US-UMd,19164,GRP_LAI,LAI_APPROACH,LAI_2000 -US-UMd,19165,GRP_LAI,LAI_APPROACH,LAI_2000 -US-UMd,19166,GRP_LAI,LAI_APPROACH,LAI_2000 -US-UMd,19167,GRP_LAI,LAI_APPROACH,LAI_2000 -US-UMd,19168,GRP_LAI,LAI_APPROACH,LAI_2000 -US-UMd,19169,GRP_LAI,LAI_APPROACH,LAI_2000 -US-UMd,19171,GRP_LAI,LAI_APPROACH,LAI_2000 -US-UMd,19172,GRP_LAI,LAI_APPROACH,LAI_2000 -US-UMd,19173,GRP_LAI,LAI_APPROACH,LAI_2000 -US-UMd,19174,GRP_LAI,LAI_APPROACH,LAI_2000 -US-UMd,19175,GRP_LAI,LAI_APPROACH,LAI_2000 -US-UMd,19176,GRP_LAI,LAI_APPROACH,LAI_2000 -US-UMd,19177,GRP_LAI,LAI_APPROACH,LAI_2000 -US-UMd,19178,GRP_LAI,LAI_APPROACH,LAI_2000 -US-UMd,19179,GRP_LAI,LAI_APPROACH,LAI_2000 -US-UMd,19180,GRP_LAI,LAI_APPROACH,LAI_2000 -US-UMd,19182,GRP_LAI,LAI_APPROACH,LAI_2000 -US-UMd,19183,GRP_LAI,LAI_APPROACH,LAI_2000 -US-UMd,19184,GRP_LAI,LAI_APPROACH,LAI_2000 -US-UMd,19185,GRP_LAI,LAI_APPROACH,LAI_2000 -US-UMd,19186,GRP_LAI,LAI_APPROACH,LAI_2000 -US-UMd,19187,GRP_LAI,LAI_APPROACH,LAI_2000 -US-UMd,19189,GRP_LAI,LAI_APPROACH,LAI_2000 -US-UMd,19190,GRP_LAI,LAI_APPROACH,LAI_2000 -US-UMd,19191,GRP_LAI,LAI_APPROACH,LAI_2000 -US-UMd,19192,GRP_LAI,LAI_APPROACH,LAI_2000 -US-UMd,19193,GRP_LAI,LAI_APPROACH,LAI_2000 -US-UMd,19195,GRP_LAI,LAI_APPROACH,LAI_2000 -US-UMd,19196,GRP_LAI,LAI_APPROACH,LAI_2000 -US-UMd,19197,GRP_LAI,LAI_APPROACH,LAI_2000 -US-UMd,19198,GRP_LAI,LAI_APPROACH,LAI_2000 -US-UMd,19154,GRP_LAI,LAI_APPROACH,Litter trap -US-UMd,19163,GRP_LAI,LAI_APPROACH,Litter trap -US-UMd,19170,GRP_LAI,LAI_APPROACH,Litter trap -US-UMd,19181,GRP_LAI,LAI_APPROACH,Litter trap -US-UMd,19188,GRP_LAI,LAI_APPROACH,Litter trap -US-UMd,19194,GRP_LAI,LAI_APPROACH,Litter trap -US-UMd,19203,GRP_LAI,LAI_APPROACH,Litter trap -US-UMd,19210,GRP_LAI,LAI_APPROACH,Litter trap -US-UMd,19217,GRP_LAI,LAI_APPROACH,Litter trap -US-UMd,19270,GRP_LAI,LAI_APPROACH,Litter trap -US-UMd,19277,GRP_LAI,LAI_APPROACH,Litter trap -US-UMd,19319,GRP_LAI,LAI_APPROACH,Litter trap -US-UMd,19320,GRP_LAI,LAI_APPROACH,Litter trap -US-UMd,19324,GRP_LAI,LAI_APPROACH,Litter trap -US-UMd,19332,GRP_LAI,LAI_APPROACH,Litter trap -US-UMd,19339,GRP_LAI,LAI_APPROACH,Litter trap -US-UMd,19222,GRP_LAI,LAI_APPROACH,"Litter traps, 1 - 3 each in 21 - 0.08 ha plots and 20 in a single 1.13 ha plot, at 1 m ht above forest floor and with an effective area of .264 m^2 each were used to collect autumnal litter fall." -US-UMd,19284,GRP_LAI,LAI_APPROACH,"Litter traps, 1 - 3 each in 21 - 0.08 ha plots and 20 in a single 1.13 ha plot, at 1 m ht above forest floor and with an effective area of .264 m^2 each were used to collect autumnal litter fall." -US-UMd,19229,GRP_LAI,LAI_APPROACH,"Three litter traps in each of 11 - 0.08 ha plots and 20 traps in a single 1.13 ha plot, at 1 m ht above forest floor and with an effective area of .264 m^2 each were used to collect autumnal litter fall." -US-UMd,19235,GRP_LAI,LAI_APPROACH,"Three litter traps in each of 11 - 0.08 ha plots and 20 traps in a single 1.13 ha plot, at 1 m ht above forest floor and with an effective area of .264 m^2 each were used to collect autumnal litter fall." -US-UMd,19241,GRP_LAI,LAI_APPROACH,"Three litter traps in each of 11 - 0.08 ha plots and 20 traps in a single 1.13 ha plot, at 1 m ht above forest floor and with an effective area of .264 m^2 each were used to collect autumnal litter fall." -US-UMd,19293,GRP_LAI,LAI_APPROACH,"Three litter traps in each of 11 - 0.08 ha plots and 20 traps in a single 1.13 ha plot, at 1 m ht above forest floor and with an effective area of .264 m^2 each were used to collect autumnal litter fall." -US-UMd,19300,GRP_LAI,LAI_APPROACH,"Three litter traps in each of 11 - 0.08 ha plots and 20 traps in a single 1.13 ha plot, at 1 m ht above forest floor and with an effective area of .264 m^2 each were used to collect autumnal litter fall." -US-UMd,19307,GRP_LAI,LAI_APPROACH,"Three litter traps in each of 11 - 0.08 ha plots and 20 traps in a single 1.13 ha plot, at 1 m ht above forest floor and with an effective area of .264 m^2 each were used to collect autumnal litter fall." -US-UMd,19320,GRP_LAI,LAI_DATE,20060111 -US-UMd,19277,GRP_LAI,LAI_DATE,20061101 -US-UMd,19284,GRP_LAI,LAI_DATE,20061101 -US-UMd,19319,GRP_LAI,LAI_DATE,20070111 -US-UMd,19174,GRP_LAI,LAI_DATE,20070525 -US-UMd,19173,GRP_LAI,LAI_DATE,20070605 -US-UMd,19172,GRP_LAI,LAI_DATE,20070727 -US-UMd,19171,GRP_LAI,LAI_DATE,20071015 -US-UMd,19222,GRP_LAI,LAI_DATE,20071101 -US-UMd,19270,GRP_LAI,LAI_DATE,20071101 -US-UMd,19170,GRP_LAI,LAI_DATE,20080111 -US-UMd,19169,GRP_LAI,LAI_DATE,20080507 -US-UMd,19168,GRP_LAI,LAI_DATE,20080520 -US-UMd,19167,GRP_LAI,LAI_DATE,20080527 -US-UMd,19166,GRP_LAI,LAI_DATE,20080605 -US-UMd,19165,GRP_LAI,LAI_DATE,20080613 -US-UMd,19164,GRP_LAI,LAI_DATE,20080708 -US-UMd,19217,GRP_LAI,LAI_DATE,20081101 -US-UMd,19229,GRP_LAI,LAI_DATE,20081101 -US-UMd,19163,GRP_LAI,LAI_DATE,20090111 -US-UMd,19162,GRP_LAI,LAI_DATE,20090513 -US-UMd,19161,GRP_LAI,LAI_DATE,20090526 -US-UMd,19160,GRP_LAI,LAI_DATE,20090607 -US-UMd,19159,GRP_LAI,LAI_DATE,20090617 -US-UMd,19158,GRP_LAI,LAI_DATE,20090703 -US-UMd,19157,GRP_LAI,LAI_DATE,20090803 -US-UMd,19156,GRP_LAI,LAI_DATE,20090923 -US-UMd,19155,GRP_LAI,LAI_DATE,20091020 -US-UMd,19210,GRP_LAI,LAI_DATE,20091101 -US-UMd,19235,GRP_LAI,LAI_DATE,20091101 -US-UMd,19154,GRP_LAI,LAI_DATE,20100111 -US-UMd,19153,GRP_LAI,LAI_DATE,20100429 -US-UMd,19152,GRP_LAI,LAI_DATE,20100507 -US-UMd,19151,GRP_LAI,LAI_DATE,20100510 -US-UMd,19198,GRP_LAI,LAI_DATE,20100521 -US-UMd,19197,GRP_LAI,LAI_DATE,20100604 -US-UMd,19196,GRP_LAI,LAI_DATE,20100611 -US-UMd,19195,GRP_LAI,LAI_DATE,20100728 -US-UMd,19203,GRP_LAI,LAI_DATE,20101101 -US-UMd,19241,GRP_LAI,LAI_DATE,20101101 -US-UMd,19194,GRP_LAI,LAI_DATE,20110111 -US-UMd,19193,GRP_LAI,LAI_DATE,20110513 -US-UMd,19192,GRP_LAI,LAI_DATE,20110524 -US-UMd,19191,GRP_LAI,LAI_DATE,20110604 -US-UMd,19190,GRP_LAI,LAI_DATE,20110622 -US-UMd,19189,GRP_LAI,LAI_DATE,20110913 -US-UMd,19293,GRP_LAI,LAI_DATE,20111101 -US-UMd,19339,GRP_LAI,LAI_DATE,20111101 -US-UMd,19188,GRP_LAI,LAI_DATE,20120111 -US-UMd,19187,GRP_LAI,LAI_DATE,20120504 -US-UMd,19186,GRP_LAI,LAI_DATE,20120515 -US-UMd,19185,GRP_LAI,LAI_DATE,20120530 -US-UMd,19184,GRP_LAI,LAI_DATE,20120719 -US-UMd,19183,GRP_LAI,LAI_DATE,20120913 -US-UMd,19182,GRP_LAI,LAI_DATE,20121002 -US-UMd,19300,GRP_LAI,LAI_DATE,20121101 -US-UMd,19332,GRP_LAI,LAI_DATE,20121101 -US-UMd,19181,GRP_LAI,LAI_DATE,20130111 -US-UMd,19180,GRP_LAI,LAI_DATE,20130508 -US-UMd,19179,GRP_LAI,LAI_DATE,20130520 -US-UMd,19178,GRP_LAI,LAI_DATE,20130529 -US-UMd,19177,GRP_LAI,LAI_DATE,20130609 -US-UMd,19176,GRP_LAI,LAI_DATE,20130621 -US-UMd,19175,GRP_LAI,LAI_DATE,20130731 -US-UMd,19307,GRP_LAI,LAI_DATE,20131101 -US-UMd,19324,GRP_LAI,LAI_DATE,20131101 -US-UMd,19203,GRP_LAI,LAI_DATE_UNC,21 -US-UMd,19210,GRP_LAI,LAI_DATE_UNC,21 -US-UMd,19217,GRP_LAI,LAI_DATE_UNC,21 -US-UMd,19270,GRP_LAI,LAI_DATE_UNC,21 -US-UMd,19277,GRP_LAI,LAI_DATE_UNC,21 -US-UMd,19324,GRP_LAI,LAI_DATE_UNC,21 -US-UMd,19332,GRP_LAI,LAI_DATE_UNC,21 -US-UMd,19339,GRP_LAI,LAI_DATE_UNC,21 -US-UMd,19222,GRP_LAI,LAI_DATE_UNC,30 -US-UMd,19229,GRP_LAI,LAI_DATE_UNC,30 -US-UMd,19235,GRP_LAI,LAI_DATE_UNC,30 -US-UMd,19241,GRP_LAI,LAI_DATE_UNC,30 -US-UMd,19284,GRP_LAI,LAI_DATE_UNC,30 -US-UMd,19293,GRP_LAI,LAI_DATE_UNC,30 -US-UMd,19300,GRP_LAI,LAI_DATE_UNC,30 -US-UMd,19307,GRP_LAI,LAI_DATE_UNC,30 -US-UMd,19203,GRP_LAI,LAI_COMMENT,"Litter traps, 3 each in 11 - 0.08 ha plots and 20 in a single 1.13 ha plot, at 1 m ht above forest floor and with an effective area of .264 m^2 were used to collect autumnal litter fall." -US-UMd,19210,GRP_LAI,LAI_COMMENT,"Litter traps, 3 each in 11 - 0.08 ha plots and 20 in a single 1.13 ha plot, at 1 m ht above forest floor and with an effective area of .264 m^2 were used to collect autumnal litter fall." -US-UMd,19217,GRP_LAI,LAI_COMMENT,"Litter traps, 3 each in 11 - 0.08 ha plots and 20 in a single 1.13 ha plot, at 1 m ht above forest floor and with an effective area of .264 m^2 were used to collect autumnal litter fall." -US-UMd,19324,GRP_LAI,LAI_COMMENT,"Litter traps, 3 each in 11 - 0.08 ha plots and 20 in a single 1.13 ha plot, at 1 m ht above forest floor and with an effective area of .264 m^2 were used to collect autumnal litter fall." -US-UMd,19332,GRP_LAI,LAI_COMMENT,"Litter traps, 3 each in 11 - 0.08 ha plots and 20 in a single 1.13 ha plot, at 1 m ht above forest floor and with an effective area of .264 m^2 were used to collect autumnal litter fall." -US-UMd,19339,GRP_LAI,LAI_COMMENT,"Litter traps, 3 each in 11 - 0.08 ha plots and 20 in a single 1.13 ha plot, at 1 m ht above forest floor and with an effective area of .264 m^2 were used to collect autumnal litter fall." -US-UMd,19277,GRP_LAI,LAI_COMMENT,"Litter traps, 3 each in 8 - 0.08 ha plots, a single trap in 13 - 0.08 ha plots and 20 in a single 1.13 ha plot, at 1 m ht above forest floor and with an effective area of .264 m^2 were used to collect autumnal litter fall." -US-UMd,19270,GRP_LAI,LAI_COMMENT,"Litter traps, 3 each in 8 - 0.08 ha plots, a single trap in 14 - 0.08 ha plots and 20 in a single 1.13 ha plot, at 1 m ht above forest floor and with an effective area of .264 m^2 were used to collect autumnal litter fall." -US-UMd,19241,GRP_LAI,LAI_COMMENT,Populus grandidentata trees that had been girdled in 2008 began to dramatically lose leaf area. -US-UMd,19193,GRP_LAI,LAI_TOT,1.24 -US-UMd,19153,GRP_LAI,LAI_TOT,1.34 -US-UMd,19180,GRP_LAI,LAI_TOT,1.37 -US-UMd,19169,GRP_LAI,LAI_TOT,1.41 -US-UMd,19162,GRP_LAI,LAI_TOT,1.45 -US-UMd,19187,GRP_LAI,LAI_TOT,1.8 -US-UMd,19152,GRP_LAI,LAI_TOT,1.97 -US-UMd,19179,GRP_LAI,LAI_TOT,2.16 -US-UMd,19151,GRP_LAI,LAI_TOT,2.26 -US-UMd,19168,GRP_LAI,LAI_TOT,2.28 -US-UMd,19186,GRP_LAI,LAI_TOT,2.43 -US-UMd,19167,GRP_LAI,LAI_TOT,2.48 -US-UMd,19192,GRP_LAI,LAI_TOT,2.5 -US-UMd,19198,GRP_LAI,LAI_TOT,2.58 -US-UMd,19203,GRP_LAI,LAI_TOT,2.69 -US-UMd,19241,GRP_LAI,LAI_TOT,2.7 -US-UMd,19154,GRP_LAI,LAI_TOT,2.73 -US-UMd,19161,GRP_LAI,LAI_TOT,2.79 -US-UMd,19185,GRP_LAI,LAI_TOT,2.95 -US-UMd,19178,GRP_LAI,LAI_TOT,3.01 -US-UMd,19155,GRP_LAI,LAI_TOT,3.15 -US-UMd,19160,GRP_LAI,LAI_TOT,3.28 -US-UMd,19174,GRP_LAI,LAI_TOT,3.33 -US-UMd,19196,GRP_LAI,LAI_TOT,3.41 -US-UMd,19171,GRP_LAI,LAI_TOT,3.45 -US-UMd,19191,GRP_LAI,LAI_TOT,3.46 -US-UMd,19190,GRP_LAI,LAI_TOT,3.48 -US-UMd,19188,GRP_LAI,LAI_TOT,3.5 -US-UMd,19177,GRP_LAI,LAI_TOT,3.51 -US-UMd,19175,GRP_LAI,LAI_TOT,3.52 -US-UMd,19166,GRP_LAI,LAI_TOT,3.55 -US-UMd,19300,GRP_LAI,LAI_TOT,3.55 -US-UMd,19332,GRP_LAI,LAI_TOT,3.55 -US-UMd,19156,GRP_LAI,LAI_TOT,3.56 -US-UMd,19197,GRP_LAI,LAI_TOT,3.58 -US-UMd,19189,GRP_LAI,LAI_TOT,3.59 -US-UMd,19182,GRP_LAI,LAI_TOT,3.62 -US-UMd,19195,GRP_LAI,LAI_TOT,3.64 -US-UMd,19176,GRP_LAI,LAI_TOT,3.68 -US-UMd,19284,GRP_LAI,LAI_TOT,3.73 -US-UMd,19159,GRP_LAI,LAI_TOT,3.79 -US-UMd,19183,GRP_LAI,LAI_TOT,3.81 -US-UMd,19277,GRP_LAI,LAI_TOT,3.86 -US-UMd,19320,GRP_LAI,LAI_TOT,3.87 -US-UMd,19307,GRP_LAI,LAI_TOT,3.91 -US-UMd,19184,GRP_LAI,LAI_TOT,3.92 -US-UMd,19157,GRP_LAI,LAI_TOT,3.95 -US-UMd,19172,GRP_LAI,LAI_TOT,3.98 -US-UMd,19324,GRP_LAI,LAI_TOT,3.98 -US-UMd,19158,GRP_LAI,LAI_TOT,3.99 -US-UMd,19164,GRP_LAI,LAI_TOT,4.02 -US-UMd,19165,GRP_LAI,LAI_TOT,4.02 -US-UMd,19173,GRP_LAI,LAI_TOT,4.12 -US-UMd,19194,GRP_LAI,LAI_TOT,4.17 -US-UMd,19293,GRP_LAI,LAI_TOT,4.21 -US-UMd,19339,GRP_LAI,LAI_TOT,4.21 -US-UMd,19319,GRP_LAI,LAI_TOT,4.31 -US-UMd,19181,GRP_LAI,LAI_TOT,4.33 -US-UMd,19210,GRP_LAI,LAI_TOT,4.34 -US-UMd,19222,GRP_LAI,LAI_TOT,4.34 -US-UMd,19235,GRP_LAI,LAI_TOT,4.34 -US-UMd,19270,GRP_LAI,LAI_TOT,4.34 -US-UMd,19163,GRP_LAI,LAI_TOT,4.35 -US-UMd,19170,GRP_LAI,LAI_TOT,4.49 -US-UMd,19217,GRP_LAI,LAI_TOT,4.52 -US-UMd,19229,GRP_LAI,LAI_TOT,4.52 -US-UMd,19171,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,109 -US-UMd,19159,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,110 -US-UMd,19174,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,111 -US-UMd,19161,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,113 -US-UMd,19172,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,113 -US-UMd,19167,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,115 -US-UMd,19197,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,116 -US-UMd,19179,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,117 -US-UMd,19164,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,118 -US-UMd,19196,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,118 -US-UMd,19151,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,119 -US-UMd,19157,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,119 -US-UMd,19160,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,119 -US-UMd,19203,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,12 -US-UMd,19210,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,12 -US-UMd,19217,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,12 -US-UMd,19229,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,12 -US-UMd,19235,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,12 -US-UMd,19241,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,12 -US-UMd,19293,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,12 -US-UMd,19300,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,12 -US-UMd,19307,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,12 -US-UMd,19324,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,12 -US-UMd,19332,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,12 -US-UMd,19339,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,12 -US-UMd,19158,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,121 -US-UMd,19166,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,124 -US-UMd,19187,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,124 -US-UMd,19195,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,124 -US-UMd,19175,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,126 -US-UMd,19180,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,126 -US-UMd,19186,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,126 -US-UMd,19173,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,127 -US-UMd,19178,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,127 -US-UMd,19192,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,127 -US-UMd,19155,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,129 -US-UMd,19193,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,129 -US-UMd,19153,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,130 -US-UMd,19162,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,130 -US-UMd,19169,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,133 -US-UMd,19182,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,135 -US-UMd,19177,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,136 -US-UMd,19184,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,139 -US-UMd,19190,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,139 -US-UMd,19152,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,141 -US-UMd,19156,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,141 -US-UMd,19165,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,143 -US-UMd,19176,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,144 -US-UMd,19191,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,146 -US-UMd,19185,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,147 -US-UMd,19183,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,152 -US-UMd,19189,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,156 -US-UMd,19154,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,16 -US-UMd,19163,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,16 -US-UMd,19170,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,16 -US-UMd,19181,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,16 -US-UMd,19188,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,16 -US-UMd,19194,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,16 -US-UMd,19319,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,16 -US-UMd,19320,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,16 -US-UMd,19277,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,22 -US-UMd,19284,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,22 -US-UMd,19222,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,23 -US-UMd,19270,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,23 -US-UMd,19198,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,39 -US-UMd,19168,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,47 -US-UMd,19180,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.22 -US-UMd,19153,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.23 -US-UMd,19162,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.23 -US-UMd,19169,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.23 -US-UMd,19193,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.23 -US-UMd,19167,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.32 -US-UMd,19151,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.33 -US-UMd,19168,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.41 -US-UMd,19179,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.43 -US-UMd,19203,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.43 -US-UMd,19241,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.43 -US-UMd,19186,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.45 -US-UMd,19187,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.45 -US-UMd,19154,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.49 -US-UMd,19171,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.52 -US-UMd,19161,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.53 -US-UMd,19174,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.53 -US-UMd,19166,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.56 -US-UMd,19192,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.56 -US-UMd,19165,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.6 -US-UMd,19198,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.62 -US-UMd,19157,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.65 -US-UMd,19160,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.65 -US-UMd,19164,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.65 -US-UMd,19155,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.68 -US-UMd,19173,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.68 -US-UMd,19172,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.69 -US-UMd,19188,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.69 -US-UMd,19300,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.69 -US-UMd,19332,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.69 -US-UMd,19159,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.73 -US-UMd,19196,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.76 -US-UMd,19158,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.77 -US-UMd,19195,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.78 -US-UMd,19178,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.79 -US-UMd,19152,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.83 -US-UMd,19156,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.83 -US-UMd,19191,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.85 -US-UMd,19197,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.86 -US-UMd,19277,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.86 -US-UMd,19284,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.86 -US-UMd,19189,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.87 -US-UMd,19320,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.89 -US-UMd,19175,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.9 -US-UMd,19177,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.93 -US-UMd,19190,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.94 -US-UMd,19176,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.96 -US-UMd,19307,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.98 -US-UMd,19324,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.98 -US-UMd,19183,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.99 -US-UMd,19182,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,1.05 -US-UMd,19184,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,1.06 -US-UMd,19319,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,1.08 -US-UMd,19194,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,1.15 -US-UMd,19222,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,1.15 -US-UMd,19163,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,1.18 -US-UMd,19181,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,1.189 -US-UMd,19293,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,1.19 -US-UMd,19339,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,1.19 -US-UMd,19210,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,1.21 -US-UMd,19235,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,1.21 -US-UMd,19270,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,1.3 -US-UMd,19185,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,1.33 -US-UMd,19170,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,1.39 -US-UMd,19217,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,1.46 -US-UMd,19229,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,1.46 -US-UMd,12365,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -US-UMd,12365,GRP_LAND_OWNERSHIP,LAND_OWNER,University of Michigan -US-UMd,12366,GRP_LOCATION,LOCATION_LAT,45.5625 -US-UMd,12366,GRP_LOCATION,LOCATION_LONG,-84.6975 -US-UMd,12366,GRP_LOCATION,LOCATION_ELEV,239 -US-UMd,12366,GRP_LOCATION,LOCATION_COMMENT,From CDIAC Tom Boden database dump -US-UMd,12367,GRP_NETWORK,NETWORK,AmeriFlux -US-UMd,87026,GRP_NETWORK,NETWORK,Phenocam -US-UMd,19204,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,BudBreak -US-UMd,19204,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_STATUS,Start -US-UMd,19204,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,Acer rubrum -US-UMd,19204,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20100416 -US-UMd,19204,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_UNC,0 -US-UMd,19204,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_APPROACH,opening of bud scales -US-UMd,19204,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,Replicates are individual trees within 60 m of flux tower. Standard deviation is days instead of YYYYMMDD. -US-UMd,19204,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_REP_NUMBER,5 -US-UMd,19204,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_VARIABILITY,3.2 -US-UMd,19211,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,BudBreak -US-UMd,19211,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_STATUS,Start -US-UMd,19211,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,Fagus grandifolia -US-UMd,19211,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20100429 -US-UMd,19211,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_UNC,0 -US-UMd,19211,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_APPROACH,opening of bud scales -US-UMd,19211,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,Replicates are individual trees within 60 m of flux tower. Standard deviation is days instead of YYYYMMDD. -US-UMd,19211,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_REP_NUMBER,5 -US-UMd,19211,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_VARIABILITY,2.6 -US-UMd,19218,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,BudBreak -US-UMd,19218,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_STATUS,Start -US-UMd,19218,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,Quercus rubra -US-UMd,19218,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20100422 -US-UMd,19218,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_UNC,0 -US-UMd,19218,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_APPROACH,opening of bud scales -US-UMd,19218,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,Replicates are individual trees within 60 m of flux tower. Standard deviation is days instead of YYYYMMDD. -US-UMd,19218,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_REP_NUMBER,5 -US-UMd,19218,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_VARIABILITY,2.5 -US-UMd,19242,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,BudBreak -US-UMd,19242,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_STATUS,Start -US-UMd,19242,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,Acer rubrum -US-UMd,19242,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20130504 -US-UMd,19242,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_UNC,0.4 -US-UMd,19242,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_APPROACH,opening of bud scales -US-UMd,19242,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,Replicates are individual trees within 60 m of flux tower. Standard deviation is days instead of YYYYMMDD. -US-UMd,19242,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_REP_NUMBER,5 -US-UMd,19242,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_VARIABILITY,0.55 -US-UMd,19245,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,BudBreak -US-UMd,19245,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_STATUS,Start -US-UMd,19245,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,Fagus grandifolia -US-UMd,19245,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20140520 -US-UMd,19245,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_UNC,0 -US-UMd,19245,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_APPROACH,opening of bud scales -US-UMd,19245,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,Replicates are individual trees within 60 m of flux tower. Standard deviation is days instead of YYYYMMDD. -US-UMd,19245,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_REP_NUMBER,4 -US-UMd,19245,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_VARIABILITY,1 -US-UMd,19251,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,BudBreak -US-UMd,19251,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_STATUS,Start -US-UMd,19251,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,Quercus rubra -US-UMd,19251,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20140521 -US-UMd,19251,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_UNC,0 -US-UMd,19251,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_APPROACH,opening of bud scales -US-UMd,19251,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,Replicates are individual trees within 60 m of flux tower. Standard deviation is days instead of YYYYMMDD. -US-UMd,19251,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_REP_NUMBER,3 -US-UMd,19251,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_VARIABILITY,1.15 -US-UMd,19271,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,BudBreak -US-UMd,19271,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_STATUS,Start -US-UMd,19271,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,Acer rubrum -US-UMd,19271,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20110510 -US-UMd,19271,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_UNC,0 -US-UMd,19271,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_APPROACH,opening of bud scales -US-UMd,19271,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,Replicates are individual trees within 60 m of flux tower. Standard deviation is days instead of YYYYMMDD. -US-UMd,19271,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_REP_NUMBER,5 -US-UMd,19271,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_VARIABILITY,1.4 -US-UMd,19278,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,BudBreak -US-UMd,19278,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_STATUS,Start -US-UMd,19278,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,Fagus grandifolia -US-UMd,19278,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20110511 -US-UMd,19278,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_UNC,0 -US-UMd,19278,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_APPROACH,opening of bud scales -US-UMd,19278,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,Replicates are individual trees within 60 m of flux tower. Standard deviation is days instead of YYYYMMDD. -US-UMd,19278,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_REP_NUMBER,5 -US-UMd,19278,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_VARIABILITY,0.9 -US-UMd,19285,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,BudBreak -US-UMd,19285,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_STATUS,Start -US-UMd,19285,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,Quercus rubra -US-UMd,19285,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20110512 -US-UMd,19285,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_UNC,0 -US-UMd,19285,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_APPROACH,opening of bud scales -US-UMd,19285,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,Replicates are individual trees within 60 m of flux tower. Standard deviation is days instead of YYYYMMDD. -US-UMd,19285,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_REP_NUMBER,5 -US-UMd,19285,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_VARIABILITY,0.4 -US-UMd,19294,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,BudBreak -US-UMd,19294,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_STATUS,Start -US-UMd,19294,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,Fagus grandifolia -US-UMd,19294,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20130506 -US-UMd,19294,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_UNC,0.6 -US-UMd,19294,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_APPROACH,opening of bud scales -US-UMd,19294,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,Replicates are individual trees within 60 m of flux tower. Standard deviation is days instead of YYYYMMDD. -US-UMd,19294,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_REP_NUMBER,5 -US-UMd,19294,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_VARIABILITY,0.55 -US-UMd,19301,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,BudBreak -US-UMd,19301,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_STATUS,Start -US-UMd,19301,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,Quercus rubra -US-UMd,19301,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20130506 -US-UMd,19301,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_UNC,0.6 -US-UMd,19301,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_APPROACH,opening of bud scales -US-UMd,19301,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,Replicates are individual trees within 60 m of flux tower. Standard deviation is days instead of YYYYMMDD. -US-UMd,19301,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_REP_NUMBER,5 -US-UMd,19301,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_VARIABILITY,0.55 -US-UMd,19308,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,BudBreak -US-UMd,19308,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_STATUS,Start -US-UMd,19308,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,Acer rubrum -US-UMd,19308,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20140518 -US-UMd,19308,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_UNC,0 -US-UMd,19308,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_APPROACH,opening of bud scales -US-UMd,19308,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,Replicates are individual trees within 60 m of flux tower. Standard deviation is days instead of YYYYMMDD. -US-UMd,19308,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_REP_NUMBER,4 -US-UMd,19308,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_VARIABILITY,0.95 -US-UMd,19325,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,BudBreak -US-UMd,19325,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_STATUS,Start -US-UMd,19325,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,Acer rubrum -US-UMd,19325,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20090505 -US-UMd,19325,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_UNC,0.4 -US-UMd,19325,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_APPROACH,opening of bud scales -US-UMd,19325,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,Replicates are individual trees within 60 m of flux tower. Standard deviation is days instead of YYYYMMDD. -US-UMd,19325,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_REP_NUMBER,5 -US-UMd,19325,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_VARIABILITY,0.9 -US-UMd,19333,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,BudBreak -US-UMd,19333,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_STATUS,Start -US-UMd,19333,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,Fagus grandifolia -US-UMd,19333,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20090510 -US-UMd,19333,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_UNC,0.4 -US-UMd,19333,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_APPROACH,opening of bud scales -US-UMd,19333,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,Replicates are individual trees within 60 m of flux tower. Standard deviation is days instead of YYYYMMDD. -US-UMd,19333,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_REP_NUMBER,5 -US-UMd,19333,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_VARIABILITY,2.4 -US-UMd,19340,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,BudBreak -US-UMd,19340,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_STATUS,Start -US-UMd,19340,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,Quercus rubra -US-UMd,19340,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20090509 -US-UMd,19340,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_UNC,0.2 -US-UMd,19340,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_APPROACH,opening of bud scales -US-UMd,19340,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,Replicates are individual trees within 60 m of flux tower. Standard deviation is days instead of YYYYMMDD. -US-UMd,19340,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_REP_NUMBER,5 -US-UMd,19340,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_VARIABILITY,1.6 -US-UMd,19223,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,leaf unfurling -US-UMd,19223,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_STATUS,Start -US-UMd,19223,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,Acer rubrum -US-UMd,19223,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20120420 -US-UMd,19223,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_UNC,0.2 -US-UMd,19223,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_APPROACH,first leaf surface visible -US-UMd,19223,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,Replicates are individual trees within 60 m of flux tower. Standard deviation is days instead of YYYYMMDD. -US-UMd,19223,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_REP_NUMBER,5 -US-UMd,19223,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_VARIABILITY,6.38 -US-UMd,19230,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,leaf unfurling -US-UMd,19230,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_STATUS,Start -US-UMd,19230,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,Fagus grandifolia -US-UMd,19230,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20120507 -US-UMd,19230,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_UNC,0.2 -US-UMd,19230,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_APPROACH,first leaf surface visible -US-UMd,19230,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,Replicates are individual trees within 60 m of flux tower. Standard deviation is days instead of YYYYMMDD. -US-UMd,19230,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_REP_NUMBER,5 -US-UMd,19230,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_VARIABILITY,1.3 -US-UMd,19236,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,leaf unfurling -US-UMd,19236,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_STATUS,Start -US-UMd,19236,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,Quercus rubra -US-UMd,19236,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20120506 -US-UMd,19236,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_UNC,0.2 -US-UMd,19236,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_APPROACH,first leaf surface visible -US-UMd,19236,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,Replicates are individual trees within 60 m of flux tower. Standard deviation is days instead of YYYYMMDD. -US-UMd,19236,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_REP_NUMBER,5 -US-UMd,19236,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_SPATIAL_VARIABILITY,2.17 -US-UMd,1700002127,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Atkins, J. W., Bohrer, G., Fahey, R. T., Hardiman, B. S., Morin, T. H., Stovall, A. E., Zimmerman, N., Gough, C. M. (2018) Quantifying Vegetation And Canopy Structural Complexity From Terrestrial Lidar Data Using The Forestr R Package, Methods In Ecology And Evolution, 9(10), 2057-2066" -US-UMd,1700002127,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/2041-210X.13061 -US-UMd,1700002127,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-UMd,1700003357,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Atkins, J. W., Fahey, R. T., Hardiman, B. H., Gough, C. M. (2018) Forest Canopy Structural Complexity And Light Absorption Relationships At The Subcontinental Scale, Journal Of Geophysical Research: Biogeosciences, 123(4), 1387-1405" -US-UMd,1700003357,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/2017JG004256 -US-UMd,1700003357,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-UMd,1700007470,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Bond-Lamberty, B., Bailey, V. L., Chen, M., Gough, C. M., Vargas, R. (2018) Globally Rising Soil Heterotrophic Respiration Over Recent Decades, Nature, 560(7716), 80-83" -US-UMd,1700007470,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1038/S41586-018-0358-X -US-UMd,1700007470,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-UMd,1700000420,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Baldocchi, D. D., Poindexter, C., Abraha, M., Desai, A. R., Bohrer, G., Arain, M. A., Griffis, T., Blanken, P. D., O'Halloran, T. L., Thomas, R. Q., Zhang, Q., Burns, S. P., Frank, J. M., Christian, D., Brown, S., Black, T. A., Gough, C. M., Law, B. E., Lee, X., Chen, J., Reed, D. E., Massman, W. J., Clark, K., Hatfield, J., Prueger, J., Bracho, R., Baker, J. M., Martin, T. A. (2018) Temporal Dynamics Of Aerodynamic Canopy Height Derived From Eddy Covariance Momentum Flux Data Across North American Flux Networks, Geophysical Research Letters, 45(2), 9275–9287" -US-UMd,1700000420,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018GL079306 -US-UMd,1700000420,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-UMd,1700000117,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Baldocchi, D. D., Poindexter, C., Abraha, M., Desai, A. R., Bohrer, G., Arain, M. A., Griffis, T., Blanken, P. D., O'Halloran, T. L., Thomas, R. Q., Zhang, Q., Burns, S. P., Frank, J. M., Christian, D., Brown, S., Black, T. A., Gough, C. M., Law, B. E., Lee, X., Chen, J., Reed, D. E., Massman, W. J., Clark, K., Hatfield, J., Prueger, J., Bracho, R., Baker, J. M., Martin, T. A. (2018) Temporal Dynamics Of Aerodynamic Canopy Height Derived From Eddy Covariance Momentum Flux Data Across North American Flux Networks, Geophysical Research Letters, 45(5), 9275–9287" -US-UMd,1700000117,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018GL079306 -US-UMd,1700000117,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-UMd,1700004320,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(9), 108350" -US-UMd,1700004320,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -US-UMd,1700004320,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-UMd,1700005625,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Curtis, P. S., Gough, C. M. (2018) Forest Aging, Disturbance And The Carbon Cycle, New Phytologist, 219(4), 1188-1193" -US-UMd,1700005625,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/NPH.15227 -US-UMd,1700005625,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-UMd,1700003747,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Detto, M., Bohrer, G., Nietz, J., Maurer, K., Vogel, C., Gough, C., Curtis, P. (2013) Multivariate Conditional Granger Causality Analysis For Lagged Response Of Soil Respiration In A Temperate Forest, Entropy, 15(12), 4266-4284" -US-UMd,1700003747,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.3390/E15104266 -US-UMd,1700003747,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-UMd,1700008028,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Fahey, R. T., Stuart-Haëntjens, E. J., Gough, C. M., De La Cruz, A., Stockton, E., Vogel, C. S., Curtis, P. S. (2016) Evaluating Forest Subcanopy Response To Moderate Severity Disturbance And Contribution To Ecosystem-Level Productivity And Resilience, Forest Ecology And Management, 376(4), 135-147" -US-UMd,1700008028,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.FORECO.2016.06.001 -US-UMd,1700008028,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-UMd,1700005274,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Fotis, A. T., Morin, T. H., Fahey, R. T., Hardiman, B. S., Bohrer, G., Curtis, P. S. (2018) Forest Structure In Space And Time: Biotic And Abiotic Determinants Of Canopy Complexity And Their Effects On Net Primary Productivity, Agricultural And Forest Meteorology, 250-251(10), 181-191" -US-UMd,1700005274,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2017.12.251 -US-UMd,1700005274,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-UMd,1700007317,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Frasson, R. P., Bohrer, G., Medvigy, D., Matheny, A. M., Morin, T. H., Vogel, C. S., Gough, C. M., Maurer, K. D., Curtis, P. S. (2015) Modeling Forest Carbon Cycle Response To Tree Mortality: Effects Of Plant Functional Type And Disturbance Intensity, Journal Of Geophysical Research: Biogeosciences, 120(11), 2178-2193" -US-UMd,1700007317,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/2015JG003035 -US-UMd,1700007317,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-UMd,1700001863,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Gough, C. M., Curtis, P. S., Hardiman, B. S., Scheuermann, C. M., Bond‐Lamberty, B. (2016) Disturbance, Complexity, And Succession Of Net Ecosystem Production In North America'S Temperate Deciduous Forests, Ecosphere, 7(6), 474" -US-UMd,1700001863,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/ECS2.1375 -US-UMd,1700001863,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-UMd,1700004620,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Gough, C. M., Hardiman, B. S., Nave, L. E., Bohrer, G., Maurer, K. D., Vogel, C. S., Nadelhoffer, K. J., Curtis, P. S. (2013) Sustained Carbon Uptake And Storage Following Moderate Disturbance In A Great Lakes Forest, Ecological Applications, 23(5), 1202-1215" -US-UMd,1700004620,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1890/12-1554.1 -US-UMd,1700004620,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-UMd,1700003795,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Hardiman, B. S., Bohrer, G., Gough, C. M., Vogel, C. S., Curtis, P. S. (2011) The Role Of Canopy Structural Complexity In Wood Net Primary Production Of A Maturing Northern Deciduous Forest, Ecology, 92(9), 1818-1827" -US-UMd,1700003795,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1890/10-2192.1 -US-UMd,1700003795,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-UMd,1700002910,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Hardiman, B. S., Gough, C. M., Halperin, A., Hofmeister, K. L., Nave, L. E., Bohrer, G., Curtis, P. S. (2013) Maintaining High Rates Of Carbon Storage In Old Forests: A Mechanism Linking Canopy Structure To Forest Function, Forest Ecology And Management, 298(3), 111-119" -US-UMd,1700002910,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.FORECO.2013.02.031 -US-UMd,1700002910,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-UMd,1700003951,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Hardiman, B., Bohrer, G., Gough, C., Curtis, P. (2013) Canopy Structural Changes Following Widespread Mortality Of Canopy Dominant Trees, Forests, 4(3), 537-552" -US-UMd,1700003951,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.3390/F4030537 -US-UMd,1700003951,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-UMd,1700006855,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Hardiman, B., LaRue, E., Atkins, J., Fahey, R., Wagner, F., Gough, C. (2018) Spatial Variation In Canopy Structure Across Forest Landscapes, Forests, 9(8), 474" -US-UMd,1700006855,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.3390/F9080474 -US-UMd,1700006855,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-UMd,1700004548,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"LaRue, E. A., Atkins, J. W., Dahlin, K., Fahey, R., Fei, S., Gough, C., Hardiman, B. S. (2018) Linking Landsat To Terrestrial Lidar: Vegetation Metrics Of Forest Greenness Are Correlated With Canopy Structural Complexity, International Journal Of Applied Earth Observation And Geoinformation, 73(6), 420-427" -US-UMd,1700004548,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.JAG.2018.07.001 -US-UMd,1700004548,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-UMd,1700004656,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Matheny, A. M., Garrity, S. R., Bohrer, G. (2017) The Calibration And Use Of Capacitance Sensors To Monitor Stem Water Content In Trees, Journal Of Visualized Experiments, 250-251(130), 181-191" -US-UMd,1700004656,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.3791/57062 -US-UMd,1700004656,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-UMd,1700002244,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Matheny, A. M., Mirfenderesgi, G., Bohrer, G. (2017) Trait-Based Representation Of Hydrological Functional Properties Of Plants In Weather And Ecosystem Models, Plant Diversity, 39(1), 1-12" -US-UMd,1700002244,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.PLD.2016.10.001 -US-UMd,1700002244,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-UMd,1700000186,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Maurer, K. D., Hardiman, B. S., Vogel, C. S., Bohrer, G. (2013) Canopy-Structure Effects On Surface Roughness Parameters: Observations In A Great Lakes Mixed-Deciduous Forest, Agricultural And Forest Meteorology, 177(12), 24-34" -US-UMd,1700000186,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2013.04.002 -US-UMd,1700000186,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-UMd,1700002631,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Nave, L. E., Gough, C. M., Maurer, K. D., Bohrer, G., Hardiman, B. S., Le Moine, J., Munoz, A. B., Nadelhoffer, K. J., Sparks, J. P., Strahm, B. D., Vogel, C. S., Curtis, P. S. (2011) Disturbance And The Resilience Of Coupled Carbon And Nitrogen Cycling In A North Temperate Forest, Journal Of Geophysical Research, 116(G4), 111-119" -US-UMd,1700002631,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2011JG001758 -US-UMd,1700002631,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-UMd,1700003273,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Nave, L. E., Sparks, J. P., Le Moine, J., Hardiman, B. S., Nadelhoffer, K. J., Tallant, J. M., Vogel, C. S., Strahm, B. D., Curtis, P. S. (2014) Changes In Soil Nitrogen Cycling In A Northern Temperate Forest Ecosystem During Succession, Biogeochemistry, 121(3), 471-488" -US-UMd,1700003273,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1007/S10533-014-0013-Z -US-UMd,1700003273,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-UMd,1700003081,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Nave, L.E., Gough, C.M., Maurer, K.D., Bohrer, G, Hardiman, B.S., Le Moine, J., Munoz, A.B., Nadelhoffer, K.J., Sparks, J.P., Strahm, B.D., Vogel, C.S., Curtis, P.S. (2011) Disturbance And The Resilience Of Coupled Carbon And Nitrogen Cycling In A North Temperate Forest, Journal Of Geophysical Research, 116(G04016), n/a-n/a" -US-UMd,1700003081,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2011JG001758 -US-UMd,1700003081,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-UMd,1700007962,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Sagara, B., Fahey, R., Vogel, C., Fotis, A., Curtis, P., Gough, C. (2018) Moderate Disturbance Has Similar Effects On Production Regardless Of Site Quality And Composition, Forests, 9(2), 70" -US-UMd,1700007962,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.3390/F9020070 -US-UMd,1700007962,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-UMd,1700006351,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Schmid, A. V., Vogel, C. S., Liebman, E., Curtis, P. S., Gough, C. M. (2016) Coarse Woody Debris And The Carbon Balance Of A Moderately Disturbed Forest, Forest Ecology And Management, 361(2), 38-45" -US-UMd,1700006351,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.FORECO.2015.11.001 -US-UMd,1700006351,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-UMd,1700007512,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Stuart-Haëntjens, E. J., Curtis, P. S., Fahey, R. T., Vogel, C. S., Gough, C. M. (2015) Net Primary Production Of A Temperate Deciduous Forest Exhibits A Threshold Response To Increasing Disturbance Severity, Ecology, 96(9), 2478-2487" -US-UMd,1700007512,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1890/14-1810.1 -US-UMd,1700007512,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-UMd,1700001719,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Stuart-Haëntjens, E., De Boeck, H. J., Lemoine, N. P., Mänd, P., Kröel-Dulay, G., Schmidt, I. K., Jentsch, A., Stampfli, A., Anderegg, W. R., Bahn, M., Kreyling, J., Wohlgemuth, T., Lloret, F., Classen, A. T., Gough, C. M., Smith, M. D. (2018) Mean Annual Precipitation Predicts Primary Production Resistance And Resilience To Extreme Drought, Science Of The Total Environment, 636(2), 360-366" -US-UMd,1700001719,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.SCITOTENV.2018.04.290 -US-UMd,1700001719,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-UMd,1700008376,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Sullivan, R. C., Cook, D. R., Ghate, V. P., Kotamarthi, V. R., Feng, Y. (2019) Improved Spatiotemporal Representativeness And Bias Reduction Of Satellite-Based Evapotranspiration Retrievals Via Use Of In Situ Meteorology And Constrained Canopy Surface Resistance, Journal Of Geophysical Research: Biogeosciences, 124(2), 342-352" -US-UMd,1700008376,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018JG004744 -US-UMd,1700008376,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-UMd,1700002400,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Sullivan, R. C., Kotamarthi, V. R., Feng, Y. (2019) Recovering Evapotranspiration Trends From Biased CMIP5 Simulations And Sensitivity To Changing Climate Over North America, Journal Of Hydrometeorology, 20(8), 1619-1633" -US-UMd,1700002400,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1175/JHM-D-18-0259.1 -US-UMd,1700002400,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-UMd,1700006633,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Thomsen, J., Bohrer, G., Matheny, A., Ivanov, V., He, L., Renninger, H., Schäfer, K. (2013) Contrasting Hydraulic Strategies During Dry Soil Conditions In Quercus Rubra And Acer Rubrum In A Sandy Site In Michigan, Forests, 4(4), 1106-1120" -US-UMd,1700006633,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.3390/F4041106 -US-UMd,1700006633,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-UMd,1700007599,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Toomey, M., Friedl, M. A., Frolking, S., Hufkens, K., Klosterman, S., Sonnentag, O., Baldocchi, D. D., Bernacchi, C. J., Biraud, S. C., Bohrer, G., Brzostek, E., Burns, S. P., Coursolle, C., Hollinger, D. Y., Margolis, H. A., McCaughey, H., Monson, R. K., Munger, J. W., Pallardy, S., Phillips, R. P., Torn, M. S., Wharton, S., Zeri, M., Richardson, A. D. (2015) Greenness Indices From Digital Cameras Predict The Timing And Seasonal Dynamics Of Canopy-Scale Photosynthesis, Ecological Applications, 25(1), 99-115" -US-UMd,1700007599,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1890/14-0005.1 -US-UMd,1700007599,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-UMd,1700004614,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Xu, B., Arain, M. A., Black, T. A., Law, B. E., Pastorello, G. Z., Chu, H. (2020) Seasonal Variability Of Forest Sensitivity To Heat And Drought Stresses: A Synthesis Based On Carbon Fluxes From North American Forest Ecosystems, Global Change Biology, 26(2), 901-918" -US-UMd,1700004614,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/GCB.14843 -US-UMd,1700004614,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-UMd,12369,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"The research objectives of the University of Michigan Biological Station are to address questions of ecosystem/atmosphere linkages that are general in nature and which will contribute to large-scale carbon cycle modeling efforts, and to test hypotheses specific to the upper Great Lakes forest ecosystems that will further understanding of productivity controls over these regionally important communities. The research focus at the UMBS Disturbance site is to examine carbon cycling processes following the transition from aspen dominated ecosystems to those of later-successional species with biologically and structurally more complex canopies." -US-UMd,18607,GRP_ROOT_BIOMASS,ROOT_BIOMASS_CRS,147.2 -US-UMd,18616,GRP_ROOT_BIOMASS,ROOT_BIOMASS_CRS,32 -US-UMd,18660,GRP_ROOT_BIOMASS,ROOT_BIOMASS_CRS,513.3 -US-UMd,18650,GRP_ROOT_BIOMASS,ROOT_BIOMASS_CRS,762.1 -US-UMd,18607,GRP_ROOT_BIOMASS,ROOT_BIOMASS_CRS_SPATIAL_VARIABILITY,109.17 -US-UMd,18616,GRP_ROOT_BIOMASS,ROOT_BIOMASS_CRS_SPATIAL_VARIABILITY,41.88 -US-UMd,18650,GRP_ROOT_BIOMASS,ROOT_BIOMASS_CRS_SPATIAL_VARIABILITY,587.65 -US-UMd,18660,GRP_ROOT_BIOMASS,ROOT_BIOMASS_CRS_SPATIAL_VARIABILITY,602.15 -US-UMd,18607,GRP_ROOT_BIOMASS,ROOT_BIOMASS_CRS_SPATIAL_REP_NUMBER,12 -US-UMd,18616,GRP_ROOT_BIOMASS,ROOT_BIOMASS_CRS_SPATIAL_REP_NUMBER,12 -US-UMd,18650,GRP_ROOT_BIOMASS,ROOT_BIOMASS_CRS_SPATIAL_REP_NUMBER,12 -US-UMd,18660,GRP_ROOT_BIOMASS,ROOT_BIOMASS_CRS_SPATIAL_REP_NUMBER,12 -US-UMd,18607,GRP_ROOT_BIOMASS,ROOT_BIOMASS_FINE,110.9 -US-UMd,18682,GRP_ROOT_BIOMASS,ROOT_BIOMASS_FINE,112.8 -US-UMd,18674,GRP_ROOT_BIOMASS,ROOT_BIOMASS_FINE,117.5 -US-UMd,18627,GRP_ROOT_BIOMASS,ROOT_BIOMASS_FINE,136.3 -US-UMd,18631,GRP_ROOT_BIOMASS,ROOT_BIOMASS_FINE,150.4 -US-UMd,18666,GRP_ROOT_BIOMASS,ROOT_BIOMASS_FINE,169.2 -US-UMd,18660,GRP_ROOT_BIOMASS,ROOT_BIOMASS_FINE,174.7 -US-UMd,18650,GRP_ROOT_BIOMASS,ROOT_BIOMASS_FINE,435.8 -US-UMd,18616,GRP_ROOT_BIOMASS,ROOT_BIOMASS_FINE,47.2 -US-UMd,18635,GRP_ROOT_BIOMASS,ROOT_BIOMASS_FINE,65.8 -US-UMd,18639,GRP_ROOT_BIOMASS,ROOT_BIOMASS_FINE,65.8 -US-UMd,18643,GRP_ROOT_BIOMASS,ROOT_BIOMASS_FINE,98.7 -US-UMd,18650,GRP_ROOT_BIOMASS,ROOT_BIOMASS_FINE_SPATIAL_VARIABILITY,106.45 -US-UMd,18635,GRP_ROOT_BIOMASS,ROOT_BIOMASS_FINE_SPATIAL_VARIABILITY,13.025022073 -US-UMd,18639,GRP_ROOT_BIOMASS,ROOT_BIOMASS_FINE_SPATIAL_VARIABILITY,13.839085952 -US-UMd,18616,GRP_ROOT_BIOMASS,ROOT_BIOMASS_FINE_SPATIAL_VARIABILITY,28.66 -US-UMd,18682,GRP_ROOT_BIOMASS,ROOT_BIOMASS_FINE_SPATIAL_VARIABILITY,29.306299664 -US-UMd,18631,GRP_ROOT_BIOMASS,ROOT_BIOMASS_FINE_SPATIAL_VARIABILITY,39.889130098 -US-UMd,18607,GRP_ROOT_BIOMASS,ROOT_BIOMASS_FINE_SPATIAL_VARIABILITY,43.71 -US-UMd,18674,GRP_ROOT_BIOMASS,ROOT_BIOMASS_FINE_SPATIAL_VARIABILITY,44.773513376 -US-UMd,18627,GRP_ROOT_BIOMASS,ROOT_BIOMASS_FINE_SPATIAL_VARIABILITY,45.587577255 -US-UMd,18666,GRP_ROOT_BIOMASS,ROOT_BIOMASS_FINE_SPATIAL_VARIABILITY,45.587577255 -US-UMd,18660,GRP_ROOT_BIOMASS,ROOT_BIOMASS_FINE_SPATIAL_VARIABILITY,51.93 -US-UMd,18643,GRP_ROOT_BIOMASS,ROOT_BIOMASS_FINE_SPATIAL_VARIABILITY,58.612599328 -US-UMd,18607,GRP_ROOT_BIOMASS,ROOT_BIOMASS_FINE_SPATIAL_REP_NUMBER,12 -US-UMd,18616,GRP_ROOT_BIOMASS,ROOT_BIOMASS_FINE_SPATIAL_REP_NUMBER,12 -US-UMd,18650,GRP_ROOT_BIOMASS,ROOT_BIOMASS_FINE_SPATIAL_REP_NUMBER,12 -US-UMd,18660,GRP_ROOT_BIOMASS,ROOT_BIOMASS_FINE_SPATIAL_REP_NUMBER,12 -US-UMd,18627,GRP_ROOT_BIOMASS,ROOT_BIOMASS_FINE_SPATIAL_REP_NUMBER,3 -US-UMd,18631,GRP_ROOT_BIOMASS,ROOT_BIOMASS_FINE_SPATIAL_REP_NUMBER,3 -US-UMd,18635,GRP_ROOT_BIOMASS,ROOT_BIOMASS_FINE_SPATIAL_REP_NUMBER,3 -US-UMd,18639,GRP_ROOT_BIOMASS,ROOT_BIOMASS_FINE_SPATIAL_REP_NUMBER,3 -US-UMd,18643,GRP_ROOT_BIOMASS,ROOT_BIOMASS_FINE_SPATIAL_REP_NUMBER,3 -US-UMd,18666,GRP_ROOT_BIOMASS,ROOT_BIOMASS_FINE_SPATIAL_REP_NUMBER,3 -US-UMd,18674,GRP_ROOT_BIOMASS,ROOT_BIOMASS_FINE_SPATIAL_REP_NUMBER,3 -US-UMd,18682,GRP_ROOT_BIOMASS,ROOT_BIOMASS_FINE_SPATIAL_REP_NUMBER,3 -US-UMd,18650,GRP_ROOT_BIOMASS,ROOT_BIOMASS_TOT,1197.9 -US-UMd,18607,GRP_ROOT_BIOMASS,ROOT_BIOMASS_TOT,258.1 -US-UMd,18660,GRP_ROOT_BIOMASS,ROOT_BIOMASS_TOT,688 -US-UMd,18616,GRP_ROOT_BIOMASS,ROOT_BIOMASS_TOT,79.3 -US-UMd,18607,GRP_ROOT_BIOMASS,ROOT_BIOMASS_TOT_SPATIAL_VARIABILITY,130.35 -US-UMd,18650,GRP_ROOT_BIOMASS,ROOT_BIOMASS_TOT_SPATIAL_VARIABILITY,614.88 -US-UMd,18660,GRP_ROOT_BIOMASS,ROOT_BIOMASS_TOT_SPATIAL_VARIABILITY,617.77 -US-UMd,18616,GRP_ROOT_BIOMASS,ROOT_BIOMASS_TOT_SPATIAL_VARIABILITY,66.39 -US-UMd,18607,GRP_ROOT_BIOMASS,ROOT_BIOMASS_TOT_SPATIAL_REP_NUMBER,12 -US-UMd,18616,GRP_ROOT_BIOMASS,ROOT_BIOMASS_TOT_SPATIAL_REP_NUMBER,12 -US-UMd,18650,GRP_ROOT_BIOMASS,ROOT_BIOMASS_TOT_SPATIAL_REP_NUMBER,12 -US-UMd,18660,GRP_ROOT_BIOMASS,ROOT_BIOMASS_TOT_SPATIAL_REP_NUMBER,12 -US-UMd,18607,GRP_ROOT_BIOMASS,ROOT_BIOMASS_UNIT,gC m-2 -US-UMd,18616,GRP_ROOT_BIOMASS,ROOT_BIOMASS_UNIT,gC m-2 -US-UMd,18627,GRP_ROOT_BIOMASS,ROOT_BIOMASS_UNIT,gC m-2 -US-UMd,18631,GRP_ROOT_BIOMASS,ROOT_BIOMASS_UNIT,gC m-2 -US-UMd,18635,GRP_ROOT_BIOMASS,ROOT_BIOMASS_UNIT,gC m-2 -US-UMd,18639,GRP_ROOT_BIOMASS,ROOT_BIOMASS_UNIT,gC m-2 -US-UMd,18643,GRP_ROOT_BIOMASS,ROOT_BIOMASS_UNIT,gC m-2 -US-UMd,18650,GRP_ROOT_BIOMASS,ROOT_BIOMASS_UNIT,gC m-2 -US-UMd,18660,GRP_ROOT_BIOMASS,ROOT_BIOMASS_UNIT,gC m-2 -US-UMd,18666,GRP_ROOT_BIOMASS,ROOT_BIOMASS_UNIT,gC m-2 -US-UMd,18674,GRP_ROOT_BIOMASS,ROOT_BIOMASS_UNIT,gC m-2 -US-UMd,18682,GRP_ROOT_BIOMASS,ROOT_BIOMASS_UNIT,gC m-2 -US-UMd,18627,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_ZERO_REF,Top of mineral soil -US-UMd,18635,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_ZERO_REF,Top of mineral soil -US-UMd,18639,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_ZERO_REF,Top of mineral soil -US-UMd,18643,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_ZERO_REF,Top of mineral soil -US-UMd,18674,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_ZERO_REF,Top of mineral soil -US-UMd,18682,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_ZERO_REF,Top of mineral soil -US-UMd,18607,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_ZERO_REF,Top of surface -US-UMd,18616,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_ZERO_REF,Top of surface -US-UMd,18631,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_ZERO_REF,Top of surface -US-UMd,18650,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_ZERO_REF,Top of surface -US-UMd,18660,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_ZERO_REF,Top of surface -US-UMd,18666,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_ZERO_REF,Top of surface -US-UMd,18631,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MIN,0 -US-UMd,18635,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MIN,0 -US-UMd,18650,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MIN,0 -US-UMd,18666,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MIN,0 -US-UMd,18674,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MIN,0 -US-UMd,18639,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MIN,10 -US-UMd,18682,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MIN,10 -US-UMd,18627,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MIN,20 -US-UMd,18643,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MIN,20 -US-UMd,18660,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MIN,20 -US-UMd,18607,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MIN,40 -US-UMd,18616,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MIN,60 -US-UMd,18635,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MAX,10 -US-UMd,18674,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MAX,10 -US-UMd,18639,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MAX,20 -US-UMd,18650,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MAX,20 -US-UMd,18682,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MAX,20 -US-UMd,18627,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MAX,40 -US-UMd,18643,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MAX,40 -US-UMd,18660,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MAX,40 -US-UMd,18631,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MAX,5 -US-UMd,18666,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MAX,5 -US-UMd,18607,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MAX,60 -US-UMd,18616,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MAX,80 -US-UMd,18631,GRP_ROOT_BIOMASS,ROOT_BIOMASS_APPROACH,"225 cm^2 ""brownie"" of organic layer removed for fine root enumeration. Thickness of organic layer varied from site-to-site." -US-UMd,18666,GRP_ROOT_BIOMASS,ROOT_BIOMASS_APPROACH,"225 cm^2 ""brownie"" of organic layer removed for fine root enumeration. Thickness of organic layer varied from site-to-site." -US-UMd,18607,GRP_ROOT_BIOMASS,ROOT_BIOMASS_APPROACH,5.2 cm diameter soil core -US-UMd,18616,GRP_ROOT_BIOMASS,ROOT_BIOMASS_APPROACH,5.2 cm diameter soil core -US-UMd,18627,GRP_ROOT_BIOMASS,ROOT_BIOMASS_APPROACH,5.2 cm diameter soil core -US-UMd,18635,GRP_ROOT_BIOMASS,ROOT_BIOMASS_APPROACH,5.2 cm diameter soil core -US-UMd,18639,GRP_ROOT_BIOMASS,ROOT_BIOMASS_APPROACH,5.2 cm diameter soil core -US-UMd,18643,GRP_ROOT_BIOMASS,ROOT_BIOMASS_APPROACH,5.2 cm diameter soil core -US-UMd,18650,GRP_ROOT_BIOMASS,ROOT_BIOMASS_APPROACH,5.2 cm diameter soil core -US-UMd,18660,GRP_ROOT_BIOMASS,ROOT_BIOMASS_APPROACH,5.2 cm diameter soil core -US-UMd,18674,GRP_ROOT_BIOMASS,ROOT_BIOMASS_APPROACH,5.2 cm diameter soil core -US-UMd,18682,GRP_ROOT_BIOMASS,ROOT_BIOMASS_APPROACH,5.2 cm diameter soil core -US-UMd,18607,GRP_ROOT_BIOMASS,ROOT_BIOMASS_DATE,20060915 -US-UMd,18616,GRP_ROOT_BIOMASS,ROOT_BIOMASS_DATE,20060915 -US-UMd,18650,GRP_ROOT_BIOMASS,ROOT_BIOMASS_DATE,20060915 -US-UMd,18660,GRP_ROOT_BIOMASS,ROOT_BIOMASS_DATE,20060915 -US-UMd,18627,GRP_ROOT_BIOMASS,ROOT_BIOMASS_DATE,20080714 -US-UMd,18666,GRP_ROOT_BIOMASS,ROOT_BIOMASS_DATE,20080714 -US-UMd,18674,GRP_ROOT_BIOMASS,ROOT_BIOMASS_DATE,20080714 -US-UMd,18682,GRP_ROOT_BIOMASS,ROOT_BIOMASS_DATE,20080714 -US-UMd,18631,GRP_ROOT_BIOMASS,ROOT_BIOMASS_DATE,20090714 -US-UMd,18635,GRP_ROOT_BIOMASS,ROOT_BIOMASS_DATE,20090714 -US-UMd,18639,GRP_ROOT_BIOMASS,ROOT_BIOMASS_DATE,20090714 -US-UMd,18643,GRP_ROOT_BIOMASS,ROOT_BIOMASS_DATE,20090714 -US-UMd,18607,GRP_ROOT_BIOMASS,ROOT_BIOMASS_DATE_UNC,15 -US-UMd,18616,GRP_ROOT_BIOMASS,ROOT_BIOMASS_DATE_UNC,15 -US-UMd,18650,GRP_ROOT_BIOMASS,ROOT_BIOMASS_DATE_UNC,15 -US-UMd,18660,GRP_ROOT_BIOMASS,ROOT_BIOMASS_DATE_UNC,15 -US-UMd,18627,GRP_ROOT_BIOMASS,ROOT_BIOMASS_DATE_UNC,28 -US-UMd,18631,GRP_ROOT_BIOMASS,ROOT_BIOMASS_DATE_UNC,28 -US-UMd,18635,GRP_ROOT_BIOMASS,ROOT_BIOMASS_DATE_UNC,28 -US-UMd,18639,GRP_ROOT_BIOMASS,ROOT_BIOMASS_DATE_UNC,28 -US-UMd,18643,GRP_ROOT_BIOMASS,ROOT_BIOMASS_DATE_UNC,28 -US-UMd,18666,GRP_ROOT_BIOMASS,ROOT_BIOMASS_DATE_UNC,28 -US-UMd,18674,GRP_ROOT_BIOMASS,ROOT_BIOMASS_DATE_UNC,28 -US-UMd,18682,GRP_ROOT_BIOMASS,ROOT_BIOMASS_DATE_UNC,28 -US-UMd,19326,GRP_SA,SA,92 -US-UMd,19326,GRP_SA,SA_DATE,20150101 -US-UMd,19326,GRP_SA,SA_DATE_UNC,365 -US-UMd,19326,GRP_SA,SA_COMMENT,"After heavy logging, fire swept through the area in 1923 creating an even aged forest" -US-UMd,12370,GRP_SITE_CHAR,TERRAIN,Flat -US-UMd,12370,GRP_SITE_CHAR,ASPECT,FLAT -US-UMd,12370,GRP_SITE_CHAR,WIND_DIRECTION,W -US-UMd,12370,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,3000 -US-UMd,12371,GRP_SITE_DESC,SITE_DESC,"The UMBS Disturbance site is an artificial disturbance site that has recently been created as part of the Forest Accelerate Succession ExperimenT (FASET). In Spring 2008, every aspen and birch tree (>6,700, ~35% canopy LAI), the dominant early successional trees, were girdled over 39 ha of the FASET treatment plot to stimulate a disturbance that will move the forest into a later successional stage, dominated by maples, oaks, and white pine. This treatment caused aspen and birch mortality within 2 - 3 years. As a result of the changed canopy structure, there is a divergence in net ecosystem exchange between the control plot (enhanced carbon uptake) and the treatment plot (reduced carbon uptake)." -US-UMd,12372,GRP_SITE_FUNDING,SITE_FUNDING,DOE/NSF -US-UMd,18651,GRP_SNAG_MASS,SNAG_MASS,124.2 -US-UMd,18651,GRP_SNAG_MASS,SNAG_MASS_SPATIAL_VARIABILITY,109.7 -US-UMd,18651,GRP_SNAG_MASS,SNAG_MASS_SPATIAL_REP_NUMBER,22 -US-UMd,18651,GRP_SNAG_MASS,SNAG_MASS_UNIT,gC m-2 -US-UMd,18651,GRP_SNAG_MASS,SNAG_MASS_APPROACH,Manual census -US-UMd,18651,GRP_SNAG_MASS,SNAG_MASS_DATE,20100721 -US-UMd,18651,GRP_SNAG_MASS,SNAG_MASS_DATE_UNC,28 -US-UMd,18651,GRP_SNAG_MASS,SNAG_MASS_COMMENT,Snags represent trees that were living at time of first census (2006) and had died by the time of next census (2010). All Populus and Betula trees stem girdled spring of 2008. -US-UMd,18661,GRP_SNAG_MASS,SNAG_MASS,233.6 -US-UMd,18661,GRP_SNAG_MASS,SNAG_MASS_SPATIAL_VARIABILITY,127.4 -US-UMd,18661,GRP_SNAG_MASS,SNAG_MASS_SPATIAL_REP_NUMBER,22 -US-UMd,18661,GRP_SNAG_MASS,SNAG_MASS_UNIT,gC m-2 -US-UMd,18661,GRP_SNAG_MASS,SNAG_MASS_APPROACH,Manual census -US-UMd,18661,GRP_SNAG_MASS,SNAG_MASS_DATE,20110721 -US-UMd,18661,GRP_SNAG_MASS,SNAG_MASS_DATE_UNC,28 -US-UMd,18661,GRP_SNAG_MASS,SNAG_MASS_COMMENT,All Populus and Betula trees stem girdled spring of 2008. -US-UMd,28433,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION,"Entic Haplorthod, glacial till, sandy, thin Wisconsin sandy lake deposits" -US-UMd,28433,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION_TAXONOMY,Other -US-UMd,19295,GRP_SPP_O,SPP_O,Acer rubrum -US-UMd,19327,GRP_SPP_O,SPP_O,Acer rubrum -US-UMd,19302,GRP_SPP_O,SPP_O,Acer saccharum -US-UMd,19334,GRP_SPP_O,SPP_O,Acer saccharum -US-UMd,19309,GRP_SPP_O,SPP_O,Betula papyrifera -US-UMd,19341,GRP_SPP_O,SPP_O,Betula papyrifera -US-UMd,19205,GRP_SPP_O,SPP_O,Fagus grandifolia -US-UMd,19246,GRP_SPP_O,SPP_O,Fagus grandifolia -US-UMd,19224,GRP_SPP_O,SPP_O,other (5 species) -US-UMd,19315,GRP_SPP_O,SPP_O,other (5 species) -US-UMd,19212,GRP_SPP_O,SPP_O,Pinus resinosa -US-UMd,19252,GRP_SPP_O,SPP_O,Pinus resinosa -US-UMd,19219,GRP_SPP_O,SPP_O,Pinus strobus -US-UMd,19257,GRP_SPP_O,SPP_O,Pinus strobus -US-UMd,19262,GRP_SPP_O,SPP_O,Populus grandidentata -US-UMd,19272,GRP_SPP_O,SPP_O,Populus grandidentata -US-UMd,19265,GRP_SPP_O,SPP_O,Populus tremuloides -US-UMd,19279,GRP_SPP_O,SPP_O,Populus tremuloides -US-UMd,19267,GRP_SPP_O,SPP_O,Quercus rubra -US-UMd,19286,GRP_SPP_O,SPP_O,Quercus rubra -US-UMd,19224,GRP_SPP_O,SPP_O_PERC,0.5 -US-UMd,19315,GRP_SPP_O,SPP_O_PERC,0.72031555723 -US-UMd,19309,GRP_SPP_O,SPP_O_PERC,1.0173965089 -US-UMd,19205,GRP_SPP_O,SPP_O_PERC,1.1 -US-UMd,19246,GRP_SPP_O,SPP_O_PERC,1.4147982447 -US-UMd,19295,GRP_SPP_O,SPP_O_PERC,10.656671635 -US-UMd,19257,GRP_SPP_O,SPP_O_PERC,10.90926692 -US-UMd,19265,GRP_SPP_O,SPP_O_PERC,2.6786414259 -US-UMd,19262,GRP_SPP_O,SPP_O_PERC,28.493429028 -US-UMd,19212,GRP_SPP_O,SPP_O_PERC,3.1 -US-UMd,19252,GRP_SPP_O,SPP_O_PERC,3.1174624397 -US-UMd,19279,GRP_SPP_O,SPP_O_PERC,3.8 -US-UMd,19286,GRP_SPP_O,SPP_O_PERC,30.5 -US-UMd,19272,GRP_SPP_O,SPP_O_PERC,32.1 -US-UMd,19267,GRP_SPP_O,SPP_O_PERC,34.683086738 -US-UMd,19334,GRP_SPP_O,SPP_O_PERC,4.2 -US-UMd,19302,GRP_SPP_O,SPP_O_PERC,6.3089315023 -US-UMd,19327,GRP_SPP_O,SPP_O_PERC,7.8 -US-UMd,19341,GRP_SPP_O,SPP_O_PERC,8.3 -US-UMd,19219,GRP_SPP_O,SPP_O_PERC,8.6 -US-UMd,19205,GRP_SPP_O,SPP_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 22 - 0.08 ha plots and a single 1.13 ha plot for DBH of trees >= 8 cm. Counts of saplings < 8 cm DBH into 2 cm increment classes. Only saplings and seedlings that were >= 1.37m in height were included in sapling counts and thus biomass. Biomass estimated from species specific equations relating DBH to above ground woody biomass" -US-UMd,19212,GRP_SPP_O,SPP_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 22 - 0.08 ha plots and a single 1.13 ha plot for DBH of trees >= 8 cm. Counts of saplings < 8 cm DBH into 2 cm increment classes. Only saplings and seedlings that were >= 1.37m in height were included in sapling counts and thus biomass. Biomass estimated from species specific equations relating DBH to above ground woody biomass" -US-UMd,19219,GRP_SPP_O,SPP_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 22 - 0.08 ha plots and a single 1.13 ha plot for DBH of trees >= 8 cm. Counts of saplings < 8 cm DBH into 2 cm increment classes. Only saplings and seedlings that were >= 1.37m in height were included in sapling counts and thus biomass. Biomass estimated from species specific equations relating DBH to above ground woody biomass" -US-UMd,19224,GRP_SPP_O,SPP_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 22 - 0.08 ha plots and a single 1.13 ha plot for DBH of trees >= 8 cm. Counts of saplings < 8 cm DBH into 2 cm increment classes. Only saplings and seedlings that were >= 1.37m in height were included in sapling counts and thus biomass. Biomass estimated from species specific equations relating DBH to above ground woody biomass" -US-UMd,19246,GRP_SPP_O,SPP_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 22 - 0.08 ha plots and a single 1.13 ha plot for DBH of trees >= 8 cm. Counts of saplings < 8 cm DBH into 2 cm increment classes. Only saplings and seedlings that were >= 1.37m in height were included in sapling counts and thus biomass. Biomass estimated from species specific equations relating DBH to above ground woody biomass" -US-UMd,19252,GRP_SPP_O,SPP_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 22 - 0.08 ha plots and a single 1.13 ha plot for DBH of trees >= 8 cm. Counts of saplings < 8 cm DBH into 2 cm increment classes. Only saplings and seedlings that were >= 1.37m in height were included in sapling counts and thus biomass. Biomass estimated from species specific equations relating DBH to above ground woody biomass" -US-UMd,19257,GRP_SPP_O,SPP_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 22 - 0.08 ha plots and a single 1.13 ha plot for DBH of trees >= 8 cm. Counts of saplings < 8 cm DBH into 2 cm increment classes. Only saplings and seedlings that were >= 1.37m in height were included in sapling counts and thus biomass. Biomass estimated from species specific equations relating DBH to above ground woody biomass" -US-UMd,19262,GRP_SPP_O,SPP_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 22 - 0.08 ha plots and a single 1.13 ha plot for DBH of trees >= 8 cm. Counts of saplings < 8 cm DBH into 2 cm increment classes. Only saplings and seedlings that were >= 1.37m in height were included in sapling counts and thus biomass. Biomass estimated from species specific equations relating DBH to above ground woody biomass" -US-UMd,19265,GRP_SPP_O,SPP_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 22 - 0.08 ha plots and a single 1.13 ha plot for DBH of trees >= 8 cm. Counts of saplings < 8 cm DBH into 2 cm increment classes. Only saplings and seedlings that were >= 1.37m in height were included in sapling counts and thus biomass. Biomass estimated from species specific equations relating DBH to above ground woody biomass" -US-UMd,19267,GRP_SPP_O,SPP_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 22 - 0.08 ha plots and a single 1.13 ha plot for DBH of trees >= 8 cm. Counts of saplings < 8 cm DBH into 2 cm increment classes. Only saplings and seedlings that were >= 1.37m in height were included in sapling counts and thus biomass. Biomass estimated from species specific equations relating DBH to above ground woody biomass" -US-UMd,19272,GRP_SPP_O,SPP_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 22 - 0.08 ha plots and a single 1.13 ha plot for DBH of trees >= 8 cm. Counts of saplings < 8 cm DBH into 2 cm increment classes. Only saplings and seedlings that were >= 1.37m in height were included in sapling counts and thus biomass. Biomass estimated from species specific equations relating DBH to above ground woody biomass" -US-UMd,19279,GRP_SPP_O,SPP_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 22 - 0.08 ha plots and a single 1.13 ha plot for DBH of trees >= 8 cm. Counts of saplings < 8 cm DBH into 2 cm increment classes. Only saplings and seedlings that were >= 1.37m in height were included in sapling counts and thus biomass. Biomass estimated from species specific equations relating DBH to above ground woody biomass" -US-UMd,19286,GRP_SPP_O,SPP_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 22 - 0.08 ha plots and a single 1.13 ha plot for DBH of trees >= 8 cm. Counts of saplings < 8 cm DBH into 2 cm increment classes. Only saplings and seedlings that were >= 1.37m in height were included in sapling counts and thus biomass. Biomass estimated from species specific equations relating DBH to above ground woody biomass" -US-UMd,19295,GRP_SPP_O,SPP_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 22 - 0.08 ha plots and a single 1.13 ha plot for DBH of trees >= 8 cm. Counts of saplings < 8 cm DBH into 2 cm increment classes. Only saplings and seedlings that were >= 1.37m in height were included in sapling counts and thus biomass. Biomass estimated from species specific equations relating DBH to above ground woody biomass" -US-UMd,19302,GRP_SPP_O,SPP_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 22 - 0.08 ha plots and a single 1.13 ha plot for DBH of trees >= 8 cm. Counts of saplings < 8 cm DBH into 2 cm increment classes. Only saplings and seedlings that were >= 1.37m in height were included in sapling counts and thus biomass. Biomass estimated from species specific equations relating DBH to above ground woody biomass" -US-UMd,19309,GRP_SPP_O,SPP_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 22 - 0.08 ha plots and a single 1.13 ha plot for DBH of trees >= 8 cm. Counts of saplings < 8 cm DBH into 2 cm increment classes. Only saplings and seedlings that were >= 1.37m in height were included in sapling counts and thus biomass. Biomass estimated from species specific equations relating DBH to above ground woody biomass" -US-UMd,19315,GRP_SPP_O,SPP_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 22 - 0.08 ha plots and a single 1.13 ha plot for DBH of trees >= 8 cm. Counts of saplings < 8 cm DBH into 2 cm increment classes. Only saplings and seedlings that were >= 1.37m in height were included in sapling counts and thus biomass. Biomass estimated from species specific equations relating DBH to above ground woody biomass" -US-UMd,19327,GRP_SPP_O,SPP_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 22 - 0.08 ha plots and a single 1.13 ha plot for DBH of trees >= 8 cm. Counts of saplings < 8 cm DBH into 2 cm increment classes. Only saplings and seedlings that were >= 1.37m in height were included in sapling counts and thus biomass. Biomass estimated from species specific equations relating DBH to above ground woody biomass" -US-UMd,19334,GRP_SPP_O,SPP_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 22 - 0.08 ha plots and a single 1.13 ha plot for DBH of trees >= 8 cm. Counts of saplings < 8 cm DBH into 2 cm increment classes. Only saplings and seedlings that were >= 1.37m in height were included in sapling counts and thus biomass. Biomass estimated from species specific equations relating DBH to above ground woody biomass" -US-UMd,19341,GRP_SPP_O,SPP_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 22 - 0.08 ha plots and a single 1.13 ha plot for DBH of trees >= 8 cm. Counts of saplings < 8 cm DBH into 2 cm increment classes. Only saplings and seedlings that were >= 1.37m in height were included in sapling counts and thus biomass. Biomass estimated from species specific equations relating DBH to above ground woody biomass" -US-UMd,19205,GRP_SPP_O,SPP_DATE,20060714 -US-UMd,19212,GRP_SPP_O,SPP_DATE,20060714 -US-UMd,19219,GRP_SPP_O,SPP_DATE,20060714 -US-UMd,19224,GRP_SPP_O,SPP_DATE,20060714 -US-UMd,19272,GRP_SPP_O,SPP_DATE,20060714 -US-UMd,19279,GRP_SPP_O,SPP_DATE,20060714 -US-UMd,19286,GRP_SPP_O,SPP_DATE,20060714 -US-UMd,19327,GRP_SPP_O,SPP_DATE,20060714 -US-UMd,19334,GRP_SPP_O,SPP_DATE,20060714 -US-UMd,19341,GRP_SPP_O,SPP_DATE,20060714 -US-UMd,19246,GRP_SPP_O,SPP_DATE,20100714 -US-UMd,19252,GRP_SPP_O,SPP_DATE,20100714 -US-UMd,19257,GRP_SPP_O,SPP_DATE,20100714 -US-UMd,19262,GRP_SPP_O,SPP_DATE,20100714 -US-UMd,19265,GRP_SPP_O,SPP_DATE,20100714 -US-UMd,19267,GRP_SPP_O,SPP_DATE,20100714 -US-UMd,19295,GRP_SPP_O,SPP_DATE,20100714 -US-UMd,19302,GRP_SPP_O,SPP_DATE,20100714 -US-UMd,19309,GRP_SPP_O,SPP_DATE,20100714 -US-UMd,19315,GRP_SPP_O,SPP_DATE,20100714 -US-UMd,19205,GRP_SPP_O,SPP_DATE_UNC,28 -US-UMd,19212,GRP_SPP_O,SPP_DATE_UNC,28 -US-UMd,19219,GRP_SPP_O,SPP_DATE_UNC,28 -US-UMd,19224,GRP_SPP_O,SPP_DATE_UNC,28 -US-UMd,19246,GRP_SPP_O,SPP_DATE_UNC,28 -US-UMd,19252,GRP_SPP_O,SPP_DATE_UNC,28 -US-UMd,19257,GRP_SPP_O,SPP_DATE_UNC,28 -US-UMd,19262,GRP_SPP_O,SPP_DATE_UNC,28 -US-UMd,19265,GRP_SPP_O,SPP_DATE_UNC,28 -US-UMd,19267,GRP_SPP_O,SPP_DATE_UNC,28 -US-UMd,19272,GRP_SPP_O,SPP_DATE_UNC,28 -US-UMd,19279,GRP_SPP_O,SPP_DATE_UNC,28 -US-UMd,19286,GRP_SPP_O,SPP_DATE_UNC,28 -US-UMd,19295,GRP_SPP_O,SPP_DATE_UNC,28 -US-UMd,19302,GRP_SPP_O,SPP_DATE_UNC,28 -US-UMd,19309,GRP_SPP_O,SPP_DATE_UNC,28 -US-UMd,19315,GRP_SPP_O,SPP_DATE_UNC,28 -US-UMd,19327,GRP_SPP_O,SPP_DATE_UNC,28 -US-UMd,19334,GRP_SPP_O,SPP_DATE_UNC,28 -US-UMd,19341,GRP_SPP_O,SPP_DATE_UNC,28 -US-UMd,19205,GRP_SPP_O,SPP_COMMENT,Only species with biomass >= 0.1% of total biomass included in results -US-UMd,19212,GRP_SPP_O,SPP_COMMENT,Only species with biomass >= 0.1% of total biomass included in results -US-UMd,19219,GRP_SPP_O,SPP_COMMENT,Only species with biomass >= 0.1% of total biomass included in results -US-UMd,19224,GRP_SPP_O,SPP_COMMENT,Only species with biomass >= 0.1% of total biomass included in results -US-UMd,19246,GRP_SPP_O,SPP_COMMENT,Only species with biomass >= 0.1% of total biomass included in results -US-UMd,19252,GRP_SPP_O,SPP_COMMENT,Only species with biomass >= 0.1% of total biomass included in results -US-UMd,19257,GRP_SPP_O,SPP_COMMENT,Only species with biomass >= 0.1% of total biomass included in results -US-UMd,19262,GRP_SPP_O,SPP_COMMENT,Only species with biomass >= 0.1% of total biomass included in results -US-UMd,19265,GRP_SPP_O,SPP_COMMENT,Only species with biomass >= 0.1% of total biomass included in results -US-UMd,19267,GRP_SPP_O,SPP_COMMENT,Only species with biomass >= 0.1% of total biomass included in results -US-UMd,19272,GRP_SPP_O,SPP_COMMENT,Only species with biomass >= 0.1% of total biomass included in results -US-UMd,19279,GRP_SPP_O,SPP_COMMENT,Only species with biomass >= 0.1% of total biomass included in results -US-UMd,19286,GRP_SPP_O,SPP_COMMENT,Only species with biomass >= 0.1% of total biomass included in results -US-UMd,19295,GRP_SPP_O,SPP_COMMENT,Only species with biomass >= 0.1% of total biomass included in results -US-UMd,19302,GRP_SPP_O,SPP_COMMENT,Only species with biomass >= 0.1% of total biomass included in results -US-UMd,19309,GRP_SPP_O,SPP_COMMENT,Only species with biomass >= 0.1% of total biomass included in results -US-UMd,19315,GRP_SPP_O,SPP_COMMENT,Only species with biomass >= 0.1% of total biomass included in results -US-UMd,19327,GRP_SPP_O,SPP_COMMENT,Only species with biomass >= 0.1% of total biomass included in results -US-UMd,19334,GRP_SPP_O,SPP_COMMENT,Only species with biomass >= 0.1% of total biomass included in results -US-UMd,19341,GRP_SPP_O,SPP_COMMENT,Only species with biomass >= 0.1% of total biomass included in results -US-UMd,19296,GRP_SPP_U,SPP_U,Acer pensylvanicum -US-UMd,19328,GRP_SPP_U,SPP_U,Acer pensylvanicum -US-UMd,19303,GRP_SPP_U,SPP_U,Acer rubra -US-UMd,19335,GRP_SPP_U,SPP_U,Acer rubra -US-UMd,19199,GRP_SPP_U,SPP_U,Acer saccharum -US-UMd,19310,GRP_SPP_U,SPP_U,Acer saccharum -US-UMd,19206,GRP_SPP_U,SPP_U,Amelanchier spp -US-UMd,19247,GRP_SPP_U,SPP_U,Amelanchier spp -US-UMd,19213,GRP_SPP_U,SPP_U,Betula papyrifera -US-UMd,19253,GRP_SPP_U,SPP_U,Betula papyrifera -US-UMd,19220,GRP_SPP_U,SPP_U,Fagus grandifolia -US-UMd,19258,GRP_SPP_U,SPP_U,Fagus grandifolia -US-UMd,19263,GRP_SPP_U,SPP_U,Ostrya virginiana -US-UMd,19273,GRP_SPP_U,SPP_U,Ostrya virginiana -US-UMd,19266,GRP_SPP_U,SPP_U,Pinus resinosa -US-UMd,19280,GRP_SPP_U,SPP_U,Pinus resinosa -US-UMd,19287,GRP_SPP_U,SPP_U,Pinus strobus -US-UMd,19314,GRP_SPP_U,SPP_U,Pinus strobus -US-UMd,19225,GRP_SPP_U,SPP_U,Populus grandidentata -US-UMd,19316,GRP_SPP_U,SPP_U,Populus grandidentata -US-UMd,19231,GRP_SPP_U,SPP_U,Populus tremuloides -US-UMd,19237,GRP_SPP_U,SPP_U,Quercus rubra -US-UMd,19317,GRP_SPP_U,SPP_U,Quercus rubra -US-UMd,19243,GRP_SPP_U,SPP_U,Tsuga canadensis -US-UMd,19318,GRP_SPP_U,SPP_U,Tsuga canadensis -US-UMd,19318,GRP_SPP_U,SPP_U_PERC,0.03 -US-UMd,19231,GRP_SPP_U,SPP_U_PERC,0.1 -US-UMd,19253,GRP_SPP_U,SPP_U_PERC,0.19433031435 -US-UMd,19316,GRP_SPP_U,SPP_U_PERC,0.24104425601 -US-UMd,19243,GRP_SPP_U,SPP_U_PERC,0.6 -US-UMd,19273,GRP_SPP_U,SPP_U_PERC,0.6 -US-UMd,19263,GRP_SPP_U,SPP_U_PERC,0.97064448134 -US-UMd,19213,GRP_SPP_U,SPP_U_PERC,1.7 -US-UMd,19328,GRP_SPP_U,SPP_U_PERC,1.9 -US-UMd,19310,GRP_SPP_U,SPP_U_PERC,12.860068694 -US-UMd,19199,GRP_SPP_U,SPP_U_PERC,14.9 -US-UMd,19220,GRP_SPP_U,SPP_U_PERC,19.3 -US-UMd,19303,GRP_SPP_U,SPP_U_PERC,19.781166364 -US-UMd,19225,GRP_SPP_U,SPP_U_PERC,2 -US-UMd,19296,GRP_SPP_U,SPP_U_PERC,2.3205346038 -US-UMd,19335,GRP_SPP_U,SPP_U_PERC,20.6 -US-UMd,19258,GRP_SPP_U,SPP_U_PERC,21.720823751 -US-UMd,19287,GRP_SPP_U,SPP_U_PERC,23.6 -US-UMd,19314,GRP_SPP_U,SPP_U_PERC,25.040443426 -US-UMd,19280,GRP_SPP_U,SPP_U_PERC,3.2 -US-UMd,19266,GRP_SPP_U,SPP_U_PERC,3.3446855143 -US-UMd,19247,GRP_SPP_U,SPP_U_PERC,3.5877230265 -US-UMd,19206,GRP_SPP_U,SPP_U_PERC,4 -US-UMd,19237,GRP_SPP_U,SPP_U_PERC,7.3 -US-UMd,19317,GRP_SPP_U,SPP_U_PERC,9.6499108147 -US-UMd,19199,GRP_SPP_U,SPP_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 22 - 0.08 ha plots and a single 1.13 ha plot for DBH of trees >= 8 cm. Counts of saplings < 8 cm DBH into 2 cm increment classes. Only saplings and seedlings that were >= 1.37m in height were included in sapling counts and thus biomass. Biomass estimated from species specific equations relating DBH to above ground woody biomass" -US-UMd,19206,GRP_SPP_U,SPP_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 22 - 0.08 ha plots and a single 1.13 ha plot for DBH of trees >= 8 cm. Counts of saplings < 8 cm DBH into 2 cm increment classes. Only saplings and seedlings that were >= 1.37m in height were included in sapling counts and thus biomass. Biomass estimated from species specific equations relating DBH to above ground woody biomass" -US-UMd,19213,GRP_SPP_U,SPP_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 22 - 0.08 ha plots and a single 1.13 ha plot for DBH of trees >= 8 cm. Counts of saplings < 8 cm DBH into 2 cm increment classes. Only saplings and seedlings that were >= 1.37m in height were included in sapling counts and thus biomass. Biomass estimated from species specific equations relating DBH to above ground woody biomass" -US-UMd,19220,GRP_SPP_U,SPP_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 22 - 0.08 ha plots and a single 1.13 ha plot for DBH of trees >= 8 cm. Counts of saplings < 8 cm DBH into 2 cm increment classes. Only saplings and seedlings that were >= 1.37m in height were included in sapling counts and thus biomass. Biomass estimated from species specific equations relating DBH to above ground woody biomass" -US-UMd,19225,GRP_SPP_U,SPP_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 22 - 0.08 ha plots and a single 1.13 ha plot for DBH of trees >= 8 cm. Counts of saplings < 8 cm DBH into 2 cm increment classes. Only saplings and seedlings that were >= 1.37m in height were included in sapling counts and thus biomass. Biomass estimated from species specific equations relating DBH to above ground woody biomass" -US-UMd,19231,GRP_SPP_U,SPP_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 22 - 0.08 ha plots and a single 1.13 ha plot for DBH of trees >= 8 cm. Counts of saplings < 8 cm DBH into 2 cm increment classes. Only saplings and seedlings that were >= 1.37m in height were included in sapling counts and thus biomass. Biomass estimated from species specific equations relating DBH to above ground woody biomass" -US-UMd,19237,GRP_SPP_U,SPP_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 22 - 0.08 ha plots and a single 1.13 ha plot for DBH of trees >= 8 cm. Counts of saplings < 8 cm DBH into 2 cm increment classes. Only saplings and seedlings that were >= 1.37m in height were included in sapling counts and thus biomass. Biomass estimated from species specific equations relating DBH to above ground woody biomass" -US-UMd,19243,GRP_SPP_U,SPP_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 22 - 0.08 ha plots and a single 1.13 ha plot for DBH of trees >= 8 cm. Counts of saplings < 8 cm DBH into 2 cm increment classes. Only saplings and seedlings that were >= 1.37m in height were included in sapling counts and thus biomass. Biomass estimated from species specific equations relating DBH to above ground woody biomass" -US-UMd,19247,GRP_SPP_U,SPP_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 22 - 0.08 ha plots and a single 1.13 ha plot for DBH of trees >= 8 cm. Counts of saplings < 8 cm DBH into 2 cm increment classes. Only saplings and seedlings that were >= 1.37m in height were included in sapling counts and thus biomass. Biomass estimated from species specific equations relating DBH to above ground woody biomass" -US-UMd,19253,GRP_SPP_U,SPP_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 22 - 0.08 ha plots and a single 1.13 ha plot for DBH of trees >= 8 cm. Counts of saplings < 8 cm DBH into 2 cm increment classes. Only saplings and seedlings that were >= 1.37m in height were included in sapling counts and thus biomass. Biomass estimated from species specific equations relating DBH to above ground woody biomass" -US-UMd,19258,GRP_SPP_U,SPP_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 22 - 0.08 ha plots and a single 1.13 ha plot for DBH of trees >= 8 cm. Counts of saplings < 8 cm DBH into 2 cm increment classes. Only saplings and seedlings that were >= 1.37m in height were included in sapling counts and thus biomass. Biomass estimated from species specific equations relating DBH to above ground woody biomass" -US-UMd,19263,GRP_SPP_U,SPP_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 22 - 0.08 ha plots and a single 1.13 ha plot for DBH of trees >= 8 cm. Counts of saplings < 8 cm DBH into 2 cm increment classes. Only saplings and seedlings that were >= 1.37m in height were included in sapling counts and thus biomass. Biomass estimated from species specific equations relating DBH to above ground woody biomass" -US-UMd,19266,GRP_SPP_U,SPP_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 22 - 0.08 ha plots and a single 1.13 ha plot for DBH of trees >= 8 cm. Counts of saplings < 8 cm DBH into 2 cm increment classes. Only saplings and seedlings that were >= 1.37m in height were included in sapling counts and thus biomass. Biomass estimated from species specific equations relating DBH to above ground woody biomass" -US-UMd,19273,GRP_SPP_U,SPP_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 22 - 0.08 ha plots and a single 1.13 ha plot for DBH of trees >= 8 cm. Counts of saplings < 8 cm DBH into 2 cm increment classes. Only saplings and seedlings that were >= 1.37m in height were included in sapling counts and thus biomass. Biomass estimated from species specific equations relating DBH to above ground woody biomass" -US-UMd,19280,GRP_SPP_U,SPP_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 22 - 0.08 ha plots and a single 1.13 ha plot for DBH of trees >= 8 cm. Counts of saplings < 8 cm DBH into 2 cm increment classes. Only saplings and seedlings that were >= 1.37m in height were included in sapling counts and thus biomass. Biomass estimated from species specific equations relating DBH to above ground woody biomass" -US-UMd,19287,GRP_SPP_U,SPP_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 22 - 0.08 ha plots and a single 1.13 ha plot for DBH of trees >= 8 cm. Counts of saplings < 8 cm DBH into 2 cm increment classes. Only saplings and seedlings that were >= 1.37m in height were included in sapling counts and thus biomass. Biomass estimated from species specific equations relating DBH to above ground woody biomass" -US-UMd,19296,GRP_SPP_U,SPP_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 22 - 0.08 ha plots and a single 1.13 ha plot for DBH of trees >= 8 cm. Counts of saplings < 8 cm DBH into 2 cm increment classes. Only saplings and seedlings that were >= 1.37m in height were included in sapling counts and thus biomass. Biomass estimated from species specific equations relating DBH to above ground woody biomass" -US-UMd,19303,GRP_SPP_U,SPP_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 22 - 0.08 ha plots and a single 1.13 ha plot for DBH of trees >= 8 cm. Counts of saplings < 8 cm DBH into 2 cm increment classes. Only saplings and seedlings that were >= 1.37m in height were included in sapling counts and thus biomass. Biomass estimated from species specific equations relating DBH to above ground woody biomass" -US-UMd,19310,GRP_SPP_U,SPP_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 22 - 0.08 ha plots and a single 1.13 ha plot for DBH of trees >= 8 cm. Counts of saplings < 8 cm DBH into 2 cm increment classes. Only saplings and seedlings that were >= 1.37m in height were included in sapling counts and thus biomass. Biomass estimated from species specific equations relating DBH to above ground woody biomass" -US-UMd,19314,GRP_SPP_U,SPP_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 22 - 0.08 ha plots and a single 1.13 ha plot for DBH of trees >= 8 cm. Counts of saplings < 8 cm DBH into 2 cm increment classes. Only saplings and seedlings that were >= 1.37m in height were included in sapling counts and thus biomass. Biomass estimated from species specific equations relating DBH to above ground woody biomass" -US-UMd,19316,GRP_SPP_U,SPP_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 22 - 0.08 ha plots and a single 1.13 ha plot for DBH of trees >= 8 cm. Counts of saplings < 8 cm DBH into 2 cm increment classes. Only saplings and seedlings that were >= 1.37m in height were included in sapling counts and thus biomass. Biomass estimated from species specific equations relating DBH to above ground woody biomass" -US-UMd,19317,GRP_SPP_U,SPP_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 22 - 0.08 ha plots and a single 1.13 ha plot for DBH of trees >= 8 cm. Counts of saplings < 8 cm DBH into 2 cm increment classes. Only saplings and seedlings that were >= 1.37m in height were included in sapling counts and thus biomass. Biomass estimated from species specific equations relating DBH to above ground woody biomass" -US-UMd,19318,GRP_SPP_U,SPP_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 22 - 0.08 ha plots and a single 1.13 ha plot for DBH of trees >= 8 cm. Counts of saplings < 8 cm DBH into 2 cm increment classes. Only saplings and seedlings that were >= 1.37m in height were included in sapling counts and thus biomass. Biomass estimated from species specific equations relating DBH to above ground woody biomass" -US-UMd,19328,GRP_SPP_U,SPP_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 22 - 0.08 ha plots and a single 1.13 ha plot for DBH of trees >= 8 cm. Counts of saplings < 8 cm DBH into 2 cm increment classes. Only saplings and seedlings that were >= 1.37m in height were included in sapling counts and thus biomass. Biomass estimated from species specific equations relating DBH to above ground woody biomass" -US-UMd,19335,GRP_SPP_U,SPP_APPROACH,"Manual measurement of Diameter at breast height (DBH, 1.37m) of trees in 22 - 0.08 ha plots and a single 1.13 ha plot for DBH of trees >= 8 cm. Counts of saplings < 8 cm DBH into 2 cm increment classes. Only saplings and seedlings that were >= 1.37m in height were included in sapling counts and thus biomass. Biomass estimated from species specific equations relating DBH to above ground woody biomass" -US-UMd,19199,GRP_SPP_U,SPP_DATE,20060714 -US-UMd,19206,GRP_SPP_U,SPP_DATE,20060714 -US-UMd,19213,GRP_SPP_U,SPP_DATE,20060714 -US-UMd,19220,GRP_SPP_U,SPP_DATE,20060714 -US-UMd,19225,GRP_SPP_U,SPP_DATE,20060714 -US-UMd,19231,GRP_SPP_U,SPP_DATE,20060714 -US-UMd,19237,GRP_SPP_U,SPP_DATE,20060714 -US-UMd,19243,GRP_SPP_U,SPP_DATE,20060714 -US-UMd,19273,GRP_SPP_U,SPP_DATE,20060714 -US-UMd,19280,GRP_SPP_U,SPP_DATE,20060714 -US-UMd,19287,GRP_SPP_U,SPP_DATE,20060714 -US-UMd,19328,GRP_SPP_U,SPP_DATE,20060714 -US-UMd,19335,GRP_SPP_U,SPP_DATE,20060714 -US-UMd,19247,GRP_SPP_U,SPP_DATE,20100714 -US-UMd,19253,GRP_SPP_U,SPP_DATE,20100714 -US-UMd,19258,GRP_SPP_U,SPP_DATE,20100714 -US-UMd,19263,GRP_SPP_U,SPP_DATE,20100714 -US-UMd,19266,GRP_SPP_U,SPP_DATE,20100714 -US-UMd,19296,GRP_SPP_U,SPP_DATE,20100714 -US-UMd,19303,GRP_SPP_U,SPP_DATE,20100714 -US-UMd,19310,GRP_SPP_U,SPP_DATE,20100714 -US-UMd,19314,GRP_SPP_U,SPP_DATE,20100714 -US-UMd,19316,GRP_SPP_U,SPP_DATE,20100714 -US-UMd,19317,GRP_SPP_U,SPP_DATE,20100714 -US-UMd,19318,GRP_SPP_U,SPP_DATE,20100714 -US-UMd,19199,GRP_SPP_U,SPP_DATE_UNC,28 -US-UMd,19206,GRP_SPP_U,SPP_DATE_UNC,28 -US-UMd,19213,GRP_SPP_U,SPP_DATE_UNC,28 -US-UMd,19220,GRP_SPP_U,SPP_DATE_UNC,28 -US-UMd,19225,GRP_SPP_U,SPP_DATE_UNC,28 -US-UMd,19231,GRP_SPP_U,SPP_DATE_UNC,28 -US-UMd,19237,GRP_SPP_U,SPP_DATE_UNC,28 -US-UMd,19243,GRP_SPP_U,SPP_DATE_UNC,28 -US-UMd,19247,GRP_SPP_U,SPP_DATE_UNC,28 -US-UMd,19253,GRP_SPP_U,SPP_DATE_UNC,28 -US-UMd,19258,GRP_SPP_U,SPP_DATE_UNC,28 -US-UMd,19263,GRP_SPP_U,SPP_DATE_UNC,28 -US-UMd,19266,GRP_SPP_U,SPP_DATE_UNC,28 -US-UMd,19273,GRP_SPP_U,SPP_DATE_UNC,28 -US-UMd,19280,GRP_SPP_U,SPP_DATE_UNC,28 -US-UMd,19287,GRP_SPP_U,SPP_DATE_UNC,28 -US-UMd,19296,GRP_SPP_U,SPP_DATE_UNC,28 -US-UMd,19303,GRP_SPP_U,SPP_DATE_UNC,28 -US-UMd,19310,GRP_SPP_U,SPP_DATE_UNC,28 -US-UMd,19314,GRP_SPP_U,SPP_DATE_UNC,28 -US-UMd,19316,GRP_SPP_U,SPP_DATE_UNC,28 -US-UMd,19317,GRP_SPP_U,SPP_DATE_UNC,28 -US-UMd,19318,GRP_SPP_U,SPP_DATE_UNC,28 -US-UMd,19328,GRP_SPP_U,SPP_DATE_UNC,28 -US-UMd,19335,GRP_SPP_U,SPP_DATE_UNC,28 -US-UMd,19199,GRP_SPP_U,SPP_COMMENT,Only species with biomass >= 0.1% of total biomass included in results -US-UMd,19206,GRP_SPP_U,SPP_COMMENT,Only species with biomass >= 0.1% of total biomass included in results -US-UMd,19213,GRP_SPP_U,SPP_COMMENT,Only species with biomass >= 0.1% of total biomass included in results -US-UMd,19220,GRP_SPP_U,SPP_COMMENT,Only species with biomass >= 0.1% of total biomass included in results -US-UMd,19225,GRP_SPP_U,SPP_COMMENT,Only species with biomass >= 0.1% of total biomass included in results -US-UMd,19231,GRP_SPP_U,SPP_COMMENT,Only species with biomass >= 0.1% of total biomass included in results -US-UMd,19237,GRP_SPP_U,SPP_COMMENT,Only species with biomass >= 0.1% of total biomass included in results -US-UMd,19243,GRP_SPP_U,SPP_COMMENT,Only species with biomass >= 0.1% of total biomass included in results -US-UMd,19247,GRP_SPP_U,SPP_COMMENT,Only species with biomass >= 0.1% of total biomass included in results -US-UMd,19253,GRP_SPP_U,SPP_COMMENT,Only species with biomass >= 0.1% of total biomass included in results -US-UMd,19258,GRP_SPP_U,SPP_COMMENT,Only species with biomass >= 0.1% of total biomass included in results -US-UMd,19263,GRP_SPP_U,SPP_COMMENT,Only species with biomass >= 0.1% of total biomass included in results -US-UMd,19266,GRP_SPP_U,SPP_COMMENT,Only species with biomass >= 0.1% of total biomass included in results -US-UMd,19273,GRP_SPP_U,SPP_COMMENT,Only species with biomass >= 0.1% of total biomass included in results -US-UMd,19280,GRP_SPP_U,SPP_COMMENT,Only species with biomass >= 0.1% of total biomass included in results -US-UMd,19287,GRP_SPP_U,SPP_COMMENT,Only species with biomass >= 0.1% of total biomass included in results -US-UMd,19296,GRP_SPP_U,SPP_COMMENT,Only species with biomass >= 0.1% of total biomass included in results -US-UMd,19303,GRP_SPP_U,SPP_COMMENT,Only species with biomass >= 0.1% of total biomass included in results -US-UMd,19310,GRP_SPP_U,SPP_COMMENT,Only species with biomass >= 0.1% of total biomass included in results -US-UMd,19314,GRP_SPP_U,SPP_COMMENT,Only species with biomass >= 0.1% of total biomass included in results -US-UMd,19316,GRP_SPP_U,SPP_COMMENT,Only species with biomass >= 0.1% of total biomass included in results -US-UMd,19317,GRP_SPP_U,SPP_COMMENT,Only species with biomass >= 0.1% of total biomass included in results -US-UMd,19318,GRP_SPP_U,SPP_COMMENT,Only species with biomass >= 0.1% of total biomass included in results -US-UMd,19328,GRP_SPP_U,SPP_COMMENT,Only species with biomass >= 0.1% of total biomass included in results -US-UMd,19335,GRP_SPP_U,SPP_COMMENT,Only species with biomass >= 0.1% of total biomass included in results -US-UMd,12373,GRP_STATE,STATE,MI -US-UMd,18688,GRP_STEM_INCR,STEM_INCR,0.006 -US-UMd,18688,GRP_STEM_INCR,STEM_INCR_SPATIAL_VARIABILITY,0.017 -US-UMd,18688,GRP_STEM_INCR,STEM_INCR_SPATIAL_REP_NUMBER,131 -US-UMd,18688,GRP_STEM_INCR,STEM_INCR_DIAM,20.33 -US-UMd,18688,GRP_STEM_INCR,STEM_INCR_NUM,131 -US-UMd,18688,GRP_STEM_INCR,STEM_INCR_APPROACH,Band Dendrometers -US-UMd,18688,GRP_STEM_INCR,STEM_INCR_DATE_START,20081104 -US-UMd,18688,GRP_STEM_INCR,STEM_INCR_DATE_END,20090511 -US-UMd,18688,GRP_STEM_INCR,STEM_INCR_DATE_UNC,0 -US-UMd,18688,GRP_STEM_INCR,STEM_INCR_COMMENT,"Within year data from a single, circular 1.13 ha plot with flux tower at the center of the plot. Standard deviation and means determined from number of stems measured in the plot. The same trees are measured repeatedly for within year data. No Populus or Betula outfitted with bands due to stem girdling of those species spring of 2008." -US-UMd,18685,GRP_STEM_INCR,STEM_INCR,0.016 -US-UMd,18685,GRP_STEM_INCR,STEM_INCR_SPATIAL_VARIABILITY,0.015 -US-UMd,18685,GRP_STEM_INCR,STEM_INCR_SPATIAL_REP_NUMBER,131 -US-UMd,18685,GRP_STEM_INCR,STEM_INCR_DIAM,20.33 -US-UMd,18685,GRP_STEM_INCR,STEM_INCR_NUM,131 -US-UMd,18685,GRP_STEM_INCR,STEM_INCR_APPROACH,Band Dendrometers -US-UMd,18685,GRP_STEM_INCR,STEM_INCR_DATE_START,20080811 -US-UMd,18685,GRP_STEM_INCR,STEM_INCR_DATE_END,20081104 -US-UMd,18685,GRP_STEM_INCR,STEM_INCR_DATE_UNC,0 -US-UMd,18685,GRP_STEM_INCR,STEM_INCR_COMMENT,"Within year data from a single, circular 1.13 ha plot with flux tower at the center of the plot. Standard deviation and means determined from number of stems measured in the plot. The same trees are measured repeatedly for within year data. No Populus or Betula outfitted with bands due to stem girdling of those species spring of 2008." -US-UMd,18694,GRP_STEM_INCR,STEM_INCR,0.021 -US-UMd,18694,GRP_STEM_INCR,STEM_INCR_SPATIAL_VARIABILITY,0.018 -US-UMd,18694,GRP_STEM_INCR,STEM_INCR_SPATIAL_REP_NUMBER,131 -US-UMd,18694,GRP_STEM_INCR,STEM_INCR_DIAM,20.4 -US-UMd,18694,GRP_STEM_INCR,STEM_INCR_NUM,131 -US-UMd,18694,GRP_STEM_INCR,STEM_INCR_APPROACH,Band Dendrometers -US-UMd,18694,GRP_STEM_INCR,STEM_INCR_DATE_START,20090529 -US-UMd,18694,GRP_STEM_INCR,STEM_INCR_DATE_END,20090617 -US-UMd,18694,GRP_STEM_INCR,STEM_INCR_DATE_UNC,0 -US-UMd,18694,GRP_STEM_INCR,STEM_INCR_COMMENT,"Within year data from a single, circular 1.13 ha plot with flux tower at the center of the plot. Standard deviation and means determined from number of stems measured in the plot. The same trees are measured repeatedly for within year data. No Populus or Betula outfitted with bands due to stem girdling of those species spring of 2008." -US-UMd,18640,GRP_STEM_INCR,STEM_INCR,0.023 -US-UMd,18640,GRP_STEM_INCR,STEM_INCR_SPATIAL_VARIABILITY,0.028 -US-UMd,18640,GRP_STEM_INCR,STEM_INCR_SPATIAL_REP_NUMBER,131 -US-UMd,18640,GRP_STEM_INCR,STEM_INCR_DIAM,20.31 -US-UMd,18640,GRP_STEM_INCR,STEM_INCR_NUM,131 -US-UMd,18640,GRP_STEM_INCR,STEM_INCR_APPROACH,Band Dendrometers -US-UMd,18640,GRP_STEM_INCR,STEM_INCR_DATE_START,20080718 -US-UMd,18640,GRP_STEM_INCR,STEM_INCR_DATE_END,20080811 -US-UMd,18640,GRP_STEM_INCR,STEM_INCR_DATE_UNC,0 -US-UMd,18640,GRP_STEM_INCR,STEM_INCR_COMMENT,"Within year data from a single, circular 1.13 ha plot with flux tower at the center of the plot. Standard deviation and means determined from number of stems measured in the plot. The same trees are measured repeatedly for within year data. No Populus or Betula outfitted with bands due to stem girdling of those species spring of 2008." -US-UMd,18698,GRP_STEM_INCR,STEM_INCR,0.026 -US-UMd,18698,GRP_STEM_INCR,STEM_INCR_SPATIAL_VARIABILITY,0.022 -US-UMd,18698,GRP_STEM_INCR,STEM_INCR_SPATIAL_REP_NUMBER,131 -US-UMd,18698,GRP_STEM_INCR,STEM_INCR_DIAM,20.48 -US-UMd,18698,GRP_STEM_INCR,STEM_INCR_NUM,131 -US-UMd,18698,GRP_STEM_INCR,STEM_INCR_APPROACH,Band Dendrometers -US-UMd,18698,GRP_STEM_INCR,STEM_INCR_DATE_START,20090714 -US-UMd,18698,GRP_STEM_INCR,STEM_INCR_DATE_END,20090803 -US-UMd,18698,GRP_STEM_INCR,STEM_INCR_DATE_UNC,0 -US-UMd,18698,GRP_STEM_INCR,STEM_INCR_COMMENT,"Within year data from a single, circular 1.13 ha plot with flux tower at the center of the plot. Standard deviation and means determined from number of stems measured in the plot. The same trees are measured repeatedly for within year data. No Populus or Betula outfitted with bands due to stem girdling of those species spring of 2008." -US-UMd,18691,GRP_STEM_INCR,STEM_INCR,0.04 -US-UMd,18691,GRP_STEM_INCR,STEM_INCR_SPATIAL_VARIABILITY,0.041 -US-UMd,18691,GRP_STEM_INCR,STEM_INCR_SPATIAL_REP_NUMBER,131 -US-UMd,18691,GRP_STEM_INCR,STEM_INCR_DIAM,20.37 -US-UMd,18691,GRP_STEM_INCR,STEM_INCR_NUM,131 -US-UMd,18691,GRP_STEM_INCR,STEM_INCR_APPROACH,Band Dendrometers -US-UMd,18691,GRP_STEM_INCR,STEM_INCR_DATE_START,20090511 -US-UMd,18691,GRP_STEM_INCR,STEM_INCR_DATE_END,20090529 -US-UMd,18691,GRP_STEM_INCR,STEM_INCR_DATE_UNC,0 -US-UMd,18691,GRP_STEM_INCR,STEM_INCR_COMMENT,"Within year data from a single, circular 1.13 ha plot with flux tower at the center of the plot. Standard deviation and means determined from number of stems measured in the plot. The same trees are measured repeatedly for within year data. No Populus or Betula outfitted with bands due to stem girdling of those species spring of 2008." -US-UMd,18700,GRP_STEM_INCR,STEM_INCR,0.042 -US-UMd,18700,GRP_STEM_INCR,STEM_INCR_SPATIAL_VARIABILITY,0.037 -US-UMd,18700,GRP_STEM_INCR,STEM_INCR_SPATIAL_REP_NUMBER,131 -US-UMd,18700,GRP_STEM_INCR,STEM_INCR_DIAM,20.52 -US-UMd,18700,GRP_STEM_INCR,STEM_INCR_NUM,131 -US-UMd,18700,GRP_STEM_INCR,STEM_INCR_APPROACH,Band Dendrometers -US-UMd,18700,GRP_STEM_INCR,STEM_INCR_DATE_START,20090803 -US-UMd,18700,GRP_STEM_INCR,STEM_INCR_DATE_END,20091106 -US-UMd,18700,GRP_STEM_INCR,STEM_INCR_DATE_UNC,0 -US-UMd,18700,GRP_STEM_INCR,STEM_INCR_COMMENT,"Within year data from a single, circular 1.13 ha plot with flux tower at the center of the plot. Standard deviation and means determined from number of stems measured in the plot. The same trees are measured repeatedly for within year data. No Populus or Betula outfitted with bands due to stem girdling of those species spring of 2008." -US-UMd,18636,GRP_STEM_INCR,STEM_INCR,0.05 -US-UMd,18636,GRP_STEM_INCR,STEM_INCR_SPATIAL_VARIABILITY,0.035 -US-UMd,18636,GRP_STEM_INCR,STEM_INCR_SPATIAL_REP_NUMBER,131 -US-UMd,18636,GRP_STEM_INCR,STEM_INCR_DIAM,20.29 -US-UMd,18636,GRP_STEM_INCR,STEM_INCR_NUM,131 -US-UMd,18636,GRP_STEM_INCR,STEM_INCR_APPROACH,Band Dendrometers -US-UMd,18636,GRP_STEM_INCR,STEM_INCR_DATE_START,20080625 -US-UMd,18636,GRP_STEM_INCR,STEM_INCR_DATE_END,20080718 -US-UMd,18636,GRP_STEM_INCR,STEM_INCR_DATE_UNC,0 -US-UMd,18636,GRP_STEM_INCR,STEM_INCR_COMMENT,"Within year data from a single, circular 1.13 ha plot with flux tower at the center of the plot. Standard deviation and means determined from number of stems measured in the plot. The same trees are measured repeatedly for within year data. No Populus or Betula outfitted with bands due to stem girdling of those species spring of 2008." -US-UMd,18696,GRP_STEM_INCR,STEM_INCR,0.056 -US-UMd,18696,GRP_STEM_INCR,STEM_INCR_SPATIAL_VARIABILITY,0.038 -US-UMd,18696,GRP_STEM_INCR,STEM_INCR_SPATIAL_REP_NUMBER,131 -US-UMd,18696,GRP_STEM_INCR,STEM_INCR_DIAM,20.45 -US-UMd,18696,GRP_STEM_INCR,STEM_INCR_NUM,131 -US-UMd,18696,GRP_STEM_INCR,STEM_INCR_APPROACH,Band Dendrometers -US-UMd,18696,GRP_STEM_INCR,STEM_INCR_DATE_START,20090617 -US-UMd,18696,GRP_STEM_INCR,STEM_INCR_DATE_END,20090714 -US-UMd,18696,GRP_STEM_INCR,STEM_INCR_DATE_UNC,0 -US-UMd,18696,GRP_STEM_INCR,STEM_INCR_COMMENT,"Within year data from a single, circular 1.13 ha plot with flux tower at the center of the plot. Standard deviation and means determined from number of stems measured in the plot. The same trees are measured repeatedly for within year data. No Populus or Betula outfitted with bands due to stem girdling of those species spring of 2008." -US-UMd,18632,GRP_STEM_INCR,STEM_INCR,0.073 -US-UMd,18632,GRP_STEM_INCR,STEM_INCR_SPATIAL_VARIABILITY,0.068 -US-UMd,18632,GRP_STEM_INCR,STEM_INCR_SPATIAL_REP_NUMBER,131 -US-UMd,18632,GRP_STEM_INCR,STEM_INCR_DIAM,20.24 -US-UMd,18632,GRP_STEM_INCR,STEM_INCR_NUM,131 -US-UMd,18632,GRP_STEM_INCR,STEM_INCR_APPROACH,Band Dendrometers -US-UMd,18632,GRP_STEM_INCR,STEM_INCR_DATE_START,20071017 -US-UMd,18632,GRP_STEM_INCR,STEM_INCR_DATE_END,20080625 -US-UMd,18632,GRP_STEM_INCR,STEM_INCR_DATE_UNC,0 -US-UMd,18632,GRP_STEM_INCR,STEM_INCR_COMMENT,"Within year data from a single, circular 1.13 ha plot with flux tower at the center of the plot. Standard deviation and means determined from number of stems measured in the plot. The same trees are measured repeatedly for within year data. No Populus or Betula outfitted with bands due to stem girdling of those species spring of 2008." -US-UMd,18652,GRP_STEM_INCR,STEM_INCR,0.152 -US-UMd,18652,GRP_STEM_INCR,STEM_INCR_SPATIAL_VARIABILITY,0.05 -US-UMd,18652,GRP_STEM_INCR,STEM_INCR_SPATIAL_REP_NUMBER,16 -US-UMd,18652,GRP_STEM_INCR,STEM_INCR_DIAM,19.13 -US-UMd,18652,GRP_STEM_INCR,STEM_INCR_NUM,392 -US-UMd,18652,GRP_STEM_INCR,STEM_INCR_APPROACH,Band Dendrometers -US-UMd,18652,GRP_STEM_INCR,STEM_INCR_DATE_START,20070430 -US-UMd,18652,GRP_STEM_INCR,STEM_INCR_DATE_END,20071022 -US-UMd,18652,GRP_STEM_INCR,STEM_INCR_DATE_UNC,4 -US-UMd,18652,GRP_STEM_INCR,STEM_INCR_COMMENT,"Annual increment determined from a subset (~25%) of trees with DBH >=10 cm within .08 ha plots and one 1.13 ha plot. Variability determined across plots. Band dendrometers were read during or after autumnal leaf-off. Year-to-year variability in number of trees due to trees out growing bands, damaged bands, or additional trees outfitted with bands. No Populus or Betula included due to stem girdling of those species in spring 2008." -US-UMd,18662,GRP_STEM_INCR,STEM_INCR,0.182 -US-UMd,18662,GRP_STEM_INCR,STEM_INCR_SPATIAL_VARIABILITY,0.071 -US-UMd,18662,GRP_STEM_INCR,STEM_INCR_SPATIAL_REP_NUMBER,16 -US-UMd,18662,GRP_STEM_INCR,STEM_INCR_DIAM,19.31 -US-UMd,18662,GRP_STEM_INCR,STEM_INCR_NUM,397 -US-UMd,18662,GRP_STEM_INCR,STEM_INCR_APPROACH,Band Dendrometers -US-UMd,18662,GRP_STEM_INCR,STEM_INCR_DATE_START,20071022 -US-UMd,18662,GRP_STEM_INCR,STEM_INCR_DATE_END,20081106 -US-UMd,18662,GRP_STEM_INCR,STEM_INCR_DATE_UNC,4 -US-UMd,18662,GRP_STEM_INCR,STEM_INCR_COMMENT,"Annual increment determined from a subset (~25%) of trees with DBH >=10 cm within .08 ha plots and one 1.13 ha plot. Variability determined across plots. Band dendrometers were read during or after autumnal leaf-off. Year-to-year variability in number of trees due to trees out growing bands, damaged bands, or additional trees outfitted with bands. No Populus or Betula included due to stem girdling of those species in spring 2008." -US-UMd,18608,GRP_STEM_INCR,STEM_INCR,0.202 -US-UMd,18608,GRP_STEM_INCR,STEM_INCR_SPATIAL_VARIABILITY,0.089 -US-UMd,18608,GRP_STEM_INCR,STEM_INCR_SPATIAL_REP_NUMBER,18 -US-UMd,18608,GRP_STEM_INCR,STEM_INCR_DIAM,19.46 -US-UMd,18608,GRP_STEM_INCR,STEM_INCR_NUM,434 -US-UMd,18608,GRP_STEM_INCR,STEM_INCR_APPROACH,Band Dendrometers -US-UMd,18608,GRP_STEM_INCR,STEM_INCR_DATE_START,20081106 -US-UMd,18608,GRP_STEM_INCR,STEM_INCR_DATE_END,20091106 -US-UMd,18608,GRP_STEM_INCR,STEM_INCR_DATE_UNC,4 -US-UMd,18608,GRP_STEM_INCR,STEM_INCR_COMMENT,"Annual increment determined from a subset (~25%) of trees with DBH >=10 cm within .08 ha plots and one 1.13 ha plot. Variability determined across plots. Band dendrometers were read during or after autumnal leaf-off. Year-to-year variability in number of trees due to trees out growing bands, damaged bands, or additional trees outfitted with bands. No Populus or Betula included due to stem girdling of those species in spring 2008." -US-UMd,18617,GRP_STEM_INCR,STEM_INCR,0.205 -US-UMd,18617,GRP_STEM_INCR,STEM_INCR_SPATIAL_VARIABILITY,0.123 -US-UMd,18617,GRP_STEM_INCR,STEM_INCR_SPATIAL_REP_NUMBER,18 -US-UMd,18617,GRP_STEM_INCR,STEM_INCR_DIAM,19.59 -US-UMd,18617,GRP_STEM_INCR,STEM_INCR_NUM,433 -US-UMd,18617,GRP_STEM_INCR,STEM_INCR_APPROACH,Band Dendrometers -US-UMd,18617,GRP_STEM_INCR,STEM_INCR_DATE_START,20091106 -US-UMd,18617,GRP_STEM_INCR,STEM_INCR_DATE_END,20101116 -US-UMd,18617,GRP_STEM_INCR,STEM_INCR_DATE_UNC,4 -US-UMd,18617,GRP_STEM_INCR,STEM_INCR_COMMENT,"Annual increment determined from a subset (~25%) of trees with DBH >=10 cm within .08 ha plots and one 1.13 ha plot. Variability determined across plots. Band dendrometers were read during or after autumnal leaf-off. Year-to-year variability in number of trees due to trees out growing bands, damaged bands, or additional trees outfitted with bands. No Populus or Betula included due to stem girdling of those species in spring 2008." -US-UMd,18683,GRP_STEM_INCR,STEM_INCR,0.209 -US-UMd,18683,GRP_STEM_INCR,STEM_INCR_SPATIAL_VARIABILITY,0.105 -US-UMd,18683,GRP_STEM_INCR,STEM_INCR_SPATIAL_REP_NUMBER,18 -US-UMd,18683,GRP_STEM_INCR,STEM_INCR_DIAM,20.02 -US-UMd,18683,GRP_STEM_INCR,STEM_INCR_NUM,532 -US-UMd,18683,GRP_STEM_INCR,STEM_INCR_APPROACH,Band Dendrometers -US-UMd,18683,GRP_STEM_INCR,STEM_INCR_DATE_START,20121108 -US-UMd,18683,GRP_STEM_INCR,STEM_INCR_DATE_END,20131001 -US-UMd,18683,GRP_STEM_INCR,STEM_INCR_DATE_UNC,4 -US-UMd,18683,GRP_STEM_INCR,STEM_INCR_COMMENT,"Annual increment determined from a subset (~25%) of trees with DBH >=10 cm within .08 ha plots and one 1.13 ha plot. Variability determined across plots. Band dendrometers were read during or after autumnal leaf-off. Year-to-year variability in number of trees due to trees out growing bands, damaged bands, or additional trees outfitted with bands. No Populus or Betula included due to stem girdling of those species in spring 2008." -US-UMd,18667,GRP_STEM_INCR,STEM_INCR,0.226 -US-UMd,18667,GRP_STEM_INCR,STEM_INCR_SPATIAL_VARIABILITY,0.088 -US-UMd,18667,GRP_STEM_INCR,STEM_INCR_SPATIAL_REP_NUMBER,18 -US-UMd,18667,GRP_STEM_INCR,STEM_INCR_DIAM,19.64 -US-UMd,18667,GRP_STEM_INCR,STEM_INCR_NUM,426 -US-UMd,18667,GRP_STEM_INCR,STEM_INCR_APPROACH,Band Dendrometers -US-UMd,18667,GRP_STEM_INCR,STEM_INCR_DATE_START,20101116 -US-UMd,18667,GRP_STEM_INCR,STEM_INCR_DATE_END,20111103 -US-UMd,18667,GRP_STEM_INCR,STEM_INCR_DATE_UNC,4 -US-UMd,18667,GRP_STEM_INCR,STEM_INCR_COMMENT,"Annual increment determined from a subset (~25%) of trees with DBH >=10 cm within .08 ha plots and one 1.13 ha plot. Variability determined across plots. Band dendrometers were read during or after autumnal leaf-off. Year-to-year variability in number of trees due to trees out growing bands, damaged bands, or additional trees outfitted with bands. No Populus or Betula included due to stem girdling of those species in spring 2008." -US-UMd,18675,GRP_STEM_INCR,STEM_INCR,0.228 -US-UMd,18675,GRP_STEM_INCR,STEM_INCR_SPATIAL_VARIABILITY,0.072 -US-UMd,18675,GRP_STEM_INCR,STEM_INCR_SPATIAL_REP_NUMBER,18 -US-UMd,18675,GRP_STEM_INCR,STEM_INCR_DIAM,19.81 -US-UMd,18675,GRP_STEM_INCR,STEM_INCR_NUM,402 -US-UMd,18675,GRP_STEM_INCR,STEM_INCR_APPROACH,Band Dendrometers -US-UMd,18675,GRP_STEM_INCR,STEM_INCR_DATE_START,20111103 -US-UMd,18675,GRP_STEM_INCR,STEM_INCR_DATE_END,20121108 -US-UMd,18675,GRP_STEM_INCR,STEM_INCR_DATE_UNC,4 -US-UMd,18675,GRP_STEM_INCR,STEM_INCR_COMMENT,"Annual increment determined from a subset (~25%) of trees with DBH >=10 cm within .08 ha plots and one 1.13 ha plot. Variability determined across plots. Band dendrometers were read during or after autumnal leaf-off. Year-to-year variability in number of trees due to trees out growing bands, damaged bands, or additional trees outfitted with bands. No Populus or Betula included due to stem girdling of those species in spring 2008." -US-UMd,18628,GRP_STEM_INCR,STEM_INCR,0.231 -US-UMd,18628,GRP_STEM_INCR,STEM_INCR_SPATIAL_VARIABILITY,0.109 -US-UMd,18628,GRP_STEM_INCR,STEM_INCR_SPATIAL_REP_NUMBER,18 -US-UMd,18628,GRP_STEM_INCR,STEM_INCR_DIAM,20.09 -US-UMd,18628,GRP_STEM_INCR,STEM_INCR_NUM,544 -US-UMd,18628,GRP_STEM_INCR,STEM_INCR_APPROACH,Band Dendrometers -US-UMd,18628,GRP_STEM_INCR,STEM_INCR_DATE_START,20131001 -US-UMd,18628,GRP_STEM_INCR,STEM_INCR_DATE_END,20141103 -US-UMd,18628,GRP_STEM_INCR,STEM_INCR_DATE_UNC,4 -US-UMd,18628,GRP_STEM_INCR,STEM_INCR_COMMENT,"Annual increment determined from a subset (~25%) of trees with DBH >=10 cm within .08 ha plots and one 1.13 ha plot. Variability determined across plots. Band dendrometers were read during or after autumnal leaf-off. Year-to-year variability in number of trees due to trees out growing bands, damaged bands, or additional trees outfitted with bands. No Populus or Betula included due to stem girdling of those species in spring 2008." -US-UMd,12380,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Christopher Gough -US-UMd,12380,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-UMd,12380,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,cmgough@vcu.edu -US-UMd,12380,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Virginia Commonwealth University -US-UMd,12380,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Department of Biology, 1000 West Cary Street, PO Box 842012,Richmond, VA USA 23284-2012" -US-UMd,29726,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Gil Bohrer -US-UMd,29726,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-UMd,29726,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,bohrer.17@osu.edu -US-UMd,29726,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Ohio State University -US-UMd,29726,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Department of Civil, Environmental and Geodetic Engineering, 417E Hitchcock Hall, 2070 Neil Avenue,Columbus, Ohio USA 43210" -US-UMd,98540,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Luke Nave -US-UMd,98540,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-UMd,98540,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,lukenave@umich.edu -US-UMd,98540,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Michigan -US-UMd,12381,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Chris Vogel -US-UMd,12381,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Affiliate -US-UMd,12381,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,csvogel@umich.edu -US-UMd,12381,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Michigan -US-UMd,12381,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"University of Michigan Biological Station, 9008 Biological Road,Pellston, MI USA 49769" -US-UMd,98539,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Peter Curtis -US-UMd,98539,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Affiliate -US-UMd,98539,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,curtis.7@osu.edu -US-UMd,98539,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Ohio State University -US-UMd,98539,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Department of Evolution, Ecology, and Organismal Biology, 318 W 12th Avenue,Columbus, OH USA 43210-1293" -US-UMd,29857,GRP_TOWER_POWER,TOWER_POWER,Direct power -US-UMd,12375,GRP_TOWER_TYPE,TOWER_TYPE,triangle -US-UMd,19288,GRP_TREES_NUM,TREES_NUM,118.79961485 -US-UMd,19288,GRP_TREES_NUM,TREES_NUM_SPP,Quercus rubra -US-UMd,19288,GRP_TREES_NUM,TREES_NUM_APPROACH,Census of trees in 22 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm. -US-UMd,19288,GRP_TREES_NUM,TREES_NUM_DATE,20060714 -US-UMd,19288,GRP_TREES_NUM,TREES_NUM_DATE_UNC,28 -US-UMd,19288,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,23 -US-UMd,19288,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,100.86192488 -US-UMd,19281,GRP_TREES_NUM,TREES_NUM,12.437810945 -US-UMd,19281,GRP_TREES_NUM,TREES_NUM_SPP,Populus tremuloides -US-UMd,19281,GRP_TREES_NUM,TREES_NUM_APPROACH,Census of trees in 22 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm. -US-UMd,19281,GRP_TREES_NUM,TREES_NUM_DATE,20060714 -US-UMd,19281,GRP_TREES_NUM,TREES_NUM_DATE_UNC,28 -US-UMd,19281,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,23 -US-UMd,19281,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,56.997210136 -US-UMd,19264,GRP_TREES_NUM,TREES_NUM,12.553239956 -US-UMd,19264,GRP_TREES_NUM,TREES_NUM_SPP,other (5 species) -US-UMd,19264,GRP_TREES_NUM,TREES_NUM_APPROACH,Census of trees in 22 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm. -US-UMd,19264,GRP_TREES_NUM,TREES_NUM_DATE,20100714 -US-UMd,19264,GRP_TREES_NUM,TREES_NUM_DATE_UNC,28 -US-UMd,19264,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,23 -US-UMd,19264,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,30.189995891 -US-UMd,19259,GRP_TREES_NUM,TREES_NUM,122.08273752 -US-UMd,19259,GRP_TREES_NUM,TREES_NUM_SPP,Quercus rubra -US-UMd,19259,GRP_TREES_NUM,TREES_NUM_APPROACH,Census of trees in 22 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm. -US-UMd,19259,GRP_TREES_NUM,TREES_NUM_DATE,20100714 -US-UMd,19259,GRP_TREES_NUM,TREES_NUM_DATE_UNC,28 -US-UMd,19259,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,23 -US-UMd,19259,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,91.63916591 -US-UMd,19221,GRP_TREES_NUM,TREES_NUM,123.46577999 -US-UMd,19221,GRP_TREES_NUM,TREES_NUM_SPP,Pinus strobus -US-UMd,19221,GRP_TREES_NUM,TREES_NUM_APPROACH,Census of trees in 22 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm. -US-UMd,19221,GRP_TREES_NUM,TREES_NUM_DATE,20060714 -US-UMd,19221,GRP_TREES_NUM,TREES_NUM_DATE_UNC,28 -US-UMd,19221,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,23 -US-UMd,19221,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,142.22382343 -US-UMd,19311,GRP_TREES_NUM,TREES_NUM,128.21732048 -US-UMd,19311,GRP_TREES_NUM,TREES_NUM_SPP,Pinus strobus -US-UMd,19311,GRP_TREES_NUM,TREES_NUM_APPROACH,Census of trees in 22 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm. -US-UMd,19311,GRP_TREES_NUM,TREES_NUM_DATE,20100714 -US-UMd,19311,GRP_TREES_NUM,TREES_NUM_DATE_UNC,28 -US-UMd,19311,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,23 -US-UMd,19311,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,149.93572094 -US-UMd,19226,GRP_TREES_NUM,TREES_NUM,13.634788734 -US-UMd,19226,GRP_TREES_NUM,TREES_NUM_SPP,other (5 species) -US-UMd,19226,GRP_TREES_NUM,TREES_NUM_APPROACH,Census of trees in 22 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm. -US-UMd,19226,GRP_TREES_NUM,TREES_NUM_DATE,20060714 -US-UMd,19226,GRP_TREES_NUM,TREES_NUM_DATE_UNC,28 -US-UMd,19226,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,23 -US-UMd,19226,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,34.104192548 -US-UMd,19274,GRP_TREES_NUM,TREES_NUM,130.98761675 -US-UMd,19274,GRP_TREES_NUM,TREES_NUM_SPP,Populus grandidentata -US-UMd,19274,GRP_TREES_NUM,TREES_NUM_APPROACH,Census of trees in 22 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm. -US-UMd,19274,GRP_TREES_NUM,TREES_NUM_DATE,20060714 -US-UMd,19274,GRP_TREES_NUM,TREES_NUM_DATE_UNC,28 -US-UMd,19274,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,23 -US-UMd,19274,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,97.439536151 -US-UMd,19254,GRP_TREES_NUM,TREES_NUM,2.7038719446 -US-UMd,19254,GRP_TREES_NUM,TREES_NUM_SPP,Populus tremuloides -US-UMd,19254,GRP_TREES_NUM,TREES_NUM_APPROACH,Census of trees in 22 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm. -US-UMd,19254,GRP_TREES_NUM,TREES_NUM_DATE,20100714 -US-UMd,19254,GRP_TREES_NUM,TREES_NUM_DATE_UNC,28 -US-UMd,19254,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,23 -US-UMd,19254,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,12.967314307 -US-UMd,19329,GRP_TREES_NUM,TREES_NUM,210.99064125 -US-UMd,19329,GRP_TREES_NUM,TREES_NUM_SPP,Acer rubrum -US-UMd,19329,GRP_TREES_NUM,TREES_NUM_APPROACH,Census of trees in 22 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm. -US-UMd,19329,GRP_TREES_NUM,TREES_NUM_DATE,20060714 -US-UMd,19329,GRP_TREES_NUM,TREES_NUM_DATE_UNC,28 -US-UMd,19329,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,23 -US-UMd,19329,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,130.32982654 -US-UMd,19232,GRP_TREES_NUM,TREES_NUM,211.53141564 -US-UMd,19232,GRP_TREES_NUM,TREES_NUM_SPP,Acer rubrum -US-UMd,19232,GRP_TREES_NUM,TREES_NUM_APPROACH,Census of trees in 22 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm. -US-UMd,19232,GRP_TREES_NUM,TREES_NUM_DATE,20100714 -US-UMd,19232,GRP_TREES_NUM,TREES_NUM_DATE_UNC,28 -US-UMd,19232,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,23 -US-UMd,19232,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,128.07197793 -US-UMd,19214,GRP_TREES_NUM,TREES_NUM,24.642658198 -US-UMd,19214,GRP_TREES_NUM,TREES_NUM_SPP,Pinus resinosa -US-UMd,19214,GRP_TREES_NUM,TREES_NUM_APPROACH,Census of trees in 22 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm. -US-UMd,19214,GRP_TREES_NUM,TREES_NUM_DATE,20060714 -US-UMd,19214,GRP_TREES_NUM,TREES_NUM_DATE_UNC,28 -US-UMd,19214,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,23 -US-UMd,19214,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,53.630892951 -US-UMd,19304,GRP_TREES_NUM,TREES_NUM,25.724206976 -US-UMd,19304,GRP_TREES_NUM,TREES_NUM_SPP,Pinus resinosa -US-UMd,19304,GRP_TREES_NUM,TREES_NUM_APPROACH,Census of trees in 22 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm. -US-UMd,19304,GRP_TREES_NUM,TREES_NUM_DATE,20100714 -US-UMd,19304,GRP_TREES_NUM,TREES_NUM_DATE_UNC,28 -US-UMd,19304,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,23 -US-UMd,19304,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,55.047940293 -US-UMd,19207,GRP_TREES_NUM,TREES_NUM,34.710250211 -US-UMd,19207,GRP_TREES_NUM,TREES_NUM_SPP,Fagus grandifolia -US-UMd,19207,GRP_TREES_NUM,TREES_NUM_APPROACH,Census of trees in 22 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm. -US-UMd,19207,GRP_TREES_NUM,TREES_NUM_DATE,20060714 -US-UMd,19207,GRP_TREES_NUM,TREES_NUM_DATE_UNC,28 -US-UMd,19207,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,23 -US-UMd,19207,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,57.090692567 -US-UMd,19297,GRP_TREES_NUM,TREES_NUM,36.524955063 -US-UMd,19297,GRP_TREES_NUM,TREES_NUM_SPP,Fagus grandifolia -US-UMd,19297,GRP_TREES_NUM,TREES_NUM_APPROACH,Census of trees in 22 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm. -US-UMd,19297,GRP_TREES_NUM,TREES_NUM_DATE,20100714 -US-UMd,19297,GRP_TREES_NUM,TREES_NUM_DATE_UNC,28 -US-UMd,19297,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,23 -US-UMd,19297,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,60.033706648 -US-UMd,19244,GRP_TREES_NUM,TREES_NUM,4.9054458374 -US-UMd,19244,GRP_TREES_NUM,TREES_NUM_SPP,Betula papyrifera -US-UMd,19244,GRP_TREES_NUM,TREES_NUM_APPROACH,Census of trees in 22 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm. -US-UMd,19244,GRP_TREES_NUM,TREES_NUM_DATE,20100714 -US-UMd,19244,GRP_TREES_NUM,TREES_NUM_DATE_UNC,28 -US-UMd,19244,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,23 -US-UMd,19244,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,11.070039287 -US-UMd,19200,GRP_TREES_NUM,TREES_NUM,51.209133249 -US-UMd,19200,GRP_TREES_NUM,TREES_NUM_SPP,Betula papyrifera -US-UMd,19200,GRP_TREES_NUM,TREES_NUM_APPROACH,Census of trees in 22 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm. -US-UMd,19200,GRP_TREES_NUM,TREES_NUM_DATE,20060714 -US-UMd,19200,GRP_TREES_NUM,TREES_NUM_DATE_UNC,28 -US-UMd,19200,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,23 -US-UMd,19200,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,60.246008977 -US-UMd,19238,GRP_TREES_NUM,TREES_NUM,80.57538395 -US-UMd,19238,GRP_TREES_NUM,TREES_NUM_SPP,Acer saccharum -US-UMd,19238,GRP_TREES_NUM,TREES_NUM_APPROACH,Census of trees in 22 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm. -US-UMd,19238,GRP_TREES_NUM,TREES_NUM_DATE,20100714 -US-UMd,19238,GRP_TREES_NUM,TREES_NUM_DATE_UNC,28 -US-UMd,19238,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,23 -US-UMd,19238,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,179.25790443 -US-UMd,19336,GRP_TREES_NUM,TREES_NUM,81.116158339 -US-UMd,19336,GRP_TREES_NUM,TREES_NUM_SPP,Acer saccharum -US-UMd,19336,GRP_TREES_NUM,TREES_NUM_APPROACH,Census of trees in 22 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm. -US-UMd,19336,GRP_TREES_NUM,TREES_NUM_DATE,20060714 -US-UMd,19336,GRP_TREES_NUM,TREES_NUM_DATE_UNC,28 -US-UMd,19336,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,23 -US-UMd,19336,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,183.13861452 -US-UMd,19248,GRP_TREES_NUM,TREES_NUM,88.279074041 -US-UMd,19248,GRP_TREES_NUM,TREES_NUM_SPP,Populus grandidentata -US-UMd,19248,GRP_TREES_NUM,TREES_NUM_APPROACH,Census of trees in 22 - 0.08 ha plots and a single 1.13 ha plot for trees with DBH >= 8 cm. -US-UMd,19248,GRP_TREES_NUM,TREES_NUM_DATE,20100714 -US-UMd,19248,GRP_TREES_NUM,TREES_NUM_DATE_UNC,28 -US-UMd,19248,GRP_TREES_NUM,TREES_NUM_SPATIAL_REP_NUMBER,23 -US-UMd,19248,GRP_TREES_NUM,TREES_NUM_SPATIAL_VARIABILITY,83.826981801 -US-UMd,12376,GRP_URL,URL,http://flux.org.ohio-state.edu/ -US-UMd,24000500,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-UMd -US-UMd,12377,GRP_UTC_OFFSET,UTC_OFFSET,-5 -US-UMd,18618,GRP_WD_BIOMASS,WD_BIOMASS_CRS,156.8 -US-UMd,18676,GRP_WD_BIOMASS,WD_BIOMASS_CRS,602.1 -US-UMd,18629,GRP_WD_BIOMASS,WD_BIOMASS_CRS,612.3 -US-UMd,18618,GRP_WD_BIOMASS,WD_BIOMASS_CRS_SPATIAL_VARIABILITY,117.9 -US-UMd,18629,GRP_WD_BIOMASS,WD_BIOMASS_CRS_SPATIAL_VARIABILITY,452 -US-UMd,18676,GRP_WD_BIOMASS,WD_BIOMASS_CRS_SPATIAL_VARIABILITY,614.6 -US-UMd,18618,GRP_WD_BIOMASS,WD_BIOMASS_CRS_SPATIAL_REP_NUMBER,8 -US-UMd,18629,GRP_WD_BIOMASS,WD_BIOMASS_CRS_SPATIAL_REP_NUMBER,8 -US-UMd,18676,GRP_WD_BIOMASS,WD_BIOMASS_CRS_SPATIAL_REP_NUMBER,8 -US-UMd,18641,GRP_WD_BIOMASS,WD_BIOMASS_FINE,10.5 -US-UMd,18637,GRP_WD_BIOMASS,WD_BIOMASS_FINE,11.4 -US-UMd,18699,GRP_WD_BIOMASS,WD_BIOMASS_FINE,15 -US-UMd,18609,GRP_WD_BIOMASS,WD_BIOMASS_FINE,15.5 -US-UMd,18668,GRP_WD_BIOMASS,WD_BIOMASS_FINE,20.9 -US-UMd,18629,GRP_WD_BIOMASS,WD_BIOMASS_FINE,22.7 -US-UMd,18618,GRP_WD_BIOMASS,WD_BIOMASS_FINE,23.2 -US-UMd,18695,GRP_WD_BIOMASS,WD_BIOMASS_FINE,25.7 -US-UMd,18676,GRP_WD_BIOMASS,WD_BIOMASS_FINE,28.5 -US-UMd,18684,GRP_WD_BIOMASS,WD_BIOMASS_FINE,30.5 -US-UMd,18686,GRP_WD_BIOMASS,WD_BIOMASS_FINE,32.9 -US-UMd,18689,GRP_WD_BIOMASS,WD_BIOMASS_FINE,33 -US-UMd,18697,GRP_WD_BIOMASS,WD_BIOMASS_FINE,36.2 -US-UMd,18701,GRP_WD_BIOMASS,WD_BIOMASS_FINE,61.4 -US-UMd,18653,GRP_WD_BIOMASS,WD_BIOMASS_FINE,7.7 -US-UMd,18633,GRP_WD_BIOMASS,WD_BIOMASS_FINE,8.6 -US-UMd,18600,GRP_WD_BIOMASS,WD_BIOMASS_FINE,9.3 -US-UMd,18692,GRP_WD_BIOMASS,WD_BIOMASS_FINE,95.8 -US-UMd,18600,GRP_WD_BIOMASS,WD_BIOMASS_FINE_SPATIAL_VARIABILITY,10.7 -US-UMd,18701,GRP_WD_BIOMASS,WD_BIOMASS_FINE_SPATIAL_VARIABILITY,109.9 -US-UMd,18699,GRP_WD_BIOMASS,WD_BIOMASS_FINE_SPATIAL_VARIABILITY,11.1 -US-UMd,18668,GRP_WD_BIOMASS,WD_BIOMASS_FINE_SPATIAL_VARIABILITY,14.2 -US-UMd,18629,GRP_WD_BIOMASS,WD_BIOMASS_FINE_SPATIAL_VARIABILITY,15.4 -US-UMd,18618,GRP_WD_BIOMASS,WD_BIOMASS_FINE_SPATIAL_VARIABILITY,17.1 -US-UMd,18695,GRP_WD_BIOMASS,WD_BIOMASS_FINE_SPATIAL_VARIABILITY,18.6 -US-UMd,18684,GRP_WD_BIOMASS,WD_BIOMASS_FINE_SPATIAL_VARIABILITY,22.9 -US-UMd,18676,GRP_WD_BIOMASS,WD_BIOMASS_FINE_SPATIAL_VARIABILITY,23.7 -US-UMd,18689,GRP_WD_BIOMASS,WD_BIOMASS_FINE_SPATIAL_VARIABILITY,28.1 -US-UMd,18686,GRP_WD_BIOMASS,WD_BIOMASS_FINE_SPATIAL_VARIABILITY,35.3 -US-UMd,18653,GRP_WD_BIOMASS,WD_BIOMASS_FINE_SPATIAL_VARIABILITY,4.7 -US-UMd,18697,GRP_WD_BIOMASS,WD_BIOMASS_FINE_SPATIAL_VARIABILITY,45.5 -US-UMd,18609,GRP_WD_BIOMASS,WD_BIOMASS_FINE_SPATIAL_VARIABILITY,6.1 -US-UMd,18641,GRP_WD_BIOMASS,WD_BIOMASS_FINE_SPATIAL_VARIABILITY,7.7 -US-UMd,18692,GRP_WD_BIOMASS,WD_BIOMASS_FINE_SPATIAL_VARIABILITY,95.1 -US-UMd,18633,GRP_WD_BIOMASS,WD_BIOMASS_FINE_SPATIAL_REP_NUMBER,10 -US-UMd,18637,GRP_WD_BIOMASS,WD_BIOMASS_FINE_SPATIAL_REP_NUMBER,10 -US-UMd,18641,GRP_WD_BIOMASS,WD_BIOMASS_FINE_SPATIAL_REP_NUMBER,10 -US-UMd,18686,GRP_WD_BIOMASS,WD_BIOMASS_FINE_SPATIAL_REP_NUMBER,10 -US-UMd,18689,GRP_WD_BIOMASS,WD_BIOMASS_FINE_SPATIAL_REP_NUMBER,10 -US-UMd,18692,GRP_WD_BIOMASS,WD_BIOMASS_FINE_SPATIAL_REP_NUMBER,10 -US-UMd,18695,GRP_WD_BIOMASS,WD_BIOMASS_FINE_SPATIAL_REP_NUMBER,10 -US-UMd,18697,GRP_WD_BIOMASS,WD_BIOMASS_FINE_SPATIAL_REP_NUMBER,10 -US-UMd,18699,GRP_WD_BIOMASS,WD_BIOMASS_FINE_SPATIAL_REP_NUMBER,10 -US-UMd,18609,GRP_WD_BIOMASS,WD_BIOMASS_FINE_SPATIAL_REP_NUMBER,12 -US-UMd,18618,GRP_WD_BIOMASS,WD_BIOMASS_FINE_SPATIAL_REP_NUMBER,12 -US-UMd,18629,GRP_WD_BIOMASS,WD_BIOMASS_FINE_SPATIAL_REP_NUMBER,12 -US-UMd,18668,GRP_WD_BIOMASS,WD_BIOMASS_FINE_SPATIAL_REP_NUMBER,12 -US-UMd,18676,GRP_WD_BIOMASS,WD_BIOMASS_FINE_SPATIAL_REP_NUMBER,12 -US-UMd,18684,GRP_WD_BIOMASS,WD_BIOMASS_FINE_SPATIAL_REP_NUMBER,12 -US-UMd,18600,GRP_WD_BIOMASS,WD_BIOMASS_FINE_SPATIAL_REP_NUMBER,23 -US-UMd,18653,GRP_WD_BIOMASS,WD_BIOMASS_FINE_SPATIAL_REP_NUMBER,8 -US-UMd,18600,GRP_WD_BIOMASS,WD_BIOMASS_UNIT,gC m-2 -US-UMd,18609,GRP_WD_BIOMASS,WD_BIOMASS_UNIT,gC m-2 -US-UMd,18618,GRP_WD_BIOMASS,WD_BIOMASS_UNIT,gC m-2 -US-UMd,18629,GRP_WD_BIOMASS,WD_BIOMASS_UNIT,gC m-2 -US-UMd,18633,GRP_WD_BIOMASS,WD_BIOMASS_UNIT,gC m-2 -US-UMd,18637,GRP_WD_BIOMASS,WD_BIOMASS_UNIT,gC m-2 -US-UMd,18641,GRP_WD_BIOMASS,WD_BIOMASS_UNIT,gC m-2 -US-UMd,18653,GRP_WD_BIOMASS,WD_BIOMASS_UNIT,gC m-2 -US-UMd,18668,GRP_WD_BIOMASS,WD_BIOMASS_UNIT,gC m-2 -US-UMd,18676,GRP_WD_BIOMASS,WD_BIOMASS_UNIT,gC m-2 -US-UMd,18684,GRP_WD_BIOMASS,WD_BIOMASS_UNIT,gC m-2 -US-UMd,18686,GRP_WD_BIOMASS,WD_BIOMASS_UNIT,gC m-2 -US-UMd,18689,GRP_WD_BIOMASS,WD_BIOMASS_UNIT,gC m-2 -US-UMd,18692,GRP_WD_BIOMASS,WD_BIOMASS_UNIT,gC m-2 -US-UMd,18695,GRP_WD_BIOMASS,WD_BIOMASS_UNIT,gC m-2 -US-UMd,18697,GRP_WD_BIOMASS,WD_BIOMASS_UNIT,gC m-2 -US-UMd,18699,GRP_WD_BIOMASS,WD_BIOMASS_UNIT,gC m-2 -US-UMd,18701,GRP_WD_BIOMASS,WD_BIOMASS_UNIT,gC m-2 -US-UMd,18633,GRP_WD_BIOMASS,WD_BIOMASS_APPROACH,2 m X 2 m plots (N=10) randomly located within 60 m of the flux tower where all twigs and branches of <=1 cm diameter were collected once per year in August. -US-UMd,18641,GRP_WD_BIOMASS,WD_BIOMASS_APPROACH,2 m X 2 m plots (N=10) randomly located within 60 m of the flux tower where all twigs and branches of <=1 cm diameter were collected once per year in August. -US-UMd,18689,GRP_WD_BIOMASS,WD_BIOMASS_APPROACH,2 m X 2 m plots (N=10) randomly located within 60 m of the flux tower where all twigs and branches of <=1 cm diameter were collected once per year in August. -US-UMd,18695,GRP_WD_BIOMASS,WD_BIOMASS_APPROACH,2 m X 2 m plots (N=10) randomly located within 60 m of the flux tower where all twigs and branches of <=1 cm diameter were collected once per year in August. -US-UMd,18699,GRP_WD_BIOMASS,WD_BIOMASS_APPROACH,2 m X 2 m plots (N=10) randomly located within 60 m of the flux tower where all twigs and branches of <=1 cm diameter were collected once per year in August. -US-UMd,18637,GRP_WD_BIOMASS,WD_BIOMASS_APPROACH,2 m X 2 m plots (N=10) randomly located within 60 m of the flux tower where all twigs and branches of > 1 cm and < 10 cm diameter were collected once per year in August. -US-UMd,18686,GRP_WD_BIOMASS,WD_BIOMASS_APPROACH,2 m X 2 m plots (N=10) randomly located within 60 m of the flux tower where all twigs and branches of > 1 cm and < 10 cm diameter were collected once per year in August. -US-UMd,18692,GRP_WD_BIOMASS,WD_BIOMASS_APPROACH,2 m X 2 m plots (N=10) randomly located within 60 m of the flux tower where all twigs and branches of > 1 cm and < 10 cm diameter were collected once per year in August. -US-UMd,18697,GRP_WD_BIOMASS,WD_BIOMASS_APPROACH,2 m X 2 m plots (N=10) randomly located within 60 m of the flux tower where all twigs and branches of > 1 cm and < 10 cm diameter were collected once per year in August. -US-UMd,18701,GRP_WD_BIOMASS,WD_BIOMASS_APPROACH,2 m X 2 m plots (N=10) randomly located within 60 m of the flux tower where all twigs and branches of > 1 cm and < 10 cm diameter were collected once per year in August. -US-UMd,18600,GRP_WD_BIOMASS,WD_BIOMASS_APPROACH,litter traps -US-UMd,18609,GRP_WD_BIOMASS,WD_BIOMASS_APPROACH,litter traps -US-UMd,18653,GRP_WD_BIOMASS,WD_BIOMASS_APPROACH,litter traps -US-UMd,18668,GRP_WD_BIOMASS,WD_BIOMASS_APPROACH,litter traps -US-UMd,18684,GRP_WD_BIOMASS,WD_BIOMASS_APPROACH,litter traps -US-UMd,18618,GRP_WD_BIOMASS,WD_BIOMASS_APPROACH,litter traps for fine woody debris. CRS woody debris censused in 8 - 0.08 ha plots during summer -US-UMd,18629,GRP_WD_BIOMASS,WD_BIOMASS_APPROACH,litter traps for fine woody debris. CRS woody debris censused in 8 - 0.08 ha plots during summer -US-UMd,18676,GRP_WD_BIOMASS,WD_BIOMASS_APPROACH,litter traps for fine woody debris. CRS woody debris censused in 8 - 0.08 ha plots during summer -US-UMd,18653,GRP_WD_BIOMASS,WD_BIOMASS_DATE,20060630 -US-UMd,18600,GRP_WD_BIOMASS,WD_BIOMASS_DATE,20070630 -US-UMd,18609,GRP_WD_BIOMASS,WD_BIOMASS_DATE,20080630 -US-UMd,18618,GRP_WD_BIOMASS,WD_BIOMASS_DATE,20090630 -US-UMd,18668,GRP_WD_BIOMASS,WD_BIOMASS_DATE,20100630 -US-UMd,18633,GRP_WD_BIOMASS,WD_BIOMASS_DATE,20100815 -US-UMd,18637,GRP_WD_BIOMASS,WD_BIOMASS_DATE,20100815 -US-UMd,18676,GRP_WD_BIOMASS,WD_BIOMASS_DATE,20110630 -US-UMd,18641,GRP_WD_BIOMASS,WD_BIOMASS_DATE,20110815 -US-UMd,18686,GRP_WD_BIOMASS,WD_BIOMASS_DATE,20110815 -US-UMd,18684,GRP_WD_BIOMASS,WD_BIOMASS_DATE,20120630 -US-UMd,18689,GRP_WD_BIOMASS,WD_BIOMASS_DATE,20120815 -US-UMd,18692,GRP_WD_BIOMASS,WD_BIOMASS_DATE,20120815 -US-UMd,18629,GRP_WD_BIOMASS,WD_BIOMASS_DATE,20130630 -US-UMd,18695,GRP_WD_BIOMASS,WD_BIOMASS_DATE,20130815 -US-UMd,18697,GRP_WD_BIOMASS,WD_BIOMASS_DATE,20130815 -US-UMd,18699,GRP_WD_BIOMASS,WD_BIOMASS_DATE,20140815 -US-UMd,18701,GRP_WD_BIOMASS,WD_BIOMASS_DATE,20140815 -US-UMd,18633,GRP_WD_BIOMASS,WD_BIOMASS_DATE_UNC,14 -US-UMd,18637,GRP_WD_BIOMASS,WD_BIOMASS_DATE_UNC,14 -US-UMd,18641,GRP_WD_BIOMASS,WD_BIOMASS_DATE_UNC,14 -US-UMd,18686,GRP_WD_BIOMASS,WD_BIOMASS_DATE_UNC,14 -US-UMd,18689,GRP_WD_BIOMASS,WD_BIOMASS_DATE_UNC,14 -US-UMd,18692,GRP_WD_BIOMASS,WD_BIOMASS_DATE_UNC,14 -US-UMd,18695,GRP_WD_BIOMASS,WD_BIOMASS_DATE_UNC,14 -US-UMd,18697,GRP_WD_BIOMASS,WD_BIOMASS_DATE_UNC,14 -US-UMd,18699,GRP_WD_BIOMASS,WD_BIOMASS_DATE_UNC,14 -US-UMd,18701,GRP_WD_BIOMASS,WD_BIOMASS_DATE_UNC,14 -US-UMd,18600,GRP_WD_BIOMASS,WD_BIOMASS_DATE_UNC,182 -US-UMd,18609,GRP_WD_BIOMASS,WD_BIOMASS_DATE_UNC,182 -US-UMd,18618,GRP_WD_BIOMASS,WD_BIOMASS_DATE_UNC,182 -US-UMd,18629,GRP_WD_BIOMASS,WD_BIOMASS_DATE_UNC,182 -US-UMd,18653,GRP_WD_BIOMASS,WD_BIOMASS_DATE_UNC,182 -US-UMd,18668,GRP_WD_BIOMASS,WD_BIOMASS_DATE_UNC,182 -US-UMd,18676,GRP_WD_BIOMASS,WD_BIOMASS_DATE_UNC,182 -US-UMd,18684,GRP_WD_BIOMASS,WD_BIOMASS_DATE_UNC,182 -US-UMd,18633,GRP_WD_BIOMASS,WD_BIOMASS_COMMENT,fine woody debris -US-UMd,18641,GRP_WD_BIOMASS,WD_BIOMASS_COMMENT,fine woody debris -US-UMd,18689,GRP_WD_BIOMASS,WD_BIOMASS_COMMENT,fine woody debris -US-UMd,18695,GRP_WD_BIOMASS,WD_BIOMASS_COMMENT,fine woody debris -US-UMd,18699,GRP_WD_BIOMASS,WD_BIOMASS_COMMENT,fine woody debris -US-UMd,18600,GRP_WD_BIOMASS,WD_BIOMASS_COMMENT,fine woody debris is composed of twigs with diameter <= 1 cm -US-UMd,18609,GRP_WD_BIOMASS,WD_BIOMASS_COMMENT,fine woody debris is composed of twigs with diameter <= 1 cm -US-UMd,18653,GRP_WD_BIOMASS,WD_BIOMASS_COMMENT,fine woody debris is composed of twigs with diameter <= 1 cm -US-UMd,18668,GRP_WD_BIOMASS,WD_BIOMASS_COMMENT,fine woody debris is composed of twigs with diameter <= 1 cm -US-UMd,18684,GRP_WD_BIOMASS,WD_BIOMASS_COMMENT,fine woody debris is composed of twigs with diameter <= 1 cm -US-UMd,18618,GRP_WD_BIOMASS,WD_BIOMASS_COMMENT,fine woody debris is composed of twigs with diameter <= 1 cm. CRS woody debris composed of downed wood with diameter >= 10 cm. -US-UMd,18629,GRP_WD_BIOMASS,WD_BIOMASS_COMMENT,fine woody debris is composed of twigs with diameter <= 1 cm. CRS woody debris composed of downed wood with diameter >= 10 cm. -US-UMd,18676,GRP_WD_BIOMASS,WD_BIOMASS_COMMENT,fine woody debris is composed of twigs with diameter <= 1 cm. CRS woody debris composed of downed wood with diameter >= 10 cm. -US-UMd,18637,GRP_WD_BIOMASS,WD_BIOMASS_COMMENT,intermediate woody debris -US-UMd,18686,GRP_WD_BIOMASS,WD_BIOMASS_COMMENT,intermediate woody debris -US-UMd,18692,GRP_WD_BIOMASS,WD_BIOMASS_COMMENT,intermediate woody debris -US-UMd,18697,GRP_WD_BIOMASS,WD_BIOMASS_COMMENT,intermediate woody debris -US-UMd,18701,GRP_WD_BIOMASS,WD_BIOMASS_COMMENT,intermediate woody debris -US-UMd,18601,GRP_WD_PROD,WD_PROD_CRS,10 -US-UMd,18654,GRP_WD_PROD,WD_PROD_CRS,384 -US-UMd,18601,GRP_WD_PROD,WD_PROD_CRS_SPATIAL_VARIABILITY,203.8 -US-UMd,18654,GRP_WD_PROD,WD_PROD_CRS_SPATIAL_VARIABILITY,602.3 -US-UMd,18601,GRP_WD_PROD,WD_PROD_CRS_SPATIAL_REP_NUMBER,8 -US-UMd,18654,GRP_WD_PROD,WD_PROD_CRS_SPATIAL_REP_NUMBER,8 -US-UMd,18642,GRP_WD_PROD,WD_PROD_FINE,128.8 -US-UMd,18690,GRP_WD_PROD,WD_PROD_FINE,141.7 -US-UMd,18669,GRP_WD_PROD,WD_PROD_FINE,15.5 -US-UMd,18622,GRP_WD_PROD,WD_PROD_FINE,20.9 -US-UMd,18638,GRP_WD_PROD,WD_PROD_FINE,22.7 -US-UMd,18677,GRP_WD_PROD,WD_PROD_FINE,23.2 -US-UMd,18693,GRP_WD_PROD,WD_PROD_FINE,240.6 -US-UMd,18630,GRP_WD_PROD,WD_PROD_FINE,28.5 -US-UMd,18634,GRP_WD_PROD,WD_PROD_FINE,30.5 -US-UMd,18687,GRP_WD_PROD,WD_PROD_FINE,375.3 -US-UMd,18610,GRP_WD_PROD,WD_PROD_FINE,7.7 -US-UMd,18619,GRP_WD_PROD,WD_PROD_FINE,9.3 -US-UMd,18619,GRP_WD_PROD,WD_PROD_FINE_SPATIAL_VARIABILITY,10.74 -US-UMd,18630,GRP_WD_PROD,WD_PROD_FINE_SPATIAL_VARIABILITY,13.65 -US-UMd,18642,GRP_WD_PROD,WD_PROD_FINE_SPATIAL_VARIABILITY,138.23 -US-UMd,18622,GRP_WD_PROD,WD_PROD_FINE_SPATIAL_VARIABILITY,14.19 -US-UMd,18638,GRP_WD_PROD,WD_PROD_FINE_SPATIAL_VARIABILITY,15.41 -US-UMd,18677,GRP_WD_PROD,WD_PROD_FINE_SPATIAL_VARIABILITY,17.24 -US-UMd,18690,GRP_WD_PROD,WD_PROD_FINE_SPATIAL_VARIABILITY,178.03 -US-UMd,18634,GRP_WD_PROD,WD_PROD_FINE_SPATIAL_VARIABILITY,22.91 -US-UMd,18687,GRP_WD_PROD,WD_PROD_FINE_SPATIAL_VARIABILITY,372.58 -US-UMd,18610,GRP_WD_PROD,WD_PROD_FINE_SPATIAL_VARIABILITY,4.67 -US-UMd,18693,GRP_WD_PROD,WD_PROD_FINE_SPATIAL_VARIABILITY,430.28 -US-UMd,18669,GRP_WD_PROD,WD_PROD_FINE_SPATIAL_VARIABILITY,6.13 -US-UMd,18642,GRP_WD_PROD,WD_PROD_FINE_SPATIAL_REP_NUMBER,10 -US-UMd,18687,GRP_WD_PROD,WD_PROD_FINE_SPATIAL_REP_NUMBER,10 -US-UMd,18690,GRP_WD_PROD,WD_PROD_FINE_SPATIAL_REP_NUMBER,10 -US-UMd,18693,GRP_WD_PROD,WD_PROD_FINE_SPATIAL_REP_NUMBER,10 -US-UMd,18622,GRP_WD_PROD,WD_PROD_FINE_SPATIAL_REP_NUMBER,12 -US-UMd,18630,GRP_WD_PROD,WD_PROD_FINE_SPATIAL_REP_NUMBER,12 -US-UMd,18634,GRP_WD_PROD,WD_PROD_FINE_SPATIAL_REP_NUMBER,12 -US-UMd,18638,GRP_WD_PROD,WD_PROD_FINE_SPATIAL_REP_NUMBER,12 -US-UMd,18669,GRP_WD_PROD,WD_PROD_FINE_SPATIAL_REP_NUMBER,12 -US-UMd,18677,GRP_WD_PROD,WD_PROD_FINE_SPATIAL_REP_NUMBER,12 -US-UMd,18619,GRP_WD_PROD,WD_PROD_FINE_SPATIAL_REP_NUMBER,23 -US-UMd,18610,GRP_WD_PROD,WD_PROD_FINE_SPATIAL_REP_NUMBER,8 -US-UMd,18601,GRP_WD_PROD,WD_PROD_UNIT,gC m-2 -US-UMd,18610,GRP_WD_PROD,WD_PROD_UNIT,gC m-2 -US-UMd,18619,GRP_WD_PROD,WD_PROD_UNIT,gC m-2 -US-UMd,18622,GRP_WD_PROD,WD_PROD_UNIT,gC m-2 -US-UMd,18630,GRP_WD_PROD,WD_PROD_UNIT,gC m-2 -US-UMd,18634,GRP_WD_PROD,WD_PROD_UNIT,gC m-2 -US-UMd,18638,GRP_WD_PROD,WD_PROD_UNIT,gC m-2 -US-UMd,18642,GRP_WD_PROD,WD_PROD_UNIT,gC m-2 -US-UMd,18654,GRP_WD_PROD,WD_PROD_UNIT,gC m-2 -US-UMd,18669,GRP_WD_PROD,WD_PROD_UNIT,gC m-2 -US-UMd,18677,GRP_WD_PROD,WD_PROD_UNIT,gC m-2 -US-UMd,18687,GRP_WD_PROD,WD_PROD_UNIT,gC m-2 -US-UMd,18690,GRP_WD_PROD,WD_PROD_UNIT,gC m-2 -US-UMd,18693,GRP_WD_PROD,WD_PROD_UNIT,gC m-2 -US-UMd,18601,GRP_WD_PROD,WD_PROD_APPROACH,Coarse woody debris plots were .08 ha in size and debris with diameter of 10 cm or greater were included. Species specific density and decay classes (5 classes each) were used to determine mass of debris. -US-UMd,18654,GRP_WD_PROD,WD_PROD_APPROACH,Coarse woody debris plots were .08 ha in size and debris with diameter of 10 cm or greater were included. Species specific density and decay classes (5 classes each) were used to determine mass of debris. -US-UMd,18619,GRP_WD_PROD,WD_PROD_APPROACH,Fine woody debris collected from 1 - 3 litter traps in each of 22 - 0.08 ha plots and 20 traps in a single 1.13 ha plot. -US-UMd,18622,GRP_WD_PROD,WD_PROD_APPROACH,Fine woody debris collected from 1 - 3 litter traps in each of 22 - 0.08 ha plots and 20 traps in a single 1.13 ha plot. -US-UMd,18630,GRP_WD_PROD,WD_PROD_APPROACH,Fine woody debris collected from 1 - 3 litter traps in each of 22 - 0.08 ha plots and 20 traps in a single 1.13 ha plot. -US-UMd,18634,GRP_WD_PROD,WD_PROD_APPROACH,Fine woody debris collected from 1 - 3 litter traps in each of 22 - 0.08 ha plots and 20 traps in a single 1.13 ha plot. -US-UMd,18638,GRP_WD_PROD,WD_PROD_APPROACH,Fine woody debris collected from 1 - 3 litter traps in each of 22 - 0.08 ha plots and 20 traps in a single 1.13 ha plot. -US-UMd,18669,GRP_WD_PROD,WD_PROD_APPROACH,Fine woody debris collected from 1 - 3 litter traps in each of 22 - 0.08 ha plots and 20 traps in a single 1.13 ha plot. -US-UMd,18677,GRP_WD_PROD,WD_PROD_APPROACH,Fine woody debris collected from 1 - 3 litter traps in each of 22 - 0.08 ha plots and 20 traps in a single 1.13 ha plot. -US-UMd,18610,GRP_WD_PROD,WD_PROD_APPROACH,fine woody debris collected from 3 - 20 litter traps of .264 m^2 in area along 350 m long transects. -US-UMd,18642,GRP_WD_PROD,WD_PROD_APPROACH,Woody debris with diameter > 1 cm and <10 cm collected from10 - 4 m^2 sub-plots within 60m of the flux tower. -US-UMd,18687,GRP_WD_PROD,WD_PROD_APPROACH,Woody debris with diameter > 1 cm and <10 cm collected from10 - 4 m^2 sub-plots within 60m of the flux tower. -US-UMd,18690,GRP_WD_PROD,WD_PROD_APPROACH,Woody debris with diameter > 1 cm and <10 cm collected from10 - 4 m^2 sub-plots within 60m of the flux tower. -US-UMd,18693,GRP_WD_PROD,WD_PROD_APPROACH,Woody debris with diameter > 1 cm and <10 cm collected from10 - 4 m^2 sub-plots within 60m of the flux tower. -US-UMd,18601,GRP_WD_PROD,WD_PROD_DATE_START,19600401 -US-UMd,18610,GRP_WD_PROD,WD_PROD_DATE_START,20060807 -US-UMd,18619,GRP_WD_PROD,WD_PROD_DATE_START,20061101 -US-UMd,18669,GRP_WD_PROD,WD_PROD_DATE_START,20071101 -US-UMd,18677,GRP_WD_PROD,WD_PROD_DATE_START,20081101 -US-UMd,18654,GRP_WD_PROD,WD_PROD_DATE_START,20090714 -US-UMd,18622,GRP_WD_PROD,WD_PROD_DATE_START,20091101 -US-UMd,18642,GRP_WD_PROD,WD_PROD_DATE_START,20100815 -US-UMd,18630,GRP_WD_PROD,WD_PROD_DATE_START,20101101 -US-UMd,18687,GRP_WD_PROD,WD_PROD_DATE_START,20110815 -US-UMd,18634,GRP_WD_PROD,WD_PROD_DATE_START,20111101 -US-UMd,18690,GRP_WD_PROD,WD_PROD_DATE_START,20120815 -US-UMd,18638,GRP_WD_PROD,WD_PROD_DATE_START,20121101 -US-UMd,18693,GRP_WD_PROD,WD_PROD_DATE_START,20130815 -US-UMd,18610,GRP_WD_PROD,WD_PROD_DATE_END,20061101 -US-UMd,18619,GRP_WD_PROD,WD_PROD_DATE_END,20071101 -US-UMd,18669,GRP_WD_PROD,WD_PROD_DATE_END,20081101 -US-UMd,18677,GRP_WD_PROD,WD_PROD_DATE_END,20091101 -US-UMd,18622,GRP_WD_PROD,WD_PROD_DATE_END,20101101 -US-UMd,18654,GRP_WD_PROD,WD_PROD_DATE_END,20110714 -US-UMd,18642,GRP_WD_PROD,WD_PROD_DATE_END,20110815 -US-UMd,18630,GRP_WD_PROD,WD_PROD_DATE_END,20111101 -US-UMd,18687,GRP_WD_PROD,WD_PROD_DATE_END,20120815 -US-UMd,18634,GRP_WD_PROD,WD_PROD_DATE_END,20121101 -US-UMd,18690,GRP_WD_PROD,WD_PROD_DATE_END,20130815 -US-UMd,18638,GRP_WD_PROD,WD_PROD_DATE_END,20131101 -US-UMd,18693,GRP_WD_PROD,WD_PROD_DATE_END,20140815 -US-UMd,18654,GRP_WD_PROD,WD_PROD_DATE_UNC,28 -US-UMd,18610,GRP_WD_PROD,WD_PROD_DATE_UNC,30 -US-UMd,18619,GRP_WD_PROD,WD_PROD_DATE_UNC,30 -US-UMd,18622,GRP_WD_PROD,WD_PROD_DATE_UNC,30 -US-UMd,18630,GRP_WD_PROD,WD_PROD_DATE_UNC,30 -US-UMd,18634,GRP_WD_PROD,WD_PROD_DATE_UNC,30 -US-UMd,18638,GRP_WD_PROD,WD_PROD_DATE_UNC,30 -US-UMd,18669,GRP_WD_PROD,WD_PROD_DATE_UNC,30 -US-UMd,18677,GRP_WD_PROD,WD_PROD_DATE_UNC,30 -US-UMd,18642,GRP_WD_PROD,WD_PROD_DATE_UNC,7 -US-UMd,18687,GRP_WD_PROD,WD_PROD_DATE_UNC,7 -US-UMd,18690,GRP_WD_PROD,WD_PROD_DATE_UNC,7 -US-UMd,18693,GRP_WD_PROD,WD_PROD_DATE_UNC,7 -US-UMd,18601,GRP_WD_PROD,WD_PROD_COMMENT,CWD = downed wood with diameter >= 10 cm -US-UMd,18654,GRP_WD_PROD,WD_PROD_COMMENT,CWD = downed wood with diameter >= 10 cm -US-UMd,18610,GRP_WD_PROD,WD_PROD_COMMENT,FWD = twigs with diameter >= 1 cm. -US-UMd,18619,GRP_WD_PROD,WD_PROD_COMMENT,FWD = twigs with diameter >= 1 cm. -US-UMd,18622,GRP_WD_PROD,WD_PROD_COMMENT,FWD = twigs with diameter >= 1 cm. -US-UMd,18630,GRP_WD_PROD,WD_PROD_COMMENT,FWD = twigs with diameter >= 1 cm. -US-UMd,18634,GRP_WD_PROD,WD_PROD_COMMENT,FWD = twigs with diameter >= 1 cm. -US-UMd,18638,GRP_WD_PROD,WD_PROD_COMMENT,FWD = twigs with diameter >= 1 cm. -US-UMd,18669,GRP_WD_PROD,WD_PROD_COMMENT,FWD = twigs with diameter >= 1 cm. -US-UMd,18677,GRP_WD_PROD,WD_PROD_COMMENT,FWD = twigs with diameter >= 1 cm. -US-UMd,18642,GRP_WD_PROD,WD_PROD_COMMENT,Intermediated woody debris with diameter > 1 cm and < 10 cm. -US-UMd,18687,GRP_WD_PROD,WD_PROD_COMMENT,Intermediated woody debris with diameter > 1 cm and < 10 cm. -US-UMd,18690,GRP_WD_PROD,WD_PROD_COMMENT,Intermediated woody debris with diameter > 1 cm and < 10 cm. -US-UMd,18693,GRP_WD_PROD,WD_PROD_COMMENT,Intermediated woody debris with diameter > 1 cm and < 10 cm. -US-UTB,98348,GRP_CLIM_AVG,MAT,10.6 -US-UTB,98348,GRP_CLIM_AVG,MAP,138.59 -US-UTB,98348,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Bwk -US-UTB,27001204,GRP_COUNTRY,COUNTRY,USA -US-UTB,98349,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Hydrologic event -US-UTB,98351,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-UTB,98351,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-UTB,98351,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,202109210700 -US-UTB,98351,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-UTB,98342,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-UTB,98342,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-UTB,98342,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,202109210700 -US-UTB,98342,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-UTB,23001204,GRP_HEADER,SITE_NAME,UFLUX Bonneville Salt Flats -US-UTB,98354,GRP_IGBP,IGBP,BSV -US-UTB,98354,GRP_IGBP,IGBP_DATE_START,202109210700 -US-UTB,98354,GRP_IGBP,IGBP_COMMENT,Salt Flats; Playa; Seasonally Innundated -US-UTB,98344,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-UTB,98344,GRP_LAND_OWNERSHIP,LAND_OWNER,US BLM -US-UTB,98339,GRP_LOCATION,LOCATION_LAT,40.7848 -US-UTB,98339,GRP_LOCATION,LOCATION_LONG,-113.8299 -US-UTB,98339,GRP_LOCATION,LOCATION_ELEV,1287 -US-UTB,98339,GRP_LOCATION,LOCATION_DATE_START,202109210700 -US-UTB,98339,GRP_LOCATION,LOCATION_COMMENT,Bonneville Salt Flats -US-UTB,98343,GRP_NETWORK,NETWORK,AmeriFlux -US-UTB,98355,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,Remote sensing calibration -US-UTB,98350,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"1594 W North Temple, Salt Lake City UT 84104, USA" -US-UTB,98352,GRP_SITE_CHAR,TERRAIN,Flat -US-UTB,98352,GRP_SITE_CHAR,ASPECT,FLAT -US-UTB,98352,GRP_SITE_CHAR,WIND_DIRECTION,NW -US-UTB,98352,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,2900 -US-UTB,98352,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,10 -US-UTB,98346,GRP_SITE_DESC,SITE_DESC,Enclosed in fence; Piezometers nearby; Replaced smaller standard station BFLAT -US-UTB,98345,GRP_STATE,STATE,UT -US-UTB,98443,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Kathryn Ladig -US-UTB,98443,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-UTB,98443,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,kladig@utah.gov -US-UTB,98443,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Utah Geological Survey -US-UTB,98338,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Paul Inkenbrandt -US-UTB,98338,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-UTB,98338,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,paulinkenbrandt@utah.gov -US-UTB,98338,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Utah Geological Survey -US-UTB,98338,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1594 W North Temple, Salt Lake City UT 84104, USA" -US-UTB,98341,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-UTB,98347,GRP_TOWER_TYPE,TOWER_TYPE,triangle -US-UTB,98353,GRP_URL,URL,https://ugs.easyfluxweb.com -US-UTB,24001204,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-UTB -US-UTB,98337,GRP_UTC_OFFSET,UTC_OFFSET,-7 -US-UTB,98337,GRP_UTC_OFFSET,UTC_OFFSET_DATE_START,202109210700 -US-UTB,98337,GRP_UTC_OFFSET,UTC_OFFSET_COMMENT,MST -US-UTW,95254,GRP_CLIM_AVG,MAT,9.6 -US-UTW,95254,GRP_CLIM_AVG,MAP,225.22 -US-UTW,95254,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfa -US-UTW,27001177,GRP_COUNTRY,COUNTRY,USA -US-UTW,96427,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Utah Geological Survey -US-UTW,96427,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-UTW,95247,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Agriculture -US-UTW,95252,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-UTW,95252,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-UTW,95252,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20210311 -US-UTW,95252,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-UTW,95263,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-UTW,95263,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-UTW,95263,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20210311 -US-UTW,95263,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-UTW,23001177,GRP_HEADER,SITE_NAME,UFLUX Wellington -US-UTW,95261,GRP_IGBP,IGBP,CRO -US-UTW,95261,GRP_IGBP,IGBP_COMMENT,Alphalfa hay -US-UTW,95260,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -US-UTW,95259,GRP_LOCATION,LOCATION_LAT,39.4453 -US-UTW,95259,GRP_LOCATION,LOCATION_LONG,-110.7288 -US-UTW,95259,GRP_LOCATION,LOCATION_ELEV,1682 -US-UTW,95259,GRP_LOCATION,LOCATION_DATE_START,20210311 -US-UTW,95253,GRP_NETWORK,NETWORK,AmeriFlux -US-UTW,95255,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,Remote sensing calibration -US-UTW,95258,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"1594 W North Temple, Salt Lake City UT 84104, USA" -US-UTW,95250,GRP_SITE_CHAR,TERRAIN,Flat -US-UTW,95250,GRP_SITE_CHAR,ASPECT,FLAT -US-UTW,95250,GRP_SITE_CHAR,WIND_DIRECTION,NNW -US-UTW,95250,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,2000 -US-UTW,95250,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,22 -US-UTW,95257,GRP_SITE_DESC,SITE_DESC,This station is located between two large pivots that irrigate alfalpha. The pivots are in line with the predominant wind direction. The farm is no-till and uses canal water to irrigate. The field is grazed by cattle in the early winter. -US-UTW,95246,GRP_SITE_FUNDING,SITE_FUNDING,"Utah Geological Survey, Central Utah Water Conservancy District" -US-UTW,95264,GRP_STATE,STATE,UT -US-UTW,98426,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Kathryn Ladig -US-UTW,98426,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-UTW,98426,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,kladig@utah.gov -US-UTW,98426,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Utah Geological Survey -US-UTW,95256,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Paul Inkenbrandt -US-UTW,95256,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-UTW,95256,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,paulinkenbrandt@utah.gov -US-UTW,95256,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Utah Geological Survey -US-UTW,95256,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1594 W North Temple, Salt Lake City UT 84104, USA" -US-UTW,95262,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-UTW,95251,GRP_TOWER_TYPE,TOWER_TYPE,tripod -US-UTW,95374,GRP_URL,URL,https://geology.utah.gov -US-UTW,24001177,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-UTW -US-UTW,95249,GRP_UTC_OFFSET,UTC_OFFSET,7 -US-UTW,95249,GRP_UTC_OFFSET,UTC_OFFSET_COMMENT,MST -US-Var,11322,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,"This research was supported in part by the Office of Science (BER), U.S. Department of Energy, Grant No. DE-FG02-03ER63638" -US-Var,18766,GRP_AG_BIOMASS_GRASS,AG_BIOMASS_GRASS,0.18958333333 -US-Var,18766,GRP_AG_BIOMASS_GRASS,AG_BIOMASS_GRASS_SPATIAL_VARIABILITY,0.11019651008 -US-Var,18766,GRP_AG_BIOMASS_GRASS,AG_BIOMASS_GRASS_ORGAN,Total -US-Var,18766,GRP_AG_BIOMASS_GRASS,AG_BIOMASS_GRASS_PHEN,Mixed/unknown -US-Var,18766,GRP_AG_BIOMASS_GRASS,AG_BIOMASS_GRASS_UNIT,kgDM m-2 -US-Var,18766,GRP_AG_BIOMASS_GRASS,AG_BIOMASS_APPROACH,six 1 m2 squares -US-Var,18766,GRP_AG_BIOMASS_GRASS,AG_BIOMASS_DATE,20040506 -US-Var,18766,GRP_AG_BIOMASS_GRASS,AG_BIOMASS_COMMENT,DDB Biomet Lab -US-Var,18770,GRP_AG_BIOMASS_GRASS,AG_BIOMASS_GRASS,0.2129375 -US-Var,18770,GRP_AG_BIOMASS_GRASS,AG_BIOMASS_GRASS_SPATIAL_VARIABILITY,0.024813444566 -US-Var,18770,GRP_AG_BIOMASS_GRASS,AG_BIOMASS_GRASS_ORGAN,Total -US-Var,18770,GRP_AG_BIOMASS_GRASS,AG_BIOMASS_GRASS_PHEN,Mixed/unknown -US-Var,18770,GRP_AG_BIOMASS_GRASS,AG_BIOMASS_GRASS_UNIT,kgDM m-2 -US-Var,18770,GRP_AG_BIOMASS_GRASS,AG_BIOMASS_APPROACH,six 1 m2 squares -US-Var,18770,GRP_AG_BIOMASS_GRASS,AG_BIOMASS_DATE,20080531 -US-Var,18770,GRP_AG_BIOMASS_GRASS,AG_BIOMASS_COMMENT,DDB Biomet Lab -US-Var,18768,GRP_AG_BIOMASS_GRASS,AG_BIOMASS_GRASS,0.29245833333 -US-Var,18768,GRP_AG_BIOMASS_GRASS,AG_BIOMASS_GRASS_SPATIAL_VARIABILITY,0.07567419199 -US-Var,18768,GRP_AG_BIOMASS_GRASS,AG_BIOMASS_GRASS_ORGAN,Total -US-Var,18768,GRP_AG_BIOMASS_GRASS,AG_BIOMASS_GRASS_PHEN,Mixed/unknown -US-Var,18768,GRP_AG_BIOMASS_GRASS,AG_BIOMASS_GRASS_UNIT,kgDM m-2 -US-Var,18768,GRP_AG_BIOMASS_GRASS,AG_BIOMASS_APPROACH,six 1 m2 squares -US-Var,18768,GRP_AG_BIOMASS_GRASS,AG_BIOMASS_DATE,20060528 -US-Var,18768,GRP_AG_BIOMASS_GRASS,AG_BIOMASS_COMMENT,DDB Biomet Lab -US-Var,18759,GRP_AG_BIOMASS_GRASS,AG_BIOMASS_GRASS,0.29370484309 -US-Var,18759,GRP_AG_BIOMASS_GRASS,AG_BIOMASS_GRASS_ORGAN,Total -US-Var,18759,GRP_AG_BIOMASS_GRASS,AG_BIOMASS_GRASS_PHEN,Mixed/unknown -US-Var,18759,GRP_AG_BIOMASS_GRASS,AG_BIOMASS_GRASS_UNIT,kgDM m-2 -US-Var,18759,GRP_AG_BIOMASS_GRASS,AG_BIOMASS_APPROACH,one 10 m2 square -US-Var,18759,GRP_AG_BIOMASS_GRASS,AG_BIOMASS_DATE,19970730 -US-Var,18759,GRP_AG_BIOMASS_GRASS,AG_BIOMASS_COMMENT,data from wefrost@ucdavis.edu -US-Var,18762,GRP_AG_BIOMASS_GRASS,AG_BIOMASS_GRASS,0.31197034841 -US-Var,18762,GRP_AG_BIOMASS_GRASS,AG_BIOMASS_GRASS_ORGAN,Total -US-Var,18762,GRP_AG_BIOMASS_GRASS,AG_BIOMASS_GRASS_PHEN,Mixed/unknown -US-Var,18762,GRP_AG_BIOMASS_GRASS,AG_BIOMASS_GRASS_UNIT,kgDM m-2 -US-Var,18762,GRP_AG_BIOMASS_GRASS,AG_BIOMASS_APPROACH,one 10 m2 square -US-Var,18762,GRP_AG_BIOMASS_GRASS,AG_BIOMASS_DATE,20000730 -US-Var,18762,GRP_AG_BIOMASS_GRASS,AG_BIOMASS_COMMENT,data from wefrost@ucdavis.edu -US-Var,18773,GRP_AG_BIOMASS_GRASS,AG_BIOMASS_GRASS,0.3251875 -US-Var,18773,GRP_AG_BIOMASS_GRASS,AG_BIOMASS_GRASS_SPATIAL_VARIABILITY,0.13476572554 -US-Var,18773,GRP_AG_BIOMASS_GRASS,AG_BIOMASS_GRASS_ORGAN,Total -US-Var,18773,GRP_AG_BIOMASS_GRASS,AG_BIOMASS_GRASS_PHEN,Mixed/unknown -US-Var,18773,GRP_AG_BIOMASS_GRASS,AG_BIOMASS_GRASS_UNIT,kgDM m-2 -US-Var,18773,GRP_AG_BIOMASS_GRASS,AG_BIOMASS_APPROACH,six 1 m2 squares -US-Var,18773,GRP_AG_BIOMASS_GRASS,AG_BIOMASS_DATE,20110706 -US-Var,18773,GRP_AG_BIOMASS_GRASS,AG_BIOMASS_COMMENT,DDB Biomet Lab -US-Var,18761,GRP_AG_BIOMASS_GRASS,AG_BIOMASS_GRASS,0.39803113417 -US-Var,18761,GRP_AG_BIOMASS_GRASS,AG_BIOMASS_GRASS_ORGAN,Total -US-Var,18761,GRP_AG_BIOMASS_GRASS,AG_BIOMASS_GRASS_PHEN,Mixed/unknown -US-Var,18761,GRP_AG_BIOMASS_GRASS,AG_BIOMASS_GRASS_UNIT,kgDM m-2 -US-Var,18761,GRP_AG_BIOMASS_GRASS,AG_BIOMASS_APPROACH,one 10 m2 square -US-Var,18761,GRP_AG_BIOMASS_GRASS,AG_BIOMASS_DATE,19990730 -US-Var,18761,GRP_AG_BIOMASS_GRASS,AG_BIOMASS_COMMENT,data from wefrost@ucdavis.edu -US-Var,18763,GRP_AG_BIOMASS_GRASS,AG_BIOMASS_GRASS,0.4285109958 -US-Var,18763,GRP_AG_BIOMASS_GRASS,AG_BIOMASS_GRASS_ORGAN,Total -US-Var,18763,GRP_AG_BIOMASS_GRASS,AG_BIOMASS_GRASS_PHEN,Mixed/unknown -US-Var,18763,GRP_AG_BIOMASS_GRASS,AG_BIOMASS_GRASS_UNIT,kgDM m-2 -US-Var,18763,GRP_AG_BIOMASS_GRASS,AG_BIOMASS_APPROACH,one 10 m2 square -US-Var,18763,GRP_AG_BIOMASS_GRASS,AG_BIOMASS_DATE,20010730 -US-Var,18763,GRP_AG_BIOMASS_GRASS,AG_BIOMASS_COMMENT,data from wefrost@ucdavis.edu -US-Var,18764,GRP_AG_BIOMASS_GRASS,AG_BIOMASS_GRASS,0.44106152706 -US-Var,18764,GRP_AG_BIOMASS_GRASS,AG_BIOMASS_GRASS_ORGAN,Total -US-Var,18764,GRP_AG_BIOMASS_GRASS,AG_BIOMASS_GRASS_PHEN,Mixed/unknown -US-Var,18764,GRP_AG_BIOMASS_GRASS,AG_BIOMASS_GRASS_UNIT,kgDM m-2 -US-Var,18764,GRP_AG_BIOMASS_GRASS,AG_BIOMASS_APPROACH,one 10 m2 square -US-Var,18764,GRP_AG_BIOMASS_GRASS,AG_BIOMASS_DATE,20020730 -US-Var,18764,GRP_AG_BIOMASS_GRASS,AG_BIOMASS_COMMENT,data from wefrost@ucdavis.edu -US-Var,18769,GRP_AG_BIOMASS_GRASS,AG_BIOMASS_GRASS,0.46734508333 -US-Var,18769,GRP_AG_BIOMASS_GRASS,AG_BIOMASS_GRASS_SPATIAL_VARIABILITY,0.14828315819 -US-Var,18769,GRP_AG_BIOMASS_GRASS,AG_BIOMASS_GRASS_ORGAN,Total -US-Var,18769,GRP_AG_BIOMASS_GRASS,AG_BIOMASS_GRASS_PHEN,Mixed/unknown -US-Var,18769,GRP_AG_BIOMASS_GRASS,AG_BIOMASS_GRASS_UNIT,kgDM m-2 -US-Var,18769,GRP_AG_BIOMASS_GRASS,AG_BIOMASS_APPROACH,six 1 m2 squares -US-Var,18769,GRP_AG_BIOMASS_GRASS,AG_BIOMASS_DATE,20070525 -US-Var,18769,GRP_AG_BIOMASS_GRASS,AG_BIOMASS_COMMENT,DDB Biomet Lab -US-Var,18760,GRP_AG_BIOMASS_GRASS,AG_BIOMASS_GRASS,0.5095291574 -US-Var,18760,GRP_AG_BIOMASS_GRASS,AG_BIOMASS_GRASS_ORGAN,Total -US-Var,18760,GRP_AG_BIOMASS_GRASS,AG_BIOMASS_GRASS_PHEN,Mixed/unknown -US-Var,18760,GRP_AG_BIOMASS_GRASS,AG_BIOMASS_GRASS_UNIT,kgDM m-2 -US-Var,18760,GRP_AG_BIOMASS_GRASS,AG_BIOMASS_APPROACH,one 10 m2 square -US-Var,18760,GRP_AG_BIOMASS_GRASS,AG_BIOMASS_DATE,19980730 -US-Var,18760,GRP_AG_BIOMASS_GRASS,AG_BIOMASS_COMMENT,data from wefrost@ucdavis.edu -US-Var,18765,GRP_AG_BIOMASS_GRASS,AG_BIOMASS_GRASS,0.52398666667 -US-Var,18765,GRP_AG_BIOMASS_GRASS,AG_BIOMASS_GRASS_ORGAN,Total -US-Var,18765,GRP_AG_BIOMASS_GRASS,AG_BIOMASS_GRASS_PHEN,Mixed/unknown -US-Var,18765,GRP_AG_BIOMASS_GRASS,AG_BIOMASS_GRASS_UNIT,kgDM m-2 -US-Var,18765,GRP_AG_BIOMASS_GRASS,AG_BIOMASS_APPROACH,one 10 m2 square -US-Var,18765,GRP_AG_BIOMASS_GRASS,AG_BIOMASS_DATE,20030730 -US-Var,18765,GRP_AG_BIOMASS_GRASS,AG_BIOMASS_COMMENT,DDB Biomet Lab -US-Var,18758,GRP_AG_BIOMASS_GRASS,AG_BIOMASS_GRASS,0.55939510749 -US-Var,18758,GRP_AG_BIOMASS_GRASS,AG_BIOMASS_GRASS_ORGAN,Total -US-Var,18758,GRP_AG_BIOMASS_GRASS,AG_BIOMASS_GRASS_PHEN,Senescent -US-Var,18758,GRP_AG_BIOMASS_GRASS,AG_BIOMASS_GRASS_UNIT,kgDM m-2 -US-Var,18758,GRP_AG_BIOMASS_GRASS,AG_BIOMASS_APPROACH,one 10 m2 square -US-Var,18758,GRP_AG_BIOMASS_GRASS,AG_BIOMASS_DATE,19960730 -US-Var,18758,GRP_AG_BIOMASS_GRASS,AG_BIOMASS_COMMENT,data from wefrost@ucdavis.edu -US-Var,18774,GRP_AG_BIOMASS_GRASS,AG_BIOMASS_GRASS,0.57047916667 -US-Var,18774,GRP_AG_BIOMASS_GRASS,AG_BIOMASS_GRASS_SPATIAL_VARIABILITY,0.037413511374 -US-Var,18774,GRP_AG_BIOMASS_GRASS,AG_BIOMASS_GRASS_ORGAN,Total -US-Var,18774,GRP_AG_BIOMASS_GRASS,AG_BIOMASS_GRASS_PHEN,Mixed/unknown -US-Var,18774,GRP_AG_BIOMASS_GRASS,AG_BIOMASS_GRASS_UNIT,kgDM m-2 -US-Var,18774,GRP_AG_BIOMASS_GRASS,AG_BIOMASS_APPROACH,six 1 m2 squares -US-Var,18774,GRP_AG_BIOMASS_GRASS,AG_BIOMASS_DATE,20120530 -US-Var,18774,GRP_AG_BIOMASS_GRASS,AG_BIOMASS_COMMENT,DDB Biomet Lab -US-Var,18771,GRP_AG_BIOMASS_GRASS,AG_BIOMASS_GRASS,0.61625 -US-Var,18771,GRP_AG_BIOMASS_GRASS,AG_BIOMASS_GRASS_SPATIAL_VARIABILITY,0.11813943364 -US-Var,18771,GRP_AG_BIOMASS_GRASS,AG_BIOMASS_GRASS_ORGAN,Total -US-Var,18771,GRP_AG_BIOMASS_GRASS,AG_BIOMASS_GRASS_PHEN,Mixed/unknown -US-Var,18771,GRP_AG_BIOMASS_GRASS,AG_BIOMASS_GRASS_UNIT,kgDM m-2 -US-Var,18771,GRP_AG_BIOMASS_GRASS,AG_BIOMASS_APPROACH,six 1 m2 squares -US-Var,18771,GRP_AG_BIOMASS_GRASS,AG_BIOMASS_DATE,20090527 -US-Var,18771,GRP_AG_BIOMASS_GRASS,AG_BIOMASS_COMMENT,DDB Biomet Lab -US-Var,18775,GRP_AG_BIOMASS_GRASS,AG_BIOMASS_GRASS,0.81735416667 -US-Var,18775,GRP_AG_BIOMASS_GRASS,AG_BIOMASS_GRASS_SPATIAL_VARIABILITY,0.18258074341 -US-Var,18775,GRP_AG_BIOMASS_GRASS,AG_BIOMASS_GRASS_ORGAN,Total -US-Var,18775,GRP_AG_BIOMASS_GRASS,AG_BIOMASS_GRASS_PHEN,Mixed/unknown -US-Var,18775,GRP_AG_BIOMASS_GRASS,AG_BIOMASS_GRASS_UNIT,kgDM m-2 -US-Var,18775,GRP_AG_BIOMASS_GRASS,AG_BIOMASS_APPROACH,six 1 m2 squares -US-Var,18775,GRP_AG_BIOMASS_GRASS,AG_BIOMASS_DATE,20130530 -US-Var,18775,GRP_AG_BIOMASS_GRASS,AG_BIOMASS_COMMENT,DDB Biomet Lab -US-Var,18772,GRP_AG_BIOMASS_GRASS,AG_BIOMASS_GRASS,0.912375 -US-Var,18772,GRP_AG_BIOMASS_GRASS,AG_BIOMASS_GRASS_SPATIAL_VARIABILITY,0.40189624263 -US-Var,18772,GRP_AG_BIOMASS_GRASS,AG_BIOMASS_GRASS_ORGAN,Total -US-Var,18772,GRP_AG_BIOMASS_GRASS,AG_BIOMASS_GRASS_PHEN,Mixed/unknown -US-Var,18772,GRP_AG_BIOMASS_GRASS,AG_BIOMASS_GRASS_UNIT,kgDM m-2 -US-Var,18772,GRP_AG_BIOMASS_GRASS,AG_BIOMASS_APPROACH,six 1 m2 squares -US-Var,18772,GRP_AG_BIOMASS_GRASS,AG_BIOMASS_DATE,20100610 -US-Var,18772,GRP_AG_BIOMASS_GRASS,AG_BIOMASS_COMMENT,DDB Biomet Lab -US-Var,18767,GRP_AG_BIOMASS_GRASS,AG_BIOMASS_GRASS,1.2890625 -US-Var,18767,GRP_AG_BIOMASS_GRASS,AG_BIOMASS_GRASS_SPATIAL_VARIABILITY,0.33151510147 -US-Var,18767,GRP_AG_BIOMASS_GRASS,AG_BIOMASS_GRASS_ORGAN,Total -US-Var,18767,GRP_AG_BIOMASS_GRASS,AG_BIOMASS_GRASS_PHEN,Mixed/unknown -US-Var,18767,GRP_AG_BIOMASS_GRASS,AG_BIOMASS_GRASS_UNIT,kgDM m-2 -US-Var,18767,GRP_AG_BIOMASS_GRASS,AG_BIOMASS_APPROACH,six 1 m2 squares -US-Var,18767,GRP_AG_BIOMASS_GRASS,AG_BIOMASS_DATE,20050610 -US-Var,18767,GRP_AG_BIOMASS_GRASS,AG_BIOMASS_COMMENT,DDB Biomet Lab -US-Var,11323,GRP_CLIM_AVG,MAT,15.8 -US-Var,11323,GRP_CLIM_AVG,MAP,559 -US-Var,11323,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Csa -US-Var,27000441,GRP_COUNTRY,COUNTRY,USA -US-Var,964,GRP_DM_GRAZE,DM_GRAZE,Other -US-Var,964,GRP_DM_GRAZE,DM_COMMENT,grazing intensity: ~100 cows per 900 acres. -US-Var,15608,GRP_DOI,DOI,10.17190/AMF/1245984 -US-Var,15608,GRP_DOI,DOI_CITATION,"Siyan Ma, Liukang Xu, Joseph Verfaillie, Dennis Baldocchi (2022), AmeriFlux BASE US-Var Vaira Ranch- Ione, Ver. 17-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1245984" -US-Var,15608,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-Var,94041,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Var,94041,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Siyan Ma -US-Var,94041,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Var,94041,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,1 -US-Var,94041,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0002-6145-196X -US-Var,94041,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,syma@berkeley.edu -US-Var,94041,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"University of California, Berkeley" -US-Var,94041,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,20050307 -US-Var,94072,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Var,94072,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Liukang Xu -US-Var,94072,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Var,94072,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,2 -US-Var,94072,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0002-1910-8383 -US-Var,94072,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,liukang.xu@licor.com -US-Var,94072,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"University of California, Berkeley" -US-Var,94072,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,200102 -US-Var,94072,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_END,200403 -US-Var,94009,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Var,94009,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Joseph Verfaillie -US-Var,94009,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Var,94009,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,8 -US-Var,94009,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0002-7009-8942 -US-Var,94009,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,jverfail@berkeley.edu -US-Var,94009,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"University of California, Berkeley" -US-Var,94009,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,200808 -US-Var,94119,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Var,94119,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Dennis Baldocchi -US-Var,94119,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Var,94119,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,9 -US-Var,94119,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0003-3496-4919 -US-Var,94119,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,Baldocchi@berkeley.edu -US-Var,94119,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"University of California, Berkeley" -US-Var,94119,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,20001001 -US-Var,31832,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,"University of California, Berkeley" -US-Var,31832,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-Var,31831,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,DOE/TCP -US-Var,31831,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-Var,8464,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Grazing -US-Var,91437,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Var,91437,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-Var,91437,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20001022 -US-Var,91437,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Var,91427,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Var,91427,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-Var,91427,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20001022 -US-Var,91427,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Var,23000441,GRP_HEADER,SITE_NAME,Vaira Ranch- Ione -US-Var,89505,GRP_HEIGHTC,HEIGHTC,0.05375 -US-Var,89505,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Var,89505,GRP_HEIGHTC,HEIGHTC_APPROACH,direct with measure tape -US-Var,89505,GRP_HEIGHTC,HEIGHTC_DATE,20001022 -US-Var,89506,GRP_HEIGHTC,HEIGHTC,0.025 -US-Var,89506,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Var,89506,GRP_HEIGHTC,HEIGHTC_APPROACH,direct with measure tape -US-Var,89506,GRP_HEIGHTC,HEIGHTC_DATE,20001022 -US-Var,89517,GRP_HEIGHTC,HEIGHTC,0.0205 -US-Var,89517,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Var,89517,GRP_HEIGHTC,HEIGHTC_APPROACH,direct with measure tape -US-Var,89517,GRP_HEIGHTC,HEIGHTC_DATE,20001104 -US-Var,89522,GRP_HEIGHTC,HEIGHTC,0.0415 -US-Var,89522,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Var,89522,GRP_HEIGHTC,HEIGHTC_APPROACH,direct with measure tape -US-Var,89522,GRP_HEIGHTC,HEIGHTC_DATE,20001104 -US-Var,89496,GRP_HEIGHTC,HEIGHTC,0.038125 -US-Var,89496,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Var,89496,GRP_HEIGHTC,HEIGHTC_APPROACH,direct with measure tape -US-Var,89496,GRP_HEIGHTC,HEIGHTC_DATE,20010103 -US-Var,89531,GRP_HEIGHTC,HEIGHTC,0.018697148 -US-Var,89531,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Var,89531,GRP_HEIGHTC,HEIGHTC_APPROACH,direct with measure tape -US-Var,89531,GRP_HEIGHTC,HEIGHTC_DATE,20010103 -US-Var,89498,GRP_HEIGHTC,HEIGHTC,0.016475089 -US-Var,89498,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Var,89498,GRP_HEIGHTC,HEIGHTC_APPROACH,direct with measure tape -US-Var,89498,GRP_HEIGHTC,HEIGHTC_DATE,20010207 -US-Var,89525,GRP_HEIGHTC,HEIGHTC,0.03 -US-Var,89525,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Var,89525,GRP_HEIGHTC,HEIGHTC_APPROACH,direct with measure tape -US-Var,89525,GRP_HEIGHTC,HEIGHTC_DATE,20010207 -US-Var,89495,GRP_HEIGHTC,HEIGHTC,0.00882 -US-Var,89495,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Var,89495,GRP_HEIGHTC,HEIGHTC_APPROACH,direct with measure tape -US-Var,89495,GRP_HEIGHTC,HEIGHTC_DATE,20020208 -US-Var,89497,GRP_HEIGHTC,HEIGHTC,0.0266 -US-Var,89497,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Var,89497,GRP_HEIGHTC,HEIGHTC_APPROACH,direct with measure tape -US-Var,89497,GRP_HEIGHTC,HEIGHTC_DATE,20020208 -US-Var,89508,GRP_HEIGHTC,HEIGHTC,0.061 -US-Var,89508,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Var,89508,GRP_HEIGHTC,HEIGHTC_APPROACH,direct with measure tape -US-Var,89508,GRP_HEIGHTC,HEIGHTC_DATE,20020228 -US-Var,89527,GRP_HEIGHTC,HEIGHTC,0.017 -US-Var,89527,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Var,89527,GRP_HEIGHTC,HEIGHTC_APPROACH,direct with measure tape -US-Var,89527,GRP_HEIGHTC,HEIGHTC_DATE,20020228 -US-Var,89492,GRP_HEIGHTC,HEIGHTC,0.067 -US-Var,89492,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Var,89492,GRP_HEIGHTC,HEIGHTC_APPROACH,direct with measure tape -US-Var,89492,GRP_HEIGHTC,HEIGHTC_DATE,20020320 -US-Var,89529,GRP_HEIGHTC,HEIGHTC,0.016 -US-Var,89529,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Var,89529,GRP_HEIGHTC,HEIGHTC_APPROACH,direct with measure tape -US-Var,89529,GRP_HEIGHTC,HEIGHTC_DATE,20020320 -US-Var,89486,GRP_HEIGHTC,HEIGHTC,0.0422 -US-Var,89486,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Var,89486,GRP_HEIGHTC,HEIGHTC_APPROACH,direct with measure tape -US-Var,89486,GRP_HEIGHTC,HEIGHTC_DATE,20020404 -US-Var,89501,GRP_HEIGHTC,HEIGHTC,0.1095 -US-Var,89501,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Var,89501,GRP_HEIGHTC,HEIGHTC_APPROACH,direct with measure tape -US-Var,89501,GRP_HEIGHTC,HEIGHTC_DATE,20020404 -US-Var,89502,GRP_HEIGHTC,HEIGHTC,0.232 -US-Var,89502,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Var,89502,GRP_HEIGHTC,HEIGHTC_APPROACH,direct with measure tape -US-Var,89502,GRP_HEIGHTC,HEIGHTC_DATE,20020411 -US-Var,89524,GRP_HEIGHTC,HEIGHTC,0.084 -US-Var,89524,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Var,89524,GRP_HEIGHTC,HEIGHTC_APPROACH,direct with measure tape -US-Var,89524,GRP_HEIGHTC,HEIGHTC_DATE,20020411 -US-Var,89494,GRP_HEIGHTC,HEIGHTC,0.299 -US-Var,89494,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Var,89494,GRP_HEIGHTC,HEIGHTC_APPROACH,direct with measure tape -US-Var,89494,GRP_HEIGHTC,HEIGHTC_DATE,20020418 -US-Var,89510,GRP_HEIGHTC,HEIGHTC,0.089 -US-Var,89510,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Var,89510,GRP_HEIGHTC,HEIGHTC_APPROACH,direct with measure tape -US-Var,89510,GRP_HEIGHTC,HEIGHTC_DATE,20020418 -US-Var,89509,GRP_HEIGHTC,HEIGHTC,0.407 -US-Var,89509,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Var,89509,GRP_HEIGHTC,HEIGHTC_APPROACH,direct with measure tape -US-Var,89509,GRP_HEIGHTC,HEIGHTC_DATE,20020426 -US-Var,89533,GRP_HEIGHTC,HEIGHTC,0.1086 -US-Var,89533,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Var,89533,GRP_HEIGHTC,HEIGHTC_APPROACH,direct with measure tape -US-Var,89533,GRP_HEIGHTC,HEIGHTC_DATE,20020426 -US-Var,89514,GRP_HEIGHTC,HEIGHTC,0.121 -US-Var,89514,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Var,89514,GRP_HEIGHTC,HEIGHTC_APPROACH,direct with measure tape -US-Var,89514,GRP_HEIGHTC,HEIGHTC_DATE,20020502 -US-Var,89534,GRP_HEIGHTC,HEIGHTC,0.55 -US-Var,89534,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Var,89534,GRP_HEIGHTC,HEIGHTC_APPROACH,direct with measure tape -US-Var,89534,GRP_HEIGHTC,HEIGHTC_DATE,20020502 -US-Var,89484,GRP_HEIGHTC,HEIGHTC,0.502 -US-Var,89484,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Var,89484,GRP_HEIGHTC,HEIGHTC_APPROACH,direct with measure tape -US-Var,89484,GRP_HEIGHTC,HEIGHTC_DATE,20020509 -US-Var,89490,GRP_HEIGHTC,HEIGHTC,0.142 -US-Var,89490,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Var,89490,GRP_HEIGHTC,HEIGHTC_APPROACH,direct with measure tape -US-Var,89490,GRP_HEIGHTC,HEIGHTC_DATE,20020509 -US-Var,89512,GRP_HEIGHTC,HEIGHTC,0.101 -US-Var,89512,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Var,89512,GRP_HEIGHTC,HEIGHTC_APPROACH,direct with measure tape -US-Var,89512,GRP_HEIGHTC,HEIGHTC_DATE,20020516 -US-Var,89521,GRP_HEIGHTC,HEIGHTC,0.506 -US-Var,89521,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Var,89521,GRP_HEIGHTC,HEIGHTC_APPROACH,direct with measure tape -US-Var,89521,GRP_HEIGHTC,HEIGHTC_DATE,20020516 -US-Var,89507,GRP_HEIGHTC,HEIGHTC,0.138 -US-Var,89507,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Var,89507,GRP_HEIGHTC,HEIGHTC_APPROACH,direct with measure tape -US-Var,89507,GRP_HEIGHTC,HEIGHTC_DATE,20020530 -US-Var,89532,GRP_HEIGHTC,HEIGHTC,0.503 -US-Var,89532,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Var,89532,GRP_HEIGHTC,HEIGHTC_APPROACH,direct with measure tape -US-Var,89532,GRP_HEIGHTC,HEIGHTC_DATE,20020530 -US-Var,89513,GRP_HEIGHTC,HEIGHTC,0.45 -US-Var,89513,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Var,89513,GRP_HEIGHTC,HEIGHTC_APPROACH,direct with measure tape -US-Var,89513,GRP_HEIGHTC,HEIGHTC_DATE,20020614 -US-Var,89504,GRP_HEIGHTC,HEIGHTC,0.325 -US-Var,89504,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Var,89504,GRP_HEIGHTC,HEIGHTC_APPROACH,direct with measure tape -US-Var,89504,GRP_HEIGHTC,HEIGHTC_DATE,20020629 -US-Var,89519,GRP_HEIGHTC,HEIGHTC,0.245 -US-Var,89519,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Var,89519,GRP_HEIGHTC,HEIGHTC_APPROACH,direct with measure tape -US-Var,89519,GRP_HEIGHTC,HEIGHTC_DATE,20020714 -US-Var,89526,GRP_HEIGHTC,HEIGHTC,0.184 -US-Var,89526,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Var,89526,GRP_HEIGHTC,HEIGHTC_APPROACH,direct with measure tape -US-Var,89526,GRP_HEIGHTC,HEIGHTC_DATE,20020729 -US-Var,89511,GRP_HEIGHTC,HEIGHTC,0.131 -US-Var,89511,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Var,89511,GRP_HEIGHTC,HEIGHTC_APPROACH,direct with measure tape -US-Var,89511,GRP_HEIGHTC,HEIGHTC_DATE,20020813 -US-Var,89500,GRP_HEIGHTC,HEIGHTC,0.107 -US-Var,89500,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Var,89500,GRP_HEIGHTC,HEIGHTC_APPROACH,direct with measure tape -US-Var,89500,GRP_HEIGHTC,HEIGHTC_DATE,20020828 -US-Var,89483,GRP_HEIGHTC,HEIGHTC,0.077 -US-Var,89483,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Var,89483,GRP_HEIGHTC,HEIGHTC_APPROACH,direct with measure tape -US-Var,89483,GRP_HEIGHTC,HEIGHTC_DATE,20020912 -US-Var,89491,GRP_HEIGHTC,HEIGHTC,0.064 -US-Var,89491,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Var,89491,GRP_HEIGHTC,HEIGHTC_APPROACH,direct with measure tape -US-Var,89491,GRP_HEIGHTC,HEIGHTC_DATE,20020927 -US-Var,89520,GRP_HEIGHTC,HEIGHTC,0.06 -US-Var,89520,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Var,89520,GRP_HEIGHTC,HEIGHTC_APPROACH,direct with measure tape -US-Var,89520,GRP_HEIGHTC,HEIGHTC_DATE,20021012 -US-Var,89503,GRP_HEIGHTC,HEIGHTC,0.05 -US-Var,89503,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Var,89503,GRP_HEIGHTC,HEIGHTC_APPROACH,direct with measure tape -US-Var,89503,GRP_HEIGHTC,HEIGHTC_DATE,20021027 -US-Var,89488,GRP_HEIGHTC,HEIGHTC,0.05 -US-Var,89488,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Var,89488,GRP_HEIGHTC,HEIGHTC_APPROACH,direct with measure tape -US-Var,89488,GRP_HEIGHTC,HEIGHTC_DATE,20021111 -US-Var,89489,GRP_HEIGHTC,HEIGHTC,0.05 -US-Var,89489,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Var,89489,GRP_HEIGHTC,HEIGHTC_APPROACH,direct with measure tape -US-Var,89489,GRP_HEIGHTC,HEIGHTC_DATE,20021126 -US-Var,89516,GRP_HEIGHTC,HEIGHTC,0.05 -US-Var,89516,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Var,89516,GRP_HEIGHTC,HEIGHTC_APPROACH,direct with measure tape -US-Var,89516,GRP_HEIGHTC,HEIGHTC_DATE,20021211 -US-Var,89530,GRP_HEIGHTC,HEIGHTC,0.05 -US-Var,89530,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Var,89530,GRP_HEIGHTC,HEIGHTC_APPROACH,direct with measure tape -US-Var,89530,GRP_HEIGHTC,HEIGHTC_DATE,20021226 -US-Var,89487,GRP_HEIGHTC,HEIGHTC,0.073213772 -US-Var,89487,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Var,89487,GRP_HEIGHTC,HEIGHTC_APPROACH,direct with measure tape -US-Var,89487,GRP_HEIGHTC,HEIGHTC_DATE,20120419 -US-Var,89518,GRP_HEIGHTC,HEIGHTC,0.165384615 -US-Var,89518,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Var,89518,GRP_HEIGHTC,HEIGHTC_APPROACH,direct with measure tape -US-Var,89518,GRP_HEIGHTC,HEIGHTC_DATE,20120419 -US-Var,89493,GRP_HEIGHTC,HEIGHTC,0.154189361 -US-Var,89493,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Var,89493,GRP_HEIGHTC,HEIGHTC_APPROACH,direct with measure tape -US-Var,89493,GRP_HEIGHTC,HEIGHTC_DATE,20120504 -US-Var,89528,GRP_HEIGHTC,HEIGHTC,0.440769231 -US-Var,89528,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Var,89528,GRP_HEIGHTC,HEIGHTC_APPROACH,direct with measure tape -US-Var,89528,GRP_HEIGHTC,HEIGHTC_DATE,20120504 -US-Var,89485,GRP_HEIGHTC,HEIGHTC,0.5865625 -US-Var,89485,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Var,89485,GRP_HEIGHTC,HEIGHTC_APPROACH,direct with measure tape -US-Var,89485,GRP_HEIGHTC,HEIGHTC_DATE,20120518 -US-Var,89515,GRP_HEIGHTC,HEIGHTC,0.235681707 -US-Var,89515,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Var,89515,GRP_HEIGHTC,HEIGHTC_APPROACH,direct with measure tape -US-Var,89515,GRP_HEIGHTC,HEIGHTC_DATE,20120518 -US-Var,89499,GRP_HEIGHTC,HEIGHTC,0.081547532 -US-Var,89499,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Var,89499,GRP_HEIGHTC,HEIGHTC_APPROACH,direct with measure tape -US-Var,89499,GRP_HEIGHTC,HEIGHTC_DATE,20130410 -US-Var,89523,GRP_HEIGHTC,HEIGHTC,0.16 -US-Var,89523,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Var,89523,GRP_HEIGHTC,HEIGHTC_APPROACH,direct with measure tape -US-Var,89523,GRP_HEIGHTC,HEIGHTC_DATE,20130410 -US-Var,89568,GRP_HEIGHTC,HEIGHTC,0.068 -US-Var,89568,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Grass -US-Var,89568,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Var,89568,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Var,89568,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,16 -US-Var,89568,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Var,89568,GRP_HEIGHTC,HEIGHTC_DATE,20140318 -US-Var,89568,GRP_HEIGHTC,HEIGHTC_COMMENT,Inside fenced area - not grazed -US-Var,89554,GRP_HEIGHTC,HEIGHTC,0.046 -US-Var,89554,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Grass -US-Var,89554,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Var,89554,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Var,89554,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Var,89554,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Var,89554,GRP_HEIGHTC,HEIGHTC_DATE,20140327 -US-Var,89554,GRP_HEIGHTC,HEIGHTC_COMMENT,Inside fenced area - not grazed -US-Var,89583,GRP_HEIGHTC,HEIGHTC,0.171 -US-Var,89583,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Grass -US-Var,89583,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Var,89583,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Var,89583,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Var,89583,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Var,89583,GRP_HEIGHTC,HEIGHTC_DATE,20140327 -US-Var,89583,GRP_HEIGHTC,HEIGHTC_COMMENT,Inside fenced area - not grazed -US-Var,89569,GRP_HEIGHTC,HEIGHTC,0.204 -US-Var,89569,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Grass -US-Var,89569,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Var,89569,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Var,89569,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,24 -US-Var,89569,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Var,89569,GRP_HEIGHTC,HEIGHTC_DATE,20140408 -US-Var,89569,GRP_HEIGHTC,HEIGHTC_COMMENT,Inside fenced area - not grazed -US-Var,89579,GRP_HEIGHTC,HEIGHTC,0.061 -US-Var,89579,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Grass -US-Var,89579,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Var,89579,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Var,89579,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,24 -US-Var,89579,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Var,89579,GRP_HEIGHTC,HEIGHTC_DATE,20140408 -US-Var,89579,GRP_HEIGHTC,HEIGHTC_COMMENT,Inside fenced area - not grazed -US-Var,89550,GRP_HEIGHTC,HEIGHTC,0.175 -US-Var,89550,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Grass -US-Var,89550,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Var,89550,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Var,89550,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Var,89550,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Var,89550,GRP_HEIGHTC,HEIGHTC_DATE,20140422 -US-Var,89550,GRP_HEIGHTC,HEIGHTC_COMMENT,Inside fenced area - not grazed -US-Var,89564,GRP_HEIGHTC,HEIGHTC,0.42 -US-Var,89564,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Grass -US-Var,89564,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Var,89564,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Var,89564,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Var,89564,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Var,89564,GRP_HEIGHTC,HEIGHTC_DATE,20140422 -US-Var,89564,GRP_HEIGHTC,HEIGHTC_COMMENT,Inside fenced area - not grazed -US-Var,89562,GRP_HEIGHTC,HEIGHTC,0.681 -US-Var,89562,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Grass -US-Var,89562,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Var,89562,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Var,89562,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,10 -US-Var,89562,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Var,89562,GRP_HEIGHTC,HEIGHTC_DATE,20140508 -US-Var,89562,GRP_HEIGHTC,HEIGHTC_COMMENT,Outside fenced area - grazed -US-Var,89586,GRP_HEIGHTC,HEIGHTC,0.401 -US-Var,89586,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Grass -US-Var,89586,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Var,89586,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Var,89586,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,10 -US-Var,89586,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Var,89586,GRP_HEIGHTC,HEIGHTC_DATE,20140508 -US-Var,89586,GRP_HEIGHTC,HEIGHTC_COMMENT,Outside fenced area - grazed -US-Var,89543,GRP_HEIGHTC,HEIGHTC,0.417 -US-Var,89543,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Grass -US-Var,89543,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Var,89543,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Var,89543,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,6 -US-Var,89543,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Var,89543,GRP_HEIGHTC,HEIGHTC_DATE,20140611 -US-Var,89543,GRP_HEIGHTC,HEIGHTC_COMMENT,Outside fenced area - grazed -US-Var,89563,GRP_HEIGHTC,HEIGHTC,0.525 -US-Var,89563,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Grass -US-Var,89563,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Var,89563,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Var,89563,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,6 -US-Var,89563,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Var,89563,GRP_HEIGHTC,HEIGHTC_DATE,20140611 -US-Var,89563,GRP_HEIGHTC,HEIGHTC_COMMENT,Outside fenced area - grazed -US-Var,89544,GRP_HEIGHTC,HEIGHTC,0.04 -US-Var,89544,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Grass -US-Var,89544,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Var,89544,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Var,89544,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,6 -US-Var,89544,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Var,89544,GRP_HEIGHTC,HEIGHTC_DATE,20141126 -US-Var,89544,GRP_HEIGHTC,HEIGHTC_COMMENT,Outside fenced area - grazed -US-Var,89584,GRP_HEIGHTC,HEIGHTC,0.011 -US-Var,89584,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Grass -US-Var,89584,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Var,89584,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Var,89584,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,6 -US-Var,89584,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Var,89584,GRP_HEIGHTC,HEIGHTC_DATE,20141126 -US-Var,89584,GRP_HEIGHTC,HEIGHTC_COMMENT,Outside fenced area - grazed -US-Var,89558,GRP_HEIGHTC,HEIGHTC,0.047 -US-Var,89558,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Grass -US-Var,89558,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Var,89558,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Var,89558,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,12 -US-Var,89558,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Var,89558,GRP_HEIGHTC,HEIGHTC_DATE,20141209 -US-Var,89558,GRP_HEIGHTC,HEIGHTC_COMMENT,Inside fenced area - not grazed -US-Var,89574,GRP_HEIGHTC,HEIGHTC,0.015 -US-Var,89574,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Grass -US-Var,89574,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Var,89574,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Var,89574,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,12 -US-Var,89574,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Var,89574,GRP_HEIGHTC,HEIGHTC_DATE,20141209 -US-Var,89574,GRP_HEIGHTC,HEIGHTC_COMMENT,Inside fenced area - not grazed -US-Var,89572,GRP_HEIGHTC,HEIGHTC,0.152 -US-Var,89572,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Grass -US-Var,89572,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Var,89572,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Var,89572,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Var,89572,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Var,89572,GRP_HEIGHTC,HEIGHTC_DATE,20150406 -US-Var,89572,GRP_HEIGHTC,HEIGHTC_COMMENT,From inside fenced area -US-Var,89581,GRP_HEIGHTC,HEIGHTC,0.294 -US-Var,89581,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Grass -US-Var,89581,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Var,89581,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Var,89581,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,20 -US-Var,89581,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Var,89581,GRP_HEIGHTC,HEIGHTC_DATE,20150406 -US-Var,89581,GRP_HEIGHTC,HEIGHTC_COMMENT,From inside fenced area -US-Var,89538,GRP_HEIGHTC,HEIGHTC,0.197 -US-Var,89538,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Grass -US-Var,89538,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Var,89538,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Var,89538,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,9 -US-Var,89538,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Var,89538,GRP_HEIGHTC,HEIGHTC_DATE,20150421 -US-Var,89566,GRP_HEIGHTC,HEIGHTC,0.477 -US-Var,89566,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Grass -US-Var,89566,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Var,89566,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Var,89566,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,9 -US-Var,89566,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Var,89566,GRP_HEIGHTC,HEIGHTC_DATE,20150421 -US-Var,89542,GRP_HEIGHTC,HEIGHTC,0.136 -US-Var,89542,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Grass -US-Var,89542,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Var,89542,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Var,89542,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,22 -US-Var,89542,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Var,89542,GRP_HEIGHTC,HEIGHTC_DATE,20150506 -US-Var,89578,GRP_HEIGHTC,HEIGHTC,0.473 -US-Var,89578,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Grass -US-Var,89578,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Var,89578,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Var,89578,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,22 -US-Var,89578,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Var,89578,GRP_HEIGHTC,HEIGHTC_DATE,20150506 -US-Var,89536,GRP_HEIGHTC,HEIGHTC,0.537 -US-Var,89536,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Grass -US-Var,89536,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Var,89536,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Var,89536,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,15 -US-Var,89536,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Var,89536,GRP_HEIGHTC,HEIGHTC_DATE,20150520 -US-Var,89548,GRP_HEIGHTC,HEIGHTC,0.221 -US-Var,89548,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Grass -US-Var,89548,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Var,89548,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Var,89548,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,15 -US-Var,89548,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Var,89548,GRP_HEIGHTC,HEIGHTC_DATE,20150520 -US-Var,89576,GRP_HEIGHTC,HEIGHTC,0.064 -US-Var,89576,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Grass -US-Var,89576,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Var,89576,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Var,89576,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,22 -US-Var,89576,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Var,89576,GRP_HEIGHTC,HEIGHTC_DATE,20160323 -US-Var,89576,GRP_HEIGHTC,HEIGHTC_COMMENT,Outside fenced area - grazed -US-Var,89582,GRP_HEIGHTC,HEIGHTC,0.118 -US-Var,89582,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Grass -US-Var,89582,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Var,89582,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Var,89582,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,22 -US-Var,89582,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Var,89582,GRP_HEIGHTC,HEIGHTC_DATE,20160323 -US-Var,89582,GRP_HEIGHTC,HEIGHTC_COMMENT,Outside fenced area - grazed -US-Var,89559,GRP_HEIGHTC,HEIGHTC,0.65 -US-Var,89559,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Grass -US-Var,89559,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Var,89559,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Var,89559,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,5 -US-Var,89559,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Var,89559,GRP_HEIGHTC,HEIGHTC_DATE,20160420 -US-Var,89559,GRP_HEIGHTC,HEIGHTC_COMMENT,Outside fenced area - grazed -US-Var,89585,GRP_HEIGHTC,HEIGHTC,0.038 -US-Var,89585,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Grass -US-Var,89585,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Var,89585,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Var,89585,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,5 -US-Var,89585,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Var,89585,GRP_HEIGHTC,HEIGHTC_DATE,20160420 -US-Var,89585,GRP_HEIGHTC,HEIGHTC_COMMENT,Outside fenced area - grazed -US-Var,89537,GRP_HEIGHTC,HEIGHTC,0.208 -US-Var,89537,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Grass -US-Var,89537,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Var,89537,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Var,89537,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,15 -US-Var,89537,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Var,89537,GRP_HEIGHTC,HEIGHTC_DATE,20160510 -US-Var,89537,GRP_HEIGHTC,HEIGHTC_COMMENT,Outside fenced area - grazed -US-Var,89541,GRP_HEIGHTC,HEIGHTC,0.681 -US-Var,89541,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Grass -US-Var,89541,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Var,89541,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Var,89541,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,15 -US-Var,89541,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Var,89541,GRP_HEIGHTC,HEIGHTC_DATE,20160510 -US-Var,89541,GRP_HEIGHTC,HEIGHTC_COMMENT,Outside fenced area - grazed -US-Var,89555,GRP_HEIGHTC,HEIGHTC,0.248 -US-Var,89555,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Grass -US-Var,89555,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Var,89555,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Var,89555,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,15 -US-Var,89555,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Var,89555,GRP_HEIGHTC,HEIGHTC_DATE,20160526 -US-Var,89555,GRP_HEIGHTC,HEIGHTC_COMMENT,Outside fenced area - grazed -US-Var,89567,GRP_HEIGHTC,HEIGHTC,0.705 -US-Var,89567,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Grass -US-Var,89567,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Var,89567,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Var,89567,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,15 -US-Var,89567,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Var,89567,GRP_HEIGHTC,HEIGHTC_DATE,20160526 -US-Var,89567,GRP_HEIGHTC,HEIGHTC_COMMENT,Outside fenced area - grazed -US-Var,89546,GRP_HEIGHTC,HEIGHTC,0.191 -US-Var,89546,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Grass -US-Var,89546,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Var,89546,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Var,89546,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,23 -US-Var,89546,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Var,89546,GRP_HEIGHTC,HEIGHTC_DATE,20160616 -US-Var,89546,GRP_HEIGHTC,HEIGHTC_COMMENT,Outside fenced area - grazed -US-Var,89570,GRP_HEIGHTC,HEIGHTC,0.655 -US-Var,89570,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Grass -US-Var,89570,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Var,89570,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Var,89570,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,23 -US-Var,89570,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Var,89570,GRP_HEIGHTC,HEIGHTC_DATE,20160616 -US-Var,89570,GRP_HEIGHTC,HEIGHTC_COMMENT,Outside fenced area - grazed -US-Var,89549,GRP_HEIGHTC,HEIGHTC,0.027 -US-Var,89549,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Grass -US-Var,89549,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Var,89549,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Var,89549,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,5 -US-Var,89549,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Var,89549,GRP_HEIGHTC,HEIGHTC_DATE,20161102 -US-Var,89549,GRP_HEIGHTC,HEIGHTC_COMMENT,Outside fenced area - grazed -US-Var,89560,GRP_HEIGHTC,HEIGHTC,0.096 -US-Var,89560,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Grass -US-Var,89560,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Var,89560,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Var,89560,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,5 -US-Var,89560,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Var,89560,GRP_HEIGHTC,HEIGHTC_DATE,20161102 -US-Var,89560,GRP_HEIGHTC,HEIGHTC_COMMENT,Outside fenced area - grazed -US-Var,89561,GRP_HEIGHTC,HEIGHTC,0.115 -US-Var,89561,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Grass -US-Var,89561,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Var,89561,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Var,89561,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,15 -US-Var,89561,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Var,89561,GRP_HEIGHTC,HEIGHTC_DATE,20170405 -US-Var,89561,GRP_HEIGHTC,HEIGHTC_COMMENT,Outside fenced area - grazed -US-Var,89573,GRP_HEIGHTC,HEIGHTC,0.285 -US-Var,89573,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Grass -US-Var,89573,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Var,89573,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Var,89573,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,15 -US-Var,89573,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Var,89573,GRP_HEIGHTC,HEIGHTC_DATE,20170405 -US-Var,89573,GRP_HEIGHTC,HEIGHTC_COMMENT,Outside fenced area - grazed -US-Var,89539,GRP_HEIGHTC,HEIGHTC,0.127 -US-Var,89539,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Grass -US-Var,89539,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Var,89539,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Var,89539,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,15 -US-Var,89539,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Var,89539,GRP_HEIGHTC,HEIGHTC_DATE,20170424 -US-Var,89539,GRP_HEIGHTC,HEIGHTC_COMMENT,Outside fenced area - grazed -US-Var,89575,GRP_HEIGHTC,HEIGHTC,0.568 -US-Var,89575,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Grass -US-Var,89575,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Var,89575,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Var,89575,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,15 -US-Var,89575,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Var,89575,GRP_HEIGHTC,HEIGHTC_DATE,20170424 -US-Var,89575,GRP_HEIGHTC,HEIGHTC_COMMENT,Outside fenced area - grazed -US-Var,89551,GRP_HEIGHTC,HEIGHTC,0.223 -US-Var,89551,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Grass -US-Var,89551,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Var,89551,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Var,89551,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,15 -US-Var,89551,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Var,89551,GRP_HEIGHTC,HEIGHTC_DATE,20170511 -US-Var,89551,GRP_HEIGHTC,HEIGHTC_COMMENT,Outside fenced area - grazed -US-Var,89577,GRP_HEIGHTC,HEIGHTC,0.643 -US-Var,89577,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Grass -US-Var,89577,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Var,89577,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Var,89577,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,15 -US-Var,89577,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Var,89577,GRP_HEIGHTC,HEIGHTC_DATE,20170511 -US-Var,89577,GRP_HEIGHTC,HEIGHTC_COMMENT,Outside fenced area - grazed -US-Var,89540,GRP_HEIGHTC,HEIGHTC,0.117 -US-Var,89540,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Grass -US-Var,89540,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Var,89540,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Var,89540,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,15 -US-Var,89540,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Var,89540,GRP_HEIGHTC,HEIGHTC_DATE,20180207 -US-Var,89587,GRP_HEIGHTC,HEIGHTC,0.041 -US-Var,89587,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Grass -US-Var,89587,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Var,89587,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Var,89587,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,15 -US-Var,89587,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Var,89587,GRP_HEIGHTC,HEIGHTC_DATE,20180207 -US-Var,89553,GRP_HEIGHTC,HEIGHTC,0.281 -US-Var,89553,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Grass -US-Var,89553,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Var,89553,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Var,89553,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,15 -US-Var,89553,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Var,89553,GRP_HEIGHTC,HEIGHTC_DATE,20180413 -US-Var,89553,GRP_HEIGHTC,HEIGHTC_COMMENT,uneven canopy due to grazing -US-Var,89580,GRP_HEIGHTC,HEIGHTC,0.069 -US-Var,89580,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Grass -US-Var,89580,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Var,89580,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Var,89580,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,15 -US-Var,89580,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Var,89580,GRP_HEIGHTC,HEIGHTC_DATE,20180413 -US-Var,89580,GRP_HEIGHTC,HEIGHTC_COMMENT,uneven canopy due to grazing -US-Var,89545,GRP_HEIGHTC,HEIGHTC,0.351 -US-Var,89545,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Grass -US-Var,89545,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Var,89545,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Var,89545,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,15 -US-Var,89545,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Var,89545,GRP_HEIGHTC,HEIGHTC_DATE,20180425 -US-Var,89556,GRP_HEIGHTC,HEIGHTC,0.098 -US-Var,89556,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Grass -US-Var,89556,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Var,89556,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Var,89556,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,15 -US-Var,89556,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Var,89556,GRP_HEIGHTC,HEIGHTC_DATE,20180425 -US-Var,89552,GRP_HEIGHTC,HEIGHTC,0.183 -US-Var,89552,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Grass -US-Var,89552,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Var,89552,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Var,89552,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,15 -US-Var,89552,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Var,89552,GRP_HEIGHTC,HEIGHTC_DATE,20180511 -US-Var,89571,GRP_HEIGHTC,HEIGHTC,0.45 -US-Var,89571,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Grass -US-Var,89571,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Var,89571,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Var,89571,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,15 -US-Var,89571,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Var,89571,GRP_HEIGHTC,HEIGHTC_DATE,20180511 -US-Var,89535,GRP_HEIGHTC,HEIGHTC,0.101 -US-Var,89535,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Grass -US-Var,89535,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Var,89535,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Var,89535,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,15 -US-Var,89535,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Var,89535,GRP_HEIGHTC,HEIGHTC_DATE,20180523 -US-Var,89557,GRP_HEIGHTC,HEIGHTC,0.459 -US-Var,89557,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Grass -US-Var,89557,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Var,89557,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Var,89557,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,15 -US-Var,89557,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Var,89557,GRP_HEIGHTC,HEIGHTC_DATE,20180523 -US-Var,89547,GRP_HEIGHTC,HEIGHTC,0.102 -US-Var,89547,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Grass -US-Var,89547,GRP_HEIGHTC,HEIGHTC_STATISTIC,Standard Deviation -US-Var,89547,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Var,89547,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,27 -US-Var,89547,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Var,89547,GRP_HEIGHTC,HEIGHTC_DATE,20190430 -US-Var,89547,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured by DS; 9 measurements each in 3 clip plot squares -US-Var,89565,GRP_HEIGHTC,HEIGHTC,0.297 -US-Var,89565,GRP_HEIGHTC,HEIGHTC_VEGTYPE,Grass -US-Var,89565,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Var,89565,GRP_HEIGHTC,HEIGHTC_STATISTIC_TYPE,Spatial -US-Var,89565,GRP_HEIGHTC,HEIGHTC_STATISTIC_NUMBER,27 -US-Var,89565,GRP_HEIGHTC,HEIGHTC_APPROACH,Tape measure from ground to top of plant -US-Var,89565,GRP_HEIGHTC,HEIGHTC_DATE,20190430 -US-Var,89565,GRP_HEIGHTC,HEIGHTC_COMMENT,Measured by DS; 9 measurements each in 3 clip plot squares -US-Var,11325,GRP_IGBP,IGBP,GRA -US-Var,11325,GRP_IGBP,IGBP_COMMENT,annual grasses and forbs -US-Var,19342,GRP_LAI,LAI_TYPE,LAI -US-Var,19343,GRP_LAI,LAI_TYPE,LAI -US-Var,19344,GRP_LAI,LAI_TYPE,LAI -US-Var,19345,GRP_LAI,LAI_TYPE,LAI -US-Var,19346,GRP_LAI,LAI_TYPE,LAI -US-Var,19347,GRP_LAI,LAI_TYPE,LAI -US-Var,19348,GRP_LAI,LAI_TYPE,LAI -US-Var,19349,GRP_LAI,LAI_TYPE,LAI -US-Var,19350,GRP_LAI,LAI_TYPE,LAI -US-Var,19351,GRP_LAI,LAI_TYPE,LAI -US-Var,19352,GRP_LAI,LAI_TYPE,LAI -US-Var,19353,GRP_LAI,LAI_TYPE,LAI -US-Var,19354,GRP_LAI,LAI_TYPE,LAI -US-Var,19355,GRP_LAI,LAI_TYPE,LAI -US-Var,19356,GRP_LAI,LAI_TYPE,LAI -US-Var,19357,GRP_LAI,LAI_TYPE,LAI -US-Var,19358,GRP_LAI,LAI_TYPE,LAI -US-Var,19359,GRP_LAI,LAI_TYPE,LAI -US-Var,19360,GRP_LAI,LAI_TYPE,LAI -US-Var,19361,GRP_LAI,LAI_TYPE,LAI -US-Var,19362,GRP_LAI,LAI_TYPE,LAI -US-Var,19363,GRP_LAI,LAI_TYPE,LAI -US-Var,19364,GRP_LAI,LAI_TYPE,LAI -US-Var,19365,GRP_LAI,LAI_TYPE,LAI -US-Var,19366,GRP_LAI,LAI_TYPE,LAI -US-Var,19367,GRP_LAI,LAI_TYPE,LAI -US-Var,19368,GRP_LAI,LAI_TYPE,LAI -US-Var,19369,GRP_LAI,LAI_TYPE,LAI -US-Var,19370,GRP_LAI,LAI_TYPE,LAI -US-Var,19371,GRP_LAI,LAI_TYPE,LAI -US-Var,19372,GRP_LAI,LAI_TYPE,LAI -US-Var,19373,GRP_LAI,LAI_TYPE,LAI -US-Var,19374,GRP_LAI,LAI_TYPE,LAI -US-Var,19375,GRP_LAI,LAI_TYPE,LAI -US-Var,19376,GRP_LAI,LAI_TYPE,LAI -US-Var,19377,GRP_LAI,LAI_TYPE,LAI -US-Var,19378,GRP_LAI,LAI_TYPE,LAI -US-Var,19379,GRP_LAI,LAI_TYPE,LAI -US-Var,19380,GRP_LAI,LAI_TYPE,LAI -US-Var,19381,GRP_LAI,LAI_TYPE,LAI -US-Var,19382,GRP_LAI,LAI_TYPE,LAI -US-Var,19383,GRP_LAI,LAI_TYPE,LAI -US-Var,19384,GRP_LAI,LAI_TYPE,LAI -US-Var,19385,GRP_LAI,LAI_TYPE,LAI -US-Var,19386,GRP_LAI,LAI_TYPE,LAI -US-Var,19387,GRP_LAI,LAI_TYPE,LAI -US-Var,19388,GRP_LAI,LAI_TYPE,LAI -US-Var,19389,GRP_LAI,LAI_TYPE,LAI -US-Var,19390,GRP_LAI,LAI_TYPE,LAI -US-Var,19391,GRP_LAI,LAI_TYPE,LAI -US-Var,19392,GRP_LAI,LAI_TYPE,LAI -US-Var,19393,GRP_LAI,LAI_TYPE,LAI -US-Var,19394,GRP_LAI,LAI_TYPE,LAI -US-Var,19395,GRP_LAI,LAI_TYPE,LAI -US-Var,19396,GRP_LAI,LAI_TYPE,LAI -US-Var,19397,GRP_LAI,LAI_TYPE,LAI -US-Var,19398,GRP_LAI,LAI_TYPE,LAI -US-Var,19399,GRP_LAI,LAI_TYPE,LAI -US-Var,19400,GRP_LAI,LAI_TYPE,LAI -US-Var,19401,GRP_LAI,LAI_TYPE,LAI -US-Var,19402,GRP_LAI,LAI_TYPE,LAI -US-Var,19403,GRP_LAI,LAI_TYPE,LAI -US-Var,19404,GRP_LAI,LAI_TYPE,LAI -US-Var,19405,GRP_LAI,LAI_TYPE,LAI -US-Var,19406,GRP_LAI,LAI_TYPE,LAI -US-Var,19407,GRP_LAI,LAI_TYPE,LAI -US-Var,19408,GRP_LAI,LAI_TYPE,LAI -US-Var,19409,GRP_LAI,LAI_TYPE,LAI -US-Var,19410,GRP_LAI,LAI_TYPE,LAI -US-Var,19411,GRP_LAI,LAI_TYPE,LAI -US-Var,19412,GRP_LAI,LAI_TYPE,LAI -US-Var,19413,GRP_LAI,LAI_TYPE,LAI -US-Var,19414,GRP_LAI,LAI_TYPE,LAI -US-Var,19415,GRP_LAI,LAI_TYPE,LAI -US-Var,19416,GRP_LAI,LAI_TYPE,LAI -US-Var,19417,GRP_LAI,LAI_TYPE,LAI -US-Var,19418,GRP_LAI,LAI_TYPE,LAI -US-Var,19419,GRP_LAI,LAI_TYPE,LAI -US-Var,19420,GRP_LAI,LAI_TYPE,LAI -US-Var,19421,GRP_LAI,LAI_TYPE,LAI -US-Var,19422,GRP_LAI,LAI_TYPE,LAI -US-Var,19423,GRP_LAI,LAI_TYPE,LAI -US-Var,19424,GRP_LAI,LAI_TYPE,LAI -US-Var,19425,GRP_LAI,LAI_TYPE,LAI -US-Var,19426,GRP_LAI,LAI_TYPE,LAI -US-Var,19427,GRP_LAI,LAI_TYPE,LAI -US-Var,19428,GRP_LAI,LAI_TYPE,LAI -US-Var,19429,GRP_LAI,LAI_TYPE,LAI -US-Var,19430,GRP_LAI,LAI_TYPE,LAI -US-Var,19431,GRP_LAI,LAI_TYPE,LAI -US-Var,19432,GRP_LAI,LAI_TYPE,LAI -US-Var,19433,GRP_LAI,LAI_TYPE,LAI -US-Var,19434,GRP_LAI,LAI_TYPE,LAI -US-Var,19435,GRP_LAI,LAI_TYPE,LAI -US-Var,19436,GRP_LAI,LAI_TYPE,LAI -US-Var,19437,GRP_LAI,LAI_TYPE,LAI -US-Var,19438,GRP_LAI,LAI_TYPE,LAI -US-Var,19439,GRP_LAI,LAI_TYPE,LAI -US-Var,19440,GRP_LAI,LAI_TYPE,LAI -US-Var,19441,GRP_LAI,LAI_TYPE,LAI -US-Var,19442,GRP_LAI,LAI_TYPE,LAI -US-Var,19443,GRP_LAI,LAI_TYPE,LAI -US-Var,19444,GRP_LAI,LAI_TYPE,LAI -US-Var,19445,GRP_LAI,LAI_TYPE,LAI -US-Var,19446,GRP_LAI,LAI_TYPE,LAI -US-Var,19447,GRP_LAI,LAI_TYPE,LAI -US-Var,19448,GRP_LAI,LAI_TYPE,LAI -US-Var,19449,GRP_LAI,LAI_TYPE,LAI -US-Var,19450,GRP_LAI,LAI_TYPE,LAI -US-Var,19451,GRP_LAI,LAI_TYPE,LAI -US-Var,19452,GRP_LAI,LAI_TYPE,LAI -US-Var,19453,GRP_LAI,LAI_TYPE,LAI -US-Var,19454,GRP_LAI,LAI_TYPE,LAI -US-Var,19455,GRP_LAI,LAI_TYPE,LAI -US-Var,19456,GRP_LAI,LAI_TYPE,LAI -US-Var,19457,GRP_LAI,LAI_TYPE,LAI -US-Var,19458,GRP_LAI,LAI_TYPE,LAI -US-Var,19459,GRP_LAI,LAI_TYPE,LAI -US-Var,19460,GRP_LAI,LAI_TYPE,LAI -US-Var,19461,GRP_LAI,LAI_TYPE,LAI -US-Var,19462,GRP_LAI,LAI_TYPE,LAI -US-Var,19342,GRP_LAI,LAI_METHOD,Direct -US-Var,19343,GRP_LAI,LAI_METHOD,Direct -US-Var,19344,GRP_LAI,LAI_METHOD,Direct -US-Var,19345,GRP_LAI,LAI_METHOD,Direct -US-Var,19346,GRP_LAI,LAI_METHOD,Direct -US-Var,19347,GRP_LAI,LAI_METHOD,Direct -US-Var,19348,GRP_LAI,LAI_METHOD,Direct -US-Var,19349,GRP_LAI,LAI_METHOD,Direct -US-Var,19350,GRP_LAI,LAI_METHOD,Direct -US-Var,19351,GRP_LAI,LAI_METHOD,Direct -US-Var,19352,GRP_LAI,LAI_METHOD,Direct -US-Var,19353,GRP_LAI,LAI_METHOD,Direct -US-Var,19354,GRP_LAI,LAI_METHOD,Direct -US-Var,19355,GRP_LAI,LAI_METHOD,Direct -US-Var,19356,GRP_LAI,LAI_METHOD,Direct -US-Var,19357,GRP_LAI,LAI_METHOD,Direct -US-Var,19358,GRP_LAI,LAI_METHOD,Direct -US-Var,19359,GRP_LAI,LAI_METHOD,Direct -US-Var,19360,GRP_LAI,LAI_METHOD,Direct -US-Var,19361,GRP_LAI,LAI_METHOD,Direct -US-Var,19362,GRP_LAI,LAI_METHOD,Direct -US-Var,19363,GRP_LAI,LAI_METHOD,Direct -US-Var,19364,GRP_LAI,LAI_METHOD,Direct -US-Var,19365,GRP_LAI,LAI_METHOD,Direct -US-Var,19366,GRP_LAI,LAI_METHOD,Direct -US-Var,19367,GRP_LAI,LAI_METHOD,Direct -US-Var,19368,GRP_LAI,LAI_METHOD,Direct -US-Var,19369,GRP_LAI,LAI_METHOD,Direct -US-Var,19370,GRP_LAI,LAI_METHOD,Direct -US-Var,19371,GRP_LAI,LAI_METHOD,Direct -US-Var,19372,GRP_LAI,LAI_METHOD,Direct -US-Var,19373,GRP_LAI,LAI_METHOD,Direct -US-Var,19374,GRP_LAI,LAI_METHOD,Direct -US-Var,19375,GRP_LAI,LAI_METHOD,Direct -US-Var,19376,GRP_LAI,LAI_METHOD,Direct -US-Var,19377,GRP_LAI,LAI_METHOD,Direct -US-Var,19378,GRP_LAI,LAI_METHOD,Direct -US-Var,19379,GRP_LAI,LAI_METHOD,Direct -US-Var,19380,GRP_LAI,LAI_METHOD,Direct -US-Var,19381,GRP_LAI,LAI_METHOD,Direct -US-Var,19382,GRP_LAI,LAI_METHOD,Direct -US-Var,19383,GRP_LAI,LAI_METHOD,Direct -US-Var,19384,GRP_LAI,LAI_METHOD,Direct -US-Var,19385,GRP_LAI,LAI_METHOD,Direct -US-Var,19386,GRP_LAI,LAI_METHOD,Direct -US-Var,19387,GRP_LAI,LAI_METHOD,Direct -US-Var,19388,GRP_LAI,LAI_METHOD,Direct -US-Var,19389,GRP_LAI,LAI_METHOD,Direct -US-Var,19390,GRP_LAI,LAI_METHOD,Direct -US-Var,19391,GRP_LAI,LAI_METHOD,Direct -US-Var,19392,GRP_LAI,LAI_METHOD,Direct -US-Var,19393,GRP_LAI,LAI_METHOD,Direct -US-Var,19394,GRP_LAI,LAI_METHOD,Direct -US-Var,19395,GRP_LAI,LAI_METHOD,Direct -US-Var,19396,GRP_LAI,LAI_METHOD,Direct -US-Var,19397,GRP_LAI,LAI_METHOD,Direct -US-Var,19398,GRP_LAI,LAI_METHOD,Direct -US-Var,19399,GRP_LAI,LAI_METHOD,Direct -US-Var,19400,GRP_LAI,LAI_METHOD,Direct -US-Var,19401,GRP_LAI,LAI_METHOD,Direct -US-Var,19402,GRP_LAI,LAI_METHOD,Direct -US-Var,19403,GRP_LAI,LAI_METHOD,Direct -US-Var,19404,GRP_LAI,LAI_METHOD,Direct -US-Var,19405,GRP_LAI,LAI_METHOD,Direct -US-Var,19406,GRP_LAI,LAI_METHOD,Direct -US-Var,19407,GRP_LAI,LAI_METHOD,Direct -US-Var,19408,GRP_LAI,LAI_METHOD,Direct -US-Var,19409,GRP_LAI,LAI_METHOD,Direct -US-Var,19410,GRP_LAI,LAI_METHOD,Direct -US-Var,19411,GRP_LAI,LAI_METHOD,Direct -US-Var,19412,GRP_LAI,LAI_METHOD,Direct -US-Var,19413,GRP_LAI,LAI_METHOD,Direct -US-Var,19414,GRP_LAI,LAI_METHOD,Direct -US-Var,19415,GRP_LAI,LAI_METHOD,Direct -US-Var,19416,GRP_LAI,LAI_METHOD,Direct -US-Var,19417,GRP_LAI,LAI_METHOD,Direct -US-Var,19418,GRP_LAI,LAI_METHOD,Direct -US-Var,19419,GRP_LAI,LAI_METHOD,Direct -US-Var,19420,GRP_LAI,LAI_METHOD,Direct -US-Var,19421,GRP_LAI,LAI_METHOD,Direct -US-Var,19422,GRP_LAI,LAI_METHOD,Direct -US-Var,19423,GRP_LAI,LAI_METHOD,Direct -US-Var,19424,GRP_LAI,LAI_METHOD,Direct -US-Var,19425,GRP_LAI,LAI_METHOD,Direct -US-Var,19426,GRP_LAI,LAI_METHOD,Direct -US-Var,19427,GRP_LAI,LAI_METHOD,Direct -US-Var,19428,GRP_LAI,LAI_METHOD,Direct -US-Var,19429,GRP_LAI,LAI_METHOD,Direct -US-Var,19430,GRP_LAI,LAI_METHOD,Direct -US-Var,19431,GRP_LAI,LAI_METHOD,Direct -US-Var,19432,GRP_LAI,LAI_METHOD,Direct -US-Var,19433,GRP_LAI,LAI_METHOD,Direct -US-Var,19434,GRP_LAI,LAI_METHOD,Direct -US-Var,19435,GRP_LAI,LAI_METHOD,Direct -US-Var,19436,GRP_LAI,LAI_METHOD,Direct -US-Var,19437,GRP_LAI,LAI_METHOD,Direct -US-Var,19438,GRP_LAI,LAI_METHOD,Direct -US-Var,19439,GRP_LAI,LAI_METHOD,Direct -US-Var,19440,GRP_LAI,LAI_METHOD,Direct -US-Var,19441,GRP_LAI,LAI_METHOD,Direct -US-Var,19442,GRP_LAI,LAI_METHOD,Direct -US-Var,19443,GRP_LAI,LAI_METHOD,Direct -US-Var,19444,GRP_LAI,LAI_METHOD,Direct -US-Var,19445,GRP_LAI,LAI_METHOD,Direct -US-Var,19446,GRP_LAI,LAI_METHOD,Direct -US-Var,19447,GRP_LAI,LAI_METHOD,Direct -US-Var,19448,GRP_LAI,LAI_METHOD,Direct -US-Var,19449,GRP_LAI,LAI_METHOD,Direct -US-Var,19450,GRP_LAI,LAI_METHOD,Direct -US-Var,19451,GRP_LAI,LAI_METHOD,Direct -US-Var,19452,GRP_LAI,LAI_METHOD,Direct -US-Var,19453,GRP_LAI,LAI_METHOD,Direct -US-Var,19454,GRP_LAI,LAI_METHOD,Direct -US-Var,19455,GRP_LAI,LAI_METHOD,Direct -US-Var,19456,GRP_LAI,LAI_METHOD,Direct -US-Var,19457,GRP_LAI,LAI_METHOD,Direct -US-Var,19458,GRP_LAI,LAI_METHOD,Direct -US-Var,19459,GRP_LAI,LAI_METHOD,Direct -US-Var,19460,GRP_LAI,LAI_METHOD,Direct -US-Var,19461,GRP_LAI,LAI_METHOD,Direct -US-Var,19462,GRP_LAI,LAI_METHOD,Direct -US-Var,19342,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 repeats; measured throught Li-cor area meter -US-Var,19343,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 repeats; measured throught Li-cor area meter -US-Var,19344,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 repeats; measured throught Li-cor area meter -US-Var,19345,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 repeats; measured throught Li-cor area meter -US-Var,19346,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 repeats; measured throught Li-cor area meter -US-Var,19347,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 repeats; measured throught Li-cor area meter -US-Var,19348,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 repeats; measured throught Li-cor area meter -US-Var,19349,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 repeats; measured throught Li-cor area meter -US-Var,19350,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 repeats; measured throught Li-cor area meter -US-Var,19351,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 repeats; measured throught Li-cor area meter -US-Var,19352,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 repeats; measured throught Li-cor area meter -US-Var,19353,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 repeats; measured throught Li-cor area meter -US-Var,19354,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 repeats; measured throught Li-cor area meter -US-Var,19355,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 repeats; measured throught Li-cor area meter -US-Var,19356,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 repeats; measured throught Li-cor area meter -US-Var,19357,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 repeats; measured throught Li-cor area meter -US-Var,19358,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 repeats; measured throught Li-cor area meter -US-Var,19359,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 repeats; measured throught Li-cor area meter -US-Var,19360,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 repeats; measured throught Li-cor area meter -US-Var,19361,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 repeats; measured throught Li-cor area meter -US-Var,19362,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 repeats; measured throught Li-cor area meter -US-Var,19363,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 repeats; measured throught Li-cor area meter -US-Var,19364,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 repeats; measured throught Li-cor area meter -US-Var,19365,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 repeats; measured throught Li-cor area meter -US-Var,19366,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 repeats; measured throught Li-cor area meter -US-Var,19367,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 repeats; measured throught Li-cor area meter -US-Var,19368,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 repeats; measured throught Li-cor area meter -US-Var,19369,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 repeats; measured throught Li-cor area meter -US-Var,19370,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 repeats; measured throught Li-cor area meter -US-Var,19371,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 repeats; measured throught Li-cor area meter -US-Var,19372,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 repeats; measured throught Li-cor area meter -US-Var,19373,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 repeats; measured throught Li-cor area meter -US-Var,19374,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 repeats; measured throught Li-cor area meter -US-Var,19375,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 repeats; measured throught Li-cor area meter -US-Var,19376,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 repeats; measured throught Li-cor area meter -US-Var,19377,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 repeats; measured throught Li-cor area meter -US-Var,19378,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 repeats; measured throught Li-cor area meter -US-Var,19379,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 repeats; measured throught Li-cor area meter -US-Var,19380,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 repeats; measured throught Li-cor area meter -US-Var,19381,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 repeats; measured throught Li-cor area meter -US-Var,19382,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 repeats; measured throught Li-cor area meter -US-Var,19383,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 repeats; measured throught Li-cor area meter -US-Var,19384,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 repeats; measured throught Li-cor area meter -US-Var,19385,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 repeats; measured throught Li-cor area meter -US-Var,19386,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 repeats; measured throught Li-cor area meter -US-Var,19387,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 repeats; measured throught Li-cor area meter -US-Var,19388,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 repeats; measured throught Li-cor area meter -US-Var,19389,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 repeats; measured throught Li-cor area meter -US-Var,19390,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 repeats; measured throught Li-cor area meter -US-Var,19391,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 repeats; measured throught Li-cor area meter -US-Var,19392,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 repeats; measured throught Li-cor area meter -US-Var,19393,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 repeats; measured throught Li-cor area meter -US-Var,19394,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 repeats; measured throught Li-cor area meter -US-Var,19395,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 repeats; measured throught Li-cor area meter -US-Var,19396,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 repeats; measured throught Li-cor area meter -US-Var,19397,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 repeats; measured throught Li-cor area meter -US-Var,19398,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 repeats; measured throught Li-cor area meter -US-Var,19399,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 repeats; measured throught Li-cor area meter -US-Var,19400,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 repeats; measured throught Li-cor area meter -US-Var,19401,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 repeats; measured throught Li-cor area meter -US-Var,19402,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 repeats; measured throught Li-cor area meter -US-Var,19403,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 repeats; measured throught Li-cor area meter -US-Var,19404,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 repeats; measured throught Li-cor area meter -US-Var,19405,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 repeats; measured throught Li-cor area meter -US-Var,19406,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 repeats; measured throught Li-cor area meter -US-Var,19407,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 repeats; measured throught Li-cor area meter -US-Var,19408,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 repeats; measured throught Li-cor area meter -US-Var,19409,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 repeats; measured throught Li-cor area meter -US-Var,19410,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 repeats; measured throught Li-cor area meter -US-Var,19411,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 repeats; measured throught Li-cor area meter -US-Var,19412,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 repeats; measured throught Li-cor area meter -US-Var,19413,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 repeats; measured throught Li-cor area meter -US-Var,19414,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 repeats; measured throught Li-cor area meter -US-Var,19415,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 repeats; measured throught Li-cor area meter -US-Var,19416,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 repeats; measured throught Li-cor area meter -US-Var,19417,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 repeats; measured throught Li-cor area meter -US-Var,19418,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 repeats; measured throught Li-cor area meter -US-Var,19419,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 repeats; measured throught Li-cor area meter -US-Var,19420,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 repeats; measured throught Li-cor area meter -US-Var,19427,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 repeats; measured throught Li-cor area meter -US-Var,19428,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 repeats; measured throught Li-cor area meter -US-Var,19429,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 repeats; measured throught Li-cor area meter -US-Var,19430,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 repeats; measured throught Li-cor area meter -US-Var,19431,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 repeats; measured throught Li-cor area meter -US-Var,19432,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 repeats; measured throught Li-cor area meter -US-Var,19433,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 repeats; measured throught Li-cor area meter -US-Var,19434,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 repeats; measured throught Li-cor area meter -US-Var,19435,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 repeats; measured throught Li-cor area meter -US-Var,19436,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 repeats; measured throught Li-cor area meter -US-Var,19437,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 repeats; measured throught Li-cor area meter -US-Var,19438,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 repeats; measured throught Li-cor area meter -US-Var,19439,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 repeats; measured throught Li-cor area meter -US-Var,19440,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 repeats; measured throught Li-cor area meter -US-Var,19441,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 repeats; measured throught Li-cor area meter -US-Var,19442,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 repeats; measured throught Li-cor area meter -US-Var,19443,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 repeats; measured throught Li-cor area meter -US-Var,19444,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 repeats; measured throught Li-cor area meter -US-Var,19446,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 repeats; measured throught Li-cor area meter -US-Var,19447,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 repeats; measured throught Li-cor area meter -US-Var,19448,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 repeats; measured throught Li-cor area meter -US-Var,19449,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 repeats; measured throught Li-cor area meter -US-Var,19450,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 repeats; measured throught Li-cor area meter -US-Var,19451,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 repeats; measured throught Li-cor area meter -US-Var,19452,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 repeats; measured throught Li-cor area meter -US-Var,19453,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 repeats; measured throught Li-cor area meter -US-Var,19454,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 repeats; measured throught Li-cor area meter -US-Var,19455,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 repeats; measured throught Li-cor area meter -US-Var,19456,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 repeats; measured throught Li-cor area meter -US-Var,19457,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 repeats; measured throught Li-cor area meter -US-Var,19458,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 repeats; measured throught Li-cor area meter -US-Var,19459,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 repeats; measured throught Li-cor area meter -US-Var,19460,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 repeats; measured throught Li-cor area meter -US-Var,19461,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 repeats; measured throught Li-cor area meter -US-Var,19462,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 repeats; measured throught Li-cor area meter -US-Var,19421,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 replicants; measured throught Li-cor area meter -US-Var,19422,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 replicants; measured throught Li-cor area meter -US-Var,19423,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 replicants; measured throught Li-cor area meter -US-Var,19424,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 replicants; measured throught Li-cor area meter -US-Var,19425,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 replicants; measured throught Li-cor area meter -US-Var,19426,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 replicants; measured throught Li-cor area meter -US-Var,19445,GRP_LAI,LAI_APPROACH,400cm2 sampling square; 3 replicants; measured throught Li-cor area meter -US-Var,19445,GRP_LAI,LAI_DATE,20011205 -US-Var,19446,GRP_LAI,LAI_DATE,20020115 -US-Var,19447,GRP_LAI,LAI_DATE,20020228 -US-Var,19448,GRP_LAI,LAI_DATE,20020320 -US-Var,19449,GRP_LAI,LAI_DATE,20020404 -US-Var,19450,GRP_LAI,LAI_DATE,20020418 -US-Var,19451,GRP_LAI,LAI_DATE,20020502 -US-Var,19452,GRP_LAI,LAI_DATE,20020516 -US-Var,19453,GRP_LAI,LAI_DATE,20021114 -US-Var,19454,GRP_LAI,LAI_DATE,20021223 -US-Var,19455,GRP_LAI,LAI_DATE,20030129 -US-Var,19456,GRP_LAI,LAI_DATE,20030221 -US-Var,19457,GRP_LAI,LAI_DATE,20030317 -US-Var,19458,GRP_LAI,LAI_DATE,20030405 -US-Var,19459,GRP_LAI,LAI_DATE,20030416 -US-Var,19460,GRP_LAI,LAI_DATE,20030430 -US-Var,19461,GRP_LAI,LAI_DATE,20030521 -US-Var,19462,GRP_LAI,LAI_DATE,20030607 -US-Var,19342,GRP_LAI,LAI_DATE,20040130 -US-Var,19343,GRP_LAI,LAI_DATE,20040305 -US-Var,19344,GRP_LAI,LAI_DATE,20040325 -US-Var,19345,GRP_LAI,LAI_DATE,20040409 -US-Var,19346,GRP_LAI,LAI_DATE,20040423 -US-Var,19347,GRP_LAI,LAI_DATE,20040506 -US-Var,19348,GRP_LAI,LAI_DATE,20041120 -US-Var,19349,GRP_LAI,LAI_DATE,20041128 -US-Var,19350,GRP_LAI,LAI_DATE,20041202 -US-Var,19351,GRP_LAI,LAI_DATE,20041215 -US-Var,19352,GRP_LAI,LAI_DATE,20041226 -US-Var,19353,GRP_LAI,LAI_DATE,20050117 -US-Var,19354,GRP_LAI,LAI_DATE,20050127 -US-Var,19355,GRP_LAI,LAI_DATE,20050226 -US-Var,19356,GRP_LAI,LAI_DATE,20050324 -US-Var,19357,GRP_LAI,LAI_DATE,20050424 -US-Var,19358,GRP_LAI,LAI_DATE,20050517 -US-Var,19359,GRP_LAI,LAI_DATE,20050601 -US-Var,19427,GRP_LAI,LAI_DATE,20050610 -US-Var,19428,GRP_LAI,LAI_DATE,20051213 -US-Var,19429,GRP_LAI,LAI_DATE,20060124 -US-Var,19430,GRP_LAI,LAI_DATE,20060209 -US-Var,19431,GRP_LAI,LAI_DATE,20060223 -US-Var,19432,GRP_LAI,LAI_DATE,20060308 -US-Var,19433,GRP_LAI,LAI_DATE,20060330 -US-Var,19434,GRP_LAI,LAI_DATE,20060418 -US-Var,19435,GRP_LAI,LAI_DATE,20060504 -US-Var,19436,GRP_LAI,LAI_DATE,20060512 -US-Var,19437,GRP_LAI,LAI_DATE,20060518 -US-Var,19438,GRP_LAI,LAI_DATE,20060528 -US-Var,19439,GRP_LAI,LAI_DATE,20061119 -US-Var,19440,GRP_LAI,LAI_DATE,20061206 -US-Var,19441,GRP_LAI,LAI_DATE,20061229 -US-Var,19442,GRP_LAI,LAI_DATE,20070110 -US-Var,19443,GRP_LAI,LAI_DATE,20070204 -US-Var,19444,GRP_LAI,LAI_DATE,20070302 -US-Var,19360,GRP_LAI,LAI_DATE,20070314 -US-Var,19361,GRP_LAI,LAI_DATE,20070328 -US-Var,19362,GRP_LAI,LAI_DATE,20070405 -US-Var,19363,GRP_LAI,LAI_DATE,20070413 -US-Var,19364,GRP_LAI,LAI_DATE,20070501 -US-Var,19365,GRP_LAI,LAI_DATE,20070510 -US-Var,19366,GRP_LAI,LAI_DATE,20070525 -US-Var,19367,GRP_LAI,LAI_DATE,20071129 -US-Var,19368,GRP_LAI,LAI_DATE,20071227 -US-Var,19369,GRP_LAI,LAI_DATE,20080130 -US-Var,19370,GRP_LAI,LAI_DATE,20080306 -US-Var,19371,GRP_LAI,LAI_DATE,20080404 -US-Var,19372,GRP_LAI,LAI_DATE,20080420 -US-Var,19373,GRP_LAI,LAI_DATE,20080506 -US-Var,19374,GRP_LAI,LAI_DATE,20080513 -US-Var,19375,GRP_LAI,LAI_DATE,20081211 -US-Var,19376,GRP_LAI,LAI_DATE,20090108 -US-Var,19377,GRP_LAI,LAI_DATE,20090119 -US-Var,19396,GRP_LAI,LAI_DATE,20090210 -US-Var,19397,GRP_LAI,LAI_DATE,20090228 -US-Var,19398,GRP_LAI,LAI_DATE,20090312 -US-Var,19399,GRP_LAI,LAI_DATE,20090327 -US-Var,19400,GRP_LAI,LAI_DATE,20090417 -US-Var,19401,GRP_LAI,LAI_DATE,20090507 -US-Var,19402,GRP_LAI,LAI_DATE,20090527 -US-Var,19403,GRP_LAI,LAI_DATE,20091105 -US-Var,19404,GRP_LAI,LAI_DATE,20091222 -US-Var,19405,GRP_LAI,LAI_DATE,20100210 -US-Var,19406,GRP_LAI,LAI_DATE,20100305 -US-Var,19407,GRP_LAI,LAI_DATE,20100321 -US-Var,19408,GRP_LAI,LAI_DATE,20100413 -US-Var,19409,GRP_LAI,LAI_DATE,20100430 -US-Var,19410,GRP_LAI,LAI_DATE,20100513 -US-Var,19411,GRP_LAI,LAI_DATE,20100528 -US-Var,19412,GRP_LAI,LAI_DATE,20100610 -US-Var,19413,GRP_LAI,LAI_DATE,20101112 -US-Var,19378,GRP_LAI,LAI_DATE,20101202 -US-Var,19379,GRP_LAI,LAI_DATE,20110105 -US-Var,19380,GRP_LAI,LAI_DATE,20110222 -US-Var,19381,GRP_LAI,LAI_DATE,20110330 -US-Var,19382,GRP_LAI,LAI_DATE,20110422 -US-Var,19383,GRP_LAI,LAI_DATE,20110510 -US-Var,19384,GRP_LAI,LAI_DATE,20110527 -US-Var,19385,GRP_LAI,LAI_DATE,20111026 -US-Var,19386,GRP_LAI,LAI_DATE,20111201 -US-Var,19387,GRP_LAI,LAI_DATE,20120104 -US-Var,19388,GRP_LAI,LAI_DATE,20120201 -US-Var,19389,GRP_LAI,LAI_DATE,20120302 -US-Var,19390,GRP_LAI,LAI_DATE,20120405 -US-Var,19391,GRP_LAI,LAI_DATE,20120504 -US-Var,19392,GRP_LAI,LAI_DATE,20120518 -US-Var,19393,GRP_LAI,LAI_DATE,20120530 -US-Var,19394,GRP_LAI,LAI_DATE,20121107 -US-Var,19395,GRP_LAI,LAI_DATE,20121211 -US-Var,19414,GRP_LAI,LAI_DATE,20130116 -US-Var,19415,GRP_LAI,LAI_DATE,20130227 -US-Var,19416,GRP_LAI,LAI_DATE,20130313 -US-Var,19417,GRP_LAI,LAI_DATE,20130327 -US-Var,19418,GRP_LAI,LAI_DATE,20130410 -US-Var,19419,GRP_LAI,LAI_DATE,20130424 -US-Var,19420,GRP_LAI,LAI_DATE,20130508 -US-Var,19421,GRP_LAI,LAI_DATE,20140210 -US-Var,19422,GRP_LAI,LAI_DATE,20140304 -US-Var,19423,GRP_LAI,LAI_DATE,20140327 -US-Var,19424,GRP_LAI,LAI_DATE,20140422 -US-Var,19425,GRP_LAI,LAI_DATE,20140508 -US-Var,19426,GRP_LAI,LAI_DATE,20150522 -US-Var,19366,GRP_LAI,LAI_COMMENT,estimated by Siyan Ma -US-Var,19374,GRP_LAI,LAI_COMMENT,estimated by Siyan Ma -US-Var,19393,GRP_LAI,LAI_COMMENT,estimated by Siyan Ma -US-Var,19402,GRP_LAI,LAI_COMMENT,estimated by Siyan Ma -US-Var,19412,GRP_LAI,LAI_COMMENT,estimated by Siyan Ma -US-Var,19426,GRP_LAI,LAI_COMMENT,estimated by Siyan Ma -US-Var,19342,GRP_LAI,LAI_COMMENT,operated by Liukang Xu -US-Var,19343,GRP_LAI,LAI_COMMENT,operated by Liukang Xu -US-Var,19344,GRP_LAI,LAI_COMMENT,operated by Liukang Xu -US-Var,19345,GRP_LAI,LAI_COMMENT,operated by Liukang Xu -US-Var,19445,GRP_LAI,LAI_COMMENT,operated by Liukang Xu -US-Var,19446,GRP_LAI,LAI_COMMENT,operated by Liukang Xu -US-Var,19447,GRP_LAI,LAI_COMMENT,operated by Liukang Xu -US-Var,19448,GRP_LAI,LAI_COMMENT,operated by Liukang Xu -US-Var,19449,GRP_LAI,LAI_COMMENT,operated by Liukang Xu -US-Var,19450,GRP_LAI,LAI_COMMENT,operated by Liukang Xu -US-Var,19451,GRP_LAI,LAI_COMMENT,operated by Liukang Xu -US-Var,19452,GRP_LAI,LAI_COMMENT,operated by Liukang Xu -US-Var,19453,GRP_LAI,LAI_COMMENT,operated by Liukang Xu -US-Var,19454,GRP_LAI,LAI_COMMENT,operated by Liukang Xu -US-Var,19455,GRP_LAI,LAI_COMMENT,operated by Liukang Xu -US-Var,19456,GRP_LAI,LAI_COMMENT,operated by Liukang Xu -US-Var,19457,GRP_LAI,LAI_COMMENT,operated by Liukang Xu -US-Var,19458,GRP_LAI,LAI_COMMENT,operated by Liukang Xu -US-Var,19459,GRP_LAI,LAI_COMMENT,operated by Liukang Xu -US-Var,19460,GRP_LAI,LAI_COMMENT,operated by Liukang Xu -US-Var,19461,GRP_LAI,LAI_COMMENT,operated by Liukang Xu -US-Var,19462,GRP_LAI,LAI_COMMENT,operated by Liukang Xu -US-Var,19346,GRP_LAI,LAI_COMMENT,operated by Siyan Ma -US-Var,19347,GRP_LAI,LAI_COMMENT,operated by Siyan Ma -US-Var,19348,GRP_LAI,LAI_COMMENT,operated by Siyan Ma -US-Var,19349,GRP_LAI,LAI_COMMENT,operated by Siyan Ma -US-Var,19350,GRP_LAI,LAI_COMMENT,operated by Siyan Ma -US-Var,19351,GRP_LAI,LAI_COMMENT,operated by Siyan Ma -US-Var,19352,GRP_LAI,LAI_COMMENT,operated by Siyan Ma -US-Var,19353,GRP_LAI,LAI_COMMENT,operated by Siyan Ma -US-Var,19354,GRP_LAI,LAI_COMMENT,operated by Siyan Ma -US-Var,19355,GRP_LAI,LAI_COMMENT,operated by Siyan Ma -US-Var,19356,GRP_LAI,LAI_COMMENT,operated by Siyan Ma -US-Var,19357,GRP_LAI,LAI_COMMENT,operated by Siyan Ma -US-Var,19358,GRP_LAI,LAI_COMMENT,operated by Siyan Ma -US-Var,19359,GRP_LAI,LAI_COMMENT,operated by Siyan Ma -US-Var,19360,GRP_LAI,LAI_COMMENT,operated by Siyan Ma -US-Var,19361,GRP_LAI,LAI_COMMENT,operated by Siyan Ma -US-Var,19362,GRP_LAI,LAI_COMMENT,operated by Siyan Ma -US-Var,19363,GRP_LAI,LAI_COMMENT,operated by Siyan Ma -US-Var,19364,GRP_LAI,LAI_COMMENT,operated by Siyan Ma -US-Var,19365,GRP_LAI,LAI_COMMENT,operated by Siyan Ma -US-Var,19367,GRP_LAI,LAI_COMMENT,operated by Siyan Ma -US-Var,19368,GRP_LAI,LAI_COMMENT,operated by Siyan Ma -US-Var,19369,GRP_LAI,LAI_COMMENT,operated by Siyan Ma -US-Var,19370,GRP_LAI,LAI_COMMENT,operated by Siyan Ma -US-Var,19371,GRP_LAI,LAI_COMMENT,operated by Siyan Ma -US-Var,19372,GRP_LAI,LAI_COMMENT,operated by Siyan Ma -US-Var,19373,GRP_LAI,LAI_COMMENT,operated by Siyan Ma -US-Var,19375,GRP_LAI,LAI_COMMENT,operated by Siyan Ma -US-Var,19376,GRP_LAI,LAI_COMMENT,operated by Siyan Ma -US-Var,19377,GRP_LAI,LAI_COMMENT,operated by Siyan Ma -US-Var,19378,GRP_LAI,LAI_COMMENT,operated by Siyan Ma -US-Var,19379,GRP_LAI,LAI_COMMENT,operated by Siyan Ma -US-Var,19380,GRP_LAI,LAI_COMMENT,operated by Siyan Ma -US-Var,19381,GRP_LAI,LAI_COMMENT,operated by Siyan Ma -US-Var,19382,GRP_LAI,LAI_COMMENT,operated by Siyan Ma -US-Var,19383,GRP_LAI,LAI_COMMENT,operated by Siyan Ma -US-Var,19384,GRP_LAI,LAI_COMMENT,operated by Siyan Ma -US-Var,19385,GRP_LAI,LAI_COMMENT,operated by Siyan Ma -US-Var,19386,GRP_LAI,LAI_COMMENT,operated by Siyan Ma -US-Var,19387,GRP_LAI,LAI_COMMENT,operated by Siyan Ma -US-Var,19388,GRP_LAI,LAI_COMMENT,operated by Siyan Ma -US-Var,19389,GRP_LAI,LAI_COMMENT,operated by Siyan Ma -US-Var,19390,GRP_LAI,LAI_COMMENT,operated by Siyan Ma -US-Var,19391,GRP_LAI,LAI_COMMENT,operated by Siyan Ma -US-Var,19392,GRP_LAI,LAI_COMMENT,operated by Siyan Ma -US-Var,19394,GRP_LAI,LAI_COMMENT,operated by Siyan Ma -US-Var,19395,GRP_LAI,LAI_COMMENT,operated by Siyan Ma -US-Var,19396,GRP_LAI,LAI_COMMENT,operated by Siyan Ma -US-Var,19397,GRP_LAI,LAI_COMMENT,operated by Siyan Ma -US-Var,19398,GRP_LAI,LAI_COMMENT,operated by Siyan Ma -US-Var,19399,GRP_LAI,LAI_COMMENT,operated by Siyan Ma -US-Var,19400,GRP_LAI,LAI_COMMENT,operated by Siyan Ma -US-Var,19401,GRP_LAI,LAI_COMMENT,operated by Siyan Ma -US-Var,19403,GRP_LAI,LAI_COMMENT,operated by Siyan Ma -US-Var,19404,GRP_LAI,LAI_COMMENT,operated by Siyan Ma -US-Var,19405,GRP_LAI,LAI_COMMENT,operated by Siyan Ma -US-Var,19406,GRP_LAI,LAI_COMMENT,operated by Siyan Ma -US-Var,19407,GRP_LAI,LAI_COMMENT,operated by Siyan Ma -US-Var,19408,GRP_LAI,LAI_COMMENT,operated by Siyan Ma -US-Var,19409,GRP_LAI,LAI_COMMENT,operated by Siyan Ma -US-Var,19410,GRP_LAI,LAI_COMMENT,operated by Siyan Ma -US-Var,19411,GRP_LAI,LAI_COMMENT,operated by Siyan Ma -US-Var,19413,GRP_LAI,LAI_COMMENT,operated by Siyan Ma -US-Var,19414,GRP_LAI,LAI_COMMENT,operated by Siyan Ma -US-Var,19415,GRP_LAI,LAI_COMMENT,operated by Siyan Ma -US-Var,19416,GRP_LAI,LAI_COMMENT,operated by Siyan Ma -US-Var,19417,GRP_LAI,LAI_COMMENT,operated by Siyan Ma -US-Var,19418,GRP_LAI,LAI_COMMENT,operated by Siyan Ma -US-Var,19419,GRP_LAI,LAI_COMMENT,operated by Siyan Ma -US-Var,19420,GRP_LAI,LAI_COMMENT,operated by Siyan Ma -US-Var,19421,GRP_LAI,LAI_COMMENT,operated by Siyan Ma -US-Var,19422,GRP_LAI,LAI_COMMENT,operated by Siyan Ma -US-Var,19423,GRP_LAI,LAI_COMMENT,operated by Siyan Ma -US-Var,19424,GRP_LAI,LAI_COMMENT,operated by Siyan Ma -US-Var,19425,GRP_LAI,LAI_COMMENT,operated by Siyan Ma -US-Var,19427,GRP_LAI,LAI_COMMENT,operated by Siyan Ma -US-Var,19428,GRP_LAI,LAI_COMMENT,operated by Siyan Ma -US-Var,19429,GRP_LAI,LAI_COMMENT,operated by Siyan Ma -US-Var,19430,GRP_LAI,LAI_COMMENT,operated by Siyan Ma -US-Var,19431,GRP_LAI,LAI_COMMENT,operated by Siyan Ma -US-Var,19432,GRP_LAI,LAI_COMMENT,operated by Siyan Ma -US-Var,19433,GRP_LAI,LAI_COMMENT,operated by Siyan Ma -US-Var,19434,GRP_LAI,LAI_COMMENT,operated by Siyan Ma -US-Var,19435,GRP_LAI,LAI_COMMENT,operated by Siyan Ma -US-Var,19436,GRP_LAI,LAI_COMMENT,operated by Siyan Ma -US-Var,19437,GRP_LAI,LAI_COMMENT,operated by Siyan Ma -US-Var,19438,GRP_LAI,LAI_COMMENT,operated by Siyan Ma -US-Var,19439,GRP_LAI,LAI_COMMENT,operated by Siyan Ma -US-Var,19440,GRP_LAI,LAI_COMMENT,operated by Siyan Ma -US-Var,19441,GRP_LAI,LAI_COMMENT,operated by Siyan Ma -US-Var,19442,GRP_LAI,LAI_COMMENT,operated by Siyan Ma -US-Var,19443,GRP_LAI,LAI_COMMENT,operated by Siyan Ma -US-Var,19444,GRP_LAI,LAI_COMMENT,operated by Siyan Ma -US-Var,19374,GRP_LAI,LAI_TOT,0 -US-Var,19427,GRP_LAI,LAI_TOT,0 -US-Var,19452,GRP_LAI,LAI_TOT,0 -US-Var,19453,GRP_LAI,LAI_TOT,0 -US-Var,19462,GRP_LAI,LAI_TOT,0 -US-Var,19359,GRP_LAI,LAI_TOT,0.04 -US-Var,19421,GRP_LAI,LAI_TOT,0.05923118548 -US-Var,19347,GRP_LAI,LAI_TOT,0.0725 -US-Var,19393,GRP_LAI,LAI_TOT,0.1 -US-Var,19412,GRP_LAI,LAI_TOT,0.1 -US-Var,19366,GRP_LAI,LAI_TOT,0.125 -US-Var,19375,GRP_LAI,LAI_TOT,0.17966666667 -US-Var,19402,GRP_LAI,LAI_TOT,0.2 -US-Var,19426,GRP_LAI,LAI_TOT,0.2 -US-Var,19438,GRP_LAI,LAI_TOT,0.3 -US-Var,19403,GRP_LAI,LAI_TOT,0.31583333333 -US-Var,19376,GRP_LAI,LAI_TOT,0.35158333333 -US-Var,19394,GRP_LAI,LAI_TOT,0.39916666667 -US-Var,19377,GRP_LAI,LAI_TOT,0.483 -US-Var,19422,GRP_LAI,LAI_TOT,0.48513743757 -US-Var,19440,GRP_LAI,LAI_TOT,0.4943775 -US-Var,19379,GRP_LAI,LAI_TOT,0.54833333333 -US-Var,19430,GRP_LAI,LAI_TOT,0.55965 -US-Var,19442,GRP_LAI,LAI_TOT,0.56993416667 -US-Var,19420,GRP_LAI,LAI_TOT,0.57083333333 -US-Var,19342,GRP_LAI,LAI_TOT,0.57891458333 -US-Var,19348,GRP_LAI,LAI_TOT,0.592015 -US-Var,19439,GRP_LAI,LAI_TOT,0.60165 -US-Var,19454,GRP_LAI,LAI_TOT,0.61 -US-Var,19349,GRP_LAI,LAI_TOT,0.63273916667 -US-Var,19350,GRP_LAI,LAI_TOT,0.67346333333 -US-Var,19367,GRP_LAI,LAI_TOT,0.69700916667 -US-Var,19431,GRP_LAI,LAI_TOT,0.698115 -US-Var,19369,GRP_LAI,LAI_TOT,0.73333333333 -US-Var,19461,GRP_LAI,LAI_TOT,0.758 -US-Var,19380,GRP_LAI,LAI_TOT,0.76333333333 -US-Var,19443,GRP_LAI,LAI_TOT,0.7951425 -US-Var,19432,GRP_LAI,LAI_TOT,0.80092166667 -US-Var,19429,GRP_LAI,LAI_TOT,0.801725 -US-Var,19404,GRP_LAI,LAI_TOT,0.82466666667 -US-Var,19428,GRP_LAI,LAI_TOT,0.83188333333 -US-Var,19446,GRP_LAI,LAI_TOT,0.85 -US-Var,19351,GRP_LAI,LAI_TOT,0.868 -US-Var,19352,GRP_LAI,LAI_TOT,0.8716575 -US-Var,19445,GRP_LAI,LAI_TOT,0.88 -US-Var,19423,GRP_LAI,LAI_TOT,0.89596781936 -US-Var,19353,GRP_LAI,LAI_TOT,0.90516416667 -US-Var,19414,GRP_LAI,LAI_TOT,0.9475 -US-Var,19455,GRP_LAI,LAI_TOT,0.96 -US-Var,19425,GRP_LAI,LAI_TOT,0.9664539996 -US-Var,19346,GRP_LAI,LAI_TOT,0.98286666667 -US-Var,19444,GRP_LAI,LAI_TOT,1.0018183333 -US-Var,19433,GRP_LAI,LAI_TOT,1.0216425 -US-Var,19437,GRP_LAI,LAI_TOT,1.0259991667 -US-Var,19387,GRP_LAI,LAI_TOT,1.0675 -US-Var,19373,GRP_LAI,LAI_TOT,1.08975 -US-Var,19378,GRP_LAI,LAI_TOT,1.0966666667 -US-Var,19386,GRP_LAI,LAI_TOT,1.1033333333 -US-Var,19405,GRP_LAI,LAI_TOT,1.125 -US-Var,19395,GRP_LAI,LAI_TOT,1.1358333333 -US-Var,19368,GRP_LAI,LAI_TOT,1.1525625 -US-Var,19389,GRP_LAI,LAI_TOT,1.165 -US-Var,19447,GRP_LAI,LAI_TOT,1.17 -US-Var,19434,GRP_LAI,LAI_TOT,1.1723183333 -US-Var,19358,GRP_LAI,LAI_TOT,1.19 -US-Var,19415,GRP_LAI,LAI_TOT,1.2108333333 -US-Var,19365,GRP_LAI,LAI_TOT,1.2246433333 -US-Var,19384,GRP_LAI,LAI_TOT,1.24 -US-Var,19419,GRP_LAI,LAI_TOT,1.2625 -US-Var,19441,GRP_LAI,LAI_TOT,1.2688 -US-Var,19396,GRP_LAI,LAI_TOT,1.275 -US-Var,19418,GRP_LAI,LAI_TOT,1.315 -US-Var,19360,GRP_LAI,LAI_TOT,1.3826775 -US-Var,19416,GRP_LAI,LAI_TOT,1.4041666667 -US-Var,19417,GRP_LAI,LAI_TOT,1.4125 -US-Var,19451,GRP_LAI,LAI_TOT,1.43 -US-Var,19370,GRP_LAI,LAI_TOT,1.4408333333 -US-Var,19398,GRP_LAI,LAI_TOT,1.5175 -US-Var,19385,GRP_LAI,LAI_TOT,1.5283333333 -US-Var,19354,GRP_LAI,LAI_TOT,1.5528508333 -US-Var,19410,GRP_LAI,LAI_TOT,1.5608333333 -US-Var,19390,GRP_LAI,LAI_TOT,1.5675 -US-Var,19456,GRP_LAI,LAI_TOT,1.58 -US-Var,19388,GRP_LAI,LAI_TOT,1.5941666667 -US-Var,19357,GRP_LAI,LAI_TOT,1.65 -US-Var,19371,GRP_LAI,LAI_TOT,1.6691666667 -US-Var,19413,GRP_LAI,LAI_TOT,1.6791666667 -US-Var,19436,GRP_LAI,LAI_TOT,1.6798783333 -US-Var,19345,GRP_LAI,LAI_TOT,1.6928 -US-Var,19372,GRP_LAI,LAI_TOT,1.7358333333 -US-Var,19344,GRP_LAI,LAI_TOT,1.7388 -US-Var,19381,GRP_LAI,LAI_TOT,1.7866666667 -US-Var,19397,GRP_LAI,LAI_TOT,1.7991666667 -US-Var,19457,GRP_LAI,LAI_TOT,1.82 -US-Var,19399,GRP_LAI,LAI_TOT,1.8558333333 -US-Var,19460,GRP_LAI,LAI_TOT,1.86 -US-Var,19448,GRP_LAI,LAI_TOT,1.87 -US-Var,19355,GRP_LAI,LAI_TOT,1.88 -US-Var,19424,GRP_LAI,LAI_TOT,1.9002614952 -US-Var,19411,GRP_LAI,LAI_TOT,1.9225 -US-Var,19435,GRP_LAI,LAI_TOT,1.9446541667 -US-Var,19400,GRP_LAI,LAI_TOT,2.01 -US-Var,19383,GRP_LAI,LAI_TOT,2.065 -US-Var,19406,GRP_LAI,LAI_TOT,2.07 -US-Var,19343,GRP_LAI,LAI_TOT,2.2038648611 -US-Var,19449,GRP_LAI,LAI_TOT,2.23 -US-Var,19364,GRP_LAI,LAI_TOT,2.28542 -US-Var,19363,GRP_LAI,LAI_TOT,2.3399166667 -US-Var,19361,GRP_LAI,LAI_TOT,2.4465533333 -US-Var,19459,GRP_LAI,LAI_TOT,2.52 -US-Var,19450,GRP_LAI,LAI_TOT,2.55 -US-Var,19362,GRP_LAI,LAI_TOT,2.5533375 -US-Var,19391,GRP_LAI,LAI_TOT,2.6141666667 -US-Var,19458,GRP_LAI,LAI_TOT,2.63 -US-Var,19409,GRP_LAI,LAI_TOT,2.6841666667 -US-Var,19401,GRP_LAI,LAI_TOT,2.725 -US-Var,19356,GRP_LAI,LAI_TOT,2.7444825 -US-Var,19408,GRP_LAI,LAI_TOT,3.4666666667 -US-Var,19407,GRP_LAI,LAI_TOT,3.485 -US-Var,19382,GRP_LAI,LAI_TOT,3.5233333333 -US-Var,19392,GRP_LAI,LAI_TOT,3.9525 -US-Var,19421,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,1 -US-Var,19422,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,1 -US-Var,19423,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,1 -US-Var,19342,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,3 -US-Var,19343,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,3 -US-Var,19344,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,3 -US-Var,19345,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,3 -US-Var,19346,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,3 -US-Var,19347,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,3 -US-Var,19348,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,3 -US-Var,19349,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,3 -US-Var,19350,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,3 -US-Var,19351,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,3 -US-Var,19352,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,3 -US-Var,19353,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,3 -US-Var,19354,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,3 -US-Var,19355,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,3 -US-Var,19356,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,3 -US-Var,19357,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,3 -US-Var,19358,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,3 -US-Var,19359,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,3 -US-Var,19360,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,3 -US-Var,19361,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,3 -US-Var,19362,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,3 -US-Var,19363,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,3 -US-Var,19364,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,3 -US-Var,19365,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,3 -US-Var,19366,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,3 -US-Var,19367,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,3 -US-Var,19368,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,3 -US-Var,19369,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,3 -US-Var,19370,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,3 -US-Var,19371,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,3 -US-Var,19372,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,3 -US-Var,19373,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,3 -US-Var,19374,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,3 -US-Var,19375,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,3 -US-Var,19376,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,3 -US-Var,19377,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,3 -US-Var,19378,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,3 -US-Var,19379,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,3 -US-Var,19380,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,3 -US-Var,19381,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,3 -US-Var,19382,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,3 -US-Var,19383,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,3 -US-Var,19384,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,3 -US-Var,19385,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,3 -US-Var,19386,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,3 -US-Var,19387,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,3 -US-Var,19388,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,3 -US-Var,19389,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,3 -US-Var,19390,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,3 -US-Var,19391,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,3 -US-Var,19392,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,3 -US-Var,19393,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,3 -US-Var,19394,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,3 -US-Var,19395,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,3 -US-Var,19396,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,3 -US-Var,19397,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,3 -US-Var,19398,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,3 -US-Var,19399,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,3 -US-Var,19400,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,3 -US-Var,19401,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,3 -US-Var,19402,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,3 -US-Var,19403,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,3 -US-Var,19404,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,3 -US-Var,19405,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,3 -US-Var,19406,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,3 -US-Var,19407,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,3 -US-Var,19408,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,3 -US-Var,19409,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,3 -US-Var,19410,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,3 -US-Var,19411,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,3 -US-Var,19412,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,3 -US-Var,19413,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,3 -US-Var,19414,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,3 -US-Var,19415,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,3 -US-Var,19416,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,3 -US-Var,19417,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,3 -US-Var,19418,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,3 -US-Var,19419,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,3 -US-Var,19420,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,3 -US-Var,19424,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,3 -US-Var,19425,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,3 -US-Var,19426,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,3 -US-Var,19427,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,3 -US-Var,19428,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,3 -US-Var,19429,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,3 -US-Var,19430,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,3 -US-Var,19431,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,3 -US-Var,19432,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,3 -US-Var,19433,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,3 -US-Var,19434,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,3 -US-Var,19435,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,3 -US-Var,19436,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,3 -US-Var,19437,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,3 -US-Var,19438,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,3 -US-Var,19439,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,3 -US-Var,19440,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,3 -US-Var,19441,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,3 -US-Var,19442,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,3 -US-Var,19443,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,3 -US-Var,19444,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,3 -US-Var,19445,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,3 -US-Var,19446,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,3 -US-Var,19447,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,3 -US-Var,19448,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,3 -US-Var,19449,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,3 -US-Var,19450,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,3 -US-Var,19451,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,3 -US-Var,19452,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,3 -US-Var,19453,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,3 -US-Var,19454,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,3 -US-Var,19455,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,3 -US-Var,19456,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,3 -US-Var,19457,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,3 -US-Var,19458,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,3 -US-Var,19459,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,3 -US-Var,19460,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,3 -US-Var,19461,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,3 -US-Var,19462,GRP_LAI,LAI_TOT_SPATIAL_REP_NUMBER,3 -US-Var,19375,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.054549480596 -US-Var,19421,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.05923118548 -US-Var,19369,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.061285363941 -US-Var,19419,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.063786754111 -US-Var,19387,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.065 -US-Var,19376,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.12253630414 -US-Var,19442,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.127794911 -US-Var,19373,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.15305227865 -US-Var,19414,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.17414074767 -US-Var,19410,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.17808588752 -US-Var,19403,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.18211145854 -US-Var,19444,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.2033506038 -US-Var,19443,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.2438625744 -US-Var,19379,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.24538659974 -US-Var,19377,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.24992198783 -US-Var,19378,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.25512660256 -US-Var,19407,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.27143139096 -US-Var,19440,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.28577285454 -US-Var,19384,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.29826844034 -US-Var,19404,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.32567740301 -US-Var,19380,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.33388184038 -US-Var,19439,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.34736278946 -US-Var,19368,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.35011844781 -US-Var,19394,GRP_LAI,LAI_TOT_SPATIAL_VARIABILITY,0.35164198176 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-US-Var,18735,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,annual grasses -US-Var,18735,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20120527 -US-Var,18735,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_UNC,3 -US-Var,18735,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_APPROACH,direct -US-Var,18736,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,Leaf senescence -US-Var,18736,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_STATUS,Peak -US-Var,18736,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,annual grasses -US-Var,18736,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20130508 -US-Var,18736,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE_UNC,3 -US-Var,18736,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_APPROACH,direct -US-Var,1700003180,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Baldocchi, D. D., Ryu, Y., Dechant, B., Eichelmann, E., Hemes, K., Ma, S., Sanchez, C. R., Shortt, R., Szutu, D., Valach, A., Verfaillie, J., Badgley, G., Zeng, Y., Berry, J. A. (2020) Outgoing Near‐Infrared Radiation From Vegetation Scales With Canopy Photosynthesis Across A Spectrum Of Function, Structure, Physiological Capacity, And Weather, Journal Of Geophysical Research: Biogeosciences, 125(7), 108204" -US-Var,1700003180,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2019JG005534 -US-Var,1700003180,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Var,1700004719,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Baldocchi, D. D., Xu, L., Kiang, N. (2004) How Plant Functional-Type, Weather, Seasonal Drought, And Soil Physical Properties Alter Water And Energy Fluxes Of An Oak–Grass Savanna And An Annual Grassland, Agricultural And Forest Meteorology, 123(1-2), 13-39" -US-Var,1700004719,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2003.11.006 -US-Var,1700004719,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Var,1700008196,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Baldocchi, D., Ma, S., Verfaillie, J. (2021) On The Inter‐ And Intra‐Annual Variability Of Ecosystem Evapotranspiration And Water Use Efficiency Of An Oak Savanna And Annual Grassland Subjected To Booms And Busts In Rainfall, Global Change Biology, 27(2), 359-375" -US-Var,1700008196,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/GCB.15414 -US-Var,1700008196,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Var,1700006213,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Baldocchi, D., Penuelas, J. (2018) The Physics And Ecology Of Mining Carbon Dioxide From The Atmosphere By Ecosystems, Global Change Biology, 45(21), 9275–9287" -US-Var,1700006213,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/GCB.14559 -US-Var,1700006213,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Var,1700008229,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Baldocchi, D., Penuelas, J. (2018) The Physics And Ecology Of Mining Carbon Dioxide From The Atmosphere By Ecosystems, Global Change Biology, 45(3-4), 9275–9287" -US-Var,1700008229,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/GCB.14559 -US-Var,1700008229,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Var,1700008253,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Barr, A., Richardson, A., Hollinger, D., Papale, D., Arain, M., Black, T., Bohrer, G., Dragoni, D., Fischer, M., Gu, L., Law, B., Margolis, H., McCaughey, J., Munger, J., Oechel, W., Schaeffer, K. (2013) Use Of Change-Point Detection For Friction–Velocity Threshold Evaluation In Eddy-Covariance Studies, Agricultural And Forest Meteorology, 171-172(7), 31-45" -US-Var,1700008253,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2012.11.023 -US-Var,1700008253,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Var,1700001032,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Baldocchi, D. D., Poindexter, C., Abraha, M., Desai, A. R., Bohrer, G., Arain, M. A., Griffis, T., Blanken, P. D., O'Halloran, T. L., Thomas, R. Q., Zhang, Q., Burns, S. P., Frank, J. M., Christian, D., Brown, S., Black, T. A., Gough, C. M., Law, B. E., Lee, X., Chen, J., Reed, D. E., Massman, W. J., Clark, K., Hatfield, J., Prueger, J., Bracho, R., Baker, J. M., Martin, T. A. (2018) Temporal Dynamics Of Aerodynamic Canopy Height Derived From Eddy Covariance Momentum Flux Data Across North American Flux Networks, Geophysical Research Letters, 45(21), 9275–9287" -US-Var,1700001032,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018GL079306 -US-Var,1700001032,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Var,1700001929,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Baldocchi, D. D., Poindexter, C., Abraha, M., Desai, A. R., Bohrer, G., Arain, M. A., Griffis, T., Blanken, P. D., O'Halloran, T. L., Thomas, R. Q., Zhang, Q., Burns, S. P., Frank, J. M., Christian, D., Brown, S., Black, T. A., Gough, C. M., Law, B. E., Lee, X., Chen, J., Reed, D. E., Massman, W. J., Clark, K., Hatfield, J., Prueger, J., Bracho, R., Baker, J. M., Martin, T. A. (2018) Temporal Dynamics Of Aerodynamic Canopy Height Derived From Eddy Covariance Momentum Flux Data Across North American Flux Networks, Geophysical Research Letters, 45(3-4), 9275–9287" -US-Var,1700001929,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018GL079306 -US-Var,1700001929,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Var,1700003444,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(6), 108350" -US-Var,1700003444,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -US-Var,1700003444,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Var,1700006321,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Dennis Baldocchi, Cove Sturtevant (2015) Does day and night sampling reduce spurious correlation between canopy photosynthesis and ecosystem respiration?, Agricultural and Forest Meteorology, 207(3-4), 117-126" -US-Var,1700006321,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2015.03.010 -US-Var,1700006321,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Var,1700004140,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Filippa, G, Cremonesea, E, Migliavacca M., Galvagno, M., Sonnentag, O., Humphrey, E., Hufkens,K., Ryu, Y. Verfaillie, J., Morra di Cella, U., Richardson, A. (2017) NDVI derived from near-infrared-enabled digital cameras: Applicability across different plant functional types, Agricultural and Forest Meteorology, 207(3-4), 117-126" -US-Var,1700004140,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2017.11.003 -US-Var,1700004140,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Var,1700000147,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Grant, R., Baldocchi, D., Ma, S. (2012) Ecological Controls On Net Ecosystem Productivity Of A Seasonally Dry Annual Grassland Under Current And Future Climates: Modelling With Ecosys, Agricultural And Forest Meteorology, 152(3-4), 189-200" -US-Var,1700000147,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2011.09.012 -US-Var,1700000147,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Var,1700002808,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Gu, L., Falge, E. M., Boden, T., Baldocchi, D. D., Black, T., Saleska, S. R., Suni, T., Verma, S. B., Vesala, T., Wofsy, S. C., Xu, L. (2005) Objective Threshold Determination For Nighttime Eddy Flux Filtering, Agricultural And Forest Meteorology, 128(3-4), 179-197" -US-Var,1700002808,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2004.11.006 -US-Var,1700002808,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Var,1700003573,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Kim, J., Guo, Q., Baldocchi, D., Leclerc, M., Xu, L., Schmid, H. (2006) Upscaling Fluxes From Tower To Landscape: Overlaying Flux Footprints On High-Resolution (IKONOS) Images Of Vegetation Cover, Agricultural And Forest Meteorology, 136(3-4), 132-146" -US-Var,1700003573,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2004.11.015 -US-Var,1700003573,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Var,1700007596,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Liu, Y., Hill, M. J., Zhang, X., Wang, Z., Richardson, A. D., Hufkens, K., Filippa, G., Baldocchi, D. D., Ma, S., Verfaillie, J., Schaaf, C. B. (2017) Using Data From Landsat, Modis, Viirs And Phenocams To Monitor The Phenology Of California Oak/Grass Savanna And Open Grassland Across Spatial Scales, Agricultural And Forest Meteorology, 237-238(21), 311-325" -US-Var,1700007596,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2017.02.026 -US-Var,1700007596,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Var,1700007278,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Liu, Y., Hill, M. J., Zhang, X., Wang, Z., Richardson, A. D., Hufkens, K., Filippa, G., Baldocchi, D. D., Ma, S., Verfaillie, J., Schaaf, C. B. (2017) Using Data From Landsat, Modis, Viirs And Phenocams To Monitor The Phenology Of California Oak/Grass Savanna And Open Grassland Across Spatial Scales, Agricultural And Forest Meteorology, 237-238(3-4), 311-325" -US-Var,1700007278,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2017.02.026 -US-Var,1700007278,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Var,1700000192,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Ma, S, Baldocchi, D.D., Wolf, S., Verfaillie, J. (2016) Slow ecosystem responses conditionally regulate annual carbon balance over 15 years in Californian oak-grass savanna, Agricultural and Forest Meteorology, (), 252-264" -US-Var,1700000192,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2016.07.016 -US-Var,1700000192,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Var,1700006903,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Ma, S., Baldocchi, D. D., Xu, L., Hehn, T. (2007) Inter-Annual Variability In Carbon Dioxide Exchange Of An Oak/Grass Savanna And Open Grassland In California, Agricultural And Forest Meteorology, 147(3-4), 157-171" -US-Var,1700006903,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2007.07.008 -US-Var,1700006903,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Primary_Citation -US-Var,1700003933,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Ma, S., Eichelmann, E., Wolf, S., Rey-Sanchez, C., Baldocchi, D. D. (2020) Transpiration And Evaporation In A Californian Oak-Grass Savanna: Field Measurements And Partitioning Model Results, Agricultural And Forest Meteorology, 295(2), 108204" -US-Var,1700003933,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2020.108204 -US-Var,1700003933,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Var,1700006189,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Matheny, A. M., Bohrer, G., Stoy, P. C., Baker, I. T., Black, A. T., Desai, A. R., Dietze, M. C., Gough, C. M., Ivanov, V. Y., Jassal, R. S., Novick, K. A., Schäfer, K. V., Verbeeck, H. (2014) Characterizing The Diurnal Patterns of Errors in The Prediction of Evapotranspiration by Several Land-Surface Models: An Nacp Analysis, Journal Of Geophysical Research: Biogeosciences, 119(7), 1458-1473" -US-Var,1700006189,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/2014JG002623 -US-Var,1700006189,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Var,1700003324,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Novick, K. A., Ficklin, D. L., Stoy, P. C., Williams, C. A., Bohrer, G., Oishi, A., Papuga, S. A., Blanken, P. D., Noormets, A., Sulman, B. N., Scott, R. L., Wang, L., Phillips, R. P. (2016) The Increasing Importance Of Atmospheric Demand For Ecosystem Water And Carbon Fluxes, Nature Climate Change, 6(11), 1023-1027" -US-Var,1700003324,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1038/NCLIMATE3114 -US-Var,1700003324,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Var,1700003408,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Novick, K. A., Konings, A. G., Gentine, P. (2019) Beyond Soil Water Potential: An Expanded View On Isohydricity Including Land–Atmosphere Interactions And Phenology, Plant, Cell & Environment, 42(6), 1802-1815" -US-Var,1700003408,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/PCE.13517 -US-Var,1700003408,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Var,1700002223,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Ryu, Y, Baldoicchi, D. D., Ma, S., Hehn, T. (2008) Interannual Variability Of Evapotranspiration And Energy Exchange Over An Annual Grassland In California, Journal Of Geophysical Research, 113(D09104), n/a-n/a" -US-Var,1700002223,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2007JD009263 -US-Var,1700002223,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Var,1700008244,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Schmidt, A., Creason, W., Law, B. E. (2018) Estimating Regional Effects Of Climate Change And Altered Land Use On Biosphere Carbon Fluxes Using Distributed Time Delay Neural Networks With Bayesian Regularized Learning, Neural Networks, 108(21), 97-113" -US-Var,1700008244,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.NEUNET.2018.08.004 -US-Var,1700008244,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Var,1700006567,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Schmidt, A., Creason, W., Law, B. E. (2018) Estimating Regional Effects Of Climate Change And Altered Land Use On Biosphere Carbon Fluxes Using Distributed Time Delay Neural Networks With Bayesian Regularized Learning, Neural Networks, 108(3-4), 97-113" -US-Var,1700006567,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.NEUNET.2018.08.004 -US-Var,1700006567,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Var,1700008541,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Sims, D. A., Rahman, A. F., Cordova, V. D., Baldocchi, D. D., Flanagan, L. B., Goldstein, A. H., Hollinger, D. Y., Misson, L., Monson, R. K., Schmid, H. P., Wofsy, S. C., Xu, L. (2005) Midday Values Of Gross CO2 Flux And Light Use Efficiency During Satellite Overpasses Can Be Used To Directly Estimate Eight-Day Mean Flux, Agricultural And Forest Meteorology, 131(1-2), 1-12" -US-Var,1700008541,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2005.04.006 -US-Var,1700008541,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Var,1700000588,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Sullivan, R. C., Cook, D. R., Ghate, V. P., Kotamarthi, V. R., Feng, Y. (2019) Improved Spatiotemporal Representativeness And Bias Reduction Of Satellite-Based Evapotranspiration Retrievals Via Use Of In Situ Meteorology And Constrained Canopy Surface Resistance, Journal Of Geophysical Research: Biogeosciences, 124(2), 342-352" -US-Var,1700000588,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018JG004744 -US-Var,1700000588,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Var,1700000468,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Sullivan, R. C., Kotamarthi, V. R., Feng, Y. (2019) Recovering Evapotranspiration Trends From Biased CMIP5 Simulations And Sensitivity To Changing Climate Over North America, Journal Of Hydrometeorology, 20(8), 1619-1633" -US-Var,1700000468,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1175/JHM-D-18-0259.1 -US-Var,1700000468,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Var,1700007692,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Toomey, M., Friedl, M. A., Frolking, S., Hufkens, K., Klosterman, S., Sonnentag, O., Baldocchi, D. D., Bernacchi, C. J., Biraud, S. C., Bohrer, G., Brzostek, E., Burns, S. P., Coursolle, C., Hollinger, D. Y., Margolis, H. A., McCaughey, H., Monson, R. K., Munger, J. W., Pallardy, S., Phillips, R. P., Torn, M. S., Wharton, S., Zeri, M., Richardson, A. D. (2015) Greenness Indices From Digital Cameras Predict The Timing And Seasonal Dynamics Of Canopy-Scale Photosynthesis, Ecological Applications, 25(1), 99-115" -US-Var,1700007692,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1890/14-0005.1 -US-Var,1700007692,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Var,1700000456,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Wolf, S., Keenan, T.F., Fisher, J.B., Baldocchi, D.D., Desai, A.R., Richardson, A.D., Scott, R.L., Law, B.E., Litvak, M.E., Brunsell, N.A., Peters, W., van der Laan-Luijkx, I.T. (2016) Warm spring reduced carbon cycle impact of the 2012 US summer drought, Proceedings of the National Academy of Sciences, 113(21), 5880-5885" -US-Var,1700000456,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1073/PNAS.1519620113 -US-Var,1700000456,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Var,1700001908,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Xu, L., Baldocchi, D. D. (2004) Seasonal Variation In Carbon Dioxide Exchange Over A Mediterranean Annual Grassland In California, Agricultural And Forest Meteorology, 123(1-2), 79-96" -US-Var,1700001908,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2003.10.004 -US-Var,1700001908,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Var,1700002418,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Xu, L., Baldocchi, D. D., Tang, J. (2004) How Soil Moisture, Rain Pulses, And Growth Alter The Response Of Ecosystem Respiration To Temperature, Global Biogeochemical Cycles, 18(4), n/a-n/a" -US-Var,1700002418,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2004GB002281 -US-Var,1700002418,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Var,1700005118,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Zhang, Q., Ficklin, D. L., Manzoni, S., Wang, L., Way, D., Phillips, R. P., Novick, K. A. (2019) Response Of Ecosystem Intrinsic Water Use Efficiency And Gross Primary Productivity To Rising Vapor Pressure Deficit, Environmental Research Letters, 14(7), 074023" -US-Var,1700005118,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1088/1748-9326/AB2603 -US-Var,1700005118,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Var,11330,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"The research approach of the University of California, Berkeley Biometeorology Laboratory involves the coordinated use of experimental measurements and theoretical models to understand the physical, biological, and chemical processes that control trace gas fluxes between the biosphere and atmosphere and to quantify their temporal and spatial variations. The research objectives of the Vaira Ranch site span from overall project goals to publication-specific topics. They are as follows: 1) Comparing radiative, convective and latent energy flux densities of an annual grassland over the course of multiple growing seasons; 2) The relative contributions of vegetation and the soil on CO2 and water vapor exchange; 3) Spatial variability of understory fluxes; 4) The impact of sloping terrain on the interpretation of flux covariances; 5) Characterize evapotranspiration, energy fluxes and related bulk parameters in monthly and annual timescales; 6) Investigate which abiotic and biotic factors control the interannual variability of water and energy fluxes; 7) The influence of growing season length on annual evapotranspiration amount; 8) Transition timing of energy-limited to water-limited modulate annual amount of evapotranspiration; 9) The controlling factors of evapotranspiration and atmospheric demand or stomatal regulation; 10) The response of evapotranspiration to changes in solar radiation amounts in water-limited and energy-limited periods." -US-Var,11331,GRP_SITE_CHAR,TERRAIN,"Medium Slope (>2 %, <5%)" -US-Var,11331,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,0 -US-Var,11332,GRP_SITE_DESC,SITE_DESC,"Located in the lower foothills of the Sierra Nevada Mountains on privately owned land, the Vaira Ranch site is classified as a grassland dominated by C3 annual grasses. Managed by local rancher, Fran Vaira, brush has been periodically removed for cattle grazing. Species include a variety of grasses and herbs, including purple false brome, smooth cat's ear, and rose clover. Growing season is confined to the wet season only, typically from October to early May." -US-Var,11333,GRP_SITE_FUNDING,SITE_FUNDING,DOE/TCP -US-Var,22047,GRP_SOIL_CHEM,SOIL_CHEM_BD,1.4333333333 -US-Var,22047,GRP_SOIL_CHEM,SOIL_CHEM_BD_SPATIAL_VARIABILITY,0.1246739337 -US-Var,22047,GRP_SOIL_CHEM,SOIL_CHEM_BD_SPATIAL_REP_NUMBER,27 -US-Var,22047,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_ZERO_REF,Top of mineral soil -US-Var,22047,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,0 -US-Var,22047,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,30 -US-Var,22047,GRP_SOIL_CHEM,SOIL_CHEM_DATE,20010425 -US-Var,22047,GRP_SOIL_CHEM,SOIL_CHEM_DATE_UNC,0 -US-Var,25277,GRP_SPP_O,SPP_O,QUDO (NRCS plant code) -US-Var,11334,GRP_STATE,STATE,CA -US-Var,21712,GRP_SWC,SWC,0.33333333333 -US-Var,21712,GRP_SWC,SWC_SPATIAL_REP_NUMBER,1 -US-Var,21712,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21712,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21712,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21712,GRP_SWC,SWC_DATE,20101007 -US-Var,21708,GRP_SWC,SWC,0.35 -US-Var,21708,GRP_SWC,SWC_SPATIAL_REP_NUMBER,1 -US-Var,21708,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21708,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21708,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21708,GRP_SWC,SWC_DATE,20100902 -US-Var,21105,GRP_SWC,SWC,0.36666666667 -US-Var,21105,GRP_SWC,SWC_SPATIAL_VARIABILITY,0 -US-Var,21105,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21105,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21105,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21105,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21105,GRP_SWC,SWC_DATE,20021002 -US-Var,21081,GRP_SWC,SWC,0.63333333333 -US-Var,21081,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.18856180832 -US-Var,21081,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21081,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21081,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21081,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21081,GRP_SWC,SWC_DATE,20020815 -US-Var,21568,GRP_SWC,SWC,0.65 -US-Var,21568,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.77781745931 -US-Var,21568,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21568,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21568,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21568,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21568,GRP_SWC,SWC_DATE,20080806 -US-Var,21576,GRP_SWC,SWC,0.65 -US-Var,21576,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.77781745931 -US-Var,21576,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21576,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21576,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21576,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21576,GRP_SWC,SWC_DATE,20080919 -US-Var,21109,GRP_SWC,SWC,0.66666666667 -US-Var,21109,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.28284271247 -US-Var,21109,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21109,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21109,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21109,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21109,GRP_SWC,SWC_DATE,20021105 -US-Var,21564,GRP_SWC,SWC,0.8 -US-Var,21564,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.14142135624 -US-Var,21564,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21564,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21564,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21564,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21564,GRP_SWC,SWC_DATE,20080731 -US-Var,21085,GRP_SWC,SWC,0.837875 -US-Var,21085,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.76067011986 -US-Var,21085,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21085,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21085,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21085,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21085,GRP_SWC,SWC_DATE,20020823 -US-Var,21860,GRP_SWC,SWC,0.8875 -US-Var,21860,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.74316328399 -US-Var,21860,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21860,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21860,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21860,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21860,GRP_SWC,SWC_DATE,20120919 -US-Var,21864,GRP_SWC,SWC,0.8875 -US-Var,21864,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.74316328399 -US-Var,21864,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21864,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21864,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21864,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21864,GRP_SWC,SWC_DATE,20121009 -US-Var,21704,GRP_SWC,SWC,0.925 -US-Var,21704,GRP_SWC,SWC_SPATIAL_REP_NUMBER,1 -US-Var,21704,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21704,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21704,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21704,GRP_SWC,SWC_DATE,20100814 -US-Var,21992,GRP_SWC,SWC,0.9375 -US-Var,21992,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.8260094834 -US-Var,21992,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21992,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21992,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21992,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21992,GRP_SWC,SWC_DATE,20140625 -US-Var,21852,GRP_SWC,SWC,0.95 -US-Var,21852,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.41231056256 -US-Var,21852,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21852,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21852,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21852,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21852,GRP_SWC,SWC_DATE,20120822 -US-Var,21065,GRP_SWC,SWC,1 -US-Var,21065,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.56568542495 -US-Var,21065,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21065,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21065,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21065,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21065,GRP_SWC,SWC_DATE,20020711 -US-Var,21572,GRP_SWC,SWC,1 -US-Var,21572,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.42426406871 -US-Var,21572,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21572,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21572,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21572,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21572,GRP_SWC,SWC_DATE,20080904 -US-Var,21093,GRP_SWC,SWC,1.0166666667 -US-Var,21093,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.0606601718 -US-Var,21093,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21093,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21093,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21093,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21093,GRP_SWC,SWC_DATE,20020905 -US-Var,21996,GRP_SWC,SWC,1.0375 -US-Var,21996,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.6342646661 -US-Var,21996,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21996,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21996,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21996,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21996,GRP_SWC,SWC_DATE,20140709 -US-Var,21213,GRP_SWC,SWC,1.05 -US-Var,21213,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.1313708499 -US-Var,21213,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21213,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21213,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21213,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21213,GRP_SWC,SWC_DATE,20030731 -US-Var,22004,GRP_SWC,SWC,1.05 -US-Var,22004,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.75498344353 -US-Var,22004,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,22004,GRP_SWC,SWC_UNIT,Volumetric -US-Var,22004,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,22004,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,22004,GRP_SWC,SWC_DATE,20140821 -US-Var,21856,GRP_SWC,SWC,1.0875 -US-Var,21856,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.82297731844 -US-Var,21856,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21856,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21856,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21856,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21856,GRP_SWC,SWC_DATE,20120905 -US-Var,21936,GRP_SWC,SWC,1.0875 -US-Var,21936,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.0036392114 -US-Var,21936,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21936,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21936,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21936,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21936,GRP_SWC,SWC_DATE,20130904 -US-Var,21069,GRP_SWC,SWC,1.15 -US-Var,21069,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.63639610307 -US-Var,21069,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21069,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21069,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21069,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21069,GRP_SWC,SWC_DATE,20020719 -US-Var,21928,GRP_SWC,SWC,1.15 -US-Var,21928,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.1 -US-Var,21928,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21928,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21928,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21928,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21928,GRP_SWC,SWC_DATE,20130728 -US-Var,21201,GRP_SWC,SWC,1.2 -US-Var,21201,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.98994949366 -US-Var,21201,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21201,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21201,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21201,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21201,GRP_SWC,SWC_DATE,20030711 -US-Var,21636,GRP_SWC,SWC,1.25 -US-Var,21636,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.91923881554 -US-Var,21636,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21636,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21636,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21636,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21636,GRP_SWC,SWC_DATE,20090705 -US-Var,21524,GRP_SWC,SWC,1.275 -US-Var,21524,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.88388347648 -US-Var,21524,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21524,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21524,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21524,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21524,GRP_SWC,SWC_DATE,20070623 -US-Var,21089,GRP_SWC,SWC,1.2833333333 -US-Var,21089,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.96637926762 -US-Var,21089,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21089,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21089,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21089,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21089,GRP_SWC,SWC_DATE,20020829 -US-Var,21924,GRP_SWC,SWC,1.2875 -US-Var,21924,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.94813413256 -US-Var,21924,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21924,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21924,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21924,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21924,GRP_SWC,SWC_DATE,20130711 -US-Var,22000,GRP_SWC,SWC,1.2875 -US-Var,22000,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.404976275 -US-Var,22000,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,22000,GRP_SWC,SWC_UNIT,Volumetric -US-Var,22000,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,22000,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,22000,GRP_SWC,SWC_DATE,20140805 -US-Var,21920,GRP_SWC,SWC,1.3208333333 -US-Var,21920,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.84725865131 -US-Var,21920,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21920,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21920,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21920,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21920,GRP_SWC,SWC_DATE,20130619 -US-Var,21073,GRP_SWC,SWC,1.35 -US-Var,21073,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.070710678119 -US-Var,21073,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21073,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21073,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21073,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21073,GRP_SWC,SWC_DATE,20020725 -US-Var,21848,GRP_SWC,SWC,1.375 -US-Var,21848,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.75332595867 -US-Var,21848,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21848,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21848,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21848,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21848,GRP_SWC,SWC_DATE,20120725 -US-Var,21944,GRP_SWC,SWC,1.4 -US-Var,21944,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.96350056219 -US-Var,21944,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21944,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21944,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21944,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21944,GRP_SWC,SWC_DATE,20131107 -US-Var,22008,GRP_SWC,SWC,1.4375 -US-Var,22008,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.7169088738 -US-Var,22008,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,22008,GRP_SWC,SWC_UNIT,Volumetric -US-Var,22008,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,22008,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,22008,GRP_SWC,SWC_DATE,20140911 -US-Var,21197,GRP_SWC,SWC,1.45 -US-Var,21197,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.25927248644 -US-Var,21197,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21197,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21197,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21197,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21197,GRP_SWC,SWC_DATE,20030703 -US-Var,21101,GRP_SWC,SWC,1.4666666667 -US-Var,21101,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.18856180832 -US-Var,21101,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21101,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21101,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21101,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21101,GRP_SWC,SWC_DATE,20020920 -US-Var,21416,GRP_SWC,SWC,1.625 -US-Var,21416,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.31819805153 -US-Var,21416,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21416,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21416,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21416,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21416,GRP_SWC,SWC_DATE,20050925 -US-Var,21520,GRP_SWC,SWC,1.6333333333 -US-Var,21520,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.2727922061 -US-Var,21520,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21520,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21520,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21520,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21520,GRP_SWC,SWC_DATE,20070531 -US-Var,21548,GRP_SWC,SWC,1.65 -US-Var,21548,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.63639610307 -US-Var,21548,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21548,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21548,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21548,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21548,GRP_SWC,SWC_DATE,20080506 -US-Var,21233,GRP_SWC,SWC,1.6833333333 -US-Var,21233,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.44783429475 -US-Var,21233,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21233,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21233,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21233,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21233,GRP_SWC,SWC_DATE,20031024 -US-Var,21077,GRP_SWC,SWC,1.7333333333 -US-Var,21077,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.4613540145 -US-Var,21077,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21077,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21077,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21077,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21077,GRP_SWC,SWC_DATE,20020801 -US-Var,21648,GRP_SWC,SWC,1.75 -US-Var,21648,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.0606601718 -US-Var,21648,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21648,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21648,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21648,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21648,GRP_SWC,SWC_DATE,20091002 -US-Var,21932,GRP_SWC,SWC,1.775 -US-Var,21932,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.1228683508 -US-Var,21932,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21932,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21932,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21932,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21932,GRP_SWC,SWC_DATE,20130813 -US-Var,21205,GRP_SWC,SWC,1.85 -US-Var,21205,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.02357022604 -US-Var,21205,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21205,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21205,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21205,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21205,GRP_SWC,SWC_DATE,20030717 -US-Var,21916,GRP_SWC,SWC,1.9375 -US-Var,21916,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.5542281042 -US-Var,21916,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21916,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21916,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21916,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21916,GRP_SWC,SWC_DATE,20130530 -US-Var,22020,GRP_SWC,SWC,10 -US-Var,22020,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.8262252939 -US-Var,22020,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,22020,GRP_SWC,SWC_UNIT,Volumetric -US-Var,22020,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,22020,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,22020,GRP_SWC,SWC_DATE,20141113 -US-Var,22022,GRP_SWC,SWC,10.025 -US-Var,22022,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.4948772034 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-US-Var,22021,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,22021,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,22021,GRP_SWC,SWC_DATE,20141113 -US-Var,21058,GRP_SWC,SWC,10.133333333 -US-Var,21058,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.7341462206 -US-Var,21058,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21058,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21058,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21058,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21058,GRP_SWC,SWC_DATE,20020620 -US-Var,21638,GRP_SWC,SWC,10.2 -US-Var,21638,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.1213203436 -US-Var,21638,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21638,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21638,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21638,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21638,GRP_SWC,SWC_DATE,20090705 -US-Var,21646,GRP_SWC,SWC,10.2 -US-Var,21646,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.969848481 -US-Var,21646,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21646,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21646,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21646,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21646,GRP_SWC,SWC_DATE,20090907 -US-Var,21757,GRP_SWC,SWC,10.2 -US-Var,21757,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.0800262467 -US-Var,21757,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21757,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21757,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21757,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21757,GRP_SWC,SWC_DATE,20110527 -US-Var,21660,GRP_SWC,SWC,10.225 -US-Var,21660,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.3286056916 -US-Var,21660,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21660,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21660,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21660,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21660,GRP_SWC,SWC_DATE,20091129 -US-Var,21901,GRP_SWC,SWC,10.25 -US-Var,21901,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.3516165254 -US-Var,21901,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21901,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21901,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21901,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21901,GRP_SWC,SWC_DATE,20130327 -US-Var,21075,GRP_SWC,SWC,10.3 -US-Var,21075,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.3840620434 -US-Var,21075,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21075,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21075,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21075,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21075,GRP_SWC,SWC_DATE,20020725 -US-Var,21986,GRP_SWC,SWC,10.3875 -US-Var,21986,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.6192192518 -US-Var,21986,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21986,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21986,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21986,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21986,GRP_SWC,SWC_DATE,20140522 -US-Var,21657,GRP_SWC,SWC,10.4 -US-Var,21657,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.5254833996 -US-Var,21657,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21657,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21657,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21657,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21657,GRP_SWC,SWC_DATE,20091105 -US-Var,21534,GRP_SWC,SWC,10.433333333 -US-Var,21534,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.1213203436 -US-Var,21534,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21534,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21534,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21534,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21534,GRP_SWC,SWC_DATE,20071129 -US-Var,21582,GRP_SWC,SWC,10.436666667 -US-Var,21582,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.5980613255 -US-Var,21582,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21582,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21582,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21582,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21582,GRP_SWC,SWC_DATE,20081030 -US-Var,21949,GRP_SWC,SWC,10.5625 -US-Var,21949,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.5616970287 -US-Var,21949,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21949,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21949,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21949,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21949,GRP_SWC,SWC_DATE,20131127 -US-Var,21961,GRP_SWC,SWC,10.5625 -US-Var,21961,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.6684499246 -US-Var,21961,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21961,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21961,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21961,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21961,GRP_SWC,SWC_DATE,20140124 -US-Var,21530,GRP_SWC,SWC,10.65 -US-Var,21530,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.98994949366 -US-Var,21530,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21530,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21530,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21530,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21530,GRP_SWC,SWC_DATE,20071107 -US-Var,21642,GRP_SWC,SWC,10.65 -US-Var,21642,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.1819805153 -US-Var,21642,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21642,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21642,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21642,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21642,GRP_SWC,SWC_DATE,20090802 -US-Var,21692,GRP_SWC,SWC,10.7 -US-Var,21692,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.8284271247 -US-Var,21692,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21692,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21692,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21692,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21692,GRP_SWC,SWC_DATE,20100528 -US-Var,21892,GRP_SWC,SWC,10.75 -US-Var,21892,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.9735969546 -US-Var,21892,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21892,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21892,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21892,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21892,GRP_SWC,SWC_DATE,20130227 -US-Var,21522,GRP_SWC,SWC,10.883333333 -US-Var,21522,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.73067700723 -US-Var,21522,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21522,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21522,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21522,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21522,GRP_SWC,SWC_DATE,20070531 -US-Var,21765,GRP_SWC,SWC,10.8875 -US-Var,21765,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.8933996209 -US-Var,21765,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21765,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21765,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21765,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21765,GRP_SWC,SWC_DATE,20110706 -US-Var,21957,GRP_SWC,SWC,10.925 -US-Var,21957,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.5711540859 -US-Var,21957,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21957,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21957,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21957,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21957,GRP_SWC,SWC_DATE,20140107 -US-Var,21290,GRP_SWC,SWC,11.016666667 -US-Var,21290,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.8620478571 -US-Var,21290,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21290,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21290,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21290,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21290,GRP_SWC,SWC_DATE,20040409 -US-Var,21295,GRP_SWC,SWC,11.025 -US-Var,21295,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.368807717 -US-Var,21295,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21295,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21295,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21295,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21295,GRP_SWC,SWC_DATE,20040423 -US-Var,22006,GRP_SWC,SWC,11.025 -US-Var,22006,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.4130244165 -US-Var,22006,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,22006,GRP_SWC,SWC_UNIT,Volumetric -US-Var,22006,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,22006,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,22006,GRP_SWC,SWC_DATE,20140821 -US-Var,21245,GRP_SWC,SWC,11.033333333 -US-Var,21245,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.5084944665 -US-Var,21245,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21245,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21245,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21245,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21245,GRP_SWC,SWC_DATE,20031119 -US-Var,21616,GRP_SWC,SWC,11.083333333 -US-Var,21616,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.5792051446 -US-Var,21616,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21616,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21616,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21616,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21616,GRP_SWC,SWC_DATE,20090417 -US-Var,21025,GRP_SWC,SWC,11.1 -US-Var,21025,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.80138768534 -US-Var,21025,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21025,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21025,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21025,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21025,GRP_SWC,SWC_DATE,20020411 -US-Var,21905,GRP_SWC,SWC,11.125 -US-Var,21905,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.881695103 -US-Var,21905,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21905,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21905,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21905,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21905,GRP_SWC,SWC_DATE,20130410 -US-Var,22002,GRP_SWC,SWC,11.15 -US-Var,22002,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.5506756346 -US-Var,22002,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,22002,GRP_SWC,SWC_UNIT,Volumetric -US-Var,22002,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,22002,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,22002,GRP_SWC,SWC_DATE,20140805 -US-Var,22026,GRP_SWC,SWC,11.1625 -US-Var,22026,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.9853118827 -US-Var,22026,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,22026,GRP_SWC,SWC_UNIT,Volumetric -US-Var,22026,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,22026,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,22026,GRP_SWC,SWC_DATE,20141126 -US-Var,20988,GRP_SWC,SWC,11.25 -US-Var,20988,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.35355339059 -US-Var,20988,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,20988,GRP_SWC,SWC_UNIT,Volumetric -US-Var,20988,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,20988,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,20988,GRP_SWC,SWC_DATE,20011110 -US-Var,21713,GRP_SWC,SWC,11.3 -US-Var,21713,GRP_SWC,SWC_SPATIAL_REP_NUMBER,1 -US-Var,21713,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21713,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21713,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21713,GRP_SWC,SWC_DATE,20101007 -US-Var,21980,GRP_SWC,SWC,11.3125 -US-Var,21980,GRP_SWC,SWC_SPATIAL_VARIABILITY,10.894599197 -US-Var,21980,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21980,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21980,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21980,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21980,GRP_SWC,SWC_DATE,20140422 -US-Var,21496,GRP_SWC,SWC,11.333333333 -US-Var,21496,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.3168205786 -US-Var,21496,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21496,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21496,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21496,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21496,GRP_SWC,SWC_DATE,20070204 -US-Var,21238,GRP_SWC,SWC,11.35 -US-Var,21238,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.4748737342 -US-Var,21238,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21238,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21238,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21238,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21238,GRP_SWC,SWC_DATE,20031107 -US-Var,21620,GRP_SWC,SWC,11.35 -US-Var,21620,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.4849242405 -US-Var,21620,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21620,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21620,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21620,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21620,GRP_SWC,SWC_DATE,20090507 -US-Var,21748,GRP_SWC,SWC,11.4125 -US-Var,21748,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.3493055227 -US-Var,21748,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21748,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21748,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21748,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21748,GRP_SWC,SWC_DATE,20110415 -US-Var,21653,GRP_SWC,SWC,11.425 -US-Var,21653,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.7629202667 -US-Var,21653,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21653,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21653,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21653,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21653,GRP_SWC,SWC_DATE,20091022 -US-Var,21801,GRP_SWC,SWC,11.4375 -US-Var,21801,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.0309996692 -US-Var,21801,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21801,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21801,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21801,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21801,GRP_SWC,SWC_DATE,20111218 -US-Var,21838,GRP_SWC,SWC,11.4375 -US-Var,21838,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.8527268966 -US-Var,21838,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21838,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21838,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21838,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21838,GRP_SWC,SWC_DATE,20120518 -US-Var,21805,GRP_SWC,SWC,11.45 -US-Var,21805,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.8234582529 -US-Var,21805,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21805,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21805,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21805,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21805,GRP_SWC,SWC_DATE,20120104 -US-Var,21465,GRP_SWC,SWC,11.5 -US-Var,21465,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.70710678119 -US-Var,21465,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21465,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21465,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21465,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21465,GRP_SWC,SWC_DATE,20060512 -US-Var,21111,GRP_SWC,SWC,11.533333333 -US-Var,21111,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.1313708499 -US-Var,21111,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21111,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21111,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21111,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21111,GRP_SWC,SWC_DATE,20021105 -US-Var,21810,GRP_SWC,SWC,11.5375 -US-Var,21810,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.782498739 -US-Var,21810,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21810,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21810,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21810,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21810,GRP_SWC,SWC_DATE,20120118 -US-Var,21533,GRP_SWC,SWC,11.633333333 -US-Var,21533,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.7812866727 -US-Var,21533,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21533,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21533,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21533,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21533,GRP_SWC,SWC_DATE,20071129 -US-Var,21778,GRP_SWC,SWC,11.641666667 -US-Var,21778,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.8520256069 -US-Var,21778,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21778,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21778,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21778,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21778,GRP_SWC,SWC_DATE,20110916 -US-Var,21705,GRP_SWC,SWC,11.65 -US-Var,21705,GRP_SWC,SWC_SPATIAL_REP_NUMBER,1 -US-Var,21705,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21705,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21705,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21705,GRP_SWC,SWC_DATE,20100814 -US-Var,21782,GRP_SWC,SWC,11.675 -US-Var,21782,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.2951701063 -US-Var,21782,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21782,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21782,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21782,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21782,GRP_SWC,SWC_DATE,20110929 -US-Var,21059,GRP_SWC,SWC,11.7 -US-Var,21059,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.84852813742 -US-Var,21059,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21059,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21059,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21059,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21059,GRP_SWC,SWC_DATE,20020620 -US-Var,21545,GRP_SWC,SWC,11.75 -US-Var,21545,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.35355339059 -US-Var,21545,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21545,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21545,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21545,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21545,GRP_SWC,SWC_DATE,20080420 -US-Var,21784,GRP_SWC,SWC,11.758333333 -US-Var,21784,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.7701619325 -US-Var,21784,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21784,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21784,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21784,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21784,GRP_SWC,SWC_DATE,20111013 -US-Var,21701,GRP_SWC,SWC,11.8 -US-Var,21701,GRP_SWC,SWC_SPATIAL_REP_NUMBER,1 -US-Var,21701,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21701,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21701,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21701,GRP_SWC,SWC_DATE,20100624 -US-Var,21709,GRP_SWC,SWC,11.8 -US-Var,21709,GRP_SWC,SWC_SPATIAL_REP_NUMBER,1 -US-Var,21709,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21709,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21709,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21709,GRP_SWC,SWC_DATE,20100902 -US-Var,21055,GRP_SWC,SWC,11.816666667 -US-Var,21055,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.0506096654 -US-Var,21055,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21055,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21055,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21055,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21055,GRP_SWC,SWC_DATE,20020613 -US-Var,21047,GRP_SWC,SWC,11.833333333 -US-Var,21047,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.0641293851 -US-Var,21047,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21047,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21047,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21047,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21047,GRP_SWC,SWC_DATE,20020516 -US-Var,21953,GRP_SWC,SWC,11.858333333 -US-Var,21953,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.2676531247 -US-Var,21953,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21953,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21953,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21953,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21953,GRP_SWC,SWC_DATE,20131217 -US-Var,21249,GRP_SWC,SWC,11.866666667 -US-Var,21249,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.4883934539 -US-Var,21249,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21249,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21249,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21249,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21249,GRP_SWC,SWC_DATE,20031206 -US-Var,20992,GRP_SWC,SWC,11.883333333 -US-Var,20992,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.82495791138 -US-Var,20992,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,20992,GRP_SWC,SWC_UNIT,Volumetric -US-Var,20992,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,20992,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,20992,GRP_SWC,SWC_DATE,20011113 -US-Var,22025,GRP_SWC,SWC,11.8875 -US-Var,22025,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.99026511602 -US-Var,22025,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,22025,GRP_SWC,SWC_UNIT,Volumetric -US-Var,22025,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,22025,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,22025,GRP_SWC,SWC_DATE,20141126 -US-Var,21063,GRP_SWC,SWC,11.916666667 -US-Var,21063,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.767766953 -US-Var,21063,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21063,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21063,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21063,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21063,GRP_SWC,SWC_DATE,20020628 -US-Var,21099,GRP_SWC,SWC,11.925 -US-Var,21099,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.2980970389 -US-Var,21099,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21099,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21099,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21099,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21099,GRP_SWC,SWC_DATE,20020912 -US-Var,21083,GRP_SWC,SWC,11.95 -US-Var,21083,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.4748737342 -US-Var,21083,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21083,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21083,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21083,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21083,GRP_SWC,SWC_DATE,20020815 -US-Var,21517,GRP_SWC,SWC,11.983333333 -US-Var,21517,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.0776491048 -US-Var,21517,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21517,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21517,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21517,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21517,GRP_SWC,SWC_DATE,20070501 -US-Var,21071,GRP_SWC,SWC,12.016666667 -US-Var,21071,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.1920310217 -US-Var,21071,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21071,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21071,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21071,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21071,GRP_SWC,SWC_DATE,20020719 -US-Var,21774,GRP_SWC,SWC,12.041666667 -US-Var,21774,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.868520856 -US-Var,21774,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21774,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21774,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21774,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21774,GRP_SWC,SWC_DATE,20110831 -US-Var,21095,GRP_SWC,SWC,12.066666667 -US-Var,21095,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.357022604 -US-Var,21095,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21095,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21095,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21095,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21095,GRP_SWC,SWC_DATE,20020905 -US-Var,21107,GRP_SWC,SWC,12.083333333 -US-Var,21107,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.9091883092 -US-Var,21107,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21107,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21107,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21107,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21107,GRP_SWC,SWC_DATE,20021002 -US-Var,21087,GRP_SWC,SWC,12.116666667 -US-Var,21087,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.6734860488 -US-Var,21087,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21087,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21087,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21087,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21087,GRP_SWC,SWC_DATE,20020823 -US-Var,21336,GRP_SWC,SWC,12.125 -US-Var,21336,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.60104076401 -US-Var,21336,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21336,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21336,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21336,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21336,GRP_SWC,SWC_DATE,20041013 -US-Var,20995,GRP_SWC,SWC,12.15 -US-Var,20995,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.9833682007 -US-Var,20995,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,20995,GRP_SWC,SWC_UNIT,Volumetric -US-Var,20995,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,20995,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,20995,GRP_SWC,SWC_DATE,20011125 -US-Var,21051,GRP_SWC,SWC,12.15 -US-Var,21051,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.4377837884 -US-Var,21051,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21051,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21051,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21051,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21051,GRP_SWC,SWC_DATE,20020530 -US-Var,21906,GRP_SWC,SWC,12.2 -US-Var,21906,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.8566106151 -US-Var,21906,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21906,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21906,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21906,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21906,GRP_SWC,SWC_DATE,20130410 -US-Var,21067,GRP_SWC,SWC,12.233333333 -US-Var,21067,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.4613540145 -US-Var,21067,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21067,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21067,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21067,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21067,GRP_SWC,SWC_DATE,20020711 -US-Var,21793,GRP_SWC,SWC,12.2625 -US-Var,21793,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.5519913225 -US-Var,21793,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21793,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21793,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21793,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21793,GRP_SWC,SWC_DATE,20111109 -US-Var,21558,GRP_SWC,SWC,12.266666667 -US-Var,21558,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.0842303978 -US-Var,21558,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21558,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21558,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21558,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21558,GRP_SWC,SWC_DATE,20080627 -US-Var,21103,GRP_SWC,SWC,12.283333333 -US-Var,21103,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.4277332821 -US-Var,21103,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21103,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21103,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21103,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21103,GRP_SWC,SWC_DATE,20020920 -US-Var,21566,GRP_SWC,SWC,12.3 -US-Var,21566,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.42426406871 -US-Var,21566,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21566,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21566,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21566,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21566,GRP_SWC,SWC_DATE,20080731 -US-Var,21754,GRP_SWC,SWC,12.3 -US-Var,21754,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.799137867 -US-Var,21754,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21754,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21754,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21754,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21754,GRP_SWC,SWC_DATE,20110510 -US-Var,21570,GRP_SWC,SWC,12.325 -US-Var,21570,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.74246212025 -US-Var,21570,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21570,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21570,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21570,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21570,GRP_SWC,SWC_DATE,20080806 -US-Var,21578,GRP_SWC,SWC,12.325 -US-Var,21578,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.74246212025 -US-Var,21578,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21578,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21578,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21578,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21578,GRP_SWC,SWC_DATE,20080919 -US-Var,21959,GRP_SWC,SWC,12.325 -US-Var,21959,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.4800289661 -US-Var,21959,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21959,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21959,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21959,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21959,GRP_SWC,SWC_DATE,20140107 -US-Var,21758,GRP_SWC,SWC,12.341666667 -US-Var,21758,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.4051122522 -US-Var,21758,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21758,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21758,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21758,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21758,GRP_SWC,SWC_DATE,20110527 -US-Var,21470,GRP_SWC,SWC,12.383333333 -US-Var,21470,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.49497474683 -US-Var,21470,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21470,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21470,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21470,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21470,GRP_SWC,SWC_DATE,20060608 -US-Var,21574,GRP_SWC,SWC,12.4 -US-Var,21574,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.28284271247 -US-Var,21574,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21574,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21574,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21574,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21574,GRP_SWC,SWC_DATE,20080904 -US-Var,21981,GRP_SWC,SWC,12.4875 -US-Var,21981,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.4665681287 -US-Var,21981,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21981,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21981,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21981,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21981,GRP_SWC,SWC_DATE,20140422 -US-Var,21239,GRP_SWC,SWC,12.533333333 -US-Var,21239,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.6398653164 -US-Var,21239,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21239,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21239,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21239,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21239,GRP_SWC,SWC_DATE,20031107 -US-Var,21079,GRP_SWC,SWC,12.55 -US-Var,21079,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.9091883092 -US-Var,21079,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21079,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21079,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21079,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21079,GRP_SWC,SWC_DATE,20020801 -US-Var,21091,GRP_SWC,SWC,12.55 -US-Var,21091,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.3906433363 -US-Var,21091,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21091,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21091,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21091,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21091,GRP_SWC,SWC_DATE,20020829 -US-Var,21113,GRP_SWC,SWC,12.566666667 -US-Var,21113,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.98994949366 -US-Var,21113,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21113,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21113,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21113,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21113,GRP_SWC,SWC_DATE,20021114 -US-Var,21766,GRP_SWC,SWC,12.575 -US-Var,21766,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.7455540914 -US-Var,21766,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21766,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21766,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21766,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21766,GRP_SWC,SWC_DATE,20110706 -US-Var,20996,GRP_SWC,SWC,12.583333333 -US-Var,20996,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.25927248644 -US-Var,20996,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,20996,GRP_SWC,SWC_UNIT,Volumetric -US-Var,20996,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,20996,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,20996,GRP_SWC,SWC_DATE,20011125 -US-Var,21806,GRP_SWC,SWC,12.5875 -US-Var,21806,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.7388115785 -US-Var,21806,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21806,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21806,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21806,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21806,GRP_SWC,SWC_DATE,20120104 -US-Var,21300,GRP_SWC,SWC,12.6 -US-Var,21300,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.14142135624 -US-Var,21300,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21300,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21300,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21300,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21300,GRP_SWC,SWC_DATE,20040506 -US-Var,21304,GRP_SWC,SWC,12.65 -US-Var,21304,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.3435028843 -US-Var,21304,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21304,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21304,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21304,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21304,GRP_SWC,SWC_DATE,20040522 -US-Var,21474,GRP_SWC,SWC,12.666666667 -US-Var,21474,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.2256517541 -US-Var,21474,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21474,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21474,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21474,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21474,GRP_SWC,SWC_DATE,20060801 -US-Var,21720,GRP_SWC,SWC,12.6875 -US-Var,21720,GRP_SWC,SWC_SPATIAL_VARIABILITY,8.9457974305 -US-Var,21720,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21720,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21720,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21720,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21720,GRP_SWC,SWC_DATE,20101112 -US-Var,21770,GRP_SWC,SWC,12.708333333 -US-Var,21770,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.4725274129 -US-Var,21770,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21770,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21770,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21770,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21770,GRP_SWC,SWC_DATE,20110720 -US-Var,21191,GRP_SWC,SWC,12.716666667 -US-Var,21191,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.0876996112 -US-Var,21191,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21191,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21191,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21191,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21191,GRP_SWC,SWC_DATE,20030620 -US-Var,21554,GRP_SWC,SWC,12.716666667 -US-Var,21554,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.58925565099 -US-Var,21554,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21554,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21554,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21554,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21554,GRP_SWC,SWC_DATE,20080531 -US-Var,21963,GRP_SWC,SWC,12.7375 -US-Var,21963,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.7848329628 -US-Var,21963,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21963,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21963,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21963,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21963,GRP_SWC,SWC_DATE,20140124 -US-Var,21199,GRP_SWC,SWC,12.75 -US-Var,21199,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.0034692134 -US-Var,21199,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21199,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21199,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21199,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21199,GRP_SWC,SWC_DATE,20030703 -US-Var,21187,GRP_SWC,SWC,12.783333333 -US-Var,21187,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.8519973508 -US-Var,21187,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21187,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21187,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21187,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21187,GRP_SWC,SWC_DATE,20030613 -US-Var,21215,GRP_SWC,SWC,12.8 -US-Var,21215,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.3234018716 -US-Var,21215,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21215,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21215,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21215,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21215,GRP_SWC,SWC_DATE,20030731 -US-Var,21237,GRP_SWC,SWC,12.8 -US-Var,21237,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.8284271247 -US-Var,21237,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21237,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21237,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21237,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21237,GRP_SWC,SWC_DATE,20031107 -US-Var,21422,GRP_SWC,SWC,12.8 -US-Var,21422,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.49497474683 -US-Var,21422,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21422,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21422,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21422,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21422,GRP_SWC,SWC_DATE,20051029 -US-Var,21697,GRP_SWC,SWC,12.85 -US-Var,21697,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.070710678119 -US-Var,21697,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21697,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21697,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21697,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21697,GRP_SWC,SWC_DATE,20100610 -US-Var,21761,GRP_SWC,SWC,12.85 -US-Var,21761,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.2790657479 -US-Var,21761,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21761,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21761,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21761,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21761,GRP_SWC,SWC_DATE,20110615 -US-Var,21324,GRP_SWC,SWC,12.866666667 -US-Var,21324,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.0370899457 -US-Var,21324,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21324,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21324,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21324,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21324,GRP_SWC,SWC_DATE,20040817 -US-Var,21203,GRP_SWC,SWC,12.9 -US-Var,21203,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.7341462206 -US-Var,21203,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21203,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21203,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21203,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21203,GRP_SWC,SWC_DATE,20030711 -US-Var,21320,GRP_SWC,SWC,12.9 -US-Var,21320,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.84852813742 -US-Var,21320,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21320,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21320,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21320,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21320,GRP_SWC,SWC_DATE,20040805 -US-Var,21223,GRP_SWC,SWC,12.916666667 -US-Var,21223,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.1819805153 -US-Var,21223,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21223,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21223,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21223,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21223,GRP_SWC,SWC_DATE,20030816 -US-Var,21951,GRP_SWC,SWC,12.9375 -US-Var,21951,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.7625654649 -US-Var,21951,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21951,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21951,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21951,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21951,GRP_SWC,SWC_DATE,20131127 -US-Var,21211,GRP_SWC,SWC,12.95 -US-Var,21211,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.7577164466 -US-Var,21211,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21211,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21211,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21211,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21211,GRP_SWC,SWC_DATE,20030725 -US-Var,21312,GRP_SWC,SWC,12.983333333 -US-Var,21312,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.070710678119 -US-Var,21312,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21312,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21312,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21312,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21312,GRP_SWC,SWC_DATE,20040708 -US-Var,21219,GRP_SWC,SWC,13 -US-Var,21219,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.1684607956 -US-Var,21219,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21219,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21219,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21219,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21219,GRP_SWC,SWC_DATE,20030806 -US-Var,21308,GRP_SWC,SWC,13 -US-Var,21308,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.1313708499 -US-Var,21308,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21308,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21308,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21308,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21308,GRP_SWC,SWC_DATE,20040607 -US-Var,21227,GRP_SWC,SWC,13.025 -US-Var,21227,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.5102290732 -US-Var,21227,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21227,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21227,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21227,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21227,GRP_SWC,SWC_DATE,20030905 -US-Var,21802,GRP_SWC,SWC,13.025 -US-Var,21802,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.7065021394 -US-Var,21802,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21802,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21802,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21802,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21802,GRP_SWC,SWC_DATE,20111218 -US-Var,21050,GRP_SWC,SWC,13.05 -US-Var,21050,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.0405591591 -US-Var,21050,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21050,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21050,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21050,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21050,GRP_SWC,SWC_DATE,20020530 -US-Var,21207,GRP_SWC,SWC,13.05 -US-Var,21207,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.6162950904 -US-Var,21207,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21207,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21207,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21207,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21207,GRP_SWC,SWC_DATE,20030717 -US-Var,21332,GRP_SWC,SWC,13.1 -US-Var,21332,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21332,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21332,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21332,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21332,GRP_SWC,SWC_DATE,20040921 -US-Var,21947,GRP_SWC,SWC,13.1 -US-Var,21947,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.0049982156 -US-Var,21947,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21947,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21947,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21947,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21947,GRP_SWC,SWC_DATE,20131107 -US-Var,21418,GRP_SWC,SWC,13.125 -US-Var,21418,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.9545941546 -US-Var,21418,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21418,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21418,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21418,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21418,GRP_SWC,SWC_DATE,20050925 -US-Var,21478,GRP_SWC,SWC,13.125 -US-Var,21478,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.60104076401 -US-Var,21478,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21478,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21478,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21478,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21478,GRP_SWC,SWC_DATE,20061104 -US-Var,21399,GRP_SWC,SWC,13.15 -US-Var,21399,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21399,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21399,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21399,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21399,GRP_SWC,SWC_DATE,20050610 -US-Var,21403,GRP_SWC,SWC,13.154166667 -US-Var,21403,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.45372685126 -US-Var,21403,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21403,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21403,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21403,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21403,GRP_SWC,SWC_DATE,20050623 -US-Var,21043,GRP_SWC,SWC,13.183333333 -US-Var,21043,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.0876996112 -US-Var,21043,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21043,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21043,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21043,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21043,GRP_SWC,SWC_DATE,20020509 -US-Var,21195,GRP_SWC,SWC,13.183333333 -US-Var,21195,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.8048568987 -US-Var,21195,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21195,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21195,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21195,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21195,GRP_SWC,SWC_DATE,20030627 -US-Var,21235,GRP_SWC,SWC,13.183333333 -US-Var,21235,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.6634355425 -US-Var,21235,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21235,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21235,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21235,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21235,GRP_SWC,SWC_DATE,20031024 -US-Var,21972,GRP_SWC,SWC,13.1875 -US-Var,21972,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.6419594247 -US-Var,21972,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21972,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21972,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21972,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21972,GRP_SWC,SWC_DATE,20140318 -US-Var,21328,GRP_SWC,SWC,13.2 -US-Var,21328,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.70710678119 -US-Var,21328,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21328,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21328,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21328,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21328,GRP_SWC,SWC_DATE,20040908 -US-Var,21407,GRP_SWC,SWC,13.2 -US-Var,21407,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.84852813742 -US-Var,21407,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21407,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21407,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21407,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21407,GRP_SWC,SWC_DATE,20050706 -US-Var,21662,GRP_SWC,SWC,13.225 -US-Var,21662,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.67175144213 -US-Var,21662,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21662,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21662,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21662,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21662,GRP_SWC,SWC_DATE,20091129 -US-Var,21414,GRP_SWC,SWC,13.266666667 -US-Var,21414,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.75424723327 -US-Var,21414,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21414,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21414,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21414,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21414,GRP_SWC,SWC_DATE,20050910 -US-Var,21231,GRP_SWC,SWC,13.283333333 -US-Var,21231,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.8048568987 -US-Var,21231,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21231,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21231,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21231,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21231,GRP_SWC,SWC_DATE,20031002 -US-Var,21183,GRP_SWC,SWC,13.3 -US-Var,21183,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.8755675768 -US-Var,21183,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21183,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21183,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21183,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21183,GRP_SWC,SWC_DATE,20030606 -US-Var,21608,GRP_SWC,SWC,13.325 -US-Var,21608,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.0960155108 -US-Var,21608,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21608,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21608,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21608,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21608,GRP_SWC,SWC_DATE,20090327 -US-Var,21902,GRP_SWC,SWC,13.325 -US-Var,21902,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.7354162084 -US-Var,21902,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21902,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21902,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21902,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21902,GRP_SWC,SWC_DATE,20130327 -US-Var,21915,GRP_SWC,SWC,13.3625 -US-Var,21915,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.0541211359 -US-Var,21915,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21915,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21915,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21915,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21915,GRP_SWC,SWC_DATE,20130508 -US-Var,21482,GRP_SWC,SWC,13.425 -US-Var,21482,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.3788582233 -US-Var,21482,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21482,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21482,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21482,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21482,GRP_SWC,SWC_DATE,20061119 -US-Var,21410,GRP_SWC,SWC,13.433333333 -US-Var,21410,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.61282587703 -US-Var,21410,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21410,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21410,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21410,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21410,GRP_SWC,SWC_DATE,20050819 -US-Var,21508,GRP_SWC,SWC,13.5 -US-Var,21508,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.2727922061 -US-Var,21508,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21508,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21508,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21508,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21508,GRP_SWC,SWC_DATE,20070328 -US-Var,21424,GRP_SWC,SWC,13.516666667 -US-Var,21424,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.2360593941 -US-Var,21424,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21424,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21424,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21424,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21424,GRP_SWC,SWC_DATE,20051213 -US-Var,21241,GRP_SWC,SWC,13.529166667 -US-Var,21241,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.13552879973 -US-Var,21241,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21241,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21241,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21241,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21241,GRP_SWC,SWC_DATE,20031110 -US-Var,21919,GRP_SWC,SWC,13.5625 -US-Var,21919,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.0187101142 -US-Var,21919,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21919,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21919,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21919,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21919,GRP_SWC,SWC_DATE,20130530 -US-Var,21952,GRP_SWC,SWC,13.5875 -US-Var,21952,GRP_SWC,SWC_SPATIAL_VARIABILITY,11.139073495 -US-Var,21952,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21952,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21952,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21952,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21952,GRP_SWC,SWC_DATE,20131217 -US-Var,21523,GRP_SWC,SWC,13.6 -US-Var,21523,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.2627416998 -US-Var,21523,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21523,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21523,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21523,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21523,GRP_SWC,SWC_DATE,20070531 -US-Var,21798,GRP_SWC,SWC,13.6625 -US-Var,21798,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.3589012416 -US-Var,21798,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21798,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21798,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21798,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21798,GRP_SWC,SWC_DATE,20111201 -US-Var,21531,GRP_SWC,SWC,13.675 -US-Var,21531,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.2980970389 -US-Var,21531,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21531,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21531,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21531,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21531,GRP_SWC,SWC_DATE,20071107 -US-Var,21923,GRP_SWC,SWC,13.7625 -US-Var,21923,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.6747828417 -US-Var,21923,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21923,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21923,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21923,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21923,GRP_SWC,SWC_DATE,20130619 -US-Var,21484,GRP_SWC,SWC,13.775 -US-Var,21484,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.0658639918 -US-Var,21484,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21484,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21484,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21484,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21484,GRP_SWC,SWC_DATE,20061226 -US-Var,21794,GRP_SWC,SWC,13.8 -US-Var,21794,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.5659475072 -US-Var,21794,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21794,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21794,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21794,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21794,GRP_SWC,SWC_DATE,20111109 -US-Var,21939,GRP_SWC,SWC,13.8125 -US-Var,21939,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.9792830714 -US-Var,21939,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21939,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21939,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21939,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21939,GRP_SWC,SWC_DATE,20130904 -US-Var,21762,GRP_SWC,SWC,13.8375 -US-Var,21762,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.6852293653 -US-Var,21762,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21762,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21762,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21762,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21762,GRP_SWC,SWC_DATE,20110615 -US-Var,21635,GRP_SWC,SWC,13.9 -US-Var,21635,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.3840620434 -US-Var,21635,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21635,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21635,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21635,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21635,GRP_SWC,SWC_DATE,20090621 -US-Var,21931,GRP_SWC,SWC,13.95 -US-Var,21931,GRP_SWC,SWC_SPATIAL_VARIABILITY,8.0802227692 -US-Var,21931,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21931,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21931,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21931,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21931,GRP_SWC,SWC_DATE,20130728 -US-Var,21927,GRP_SWC,SWC,14 -US-Var,21927,GRP_SWC,SWC_SPATIAL_VARIABILITY,8.0472562612 -US-Var,21927,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21927,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21927,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21927,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21927,GRP_SWC,SWC_DATE,20130711 -US-Var,21976,GRP_SWC,SWC,14.075 -US-Var,21976,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.3245591449 -US-Var,21976,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21976,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21976,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21976,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21976,GRP_SWC,SWC_DATE,20140408 -US-Var,22023,GRP_SWC,SWC,14.15 -US-Var,22023,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.1299836372 -US-Var,22023,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,22023,GRP_SWC,SWC_UNIT,Volumetric -US-Var,22023,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,22023,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,22023,GRP_SWC,SWC_DATE,20141113 -US-Var,21039,GRP_SWC,SWC,14.265 -US-Var,21039,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.1708178182 -US-Var,21039,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21039,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21039,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21039,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21039,GRP_SWC,SWC_DATE,20020502 -US-Var,21797,GRP_SWC,SWC,14.3125 -US-Var,21797,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.2790687194 -US-Var,21797,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21797,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21797,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21797,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21797,GRP_SWC,SWC_DATE,20111201 -US-Var,21990,GRP_SWC,SWC,14.375 -US-Var,21990,GRP_SWC,SWC_SPATIAL_VARIABILITY,11.71960608 -US-Var,21990,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21990,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21990,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21990,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21990,GRP_SWC,SWC_DATE,20140611 -US-Var,21943,GRP_SWC,SWC,14.470833333 -US-Var,21943,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.1021172508 -US-Var,21943,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21943,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21943,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21943,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21943,GRP_SWC,SWC_DATE,20130925 -US-Var,21428,GRP_SWC,SWC,14.533333333 -US-Var,21428,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.8554665641 -US-Var,21428,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21428,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21428,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21428,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21428,GRP_SWC,SWC_DATE,20051229 -US-Var,21661,GRP_SWC,SWC,14.55 -US-Var,21661,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.767766953 -US-Var,21661,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21661,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21661,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21661,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21661,GRP_SWC,SWC_DATE,20091129 -US-Var,21789,GRP_SWC,SWC,14.55 -US-Var,21789,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.4114077035 -US-Var,21789,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21789,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21789,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21789,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21789,GRP_SWC,SWC_DATE,20111026 -US-Var,21698,GRP_SWC,SWC,14.566666667 -US-Var,21698,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.0641293851 -US-Var,21698,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21698,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21698,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21698,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21698,GRP_SWC,SWC_DATE,20100610 -US-Var,21888,GRP_SWC,SWC,14.625 -US-Var,21888,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.4311842932 -US-Var,21888,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21888,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21888,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21888,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21888,GRP_SWC,SWC_DATE,20130206 -US-Var,21316,GRP_SWC,SWC,14.675 -US-Var,21316,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.6617009358 -US-Var,21316,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21316,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21316,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21316,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21316,GRP_SWC,SWC_DATE,20040721 -US-Var,21030,GRP_SWC,SWC,14.716666667 -US-Var,21030,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.0876996112 -US-Var,21030,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21030,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21030,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21030,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21030,GRP_SWC,SWC_DATE,20020418 -US-Var,21897,GRP_SWC,SWC,14.775 -US-Var,21897,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.6087778568 -US-Var,21897,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21897,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21897,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21897,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21897,GRP_SWC,SWC_DATE,20130313 -US-Var,21954,GRP_SWC,SWC,14.779166667 -US-Var,21954,GRP_SWC,SWC_SPATIAL_VARIABILITY,11.299634335 -US-Var,21954,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21954,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21954,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21954,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21954,GRP_SWC,SWC_DATE,20131217 -US-Var,21935,GRP_SWC,SWC,14.7875 -US-Var,21935,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.4829110868 -US-Var,21935,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21935,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21935,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21935,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21935,GRP_SWC,SWC_DATE,20130813 -US-Var,21504,GRP_SWC,SWC,14.8 -US-Var,21504,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.70710678119 -US-Var,21504,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21504,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21504,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21504,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21504,GRP_SWC,SWC_DATE,20070316 -US-Var,22019,GRP_SWC,SWC,14.8125 -US-Var,22019,GRP_SWC,SWC_SPATIAL_VARIABILITY,8.0436698714 -US-Var,22019,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,22019,GRP_SWC,SWC_UNIT,Volumetric -US-Var,22019,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,22019,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,22019,GRP_SWC,SWC_DATE,20141024 -US-Var,21812,GRP_SWC,SWC,14.8375 -US-Var,21812,GRP_SWC,SWC_SPATIAL_VARIABILITY,11.330811607 -US-Var,21812,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21812,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21812,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21812,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21812,GRP_SWC,SWC_DATE,20120201 -US-Var,21995,GRP_SWC,SWC,14.9875 -US-Var,21995,GRP_SWC,SWC_SPATIAL_VARIABILITY,8.2828512603 -US-Var,21995,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21995,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21995,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21995,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21995,GRP_SWC,SWC_DATE,20140625 -US-Var,21513,GRP_SWC,SWC,15 -US-Var,21513,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.4648232278 -US-Var,21513,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21513,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21513,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21513,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21513,GRP_SWC,SWC_DATE,20070405 -US-Var,21243,GRP_SWC,SWC,15.058333333 -US-Var,21243,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.55390031193 -US-Var,21243,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21243,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21243,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21243,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21243,GRP_SWC,SWC_DATE,20031110 -US-Var,21119,GRP_SWC,SWC,15.075 -US-Var,21119,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.2273863607 -US-Var,21119,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21119,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21119,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21119,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21119,GRP_SWC,SWC_DATE,20021206 -US-Var,21535,GRP_SWC,SWC,15.083333333 -US-Var,21535,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.30641293851 -US-Var,21535,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21535,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21535,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21535,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21535,GRP_SWC,SWC_DATE,20071129 -US-Var,22007,GRP_SWC,SWC,15.125 -US-Var,22007,GRP_SWC,SWC_SPATIAL_VARIABILITY,9.3131179884 -US-Var,22007,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,22007,GRP_SWC,SWC_UNIT,Volumetric -US-Var,22007,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,22007,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,22007,GRP_SWC,SWC_DATE,20140821 -US-Var,21481,GRP_SWC,SWC,15.15 -US-Var,21481,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.1920310217 -US-Var,21481,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21481,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21481,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21481,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21481,GRP_SWC,SWC_DATE,20061119 -US-Var,22015,GRP_SWC,SWC,15.2375 -US-Var,22015,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.5726894166 -US-Var,22015,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,22015,GRP_SWC,SWC_UNIT,Volumetric -US-Var,22015,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,22015,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,22015,GRP_SWC,SWC_DATE,20140930 -US-Var,21911,GRP_SWC,SWC,15.25 -US-Var,21911,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.2474133317 -US-Var,21911,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21911,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21911,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21911,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21911,GRP_SWC,SWC_DATE,20130424 -US-Var,20989,GRP_SWC,SWC,15.283333333 -US-Var,20989,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.9563287613 -US-Var,20989,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,20989,GRP_SWC,SWC_UNIT,Volumetric -US-Var,20989,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,20989,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,20989,GRP_SWC,SWC_DATE,20011113 -US-Var,21357,GRP_SWC,SWC,15.316666667 -US-Var,21357,GRP_SWC,SWC_SPATIAL_VARIABILITY,9.6873629023 -US-Var,21357,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21357,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21357,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21357,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21357,GRP_SWC,SWC_DATE,20041226 -US-Var,21425,GRP_SWC,SWC,15.316666667 -US-Var,21425,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.6634355425 -US-Var,21425,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21425,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21425,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21425,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21425,GRP_SWC,SWC_DATE,20051213 -US-Var,21518,GRP_SWC,SWC,15.316666667 -US-Var,21518,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.9091883092 -US-Var,21518,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21518,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21518,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21518,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21518,GRP_SWC,SWC_DATE,20070501 -US-Var,21179,GRP_SWC,SWC,15.333333333 -US-Var,21179,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.6870057685 -US-Var,21179,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21179,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21179,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21179,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21179,GRP_SWC,SWC_DATE,20030530 -US-Var,21714,GRP_SWC,SWC,15.333333333 -US-Var,21714,GRP_SWC,SWC_SPATIAL_REP_NUMBER,1 -US-Var,21714,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21714,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21714,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21714,GRP_SWC,SWC_DATE,20101007 -US-Var,21296,GRP_SWC,SWC,15.375 -US-Var,21296,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.0960155108 -US-Var,21296,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21296,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21296,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21296,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21296,GRP_SWC,SWC_DATE,20040423 -US-Var,21875,GRP_SWC,SWC,15.375 -US-Var,21875,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.5346016343 -US-Var,21875,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21875,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21875,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21875,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21875,GRP_SWC,SWC_DATE,20121107 -US-Var,21550,GRP_SWC,SWC,15.425 -US-Var,21550,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.10606601718 -US-Var,21550,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21550,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21550,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21550,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21550,GRP_SWC,SWC_DATE,20080506 -US-Var,21291,GRP_SWC,SWC,15.433333333 -US-Var,21291,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.98994949366 -US-Var,21291,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21291,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21291,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21291,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21291,GRP_SWC,SWC_DATE,20040409 -US-Var,21790,GRP_SWC,SWC,15.441666667 -US-Var,21790,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.9871509056 -US-Var,21790,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21790,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21790,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21790,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21790,GRP_SWC,SWC_DATE,20111026 -US-Var,21337,GRP_SWC,SWC,15.45 -US-Var,21337,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.2932503526 -US-Var,21337,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21337,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21337,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21337,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21337,GRP_SWC,SWC_DATE,20041103 -US-Var,21999,GRP_SWC,SWC,15.4875 -US-Var,21999,GRP_SWC,SWC_SPATIAL_VARIABILITY,8.2853661154 -US-Var,21999,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21999,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21999,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21999,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21999,GRP_SWC,SWC_DATE,20140709 -US-Var,22011,GRP_SWC,SWC,15.5375 -US-Var,22011,GRP_SWC,SWC_SPATIAL_VARIABILITY,8.475 -US-Var,22011,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,22011,GRP_SWC,SWC_UNIT,Volumetric -US-Var,22011,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,22011,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,22011,GRP_SWC,SWC_DATE,20140911 -US-Var,21456,GRP_SWC,SWC,15.583333333 -US-Var,21456,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.3403908046 -US-Var,21456,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21456,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21456,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21456,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21456,GRP_SWC,SWC_DATE,20060418 -US-Var,20993,GRP_SWC,SWC,15.7 -US-Var,20993,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.1313708499 -US-Var,20993,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,20993,GRP_SWC,SWC_UNIT,Volumetric -US-Var,20993,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,20993,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,20993,GRP_SWC,SWC_DATE,20011125 -US-Var,21871,GRP_SWC,SWC,15.7 -US-Var,21871,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.8254425986 -US-Var,21871,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21871,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21871,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21871,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21871,GRP_SWC,SWC_DATE,20121024 -US-Var,21035,GRP_SWC,SWC,15.75 -US-Var,21035,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.7577164466 -US-Var,21035,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21035,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21035,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21035,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21035,GRP_SWC,SWC_DATE,20020426 -US-Var,21527,GRP_SWC,SWC,15.775 -US-Var,21527,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.38890872965 -US-Var,21527,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21527,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21527,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21527,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21527,GRP_SWC,SWC_DATE,20070623 -US-Var,20990,GRP_SWC,SWC,15.783333333 -US-Var,20990,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.1618795027 -US-Var,20990,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,20990,GRP_SWC,SWC_UNIT,Volumetric -US-Var,20990,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,20990,GRP_SWC,SWC_PROFILE_MAX,30 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-US-Var,21621,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21621,GRP_SWC,SWC_DATE,20090507 -US-Var,21622,GRP_SWC,SWC,15.95 -US-Var,21622,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.3334523779 -US-Var,21622,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21622,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21622,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21622,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21622,GRP_SWC,SWC_DATE,20090507 -US-Var,21021,GRP_SWC,SWC,15.975 -US-Var,21021,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.31819805153 -US-Var,21021,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21021,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21021,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21021,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21021,GRP_SWC,SWC_DATE,20020404 -US-Var,21174,GRP_SWC,SWC,16.1125 -US-Var,21174,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.300520382 -US-Var,21174,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21174,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21174,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21174,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21174,GRP_SWC,SWC_DATE,20030521 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-US-Var,21843,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21843,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21843,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21843,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21843,GRP_SWC,SWC_DATE,20120530 -US-Var,21847,GRP_SWC,SWC,16.25 -US-Var,21847,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.8510339852 -US-Var,21847,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21847,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21847,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21847,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21847,GRP_SWC,SWC_DATE,20120704 -US-Var,21898,GRP_SWC,SWC,16.3375 -US-Var,21898,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.968463042 -US-Var,21898,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21898,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21898,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21898,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21898,GRP_SWC,SWC_DATE,20130313 -US-Var,21987,GRP_SWC,SWC,16.3625 -US-Var,21987,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.8491331568 -US-Var,21987,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21987,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21987,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21987,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21987,GRP_SWC,SWC_DATE,20140522 -US-Var,22003,GRP_SWC,SWC,16.375 -US-Var,22003,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.8593362739 -US-Var,22003,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,22003,GRP_SWC,SWC_UNIT,Volumetric -US-Var,22003,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,22003,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,22003,GRP_SWC,SWC_DATE,20140805 -US-Var,21583,GRP_SWC,SWC,16.411666667 -US-Var,21583,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.0746696663 -US-Var,21583,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21583,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21583,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21583,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21583,GRP_SWC,SWC_DATE,20081030 -US-Var,21427,GRP_SWC,SWC,16.416666667 -US-Var,21427,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.68353655515 -US-Var,21427,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21427,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21427,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21427,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21427,GRP_SWC,SWC_DATE,20051213 -US-Var,21706,GRP_SWC,SWC,16.5 -US-Var,21706,GRP_SWC,SWC_SPATIAL_REP_NUMBER,1 -US-Var,21706,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21706,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21706,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21706,GRP_SWC,SWC_DATE,20100814 -US-Var,21859,GRP_SWC,SWC,16.55 -US-Var,21859,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.6808202687 -US-Var,21859,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21859,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21859,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21859,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21859,GRP_SWC,SWC_DATE,20120905 -US-Var,21811,GRP_SWC,SWC,16.6125 -US-Var,21811,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.2237311458 -US-Var,21811,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21811,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21811,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21811,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21811,GRP_SWC,SWC_DATE,20120118 -US-Var,21851,GRP_SWC,SWC,16.65 -US-Var,21851,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.5544688761 -US-Var,21851,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21851,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21851,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21851,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21851,GRP_SWC,SWC_DATE,20120725 -US-Var,21855,GRP_SWC,SWC,16.6875 -US-Var,21855,GRP_SWC,SWC_SPATIAL_VARIABILITY,8.0315393917 -US-Var,21855,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21855,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21855,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21855,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21855,GRP_SWC,SWC_DATE,20120822 -US-Var,21052,GRP_SWC,SWC,16.7 -US-Var,21052,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.5084944665 -US-Var,21052,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21052,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21052,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21052,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21052,GRP_SWC,SWC_DATE,20020530 -US-Var,21593,GRP_SWC,SWC,16.75 -US-Var,21593,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.8991378029 -US-Var,21593,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21593,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21593,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21593,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21593,GRP_SWC,SWC_DATE,20081211 -US-Var,21594,GRP_SWC,SWC,16.75 -US-Var,21594,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.38059283 -US-Var,21594,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21594,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21594,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21594,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21594,GRP_SWC,SWC_DATE,20081211 -US-Var,21863,GRP_SWC,SWC,16.75 -US-Var,21863,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.5519313203 -US-Var,21863,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21863,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21863,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21863,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21863,GRP_SWC,SWC_DATE,20120919 -US-Var,21867,GRP_SWC,SWC,16.75 -US-Var,21867,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.5519313203 -US-Var,21867,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21867,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21867,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21867,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21867,GRP_SWC,SWC_DATE,20121009 -US-Var,21419,GRP_SWC,SWC,16.775 -US-Var,21419,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.67175144213 -US-Var,21419,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21419,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21419,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21419,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21419,GRP_SWC,SWC_DATE,20050925 -US-Var,21693,GRP_SWC,SWC,16.775 -US-Var,21693,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.9545941546 -US-Var,21693,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21693,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21693,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21693,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21693,GRP_SWC,SWC_DATE,20100528 -US-Var,21112,GRP_SWC,SWC,16.783333333 -US-Var,21112,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.1078006239 -US-Var,21112,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21112,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21112,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21112,GRP_SWC,SWC_PROFILE_MAX,60 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-US-Var,21736,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21736,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21736,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21736,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21736,GRP_SWC,SWC_DATE,20110222 -US-Var,21415,GRP_SWC,SWC,17.016666667 -US-Var,21415,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.54211519891 -US-Var,21415,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21415,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21415,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21415,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21415,GRP_SWC,SWC_DATE,20050910 -US-Var,21684,GRP_SWC,SWC,17.075 -US-Var,21684,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.1871843354 -US-Var,21684,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21684,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21684,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21684,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21684,GRP_SWC,SWC_DATE,20100402 -US-Var,21803,GRP_SWC,SWC,17.1125 -US-Var,21803,GRP_SWC,SWC_SPATIAL_VARIABILITY,8.0864469948 -US-Var,21803,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21803,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21803,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21803,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21803,GRP_SWC,SWC_DATE,20111218 -US-Var,21056,GRP_SWC,SWC,17.133333333 -US-Var,21056,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.61282587703 -US-Var,21056,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21056,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21056,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21056,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21056,GRP_SWC,SWC_DATE,20020613 -US-Var,21655,GRP_SWC,SWC,17.2 -US-Var,21655,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.4142135624 -US-Var,21655,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21655,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21655,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21655,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21655,GRP_SWC,SWC_DATE,20091022 -US-Var,21783,GRP_SWC,SWC,17.208333333 -US-Var,21783,GRP_SWC,SWC_SPATIAL_VARIABILITY,9.3686781154 -US-Var,21783,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21783,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21783,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21783,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21783,GRP_SWC,SWC_DATE,20110929 -US-Var,21833,GRP_SWC,SWC,17.233333333 -US-Var,21833,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.9454464368 -US-Var,21833,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21833,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21833,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21833,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21833,GRP_SWC,SWC_DATE,20120504 -US-Var,21627,GRP_SWC,SWC,17.275 -US-Var,21627,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.88388347648 -US-Var,21627,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21627,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21627,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21627,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21627,GRP_SWC,SWC_DATE,20090527 -US-Var,21123,GRP_SWC,SWC,17.325 -US-Var,21123,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.5202795796 -US-Var,21123,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21123,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21123,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21123,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21123,GRP_SWC,SWC_DATE,20021214 -US-Var,21955,GRP_SWC,SWC,17.366666667 -US-Var,21955,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.756323585 -US-Var,21955,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21955,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21955,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21955,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21955,GRP_SWC,SWC_DATE,20131217 -US-Var,21251,GRP_SWC,SWC,17.383333333 -US-Var,21251,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.8620478571 -US-Var,21251,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21251,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21251,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21251,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21251,GRP_SWC,SWC_DATE,20031206 -US-Var,21247,GRP_SWC,SWC,17.391666667 -US-Var,21247,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.6381307097 -US-Var,21247,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21247,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21247,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21247,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21247,GRP_SWC,SWC_DATE,20031119 -US-Var,21060,GRP_SWC,SWC,17.45 -US-Var,21060,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.1549410759 -US-Var,21060,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21060,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21060,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21060,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21060,GRP_SWC,SWC_DATE,20020620 -US-Var,21411,GRP_SWC,SWC,17.45 -US-Var,21411,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.82495791138 -US-Var,21411,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21411,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21411,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21411,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21411,GRP_SWC,SWC_DATE,20050819 -US-Var,21408,GRP_SWC,SWC,17.525 -US-Var,21408,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.9545941546 -US-Var,21408,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21408,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21408,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21408,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21408,GRP_SWC,SWC_DATE,20050706 -US-Var,21767,GRP_SWC,SWC,17.6125 -US-Var,21767,GRP_SWC,SWC_SPATIAL_VARIABILITY,10.437302892 -US-Var,21767,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21767,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21767,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21767,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21767,GRP_SWC,SWC_DATE,20110706 -US-Var,21479,GRP_SWC,SWC,17.65 -US-Var,21479,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.6263455967 -US-Var,21479,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21479,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21479,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21479,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21479,GRP_SWC,SWC_DATE,20061104 -US-Var,21555,GRP_SWC,SWC,17.65 -US-Var,21555,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.49497474683 -US-Var,21555,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21555,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21555,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21555,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21555,GRP_SWC,SWC_DATE,20080531 -US-Var,21659,GRP_SWC,SWC,17.65 -US-Var,21659,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.202081528 -US-Var,21659,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21659,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21659,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21659,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21659,GRP_SWC,SWC_DATE,20091105 -US-Var,21108,GRP_SWC,SWC,17.666666667 -US-Var,21108,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.80138768534 -US-Var,21108,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21108,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21108,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21108,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21108,GRP_SWC,SWC_DATE,20021002 -US-Var,21799,GRP_SWC,SWC,17.6875 -US-Var,21799,GRP_SWC,SWC_SPATIAL_VARIABILITY,8.8526243755 -US-Var,21799,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21799,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21799,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21799,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21799,GRP_SWC,SWC_DATE,20111201 -US-Var,21064,GRP_SWC,SWC,17.7 -US-Var,21064,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.3670731103 -US-Var,21064,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21064,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21064,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21064,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21064,GRP_SWC,SWC_DATE,20020628 -US-Var,21044,GRP_SWC,SWC,17.716666667 -US-Var,21044,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.7206265009 -US-Var,21044,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21044,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21044,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21044,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21044,GRP_SWC,SWC_DATE,20020509 -US-Var,21240,GRP_SWC,SWC,17.808333333 -US-Var,21240,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.48318963381 -US-Var,21240,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21240,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21240,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21240,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21240,GRP_SWC,SWC_DATE,20031107 -US-Var,21795,GRP_SWC,SWC,17.8125 -US-Var,21795,GRP_SWC,SWC_SPATIAL_VARIABILITY,8.834154836 -US-Var,21795,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21795,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21795,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21795,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21795,GRP_SWC,SWC_DATE,20111109 -US-Var,21116,GRP_SWC,SWC,17.883333333 -US-Var,21116,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.070710678119 -US-Var,21116,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21116,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21116,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21116,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21116,GRP_SWC,SWC_DATE,20021114 -US-Var,21771,GRP_SWC,SWC,17.9 -US-Var,21771,GRP_SWC,SWC_SPATIAL_VARIABILITY,9.8877028003 -US-Var,21771,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21771,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21771,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21771,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21771,GRP_SWC,SWC_DATE,20110720 -US-Var,21763,GRP_SWC,SWC,17.95 -US-Var,21763,GRP_SWC,SWC_SPATIAL_VARIABILITY,9.8470807857 -US-Var,21763,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21763,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21763,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21763,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21763,GRP_SWC,SWC_DATE,20110615 -US-Var,21031,GRP_SWC,SWC,17.966666667 -US-Var,21031,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.2156012477 -US-Var,21031,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21031,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21031,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21031,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21031,GRP_SWC,SWC_DATE,20020418 -US-Var,21546,GRP_SWC,SWC,17.966666667 -US-Var,21546,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.51854497287 -US-Var,21546,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21546,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21546,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21546,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21546,GRP_SWC,SWC_DATE,20080420 -US-Var,21779,GRP_SWC,SWC,17.983333333 -US-Var,21779,GRP_SWC,SWC_SPATIAL_VARIABILITY,9.6682182663 -US-Var,21779,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21779,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21779,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21779,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21779,GRP_SWC,SWC_DATE,20110916 -US-Var,21492,GRP_SWC,SWC,18.025 -US-Var,21492,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.4294678888 -US-Var,21492,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21492,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21492,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21492,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21492,GRP_SWC,SWC_DATE,20070119 -US-Var,21828,GRP_SWC,SWC,18.0375 -US-Var,21828,GRP_SWC,SWC_SPATIAL_VARIABILITY,13.426489675 -US-Var,21828,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21828,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21828,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21828,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21828,GRP_SWC,SWC_DATE,20120405 -US-Var,21639,GRP_SWC,SWC,18.05 -US-Var,21639,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.4849242405 -US-Var,21639,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21639,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21639,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21639,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21639,GRP_SWC,SWC_DATE,20090705 -US-Var,21775,GRP_SWC,SWC,18.183333333 -US-Var,21775,GRP_SWC,SWC_SPATIAL_VARIABILITY,9.7573713825 -US-Var,21775,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21775,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21775,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21775,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21775,GRP_SWC,SWC_DATE,20110831 -US-Var,21907,GRP_SWC,SWC,18.1875 -US-Var,21907,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.818394443 -US-Var,21907,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21907,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21907,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21907,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21907,GRP_SWC,SWC_DATE,20130410 -US-Var,21755,GRP_SWC,SWC,18.2 -US-Var,21755,GRP_SWC,SWC_SPATIAL_VARIABILITY,8.7904304028 -US-Var,21755,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21755,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21755,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21755,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21755,GRP_SWC,SWC_DATE,20110510 -US-Var,21475,GRP_SWC,SWC,18.333333333 -US-Var,21475,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.8856180832 -US-Var,21475,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21475,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21475,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21475,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21475,GRP_SWC,SWC_DATE,20060801 -US-Var,21834,GRP_SWC,SWC,18.341666667 -US-Var,21834,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.9440212726 -US-Var,21834,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21834,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21834,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21834,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21834,GRP_SWC,SWC_DATE,20120504 -US-Var,21820,GRP_SWC,SWC,18.375 -US-Var,21820,GRP_SWC,SWC_SPATIAL_VARIABILITY,15.658517384 -US-Var,21820,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21820,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21820,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21820,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21820,GRP_SWC,SWC_DATE,20120302 -US-Var,21643,GRP_SWC,SWC,18.4 -US-Var,21643,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.1313708499 -US-Var,21643,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21643,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21643,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21643,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21643,GRP_SWC,SWC_DATE,20090802 -US-Var,21824,GRP_SWC,SWC,18.4375 -US-Var,21824,GRP_SWC,SWC_SPATIAL_VARIABILITY,14.063035175 -US-Var,21824,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21824,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21824,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21824,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21824,GRP_SWC,SWC_DATE,20120321 -US-Var,21461,GRP_SWC,SWC,18.45 -US-Var,21461,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.77781745931 -US-Var,21461,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21461,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21461,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21461,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21461,GRP_SWC,SWC_DATE,20060504 -US-Var,21092,GRP_SWC,SWC,18.483333333 -US-Var,21092,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.25927248644 -US-Var,21092,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21092,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21092,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21092,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21092,GRP_SWC,SWC_DATE,20020829 -US-Var,21541,GRP_SWC,SWC,18.5 -US-Var,21541,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.2727922061 -US-Var,21541,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21541,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21541,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21541,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21541,GRP_SWC,SWC_DATE,20080404 -US-Var,21088,GRP_SWC,SWC,18.508333333 -US-Var,21088,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.76603234629 -US-Var,21088,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21088,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21088,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21088,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21088,GRP_SWC,SWC_DATE,20020823 -US-Var,21120,GRP_SWC,SWC,18.525 -US-Var,21120,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.166726189 -US-Var,21120,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21120,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21120,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21120,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21120,GRP_SWC,SWC_DATE,20021206 -US-Var,21744,GRP_SWC,SWC,18.5625 -US-Var,21744,GRP_SWC,SWC_SPATIAL_VARIABILITY,15.081300508 -US-Var,21744,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21744,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21744,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21744,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21744,GRP_SWC,SWC_DATE,20110330 -US-Var,21724,GRP_SWC,SWC,18.566666667 -US-Var,21724,GRP_SWC,SWC_SPATIAL_VARIABILITY,11.620491957 -US-Var,21724,GRP_SWC,SWC_SPATIAL_REP_NUMBER,3 -US-Var,21724,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21724,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21724,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21724,GRP_SWC,SWC_DATE,20101202 -US-Var,21982,GRP_SWC,SWC,18.6375 -US-Var,21982,GRP_SWC,SWC_SPATIAL_VARIABILITY,9.8372061583 -US-Var,21982,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21982,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21982,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21982,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21982,GRP_SWC,SWC_DATE,20140422 -US-Var,21786,GRP_SWC,SWC,18.65 -US-Var,21786,GRP_SWC,SWC_SPATIAL_VARIABILITY,9.2309262807 -US-Var,21786,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21786,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21786,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21786,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21786,GRP_SWC,SWC_DATE,20111013 -US-Var,21244,GRP_SWC,SWC,18.658333333 -US-Var,21244,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.71889189421 -US-Var,21244,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21244,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21244,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21244,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21244,GRP_SWC,SWC_DATE,20031110 -US-Var,21791,GRP_SWC,SWC,18.658333333 -US-Var,21791,GRP_SWC,SWC_SPATIAL_VARIABILITY,8.3790468387 -US-Var,21791,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21791,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21791,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21791,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21791,GRP_SWC,SWC_DATE,20111026 -US-Var,21080,GRP_SWC,SWC,18.666666667 -US-Var,21080,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.61282587703 -US-Var,21080,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21080,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21080,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21080,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21080,GRP_SWC,SWC_DATE,20020801 -US-Var,21740,GRP_SWC,SWC,18.675 -US-Var,21740,GRP_SWC,SWC_SPATIAL_VARIABILITY,15.508549016 -US-Var,21740,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21740,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21740,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21740,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21740,GRP_SWC,SWC_DATE,20110308 -US-Var,21068,GRP_SWC,SWC,18.716666667 -US-Var,21068,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.87209836346 -US-Var,21068,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21068,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21068,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21068,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21068,GRP_SWC,SWC_DATE,20020711 -US-Var,21663,GRP_SWC,SWC,18.75 -US-Var,21663,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.4142135624 -US-Var,21663,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21663,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21663,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21663,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21663,GRP_SWC,SWC_DATE,20091129 -US-Var,21884,GRP_SWC,SWC,18.7625 -US-Var,21884,GRP_SWC,SWC_SPATIAL_VARIABILITY,9.183261494 -US-Var,21884,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21884,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21884,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21884,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21884,GRP_SWC,SWC_DATE,20130116 -US-Var,21076,GRP_SWC,SWC,18.8 -US-Var,21076,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.2727922061 -US-Var,21076,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21076,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21076,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21076,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21076,GRP_SWC,SWC_DATE,20020725 -US-Var,21104,GRP_SWC,SWC,18.8 -US-Var,21104,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.3670731103 -US-Var,21104,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21104,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21104,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21104,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21104,GRP_SWC,SWC_DATE,20020920 -US-Var,21839,GRP_SWC,SWC,18.8125 -US-Var,21839,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.9714464392 -US-Var,21839,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21839,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21839,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21839,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21839,GRP_SWC,SWC_DATE,20120518 -US-Var,21390,GRP_SWC,SWC,18.825 -US-Var,21390,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.368807717 -US-Var,21390,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21390,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21390,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21390,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21390,GRP_SWC,SWC_DATE,20050425 -US-Var,21072,GRP_SWC,SWC,18.85 -US-Var,21072,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.91923881554 -US-Var,21072,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21072,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21072,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21072,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21072,GRP_SWC,SWC_DATE,20020719 -US-Var,21096,GRP_SWC,SWC,18.85 -US-Var,21096,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.58925565099 -US-Var,21096,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21096,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21096,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21096,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21096,GRP_SWC,SWC_DATE,20020905 -US-Var,21651,GRP_SWC,SWC,18.85 -US-Var,21651,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.4849242405 -US-Var,21651,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21651,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21651,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21651,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21651,GRP_SWC,SWC_DATE,20091002 -US-Var,21903,GRP_SWC,SWC,18.8875 -US-Var,21903,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.9381331768 -US-Var,21903,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21903,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21903,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21903,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21903,GRP_SWC,SWC_DATE,20130327 -US-Var,21426,GRP_SWC,SWC,18.933333333 -US-Var,21426,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.28284271247 -US-Var,21426,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21426,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21426,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21426,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21426,GRP_SWC,SWC_DATE,20051213 -US-Var,21084,GRP_SWC,SWC,18.95 -US-Var,21084,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.0606601718 -US-Var,21084,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21084,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21084,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21084,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21084,GRP_SWC,SWC_DATE,20020815 -US-Var,21286,GRP_SWC,SWC,18.95 -US-Var,21286,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21286,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21286,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21286,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21286,GRP_SWC,SWC_DATE,20040325 -US-Var,21514,GRP_SWC,SWC,19 -US-Var,21514,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.5556349186 -US-Var,21514,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21514,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21514,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21514,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21514,GRP_SWC,SWC_DATE,20070405 -US-Var,21876,GRP_SWC,SWC,19 -US-Var,21876,GRP_SWC,SWC_SPATIAL_VARIABILITY,9.9943317269 -US-Var,21876,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21876,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21876,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21876,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21876,GRP_SWC,SWC_DATE,20121211 -US-Var,21100,GRP_SWC,SWC,19.025 -US-Var,21100,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.166726189 -US-Var,21100,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21100,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21100,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21100,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21100,GRP_SWC,SWC_DATE,20020912 -US-Var,21807,GRP_SWC,SWC,19.025 -US-Var,21807,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.0940544796 -US-Var,21807,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21807,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21807,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21807,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21807,GRP_SWC,SWC_DATE,20120104 -US-Var,21281,GRP_SWC,SWC,19.033333333 -US-Var,21281,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.80138768534 -US-Var,21281,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21281,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21281,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21281,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21281,GRP_SWC,SWC_DATE,20040321 -US-Var,21668,GRP_SWC,SWC,19.083333333 -US-Var,21668,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.30641293851 -US-Var,21668,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21668,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21668,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21668,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21668,GRP_SWC,SWC_DATE,20100108 -US-Var,21617,GRP_SWC,SWC,19.15 -US-Var,21617,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.1819805153 -US-Var,21617,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21617,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21617,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21617,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21617,GRP_SWC,SWC_DATE,20090417 -US-Var,21694,GRP_SWC,SWC,19.15 -US-Var,21694,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.7476659403 -US-Var,21694,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21694,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21694,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21694,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21694,GRP_SWC,SWC_DATE,20100528 -US-Var,21893,GRP_SWC,SWC,19.15 -US-Var,21893,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.9372732015 -US-Var,21893,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21893,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21893,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21893,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21893,GRP_SWC,SWC_DATE,20130227 -US-Var,21124,GRP_SWC,SWC,19.2 -US-Var,21124,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.56568542495 -US-Var,21124,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21124,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21124,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21124,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21124,GRP_SWC,SWC_DATE,20021214 -US-Var,21647,GRP_SWC,SWC,19.2 -US-Var,21647,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.4142135624 -US-Var,21647,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21647,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21647,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21647,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21647,GRP_SWC,SWC_DATE,20090907 -US-Var,21175,GRP_SWC,SWC,19.241666667 -US-Var,21175,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.8402122378 -US-Var,21175,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21175,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21175,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21175,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21175,GRP_SWC,SWC_DATE,20030521 -US-Var,21519,GRP_SWC,SWC,19.283333333 -US-Var,21519,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.4176827757 -US-Var,21519,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21519,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21519,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21519,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21519,GRP_SWC,SWC_DATE,20070501 -US-Var,21721,GRP_SWC,SWC,19.3125 -US-Var,21721,GRP_SWC,SWC_SPATIAL_VARIABILITY,10.069456705 -US-Var,21721,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21721,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21721,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21721,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21721,GRP_SWC,SWC_DATE,20101112 -US-Var,21026,GRP_SWC,SWC,19.35 -US-Var,21026,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.4748737342 -US-Var,21026,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21026,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21026,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21026,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21026,GRP_SWC,SWC_DATE,20020411 -US-Var,21236,GRP_SWC,SWC,19.35 -US-Var,21236,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.35355339059 -US-Var,21236,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21236,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21236,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21236,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21236,GRP_SWC,SWC_DATE,20031024 -US-Var,21585,GRP_SWC,SWC,19.35 -US-Var,21585,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.8890872965 -US-Var,21585,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21585,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21585,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21585,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21585,GRP_SWC,SWC_DATE,20081113 -US-Var,21204,GRP_SWC,SWC,19.4 -US-Var,21204,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.80138768534 -US-Var,21204,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21204,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21204,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21204,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21204,GRP_SWC,SWC_DATE,20030711 -US-Var,21590,GRP_SWC,SWC,19.4 -US-Var,21590,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.14142135624 -US-Var,21590,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21590,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21590,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21590,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21590,GRP_SWC,SWC_DATE,20081126 -US-Var,21598,GRP_SWC,SWC,19.4 -US-Var,21598,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.14142135624 -US-Var,21598,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21598,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21598,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21598,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21598,GRP_SWC,SWC_DATE,20090108 -US-Var,21483,GRP_SWC,SWC,19.425 -US-Var,21483,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.88388347648 -US-Var,21483,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21483,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21483,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21483,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21483,GRP_SWC,SWC_DATE,20061119 -US-Var,21196,GRP_SWC,SWC,19.433333333 -US-Var,21196,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.94280904158 -US-Var,21196,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21196,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21196,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21196,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21196,GRP_SWC,SWC_DATE,20030627 -US-Var,21192,GRP_SWC,SWC,19.45 -US-Var,21192,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.58925565099 -US-Var,21192,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21192,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21192,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21192,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21192,GRP_SWC,SWC_DATE,20030620 -US-Var,21340,GRP_SWC,SWC,19.5 -US-Var,21340,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.357022604 -US-Var,21340,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21340,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21340,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21340,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21340,GRP_SWC,SWC_DATE,20041103 -US-Var,21722,GRP_SWC,SWC,19.520833333 -US-Var,21722,GRP_SWC,SWC_SPATIAL_VARIABILITY,11.243593855 -US-Var,21722,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21722,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21722,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21722,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21722,GRP_SWC,SWC_DATE,20101112 -US-Var,21200,GRP_SWC,SWC,19.533333333 -US-Var,21200,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.61282587703 -US-Var,21200,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21200,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21200,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21200,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21200,GRP_SWC,SWC_DATE,20030703 -US-Var,21040,GRP_SWC,SWC,19.6 -US-Var,21040,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.3617366492 -US-Var,21040,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21040,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21040,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21040,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21040,GRP_SWC,SWC_DATE,20020502 -US-Var,21188,GRP_SWC,SWC,19.65 -US-Var,21188,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.49497474683 -US-Var,21188,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21188,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21188,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21188,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21188,GRP_SWC,SWC_DATE,20030613 -US-Var,21559,GRP_SWC,SWC,19.683333333 -US-Var,21559,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.9563287613 -US-Var,21559,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21559,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21559,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21559,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21559,GRP_SWC,SWC_DATE,20080627 -US-Var,21716,GRP_SWC,SWC,19.7 -US-Var,21716,GRP_SWC,SWC_SPATIAL_REP_NUMBER,1 -US-Var,21716,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21716,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21716,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21716,GRP_SWC,SWC_DATE,20101028 -US-Var,21880,GRP_SWC,SWC,19.7125 -US-Var,21880,GRP_SWC,SWC_SPATIAL_VARIABILITY,9.7318527698 -US-Var,21880,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21880,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21880,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21880,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21880,GRP_SWC,SWC_DATE,20130101 -US-Var,21614,GRP_SWC,SWC,19.75 -US-Var,21614,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.4748737342 -US-Var,21614,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21614,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21614,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21614,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21614,GRP_SWC,SWC_DATE,20090403 -US-Var,22031,GRP_SWC,SWC,19.75 -US-Var,22031,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.2794638837 -US-Var,22031,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,22031,GRP_SWC,SWC_UNIT,Volumetric -US-Var,22031,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,22031,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,22031,GRP_SWC,SWC_DATE,20141209 -US-Var,21246,GRP_SWC,SWC,19.775 -US-Var,21246,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.3587572106 -US-Var,21246,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21246,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21246,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21246,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21246,GRP_SWC,SWC_DATE,20031119 -US-Var,21257,GRP_SWC,SWC,19.85 -US-Var,21257,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.9903066274 -US-Var,21257,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21257,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21257,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21257,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21257,GRP_SWC,SWC_DATE,20031219 -US-Var,21250,GRP_SWC,SWC,19.9 -US-Var,21250,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.2526911935 -US-Var,21250,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21250,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21250,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21250,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21250,GRP_SWC,SWC_DATE,20031206 -US-Var,21787,GRP_SWC,SWC,19.925 -US-Var,21787,GRP_SWC,SWC_SPATIAL_VARIABILITY,8.5671368224 -US-Var,21787,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21787,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21787,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21787,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21787,GRP_SWC,SWC_DATE,20111013 -US-Var,21220,GRP_SWC,SWC,19.966666667 -US-Var,21220,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.4613540145 -US-Var,21220,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21220,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21220,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21220,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21220,GRP_SWC,SWC_DATE,20030806 -US-Var,21292,GRP_SWC,SWC,19.966666667 -US-Var,21292,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.51854497287 -US-Var,21292,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21292,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21292,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21292,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21292,GRP_SWC,SWC_DATE,20040409 -US-Var,21229,GRP_SWC,SWC,2.0166666667 -US-Var,21229,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.54211519891 -US-Var,21229,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21229,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21229,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21229,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21229,GRP_SWC,SWC_DATE,20031002 -US-Var,21844,GRP_SWC,SWC,2.0833333333 -US-Var,21844,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.40722639076 -US-Var,21844,GRP_SWC,SWC_SPATIAL_REP_NUMBER,3 -US-Var,21844,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21844,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21844,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21844,GRP_SWC,SWC_DATE,20120704 -US-Var,21640,GRP_SWC,SWC,2.1 -US-Var,21640,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.0606601718 -US-Var,21640,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21640,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21640,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21640,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21640,GRP_SWC,SWC_DATE,20090802 -US-Var,21840,GRP_SWC,SWC,2.1 -US-Var,21840,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.8779421361 -US-Var,21840,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21840,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21840,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21840,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21840,GRP_SWC,SWC_DATE,20120530 -US-Var,21644,GRP_SWC,SWC,2.15 -US-Var,21644,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.91923881554 -US-Var,21644,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21644,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21644,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21644,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21644,GRP_SWC,SWC_DATE,20090907 -US-Var,21628,GRP_SWC,SWC,2.25 -US-Var,21628,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.4849242405 -US-Var,21628,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21628,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21628,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21628,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21628,GRP_SWC,SWC_DATE,20090609 -US-Var,21780,GRP_SWC,SWC,2.2541666667 -US-Var,21780,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.8401577529 -US-Var,21780,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21780,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21780,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21780,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21780,GRP_SWC,SWC_DATE,20110929 -US-Var,21776,GRP_SWC,SWC,2.3166666667 -US-Var,21776,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.4169607538 -US-Var,21776,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21776,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21776,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21776,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21776,GRP_SWC,SWC_DATE,20110916 -US-Var,21097,GRP_SWC,SWC,2.35 -US-Var,21097,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.14142135624 -US-Var,21097,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21097,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21097,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21097,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21097,GRP_SWC,SWC_DATE,20020912 -US-Var,21193,GRP_SWC,SWC,2.3666666667 -US-Var,21193,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.65996632911 -US-Var,21193,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21193,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21193,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21193,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21193,GRP_SWC,SWC_DATE,20030627 -US-Var,21624,GRP_SWC,SWC,2.375 -US-Var,21624,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.60104076401 -US-Var,21624,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21624,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21624,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21624,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21624,GRP_SWC,SWC_DATE,20090527 -US-Var,21752,GRP_SWC,SWC,2.375 -US-Var,21752,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.1592822882 -US-Var,21752,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21752,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21752,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21752,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21752,GRP_SWC,SWC_DATE,20110510 -US-Var,21330,GRP_SWC,SWC,2.425 -US-Var,21330,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.803122292 -US-Var,21330,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21330,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21330,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21330,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21330,GRP_SWC,SWC_DATE,20040921 -US-Var,21580,GRP_SWC,SWC,2.4266666667 -US-Var,21580,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.9893270777 -US-Var,21580,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21580,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21580,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21580,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21580,GRP_SWC,SWC_DATE,20081030 -US-Var,21209,GRP_SWC,SWC,2.45 -US-Var,21209,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.2391714738 -US-Var,21209,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21209,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21209,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21209,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21209,GRP_SWC,SWC_DATE,20030725 -US-Var,21045,GRP_SWC,SWC,2.5 -US-Var,21045,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21045,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21045,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21045,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21045,GRP_SWC,SWC_DATE,20020516 -US-Var,21061,GRP_SWC,SWC,2.5 -US-Var,21061,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.14142135624 -US-Var,21061,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21061,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21061,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21061,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21061,GRP_SWC,SWC_DATE,20020628 -US-Var,21772,GRP_SWC,SWC,2.5083333333 -US-Var,21772,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.7789666164 -US-Var,21772,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21772,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21772,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21772,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21772,GRP_SWC,SWC_DATE,20110831 -US-Var,20985,GRP_SWC,SWC,2.6 -US-Var,20985,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.70710678119 -US-Var,20985,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,20985,GRP_SWC,SWC_UNIT,Volumetric -US-Var,20985,GRP_SWC,SWC_PROFILE_ZERO_REF,Top of mineral soil -US-Var,20985,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,20985,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,20985,GRP_SWC,SWC_APPROACH,"TDR probes from Environmental Sensors Inc. (ESI), Canada, Moisture Points, 1-800-799-6324" -US-Var,20985,GRP_SWC,SWC_DATE,20011110 -US-Var,21556,GRP_SWC,SWC,2.6 -US-Var,21556,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.2627416998 -US-Var,21556,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21556,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21556,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21556,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21556,GRP_SWC,SWC_DATE,20080627 -US-Var,21912,GRP_SWC,SWC,2.6 -US-Var,21912,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.7958284996 -US-Var,21912,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21912,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21912,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21912,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21912,GRP_SWC,SWC_DATE,20130508 -US-Var,21321,GRP_SWC,SWC,2.6166666667 -US-Var,21321,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.4277332821 -US-Var,21321,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21321,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21321,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21321,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21321,GRP_SWC,SWC_DATE,20040817 -US-Var,21185,GRP_SWC,SWC,2.8 -US-Var,21185,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.14142135624 -US-Var,21185,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21185,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21185,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21185,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21185,GRP_SWC,SWC_DATE,20030613 -US-Var,21908,GRP_SWC,SWC,2.8625 -US-Var,21908,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.8222582144 -US-Var,21908,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21908,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21908,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21908,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21908,GRP_SWC,SWC_DATE,20130424 -US-Var,21189,GRP_SWC,SWC,2.9 -US-Var,21189,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.70710678119 -US-Var,21189,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21189,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21189,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21189,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21189,GRP_SWC,SWC_DATE,20030620 -US-Var,21333,GRP_SWC,SWC,2.925 -US-Var,21333,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.31819805153 -US-Var,21333,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21333,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21333,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21333,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21333,GRP_SWC,SWC_DATE,20041013 -US-Var,20986,GRP_SWC,SWC,2.95 -US-Var,20986,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.0506096654 -US-Var,20986,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,20986,GRP_SWC,SWC_UNIT,Volumetric -US-Var,20986,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,20986,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,20986,GRP_SWC,SWC_DATE,20011110 -US-Var,21297,GRP_SWC,SWC,2.95 -US-Var,21297,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.28284271247 -US-Var,21297,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21297,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21297,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21297,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21297,GRP_SWC,SWC_DATE,20040506 -US-Var,21181,GRP_SWC,SWC,2.9833333333 -US-Var,21181,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.1178511302 -US-Var,21181,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21181,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21181,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21181,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21181,GRP_SWC,SWC_DATE,20030606 -US-Var,21894,GRP_SWC,SWC,20.025 -US-Var,21894,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.6870466852 -US-Var,21894,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21894,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21894,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21894,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21894,GRP_SWC,SWC_DATE,20130227 -US-Var,21349,GRP_SWC,SWC,20.066666667 -US-Var,21349,GRP_SWC,SWC_SPATIAL_VARIABILITY,9.4752308679 -US-Var,21349,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21349,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21349,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21349,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21349,GRP_SWC,SWC_DATE,20041212 -US-Var,21184,GRP_SWC,SWC,20.1 -US-Var,21184,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.84852813742 -US-Var,21184,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21184,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21184,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21184,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21184,GRP_SWC,SWC_DATE,20030606 -US-Var,21587,GRP_SWC,SWC,20.116666667 -US-Var,21587,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.3435028843 -US-Var,21587,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21587,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21587,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21587,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21587,GRP_SWC,SWC_DATE,20081113 -US-Var,21232,GRP_SWC,SWC,20.133333333 -US-Var,21232,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.178511302 -US-Var,21232,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21232,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21232,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21232,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21232,GRP_SWC,SWC_DATE,20031002 -US-Var,21224,GRP_SWC,SWC,20.15 -US-Var,21224,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.77781745931 -US-Var,21224,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21224,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21224,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21224,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21224,GRP_SWC,SWC_DATE,20030816 -US-Var,21228,GRP_SWC,SWC,20.2 -US-Var,21228,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.28284271247 -US-Var,21228,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21228,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21228,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21228,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21228,GRP_SWC,SWC_DATE,20030905 -US-Var,21551,GRP_SWC,SWC,20.2 -US-Var,21551,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.2727922061 -US-Var,21551,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21551,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21551,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21551,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21551,GRP_SWC,SWC_DATE,20080506 -US-Var,21571,GRP_SWC,SWC,20.225 -US-Var,21571,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.0960155108 -US-Var,21571,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21571,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21571,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21571,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21571,GRP_SWC,SWC_DATE,20080806 -US-Var,21579,GRP_SWC,SWC,20.225 -US-Var,21579,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.0960155108 -US-Var,21579,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21579,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21579,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21579,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21579,GRP_SWC,SWC_DATE,20080919 -US-Var,21394,GRP_SWC,SWC,20.25 -US-Var,21394,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.8083261121 -US-Var,21394,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21394,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21394,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21394,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21394,GRP_SWC,SWC_DATE,20050517 -US-Var,22032,GRP_SWC,SWC,20.25 -US-Var,22032,GRP_SWC,SWC_SPATIAL_VARIABILITY,8.5423455015 -US-Var,22032,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,22032,GRP_SWC,SWC_UNIT,Volumetric -US-Var,22032,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,22032,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,22032,GRP_SWC,SWC_DATE,20141223 -US-Var,21785,GRP_SWC,SWC,20.266666667 -US-Var,21785,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.6454278597 -US-Var,21785,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21785,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21785,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21785,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21785,GRP_SWC,SWC_DATE,20111013 -US-Var,21208,GRP_SWC,SWC,20.283333333 -US-Var,21208,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.4849242405 -US-Var,21208,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21208,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21208,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21208,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21208,GRP_SWC,SWC_DATE,20030717 -US-Var,21248,GRP_SWC,SWC,20.358333333 -US-Var,21248,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.27105759945 -US-Var,21248,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21248,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21248,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21248,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21248,GRP_SWC,SWC_DATE,20031119 -US-Var,21750,GRP_SWC,SWC,20.3875 -US-Var,21750,GRP_SWC,SWC_SPATIAL_VARIABILITY,9.1264610702 -US-Var,21750,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21750,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21750,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21750,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21750,GRP_SWC,SWC_DATE,20110415 -US-Var,21341,GRP_SWC,SWC,20.425 -US-Var,21341,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.6415999231 -US-Var,21341,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21341,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21341,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21341,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21341,GRP_SWC,SWC_DATE,20041120 -US-Var,21242,GRP_SWC,SWC,20.4375 -US-Var,21242,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.9268659787 -US-Var,21242,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21242,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21242,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21242,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21242,GRP_SWC,SWC_DATE,20031110 -US-Var,21169,GRP_SWC,SWC,20.45 -US-Var,21169,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.1178511302 -US-Var,21169,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21169,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21169,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21169,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21169,GRP_SWC,SWC_DATE,20030509 -US-Var,21567,GRP_SWC,SWC,20.45 -US-Var,21567,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.6263455967 -US-Var,21567,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21567,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21567,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21567,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21567,GRP_SWC,SWC_DATE,20080731 -US-Var,21562,GRP_SWC,SWC,20.573475 -US-Var,21562,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.1486242554 -US-Var,21562,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21562,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21562,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21562,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21562,GRP_SWC,SWC_DATE,20080712 -US-Var,21114,GRP_SWC,SWC,20.6 -US-Var,21114,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.5254833996 -US-Var,21114,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21114,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21114,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21114,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21114,GRP_SWC,SWC_DATE,20021114 -US-Var,21444,GRP_SWC,SWC,20.65 -US-Var,21444,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.3334523779 -US-Var,21444,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21444,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21444,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21444,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21444,GRP_SWC,SWC_DATE,20060223 -US-Var,21595,GRP_SWC,SWC,20.683333333 -US-Var,21595,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.25927248644 -US-Var,21595,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21595,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21595,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21595,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21595,GRP_SWC,SWC_DATE,20081211 -US-Var,21609,GRP_SWC,SWC,20.725 -US-Var,21609,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.5102290732 -US-Var,21609,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21609,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21609,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21609,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21609,GRP_SWC,SWC_DATE,20090327 -US-Var,21212,GRP_SWC,SWC,20.75 -US-Var,21212,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.63639610307 -US-Var,21212,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21212,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21212,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21212,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21212,GRP_SWC,SWC_DATE,20030725 -US-Var,21591,GRP_SWC,SWC,20.75 -US-Var,21591,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.77781745931 -US-Var,21591,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21591,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21591,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21591,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21591,GRP_SWC,SWC_DATE,20081126 -US-Var,21599,GRP_SWC,SWC,20.75 -US-Var,21599,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.77781745931 -US-Var,21599,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21599,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21599,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21599,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21599,GRP_SWC,SWC_DATE,20090108 -US-Var,21216,GRP_SWC,SWC,20.8 -US-Var,21216,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.70710678119 -US-Var,21216,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21216,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21216,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21216,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21216,GRP_SWC,SWC_DATE,20030731 -US-Var,21575,GRP_SWC,SWC,20.85 -US-Var,21575,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.3435028843 -US-Var,21575,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21575,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21575,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21575,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21575,GRP_SWC,SWC_DATE,20080904 -US-Var,21027,GRP_SWC,SWC,20.933333333 -US-Var,21027,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.0641293851 -US-Var,21027,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21027,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21027,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21027,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21027,GRP_SWC,SWC_DATE,20020411 -US-Var,21487,GRP_SWC,SWC,20.95 -US-Var,21487,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.2526911935 -US-Var,21487,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21487,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21487,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21487,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21487,GRP_SWC,SWC_DATE,20061226 -US-Var,22027,GRP_SWC,SWC,20.9625 -US-Var,22027,GRP_SWC,SWC_SPATIAL_VARIABILITY,10.963300522 -US-Var,22027,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,22027,GRP_SWC,SWC_UNIT,Volumetric -US-Var,22027,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,22027,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,22027,GRP_SWC,SWC_DATE,20141126 -US-Var,21287,GRP_SWC,SWC,21 -US-Var,21287,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21287,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21287,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21287,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21287,GRP_SWC,SWC_DATE,20040325 -US-Var,21377,GRP_SWC,SWC,21.025 -US-Var,21377,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.4294678888 -US-Var,21377,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21377,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21377,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21377,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21377,GRP_SWC,SWC_DATE,20050309 -US-Var,21509,GRP_SWC,SWC,21.05 -US-Var,21509,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.0405591591 -US-Var,21509,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21509,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21509,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21509,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21509,GRP_SWC,SWC_DATE,20070328 -US-Var,21737,GRP_SWC,SWC,21.058333333 -US-Var,21737,GRP_SWC,SWC_SPATIAL_VARIABILITY,12.812678183 -US-Var,21737,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21737,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21737,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21737,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21737,GRP_SWC,SWC_DATE,20110222 -US-Var,21036,GRP_SWC,SWC,21.085 -US-Var,21036,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.3829498526 -US-Var,21036,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21036,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21036,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21036,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21036,GRP_SWC,SWC_DATE,20020426 -US-Var,21462,GRP_SWC,SWC,21.275 -US-Var,21462,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.1767766953 -US-Var,21462,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21462,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21462,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21462,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21462,GRP_SWC,SWC_DATE,20060504 -US-Var,21391,GRP_SWC,SWC,21.3 -US-Var,21391,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.84852813742 -US-Var,21391,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21391,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21391,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21391,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21391,GRP_SWC,SWC_DATE,20050425 -US-Var,21632,GRP_SWC,SWC,21.3 -US-Var,21632,GRP_SWC,SWC_SPATIAL_VARIABILITY,26.30437226 -US-Var,21632,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21632,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21632,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21632,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21632,GRP_SWC,SWC_DATE,20090621 -US-Var,21252,GRP_SWC,SWC,21.4 -US-Var,21252,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.98994949366 -US-Var,21252,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21252,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21252,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21252,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21252,GRP_SWC,SWC_DATE,20031206 -US-Var,21395,GRP_SWC,SWC,21.45 -US-Var,21395,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.969848481 -US-Var,21395,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21395,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21395,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21395,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21395,GRP_SWC,SWC_DATE,20050517 -US-Var,21619,GRP_SWC,SWC,21.45 -US-Var,21619,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.0876996112 -US-Var,21619,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21619,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21619,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21619,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21619,GRP_SWC,SWC_DATE,20090417 -US-Var,21680,GRP_SWC,SWC,21.525 -US-Var,21680,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.1566756826 -US-Var,21680,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21680,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21680,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21680,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21680,GRP_SWC,SWC_DATE,20100321 -US-Var,21488,GRP_SWC,SWC,21.6 -US-Var,21488,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.6870057685 -US-Var,21488,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21488,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21488,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21488,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21488,GRP_SWC,SWC_DATE,20070110 -US-Var,21973,GRP_SWC,SWC,21.7 -US-Var,21973,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.2005951959 -US-Var,21973,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21973,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21973,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21973,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21973,GRP_SWC,SWC_DATE,20140318 -US-Var,21623,GRP_SWC,SWC,21.8 -US-Var,21623,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.4142135624 -US-Var,21623,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21623,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21623,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21623,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21623,GRP_SWC,SWC_DATE,20090507 -US-Var,21353,GRP_SWC,SWC,21.95 -US-Var,21353,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.1518289963 -US-Var,21353,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21353,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21353,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21353,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21353,GRP_SWC,SWC_DATE,20041215 -US-Var,21890,GRP_SWC,SWC,22.05 -US-Var,21890,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.9422218067 -US-Var,21890,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21890,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21890,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21890,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21890,GRP_SWC,SWC_DATE,20130206 -US-Var,21373,GRP_SWC,SWC,22.083333333 -US-Var,21373,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.0575480922 -US-Var,21373,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21373,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21373,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21373,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21373,GRP_SWC,SWC_DATE,20050226 -US-Var,21467,GRP_SWC,SWC,22.1 -US-Var,21467,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.3199326582 -US-Var,21467,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21467,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21467,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21467,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21467,GRP_SWC,SWC_DATE,20060512 -US-Var,21816,GRP_SWC,SWC,22.104166667 -US-Var,21816,GRP_SWC,SWC_SPATIAL_VARIABILITY,11.533625358 -US-Var,21816,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21816,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21816,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21816,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21816,GRP_SWC,SWC_DATE,20120216 -US-Var,21618,GRP_SWC,SWC,22.216666667 -US-Var,21618,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.96637926762 -US-Var,21618,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21618,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21618,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21618,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21618,GRP_SWC,SWC_DATE,20090417 -US-Var,21180,GRP_SWC,SWC,22.233333333 -US-Var,21180,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.75424723327 -US-Var,21180,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21180,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21180,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21180,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21180,GRP_SWC,SWC_DATE,20030530 -US-Var,21432,GRP_SWC,SWC,22.283333333 -US-Var,21432,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.6433345298 -US-Var,21432,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21432,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21432,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21432,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21432,GRP_SWC,SWC_DATE,20060110 -US-Var,21741,GRP_SWC,SWC,22.3 -US-Var,21741,GRP_SWC,SWC_SPATIAL_VARIABILITY,12.012493496 -US-Var,21741,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21741,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21741,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21741,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21741,GRP_SWC,SWC_DATE,20110308 -US-Var,21013,GRP_SWC,SWC,22.316666667 -US-Var,21013,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.2090199547 -US-Var,21013,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21013,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21013,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21013,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21013,GRP_SWC,SWC_DATE,20020228 -US-Var,21542,GRP_SWC,SWC,22.333333333 -US-Var,21542,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.75424723327 -US-Var,21542,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21542,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21542,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21542,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21542,GRP_SWC,SWC_DATE,20080404 -US-Var,21745,GRP_SWC,SWC,22.3375 -US-Var,21745,GRP_SWC,SWC_SPATIAL_VARIABILITY,10.609694859 -US-Var,21745,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21745,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21745,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21745,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21745,GRP_SWC,SWC_DATE,20110330 -US-Var,20994,GRP_SWC,SWC,22.35 -US-Var,20994,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.8991378029 -US-Var,20994,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,20994,GRP_SWC,SWC_UNIT,Volumetric -US-Var,20994,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,20994,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,20994,GRP_SWC,SWC_DATE,20011125 -US-Var,21899,GRP_SWC,SWC,22.4 -US-Var,21899,GRP_SWC,SWC_SPATIAL_VARIABILITY,8.7381348124 -US-Var,21899,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21899,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21899,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21899,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21899,GRP_SWC,SWC_DATE,20130313 -US-Var,21991,GRP_SWC,SWC,22.425 -US-Var,21991,GRP_SWC,SWC_SPATIAL_VARIABILITY,12.218053582 -US-Var,21991,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21991,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21991,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21991,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21991,GRP_SWC,SWC_DATE,20140611 -US-Var,21121,GRP_SWC,SWC,22.45 -US-Var,21121,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.5961940777 -US-Var,21121,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21121,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21121,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21121,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21121,GRP_SWC,SWC_DATE,20021214 -US-Var,21723,GRP_SWC,SWC,22.466666667 -US-Var,21723,GRP_SWC,SWC_SPATIAL_VARIABILITY,10.68097998 -US-Var,21723,GRP_SWC,SWC_SPATIAL_REP_NUMBER,3 -US-Var,21723,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21723,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21723,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21723,GRP_SWC,SWC_DATE,20101112 -US-Var,21889,GRP_SWC,SWC,22.55 -US-Var,21889,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.3307285306 -US-Var,21889,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21889,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21889,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21889,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21889,GRP_SWC,SWC_DATE,20130206 -US-Var,21729,GRP_SWC,SWC,22.558333333 -US-Var,21729,GRP_SWC,SWC_SPATIAL_VARIABILITY,13.058681659 -US-Var,21729,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21729,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21729,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21729,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21729,GRP_SWC,SWC_DATE,20101230 -US-Var,21733,GRP_SWC,SWC,22.558333333 -US-Var,21733,GRP_SWC,SWC_SPATIAL_VARIABILITY,13.058681659 -US-Var,21733,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21733,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21733,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21733,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21733,GRP_SWC,SWC_DATE,20110119 -US-Var,21510,GRP_SWC,SWC,22.566666667 -US-Var,21510,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.70710678119 -US-Var,21510,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21510,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21510,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21510,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21510,GRP_SWC,SWC_DATE,20070328 -US-Var,21728,GRP_SWC,SWC,22.6 -US-Var,21728,GRP_SWC,SWC_SPATIAL_VARIABILITY,12.586971512 -US-Var,21728,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21728,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21728,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21728,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21728,GRP_SWC,SWC_DATE,20101230 -US-Var,21732,GRP_SWC,SWC,22.6 -US-Var,21732,GRP_SWC,SWC_SPATIAL_VARIABILITY,12.586971512 -US-Var,21732,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21732,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21732,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21732,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21732,GRP_SWC,SWC_DATE,20110119 -US-Var,21813,GRP_SWC,SWC,22.6625 -US-Var,21813,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.596637401 -US-Var,21813,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21813,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21813,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21813,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21813,GRP_SWC,SWC_DATE,20120201 -US-Var,21345,GRP_SWC,SWC,22.7 -US-Var,21345,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.8083261121 -US-Var,21345,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21345,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21345,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21345,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21345,GRP_SWC,SWC_DATE,20041128 -US-Var,21686,GRP_SWC,SWC,22.725 -US-Var,21686,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.338656198 -US-Var,21686,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21686,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21686,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21686,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21686,GRP_SWC,SWC_DATE,20100402 -US-Var,21610,GRP_SWC,SWC,22.85 -US-Var,21610,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.4648232278 -US-Var,21610,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21610,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21610,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21610,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21610,GRP_SWC,SWC_DATE,20090327 -US-Var,21725,GRP_SWC,SWC,22.95 -US-Var,21725,GRP_SWC,SWC_SPATIAL_VARIABILITY,10.617556216 -US-Var,21725,GRP_SWC,SWC_SPATIAL_REP_NUMBER,3 -US-Var,21725,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21725,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21725,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21725,GRP_SWC,SWC_DATE,20101202 -US-Var,21339,GRP_SWC,SWC,22.983333333 -US-Var,21339,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.4277332821 -US-Var,21339,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21339,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21339,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21339,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21339,GRP_SWC,SWC_DATE,20041103 -US-Var,21885,GRP_SWC,SWC,23.133333333 -US-Var,21885,GRP_SWC,SWC_SPATIAL_VARIABILITY,8.5380195466 -US-Var,21885,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21885,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21885,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21885,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21885,GRP_SWC,SWC_DATE,20130116 -US-Var,21440,GRP_SWC,SWC,23.2 -US-Var,21440,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.404163056 -US-Var,21440,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21440,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21440,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21440,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21440,GRP_SWC,SWC_DATE,20060210 -US-Var,21974,GRP_SWC,SWC,23.325 -US-Var,21974,GRP_SWC,SWC_SPATIAL_VARIABILITY,9.0293502904 -US-Var,21974,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21974,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21974,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21974,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21974,GRP_SWC,SWC_DATE,20140318 -US-Var,20997,GRP_SWC,SWC,23.366666667 -US-Var,20997,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.8925565099 -US-Var,20997,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,20997,GRP_SWC,SWC_UNIT,Volumetric -US-Var,20997,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,20997,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,20997,GRP_SWC,SWC_DATE,20011205 -US-Var,21486,GRP_SWC,SWC,23.375 -US-Var,21486,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.0759144982 -US-Var,21486,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21486,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21486,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21486,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21486,GRP_SWC,SWC_DATE,20061226 -US-Var,21814,GRP_SWC,SWC,23.4125 -US-Var,21814,GRP_SWC,SWC_SPATIAL_VARIABILITY,8.5639141168 -US-Var,21814,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21814,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21814,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21814,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21814,GRP_SWC,SWC_DATE,20120201 -US-Var,21664,GRP_SWC,SWC,23.416666667 -US-Var,21664,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.3774807504 -US-Var,21664,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21664,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21664,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21664,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21664,GRP_SWC,SWC_DATE,20091222 -US-Var,21547,GRP_SWC,SWC,23.45 -US-Var,21547,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.1920310217 -US-Var,21547,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21547,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21547,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21547,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21547,GRP_SWC,SWC_DATE,20080420 -US-Var,21369,GRP_SWC,SWC,23.5 -US-Var,21369,GRP_SWC,SWC_SPATIAL_VARIABILITY,13.010764774 -US-Var,21369,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21369,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21369,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21369,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21369,GRP_SWC,SWC_DATE,20050208 -US-Var,21023,GRP_SWC,SWC,23.525 -US-Var,21023,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.4395183951 -US-Var,21023,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21023,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21023,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21023,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21023,GRP_SWC,SWC_DATE,20020404 -US-Var,22030,GRP_SWC,SWC,23.525 -US-Var,22030,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.8114349835 -US-Var,22030,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,22030,GRP_SWC,SWC_UNIT,Volumetric -US-Var,22030,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,22030,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,22030,GRP_SWC,SWC_DATE,20141209 -US-Var,21338,GRP_SWC,SWC,23.633333333 -US-Var,21338,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.8554665641 -US-Var,21338,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21338,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21338,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21338,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21338,GRP_SWC,SWC_DATE,20041103 -US-Var,21978,GRP_SWC,SWC,23.6625 -US-Var,21978,GRP_SWC,SWC_SPATIAL_VARIABILITY,8.6912192279 -US-Var,21978,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21978,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21978,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21978,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21978,GRP_SWC,SWC_DATE,20140408 -US-Var,21385,GRP_SWC,SWC,23.675 -US-Var,21385,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.2478445072 -US-Var,21385,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21385,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21385,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21385,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21385,GRP_SWC,SWC_DATE,20050410 -US-Var,21505,GRP_SWC,SWC,23.7 -US-Var,21505,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.5455844123 -US-Var,21505,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21505,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21505,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21505,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21505,GRP_SWC,SWC_DATE,20070316 -US-Var,22029,GRP_SWC,SWC,23.775 -US-Var,22029,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.0188810174 -US-Var,22029,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,22029,GRP_SWC,SWC_UNIT,Volumetric -US-Var,22029,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,22029,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,22029,GRP_SWC,SWC_DATE,20141209 -US-Var,21667,GRP_SWC,SWC,23.783333333 -US-Var,21667,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.7005254882 -US-Var,21667,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21667,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21667,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21667,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21667,GRP_SWC,SWC_DATE,20091222 -US-Var,21977,GRP_SWC,SWC,23.8 -US-Var,21977,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.9619019002 -US-Var,21977,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21977,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21977,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21977,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21977,GRP_SWC,SWC_DATE,20140408 -US-Var,21685,GRP_SWC,SWC,23.85 -US-Var,21685,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.21213203436 -US-Var,21685,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21685,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21685,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21685,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21685,GRP_SWC,SWC_DATE,20100402 -US-Var,21964,GRP_SWC,SWC,23.85 -US-Var,21964,GRP_SWC,SWC_SPATIAL_VARIABILITY,9.7898757227 -US-Var,21964,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21964,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21964,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21964,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21964,GRP_SWC,SWC_DATE,20140210 -US-Var,21968,GRP_SWC,SWC,23.85 -US-Var,21968,GRP_SWC,SWC_SPATIAL_VARIABILITY,9.7898757227 -US-Var,21968,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21968,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21968,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21968,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21968,GRP_SWC,SWC_DATE,20140304 -US-Var,21253,GRP_SWC,SWC,23.916666667 -US-Var,21253,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.4818121609 -US-Var,21253,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21253,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21253,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21253,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21253,GRP_SWC,SWC_DATE,20031215 -US-Var,21436,GRP_SWC,SWC,23.975 -US-Var,21436,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.8436814511 -US-Var,21436,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21436,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21436,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21436,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21436,GRP_SWC,SWC_DATE,20060124 -US-Var,21666,GRP_SWC,SWC,24.033333333 -US-Var,21666,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.7039947016 -US-Var,21666,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21666,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21666,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21666,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21666,GRP_SWC,SWC_DATE,20091222 -US-Var,21017,GRP_SWC,SWC,24.1 -US-Var,21017,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.5355339059 -US-Var,21017,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21017,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21017,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21017,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21017,GRP_SWC,SWC_DATE,20020320 -US-Var,21829,GRP_SWC,SWC,24.1 -US-Var,21829,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.7946562892 -US-Var,21829,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21829,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21829,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21829,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21829,GRP_SWC,SWC_DATE,20120405 -US-Var,21738,GRP_SWC,SWC,24.125 -US-Var,21738,GRP_SWC,SWC_SPATIAL_VARIABILITY,9.8163648322 -US-Var,21738,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21738,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21738,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21738,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21738,GRP_SWC,SWC_DATE,20110222 -US-Var,21396,GRP_SWC,SWC,24.3 -US-Var,21396,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.9597979746 -US-Var,21396,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21396,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21396,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21396,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21396,GRP_SWC,SWC_DATE,20050517 -US-Var,21139,GRP_SWC,SWC,24.5 -US-Var,21139,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.2526911935 -US-Var,21139,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21139,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21139,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21139,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21139,GRP_SWC,SWC_DATE,20030213 -US-Var,21835,GRP_SWC,SWC,24.5125 -US-Var,21835,GRP_SWC,SWC_SPATIAL_VARIABILITY,9.9445441491 -US-Var,21835,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21835,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21835,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21835,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21835,GRP_SWC,SWC_DATE,20120504 -US-Var,21604,GRP_SWC,SWC,24.516666667 -US-Var,21604,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.3604918173 -US-Var,21604,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21604,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21604,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21604,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21604,GRP_SWC,SWC_DATE,20090227 -US-Var,21726,GRP_SWC,SWC,24.55 -US-Var,21726,GRP_SWC,SWC_SPATIAL_VARIABILITY,10.764873432 -US-Var,21726,GRP_SWC,SWC_SPATIAL_REP_NUMBER,3 -US-Var,21726,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21726,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21726,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21726,GRP_SWC,SWC_DATE,20101202 -US-Var,21022,GRP_SWC,SWC,24.575 -US-Var,21022,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.7930717857 -US-Var,21022,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21022,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21022,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21022,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21022,GRP_SWC,SWC_DATE,20020404 -US-Var,21361,GRP_SWC,SWC,24.583333333 -US-Var,21361,GRP_SWC,SWC_SPATIAL_VARIABILITY,11.00729556 -US-Var,21361,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21361,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21361,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21361,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21361,GRP_SWC,SWC_DATE,20050117 -US-Var,21001,GRP_SWC,SWC,24.7 -US-Var,21001,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.6468037432 -US-Var,21001,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21001,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21001,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21001,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21001,GRP_SWC,SWC_DATE,20011219 -US-Var,21381,GRP_SWC,SWC,24.766666667 -US-Var,21381,GRP_SWC,SWC_SPATIAL_VARIABILITY,10.795163526 -US-Var,21381,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21381,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21381,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21381,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21381,GRP_SWC,SWC_DATE,20050324 -US-Var,21669,GRP_SWC,SWC,24.85 -US-Var,21669,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.1819805153 -US-Var,21669,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21669,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21669,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21669,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21669,GRP_SWC,SWC_DATE,20100108 -US-Var,21895,GRP_SWC,SWC,24.85 -US-Var,21895,GRP_SWC,SWC_SPATIAL_VARIABILITY,9.2385063728 -US-Var,21895,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21895,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21895,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21895,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21895,GRP_SWC,SWC_DATE,20130227 -US-Var,21457,GRP_SWC,SWC,24.933333333 -US-Var,21457,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.8554665641 -US-Var,21457,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21457,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21457,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21457,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21457,GRP_SWC,SWC_DATE,20060418 -US-Var,21485,GRP_SWC,SWC,24.95 -US-Var,21485,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.374011537 -US-Var,21485,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21485,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21485,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21485,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21485,GRP_SWC,SWC_DATE,20061226 -US-Var,21137,GRP_SWC,SWC,25 -US-Var,21137,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.9798989873 -US-Var,21137,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21137,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21137,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21137,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21137,GRP_SWC,SWC_DATE,20030213 -US-Var,21825,GRP_SWC,SWC,25 -US-Var,21825,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.0385841379 -US-Var,21825,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21825,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21825,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21825,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21825,GRP_SWC,SWC_DATE,20120321 -US-Var,21283,GRP_SWC,SWC,25.016666667 -US-Var,21283,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.1920310217 -US-Var,21283,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21283,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21283,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21283,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21283,GRP_SWC,SWC_DATE,20040321 -US-Var,21878,GRP_SWC,SWC,25.141666667 -US-Var,21878,GRP_SWC,SWC_SPATIAL_VARIABILITY,9.2097120637 -US-Var,21878,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21878,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21878,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21878,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21878,GRP_SWC,SWC_DATE,20121211 -US-Var,21125,GRP_SWC,SWC,25.166666667 -US-Var,21125,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.9026070162 -US-Var,21125,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21125,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21125,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21125,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21125,GRP_SWC,SWC_DATE,20021223 -US-Var,21718,GRP_SWC,SWC,25.2 -US-Var,21718,GRP_SWC,SWC_SPATIAL_REP_NUMBER,1 -US-Var,21718,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21718,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21718,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21718,GRP_SWC,SWC_DATE,20101028 -US-Var,21138,GRP_SWC,SWC,25.25 -US-Var,21138,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.4748737342 -US-Var,21138,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21138,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21138,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21138,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21138,GRP_SWC,SWC_DATE,20030213 -US-Var,21157,GRP_SWC,SWC,25.25 -US-Var,21157,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.7206265009 -US-Var,21157,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21157,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21157,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21157,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21157,GRP_SWC,SWC_DATE,20030416 -US-Var,21695,GRP_SWC,SWC,25.25 -US-Var,21695,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.4648232278 -US-Var,21695,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21695,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21695,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21695,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21695,GRP_SWC,SWC_DATE,20100528 -US-Var,21830,GRP_SWC,SWC,25.3375 -US-Var,21830,GRP_SWC,SWC_SPATIAL_VARIABILITY,8.5674164717 -US-Var,21830,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21830,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21830,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21830,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21830,GRP_SWC,SWC_DATE,20120405 -US-Var,21497,GRP_SWC,SWC,25.35 -US-Var,21497,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.8991378029 -US-Var,21497,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21497,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21497,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21497,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21497,GRP_SWC,SWC_DATE,20070204 -US-Var,21269,GRP_SWC,SWC,25.4 -US-Var,21269,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.35355339059 -US-Var,21269,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21269,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21269,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21269,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21269,GRP_SWC,SWC_DATE,20040123 -US-Var,21688,GRP_SWC,SWC,25.4 -US-Var,21688,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.5355339059 -US-Var,21688,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21688,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21688,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21688,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21688,GRP_SWC,SWC_DATE,20100430 -US-Var,21515,GRP_SWC,SWC,25.425 -US-Var,21515,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.9445436483 -US-Var,21515,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21515,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21515,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21515,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21515,GRP_SWC,SWC_DATE,20070405 -US-Var,21886,GRP_SWC,SWC,25.475 -US-Var,21886,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.3041654782 -US-Var,21886,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21886,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21886,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21886,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21886,GRP_SWC,SWC_DATE,20130116 -US-Var,21817,GRP_SWC,SWC,25.508333333 -US-Var,21817,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.1994390723 -US-Var,21817,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21817,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21817,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21817,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21817,GRP_SWC,SWC_DATE,20120216 -US-Var,21818,GRP_SWC,SWC,25.520833333 -US-Var,21818,GRP_SWC,SWC_SPATIAL_VARIABILITY,9.691036093 -US-Var,21818,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21818,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21818,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21818,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21818,GRP_SWC,SWC_DATE,20120216 -US-Var,21751,GRP_SWC,SWC,25.525 -US-Var,21751,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.9708318795 -US-Var,21751,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21751,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21751,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21751,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21751,GRP_SWC,SWC_DATE,20110415 -US-Var,21826,GRP_SWC,SWC,25.525 -US-Var,21826,GRP_SWC,SWC_SPATIAL_VARIABILITY,9.2116321391 -US-Var,21826,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21826,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21826,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21826,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21826,GRP_SWC,SWC_DATE,20120321 -US-Var,21282,GRP_SWC,SWC,25.566666667 -US-Var,21282,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.7441967269 -US-Var,21282,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21282,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21282,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21282,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21282,GRP_SWC,SWC_DATE,20040321 -US-Var,21005,GRP_SWC,SWC,25.6 -US-Var,21005,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.7882250994 -US-Var,21005,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21005,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21005,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21005,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21005,GRP_SWC,SWC_DATE,20020115 -US-Var,21703,GRP_SWC,SWC,25.6 -US-Var,21703,GRP_SWC,SWC_SPATIAL_REP_NUMBER,1 -US-Var,21703,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21703,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21703,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21703,GRP_SWC,SWC_DATE,20100624 -US-Var,21122,GRP_SWC,SWC,25.625 -US-Var,21122,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.4901280605 -US-Var,21122,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21122,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21122,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21122,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21122,GRP_SWC,SWC_DATE,20021214 -US-Var,21536,GRP_SWC,SWC,25.7 -US-Var,21536,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.98994949366 -US-Var,21536,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21536,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21536,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21536,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21536,GRP_SWC,SWC_DATE,20080130 -US-Var,21392,GRP_SWC,SWC,25.725 -US-Var,21392,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.3587572106 -US-Var,21392,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21392,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21392,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21392,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21392,GRP_SWC,SWC_DATE,20050425 -US-Var,21171,GRP_SWC,SWC,25.783333333 -US-Var,21171,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.6634355425 -US-Var,21171,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21171,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21171,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21171,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21171,GRP_SWC,SWC_DATE,20030509 -US-Var,21746,GRP_SWC,SWC,25.7875 -US-Var,21746,GRP_SWC,SWC_SPATIAL_VARIABILITY,8.619200949 -US-Var,21746,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21746,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21746,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21746,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21746,GRP_SWC,SWC_DATE,20110330 -US-Var,21145,GRP_SWC,SWC,25.8 -US-Var,21145,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.1313708499 -US-Var,21145,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21145,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21145,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21145,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21145,GRP_SWC,SWC_DATE,20030227 -US-Var,21155,GRP_SWC,SWC,25.883333333 -US-Var,21155,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.7105759945 -US-Var,21155,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21155,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21155,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21155,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21155,GRP_SWC,SWC_DATE,20030405 -US-Var,21742,GRP_SWC,SWC,25.933333333 -US-Var,21742,GRP_SWC,SWC_SPATIAL_VARIABILITY,10.367899176 -US-Var,21742,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21742,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21742,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21742,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21742,GRP_SWC,SWC_DATE,20110308 -US-Var,21032,GRP_SWC,SWC,25.966666667 -US-Var,21032,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.178511302 -US-Var,21032,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21032,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21032,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21032,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21032,GRP_SWC,SWC_DATE,20020418 -US-Var,21506,GRP_SWC,SWC,25.975 -US-Var,21506,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.3788582233 -US-Var,21506,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21506,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21506,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21506,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21506,GRP_SWC,SWC_DATE,20070316 -US-Var,21665,GRP_SWC,SWC,26 -US-Var,21665,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.939696962 -US-Var,21665,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21665,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21665,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21665,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21665,GRP_SWC,SWC_DATE,20091222 -US-Var,21717,GRP_SWC,SWC,26.033333333 -US-Var,21717,GRP_SWC,SWC_SPATIAL_REP_NUMBER,1 -US-Var,21717,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21717,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21717,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21717,GRP_SWC,SWC_DATE,20101028 -US-Var,21819,GRP_SWC,SWC,26.066666667 -US-Var,21819,GRP_SWC,SWC_SPATIAL_VARIABILITY,13.824454982 -US-Var,21819,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21819,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21819,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21819,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21819,GRP_SWC,SWC_DATE,20120216 -US-Var,21983,GRP_SWC,SWC,26.1 -US-Var,21983,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.2689980969 -US-Var,21983,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21983,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21983,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21983,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21983,GRP_SWC,SWC_DATE,20140422 -US-Var,21170,GRP_SWC,SWC,26.15 -US-Var,21170,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.6162950904 -US-Var,21170,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21170,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21170,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21170,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21170,GRP_SWC,SWC_DATE,20030509 -US-Var,21129,GRP_SWC,SWC,26.166666667 -US-Var,21129,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.0169889331 -US-Var,21129,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21129,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21129,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21129,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21129,GRP_SWC,SWC_DATE,20030104 -US-Var,21452,GRP_SWC,SWC,26.183333333 -US-Var,21452,GRP_SWC,SWC_SPATIAL_VARIABILITY,9.2159583815 -US-Var,21452,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21452,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21452,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21452,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21452,GRP_SWC,SWC_DATE,20060330 -US-Var,21500,GRP_SWC,SWC,26.275 -US-Var,21500,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.00520382 -US-Var,21500,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21500,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21500,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21500,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21500,GRP_SWC,SWC_DATE,20070302 -US-Var,21681,GRP_SWC,SWC,26.3 -US-Var,21681,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.0405591591 -US-Var,21681,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21681,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21681,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21681,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21681,GRP_SWC,SWC_DATE,20100321 -US-Var,21153,GRP_SWC,SWC,26.333333333 -US-Var,21153,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.1584102893 -US-Var,21153,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21153,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21153,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21153,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21153,GRP_SWC,SWC_DATE,20030405 -US-Var,21822,GRP_SWC,SWC,26.35 -US-Var,21822,GRP_SWC,SWC_SPATIAL_VARIABILITY,9.6171721415 -US-Var,21822,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21822,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21822,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21822,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21822,GRP_SWC,SWC_DATE,20120302 -US-Var,21821,GRP_SWC,SWC,26.45 -US-Var,21821,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.6742106646 -US-Var,21821,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21821,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21821,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21821,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21821,GRP_SWC,SWC_DATE,20120302 -US-Var,21288,GRP_SWC,SWC,26.5 -US-Var,21288,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21288,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21288,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21288,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21288,GRP_SWC,SWC_DATE,20040325 -US-Var,21445,GRP_SWC,SWC,26.5 -US-Var,21445,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.969848481 -US-Var,21445,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21445,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21445,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21445,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21445,GRP_SWC,SWC_DATE,20060223 -US-Var,21365,GRP_SWC,SWC,26.583333333 -US-Var,21365,GRP_SWC,SWC_SPATIAL_VARIABILITY,10.53589104 -US-Var,21365,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21365,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21365,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21365,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21365,GRP_SWC,SWC_DATE,20050127 -US-Var,21601,GRP_SWC,SWC,26.616666667 -US-Var,21601,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.2492219801 -US-Var,21601,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21601,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21601,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21601,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21601,GRP_SWC,SWC_DATE,20090210 -US-Var,21815,GRP_SWC,SWC,26.625 -US-Var,21815,GRP_SWC,SWC_SPATIAL_VARIABILITY,10.129865086 -US-Var,21815,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21815,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21815,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21815,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21815,GRP_SWC,SWC_DATE,20120201 -US-Var,21261,GRP_SWC,SWC,26.633333333 -US-Var,21261,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.3098821519 -US-Var,21261,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21261,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21261,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21261,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21261,GRP_SWC,SWC_DATE,20031231 -US-Var,21358,GRP_SWC,SWC,26.733333333 -US-Var,21358,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.7812866727 -US-Var,21358,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21358,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21358,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21358,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21358,GRP_SWC,SWC_DATE,20041226 -US-Var,21133,GRP_SWC,SWC,26.8 -US-Var,21133,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.1313708499 -US-Var,21133,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21133,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21133,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21133,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21133,GRP_SWC,SWC_DATE,20030129 -US-Var,21511,GRP_SWC,SWC,26.8 -US-Var,21511,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.5355339059 -US-Var,21511,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21511,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21511,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21511,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21511,GRP_SWC,SWC_DATE,20070328 -US-Var,21176,GRP_SWC,SWC,26.804166667 -US-Var,21176,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.94870159809 -US-Var,21176,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21176,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21176,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21176,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21176,GRP_SWC,SWC_DATE,20030521 -US-Var,21877,GRP_SWC,SWC,26.9 -US-Var,21877,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.7782687086 -US-Var,21877,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21877,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21877,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21877,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21877,GRP_SWC,SWC_DATE,20121211 -US-Var,21882,GRP_SWC,SWC,26.9 -US-Var,21882,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.9571306346 -US-Var,21882,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21882,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21882,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21882,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21882,GRP_SWC,SWC_DATE,20130101 -US-Var,21342,GRP_SWC,SWC,26.95 -US-Var,21342,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.6769552622 -US-Var,21342,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21342,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21342,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21342,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21342,GRP_SWC,SWC_DATE,20041120 -US-Var,21463,GRP_SWC,SWC,26.95 -US-Var,21463,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.1112698372 -US-Var,21463,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21463,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21463,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21463,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21463,GRP_SWC,SWC_DATE,20060504 -US-Var,21498,GRP_SWC,SWC,26.95 -US-Var,21498,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.9091883092 -US-Var,21498,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21498,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21498,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21498,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21498,GRP_SWC,SWC_DATE,20070204 -US-Var,21147,GRP_SWC,SWC,27 -US-Var,21147,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.5927248644 -US-Var,21147,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21147,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21147,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21147,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21147,GRP_SWC,SWC_DATE,20030227 -US-Var,21277,GRP_SWC,SWC,27.033333333 -US-Var,21277,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.8925565099 -US-Var,21277,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21277,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21277,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21277,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21277,GRP_SWC,SWC_DATE,20040305 -US-Var,21881,GRP_SWC,SWC,27.0375 -US-Var,21881,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.8767091021 -US-Var,21881,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21881,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21881,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21881,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21881,GRP_SWC,SWC_DATE,20130101 -US-Var,21563,GRP_SWC,SWC,27.1726 -US-Var,21563,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.5793583511 -US-Var,21563,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21563,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21563,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21563,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21563,GRP_SWC,SWC_DATE,20080712 -US-Var,21446,GRP_SWC,SWC,27.325 -US-Var,21446,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.60104076401 -US-Var,21446,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21446,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21446,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21446,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21446,GRP_SWC,SWC_DATE,20060223 -US-Var,21151,GRP_SWC,SWC,27.383333333 -US-Var,21151,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.3234018716 -US-Var,21151,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21151,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21151,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21151,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21151,GRP_SWC,SWC_DATE,20030317 -US-Var,21671,GRP_SWC,SWC,27.4 -US-Var,21671,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.70710678119 -US-Var,21671,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21671,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21671,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21671,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21671,GRP_SWC,SWC_DATE,20100108 -US-Var,21670,GRP_SWC,SWC,27.425 -US-Var,21670,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.0253048327 -US-Var,21670,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21670,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21670,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21670,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21670,GRP_SWC,SWC_DATE,20100108 -US-Var,21154,GRP_SWC,SWC,27.433333333 -US-Var,21154,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.9126575226 -US-Var,21154,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21154,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21154,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21154,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21154,GRP_SWC,SWC_DATE,20030405 -US-Var,21458,GRP_SWC,SWC,27.466666667 -US-Var,21458,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.4682924412 -US-Var,21458,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21458,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21458,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21458,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21458,GRP_SWC,SWC_DATE,20060418 -US-Var,21271,GRP_SWC,SWC,27.5 -US-Var,21271,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.7577164466 -US-Var,21271,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21271,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21271,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21271,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21271,GRP_SWC,SWC_DATE,20040123 -US-Var,21448,GRP_SWC,SWC,27.5 -US-Var,21448,GRP_SWC,SWC_SPATIAL_VARIABILITY,9.52237132 -US-Var,21448,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21448,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21448,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21448,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21448,GRP_SWC,SWC_DATE,20060308 -US-Var,21386,GRP_SWC,SWC,27.525 -US-Var,21386,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.4395183951 -US-Var,21386,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21386,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21386,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21386,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21386,GRP_SWC,SWC_DATE,20050410 -US-Var,21615,GRP_SWC,SWC,27.575 -US-Var,21615,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.5001785669 -US-Var,21615,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21615,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21615,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21615,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21615,GRP_SWC,SWC_DATE,20090403 -US-Var,21019,GRP_SWC,SWC,27.616666667 -US-Var,21019,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.5320646926 -US-Var,21019,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21019,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21019,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21019,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21019,GRP_SWC,SWC_DATE,20020320 -US-Var,21146,GRP_SWC,SWC,27.7 -US-Var,21146,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.1112698372 -US-Var,21146,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21146,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21146,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21146,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21146,GRP_SWC,SWC_DATE,20030227 -US-Var,21374,GRP_SWC,SWC,27.7 -US-Var,21374,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.2526911935 -US-Var,21374,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21374,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21374,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21374,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21374,GRP_SWC,SWC_DATE,20050226 -US-Var,21141,GRP_SWC,SWC,27.75 -US-Var,21141,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.3334523779 -US-Var,21141,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21141,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21141,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21141,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21141,GRP_SWC,SWC_DATE,20030221 -US-Var,21354,GRP_SWC,SWC,27.75 -US-Var,21354,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.1819805153 -US-Var,21354,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21354,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21354,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21354,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21354,GRP_SWC,SWC_DATE,20041215 -US-Var,21165,GRP_SWC,SWC,27.85 -US-Var,21165,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.0506096654 -US-Var,21165,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21165,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21165,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21165,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21165,GRP_SWC,SWC_DATE,20030430 -US-Var,21543,GRP_SWC,SWC,27.866666667 -US-Var,21543,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.2055507414 -US-Var,21543,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21543,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21543,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21543,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21543,GRP_SWC,SWC_DATE,20080404 -US-Var,21676,GRP_SWC,SWC,27.916666667 -US-Var,21676,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.96637926762 -US-Var,21676,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21676,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21676,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21676,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21676,GRP_SWC,SWC_DATE,20100305 -US-Var,21891,GRP_SWC,SWC,27.925 -US-Var,21891,GRP_SWC,SWC_SPATIAL_VARIABILITY,9.1175197651 -US-Var,21891,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21891,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21891,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21891,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21891,GRP_SWC,SWC_DATE,20130206 -US-Var,21699,GRP_SWC,SWC,27.933333333 -US-Var,21699,GRP_SWC,SWC_SPATIAL_REP_NUMBER,1 -US-Var,21699,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21699,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21699,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21699,GRP_SWC,SWC_DATE,20100610 -US-Var,22033,GRP_SWC,SWC,27.95 -US-Var,22033,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.4440770413 -US-Var,22033,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,22033,GRP_SWC,SWC_UNIT,Volumetric -US-Var,22033,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,22033,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,22033,GRP_SWC,SWC_DATE,20141223 -US-Var,21149,GRP_SWC,SWC,27.983333333 -US-Var,21149,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.3705423237 -US-Var,21149,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21149,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21149,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21149,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21149,GRP_SWC,SWC_DATE,20030317 -US-Var,21258,GRP_SWC,SWC,28.05 -US-Var,21258,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.7577164466 -US-Var,21258,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21258,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21258,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21258,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21258,GRP_SWC,SWC_DATE,20031219 -US-Var,21359,GRP_SWC,SWC,28.05 -US-Var,21359,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.0135197197 -US-Var,21359,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21359,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21359,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21359,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21359,GRP_SWC,SWC_DATE,20041226 -US-Var,21259,GRP_SWC,SWC,28.1 -US-Var,21259,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.5556349186 -US-Var,21259,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21259,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21259,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21259,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21259,GRP_SWC,SWC_DATE,20031219 -US-Var,21366,GRP_SWC,SWC,28.1 -US-Var,21366,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.9497474683 -US-Var,21366,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21366,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21366,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21366,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21366,GRP_SWC,SWC_DATE,20050127 -US-Var,21159,GRP_SWC,SWC,28.15 -US-Var,21159,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.7206265009 -US-Var,21159,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21159,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21159,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21159,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21159,GRP_SWC,SWC_DATE,20030416 -US-Var,21350,GRP_SWC,SWC,28.15 -US-Var,21350,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.3334523779 -US-Var,21350,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21350,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21350,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21350,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21350,GRP_SWC,SWC_DATE,20041212 -US-Var,21270,GRP_SWC,SWC,28.175 -US-Var,21270,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.570889245 -US-Var,21270,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21270,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21270,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21270,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21270,GRP_SWC,SWC_DATE,20040123 -US-Var,21343,GRP_SWC,SWC,28.225 -US-Var,21343,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.1767766953 -US-Var,21343,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21343,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21343,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21343,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21343,GRP_SWC,SWC_DATE,20041120 -US-Var,21143,GRP_SWC,SWC,28.235 -US-Var,21143,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.2132442251 -US-Var,21143,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21143,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21143,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21143,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21143,GRP_SWC,SWC_DATE,20030221 -US-Var,21163,GRP_SWC,SWC,28.25 -US-Var,21163,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.0977501175 -US-Var,21163,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21163,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21163,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21163,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21163,GRP_SWC,SWC_DATE,20030425 -US-Var,21672,GRP_SWC,SWC,28.283333333 -US-Var,21672,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.814907405 -US-Var,21672,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21672,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21672,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21672,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21672,GRP_SWC,SWC_DATE,20100210 -US-Var,21346,GRP_SWC,SWC,28.35 -US-Var,21346,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.1819805153 -US-Var,21346,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21346,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21346,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21346,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21346,GRP_SWC,SWC_DATE,20041128 -US-Var,21387,GRP_SWC,SWC,28.375 -US-Var,21387,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.1767766953 -US-Var,21387,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21387,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21387,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21387,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21387,GRP_SWC,SWC_DATE,20050410 -US-Var,21707,GRP_SWC,SWC,28.4 -US-Var,21707,GRP_SWC,SWC_SPATIAL_REP_NUMBER,1 -US-Var,21707,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21707,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21707,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21707,GRP_SWC,SWC_DATE,20100814 -US-Var,21715,GRP_SWC,SWC,28.4 -US-Var,21715,GRP_SWC,SWC_SPATIAL_REP_NUMBER,1 -US-Var,21715,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21715,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21715,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21715,GRP_SWC,SWC_DATE,20101007 -US-Var,21378,GRP_SWC,SWC,28.5 -US-Var,21378,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.4849242405 -US-Var,21378,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21378,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21378,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21378,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21378,GRP_SWC,SWC_DATE,20050309 -US-Var,21711,GRP_SWC,SWC,28.5 -US-Var,21711,GRP_SWC,SWC_SPATIAL_REP_NUMBER,1 -US-Var,21711,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21711,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21711,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21711,GRP_SWC,SWC_DATE,20100902 -US-Var,21362,GRP_SWC,SWC,28.516666667 -US-Var,21362,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.559104132 -US-Var,21362,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21362,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21362,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21362,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21362,GRP_SWC,SWC_DATE,20050117 -US-Var,21370,GRP_SWC,SWC,28.55 -US-Var,21370,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.6162950904 -US-Var,21370,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21370,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21370,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21370,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21370,GRP_SWC,SWC_DATE,20050208 -US-Var,21158,GRP_SWC,SWC,28.583333333 -US-Var,21158,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.2291209674 -US-Var,21158,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21158,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21158,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21158,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21158,GRP_SWC,SWC_DATE,20030416 -US-Var,21015,GRP_SWC,SWC,28.6 -US-Var,21015,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.6027753707 -US-Var,21015,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21015,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21015,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21015,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21015,GRP_SWC,SWC_DATE,20020228 -US-Var,21009,GRP_SWC,SWC,28.625 -US-Var,21009,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.8135299321 -US-Var,21009,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21009,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21009,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21009,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21009,GRP_SWC,SWC_DATE,20020208 -US-Var,21135,GRP_SWC,SWC,28.666666667 -US-Var,21135,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.4142135624 -US-Var,21135,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21135,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21135,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21135,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21135,GRP_SWC,SWC_DATE,20030129 -US-Var,21134,GRP_SWC,SWC,28.683333333 -US-Var,21134,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.8048568987 -US-Var,21134,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21134,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21134,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21134,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21134,GRP_SWC,SWC_DATE,20030129 -US-Var,21278,GRP_SWC,SWC,28.75 -US-Var,21278,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.1819805153 -US-Var,21278,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21278,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21278,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21278,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21278,GRP_SWC,SWC_DATE,20040305 -US-Var,21493,GRP_SWC,SWC,28.775 -US-Var,21493,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.9344931419 -US-Var,21493,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21493,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21493,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21493,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21493,GRP_SWC,SWC_DATE,20070119 -US-Var,21127,GRP_SWC,SWC,28.833333333 -US-Var,21127,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.4142135624 -US-Var,21127,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21127,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21127,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21127,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21127,GRP_SWC,SWC_DATE,20021223 -US-Var,21375,GRP_SWC,SWC,28.9 -US-Var,21375,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21375,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21375,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21375,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21375,GRP_SWC,SWC_DATE,20050226 -US-Var,21351,GRP_SWC,SWC,28.933333333 -US-Var,21351,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.18856180832 -US-Var,21351,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21351,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21351,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21351,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21351,GRP_SWC,SWC_DATE,20041212 -US-Var,21437,GRP_SWC,SWC,28.95 -US-Var,21437,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.3334523779 -US-Var,21437,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21437,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21437,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21437,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21437,GRP_SWC,SWC_DATE,20060124 -US-Var,21142,GRP_SWC,SWC,28.965 -US-Var,21142,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.0617723625 -US-Var,21142,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21142,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21142,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21142,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21142,GRP_SWC,SWC_DATE,20030221 -US-Var,21150,GRP_SWC,SWC,28.966666667 -US-Var,21150,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.7812866727 -US-Var,21150,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21150,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21150,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21150,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21150,GRP_SWC,SWC_DATE,20030317 -US-Var,21975,GRP_SWC,SWC,28.9875 -US-Var,21975,GRP_SWC,SWC_SPATIAL_VARIABILITY,9.575609206 -US-Var,21975,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21975,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21975,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21975,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21975,GRP_SWC,SWC_DATE,20140318 -US-Var,21028,GRP_SWC,SWC,29 -US-Var,21028,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.1213203436 -US-Var,21028,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21028,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21028,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21028,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21028,GRP_SWC,SWC_DATE,20020411 -US-Var,21379,GRP_SWC,SWC,29.05 -US-Var,21379,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.77781745931 -US-Var,21379,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21379,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21379,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21379,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21379,GRP_SWC,SWC_DATE,20050309 -US-Var,21262,GRP_SWC,SWC,29.066666667 -US-Var,21262,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.7812866727 -US-Var,21262,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21262,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21262,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21262,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21262,GRP_SWC,SWC_DATE,20031231 -US-Var,21279,GRP_SWC,SWC,29.083333333 -US-Var,21279,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.2863119258 -US-Var,21279,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21279,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21279,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21279,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21279,GRP_SWC,SWC_DATE,20040305 -US-Var,21689,GRP_SWC,SWC,29.125 -US-Var,21689,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.4395183951 -US-Var,21689,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21689,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21689,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21689,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21689,GRP_SWC,SWC_DATE,20100430 -US-Var,21131,GRP_SWC,SWC,29.133333333 -US-Var,21131,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.4613540145 -US-Var,21131,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21131,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21131,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21131,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21131,GRP_SWC,SWC_DATE,20030104 -US-Var,21018,GRP_SWC,SWC,29.166666667 -US-Var,21018,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.6398653164 -US-Var,21018,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21018,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21018,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21018,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21018,GRP_SWC,SWC_DATE,20020320 -US-Var,21255,GRP_SWC,SWC,29.183333333 -US-Var,21255,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.2863119258 -US-Var,21255,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21255,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21255,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21255,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21255,GRP_SWC,SWC_DATE,20031215 -US-Var,22034,GRP_SWC,SWC,29.1875 -US-Var,22034,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.0174039597 -US-Var,22034,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,22034,GRP_SWC,SWC_UNIT,Volumetric -US-Var,22034,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,22034,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,22034,GRP_SWC,SWC_DATE,20141223 -US-Var,21673,GRP_SWC,SWC,29.266666667 -US-Var,21673,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.2256517541 -US-Var,21673,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21673,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21673,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21673,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21673,GRP_SWC,SWC_DATE,20100210 -US-Var,21254,GRP_SWC,SWC,29.4 -US-Var,21254,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.6870057685 -US-Var,21254,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21254,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21254,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21254,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21254,GRP_SWC,SWC_DATE,20031215 -US-Var,21275,GRP_SWC,SWC,29.45 -US-Var,21275,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.4849242405 -US-Var,21275,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21275,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21275,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21275,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21275,GRP_SWC,SWC_DATE,20040130 -US-Var,21126,GRP_SWC,SWC,29.5 -US-Var,21126,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.2526911935 -US-Var,21126,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21126,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21126,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21126,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21126,GRP_SWC,SWC_DATE,20021223 -US-Var,21274,GRP_SWC,SWC,29.5 -US-Var,21274,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.3234018716 -US-Var,21274,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21274,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21274,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21274,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21274,GRP_SWC,SWC_DATE,20040130 -US-Var,21355,GRP_SWC,SWC,29.5 -US-Var,21355,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.80138768534 -US-Var,21355,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21355,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21355,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21355,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21355,GRP_SWC,SWC_DATE,20041215 -US-Var,21494,GRP_SWC,SWC,29.533333333 -US-Var,21494,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.0842303978 -US-Var,21494,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21494,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21494,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21494,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21494,GRP_SWC,SWC_DATE,20070119 -US-Var,21014,GRP_SWC,SWC,29.55 -US-Var,21014,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.7577164466 -US-Var,21014,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21014,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21014,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21014,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21014,GRP_SWC,SWC_DATE,20020228 -US-Var,21167,GRP_SWC,SWC,29.55 -US-Var,21167,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.4748737342 -US-Var,21167,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21167,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21167,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21167,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21167,GRP_SWC,SWC_DATE,20030430 -US-Var,21449,GRP_SWC,SWC,29.583333333 -US-Var,21449,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.5691546383 -US-Var,21449,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21449,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21449,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21449,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21449,GRP_SWC,SWC_DATE,20060308 -US-Var,21371,GRP_SWC,SWC,29.6 -US-Var,21371,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.18856180832 -US-Var,21371,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21371,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21371,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21371,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21371,GRP_SWC,SWC_DATE,20050208 -US-Var,21263,GRP_SWC,SWC,29.666666667 -US-Var,21263,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.6027753707 -US-Var,21263,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21263,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21263,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21263,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21263,GRP_SWC,SWC_DATE,20031231 -US-Var,21347,GRP_SWC,SWC,29.7 -US-Var,21347,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21347,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21347,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21347,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21347,GRP_SWC,SWC_DATE,20041128 -US-Var,21166,GRP_SWC,SWC,29.725 -US-Var,21166,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.7930717857 -US-Var,21166,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21166,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21166,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21166,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21166,GRP_SWC,SWC_DATE,20030430 -US-Var,21823,GRP_SWC,SWC,29.85 -US-Var,21823,GRP_SWC,SWC_SPATIAL_VARIABILITY,9.5619035762 -US-Var,21823,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21823,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21823,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21823,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21823,GRP_SWC,SWC_DATE,20120302 -US-Var,21438,GRP_SWC,SWC,29.95 -US-Var,21438,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.070710678119 -US-Var,21438,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21438,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21438,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21438,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21438,GRP_SWC,SWC_DATE,20060124 -US-Var,21700,GRP_SWC,SWC,3 -US-Var,21700,GRP_SWC,SWC_SPATIAL_REP_NUMBER,1 -US-Var,21700,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21700,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21700,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21700,GRP_SWC,SWC_DATE,20100624 -US-Var,21472,GRP_SWC,SWC,3.0166666667 -US-Var,21472,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.87209836346 -US-Var,21472,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21472,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21472,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21472,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21472,GRP_SWC,SWC_DATE,20060801 -US-Var,21041,GRP_SWC,SWC,3.0333333333 -US-Var,21041,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.094280904158 -US-Var,21041,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21041,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21041,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21041,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21041,GRP_SWC,SWC_DATE,20020509 -US-Var,21836,GRP_SWC,SWC,3.0666666667 -US-Var,21836,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.0067940159 -US-Var,21836,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21836,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21836,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21836,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21836,GRP_SWC,SWC_DATE,20120518 -US-Var,21057,GRP_SWC,SWC,3.0833333333 -US-Var,21057,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.070710678119 -US-Var,21057,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21057,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21057,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21057,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21057,GRP_SWC,SWC_DATE,20020620 -US-Var,21544,GRP_SWC,SWC,3.1333333333 -US-Var,21544,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.75424723327 -US-Var,21544,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21544,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21544,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21544,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21544,GRP_SWC,SWC_DATE,20080420 -US-Var,21696,GRP_SWC,SWC,3.1333333333 -US-Var,21696,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.7441967269 -US-Var,21696,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21696,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21696,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21696,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21696,GRP_SWC,SWC_DATE,20100610 -US-Var,22016,GRP_SWC,SWC,3.175 -US-Var,22016,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.2227985364 -US-Var,22016,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,22016,GRP_SWC,SWC_UNIT,Volumetric -US-Var,22016,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,22016,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,22016,GRP_SWC,SWC_DATE,20141024 -US-Var,21464,GRP_SWC,SWC,3.25 -US-Var,21464,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.0606601718 -US-Var,21464,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21464,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21464,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21464,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21464,GRP_SWC,SWC_DATE,20060512 -US-Var,21808,GRP_SWC,SWC,3.3875 -US-Var,21808,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.9758402175 -US-Var,21808,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21808,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21808,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21808,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21808,GRP_SWC,SWC_DATE,20120118 -US-Var,21225,GRP_SWC,SWC,3.4 -US-Var,21225,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.4142135624 -US-Var,21225,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21225,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21225,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21225,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21225,GRP_SWC,SWC_DATE,20030905 -US-Var,21221,GRP_SWC,SWC,3.4166666667 -US-Var,21221,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.25927248644 -US-Var,21221,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21221,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21221,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21221,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21221,GRP_SWC,SWC_DATE,20030816 -US-Var,21322,GRP_SWC,SWC,3.55 -US-Var,21322,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.9091883092 -US-Var,21322,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21322,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21322,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21322,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21322,GRP_SWC,SWC_DATE,20040817 -US-Var,21941,GRP_SWC,SWC,3.5958333333 -US-Var,21941,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.7773458677 -US-Var,21941,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21941,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21941,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21941,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21941,GRP_SWC,SWC_DATE,20130925 -US-Var,21334,GRP_SWC,SWC,3.625 -US-Var,21334,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.4395183951 -US-Var,21334,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21334,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21334,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21334,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21334,GRP_SWC,SWC_DATE,20041013 -US-Var,21528,GRP_SWC,SWC,3.65 -US-Var,21528,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.1313708499 -US-Var,21528,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21528,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21528,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21528,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21528,GRP_SWC,SWC_DATE,20071107 -US-Var,21301,GRP_SWC,SWC,3.75 -US-Var,21301,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.9091883092 -US-Var,21301,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21301,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21301,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21301,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21301,GRP_SWC,SWC_DATE,20040522 -US-Var,21293,GRP_SWC,SWC,3.8 -US-Var,21293,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.91923881554 -US-Var,21293,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21293,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21293,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21293,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21293,GRP_SWC,SWC_DATE,20040423 -US-Var,21326,GRP_SWC,SWC,3.8333333333 -US-Var,21326,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.8856180832 -US-Var,21326,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21326,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21326,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21326,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21326,GRP_SWC,SWC_DATE,20040908 -US-Var,21532,GRP_SWC,SWC,3.8616666667 -US-Var,21532,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.3169532197 -US-Var,21532,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21532,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21532,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21532,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21532,GRP_SWC,SWC_DATE,20071129 -US-Var,21441,GRP_SWC,SWC,30 -US-Var,21441,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.0911688245 -US-Var,21441,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21441,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21441,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21441,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21441,GRP_SWC,SWC_DATE,20060210 -US-Var,21979,GRP_SWC,SWC,30 -US-Var,21979,GRP_SWC,SWC_SPATIAL_VARIABILITY,9.5148130127 -US-Var,21979,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21979,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21979,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21979,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21979,GRP_SWC,SWC_DATE,20140408 -US-Var,21682,GRP_SWC,SWC,30.025 -US-Var,21682,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.1064231509 -US-Var,21682,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21682,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21682,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21682,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21682,GRP_SWC,SWC_DATE,20100321 -US-Var,21966,GRP_SWC,SWC,30.0375 -US-Var,21966,GRP_SWC,SWC_SPATIAL_VARIABILITY,11.988770788 -US-Var,21966,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21966,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21966,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21966,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21966,GRP_SWC,SWC_DATE,20140210 -US-Var,21970,GRP_SWC,SWC,30.0375 -US-Var,21970,GRP_SWC,SWC_SPATIAL_VARIABILITY,11.988770788 -US-Var,21970,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21970,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21970,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21970,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21970,GRP_SWC,SWC_DATE,20140304 -US-Var,21162,GRP_SWC,SWC,30.05 -US-Var,21162,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.6062445841 -US-Var,21162,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21162,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21162,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21162,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21162,GRP_SWC,SWC_DATE,20030425 -US-Var,21605,GRP_SWC,SWC,30.058333333 -US-Var,21605,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.6752206555 -US-Var,21605,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21605,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21605,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21605,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21605,GRP_SWC,SWC_DATE,20090227 -US-Var,21161,GRP_SWC,SWC,30.083333333 -US-Var,21161,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.4547727215 -US-Var,21161,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21161,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21161,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21161,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21161,GRP_SWC,SWC_DATE,20030425 -US-Var,21489,GRP_SWC,SWC,30.116666667 -US-Var,21489,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.4277332821 -US-Var,21489,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21489,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21489,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21489,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21489,GRP_SWC,SWC_DATE,20070110 -US-Var,21363,GRP_SWC,SWC,30.133333333 -US-Var,21363,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.047140452079 -US-Var,21363,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21363,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21363,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21363,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21363,GRP_SWC,SWC_DATE,20050117 -US-Var,20999,GRP_SWC,SWC,30.166666667 -US-Var,20999,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.51854497287 -US-Var,20999,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,20999,GRP_SWC,SWC_UNIT,Volumetric -US-Var,20999,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,20999,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,20999,GRP_SWC,SWC_DATE,20011205 -US-Var,21453,GRP_SWC,SWC,30.25 -US-Var,21453,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.4748737342 -US-Var,21453,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21453,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21453,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21453,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21453,GRP_SWC,SWC_DATE,20060330 -US-Var,21011,GRP_SWC,SWC,30.275 -US-Var,21011,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.9545941546 -US-Var,21011,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21011,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21011,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21011,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21011,GRP_SWC,SWC_DATE,20020208 -US-Var,21003,GRP_SWC,SWC,30.45 -US-Var,21003,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.35355339059 -US-Var,21003,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21003,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21003,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21003,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21003,GRP_SWC,SWC_DATE,20011219 -US-Var,21383,GRP_SWC,SWC,30.45 -US-Var,21383,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.77781745931 -US-Var,21383,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21383,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21383,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21383,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21383,GRP_SWC,SWC_DATE,20050324 -US-Var,21501,GRP_SWC,SWC,30.483333333 -US-Var,21501,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.5220141862 -US-Var,21501,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21501,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21501,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21501,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21501,GRP_SWC,SWC_DATE,20070302 -US-Var,21130,GRP_SWC,SWC,30.533333333 -US-Var,21130,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.0741798915 -US-Var,21130,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21130,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21130,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21130,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21130,GRP_SWC,SWC_DATE,20030104 -US-Var,21367,GRP_SWC,SWC,30.6 -US-Var,21367,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.70710678119 -US-Var,21367,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21367,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21367,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21367,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21367,GRP_SWC,SWC_DATE,20050127 -US-Var,21007,GRP_SWC,SWC,30.616666667 -US-Var,21007,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.77781745931 -US-Var,21007,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21007,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21007,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21007,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21007,GRP_SWC,SWC_DATE,20020115 -US-Var,21382,GRP_SWC,SWC,30.65 -US-Var,21382,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.7476659403 -US-Var,21382,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21382,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21382,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21382,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21382,GRP_SWC,SWC_DATE,20050324 -US-Var,21674,GRP_SWC,SWC,30.716666667 -US-Var,21674,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.9833682007 -US-Var,21674,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21674,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21674,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21674,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21674,GRP_SWC,SWC_DATE,20100210 -US-Var,21454,GRP_SWC,SWC,30.8 -US-Var,21454,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.37712361663 -US-Var,21454,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21454,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21454,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21454,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21454,GRP_SWC,SWC_DATE,20060330 -US-Var,21677,GRP_SWC,SWC,30.816666667 -US-Var,21677,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.2863119258 -US-Var,21677,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21677,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21677,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21677,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21677,GRP_SWC,SWC_DATE,20100305 -US-Var,21602,GRP_SWC,SWC,30.833333333 -US-Var,21602,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.0069384267 -US-Var,21602,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21602,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21602,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21602,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21602,GRP_SWC,SWC_DATE,20090210 -US-Var,21442,GRP_SWC,SWC,30.866666667 -US-Var,21442,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.2897811392 -US-Var,21442,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21442,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21442,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21442,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21442,GRP_SWC,SWC_DATE,20060210 -US-Var,21450,GRP_SWC,SWC,30.883333333 -US-Var,21450,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.1178511302 -US-Var,21450,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21450,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21450,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21450,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21450,GRP_SWC,SWC_DATE,20060308 -US-Var,21490,GRP_SWC,SWC,30.916666667 -US-Var,21490,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.30641293851 -US-Var,21490,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21490,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21490,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21490,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21490,GRP_SWC,SWC_DATE,20070110 -US-Var,21611,GRP_SWC,SWC,30.95 -US-Var,21611,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.2526911935 -US-Var,21611,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21611,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21611,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21611,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21611,GRP_SWC,SWC_DATE,20090327 -US-Var,21273,GRP_SWC,SWC,31 -US-Var,21273,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.4849242405 -US-Var,21273,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21273,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21273,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21273,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21273,GRP_SWC,SWC_DATE,20040130 -US-Var,21499,GRP_SWC,SWC,31.25 -US-Var,21499,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.3133513652 -US-Var,21499,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21499,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21499,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21499,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21499,GRP_SWC,SWC_DATE,20070204 -US-Var,21537,GRP_SWC,SWC,31.35 -US-Var,21537,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.8890872965 -US-Var,21537,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21537,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21537,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21537,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21537,GRP_SWC,SWC_DATE,20080130 -US-Var,21887,GRP_SWC,SWC,31.395833333 -US-Var,21887,GRP_SWC,SWC_SPATIAL_VARIABILITY,8.3459945483 -US-Var,21887,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21887,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21887,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21887,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21887,GRP_SWC,SWC_DATE,20130116 -US-Var,21600,GRP_SWC,SWC,31.416666667 -US-Var,21600,GRP_SWC,SWC_SPATIAL_VARIABILITY,11.997245054 -US-Var,21600,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21600,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21600,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21600,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21600,GRP_SWC,SWC_DATE,20090210 -US-Var,21831,GRP_SWC,SWC,31.5125 -US-Var,21831,GRP_SWC,SWC_SPATIAL_VARIABILITY,9.9488169313 -US-Var,21831,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21831,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21831,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21831,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21831,GRP_SWC,SWC_DATE,20120405 -US-Var,21739,GRP_SWC,SWC,31.6 -US-Var,21739,GRP_SWC,SWC_SPATIAL_VARIABILITY,9.4798421615 -US-Var,21739,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21739,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21739,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21739,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21739,GRP_SWC,SWC_DATE,20110222 -US-Var,21690,GRP_SWC,SWC,31.625 -US-Var,21690,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.6617009358 -US-Var,21690,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21690,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21690,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21690,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21690,GRP_SWC,SWC_DATE,20100430 -US-Var,21360,GRP_SWC,SWC,31.65 -US-Var,21360,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.6634355425 -US-Var,21360,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21360,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21360,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21360,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21360,GRP_SWC,SWC_DATE,20041226 -US-Var,21433,GRP_SWC,SWC,31.866666667 -US-Var,21433,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.5996632911 -US-Var,21433,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21433,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21433,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21433,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21433,GRP_SWC,SWC_DATE,20060110 -US-Var,21507,GRP_SWC,SWC,31.875 -US-Var,21507,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.5001785669 -US-Var,21507,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21507,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21507,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21507,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21507,GRP_SWC,SWC_DATE,20070316 -US-Var,21006,GRP_SWC,SWC,31.883333333 -US-Var,21006,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.8620478571 -US-Var,21006,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21006,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21006,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21006,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21006,GRP_SWC,SWC_DATE,20020115 -US-Var,21152,GRP_SWC,SWC,32.016666667 -US-Var,21152,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.1078006239 -US-Var,21152,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21152,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21152,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21152,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21152,GRP_SWC,SWC_DATE,20030317 -US-Var,20998,GRP_SWC,SWC,32.05 -US-Var,20998,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.77781745931 -US-Var,20998,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,20998,GRP_SWC,SWC_UNIT,Volumetric -US-Var,20998,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,20998,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,20998,GRP_SWC,SWC_DATE,20011205 -US-Var,21388,GRP_SWC,SWC,32.05 -US-Var,21388,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.7577164466 -US-Var,21388,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21388,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21388,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21388,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21388,GRP_SWC,SWC_DATE,20050410 -US-Var,21447,GRP_SWC,SWC,32.05 -US-Var,21447,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.7577164466 -US-Var,21447,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21447,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21447,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21447,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21447,GRP_SWC,SWC_DATE,20060223 -US-Var,21502,GRP_SWC,SWC,32.083333333 -US-Var,21502,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.44783429475 -US-Var,21502,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21502,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21502,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21502,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21502,GRP_SWC,SWC_DATE,20070302 -US-Var,21747,GRP_SWC,SWC,32.0875 -US-Var,21747,GRP_SWC,SWC_SPATIAL_VARIABILITY,10.648581674 -US-Var,21747,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21747,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21747,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21747,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21747,GRP_SWC,SWC_DATE,20110330 -US-Var,21024,GRP_SWC,SWC,32.1 -US-Var,21024,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.4849242405 -US-Var,21024,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21024,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21024,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21024,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21024,GRP_SWC,SWC_DATE,20020404 -US-Var,21140,GRP_SWC,SWC,32.1 -US-Var,21140,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21140,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21140,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21140,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21140,GRP_SWC,SWC_DATE,20030213 -US-Var,21010,GRP_SWC,SWC,32.125 -US-Var,21010,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.0152543264 -US-Var,21010,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21010,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21010,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21010,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21010,GRP_SWC,SWC_DATE,20020208 -US-Var,21434,GRP_SWC,SWC,32.15 -US-Var,21434,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.9462782549 -US-Var,21434,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21434,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21434,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21434,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21434,GRP_SWC,SWC_DATE,20060110 -US-Var,21827,GRP_SWC,SWC,32.15 -US-Var,21827,GRP_SWC,SWC_SPATIAL_VARIABILITY,8.8764670149 -US-Var,21827,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21827,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21827,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21827,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21827,GRP_SWC,SWC_DATE,20120321 -US-Var,21879,GRP_SWC,SWC,32.358333333 -US-Var,21879,GRP_SWC,SWC_SPATIAL_VARIABILITY,8.3066405832 -US-Var,21879,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21879,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21879,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21879,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21879,GRP_SWC,SWC_DATE,20121211 -US-Var,21443,GRP_SWC,SWC,32.45 -US-Var,21443,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.3435028843 -US-Var,21443,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21443,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21443,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21443,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21443,GRP_SWC,SWC_DATE,20060210 -US-Var,21431,GRP_SWC,SWC,32.466666667 -US-Var,21431,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.94280904158 -US-Var,21431,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21431,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21431,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21431,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21431,GRP_SWC,SWC_DATE,20051229 -US-Var,21883,GRP_SWC,SWC,32.475 -US-Var,21883,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.8015489915 -US-Var,21883,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21883,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21883,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21883,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21883,GRP_SWC,SWC_DATE,20130101 -US-Var,21156,GRP_SWC,SWC,32.5 -US-Var,21156,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.70710678119 -US-Var,21156,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21156,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21156,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21156,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21156,GRP_SWC,SWC_DATE,20030405 -US-Var,21538,GRP_SWC,SWC,32.5 -US-Var,21538,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.56568542495 -US-Var,21538,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21538,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21538,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21538,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21538,GRP_SWC,SWC_DATE,20080130 -US-Var,21352,GRP_SWC,SWC,32.6 -US-Var,21352,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.4984439602 -US-Var,21352,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21352,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21352,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21352,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21352,GRP_SWC,SWC_DATE,20041212 -US-Var,22035,GRP_SWC,SWC,32.6625 -US-Var,22035,GRP_SWC,SWC_SPATIAL_VARIABILITY,8.5427722862 -US-Var,22035,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,22035,GRP_SWC,SWC_UNIT,Volumetric -US-Var,22035,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,22035,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,22035,GRP_SWC,SWC_DATE,20141223 -US-Var,21344,GRP_SWC,SWC,32.725 -US-Var,21344,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.1466251763 -US-Var,21344,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21344,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21344,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21344,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21344,GRP_SWC,SWC_DATE,20041120 -US-Var,21429,GRP_SWC,SWC,32.733333333 -US-Var,21429,GRP_SWC,SWC_SPATIAL_VARIABILITY,6.1282587703 -US-Var,21429,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21429,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21429,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21429,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21429,GRP_SWC,SWC_DATE,20051229 -US-Var,21435,GRP_SWC,SWC,32.8 -US-Var,21435,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.5556349186 -US-Var,21435,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21435,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21435,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21435,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21435,GRP_SWC,SWC_DATE,20060110 -US-Var,21965,GRP_SWC,SWC,32.8125 -US-Var,21965,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.3981767056 -US-Var,21965,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21965,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21965,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21965,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21965,GRP_SWC,SWC_DATE,20140210 -US-Var,21969,GRP_SWC,SWC,32.8125 -US-Var,21969,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.3981767056 -US-Var,21969,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21969,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21969,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21969,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21969,GRP_SWC,SWC_DATE,20140304 -US-Var,21002,GRP_SWC,SWC,32.85 -US-Var,21002,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.0506096654 -US-Var,21002,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21002,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21002,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21002,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21002,GRP_SWC,SWC_DATE,20011219 -US-Var,21348,GRP_SWC,SWC,32.9 -US-Var,21348,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.1112698372 -US-Var,21348,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21348,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21348,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21348,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21348,GRP_SWC,SWC_DATE,20041128 -US-Var,21606,GRP_SWC,SWC,32.95 -US-Var,21606,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.8689862838 -US-Var,21606,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21606,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21606,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21606,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21606,GRP_SWC,SWC_DATE,20090227 -US-Var,21372,GRP_SWC,SWC,33.016666667 -US-Var,21372,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.0876996112 -US-Var,21372,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21372,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21372,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21372,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21372,GRP_SWC,SWC_DATE,20050208 -US-Var,21376,GRP_SWC,SWC,33.05 -US-Var,21376,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.7577164466 -US-Var,21376,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21376,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21376,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21376,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21376,GRP_SWC,SWC_DATE,20050226 -US-Var,21356,GRP_SWC,SWC,33.116666667 -US-Var,21356,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.9462782549 -US-Var,21356,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21356,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21356,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21356,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21356,GRP_SWC,SWC_DATE,20041215 -US-Var,21364,GRP_SWC,SWC,33.15 -US-Var,21364,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.2391714738 -US-Var,21364,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21364,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21364,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21364,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21364,GRP_SWC,SWC_DATE,20050117 -US-Var,21380,GRP_SWC,SWC,33.225 -US-Var,21380,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.0759144982 -US-Var,21380,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21380,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21380,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21380,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21380,GRP_SWC,SWC_DATE,20050309 -US-Var,21284,GRP_SWC,SWC,33.283333333 -US-Var,21284,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.40069384267 -US-Var,21284,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21284,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21284,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21284,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21284,GRP_SWC,SWC_DATE,20040321 -US-Var,21430,GRP_SWC,SWC,33.283333333 -US-Var,21430,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.1247895569 -US-Var,21430,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21430,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21430,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21430,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21430,GRP_SWC,SWC_DATE,20051229 -US-Var,21384,GRP_SWC,SWC,33.3 -US-Var,21384,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.1112698372 -US-Var,21384,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21384,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21384,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21384,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21384,GRP_SWC,SWC_DATE,20050324 -US-Var,21148,GRP_SWC,SWC,33.366666667 -US-Var,21148,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.37712361663 -US-Var,21148,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21148,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21148,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21148,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21148,GRP_SWC,SWC_DATE,20030227 -US-Var,21439,GRP_SWC,SWC,33.45 -US-Var,21439,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.7577164466 -US-Var,21439,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21439,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21439,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21439,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21439,GRP_SWC,SWC_DATE,20060124 -US-Var,21459,GRP_SWC,SWC,33.466666667 -US-Var,21459,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.9327585352 -US-Var,21459,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21459,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21459,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21459,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21459,GRP_SWC,SWC_DATE,20060418 -US-Var,21495,GRP_SWC,SWC,33.75 -US-Var,21495,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.7476659403 -US-Var,21495,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21495,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21495,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21495,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21495,GRP_SWC,SWC_DATE,20070119 -US-Var,21368,GRP_SWC,SWC,33.816666667 -US-Var,21368,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.4176827757 -US-Var,21368,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21368,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21368,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21368,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21368,GRP_SWC,SWC_DATE,20050127 -US-Var,21172,GRP_SWC,SWC,33.85 -US-Var,21172,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.0135197197 -US-Var,21172,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21172,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21172,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21172,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21172,GRP_SWC,SWC_DATE,20030509 -US-Var,21451,GRP_SWC,SWC,33.883333333 -US-Var,21451,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.8991378029 -US-Var,21451,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21451,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21451,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21451,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21451,GRP_SWC,SWC_DATE,20060308 -US-Var,21719,GRP_SWC,SWC,33.966666667 -US-Var,21719,GRP_SWC,SWC_SPATIAL_REP_NUMBER,1 -US-Var,21719,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21719,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21719,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21719,GRP_SWC,SWC_DATE,20101028 -US-Var,21260,GRP_SWC,SWC,34 -US-Var,21260,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.42426406871 -US-Var,21260,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21260,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21260,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21260,GRP_SWC,SWC_PROFILE_MAX,60 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-US-Var,21455,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.8048568987 -US-Var,21455,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21455,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21455,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21455,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21455,GRP_SWC,SWC_DATE,20060330 -US-Var,21144,GRP_SWC,SWC,34.4 -US-Var,21144,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.18384776311 -US-Var,21144,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21144,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21144,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21144,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21144,GRP_SWC,SWC_DATE,20030221 -US-Var,21272,GRP_SWC,SWC,34.4 -US-Var,21272,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.14142135624 -US-Var,21272,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21272,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21272,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21272,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21272,GRP_SWC,SWC_DATE,20040123 -US-Var,21683,GRP_SWC,SWC,34.475 -US-Var,21683,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.0960155108 -US-Var,21683,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21683,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21683,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21683,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21683,GRP_SWC,SWC_DATE,20100321 -US-Var,21020,GRP_SWC,SWC,34.533333333 -US-Var,21020,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21020,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21020,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21020,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21020,GRP_SWC,SWC_DATE,20020320 -US-Var,21491,GRP_SWC,SWC,34.7 -US-Var,21491,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.6769552622 -US-Var,21491,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21491,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21491,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21491,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21491,GRP_SWC,SWC_DATE,20070110 -US-Var,21276,GRP_SWC,SWC,34.75 -US-Var,21276,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.49497474683 -US-Var,21276,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21276,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21276,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21276,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21276,GRP_SWC,SWC_DATE,20040130 -US-Var,21264,GRP_SWC,SWC,34.766666667 -US-Var,21264,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.047140452079 -US-Var,21264,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21264,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21264,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21264,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21264,GRP_SWC,SWC_DATE,20031231 -US-Var,21000,GRP_SWC,SWC,34.783333333 -US-Var,21000,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.35355339059 -US-Var,21000,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21000,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21000,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21000,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21000,GRP_SWC,SWC_DATE,20011205 -US-Var,21687,GRP_SWC,SWC,34.825 -US-Var,21687,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.166726189 -US-Var,21687,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21687,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21687,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21687,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21687,GRP_SWC,SWC_DATE,20100402 -US-Var,21256,GRP_SWC,SWC,34.925 -US-Var,21256,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.45961940777 -US-Var,21256,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21256,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21256,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21256,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21256,GRP_SWC,SWC_DATE,20031215 -US-Var,21160,GRP_SWC,SWC,35.05 -US-Var,21160,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.49497474683 -US-Var,21160,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21160,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21160,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21160,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21160,GRP_SWC,SWC_DATE,20030416 -US-Var,21128,GRP_SWC,SWC,35.116666667 -US-Var,21128,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.44783429475 -US-Var,21128,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21128,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21128,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21128,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21128,GRP_SWC,SWC_DATE,20021223 -US-Var,21967,GRP_SWC,SWC,35.175 -US-Var,21967,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.3731585993 -US-Var,21967,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21967,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21967,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21967,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21967,GRP_SWC,SWC_DATE,20140210 -US-Var,21971,GRP_SWC,SWC,35.175 -US-Var,21971,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.3731585993 -US-Var,21971,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21971,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21971,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21971,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21971,GRP_SWC,SWC_DATE,20140304 -US-Var,21004,GRP_SWC,SWC,35.233333333 -US-Var,21004,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.32998316455 -US-Var,21004,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21004,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21004,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21004,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21004,GRP_SWC,SWC_DATE,20011219 -US-Var,21016,GRP_SWC,SWC,35.3 -US-Var,21016,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21016,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21016,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21016,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21016,GRP_SWC,SWC_DATE,20020228 -US-Var,21164,GRP_SWC,SWC,35.383333333 -US-Var,21164,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.1549410759 -US-Var,21164,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21164,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21164,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21164,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21164,GRP_SWC,SWC_DATE,20030425 -US-Var,21008,GRP_SWC,SWC,35.416666667 -US-Var,21008,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.58925565099 -US-Var,21008,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21008,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21008,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21008,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21008,GRP_SWC,SWC_DATE,20020115 -US-Var,21280,GRP_SWC,SWC,35.416666667 -US-Var,21280,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.40069384267 -US-Var,21280,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21280,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21280,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21280,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21280,GRP_SWC,SWC_DATE,20040305 -US-Var,21012,GRP_SWC,SWC,35.45 -US-Var,21012,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.28284271247 -US-Var,21012,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21012,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21012,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21012,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21012,GRP_SWC,SWC_DATE,20020208 -US-Var,21168,GRP_SWC,SWC,35.5 -US-Var,21168,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.56568542495 -US-Var,21168,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21168,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21168,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21168,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21168,GRP_SWC,SWC_DATE,20030430 -US-Var,21132,GRP_SWC,SWC,35.566666667 -US-Var,21132,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.51854497287 -US-Var,21132,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21132,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21132,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21132,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21132,GRP_SWC,SWC_DATE,20030104 -US-Var,21503,GRP_SWC,SWC,35.816666667 -US-Var,21503,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.1348400633 -US-Var,21503,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21503,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21503,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21503,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21503,GRP_SWC,SWC_DATE,20070302 -US-Var,21727,GRP_SWC,SWC,35.983333333 -US-Var,21727,GRP_SWC,SWC_SPATIAL_VARIABILITY,7.1579210203 -US-Var,21727,GRP_SWC,SWC_SPATIAL_REP_NUMBER,3 -US-Var,21727,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21727,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21727,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21727,GRP_SWC,SWC_DATE,20101202 -US-Var,21539,GRP_SWC,SWC,36.7 -US-Var,21539,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.8384776311 -US-Var,21539,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21539,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21539,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21539,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21539,GRP_SWC,SWC_DATE,20080130 -US-Var,21607,GRP_SWC,SWC,36.875 -US-Var,21607,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.88388347648 -US-Var,21607,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21607,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21607,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21607,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21607,GRP_SWC,SWC_DATE,20090227 -US-Var,21267,GRP_SWC,SWC,37.3 -US-Var,21267,GRP_SWC,SWC_SPATIAL_REP_NUMBER,1 -US-Var,21267,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21267,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21267,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21267,GRP_SWC,SWC_DATE,20040108 -US-Var,21675,GRP_SWC,SWC,37.333333333 -US-Var,21675,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.1313708499 -US-Var,21675,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21675,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21675,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21675,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21675,GRP_SWC,SWC_DATE,20100210 -US-Var,21265,GRP_SWC,SWC,37.4 -US-Var,21265,GRP_SWC,SWC_SPATIAL_REP_NUMBER,1 -US-Var,21265,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21265,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21265,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21265,GRP_SWC,SWC_DATE,20040108 -US-Var,21743,GRP_SWC,SWC,37.766666667 -US-Var,21743,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.5315258092 -US-Var,21743,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21743,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21743,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21743,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21743,GRP_SWC,SWC_DATE,20110308 -US-Var,21691,GRP_SWC,SWC,37.825 -US-Var,21691,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.6415999231 -US-Var,21691,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21691,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21691,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21691,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21691,GRP_SWC,SWC_DATE,20100430 -US-Var,21603,GRP_SWC,SWC,38.1 -US-Var,21603,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.6669047558 -US-Var,21603,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21603,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21603,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21603,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21603,GRP_SWC,SWC_DATE,20090210 -US-Var,21268,GRP_SWC,SWC,39 -US-Var,21268,GRP_SWC,SWC_SPATIAL_REP_NUMBER,1 -US-Var,21268,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21268,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21268,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21268,GRP_SWC,SWC_DATE,20040108 -US-Var,21730,GRP_SWC,SWC,39.025 -US-Var,21730,GRP_SWC,SWC_SPATIAL_VARIABILITY,25.223715692 -US-Var,21730,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21730,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21730,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21730,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21730,GRP_SWC,SWC_DATE,20101230 -US-Var,21734,GRP_SWC,SWC,39.025 -US-Var,21734,GRP_SWC,SWC_SPATIAL_VARIABILITY,25.223715692 -US-Var,21734,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21734,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21734,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21734,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21734,GRP_SWC,SWC_DATE,20110119 -US-Var,21053,GRP_SWC,SWC,4 -US-Var,21053,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.14142135624 -US-Var,21053,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21053,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21053,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21053,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21053,GRP_SWC,SWC_DATE,20020613 -US-Var,21592,GRP_SWC,SWC,4.05 -US-Var,21592,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.0405591591 -US-Var,21592,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21592,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21592,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21592,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21592,GRP_SWC,SWC_DATE,20081211 -US-Var,21937,GRP_SWC,SWC,4.1125 -US-Var,21937,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.3407174826 -US-Var,21937,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21937,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21937,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21937,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21937,GRP_SWC,SWC_DATE,20130904 -US-Var,21468,GRP_SWC,SWC,4.1666666667 -US-Var,21468,GRP_SWC,SWC_SPATIAL_REP_NUMBER,1 -US-Var,21468,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21468,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21468,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21468,GRP_SWC,SWC_DATE,20060608 -US-Var,21401,GRP_SWC,SWC,4.2041666667 -US-Var,21401,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.88977603299 -US-Var,21401,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21401,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21401,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21401,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21401,GRP_SWC,SWC_DATE,20050623 -US-Var,21318,GRP_SWC,SWC,4.2333333333 -US-Var,21318,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.7341462206 -US-Var,21318,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21318,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21318,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21318,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21318,GRP_SWC,SWC_DATE,20040805 -US-Var,21768,GRP_SWC,SWC,4.3166666667 -US-Var,21768,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.792829492 -US-Var,21768,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21768,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21768,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21768,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21768,GRP_SWC,SWC_DATE,20110720 -US-Var,21552,GRP_SWC,SWC,4.35 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-US-Var,21177,GRP_SWC,SWC_DATE,20030530 -US-Var,21310,GRP_SWC,SWC,4.6666666667 -US-Var,21310,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.5927248644 -US-Var,21310,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21310,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21310,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21310,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21310,GRP_SWC,SWC_DATE,20040708 -US-Var,21033,GRP_SWC,SWC,4.75 -US-Var,21033,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.11313708499 -US-Var,21033,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21033,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21033,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21033,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21033,GRP_SWC,SWC_DATE,20020426 -US-Var,21656,GRP_SWC,SWC,4.75 -US-Var,21656,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.7476659403 -US-Var,21656,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21656,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21656,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21656,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21656,GRP_SWC,SWC_DATE,20091105 -US-Var,21853,GRP_SWC,SWC,4.7625 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-US-Var,21945,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21945,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21945,GRP_SWC,SWC_DATE,20131107 -US-Var,21940,GRP_SWC,SWC,4.8875 -US-Var,21940,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.7068970551 -US-Var,21940,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21940,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21940,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21940,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21940,GRP_SWC,SWC_DATE,20130925 -US-Var,21731,GRP_SWC,SWC,40.208333333 -US-Var,21731,GRP_SWC,SWC_SPATIAL_VARIABILITY,8.4133656893 -US-Var,21731,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21731,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21731,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21731,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21731,GRP_SWC,SWC_DATE,20101230 -US-Var,21735,GRP_SWC,SWC,40.208333333 -US-Var,21735,GRP_SWC,SWC_SPATIAL_VARIABILITY,8.4133656893 -US-Var,21735,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21735,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21735,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21735,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21735,GRP_SWC,SWC_DATE,20110119 -US-Var,21266,GRP_SWC,SWC,47.4 -US-Var,21266,GRP_SWC,SWC_SPATIAL_REP_NUMBER,1 -US-Var,21266,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21266,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21266,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21266,GRP_SWC,SWC_DATE,20040108 -US-Var,21857,GRP_SWC,SWC,5.0125 -US-Var,21857,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.5698167898 -US-Var,21857,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21857,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21857,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21857,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21857,GRP_SWC,SWC_DATE,20120905 -US-Var,21925,GRP_SWC,SWC,5.1375 -US-Var,21925,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.7390311547 -US-Var,21925,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21925,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21925,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21925,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21925,GRP_SWC,SWC_DATE,20130711 -US-Var,21516,GRP_SWC,SWC,5.2 -US-Var,21516,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.2627416998 -US-Var,21516,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21516,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21516,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21516,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21516,GRP_SWC,SWC_DATE,20070501 -US-Var,21900,GRP_SWC,SWC,5.2875 -US-Var,21900,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.121264434 -US-Var,21900,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21900,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21900,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21900,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21900,GRP_SWC,SWC_DATE,20130327 -US-Var,21849,GRP_SWC,SWC,5.375 -US-Var,21849,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.6014419079 -US-Var,21849,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21849,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21849,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21849,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21849,GRP_SWC,SWC_DATE,20120725 -US-Var,21872,GRP_SWC,SWC,5.3833333333 -US-Var,21872,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.6499303061 -US-Var,21872,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21872,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21872,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21872,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21872,GRP_SWC,SWC_DATE,20121107 -US-Var,21649,GRP_SWC,SWC,5.4 -US-Var,21649,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.8284271247 -US-Var,21649,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21649,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21649,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21649,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21649,GRP_SWC,SWC_DATE,20091002 -US-Var,21956,GRP_SWC,SWC,5.4375 -US-Var,21956,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.7362915902 -US-Var,21956,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21956,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21956,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21956,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21956,GRP_SWC,SWC_DATE,20140107 -US-Var,21306,GRP_SWC,SWC,5.45 -US-Var,21306,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.3334523779 -US-Var,21306,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21306,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21306,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21306,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21306,GRP_SWC,SWC_DATE,20040607 -US-Var,22012,GRP_SWC,SWC,5.4875 -US-Var,22012,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.8953341834 -US-Var,22012,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,22012,GRP_SWC,SWC_UNIT,Volumetric -US-Var,22012,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,22012,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,22012,GRP_SWC,SWC_DATE,20140930 -US-Var,21760,GRP_SWC,SWC,5.55 -US-Var,21760,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.1111636633 -US-Var,21760,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21760,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21760,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21760,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21760,GRP_SWC,SWC_DATE,20110615 -US-Var,21921,GRP_SWC,SWC,5.55 -US-Var,21921,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.6554974424 -US-Var,21921,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21921,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21921,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21921,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21921,GRP_SWC,SWC_DATE,20130619 -US-Var,22017,GRP_SWC,SWC,5.6625 -US-Var,22017,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.422249299 -US-Var,22017,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,22017,GRP_SWC,SWC_UNIT,Volumetric -US-Var,22017,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,22017,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,22017,GRP_SWC,SWC_DATE,20141024 -US-Var,21302,GRP_SWC,SWC,5.7 -US-Var,21302,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.5455844123 -US-Var,21302,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21302,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21302,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21302,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21302,GRP_SWC,SWC_DATE,20040522 -US-Var,21298,GRP_SWC,SWC,5.825 -US-Var,21298,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.1566756826 -US-Var,21298,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21298,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21298,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21298,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21298,GRP_SWC,SWC_DATE,20040506 -US-Var,21645,GRP_SWC,SWC,5.85 -US-Var,21645,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.3334523779 -US-Var,21645,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21645,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21645,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21645,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21645,GRP_SWC,SWC_DATE,20090907 -US-Var,21804,GRP_SWC,SWC,5.85 -US-Var,21804,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.9433488306 -US-Var,21804,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21804,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21804,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21804,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21804,GRP_SWC,SWC_DATE,20120104 -US-Var,21305,GRP_SWC,SWC,5.9 -US-Var,21305,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.5355339059 -US-Var,21305,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21305,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21305,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21305,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21305,GRP_SWC,SWC_DATE,20040607 -US-Var,21329,GRP_SWC,SWC,5.975 -US-Var,21329,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.2173358544 -US-Var,21329,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21329,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21329,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21329,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21329,GRP_SWC,SWC_DATE,20040921 -US-Var,21037,GRP_SWC,SWC,5.985 -US-Var,21037,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.7182694783 -US-Var,21037,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21037,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21037,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21037,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21037,GRP_SWC,SWC_DATE,20020502 -US-Var,21917,GRP_SWC,SWC,6.025 -US-Var,21917,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.5575052949 -US-Var,21917,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21917,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21917,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21917,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21917,GRP_SWC,SWC_DATE,20130530 -US-Var,21997,GRP_SWC,SWC,6.05 -US-Var,21997,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.4647515088 -US-Var,21997,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21997,GRP_SWC,SWC_UNIT,Volumetric 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-US-Var,21420,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21420,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21420,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21420,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21420,GRP_SWC,SWC_DATE,20051029 -US-Var,21629,GRP_SWC,SWC,6.325 -US-Var,21629,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.5102290732 -US-Var,21629,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21629,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21629,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21629,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21629,GRP_SWC,SWC_DATE,20090609 -US-Var,21913,GRP_SWC,SWC,6.35 -US-Var,21913,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.6811067367 -US-Var,21913,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21913,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21913,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21913,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21913,GRP_SWC,SWC_DATE,20130508 -US-Var,21525,GRP_SWC,SWC,6.375 -US-Var,21525,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.0152543264 -US-Var,21525,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21525,GRP_SWC,SWC_UNIT,Volumetric 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-US-Var,21046,GRP_SWC,SWC_DATE,20020516 -US-Var,21581,GRP_SWC,SWC,6.6 -US-Var,21581,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.42426406871 -US-Var,21581,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21581,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21581,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21581,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21581,GRP_SWC,SWC_DATE,20081030 -US-Var,22005,GRP_SWC,SWC,6.6 -US-Var,22005,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.190872399 -US-Var,22005,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,22005,GRP_SWC,SWC_UNIT,Volumetric -US-Var,22005,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,22005,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,22005,GRP_SWC,SWC_DATE,20140821 -US-Var,21413,GRP_SWC,SWC,6.6333333333 -US-Var,21413,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.6870057685 -US-Var,21413,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21413,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21413,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21413,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21413,GRP_SWC,SWC_DATE,20050910 -US-Var,21421,GRP_SWC,SWC,6.725 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-US-Var,21557,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21557,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21557,GRP_SWC,SWC_DATE,20080627 -US-Var,21565,GRP_SWC,SWC,6.9 -US-Var,21565,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.2727922061 -US-Var,21565,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21565,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21565,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21565,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21565,GRP_SWC,SWC_DATE,20080731 -US-Var,22001,GRP_SWC,SWC,6.9125 -US-Var,22001,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.7838197191 -US-Var,22001,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,22001,GRP_SWC,SWC_UNIT,Volumetric -US-Var,22001,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,22001,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,22001,GRP_SWC,SWC_DATE,20140805 -US-Var,21909,GRP_SWC,SWC,6.925 -US-Var,21909,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.677218706 -US-Var,21909,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21909,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21909,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21909,GRP_SWC,SWC_PROFILE_MAX,30 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-US-Var,21837,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21837,GRP_SWC,SWC_DATE,20120518 -US-Var,21106,GRP_SWC,SWC,7.25 -US-Var,21106,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.6162950904 -US-Var,21106,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21106,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21106,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21106,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21106,GRP_SWC,SWC_DATE,20021002 -US-Var,21512,GRP_SWC,SWC,7.325 -US-Var,21512,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.74246212025 -US-Var,21512,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21512,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21512,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21512,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21512,GRP_SWC,SWC_DATE,20070405 -US-Var,21792,GRP_SWC,SWC,7.325 -US-Var,21792,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.2791159523 -US-Var,21792,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21792,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21792,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21792,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21792,GRP_SWC,SWC_DATE,20111109 -US-Var,21042,GRP_SWC,SWC,7.35 -US-Var,21042,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.7476659403 -US-Var,21042,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21042,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21042,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21042,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21042,GRP_SWC,SWC_DATE,20020509 -US-Var,21473,GRP_SWC,SWC,7.4 -US-Var,21473,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.5254833996 -US-Var,21473,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21473,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21473,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21473,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21473,GRP_SWC,SWC_DATE,20060801 -US-Var,21521,GRP_SWC,SWC,7.4 -US-Var,21521,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.1213203436 -US-Var,21521,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21521,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21521,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21521,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21521,GRP_SWC,SWC_DATE,20070531 -US-Var,21190,GRP_SWC,SWC,7.45 -US-Var,21190,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.7577164466 -US-Var,21190,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21190,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21190,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21190,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21190,GRP_SWC,SWC_DATE,20030620 -US-Var,21409,GRP_SWC,SWC,7.45 -US-Var,21409,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.0506096654 -US-Var,21409,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21409,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21409,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21409,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21409,GRP_SWC,SWC_DATE,20050819 -US-Var,21182,GRP_SWC,SWC,7.4666666667 -US-Var,21182,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.1684607956 -US-Var,21182,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21182,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21182,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21182,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21182,GRP_SWC,SWC_DATE,20030606 -US-Var,21796,GRP_SWC,SWC,7.5 -US-Var,21796,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.0834699435 -US-Var,21796,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21796,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21796,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21796,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21796,GRP_SWC,SWC_DATE,20111201 -US-Var,21285,GRP_SWC,SWC,7.55 -US-Var,21285,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21285,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21285,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21285,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21285,GRP_SWC,SWC_DATE,20040325 -US-Var,21397,GRP_SWC,SWC,7.55 -US-Var,21397,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.42426406871 -US-Var,21397,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21397,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21397,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21397,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21397,GRP_SWC,SWC_DATE,20050610 -US-Var,21946,GRP_SWC,SWC,7.55 -US-Var,21946,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.8687780808 -US-Var,21946,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21946,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21946,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21946,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21946,GRP_SWC,SWC_DATE,20131107 -US-Var,21110,GRP_SWC,SWC,7.5833333333 -US-Var,21110,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.5792051446 -US-Var,21110,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21110,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21110,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21110,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21110,GRP_SWC,SWC_DATE,20021105 -US-Var,21098,GRP_SWC,SWC,7.6 -US-Var,21098,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.404163056 -US-Var,21098,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21098,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21098,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21098,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21098,GRP_SWC,SWC_DATE,20020912 -US-Var,21186,GRP_SWC,SWC,7.6166666667 -US-Var,21186,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.5220141862 -US-Var,21186,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21186,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21186,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21186,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21186,GRP_SWC,SWC_DATE,20030613 -US-Var,21194,GRP_SWC,SWC,7.6333333333 -US-Var,21194,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.2156012477 -US-Var,21194,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21194,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21194,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21194,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21194,GRP_SWC,SWC_DATE,20030627 -US-Var,21406,GRP_SWC,SWC,7.65 -US-Var,21406,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.3334523779 -US-Var,21406,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21406,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21406,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21406,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21406,GRP_SWC,SWC_DATE,20050706 -US-Var,21553,GRP_SWC,SWC,7.65 -US-Var,21553,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.4849242405 -US-Var,21553,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21553,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21553,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21553,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21553,GRP_SWC,SWC_DATE,20080531 -US-Var,21086,GRP_SWC,SWC,7.6833333333 -US-Var,21086,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.7105759945 -US-Var,21086,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21086,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21086,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21086,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21086,GRP_SWC,SWC_DATE,20020823 -US-Var,21303,GRP_SWC,SWC,7.7 -US-Var,21303,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.1213203436 -US-Var,21303,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21303,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21303,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21303,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21303,GRP_SWC,SWC_DATE,20040522 -US-Var,21398,GRP_SWC,SWC,7.8 -US-Var,21398,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.9091883092 -US-Var,21398,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21398,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21398,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21398,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21398,GRP_SWC,SWC_DATE,20050610 -US-Var,21788,GRP_SWC,SWC,7.8166666667 -US-Var,21788,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.5236416009 -US-Var,21788,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21788,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21788,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21788,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21788,GRP_SWC,SWC_DATE,20111026 -US-Var,21950,GRP_SWC,SWC,7.8166666667 -US-Var,21950,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.939129478 -US-Var,21950,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21950,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21950,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21950,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21950,GRP_SWC,SWC_DATE,20131127 -US-Var,21904,GRP_SWC,SWC,7.825 -US-Var,21904,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.6998873857 -US-Var,21904,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21904,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21904,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21904,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21904,GRP_SWC,SWC_DATE,20130410 -US-Var,21637,GRP_SWC,SWC,7.85 -US-Var,21637,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.6162950904 -US-Var,21637,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21637,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21637,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21637,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21637,GRP_SWC,SWC_DATE,20090705 -US-Var,21090,GRP_SWC,SWC,7.8833333333 -US-Var,21090,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.993418707 -US-Var,21090,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21090,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21090,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21090,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21090,GRP_SWC,SWC_DATE,20020829 -US-Var,21049,GRP_SWC,SWC,7.9 -US-Var,21049,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.14142135624 -US-Var,21049,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21049,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21049,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21049,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21049,GRP_SWC,SWC_DATE,20020530 -US-Var,21074,GRP_SWC,SWC,7.9 -US-Var,21074,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.404163056 -US-Var,21074,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21074,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21074,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21074,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21074,GRP_SWC,SWC_DATE,20020725 -US-Var,21540,GRP_SWC,SWC,7.9 -US-Var,21540,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.2727922061 -US-Var,21540,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21540,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21540,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21540,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21540,GRP_SWC,SWC_DATE,20080404 -US-Var,21173,GRP_SWC,SWC,7.9125 -US-Var,21173,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.3864853865 -US-Var,21173,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21173,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21173,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21173,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21173,GRP_SWC,SWC_DATE,20030521 -US-Var,21210,GRP_SWC,SWC,7.9166666667 -US-Var,21210,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.5220141862 -US-Var,21210,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21210,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21210,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21210,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21210,GRP_SWC,SWC_DATE,20030725 -US-Var,21918,GRP_SWC,SWC,7.95 -US-Var,21918,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.252646235 -US-Var,21918,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21918,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21918,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21918,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21918,GRP_SWC,SWC_DATE,20130530 -US-Var,21327,GRP_SWC,SWC,8.0166666667 -US-Var,21327,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.2391714738 -US-Var,21327,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21327,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21327,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21327,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21327,GRP_SWC,SWC_DATE,20040908 -US-Var,21845,GRP_SWC,SWC,8.0166666667 -US-Var,21845,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.003954424 -US-Var,21845,GRP_SWC,SWC_SPATIAL_REP_NUMBER,3 -US-Var,21845,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21845,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21845,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21845,GRP_SWC,SWC_DATE,20120704 -US-Var,21315,GRP_SWC,SWC,8.025 -US-Var,21315,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.0759144982 -US-Var,21315,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21315,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21315,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21315,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21315,GRP_SWC,SWC_DATE,20040721 -US-Var,21402,GRP_SWC,SWC,8.0375 -US-Var,21402,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.50260191 -US-Var,21402,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21402,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21402,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21402,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21402,GRP_SWC,SWC_DATE,20050623 -US-Var,21198,GRP_SWC,SWC,8.05 -US-Var,21198,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.4748737342 -US-Var,21198,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21198,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21198,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21198,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21198,GRP_SWC,SWC_DATE,20030703 -US-Var,21988,GRP_SWC,SWC,8.0625 -US-Var,21988,GRP_SWC,SWC_SPATIAL_VARIABILITY,13.369266684 -US-Var,21988,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21988,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21988,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21988,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21988,GRP_SWC,SWC_DATE,20140611 -US-Var,21082,GRP_SWC,SWC,8.0666666667 -US-Var,21082,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.4513035081 -US-Var,21082,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21082,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21082,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21082,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21082,GRP_SWC,SWC_DATE,20020815 -US-Var,21938,GRP_SWC,SWC,8.1 -US-Var,21938,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.9268307832 -US-Var,21938,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21938,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21938,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21938,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21938,GRP_SWC,SWC_DATE,20130904 -US-Var,21206,GRP_SWC,SWC,8.1166666667 -US-Var,21206,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.9462782549 -US-Var,21206,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21206,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21206,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21206,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21206,GRP_SWC,SWC_DATE,20030717 -US-Var,21214,GRP_SWC,SWC,8.175 -US-Var,21214,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.8637824638 -US-Var,21214,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21214,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21214,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21214,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21214,GRP_SWC,SWC_DATE,20030731 -US-Var,21989,GRP_SWC,SWC,8.1875 -US-Var,21989,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.4253436183 -US-Var,21989,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21989,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21989,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21989,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21989,GRP_SWC,SWC_DATE,20140611 -US-Var,21480,GRP_SWC,SWC,8.25 -US-Var,21480,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.7476659403 -US-Var,21480,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21480,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21480,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21480,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21480,GRP_SWC,SWC_DATE,20061119 -US-Var,21896,GRP_SWC,SWC,8.275 -US-Var,21896,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.0547297485 -US-Var,21896,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21896,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21896,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21896,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21896,GRP_SWC,SWC_DATE,20130313 -US-Var,21914,GRP_SWC,SWC,8.2875 -US-Var,21914,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.3101382422 -US-Var,21914,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21914,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21914,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21914,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21914,GRP_SWC,SWC_DATE,20130508 -US-Var,21560,GRP_SWC,SWC,8.28895 -US-Var,21560,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.2922022873 -US-Var,21560,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21560,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21560,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21560,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21560,GRP_SWC,SWC_DATE,20080712 -US-Var,21070,GRP_SWC,SWC,8.3 -US-Var,21070,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.5455844123 -US-Var,21070,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21070,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21070,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21070,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21070,GRP_SWC,SWC_DATE,20020719 -US-Var,21926,GRP_SWC,SWC,8.3 -US-Var,21926,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.4440972087 -US-Var,21926,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21926,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21926,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21926,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21926,GRP_SWC,SWC_DATE,20130711 -US-Var,21307,GRP_SWC,SWC,8.35 -US-Var,21307,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.3334523779 -US-Var,21307,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21307,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21307,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21307,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21307,GRP_SWC,SWC_DATE,20040607 -US-Var,21781,GRP_SWC,SWC,8.3583333333 -US-Var,21781,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.327731433 -US-Var,21781,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21781,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21781,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21781,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21781,GRP_SWC,SWC_DATE,20110929 -US-Var,21985,GRP_SWC,SWC,8.3625 -US-Var,21985,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.7878830081 -US-Var,21985,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21985,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21985,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21985,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21985,GRP_SWC,SWC_DATE,20140522 -US-Var,21202,GRP_SWC,SWC,8.45 -US-Var,21202,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.0506096654 -US-Var,21202,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21202,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21202,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21202,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21202,GRP_SWC,SWC_DATE,20030711 -US-Var,21078,GRP_SWC,SWC,8.5166666667 -US-Var,21078,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.0876996112 -US-Var,21078,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21078,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21078,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21078,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21078,GRP_SWC,SWC_DATE,20020801 -US-Var,21230,GRP_SWC,SWC,8.55 -US-Var,21230,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.1819805153 -US-Var,21230,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21230,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21230,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21230,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21230,GRP_SWC,SWC_DATE,20031002 -US-Var,21299,GRP_SWC,SWC,8.55 -US-Var,21299,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.4748737342 -US-Var,21299,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21299,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21299,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21299,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21299,GRP_SWC,SWC_DATE,20040506 -US-Var,21994,GRP_SWC,SWC,8.5625 -US-Var,21994,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.0687564221 -US-Var,21994,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21994,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21994,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21994,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21994,GRP_SWC,SWC_DATE,20140625 -US-Var,20991,GRP_SWC,SWC,8.6 -US-Var,20991,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.0370899457 -US-Var,20991,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,20991,GRP_SWC,SWC_UNIT,Volumetric -US-Var,20991,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,20991,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,20991,GRP_SWC,SWC_DATE,20011113 -US-Var,21234,GRP_SWC,SWC,8.6 -US-Var,21234,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.3941125497 -US-Var,21234,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21234,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21234,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21234,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21234,GRP_SWC,SWC_DATE,20031024 -US-Var,21549,GRP_SWC,SWC,8.6 -US-Var,21549,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.767766953 -US-Var,21549,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21549,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21549,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21549,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21549,GRP_SWC,SWC_DATE,20080506 -US-Var,21930,GRP_SWC,SWC,8.6 -US-Var,21930,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.3673027527 -US-Var,21930,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21930,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21930,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21930,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21930,GRP_SWC,SWC_DATE,20130728 -US-Var,21948,GRP_SWC,SWC,8.6 -US-Var,21948,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.7300580871 -US-Var,21948,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21948,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21948,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21948,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21948,GRP_SWC,SWC_DATE,20131127 -US-Var,21777,GRP_SWC,SWC,8.725 -US-Var,21777,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.3500692277 -US-Var,21777,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21777,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21777,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21777,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21777,GRP_SWC,SWC_DATE,20110916 -US-Var,21066,GRP_SWC,SWC,8.75 -US-Var,21066,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.7577164466 -US-Var,21066,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21066,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21066,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21066,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21066,GRP_SWC,SWC_DATE,20020711 -US-Var,20987,GRP_SWC,SWC,8.8 -US-Var,20987,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.1313708499 -US-Var,20987,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,20987,GRP_SWC,SWC_UNIT,Volumetric -US-Var,20987,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,20987,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,20987,GRP_SWC,SWC_DATE,20011110 -US-Var,21389,GRP_SWC,SWC,8.8 -US-Var,21389,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.8284271247 -US-Var,21389,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21389,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21389,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21389,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21389,GRP_SWC,SWC_DATE,20050425 -US-Var,21393,GRP_SWC,SWC,8.8 -US-Var,21393,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.2325901808 -US-Var,21393,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21393,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21393,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21393,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21393,GRP_SWC,SWC_DATE,20050517 -US-Var,21922,GRP_SWC,SWC,8.8 -US-Var,21922,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.3129649508 -US-Var,21922,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21922,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21922,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21922,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21922,GRP_SWC,SWC_DATE,20130619 -US-Var,21846,GRP_SWC,SWC,8.85 -US-Var,21846,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.598437282 -US-Var,21846,GRP_SWC,SWC_SPATIAL_REP_NUMBER,3 -US-Var,21846,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21846,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21846,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21846,GRP_SWC,SWC_DATE,20120704 -US-Var,21858,GRP_SWC,SWC,8.8625 -US-Var,21858,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.8211988481 -US-Var,21858,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21858,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21858,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21858,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21858,GRP_SWC,SWC_DATE,20120905 -US-Var,21870,GRP_SWC,SWC,8.8625 -US-Var,21870,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.7016619402 -US-Var,21870,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21870,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21870,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21870,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21870,GRP_SWC,SWC_DATE,20121024 -US-Var,21029,GRP_SWC,SWC,8.8833333333 -US-Var,21029,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.16499158228 -US-Var,21029,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21029,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21029,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21029,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21029,GRP_SWC,SWC_DATE,20020418 -US-Var,21038,GRP_SWC,SWC,8.9 -US-Var,21038,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.5679098065 -US-Var,21038,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21038,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21038,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21038,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21038,GRP_SWC,SWC_DATE,20020502 -US-Var,21460,GRP_SWC,SWC,8.9 -US-Var,21460,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.70710678119 -US-Var,21460,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21460,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21460,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21460,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21460,GRP_SWC,SWC_DATE,20060504 -US-Var,21933,GRP_SWC,SWC,8.9125 -US-Var,21933,GRP_SWC,SWC_SPATIAL_VARIABILITY,8.4311303117 -US-Var,21933,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21933,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21933,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21933,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21933,GRP_SWC,SWC_DATE,20130813 -US-Var,21773,GRP_SWC,SWC,8.9166666667 -US-Var,21773,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.2741508005 -US-Var,21773,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21773,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21773,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21773,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21773,GRP_SWC,SWC_DATE,20110831 -US-Var,21654,GRP_SWC,SWC,8.95 -US-Var,21654,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.7577164466 -US-Var,21654,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21654,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21654,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21654,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21654,GRP_SWC,SWC_DATE,20091022 -US-Var,21331,GRP_SWC,SWC,8.975 -US-Var,21331,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.60104076401 -US-Var,21331,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21331,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21331,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21331,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21331,GRP_SWC,SWC_DATE,20040921 -US-Var,21631,GRP_SWC,SWC,8.975 -US-Var,21631,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.1466251763 -US-Var,21631,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21631,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21631,GRP_SWC,SWC_PROFILE_MIN,45 -US-Var,21631,GRP_SWC,SWC_PROFILE_MAX,60 -US-Var,21631,GRP_SWC,SWC_DATE,20090609 -US-Var,21942,GRP_SWC,SWC,8.9875 -US-Var,21942,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.6908409466 -US-Var,21942,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21942,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21942,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21942,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21942,GRP_SWC,SWC_DATE,20130925 -US-Var,21998,GRP_SWC,SWC,9.0125 -US-Var,21998,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.0460174065 -US-Var,21998,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21998,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21998,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21998,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21998,GRP_SWC,SWC_DATE,20140709 -US-Var,21323,GRP_SWC,SWC,9.05 -US-Var,21323,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.35355339059 -US-Var,21323,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21323,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21323,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21323,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21323,GRP_SWC,SWC_DATE,20040817 -US-Var,22024,GRP_SWC,SWC,9.0833333333 -US-Var,22024,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.2291646141 -US-Var,22024,GRP_SWC,SWC_SPATIAL_REP_NUMBER,3 -US-Var,22024,GRP_SWC,SWC_UNIT,Volumetric -US-Var,22024,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,22024,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,22024,GRP_SWC,SWC_DATE,20141126 -US-Var,21658,GRP_SWC,SWC,9.1 -US-Var,21658,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.3941125497 -US-Var,21658,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21658,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21658,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21658,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21658,GRP_SWC,SWC_DATE,20091105 -US-Var,21650,GRP_SWC,SWC,9.2166666667 -US-Var,21650,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.3334523779 -US-Var,21650,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21650,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21650,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21650,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21650,GRP_SWC,SWC_DATE,20091002 -US-Var,21226,GRP_SWC,SWC,9.225 -US-Var,21226,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.2880465325 -US-Var,21226,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21226,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21226,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21226,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21226,GRP_SWC,SWC_DATE,20030905 -US-Var,21634,GRP_SWC,SWC,9.25 -US-Var,21634,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.1819805153 -US-Var,21634,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21634,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21634,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21634,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21634,GRP_SWC,SWC_DATE,20090621 -US-Var,21335,GRP_SWC,SWC,9.275 -US-Var,21335,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.0253048327 -US-Var,21335,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21335,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21335,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21335,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21335,GRP_SWC,SWC_DATE,20041013 -US-Var,21477,GRP_SWC,SWC,9.275 -US-Var,21477,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.1466251763 -US-Var,21477,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21477,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21477,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21477,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21477,GRP_SWC,SWC_DATE,20061104 -US-Var,21842,GRP_SWC,SWC,9.275 -US-Var,21842,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.6102241449 -US-Var,21842,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21842,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21842,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21842,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21842,GRP_SWC,SWC_DATE,20120530 -US-Var,21319,GRP_SWC,SWC,9.3 -US-Var,21319,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.14142135624 -US-Var,21319,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21319,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21319,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21319,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21319,GRP_SWC,SWC_DATE,20040805 -US-Var,21626,GRP_SWC,SWC,9.3 -US-Var,21626,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.2426406871 -US-Var,21626,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21626,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21626,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21626,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21626,GRP_SWC,SWC_DATE,20090527 -US-Var,22018,GRP_SWC,SWC,9.3 -US-Var,22018,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.1135953455 -US-Var,22018,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,22018,GRP_SWC,SWC_UNIT,Volumetric -US-Var,22018,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,22018,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,22018,GRP_SWC,SWC_DATE,20141024 -US-Var,21809,GRP_SWC,SWC,9.325 -US-Var,21809,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.2131241287 -US-Var,21809,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21809,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21809,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21809,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21809,GRP_SWC,SWC_DATE,20120118 -US-Var,21850,GRP_SWC,SWC,9.325 -US-Var,21850,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.8903817165 -US-Var,21850,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21850,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21850,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21850,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21850,GRP_SWC,SWC_DATE,20120725 -US-Var,21062,GRP_SWC,SWC,9.4 -US-Var,21062,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.404163056 -US-Var,21062,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21062,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21062,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21062,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21062,GRP_SWC,SWC_DATE,20020628 -US-Var,21854,GRP_SWC,SWC,9.425 -US-Var,21854,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.8835608593 -US-Var,21854,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21854,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21854,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21854,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21854,GRP_SWC,SWC_DATE,20120822 -US-Var,21874,GRP_SWC,SWC,9.4416666667 -US-Var,21874,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.2494355958 -US-Var,21874,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21874,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21874,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21874,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21874,GRP_SWC,SWC_DATE,20121107 -US-Var,21862,GRP_SWC,SWC,9.4625 -US-Var,21862,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.510242972 -US-Var,21862,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21862,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21862,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21862,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21862,GRP_SWC,SWC_DATE,20120919 -US-Var,21866,GRP_SWC,SWC,9.4625 -US-Var,21866,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.510242972 -US-Var,21866,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21866,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21866,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21866,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21866,GRP_SWC,SWC_DATE,20121009 -US-Var,21218,GRP_SWC,SWC,9.4833333333 -US-Var,21218,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.7948063924 -US-Var,21218,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21218,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21218,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21218,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21218,GRP_SWC,SWC_DATE,20030806 -US-Var,21117,GRP_SWC,SWC,9.525 -US-Var,21117,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.60104076401 -US-Var,21117,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21117,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21117,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21117,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21117,GRP_SWC,SWC_DATE,20021206 -US-Var,21034,GRP_SWC,SWC,9.55 -US-Var,21034,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.7476659403 -US-Var,21034,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21034,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21034,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21034,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21034,GRP_SWC,SWC_DATE,20020426 -US-Var,21222,GRP_SWC,SWC,9.55 -US-Var,21222,GRP_SWC,SWC_SPATIAL_VARIABILITY,3.3234018716 -US-Var,21222,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21222,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21222,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21222,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21222,GRP_SWC,SWC_DATE,20030816 -US-Var,21934,GRP_SWC,SWC,9.55 -US-Var,21934,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.4335378285 -US-Var,21934,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21934,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21934,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21934,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21934,GRP_SWC,SWC_DATE,20130813 -US-Var,21311,GRP_SWC,SWC,9.5666666667 -US-Var,21311,GRP_SWC,SWC_SPATIAL_VARIABILITY,0.18856180832 -US-Var,21311,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21311,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21311,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21311,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21311,GRP_SWC,SWC_DATE,20040708 -US-Var,21584,GRP_SWC,SWC,9.7333333333 -US-Var,21584,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.2156012477 -US-Var,21584,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21584,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21584,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21584,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21584,GRP_SWC,SWC_DATE,20081113 -US-Var,21178,GRP_SWC,SWC,9.75 -US-Var,21178,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.0506096654 -US-Var,21178,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21178,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21178,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21178,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21178,GRP_SWC,SWC_DATE,20030530 -US-Var,21962,GRP_SWC,SWC,9.75 -US-Var,21962,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.9961651961 -US-Var,21962,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21962,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21962,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21962,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21962,GRP_SWC,SWC_DATE,20140124 -US-Var,21054,GRP_SWC,SWC,9.8 -US-Var,21054,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.6870057685 -US-Var,21054,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21054,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21054,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21054,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21054,GRP_SWC,SWC_DATE,20020613 -US-Var,21873,GRP_SWC,SWC,9.825 -US-Var,21873,GRP_SWC,SWC_SPATIAL_VARIABILITY,1.6560495162 -US-Var,21873,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21873,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21873,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21873,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21873,GRP_SWC,SWC_DATE,20121107 -US-Var,21526,GRP_SWC,SWC,9.875 -US-Var,21526,GRP_SWC,SWC_SPATIAL_VARIABILITY,2.0859650045 -US-Var,21526,GRP_SWC,SWC_SPATIAL_REP_NUMBER,2 -US-Var,21526,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21526,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21526,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21526,GRP_SWC,SWC_DATE,20070623 -US-Var,21832,GRP_SWC,SWC,9.875 -US-Var,21832,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.2694876411 -US-Var,21832,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21832,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21832,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21832,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21832,GRP_SWC,SWC_DATE,20120504 -US-Var,21910,GRP_SWC,SWC,9.8875 -US-Var,21910,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.3259632839 -US-Var,21910,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21910,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21910,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21910,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21910,GRP_SWC,SWC_DATE,20130424 -US-Var,21868,GRP_SWC,SWC,9.9 -US-Var,21868,GRP_SWC,SWC_SPATIAL_VARIABILITY,4.7881798908 -US-Var,21868,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21868,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21868,GRP_SWC,SWC_PROFILE_MIN,0 -US-Var,21868,GRP_SWC,SWC_PROFILE_MAX,15 -US-Var,21868,GRP_SWC,SWC_DATE,20121024 -US-Var,21769,GRP_SWC,SWC,9.925 -US-Var,21769,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.9050119955 -US-Var,21769,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21769,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21769,GRP_SWC,SWC_PROFILE_MIN,15 -US-Var,21769,GRP_SWC,SWC_PROFILE_MAX,30 -US-Var,21769,GRP_SWC,SWC_DATE,20110720 -US-Var,21958,GRP_SWC,SWC,9.95 -US-Var,21958,GRP_SWC,SWC_SPATIAL_VARIABILITY,5.0518973333 -US-Var,21958,GRP_SWC,SWC_SPATIAL_REP_NUMBER,4 -US-Var,21958,GRP_SWC,SWC_UNIT,Volumetric -US-Var,21958,GRP_SWC,SWC_PROFILE_MIN,30 -US-Var,21958,GRP_SWC,SWC_PROFILE_MAX,45 -US-Var,21958,GRP_SWC,SWC_DATE,20140107 -US-Var,11335,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Dennis Baldocchi -US-Var,11335,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Var,11335,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,Baldocchi@berkeley.edu -US-Var,11335,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"University of California, Berkeley" -US-Var,11335,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Department of Environmental Science, Policy and Management, 130 Mulford Hall, Berkeley, CA USA 94720-3110" -US-Var,11341,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Joe Verfaillie -US-Var,11341,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,AncContact -US-Var,11341,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,jverfail@berkeley.edu -US-Var,11341,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"University of California, Berkeley" -US-Var,11339,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Siyan Ma -US-Var,11339,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-Var,11339,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,syma@berkeley.edu -US-Var,11339,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"University of California, Berkeley" -US-Var,81431,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Daphne Szutu -US-Var,81431,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Technician -US-Var,81431,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,daphneszutu@berkeley.edu -US-Var,81431,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,UC Berkeley -US-Var,30455,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-Var,30454,GRP_TOWER_TYPE,TOWER_TYPE,tripod -US-Var,11336,GRP_URL,URL,http://nature.berkeley.edu/biometlab/sites.php?tab=US-Var -US-Var,24000441,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-Var -US-Var,11337,GRP_UTC_OFFSET,UTC_OFFSET,-8 -US-Vcm,11678,GRP_CLIM_AVG,MAT,6.4 -US-Vcm,11678,GRP_CLIM_AVG,MAP,646 -US-Vcm,11678,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfb -US-Vcm,27000471,GRP_COUNTRY,COUNTRY,USA -US-Vcm,15657,GRP_DOI,DOI,10.17190/AMF/1246121 -US-Vcm,15657,GRP_DOI,DOI_CITATION,"Marcy Litvak (2022), AmeriFlux BASE US-Vcm Valles Caldera Mixed Conifer, Ver. 20-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1246121" -US-Vcm,15657,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-Vcm,32259,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Vcm,32259,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Marcy Litvak -US-Vcm,32259,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Vcm,32259,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,mlitvak@unm.edu -US-Vcm,32259,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of New Mexico -US-Vcm,32261,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,University of New Mexico -US-Vcm,32261,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-Vcm,32260,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,NSF -US-Vcm,32260,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-Vcm,15486,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Drought -US-Vcm,15497,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Fire -US-Vcm,15503,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Grazing -US-Vcm,15500,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Pests and disease -US-Vcm,15487,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Vcm,15487,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-Vcm,15487,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,200701010000 -US-Vcm,15487,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Vcm,15498,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Vcm,15498,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-Vcm,15498,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,200701010000 -US-Vcm,15498,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Vcm,23000471,GRP_HEADER,SITE_NAME,Valles Caldera Mixed Conifer -US-Vcm,11680,GRP_IGBP,IGBP,ENF -US-Vcm,15488,GRP_IGBP,IGBP,ENF -US-Vcm,15488,GRP_IGBP,IGBP_DATE_START,200701010000 -US-Vcm,15488,GRP_IGBP,IGBP_COMMENT,"Spruce, fir, pine" -US-Vcm,15489,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-Vcm,15489,GRP_LAND_OWNERSHIP,LAND_OWNER,Department of Interior -US-Vcm,11681,GRP_LOCATION,LOCATION_LAT,35.8884 -US-Vcm,11681,GRP_LOCATION,LOCATION_LONG,-106.5321 -US-Vcm,11681,GRP_LOCATION,LOCATION_ELEV,3003 -US-Vcm,11681,GRP_LOCATION,LOCATION_COMMENT,From CDIAC Tom Boden database dump -US-Vcm,15490,GRP_LOCATION,LOCATION_LAT,35.8884 -US-Vcm,15490,GRP_LOCATION,LOCATION_LONG,-106.5321 -US-Vcm,15490,GRP_LOCATION,LOCATION_ELEV,3030 -US-Vcm,15490,GRP_LOCATION,LOCATION_DATE_START,200701010000 -US-Vcm,11682,GRP_NETWORK,NETWORK,AmeriFlux -US-Vcm,1700005583,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Anderson-Teixeira, K. J., Delong, J. P., Fox, A. M., Brese, D. A., Litvak, M. E. (2011) Differential Responses Of Production And Respiration To Temperature And Moisture Drive The Carbon Balance Across A Climatic Gradient In New Mexico, Global Change Biology, 17(1), 410-424" -US-Vcm,1700005583,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/J.1365-2486.2010.02269.X -US-Vcm,1700005583,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Vcm,1700001638,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Biederman, J. A., Scott, R. L., Bell, T. W., Bowling, D. R., Dore, S., Garatuza-Payan, J., Kolb, T. E., Krishnan, P., Krofcheck, D. J., Litvak, M. E., Maurer, G. E., Meyers, T. P., Oechel, W. C., Papuga, S. A., Ponce-Campos, G. E., Rodriguez, J. C., Smith, W. K., Vargas, R., Watts, C. J., Yepez, E. A., Goulden, M. L. (2017) Co2 Exchange And Evapotranspiration Across Dryland Ecosystems Of Southwestern North America, Global Change Biology, 23(10), 4204-4221" -US-Vcm,1700001638,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/GCB.13686 -US-Vcm,1700001638,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Vcm,1700005838,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Biederman, J. A., Scott, R. L., Goulden, M. L., Vargas, R., Litvak, M. E., Kolb, T. E., Yepez, E. A., Oechel, W. C., Blanken, P. D., Bell, T. W., Garatuza-Payan, J., Maurer, G. E., Dore, S., Burns, S. P. (2016) Terrestrial Carbon Balance In A Drier World: The Effects Of Water Availability In Southwestern North America, Global Change Biology, 22(5), 1867-1879" -US-Vcm,1700005838,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/GCB.13222 -US-Vcm,1700005838,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Vcm,1700001596,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Baldocchi, D. D., Poindexter, C., Abraha, M., Desai, A. R., Bohrer, G., Arain, M. A., Griffis, T., Blanken, P. D., O'Halloran, T. L., Thomas, R. Q., Zhang, Q., Burns, S. P., Frank, J. M., Christian, D., Brown, S., Black, T. A., Gough, C. M., Law, B. E., Lee, X., Chen, J., Reed, D. E., Massman, W. J., Clark, K., Hatfield, J., Prueger, J., Bracho, R., Baker, J. M., Martin, T. A. (2018) Temporal Dynamics Of Aerodynamic Canopy Height Derived From Eddy Covariance Momentum Flux Data Across North American Flux Networks, Geophysical Research Letters, 45(21), 9275–9287" -US-Vcm,1700001596,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018GL079306 -US-Vcm,1700001596,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Vcm,1700001098,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(12), 108350" -US-Vcm,1700001098,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -US-Vcm,1700001098,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Vcm,1700006477,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Knowles, J. F., Molotch, N. P., Trujillo, E., Litvak, M. E. (2018) Snowmelt‐Driven Trade‐Offs Between Early And Late Season Productivity Negatively Impact Forest Carbon Uptake During Drought, Geophysical Research Letters, 45(7), 3087-3096" -US-Vcm,1700006477,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/2017GL076504 -US-Vcm,1700006477,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Vcm,1700008385,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Knowles, J. F., Scott, R. L., Biederman, J. A., Blanken, P. D., Burns, S. P., Dore, S., Kolb, T. E., Litvak, M. E., Barron‐Gafford, G. A. (2020) Montane Forest Productivity Across A Semiarid Climatic Gradient, Global Change Biology, 26(12), 6945-6958" -US-Vcm,1700008385,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/GCB.15335 -US-Vcm,1700008385,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Vcm,1700003534,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Perdrial, J., Brooks, P. D., Swetnam, T., Lohse, K. A., Rasmussen, C., Litvak, M., Harpold, A. A., Zapata-Rios, X., Broxton, P., Mitra, B., Meixner, T., Condon, K., Huckle, D., Stielstra, C., Vázquez-Ortega, A., Lybrand, R., Holleran, M., Orem, C., Pelletier, J., Chorover, J. (2018) A Net Ecosystem Carbon Budget For Snow Dominated Forested Headwater Catchments: Linking Water And Carbon Fluxes To Critical Zone Carbon Storage, Biogeochemistry, 138(3), 225-243" -US-Vcm,1700003534,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Vcm,1700005607,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Remy, C. C., Krofcheck, D. J., Keyser, A. R., Litvak, M. E., Collins, S. L., Hurteau, M. D. (2019) Integrating Species‐Specific Information In Models Improves Regional Projections Under Climate Change, Geophysical Research Letters, 46(12), 6554-6562" -US-Vcm,1700005607,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2019GL082762 -US-Vcm,1700005607,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Vcm,1700005028,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Senay, G. B., Schauer, M., Velpuri, N. M., Singh, R. K., Kagone, S., Friedrichs, M., Litvak, M. E., Douglas-Mankin, K. R. (2019) Long-Term (1986–2015) Crop Water Use Characterization Over The Upper Rio Grande Basin Of United States And Mexico Using Landsat-Based Evapotranspiration, Remote Sensing, 11(13), 1587" -US-Vcm,1700005028,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.3390/RS11131587 -US-Vcm,1700005028,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Vcm,1700003213,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Smith, W. K., Biederman, J. A., Scott, R. L., Moore, D. J., He, M., Kimball, J. S., Yan, D., Hudson, A., Barnes, M. L., MacBean, N., Fox, A. M., Litvak, M. E. (2018) Chlorophyll Fluorescence Better Captures Seasonal And Interannual Gross Primary Productivity Dynamics Across Dryland Ecosystems Of Southwestern North America, Geophysical Research Letters, 45(2), 748-757" -US-Vcm,1700003213,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/2017GL075922 -US-Vcm,1700003213,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Vcm,1700008202,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Wolf, S., Keenan, T. F., Fisher, J. B., Baldocchi, D. D., Desai, A. R., Richardson, A. D., Scott, R. L., Law, B. E., Litvak, M. E., Brunsell, N. A., Peters, W., van der Laan-Luijkx, I. T. (2016) Warm Spring Reduced Carbon Cycle Impact Of The 2012 Us Summer Drought, Proceedings Of The National Academy Of Sciences, 113(21), 5880-5885" -US-Vcm,1700008202,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1073/PNAS.1519620113 -US-Vcm,1700008202,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Vcm,1700005982,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Wolf, S., Keenan, T.F., Fisher, J.B., Baldocchi, D.D., Desai, A.R., Richardson, A.D., Scott, R.L., Law, B.E., Litvak, M.E., Brunsell, N.A., Peters, W., van der Laan-Luijkx, I.T. (2016) Warm spring reduced carbon cycle impact of the 2012 US summer drought, Proceedings of the National Academy of Sciences, 113(21), 5880-5885" -US-Vcm,1700005982,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1073/PNAS.1519620113 -US-Vcm,1700005982,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Vcm,30671,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"Research topics and objectives include 1) To understand the coupled water and energy cycles in semiarid environments; 2) Quantify carbon, water and energy fluxes in addition to inter-annual variability in these fluxes; 3) Quantify the extent to which water and carbon fluxes are controlled by soil moisture and rainfall, and the sensitivity of fluxes in this biome to changes in temperature and precipitation; 4) Quantify the impact of a stand replacing burn on carbon, water and energy fluxes, and how these fluxes change as the stand recovers. We were fortunate to have access to the Ameriflux rapid response tower to set up in a nearby unburned subalpine mixed conifer site to do this comparison." -US-Vcm,11683,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"University of New Mexico, 219 Yale Blvd. NE, Castetter Hall Rm 1480, Albuquerque, NM 87131" -US-Vcm,11684,GRP_SITE_CHAR,WIND_DIRECTION,NW -US-Vcm,30672,GRP_SITE_DESC,SITE_DESC,"The Valles Caldera Mixed Conifer site is located in the 1200 km2 Jemez River basin in north-central New Mexico. Common to elevations ranging from 3040 to 2740 m in the region, the mixed conifer stand, within the entirety of the tower footprint in all directions, provides an excellent setting for studying the seasonal interaction between snow and vegetation. In late May 2013, this site experienced a stand-replacing wildfire. It was a very hot fire that killed every single tree, and burned off a lot of surface organic matter. We have a big gap in fluxes from May 2013- Jan 2014. We were not even allowed in to the site until Oct 2013, and it took us 2-3 months to clean up the debris, remove burned infrastructure, have the tower structure assessed, and resinstrument the site." -US-Vcm,11686,GRP_SITE_FUNDING,SITE_FUNDING,NSF -US-Vcm,11687,GRP_STATE,STATE,NM -US-Vcm,15494,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Marcy Litvak -US-Vcm,15494,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Vcm,15494,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,mlitvak@unm.edu -US-Vcm,15494,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of New Mexico -US-Vcm,81434,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Tomer Duman -US-Vcm,81434,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,DataManager -US-Vcm,81434,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,tomerduman@gmail.com -US-Vcm,81434,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of New Mexico -US-Vcm,99222,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Anthony Luketich -US-Vcm,99222,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Technician -US-Vcm,99222,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,luketich@unm.edu -US-Vcm,99222,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of New Mexico -US-Vcm,29847,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-Vcm,15495,GRP_TOWER_TYPE,TOWER_TYPE,triangle -US-Vcm,81432,GRP_URL,URL,http://www.litvaklab.org/subalpine-mixed-conifer.html -US-Vcm,24000471,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-Vcm -US-Vcm,11690,GRP_UTC_OFFSET,UTC_OFFSET,-7 -US-Vcm,15496,GRP_UTC_OFFSET,UTC_OFFSET,-7 -US-Vcm,15496,GRP_UTC_OFFSET,UTC_OFFSET_DATE_START,200701010000 -US-Vcp,12402,GRP_CLIM_AVG,MAT,9.8 -US-Vcp,12402,GRP_CLIM_AVG,MAP,550 -US-Vcp,12402,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfb -US-Vcp,27000472,GRP_COUNTRY,COUNTRY,USA -US-Vcp,15727,GRP_DOI,DOI,10.17190/AMF/1246122 -US-Vcp,15727,GRP_DOI,DOI_CITATION,"Marcy Litvak (2022), AmeriFlux BASE US-Vcp Valles Caldera Ponderosa Pine, Ver. 17-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1246122" -US-Vcp,15727,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-Vcp,32262,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Vcp,32262,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Marcy Litvak -US-Vcp,32262,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Vcp,32262,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,mlitvak@unm.edu -US-Vcp,32262,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of New Mexico -US-Vcp,32264,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,University of New Mexico -US-Vcp,32264,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-Vcp,32263,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,AmeriFlux Core Site -US-Vcp,32263,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-Vcp,15505,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Drought -US-Vcp,15516,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Forestry -US-Vcp,15519,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Grazing -US-Vcp,15506,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Vcp,15506,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-Vcp,15506,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,200701010000 -US-Vcp,15506,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Vcp,15517,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Vcp,15517,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-Vcp,15517,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,200701010000 -US-Vcp,15517,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Vcp,23000472,GRP_HEADER,SITE_NAME,Valles Caldera Ponderosa Pine -US-Vcp,12404,GRP_IGBP,IGBP,ENF -US-Vcp,15507,GRP_IGBP,IGBP,ENF -US-Vcp,15507,GRP_IGBP,IGBP_DATE_START,200701010000 -US-Vcp,15507,GRP_IGBP,IGBP_COMMENT,Ponderosa pine -US-Vcp,15508,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-Vcp,15508,GRP_LAND_OWNERSHIP,LAND_OWNER,Department of Interior -US-Vcp,12406,GRP_LOCATION,LOCATION_LAT,35.8624 -US-Vcp,12406,GRP_LOCATION,LOCATION_LONG,-106.5974 -US-Vcp,12406,GRP_LOCATION,LOCATION_ELEV,2542 -US-Vcp,12406,GRP_LOCATION,LOCATION_COMMENT,From CDIAC Tom Boden database dump -US-Vcp,15509,GRP_LOCATION,LOCATION_LAT,35.8642 -US-Vcp,15509,GRP_LOCATION,LOCATION_LONG,-106.5967 -US-Vcp,15509,GRP_LOCATION,LOCATION_ELEV,2500 -US-Vcp,15509,GRP_LOCATION,LOCATION_DATE_START,200701010000 -US-Vcp,12407,GRP_NETWORK,NETWORK,AmeriFlux -US-Vcp,1700000414,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Anderson-Teixeira, K. J., Delong, J. P., Fox, A. M., Brese, D. A., Litvak, M. E. (2011) Differential Responses Of Production And Respiration To Temperature And Moisture Drive The Carbon Balance Across A Climatic Gradient In New Mexico, Global Change Biology, 17(1), 410-424" -US-Vcp,1700000414,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/J.1365-2486.2010.02269.X -US-Vcp,1700000414,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Vcp,1700003060,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Biederman, J. A., Scott, R. L., Bell, T. W., Bowling, D. R., Dore, S., Garatuza-Payan, J., Kolb, T. E., Krishnan, P., Krofcheck, D. J., Litvak, M. E., Maurer, G. E., Meyers, T. P., Oechel, W. C., Papuga, S. A., Ponce-Campos, G. E., Rodriguez, J. C., Smith, W. K., Vargas, R., Watts, C. J., Yepez, E. A., Goulden, M. L. (2017) Co2 Exchange And Evapotranspiration Across Dryland Ecosystems Of Southwestern North America, Global Change Biology, 23(10), 4204-4221" -US-Vcp,1700003060,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/GCB.13686 -US-Vcp,1700003060,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Vcp,1700007446,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Biederman, J. A., Scott, R. L., Goulden, M. L., Vargas, R., Litvak, M. E., Kolb, T. E., Yepez, E. A., Oechel, W. C., Blanken, P. D., Bell, T. W., Garatuza-Payan, J., Maurer, G. E., Dore, S., Burns, S. P. (2016) Terrestrial Carbon Balance In A Drier World: The Effects Of Water Availability In Southwestern North America, Global Change Biology, 22(5), 1867-1879" -US-Vcp,1700007446,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/GCB.13222 -US-Vcp,1700007446,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Vcp,1700000330,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(12), 108350" -US-Vcp,1700000330,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -US-Vcp,1700000330,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Vcp,1700002634,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Knowles, J. F., Molotch, N. P., Trujillo, E., Litvak, M. E. (2018) Snowmelt‐Driven Trade‐Offs Between Early And Late Season Productivity Negatively Impact Forest Carbon Uptake During Drought, Geophysical Research Letters, 45(7), 3087-3096" -US-Vcp,1700002634,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/2017GL076504 -US-Vcp,1700002634,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Vcp,1700007455,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Knowles, J. F., Scott, R. L., Biederman, J. A., Blanken, P. D., Burns, S. P., Dore, S., Kolb, T. E., Litvak, M. E., Barron‐Gafford, G. A. (2020) Montane Forest Productivity Across A Semiarid Climatic Gradient, Global Change Biology, 26(12), 6945-6958" -US-Vcp,1700007455,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/GCB.15335 -US-Vcp,1700007455,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Vcp,1700000885,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Perdrial, J., Brooks, P. D., Swetnam, T., Lohse, K. A., Rasmussen, C., Litvak, M., Harpold, A. A., Zapata-Rios, X., Broxton, P., Mitra, B., Meixner, T., Condon, K., Huckle, D., Stielstra, C., Vázquez-Ortega, A., Lybrand, R., Holleran, M., Orem, C., Pelletier, J., Chorover, J. (2018) A Net Ecosystem Carbon Budget For Snow Dominated Forested Headwater Catchments: Linking Water And Carbon Fluxes To Critical Zone Carbon Storage, Biogeochemistry, 138(3), 225-243" -US-Vcp,1700000885,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Vcp,1700005289,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Remy, C. C., Krofcheck, D. J., Keyser, A. R., Litvak, M. E., Collins, S. L., Hurteau, M. D. (2019) Integrating Species‐Specific Information In Models Improves Regional Projections Under Climate Change, Geophysical Research Letters, 46(12), 6554-6562" -US-Vcp,1700005289,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2019GL082762 -US-Vcp,1700005289,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Vcp,1700008226,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Senay, G. B., Schauer, M., Velpuri, N. M., Singh, R. K., Kagone, S., Friedrichs, M., Litvak, M. E., Douglas-Mankin, K. R. (2019) Long-Term (1986–2015) Crop Water Use Characterization Over The Upper Rio Grande Basin Of United States And Mexico Using Landsat-Based Evapotranspiration, Remote Sensing, 11(13), 1587" -US-Vcp,1700008226,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.3390/RS11131587 -US-Vcp,1700008226,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Vcp,1700000450,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Smith, W. K., Biederman, J. A., Scott, R. L., Moore, D. J., He, M., Kimball, J. S., Yan, D., Hudson, A., Barnes, M. L., MacBean, N., Fox, A. M., Litvak, M. E. (2018) Chlorophyll Fluorescence Better Captures Seasonal And Interannual Gross Primary Productivity Dynamics Across Dryland Ecosystems Of Southwestern North America, Geophysical Research Letters, 45(2), 748-757" -US-Vcp,1700000450,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/2017GL075922 -US-Vcp,1700000450,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Vcp,1700005010,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Wolf, S., Keenan, T. F., Fisher, J. B., Baldocchi, D. D., Desai, A. R., Richardson, A. D., Scott, R. L., Law, B. E., Litvak, M. E., Brunsell, N. A., Peters, W., van der Laan-Luijkx, I. T. (2016) Warm Spring Reduced Carbon Cycle Impact Of The 2012 Us Summer Drought, Proceedings Of The National Academy Of Sciences, 113(21), 5880-5885" -US-Vcp,1700005010,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1073/PNAS.1519620113 -US-Vcp,1700005010,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Vcp,1700008304,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Wolf, S., Keenan, T.F., Fisher, J.B., Baldocchi, D.D., Desai, A.R., Richardson, A.D., Scott, R.L., Law, B.E., Litvak, M.E., Brunsell, N.A., Peters, W., van der Laan-Luijkx, I.T. (2016) Warm spring reduced carbon cycle impact of the 2012 US summer drought, Proceedings of the National Academy of Sciences, 113(21), 5880-5885" -US-Vcp,1700008304,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1073/PNAS.1519620113 -US-Vcp,1700008304,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Vcp,30675,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"Research topics and objectives include 1) To understand the coupled water and energy cycles in semiarid environments; 2) Quantify carbon, water and energy fluxes in addition to inter-annual variability in these fluxes; 3) Quantify the extent to which water and carbon fluxes are controlled by soil moisture and rainfall, and the sensitivity of fluxes in this biome to changes in temperature and precipitation." -US-Vcp,12408,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"University of New Mexico, 219 Yale Blvd. NE, Castetter Hall Rm 1480, Albuquerque, NM 87131" -US-Vcp,12409,GRP_SITE_CHAR,WIND_DIRECTION,NW -US-Vcp,12410,GRP_SITE_DESC,SITE_DESC,The Valles Caldera Ponderosa Pine site is located in the 1200km2 Jemez River basin of the Jemez Mountains in north-central New Mexico at the southern margin of the Rocky Mountain ecoregion. The Ponderosa Pine forest is the warmest and lowest (below 2700m) zone of the forests in the Valles Caldera National Preserve. Its vegetation is composed of a Ponderosa Pine (Pinus Ponderosa) overstory and a Gambel Oak (Quercus gambelii) understory. -US-Vcp,12411,GRP_SITE_FUNDING,SITE_FUNDING,AmeriFlux Core Site -US-Vcp,12412,GRP_STATE,STATE,NM -US-Vcp,15513,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Marcy Litvak -US-Vcp,15513,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Vcp,15513,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,mlitvak@unm.edu -US-Vcp,15513,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of New Mexico -US-Vcp,81435,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Tomer Duman -US-Vcp,81435,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,DataManager -US-Vcp,81435,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,tomerduman@gmail.com -US-Vcp,81435,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of New Mexico -US-Vcp,99187,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Anthony Luketich -US-Vcp,99187,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Technician -US-Vcp,99187,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,luketich@unm.edu -US-Vcp,99187,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of New Mexico -US-Vcp,29848,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-Vcp,15514,GRP_TOWER_TYPE,TOWER_TYPE,triangle -US-Vcp,81437,GRP_URL,URL,http://www.litvaklab.org/ponderosa-pine.html -US-Vcp,24000472,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-Vcp -US-Vcp,12415,GRP_UTC_OFFSET,UTC_OFFSET,-7 -US-Vcp,15515,GRP_UTC_OFFSET,UTC_OFFSET,-7 -US-Vcp,15515,GRP_UTC_OFFSET,UTC_OFFSET_DATE_START,200701010000 -US-Vcs,30479,GRP_CLIM_AVG,MAT,4.6 -US-Vcs,30479,GRP_CLIM_AVG,MAP,550.93 -US-Vcs,30479,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfb -US-Vcs,27000693,GRP_COUNTRY,COUNTRY,USA -US-Vcs,79335,GRP_DOI,DOI,10.17190/AMF/1418681 -US-Vcs,79335,GRP_DOI,DOI_CITATION,"Marcy Litvak (2022), AmeriFlux BASE US-Vcs Valles Caldera Sulphur Springs Mixed Conifer, Ver. 11-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1418681" -US-Vcs,79335,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-Vcs,33691,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Vcs,33691,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Marcy Litvak -US-Vcs,33691,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Vcs,33691,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,mlitvak@unm.edu -US-Vcs,33691,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of New Mexico -US-Vcs,33700,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,University of New Mexico -US-Vcs,33700,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-Vcs,30480,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Drought -US-Vcs,30482,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Fire -US-Vcs,30481,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Grazing -US-Vcs,30483,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Pests and disease -US-Vcs,30486,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Vcs,30486,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-Vcs,30486,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201601010000 -US-Vcs,30486,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Vcs,30485,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Vcs,30485,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-Vcs,30485,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201601010000 -US-Vcs,30485,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Vcs,23000693,GRP_HEADER,SITE_NAME,Valles Caldera Sulphur Springs Mixed Conifer -US-Vcs,30487,GRP_IGBP,IGBP,ENF -US-Vcs,30487,GRP_IGBP,IGBP_DATE_START,201601010000 -US-Vcs,30487,GRP_IGBP,IGBP_COMMENT,"Spruce, fir, pine, aspen" -US-Vcs,30488,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-Vcs,30488,GRP_LAND_OWNERSHIP,LAND_OWNER,Department of Interior -US-Vcs,30489,GRP_LOCATION,LOCATION_LAT,35.9193 -US-Vcs,30489,GRP_LOCATION,LOCATION_LONG,-106.6142 -US-Vcs,30489,GRP_LOCATION,LOCATION_ELEV,2752 -US-Vcs,30489,GRP_LOCATION,LOCATION_DATE_START,201601010000 -US-Vcs,30490,GRP_NETWORK,NETWORK,AmeriFlux -US-Vcs,87027,GRP_NETWORK,NETWORK,Phenocam -US-Vcs,1700003507,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(12), 108350" -US-Vcs,1700003507,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -US-Vcs,1700003507,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Vcs,1700000534,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Knowles, J. F., Scott, R. L., Biederman, J. A., Blanken, P. D., Burns, S. P., Dore, S., Kolb, T. E., Litvak, M. E., Barron‐Gafford, G. A. (2020) Montane Forest Productivity Across A Semiarid Climatic Gradient, Global Change Biology, 26(12), 6945-6958" -US-Vcs,1700000534,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/GCB.15335 -US-Vcs,1700000534,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Vcs,1700007842,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Remy, C. C., Krofcheck, D. J., Keyser, A. R., Litvak, M. E., Collins, S. L., Hurteau, M. D. (2019) Integrating Species‐Specific Information In Models Improves Regional Projections Under Climate Change, Geophysical Research Letters, 46(12), 6554-6562" -US-Vcs,1700007842,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2019GL082762 -US-Vcs,1700007842,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Vcs,30491,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"University of New Mexico, Biology - Castetter Hall Room 137, 219 Yale Blvd NE, Albuquerque NM 87131" -US-Vcs,30492,GRP_SITE_CHAR,TERRAIN,Hilltop -US-Vcs,30492,GRP_SITE_CHAR,ASPECT,SE -US-Vcs,30492,GRP_SITE_CHAR,WIND_DIRECTION,WSW -US-Vcs,30774,GRP_SITE_DESC,SITE_DESC,None supplied. -US-Vcs,30493,GRP_STATE,STATE,NM -US-Vcs,30497,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Marcy Litvak -US-Vcs,30497,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Vcs,30497,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,mlitvak@unm.edu -US-Vcs,30497,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of New Mexico -US-Vcs,81439,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Tomer Duman -US-Vcs,81439,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,DataManager -US-Vcs,81439,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,tomerduman@gmail.com -US-Vcs,81439,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of New Mexico -US-Vcs,99195,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Anthony Luketich -US-Vcs,99195,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Technician -US-Vcs,99195,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,luketich@unm.edu -US-Vcs,99195,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Universtiy of New Mexico -US-Vcs,30500,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-Vcs,30498,GRP_TOWER_TYPE,TOWER_TYPE,triangle -US-Vcs,95040,GRP_URL,URL,http://www.litvaklab.org/new-subalpine-mixed-conifer-us-vcs.html -US-Vcs,24000693,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-Vcs -US-Vcs,30499,GRP_UTC_OFFSET,UTC_OFFSET,-7 -US-Vcs,30499,GRP_UTC_OFFSET,UTC_OFFSET_DATE_START,201601010000 -US-WCr,23766,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER,10.29 -US-WCr,23766,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_ORGAN,Total -US-WCr,23766,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_PHEN,Mixed/unknown -US-WCr,23766,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_UNIT,kgDM m-2 -US-WCr,26890,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,0.8 -US-WCr,26890,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Foliage -US-WCr,26890,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-WCr,26890,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-WCr,26890,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,"ABBA, Balsam Fir" -US-WCr,26889,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,1.2 -US-WCr,26889,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Foliage -US-WCr,26889,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-WCr,26889,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-WCr,26889,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,"POTR5, Quaking Aspen" -US-WCr,27956,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,142.77 -US-WCr,27956,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Foliage -US-WCr,27956,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-WCr,27956,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-WCr,27956,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,Jon Martin -US-WCr,29041,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,1470 -US-WCr,29041,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Foliage -US-WCr,29041,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-WCr,29041,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-WCr,29041,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,"ACRU, Red Maple" -US-WCr,27034,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,199 -US-WCr,27034,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Wood -US-WCr,27034,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-WCr,27034,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-WCr,27034,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,Live Aboveground Woody BioMass; www.cheas.psu.edu/data/cheas/biometry -US-WCr,27034,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,(without twigs/branches)P. Bolstad -US-WCr,27587,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,2120 -US-WCr,27587,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Foliage -US-WCr,27587,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-WCr,27587,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-WCr,27587,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,"FRPE, Green Ash" -US-WCr,29156,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,223.5 -US-WCr,29156,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Wood -US-WCr,29156,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-WCr,29156,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-WCr,29156,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,Live Aboveground Woody BioMass; www.cheas.psu.edu/data/cheas/biometry -US-WCr,29156,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,(with twigs/branches)P. Bolstad -US-WCr,26888,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,300 -US-WCr,26888,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Foliage -US-WCr,26888,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-WCr,26888,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-WCr,26888,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,"QUMA2, Bur Oak" -US-WCr,26742,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,320 -US-WCr,26742,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Foliage -US-WCr,26742,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-WCr,26742,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-WCr,26742,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,"OSVI, Hophornbeam" -US-WCr,27033,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,3710 -US-WCr,27033,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Foliage -US-WCr,27033,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-WCr,27033,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-WCr,27033,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,"ACSA3, Sugar Maple" -US-WCr,27586,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,3820 -US-WCr,27586,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Foliage -US-WCr,27586,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-WCr,27586,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-WCr,27586,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,"TIAM, American Basswood" -US-WCr,27335,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,5520 -US-WCr,27335,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Foliage -US-WCr,27335,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-WCr,27335,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-WCr,27335,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,"QURU, Northern Red Oak" -US-WCr,28571,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE,7361.89 -US-WCr,28571,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_ORGAN,Wood -US-WCr,28571,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_PHEN,Mixed/unknown -US-WCr,28571,GRP_AG_BIOMASS_TREE,AG_BIOMASS_TREE_UNIT,gC m-2 -US-WCr,28571,GRP_AG_BIOMASS_TREE,AG_BIOMASS_APPROACH,Live Aboveground Woody BioMass; www.cheas.psu.edu/data/cheas/biometry -US-WCr,28571,GRP_AG_BIOMASS_TREE,AG_BIOMASS_COMMENT,Jon Martin -US-WCr,27330,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS,0.111 -US-WCr,27330,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_UNIT,gC m-2 -US-WCr,27330,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_DATE,1999 -US-WCr,27330,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_COMMENT,average over 1999-2002; Bolstadt et al 2003 -US-WCr,27949,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS,0.111 -US-WCr,27949,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_UNIT,gC m-2 -US-WCr,27949,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_DATE,2000 -US-WCr,27949,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_COMMENT,average over 1999-2002; Bolstadt et al 2003 -US-WCr,27955,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS,0.111 -US-WCr,27955,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_UNIT,gC m-2 -US-WCr,27955,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_DATE,2002 -US-WCr,27955,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_COMMENT,average over 1999-2002; Bolstadt et al 2003 -US-WCr,28567,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS,0.111 -US-WCr,28567,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_UNIT,gC m-2 -US-WCr,28567,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_DATE,2001 -US-WCr,28567,GRP_AG_LIT_BIOMASS,AG_LIT_BIOMASS_COMMENT,average over 1999-2002; Bolstadt et al 2003 -US-WCr,28559,GRP_AG_LIT_CHEM,AG_LIT_C,3.7 -US-WCr,26897,GRP_AG_LIT_CHEM,AG_LIT_C,4.69 -US-WCr,26897,GRP_AG_LIT_CHEM,AG_LIT_N,0.076 -US-WCr,28559,GRP_AG_LIT_CHEM,AG_LIT_N,0.1163 -US-WCr,28559,GRP_AG_LIT_CHEM,AG_LIT_COMMENT,"P. Bolstad, from Willow Creek" -US-WCr,26897,GRP_AG_LIT_CHEM,AG_LIT_COMMENT,P. Weishampel -US-WCr,27338,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT,133 -US-WCr,27339,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT,139 -US-WCr,29502,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT,140.16 -US-WCr,27588,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT,20 -US-WCr,27340,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT,33 -US-WCr,27959,GRP_AG_LIT_PROD,AG_LIT_PROD_TOT,33 -US-WCr,27338,GRP_AG_LIT_PROD,AG_LIT_PROD_UNIT,gC m-2 -US-WCr,27339,GRP_AG_LIT_PROD,AG_LIT_PROD_UNIT,gC m-2 -US-WCr,27340,GRP_AG_LIT_PROD,AG_LIT_PROD_UNIT,gC m-2 -US-WCr,27588,GRP_AG_LIT_PROD,AG_LIT_PROD_UNIT,gC m-2 -US-WCr,27959,GRP_AG_LIT_PROD,AG_LIT_PROD_UNIT,gC m-2 -US-WCr,29502,GRP_AG_LIT_PROD,AG_LIT_PROD_UNIT,gC m-2 -US-WCr,27959,GRP_AG_LIT_PROD,AG_LIT_PROD_COMMENT,"basswood. Cook et al., 2008, Table 1" -US-WCr,27338,GRP_AG_LIT_PROD,AG_LIT_PROD_COMMENT,"Cook et al 2004, Table 1" -US-WCr,27340,GRP_AG_LIT_PROD,AG_LIT_PROD_COMMENT,"green ash. Cook et al., 2008, Table 1" -US-WCr,27588,GRP_AG_LIT_PROD,AG_LIT_PROD_COMMENT,"red oak. Cook et al., 2008, Table 1" -US-WCr,27339,GRP_AG_LIT_PROD,AG_LIT_PROD_COMMENT,"sugar maple. Cook et al., 2008, Table 1" -US-WCr,29502,GRP_AG_LIT_PROD,AG_LIT_PROD_COMMENT,www.cheas.psu.edu -US-WCr,26891,GRP_AG_PROD_TREE,AG_PROD_TREE,142.77 -US-WCr,26891,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Foliage -US-WCr,26891,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-WCr,26891,GRP_AG_PROD_TREE,AG_PROD_COMMENT,Cook et al 2004 -US-WCr,26743,GRP_AG_PROD_TREE,AG_PROD_TREE,156.29 -US-WCr,26743,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Wood -US-WCr,26743,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-WCr,26743,GRP_AG_PROD_TREE,AG_PROD_COMMENT,Cook et al 2004 -US-WCr,26892,GRP_AG_PROD_TREE,AG_PROD_TREE,162 -US-WCr,26892,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Wood -US-WCr,26892,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-WCr,26892,GRP_AG_PROD_TREE,AG_PROD_COMMENT,"Change in biomass, boles & branches, Cook et al 2004, Table 1" -US-WCr,28554,GRP_AG_PROD_TREE,AG_PROD_TREE,264.5 -US-WCr,28554,GRP_AG_PROD_TREE,AG_PROD_TREE_ORGAN,Total -US-WCr,28554,GRP_AG_PROD_TREE,AG_PROD_TREE_UNIT,gC m-2 -US-WCr,28554,GRP_AG_PROD_TREE,AG_PROD_COMMENT,"from Cheas website, aboveground growth increment" -US-WCr,28314,GRP_BIOMASS_CHEM,BIOMASS_C,4.74 -US-WCr,29508,GRP_BIOMASS_CHEM,BIOMASS_N,0.101 -US-WCr,26895,GRP_BIOMASS_CHEM,BIOMASS_N,0.119 -US-WCr,27042,GRP_BIOMASS_CHEM,BIOMASS_N,0.184 -US-WCr,26896,GRP_BIOMASS_CHEM,BIOMASS_N,0.194 -US-WCr,28313,GRP_BIOMASS_CHEM,BIOMASS_N,0.209 -US-WCr,28558,GRP_BIOMASS_CHEM,BIOMASS_N,0.221 -US-WCr,26749,GRP_BIOMASS_CHEM,BIOMASS_N,0.229 -US-WCr,29507,GRP_BIOMASS_CHEM,BIOMASS_N,0.245 -US-WCr,26749,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-WCr,26895,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-WCr,26896,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-WCr,27042,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-WCr,28313,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-WCr,28314,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-WCr,28558,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-WCr,29507,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-WCr,29508,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-WCr,26749,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-WCr,26895,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-WCr,26896,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-WCr,27042,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-WCr,28313,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-WCr,28314,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-WCr,28558,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-WCr,29507,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-WCr,29508,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-WCr,28314,GRP_BIOMASS_CHEM,BIOMASS_SPP,(All) -US-WCr,29508,GRP_BIOMASS_CHEM,BIOMASS_SPP,ABBA (NRCS plant code) -US-WCr,26895,GRP_BIOMASS_CHEM,BIOMASS_SPP,ACRU (NRCS plant code) -US-WCr,27042,GRP_BIOMASS_CHEM,BIOMASS_SPP,ACSA3 (NRCS plant code) -US-WCr,29507,GRP_BIOMASS_CHEM,BIOMASS_SPP,FRPE (NRCS plant code) -US-WCr,26896,GRP_BIOMASS_CHEM,BIOMASS_SPP,OSVI (NRCS plant code) -US-WCr,28313,GRP_BIOMASS_CHEM,BIOMASS_SPP,POTR5 (NRCS plant code) -US-WCr,28558,GRP_BIOMASS_CHEM,BIOMASS_SPP,QURU (NRCS plant code) -US-WCr,26749,GRP_BIOMASS_CHEM,BIOMASS_SPP,TIAM (NRCS plant code) -US-WCr,26749,GRP_BIOMASS_CHEM,BIOMASS_DATE,2000 -US-WCr,26895,GRP_BIOMASS_CHEM,BIOMASS_DATE,2000 -US-WCr,26896,GRP_BIOMASS_CHEM,BIOMASS_DATE,2000 -US-WCr,27042,GRP_BIOMASS_CHEM,BIOMASS_DATE,2000 -US-WCr,28313,GRP_BIOMASS_CHEM,BIOMASS_DATE,2000 -US-WCr,28558,GRP_BIOMASS_CHEM,BIOMASS_DATE,2000 -US-WCr,29507,GRP_BIOMASS_CHEM,BIOMASS_DATE,2000 -US-WCr,29508,GRP_BIOMASS_CHEM,BIOMASS_DATE,2000 -US-WCr,26749,GRP_BIOMASS_CHEM,BIOMASS_COMMENT,"(American Basswood); Paul. Bolstad, 126 leaf samples, taken at Willow Creek" -US-WCr,29508,GRP_BIOMASS_CHEM,BIOMASS_COMMENT,"(Balsam Fir); Paul. Bolstad, 126 leaf samples, taken at Willow Creek" -US-WCr,29507,GRP_BIOMASS_CHEM,BIOMASS_COMMENT,"(Green Ash); Paul. Bolstad, 126 leaf samples, taken at Willow Creek" -US-WCr,26896,GRP_BIOMASS_CHEM,BIOMASS_COMMENT,"(Hophornbeam); Paul. Bolstad, 126 leaf samples, taken at Willow Creek" -US-WCr,28558,GRP_BIOMASS_CHEM,BIOMASS_COMMENT,"(Northern Red Oak); Paul. Bolstad, 126 leaf samples, taken at Willow Creek" -US-WCr,28313,GRP_BIOMASS_CHEM,BIOMASS_COMMENT,"(Quaking Aspen); Paul. Bolstad, 126 leaf samples, taken at Willow Creek" -US-WCr,26895,GRP_BIOMASS_CHEM,BIOMASS_COMMENT,"(Red Maple); Paul. Bolstad, 126 leaf samples, taken at Willow Creek" -US-WCr,27042,GRP_BIOMASS_CHEM,BIOMASS_COMMENT,"(Sugar Maple); Paul. Bolstad, 126 leaf samples, taken at Willow Creek" -US-WCr,28314,GRP_BIOMASS_CHEM,BIOMASS_COMMENT,"Paul Bolstad, from Willow Creek" -US-WCr,14447,GRP_CLIM_AVG,MAT,4.02 -US-WCr,14447,GRP_CLIM_AVG,MAP,787 -US-WCr,14447,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfb -US-WCr,27000444,GRP_COUNTRY,COUNTRY,USA -US-WCr,1131,GRP_DM_FORESTRY,DM_FORESTRY,Clearcutting -US-WCr,1131,GRP_DM_FORESTRY,DM_DATE,1993 -US-WCr,1131,GRP_DM_FORESTRY,DM_COMMENT,removed; 2007 Fluxnet File -US-WCr,15618,GRP_DOI,DOI,10.17190/AMF/1246111 -US-WCr,15618,GRP_DOI,DOI_CITATION,"Ankur Desai (2022), AmeriFlux BASE US-WCr Willow Creek, Ver. 22-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1246111" -US-WCr,15618,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-WCr,32227,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-WCr,32227,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Ankur Desai -US-WCr,32227,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-WCr,32227,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,desai@aos.wisc.edu -US-WCr,32227,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of Wisconsin -US-WCr,32229,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,University of Wisconsin -US-WCr,32229,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-WCr,32228,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,DOE Ameriflux Network Management Project -US-WCr,32228,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-WCr,14448,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Forestry -US-WCr,91750,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-WCr,91750,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-WCr,91750,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,19990101 -US-WCr,91750,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-WCr,91750,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,"No flux measurements 2007- mid 2010, also Jan-Apr 2020, confirm 4/1/2020" -US-WCr,91749,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-WCr,91749,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-WCr,91749,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,19990101 -US-WCr,91749,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-WCr,91749,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_COMMENT,confirmed 4/1/2020 -US-WCr,14464,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-WCr,14464,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-WCr,14464,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,1999 -US-WCr,14464,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-WCr,23000444,GRP_HEADER,SITE_NAME,Willow Creek -US-WCr,88193,GRP_HEIGHTC,HEIGHTC,24.3 -US-WCr,88193,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-WCr,88193,GRP_HEIGHTC,HEIGHTC_DATE,20050404 -US-WCr,88193,GRP_HEIGHTC,HEIGHTC_COMMENT,From Ameriflux Site Info Page -US-WCr,14450,GRP_IGBP,IGBP,DBF -US-WCr,14450,GRP_IGBP,IGBP_COMMENT,"sugar maple (Acer saccharum), basswood (Tilia americana), and yellow birch (Betula alleghaniensis)." -US-WCr,27029,GRP_LAI,LAI_TYPE,LAI -US-WCr,27332,GRP_LAI,LAI_TYPE,LAI -US-WCr,27954,GRP_LAI,LAI_TYPE,LAI -US-WCr,28216,GRP_LAI,LAI_TYPE,LAI -US-WCr,28310,GRP_LAI,LAI_TYPE,LAI -US-WCr,28566,GRP_LAI,LAI_TYPE,LAI -US-WCr,29149,GRP_LAI,LAI_TYPE,LAI -US-WCr,29150,GRP_LAI,LAI_TYPE,LAI -US-WCr,28216,GRP_LAI,LAI_COMMENT,(max) www.cheas.psu.edu -US-WCr,28310,GRP_LAI,LAI_COMMENT,"1998-2000 average over entire footprint, P. Bolstad" -US-WCr,29149,GRP_LAI,LAI_COMMENT,"ACSA3 ,sugar maple, Cook et al., 2008; Table 1" -US-WCr,27332,GRP_LAI,LAI_COMMENT,Cook et al 2004 -US-WCr,29150,GRP_LAI,LAI_COMMENT,"FRPE, green ash, Cook et al., 2008; Table 1" -US-WCr,27954,GRP_LAI,LAI_COMMENT,"over all species, Cook et al., 2008; Table 1" -US-WCr,28566,GRP_LAI,LAI_COMMENT,"QURU, red oak, Cook et al., 2008; Table 1" -US-WCr,27029,GRP_LAI,LAI_COMMENT,"TIAM, basswood, Cook et al., 2008; Table 1" -US-WCr,28566,GRP_LAI,LAI_TOT,0.32 -US-WCr,29150,GRP_LAI,LAI_TOT,0.64 -US-WCr,27029,GRP_LAI,LAI_TOT,0.68 -US-WCr,29149,GRP_LAI,LAI_TOT,3.73 -US-WCr,28310,GRP_LAI,LAI_TOT,4.05 -US-WCr,27332,GRP_LAI,LAI_TOT,5.3 -US-WCr,27954,GRP_LAI,LAI_TOT,5.36 -US-WCr,28216,GRP_LAI,LAI_TOT,5.36 -US-WCr,14451,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-WCr,14451,GRP_LAND_OWNERSHIP,LAND_OWNER,USDA-Forest Service. Chequamegon-Nicollet National Forest. -US-WCr,26744,GRP_LMA,LMA,21.82 -US-WCr,26744,GRP_LMA,LMA_SPP,ACSA3 (NRCS plant code) -US-WCr,26744,GRP_LMA,LMA_DATE,1999 -US-WCr,26744,GRP_LMA,LMA_COMMENT,"1999-2002; (Sugar Maple); ; Bolstadt et al 2003, Table 2" -US-WCr,26747,GRP_LMA,LMA,21.82 -US-WCr,26747,GRP_LMA,LMA_SPP,ACSA3 (NRCS plant code) -US-WCr,26747,GRP_LMA,LMA_DATE,2002 -US-WCr,26747,GRP_LMA,LMA_COMMENT,"1999-2002; (Sugar Maple); ; Bolstadt et al 2003, Table 2" -US-WCr,27343,GRP_LMA,LMA,21.82 -US-WCr,27343,GRP_LMA,LMA_SPP,ACSA3 (NRCS plant code) -US-WCr,27343,GRP_LMA,LMA_DATE,2001 -US-WCr,27343,GRP_LMA,LMA_COMMENT,"1999-2002; (Sugar Maple); ; Bolstadt et al 2003, Table 2" -US-WCr,29154,GRP_LMA,LMA,21.82 -US-WCr,29154,GRP_LMA,LMA_SPP,ACSA3 (NRCS plant code) -US-WCr,29154,GRP_LMA,LMA_DATE,2000 -US-WCr,29154,GRP_LMA,LMA_COMMENT,"1999-2002; (Sugar Maple); ; Bolstadt et al 2003, Table 2" -US-WCr,27037,GRP_LMA,LMA,27.92 -US-WCr,27037,GRP_LMA,LMA_SPP,ULRU (NRCS plant code) -US-WCr,27037,GRP_LMA,LMA_DATE,1999 -US-WCr,27037,GRP_LMA,LMA_COMMENT,"1999-2002; (Slippery Elm); Bolstadt et al 2003, Table 2" -US-WCr,27040,GRP_LMA,LMA,27.92 -US-WCr,27040,GRP_LMA,LMA_SPP,ULRU (NRCS plant code) -US-WCr,27040,GRP_LMA,LMA_DATE,2001 -US-WCr,27040,GRP_LMA,LMA_COMMENT,"1999-2002; (Slippery Elm); Bolstadt et al 2003, Table 2" -US-WCr,27342,GRP_LMA,LMA,27.92 -US-WCr,27342,GRP_LMA,LMA_SPP,ULRU (NRCS plant code) -US-WCr,27342,GRP_LMA,LMA_DATE,2000 -US-WCr,27342,GRP_LMA,LMA_COMMENT,"1999-2002; (Slippery Elm); Bolstadt et al 2003, Table 2" -US-WCr,29506,GRP_LMA,LMA,27.92 -US-WCr,29506,GRP_LMA,LMA_SPP,ULRU (NRCS plant code) -US-WCr,29506,GRP_LMA,LMA_DATE,2002 -US-WCr,29506,GRP_LMA,LMA_COMMENT,"1999-2002; (Slippery Elm); Bolstadt et al 2003, Table 2" -US-WCr,26746,GRP_LMA,LMA,28.33 -US-WCr,26746,GRP_LMA,LMA_SPP,TIAM (NRCS plant code) -US-WCr,26746,GRP_LMA,LMA_DATE,1999 -US-WCr,26746,GRP_LMA,LMA_COMMENT,"1999-2002; (American Basswood); Bolstadt et al 2003, Table 2" -US-WCr,26894,GRP_LMA,LMA,28.33 -US-WCr,26894,GRP_LMA,LMA_SPP,TIAM (NRCS plant code) -US-WCr,26894,GRP_LMA,LMA_DATE,2002 -US-WCr,26894,GRP_LMA,LMA_COMMENT,"1999-2002; (American Basswood); Bolstadt et al 2003, Table 2" -US-WCr,27341,GRP_LMA,LMA,28.33 -US-WCr,27341,GRP_LMA,LMA_SPP,TIAM (NRCS plant code) -US-WCr,27341,GRP_LMA,LMA_DATE,2000 -US-WCr,27341,GRP_LMA,LMA_COMMENT,"1999-2002; (American Basswood); Bolstadt et al 2003, Table 2" -US-WCr,29505,GRP_LMA,LMA,28.33 -US-WCr,29505,GRP_LMA,LMA_SPP,TIAM (NRCS plant code) -US-WCr,29505,GRP_LMA,LMA_DATE,2001 -US-WCr,29505,GRP_LMA,LMA_COMMENT,"1999-2002; (American Basswood); Bolstadt et al 2003, Table 2" -US-WCr,26748,GRP_LMA,LMA,28.46 -US-WCr,26748,GRP_LMA,LMA_SPP,POTR5 (NRCS plant code) -US-WCr,26748,GRP_LMA,LMA_DATE,2002 -US-WCr,26748,GRP_LMA,LMA_COMMENT,"1999-2002; (Quaking Aspen); Bolstadt et al 2003, Table 2" -US-WCr,27039,GRP_LMA,LMA,28.46 -US-WCr,27039,GRP_LMA,LMA_SPP,POTR5 (NRCS plant code) -US-WCr,27039,GRP_LMA,LMA_DATE,2001 -US-WCr,27039,GRP_LMA,LMA_COMMENT,"1999-2002; (Quaking Aspen); Bolstadt et al 2003, Table 2" -US-WCr,28555,GRP_LMA,LMA,28.46 -US-WCr,28555,GRP_LMA,LMA_SPP,POTR5 (NRCS plant code) -US-WCr,28555,GRP_LMA,LMA_DATE,1999 -US-WCr,28555,GRP_LMA,LMA_COMMENT,"1999-2002; (Quaking Aspen); Bolstadt et al 2003, Table 2" -US-WCr,29504,GRP_LMA,LMA,28.46 -US-WCr,29504,GRP_LMA,LMA_SPP,POTR5 (NRCS plant code) -US-WCr,29504,GRP_LMA,LMA_DATE,2000 -US-WCr,29504,GRP_LMA,LMA_COMMENT,"1999-2002; (Quaking Aspen); Bolstadt et al 2003, Table 2" -US-WCr,26745,GRP_LMA,LMA,33.09 -US-WCr,26745,GRP_LMA,LMA_SPP,FRPE (NRCS plant code) -US-WCr,26745,GRP_LMA,LMA_DATE,1999 -US-WCr,26745,GRP_LMA,LMA_COMMENT,"1999-2002; (Green Ash); Bolstadt et al 2003, Table 2" -US-WCr,27038,GRP_LMA,LMA,33.09 -US-WCr,27038,GRP_LMA,LMA_SPP,FRPE (NRCS plant code) -US-WCr,27038,GRP_LMA,LMA_DATE,2000 -US-WCr,27038,GRP_LMA,LMA_COMMENT,"1999-2002; (Green Ash); Bolstadt et al 2003, Table 2" -US-WCr,27589,GRP_LMA,LMA,33.09 -US-WCr,27589,GRP_LMA,LMA_SPP,FRPE (NRCS plant code) -US-WCr,27589,GRP_LMA,LMA_DATE,2001 -US-WCr,27589,GRP_LMA,LMA_COMMENT,"1999-2002; (Green Ash); Bolstadt et al 2003, Table 2" -US-WCr,28557,GRP_LMA,LMA,33.09 -US-WCr,28557,GRP_LMA,LMA_SPP,FRPE (NRCS plant code) -US-WCr,28557,GRP_LMA,LMA_DATE,2002 -US-WCr,28557,GRP_LMA,LMA_COMMENT,"1999-2002; (Green Ash); Bolstadt et al 2003, Table 2" -US-WCr,27041,GRP_LMA,LMA,43.67 -US-WCr,27041,GRP_LMA,LMA_SPP,QURU (NRCS plant code) -US-WCr,27041,GRP_LMA,LMA_DATE,2002 -US-WCr,27041,GRP_LMA,LMA_COMMENT,"1999-2002; (Northern Red Oak); Bolstadt et al 2003, Table 2" -US-WCr,27960,GRP_LMA,LMA,43.67 -US-WCr,27960,GRP_LMA,LMA_SPP,QURU (NRCS plant code) -US-WCr,27960,GRP_LMA,LMA_DATE,2000 -US-WCr,27960,GRP_LMA,LMA_COMMENT,"1999-2002; (Northern Red Oak); Bolstadt et al 2003, Table 2" -US-WCr,28556,GRP_LMA,LMA,43.67 -US-WCr,28556,GRP_LMA,LMA_SPP,QURU (NRCS plant code) -US-WCr,28556,GRP_LMA,LMA_DATE,2001 -US-WCr,28556,GRP_LMA,LMA_COMMENT,"1999-2002; (Northern Red Oak); Bolstadt et al 2003, Table 2" -US-WCr,29503,GRP_LMA,LMA,43.67 -US-WCr,29503,GRP_LMA,LMA_SPP,QURU (NRCS plant code) -US-WCr,29503,GRP_LMA,LMA_DATE,1999 -US-WCr,29503,GRP_LMA,LMA_COMMENT,"1999-2002; (Northern Red Oak); Bolstadt et al 2003, Table 2" -US-WCr,14452,GRP_LOCATION,LOCATION_LAT,45.8059 -US-WCr,14452,GRP_LOCATION,LOCATION_LONG,-90.0799 -US-WCr,14452,GRP_LOCATION,LOCATION_ELEV,520.00 -US-WCr,25049,GRP_NEP,NEP,556.5 -US-WCr,14453,GRP_NETWORK,NETWORK,AmeriFlux -US-WCr,87028,GRP_NETWORK,NETWORK,Phenocam -US-WCr,26751,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,BudBreak -US-WCr,26751,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,(All) -US-WCr,26751,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20030511 -US-WCr,26751,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,www.cheas.psu.edu/data/cheas/phenology -US-WCr,26752,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,BudBreak -US-WCr,26752,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,(All) -US-WCr,26752,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20040510 -US-WCr,26752,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,www.cheas.psu.edu/data/cheas/phenology -US-WCr,26753,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,BudBreak -US-WCr,26753,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,(All) -US-WCr,26753,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20050510 -US-WCr,26753,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,www.cheas.psu.edu/data/cheas/phenology -US-WCr,27046,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,BudBreak -US-WCr,27046,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,(All) -US-WCr,27046,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20000429 -US-WCr,27046,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,www.cheas.psu.edu/data/cheas/phenology -US-WCr,27592,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,BudBreak -US-WCr,27592,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,(All) -US-WCr,27592,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20010429 -US-WCr,27592,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,www.cheas.psu.edu/data/cheas/phenology -US-WCr,28561,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,BudBreak -US-WCr,28561,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,(All) -US-WCr,28561,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20020417 -US-WCr,28561,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,www.cheas.psu.edu/data/cheas/phenology -US-WCr,29043,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,BudBreak -US-WCr,29043,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,(All) -US-WCr,29043,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20060426 -US-WCr,29043,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,www.cheas.psu.edu/data/cheas/phenology -US-WCr,29509,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,BudBreak -US-WCr,29509,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,(All) -US-WCr,29509,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,19990425 -US-WCr,29509,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,www.cheas.psu.edu/data/cheas/phenology -US-WCr,27345,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,Leaf senescence -US-WCr,27345,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,(All) -US-WCr,27345,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20030608 -US-WCr,27345,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,www.cheas.psu.edu/data/cheas/phenology -US-WCr,27346,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,Leaf senescence -US-WCr,27346,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,(All) -US-WCr,27346,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20050607 -US-WCr,27346,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,www.cheas.psu.edu/data/cheas/phenology -US-WCr,27593,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,Leaf senescence -US-WCr,27593,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,(All) -US-WCr,27593,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20010527 -US-WCr,27593,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,www.cheas.psu.edu/data/cheas/phenology -US-WCr,28573,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,Leaf senescence -US-WCr,28573,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,(All) -US-WCr,28573,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20020425 -US-WCr,28573,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,www.cheas.psu.edu/data/cheas/phenology -US-WCr,28574,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,Leaf senescence -US-WCr,28574,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,(All) -US-WCr,28574,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20040611 -US-WCr,28574,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,www.cheas.psu.edu/data/cheas/phenology -US-WCr,29044,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,Leaf senescence -US-WCr,29044,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,(All) -US-WCr,29044,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20000528 -US-WCr,29044,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,www.cheas.psu.edu/data/cheas/phenology -US-WCr,29510,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,Leaf senescence -US-WCr,29510,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,(All) -US-WCr,29510,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,19990527 -US-WCr,29510,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,www.cheas.psu.edu/data/cheas/phenology -US-WCr,29511,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,Leaf senescence -US-WCr,29511,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,(All) -US-WCr,29511,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20060601 -US-WCr,29511,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,www.cheas.psu.edu/data/cheas/phenology -US-WCr,27048,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,Maximum leaf expansion -US-WCr,27048,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,(All) -US-WCr,27048,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20001021 -US-WCr,27048,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,www.cheas.psu.edu/data/cheas/phenology -US-WCr,27347,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,Maximum leaf expansion -US-WCr,27347,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,(All) -US-WCr,27347,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20051028 -US-WCr,27347,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,www.cheas.psu.edu/data/cheas/phenology -US-WCr,27961,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,Maximum leaf expansion -US-WCr,27961,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,(All) -US-WCr,27961,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20041027 -US-WCr,27961,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,www.cheas.psu.edu/data/cheas/phenology -US-WCr,27962,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,Maximum leaf expansion -US-WCr,27962,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,(All) -US-WCr,27962,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20061015 -US-WCr,27962,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,www.cheas.psu.edu/data/cheas/phenology -US-WCr,28575,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,Maximum leaf expansion -US-WCr,28575,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,(All) -US-WCr,28575,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20021023 -US-WCr,28575,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,www.cheas.psu.edu/data/cheas/phenology -US-WCr,28576,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,Maximum leaf expansion -US-WCr,28576,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,(All) -US-WCr,28576,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20031026 -US-WCr,28576,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,www.cheas.psu.edu/data/cheas/phenology -US-WCr,29158,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,Maximum leaf expansion -US-WCr,29158,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,(All) -US-WCr,29158,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,19991020 -US-WCr,29158,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,www.cheas.psu.edu/data/cheas/phenology -US-WCr,29159,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,Maximum leaf expansion -US-WCr,29159,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,(All) -US-WCr,29159,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20011018 -US-WCr,29159,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,www.cheas.psu.edu/data/cheas/phenology -US-WCr,26754,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,Total leaf-off -US-WCr,26754,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,(All) -US-WCr,26754,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20050926 -US-WCr,26754,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,www.cheas.psu.edu/data/cheas/phenology -US-WCr,26900,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,Total leaf-off -US-WCr,26900,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,(All) -US-WCr,26900,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20031004 -US-WCr,26900,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,www.cheas.psu.edu/data/cheas/phenology -US-WCr,26901,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,Total leaf-off -US-WCr,26901,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,(All) -US-WCr,26901,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20041004 -US-WCr,26901,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,www.cheas.psu.edu/data/cheas/phenology -US-WCr,27047,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,Total leaf-off -US-WCr,27047,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,(All) -US-WCr,27047,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20060925 -US-WCr,27047,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,www.cheas.psu.edu/data/cheas/phenology -US-WCr,27594,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,Total leaf-off -US-WCr,27594,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,(All) -US-WCr,27594,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20000926 -US-WCr,27594,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,www.cheas.psu.edu/data/cheas/phenology -US-WCr,28316,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,Total leaf-off -US-WCr,28316,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,(All) -US-WCr,28316,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20010926 -US-WCr,28316,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,www.cheas.psu.edu/data/cheas/phenology -US-WCr,28562,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,Total leaf-off -US-WCr,28562,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,(All) -US-WCr,28562,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,20020930 -US-WCr,28562,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,www.cheas.psu.edu/data/cheas/phenology -US-WCr,29045,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_TYPE,Total leaf-off -US-WCr,29045,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_SPP,(All) -US-WCr,29045,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_DATE,19990925 -US-WCr,29045,GRP_PHEN_EVENT_TYPE,PHEN_EVENT_COMMENT,www.cheas.psu.edu/data/cheas/phenology -US-WCr,1700008418,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Baker, I., Denning, A. S., Hanan, N., Prihodko, L., Uliasz, M., Vidale, P., Davis, K., Bakwin, P. (2003) Simulated And Observed Fluxes Of Sensible And Latent Heat And CO2 At The WLEF-TV Tower Using SiB2.5, Global Change Biology, 9(9), 1262-1277" -US-WCr,1700008418,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1046/J.1365-2486.2003.00671.X -US-WCr,1700008418,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-WCr,1700003729,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Bakwin, P. S., Davis, K. J., Yi, C., Wofsy, S. C., Munger, J. W., Haszpra, L., Barcza, Z. (2004) Regional Carbon Dioxide Fluxes From Mixing Ratio Data, Tellus Series B-Chemical and Physical Meteorology, 56(4), 301-311" -US-WCr,1700003729,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.3402/TELLUSB.V56I4.16446 -US-WCr,1700003729,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-WCr,1700000627,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Baldocchi, D., Penuelas, J. (2018) The Physics And Ecology Of Mining Carbon Dioxide From The Atmosphere By Ecosystems, Global Change Biology, 120(4), 600-616" -US-WCr,1700000627,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/GCB.14559 -US-WCr,1700000627,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-WCr,1700002784,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Barr, A., Richardson, A., Hollinger, D., Papale, D., Arain, M., Black, T., Bohrer, G., Dragoni, D., Fischer, M., Gu, L., Law, B., Margolis, H., McCaughey, J., Munger, J., Oechel, W., Schaeffer, K. (2013) Use Of Change-Point Detection For Friction–Velocity Threshold Evaluation In Eddy-Covariance Studies, Agricultural And Forest Meteorology, 171-172(7458), 31-45" -US-WCr,1700002784,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2012.11.023 -US-WCr,1700002784,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-WCr,1700000804,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Besnard, S., Carvalhais, N., Arain, M. A., Black, A., de Bruin, S., Buchmann, N., Cescatti, A., Chen, J., Clevers, J. G., Desai, A. R., Gough, C. M., Havrankova, K., Herold, M., Hörtnagl, L., Jung, M., Knohl, A., Kruijt, B., Krupkova, L., Law, B. E., Lindroth, A., Noormets, A., Roupsard, O., Steinbrecher, R., Varlagin, A., Vincke, C., Reichstein, M. (2018) Quantifying The Effect Of Forest Age In Annual Net Forest Carbon Balance, Environmental Research Letters, 13(12), 124018" -US-WCr,1700000804,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1088/1748-9326/AAEAEB -US-WCr,1700000804,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-WCr,1700002145,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Bolstad, P. V., Davis, K. J., Martin, J., Cook, B. D., Wang, W. (2004) Component And Whole-System Respiration Fluxes In Northern Deciduous Forests, Tree Physiology, 24(5), 493-504" -US-WCr,1700002145,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1093/TREEPHYS/24.5.493 -US-WCr,1700002145,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-WCr,1700007644,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(6), 108350" -US-WCr,1700007644,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -US-WCr,1700007644,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-WCr,1700004536,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Cook, B. D., Davis, K. J., Wang, W., Desai, A., Berger, B. W., Teclaw, R. M., Martin, J. G., Bolstad, P. V., Bakwin, P. S., Yi, C., Heilman, W. (2004) Carbon Exchange And Venting Anomalies In An Upland Deciduous Forest In Northern Wisconsin, USA, Agricultural And Forest Meteorology, 126(3-4), 271-295" -US-WCr,1700004536,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2004.06.008 -US-WCr,1700004536,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Primary_Citation -US-WCr,1700003171,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Curtis, P. S., Hanson, P. J., Bolstad, P., Barford, C., Randolph, J., Schmid, H., Wilson, K. B. (2002) Biometric And Eddy-Covariance Based Estimates Of Annual Carbon Storage In Five Eastern North American Deciduous Forests, Agricultural And Forest Meteorology, 113(1-4), 3-19" -US-WCr,1700003171,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/S0168-1923(02)00099-0 -US-WCr,1700003171,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-WCr,1700000645,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Davis, K. J., Bakwin, P. S., Yi, C., Berger, B. W., Zhao, C., Teclaw, R. M., Isebrands, J. G. (2003) The Annual Cycles Of CO2 And H2O Exchange Over A Northern Mixed Forest As Observed From A Very Tall Tower, Global Change Biology, 9(9), 1278-1293" -US-WCr,1700000645,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1046/J.1365-2486.2003.00672.X -US-WCr,1700000645,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-WCr,1700007857,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Desai, A. R., Bolstad, P. V., Cook, B. D., Davis, K. J., Carey, E. V. (2005) Comparing Net Ecosystem Exchange Of Carbon Dioxide Between An Old-Growth And Mature Forest In The Upper Midwest, Usa, Agricultural And Forest Meteorology, 128(1-2), 33-55" -US-WCr,1700007857,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2004.09.005 -US-WCr,1700007857,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-WCr,1700003903,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Desai, A. R., Noormets, A., Bolstad, P. V., Chen, J., Cook, B. D., Davis, K. J., Euskirchen, E. S., Gough, C., Martin, J. G., Ricciuto, D. M., Schmid, H. P., Tang, J., Wang, W. (2008) Influence Of Vegetation And Seasonal Forcing On Carbon Dioxide Fluxes Across The Upper Midwest, Usa: Implications For Regional Scaling, Agricultural And Forest Meteorology, 148(2), 288-308" -US-WCr,1700003903,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2007.08.001 -US-WCr,1700003903,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-WCr,1700002382,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Desai, A.R. (2010) Climatic And Phenological Controls On Coherent Regional Interannual Variability Of Carbon Dioxide Flux In A Heterogeneous Landscape, Journal Of Geophysical Research, 115(G00J02), n/a-n/a" -US-WCr,1700002382,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2010JG001423 -US-WCr,1700002382,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-WCr,1700004275,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Helliker, B. R., Song, X., Goulden, M. L., Clark, K., Bolstad, P., Munger, J. W., Chen, J., Noormets, A., Hollinger, D., Wofsy, S., Martin, T., Baldocchi, D., Euskirchenn, E., Desai, A., Burns, S. P. (2018) Assessing The Interplay Between Canopy Energy Balance And Photosynthesis With Cellulose δ18o: Large-Scale Patterns And Independent Ground-Truthing, Oecologia, 120(4), 600-616" -US-WCr,1700004275,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1007/S00442-018-4198-Z -US-WCr,1700004275,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-WCr,1700006777,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Helliker, B. R., Song, X., Goulden, M. L., Clark, K., Bolstad, P., Munger, J. W., Chen, J., Noormets, A., Hollinger, D., Wofsy, S., Martin, T., Baldocchi, D., Euskirchenn, E., Desai, A., Burns, S. P. (2018) Assessing The Interplay Between Canopy Energy Balance And Photosynthesis With Cellulose δ18o: Large-Scale Patterns And Independent Ground-Truthing, Oecologia, 187(4), 995-1007" -US-WCr,1700006777,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1007/S00442-018-4198-Z -US-WCr,1700006777,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-WCr,1700002550,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Hibbard, K. A., Law, B. E., Reichstein, M., Sulzman, J. (2005) An Analysis Of Soil Respiration Across Northern Hemisphere Temperate Ecosystems, Biogeochemistry, 73(1), 29-70" -US-WCr,1700002550,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1007/S10533-004-2946-0 -US-WCr,1700002550,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-WCr,1700000102,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Keenan, T. F., Hollinger, D. Y., Bohrer, G., Dragoni, D., Munger, J. W., Schmid, H. P., Richardson, A. D. (2013) Increase In Forest Water-Use Efficiency As Atmospheric Carbon Dioxide Concentrations Rise, Nature, 499(7458), 324-327" -US-WCr,1700000102,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1038/NATURE12291 -US-WCr,1700000102,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-WCr,1700005280,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Martin, J. G., Bolstad, P. V. (2005) Annual Soil Respiration In Broadleaf Forests Of Northern Wisconsin: Influence Of Moisture And Site Biological, Chemical, And Physical Characteristics, Biogeochemistry, 73(1), 149-182" -US-WCr,1700005280,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1007/S10533-004-5166-8 -US-WCr,1700005280,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-WCr,1700004227,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Matheny, A. M., Bohrer, G., Stoy, P. C., Baker, I. T., Black, A. T., Desai, A. R., Dietze, M. C., Gough, C. M., Ivanov, V. Y., Jassal, R. S., Novick, K. A., Schäfer, K. V., Verbeeck, H. (2014) Characterizing The Diurnal Patterns of Errors in The Prediction of Evapotranspiration by Several Land-Surface Models: An Nacp Analysis, Journal Of Geophysical Research: Biogeosciences, 119(7), 1458-1473" -US-WCr,1700004227,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/2014JG002623 -US-WCr,1700004227,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-WCr,1700004788,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Novick, K. A., Ficklin, D. L., Stoy, P. C., Williams, C. A., Bohrer, G., Oishi, A., Papuga, S. A., Blanken, P. D., Noormets, A., Sulman, B. N., Scott, R. L., Wang, L., Phillips, R. P. (2016) The Increasing Importance Of Atmospheric Demand For Ecosystem Water And Carbon Fluxes, Nature Climate Change, 6(11), 1023-1027" -US-WCr,1700004788,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1038/NCLIMATE3114 -US-WCr,1700004788,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-WCr,1700001488,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Novick, K. A., Konings, A. G., Gentine, P. (2019) Beyond Soil Water Potential: An Expanded View On Isohydricity Including Land–Atmosphere Interactions And Phenology, Plant, Cell & Environment, 42(6), 1802-1815" -US-WCr,1700001488,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/PCE.13517 -US-WCr,1700001488,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-WCr,1700008634,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Phillips, C. L., McFarlane, K. J., LaFranchi, B., Desai, A. R., Miller, J. B., Lehman, S. J. (2015) Observations of 14CO2 In Ecosystem Respiration From A Temperate Deciduous Forest In Northern Wisconsin, Journal Of Geophysical Research: Biogeosciences, 120(4), 600-616" -US-WCr,1700008634,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/2014JG002808 -US-WCr,1700008634,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-WCr,1700004701,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Phillips, C., McFarlane, K.J., Risk, D., Desai, A.R. (2013) Biological And Physical Influences On Soil 14CO2 Seasonal Dynamics In A Temperate Hardwood Forest, Biogeosciences, 10(12), 7999-8012" -US-WCr,1700004701,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.5194/BG-10-7999-2013 -US-WCr,1700004701,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-WCr,1700001383,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Potter, B. E., Teclaw, R. M., Zasada, J. C. (2001) The Impact Of Forest Structure On Near-Ground Temperatures During Two Years Of Contrasting Temperature Extremes, Agricultural And Forest Meteorology, 106(4), 331-336" -US-WCr,1700001383,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/S0168-1923(00)00220-3 -US-WCr,1700001383,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-WCr,1700004038,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Richardson, A. D., Anderson, R. S., Arain, M. A., Barr, A. G., Bohrer, G., Chen, G., Chen, J. M., Ciais, P., Davis, K. J., Desai, A. R., Dietze, M. C., Dragoni, D., Garrity, S. R., Gough, C. M., Grant, R., Hollinger, D. Y., Margolis, H. A., McCaughey, H., Migliavacca, M., Monson, R. K., Munger, J. W., Poulter, B., Raczka, B. M., Ricciuto, D. M., Sahoo, A. K., Schaefer, K., Tian, H., Vargas, R., Verbeeck, H., Xiao, J., Xue, Y. (2012) Terrestrial Biosphere Models Need Better Representation Of Vegetation Phenology: Results From The North American Carbon Program Site Synthesis, Global Change Biology, 18(2), 566-584" -US-WCr,1700004038,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/J.1365-2486.2011.02562.X -US-WCr,1700004038,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-WCr,1700009054,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Scott Denning, A., Nicholls, M., Prihodko, L., Baker, I., Vidale, P., Davis, K., Bakwin, P. (2003) Simulated Variations In Atmospheric CO2 Over A Wisconsin Forest Using A Coupled Ecosystem-Atmosphere Model, Global Change Biology, 9(9), 1241-1250" -US-WCr,1700009054,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1046/J.1365-2486.2003.00613.X -US-WCr,1700009054,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-WCr,1700006885,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Sullivan, R. C., Cook, D. R., Ghate, V. P., Kotamarthi, V. R., Feng, Y. (2019) Improved Spatiotemporal Representativeness And Bias Reduction Of Satellite-Based Evapotranspiration Retrievals Via Use Of In Situ Meteorology And Constrained Canopy Surface Resistance, Journal Of Geophysical Research: Biogeosciences, 124(2), 342-352" -US-WCr,1700006885,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018JG004744 -US-WCr,1700006885,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-WCr,1700008847,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Sullivan, R. C., Kotamarthi, V. R., Feng, Y. (2019) Recovering Evapotranspiration Trends From Biased CMIP5 Simulations And Sensitivity To Changing Climate Over North America, Journal Of Hydrometeorology, 20(8), 1619-1633" -US-WCr,1700008847,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1175/JHM-D-18-0259.1 -US-WCr,1700008847,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-WCr,1700008988,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Werner, C., Davis, K., Bakwin, P., Yi, C., Hurst, D., Lock, L. (2003) Regional-Scale Measurements Of CH4 Exchange From A Tall Tower Over A Mixed Temperate/Boreal Lowland And Wetland Forest, Global Change Biology, 9(9), 1251-1261" -US-WCr,1700008988,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1046/J.1365-2486.2003.00670.X -US-WCr,1700008988,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-WCr,1700006864,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Whelan, M. E., Hilton, T. W., Berry, J. A., Berkelhammer, M., Desai, A. R., Campbell, J. E. (2016) Carbonyl Sulfide Exchange In Soils For Better Estimates Of Ecosystem Carbon Uptake, Atmospheric Chemistry And Physics, 16(6), 3711-3726" -US-WCr,1700006864,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.5194/ACP-16-3711-2016 -US-WCr,1700006864,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-WCr,1700008154,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Xu, B., Arain, M. A., Black, T. A., Law, B. E., Pastorello, G. Z., Chu, H. (2020) Seasonal Variability Of Forest Sensitivity To Heat And Drought Stresses: A Synthesis Based On Carbon Fluxes From North American Forest Ecosystems, Global Change Biology, 26(2), 901-918" -US-WCr,1700008154,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/GCB.14843 -US-WCr,1700008154,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-WCr,1700008466,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Yi, C., Davis, K. J., Bakwin, P. S., Denning, A. S., Zhang, N., Desai, A., Lin, J. C., Gerbig, C. (2004) Observed Covariance Between Ecosystem Carbon Exchange And Atmospheric Boundary Layer Dynamics At A Site In Northern Wisconsin, Journal Of Geophysical Research: Atmospheres, 109(D8), n/a-n/a" -US-WCr,1700008466,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2003JD004164 -US-WCr,1700008466,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-WCr,1700007752,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Yi, C., Li, R., Bakwin, P. S., Desai, A., Ricciuto, D. M., Burns, S. P., Turnipseed, A. A., Wofsy, S. C., Munger, J. W., Wilson, K., Monson, R. K. (2004) A Nonparametric Method For Separating Photosynthesis And Respiration Components In CO2 Flux Measurements, Geophysical Research Letters, 31(17), n/a-n/a" -US-WCr,1700007752,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2004GL020490 -US-WCr,1700007752,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-WCr,1700003552,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Zhang, Q., Ficklin, D. L., Manzoni, S., Wang, L., Way, D., Phillips, R. P., Novick, K. A. (2019) Response Of Ecosystem Intrinsic Water Use Efficiency And Gross Primary Productivity To Rising Vapor Pressure Deficit, Environmental Research Letters, 14(7), 074023" -US-WCr,1700003552,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1088/1748-9326/AB2603 -US-WCr,1700003552,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-WCr,14455,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"The research and science objectives of the Willow Creek site are as follows: 1) Continuously measure the turbulent fluxes of carbon, water vapor, and temperature above an upland deciduous forest; 2) Quantify the differential impact of environmental drivers, radiation, and vapor pressure deficit in an upland forest; 3) Determine the key driver, radiation or vapor pressure deficit, of flux data for each tower year, and on the basis of this analysis apply the appropriate model to help explain observed intersite, interannual, and interseasonal variation in evapotranspiration; 4) Contribute to cross-site comparisons of biometric estimates of annual carbon storage to assess the viability of a synthesis that could provide an independant constraint on meteorologically based estimates of the same variable. (Mackay et al. (2007); Cook et al. (2004); Curtis et al. (2002))" -US-WCr,29157,GRP_ROOT_BIOMASS,ROOT_BIOMASS_CRS,1.245 -US-WCr,29042,GRP_ROOT_BIOMASS,ROOT_BIOMASS_CRS,1.611 -US-WCr,27035,GRP_ROOT_BIOMASS,ROOT_BIOMASS_CRS,3.518 -US-WCr,29157,GRP_ROOT_BIOMASS,ROOT_BIOMASS_FINE,0.822 -US-WCr,27035,GRP_ROOT_BIOMASS,ROOT_BIOMASS_FINE,0.884 -US-WCr,29042,GRP_ROOT_BIOMASS,ROOT_BIOMASS_FINE,2.226 -US-WCr,27337,GRP_ROOT_BIOMASS,ROOT_BIOMASS_TOT,10.306 -US-WCr,27035,GRP_ROOT_BIOMASS,ROOT_BIOMASS_UNIT,gC m-2 -US-WCr,27337,GRP_ROOT_BIOMASS,ROOT_BIOMASS_UNIT,gC m-2 -US-WCr,29042,GRP_ROOT_BIOMASS,ROOT_BIOMASS_UNIT,gC m-2 -US-WCr,29157,GRP_ROOT_BIOMASS,ROOT_BIOMASS_UNIT,gC m-2 -US-WCr,27035,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MIN,0 -US-WCr,27337,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MIN,0 -US-WCr,29042,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MIN,0 -US-WCr,29157,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MIN,0 -US-WCr,27035,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MAX,100 -US-WCr,27337,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MAX,100 -US-WCr,29042,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MAX,30 -US-WCr,29157,GRP_ROOT_BIOMASS,ROOT_BIOMASS_PROFILE_MAX,60 -US-WCr,27337,GRP_ROOT_BIOMASS,ROOT_BIOMASS_COMMENT,"measured to depth of 1 meter, does not include stump/rootball mass; described in Martin et al., 2005, JGR in press" -US-WCr,27035,GRP_ROOT_BIOMASS,ROOT_BIOMASS_COMMENT,www.cheas.psu.edu -US-WCr,29042,GRP_ROOT_BIOMASS,ROOT_BIOMASS_COMMENT,www.cheas.psu.edu -US-WCr,29157,GRP_ROOT_BIOMASS,ROOT_BIOMASS_COMMENT,www.cheas.psu.edu -US-WCr,28560,GRP_ROOT_CHEM,ROOT_C,4.114 -US-WCr,26898,GRP_ROOT_CHEM,ROOT_N,0.068 -US-WCr,26750,GRP_ROOT_CHEM,ROOT_N,0.073 -US-WCr,28315,GRP_ROOT_CHEM,ROOT_N,0.091 -US-WCr,26750,GRP_ROOT_CHEM,ROOT_SPP,(Unknown) -US-WCr,26898,GRP_ROOT_CHEM,ROOT_SPP,(Unknown) -US-WCr,28315,GRP_ROOT_CHEM,ROOT_SPP,(Unknown) -US-WCr,28560,GRP_ROOT_CHEM,ROOT_SPP,(Unknown) -US-WCr,26750,GRP_ROOT_CHEM,ROOT_DATE,1999 -US-WCr,26898,GRP_ROOT_CHEM,ROOT_DATE,1999 -US-WCr,28315,GRP_ROOT_CHEM,ROOT_DATE,1999 -US-WCr,28315,GRP_ROOT_CHEM,ROOT_COMMENT,"1998-99 average; 0-30 cm, P. Bolstad, taken from Willow Creek" -US-WCr,26898,GRP_ROOT_CHEM,ROOT_COMMENT,"1998-99 average; 30-60 cm, P. Bolstad, taken from Willow Creek" -US-WCr,26750,GRP_ROOT_CHEM,ROOT_COMMENT,"1998-99 average; 60-100 cm, P. Bolstad, taken from Willow Creek" -US-WCr,28560,GRP_ROOT_CHEM,ROOT_COMMENT,Martin & Bolstad 2005 -US-WCr,26893,GRP_ROOT_PROD,ROOT_PROD_FINE,0.384 -US-WCr,27036,GRP_ROOT_PROD,ROOT_PROD_TOT,32 -US-WCr,26893,GRP_ROOT_PROD,ROOT_PROD_UNIT,gC m-2 -US-WCr,27036,GRP_ROOT_PROD,ROOT_PROD_UNIT,gC m-2 -US-WCr,26893,GRP_ROOT_PROD,ROOT_PROD_COMMENT,Bolstadt et al 2003 -US-WCr,27036,GRP_ROOT_PROD,ROOT_PROD_COMMENT,"stump & roots, Cook et al 2004, Table 1" -US-WCr,26877,GRP_SA,SA,70 -US-WCr,28552,GRP_SA,SA,78 -US-WCr,28552,GRP_SA,SA_DATE,2000 -US-WCr,28552,GRP_SA,SA_COMMENT,(range 65-90) Bolstadt et al 2003 -US-WCr,22215,GRP_SITE_CHAR,TERRAIN,Gentle slope (<2 %) -US-WCr,22215,GRP_SITE_CHAR,ASPECT,SE -US-WCr,22215,GRP_SITE_CHAR,WIND_DIRECTION,W -US-WCr,22215,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,1000 -US-WCr,22215,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,100 -US-WCr,14457,GRP_SITE_DESC,SITE_DESC,"Upland decduous broadleaf forest. Mainly sugar maple, also basswood. Uniform stand atop a very modest hill. Clearcut approximately 80 years ago. Chosen to be representative of the upland deciduous broadleaf forests within the WLEF tall tower flux footprint. It appears to be more heavily forested and more productive than most of the upland deciduous broadleaf forests in the WLEF flux footprint (see publications for more details). It is also important that SE winds are screened from the flux data (see Cook et al, 2004 for details). Propane generator power." -US-WCr,14458,GRP_SITE_FUNDING,SITE_FUNDING,DOE Ameriflux Network Management Project -US-WCr,27044,GRP_SOIL_CHEM,SOIL_CHEM_C_ORG,107 -US-WCr,27591,GRP_SOIL_CHEM,SOIL_CHEM_C_ORG,94.73 -US-WCr,27044,GRP_SOIL_CHEM,SOIL_CHEM_N_TOT,7.4 -US-WCr,27344,GRP_SOIL_CHEM,SOIL_CHEM_BD,1.55 -US-WCr,27590,GRP_SOIL_CHEM,SOIL_CHEM_BD,2.18 -US-WCr,27043,GRP_SOIL_CHEM,SOIL_CHEM_BD,2.53 -US-WCr,27044,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,0 -US-WCr,27344,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,0 -US-WCr,27591,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,0 -US-WCr,27590,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,1 -US-WCr,27043,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,2 -US-WCr,27344,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,1 -US-WCr,27590,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,2 -US-WCr,27044,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,30 -US-WCr,27043,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,4 -US-WCr,27591,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,60 -US-WCr,27044,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,"(0-30 cm, including litter layer); Cook et al 2004" -US-WCr,27591,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,(top 60 cm); 2007 Fluxnet file -US-WCr,27043,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,P. Bolstad -US-WCr,27344,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,P. Bolstad -US-WCr,27590,GRP_SOIL_CHEM,SOIL_CHEM_COMMENT,P. Bolstad -US-WCr,27814,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION,"Entic Haplorthod - Sandy loam soils at this site (about 54% sand, 33% silt, and 13% clay in the upper 30 cm) have developed from acidic, reddish, unsorted, coarse glacial till with 1040% rock fragments. Soils have been subjected to mixing by windthrows, burrowing animals and earthworm activity, and frost action. Mottling and saturated soils were observed between 50 and 100 cm below the surface at different times during the year in these somewhat poorly drained soils." -US-WCr,27814,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION_TAXONOMY,Other -US-WCr,23790,GRP_SOIL_DEPTH,SOIL_DEPTH,70 -US-WCr,24418,GRP_SOIL_DEPTH,SOIL_DEPTH,30 -US-WCr,24543,GRP_SOIL_DEPTH,SOIL_DEPTH,300 -US-WCr,24543,GRP_SOIL_DEPTH,SOIL_DEPTH_COMMENT," -3+" -US-WCr,25058,GRP_SOIL_DEPTH,SOIL_DEPTH,8 -US-WCr,25058,GRP_SOIL_DEPTH,SOIL_DEPTH_COMMENT,~0.08 -US-WCr,26899,GRP_SOIL_TEX,SOIL_TEX_SAND,54 -US-WCr,27045,GRP_SOIL_TEX,SOIL_TEX_SAND,59.3 -US-WCr,26899,GRP_SOIL_TEX,SOIL_TEX_SILT,33 -US-WCr,27045,GRP_SOIL_TEX,SOIL_TEX_SILT,34 -US-WCr,26899,GRP_SOIL_TEX,SOIL_TEX_CLAY,13 -US-WCr,27045,GRP_SOIL_TEX,SOIL_TEX_CLAY,6.9 -US-WCr,26899,GRP_SOIL_TEX,SOIL_TEX_PROFILE_MIN,0 -US-WCr,26899,GRP_SOIL_TEX,SOIL_TEX_PROFILE_MAX,30 -US-WCr,26899,GRP_SOIL_TEX,SOIL_TEX_COMMENT,(Top 0-30 cm.) Cook et al 2004; (2007 Fluxnet file) -US-WCr,27045,GRP_SOIL_TEX,SOIL_TEX_COMMENT,from Cheas website -US-WCr,27963,GRP_SPP_O,SPP_O,ACRU (NRCS plant code) -US-WCr,27049,GRP_SPP_O,SPP_O,ACSA3 (NRCS plant code) -US-WCr,29161,GRP_SPP_O,SPP_O,BEPA (NRCS plant code) -US-WCr,29512,GRP_SPP_O,SPP_O,FRPE (NRCS plant code) -US-WCr,27348,GRP_SPP_O,SPP_O,OSVI (NRCS plant code) -US-WCr,27964,GRP_SPP_O,SPP_O,POTR5 (NRCS plant code) -US-WCr,27965,GRP_SPP_O,SPP_O,QUAL (NRCS plant code) -US-WCr,29160,GRP_SPP_O,SPP_O,QURU (NRCS plant code) -US-WCr,27050,GRP_SPP_O,SPP_O,TIAM (NRCS plant code) -US-WCr,29512,GRP_SPP_O,SPP_O_PERC,13.1 -US-WCr,27348,GRP_SPP_O,SPP_O_PERC,2 -US-WCr,27963,GRP_SPP_O,SPP_O_PERC,2 -US-WCr,27964,GRP_SPP_O,SPP_O_PERC,2 -US-WCr,27965,GRP_SPP_O,SPP_O_PERC,2 -US-WCr,29161,GRP_SPP_O,SPP_O_PERC,2 -US-WCr,27050,GRP_SPP_O,SPP_O_PERC,32.5 -US-WCr,27049,GRP_SPP_O,SPP_O_PERC,43.2 -US-WCr,29160,GRP_SPP_O,SPP_O_PERC,6.2 -US-WCr,27049,GRP_SPP_O,SPP_DATE,2000 -US-WCr,27050,GRP_SPP_O,SPP_DATE,2000 -US-WCr,27348,GRP_SPP_O,SPP_DATE,2000 -US-WCr,27963,GRP_SPP_O,SPP_DATE,2000 -US-WCr,27964,GRP_SPP_O,SPP_DATE,2000 -US-WCr,27965,GRP_SPP_O,SPP_DATE,2000 -US-WCr,29160,GRP_SPP_O,SPP_DATE,2000 -US-WCr,29161,GRP_SPP_O,SPP_DATE,2000 -US-WCr,29512,GRP_SPP_O,SPP_DATE,2000 -US-WCr,27049,GRP_SPP_O,SPP_COMMENT,"(Acer saccharum Marsh.) (Sugar Maple); overstory dominant species based on Basal Area Measurements, Paul Bolstad" -US-WCr,29512,GRP_SPP_O,SPP_COMMENT,"(Fraxinus pennsylvanica Marsh) (Green Ash); overstory dominant species based on Basal Area Measurements, Paul Bolstad" -US-WCr,29160,GRP_SPP_O,SPP_COMMENT,"(Northern Red Oak); overstory dominant species based on Basal Area Measurements, Paul Bolstad" -US-WCr,27050,GRP_SPP_O,SPP_COMMENT,"(Tilia americana L.) (American Basswood); overstory dominant species based on Basal Area Measurements, Paul Bolstad" -US-WCr,27348,GRP_SPP_O,SPP_COMMENT,"< 2%; (Hophornbeam); overstory dominant species based on Basal Area Measurements, Paul Bolstad" -US-WCr,29161,GRP_SPP_O,SPP_COMMENT,"< 2%; (Paper Birch); overstory dominant species based on Basal Area Measurements, Paul Bolstad" -US-WCr,27964,GRP_SPP_O,SPP_COMMENT,"< 2%; (Quaking Aspen); overstory dominant species based on Basal Area Measurements, Paul Bolstad" -US-WCr,27963,GRP_SPP_O,SPP_COMMENT,"< 2%; (Red Maple); overstory dominant species based on Basal Area Measurements, Paul Bolstad" -US-WCr,27965,GRP_SPP_O,SPP_COMMENT,"< 2%; (White Oad); overstory dominant species based on Basal Area Measurements, Paul Bolstad" -US-WCr,14459,GRP_STATE,STATE,WI -US-WCr,14460,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Ankur Desai -US-WCr,14460,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-WCr,14460,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,desai@aos.wisc.edu -US-WCr,14460,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Wisconsin -US-WCr,14460,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Department of Atmospheric and Oceanic Sciences, 1225 W Dayton St, Madison, WI 53706" -US-WCr,14466,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Jonathan Thom -US-WCr,14466,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-WCr,14466,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,jthom@ssec.wisc.edu -US-WCr,14466,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Wisconsin -US-WCr,14466,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Space Sciences and Engineering, 1225 W Dayton St,Madison, WI 53706" -US-WCr,29843,GRP_TOWER_POWER,TOWER_POWER,Gasoline generator -US-WCr,14461,GRP_TOWER_TYPE,TOWER_TYPE,triangle -US-WCr,14462,GRP_URL,URL,http://flux.aos.wisc.edu/twiki/bin/view/Main/ChEASData -US-WCr,24000444,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-WCr -US-WCr,14463,GRP_UTC_OFFSET,UTC_OFFSET,-6 -US-WCr,27958,GRP_WD_BIOMASS,WD_BIOMASS_CRS,497.3 -US-WCr,27957,GRP_WD_BIOMASS,WD_BIOMASS_CRS,499.84 -US-WCr,28572,GRP_WD_BIOMASS,WD_BIOMASS_CRS,571.83 -US-WCr,27336,GRP_WD_BIOMASS,WD_BIOMASS_CRS,584.32 -US-WCr,27336,GRP_WD_BIOMASS,WD_BIOMASS_UNIT,gC m-2 -US-WCr,27957,GRP_WD_BIOMASS,WD_BIOMASS_UNIT,gC m-2 -US-WCr,27958,GRP_WD_BIOMASS,WD_BIOMASS_UNIT,gC m-2 -US-WCr,28572,GRP_WD_BIOMASS,WD_BIOMASS_UNIT,gC m-2 -US-WCr,27336,GRP_WD_BIOMASS,WD_BIOMASS_DATE,2000 -US-WCr,27957,GRP_WD_BIOMASS,WD_BIOMASS_DATE,2000 -US-WCr,27958,GRP_WD_BIOMASS,WD_BIOMASS_DATE,2000 -US-WCr,28572,GRP_WD_BIOMASS,WD_BIOMASS_DATE,2000 -US-WCr,27958,GRP_WD_BIOMASS,WD_BIOMASS_COMMENT,NE quadrant; http://www.cheas.psu.edu/data/cheas/publish-on-cheas/Willow%20Creek/Site%20Characterization/Coarse%20Woody%20Debris/cwd00.xls -US-WCr,28572,GRP_WD_BIOMASS,WD_BIOMASS_COMMENT,NW quadrant; http://www.cheas.psu.edu/data/cheas/publish-on-cheas/Willow%20Creek/Site%20Characterization/Coarse%20Woody%20Debris/cwd00.xls -US-WCr,27336,GRP_WD_BIOMASS,WD_BIOMASS_COMMENT,SE quadrant; http://www.cheas.psu.edu/data/cheas/publish-on-cheas/Willow%20Creek/Site%20Characterization/Coarse%20Woody%20Debris/cwd00.xls -US-WCr,27957,GRP_WD_BIOMASS,WD_BIOMASS_COMMENT,SW quadrant; http://www.cheas.psu.edu/data/cheas/publish-on-cheas/Willow%20Creek/Site%20Characterization/Coarse%20Woody%20Debris/cwd00.xls -US-Whs,11859,GRP_CLIM_AVG,MAT,17.6 -US-Whs,11859,GRP_CLIM_AVG,MAP,320 -US-Whs,11859,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Bsk -US-Whs,27000446,GRP_COUNTRY,COUNTRY,USA -US-Whs,15631,GRP_DOI,DOI,10.17190/AMF/1246113 -US-Whs,15631,GRP_DOI,DOI_CITATION,"Russ Scott (2022), AmeriFlux BASE US-Whs Walnut Gulch Lucky Hills Shrub, Ver. 19-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1246113" -US-Whs,15631,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-Whs,32233,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Whs,32233,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Russ Scott -US-Whs,32233,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Whs,32233,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,russ.scott@ars.usda.gov -US-Whs,32233,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,United States Department of Agriculture -US-Whs,32235,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,United States Department of Agriculture -US-Whs,32235,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-Whs,32234,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,"USDA, DOE-Ameriflux" -US-Whs,32234,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-Whs,22201,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Undisturbed -US-Whs,11860,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Whs,11860,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-Whs,11860,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20070629 -US-Whs,11860,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Whs,11874,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Whs,11874,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-Whs,11874,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20070629 -US-Whs,11874,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Whs,23000446,GRP_HEADER,SITE_NAME,Walnut Gulch Lucky Hills Shrub -US-Whs,88644,GRP_HEIGHTC,HEIGHTC,1 -US-Whs,88644,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Whs,88644,GRP_HEIGHTC,HEIGHTC_DATE,20000101 -US-Whs,11861,GRP_IGBP,IGBP,OSH -US-Whs,11862,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-Whs,11862,GRP_LAND_OWNERSHIP,LAND_OWNER,Leased AZ State Public land -US-Whs,11863,GRP_LOCATION,LOCATION_LAT,31.7438 -US-Whs,11863,GRP_LOCATION,LOCATION_LONG,-110.0522 -US-Whs,11863,GRP_LOCATION,LOCATION_ELEV,1370 -US-Whs,11864,GRP_NETWORK,NETWORK,AmeriFlux -US-Whs,87030,GRP_NETWORK,NETWORK,Phenocam -US-Whs,1700004278,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Biederman, J. A., Scott, R. L., Bell, T. W., Bowling, D. R., Dore, S., Garatuza-Payan, J., Kolb, T. E., Krishnan, P., Krofcheck, D. J., Litvak, M. E., Maurer, G. E., Meyers, T. P., Oechel, W. C., Papuga, S. A., Ponce-Campos, G. E., Rodriguez, J. C., Smith, W. K., Vargas, R., Watts, C. J., Yepez, E. A., Goulden, M. L. (2017) Co2 Exchange And Evapotranspiration Across Dryland Ecosystems Of Southwestern North America, Global Change Biology, 23(10), 4204-4221" -US-Whs,1700004278,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/GCB.13686 -US-Whs,1700004278,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Whs,1700000936,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Biederman, J. A., Scott, R. L., Goulden, M. L., Vargas, R., Litvak, M. E., Kolb, T. E., Yepez, E. A., Oechel, W. C., Blanken, P. D., Bell, T. W., Garatuza-Payan, J., Maurer, G. E., Dore, S., Burns, S. P. (2016) Terrestrial Carbon Balance In A Drier World: The Effects Of Water Availability In Southwestern North America, Global Change Biology, 22(5), 1867-1879" -US-Whs,1700000936,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/GCB.13222 -US-Whs,1700000936,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Whs,1700007197,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(6), 108350" -US-Whs,1700007197,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -US-Whs,1700007197,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Whs,1700002055,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Hamerlynck, E. P., Scott, R. L., Sánchez-Cañete, E. P., Barron-Gafford, G. A. (2013) Nocturnal Soil CO2 Uptake And Its Relationship To Subsurface Soil And Ecosystem Carbon Fluxes In A Chihuahuan Desert Shrubland, Journal Of Geophysical Research: Biogeosciences, 118(4), 1593-1603" -US-Whs,1700002055,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/2013JG002495 -US-Whs,1700002055,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Whs,1700003777,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Li, F., Kustas, W. P., Anderson, M. C., Prueger, J. H., Scott, R. L. (2008) Effect Of Remote Sensing Spatial Resolution On Interpreting Tower-Based Flux Observations, Remote Sensing Of Environment, 112(2), 337-349" -US-Whs,1700003777,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.RSE.2006.11.032 -US-Whs,1700003777,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Whs,1700001095,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Moran, M. S., Hamerlynck, E. P., Scott, R. L., Stone, J. J., Holifield Collins, C. D., Keefer, T. O., Bryant, R., DeYoung, L., Nearing, G. S., Sugg, Z., Hymer, D. C. (2010) Hydrologic Response To Precipitation Pulses Under And Between Shrubs In The Chihuahuan Desert, Arizona, Water Resources Research, 46(W10509), n/a-n/a" -US-Whs,1700001095,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2009WR008842 -US-Whs,1700001095,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Whs,1700000297,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Moran, M., Scott, R., Keefer, T., Emmerich, W., Hernandez, M., Nearing, G., Paige, G., Cosh, M., O’Neill, P. (2009) Partitioning Evapotranspiration In Semiarid Grassland And Shrubland Ecosystems Using Time Series Of Soil Surface Temperature, Agricultural And Forest Meteorology, 149(1), 59-72" -US-Whs,1700000297,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2008.07.004 -US-Whs,1700000297,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Whs,1700001500,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Novick, K. A., Ficklin, D. L., Stoy, P. C., Williams, C. A., Bohrer, G., Oishi, A., Papuga, S. A., Blanken, P. D., Noormets, A., Sulman, B. N., Scott, R. L., Wang, L., Phillips, R. P. (2016) The Increasing Importance Of Atmospheric Demand For Ecosystem Water And Carbon Fluxes, Nature Climate Change, 6(11), 1023-1027" -US-Whs,1700001500,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1038/NCLIMATE3114 -US-Whs,1700001500,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Whs,1700000780,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Novick, K. A., Konings, A. G., Gentine, P. (2019) Beyond Soil Water Potential: An Expanded View On Isohydricity Including Land–Atmosphere Interactions And Phenology, Plant, Cell & Environment, 42(6), 1802-1815" -US-Whs,1700000780,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/PCE.13517 -US-Whs,1700000780,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Whs,1700005766,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Scott, R. L. (2010) Using Watershed Water Balance To Evaluate The Accuracy Of Eddy Covariance Evaporation Measurements For Three Semiarid Ecosystems, Agricultural And Forest Meteorology, 150(2), 219-225" -US-Whs,1700005766,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2009.11.002 -US-Whs,1700005766,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Whs,1700006561,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Scott, R. L., Biederman, J. A., Hamerlynck, E. P., Barron-Gafford, G. A. (2015) The Carbon Balance Pivot Point Of Southwestern U.S. Semiarid Ecosystems: Insights From The 21st Century Drought, Journal Of Geophysical Research: Biogeosciences, 120(12), 2612-2624" -US-Whs,1700006561,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/2015JG003181 -US-Whs,1700006561,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Whs,1700008766,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Scott, R. L., Huxman, T. E., Cable, W. L., Emmerich, W. E. (2006) Partitioning Of Evapotranspiration And Its Relation To Carbon Dioxide Exchange In A Chihuahuan Desert Shrubland, Hydrological Processes, 20(15), 3227-3243" -US-Whs,1700008766,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/HYP.6329 -US-Whs,1700008766,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Whs,1700006180,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Scott, R.L., Biederman, J.A., Hamerlynck, E.P., Barron-Gafford, G. (2015) The carbon balance pivot point of southwestern U.S. semiarid ecosystems: Insights from the 21st century drought, Journal of Geophysical Research: Biogeosciences, 120(15), 2612-2624" -US-Whs,1700006180,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/2015JG003181 -US-Whs,1700006180,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Primary_Citation -US-Whs,1700002889,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Scott, R.L., Biederman, J.A., Hamerlynck, E.P., Barron-Gafford, G. (2015) The carbon balance pivot point of southwestern U.S. semiarid ecosystems: Insights from the 21st century drought, Journal of Geophysical Research: Biogeosciences, 120(21), 2612-2624" -US-Whs,1700002889,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/2015JG003181 -US-Whs,1700002889,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Primary_Citation -US-Whs,1700001782,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Smith, W. K., Biederman, J. A., Scott, R. L., Moore, D. J., He, M., Kimball, J. S., Yan, D., Hudson, A., Barnes, M. L., MacBean, N., Fox, A. M., Litvak, M. E. (2018) Chlorophyll Fluorescence Better Captures Seasonal And Interannual Gross Primary Productivity Dynamics Across Dryland Ecosystems Of Southwestern North America, Geophysical Research Letters, 45(2), 748-757" -US-Whs,1700001782,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/2017GL075922 -US-Whs,1700001782,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Whs,1700003783,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Sullivan, R. C., Cook, D. R., Ghate, V. P., Kotamarthi, V. R., Feng, Y. (2019) Improved Spatiotemporal Representativeness And Bias Reduction Of Satellite-Based Evapotranspiration Retrievals Via Use Of In Situ Meteorology And Constrained Canopy Surface Resistance, Journal Of Geophysical Research: Biogeosciences, 124(2), 342-352" -US-Whs,1700003783,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018JG004744 -US-Whs,1700003783,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Whs,1700002517,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Sullivan, R. C., Kotamarthi, V. R., Feng, Y. (2019) Recovering Evapotranspiration Trends From Biased CMIP5 Simulations And Sensitivity To Changing Climate Over North America, Journal Of Hydrometeorology, 20(8), 1619-1633" -US-Whs,1700002517,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1175/JHM-D-18-0259.1 -US-Whs,1700002517,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Whs,1700005535,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Watts, C. J., Scott, R. L., Garatuza-Payan, J., Rodriguez, J. C., Prueger, J. H., Kustas, W. P., Douglas, M. (2007) Changes In Vegetation Condition And Surface Fluxes During NAME 2004, Journal Of Climate, 20(9), 1810-1820" -US-Whs,1700005535,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1175/JCLI4088.1 -US-Whs,1700005535,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Whs,1700000756,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Wolf, S., Keenan, T.F., Fisher, J.B., Baldocchi, D.D., Desai, A.R., Richardson, A.D., Scott, R.L., Law, B.E., Litvak, M.E., Brunsell, N.A., Peters, W., van der Laan-Luijkx, I.T. (2016) Warm spring reduced carbon cycle impact of the 2012 US summer drought, Proceedings of the National Academy of Sciences, 113(21), 5880-5885" -US-Whs,1700000756,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1073/PNAS.1519620113 -US-Whs,1700000756,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Whs,1700006012,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Zhang, Q., Ficklin, D. L., Manzoni, S., Wang, L., Way, D., Phillips, R. P., Novick, K. A. (2019) Response Of Ecosystem Intrinsic Water Use Efficiency And Gross Primary Productivity To Rising Vapor Pressure Deficit, Environmental Research Letters, 14(7), 074023" -US-Whs,1700006012,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1088/1748-9326/AB2603 -US-Whs,1700006012,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Whs,11866,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"Desert shrubland carbon and water cycling, ET partitioning, soil respiration" -US-Whs,11867,GRP_SITE_CHAR,TERRAIN,Undulated/Variable -US-Whs,11867,GRP_SITE_CHAR,ASPECT,S -US-Whs,11867,GRP_SITE_CHAR,WIND_DIRECTION,W -US-Whs,11867,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,1500 -US-Whs,11867,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,0 -US-Whs,11868,GRP_SITE_DESC,SITE_DESC,"A semiarid Chihuahuan Desert shrubland located in the USDA-ARS Walnut Gulch Experimental Watershed (WGEW) surrounding the town of Tombstone, AZ. The site vegetation is comprised of a diverse stand of mainly Chihuahuan desert shrub species like acacia constricta, larrea tridentata, and florensia cernua." -US-Whs,11869,GRP_SITE_FUNDING,SITE_FUNDING,"USDA, DOE-Ameriflux" -US-Whs,11870,GRP_STATE,STATE,AZ -US-Whs,11871,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Russ Scott -US-Whs,11871,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Whs,11871,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,russ.scott@ars.usda.gov -US-Whs,11871,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,United States Department of Agriculture -US-Whs,11871,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"USDA-ARS Southwest Watershed Research Center, 2000 East Allen Rd.,Tucson, AZ USA 85719" -US-Whs,81554,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Ross Bryant -US-Whs,81554,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Technician -US-Whs,81554,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,Ross.Bryant@ars.usda.gov -US-Whs,81554,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,USDA-ARS-SWRC -US-Whs,81554,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"2000 East Allen Rd -Tucson, AZ. 85719" -US-Whs,29845,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-Whs,11872,GRP_TOWER_TYPE,TOWER_TYPE,triangle -US-Whs,29706,GRP_URL,URL,https://www.ars.usda.gov/pacific-west-area/tucson-az/southwest-watershed-research -US-Whs,24000446,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-Whs -US-Whs,11873,GRP_UTC_OFFSET,UTC_OFFSET,-7 -US-Wi0,927,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfb -US-Wi0,27000319,GRP_COUNTRY,COUNTRY,USA -US-Wi0,15731,GRP_DOI,DOI,10.17190/AMF/1246016 -US-Wi0,15731,GRP_DOI,DOI_CITATION,"Jiquan Chen (2020), AmeriFlux BASE US-Wi0 Young red pine (YRP), Ver. 3-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1246016" -US-Wi0,15731,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-Wi0,31914,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Wi0,31914,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Jiquan Chen -US-Wi0,31914,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Wi0,31914,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,jqchen@msu.edu -US-Wi0,31914,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Michigan State University -US-Wi0,31916,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Michigan State University -US-Wi0,31916,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-Wi0,31915,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,NSF -US-Wi0,31915,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-Wi0,3779,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Wi0,3779,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-Wi0,3779,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,2002 -US-Wi0,3779,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,2002 -US-Wi0,3779,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Wi0,23000319,GRP_HEADER,SITE_NAME,Young red pine (YRP) -US-Wi0,88350,GRP_HEIGHTC,HEIGHTC,4 -US-Wi0,88350,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Wi0,88350,GRP_HEIGHTC,HEIGHTC_DATE,20020701 -US-Wi0,88350,GRP_HEIGHTC,HEIGHTC_DATE_UNC,60 -US-Wi0,88350,GRP_HEIGHTC,HEIGHTC_COMMENT,"Noormets, A. et al. (2008). Agricultural and Forest Meteorology, 148(2), 216-230. " -US-Wi0,68,GRP_IGBP,IGBP,ENF -US-Wi0,24273,GRP_LAI,LAI_TYPE,LAI -US-Wi0,24273,GRP_LAI,LAI_TOT,0.5 -US-Wi0,24273,GRP_LAI,LAI_U,0 -US-Wi0,1580,GRP_LOCATION,LOCATION_LAT,46.6188 -US-Wi0,1580,GRP_LOCATION,LOCATION_LONG,-91.0814 -US-Wi0,1580,GRP_LOCATION,LOCATION_ELEV,349 -US-Wi0,7214,GRP_NETWORK,NETWORK,AmeriFlux -US-Wi0,1700004524,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Baldocchi, D. D., Poindexter, C., Abraha, M., Desai, A. R., Bohrer, G., Arain, M. A., Griffis, T., Blanken, P. D., O'Halloran, T. L., Thomas, R. Q., Zhang, Q., Burns, S. P., Frank, J. M., Christian, D., Brown, S., Black, T. A., Gough, C. M., Law, B. E., Lee, X., Chen, J., Reed, D. E., Massman, W. J., Clark, K., Hatfield, J., Prueger, J., Bracho, R., Baker, J. M., Martin, T. A. (2018) Temporal Dynamics Of Aerodynamic Canopy Height Derived From Eddy Covariance Momentum Flux Data Across North American Flux Networks, Geophysical Research Letters, 45(2), 9275–9287" -US-Wi0,1700004524,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018GL079306 -US-Wi0,1700004524,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Wi0,1700005067,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(2), 108350" -US-Wi0,1700005067,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -US-Wi0,1700005067,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Wi0,1700006390,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Desai, A. R., Noormets, A., Bolstad, P. V., Chen, J., Cook, B. D., Davis, K. J., Euskirchen, E. S., Gough, C., Martin, J. G., Ricciuto, D. M., Schmid, H. P., Tang, J., Wang, W. (2008) Influence Of Vegetation And Seasonal Forcing On Carbon Dioxide Fluxes Across The Upper Midwest, Usa: Implications For Regional Scaling, Agricultural And Forest Meteorology, 148(2), 288-308" -US-Wi0,1700006390,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2007.08.001 -US-Wi0,1700006390,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Wi0,1700007761,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Noormets, A., Chen, J., Crow, T. R. (2007) Age-Dependent Changes In Ecosystem Carbon Fluxes In Managed Forests In Northern Wisconsin, USA, Ecosystems, 10(2), 187-203" -US-Wi0,1700007761,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1007/S10021-007-9018-Y -US-Wi0,1700007761,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Wi0,1700005301,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Noormets, A., Desai, A., Cook, B., Euskirchen, E., Ricciuto, D., Davis, K., Bolstad, P., Schmid, H., Vogel, C., Carey, E., Su, H., Chen, J. (2008) Moisture Sensitivity Of Ecosystem Respiration: Comparison Of 14 Forest Ecosystems In The Upper Great Lakes Region, USA, Agricultural And Forest Meteorology, 148(2), 216-230" -US-Wi0,1700005301,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2007.08.002 -US-Wi0,1700005301,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Wi0,6724,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"The research and science objectives of the Wisconsin Young Red Pine are as follows: 1) Enhance our understanding of landscape-level carbon exchange in disturbed land mosaics, taking into specific consideration age structure and the area-of- edge-influences (AEI); 2) Determine how the cumulative NEP of a landscape is determined by the land mosaic; that is, the various ages and types of ecosystems present, as well as their arrangement; 3) Investigate the temporal and spatial changes in landscape structure and vegetative composition across a landscape managed for multiple uses within the Chequamegon National Forest in northern Wisconsin; 4) Quantify the developmental changes in Carbon fluxes following stand replacing disturbances; 5) Investigate the common factors that might explain the observed variability among the closely spaced, but diverse, forest ecosystems that represent a disturbed, actively managed and climatically homogeneous forest landscape; 6) Quantify the role of soil moisture in affecting ecosystem respiration; 7) Identify landscape-level patterns in the temperature and moisture response of ecosystem respiration as determined by forest functional type and stage of development. (Project Overview by Primary Investigators: J. Chen and K. Brosofske; Bresee et al., 2004; Noormets et al., 2007; Noormets et al., 2008)" -US-Wi0,24950,GRP_SA,SA,8 -US-Wi0,5009,GRP_SITE_CHAR,TERRAIN,"Significant Slope (>5%, <10%)" -US-Wi0,10125,GRP_SITE_DESC,SITE_DESC,"The Wisconsin Young Red Pine site is located in the Washburn Ranger District of the northeastern section of Chequamegon National Forest. A member of the northern coniferous-deciduous biome, surveys from the mid-19th century indicate the region consisted of a mixed stand of red, white, and jack pines. After extensive timber harvesting, wildfires, and farming activity, the region turned into a fragmented mosaic of stands of various ages and composition. As an assemblage, the ten Wisconsin sites are indicative of the successional stages of development in the predominant stand types of a physically homogeneous landscape. Thinned every 7 years until they reach 100 to 150 years of age, the red pine plantations of all ages occupy approximately 25% of the region." -US-Wi0,764,GRP_SITE_FUNDING,SITE_FUNDING,NSF -US-Wi0,28937,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION,"Deep loamy sills with ground moraine, classified as Psamments and Orthods" -US-Wi0,28937,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION_TAXONOMY,Other -US-Wi0,23924,GRP_SPP_O,SPP_O,Pinus resinosa -US-Wi0,6605,GRP_STATE,STATE,WI -US-Wi0,12547,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Jiquan Chen -US-Wi0,12547,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Wi0,12547,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,jqchen@msu.edu -US-Wi0,12547,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Michigan State University -US-Wi0,9294,GRP_URL,URL,http://research.eeescience.utoledo.edu/lees/research/carbon/ -US-Wi0,24000319,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-Wi0 -US-Wi0,7881,GRP_UTC_OFFSET,UTC_OFFSET,-6 -US-Wi1,3487,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfb -US-Wi1,27000318,GRP_COUNTRY,COUNTRY,USA -US-Wi1,15698,GRP_DOI,DOI,10.17190/AMF/1246015 -US-Wi1,15698,GRP_DOI,DOI_CITATION,"Jiquan Chen (2020), AmeriFlux BASE US-Wi1 Intermediate hardwood (IHW), Ver. 3-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1246015" -US-Wi1,15698,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-Wi1,31911,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Wi1,31911,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Jiquan Chen -US-Wi1,31911,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Wi1,31911,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,jqchen@msu.edu -US-Wi1,31911,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Michigan State University -US-Wi1,31913,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Michigan State University -US-Wi1,31913,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-Wi1,31912,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,NSF -US-Wi1,31912,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-Wi1,1234,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Wi1,1234,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-Wi1,1234,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,2003 -US-Wi1,1234,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,2003 -US-Wi1,1234,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Wi1,23000318,GRP_HEADER,SITE_NAME,Intermediate hardwood (IHW) -US-Wi1,88351,GRP_HEIGHTC,HEIGHTC,6 -US-Wi1,88351,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Wi1,88351,GRP_HEIGHTC,HEIGHTC_DATE,20030701 -US-Wi1,88351,GRP_HEIGHTC,HEIGHTC_DATE_UNC,60 -US-Wi1,88351,GRP_HEIGHTC,HEIGHTC_COMMENT,"Noormets, A. et al. (2008). Agricultural and Forest Meteorology, 148(2), 216-230. " -US-Wi1,892,GRP_IGBP,IGBP,DBF -US-Wi1,23893,GRP_LAI,LAI_TYPE,LAI -US-Wi1,23893,GRP_LAI,LAI_TOT,3 -US-Wi1,23893,GRP_LAI,LAI_U,0 -US-Wi1,10106,GRP_LOCATION,LOCATION_LAT,46.7305 -US-Wi1,10106,GRP_LOCATION,LOCATION_LONG,-91.2329 -US-Wi1,10106,GRP_LOCATION,LOCATION_ELEV,352 -US-Wi1,8942,GRP_NETWORK,NETWORK,AmeriFlux -US-Wi1,1700005235,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Baldocchi, D. D., Poindexter, C., Abraha, M., Desai, A. R., Bohrer, G., Arain, M. A., Griffis, T., Blanken, P. D., O'Halloran, T. L., Thomas, R. Q., Zhang, Q., Burns, S. P., Frank, J. M., Christian, D., Brown, S., Black, T. A., Gough, C. M., Law, B. E., Lee, X., Chen, J., Reed, D. E., Massman, W. J., Clark, K., Hatfield, J., Prueger, J., Bracho, R., Baker, J. M., Martin, T. A. (2018) Temporal Dynamics Of Aerodynamic Canopy Height Derived From Eddy Covariance Momentum Flux Data Across North American Flux Networks, Geophysical Research Letters, 45(2), 9275–9287" -US-Wi1,1700005235,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018GL079306 -US-Wi1,1700005235,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Wi1,1700006843,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(2), 108350" -US-Wi1,1700006843,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -US-Wi1,1700006843,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Wi1,1700005505,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Desai, A. R., Noormets, A., Bolstad, P. V., Chen, J., Cook, B. D., Davis, K. J., Euskirchen, E. S., Gough, C., Martin, J. G., Ricciuto, D. M., Schmid, H. P., Tang, J., Wang, W. (2008) Influence Of Vegetation And Seasonal Forcing On Carbon Dioxide Fluxes Across The Upper Midwest, Usa: Implications For Regional Scaling, Agricultural And Forest Meteorology, 148(2), 288-308" -US-Wi1,1700005505,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2007.08.001 -US-Wi1,1700005505,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Wi1,1700000015,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Noormets, A., Chen, J., Crow, T. R. (2007) Age-Dependent Changes In Ecosystem Carbon Fluxes In Managed Forests In Northern Wisconsin, USA, Ecosystems, 10(2), 187-203" -US-Wi1,1700000015,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1007/S10021-007-9018-Y -US-Wi1,1700000015,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Wi1,1700001446,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Noormets, A., Desai, A., Cook, B., Euskirchen, E., Ricciuto, D., Davis, K., Bolstad, P., Schmid, H., Vogel, C., Carey, E., Su, H., Chen, J. (2008) Moisture Sensitivity Of Ecosystem Respiration: Comparison Of 14 Forest Ecosystems In The Upper Great Lakes Region, USA, Agricultural And Forest Meteorology, 148(2), 216-230" -US-Wi1,1700001446,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2007.08.002 -US-Wi1,1700001446,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Wi1,6721,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"The research and science objectives of the Wisconsin Intermediate Hardwoods are as follows: 1) Enhance our understanding of landscape-level carbon exchange in disturbed land mosaics, taking into specific consideration age structure and the area-of- edge-influences (AEI); 2) Determine how the cumulative NEP of a landscape is determined by the land mosaic; that is, the various ages and types of ecosystems present, as well as their arrangement; 3) Investigate the temporal and spatial changes in landscape structure and vegetative composition across a landscape managed for multiple uses within the Chequamegon National Forest in northern Wisconsin; 4) Quantify the developmental changes in Carbon fluxes following stand replacing disturbances; 5) Investigate the common factors that might explain the observed variability among the closely spaced, but diverse, forest ecosystems that represent a disturbed, actively managed and climatically homogeneous forest landscape; 6) Quantify the role of soil moisture in affecting ecosystem respiration; 7) Identify landscape-level patterns in the temperature and moisture response of ecosystem respiration as determined by forest functional type and stage of development. (Project Overview by Primary Investigators: J. Chen and K. Brosofske; Bresee et al., 2004; Noormets et al., 2007; Noormets et al., 2008)" -US-Wi1,24183,GRP_SA,SA,17 -US-Wi1,4103,GRP_SITE_CHAR,TERRAIN,"Significant Slope (>5%, <10%)" -US-Wi1,1591,GRP_SITE_DESC,SITE_DESC,"The Wisconsin Intermediate Hardwoods site is located in the Washburn Ranger District of the Chequamegon National Forest. A member of the northern coniferous-deciduous biome, surveys from the mid-19th century indicate the region consisted of a mixed stand of red, white, and jack pines. After extensive timber harvesting, wildfires, and farming activity, the region turned into a fragmented mosaic of stands of various ages and composition. The intermediate hardwoods site is one of ten sites that collectively represent the successional stages of development in the predominant stand types of a physically homogeneous landscape. In 2001, northern hardwood stands of all ages occupied 45% of the region." -US-Wi1,10153,GRP_SITE_FUNDING,SITE_FUNDING,NSF -US-Wi1,27485,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION,"Deep loamy sills with ground moraine, classified as Psamments and Orthods" -US-Wi1,27485,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION_TAXONOMY,Other -US-Wi1,24178,GRP_SPP_O,SPP_O,"Populus grandidentata, P. sp." -US-Wi1,7432,GRP_STATE,STATE,WI -US-Wi1,12548,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Jiquan Chen -US-Wi1,12548,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Wi1,12548,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,jqchen@msu.edu -US-Wi1,12548,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Michigan State University -US-Wi1,10134,GRP_URL,URL,http://research.eeescience.utoledo.edu/lees/research/carbon/ -US-Wi1,24000318,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-Wi1 -US-Wi1,245,GRP_UTC_OFFSET,UTC_OFFSET,-6 -US-Wi2,9458,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfb -US-Wi2,27000320,GRP_COUNTRY,COUNTRY,USA -US-Wi2,15744,GRP_DOI,DOI,10.17190/AMF/1246017 -US-Wi2,15744,GRP_DOI,DOI_CITATION,"Jiquan Chen (2020), AmeriFlux BASE US-Wi2 Intermediate red pine (IRP), Ver. 3-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1246017" -US-Wi2,15744,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-Wi2,31917,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Wi2,31917,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Jiquan Chen -US-Wi2,31917,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Wi2,31917,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,jqchen@msu.edu -US-Wi2,31917,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Michigan State University -US-Wi2,31919,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Michigan State University -US-Wi2,31919,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-Wi2,31918,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,NSF -US-Wi2,31918,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-Wi2,9771,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Wi2,9771,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-Wi2,9771,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,2003 -US-Wi2,9771,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,2003 -US-Wi2,9771,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Wi2,23000320,GRP_HEADER,SITE_NAME,Intermediate red pine (IRP) -US-Wi2,88352,GRP_HEIGHTC,HEIGHTC,6 -US-Wi2,88352,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Wi2,88352,GRP_HEIGHTC,HEIGHTC_DATE,20030701 -US-Wi2,88352,GRP_HEIGHTC,HEIGHTC_DATE_UNC,60 -US-Wi2,88352,GRP_HEIGHTC,HEIGHTC_COMMENT,"Noormets, A. et al. (2008). Agricultural and Forest Meteorology, 148(2), 216-230. " -US-Wi2,1752,GRP_IGBP,IGBP,ENF -US-Wi2,25043,GRP_LAI,LAI_TYPE,LAI -US-Wi2,25043,GRP_LAI,LAI_TOT,3.2 -US-Wi2,25043,GRP_LAI,LAI_U,0 -US-Wi2,1581,GRP_LOCATION,LOCATION_LAT,46.6869 -US-Wi2,1581,GRP_LOCATION,LOCATION_LONG,-91.1528 -US-Wi2,1581,GRP_LOCATION,LOCATION_ELEV,395 -US-Wi2,3809,GRP_NETWORK,NETWORK,AmeriFlux -US-Wi2,1700006936,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Desai, A. R., Noormets, A., Bolstad, P. V., Chen, J., Cook, B. D., Davis, K. J., Euskirchen, E. S., Gough, C., Martin, J. G., Ricciuto, D. M., Schmid, H. P., Tang, J., Wang, W. (2008) Influence Of Vegetation And Seasonal Forcing On Carbon Dioxide Fluxes Across The Upper Midwest, Usa: Implications For Regional Scaling, Agricultural And Forest Meteorology, 148(2), 288-308" -US-Wi2,1700006936,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2007.08.001 -US-Wi2,1700006936,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Wi2,1700008109,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Noormets, A., Chen, J., Crow, T. R. (2007) Age-Dependent Changes In Ecosystem Carbon Fluxes In Managed Forests In Northern Wisconsin, USA, Ecosystems, 10(2), 187-203" -US-Wi2,1700008109,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1007/S10021-007-9018-Y -US-Wi2,1700008109,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Wi2,1700007647,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Noormets, A., Desai, A., Cook, B., Euskirchen, E., Ricciuto, D., Davis, K., Bolstad, P., Schmid, H., Vogel, C., Carey, E., Su, H., Chen, J. (2008) Moisture Sensitivity Of Ecosystem Respiration: Comparison Of 14 Forest Ecosystems In The Upper Great Lakes Region, USA, Agricultural And Forest Meteorology, 148(2), 216-230" -US-Wi2,1700007647,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2007.08.002 -US-Wi2,1700007647,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Wi2,2477,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"The research and science objectives of the Wisconsin Intermediate Red Pine are as follows: 1) Enhance our understanding of landscape-level carbon exchange in disturbed land mosaics, taking into specific consideration age structure and the area-of- edge-influences (AEI); 2) Determine how the cumulative NEP of a landscape is determined by the land mosaic; that is, the various ages and types of ecosystems present, as well as their arrangement; 3) Investigate the temporal and spatial changes in landscape structure and vegetative composition across a landscape managed for multiple uses within the Chequamegon National Forest in northern Wisconsin; 4) Quantify the developmental changes in Carbon fluxes following stand replacing disturbances; 5) Investigate the common factors that might explain the observed variability among the closely spaced, but diverse, forest ecosystems that represent a disturbed, actively managed and climatically homogeneous forest landscape; 6) Quantify the role of soil moisture in affecting ecosystem respiration; 7) Identify landscape-level patterns in the temperature and moisture response of ecosystem respiration as determined by forest functional type and stage of development. (Project Overview by Primary Investigators: J. Chen and K. Brosofske; Bresee et al., 2004; Noormets et al., 2007; Noormets et al., 2008)" -US-Wi2,24560,GRP_SA,SA,21 -US-Wi2,3301,GRP_SITE_CHAR,TERRAIN,"Significant Slope (>5%, <10%)" -US-Wi2,1592,GRP_SITE_DESC,SITE_DESC,"The Wisconsin Intermediate Red Pine site is located in the Washburn Ranger District of the northeastern section of Chequamegon National Forest. A member of the northern coniferous-deciduous biome, surveys from the mid-19th century indicate the region consisted of a mixed stand of red, white, and jack pines. After extensive timber harvesting, wildfires, and farming activity, the region turned into a fragmented mosaic of stands of various ages and composition. The intermediate red pine site is one of ten sites that collectively represent the successional stages of development in the predominant stand types of a physically homogeneous landscape. Thinned every 7 years until they reach 100 to 150 years of age, the red pine plantations of all ages occupy approximately 25% of the region." -US-Wi2,9309,GRP_SITE_FUNDING,SITE_FUNDING,NSF -US-Wi2,28811,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION,"Deep loamy sills with ground moraine, classified as Psamments and Orthods" -US-Wi2,28811,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION_TAXONOMY,Other -US-Wi2,23925,GRP_SPP_O,SPP_O,Pinus resinosa -US-Wi2,2327,GRP_STATE,STATE,WI -US-Wi2,12549,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Jiquan Chen -US-Wi2,12549,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Wi2,12549,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,jqchen@msu.edu -US-Wi2,12549,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Michigan State University -US-Wi2,7550,GRP_URL,URL,http://research.eeescience.utoledo.edu/lees/research/carbon/ -US-Wi2,24000320,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-Wi2 -US-Wi2,1938,GRP_UTC_OFFSET,UTC_OFFSET,-6 -US-Wi3,23897,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER,22 -US-Wi3,23897,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_ORGAN,Total -US-Wi3,23897,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_PHEN,Mixed/unknown -US-Wi3,23897,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_UNIT,kgDM m-2 -US-Wi3,5194,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfb -US-Wi3,27000321,GRP_COUNTRY,COUNTRY,USA -US-Wi3,15694,GRP_DOI,DOI,10.17190/AMF/1246018 -US-Wi3,15694,GRP_DOI,DOI_CITATION,"Jiquan Chen (2020), AmeriFlux BASE US-Wi3 Mature hardwood (MHW), Ver. 3-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1246018" -US-Wi3,15694,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-Wi3,31920,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Wi3,31920,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Jiquan Chen -US-Wi3,31920,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Wi3,31920,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,jqchen@msu.edu -US-Wi3,31920,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Michigan State University -US-Wi3,31922,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Michigan State University -US-Wi3,31922,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-Wi3,31921,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,NSF -US-Wi3,31921,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-Wi3,5497,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Wi3,5497,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-Wi3,5497,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,2002 -US-Wi3,5497,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,2004 -US-Wi3,5497,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Wi3,23000321,GRP_HEADER,SITE_NAME,Mature hardwood (MHW) -US-Wi3,88353,GRP_HEIGHTC,HEIGHTC,18 -US-Wi3,88353,GRP_HEIGHTC,HEIGHTC_STATISTIC,Minimum -US-Wi3,88353,GRP_HEIGHTC,HEIGHTC_DATE,20040701 -US-Wi3,88353,GRP_HEIGHTC,HEIGHTC_DATE_UNC,60 -US-Wi3,88353,GRP_HEIGHTC,HEIGHTC_COMMENT,"Noormets, A. et al. (2008). Agricultural and Forest Meteorology, 148(2), 216-230. " -US-Wi3,88354,GRP_HEIGHTC,HEIGHTC,23 -US-Wi3,88354,GRP_HEIGHTC,HEIGHTC_STATISTIC,Maximum -US-Wi3,88354,GRP_HEIGHTC,HEIGHTC_DATE,20040701 -US-Wi3,88354,GRP_HEIGHTC,HEIGHTC_DATE_UNC,60 -US-Wi3,88354,GRP_HEIGHTC,HEIGHTC_COMMENT,"Noormets, A. et al. (2008). Agricultural and Forest Meteorology, 148(2), 216-230. " -US-Wi3,88355,GRP_HEIGHTC,HEIGHTC,20.5 -US-Wi3,88355,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Wi3,88355,GRP_HEIGHTC,HEIGHTC_DATE,20040701 -US-Wi3,88355,GRP_HEIGHTC,HEIGHTC_DATE_UNC,60 -US-Wi3,88355,GRP_HEIGHTC,HEIGHTC_COMMENT,"Noormets, A. et al. (2008). Agricultural and Forest Meteorology, 148(2), 216-230. " -US-Wi3,2614,GRP_IGBP,IGBP,DBF -US-Wi3,24788,GRP_LAI,LAI_TYPE,LAI -US-Wi3,24791,GRP_LAI,LAI_TYPE,LAI -US-Wi3,24791,GRP_LAI,LAI_COMMENT," -~1" -US-Wi3,24788,GRP_LAI,LAI_TOT,3.9 -US-Wi3,24791,GRP_LAI,LAI_U,1 -US-Wi3,6675,GRP_LOCATION,LOCATION_LAT,46.6347 -US-Wi3,6675,GRP_LOCATION,LOCATION_LONG,-91.0987 -US-Wi3,6675,GRP_LOCATION,LOCATION_ELEV,411 -US-Wi3,6384,GRP_NETWORK,NETWORK,AmeriFlux -US-Wi3,1700004110,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Baldocchi, D. D., Poindexter, C., Abraha, M., Desai, A. R., Bohrer, G., Arain, M. A., Griffis, T., Blanken, P. D., O'Halloran, T. L., Thomas, R. Q., Zhang, Q., Burns, S. P., Frank, J. M., Christian, D., Brown, S., Black, T. A., Gough, C. M., Law, B. E., Lee, X., Chen, J., Reed, D. E., Massman, W. J., Clark, K., Hatfield, J., Prueger, J., Bracho, R., Baker, J. M., Martin, T. A. (2018) Temporal Dynamics Of Aerodynamic Canopy Height Derived From Eddy Covariance Momentum Flux Data Across North American Flux Networks, Geophysical Research Letters, 45(2), 9275–9287" -US-Wi3,1700004110,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018GL079306 -US-Wi3,1700004110,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Wi3,1700003702,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(2), 108350" -US-Wi3,1700003702,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -US-Wi3,1700003702,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Wi3,1700004158,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Desai, A. R., Noormets, A., Bolstad, P. V., Chen, J., Cook, B. D., Davis, K. J., Euskirchen, E. S., Gough, C., Martin, J. G., Ricciuto, D. M., Schmid, H. P., Tang, J., Wang, W. (2008) Influence Of Vegetation And Seasonal Forcing On Carbon Dioxide Fluxes Across The Upper Midwest, Usa: Implications For Regional Scaling, Agricultural And Forest Meteorology, 148(2), 288-308" -US-Wi3,1700004158,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2007.08.001 -US-Wi3,1700004158,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Wi3,1700001251,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Noormets, A., Chen, J., Crow, T. R. (2007) Age-Dependent Changes In Ecosystem Carbon Fluxes In Managed Forests In Northern Wisconsin, USA, Ecosystems, 10(2), 187-203" -US-Wi3,1700001251,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1007/S10021-007-9018-Y -US-Wi3,1700001251,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Wi3,1700003234,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Noormets, A., Desai, A., Cook, B., Euskirchen, E., Ricciuto, D., Davis, K., Bolstad, P., Schmid, H., Vogel, C., Carey, E., Su, H., Chen, J. (2008) Moisture Sensitivity Of Ecosystem Respiration: Comparison Of 14 Forest Ecosystems In The Upper Great Lakes Region, USA, Agricultural And Forest Meteorology, 148(2), 216-230" -US-Wi3,1700003234,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2007.08.002 -US-Wi3,1700003234,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Wi3,3293,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"The research and science objectives of the Wisconsin Mature Hardwoods are as follows: 1) Enhance our understanding of landscape-level carbon exchange in disturbed land mosaics, taking into specific consideration age structure and the area-of- edge-influences (AEI); 2) Determine how the cumulative NEP of a landscape is determined by the land mosaic; that is, the various ages and types of ecosystems present, as well as their arrangement; 3) Investigate the temporal and spatial changes in landscape structure and vegetative composition across a landscape managed for multiple uses within the Chequamegon National Forest in northern Wisconsin; 4) Quantify the developmental changes in Carbon fluxes following stand replacing disturbances; 5) Investigate the common factors that might explain the observed variability among the closely spaced, but diverse, forest ecosystems that represent a disturbed, actively managed and climatically homogeneous forest landscape; 6) Quantify the role of soil moisture in affecting ecosystem respiration; 7) Identify landscape-level patterns in the temperature and moisture response of ecosystem respiration as determined by forest functional type and stage of development. (Project Overview by Primary Investigators: J. Chen and K. Brosofske; Bresee et al., 2004; Noormets et al., 2007; Noormets et al., 2008)" -US-Wi3,24823,GRP_SA,SA,66 -US-Wi3,24823,GRP_SA,SA_COMMENT,(range 65-67) template: MHW02:65; MHW03:66;MHW04:67; -US-Wi3,5854,GRP_SITE_CHAR,TERRAIN,"Significant Slope (>5%, <10%)" -US-Wi3,6692,GRP_SITE_DESC,SITE_DESC,"The Wisconsin Mature Hardwood site is located in the Washburn Ranger District of the northeastern section of Chequamegon National Forest. A member of the northern coniferous-deciduous biome, surveys from the mid-19th century indicate the region consisted of a mixed stand of red, white, and jack pines. After extensive timber harvesting, wildfires, and farming activity, the region turned into a fragmented mosaic of stands of various ages and composition. As an assemblage, the ten Wisconsin sites are indicative of the successional stages of development in the predominant stand types of a physically homogeneous landscape. The mature hardwood stand represents a typical naturally regenerated second-growth forest, free of anthropogenic disturbances for at least 70 years." -US-Wi3,8423,GRP_SITE_FUNDING,SITE_FUNDING,NSF -US-Wi3,27486,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION,"Deep loamy sills with ground moraine, classified as Psamments and Orthods" -US-Wi3,27486,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION_TAXONOMY,Other -US-Wi3,25068,GRP_SPP_O,SPP_O,"Populus grandidentata, Betula papyrifera, Quercus rubra, Acer saccharum, A. rubrum" -US-Wi3,4899,GRP_STATE,STATE,WI -US-Wi3,12550,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Jiquan Chen -US-Wi3,12550,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Wi3,12550,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,jqchen@msu.edu -US-Wi3,12550,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Michigan State University -US-Wi3,5013,GRP_URL,URL,http://research.eeescience.utoledo.edu/lees/research/carbon/ -US-Wi3,24000321,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-Wi3 -US-Wi3,33579,GRP_UTC_OFFSET,UTC_OFFSET,-6 -US-Wi3,33579,GRP_UTC_OFFSET,UTC_OFFSET_COMMENT,Added by AMF data processing team for data QAQC checks. -US-Wi4,24148,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER,12 -US-Wi4,24148,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_ORGAN,Total -US-Wi4,24148,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_PHEN,Mixed/unknown -US-Wi4,24148,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_UNIT,kgDM m-2 -US-Wi4,24148,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_COMMENT,(range 11.5-12.5) 2003: 11.5 2005: 12.5 -US-Wi4,9459,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfb -US-Wi4,27000322,GRP_COUNTRY,COUNTRY,USA -US-Wi4,15752,GRP_DOI,DOI,10.17190/AMF/1246019 -US-Wi4,15752,GRP_DOI,DOI_CITATION,"Jiquan Chen (2020), AmeriFlux BASE US-Wi4 Mature red pine (MRP), Ver. 3-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1246019" -US-Wi4,15752,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-Wi4,31923,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Wi4,31923,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Jiquan Chen -US-Wi4,31923,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Wi4,31923,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,jqchen@msu.edu -US-Wi4,31923,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Michigan State University -US-Wi4,31925,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Michigan State University -US-Wi4,31925,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-Wi4,31924,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,NSF -US-Wi4,31924,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-Wi4,2113,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Wi4,2113,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-Wi4,2113,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,2002 -US-Wi4,2113,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,2005 -US-Wi4,2113,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Wi4,23000322,GRP_HEADER,SITE_NAME,Mature red pine (MRP) -US-Wi4,88356,GRP_HEIGHTC,HEIGHTC,17 -US-Wi4,88356,GRP_HEIGHTC,HEIGHTC_STATISTIC,Minimum -US-Wi4,88356,GRP_HEIGHTC,HEIGHTC_DATE,20050701 -US-Wi4,88356,GRP_HEIGHTC,HEIGHTC_DATE_UNC,60 -US-Wi4,88356,GRP_HEIGHTC,HEIGHTC_COMMENT,"Noormets, A. et al. (2008). Agricultural and Forest Meteorology, 148(2), 216-230. " -US-Wi4,88357,GRP_HEIGHTC,HEIGHTC,19 -US-Wi4,88357,GRP_HEIGHTC,HEIGHTC_STATISTIC,Maximum -US-Wi4,88357,GRP_HEIGHTC,HEIGHTC_DATE,20050701 -US-Wi4,88357,GRP_HEIGHTC,HEIGHTC_DATE_UNC,60 -US-Wi4,88357,GRP_HEIGHTC,HEIGHTC_COMMENT,"Noormets, A. et al. (2008). Agricultural and Forest Meteorology, 148(2), 216-230. " -US-Wi4,88358,GRP_HEIGHTC,HEIGHTC,18 -US-Wi4,88358,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Wi4,88358,GRP_HEIGHTC,HEIGHTC_DATE,20050701 -US-Wi4,88358,GRP_HEIGHTC,HEIGHTC_DATE_UNC,60 -US-Wi4,88358,GRP_HEIGHTC,HEIGHTC_COMMENT,"Noormets, A. et al. (2008). Agricultural and Forest Meteorology, 148(2), 216-230. " -US-Wi4,9432,GRP_IGBP,IGBP,ENF -US-Wi4,24789,GRP_LAI,LAI_TYPE,LAI -US-Wi4,24920,GRP_LAI,LAI_TYPE,LAI -US-Wi4,24920,GRP_LAI,LAI_COMMENT,~1 -US-Wi4,24789,GRP_LAI,LAI_TOT,2.8 -US-Wi4,24920,GRP_LAI,LAI_U,1 -US-Wi4,9266,GRP_LOCATION,LOCATION_LAT,46.7393 -US-Wi4,9266,GRP_LOCATION,LOCATION_LONG,-91.1663 -US-Wi4,9266,GRP_LOCATION,LOCATION_ELEV,352 -US-Wi4,2964,GRP_NETWORK,NETWORK,AmeriFlux -US-Wi4,1700006429,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Baldocchi, D. D., Poindexter, C., Abraha, M., Desai, A. R., Bohrer, G., Arain, M. A., Griffis, T., Blanken, P. D., O'Halloran, T. L., Thomas, R. Q., Zhang, Q., Burns, S. P., Frank, J. M., Christian, D., Brown, S., Black, T. A., Gough, C. M., Law, B. E., Lee, X., Chen, J., Reed, D. E., Massman, W. J., Clark, K., Hatfield, J., Prueger, J., Bracho, R., Baker, J. M., Martin, T. A. (2018) Temporal Dynamics Of Aerodynamic Canopy Height Derived From Eddy Covariance Momentum Flux Data Across North American Flux Networks, Geophysical Research Letters, 45(2), 9275–9287" -US-Wi4,1700006429,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018GL079306 -US-Wi4,1700006429,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Wi4,1700007464,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(2), 108350" -US-Wi4,1700007464,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -US-Wi4,1700007464,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Wi4,1700003057,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Desai, A. R., Noormets, A., Bolstad, P. V., Chen, J., Cook, B. D., Davis, K. J., Euskirchen, E. S., Gough, C., Martin, J. G., Ricciuto, D. M., Schmid, H. P., Tang, J., Wang, W. (2008) Influence Of Vegetation And Seasonal Forcing On Carbon Dioxide Fluxes Across The Upper Midwest, Usa: Implications For Regional Scaling, Agricultural And Forest Meteorology, 148(2), 288-308" -US-Wi4,1700003057,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2007.08.001 -US-Wi4,1700003057,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Wi4,1700007272,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Noormets, A., Chen, J., Crow, T. R. (2007) Age-Dependent Changes In Ecosystem Carbon Fluxes In Managed Forests In Northern Wisconsin, USA, Ecosystems, 10(2), 187-203" -US-Wi4,1700007272,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1007/S10021-007-9018-Y -US-Wi4,1700007272,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Wi4,1700005355,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Noormets, A., Desai, A., Cook, B., Euskirchen, E., Ricciuto, D., Davis, K., Bolstad, P., Schmid, H., Vogel, C., Carey, E., Su, H., Chen, J. (2008) Moisture Sensitivity Of Ecosystem Respiration: Comparison Of 14 Forest Ecosystems In The Upper Great Lakes Region, USA, Agricultural And Forest Meteorology, 148(2), 216-230" -US-Wi4,1700005355,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2007.08.002 -US-Wi4,1700005355,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Wi4,7539,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"The research and science objectives of the Wisconsin Mature Red Pine are as follows: 1) Enhance our understanding of landscape-level carbon exchange in disturbed land mosaics, taking into specific consideration age structure and the area-of- edge-influences (AEI); 2) Determine how the cumulative NEP of a landscape is determined by the land mosaic; that is, the various ages and types of ecosystems present, as well as their arrangement; 3) Investigate the temporal and spatial changes in landscape structure and vegetative composition across a landscape managed for multiple uses within the Chequamegon National Forest in northern Wisconsin; 4) Quantify the developmental changes in Carbon fluxes following stand replacing disturbances; 5) Investigate the common factors that might explain the observed variability among the closely spaced, but diverse, forest ecosystems that represent a disturbed, actively managed and climatically homogeneous forest landscape; 6) Quantify the role of soil moisture in affecting ecosystem respiration; 7) Identify landscape-level patterns in the temperature and moisture response of ecosystem respiration as determined by forest functional type and stage of development. (Project Overview by Primary Investigators: J. Chen and K. Brosofske; Bresee et al., 2004; Noormets et al., 2007; Noormets et al., 2008)" -US-Wi4,24824,GRP_SA,SA,66 -US-Wi4,24824,GRP_SA,SA_COMMENT,"(range 65-67) template: MRP02:64, MRP03:65, MRP04:66, MRP05:67," -US-Wi4,3302,GRP_SITE_CHAR,TERRAIN,"Significant Slope (>5%, <10%)" -US-Wi4,4100,GRP_SITE_DESC,SITE_DESC,"The Wisconsin Mature Red Pine site is located in the Washburn Ranger District of the northeastern section of Chequamegon National Forest. A member of the northern coniferous-deciduous biome, surveys from the mid-19th century indicate the region consisted of a mixed stand of red, white, and jack pines. After extensive timber harvesting, wildfires, and farming activity, the region turned into a fragmented mosaic of stands of various ages and composition. As an assemblage, the ten Wisconsin sites are indicative of the successional stages of development in the predominant stand types of a physically homogeneous landscape. Thinned every 7 years until they reach 100 to 150 years of age, the red pine plantations of all ages occupy approximately 25% of the region." -US-Wi4,5033,GRP_SITE_FUNDING,SITE_FUNDING,NSF -US-Wi4,28936,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION,"Deep loamy sills with ground moraine, classified as Psamments and Orthods" -US-Wi4,28936,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION_TAXONOMY,Other -US-Wi4,24678,GRP_SPP_O,SPP_O,Pinus resinosa -US-Wi4,2328,GRP_STATE,STATE,WI -US-Wi4,12551,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Jiquan Chen -US-Wi4,12551,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Wi4,12551,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,jqchen@msu.edu -US-Wi4,12551,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Michigan State University -US-Wi4,744,GRP_URL,URL,http://research.eeescience.utoledo.edu/lees/research/carbon/ -US-Wi4,24000322,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-Wi4 -US-Wi4,1084,GRP_UTC_OFFSET,UTC_OFFSET,-6 -US-Wi5,1779,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfb -US-Wi5,27000323,GRP_COUNTRY,COUNTRY,USA -US-Wi5,15749,GRP_DOI,DOI,10.17190/AMF/1246020 -US-Wi5,15749,GRP_DOI,DOI_CITATION,"Jiquan Chen (2020), AmeriFlux BASE US-Wi5 Mixed young jack pine (MYJP), Ver. 3-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1246020" -US-Wi5,15749,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-Wi5,31926,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Wi5,31926,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Jiquan Chen -US-Wi5,31926,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Wi5,31926,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,jqchen@msu.edu -US-Wi5,31926,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Michigan State University -US-Wi5,31928,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Michigan State University -US-Wi5,31928,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-Wi5,31927,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,NSF -US-Wi5,31927,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-Wi5,8073,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Wi5,8073,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-Wi5,8073,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,2004 -US-Wi5,8073,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,2004 -US-Wi5,8073,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Wi5,23000323,GRP_HEADER,SITE_NAME,Mixed young jack pine (MYJP) -US-Wi5,88359,GRP_HEIGHTC,HEIGHTC,4 -US-Wi5,88359,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Wi5,88359,GRP_HEIGHTC,HEIGHTC_DATE,20040701 -US-Wi5,88359,GRP_HEIGHTC,HEIGHTC_DATE_UNC,60 -US-Wi5,88359,GRP_HEIGHTC,HEIGHTC_COMMENT,"Noormets, A. et al. (2008). Agricultural and Forest Meteorology, 148(2), 216-230. " -US-Wi5,3453,GRP_IGBP,IGBP,ENF -US-Wi5,25044,GRP_LAI,LAI_TYPE,LAI -US-Wi5,25044,GRP_LAI,LAI_TOT,0.8 -US-Wi5,25044,GRP_LAI,LAI_U,0 -US-Wi5,724,GRP_LOCATION,LOCATION_LAT,46.6531 -US-Wi5,724,GRP_LOCATION,LOCATION_LONG,-91.0858 -US-Wi5,724,GRP_LOCATION,LOCATION_ELEV,353 -US-Wi5,8943,GRP_NETWORK,NETWORK,AmeriFlux -US-Wi5,1700007773,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Baldocchi, D. D., Poindexter, C., Abraha, M., Desai, A. R., Bohrer, G., Arain, M. A., Griffis, T., Blanken, P. D., O'Halloran, T. L., Thomas, R. Q., Zhang, Q., Burns, S. P., Frank, J. M., Christian, D., Brown, S., Black, T. A., Gough, C. M., Law, B. E., Lee, X., Chen, J., Reed, D. E., Massman, W. J., Clark, K., Hatfield, J., Prueger, J., Bracho, R., Baker, J. M., Martin, T. A. (2018) Temporal Dynamics Of Aerodynamic Canopy Height Derived From Eddy Covariance Momentum Flux Data Across North American Flux Networks, Geophysical Research Letters, 45(), 9275–9287" -US-Wi5,1700007773,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018GL079306 -US-Wi5,1700007773,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Wi5,1700004479,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(), 108350" -US-Wi5,1700004479,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -US-Wi5,1700004479,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Wi5,9319,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"The research and science objectives of the Wisconsin Mixed Young Jack Pine are as follows: 1) Enhance our understanding of landscape-level carbon exchange in disturbed land mosaics, taking into specific consideration age structure and the area-of- edge-influences (AEI); 2) Determine how the cumulative NEP of a landscape is determined by the land mosaic; that is, the various ages and types of ecosystems present, as well as their arrangement; 3) Investigate the temporal and spatial changes in landscape structure and vegetative composition across a landscape managed for multiple uses within the Chequamegon National Forest in northern Wisconsin; 4) Quantify the developmental changes in Carbon fluxes following stand replacing disturbances; 5) Investigate the common factors that might explain the observed variability among the closely spaced, but diverse, forest ecosystems that represent a disturbed, actively managed and climatically homogeneous forest landscape; 6) Quantify the role of soil moisture in affecting ecosystem respiration; 7) Identify landscape-level patterns in the temperature and moisture response of ecosystem respiration as determined by forest functional type and stage of development. (Project Overview by Primary Investigators: J. Chen and K. Brosofske; Bresee et al., 2004; Noormets et al., 2007; Noormets et al., 2008)" -US-Wi5,24561,GRP_SA,SA_MAX,15 -US-Wi5,24815,GRP_SA,SA,13 -US-Wi5,24815,GRP_SA,SA_COMMENT,(range 10-15) 10_15 -US-Wi5,5855,GRP_SITE_CHAR,TERRAIN,"Significant Slope (>5%, <10%)" -US-Wi5,9295,GRP_SITE_DESC,SITE_DESC,"The Wisconsin Mixed Young Jack Pine site is located in the Washburn Ranger District of the northeastern section of Chequamegon National Forest. A member of the northern coniferous-deciduous biome, surveys from the mid-19th century indicate the region consisted of a mixed stand of red, white, and jack pines. After extensive timber harvesting, wildfires, and farming activity, the region turned into a fragmented mosaic of stands of various ages and composition. As an assemblage, the ten Wisconsin sites are indicative of the successional stages of development in the predominant stand types of a physically homogeneous landscape. Clearcut on 40 to 70 year intervals, jack pine stands occupy approximately 13% of the region." -US-Wi5,7563,GRP_SITE_FUNDING,SITE_FUNDING,NSF -US-Wi5,27816,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION,"Deep loamy sills with ground moraine, classified as Psamments and Orthods" -US-Wi5,27816,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION_TAXONOMY,Other -US-Wi5,23797,GRP_SPP_O,SPP_O,"Pinus banksiana, Prunus serotina, Rosa sp." -US-Wi5,8295,GRP_STATE,STATE,WI -US-Wi5,12552,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Jiquan Chen -US-Wi5,12552,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Wi5,12552,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,jqchen@msu.edu -US-Wi5,12552,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Michigan State University -US-Wi5,1599,GRP_URL,URL,http://research.eeescience.utoledo.edu/lees/research/carbon/ -US-Wi5,24000323,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-Wi5 -US-Wi5,8726,GRP_UTC_OFFSET,UTC_OFFSET,-6 -US-Wi6,5195,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfb -US-Wi6,27000324,GRP_COUNTRY,COUNTRY,USA -US-Wi6,15738,GRP_DOI,DOI,10.17190/AMF/1246021 -US-Wi6,15738,GRP_DOI,DOI_CITATION,"Jiquan Chen (2020), AmeriFlux BASE US-Wi6 Pine barrens #1 (PB1), Ver. 3-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1246021" -US-Wi6,15738,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-Wi6,31929,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Wi6,31929,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Jiquan Chen -US-Wi6,31929,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Wi6,31929,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,jqchen@msu.edu -US-Wi6,31929,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Michigan State University -US-Wi6,31931,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Michigan State University -US-Wi6,31931,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-Wi6,31930,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,NSF -US-Wi6,31930,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-Wi6,8074,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Wi6,8074,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-Wi6,8074,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,2002 -US-Wi6,8074,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,2002 -US-Wi6,8074,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Wi6,23000324,GRP_HEADER,SITE_NAME,Pine barrens #1 (PB1) -US-Wi6,88360,GRP_HEIGHTC,HEIGHTC,0.5 -US-Wi6,88360,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Wi6,88360,GRP_HEIGHTC,HEIGHTC_DATE,20020701 -US-Wi6,88360,GRP_HEIGHTC,HEIGHTC_DATE_UNC,60 -US-Wi6,88360,GRP_HEIGHTC,HEIGHTC_COMMENT,"Noormets, A. et al. (2008). Agricultural and Forest Meteorology, 148(2), 216-230. " -US-Wi6,6836,GRP_IGBP,IGBP,OSH -US-Wi6,24685,GRP_LAI,LAI_TYPE,LAI -US-Wi6,24685,GRP_LAI,LAI_U,0 -US-Wi6,4997,GRP_LOCATION,LOCATION_LAT,46.6249 -US-Wi6,4997,GRP_LOCATION,LOCATION_LONG,-91.2982 -US-Wi6,4997,GRP_LOCATION,LOCATION_ELEV,371 -US-Wi6,2149,GRP_NETWORK,NETWORK,AmeriFlux -US-Wi6,1700001770,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(2), 108350" -US-Wi6,1700001770,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -US-Wi6,1700001770,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Wi6,1700005400,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Desai, A. R., Noormets, A., Bolstad, P. V., Chen, J., Cook, B. D., Davis, K. J., Euskirchen, E. S., Gough, C., Martin, J. G., Ricciuto, D. M., Schmid, H. P., Tang, J., Wang, W. (2008) Influence Of Vegetation And Seasonal Forcing On Carbon Dioxide Fluxes Across The Upper Midwest, Usa: Implications For Regional Scaling, Agricultural And Forest Meteorology, 148(2), 288-308" -US-Wi6,1700005400,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2007.08.001 -US-Wi6,1700005400,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Wi6,1700002658,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Noormets, A., Chen, J., Crow, T. R. (2007) Age-Dependent Changes In Ecosystem Carbon Fluxes In Managed Forests In Northern Wisconsin, USA, Ecosystems, 10(2), 187-203" -US-Wi6,1700002658,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1007/S10021-007-9018-Y -US-Wi6,1700002658,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Wi6,1700008073,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Noormets, A., Desai, A., Cook, B., Euskirchen, E., Ricciuto, D., Davis, K., Bolstad, P., Schmid, H., Vogel, C., Carey, E., Su, H., Chen, J. (2008) Moisture Sensitivity Of Ecosystem Respiration: Comparison Of 14 Forest Ecosystems In The Upper Great Lakes Region, USA, Agricultural And Forest Meteorology, 148(2), 216-230" -US-Wi6,1700008073,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2007.08.002 -US-Wi6,1700008073,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Wi6,2479,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"The research and science objectives of the Wisconsin Pine Barrens are as follows: 1) Enhance our understanding of landscape-level carbon exchange in disturbed land mosaics, taking into specific consideration age structure and the area-of- edge-influences (AEI); 2) Determine how the cumulative NEP of a landscape is determined by the land mosaic; that is, the various ages and types of ecosystems present, as well as their arrangement; 3) Investigate the temporal and spatial changes in landscape structure and vegetative composition across a landscape managed for multiple uses within the Chequamegon National Forest in northern Wisconsin; 4) Quantify the developmental changes in Carbon fluxes following stand replacing disturbances; 5) Investigate the common factors that might explain the observed variability among the closely spaced, but diverse, forest ecosystems that represent a disturbed, actively managed and climatically homogeneous forest landscape; 6) Quantify the role of soil moisture in affecting ecosystem respiration; 7) Identify landscape-level patterns in the temperature and moisture response of ecosystem respiration as determined by forest functional type and stage of development. (Project Overview by Primary Investigators: J. Chen and K. Brosofske; Bresee et al., 2004; Noormets et al., 2007; Noormets et al., 2008)" -US-Wi6,24683,GRP_SA,SA,7 -US-Wi6,24683,GRP_SA,SA_MAX,12 -US-Wi6,2449,GRP_SITE_CHAR,TERRAIN,"Significant Slope (>5%, <10%)" -US-Wi6,5860,GRP_SITE_DESC,SITE_DESC,"The Wisconsin Pine Barrens site is located in the Washburn Ranger District of the northeastern section of Chequamegon National Forest. A member of the northern coniferous-deciduous biome, surveys from the mid-19th century indicate the region consisted of a mixed stand of red, white, and jack pines. After extensive timber harvesting, wildfires, and farming activity, the region turned into a fragmented mosaic of stands of various ages and composition. As an assemblage, the ten Wisconsin sites are indicative of the successional stages of development in the predominant stand types of a physically homogeneous landscape. In order to establish and maintain both natural and plantation jack pine stands, pine barrens undergo prescribed burns and harvesting rotations. Pine Barrens occupy 17% of the region in 2001." -US-Wi6,765,GRP_SITE_FUNDING,SITE_FUNDING,NSF -US-Wi6,29311,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION,"Deep loamy sills with ground moraine, classified as Psamments and Orthods" -US-Wi6,29311,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION_TAXONOMY,Other -US-Wi6,25069,GRP_SPP_O,SPP_O,"Vaccinium angustifolium, Andropogon scoparius, Comptonia peregrina, Salix humilis" -US-Wi6,4900,GRP_STATE,STATE,WI -US-Wi6,12553,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Jiquan Chen -US-Wi6,12553,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Wi6,12553,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,jqchen@msu.edu -US-Wi6,12553,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Michigan State University -US-Wi6,8416,GRP_URL,URL,http://research.eeescience.utoledo.edu/lees/research/carbon/ -US-Wi6,24000324,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-Wi6 -US-Wi6,1939,GRP_UTC_OFFSET,UTC_OFFSET,-6 -US-Wi7,928,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfb -US-Wi7,27000325,GRP_COUNTRY,COUNTRY,USA -US-Wi7,15739,GRP_DOI,DOI,10.17190/AMF/1246022 -US-Wi7,15739,GRP_DOI,DOI_CITATION,"Jiquan Chen (2020), AmeriFlux BASE US-Wi7 Red pine clearcut (RPCC), Ver. 3-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1246022" -US-Wi7,15739,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-Wi7,31932,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Wi7,31932,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Jiquan Chen -US-Wi7,31932,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Wi7,31932,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,jqchen@msu.edu -US-Wi7,31932,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Michigan State University -US-Wi7,31934,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Michigan State University -US-Wi7,31934,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-Wi7,31933,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,NSF -US-Wi7,31933,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-Wi7,3780,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Wi7,3780,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-Wi7,3780,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,2005 -US-Wi7,3780,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,2005 -US-Wi7,3780,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Wi7,23000325,GRP_HEADER,SITE_NAME,Red pine clearcut (RPCC) -US-Wi7,4259,GRP_IGBP,IGBP,OSH -US-Wi7,24432,GRP_LAI,LAI_TYPE,LAI -US-Wi7,24432,GRP_LAI,LAI_TOT,0 -US-Wi7,24432,GRP_LAI,LAI_U,0 -US-Wi7,2423,GRP_LOCATION,LOCATION_LAT,46.6491 -US-Wi7,2423,GRP_LOCATION,LOCATION_LONG,-91.0693 -US-Wi7,2423,GRP_LOCATION,LOCATION_ELEV,335 -US-Wi7,8102,GRP_NETWORK,NETWORK,AmeriFlux -US-Wi7,1700001896,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(), 108350" -US-Wi7,1700001896,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -US-Wi7,1700001896,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Wi7,6689,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"The research and science objectives of the Wisconsin Clearcut Red Pine are as follows: 1) Enhance our understanding of landscape-level carbon exchange in disturbed land mosaics, taking into specific consideration age structure and the area-of- edge-influences (AEI); 2) Determine how the cumulative NEP of a landscape is determined by the land mosaic; that is, the various ages and types of ecosystems present, as well as their arrangement; 3) Investigate the temporal and spatial changes in landscape structure and vegetative composition across a landscape managed for multiple uses within the Chequamegon National Forest in northern Wisconsin; 4) Quantify the developmental changes in Carbon fluxes following stand replacing disturbances; 5) Investigate the common factors that might explain the observed variability among the closely spaced, but diverse, forest ecosystems that represent a disturbed, actively managed and climatically homogeneous forest landscape; 6) Quantify the role of soil moisture in affecting ecosystem respiration; 7) Identify landscape-level patterns in the temperature and moisture response of ecosystem respiration as determined by forest functional type and stage of development. (Project Overview by Primary Investigators: J. Chen and K. Brosofske; Bresee et al., 2004; Noormets et al., 2007; Noormets et al., 2008)" -US-Wi7,23661,GRP_SA,SA,5 -US-Wi7,23661,GRP_SA,SA_COMMENT,<5 -US-Wi7,5008,GRP_SITE_CHAR,TERRAIN,"Significant Slope (>5%, <10%)" -US-Wi7,5014,GRP_SITE_DESC,SITE_DESC,"The Wisconsin Clearcut Red Pine site is located in the Washburn Ranger District of the northeastern section of Chequamegon National Forest. A member of the northern coniferous-deciduous biome, surveys from the mid-19th century indicate the region consisted of a mixed stand of red, white, and jack pines. After extensive timber harvesting, wildfires, and farming activity, the region turned into a fragmented mosaic of stands of various ages and composition. The red pine clearcut site is one of ten sites that collectively represent the successional stages of development in the predominant stand types of a physically homogeneous landscape. Thinned every 7 years until they reach 100 to 150 years of age, the red pine plantations or all ages occupy approximately 25% of the region." -US-Wi7,10154,GRP_SITE_FUNDING,SITE_FUNDING,NSF -US-Wi7,29622,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION,"Deep loamy sills with ground moraine, classified as Psamments and Orthods" -US-Wi7,29622,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION_TAXONOMY,Other -US-Wi7,7433,GRP_STATE,STATE,WI -US-Wi7,12554,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Jiquan Chen -US-Wi7,12554,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Wi7,12554,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,jqchen@msu.edu -US-Wi7,12554,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Michigan State University -US-Wi7,5857,GRP_URL,URL,http://research.eeescience.utoledo.edu/lees/research/carbon/ -US-Wi7,24000325,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-Wi7 -US-Wi7,6182,GRP_UTC_OFFSET,UTC_OFFSET,-6 -US-Wi8,101,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfb -US-Wi8,27000326,GRP_COUNTRY,COUNTRY,USA -US-Wi8,15654,GRP_DOI,DOI,10.17190/AMF/1246023 -US-Wi8,15654,GRP_DOI,DOI_CITATION,"Jiquan Chen (2020), AmeriFlux BASE US-Wi8 Young hardwood clearcut (YHW), Ver. 3-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1246023" -US-Wi8,15654,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-Wi8,31935,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Wi8,31935,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Jiquan Chen -US-Wi8,31935,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Wi8,31935,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,jqchen@msu.edu -US-Wi8,31935,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Michigan State University -US-Wi8,31937,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Michigan State University -US-Wi8,31937,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-Wi8,31936,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,NSF -US-Wi8,31936,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-Wi8,3781,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Wi8,3781,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-Wi8,3781,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,2002 -US-Wi8,3781,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,2002 -US-Wi8,3781,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Wi8,23000326,GRP_HEADER,SITE_NAME,Young hardwood clearcut (YHW) -US-Wi8,88361,GRP_HEIGHTC,HEIGHTC,1.5 -US-Wi8,88361,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Wi8,88361,GRP_HEIGHTC,HEIGHTC_DATE,20020701 -US-Wi8,88361,GRP_HEIGHTC,HEIGHTC_DATE_UNC,60 -US-Wi8,88361,GRP_HEIGHTC,HEIGHTC_COMMENT,"Noormets, A. et al. (2008). Agricultural and Forest Meteorology, 148(2), 216-230. " -US-Wi8,7701,GRP_IGBP,IGBP,DBF -US-Wi8,24274,GRP_LAI,LAI_TYPE,LAI -US-Wi8,24274,GRP_LAI,LAI_TOT,1.2 -US-Wi8,24274,GRP_LAI,LAI_U,0 -US-Wi8,4992,GRP_LOCATION,LOCATION_LAT,46.7223 -US-Wi8,4992,GRP_LOCATION,LOCATION_LONG,-91.2524 -US-Wi8,4992,GRP_LOCATION,LOCATION_ELEV,348 -US-Wi8,1267,GRP_NETWORK,NETWORK,AmeriFlux -US-Wi8,1700004440,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Baldocchi, D. D., Poindexter, C., Abraha, M., Desai, A. R., Bohrer, G., Arain, M. A., Griffis, T., Blanken, P. D., O'Halloran, T. L., Thomas, R. Q., Zhang, Q., Burns, S. P., Frank, J. M., Christian, D., Brown, S., Black, T. A., Gough, C. M., Law, B. E., Lee, X., Chen, J., Reed, D. E., Massman, W. J., Clark, K., Hatfield, J., Prueger, J., Bracho, R., Baker, J. M., Martin, T. A. (2018) Temporal Dynamics Of Aerodynamic Canopy Height Derived From Eddy Covariance Momentum Flux Data Across North American Flux Networks, Geophysical Research Letters, 45(2), 9275–9287" -US-Wi8,1700004440,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018GL079306 -US-Wi8,1700004440,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Wi8,1700003570,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(2), 108350" -US-Wi8,1700003570,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -US-Wi8,1700003570,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Wi8,1700008643,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Desai, A. R., Noormets, A., Bolstad, P. V., Chen, J., Cook, B. D., Davis, K. J., Euskirchen, E. S., Gough, C., Martin, J. G., Ricciuto, D. M., Schmid, H. P., Tang, J., Wang, W. (2008) Influence Of Vegetation And Seasonal Forcing On Carbon Dioxide Fluxes Across The Upper Midwest, Usa: Implications For Regional Scaling, Agricultural And Forest Meteorology, 148(2), 288-308" -US-Wi8,1700008643,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2007.08.001 -US-Wi8,1700008643,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Wi8,1700000957,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Noormets, A., Chen, J., Crow, T. R. (2007) Age-Dependent Changes In Ecosystem Carbon Fluxes In Managed Forests In Northern Wisconsin, USA, Ecosystems, 10(2), 187-203" -US-Wi8,1700000957,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1007/S10021-007-9018-Y -US-Wi8,1700000957,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Wi8,1700005265,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Noormets, A., Desai, A., Cook, B., Euskirchen, E., Ricciuto, D., Davis, K., Bolstad, P., Schmid, H., Vogel, C., Carey, E., Su, H., Chen, J. (2008) Moisture Sensitivity Of Ecosystem Respiration: Comparison Of 14 Forest Ecosystems In The Upper Great Lakes Region, USA, Agricultural And Forest Meteorology, 148(2), 216-230" -US-Wi8,1700005265,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2007.08.002 -US-Wi8,1700005265,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Wi8,10119,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"The research and science objectives of the Wisconsin Clearcut Young Hardwoods are as follows: 1) Enhance our understanding of landscape-level carbon exchange in disturbed land mosaics, taking into specific consideration age structure and the area-of- edge-influences (AEI); 2) Determine how the cumulative NEP of a landscape is determined by the land mosaic; that is, the various ages and types of ecosystems present, as well as their arrangement; 3) Investigate the temporal and spatial changes in landscape structure and vegetative composition across a landscape managed for multiple uses within the Chequamegon National Forest in northern Wisconsin; 4) Quantify the developmental changes in Carbon fluxes following stand replacing disturbances; 5) Investigate the common factors that might explain the observed variability among the closely spaced, but diverse, forest ecosystems that represent a disturbed, actively managed and climatically homogeneous forest landscape; 6) Quantify the role of soil moisture in affecting ecosystem respiration; 7) Identify landscape-level patterns in the temperature and moisture response of ecosystem respiration as determined by forest functional type and stage of development. (Project Overview by Primary Investigators: J. Chen and K. Brosofske; Bresee et al., 2004; Noormets et al., 2007; Noormets et al., 2008)" -US-Wi8,23927,GRP_SA,SA,3 -US-Wi8,8411,GRP_SITE_CHAR,TERRAIN,"Significant Slope (>5%, <10%)" -US-Wi8,1601,GRP_SITE_DESC,SITE_DESC,"The Wisconsin Clearcut Young Hardwood site is located in the Washburn Ranger District of the northeastern section of Chequamegon National Forest. A member of the northern coniferous-deciduous biome, surveys from the mid-19th century indicate the region consisted of a mixed stand of red, white, and jack pines. After extensive timber harvesting, wildfires, and farming activity, the region turned into a fragmented mosaic of stands of various ages and composition. The young hardwood clearcut site is one of ten sites that collectively represent the successional stages of development in the predominant stand types of a physically homogeneous landscape. In 2001, northern hardwood stands of all ages occupied 45% of the region." -US-Wi8,10155,GRP_SITE_FUNDING,SITE_FUNDING,NSF -US-Wi8,27487,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION,"Deep loamy sills with ground moraine, classified as Psamments and Orthods" -US-Wi8,27487,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION_TAXONOMY,Other -US-Wi8,24557,GRP_SPP_O,SPP_O,"Populus grandidentata, Acer rubrum, P. tremuloides" -US-Wi8,3184,GRP_STATE,STATE,WI -US-Wi8,12555,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Jiquan Chen -US-Wi8,12555,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Wi8,12555,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,jqchen@msu.edu -US-Wi8,12555,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Michigan State University -US-Wi8,2451,GRP_URL,URL,http://research.eeescience.utoledo.edu/lees/research/carbon/ -US-Wi8,24000326,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-Wi8 -US-Wi8,6183,GRP_UTC_OFFSET,UTC_OFFSET,-6 -US-Wi9,8570,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfb -US-Wi9,27000327,GRP_COUNTRY,COUNTRY,USA -US-Wi9,15669,GRP_DOI,DOI,10.17190/AMF/1246024 -US-Wi9,15669,GRP_DOI,DOI_CITATION,"Jiquan Chen (2020), AmeriFlux BASE US-Wi9 Young Jack pine (YJP), Ver. 3-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1246024" -US-Wi9,15669,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-Wi9,31938,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Wi9,31938,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Jiquan Chen -US-Wi9,31938,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Wi9,31938,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,jqchen@msu.edu -US-Wi9,31938,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Michigan State University -US-Wi9,31940,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Michigan State University -US-Wi9,31940,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-Wi9,31939,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,NSF -US-Wi9,31939,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-Wi9,1235,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Wi9,1235,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-Wi9,1235,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,2004 -US-Wi9,1235,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,2005 -US-Wi9,1235,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Wi9,23000327,GRP_HEADER,SITE_NAME,Young Jack pine (YJP) -US-Wi9,88362,GRP_HEIGHTC,HEIGHTC,2.3 -US-Wi9,88362,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Wi9,88362,GRP_HEIGHTC,HEIGHTC_DATE,20040701 -US-Wi9,88362,GRP_HEIGHTC,HEIGHTC_DATE_UNC,60 -US-Wi9,88362,GRP_HEIGHTC,HEIGHTC_COMMENT,"Noormets, A. et al. (2008). Agricultural and Forest Meteorology, 148(2), 216-230. " -US-Wi9,69,GRP_IGBP,IGBP,ENF -US-Wi9,24405,GRP_LAI,LAI_TYPE,LAI -US-Wi9,24405,GRP_LAI,LAI_TOT,1.5 -US-Wi9,24405,GRP_LAI,LAI_U,0 -US-Wi9,92891,GRP_LOCATION,LOCATION_LAT,46.7385 -US-Wi9,92891,GRP_LOCATION,LOCATION_LONG,-91.0746 -US-Wi9,92891,GRP_LOCATION,LOCATION_ELEV,350 -US-Wi9,5538,GRP_NETWORK,NETWORK,AmeriFlux -US-Wi9,1700001752,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Baldocchi, D. D., Poindexter, C., Abraha, M., Desai, A. R., Bohrer, G., Arain, M. A., Griffis, T., Blanken, P. D., O'Halloran, T. L., Thomas, R. Q., Zhang, Q., Burns, S. P., Frank, J. M., Christian, D., Brown, S., Black, T. A., Gough, C. M., Law, B. E., Lee, X., Chen, J., Reed, D. E., Massman, W. J., Clark, K., Hatfield, J., Prueger, J., Bracho, R., Baker, J. M., Martin, T. A. (2018) Temporal Dynamics Of Aerodynamic Canopy Height Derived From Eddy Covariance Momentum Flux Data Across North American Flux Networks, Geophysical Research Letters, 45(), 9275–9287" -US-Wi9,1700001752,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018GL079306 -US-Wi9,1700001752,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Wi9,1700001068,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(), 108350" -US-Wi9,1700001068,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -US-Wi9,1700001068,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Wi9,4128,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"The research and science objectives of the Wisconsin Young Jack Pine are as follows: 1) Enhance our understanding of landscape-level carbon exchange in disturbed land mosaics, taking into specific consideration age structure and the area-of- edge-influences (AEI); 2) Determine how the cumulative NEP of a landscape is determined by the land mosaic; that is, the various ages and types of ecosystems present, as well as their arrangement; 3) Investigate the temporal and spatial changes in landscape structure and vegetative composition across a landscape managed for multiple uses within the Chequamegon National Forest in northern Wisconsin; 4) Quantify the developmental changes in Carbon fluxes following stand replacing disturbances; 5) Investigate the common factors that might explain the observed variability among the closely spaced, but diverse, forest ecosystems that represent a disturbed, actively managed and climatically homogeneous forest landscape; 6) Quantify the role of soil moisture in affecting ecosystem respiration; 7) Identify landscape-level patterns in the temperature and moisture response of ecosystem respiration as determined by forest functional type and stage of development. (Project Overview by Primary Investigators: J. Chen and K. Brosofske; Bresee et al., 2004; Noormets et al., 2007; Noormets et al., 2008)" -US-Wi9,24816,GRP_SA,SA,15 -US-Wi9,9292,GRP_SITE_CHAR,TERRAIN,"Significant Slope (>5%, <10%)" -US-Wi9,736,GRP_SITE_DESC,SITE_DESC,"The Wisconsin Young Jack Pine site is located in the Washburn Ranger District of the northeastern section of Chequamegon National Forest. A member of the northern coniferous-deciduous biome, surveys from the mid-19th century indicate the region consisted of a mixed stand of red, white, and jack pines. After extensive timber harvesting, wildfires, and farming activity, the region turned into a fragmented mosaic of stands of various ages and composition. As an assemblage, the ten Wisconsin sites are indicative of the successional stages of development in the predominant stand types of a physically homogeneous landscape. Clearcut on 40 to 70 year intervals, jack pine stands occupy approximately 13% of the region." -US-Wi9,7564,GRP_SITE_FUNDING,SITE_FUNDING,NSF -US-Wi9,28785,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION,"Deep loamy sills with ground moraine, classified as Psamments and Orthods" -US-Wi9,28785,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION_TAXONOMY,Other -US-Wi9,24035,GRP_SPP_O,SPP_O,Pinus banksiana -US-Wi9,1487,GRP_STATE,STATE,WI -US-Wi9,12556,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Jiquan Chen -US-Wi9,12556,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Wi9,12556,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,jqchen@msu.edu -US-Wi9,12556,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Michigan State University -US-Wi9,1600,GRP_URL,URL,http://research.eeescience.utoledo.edu/lees/research/carbon/ -US-Wi9,24000327,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-Wi9 -US-Wi9,8727,GRP_UTC_OFFSET,UTC_OFFSET,-6 -US-Wjs,12422,GRP_CLIM_AVG,MAT,15.2 -US-Wjs,12422,GRP_CLIM_AVG,MAP,361 -US-Wjs,12422,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Bsk -US-Wjs,27000469,GRP_COUNTRY,COUNTRY,USA -US-Wjs,15656,GRP_DOI,DOI,10.17190/AMF/1246120 -US-Wjs,15656,GRP_DOI,DOI_CITATION,"Marcy Litvak (2022), AmeriFlux BASE US-Wjs Willard Juniper Savannah, Ver. 17-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1246120" -US-Wjs,15656,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-Wjs,32256,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Wjs,32256,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Marcy Litvak -US-Wjs,32256,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Wjs,32256,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,mlitvak@unm.edu -US-Wjs,32256,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of New Mexico -US-Wjs,32258,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,University of New Mexico -US-Wjs,32258,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-Wjs,32257,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,NSF -US-Wjs,32257,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-Wjs,15523,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Drought -US-Wjs,15534,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Wjs,15534,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-Wjs,15534,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,200701010000 -US-Wjs,15534,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Wjs,12423,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Wjs,12423,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-Wjs,12423,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20070101 -US-Wjs,12423,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Wjs,15524,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Wjs,15524,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-Wjs,15524,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,200705041330 -US-Wjs,15524,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Wjs,23000469,GRP_HEADER,SITE_NAME,Willard Juniper Savannah -US-Wjs,15525,GRP_IGBP,IGBP,SAV -US-Wjs,15525,GRP_IGBP,IGBP_DATE_START,200705041330 -US-Wjs,15525,GRP_IGBP,IGBP_COMMENT,Juniper savannah (~26% Juniper cover) -US-Wjs,15526,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -US-Wjs,15526,GRP_LAND_OWNERSHIP,LAND_OWNER,Leroy Humphries 7 up 7 down Ranch -US-Wjs,15527,GRP_LOCATION,LOCATION_LAT,34.4255 -US-Wjs,15527,GRP_LOCATION,LOCATION_LONG,-105.8615 -US-Wjs,15527,GRP_LOCATION,LOCATION_ELEV,1931 -US-Wjs,15527,GRP_LOCATION,LOCATION_DATE_START,200705041330 -US-Wjs,12427,GRP_NETWORK,NETWORK,AmeriFlux -US-Wjs,1700000216,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Anderson-Teixeira, K. J., Delong, J. P., Fox, A. M., Brese, D. A., Litvak, M. E. (2011) Differential Responses Of Production And Respiration To Temperature And Moisture Drive The Carbon Balance Across A Climatic Gradient In New Mexico, Global Change Biology, 17(1), 410-424" -US-Wjs,1700000216,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/J.1365-2486.2010.02269.X -US-Wjs,1700000216,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Wjs,1700002469,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Biederman, J. A., Scott, R. L., Bell, T. W., Bowling, D. R., Dore, S., Garatuza-Payan, J., Kolb, T. E., Krishnan, P., Krofcheck, D. J., Litvak, M. E., Maurer, G. E., Meyers, T. P., Oechel, W. C., Papuga, S. A., Ponce-Campos, G. E., Rodriguez, J. C., Smith, W. K., Vargas, R., Watts, C. J., Yepez, E. A., Goulden, M. L. (2017) Co2 Exchange And Evapotranspiration Across Dryland Ecosystems Of Southwestern North America, Global Change Biology, 23(10), 4204-4221" -US-Wjs,1700002469,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/GCB.13686 -US-Wjs,1700002469,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Wjs,1700001038,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Biederman, J. A., Scott, R. L., Goulden, M. L., Vargas, R., Litvak, M. E., Kolb, T. E., Yepez, E. A., Oechel, W. C., Blanken, P. D., Bell, T. W., Garatuza-Payan, J., Maurer, G. E., Dore, S., Burns, S. P. (2016) Terrestrial Carbon Balance In A Drier World: The Effects Of Water Availability In Southwestern North America, Global Change Biology, 22(5), 1867-1879" -US-Wjs,1700001038,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/GCB.13222 -US-Wjs,1700001038,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Wjs,1700008415,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(5), 108350" -US-Wjs,1700008415,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -US-Wjs,1700008415,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Wjs,1700004182,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Dettweiler-Robinson, E., Nuanez, M., Litvak, M. E. (2018) Biocrust Contribution To Ecosystem Carbon Fluxes Varies Along An Elevational Gradient, Ecosphere, 9(6), e02315" -US-Wjs,1700004182,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/ECS2.2315 -US-Wjs,1700004182,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Wjs,1700001635,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Senay, G. B., Schauer, M., Velpuri, N. M., Singh, R. K., Kagone, S., Friedrichs, M., Litvak, M. E., Douglas-Mankin, K. R. (2019) Long-Term (1986–2015) Crop Water Use Characterization Over The Upper Rio Grande Basin Of United States And Mexico Using Landsat-Based Evapotranspiration, Remote Sensing, 11(13), 1587" -US-Wjs,1700001635,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.3390/RS11131587 -US-Wjs,1700001635,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Wjs,1700005079,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Wolf, S., Keenan, T. F., Fisher, J. B., Baldocchi, D. D., Desai, A. R., Richardson, A. D., Scott, R. L., Law, B. E., Litvak, M. E., Brunsell, N. A., Peters, W., van der Laan-Luijkx, I. T. (2016) Warm Spring Reduced Carbon Cycle Impact Of The 2012 Us Summer Drought, Proceedings Of The National Academy Of Sciences, 113(21), 5880-5885" -US-Wjs,1700005079,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1073/PNAS.1519620113 -US-Wjs,1700005079,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Wjs,1700004953,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Wolf, S., Keenan, T.F., Fisher, J.B., Baldocchi, D.D., Desai, A.R., Richardson, A.D., Scott, R.L., Law, B.E., Litvak, M.E., Brunsell, N.A., Peters, W., van der Laan-Luijkx, I.T. (2016) Warm spring reduced carbon cycle impact of the 2012 US summer drought, Proceedings of the National Academy of Sciences, 113(21), 5880-5885" -US-Wjs,1700004953,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1073/PNAS.1519620113 -US-Wjs,1700004953,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Wjs,30676,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"Research topics and objectives include 1) To understand the coupled water and energy cycles in semiarid environments; 2) Quantify carbon, water and energy fluxes in addition to inter-annual variability in these fluxes; 3) Quantify the extent to which water and carbon fluxes are controlled by soil moisture and rainfall, and the sensitivity of fluxes in this biome to changes in temperature and precipitation." -US-Wjs,12428,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"University of New Mexico, 219 Yale Blvd. NE, Castetter Hall Rm 1480, Albuquerque, NM 87131" -US-Wjs,12429,GRP_SITE_CHAR,WIND_DIRECTION,SW -US-Wjs,12430,GRP_SITE_DESC,SITE_DESC,The Juniper Savanna site is located in the Southwestern Tablelands in central New Mexico on a private ranch. Its vegetation is composed of Juniperus monosperma and intermittently grazed C4 perennial grasses of which the dominant species is Bouteloua gracilis. -US-Wjs,12431,GRP_SITE_FUNDING,SITE_FUNDING,NSF -US-Wjs,12432,GRP_STATE,STATE,NM -US-Wjs,15531,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Marcy Litvak -US-Wjs,15531,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Wjs,15531,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,mlitvak@unm.edu -US-Wjs,15531,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of New Mexico -US-Wjs,81442,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Tomer Duman -US-Wjs,81442,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,DataManager -US-Wjs,81442,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,tomerduman@gmail.com -US-Wjs,81442,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of New Mexico -US-Wjs,99178,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Anthony Luketich -US-Wjs,99178,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Technician -US-Wjs,99178,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,luketich@unm.edu -US-Wjs,99178,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of New Mexico -US-Wjs,29846,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-Wjs,15532,GRP_TOWER_TYPE,TOWER_TYPE,triangle -US-Wjs,81440,GRP_URL,URL,http://www.litvaklab.org/juniper-savanna.html -US-Wjs,24000469,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-Wjs -US-Wjs,15533,GRP_UTC_OFFSET,UTC_OFFSET,-7 -US-Wjs,15533,GRP_UTC_OFFSET,UTC_OFFSET_DATE_START,200705041330 -US-Wkg,24794,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER,0.1 -US-Wkg,24794,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_ORGAN,Total -US-Wkg,24794,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_PHEN,Mixed/unknown -US-Wkg,24794,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_UNIT,kgDM m-2 -US-Wkg,24794,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_COMMENT,"Russ Scott: -From Nouvellon, Remote Sensing Env., 78, 1313-149, 2001" -US-Wkg,11797,GRP_CLIM_AVG,MAT,15.64 -US-Wkg,11797,GRP_CLIM_AVG,MAP,407 -US-Wkg,11797,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Bsk -US-Wkg,27000445,GRP_COUNTRY,COUNTRY,USA -US-Wkg,15764,GRP_DOI,DOI,10.17190/AMF/1246112 -US-Wkg,15764,GRP_DOI,DOI_CITATION,"Russell Scott (2022), AmeriFlux BASE US-Wkg Walnut Gulch Kendall Grasslands, Ver. 19-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1246112" -US-Wkg,15764,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-Wkg,32230,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Wkg,32230,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Russell Scott -US-Wkg,32230,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Wkg,32230,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,russ.scott@ars.usda.gov -US-Wkg,32230,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,United States Department of Agriculture -US-Wkg,32232,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,United States Department of Agriculture -US-Wkg,32232,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-Wkg,32231,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,"USDA-ARS, DOE" -US-Wkg,32231,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-Wkg,11798,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Grazing -US-Wkg,11799,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Wkg,11799,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-Wkg,11799,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,2004 -US-Wkg,11799,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Wkg,23000445,GRP_HEADER,SITE_NAME,Walnut Gulch Kendall Grasslands -US-Wkg,88645,GRP_HEIGHTC,HEIGHTC,0.5 -US-Wkg,88645,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-Wkg,88645,GRP_HEIGHTC,HEIGHTC_DATE,20000101 -US-Wkg,88646,GRP_HEIGHTC,HEIGHTC,0.4 -US-Wkg,88646,GRP_HEIGHTC,HEIGHTC_STATISTIC,Minimum -US-Wkg,88646,GRP_HEIGHTC,HEIGHTC_DATE,20000101 -US-Wkg,88647,GRP_HEIGHTC,HEIGHTC,0.7 -US-Wkg,88647,GRP_HEIGHTC,HEIGHTC_STATISTIC,Maximum -US-Wkg,88647,GRP_HEIGHTC,HEIGHTC_DATE,20000101 -US-Wkg,11800,GRP_IGBP,IGBP,GRA -US-Wkg,23760,GRP_LAI,LAI_TYPE,LAI -US-Wkg,23760,GRP_LAI,LAI_COMMENT,"Russ Scott: -From Nouvellon, Remote Sensing Env., 78, 1313-149, 2001" -US-Wkg,23760,GRP_LAI,LAI_TOT,0.9 -US-Wkg,11801,GRP_LOCATION,LOCATION_LAT,31.7365 -US-Wkg,11801,GRP_LOCATION,LOCATION_LONG,-109.9419 -US-Wkg,11801,GRP_LOCATION,LOCATION_ELEV,1531 -US-Wkg,24660,GRP_NEP,NEP,75 -US-Wkg,24660,GRP_NEP,NEP_COMMENT,"(range 0.05-0.1) Russ Scott: -From Nouvellon, Remote Sensing Env., 78, 1313-149, 2001" -US-Wkg,11802,GRP_NETWORK,NETWORK,AmeriFlux -US-Wkg,87031,GRP_NETWORK,NETWORK,Phenocam -US-Wkg,1700000966,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Biederman, J. A., Scott, R. L., Bell, T. W., Bowling, D. R., Dore, S., Garatuza-Payan, J., Kolb, T. E., Krishnan, P., Krofcheck, D. J., Litvak, M. E., Maurer, G. E., Meyers, T. P., Oechel, W. C., Papuga, S. A., Ponce-Campos, G. E., Rodriguez, J. C., Smith, W. K., Vargas, R., Watts, C. J., Yepez, E. A., Goulden, M. L. (2017) Co2 Exchange And Evapotranspiration Across Dryland Ecosystems Of Southwestern North America, Global Change Biology, 23(10), 4204-4221" -US-Wkg,1700000966,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/GCB.13686 -US-Wkg,1700000966,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Wkg,1700005589,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Biederman, J. A., Scott, R. L., Goulden, M. L., Vargas, R., Litvak, M. E., Kolb, T. E., Yepez, E. A., Oechel, W. C., Blanken, P. D., Bell, T. W., Garatuza-Payan, J., Maurer, G. E., Dore, S., Burns, S. P. (2016) Terrestrial Carbon Balance In A Drier World: The Effects Of Water Availability In Southwestern North America, Global Change Biology, 22(5), 1867-1879" -US-Wkg,1700005589,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/GCB.13222 -US-Wkg,1700005589,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Wkg,1700004677,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Blonquist, J. M., Montzka, S. A., Munger, J. W., Yakir, D., Desai, A. R., Dragoni, D., Griffis, T. J., Monson, R. K., Scott, R. L., Bowling, D. R. (2011) The Potential Of Carbonyl Sulfide As A Proxy For Gross Primary Production At Flux Tower Sites, Journal Of Geophysical Research: Biogeosciences, 116(G4), n/a-n/a" -US-Wkg,1700004677,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2011JG001723 -US-Wkg,1700004677,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Wkg,1700005841,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(6), 108350" -US-Wkg,1700005841,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -US-Wkg,1700005841,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Wkg,1700008085,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Dennis Baldocchi, Cove Sturtevant (2015) Does day and night sampling reduce spurious correlation between canopy photosynthesis and ecosystem respiration?, Agricultural and Forest Meteorology, 207(G4), 117-126" -US-Wkg,1700008085,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2015.03.010 -US-Wkg,1700008085,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Wkg,1700007302,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Emmerich, W. E. (2003) Carbon Dioxide Fluxes In A Semiarid Environment With High Carbonate Soils, Agricultural And Forest Meteorology, 116(1-2), 91-102" -US-Wkg,1700007302,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/S0168-1923(02)00231-9 -US-Wkg,1700007302,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Wkg,1700003090,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Emmerich, W. E. (2007) Ecosystem Water Use Efficiency In A Semiarid Shrubland And Grassland Community, Rangeland Ecology & Management, 60(5), 464-470" -US-Wkg,1700003090,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.2111/1551-5028(2007)60[464:EWUEIA]2.0.CO;2 -US-Wkg,1700003090,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Wkg,1700000504,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Krishnan, P., Meyers, T. P., Scott, R. L., Kennedy, L., Heuer, M. (2012) Energy Exchange And Evapotranspiration Over Two Temperate Semi-Arid Grasslands In North America, Agricultural And Forest Meteorology, 153(2), 31-44" -US-Wkg,1700000504,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2011.09.017 -US-Wkg,1700000504,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Wkg,1700004683,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Li, F., Kustas, W. P., Anderson, M. C., Prueger, J. H., Scott, R. L. (2008) Effect Of Remote Sensing Spatial Resolution On Interpreting Tower-Based Flux Observations, Remote Sensing Of Environment, 112(2), 337-349" -US-Wkg,1700004683,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.RSE.2006.11.032 -US-Wkg,1700004683,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Wkg,1700007797,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Moran, M. S., Scott, R. L., Hamerlynck, E. P., Green, K. N., Emmerich, W. E., Holifield Collins, C. D. (2009) Soil Evaporation Response To Lehmann Lovegrass (Eragrostis Lehmanniana) Invasion In A Semiarid Watershed, Agricultural And Forest Meteorology, 149(12), 2133-2142" -US-Wkg,1700007797,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2009.03.018 -US-Wkg,1700007797,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Wkg,1700000051,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Moran, M., Scott, R., Keefer, T., Emmerich, W., Hernandez, M., Nearing, G., Paige, G., Cosh, M., O’Neill, P. (2009) Partitioning Evapotranspiration In Semiarid Grassland And Shrubland Ecosystems Using Time Series Of Soil Surface Temperature, Agricultural And Forest Meteorology, 149(1), 59-72" -US-Wkg,1700000051,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2008.07.004 -US-Wkg,1700000051,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Wkg,1700000996,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Novick, K. A., Ficklin, D. L., Stoy, P. C., Williams, C. A., Bohrer, G., Oishi, A., Papuga, S. A., Blanken, P. D., Noormets, A., Sulman, B. N., Scott, R. L., Wang, L., Phillips, R. P. (2016) The Increasing Importance Of Atmospheric Demand For Ecosystem Water And Carbon Fluxes, Nature Climate Change, 6(11), 1023-1027" -US-Wkg,1700000996,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1038/NCLIMATE3114 -US-Wkg,1700000996,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Wkg,1700007893,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Novick, K. A., Konings, A. G., Gentine, P. (2019) Beyond Soil Water Potential: An Expanded View On Isohydricity Including Land–Atmosphere Interactions And Phenology, Plant, Cell & Environment, 42(6), 1802-1815" -US-Wkg,1700007893,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/PCE.13517 -US-Wkg,1700007893,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Wkg,1700006498,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"P. Hamerlynck, E., L. Scott, R., Barron-Gafford, G. A. (2013) Consequences Of Cool-Season Drought-Induced Plant Mortality To Chihuahuan Desert Grassland Ecosystem And Soil Respiration Dynamics, Ecosystems, 16(7), 1178-1191" -US-Wkg,1700006498,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1007/S10021-013-9675-Y -US-Wkg,1700006498,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Wkg,1700005724,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Polyakov, V.O., Nearing, M.A., Stone, J.J., Hamerlynck, E.P., Nichols, M.H., Holifield Collins, C.D., Scott, R.L. (2010) Runoff And Erosional Responses To A Drought-Induced Shift In A Desert Grassland Community Composition, Journal Of Geophysical Research: Biogeosciences, 115(G4), n/a-n/a" -US-Wkg,1700005724,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2010JG001386 -US-Wkg,1700005724,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Wkg,1700006828,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Scott, R. L. (2010) Using Watershed Water Balance To Evaluate The Accuracy Of Eddy Covariance Evaporation Measurements For Three Semiarid Ecosystems, Agricultural And Forest Meteorology, 150(2), 219-225" -US-Wkg,1700006828,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2009.11.002 -US-Wkg,1700006828,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Wkg,1700001047,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Scott, R. L., Biederman, J. A., Hamerlynck, E. P., Barron-Gafford, G. A. (2015) The Carbon Balance Pivot Point Of Southwestern U.S. Semiarid Ecosystems: Insights From The 21st Century Drought, Journal Of Geophysical Research: Biogeosciences, 120(12), 2612-2624" -US-Wkg,1700001047,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/2015JG003181 -US-Wkg,1700001047,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Wkg,1700005382,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Scott, R.L., Biederman, J.A., Hamerlynck, E.P., Barron-Gafford, G. (2015) The carbon balance pivot point of southwestern U.S. semiarid ecosystems: Insights from the 21st century drought, Journal of Geophysical Research: Biogeosciences, 120(21), 2612-2624" -US-Wkg,1700005382,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/2015JG003181 -US-Wkg,1700005382,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Wkg,1700002412,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Scott, R.L., Hamerlynck, E.P., Jenerette, G.D., Moran, M.S., Barron-Gafford, G. (2010) Carbon Dioxide Exchange In A Semidesert Grassland Through Drought-Induced Vegetation Change, Journal Of Geophysical Research: Biogeosciences, 115(G3), n/a-n/a" -US-Wkg,1700002412,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2010JG001348 -US-Wkg,1700002412,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Primary_Citation -US-Wkg,1700001062,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Smith, W. K., Biederman, J. A., Scott, R. L., Moore, D. J., He, M., Kimball, J. S., Yan, D., Hudson, A., Barnes, M. L., MacBean, N., Fox, A. M., Litvak, M. E. (2018) Chlorophyll Fluorescence Better Captures Seasonal And Interannual Gross Primary Productivity Dynamics Across Dryland Ecosystems Of Southwestern North America, Geophysical Research Letters, 45(2), 748-757" -US-Wkg,1700001062,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/2017GL075922 -US-Wkg,1700001062,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Wkg,1700004356,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Sullivan, R. C., Cook, D. R., Ghate, V. P., Kotamarthi, V. R., Feng, Y. (2019) Improved Spatiotemporal Representativeness And Bias Reduction Of Satellite-Based Evapotranspiration Retrievals Via Use Of In Situ Meteorology And Constrained Canopy Surface Resistance, Journal Of Geophysical Research: Biogeosciences, 124(2), 342-352" -US-Wkg,1700004356,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018JG004744 -US-Wkg,1700004356,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Wkg,1700003867,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Sullivan, R. C., Kotamarthi, V. R., Feng, Y. (2019) Recovering Evapotranspiration Trends From Biased CMIP5 Simulations And Sensitivity To Changing Climate Over North America, Journal Of Hydrometeorology, 20(8), 1619-1633" -US-Wkg,1700003867,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1175/JHM-D-18-0259.1 -US-Wkg,1700003867,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Wkg,1700006450,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Watts, C. J., Scott, R. L., Garatuza-Payan, J., Rodriguez, J. C., Prueger, J. H., Kustas, W. P., Douglas, M. (2007) Changes In Vegetation Condition And Surface Fluxes During NAME 2004, Journal Of Climate, 20(9), 1810-1820" -US-Wkg,1700006450,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1175/JCLI4088.1 -US-Wkg,1700006450,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Wkg,1700002208,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Wolf, S., Keenan, T.F., Fisher, J.B., Baldocchi, D.D., Desai, A.R., Richardson, A.D., Scott, R.L., Law, B.E., Litvak, M.E., Brunsell, N.A., Peters, W., van der Laan-Luijkx, I.T. (2016) Warm spring reduced carbon cycle impact of the 2012 US summer drought, Proceedings of the National Academy of Sciences, 113(21), 5880-5885" -US-Wkg,1700002208,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1073/PNAS.1519620113 -US-Wkg,1700002208,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Wkg,1700000852,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Zhang, Q., Phillips, R. P., Manzoni, S., Scott, R. L., Oishi, A. C., Finzi, A., Daly, E., Vargas, R., Novick, K. A. (2018) Changes In Photosynthesis And Soil Moisture Drive The Seasonal Soil Respiration-Temperature Hysteresis Relationship, Agricultural And Forest Meteorology, 259(21), 184-195" -US-Wkg,1700000852,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2018.05.005 -US-Wkg,1700000852,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Wkg,1700004596,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Zhang, Q., Phillips, R. P., Manzoni, S., Scott, R. L., Oishi, A. C., Finzi, A., Daly, E., Vargas, R., Novick, K. A. (2018) Changes In Photosynthesis And Soil Moisture Drive The Seasonal Soil Respiration-Temperature Hysteresis Relationship, Agricultural And Forest Meteorology, 259(G4), 184-195" -US-Wkg,1700004596,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2018.05.005 -US-Wkg,1700004596,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Wkg,11804,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,Long-term energy and CO2 exchange study for semiarid warm season desert grassland. -US-Wkg,11805,GRP_SITE_DESC,SITE_DESC,"This site is located in a small, intensively-studied, experimental watershed within USDA-ARS's Walnut Gulch Experimental Watershed. Eddy covariance measurements of energy, water and CO2 fluxes began in the spring of 2004, though meteorological (including Bowen ratio) and hydrological measurements are available much further back." -US-Wkg,11806,GRP_SITE_FUNDING,SITE_FUNDING,"USDA-ARS, DOE" -US-Wkg,23933,GRP_SOIL_CHEM,SOIL_CHEM_C_ORG,0 -US-Wkg,24942,GRP_SOIL_CHEM,SOIL_CHEM_C_ORG,10 -US-Wkg,24174,GRP_SOIL_CHEM,SOIL_CHEM_C_ORG,7.5 -US-Wkg,24942,GRP_SOIL_CHEM,SOIL_CHEM_PH_SALT,7.4 -US-Wkg,24174,GRP_SOIL_CHEM,SOIL_CHEM_PH_SALT,7.6 -US-Wkg,23933,GRP_SOIL_CHEM,SOIL_CHEM_BD,0 -US-Wkg,24942,GRP_SOIL_CHEM,SOIL_CHEM_BD,1.35 -US-Wkg,24174,GRP_SOIL_CHEM,SOIL_CHEM_BD,1.4 -US-Wkg,23933,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,0 -US-Wkg,24174,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,0 -US-Wkg,24942,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,0 -US-Wkg,23933,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,0 -US-Wkg,24174,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,147 -US-Wkg,24942,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,5 -US-Wkg,24942,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,A -US-Wkg,24174,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,B -US-Wkg,23933,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,Organic -US-Wkg,29420,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION,"Course-loamy, mixed, thermic, Ustollic Haplargids with limestone fragments" -US-Wkg,29420,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION_TAXONOMY,Other -US-Wkg,23909,GRP_SOIL_DEPTH,SOIL_DEPTH,150 -US-Wkg,23920,GRP_SOIL_DEPTH,SOIL_DEPTH,147 -US-Wkg,24164,GRP_SOIL_DEPTH,SOIL_DEPTH,5 -US-Wkg,25081,GRP_SOIL_DEPTH,SOIL_DEPTH,0 -US-Wkg,23654,GRP_SOIL_TEX,SOIL_TEX_SAND,67 -US-Wkg,24295,GRP_SOIL_TEX,SOIL_TEX_SAND,70 -US-Wkg,23654,GRP_SOIL_TEX,SOIL_TEX_SILT,16 -US-Wkg,24295,GRP_SOIL_TEX,SOIL_TEX_SILT,20 -US-Wkg,24295,GRP_SOIL_TEX,SOIL_TEX_CLAY,10 -US-Wkg,23654,GRP_SOIL_TEX,SOIL_TEX_CLAY,17 -US-Wkg,23654,GRP_SOIL_TEX,SOIL_TEX_PROFILE_MIN,0 -US-Wkg,24295,GRP_SOIL_TEX,SOIL_TEX_PROFILE_MIN,0 -US-Wkg,24295,GRP_SOIL_TEX,SOIL_TEX_PROFILE_MAX,147 -US-Wkg,23654,GRP_SOIL_TEX,SOIL_TEX_PROFILE_MAX,5 -US-Wkg,23654,GRP_SOIL_TEX,SOIL_TEX_HORIZON,A -US-Wkg,24295,GRP_SOIL_TEX,SOIL_TEX_HORIZON,B -US-Wkg,23795,GRP_SPP_O,SPP_O,"Bouteloua spp., Eragrostis lehmanniana" -US-Wkg,11807,GRP_STATE,STATE,AZ -US-Wkg,11808,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Russell Scott -US-Wkg,11808,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Wkg,11808,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,russ.scott@ars.usda.gov -US-Wkg,11808,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,United States Department of Agriculture -US-Wkg,11808,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"USDA-ARS Southwest Watershed Research Center, 2000 East Allen Rd.,Tucson, AZ USA 85719" -US-Wkg,81553,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Ross Bryant -US-Wkg,81553,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,Technician -US-Wkg,81553,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,ross.bryant@ars.usda.gov -US-Wkg,81553,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,USDA-ARS-SWRC -US-Wkg,81553,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"2000 East Allen Rd -Tucson AZ 85719" -US-Wkg,29844,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-Wkg,29710,GRP_TOWER_TYPE,TOWER_TYPE,triangle -US-Wkg,11809,GRP_URL,URL,http://ars.usda.gov/PandP/docs.htm?docid=10978&page=1 -US-Wkg,24000445,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-Wkg -US-Wkg,11810,GRP_UTC_OFFSET,UTC_OFFSET,-7 -US-Wlr,12463,GRP_CLIM_AVG,MAT,13.52 -US-Wlr,12463,GRP_CLIM_AVG,MAP,881 -US-Wlr,12463,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Cfa -US-Wlr,27000448,GRP_COUNTRY,COUNTRY,USA -US-Wlr,15770,GRP_DOI,DOI,10.17190/AMF/1246115 -US-Wlr,15770,GRP_DOI,DOI_CITATION,"David Cook, Richard L. Coulter (2018), AmeriFlux BASE US-Wlr Walnut River Watershed (Smileyburg), Ver. 4-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1246115" -US-Wlr,15770,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-Wlr,32239,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Wlr,32239,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,David Cook -US-Wlr,32239,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Wlr,32239,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,drcook@anl.gov -US-Wlr,32239,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Argonne National Laboratory -US-Wlr,32240,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Wlr,32240,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Richard L. Coulter -US-Wlr,32240,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Wlr,32240,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,rlcoulter@anl.gov -US-Wlr,32240,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Argonne National Laboratory -US-Wlr,32242,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Argonne National Laboratory -US-Wlr,32242,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-Wlr,32241,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,DOE/TCP -US-Wlr,32241,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-Wlr,12464,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Wlr,12464,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-Wlr,12464,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,2001 -US-Wlr,12464,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,2004 -US-Wlr,12464,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Wlr,23000448,GRP_HEADER,SITE_NAME,Walnut River Watershed (Smileyburg) -US-Wlr,12465,GRP_IGBP,IGBP,GRA -US-Wlr,12466,GRP_LOCATION,LOCATION_LAT,37.5208 -US-Wlr,12466,GRP_LOCATION,LOCATION_LONG,-96.8550 -US-Wlr,12466,GRP_LOCATION,LOCATION_ELEV,408 -US-Wlr,12467,GRP_NETWORK,NETWORK,AmeriFlux -US-Wlr,1700000660,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chen, F., Yates, D. N., Nagai, H., LeMone, M. A., Ikeda, K., Grossman, R. L. (2003) Land Surface Heterogeneity In The Cooperative Atmosphere Surface Exchange Study (CASE-97). Part I: Comparing Modeled Surface Flux Maps With Surface-Flux Tower And Aircraft Measurements, Journal Of Hydrometeorology, 4(2), 196-218" -US-Wlr,1700000660,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1175/1525-7541(2003)4<196:LSHITC>2.0.CO;2 -US-Wlr,1700000660,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Wlr,1700004809,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(D6), 108350" -US-Wlr,1700004809,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -US-Wlr,1700004809,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Wlr,1700004287,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Coulter, R., Pekour, M., Cook, D., Klazura, G., Martin, T., Lucas, J. (2006) Surface Energy And Carbon Dioxide Fluxes Above Different Vegetation Types Within ABLE, Agricultural And Forest Meteorology, 136(3-4), 147-158" -US-Wlr,1700004287,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2004.11.011 -US-Wlr,1700004287,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Wlr,1700004776,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Gao, W., Coulter, R. L., Lesht, B. M., Qiu, J., Wesely, M. L. (1998) Estimating Clear-Sky Regional Surface Fluxes In The Southern Great Plains Atmospheric Radiation Measurement Site With Ground Measurements And Satellite Observations, Journal Of Applied Meteorology, 37(1), 5-22" -US-Wlr,1700004776,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1175/1520-0450(1998)037<0005:ECSRSF>2.0.CO;2 -US-Wlr,1700004776,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Wlr,1700003825,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Grossman, R. L., Yates, D., LeMone, M. A., Wesely, M. L., Song, J. (2005) Observed Effects Of Horizontal Radiative Surface Temperature Variations On The Atmosphere Over A Midwest Watershed During CASES 97, Journal Of Geophysical Research: Atmospheres, 110(D6), n/a-n/a" -US-Wlr,1700003825,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2004JD004542 -US-Wlr,1700003825,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Wlr,1700004149,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Jacobs, J. M., Coulter, R. L., Brutsaert, W. (2000) Surface Heat Flux Estimation With Wind-Profiler/RASS And Radiosonde Observations, Advances In Water Resources, 23(4), 339-348" -US-Wlr,1700004149,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/S0309-1708(99)00028-7 -US-Wlr,1700004149,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Wlr,1700005769,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"LeMone, M. A., Grossman, R. L., Coulter, R. L., Wesley, M. L., Klazura, G. E., Poulos, G. S., Blumen, W., Lundquist, J. K., Cuenca, R. H., Kelly, S. F., Brandes, E. A., Oncley, S. P., McMillen, R. T., Hicks, B. B. (2000) Land–Atmosphere Interaction Research, Early Results, And Opportunities In The Walnut River Watershed In Southeast Kansas: CASES And ABLE, Bulletin Of The American Meteorological Society, 81(4), 757-779" -US-Wlr,1700005769,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1175/1520-0477(2000)081<0757:LIRERA>2.3.CO;2 -US-Wlr,1700005769,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Wlr,1700001986,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Song, J., Liao, K., Coulter, R. L., Lesht, B. M. (2005) Climatology Of The Low-Level Jet At The Southern Great Plains Atmospheric Boundary Layer Experiments Site, Journal Of Applied Meteorology, 44(10), 1593-1606" -US-Wlr,1700001986,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1175/JAM2294.1 -US-Wlr,1700001986,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Wlr,1700009024,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Song, J., Wesely, M. (2003) On Comparison Of Modeled Surface Flux Variations To Aircraft Observations, Agricultural And Forest Meteorology, 117(3-4), 159-171" -US-Wlr,1700009024,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/S0168-1923(03)00042-X -US-Wlr,1700009024,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Wlr,1700004062,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Song, J., Wesely, M. L., Coulter, R. L., Brandes, E. A. (2000) Estimating Watershed Evapotranspiration With Pass. Part I: Inferring Root-Zone Moisture Conditions Using Satellite Data, Journal Of Hydrometeorology, 1(5), 447-461" -US-Wlr,1700004062,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1175/1525-7541(2000)001<0447:EWEWPP>2.0.CO;2 -US-Wlr,1700004062,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Wlr,12469,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,Measurements of the planetary boundary layer -US-Wlr,12470,GRP_SITE_DESC,SITE_DESC,"The Walnut River Watershed site rests on a C3/C4 mixed grassland, tallgrass prairie grazed by cattle. The land is owned by a local farmer and the land is leased on a year-to-year basis." -US-Wlr,12471,GRP_SITE_FUNDING,SITE_FUNDING,DOE/TCP -US-Wlr,12472,GRP_STATE,STATE,KS -US-Wlr,92229,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,David Cook -US-Wlr,92229,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Wlr,92229,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,dsgcook@prodigy.net -US-Wlr,92229,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Argonne National Laboratory -US-Wlr,92229,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Atmospheric and Climate Research Program, Building 203, 9700 South Cass Avenue,Argonne, IL USA 60439" -US-Wlr,12473,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Richard L. Coulter -US-Wlr,12473,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Wlr,12473,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,rlcoulter@anl.gov -US-Wlr,12473,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Argonne National Laboratory -US-Wlr,12473,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"Environmental Science Division, Climate Research Section, Building 203, 9700 South Cass Avenue,Argonne, IL USA 60439" -US-Wlr,12474,GRP_URL,URL,http://gonzalo.er.anl.gov/ABLE/index.html -US-Wlr,24000448,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-Wlr -US-Wlr,33660,GRP_UTC_OFFSET,UTC_OFFSET,-6 -US-Wlr,33660,GRP_UTC_OFFSET,UTC_OFFSET_COMMENT,Added by AMF data processing team for data QAQC checks. -US-WPT,12738,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,Supported by NOAA (NA10OAR4170224) & NSF (NSF1034791) -US-WPT,12738,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT_COMMENT,Acknowledgement John Simpson and Winous Point Marsh Conservancy for fully support -US-WPT,12739,GRP_CLIM_AVG,MAT,10.1 -US-WPT,12739,GRP_CLIM_AVG,MAP,849 -US-WPT,12739,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfa -US-WPT,27000536,GRP_COUNTRY,COUNTRY,USA -US-WPT,15672,GRP_DOI,DOI,10.17190/AMF/1246155 -US-WPT,15672,GRP_DOI,DOI_CITATION,"Jiquan Chen, Housen Chu (2019), AmeriFlux BASE US-WPT Winous Point North Marsh, Ver. 4-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1246155" -US-WPT,15672,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-WPT,88155,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-WPT,88155,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Jiquan Chen -US-WPT,88155,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-WPT,88155,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,1 -US-WPT,88155,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,jqchen@msu.edu -US-WPT,88155,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,University of Toledo / Michigan State University -US-WPT,88152,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-WPT,88152,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Housen Chu -US-WPT,88152,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-WPT,88152,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORDINAL,2 -US-WPT,88152,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ORCID,0000-0002-8131-4938 -US-WPT,32406,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,University of Toledo / Michigan State University -US-WPT,32406,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-WPT,32405,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,NOAA & NSF -US-WPT,32405,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-WPT,12740,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Hydrologic event -US-WPT,12760,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Storm or wind -US-WPT,12755,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Temperature extreme -US-WPT,12741,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-WPT,12741,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-WPT,12741,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20110101 -US-WPT,12741,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20131231 -US-WPT,12741,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-WPT,12761,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-WPT,12761,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H -US-WPT,12761,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20110101 -US-WPT,12761,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20131231 -US-WPT,12761,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-WPT,12756,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-WPT,12756,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-WPT,12756,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20110101 -US-WPT,12756,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20131231 -US-WPT,12756,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-WPT,12762,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-WPT,12762,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CH4 -US-WPT,12762,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20110311 -US-WPT,12762,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,20131231 -US-WPT,12762,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-WPT,23000536,GRP_HEADER,SITE_NAME,Winous Point North Marsh -US-WPT,88236,GRP_HEIGHTC,HEIGHTC,1.7 -US-WPT,88236,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-WPT,88236,GRP_HEIGHTC,HEIGHTC_DATE,20110801 -US-WPT,88236,GRP_HEIGHTC,HEIGHTC_DATE_UNC,30 -US-WPT,88236,GRP_HEIGHTC,HEIGHTC_COMMENT,"canopy height above sediment surface, the site is innudated with water level varying from 0.3 to 0.7 m above sediment" -US-WPT,88235,GRP_HEIGHTC,HEIGHTC,1.47 -US-WPT,88235,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-WPT,88235,GRP_HEIGHTC,HEIGHTC_DATE,20120801 -US-WPT,88235,GRP_HEIGHTC,HEIGHTC_DATE_UNC,30 -US-WPT,88235,GRP_HEIGHTC,HEIGHTC_COMMENT,"canopy height above sediment surface, the site is innudated with water level varying from 0.3 to 0.7 m above sediment" -US-WPT,88234,GRP_HEIGHTC,HEIGHTC,1.27 -US-WPT,88234,GRP_HEIGHTC,HEIGHTC_STATISTIC,Mean -US-WPT,88234,GRP_HEIGHTC,HEIGHTC_DATE,20130801 -US-WPT,88234,GRP_HEIGHTC,HEIGHTC_DATE_UNC,30 -US-WPT,88234,GRP_HEIGHTC,HEIGHTC_COMMENT,"canopy height above sediment surface, the site is innudated with water level varying from 0.3 to 0.7 m above sediment" -US-WPT,12742,GRP_IGBP,IGBP,WET -US-WPT,12743,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -US-WPT,12743,GRP_LAND_OWNERSHIP,LAND_OWNER,Winous Point Marsh Conservancy -US-WPT,12744,GRP_LOCATION,LOCATION_LAT,41.4646 -US-WPT,12744,GRP_LOCATION,LOCATION_LONG,-82.9962 -US-WPT,12744,GRP_LOCATION,LOCATION_ELEV,175 -US-WPT,12744,GRP_LOCATION,LOCATION_DATE_START,20100920 -US-WPT,12744,GRP_LOCATION,LOCATION_COMMENT,"The tower was constructed in August and continuous measurement began in September, 2010." -US-WPT,12745,GRP_NETWORK,NETWORK,AmeriFlux -US-WPT,1700000354,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Chen, J., Gottgens, J. F., Desai, A. R., Ouyang, Z., Qian, S. S. (2016) Response And Biophysical Regulation Of Carbon Dioxide Fluxes To Climate Variability And Anomaly In Contrasting Ecosystems In Northwestern Ohio, Usa, Agricultural And Forest Meteorology, 220(2), 50-68" -US-WPT,1700000354,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2016.01.008 -US-WPT,1700000354,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-WPT,1700007875,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Chen, J., Gottgens, J. F., Desai, A. R., Ouyang, Z., Qian, S. S. (2016) Response And Biophysical Regulation Of Carbon Dioxide Fluxes To Climate Variability And Anomaly In Contrasting Ecosystems In Northwestern Ohio, Usa, Agricultural And Forest Meteorology, 220(3), 50-68" -US-WPT,1700007875,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2016.01.008 -US-WPT,1700007875,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-WPT,1700001713,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Chen, J., Gottgens, J. F., Ouyang, Z., John, R., Czajkowski, K., Becker, R. (2014) Net Ecosystem Methane And Carbon Dioxide Exchanges In A Lake Erie Coastal Marsh And A Nearby Cropland, Journal Of Geophysical Research: Biogeosciences, 119(5), 722-740" -US-WPT,1700001713,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/2013JG002520 -US-WPT,1700001713,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-WPT,1700005238,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Gottgens, J. F., Chen, J., Sun, G., Desai, A. R., Ouyang, Z., Shao, C., Czajkowski, K. (2015) Climatic Variability, Hydrologic Anomaly, And Methane Emission Can Turn Productive Freshwater Marshes Into Net Carbon Sources, Global Change Biology, 21(3), 1165-1181" -US-WPT,1700005238,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/GCB.12760 -US-WPT,1700005238,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Primary_Citation -US-WPT,1700006723,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(2), 108350" -US-WPT,1700006723,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -US-WPT,1700006723,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-WPT,1700007053,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Qiu, C., Zhu, D., Ciais, P., Guenet, B., Krinner, G., Peng, S., Aurela, M., Bernhofer, C., Brümmer, C., Bret-Harte, S., Chu, H., Chen, J., Desai, A. R., Dušek, J., Euskirchen, E. S., Fortuniak, K., Flanagan, L. B., Friborg, T., Grygoruk, M., Gogo, S., Grünwald, T., Hansen, B. U., Holl, D., Humphreys, E., Hurkuck, M., Kiely, G., Klatt, J., Kutzbach, L., Largeron, C., Laggoun-Défarge, F., Lund, M., Lafleur, P. M., Li, X., Mammarella, I., Merbold, L., Nilsson, M. B., Olejnik, J., Ottosson-Löfvenius, M., Oechel, W., Parmentier, F. W., Peichl, M., Pirk, N., Peltola, O., Pawlak, W., Rasse, D., Rinne, J., Shaver, G., Schmid, H. P., Sottocornola, M., Steinbrecher, R., Sachs, T., Urbaniak, M., Zona, D., Ziemblinska, K. (2018) Orchidee-Peat (Revision 4596), A Model For Northern Peatland Co&Lt;Sub&Gt;2&Lt;/Sub&Gt;, Water, And Energy Fluxes On Daily To Annual Scales, Geoscientific Model Development, 11(2), 497-519" -US-WPT,1700007053,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.5194/GMD-11-497-2018 -US-WPT,1700007053,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-WPT,12758,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"202 Manly Miles Bldg. 1405 South Harrison Road Michigan State University, East Lansing, MI 48823" -US-WPT,12747,GRP_SITE_CHAR,TERRAIN,Flat -US-WPT,12747,GRP_SITE_CHAR,ASPECT,FLAT -US-WPT,12747,GRP_SITE_CHAR,WIND_DIRECTION,WNW -US-WPT,12747,GRP_SITE_CHAR,SURFACE_HOMOGENEITY,250 -US-WPT,12747,GRP_SITE_CHAR,SITE_SNOW_COVER_DAYS,60 -US-WPT,12748,GRP_SITE_DESC,SITE_DESC,"The marsh site has been owned by the Winous Point Shooting Club since 1856 and has been managed by wildlife biologists since 1946. The hydrology of the marsh is relatively isolated by the surrounding dikes and drainages and only receives drainage from nearby croplands through three connecting ditches. Since 2001, the marsh has been managed to maintain year-round inundation with the lowest water levels in September. Within the 0–250 m fetch of the tower, the marsh comprises 42.9% of floating-leaved vegetation, 52.7% of emergent vegetation, and 4.4% of dike and upland during the growing season. Dominant emergent plants include narrow-leaved cattail (Typha angustifolia), rose mallow (Hibiscus moscheutos), and bur reed (Sparganium americanum). Common floating-leaved species are water lily (Nymphaea odorata) and American lotus (Nelumbo lutea) with foliage usually covering the water surface from late May to early October." -US-WPT,12749,GRP_SITE_FUNDING,SITE_FUNDING,NOAA & NSF -US-WPT,12750,GRP_STATE,STATE,OH -US-WPT,12759,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Jiquan Chen -US-WPT,12759,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-WPT,12759,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,jqchen@msu.edu -US-WPT,12759,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,University of Toledo / Michigan State University -US-WPT,12759,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"202 Manly Miles Bldg. 1405 South Harrison Road Michigan State University, East Lansing, MI 48823" -US-WPT,95539,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Housen Chu -US-WPT,95539,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-WPT,95539,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,chu.housen@gmail.com -US-WPT,95539,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Lawrence Berkeley National Lab -US-WPT,29870,GRP_TOWER_POWER,TOWER_POWER,Direct power -US-WPT,12752,GRP_TOWER_TYPE,TOWER_TYPE,triangle -US-WPT,12753,GRP_URL,URL,http://lees.geo.msu.edu/index.html -US-WPT,24000536,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-WPT -US-WPT,12754,GRP_UTC_OFFSET,UTC_OFFSET,-5 -US-Wrc,24535,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER,39.8 -US-Wrc,24535,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_ORGAN,Total -US-Wrc,24535,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_PHEN,Mixed/unknown -US-Wrc,24535,GRP_AG_BIOMASS_OTHER,AG_BIOMASS_OTHER_UNIT,kgDM m-2 -US-Wrc,29065,GRP_BIOMASS_CHEM,BIOMASS_N,0.122 -US-Wrc,29065,GRP_BIOMASS_CHEM,BIOMASS_ORGAN,Total -US-Wrc,29065,GRP_BIOMASS_CHEM,BIOMASS_PHEN,Mixed/unknown -US-Wrc,29065,GRP_BIOMASS_CHEM,BIOMASS_SPP,(All) -US-Wrc,30456,GRP_CLIM_AVG,MAT,8.8 -US-Wrc,30456,GRP_CLIM_AVG,MAP,2452 -US-Wrc,30456,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Csb -US-Wrc,27000447,GRP_COUNTRY,COUNTRY,USA -US-Wrc,15742,GRP_DOI,DOI,10.17190/AMF/1246114 -US-Wrc,15742,GRP_DOI,DOI_CITATION,"Sonia Wharton (2016), AmeriFlux BASE US-Wrc Wind River Crane Site, Ver. 8-1, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1246114" -US-Wrc,15742,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-Wrc,32236,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-Wrc,32236,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,Sonia Wharton -US-Wrc,32236,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-Wrc,32236,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,wharton4@llnl.gov -US-Wrc,32236,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,Lawrence Livermore National Laboratory -US-Wrc,32238,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,Lawrence Livermore National Laboratory -US-Wrc,32238,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-Wrc,32237,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,"USFS, Univ. of Washington" -US-Wrc,32237,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-Wrc,29998,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-Wrc,29998,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-Wrc,29998,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,1998 -US-Wrc,29998,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_END,2016 -US-Wrc,29998,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-Wrc,23000447,GRP_HEADER,SITE_NAME,Wind River Crane Site -US-Wrc,24914,GRP_HEIGHTC,HEIGHTC,60 -US-Wrc,12446,GRP_IGBP,IGBP,ENF -US-Wrc,26773,GRP_LAI,LAI_TYPE,LAI -US-Wrc,26773,GRP_LAI,LAI_COMMENT,(range 8.2-9.2) Parker et al. 2004 -US-Wrc,26773,GRP_LAI,LAI_TOT,8.7 -US-Wrc,26773,GRP_LAI,LAI_U,1.7 -US-Wrc,12447,GRP_LOCATION,LOCATION_LAT,45.8205 -US-Wrc,12447,GRP_LOCATION,LOCATION_LONG,-121.9519 -US-Wrc,12447,GRP_LOCATION,LOCATION_ELEV,371 -US-Wrc,23768,GRP_NEP,NEP,600 -US-Wrc,12448,GRP_NETWORK,NETWORK,AmeriFlux -US-Wrc,87033,GRP_NETWORK,NETWORK,Phenocam -US-Wrc,1700000654,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Baldocchi, D. D., Poindexter, C., Abraha, M., Desai, A. R., Bohrer, G., Arain, M. A., Griffis, T., Blanken, P. D., O'Halloran, T. L., Thomas, R. Q., Zhang, Q., Burns, S. P., Frank, J. M., Christian, D., Brown, S., Black, T. A., Gough, C. M., Law, B. E., Lee, X., Chen, J., Reed, D. E., Massman, W. J., Clark, K., Hatfield, J., Prueger, J., Bracho, R., Baker, J. M., Martin, T. A. (2018) Temporal Dynamics Of Aerodynamic Canopy Height Derived From Eddy Covariance Momentum Flux Data Across North American Flux Networks, Geophysical Research Letters, 45(5), 9275–9287" -US-Wrc,1700000654,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018GL079306 -US-Wrc,1700000654,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Wrc,1700001686,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(1), 108350" -US-Wrc,1700001686,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -US-Wrc,1700001686,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Wrc,1700008628,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Dennis Baldocchi, Cove Sturtevant (2015) Does day and night sampling reduce spurious correlation between canopy photosynthesis and ecosystem respiration?, Agricultural and Forest Meteorology, 207(5), 117-126" -US-Wrc,1700008628,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2015.03.010 -US-Wrc,1700008628,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Wrc,1700000621,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Falk, M., Paw U, K.T., Wharton, S., Schroeder, M. (2005) Is soil respiration a major contributor to the carbon budget within a Pacific Northwest old-growth forest?, Agricultural and Forest Meteorology, 135(5), 269-283" -US-Wrc,1700000621,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Wrc,1700003369,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Falk, M., Wharton, S., Schroeder, M., Ustin, S., U, K. T. (2008) Flux Partitioning In An Old-Growth Forest: Seasonal And Interannual Dynamics, Tree Physiology, 28(4), 509-520" -US-Wrc,1700003369,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1093/TREEPHYS/28.4.509 -US-Wrc,1700003369,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Wrc,1700005673,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Harmon, M.E., Bible, K., Ryan, M.G., Shaw, D.C., Chen, H., Klopatek, J., Li, X. (2004) Production, Respiration, And Overall Carbon Balance In An Old-Growth Pseudotsuga-Tsuga Forest Ecosystem, Ecosystems, 7(5), 498-512" -US-Wrc,1700005673,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1007/S10021-004-0140-9 -US-Wrc,1700005673,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Wrc,1700002010,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Matthias Falk (2016) Climate Indices Strongly Influence Old-Growth Forest Carbon Exchange, Environmental Research Letters, 11(4), 1-12" -US-Wrc,1700002010,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Wrc,1700001239,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Matthias Falk (2016) Climate Indices Strongly Influence Old-Growth Forest Carbon Exchange, Environmental Research Letters, 11(5), 1-12" -US-Wrc,1700001239,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Wrc,1700005646,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Paw U, K., Falk, M., Suchanek, T., Ustin, S., Chen, J., Park, Y., Winner, W., Thomas, S., Hsiao, T., Shaw, R., King, T., Pyles, R., Schroeder, M., Matista, A. (2004) Carbon Dioxide Exchange Between An Old-Growth Forest And The Atmosphere, Ecosystems, 7(5), 513-524" -US-Wrc,1700005646,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1007/S10021-004-0141-8 -US-Wrc,1700005646,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Wrc,1700006285,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Raczka, B., Biraud, S. C., Ehleringer, J. R., Lai, C., Miller, J. B., Pataki, D. E., Saleska, S. R., Torn, M. S., Vaughn, B. H., Wehr, R., Bowling, D. R. (2017) Does Vapor Pressure Deficit Drive The Seasonality Of δ13C Of The Net Land-Atmosphere Co2 Exchange Across The United States?, Journal Of Geophysical Research: Biogeosciences, 122(8), 1969-1987" -US-Wrc,1700006285,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/2017JG003795 -US-Wrc,1700006285,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Wrc,1700003993,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Rastogi, B., Berkelhammer, M., Wharton, S., Whelan, M. E., Itter, M. S., Leen, J. B., Gupta, M. X., Noone, D., Still, C. J. (2018) Large Uptake Of Atmospheric Ocs Observed At A Moist Old Growth Forest: Controls And Implications For Carbon Cycle Applications, Journal Of Geophysical Research: Biogeosciences, 123(11), 3424-3438" -US-Wrc,1700003993,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1029/2018JG004430 -US-Wrc,1700003993,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Wrc,1700002601,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Rastogi, B., Berkelhammer, M., Wharton, S., Whelan, M. E., Meinzer, F. C., Noone, D., Still, C. J. (2018) Ecosystem Fluxes Of Carbonyl Sulfide In An Old-Growth Forest: Temporal Dynamics And Responses To Diffuse Radiation And Heat Waves, Biogeosciences, 15(23), 7127-7139" -US-Wrc,1700002601,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.5194/BG-15-7127-2018 -US-Wrc,1700002601,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Wrc,1700008133,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Shaw, D., Franklin, J., Bible, K., Klopatek, J., Freeman, E., Greene, S., Parker, G. (2004) Ecological Setting Of The Wind River Old-Growth Forest, Ecosystems, 7(5), 427-439" -US-Wrc,1700008133,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1007/S10021-004-0135-6 -US-Wrc,1700008133,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Wrc,1700008061,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Still, C. J., Rastogi, B., Page, G. F., Griffith, D. M., Sibley, A., Schulze, M., Hawkins, L., Pau, S., Detto, M., Helliker, B. R. (2021) Imaging Canopy Temperature: Shedding (Thermal) Light On Ecosystem Processes, New Phytologist, 230(5), 1746-1753" -US-Wrc,1700008061,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/NPH.17321 -US-Wrc,1700008061,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Wrc,1700003567,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Still, C., Powell, R., Aubrecht, D., Kim, Y., Helliker, B., Roberts, D., Richardson, A. D., Goulden, M. (2019) Thermal Imaging In Plant And Ecosystem Ecology: Applications And Challenges, Ecosphere, 10(6), 108350" -US-Wrc,1700003567,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/ECS2.2768 -US-Wrc,1700003567,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Wrc,1700004380,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Still, C., Powell, R., Aubrecht, D., Kim, Y., Helliker, B., Roberts, D., Richardson, A. D., Goulden, M. (2019) Thermal Imaging In Plant And Ecosystem Ecology: Applications And Challenges, Ecosphere, 10(6), 99-115" -US-Wrc,1700004380,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1002/ECS2.2768 -US-Wrc,1700004380,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Wrc,1700008505,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Taylor, A.J., Lai, C.-T., Hopkins, F.M., Wharton, S., Bible, K., Xu, X., Phillips, C., Bush, S., Ehleringer, J.R. (2015) Radiocarbon-based partitioning of soil respiration in an old-growth coniferous forest, Ecosystems, 18(5), 459-470" -US-Wrc,1700008505,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Wrc,1700002094,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Toomey, M., Friedl, M. A., Frolking, S., Hufkens, K., Klosterman, S., Sonnentag, O., Baldocchi, D. D., Bernacchi, C. J., Biraud, S. C., Bohrer, G., Brzostek, E., Burns, S. P., Coursolle, C., Hollinger, D. Y., Margolis, H. A., McCaughey, H., Monson, R. K., Munger, J. W., Pallardy, S., Phillips, R. P., Torn, M. S., Wharton, S., Zeri, M., Richardson, A. D. (2015) Greenness Indices From Digital Cameras Predict The Timing And Seasonal Dynamics Of Canopy-Scale Photosynthesis, Ecological Applications, 25(1), 99-115" -US-Wrc,1700002094,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1890/14-0005.1 -US-Wrc,1700002094,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Wrc,1700002979,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Wharton, S., Chasmer, L., Falk, M., Paw U, K.T. (2009) Strong links between teleconnections and ecosystem exchange found at a Pacific Northwest old-growth forest from flux tower and MODIS EVI data, Global Change Biology, 15(5), 2187-2205" -US-Wrc,1700002979,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1111/J.1365-2486.2009.01952.X -US-Wrc,1700002979,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Wrc,1700004617,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Wharton, S., Falk, M., Bible, K., Schroeder, M., Paw U, K.T. (2012) Old-Growth CO2 Flux Measurements Reveal High Sensitivity To Climate Anomalies Across Seasonal, Annual And Decadal Time Scales, Agricultural and Forest Meteorology, 161(5), 1-14" -US-Wrc,1700004617,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2012.03.007 -US-Wrc,1700004617,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Wrc,1700000687,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Wharton, S., Ma, S., Baldocchi, D.D., Falk, M., Newman, J.F., Osuna, J.L, Bible, K. (2017) Influence of regional nighttime atmospheric regimes on canopy turbulence and gradients at a closed and open forest in mountain-valley terrain, Agricultural and Forest Meteorology, 237–238(5), 18-29" -US-Wrc,1700000687,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2017.01.020 -US-Wrc,1700000687,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Wrc,1700006675,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Wharton, S., Schroeder, M., Bible, K., Falk, M., Paw U, K.T. (2009) Stand-level gas-exchange responses to seasonal drought in very young versus old Douglas-fir forests of the Pacific Northwest, Tree Physiology, 29(5), 959-974" -US-Wrc,1700006675,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1093/TREEPHYS/TPP039 -US-Wrc,1700006675,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Wrc,1700006030,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Wharton, S., Schroeder, M., Paw U, K.T., Falk, M., Bible, K. (2009) Turbulence considerations for comparing ecosystem exchange over old-growth and clear-cut stands for limited fetch and complex canopy flow conditions, Agricultural and Forest Meteorology, 149(5), 1477-1490" -US-Wrc,1700006030,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-Wrc,12450,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,"Research and monitoring objectives are to 1) Describe the estimation of CO2 exchange from the oldest forest ecosystem (500 years old) in the AmeriFlux network, based on eddy covariance, using accepted AmeriFlux correction techniques for low friction velocities and turbulence levels, and related advection calculation methods; 2) Examine the CO2 exchange response to diurnal, seasonal, annual, and interannual variations, and relate the exchange to meteorologic variables such as photosynthetically active radiation (PAR) and soil and air temperatures; 3) Relate measurements to ecosystem physiological processes and identify when the forest is a source or sink in relation to these processes; 4) support collaborative efforts with other ecological studies." -US-Wrc,24818,GRP_SA,SA,475 -US-Wrc,24818,GRP_SA,SA_MAX,500 -US-Wrc,12451,GRP_SITE_CHAR,TERRAIN,"Medium Slope (>2 %, <5%)" -US-Wrc,12452,GRP_SITE_DESC,SITE_DESC,"Wind River Field Station flux tower site is located in the T.T. Munger Research Area of the Wind River Ranger District in the Gifford Pinchot National Forest. Protected since 1926, the T.T. Munger Research Natural Area (RNA) is administered by the USDA Forest Service Pacific Northwest Research Station and Gifford Pinchot National Forest. The Douglas-fir/western hemlock dominant stand is approximately 500 years old and represents end points of several ecological gradients including age, biomass, structural complexity, and density of the dominant overstory species. A complete stand replacement fire, approximately 450-500 years ago, resulted in the initial establishment. No significant disturbances have occurred since the fire aside from those confined to small groups of single trees, such as overturn from high wind activity and mechanical damage from winter precipitation." -US-Wrc,12453,GRP_SITE_FUNDING,SITE_FUNDING,"USFS, Univ. of Washington" -US-Wrc,24287,GRP_SOIL_CHEM,SOIL_CHEM_C_ORG,111 -US-Wrc,23786,GRP_SOIL_CHEM,SOIL_CHEM_C_ORG,13 -US-Wrc,24946,GRP_SOIL_CHEM,SOIL_CHEM_C_ORG,41 -US-Wrc,24551,GRP_SOIL_CHEM,SOIL_CHEM_C_ORG,56 -US-Wrc,24551,GRP_SOIL_CHEM,SOIL_CHEM_PH_SALT,5.3 -US-Wrc,24946,GRP_SOIL_CHEM,SOIL_CHEM_PH_SALT,5.3 -US-Wrc,24551,GRP_SOIL_CHEM,SOIL_CHEM_BD,0.81 -US-Wrc,24946,GRP_SOIL_CHEM,SOIL_CHEM_BD,0.81 -US-Wrc,23786,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,0 -US-Wrc,24551,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,0 -US-Wrc,24946,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,0 -US-Wrc,24287,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MIN,200 -US-Wrc,24551,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,10 -US-Wrc,24287,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,300 -US-Wrc,24946,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,35 -US-Wrc,23786,GRP_SOIL_CHEM,SOIL_CHEM_PROFILE_MAX,5.8 -US-Wrc,24551,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,A -US-Wrc,24946,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,B -US-Wrc,23786,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,Organic -US-Wrc,24287,GRP_SOIL_CHEM,SOIL_CHEM_HORIZON,Total -US-Wrc,28784,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION,"Entic Vitrands: medial, mesic, well drained, loams and silt loams, generally stone free, and derived from volcanic tephra." -US-Wrc,28784,GRP_SOIL_CLASSIFICATION,SOIL_CLASSIFICATION_TAXONOMY,Other -US-Wrc,23649,GRP_SOIL_DEPTH,SOIL_DEPTH,5.8 -US-Wrc,24030,GRP_SOIL_DEPTH,SOIL_DEPTH,10 -US-Wrc,24286,GRP_SOIL_DEPTH,SOIL_DEPTH,250 -US-Wrc,25065,GRP_SOIL_DEPTH,SOIL_DEPTH,35 -US-Wrc,27981,GRP_SOIL_TEX,SOIL_TEX_SAND,60 -US-Wrc,27981,GRP_SOIL_TEX,SOIL_TEX_SILT,30 -US-Wrc,27981,GRP_SOIL_TEX,SOIL_TEX_CLAY,10 -US-Wrc,27981,GRP_SOIL_TEX,SOIL_TEX_HORIZON,A-Horizon -US-Wrc,23796,GRP_SPP_O,SPP_O,"Pseudotsuga menziesii, Tsuga heterophylla" -US-Wrc,12454,GRP_STATE,STATE,WA -US-Wrc,12459,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Sonia Wharton -US-Wrc,12459,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-Wrc,12459,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,wharton4@llnl.gov -US-Wrc,12459,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Lawrence Livermore National Laboratory -US-Wrc,12456,GRP_URL,URL,http://depts.washington.edu/wrccrf/ -US-Wrc,24000447,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-Wrc -US-Wrc,12457,GRP_UTC_OFFSET,UTC_OFFSET,-8 -US-xAB,85351,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,The National Ecological Observatory Network is a project solely funded by the National Science Foundation and managed under cooperative agreement by Battelle. -US-xAB,85355,GRP_CLIM_AVG,MAT,10 -US-xAB,85355,GRP_CLIM_AVG,MAP,2450.59 -US-xAB,85355,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Csb -US-xAB,27001013,GRP_COUNTRY,COUNTRY,USA -US-xAB,91708,GRP_DOI,DOI,10.17190/AMF/1617726 -US-xAB,91708,GRP_DOI,DOI_CITATION,"NEON (National Ecological Observatory Network) (2022), AmeriFlux BASE US-xAB NEON Abby Road (ABBY), Ver. 6-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1617726" -US-xAB,91708,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-xAB,96151,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-xAB,96151,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,NEON (National Ecological Observatory Network) -US-xAB,96151,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-xAB,96151,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,neon-ameriflux@battelleecology.org -US-xAB,96151,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"NEON Program, Battelle" -US-xAB,96151,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,20160101 -US-xAB,96197,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,National Ecological Observatory Network -US-xAB,96197,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-xAB,91628,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,National Science Foundation (NSF) -US-xAB,91628,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-xAB,85360,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Forestry -US-xAB,85347,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-xAB,85347,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-xAB,85347,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20170428 -US-xAB,85347,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-xAB,85348,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-xAB,85348,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-xAB,85348,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20170428 -US-xAB,85348,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-xAB,23001013,GRP_HEADER,SITE_NAME,NEON Abby Road (ABBY) -US-xAB,85352,GRP_IGBP,IGBP,ENF -US-xAB,85342,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-xAB,85342,GRP_LAND_OWNERSHIP,LAND_OWNER,Washington Department of Natural Resources -US-xAB,85341,GRP_LOCATION,LOCATION_LAT,45.7624 -US-xAB,85341,GRP_LOCATION,LOCATION_LONG,-122.3303 -US-xAB,85341,GRP_LOCATION,LOCATION_ELEV,363 -US-xAB,85361,GRP_NETWORK,NETWORK,AmeriFlux -US-xAB,85350,GRP_NETWORK,NETWORK,NEON -US-xAB,87035,GRP_NETWORK,NETWORK,Phenocam -US-xAB,1700004902,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Metzger, S., Ayres, E., Durden, D., Florian, C., Lee, R., Lunch, C., Luo, H., Pingintha-Durden, N., Roberti, J. A., SanClements, M., Sturtevant, C., Xu, K., Zulueta, R. C. (2019) From NEON field sites to data portal: a community resource for surface–atmosphere research comes online, Bulletin Of The American Meteorological Society, 100(11), 2305-2325" -US-xAB,1700004902,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1175/BAMS-D-17-0307.1 -US-xAB,1700004902,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-xAB,1700000210,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Xu, K., Pingintha-Durden, N., Luo, H., Durden, D., Sturtevant, C., Desai, A. R., Florian, C., Metzger, S. (2019) The Eddy-Covariance Storage Term In Air: Consistent Community Resources Improve Flux Measurement Reliability, Agricultural And Forest Meteorology, 279(107734), 107734" -US-xAB,1700000210,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2019.107734 -US-xAB,1700000210,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-xAB,1700001344,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Xu, K., Pingintha-Durden, N., Luo, H., Durden, D., Sturtevant, C., Desai, A. R., Florian, C., Metzger, S. (2019) The Eddy-Covariance Storage Term In Air: Consistent Community Resources Improve Flux Measurement Reliability, Agricultural And Forest Meteorology, 279(11), 107734" -US-xAB,1700001344,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2019.107734 -US-xAB,1700001344,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-xAB,85356,GRP_SITE_CHAR,WIND_DIRECTION,SSE -US-xAB,85353,GRP_SITE_DESC,SITE_DESC,"The Abby Road (NEON 4-letter code: ABBY) field site is located in Yacolt Burn State Forest which is approximately 30 miles from Vancouver, WA and Portland, OR. Yacolt Burn State Forest is a relatively young growth industrial timber production forest. The Washington Department of Natural Resources (DNR) also allows an array of recreational activities including moutain biking, hiking and camping. " -US-xAB,85343,GRP_SITE_FUNDING,SITE_FUNDING,National Science Foundation (NSF) -US-xAB,85359,GRP_STATE,STATE,WA -US-xAB,95932,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,National Ecological Observatory Network -US-xAB,95932,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-xAB,95932,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,neon-ameriflux@battelleecology.org -US-xAB,95932,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xAB,95932,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xAB,95930,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,David Durden -US-xAB,95930,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-xAB,95930,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,ddurden@battelleecology.org -US-xAB,95930,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xAB,95930,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xAB,95931,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Stefan Metzger -US-xAB,95931,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-xAB,95931,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,smetzger@battelleecology.org -US-xAB,95931,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xAB,95931,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xAB,95933,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Christopher Florian -US-xAB,95933,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,BADMContact -US-xAB,95933,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,cflorian@battelleecology.org -US-xAB,95933,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xAB,95933,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xAB,95929,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Cove Sturtevant -US-xAB,95929,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,DataManager -US-xAB,95929,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,csturtevant@battelleecology.org -US-xAB,95929,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xAB,95929,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xAB,85354,GRP_TOWER_POWER,TOWER_POWER,Direct power -US-xAB,85357,GRP_TOWER_TYPE,TOWER_TYPE,walk-up -US-xAB,85346,GRP_URL,URL,http://www.neonscience.org/field-sites/field-sites-map/ABBY -US-xAB,24001013,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-xAB -US-xAB,85349,GRP_UTC_OFFSET,UTC_OFFSET,-8 -US-xAB,85349,GRP_UTC_OFFSET,UTC_OFFSET_COMMENT,"Pacific Standard Time (PST), please note that timestamps are converted to local standard time upon submission to AmeriFlux. Data retrieved from the NEON Data Portal will be in UTC time." -US-xAE,86252,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,The National Ecological Observatory Network is a project solely funded by the National Science Foundation and managed under cooperative agreement by Battelle. -US-xAE,86247,GRP_CLIM_AVG,MAT,15.5 -US-xAE,86247,GRP_CLIM_AVG,MAP,778.85 -US-xAE,86247,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Cfa -US-xAE,27001054,GRP_COUNTRY,COUNTRY,USA -US-xAE,94281,GRP_DOI,DOI,10.17190/AMF/1671891 -US-xAE,94281,GRP_DOI,DOI_CITATION,"NEON (National Ecological Observatory Network) (2022), AmeriFlux BASE US-xAE NEON Klemme Range Research Station (OAES), Ver. 4-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1671891" -US-xAE,94281,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-xAE,96152,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-xAE,96152,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,NEON (National Ecological Observatory Network) -US-xAE,96152,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-xAE,96152,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,neon-ameriflux@battelleecology.org -US-xAE,96152,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"NEON Program, Battelle" -US-xAE,96152,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,20160101 -US-xAE,96198,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,National Ecological Observatory Network -US-xAE,96198,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-xAE,94251,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,National Science Foundation (NSF) -US-xAE,94251,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-xAE,86237,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Fire -US-xAE,86238,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Grazing -US-xAE,86249,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-xAE,86249,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-xAE,86249,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20170922 -US-xAE,86249,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-xAE,86248,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-xAE,86248,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-xAE,86248,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20170922 -US-xAE,86248,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-xAE,86245,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Other -US-xAE,86245,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,Isotopes -US-xAE,86245,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20170922 -US-xAE,86245,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-xAE,23001054,GRP_HEADER,SITE_NAME,NEON Klemme Range Research Station (OAES) -US-xAE,86233,GRP_IGBP,IGBP,GRA -US-xAE,86246,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -US-xAE,86246,GRP_LAND_OWNERSHIP,LAND_OWNER,"Oklahoma State University, Oklahoma Agricultural Experimental Station" -US-xAE,86250,GRP_LOCATION,LOCATION_LAT,35.4106 -US-xAE,86250,GRP_LOCATION,LOCATION_LONG,-99.0588 -US-xAE,86250,GRP_LOCATION,LOCATION_ELEV,516 -US-xAE,86240,GRP_NETWORK,NETWORK,AmeriFlux -US-xAE,86231,GRP_NETWORK,NETWORK,NEON -US-xAE,87036,GRP_NETWORK,NETWORK,Phenocam -US-xAE,1700003426,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Metzger, S., Ayres, E., Durden, D., Florian, C., Lee, R., Lunch, C., Luo, H., Pingintha-Durden, N., Roberti, J. A., SanClements, M., Sturtevant, C., Xu, K., Zulueta, R. C. (2019) From NEON field sites to data portal: a community resource for surface–atmosphere research comes online, Bulletin Of The American Meteorological Society, 100(11), 2305-2325" -US-xAE,1700003426,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1175/BAMS-D-17-0307.1 -US-xAE,1700003426,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-xAE,86239,GRP_SITE_CHAR,WIND_DIRECTION,SE -US-xAE,86251,GRP_SITE_DESC,SITE_DESC,"The 1,560-acre Klemme Range Research Station is a grassland site managed for livestock grazing and pasture, located in the middle of the Rolling Red Plains Resource Area. The Rolling Red Plains extends from south of the Red River to north of the Oklahoma/Kansas border consisting of approximately 9.4 million acres, which occupies a significant portion of Western Oklahoma excluding the Oklahoma Panhandle." -US-xAE,86243,GRP_SITE_FUNDING,SITE_FUNDING,National Science Foundation (NSF) -US-xAE,86235,GRP_STATE,STATE,OK -US-xAE,95938,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,National Ecological Observatory Network -US-xAE,95938,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-xAE,95938,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,neon-ameriflux@battelleecology.org -US-xAE,95938,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xAE,95938,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xAE,95936,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,David Durden -US-xAE,95936,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-xAE,95936,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,ddurden@battelleecology.org -US-xAE,95936,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xAE,95936,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xAE,95934,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Stefan Metzger -US-xAE,95934,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-xAE,95934,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,smetzger@battelleecology.org -US-xAE,95934,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xAE,95934,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xAE,95935,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Christopher Florian -US-xAE,95935,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,BADMContact -US-xAE,95935,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,cflorian@battelleecology.org -US-xAE,95935,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xAE,95935,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xAE,95937,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Cove Sturtevant -US-xAE,95937,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,DataManager -US-xAE,95937,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,csturtevant@battelleecology.org -US-xAE,95937,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xAE,95937,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xAE,86242,GRP_TOWER_POWER,TOWER_POWER,Direct power -US-xAE,86236,GRP_TOWER_TYPE,TOWER_TYPE,walk-up -US-xAE,86234,GRP_URL,URL,https://www.neonscience.org/field-sites/field-sites-map/OAES -US-xAE,24001054,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-xAE -US-xAE,86244,GRP_UTC_OFFSET,UTC_OFFSET,-6 -US-xAE,86244,GRP_UTC_OFFSET,UTC_OFFSET_COMMENT,"Central Standard Time (CST), please note that timestamps are converted to local standard time upon submission to AmeriFlux. Data retrieved from the NEON Data Portal will be in UTC time." -US-xBA,85239,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,The National Ecological Observatory Network is a project solely funded by the National Science Foundation and managed under cooperative agreement by Battelle. -US-xBA,85228,GRP_CLIM_AVG,MAT,-12 -US-xBA,85228,GRP_CLIM_AVG,MAP,110 -US-xBA,85228,GRP_CLIM_AVG,CLIMATE_KOEPPEN,ET -US-xBA,27001012,GRP_COUNTRY,COUNTRY,USA -US-xBA,94280,GRP_DOI,DOI,10.17190/AMF/1671892 -US-xBA,94280,GRP_DOI,DOI_CITATION,"NEON (National Ecological Observatory Network) (2022), AmeriFlux BASE US-xBA NEON Barrow Environmental Observatory (BARR), Ver. 5-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1671892" -US-xBA,94280,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-xBA,96153,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-xBA,96153,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,NEON (National Ecological Observatory Network) -US-xBA,96153,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-xBA,96153,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,neon-ameriflux@battelleecology.org -US-xBA,96153,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"NEON Program, Battelle" -US-xBA,96153,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,20160101 -US-xBA,96199,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,National Ecological Observatory Network -US-xBA,96199,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-xBA,94257,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,National Science Foundation (NSF) -US-xBA,94257,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-xBA,85231,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-xBA,85231,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-xBA,85231,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20170421 -US-xBA,85231,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-xBA,85235,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-xBA,85235,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-xBA,85235,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20170421 -US-xBA,85235,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-xBA,85238,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Other -US-xBA,85238,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,Isotopes -US-xBA,85238,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20170421 -US-xBA,85238,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-xBA,23001012,GRP_HEADER,SITE_NAME,NEON Barrow Environmental Observatory (BARR) -US-xBA,85241,GRP_IGBP,IGBP,WET -US-xBA,85230,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -US-xBA,85230,GRP_LAND_OWNERSHIP,LAND_OWNER,Barrow Environmental Observatory -US-xBA,85243,GRP_LOCATION,LOCATION_LAT,71.2824 -US-xBA,85243,GRP_LOCATION,LOCATION_LONG,-156.6194 -US-xBA,85243,GRP_LOCATION,LOCATION_ELEV,6 -US-xBA,85240,GRP_NETWORK,NETWORK,AmeriFlux -US-xBA,85245,GRP_NETWORK,NETWORK,NEON -US-xBA,87037,GRP_NETWORK,NETWORK,Phenocam -US-xBA,1700002040,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Metzger, S., Ayres, E., Durden, D., Florian, C., Lee, R., Lunch, C., Luo, H., Pingintha-Durden, N., Roberti, J. A., SanClements, M., Sturtevant, C., Xu, K., Zulueta, R. C. (2019) From NEON field sites to data portal: a community resource for surface–atmosphere research comes online, Bulletin Of The American Meteorological Society, 100(11), 2305-2325" -US-xBA,1700002040,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1175/BAMS-D-17-0307.1 -US-xBA,1700002040,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-xBA,85233,GRP_SITE_CHAR,WIND_DIRECTION,E -US-xBA,85234,GRP_SITE_DESC,SITE_DESC,"Located three hundred miles north of the Arctic Circle, the Barrow field site landscape is representative of the polygon tundra and lake systems across the northern extent of the North Slope of Alaska. Barrow spans 50 square kilometers and includes a 26’ tall meteorological flux tower and nearby soil sensors. NEON scientists also collect field observations throughout the field site." -US-xBA,85227,GRP_SITE_FUNDING,SITE_FUNDING,National Science Foundation (NSF) -US-xBA,85226,GRP_STATE,STATE,AK -US-xBA,95940,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,National Ecological Observatory Network -US-xBA,95940,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-xBA,95940,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,neon-ameriflux@battelleecology.org -US-xBA,95940,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xBA,95940,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xBA,95943,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,David Durden -US-xBA,95943,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-xBA,95943,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,ddurden@battelleecology.org -US-xBA,95943,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xBA,95943,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xBA,95941,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Stefan Metzger -US-xBA,95941,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-xBA,95941,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,smetzger@battelleecology.org -US-xBA,95941,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xBA,95941,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xBA,95939,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Christopher Florian -US-xBA,95939,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,BADMContact -US-xBA,95939,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,cflorian@battelleecology.org -US-xBA,95939,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xBA,95939,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xBA,95942,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Cove Sturtevant -US-xBA,95942,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,DataManager -US-xBA,95942,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,csturtevant@battelleecology.org -US-xBA,95942,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xBA,95942,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xBA,85237,GRP_TOWER_POWER,TOWER_POWER,Direct power -US-xBA,85229,GRP_TOWER_TYPE,TOWER_TYPE,walk-up -US-xBA,85236,GRP_URL,URL,https://www.neonscience.org/field-sites/field-sites-map/BARR -US-xBA,24001012,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-xBA -US-xBA,85232,GRP_UTC_OFFSET,UTC_OFFSET,-9 -US-xBA,85232,GRP_UTC_OFFSET,UTC_OFFSET_COMMENT,"Alaska Standard Time (AKST), please note that timestamps are converted to local standard time upon submission to AmeriFlux. Data retrieved from the NEON Data Portal will be in UTC time." -US-xBL,85339,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,The National Ecological Observatory Network is a project solely funded by the National Science Foundation and managed under cooperative agreement by Battelle. -US-xBL,85326,GRP_CLIM_AVG,MAT,12.1 -US-xBL,85326,GRP_CLIM_AVG,MAP,982.55 -US-xBL,85326,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Cfa -US-xBL,27001014,GRP_COUNTRY,COUNTRY,USA -US-xBL,94278,GRP_DOI,DOI,10.17190/AMF/1671893 -US-xBL,94278,GRP_DOI,DOI_CITATION,"NEON (National Ecological Observatory Network) (2022), AmeriFlux BASE US-xBL NEON Blandy Experimental Farm (BLAN), Ver. 5-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1671893" -US-xBL,94278,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-xBL,96154,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-xBL,96154,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,NEON (National Ecological Observatory Network) -US-xBL,96154,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-xBL,96154,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,neon-ameriflux@battelleecology.org -US-xBL,96154,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"NEON Program, Battelle" -US-xBL,96154,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,20160101 -US-xBL,96200,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,National Ecological Observatory Network -US-xBL,96200,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-xBL,94248,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,National Science Foundation (NSF) -US-xBL,94248,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-xBL,85335,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-xBL,85335,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-xBL,85335,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20160908 -US-xBL,85335,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-xBL,85321,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-xBL,85321,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-xBL,85321,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20160908 -US-xBL,85321,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-xBL,85334,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Other -US-xBL,85334,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,Isotopes -US-xBL,85334,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20160908 -US-xBL,85334,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-xBL,23001014,GRP_HEADER,SITE_NAME,NEON Blandy Experimental Farm (BLAN) -US-xBL,85328,GRP_IGBP,IGBP,DBF -US-xBL,85322,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -US-xBL,85322,GRP_LAND_OWNERSHIP,LAND_OWNER,University of Virginia -US-xBL,85327,GRP_LOCATION,LOCATION_LAT,39.0603 -US-xBL,85327,GRP_LOCATION,LOCATION_LONG,-78.0716 -US-xBL,85327,GRP_LOCATION,LOCATION_ELEV,183 -US-xBL,85330,GRP_NETWORK,NETWORK,AmeriFlux -US-xBL,85340,GRP_NETWORK,NETWORK,NEON -US-xBL,87038,GRP_NETWORK,NETWORK,Phenocam -US-xBL,1700002988,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Metzger, S., Ayres, E., Durden, D., Florian, C., Lee, R., Lunch, C., Luo, H., Pingintha-Durden, N., Roberti, J. A., SanClements, M., Sturtevant, C., Xu, K., Zulueta, R. C. (2019) From NEON field sites to data portal: a community resource for surface–atmosphere research comes online, Bulletin Of The American Meteorological Society, 100(11), 2305-2325" -US-xBL,1700002988,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1175/BAMS-D-17-0307.1 -US-xBL,1700002988,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-xBL,85329,GRP_SITE_CHAR,WIND_DIRECTION,SW -US-xBL,85331,GRP_SITE_DESC,SITE_DESC,The Blandy Experimental Farm contains several land use types typically found in rural-suburban landscapes. This mix of land use types is typical and representative in the Middle Atlantic Domain. This site will be under increasing ecological pressure from urbanization within the rapidly growing megapolitan area. The amount of land cover and associated ecosystem processes in each of these land use types is expected to change over time. -US-xBL,85325,GRP_SITE_FUNDING,SITE_FUNDING,National Science Foundation (NSF) -US-xBL,85323,GRP_STATE,STATE,VA -US-xBL,95945,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,National Ecological Observatory Network -US-xBL,95945,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-xBL,95945,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,neon-ameriflux@battelleecology.org -US-xBL,95945,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xBL,95945,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xBL,95944,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,David Durden -US-xBL,95944,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-xBL,95944,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,ddurden@battelleecology.org -US-xBL,95944,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xBL,95944,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xBL,95947,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Stefan Metzger -US-xBL,95947,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-xBL,95947,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,smetzger@battelleecology.org -US-xBL,95947,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xBL,95947,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xBL,95946,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Christopher Florian -US-xBL,95946,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,BADMContact -US-xBL,95946,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,cflorian@battelleecology.org -US-xBL,95946,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xBL,95946,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xBL,95948,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Cove Sturtevant -US-xBL,95948,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,DataManager -US-xBL,95948,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,csturtevant@battelleecology.org -US-xBL,95948,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xBL,95948,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xBL,85324,GRP_TOWER_POWER,TOWER_POWER,Direct power -US-xBL,85332,GRP_TOWER_TYPE,TOWER_TYPE,walk-up -US-xBL,86542,GRP_URL,URL,https://www.neonscience.org/field-sites/field-sites-map/BLAN -US-xBL,24001014,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-xBL -US-xBL,85333,GRP_UTC_OFFSET,UTC_OFFSET,-5 -US-xBL,85333,GRP_UTC_OFFSET,UTC_OFFSET_COMMENT,"Eastern Standard Time (EST), please note that timestamps are converted to local standard time upon submission to AmeriFlux. Data retrieved from the NEON Data Portal will be in UTC time." -US-xBN,85535,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,The National Ecological Observatory Network is a project solely funded by the National Science Foundation and managed under cooperative agreement by Battelle. -US-xBN,85549,GRP_CLIM_AVG,MAT,-2 -US-xBN,85549,GRP_CLIM_AVG,MAP,275 -US-xBN,85549,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dwc -US-xBN,27001028,GRP_COUNTRY,COUNTRY,USA -US-xBN,91691,GRP_DOI,DOI,10.17190/AMF/1617727 -US-xBN,91691,GRP_DOI,DOI_CITATION,"NEON (National Ecological Observatory Network) (2022), AmeriFlux BASE US-xBN NEON Caribou Creek - Poker Flats Watershed (BONA), Ver. 6-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1617727" -US-xBN,91691,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-xBN,96155,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-xBN,96155,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,NEON (National Ecological Observatory Network) -US-xBN,96155,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-xBN,96155,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,neon-ameriflux@battelleecology.org -US-xBN,96155,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"NEON Program, Battelle" -US-xBN,96155,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,20160101 -US-xBN,96201,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,National Ecological Observatory Network -US-xBN,96201,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-xBN,91605,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,National Science Foundation (NSF) -US-xBN,91605,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-xBN,85543,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-xBN,85543,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-xBN,85543,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20171110 -US-xBN,85543,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-xBN,85546,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-xBN,85546,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-xBN,85546,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20171110 -US-xBN,85546,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-xBN,85536,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Other -US-xBN,85536,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,Isotopes -US-xBN,85536,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20171110 -US-xBN,85536,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-xBN,23001028,GRP_HEADER,SITE_NAME,NEON Caribou Creek - Poker Flats Watershed (BONA) -US-xBN,85550,GRP_IGBP,IGBP,ENF -US-xBN,85532,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -US-xBN,85532,GRP_LAND_OWNERSHIP,LAND_OWNER,University of Alaska -US-xBN,85545,GRP_LOCATION,LOCATION_LAT,65.1540 -US-xBN,85545,GRP_LOCATION,LOCATION_LONG,-147.5026 -US-xBN,85545,GRP_LOCATION,LOCATION_ELEV,263 -US-xBN,85537,GRP_NETWORK,NETWORK,AmeriFlux -US-xBN,85533,GRP_NETWORK,NETWORK,NEON -US-xBN,87039,GRP_NETWORK,NETWORK,Phenocam -US-xBN,1700003621,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Metzger, S., Ayres, E., Durden, D., Florian, C., Lee, R., Lunch, C., Luo, H., Pingintha-Durden, N., Roberti, J. A., SanClements, M., Sturtevant, C., Xu, K., Zulueta, R. C. (2019) From NEON field sites to data portal: a community resource for surface–atmosphere research comes online, Bulletin Of The American Meteorological Society, 100(11), 2305-2325" -US-xBN,1700003621,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1175/BAMS-D-17-0307.1 -US-xBN,1700003621,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-xBN,85548,GRP_SITE_CHAR,WIND_DIRECTION,NE -US-xBN,85539,GRP_SITE_FUNDING,SITE_FUNDING,National Science Foundation (NSF) -US-xBN,85541,GRP_STATE,STATE,AK -US-xBN,95952,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,National Ecological Observatory Network -US-xBN,95952,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-xBN,95952,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,neon-ameriflux@battelleecology.org -US-xBN,95952,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xBN,95952,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xBN,95953,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,David Durden -US-xBN,95953,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-xBN,95953,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,ddurden@battelleecology.org -US-xBN,95953,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xBN,95953,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xBN,95949,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Stefan Metzger -US-xBN,95949,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-xBN,95949,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,smetzger@battelleecology.org -US-xBN,95949,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xBN,95949,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xBN,95950,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Christopher Florian -US-xBN,95950,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,BADMContact -US-xBN,95950,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,cflorian@battelleecology.org -US-xBN,95950,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xBN,95950,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xBN,95951,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Cove Sturtevant -US-xBN,95951,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,DataManager -US-xBN,95951,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,csturtevant@battelleecology.org -US-xBN,95951,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xBN,95951,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xBN,85534,GRP_TOWER_POWER,TOWER_POWER,Direct power -US-xBN,85547,GRP_TOWER_TYPE,TOWER_TYPE,walk-up -US-xBN,85540,GRP_URL,URL,https://www.neonscience.org/field-sites/field-sites-map/BONA -US-xBN,24001028,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-xBN -US-xBN,85538,GRP_UTC_OFFSET,UTC_OFFSET,-9 -US-xBN,85538,GRP_UTC_OFFSET,UTC_OFFSET_COMMENT,"Alaska Standard Time (AKST), please note that timestamps are converted to local standard time upon submission to AmeriFlux. Data retrieved from the NEON Data Portal will be in UTC time." -US-xBR,79803,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,The National Ecological Observatory Network is a project solely funded by the National Science Foundation and managed under cooperative agreement by Battelle. -US-xBR,79804,GRP_CLIM_AVG,MAT,5.6 -US-xBR,79804,GRP_CLIM_AVG,MAP,1246 -US-xBR,79804,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfb -US-xBR,27000961,GRP_COUNTRY,COUNTRY,USA -US-xBR,90037,GRP_DOI,DOI,10.17190/AMF/1579542 -US-xBR,90037,GRP_DOI,DOI_CITATION,"NEON (National Ecological Observatory Network) (2022), AmeriFlux BASE US-xBR NEON Bartlett Experimental Forest (BART), Ver. 6-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1579542" -US-xBR,90037,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-xBR,95914,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-xBR,95914,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,NEON (National Ecological Observatory Network) -US-xBR,95914,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-xBR,95914,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,neon-ameriflux@battelleecology.org -US-xBR,95914,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"NEON Program, Battelle" -US-xBR,95914,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,20160101 -US-xBR,95915,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,National Ecological Observatory Network -US-xBR,95915,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-xBR,88184,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,National Science Foundation (NSF) -US-xBR,88184,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-xBR,79805,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Forestry -US-xBR,79806,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-xBR,79806,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-xBR,79806,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20161206 -US-xBR,79806,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-xBR,79807,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-xBR,79807,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-xBR,79807,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20161206 -US-xBR,79807,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-xBR,23000961,GRP_HEADER,SITE_NAME,NEON Bartlett Experimental Forest (BART) -US-xBR,79808,GRP_IGBP,IGBP,DBF -US-xBR,79818,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-xBR,79818,GRP_LAND_OWNERSHIP,LAND_OWNER,U.S. Forest Service -US-xBR,79819,GRP_LOCATION,LOCATION_LAT,44.0639 -US-xBR,79819,GRP_LOCATION,LOCATION_LONG,-71.2873 -US-xBR,79819,GRP_LOCATION,LOCATION_ELEV,232 -US-xBR,79821,GRP_NETWORK,NETWORK,AmeriFlux -US-xBR,79820,GRP_NETWORK,NETWORK,NEON -US-xBR,87040,GRP_NETWORK,NETWORK,Phenocam -US-xBR,1700001218,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(11), 108350" -US-xBR,1700001218,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -US-xBR,1700001218,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-xBR,1700007140,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Metzger, S., Ayres, E., Durden, D., Florian, C., Lee, R., Lunch, C., Luo, H., Pingintha-Durden, N., Roberti, J. A., SanClements, M., Sturtevant, C., Xu, K., Zulueta, R. C. (2019) From NEON field sites to data portal: a community resource for surface–atmosphere research comes online, Bulletin Of The American Meteorological Society, 100(11), 2305-2325" -US-xBR,1700007140,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1175/BAMS-D-17-0307.1 -US-xBR,1700007140,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-xBR,1700002283,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Xu, K., Pingintha-Durden, N., Luo, H., Durden, D., Sturtevant, C., Desai, A. R., Florian, C., Metzger, S. (2019) The Eddy-Covariance Storage Term In Air: Consistent Community Resources Improve Flux Measurement Reliability, Agricultural And Forest Meteorology, 279(107734), 107734" -US-xBR,1700002283,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2019.107734 -US-xBR,1700002283,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-xBR,1700001254,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Xu, K., Pingintha-Durden, N., Luo, H., Durden, D., Sturtevant, C., Desai, A. R., Florian, C., Metzger, S. (2019) The Eddy-Covariance Storage Term In Air: Consistent Community Resources Improve Flux Measurement Reliability, Agricultural And Forest Meteorology, 279(11), 107734" -US-xBR,1700001254,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2019.107734 -US-xBR,1700001254,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-xBR,79822,GRP_SITE_CHAR,WIND_DIRECTION,S -US-xBR,79823,GRP_SITE_DESC,SITE_DESC,"The Bartlett Experimental Forest is an actively managed forest; managed portions (30%) reflect a range of forest patch sizes and structural distributions. The Bartlett forest has a history of logging dating from colonial times through the beginning of the 20th century. Approximately 70% of the land area has remained uncut since the early 1900s. Natural disturbances include late 19th century fire, beech scale-Nectria complex (beech bark disease) beginning in the 1940s, severe wind disturbance resulting from hurricanes in 1938 and 1954 and a damaging ice storm in 1998." -US-xBR,79812,GRP_SITE_FUNDING,SITE_FUNDING,National Science Foundation (NSF) -US-xBR,79813,GRP_STATE,STATE,NH -US-xBR,95073,GRP_TEAM_CONTACT,TEAM_CONTACT_NAME,NEON User Inquiries -US-xBR,95073,GRP_TEAM_CONTACT,TEAM_CONTACT_EMAIL,neon-ameriflux-inquiry@battelleecology.org -US-xBR,95678,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,National Ecological Observatory Network -US-xBR,95678,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-xBR,95678,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,neon-ameriflux@battelleecology.org -US-xBR,95678,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xBR,95678,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xBR,95367,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,David Durden -US-xBR,95367,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-xBR,95367,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,ddurden@battelleecology.org -US-xBR,95367,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xBR,95367,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xBR,95366,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Stefan Metzger -US-xBR,95366,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-xBR,95366,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,smetzger@battelleecology.org -US-xBR,95366,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xBR,95366,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xBR,95368,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Christopher Florian -US-xBR,95368,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,BADMContact -US-xBR,95368,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,cflorian@battelleecology.org -US-xBR,95368,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xBR,95368,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xBR,95375,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Cove Sturtevant -US-xBR,95375,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,DataManager -US-xBR,95375,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,csturtevant@battelleecology.org -US-xBR,95375,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xBR,95375,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xBR,79817,GRP_TOWER_POWER,TOWER_POWER,Direct power -US-xBR,79809,GRP_TOWER_TYPE,TOWER_TYPE,walk-up -US-xBR,79810,GRP_URL,URL,http://www.neonscience.org/field-sites/field-sites-map/BART -US-xBR,24000961,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-xBR -US-xBR,79811,GRP_UTC_OFFSET,UTC_OFFSET,-5 -US-xBR,79811,GRP_UTC_OFFSET,UTC_OFFSET_COMMENT,"Eastern Standard Time (EST), please note that timestamps are converted to local standard time upon submission to AmeriFlux. Data retrieved from the NEON Data Portal will be in UTC time." -US-xCL,79485,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,The National Ecological Observatory Network is a project solely funded by the National Science Foundation and managed under cooperative agreement by Battelle. -US-xCL,79495,GRP_CLIM_AVG,MAT,17.5 -US-xCL,79495,GRP_CLIM_AVG,MAP,925.61 -US-xCL,79495,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Cfa -US-xCL,27000947,GRP_COUNTRY,COUNTRY,USA -US-xCL,94274,GRP_DOI,DOI,10.17190/AMF/1671894 -US-xCL,94274,GRP_DOI,DOI_CITATION,"NEON (National Ecological Observatory Network) (2022), AmeriFlux BASE US-xCL NEON LBJ National Grassland (CLBJ), Ver. 4-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1671894" -US-xCL,94274,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-xCL,96156,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-xCL,96156,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,NEON (National Ecological Observatory Network) -US-xCL,96156,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-xCL,96156,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,neon-ameriflux@battelleecology.org -US-xCL,96156,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"NEON Program, Battelle" -US-xCL,96156,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,20160101 -US-xCL,96202,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,National Ecological Observatory Network -US-xCL,96202,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-xCL,79489,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Fire -US-xCL,79484,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Grazing -US-xCL,79490,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Land cover change -US-xCL,79488,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-xCL,79488,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-xCL,79488,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20170919 -US-xCL,79488,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-xCL,79499,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-xCL,79499,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-xCL,79499,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20170919 -US-xCL,79499,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-xCL,79497,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Other -US-xCL,79497,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,Isotopes -US-xCL,79497,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20170919 -US-xCL,79497,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-xCL,23000947,GRP_HEADER,SITE_NAME,NEON LBJ National Grassland (CLBJ) -US-xCL,79491,GRP_IGBP,IGBP,GRA -US-xCL,79501,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-xCL,79501,GRP_LAND_OWNERSHIP,LAND_OWNER,U. S. Forest Service -US-xCL,79493,GRP_LOCATION,LOCATION_LAT,33.4012 -US-xCL,79493,GRP_LOCATION,LOCATION_LONG,-97.5700 -US-xCL,79493,GRP_LOCATION,LOCATION_ELEV,259 -US-xCL,79493,GRP_LOCATION,LOCATION_DATE_START,20170919 -US-xCL,79486,GRP_NETWORK,NETWORK,AmeriFlux -US-xCL,79506,GRP_NETWORK,NETWORK,NEON -US-xCL,87041,GRP_NETWORK,NETWORK,Phenocam -US-xCL,1700008796,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Metzger, S., Ayres, E., Durden, D., Florian, C., Lee, R., Lunch, C., Luo, H., Pingintha-Durden, N., Roberti, J. A., SanClements, M., Sturtevant, C., Xu, K., Zulueta, R. C. (2019) From NEON field sites to data portal: a community resource for surface–atmosphere research comes online, Bulletin Of The American Meteorological Society, 100(11), 2305-2325" -US-xCL,1700008796,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1175/BAMS-D-17-0307.1 -US-xCL,1700008796,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-xCL,79503,GRP_SITE_CHAR,WIND_DIRECTION,S -US-xCL,79496,GRP_SITE_DESC,SITE_DESC,"The LBJ Grasslands is 16,800 acres of land managed by the US Forest Service under the US Department of Agriculture. There is a rich legacy of land use, ranging back to the mid-19th century. Currently, LBJ Grasslands are used for recreation and hunting, livestock grazing, and fossil fuel extraction. Ongoing ecological monitoring is performed at the site, along with prescribed burning." -US-xCL,79498,GRP_STATE,STATE,TX -US-xCL,95958,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,National Ecological Observatory Network -US-xCL,95958,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-xCL,95958,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,neon-ameriflux@battelleecology.org -US-xCL,95958,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xCL,95958,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xCL,95955,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,David Durden -US-xCL,95955,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-xCL,95955,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,ddurden@battelleecology.org -US-xCL,95955,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xCL,95955,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xCL,95954,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Stefan Metzger -US-xCL,95954,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-xCL,95954,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,smetzger@battelleecology.org -US-xCL,95954,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xCL,95954,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xCL,95956,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Christopher Florian -US-xCL,95956,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,BADMContact -US-xCL,95956,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,cflorian@battelleecology.org -US-xCL,95956,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xCL,95956,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xCL,95957,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Cove Sturtevant -US-xCL,95957,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,DataManager -US-xCL,95957,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,csturtevant@battelleecology.org -US-xCL,95957,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xCL,95957,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xCL,79494,GRP_TOWER_POWER,TOWER_POWER,Direct power -US-xCL,79500,GRP_TOWER_TYPE,TOWER_TYPE,walk-up -US-xCL,79505,GRP_URL,URL,http://www.neonscience.org/field-sites/field-sites-map/CLBJ -US-xCL,24000947,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-xCL -US-xCL,79492,GRP_UTC_OFFSET,UTC_OFFSET,-6 -US-xCL,79492,GRP_UTC_OFFSET,UTC_OFFSET_COMMENT,"Central Standard Time (CST), please note that timestamps are converted to local standard time upon submission to AmeriFlux. Data retrieved from the NEON Data Portal will be in UTC time." -US-xCP,30457,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,The National Ecological Observatory Network is a project solely funded by the National Science Foundation and managed under cooperative agreement by Battelle. -US-xCP,30458,GRP_CLIM_AVG,MAT,8.6 -US-xCP,30458,GRP_CLIM_AVG,MAP,320 -US-xCP,30458,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Bsk -US-xCP,27000691,GRP_COUNTRY,COUNTRY,USA -US-xCP,90046,GRP_DOI,DOI,10.17190/AMF/1579720 -US-xCP,90046,GRP_DOI,DOI_CITATION,"NEON (National Ecological Observatory Network) (2022), AmeriFlux BASE US-xCP NEON Central Plains Experimental Range (CPER), Ver. 6-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1579720" -US-xCP,90046,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-xCP,96157,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-xCP,96157,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,NEON (National Ecological Observatory Network) -US-xCP,96157,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-xCP,96157,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,neon-ameriflux@battelleecology.org -US-xCP,96157,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"NEON Program, Battelle" -US-xCP,96157,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,20160101 -US-xCP,96203,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,National Ecological Observatory Network -US-xCP,96203,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-xCP,90018,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,National Science Foundation (NSF) -US-xCP,90018,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-xCP,30459,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Grazing -US-xCP,30462,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-xCP,30462,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-xCP,30462,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20160803 -US-xCP,30462,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-xCP,30460,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-xCP,30460,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-xCP,30460,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20160803 -US-xCP,30460,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-xCP,30461,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Other -US-xCP,30461,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,Isotopes -US-xCP,30461,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20160803 -US-xCP,30461,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-xCP,23000691,GRP_HEADER,SITE_NAME,NEON Central Plains Experimental Range (CPER) -US-xCP,30463,GRP_IGBP,IGBP,GRA -US-xCP,30464,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-xCP,30464,GRP_LAND_OWNERSHIP,LAND_OWNER,United States Department of Agriculture (USDA) -US-xCP,30465,GRP_LOCATION,LOCATION_LAT,40.8155 -US-xCP,30465,GRP_LOCATION,LOCATION_LONG,-104.7456 -US-xCP,30465,GRP_LOCATION,LOCATION_ELEV,1654 -US-xCP,30466,GRP_NETWORK,NETWORK,AmeriFlux -US-xCP,30467,GRP_NETWORK,NETWORK,NEON -US-xCP,87042,GRP_NETWORK,NETWORK,Phenocam -US-xCP,1700005781,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(11), 108350" -US-xCP,1700005781,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -US-xCP,1700005781,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-xCP,1700001662,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Metzger, S., Ayres, E., Durden, D., Florian, C., Lee, R., Lunch, C., Luo, H., Pingintha-Durden, N., Roberti, J. A., SanClements, M., Sturtevant, C., Xu, K., Zulueta, R. C. (2019) From NEON field sites to data portal: a community resource for surface–atmosphere research comes online, Bulletin Of The American Meteorological Society, 100(11), 2305-2325" -US-xCP,1700001662,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1175/BAMS-D-17-0307.1 -US-xCP,1700001662,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-xCP,30468,GRP_SITE_CHAR,WIND_DIRECTION,NW -US-xCP,30469,GRP_SITE_DESC,SITE_DESC,"Central Plains Experimental Range (CPER) site in north central Colorado. CPER served as part of the Shortgrass Steppe LTER from 1982-2014 and is now home to a fully instrumented NEON site and a wealth of relevant historical data as well as ongoing collections of complementary data(i.e. airborne remote sensing, soil temperature and moisture, phenology measurements, plant biomass and more)" -US-xCP,30470,GRP_SITE_FUNDING,SITE_FUNDING,National Science Foundation (NSF) -US-xCP,30471,GRP_STATE,STATE,CO -US-xCP,95962,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,National Ecological Observatory Network -US-xCP,95962,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-xCP,95962,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,neon-ameriflux@battelleecology.org -US-xCP,95962,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xCP,95962,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xCP,95961,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,David Durden -US-xCP,95961,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-xCP,95961,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,ddurden@battelleecology.org -US-xCP,95961,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xCP,95961,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xCP,95959,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Stefan Metzger -US-xCP,95959,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-xCP,95959,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,smetzger@battelleecology.org -US-xCP,95959,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xCP,95959,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xCP,95960,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Christopher Florian -US-xCP,95960,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,BADMContact -US-xCP,95960,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,cflorian@battelleecology.org -US-xCP,95960,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xCP,95960,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xCP,95963,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Cove Sturtevant -US-xCP,95963,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,DataManager -US-xCP,95963,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,csturtevant@battelleecology.org -US-xCP,95963,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xCP,95963,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xCP,30477,GRP_TOWER_POWER,TOWER_POWER,Direct power -US-xCP,30474,GRP_TOWER_TYPE,TOWER_TYPE,walk-up -US-xCP,30475,GRP_URL,URL,http://www.neonscience.org/science-design/field-sites/central-plains-experimental-range -US-xCP,24000691,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-xCP -US-xCP,79379,GRP_UTC_OFFSET,UTC_OFFSET,-7 -US-xCP,79379,GRP_UTC_OFFSET,UTC_OFFSET_COMMENT,"Mountain Standard Time (MST), please note that timestamps are converted to local standard time upon submission to AmeriFlux. Data retrieved from the NEON Data Portal will be in UTC time." -US-xDC,85579,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,The National Ecological Observatory Network is a project solely funded by the National Science Foundation and managed under cooperative agreement by Battelle. -US-xDC,85575,GRP_CLIM_AVG,MAT,4.9 -US-xDC,85575,GRP_CLIM_AVG,MAP,489.74 -US-xDC,85575,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfb -US-xDC,27001027,GRP_COUNTRY,COUNTRY,USA -US-xDC,91681,GRP_DOI,DOI,10.17190/AMF/1617728 -US-xDC,91681,GRP_DOI,DOI_CITATION,"NEON (National Ecological Observatory Network) (2022), AmeriFlux BASE US-xDC NEON Dakota Coteau Field School (DCFS), Ver. 6-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1617728" -US-xDC,91681,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-xDC,96158,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-xDC,96158,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,NEON (National Ecological Observatory Network) -US-xDC,96158,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-xDC,96158,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,neon-ameriflux@battelleecology.org -US-xDC,96158,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"NEON Program, Battelle" -US-xDC,96158,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,20160101 -US-xDC,96204,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,National Ecological Observatory Network -US-xDC,96204,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-xDC,91613,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,National Science Foundation (NSF) -US-xDC,91613,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-xDC,85578,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-xDC,85578,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-xDC,85578,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20170906 -US-xDC,85578,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-xDC,85586,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-xDC,85586,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-xDC,85586,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20170906 -US-xDC,85586,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-xDC,85590,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Other -US-xDC,85590,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,Isotopes -US-xDC,85590,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20170906 -US-xDC,85590,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-xDC,23001027,GRP_HEADER,SITE_NAME,NEON Dakota Coteau Field School (DCFS) -US-xDC,85588,GRP_IGBP,IGBP,GRA -US-xDC,85573,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-xDC,85573,GRP_LAND_OWNERSHIP,LAND_OWNER,State of North Dakota Land Trust -US-xDC,85591,GRP_LOCATION,LOCATION_LAT,47.1617 -US-xDC,85591,GRP_LOCATION,LOCATION_LONG,-99.1066 -US-xDC,85591,GRP_LOCATION,LOCATION_ELEV,559 -US-xDC,85584,GRP_NETWORK,NETWORK,AmeriFlux -US-xDC,85576,GRP_NETWORK,NETWORK,NEON -US-xDC,87043,GRP_NETWORK,NETWORK,Phenocam -US-xDC,1700008640,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Metzger, S., Ayres, E., Durden, D., Florian, C., Lee, R., Lunch, C., Luo, H., Pingintha-Durden, N., Roberti, J. A., SanClements, M., Sturtevant, C., Xu, K., Zulueta, R. C. (2019) From NEON field sites to data portal: a community resource for surface–atmosphere research comes online, Bulletin Of The American Meteorological Society, 100(11), 2305-2325" -US-xDC,1700008640,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1175/BAMS-D-17-0307.1 -US-xDC,1700008640,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-xDC,85572,GRP_SITE_CHAR,WIND_DIRECTION,NW -US-xDC,86427,GRP_SITE_DESC,SITE_DESC,"The Dakota Coteau Field School (DCFS) and Prairie Lake (PRLA) field sites are co-located in an agricultural area used primarily for cattle grazing, just a few miles east of the Woodworth and Prairie Pothole sites at the Chase Lake National Wildlife Refuge. DCFS covers 7.8 km2 (3 square miles) of grazing land in Stutsman County, ND, between the tiny communities of Pingree and Woodworth. - -The population here is sparse, but the land has been transformed by agricultural activities over the last 150 years. The field site has been used only for grazing, but other land in the surrounding area has been converted to corn and soybean production. - -DCFS is located in an area known as the ""Prairie Pothole Region,"" a band of tall and mixed prairie that stretches across parts of North and South Dakota, Minnesota and the Canadian provinces of Alberta, Saskatchewan and Manitoba. Historically, this area supported tall to mid-height prairie grasses, including blue gamma and green needlegrass. The land here is pocked by thousands of depressions left behind by glaciers 10,000 years ago, resulting in a series of small lakes and wetland areas known as prairie potholes. These potholes receive most of their water from spring snowmelt and are a primary source of groundwater recharge for the region. - -NEON data will help researchers monitor the effects of climate change on the Northern Plains ecosystem. Over the last 30 years, the hydrological cycle in the plains has changed dramatically, trending wetter overall and diverging from the historical ten-year cycles. Temperatures are also rising, leading to changes in plant phenology cycles and species distribution that could negatively impact migratory bird populations and other animal species." -US-xDC,85577,GRP_SITE_FUNDING,SITE_FUNDING,National Science Foundation (NSF) -US-xDC,85585,GRP_STATE,STATE,ND -US-xDC,95966,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,National Ecological Observatory Network -US-xDC,95966,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-xDC,95966,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,neon-ameriflux@battelleecology.org -US-xDC,95966,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xDC,95966,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xDC,95968,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,David Durden -US-xDC,95968,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-xDC,95968,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,ddurden@battelleecology.org -US-xDC,95968,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xDC,95968,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xDC,95967,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Stefan Metzger -US-xDC,95967,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-xDC,95967,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,smetzger@battelleecology.org -US-xDC,95967,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xDC,95967,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xDC,95965,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Christopher Florian -US-xDC,95965,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,BADMContact -US-xDC,95965,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,cflorian@battelleecology.org -US-xDC,95965,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xDC,95965,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xDC,95964,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Cove Sturtevant -US-xDC,95964,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,DataManager -US-xDC,95964,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,csturtevant@battelleecology.org -US-xDC,95964,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xDC,95964,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xDC,85582,GRP_TOWER_POWER,TOWER_POWER,Direct power -US-xDC,85583,GRP_TOWER_TYPE,TOWER_TYPE,walk-up -US-xDC,85589,GRP_URL,URL,https://www.neonscience.org/field-sites/field-sites-map/dcfs -US-xDC,24001027,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-xDC -US-xDC,85574,GRP_UTC_OFFSET,UTC_OFFSET,-6 -US-xDC,85574,GRP_UTC_OFFSET,UTC_OFFSET_COMMENT,"Central Standard Time (CST), please note that timestamps are converted to local standard time upon submission to AmeriFlux. Data retrieved from the NEON Data Portal will be in UTC time." -US-xDJ,85568,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,The National Ecological Observatory Network is a project solely funded by the National Science Foundation and managed under cooperative agreement by Battelle. -US-xDJ,85570,GRP_CLIM_AVG,MAT,-2 -US-xDJ,85570,GRP_CLIM_AVG,MAP,300 -US-xDJ,85570,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfc -US-xDJ,27001026,GRP_COUNTRY,COUNTRY,USA -US-xDJ,92875,GRP_DOI,DOI,10.17190/AMF/1634884 -US-xDJ,92875,GRP_DOI,DOI_CITATION,"NEON (National Ecological Observatory Network) (2022), AmeriFlux BASE US-xDJ NEON Delta Junction (DEJU), Ver. 6-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1634884" -US-xDJ,92875,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-xDJ,96159,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-xDJ,96159,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,NEON (National Ecological Observatory Network) -US-xDJ,96159,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-xDJ,96159,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,neon-ameriflux@battelleecology.org -US-xDJ,96159,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"NEON Program, Battelle" -US-xDJ,96159,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,20160101 -US-xDJ,96205,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,National Ecological Observatory Network -US-xDJ,96205,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-xDJ,92843,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,National Science Foundation (NSF) -US-xDJ,92843,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-xDJ,85554,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-xDJ,85554,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-xDJ,85554,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20170307 -US-xDJ,85554,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-xDJ,85560,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-xDJ,85560,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-xDJ,85560,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20170307 -US-xDJ,85560,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-xDJ,85564,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Other -US-xDJ,85564,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,Isotopes -US-xDJ,85564,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20170307 -US-xDJ,85564,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-xDJ,23001026,GRP_HEADER,SITE_NAME,NEON Delta Junction (DEJU) -US-xDJ,85558,GRP_IGBP,IGBP,ENF -US-xDJ,85556,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-xDJ,85556,GRP_LAND_OWNERSHIP,LAND_OWNER,Bureau of Land Management -US-xDJ,85562,GRP_LOCATION,LOCATION_LAT,63.8811 -US-xDJ,85562,GRP_LOCATION,LOCATION_LONG,-145.7514 -US-xDJ,85562,GRP_LOCATION,LOCATION_ELEV,529 -US-xDJ,85555,GRP_NETWORK,NETWORK,AmeriFlux -US-xDJ,85566,GRP_NETWORK,NETWORK,NEON -US-xDJ,87044,GRP_NETWORK,NETWORK,Phenocam -US-xDJ,1700006375,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Metzger, S., Ayres, E., Durden, D., Florian, C., Lee, R., Lunch, C., Luo, H., Pingintha-Durden, N., Roberti, J. A., SanClements, M., Sturtevant, C., Xu, K., Zulueta, R. C. (2019) From NEON field sites to data portal: a community resource for surface–atmosphere research comes online, Bulletin Of The American Meteorological Society, 100(11), 2305-2325" -US-xDJ,1700006375,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1175/BAMS-D-17-0307.1 -US-xDJ,1700006375,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-xDJ,85557,GRP_SITE_CHAR,WIND_DIRECTION,S -US-xDJ,85567,GRP_SITE_FUNDING,SITE_FUNDING,National Science Foundation (NSF) -US-xDJ,85561,GRP_STATE,STATE,AK -US-xDJ,95973,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,National Ecological Observatory Network -US-xDJ,95973,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-xDJ,95973,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,neon-ameriflux@battelleecology.org -US-xDJ,95973,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xDJ,95973,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xDJ,95971,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,David Durden -US-xDJ,95971,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-xDJ,95971,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,ddurden@battelleecology.org -US-xDJ,95971,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xDJ,95971,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xDJ,95972,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Stefan Metzger -US-xDJ,95972,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-xDJ,95972,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,smetzger@battelleecology.org -US-xDJ,95972,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xDJ,95972,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xDJ,95970,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Christopher Florian -US-xDJ,95970,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,BADMContact -US-xDJ,95970,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,cflorian@battelleecology.org -US-xDJ,95970,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xDJ,95970,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xDJ,95969,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Cove Sturtevant -US-xDJ,95969,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,DataManager -US-xDJ,95969,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,csturtevant@battelleecology.org -US-xDJ,95969,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xDJ,95969,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xDJ,85563,GRP_TOWER_POWER,TOWER_POWER,Direct power -US-xDJ,85552,GRP_TOWER_TYPE,TOWER_TYPE,walk-up -US-xDJ,85565,GRP_URL,URL,https://www.neonscience.org/field-sites/field-sites-map/deju -US-xDJ,24001026,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-xDJ -US-xDJ,85571,GRP_UTC_OFFSET,UTC_OFFSET,-9 -US-xDJ,85571,GRP_UTC_OFFSET,UTC_OFFSET_COMMENT,"Alaska Standard Time (AKST), please note that timestamps are converted to local standard time upon submission to AmeriFlux. Data retrieved from the NEON Data Portal will be in UTC time." -US-xDL,85526,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,The National Ecological Observatory Network is a project solely funded by the National Science Foundation and managed under cooperative agreement by Battelle. -US-xDL,85514,GRP_CLIM_AVG,MAT,17.6 -US-xDL,85514,GRP_CLIM_AVG,MAP,1372 -US-xDL,85514,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Cfa -US-xDL,27001025,GRP_COUNTRY,COUNTRY,USA -US-xDL,90048,GRP_DOI,DOI,10.17190/AMF/1579721 -US-xDL,90048,GRP_DOI,DOI_CITATION,"NEON (National Ecological Observatory Network) (2022), AmeriFlux BASE US-xDL NEON Dead Lake (DELA), Ver. 5-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1579721" -US-xDL,90048,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-xDL,96160,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-xDL,96160,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,NEON (National Ecological Observatory Network) -US-xDL,96160,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-xDL,96160,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,neon-ameriflux@battelleecology.org -US-xDL,96160,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"NEON Program, Battelle" -US-xDL,96160,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,20160101 -US-xDL,96206,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,National Ecological Observatory Network -US-xDL,96206,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-xDL,90023,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,National Science Foundation (NSF) -US-xDL,90023,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-xDL,85517,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-xDL,85517,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-xDL,85517,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20170224 -US-xDL,85517,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-xDL,85523,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-xDL,85523,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-xDL,85523,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20170224 -US-xDL,85523,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-xDL,85519,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Other -US-xDL,85519,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,Isotopes -US-xDL,85519,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20170224 -US-xDL,85519,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-xDL,23001025,GRP_HEADER,SITE_NAME,NEON Dead Lake (DELA) -US-xDL,85513,GRP_IGBP,IGBP,MF -US-xDL,85521,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-xDL,85521,GRP_LAND_OWNERSHIP,LAND_OWNER,U.S. Army Corps of Engineers -US-xDL,85529,GRP_LOCATION,LOCATION_LAT,32.5417 -US-xDL,85529,GRP_LOCATION,LOCATION_LONG,-87.8039 -US-xDL,85529,GRP_LOCATION,LOCATION_ELEV,22 -US-xDL,85525,GRP_NETWORK,NETWORK,AmeriFlux -US-xDL,85531,GRP_NETWORK,NETWORK,NEON -US-xDL,87045,GRP_NETWORK,NETWORK,Phenocam -US-xDL,1700006186,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(11), 108350" -US-xDL,1700006186,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -US-xDL,1700006186,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-xDL,1700002013,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Metzger, S., Ayres, E., Durden, D., Florian, C., Lee, R., Lunch, C., Luo, H., Pingintha-Durden, N., Roberti, J. A., SanClements, M., Sturtevant, C., Xu, K., Zulueta, R. C. (2019) From NEON field sites to data portal: a community resource for surface–atmosphere research comes online, Bulletin Of The American Meteorological Society, 100(11), 2305-2325" -US-xDL,1700002013,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1175/BAMS-D-17-0307.1 -US-xDL,1700002013,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-xDL,85520,GRP_SITE_CHAR,WIND_DIRECTION,SW -US-xDL,85518,GRP_SITE_DESC,SITE_DESC,"The Dead Lake site is just northeast of Demopolis, AL near the Black Warrior River. The site is in Major Land Resource Area (MLRA) 133A–Southern Coastal Plains, near the boundary of MLRA 135A–Alabama and Mississippi Blackland Prairie. Surrounded by woody wetlands and evergreen forest, DELA sits on the flood plain steps and stream terraces of an inside meander of the Black Warrior River in Greene Co., AL." -US-xDL,85522,GRP_SITE_FUNDING,SITE_FUNDING,National Science Foundation (NSF) -US-xDL,85524,GRP_STATE,STATE,AL -US-xDL,95975,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,National Ecological Observatory Network -US-xDL,95975,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-xDL,95975,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,neon-ameriflux@battelleecology.org -US-xDL,95975,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xDL,95975,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xDL,95977,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,David Durden -US-xDL,95977,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-xDL,95977,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,ddurden@battelleecology.org -US-xDL,95977,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xDL,95977,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xDL,95978,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Stefan Metzger -US-xDL,95978,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-xDL,95978,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,smetzger@battelleecology.org -US-xDL,95978,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xDL,95978,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xDL,95976,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Christopher Florian -US-xDL,95976,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,BADMContact -US-xDL,95976,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,cflorian@battelleecology.org -US-xDL,95976,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xDL,95976,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xDL,95974,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Cove Sturtevant -US-xDL,95974,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,DataManager -US-xDL,95974,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,csturtevant@battelleecology.org -US-xDL,95974,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xDL,95974,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xDL,85512,GRP_TOWER_POWER,TOWER_POWER,Direct power -US-xDL,85516,GRP_TOWER_TYPE,TOWER_TYPE,walk-up -US-xDL,85530,GRP_URL,URL,https://www.neonscience.org/field-sites/field-sites-map/dela -US-xDL,24001025,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-xDL -US-xDL,85511,GRP_UTC_OFFSET,UTC_OFFSET,-5 -US-xDL,85511,GRP_UTC_OFFSET,UTC_OFFSET_COMMENT,"Eastern Standard Time (EST), please note that timestamps are converted to local standard time upon submission to AmeriFlux. Data retrieved from the NEON Data Portal will be in UTC time." -US-xDS,85507,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,The National Ecological Observatory Network is a project solely funded by the National Science Foundation and managed under cooperative agreement by Battelle. -US-xDS,85508,GRP_CLIM_AVG,MAT,22.5 -US-xDS,85508,GRP_CLIM_AVG,MAP,1216.09 -US-xDS,85508,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Cfa -US-xDS,27001024,GRP_COUNTRY,COUNTRY,USA -US-xDS,94279,GRP_DOI,DOI,10.17190/AMF/1671895 -US-xDS,94279,GRP_DOI,DOI_CITATION,"NEON (National Ecological Observatory Network) (2022), AmeriFlux BASE US-xDS NEON Disney Wilderness Preserve (DSNY), Ver. 5-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1671895" -US-xDS,94279,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-xDS,96161,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-xDS,96161,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,NEON (National Ecological Observatory Network) -US-xDS,96161,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-xDS,96161,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,neon-ameriflux@battelleecology.org -US-xDS,96161,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"NEON Program, Battelle" -US-xDS,96161,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,20160101 -US-xDS,96207,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,National Ecological Observatory Network -US-xDS,96207,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-xDS,94256,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,National Science Foundation (NSF) -US-xDS,94256,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-xDS,85499,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Agriculture -US-xDS,85502,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Fire -US-xDS,85488,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-xDS,85488,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-xDS,85488,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20170221 -US-xDS,85488,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-xDS,85504,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-xDS,85504,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-xDS,85504,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20170221 -US-xDS,85504,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-xDS,85500,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Other -US-xDS,85500,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,Isotopes -US-xDS,85500,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20170221 -US-xDS,85500,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-xDS,23001024,GRP_HEADER,SITE_NAME,NEON Disney Wilderness Preserve (DSNY) -US-xDS,85489,GRP_IGBP,IGBP,CVM -US-xDS,85501,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-xDS,85501,GRP_LAND_OWNERSHIP,LAND_OWNER,The Nature Conservancy -US-xDS,85491,GRP_LOCATION,LOCATION_LAT,28.1250 -US-xDS,85491,GRP_LOCATION,LOCATION_LONG,-81.4362 -US-xDS,85491,GRP_LOCATION,LOCATION_ELEV,15 -US-xDS,85495,GRP_NETWORK,NETWORK,AmeriFlux -US-xDS,85503,GRP_NETWORK,NETWORK,NEON -US-xDS,87046,GRP_NETWORK,NETWORK,Phenocam -US-xDS,1700004071,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Metzger, S., Ayres, E., Durden, D., Florian, C., Lee, R., Lunch, C., Luo, H., Pingintha-Durden, N., Roberti, J. A., SanClements, M., Sturtevant, C., Xu, K., Zulueta, R. C. (2019) From NEON field sites to data portal: a community resource for surface–atmosphere research comes online, Bulletin Of The American Meteorological Society, 100(11), 2305-2325" -US-xDS,1700004071,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1175/BAMS-D-17-0307.1 -US-xDS,1700004071,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-xDS,85497,GRP_SITE_CHAR,WIND_DIRECTION,E -US-xDS,85505,GRP_SITE_DESC,SITE_DESC,"The 12,000-acre Disney Wilderness Preserve straddles the headwaters of the Everglades ecosystem in south-central Florida. This site is seasonally wet and flooded. The Disney site was heavily logged and used as ranchland for decades. However, vegetation and site conditions have been restored to closely represent site condition records, documented by the area’s first Spanish missionaries. The large-scale wetland and upland restoration at Disney included the removal of non-native, invasive plants and grasses and the removal of agricultural ditches. The primary management activity is controlled burns." -US-xDS,85493,GRP_SITE_FUNDING,SITE_FUNDING,National Science Foundation (NSF) -US-xDS,85506,GRP_STATE,STATE,FL -US-xDS,95982,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,National Ecological Observatory Network -US-xDS,95982,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-xDS,95982,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,neon-ameriflux@battelleecology.org -US-xDS,95982,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xDS,95982,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xDS,95979,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,David Durden -US-xDS,95979,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-xDS,95979,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,ddurden@battelleecology.org -US-xDS,95979,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xDS,95979,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xDS,95980,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Stefan Metzger -US-xDS,95980,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-xDS,95980,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,smetzger@battelleecology.org -US-xDS,95980,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xDS,95980,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xDS,95981,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Christopher Florian -US-xDS,95981,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,BADMContact -US-xDS,95981,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,cflorian@battelleecology.org -US-xDS,95981,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xDS,95981,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xDS,95983,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Cove Sturtevant -US-xDS,95983,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,DataManager -US-xDS,95983,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,csturtevant@battelleecology.org -US-xDS,95983,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xDS,95983,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xDS,85496,GRP_TOWER_POWER,TOWER_POWER,Direct power -US-xDS,85510,GRP_TOWER_TYPE,TOWER_TYPE,walk-up -US-xDS,85494,GRP_URL,URL,https://www.neonscience.org/field-sites/field-sites-map/DSNY -US-xDS,24001024,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-xDS -US-xDS,85490,GRP_UTC_OFFSET,UTC_OFFSET,-5 -US-xDS,85490,GRP_UTC_OFFSET,UTC_OFFSET_COMMENT,"Eastern Standard Time (EST), please note that timestamps are converted to local standard time upon submission to AmeriFlux. Data retrieved from the NEON Data Portal will be in UTC time." -US-xGR,85469,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,The National Ecological Observatory Network is a project solely funded by the National Science Foundation and managed under cooperative agreement by Battelle. -US-xGR,85467,GRP_CLIM_AVG,MAT,13.1 -US-xGR,85467,GRP_CLIM_AVG,MAP,1375 -US-xGR,85467,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Cfa -US-xGR,27001023,GRP_COUNTRY,COUNTRY,USA -US-xGR,92866,GRP_DOI,DOI,10.17190/AMF/1634885 -US-xGR,92866,GRP_DOI,DOI_CITATION,"NEON (National Ecological Observatory Network) (2022), AmeriFlux BASE US-xGR NEON Great Smoky Mountains National Park, Twin Creeks (GRSM), Ver. 5-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1634885" -US-xGR,92866,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-xGR,96162,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-xGR,96162,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,NEON (National Ecological Observatory Network) -US-xGR,96162,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-xGR,96162,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,neon-ameriflux@battelleecology.org -US-xGR,96162,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"NEON Program, Battelle" -US-xGR,96162,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,20160101 -US-xGR,96208,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,National Ecological Observatory Network -US-xGR,96208,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-xGR,92842,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,National Science Foundation (NSF) -US-xGR,92842,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-xGR,85483,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-xGR,85483,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-xGR,85483,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20171019 -US-xGR,85483,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-xGR,85471,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-xGR,85471,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-xGR,85471,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20171019 -US-xGR,85471,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-xGR,85486,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Other -US-xGR,85486,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,Isotopes -US-xGR,85486,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20171019 -US-xGR,85486,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-xGR,23001023,GRP_HEADER,SITE_NAME,"NEON Great Smoky Mountains National Park, Twin Creeks (GRSM)" -US-xGR,85474,GRP_IGBP,IGBP,DBF -US-xGR,85485,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-xGR,85485,GRP_LAND_OWNERSHIP,LAND_OWNER,National Park Service -US-xGR,85476,GRP_LOCATION,LOCATION_LAT,35.6890 -US-xGR,85476,GRP_LOCATION,LOCATION_LONG,-83.5019 -US-xGR,85476,GRP_LOCATION,LOCATION_ELEV,579 -US-xGR,85477,GRP_NETWORK,NETWORK,AmeriFlux -US-xGR,85480,GRP_NETWORK,NETWORK,NEON -US-xGR,87047,GRP_NETWORK,NETWORK,Phenocam -US-xGR,1700002955,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Metzger, S., Ayres, E., Durden, D., Florian, C., Lee, R., Lunch, C., Luo, H., Pingintha-Durden, N., Roberti, J. A., SanClements, M., Sturtevant, C., Xu, K., Zulueta, R. C. (2019) From NEON field sites to data portal: a community resource for surface–atmosphere research comes online, Bulletin Of The American Meteorological Society, 100(11), 2305-2325" -US-xGR,1700002955,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1175/BAMS-D-17-0307.1 -US-xGR,1700002955,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-xGR,85479,GRP_SITE_CHAR,WIND_DIRECTION,SW -US-xGR,85481,GRP_SITE_DESC,SITE_DESC,"Great Smoky Mountains National Park straddles the ridgeline of the Great Smoky Mountains, the lower section in latitude of the Blue Ridge Mountains, which divides the larger Appalachian Mountain chain. The border between Tennessee and North Carolina runs northeast to southwest through the centerline of the park. Plants and animals common in the country's Northeast have found suitable ecological niches in the park's higher elevations, while southern species find homes in the balmier lower reaches." -US-xGR,85475,GRP_SITE_FUNDING,SITE_FUNDING,National Science Foundation (NSF) -US-xGR,85484,GRP_STATE,STATE,TN -US-xGR,95985,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,National Ecological Observatory Network -US-xGR,95985,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-xGR,95985,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,neon-ameriflux@battelleecology.org -US-xGR,95985,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xGR,95985,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xGR,95986,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,David Durden -US-xGR,95986,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-xGR,95986,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,ddurden@battelleecology.org -US-xGR,95986,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xGR,95986,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xGR,95988,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Stefan Metzger -US-xGR,95988,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-xGR,95988,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,smetzger@battelleecology.org -US-xGR,95988,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xGR,95988,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xGR,95984,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Christopher Florian -US-xGR,95984,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,BADMContact -US-xGR,95984,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,cflorian@battelleecology.org -US-xGR,95984,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xGR,95984,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xGR,95987,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Cove Sturtevant -US-xGR,95987,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,DataManager -US-xGR,95987,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,csturtevant@battelleecology.org -US-xGR,95987,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xGR,95987,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xGR,85472,GRP_TOWER_POWER,TOWER_POWER,Direct power -US-xGR,85487,GRP_TOWER_TYPE,TOWER_TYPE,walk-up -US-xGR,85478,GRP_URL,URL,https://www.neonscience.org/field-sites/field-sites-map/grsm -US-xGR,24001023,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-xGR -US-xGR,85482,GRP_UTC_OFFSET,UTC_OFFSET,-5 -US-xGR,85482,GRP_UTC_OFFSET,UTC_OFFSET_COMMENT,"Eastern Standard Time (EST), please note that timestamps are converted to local standard time upon submission to AmeriFlux. Data retrieved from the NEON Data Portal will be in UTC time." -US-xHA,79785,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,The National Ecological Observatory Network is a project solely funded by the National Science Foundation and managed under cooperative agreement by Battelle. -US-xHA,79802,GRP_CLIM_AVG,MAT,6.62 -US-xHA,79802,GRP_CLIM_AVG,MAP,1071 -US-xHA,79802,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfb -US-xHA,27000960,GRP_COUNTRY,COUNTRY,USA -US-xHA,87987,GRP_DOI,DOI,10.17190/AMF/1562391 -US-xHA,87987,GRP_DOI,DOI_CITATION,"NEON (National Ecological Observatory Network) (2022), AmeriFlux BASE US-xHA NEON Harvard Forest (HARV), Ver. 6-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1562391" -US-xHA,87987,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-xHA,96163,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-xHA,96163,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,NEON (National Ecological Observatory Network) -US-xHA,96163,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-xHA,96163,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,neon-ameriflux@battelleecology.org -US-xHA,96163,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"NEON Program, Battelle" -US-xHA,96163,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,20160101 -US-xHA,96209,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,National Ecological Observatory Network -US-xHA,96209,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-xHA,87967,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,National Science Foundation (NSF) -US-xHA,87967,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-xHA,79795,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Forestry -US-xHA,79796,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-xHA,79796,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-xHA,79796,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20170308 -US-xHA,79796,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-xHA,79789,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-xHA,79789,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-xHA,79789,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20170308 -US-xHA,79789,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-xHA,79791,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Other -US-xHA,79791,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,Isotopes -US-xHA,79791,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20170308 -US-xHA,79791,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-xHA,23000960,GRP_HEADER,SITE_NAME,NEON Harvard Forest (HARV) -US-xHA,79781,GRP_IGBP,IGBP,DBF -US-xHA,79784,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -US-xHA,79784,GRP_LAND_OWNERSHIP,LAND_OWNER,Harvard University -US-xHA,81383,GRP_LOCATION,LOCATION_LAT,42.5369 -US-xHA,81383,GRP_LOCATION,LOCATION_LONG,-72.1727 -US-xHA,81383,GRP_LOCATION,LOCATION_ELEV,351 -US-xHA,79801,GRP_NETWORK,NETWORK,AmeriFlux -US-xHA,79783,GRP_NETWORK,NETWORK,NEON -US-xHA,87048,GRP_NETWORK,NETWORK,Phenocam -US-xHA,1700006615,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(11), 108350" -US-xHA,1700006615,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -US-xHA,1700006615,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-xHA,1700001842,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Metzger, S., Ayres, E., Durden, D., Florian, C., Lee, R., Lunch, C., Luo, H., Pingintha-Durden, N., Roberti, J. A., SanClements, M., Sturtevant, C., Xu, K., Zulueta, R. C. (2019) From NEON field sites to data portal: a community resource for surface–atmosphere research comes online, Bulletin Of The American Meteorological Society, 100(11), 2305-2325" -US-xHA,1700001842,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1175/BAMS-D-17-0307.1 -US-xHA,1700001842,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-xHA,79782,GRP_SITE_CHAR,WIND_DIRECTION,NW -US-xHA,79794,GRP_SITE_DESC,SITE_DESC,"The Harvard Forest site is comprised of 3,750 acres of land and multiple research facilities; it is the core NEON site for the Northeast region. Harvard Forest is a department of the Faculty of Arts and Sciences of Harvard University. Representative habitats at Harvard Forest include northern, transition, and central forests; marshes, swamps, and conifer-dominated bogs; and forest plantations. Since its inception in 1907, research and education have been the focus of Harvard Forest: the original purpose was to develop a field laboratory for students, a research center in forestry and related disciplines, and a demonstration of practical sustained forestry. Since 1988, Harvard Forest has been a Long-Term Ecological Research site, funded by the National Science Foundation to conduct integrated, long-term studies of forest dynamics." -US-xHA,79792,GRP_SITE_FUNDING,SITE_FUNDING,National Science Foundation (NSF) -US-xHA,79788,GRP_STATE,STATE,MA -US-xHA,95990,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,National Ecological Observatory Network -US-xHA,95990,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-xHA,95990,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,neon-ameriflux@battelleecology.org -US-xHA,95990,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xHA,95990,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xHA,95992,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,David Durden -US-xHA,95992,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-xHA,95992,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,ddurden@battelleecology.org -US-xHA,95992,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xHA,95992,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xHA,95989,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Stefan Metzger -US-xHA,95989,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-xHA,95989,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,smetzger@battelleecology.org -US-xHA,95989,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xHA,95989,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xHA,95993,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Christopher Florian -US-xHA,95993,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,BADMContact -US-xHA,95993,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,cflorian@battelleecology.org -US-xHA,95993,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xHA,95993,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xHA,95991,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Cove Sturtevant -US-xHA,95991,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,DataManager -US-xHA,95991,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,csturtevant@battelleecology.org -US-xHA,95991,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xHA,95991,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xHA,79787,GRP_TOWER_POWER,TOWER_POWER,Direct power -US-xHA,79790,GRP_TOWER_TYPE,TOWER_TYPE,walk-up -US-xHA,79800,GRP_URL,URL,http://www.neonscience.org/field-sites/field-sites-map/HARV -US-xHA,24000960,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-xHA -US-xHA,79793,GRP_UTC_OFFSET,UTC_OFFSET,-5 -US-xHA,79793,GRP_UTC_OFFSET,UTC_OFFSET_COMMENT,"Eastern Standard Time (EST), please note that timestamps are converted to local standard time upon submission to AmeriFlux. Data retrieved from the NEON Data Portal will be in UTC time." -US-xHE,85463,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,The National Ecological Observatory Network is a project solely funded by the National Science Foundation and managed under cooperative agreement by Battelle. -US-xHE,85448,GRP_CLIM_AVG,MAT,-4 -US-xHE,85448,GRP_CLIM_AVG,MAP,320 -US-xHE,85448,GRP_CLIM_AVG,CLIMATE_KOEPPEN,ET -US-xHE,27001022,GRP_COUNTRY,COUNTRY,USA -US-xHE,91688,GRP_DOI,DOI,10.17190/AMF/1617729 -US-xHE,91688,GRP_DOI,DOI_CITATION,"NEON (National Ecological Observatory Network) (2022), AmeriFlux BASE US-xHE NEON Healy (HEAL), Ver. 5-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1617729" -US-xHE,91688,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-xHE,96164,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-xHE,96164,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,NEON (National Ecological Observatory Network) -US-xHE,96164,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-xHE,96164,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,neon-ameriflux@battelleecology.org -US-xHE,96164,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"NEON Program, Battelle" -US-xHE,96164,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,20160101 -US-xHE,96210,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,National Ecological Observatory Network -US-xHE,96210,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-xHE,91615,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,National Science Foundation -US-xHE,91615,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-xHE,85451,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-xHE,85451,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-xHE,85451,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20170815 -US-xHE,85451,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-xHE,85453,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-xHE,85453,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-xHE,85453,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20170815 -US-xHE,85453,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-xHE,85465,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Other -US-xHE,85465,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,Isotopes -US-xHE,85465,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20170815 -US-xHE,85465,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-xHE,23001022,GRP_HEADER,SITE_NAME,NEON Healy (HEAL) -US-xHE,85447,GRP_IGBP,IGBP,OSH -US-xHE,85461,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-xHE,85461,GRP_LAND_OWNERSHIP,LAND_OWNER,Alaska Department of Natural Resources -US-xHE,85455,GRP_LOCATION,LOCATION_LAT,63.8757 -US-xHE,85455,GRP_LOCATION,LOCATION_LONG,-149.2133 -US-xHE,85455,GRP_LOCATION,LOCATION_ELEV,705 -US-xHE,85450,GRP_NETWORK,NETWORK,AmeriFlux -US-xHE,85462,GRP_NETWORK,NETWORK,NEON -US-xHE,87049,GRP_NETWORK,NETWORK,Phenocam -US-xHE,1700005097,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Metzger, S., Ayres, E., Durden, D., Florian, C., Lee, R., Lunch, C., Luo, H., Pingintha-Durden, N., Roberti, J. A., SanClements, M., Sturtevant, C., Xu, K., Zulueta, R. C. (2019) From NEON field sites to data portal: a community resource for surface–atmosphere research comes online, Bulletin Of The American Meteorological Society, 100(11), 2305-2325" -US-xHE,1700005097,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1175/BAMS-D-17-0307.1 -US-xHE,1700005097,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-xHE,85464,GRP_SITE_CHAR,WIND_DIRECTION,SW -US-xHE,85459,GRP_SITE_FUNDING,SITE_FUNDING,National Science Foundation -US-xHE,85452,GRP_STATE,STATE,AK -US-xHE,95997,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,National Ecological Observatory Network -US-xHE,95997,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-xHE,95997,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,neon-ameriflux@battelleecology.org -US-xHE,95997,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xHE,95997,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xHE,95995,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,David Durden -US-xHE,95995,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-xHE,95995,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,ddurden@battelleecology.org -US-xHE,95995,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xHE,95995,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xHE,95994,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Stefan Metzger -US-xHE,95994,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-xHE,95994,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,smetzger@battelleecology.org -US-xHE,95994,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xHE,95994,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xHE,95996,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Christopher Florian -US-xHE,95996,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,BADMContact -US-xHE,95996,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,cflorian@battelleecology.org -US-xHE,95996,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xHE,95996,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xHE,95998,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Cove Sturtevant -US-xHE,95998,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,DataManager -US-xHE,95998,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,csturtevant@battelleecology.org -US-xHE,95998,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xHE,95998,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xHE,85454,GRP_TOWER_POWER,TOWER_POWER,Direct power -US-xHE,85458,GRP_TOWER_TYPE,TOWER_TYPE,walk-up -US-xHE,85456,GRP_URL,URL,https://www.neonscience.org/field-sites/field-sites-map/HEAL -US-xHE,24001022,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-xHE -US-xHE,85457,GRP_UTC_OFFSET,UTC_OFFSET,-9 -US-xHE,85457,GRP_UTC_OFFSET,UTC_OFFSET_COMMENT,"Alaska Standard Time (AKST), please note that timestamps are converted to local standard time upon submission to AmeriFlux. Data retrieved from the NEON Data Portal will be in UTC time." -US-xJE,81964,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,The National Ecological Observatory Network is a project solely funded by the National Science Foundation and managed under cooperative agreement by Battelle. -US-xJE,81961,GRP_CLIM_AVG,MAT,19.2 -US-xJE,81961,GRP_CLIM_AVG,MAP,1307.97 -US-xJE,81961,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Cfa -US-xJE,27000975,GRP_COUNTRY,COUNTRY,USA -US-xJE,91712,GRP_DOI,DOI,10.17190/AMF/1617730 -US-xJE,91712,GRP_DOI,DOI_CITATION,"NEON (National Ecological Observatory Network) (2022), AmeriFlux BASE US-xJE NEON Jones Ecological Research Center (JERC), Ver. 5-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1617730" -US-xJE,91712,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-xJE,96165,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-xJE,96165,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,NEON (National Ecological Observatory Network) -US-xJE,96165,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-xJE,96165,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,neon-ameriflux@battelleecology.org -US-xJE,96165,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"NEON Program, Battelle" -US-xJE,96165,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,20160101 -US-xJE,96211,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,National Ecological Observatory Network -US-xJE,96211,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-xJE,91608,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,National Science Foundation (NSF) -US-xJE,91608,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-xJE,81954,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Fire -US-xJE,81951,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-xJE,81951,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-xJE,81951,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20170113 -US-xJE,81951,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-xJE,81949,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-xJE,81949,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-xJE,81949,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20170113 -US-xJE,81949,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-xJE,23000975,GRP_HEADER,SITE_NAME,NEON Jones Ecological Research Center (JERC) -US-xJE,81962,GRP_IGBP,IGBP,ENF -US-xJE,81966,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -US-xJE,81966,GRP_LAND_OWNERSHIP,LAND_OWNER,Private Owner -US-xJE,81955,GRP_LOCATION,LOCATION_LAT,31.1948 -US-xJE,81955,GRP_LOCATION,LOCATION_LONG,-84.4686 -US-xJE,81955,GRP_LOCATION,LOCATION_ELEV,44 -US-xJE,81952,GRP_NETWORK,NETWORK,AmeriFlux -US-xJE,81953,GRP_NETWORK,NETWORK,NEON -US-xJE,87050,GRP_NETWORK,NETWORK,Phenocam -US-xJE,1700007941,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Metzger, S., Ayres, E., Durden, D., Florian, C., Lee, R., Lunch, C., Luo, H., Pingintha-Durden, N., Roberti, J. A., SanClements, M., Sturtevant, C., Xu, K., Zulueta, R. C. (2019) From NEON field sites to data portal: a community resource for surface–atmosphere research comes online, Bulletin Of The American Meteorological Society, 100(11), 2305-2325" -US-xJE,1700007941,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1175/BAMS-D-17-0307.1 -US-xJE,1700007941,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-xJE,81965,GRP_SITE_CHAR,WIND_DIRECTION,NE -US-xJE,81963,GRP_SITE_DESC,SITE_DESC,"This terrestrial relocatable field site is located in the Joseph Jones Ecological Research Center is an 11,000-hectare reserve located within the Lower Coastal Plains and Flatwoods areas in southern Georgia. The Jones site has been managed with low intensity, dormant-season prescribed fires for the past 75 years at a frequency of every 3-4 years." -US-xJE,81957,GRP_SITE_FUNDING,SITE_FUNDING,National Science Foundation (NSF) -US-xJE,81947,GRP_STATE,STATE,GA -US-xJE,96002,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,National Ecological Observatory Network -US-xJE,96002,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-xJE,96002,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,neon-ameriflux@battelleecology.org -US-xJE,96002,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xJE,96002,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xJE,96000,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,David Durden -US-xJE,96000,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-xJE,96000,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,ddurden@battelleecology.org -US-xJE,96000,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xJE,96000,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xJE,95999,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Stefan Metzger -US-xJE,95999,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-xJE,95999,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,smetzger@battelleecology.org -US-xJE,95999,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xJE,95999,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xJE,96003,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Christopher Florian -US-xJE,96003,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,BADMContact -US-xJE,96003,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,cflorian@battelleecology.org -US-xJE,96003,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xJE,96003,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xJE,96001,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Cove Sturtevant -US-xJE,96001,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,DataManager -US-xJE,96001,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,csturtevant@battelleecology.org -US-xJE,96001,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xJE,96001,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xJE,81956,GRP_TOWER_POWER,TOWER_POWER,Direct power -US-xJE,81959,GRP_TOWER_TYPE,TOWER_TYPE,walk-up -US-xJE,81967,GRP_URL,URL,http://www.neonscience.org/field-sites/field-sites-map/JERC -US-xJE,24000975,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-xJE -US-xJE,81948,GRP_UTC_OFFSET,UTC_OFFSET,-5 -US-xJE,81948,GRP_UTC_OFFSET,UTC_OFFSET_COMMENT,"Eastern Standard Time (EST), please note that timestamps are converted to local standard time upon submission to AmeriFlux. Data retrieved from the NEON Data Portal will be in UTC time." -US-xJR,85437,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,The National Ecological Observatory Network is a project solely funded by the National Science Foundation and managed under cooperative agreement by Battelle. -US-xJR,85900,GRP_CLIM_AVG,MAT,15.7 -US-xJR,85900,GRP_CLIM_AVG,MAP,271.33 -US-xJR,85900,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Bsk -US-xJR,27001021,GRP_COUNTRY,COUNTRY,USA -US-xJR,91685,GRP_DOI,DOI,10.17190/AMF/1617731 -US-xJR,91685,GRP_DOI,DOI_CITATION,"NEON (National Ecological Observatory Network) (2022), AmeriFlux BASE US-xJR NEON Jornada LTER (JORN), Ver. 5-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1617731" -US-xJR,91685,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-xJR,96166,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-xJR,96166,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,NEON (National Ecological Observatory Network) -US-xJR,96166,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-xJR,96166,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,neon-ameriflux@battelleecology.org -US-xJR,96166,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"NEON Program, Battelle" -US-xJR,96166,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,20160101 -US-xJR,96212,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,National Ecological Observatory Network -US-xJR,96212,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-xJR,91606,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,National Science Foundation (NSF) -US-xJR,91606,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-xJR,85445,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Grazing -US-xJR,85427,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-xJR,85427,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-xJR,85427,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20170911 -US-xJR,85427,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-xJR,85433,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-xJR,85433,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-xJR,85433,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20170911 -US-xJR,85433,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-xJR,85444,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Other -US-xJR,85444,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,Isotopes -US-xJR,85444,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20170911 -US-xJR,85444,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-xJR,23001021,GRP_HEADER,SITE_NAME,NEON Jornada LTER (JORN) -US-xJR,85441,GRP_IGBP,IGBP,OSH -US-xJR,85428,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-xJR,85428,GRP_LAND_OWNERSHIP,LAND_OWNER,"U.S. Department of Agriculture, Agricultural Research Service" -US-xJR,85430,GRP_LOCATION,LOCATION_LAT,32.5907 -US-xJR,85430,GRP_LOCATION,LOCATION_LONG,-106.8425 -US-xJR,85430,GRP_LOCATION,LOCATION_ELEV,1329 -US-xJR,85442,GRP_NETWORK,NETWORK,AmeriFlux -US-xJR,85431,GRP_NETWORK,NETWORK,NEON -US-xJR,87051,GRP_NETWORK,NETWORK,Phenocam -US-xJR,1700007833,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Metzger, S., Ayres, E., Durden, D., Florian, C., Lee, R., Lunch, C., Luo, H., Pingintha-Durden, N., Roberti, J. A., SanClements, M., Sturtevant, C., Xu, K., Zulueta, R. C. (2019) From NEON field sites to data portal: a community resource for surface–atmosphere research comes online, Bulletin Of The American Meteorological Society, 100(11), 2305-2325" -US-xJR,1700007833,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1175/BAMS-D-17-0307.1 -US-xJR,1700007833,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-xJR,85434,GRP_SITE_CHAR,WIND_DIRECTION,SW -US-xJR,85443,GRP_SITE_DESC,SITE_DESC,"Land use at Jornada has contrasting livestock grazing histories (including ungrazed lands), dating back to 1902, which are representative of the pervasive land use in desert-southwest wildlands. Historical accounts of the region report significant changes in vegetation starting in the late 1800s coincident with the expansion of livestock grazing. By 1912, sufficiently dramatic changes lead area scientists and private landowners to convince the U.S. government to set aside Public Domain Lands for the Jornada Range Reserve for the purpose of scientific investigation on shrub invasion and subsequent loss of forage grasses. Much of this early research focused on quantifying utilization levels for forage species, developing livestock production strategies to deal with drought, and developing methods for shrub control and grass recovery. Exclosures were constructed and long-term plots were established throughout the range to monitor the continued expansion of shrubs across the landscape. Over the decades, numerous trials of various remediation approaches were implemented, from manual and mechanical shrub removal to herbicide application to construction of terraces or other means of redirecting surface flow of runoff. " -US-xJR,85425,GRP_SITE_FUNDING,SITE_FUNDING,National Science Foundation (NSF) -US-xJR,85436,GRP_STATE,STATE,NM -US-xJR,96005,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,National Ecological Observatory Network -US-xJR,96005,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-xJR,96005,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,neon-ameriflux@battelleecology.org -US-xJR,96005,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xJR,96005,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xJR,96006,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,David Durden -US-xJR,96006,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-xJR,96006,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,ddurden@battelleecology.org -US-xJR,96006,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xJR,96006,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xJR,96004,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Stefan Metzger -US-xJR,96004,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-xJR,96004,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,smetzger@battelleecology.org -US-xJR,96004,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xJR,96004,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xJR,96007,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Christopher Florian -US-xJR,96007,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,BADMContact -US-xJR,96007,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,cflorian@battelleecology.org -US-xJR,96007,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xJR,96007,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xJR,96008,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Cove Sturtevant -US-xJR,96008,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,DataManager -US-xJR,96008,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,csturtevant@battelleecology.org -US-xJR,96008,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xJR,96008,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xJR,85439,GRP_TOWER_POWER,TOWER_POWER,Direct power -US-xJR,85429,GRP_TOWER_TYPE,TOWER_TYPE,walk-up -US-xJR,85426,GRP_URL,URL,https://www.neonscience.org/field-sites/field-sites-map/JORN -US-xJR,24001021,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-xJR -US-xJR,85446,GRP_UTC_OFFSET,UTC_OFFSET,-7 -US-xJR,85446,GRP_UTC_OFFSET,UTC_OFFSET_COMMENT,"Mountain Standard Time (MST), please note that timestamps are converted to local standard time upon submission to AmeriFlux. Data retrieved from the NEON Data Portal will be in UTC time." -US-xKA,85421,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,The National Ecological Observatory Network is a project solely funded by the National Science Foundation and managed under cooperative agreement by Battelle. -US-xKA,85418,GRP_CLIM_AVG,MAT,12.7 -US-xKA,85418,GRP_CLIM_AVG,MAP,850.63 -US-xKA,85418,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Cfa -US-xKA,27001020,GRP_COUNTRY,COUNTRY,USA -US-xKA,90052,GRP_DOI,DOI,10.17190/AMF/1579722 -US-xKA,90052,GRP_DOI,DOI_CITATION,"NEON (National Ecological Observatory Network) (2022), AmeriFlux BASE US-xKA NEON Konza Prairie Biological Station - Relocatable (KONA), Ver. 5-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1579722" -US-xKA,90052,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-xKA,96167,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-xKA,96167,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,NEON (National Ecological Observatory Network) -US-xKA,96167,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-xKA,96167,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,neon-ameriflux@battelleecology.org -US-xKA,96167,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"NEON Program, Battelle" -US-xKA,96167,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,20160101 -US-xKA,96213,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,National Ecological Observatory Network -US-xKA,96213,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-xKA,90022,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,National Science Foundation (NSF) -US-xKA,90022,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-xKA,85405,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Fire -US-xKA,85407,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Grazing -US-xKA,85406,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-xKA,85406,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-xKA,85406,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20170818 -US-xKA,85406,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-xKA,85417,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-xKA,85417,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-xKA,85417,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20170818 -US-xKA,85417,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-xKA,85419,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Other -US-xKA,85419,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,Isotopes -US-xKA,85419,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20170818 -US-xKA,85419,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-xKA,23001020,GRP_HEADER,SITE_NAME,NEON Konza Prairie Biological Station - Relocatable (KONA) -US-xKA,85412,GRP_IGBP,IGBP,GRA -US-xKA,85404,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-xKA,85404,GRP_LAND_OWNERSHIP,LAND_OWNER,"The Nature Conservancy, Kansas State University" -US-xKA,85411,GRP_LOCATION,LOCATION_LAT,39.1104 -US-xKA,85411,GRP_LOCATION,LOCATION_LONG,-96.6129 -US-xKA,85411,GRP_LOCATION,LOCATION_ELEV,1329 -US-xKA,85420,GRP_NETWORK,NETWORK,AmeriFlux -US-xKA,85413,GRP_NETWORK,NETWORK,NEON -US-xKA,87052,GRP_NETWORK,NETWORK,Phenocam -US-xKA,1700003270,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(11), 108350" -US-xKA,1700003270,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -US-xKA,1700003270,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-xKA,1700003432,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Metzger, S., Ayres, E., Durden, D., Florian, C., Lee, R., Lunch, C., Luo, H., Pingintha-Durden, N., Roberti, J. A., SanClements, M., Sturtevant, C., Xu, K., Zulueta, R. C. (2019) From NEON field sites to data portal: a community resource for surface–atmosphere research comes online, Bulletin Of The American Meteorological Society, 100(11), 2305-2325" -US-xKA,1700003432,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1175/BAMS-D-17-0307.1 -US-xKA,1700003432,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-xKA,85403,GRP_SITE_CHAR,WIND_DIRECTION,SSW -US-xKA,85408,GRP_SITE_DESC,SITE_DESC,"Konza Prairie Biological Station (KPBS) was established to provide a ""natural laboratory"" to conduct ecological research and is located on a 3,487 hectare native tallgrass prairie preserve." -US-xKA,85409,GRP_SITE_FUNDING,SITE_FUNDING,National Science Foundation (NSF) -US-xKA,85424,GRP_STATE,STATE,KS -US-xKA,96011,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,National Ecological Observatory Network -US-xKA,96011,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-xKA,96011,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,neon-ameriflux@battelleecology.org -US-xKA,96011,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xKA,96011,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xKA,96010,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,David Durden -US-xKA,96010,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-xKA,96010,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,ddurden@battelleecology.org -US-xKA,96010,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xKA,96010,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xKA,96009,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Stefan Metzger -US-xKA,96009,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-xKA,96009,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,smetzger@battelleecology.org -US-xKA,96009,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xKA,96009,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xKA,96013,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Christopher Florian -US-xKA,96013,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,BADMContact -US-xKA,96013,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,cflorian@battelleecology.org -US-xKA,96013,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xKA,96013,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xKA,96012,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Cove Sturtevant -US-xKA,96012,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,DataManager -US-xKA,96012,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,csturtevant@battelleecology.org -US-xKA,96012,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xKA,96012,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xKA,85402,GRP_TOWER_POWER,TOWER_POWER,Direct power -US-xKA,85415,GRP_TOWER_TYPE,TOWER_TYPE,walk-up -US-xKA,85416,GRP_URL,URL,https://www.neonscience.org/field-sites/field-sites-map/kona -US-xKA,24001020,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-xKA -US-xKA,85423,GRP_UTC_OFFSET,UTC_OFFSET,-6 -US-xKA,85423,GRP_UTC_OFFSET,UTC_OFFSET_COMMENT,"Central Standard Time (CST), please note that timestamps are converted to local standard time upon submission to AmeriFlux. Data retrieved from the NEON Data Portal will be in UTC time." -US-xKZ,79310,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,The National Ecological Observatory Network is a project solely funded by the National Science Foundation and managed under cooperative agreement by Battelle. -US-xKZ,79311,GRP_CLIM_AVG,MAT,12.4 -US-xKZ,79311,GRP_CLIM_AVG,MAP,870.38 -US-xKZ,79311,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Cfa -US-xKZ,27000944,GRP_COUNTRY,COUNTRY,USA -US-xKZ,87988,GRP_DOI,DOI,10.17190/AMF/1562392 -US-xKZ,87988,GRP_DOI,DOI_CITATION,"NEON (National Ecological Observatory Network) (2022), AmeriFlux BASE US-xKZ NEON Konza Prairie Biological Station (KONZ), Ver. 6-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1562392" -US-xKZ,87988,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-xKZ,96168,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-xKZ,96168,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,NEON (National Ecological Observatory Network) -US-xKZ,96168,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-xKZ,96168,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,neon-ameriflux@battelleecology.org -US-xKZ,96168,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"NEON Program, Battelle" -US-xKZ,96168,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,20160101 -US-xKZ,96214,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,National Ecological Observatory Network -US-xKZ,96214,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-xKZ,87972,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,National Science Foundation (NSF) -US-xKZ,87972,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-xKZ,79313,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Fire -US-xKZ,79312,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Grazing -US-xKZ,79314,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-xKZ,79314,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-xKZ,79314,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20170825 -US-xKZ,79314,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-xKZ,79316,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-xKZ,79316,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-xKZ,79316,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20170825 -US-xKZ,79316,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-xKZ,79315,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Other -US-xKZ,79315,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,Isotopes -US-xKZ,79315,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20170825 -US-xKZ,79315,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-xKZ,23000944,GRP_HEADER,SITE_NAME,NEON Konza Prairie Biological Station (KONZ) -US-xKZ,79317,GRP_IGBP,IGBP,GRA -US-xKZ,79318,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-xKZ,79318,GRP_LAND_OWNERSHIP,LAND_OWNER,"The Nature Conservancy, Kansas State University, LTER" -US-xKZ,79319,GRP_LOCATION,LOCATION_LAT,39.1008 -US-xKZ,79319,GRP_LOCATION,LOCATION_LONG,-96.5631 -US-xKZ,79319,GRP_LOCATION,LOCATION_ELEV,381 -US-xKZ,79320,GRP_NETWORK,NETWORK,AmeriFlux -US-xKZ,79321,GRP_NETWORK,NETWORK,NEON -US-xKZ,87053,GRP_NETWORK,NETWORK,Phenocam -US-xKZ,1700002781,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(11), 108350" -US-xKZ,1700002781,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -US-xKZ,1700002781,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-xKZ,1700008550,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Metzger, S., Ayres, E., Durden, D., Florian, C., Lee, R., Lunch, C., Luo, H., Pingintha-Durden, N., Roberti, J. A., SanClements, M., Sturtevant, C., Xu, K., Zulueta, R. C. (2019) From NEON field sites to data portal: a community resource for surface–atmosphere research comes online, Bulletin Of The American Meteorological Society, 100(11), 2305-2325" -US-xKZ,1700008550,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1175/BAMS-D-17-0307.1 -US-xKZ,1700008550,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-xKZ,79322,GRP_SITE_CHAR,WIND_DIRECTION,SSW -US-xKZ,79323,GRP_SITE_DESC,SITE_DESC,"Konza Prairie Biological Station (KPBS) was established to provide a ""natural laboratory"" to conduct ecological research and is located on a 3,487 hectare native tallgrass prairie preserve. KPBS is a field research station dedicated to conservation, education and long-term ecological research. Over 1,580 scientific papers have been published by scientists conducting studies at KPBS. The study of ecological patterns and processes in native tallgrass prairie ecosystems is the primary subject of research." -US-xKZ,79324,GRP_SITE_FUNDING,SITE_FUNDING,National Science Foundation (NSF) -US-xKZ,79325,GRP_STATE,STATE,KS -US-xKZ,96015,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,National Ecological Observatory Network -US-xKZ,96015,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-xKZ,96015,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,neon-ameriflux@battelleecology.org -US-xKZ,96015,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xKZ,96015,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xKZ,96018,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,David Durden -US-xKZ,96018,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-xKZ,96018,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,ddurden@battelleecology.org -US-xKZ,96018,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xKZ,96018,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xKZ,96014,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Stefan Metzger -US-xKZ,96014,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-xKZ,96014,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,smetzger@battelleecology.org -US-xKZ,96014,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xKZ,96014,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xKZ,96016,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Christopher Florian -US-xKZ,96016,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,BADMContact -US-xKZ,96016,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,cflorian@battelleecology.org -US-xKZ,96016,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xKZ,96016,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xKZ,96017,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Cove Sturtevant -US-xKZ,96017,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,DataManager -US-xKZ,96017,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,csturtevant@battelleecology.org -US-xKZ,96017,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xKZ,96017,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xKZ,79329,GRP_TOWER_POWER,TOWER_POWER,Direct power -US-xKZ,79330,GRP_TOWER_TYPE,TOWER_TYPE,walk-up -US-xKZ,79331,GRP_URL,URL,http://www.neonscience.org/field-sites/field-sites-map/KONZ -US-xKZ,24000944,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-xKZ -US-xKZ,79382,GRP_UTC_OFFSET,UTC_OFFSET,-6 -US-xKZ,79382,GRP_UTC_OFFSET,UTC_OFFSET_COMMENT,"Central Standard Time (CST), please note that timestamps are converted to local standard time upon submission to AmeriFlux. Data retrieved from the NEON Data Portal will be in UTC time." -US-xLE,85383,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,The National Ecological Observatory Network is a project solely funded by the National Science Foundation and managed under cooperative agreement by Battelle. -US-xLE,85388,GRP_CLIM_AVG,MAT,18.1 -US-xLE,85388,GRP_CLIM_AVG,MAP,1386.24 -US-xLE,85388,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Cfa -US-xLE,27001019,GRP_COUNTRY,COUNTRY,USA -US-xLE,95627,GRP_DOI,DOI,10.17190/AMF/1773398 -US-xLE,95627,GRP_DOI,DOI_CITATION,"NEON (National Ecological Observatory Network) (2022), AmeriFlux BASE US-xLE NEON Lenoir Landing (LENO), Ver. 3-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1773398" -US-xLE,95627,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-xLE,96169,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-xLE,96169,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,NEON (National Ecological Observatory Network) -US-xLE,96169,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-xLE,96169,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,neon-ameriflux@battelleecology.org -US-xLE,96169,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"NEON Program, Battelle" -US-xLE,96169,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,20160101 -US-xLE,96215,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,National Ecological Observatory Network -US-xLE,96215,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-xLE,95599,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,National Science Foundation (NSF) -US-xLE,95599,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-xLE,85387,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-xLE,85387,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-xLE,85387,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20170828 -US-xLE,85387,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-xLE,85392,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-xLE,85392,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-xLE,85392,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20170828 -US-xLE,85392,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-xLE,85397,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Other -US-xLE,85397,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,Isotopes -US-xLE,85397,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20170828 -US-xLE,85397,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-xLE,23001019,GRP_HEADER,SITE_NAME,NEON Lenoir Landing (LENO) -US-xLE,85384,GRP_IGBP,IGBP,DBF -US-xLE,85391,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-xLE,85391,GRP_LAND_OWNERSHIP,LAND_OWNER,U.S. Army Corps of Engineers -US-xLE,85396,GRP_LOCATION,LOCATION_LAT,31.8539 -US-xLE,85396,GRP_LOCATION,LOCATION_LONG,-88.1612 -US-xLE,85396,GRP_LOCATION,LOCATION_ELEV,20 -US-xLE,85393,GRP_NETWORK,NETWORK,AmeriFlux -US-xLE,85390,GRP_NETWORK,NETWORK,NEON -US-xLE,87054,GRP_NETWORK,NETWORK,Phenocam -US-xLE,1700007542,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Metzger, S., Ayres, E., Durden, D., Florian, C., Lee, R., Lunch, C., Luo, H., Pingintha-Durden, N., Roberti, J. A., SanClements, M., Sturtevant, C., Xu, K., Zulueta, R. C. (2019) From NEON field sites to data portal: a community resource for surface–atmosphere research comes online, Bulletin Of The American Meteorological Society, 100(11), 2305-2325" -US-xLE,1700007542,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1175/BAMS-D-17-0307.1 -US-xLE,1700007542,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-xLE,85386,GRP_SITE_CHAR,WIND_DIRECTION,NNW -US-xLE,86428,GRP_SITE_DESC,SITE_DESC,"This terrestrial field site is located in a hardwood bottomland with seasonal flooding each spring located in southwest Alabama. The meteorological/flux tower and tower sampling plots are located at Lenoir Landing and the distributed plots are located approximately 5 km south of the tower at Choctaw National Wildlife Refuge. - -The ecosystem at LENO is dominated by closed-canopy pine-oak mixed forest with a developed understory, and also includes a small fraction of meadows, wetlands, and smaller water bodies. Dominant plant species include American sweetgum (Liquidambar styraciflua), American hornbeam (Carpinus caroliniana), and loblolly pine (Pinus taeda). Choctaw National Wildlife Refuge also provides a protected wintering area for waterfowl and wood duck brood habitat. This site is colocated with the Lower Tombigbee river aquatic site." -US-xLE,85395,GRP_SITE_FUNDING,SITE_FUNDING,National Science Foundation (NSF) -US-xLE,85394,GRP_STATE,STATE,AL -US-xLE,96023,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,National Ecological Observatory Network -US-xLE,96023,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-xLE,96023,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,neon-ameriflux@battelleecology.org -US-xLE,96023,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xLE,96023,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xLE,96019,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,David Durden -US-xLE,96019,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-xLE,96019,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,ddurden@battelleecology.org -US-xLE,96019,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xLE,96019,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xLE,96021,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Stefan Metzger -US-xLE,96021,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-xLE,96021,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,smetzger@battelleecology.org -US-xLE,96021,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xLE,96021,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xLE,96022,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Christopher Florian -US-xLE,96022,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,BADMContact -US-xLE,96022,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,cflorian@battelleecology.org -US-xLE,96022,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xLE,96022,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xLE,96020,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Cove Sturtevant -US-xLE,96020,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,DataManager -US-xLE,96020,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,csturtevant@battelleecology.org -US-xLE,96020,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xLE,96020,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xLE,85399,GRP_TOWER_POWER,TOWER_POWER,Direct power -US-xLE,85401,GRP_TOWER_TYPE,TOWER_TYPE,walk-up -US-xLE,85398,GRP_URL,URL,https://www.neonscience.org/field-sites/field-sites-map/leno -US-xLE,24001019,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-xLE -US-xLE,85389,GRP_UTC_OFFSET,UTC_OFFSET,-5 -US-xLE,85389,GRP_UTC_OFFSET,UTC_OFFSET_COMMENT,"Eastern Standard Time (EST), please note that timestamps are converted to local standard time upon submission to AmeriFlux. Data retrieved from the NEON Data Portal will be in UTC time." -US-xMB,86043,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,The National Ecological Observatory Network is a project solely funded by the National Science Foundation and managed under cooperative agreement by Battelle. -US-xMB,86059,GRP_CLIM_AVG,MAT,10.1 -US-xMB,86059,GRP_CLIM_AVG,MAP,319.46 -US-xMB,86059,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Bsk -US-xMB,27001044,GRP_COUNTRY,COUNTRY,USA -US-xMB,94284,GRP_DOI,DOI,10.17190/AMF/1671896 -US-xMB,94284,GRP_DOI,DOI_CITATION,"NEON (National Ecological Observatory Network) (2022), AmeriFlux BASE US-xMB NEON Moab (MOAB), Ver. 4-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1671896" -US-xMB,94284,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-xMB,96170,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-xMB,96170,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,NEON (National Ecological Observatory Network) -US-xMB,96170,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-xMB,96170,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,neon-ameriflux@battelleecology.org -US-xMB,96170,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"NEON Program, Battelle" -US-xMB,96170,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,20160101 -US-xMB,96216,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,National Ecological Observatory Network -US-xMB,96216,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-xMB,94249,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,National Science Foundation (NSF) -US-xMB,94249,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-xMB,86057,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-xMB,86057,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-xMB,86057,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20170815 -US-xMB,86057,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-xMB,86049,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-xMB,86049,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-xMB,86049,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20170815 -US-xMB,86049,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-xMB,86053,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-xMB,86053,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,Isotopes -US-xMB,86053,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20170815 -US-xMB,86053,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-xMB,23001044,GRP_HEADER,SITE_NAME,NEON Moab (MOAB) -US-xMB,86042,GRP_IGBP,IGBP,OSH -US-xMB,86061,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-xMB,86061,GRP_LAND_OWNERSHIP,LAND_OWNER,Bureau of Land Management -US-xMB,86046,GRP_LOCATION,LOCATION_LAT,38.2483 -US-xMB,86046,GRP_LOCATION,LOCATION_LONG,-109.3883 -US-xMB,86046,GRP_LOCATION,LOCATION_ELEV,1767 -US-xMB,86054,GRP_NETWORK,NETWORK,AmeriFlux -US-xMB,86052,GRP_NETWORK,NETWORK,NEON -US-xMB,87055,GRP_NETWORK,NETWORK,Phenocam -US-xMB,1700000432,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Metzger, S., Ayres, E., Durden, D., Florian, C., Lee, R., Lunch, C., Luo, H., Pingintha-Durden, N., Roberti, J. A., SanClements, M., Sturtevant, C., Xu, K., Zulueta, R. C. (2019) From NEON field sites to data portal: a community resource for surface–atmosphere research comes online, Bulletin Of The American Meteorological Society, 100(11), 2305-2325" -US-xMB,1700000432,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1175/BAMS-D-17-0307.1 -US-xMB,1700000432,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-xMB,86041,GRP_SITE_CHAR,WIND_DIRECTION,SSW -US-xMB,86055,GRP_SITE_DESC,SITE_DESC,"The NEON MOAB site is located approximately 40 km south of the town of Moab and is characteristic of the Colorado Plateau. MOAB was selected with other sites that share a similar latitude in domains 10, 13, and 15, to assess dust generation, nutrient transport, and nutrient deposition. The western half of the site, including the tower airshed, is a grazed shrub land, often with pockets of barren soil. To the east, in the higher elevations, evergreen forests sit atop the mesas. Biological soil crust, dominated by cyanobacteria, is a living groundcover across the area. -" -US-xMB,86050,GRP_SITE_FUNDING,SITE_FUNDING,National Science Foundation (NSF) -US-xMB,86060,GRP_STATE,STATE,UT -US-xMB,96024,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,National Ecological Observatory Network -US-xMB,96024,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-xMB,96024,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,neon-ameriflux@battelleecology.org -US-xMB,96024,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xMB,96024,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xMB,96027,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,David Durden -US-xMB,96027,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-xMB,96027,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,ddurden@battelleecology.org -US-xMB,96027,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xMB,96027,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xMB,96028,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Stefan Metzger -US-xMB,96028,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-xMB,96028,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,smetzger@battelleecology.org -US-xMB,96028,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xMB,96028,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xMB,96025,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Christopher Florian -US-xMB,96025,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,BADMContact -US-xMB,96025,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,cflorian@battelleecology.org -US-xMB,96025,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xMB,96025,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xMB,96026,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Cove Sturtevant -US-xMB,96026,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,DataManager -US-xMB,96026,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,csturtevant@battelleecology.org -US-xMB,96026,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xMB,96026,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xMB,86044,GRP_TOWER_POWER,TOWER_POWER,Direct power -US-xMB,86051,GRP_TOWER_TYPE,TOWER_TYPE,walk-up -US-xMB,86056,GRP_URL,URL,https://www.neonscience.org/field-sites/field-sites-map/MOAB -US-xMB,24001044,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-xMB -US-xMB,86048,GRP_UTC_OFFSET,UTC_OFFSET,-7 -US-xMB,86048,GRP_UTC_OFFSET,UTC_OFFSET_COMMENT,"Mountain Standard Time (MST), please note that timestamps are converted to local standard time upon submission to AmeriFlux. Data retrieved from the NEON Data Portal will be in UTC time." -US-xML,85372,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,The National Ecological Observatory Network is a project solely funded by the National Science Foundation and managed under cooperative agreement by Battelle. -US-xML,85371,GRP_CLIM_AVG,MAT,8.8 -US-xML,85371,GRP_CLIM_AVG,MAP,1227.82 -US-xML,85371,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfb -US-xML,27001018,GRP_COUNTRY,COUNTRY,USA -US-xML,94283,GRP_DOI,DOI,10.17190/AMF/1671897 -US-xML,94283,GRP_DOI,DOI_CITATION,"NEON (National Ecological Observatory Network) (2022), AmeriFlux BASE US-xML NEON Mountain Lake Biological Station (MLBS), Ver. 4-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1671897" -US-xML,94283,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-xML,96171,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-xML,96171,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,NEON (National Ecological Observatory Network) -US-xML,96171,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-xML,96171,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,neon-ameriflux@battelleecology.org -US-xML,96171,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"NEON Program, Battelle" -US-xML,96171,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,20160101 -US-xML,96217,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,National Ecological Observatory Network -US-xML,96217,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-xML,94246,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,National Science Foundation (NSF) -US-xML,94246,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-xML,85362,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-xML,85362,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-xML,85362,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20170918 -US-xML,85362,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-xML,85376,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-xML,85376,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-xML,85376,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20170918 -US-xML,85376,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-xML,85364,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Other -US-xML,85364,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,Isotopes -US-xML,85364,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20170918 -US-xML,85364,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-xML,23001018,GRP_HEADER,SITE_NAME,NEON Mountain Lake Biological Station (MLBS) -US-xML,85381,GRP_IGBP,IGBP,DBF -US-xML,85379,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -US-xML,85379,GRP_LAND_OWNERSHIP,LAND_OWNER,Private Owner - University of Virginia -US-xML,85375,GRP_LOCATION,LOCATION_LAT,37.3783 -US-xML,85375,GRP_LOCATION,LOCATION_LONG,-80.5248 -US-xML,85375,GRP_LOCATION,LOCATION_ELEV,1126 -US-xML,85369,GRP_NETWORK,NETWORK,AmeriFlux -US-xML,85377,GRP_NETWORK,NETWORK,NEON -US-xML,87056,GRP_NETWORK,NETWORK,Phenocam -US-xML,1700000369,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Metzger, S., Ayres, E., Durden, D., Florian, C., Lee, R., Lunch, C., Luo, H., Pingintha-Durden, N., Roberti, J. A., SanClements, M., Sturtevant, C., Xu, K., Zulueta, R. C. (2019) From NEON field sites to data portal: a community resource for surface–atmosphere research comes online, Bulletin Of The American Meteorological Society, 100(11), 2305-2325" -US-xML,1700000369,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1175/BAMS-D-17-0307.1 -US-xML,1700000369,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-xML,85366,GRP_SITE_DESC,SITE_DESC,"Mountain Lake Biological Station (MLBS) is a remote, but accessible research station and is a unit of the College of Arts & Sciences at University of Virginia. It sits at 1160 meters on the top of Salt Pond Mountain in the southern Appalachian mountains in southwestern Virginia. It consists of 259 hectares of forested reserve." -US-xML,85374,GRP_SITE_FUNDING,SITE_FUNDING,National Science Foundation (NSF) -US-xML,85378,GRP_STATE,STATE,VA -US-xML,96032,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,National Ecological Observatory Network -US-xML,96032,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-xML,96032,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,neon-ameriflux@battelleecology.org -US-xML,96032,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xML,96032,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xML,96029,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,David Durden -US-xML,96029,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-xML,96029,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,ddurden@battelleecology.org -US-xML,96029,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xML,96029,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xML,96031,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Stefan Metzger -US-xML,96031,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-xML,96031,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,smetzger@battelleecology.org -US-xML,96031,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xML,96031,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xML,96030,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Christopher Florian -US-xML,96030,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,BADMContact -US-xML,96030,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,cflorian@battelleecology.org -US-xML,96030,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xML,96030,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xML,96033,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Cove Sturtevant -US-xML,96033,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,DataManager -US-xML,96033,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,csturtevant@battelleecology.org -US-xML,96033,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xML,96033,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xML,85370,GRP_TOWER_POWER,TOWER_POWER,Direct power -US-xML,85373,GRP_TOWER_TYPE,TOWER_TYPE,walk-up -US-xML,85367,GRP_URL,URL,https://www.neonscience.org/field-sites/field-sites-map/MLBS -US-xML,24001018,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-xML -US-xML,85368,GRP_UTC_OFFSET,UTC_OFFSET,-5 -US-xML,85368,GRP_UTC_OFFSET,UTC_OFFSET_COMMENT,"Eastern Standard Time (EST), please note that timestamps are converted to local standard time upon submission to AmeriFlux. Data retrieved from the NEON Data Portal will be in UTC time." -US-xNG,81930,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,The National Ecological Observatory Network is a project solely funded by the National Science Foundation and managed under cooperative agreement by Battelle. -US-xNG,81932,GRP_CLIM_AVG,MAT,5.9 -US-xNG,81932,GRP_CLIM_AVG,MAP,456.51 -US-xNG,81932,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfb -US-xNG,27000977,GRP_COUNTRY,COUNTRY,USA -US-xNG,91678,GRP_DOI,DOI,10.17190/AMF/1617732 -US-xNG,91678,GRP_DOI,DOI_CITATION,"NEON (National Ecological Observatory Network) (2022), AmeriFlux BASE US-xNG NEON Northern Great Plains Research Laboratory (NOGP), Ver. 5-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1617732" -US-xNG,91678,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-xNG,96172,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-xNG,96172,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,NEON (National Ecological Observatory Network) -US-xNG,96172,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-xNG,96172,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,neon-ameriflux@battelleecology.org -US-xNG,96172,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"NEON Program, Battelle" -US-xNG,96172,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,20160101 -US-xNG,96218,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,National Ecological Observatory Network -US-xNG,96218,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-xNG,91609,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,National Science Foundation (NSF) -US-xNG,91609,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-xNG,81945,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Agriculture -US-xNG,81926,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Grazing -US-xNG,81936,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-xNG,81936,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-xNG,81936,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20170728 -US-xNG,81936,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-xNG,81940,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-xNG,81940,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-xNG,81940,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20170728 -US-xNG,81940,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-xNG,23000977,GRP_HEADER,SITE_NAME,NEON Northern Great Plains Research Laboratory (NOGP) -US-xNG,81925,GRP_IGBP,IGBP,GRA -US-xNG,81939,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-xNG,81939,GRP_LAND_OWNERSHIP,LAND_OWNER,"U.S. Department of Agriculture, Agricultural Research Service" -US-xNG,81928,GRP_LOCATION,LOCATION_LAT,46.7697 -US-xNG,81928,GRP_LOCATION,LOCATION_LONG,-100.9154 -US-xNG,81928,GRP_LOCATION,LOCATION_ELEV,578 -US-xNG,81931,GRP_NETWORK,NETWORK,AmeriFlux -US-xNG,81927,GRP_NETWORK,NETWORK,NEON -US-xNG,87057,GRP_NETWORK,NETWORK,Phenocam -US-xNG,1700002076,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Metzger, S., Ayres, E., Durden, D., Florian, C., Lee, R., Lunch, C., Luo, H., Pingintha-Durden, N., Roberti, J. A., SanClements, M., Sturtevant, C., Xu, K., Zulueta, R. C. (2019) From NEON field sites to data portal: a community resource for surface–atmosphere research comes online, Bulletin Of The American Meteorological Society, 100(11), 2305-2325" -US-xNG,1700002076,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1175/BAMS-D-17-0307.1 -US-xNG,1700002076,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-xNG,81941,GRP_SITE_CHAR,WIND_DIRECTION,NW -US-xNG,81929,GRP_SITE_DESC,SITE_DESC,This site is located at the Northern Great Plains Research Laboratory -US-xNG,81933,GRP_SITE_FUNDING,SITE_FUNDING,National Science Foundation (NSF) -US-xNG,81946,GRP_STATE,STATE,ND -US-xNG,96037,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,National Ecological Observatory Network -US-xNG,96037,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-xNG,96037,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,neon-ameriflux@battelleecology.org -US-xNG,96037,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xNG,96037,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xNG,96035,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,David Durden -US-xNG,96035,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-xNG,96035,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,ddurden@battelleecology.org -US-xNG,96035,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xNG,96035,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xNG,96034,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Stefan Metzger -US-xNG,96034,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-xNG,96034,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,smetzger@battelleecology.org -US-xNG,96034,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xNG,96034,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xNG,96036,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Christopher Florian -US-xNG,96036,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,BADMContact -US-xNG,96036,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,cflorian@battelleecology.org -US-xNG,96036,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xNG,96036,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xNG,96038,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Cove Sturtevant -US-xNG,96038,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,DataManager -US-xNG,96038,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,csturtevant@battelleecology.org -US-xNG,96038,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xNG,96038,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xNG,81942,GRP_TOWER_POWER,TOWER_POWER,Direct power -US-xNG,81944,GRP_TOWER_TYPE,TOWER_TYPE,walk-up -US-xNG,81934,GRP_URL,URL,https://www.neonscience.org/field-sites/field-sites-map/NOGP -US-xNG,24000977,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-xNG -US-xNG,81938,GRP_UTC_OFFSET,UTC_OFFSET,-6 -US-xNG,81938,GRP_UTC_OFFSET,UTC_OFFSET_COMMENT,"Central Standard Time (CST), please note that timestamps are converted to local standard time upon submission to AmeriFlux. Data retrieved from the NEON Data Portal will be in UTC time." -US-xNQ,81905,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,The National Ecological Observatory Network is a project solely funded by the National Science Foundation and managed under cooperative agreement by Battelle. -US-xNQ,81912,GRP_CLIM_AVG,MAT,9 -US-xNQ,81912,GRP_CLIM_AVG,MAP,288.31 -US-xNQ,81912,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfb -US-xNQ,27000976,GRP_COUNTRY,COUNTRY,USA -US-xNQ,91699,GRP_DOI,DOI,10.17190/AMF/1617733 -US-xNQ,91699,GRP_DOI,DOI_CITATION,"NEON (National Ecological Observatory Network) (2022), AmeriFlux BASE US-xNQ NEON Onaqui-Ault (ONAQ), Ver. 5-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1617733" -US-xNQ,91699,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-xNQ,96173,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-xNQ,96173,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,NEON (National Ecological Observatory Network) -US-xNQ,96173,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-xNQ,96173,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,neon-ameriflux@battelleecology.org -US-xNQ,96173,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"NEON Program, Battelle" -US-xNQ,96173,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,20160101 -US-xNQ,96219,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,National Ecological Observatory Network -US-xNQ,96219,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-xNQ,81924,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Fire -US-xNQ,81909,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Grazing -US-xNQ,81911,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-xNQ,81911,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-xNQ,81911,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20170412 -US-xNQ,81911,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-xNQ,81903,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-xNQ,81903,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-xNQ,81903,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20170412 -US-xNQ,81903,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-xNQ,81904,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Other -US-xNQ,81904,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,Isotopes -US-xNQ,81904,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20170412 -US-xNQ,81904,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-xNQ,23000976,GRP_HEADER,SITE_NAME,NEON Onaqui-Ault (ONAQ) -US-xNQ,81919,GRP_IGBP,IGBP,OSH -US-xNQ,81907,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-xNQ,81907,GRP_LAND_OWNERSHIP,LAND_OWNER,"Bureau of Land Management, U.S. Forest Service" -US-xNQ,81917,GRP_LOCATION,LOCATION_LAT,40.1776 -US-xNQ,81917,GRP_LOCATION,LOCATION_LONG,-112.4524 -US-xNQ,81917,GRP_LOCATION,LOCATION_ELEV,1685 -US-xNQ,81913,GRP_NETWORK,NETWORK,AmeriFlux -US-xNQ,81920,GRP_NETWORK,NETWORK,NEON -US-xNQ,87058,GRP_NETWORK,NETWORK,Phenocam -US-xNQ,1700000618,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Metzger, S., Ayres, E., Durden, D., Florian, C., Lee, R., Lunch, C., Luo, H., Pingintha-Durden, N., Roberti, J. A., SanClements, M., Sturtevant, C., Xu, K., Zulueta, R. C. (2019) From NEON field sites to data portal: a community resource for surface–atmosphere research comes online, Bulletin Of The American Meteorological Society, 100(11), 2305-2325" -US-xNQ,1700000618,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1175/BAMS-D-17-0307.1 -US-xNQ,1700000618,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-xNQ,81923,GRP_SITE_CHAR,WIND_DIRECTION,S -US-xNQ,81906,GRP_SITE_DESC,SITE_DESC,"The Onaqui-Ault site is located south of the rapidly developing Salt Lake City area, also near Provo and Logan, anchoring this arid urban-rural megatransect. The Onaqui-Benmore area has been grazed by domestic livestock since settlement. By the 1980's, the U.S. Forest Service instituted a light to moderate fall and winter grazing regime that continues today.Fire has always been a component of sagebrush steppe, one of the dominant vegetation types in the area. However, the invasions of exotic annual vegetation, especially Bromus tectorum, also known as drooping brome or cheatgrass, have dramatically shortened fire return intervals. The invasion-fire feedback has resulted in the loss of native perennial species from extensive areas of the region." -US-xNQ,81922,GRP_STATE,STATE,UT -US-xNQ,96041,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,National Ecological Observatory Network -US-xNQ,96041,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-xNQ,96041,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,neon-ameriflux@battelleecology.org -US-xNQ,96041,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xNQ,96041,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xNQ,96042,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,David Durden -US-xNQ,96042,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-xNQ,96042,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,ddurden@battelleecology.org -US-xNQ,96042,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xNQ,96042,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xNQ,96043,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Stefan Metzger -US-xNQ,96043,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-xNQ,96043,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,smetzger@battelleecology.org -US-xNQ,96043,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xNQ,96043,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xNQ,96039,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Christopher Florian -US-xNQ,96039,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,BADMContact -US-xNQ,96039,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,cflorian@battelleecology.org -US-xNQ,96039,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xNQ,96039,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xNQ,96040,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Cove Sturtevant -US-xNQ,96040,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,DataManager -US-xNQ,96040,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,csturtevant@battelleecology.org -US-xNQ,96040,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xNQ,96040,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xNQ,81916,GRP_TOWER_POWER,TOWER_POWER,Direct power -US-xNQ,81910,GRP_TOWER_TYPE,TOWER_TYPE,walk-up -US-xNQ,81921,GRP_URL,URL,http://www.neonscience.org/field-sites/field-sites-map/ONAQ -US-xNQ,24000976,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-xNQ -US-xNQ,81908,GRP_UTC_OFFSET,UTC_OFFSET,-7 -US-xNQ,81908,GRP_UTC_OFFSET,UTC_OFFSET_COMMENT,"Mountain Standard Time (MST), please note that timestamps are converted to local standard time upon submission to AmeriFlux. Data retrieved from the NEON Data Portal will be in UTC time." -US-xNW,83362,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,The National Ecological Observatory Network is a project solely funded by the National Science Foundation and managed under cooperative agreement by Battelle. -US-xNW,83376,GRP_CLIM_AVG,MAT,0.3 -US-xNW,83376,GRP_CLIM_AVG,MAP,1004.54 -US-xNW,83376,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfc -US-xNW,27000978,GRP_COUNTRY,COUNTRY,USA -US-xNW,94273,GRP_DOI,DOI,10.17190/AMF/1671898 -US-xNW,94273,GRP_DOI,DOI_CITATION,"NEON (National Ecological Observatory Network) (2022), AmeriFlux BASE US-xNW NEON Niwot Ridge Mountain Research Station (NIWO), Ver. 4-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1671898" -US-xNW,94273,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-xNW,96174,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-xNW,96174,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,NEON (National Ecological Observatory Network) -US-xNW,96174,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-xNW,96174,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,neon-ameriflux@battelleecology.org -US-xNW,96174,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"NEON Program, Battelle" -US-xNW,96174,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,20160101 -US-xNW,96220,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,National Ecological Observatory Network -US-xNW,96220,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-xNW,94250,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,National Science Foundation (NSF) -US-xNW,94250,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-xNW,83369,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-xNW,83369,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-xNW,83369,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20170417 -US-xNW,83369,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-xNW,83373,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-xNW,83373,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-xNW,83373,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20170417 -US-xNW,83373,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-xNW,83368,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Other -US-xNW,83368,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,Isotopes -US-xNW,83368,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20170417 -US-xNW,83368,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-xNW,23000978,GRP_HEADER,SITE_NAME,NEON Niwot Ridge Mountain Research Station (NIWO) -US-xNW,83361,GRP_IGBP,IGBP,ENF -US-xNW,83364,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-xNW,83364,GRP_LAND_OWNERSHIP,LAND_OWNER,"University of Colorado at Boulder, U.S. Forest Service, LTER" -US-xNW,83367,GRP_LOCATION,LOCATION_LAT,40.0543 -US-xNW,83367,GRP_LOCATION,LOCATION_LONG,-105.5824 -US-xNW,83367,GRP_LOCATION,LOCATION_ELEV,3513 -US-xNW,83360,GRP_NETWORK,NETWORK,AmeriFlux -US-xNW,83372,GRP_NETWORK,NETWORK,NEON -US-xNW,87059,GRP_NETWORK,NETWORK,Phenocam -US-xNW,1700006636,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Metzger, S., Ayres, E., Durden, D., Florian, C., Lee, R., Lunch, C., Luo, H., Pingintha-Durden, N., Roberti, J. A., SanClements, M., Sturtevant, C., Xu, K., Zulueta, R. C. (2019) From NEON field sites to data portal: a community resource for surface–atmosphere research comes online, Bulletin Of The American Meteorological Society, 100(11), 2305-2325" -US-xNW,1700006636,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1175/BAMS-D-17-0307.1 -US-xNW,1700006636,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-xNW,83358,GRP_SITE_CHAR,WIND_DIRECTION,W -US-xNW,83374,GRP_SITE_DESC,SITE_DESC,"The Niwot Ridge sits approximately 27 km west of Boulder, Colorado, and 6 km east of the Continental Divide. Topography, climate, and biota of the site are representative of Rocky Mountain alpine ecosystems, including extensive alpine tundra (mostly herbs, some shrubs and scree) and subalpine coniferous forests (Abies lasciocarpa and Picea engelmanii at higher elevations), talus slopes, wetlands and a variety of glacial landforms. - -Characterized by cold and relatively long winters, Niwot Ridge has an average annual temperature of 1.5°C and average annual precipitation of 800 mm. Most precipitation falls as snow and summer precipitation falls primarily during afternoon thunderstorms. Located on the eastern side of the Continental Divide at 3,000-3,500 m elevation, the site best captures chemical inputs produced along the Front Range and is well situated to observe other east/west flows across the Southern Rockies in conjunction with other NEON sites." -US-xNW,83377,GRP_SITE_FUNDING,SITE_FUNDING,National Science Foundation (NSF) -US-xNW,83366,GRP_STATE,STATE,CO -US-xNW,96044,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,National Ecological Observatory Network -US-xNW,96044,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-xNW,96044,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,neon-ameriflux@battelleecology.org -US-xNW,96044,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xNW,96044,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xNW,96046,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,David Durden -US-xNW,96046,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-xNW,96046,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,ddurden@battelleecology.org -US-xNW,96046,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xNW,96046,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xNW,96047,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Stefan Metzger -US-xNW,96047,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-xNW,96047,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,smetzger@battelleecology.org -US-xNW,96047,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xNW,96047,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xNW,96045,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Christopher Florian -US-xNW,96045,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,BADMContact -US-xNW,96045,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,cflorian@battelleecology.org -US-xNW,96045,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xNW,96045,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xNW,96048,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Cove Sturtevant -US-xNW,96048,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,DataManager -US-xNW,96048,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,csturtevant@battelleecology.org -US-xNW,96048,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xNW,96048,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xNW,83375,GRP_TOWER_POWER,TOWER_POWER,Direct power -US-xNW,83371,GRP_TOWER_TYPE,TOWER_TYPE,walk-up -US-xNW,24000978,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-xNW -US-xNW,83359,GRP_UTC_OFFSET,UTC_OFFSET,-7 -US-xNW,83359,GRP_UTC_OFFSET,UTC_OFFSET_COMMENT,"Mountain Standard Time (MST), please note that timestamps are converted to local standard time upon submission to AmeriFlux. Data retrieved from the NEON Data Portal will be in UTC time." -US-xPU,86080,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,The National Ecological Observatory Network is a project solely funded by the National Science Foundation and managed under cooperative agreement by Battelle. -US-xPU,86079,GRP_CLIM_AVG,MAT,13 -US-xPU,86079,GRP_CLIM_AVG,MAP,2685 -US-xPU,86079,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Cfb -US-xPU,27001045,GRP_COUNTRY,COUNTRY,USA -US-xPU,95622,GRP_DOI,DOI,10.17190/AMF/1773399 -US-xPU,95622,GRP_DOI,DOI_CITATION,"NEON (National Ecological Observatory Network) (2022), AmeriFlux BASE US-xPU NEON Pu'u Maka'ala Natural Area Reserve (PUUM), Ver. 3-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1773399" -US-xPU,95622,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-xPU,96175,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-xPU,96175,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,NEON (National Ecological Observatory Network) -US-xPU,96175,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-xPU,96175,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,neon-ameriflux@battelleecology.org -US-xPU,96175,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"NEON Program, Battelle" -US-xPU,96175,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,20160101 -US-xPU,96221,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,National Ecological Observatory Network -US-xPU,96221,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-xPU,95606,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,National Science Foundation (NSF) -US-xPU,95606,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-xPU,86069,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-xPU,86069,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-xPU,86069,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,2019 -US-xPU,86069,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-xPU,86068,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-xPU,86068,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-xPU,86068,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,2019 -US-xPU,86068,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-xPU,86070,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Other -US-xPU,86070,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,Isotopes -US-xPU,86070,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,2019 -US-xPU,86070,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-xPU,23001045,GRP_HEADER,SITE_NAME,NEON Pu'u Maka'ala Natural Area Reserve (PUUM) -US-xPU,86081,GRP_IGBP,IGBP,EBF -US-xPU,86066,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-xPU,86066,GRP_LAND_OWNERSHIP,LAND_OWNER,"Hawaii State Forest Reserve System Department of Land and Natural Resources, Division of Forestry and Wildlife" -US-xPU,86077,GRP_LOCATION,LOCATION_LAT,19.5531 -US-xPU,86077,GRP_LOCATION,LOCATION_LONG,-155.3173 -US-xPU,86077,GRP_LOCATION,LOCATION_ELEV,1685 -US-xPU,86082,GRP_NETWORK,NETWORK,AmeriFlux -US-xPU,86064,GRP_NETWORK,NETWORK,NEON -US-xPU,1700004500,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Metzger, S., Ayres, E., Durden, D., Florian, C., Lee, R., Lunch, C., Luo, H., Pingintha-Durden, N., Roberti, J. A., SanClements, M., Sturtevant, C., Xu, K., Zulueta, R. C. (2019) From NEON field sites to data portal: a community resource for surface–atmosphere research comes online, Bulletin Of The American Meteorological Society, 100(11), 2305-2325" -US-xPU,1700004500,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1175/BAMS-D-17-0307.1 -US-xPU,1700004500,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-xPU,86063,GRP_SITE_CHAR,WIND_DIRECTION,ESE -US-xPU,86065,GRP_SITE_DESC,SITE_DESC,"NEON's PUUM field site is located in the Pu'u Maka'ala Natural Area Reserve (NAR) on the eastern side of Hawaii’s “Big Island,” managed by the Hawaii Division of Forestry and Wildlife (DOFAW). More than 18,000 acres in size, the NAR is home to a rainforest with many native species, some of them endangered. It was established to protect some of the Big Island’s best wet native forest and unique geologic features." -US-xPU,86074,GRP_SITE_FUNDING,SITE_FUNDING,National Science Foundation (NSF) -US-xPU,86071,GRP_STATE,STATE,HI -US-xPU,96053,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,National Ecological Observatory Network -US-xPU,96053,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-xPU,96053,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,neon-ameriflux@battelleecology.org -US-xPU,96053,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xPU,96053,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xPU,96049,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,David Durden -US-xPU,96049,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-xPU,96049,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,ddurden@battelleecology.org -US-xPU,96049,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xPU,96049,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xPU,96052,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Stefan Metzger -US-xPU,96052,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-xPU,96052,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,smetzger@battelleecology.org -US-xPU,96052,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xPU,96052,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xPU,96051,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Christopher Florian -US-xPU,96051,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,BADMContact -US-xPU,96051,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,cflorian@battelleecology.org -US-xPU,96051,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xPU,96051,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xPU,96050,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Cove Sturtevant -US-xPU,96050,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,DataManager -US-xPU,96050,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,csturtevant@battelleecology.org -US-xPU,96050,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xPU,96050,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xPU,86062,GRP_TOWER_POWER,TOWER_POWER,Direct power -US-xPU,86078,GRP_TOWER_TYPE,TOWER_TYPE,walk-up -US-xPU,86075,GRP_URL,URL,https://www.neonscience.org/field-sites/field-sites-map/PUUM -US-xPU,24001045,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-xPU -US-xPU,86073,GRP_UTC_OFFSET,UTC_OFFSET,-10 -US-xPU,86073,GRP_UTC_OFFSET,UTC_OFFSET_COMMENT,"Hawaii Standard Time (HST), please note that timestamps are converted to local standard time upon submission to AmeriFlux. Data retrieved from the NEON Data Portal will be in UTC time." -US-xRM,86150,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,The National Ecological Observatory Network is a project solely funded by the National Science Foundation and managed under cooperative agreement by Battelle. -US-xRM,86153,GRP_CLIM_AVG,MAT,2.9 -US-xRM,86153,GRP_CLIM_AVG,MAP,730.59 -US-xRM,86153,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfc -US-xRM,27001050,GRP_COUNTRY,COUNTRY,USA -US-xRM,90047,GRP_DOI,DOI,10.17190/AMF/1579723 -US-xRM,90047,GRP_DOI,DOI_CITATION,"NEON (National Ecological Observatory Network) (2022), AmeriFlux BASE US-xRM NEON Rocky Mountain National Park, CASTNET (RMNP), Ver. 5-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1579723" -US-xRM,90047,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-xRM,96176,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-xRM,96176,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,NEON (National Ecological Observatory Network) -US-xRM,96176,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-xRM,96176,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,neon-ameriflux@battelleecology.org -US-xRM,96176,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"NEON Program, Battelle" -US-xRM,96176,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,20160101 -US-xRM,96222,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,National Ecological Observatory Network -US-xRM,96222,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-xRM,90016,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,National Science Foundation (NSF) -US-xRM,90016,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-xRM,86147,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-xRM,86147,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-xRM,86147,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20170207 -US-xRM,86147,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-xRM,86146,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-xRM,86146,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-xRM,86146,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20170207 -US-xRM,86146,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-xRM,86155,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Other -US-xRM,86155,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,Isotopes -US-xRM,86155,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20170207 -US-xRM,86155,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-xRM,23001050,GRP_HEADER,SITE_NAME,"NEON Rocky Mountain National Park, CASTNET (RMNP)" -US-xRM,86149,GRP_IGBP,IGBP,ENF -US-xRM,86152,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-xRM,86152,GRP_LAND_OWNERSHIP,LAND_OWNER,National Park Service -US-xRM,86161,GRP_LOCATION,LOCATION_LAT,40.2759 -US-xRM,86161,GRP_LOCATION,LOCATION_LONG,-105.5459 -US-xRM,86161,GRP_LOCATION,LOCATION_ELEV,2743 -US-xRM,86156,GRP_NETWORK,NETWORK,AmeriFlux -US-xRM,86151,GRP_NETWORK,NETWORK,NEON -US-xRM,87060,GRP_NETWORK,NETWORK,Phenocam -US-xRM,1700005847,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(11), 108350" -US-xRM,1700005847,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -US-xRM,1700005847,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-xRM,1700008514,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Metzger, S., Ayres, E., Durden, D., Florian, C., Lee, R., Lunch, C., Luo, H., Pingintha-Durden, N., Roberti, J. A., SanClements, M., Sturtevant, C., Xu, K., Zulueta, R. C. (2019) From NEON field sites to data portal: a community resource for surface–atmosphere research comes online, Bulletin Of The American Meteorological Society, 100(11), 2305-2325" -US-xRM,1700008514,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1175/BAMS-D-17-0307.1 -US-xRM,1700008514,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-xRM,86160,GRP_SITE_CHAR,WIND_DIRECTION,NW -US-xRM,86165,GRP_SITE_DESC,SITE_DESC,"NEON's Rocky Mountain National Park (RMNP) tower stands 12 km south of Estes Park, Colorado, representing a growing mosaic of urban and exurban areas. While the property is owned by RMNP, it is not contiguous with the core park boundaries. -As a mid-elevation site (2,750 m) on the east side of the Continental Divide, the site is aptly situated to investigate the chemical climate (i.e., pollution) generated along the Front Range as well as dust deposition produced and transported from the Great Basin to higher elevations. This is a particularly salient issue given recent estimates which project that an additional two million residents will inhabit the Front Range in twenty years. -" -US-xRM,86164,GRP_SITE_FUNDING,SITE_FUNDING,National Science Foundation (NSF) -US-xRM,86159,GRP_STATE,STATE,CO -US-xRM,96058,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,National Ecological Observatory Network -US-xRM,96058,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-xRM,96058,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,neon-ameriflux@battelleecology.org -US-xRM,96058,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xRM,96058,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xRM,96056,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,David Durden -US-xRM,96056,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-xRM,96056,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,ddurden@battelleecology.org -US-xRM,96056,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xRM,96056,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xRM,96055,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Stefan Metzger -US-xRM,96055,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-xRM,96055,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,smetzger@battelleecology.org -US-xRM,96055,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xRM,96055,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xRM,96057,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Christopher Florian -US-xRM,96057,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,BADMContact -US-xRM,96057,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,cflorian@battelleecology.org -US-xRM,96057,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xRM,96057,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xRM,96054,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Cove Sturtevant -US-xRM,96054,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,DataManager -US-xRM,96054,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,csturtevant@battelleecology.org -US-xRM,96054,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xRM,96054,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xRM,86154,GRP_TOWER_POWER,TOWER_POWER,Direct power -US-xRM,86148,GRP_TOWER_TYPE,TOWER_TYPE,walk-up -US-xRM,86162,GRP_URL,URL,https://www.neonscience.org/field-sites/field-sites-map/RMNP -US-xRM,24001050,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-xRM -US-xRM,86166,GRP_UTC_OFFSET,UTC_OFFSET,-7 -US-xRM,86166,GRP_UTC_OFFSET,UTC_OFFSET_COMMENT,"Mountain Standard Time (MST), please note that timestamps are converted to local standard time upon submission to AmeriFlux. Data retrieved from the NEON Data Portal will be in UTC time." -US-xRN,86167,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,The National Ecological Observatory Network is a project solely funded by the National Science Foundation and managed under cooperative agreement by Battelle. -US-xRN,86171,GRP_CLIM_AVG,MAT,14.4 -US-xRN,86171,GRP_CLIM_AVG,MAP,1340.32 -US-xRN,86171,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Cfa -US-xRN,27001051,GRP_COUNTRY,COUNTRY,USA -US-xRN,95628,GRP_DOI,DOI,10.17190/AMF/1773400 -US-xRN,95628,GRP_DOI,DOI_CITATION,"NEON (National Ecological Observatory Network) (2022), AmeriFlux BASE US-xRN NEON Oak Ridge National Lab (ORNL), Ver. 3-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1773400" -US-xRN,95628,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-xRN,96177,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-xRN,96177,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,NEON (National Ecological Observatory Network) -US-xRN,96177,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-xRN,96177,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,neon-ameriflux@battelleecology.org -US-xRN,96177,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"NEON Program, Battelle" -US-xRN,96177,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,20160101 -US-xRN,96223,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,National Ecological Observatory Network -US-xRN,96223,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-xRN,95603,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,National Science Foundation (NSF) -US-xRN,95603,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-xRN,86176,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-xRN,86176,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-xRN,86176,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20170216 -US-xRN,86176,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-xRN,86169,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-xRN,86169,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-xRN,86169,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20170216 -US-xRN,86169,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-xRN,86180,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Other -US-xRN,86180,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,Isotopes -US-xRN,86180,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20170216 -US-xRN,86180,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-xRN,23001051,GRP_HEADER,SITE_NAME,NEON Oak Ridge National Lab (ORNL) -US-xRN,86187,GRP_IGBP,IGBP,DBF -US-xRN,86177,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -US-xRN,86177,GRP_LAND_OWNERSHIP,LAND_OWNER,U.S. Department of Energy -US-xRN,86172,GRP_LOCATION,LOCATION_LAT,35.9641 -US-xRN,86172,GRP_LOCATION,LOCATION_LONG,-84.2826 -US-xRN,86172,GRP_LOCATION,LOCATION_ELEV,334 -US-xRN,86186,GRP_NETWORK,NETWORK,AmeriFlux -US-xRN,86174,GRP_NETWORK,NETWORK,NEON -US-xRN,87061,GRP_NETWORK,NETWORK,Phenocam -US-xRN,1700003675,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Metzger, S., Ayres, E., Durden, D., Florian, C., Lee, R., Lunch, C., Luo, H., Pingintha-Durden, N., Roberti, J. A., SanClements, M., Sturtevant, C., Xu, K., Zulueta, R. C. (2019) From NEON field sites to data portal: a community resource for surface–atmosphere research comes online, Bulletin Of The American Meteorological Society, 100(11), 2305-2325" -US-xRN,1700003675,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1175/BAMS-D-17-0307.1 -US-xRN,1700003675,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-xRN,86170,GRP_SITE_CHAR,WIND_DIRECTION,W -US-xRN,86185,GRP_SITE_DESC,SITE_DESC,"Oak Ridge National Laboratory (ORNL) is located at the U.S. Department of Energy's Oak Ridge Reservation in Roane County, Tennessee. The ORNL reservation is situated within the borders of five parallel ridges and valleys to the north of the Clinch River that are part of the Ridge-and-Valley Appalachians physiographic province (Environmental Sciences Division n.d.). The NEON tower site and Walker Branch aquatic site at ORNL are located within the Walker Branch Watershed, a 100 ha area that has served as the site for long-term environmental studies by the Environmental Sciences Division at ORNL, NOAA, and many visiting university researchers." -US-xRN,86182,GRP_SITE_FUNDING,SITE_FUNDING,National Science Foundation (NSF) -US-xRN,86173,GRP_STATE,STATE,TN -US-xRN,96062,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,National Ecological Observatory Network -US-xRN,96062,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-xRN,96062,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,neon-ameriflux@battelleecology.org -US-xRN,96062,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xRN,96062,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xRN,96061,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,David Durden -US-xRN,96061,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-xRN,96061,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,ddurden@battelleecology.org -US-xRN,96061,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xRN,96061,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xRN,96059,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Stefan Metzger -US-xRN,96059,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-xRN,96059,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,smetzger@battelleecology.org -US-xRN,96059,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xRN,96059,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xRN,96063,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Christopher Florian -US-xRN,96063,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,BADMContact -US-xRN,96063,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,cflorian@battelleecology.org -US-xRN,96063,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xRN,96063,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xRN,96060,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Cove Sturtevant -US-xRN,96060,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,DataManager -US-xRN,96060,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,csturtevant@battelleecology.org -US-xRN,96060,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xRN,96060,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xRN,86181,GRP_TOWER_POWER,TOWER_POWER,Direct power -US-xRN,86179,GRP_TOWER_TYPE,TOWER_TYPE,walk-up -US-xRN,86178,GRP_URL,URL,http://www.neonscience.org/field-sites/field-sites-map/ORNL -US-xRN,24001051,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-xRN -US-xRN,86175,GRP_UTC_OFFSET,UTC_OFFSET,-5 -US-xRN,86175,GRP_UTC_OFFSET,UTC_OFFSET_COMMENT,"Eastern Standard Time (EST), please note that timestamps are converted to local standard time upon submission to AmeriFlux. Data retrieved from the NEON Data Portal will be in UTC time." -US-xSB,79727,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,The National Ecological Observatory Network is a project solely funded by the National Science Foundation and managed under cooperative agreement by Battelle. -US-xSB,79724,GRP_CLIM_AVG,MAT,20.9 -US-xSB,79724,GRP_CLIM_AVG,MAP,1302.09 -US-xSB,79724,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Cfa -US-xSB,27000957,GRP_COUNTRY,COUNTRY,USA -US-xSB,94272,GRP_DOI,DOI,10.17190/AMF/1671899 -US-xSB,94272,GRP_DOI,DOI_CITATION,"NEON (National Ecological Observatory Network) (2022), AmeriFlux BASE US-xSB NEON Ordway-Swisher Biological Station (OSBS), Ver. 4-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1671899" -US-xSB,94272,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-xSB,96178,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-xSB,96178,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,NEON (National Ecological Observatory Network) -US-xSB,96178,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-xSB,96178,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,neon-ameriflux@battelleecology.org -US-xSB,96178,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"NEON Program, Battelle" -US-xSB,96178,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,20160101 -US-xSB,96224,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,National Ecological Observatory Network -US-xSB,96224,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-xSB,94253,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,National Science Foundation (NSF) -US-xSB,94253,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-xSB,79731,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Fire -US-xSB,79728,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-xSB,79728,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-xSB,79728,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20160928 -US-xSB,79728,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-xSB,79719,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-xSB,79719,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-xSB,79719,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20160928 -US-xSB,79719,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-xSB,79729,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Other -US-xSB,79729,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,Isotopes -US-xSB,79729,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20160928 -US-xSB,79729,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-xSB,23000957,GRP_HEADER,SITE_NAME,NEON Ordway-Swisher Biological Station (OSBS) -US-xSB,79717,GRP_IGBP,IGBP,ENF -US-xSB,79723,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-xSB,79723,GRP_LAND_OWNERSHIP,LAND_OWNER,University of Florida Foundation -US-xSB,79737,GRP_LOCATION,LOCATION_LAT,29.6893 -US-xSB,79737,GRP_LOCATION,LOCATION_LONG,-81.9934 -US-xSB,79737,GRP_LOCATION,LOCATION_ELEV,45 -US-xSB,79725,GRP_NETWORK,NETWORK,AmeriFlux -US-xSB,79720,GRP_NETWORK,NETWORK,NEON -US-xSB,87062,GRP_NETWORK,NETWORK,Phenocam -US-xSB,1700003540,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Metzger, S., Ayres, E., Durden, D., Florian, C., Lee, R., Lunch, C., Luo, H., Pingintha-Durden, N., Roberti, J. A., SanClements, M., Sturtevant, C., Xu, K., Zulueta, R. C. (2019) From NEON field sites to data portal: a community resource for surface–atmosphere research comes online, Bulletin Of The American Meteorological Society, 100(11), 2305-2325" -US-xSB,1700003540,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1175/BAMS-D-17-0307.1 -US-xSB,1700003540,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-xSB,79722,GRP_SITE_DESC,SITE_DESC,"The Ordway-Swisher Biological Station (OSBS) is operated by the University of Florida and comprises over 9,300 acres. It is a year-round field station established for the long-term study and conservation of unique ecosystems through management, research and education. The Station is located approximately 20 miles east of Gainesville in Melrose (Putnam County, Florida). There are two aquatic arrays at Ordway-Swisher, representing the two dominant aquatic features on the landscape: 1) Suggs lake, a shallow surface water lake that is rich in taxa and biologically active in structure and function; and 2) Barco lake, a deep lake connected to ground water. The forest is maintained by fire and has a relatively open structure: it is managed with prescribed burns at a frequency of 3-4 years." -US-xSB,79718,GRP_SITE_FUNDING,SITE_FUNDING,National Science Foundation (NSF) -US-xSB,79730,GRP_STATE,STATE,FL -US-xSB,96066,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,National Ecological Observatory Network -US-xSB,96066,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-xSB,96066,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,neon-ameriflux@battelleecology.org -US-xSB,96066,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xSB,96066,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xSB,96068,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,David Durden -US-xSB,96068,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-xSB,96068,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,ddurden@battelleecology.org -US-xSB,96068,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xSB,96068,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xSB,96065,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Stefan Metzger -US-xSB,96065,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-xSB,96065,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,smetzger@battelleecology.org -US-xSB,96065,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xSB,96065,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xSB,96064,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Christopher Florian -US-xSB,96064,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,BADMContact -US-xSB,96064,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,cflorian@battelleecology.org -US-xSB,96064,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xSB,96064,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xSB,96067,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Cove Sturtevant -US-xSB,96067,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,DataManager -US-xSB,96067,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,csturtevant@battelleecology.org -US-xSB,96067,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xSB,96067,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xSB,79726,GRP_TOWER_POWER,TOWER_POWER,Direct power -US-xSB,79732,GRP_TOWER_TYPE,TOWER_TYPE,walk-up -US-xSB,79734,GRP_URL,URL,http://www.neonscience.org/field-sites/field-sites-map/OSBS -US-xSB,24000957,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-xSB -US-xSB,79735,GRP_UTC_OFFSET,UTC_OFFSET,-5 -US-xSB,79735,GRP_UTC_OFFSET,UTC_OFFSET_COMMENT,"Eastern Standard Time (EST), please note that timestamps are converted to local standard time upon submission to AmeriFlux. Data retrieved from the NEON Data Portal will be in UTC time." -US-xSC,86201,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,The National Ecological Observatory Network is a project solely funded by the National Science Foundation and managed under cooperative agreement by Battelle. -US-xSC,86202,GRP_CLIM_AVG,MAT,11.6 -US-xSC,86202,GRP_CLIM_AVG,MAP,1125.5 -US-xSC,86202,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Cfa -US-xSC,27001052,GRP_COUNTRY,COUNTRY,USA -US-xSC,94282,GRP_DOI,DOI,10.17190/AMF/1671900 -US-xSC,94282,GRP_DOI,DOI_CITATION,"NEON (National Ecological Observatory Network) (2022), AmeriFlux BASE US-xSC NEON Smithsonian Conservation Biology Institute (SCBI), Ver. 4-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1671900" -US-xSC,94282,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-xSC,96179,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-xSC,96179,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,NEON (National Ecological Observatory Network) -US-xSC,96179,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-xSC,96179,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,neon-ameriflux@battelleecology.org -US-xSC,96179,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"NEON Program, Battelle" -US-xSC,96179,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,20160101 -US-xSC,96225,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,National Ecological Observatory Network -US-xSC,96225,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-xSC,94247,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,National Science Foundation (NSF) -US-xSC,94247,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-xSC,87139,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-xSC,87139,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-xSC,87139,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20160713 -US-xSC,87139,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-xSC,87166,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-xSC,87166,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-xSC,87166,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20160713 -US-xSC,87166,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-xSC,87140,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Other -US-xSC,87140,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,Isotopes -US-xSC,87140,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20160713 -US-xSC,87140,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-xSC,23001052,GRP_HEADER,SITE_NAME,NEON Smithsonian Conservation Biology Institute (SCBI) -US-xSC,86195,GRP_IGBP,IGBP,DBF -US-xSC,86199,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -US-xSC,86199,GRP_LAND_OWNERSHIP,LAND_OWNER,Smithsonian Institution -US-xSC,86193,GRP_LOCATION,LOCATION_LAT,38.8929 -US-xSC,86193,GRP_LOCATION,LOCATION_LONG,-78.1395 -US-xSC,86193,GRP_LOCATION,LOCATION_ELEV,361 -US-xSC,86205,GRP_NETWORK,NETWORK,AmeriFlux -US-xSC,86189,GRP_NETWORK,NETWORK,NEON -US-xSC,87063,GRP_NETWORK,NETWORK,Phenocam -US-xSC,1700003738,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Metzger, S., Ayres, E., Durden, D., Florian, C., Lee, R., Lunch, C., Luo, H., Pingintha-Durden, N., Roberti, J. A., SanClements, M., Sturtevant, C., Xu, K., Zulueta, R. C. (2019) From NEON field sites to data portal: a community resource for surface–atmosphere research comes online, Bulletin Of The American Meteorological Society, 100(11), 2305-2325" -US-xSC,1700003738,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1175/BAMS-D-17-0307.1 -US-xSC,1700003738,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-xSC,86207,GRP_SITE_CHAR,WIND_DIRECTION,SSE -US-xSC,86191,GRP_SITE_DESC,SITE_DESC,"The Smithsonian Conservation Biology Institute (SCBI) site is a mid-continent forested eastern deciduous site, species include Oaks, Hickories, and Ash, and contains well defined ground cover and understory strata." -US-xSC,86203,GRP_SITE_FUNDING,SITE_FUNDING,National Science Foundation (NSF) -US-xSC,86198,GRP_STATE,STATE,VA -US-xSC,96071,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,National Ecological Observatory Network -US-xSC,96071,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-xSC,96071,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,neon-ameriflux@battelleecology.org -US-xSC,96071,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xSC,96071,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xSC,96070,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,David Durden -US-xSC,96070,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-xSC,96070,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,ddurden@battelleecology.org -US-xSC,96070,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xSC,96070,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xSC,96072,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Stefan Metzger -US-xSC,96072,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-xSC,96072,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,smetzger@battelleecology.org -US-xSC,96072,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xSC,96072,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xSC,96073,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Christopher Florian -US-xSC,96073,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,BADMContact -US-xSC,96073,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,cflorian@battelleecology.org -US-xSC,96073,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xSC,96073,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xSC,96069,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Cove Sturtevant -US-xSC,96069,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,DataManager -US-xSC,96069,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,csturtevant@battelleecology.org -US-xSC,96069,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xSC,96069,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xSC,86208,GRP_TOWER_POWER,TOWER_POWER,Direct power -US-xSC,86204,GRP_TOWER_TYPE,TOWER_TYPE,walk-up -US-xSC,86196,GRP_URL,URL,http://www.neonscience.org/field-sites/field-sites-map/SCBI -US-xSC,24001052,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-xSC -US-xSC,86192,GRP_UTC_OFFSET,UTC_OFFSET,-5 -US-xSC,86192,GRP_UTC_OFFSET,UTC_OFFSET_COMMENT,"Eastern Standard Time (EST), please note that timestamps are converted to local standard time upon submission to AmeriFlux. Data retrieved from the NEON Data Portal will be in UTC time." -US-xSE,81886,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,The National Ecological Observatory Network is a project solely funded by the National Science Foundation and managed under cooperative agreement by Battelle. -US-xSE,81883,GRP_CLIM_AVG,MAT,13.6 -US-xSE,81883,GRP_CLIM_AVG,MAP,1074.65 -US-xSE,81883,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Cfa -US-xSE,27000974,GRP_COUNTRY,COUNTRY,USA -US-xSE,91680,GRP_DOI,DOI,10.17190/AMF/1617734 -US-xSE,91680,GRP_DOI,DOI_CITATION,"NEON (National Ecological Observatory Network) (2022), AmeriFlux BASE US-xSE NEON Smithsonian Environmental Research Center (SERC), Ver. 5-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1617734" -US-xSE,91680,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-xSE,96180,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-xSE,96180,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,NEON (National Ecological Observatory Network) -US-xSE,96180,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-xSE,96180,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,neon-ameriflux@battelleecology.org -US-xSE,96180,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"NEON Program, Battelle" -US-xSE,96180,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,20160101 -US-xSE,96226,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,National Ecological Observatory Network -US-xSE,96226,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-xSE,91604,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,National Science Foundation (NSF) -US-xSE,91604,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-xSE,81902,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Agriculture -US-xSE,81894,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-xSE,81894,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-xSE,81894,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20160216 -US-xSE,81894,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-xSE,81892,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-xSE,81892,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-xSE,81892,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20160216 -US-xSE,81892,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-xSE,23000974,GRP_HEADER,SITE_NAME,NEON Smithsonian Environmental Research Center (SERC) -US-xSE,81888,GRP_IGBP,IGBP,DBF -US-xSE,81884,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -US-xSE,81884,GRP_LAND_OWNERSHIP,LAND_OWNER,Smithsonian Institution -US-xSE,81882,GRP_LOCATION,LOCATION_LAT,38.8901 -US-xSE,81882,GRP_LOCATION,LOCATION_LONG,-76.5600 -US-xSE,81882,GRP_LOCATION,LOCATION_ELEV,15 -US-xSE,81897,GRP_NETWORK,NETWORK,AmeriFlux -US-xSE,81887,GRP_NETWORK,NETWORK,NEON -US-xSE,87064,GRP_NETWORK,NETWORK,Phenocam -US-xSE,1700006666,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Metzger, S., Ayres, E., Durden, D., Florian, C., Lee, R., Lunch, C., Luo, H., Pingintha-Durden, N., Roberti, J. A., SanClements, M., Sturtevant, C., Xu, K., Zulueta, R. C. (2019) From NEON field sites to data portal: a community resource for surface–atmosphere research comes online, Bulletin Of The American Meteorological Society, 100(11), 2305-2325" -US-xSE,1700006666,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1175/BAMS-D-17-0307.1 -US-xSE,1700006666,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-xSE,81893,GRP_SITE_CHAR,WIND_DIRECTION,SSW -US-xSE,81900,GRP_SITE_DESC,SITE_DESC,"This site is operated at the Smithsonian Environmental Research Center, which is comprised of forests, wetlands, marshes and shoreline on the Chesapeake Bay" -US-xSE,81889,GRP_SITE_FUNDING,SITE_FUNDING,National Science Foundation (NSF) -US-xSE,81899,GRP_STATE,STATE,MD -US-xSE,96078,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,National Ecological Observatory Network -US-xSE,96078,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-xSE,96078,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,neon-ameriflux@battelleecology.org -US-xSE,96078,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xSE,96078,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xSE,96076,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,David Durden -US-xSE,96076,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-xSE,96076,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,ddurden@battelleecology.org -US-xSE,96076,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xSE,96076,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xSE,96074,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Stefan Metzger -US-xSE,96074,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-xSE,96074,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,smetzger@battelleecology.org -US-xSE,96074,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xSE,96074,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xSE,96075,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Christopher Florian -US-xSE,96075,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,BADMContact -US-xSE,96075,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,cflorian@battelleecology.org -US-xSE,96075,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xSE,96075,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xSE,96077,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Cove Sturtevant -US-xSE,96077,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,DataManager -US-xSE,96077,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,csturtevant@battelleecology.org -US-xSE,96077,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xSE,96077,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xSE,81890,GRP_TOWER_POWER,TOWER_POWER,Direct power -US-xSE,81898,GRP_TOWER_TYPE,TOWER_TYPE,walk-up -US-xSE,81896,GRP_URL,URL,https://www.neonscience.org/field-sites/field-sites-map/SERC -US-xSE,24000974,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-xSE -US-xSE,81895,GRP_UTC_OFFSET,UTC_OFFSET,-5 -US-xSE,81895,GRP_UTC_OFFSET,UTC_OFFSET_COMMENT,"Eastern Standard Time (EST), please note that timestamps are converted to local standard time upon submission to AmeriFlux. Data retrieved from the NEON Data Portal will be in UTC time." -US-xSJ,86318,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,The National Ecological Observatory Network is a project solely funded by the National Science Foundation and managed under cooperative agreement by Battelle. -US-xSJ,86319,GRP_CLIM_AVG,MAT,16.4 -US-xSJ,86319,GRP_CLIM_AVG,MAP,539.62 -US-xSJ,86319,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Csa -US-xSJ,27001061,GRP_COUNTRY,COUNTRY,USA -US-xSJ,94277,GRP_DOI,DOI,10.17190/AMF/1671901 -US-xSJ,94277,GRP_DOI,DOI_CITATION,"NEON (National Ecological Observatory Network) (2022), AmeriFlux BASE US-xSJ NEON San Joaquin Experimental Range (SJER), Ver. 4-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1671901" -US-xSJ,94277,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-xSJ,96181,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-xSJ,96181,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,NEON (National Ecological Observatory Network) -US-xSJ,96181,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-xSJ,96181,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,neon-ameriflux@battelleecology.org -US-xSJ,96181,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"NEON Program, Battelle" -US-xSJ,96181,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,20160101 -US-xSJ,96227,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,National Ecological Observatory Network -US-xSJ,96227,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-xSJ,94254,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,National Science Foundation (NSF) -US-xSJ,94254,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-xSJ,86329,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-xSJ,86329,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-xSJ,86329,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20181002 -US-xSJ,86329,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-xSJ,86327,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-xSJ,86327,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-xSJ,86327,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20181002 -US-xSJ,86327,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-xSJ,86330,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Other -US-xSJ,86330,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,Isotopes -US-xSJ,86330,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20181002 -US-xSJ,86330,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-xSJ,23001061,GRP_HEADER,SITE_NAME,NEON San Joaquin Experimental Range (SJER) -US-xSJ,86322,GRP_IGBP,IGBP,SAV -US-xSJ,86323,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-xSJ,86323,GRP_LAND_OWNERSHIP,LAND_OWNER,U.S. Forest Service -US-xSJ,86314,GRP_LOCATION,LOCATION_LAT,37.1088 -US-xSJ,86314,GRP_LOCATION,LOCATION_LONG,-119.7323 -US-xSJ,86314,GRP_LOCATION,LOCATION_ELEV,368 -US-xSJ,86325,GRP_NETWORK,NETWORK,AmeriFlux -US-xSJ,86321,GRP_NETWORK,NETWORK,NEON -US-xSJ,1700000555,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Metzger, S., Ayres, E., Durden, D., Florian, C., Lee, R., Lunch, C., Luo, H., Pingintha-Durden, N., Roberti, J. A., SanClements, M., Sturtevant, C., Xu, K., Zulueta, R. C. (2019) From NEON field sites to data portal: a community resource for surface–atmosphere research comes online, Bulletin Of The American Meteorological Society, 100(11), 2305-2325" -US-xSJ,1700000555,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1175/BAMS-D-17-0307.1 -US-xSJ,1700000555,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-xSJ,86320,GRP_SITE_CHAR,WIND_DIRECTION,NW -US-xSJ,86331,GRP_SITE_DESC,SITE_DESC,"Located at The San Joaquin Experimental Range, in the western foothills of the Sierra Nevada, this 18.2 kilometer terrestrial field site is a mix of open woodlands, shrubs and grasslands with low density cattle grazing. SJER is an ecosystem research experimental area. It was originally conceived as a cooperative interdisciplinary research center to identify cost-effect methods of commercial livestock production in the annual grass-oak pine woodlands, while maintaining the integrity of the ecosystem. More recently, research objectives have expanded and diversified to include research projects making contributions to our knowledge of the patterns and processes working in this ecosystem. -" -US-xSJ,86317,GRP_SITE_FUNDING,SITE_FUNDING,National Science Foundation (NSF) -US-xSJ,86315,GRP_STATE,STATE,CA -US-xSJ,96080,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,National Ecological Observatory Network -US-xSJ,96080,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-xSJ,96080,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,neon-ameriflux@battelleecology.org -US-xSJ,96080,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xSJ,96080,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xSJ,96081,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,David Durden -US-xSJ,96081,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-xSJ,96081,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,ddurden@battelleecology.org -US-xSJ,96081,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xSJ,96081,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xSJ,96083,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Stefan Metzger -US-xSJ,96083,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-xSJ,96083,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,smetzger@battelleecology.org -US-xSJ,96083,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xSJ,96083,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xSJ,96079,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Christopher Florian -US-xSJ,96079,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,BADMContact -US-xSJ,96079,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,cflorian@battelleecology.org -US-xSJ,96079,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xSJ,96079,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xSJ,96082,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Cove Sturtevant -US-xSJ,96082,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,DataManager -US-xSJ,96082,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,csturtevant@battelleecology.org -US-xSJ,96082,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xSJ,96082,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xSJ,86326,GRP_TOWER_POWER,TOWER_POWER,Direct power -US-xSJ,86328,GRP_TOWER_TYPE,TOWER_TYPE,walk-up -US-xSJ,86332,GRP_URL,URL,https://www.neonscience.org/field-sites/field-sites-map/SJER -US-xSJ,24001061,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-xSJ -US-xSJ,86324,GRP_UTC_OFFSET,UTC_OFFSET,-8 -US-xSJ,86324,GRP_UTC_OFFSET,UTC_OFFSET_COMMENT,"Pacific Standard Time (PST), please note that timestamps are converted to local standard time upon submission to AmeriFlux. Data retrieved from the NEON Data Portal will be in UTC time." -US-xSL,87104,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,The National Ecological Observatory Network is a project solely funded by the National Science Foundation and managed under cooperative agreement by Battelle. -US-xSL,87106,GRP_CLIM_AVG,MAT,9.7 -US-xSL,87106,GRP_CLIM_AVG,MAP,432.67 -US-xSL,87106,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Bsk -US-xSL,27001075,GRP_COUNTRY,COUNTRY,USA -US-xSL,91692,GRP_DOI,DOI,10.17190/AMF/1617735 -US-xSL,91692,GRP_DOI,DOI_CITATION,"NEON (National Ecological Observatory Network) (2022), AmeriFlux BASE US-xSL NEON North Sterling, CO (STER), Ver. 5-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1617735" -US-xSL,91692,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-xSL,96182,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-xSL,96182,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,NEON (National Ecological Observatory Network) -US-xSL,96182,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-xSL,96182,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,neon-ameriflux@battelleecology.org -US-xSL,96182,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"NEON Program, Battelle" -US-xSL,96182,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,20160101 -US-xSL,96228,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,National Ecological Observatory Network -US-xSL,96228,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-xSL,91629,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,National Science Foundation (NSF) -US-xSL,91629,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-xSL,87108,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Agriculture -US-xSL,87094,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-xSL,87094,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-xSL,87094,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20170725 -US-xSL,87094,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-xSL,87095,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-xSL,87095,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-xSL,87095,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20170725 -US-xSL,87095,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-xSL,87096,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Other -US-xSL,87096,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,Isotopes -US-xSL,87096,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20170725 -US-xSL,87096,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-xSL,23001075,GRP_HEADER,SITE_NAME,"NEON North Sterling, CO (STER)" -US-xSL,98554,GRP_IGBP,IGBP,CRO -US-xSL,98554,GRP_IGBP,IGBP_DATE_START,20180101 -US-xSL,87102,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -US-xSL,87102,GRP_LAND_OWNERSHIP,LAND_OWNER,Private Owner -US-xSL,87100,GRP_LOCATION,LOCATION_LAT,40.4619 -US-xSL,87100,GRP_LOCATION,LOCATION_LONG,-103.0293 -US-xSL,87100,GRP_LOCATION,LOCATION_ELEV,1364 -US-xSL,87093,GRP_NETWORK,NETWORK,AmeriFlux -US-xSL,87092,GRP_NETWORK,NETWORK,NEON -US-xSL,1700006381,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Metzger, S., Ayres, E., Durden, D., Florian, C., Lee, R., Lunch, C., Luo, H., Pingintha-Durden, N., Roberti, J. A., SanClements, M., Sturtevant, C., Xu, K., Zulueta, R. C. (2019) From NEON field sites to data portal: a community resource for surface–atmosphere research comes online, Bulletin Of The American Meteorological Society, 100(11), 2305-2325" -US-xSL,1700006381,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1175/BAMS-D-17-0307.1 -US-xSL,1700006381,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-xSL,87107,GRP_SITE_CHAR,WIND_DIRECTION,NW -US-xSL,87098,GRP_SITE_DESC,SITE_DESC,"The North Sterling site, located outside of Sterling in Northeastern Colorado, is characterized by flat terrain and represents an agronomic site within urban and formerly urban areas. -The site is at the edge of a non-tilled experimental field that is used for the long-term sustainable Dryland Agroecosystems Project (DAP), which was initiated in 1985 at three sites in eastern Colorado (Sterling, Stratton, and Walsh) to evaluate the effects of cropping intensity on production, water use efficiency and selected soil chemical and physical properties. The DAP site was established in 1985 and was chosen because of representative soils present in the catena." -US-xSL,87099,GRP_SITE_FUNDING,SITE_FUNDING,National Science Foundation (NSF) -US-xSL,87097,GRP_STATE,STATE,CO -US-xSL,96085,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,National Ecological Observatory Network -US-xSL,96085,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-xSL,96085,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,neon-ameriflux@battelleecology.org -US-xSL,96085,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xSL,96085,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xSL,96084,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,David Durden -US-xSL,96084,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-xSL,96084,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,ddurden@battelleecology.org -US-xSL,96084,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xSL,96084,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xSL,96087,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Stefan Metzger -US-xSL,96087,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-xSL,96087,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,smetzger@battelleecology.org -US-xSL,96087,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xSL,96087,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xSL,96086,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Christopher Florian -US-xSL,96086,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,BADMContact -US-xSL,96086,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,cflorian@battelleecology.org -US-xSL,96086,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xSL,96086,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xSL,96088,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Cove Sturtevant -US-xSL,96088,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,DataManager -US-xSL,96088,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,csturtevant@battelleecology.org -US-xSL,96088,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xSL,96088,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xSL,87110,GRP_TOWER_POWER,TOWER_POWER,Direct power -US-xSL,87109,GRP_TOWER_TYPE,TOWER_TYPE,walk-up -US-xSL,87103,GRP_URL,URL,https://www.neonscience.org/field-sites/field-sites-map/STER -US-xSL,24001075,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-xSL -US-xSL,87105,GRP_UTC_OFFSET,UTC_OFFSET,-7 -US-xSL,87105,GRP_UTC_OFFSET,UTC_OFFSET_COMMENT,"Mountain Standard Time (MST), please note that timestamps are converted to local standard time upon submission to AmeriFlux. Data retrieved from the NEON Data Portal will be in UTC time." -US-xSP,86379,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,The National Ecological Observatory Network is a project solely funded by the National Science Foundation and managed under cooperative agreement by Battelle. -US-xSP,86395,GRP_CLIM_AVG,MAT,13.4 -US-xSP,86395,GRP_CLIM_AVG,MAP,900.35 -US-xSP,86395,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Csa -US-xSP,27001060,GRP_COUNTRY,COUNTRY,USA -US-xSP,91701,GRP_DOI,DOI,10.17190/AMF/1617736 -US-xSP,91701,GRP_DOI,DOI_CITATION,"NEON (National Ecological Observatory Network) (2022), AmeriFlux BASE US-xSP NEON Soaproot Saddle (SOAP), Ver. 5-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1617736" -US-xSP,91701,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-xSP,96183,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-xSP,96183,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,NEON (National Ecological Observatory Network) -US-xSP,96183,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-xSP,96183,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,neon-ameriflux@battelleecology.org -US-xSP,96183,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"NEON Program, Battelle" -US-xSP,96183,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,20160101 -US-xSP,96229,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,National Ecological Observatory Network -US-xSP,96229,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-xSP,91636,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,National Science Foundation (NSF) -US-xSP,91636,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-xSP,86384,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Forestry -US-xSP,86377,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Pests and disease -US-xSP,86399,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-xSP,86399,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-xSP,86399,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20170919 -US-xSP,86399,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-xSP,86386,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-xSP,86386,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-xSP,86386,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20170919 -US-xSP,86386,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-xSP,86383,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Other -US-xSP,86383,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,Isotopes -US-xSP,86383,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20170919 -US-xSP,86383,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-xSP,23001060,GRP_HEADER,SITE_NAME,NEON Soaproot Saddle (SOAP) -US-xSP,86389,GRP_IGBP,IGBP,ENF -US-xSP,86381,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-xSP,86381,GRP_LAND_OWNERSHIP,LAND_OWNER,U.S. Forest Service -US-xSP,86380,GRP_LOCATION,LOCATION_LAT,37.0334 -US-xSP,86380,GRP_LOCATION,LOCATION_LONG,-119.2622 -US-xSP,86380,GRP_LOCATION,LOCATION_ELEV,1160 -US-xSP,86394,GRP_NETWORK,NETWORK,AmeriFlux -US-xSP,86397,GRP_NETWORK,NETWORK,NEON -US-xSP,87065,GRP_NETWORK,NETWORK,Phenocam -US-xSP,1700006969,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Metzger, S., Ayres, E., Durden, D., Florian, C., Lee, R., Lunch, C., Luo, H., Pingintha-Durden, N., Roberti, J. A., SanClements, M., Sturtevant, C., Xu, K., Zulueta, R. C. (2019) From NEON field sites to data portal: a community resource for surface–atmosphere research comes online, Bulletin Of The American Meteorological Society, 100(11), 2305-2325" -US-xSP,1700006969,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1175/BAMS-D-17-0307.1 -US-xSP,1700006969,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-xSP,86393,GRP_SITE_CHAR,WIND_DIRECTION,NW -US-xSP,86385,GRP_SITE_DESC,SITE_DESC,"The Soaproot Saddle is a complex terrain of coarse hills, steep slopes and narrow drainages. With an elevation of 3274 - 4537’ this site encompasses 1438 acres of mixed conifer forests that are experiencing high levels of mortality due to native Pine beetles.  At the core of this site stands a 171’ tall flux tower that collects physical and chemical properties of atmosphere and related process. Soaproot Saddle also hosts an array of sensor measurements along with field observations collected by highly trained NEON staff. The automated instrument measurements and some of the terrestrial observational safor this field site are colocted with NEON's aquatic site, Upper Big Creek, which is located just north of Soaproot Saddle's site boundaries." -US-xSP,86382,GRP_SITE_FUNDING,SITE_FUNDING,National Science Foundation (NSF) -US-xSP,86391,GRP_STATE,STATE,CA -US-xSP,96093,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,National Ecological Observatory Network -US-xSP,96093,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-xSP,96093,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,neon-ameriflux@battelleecology.org -US-xSP,96093,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xSP,96093,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xSP,96089,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,David Durden -US-xSP,96089,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-xSP,96089,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,ddurden@battelleecology.org -US-xSP,96089,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xSP,96089,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xSP,96090,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Stefan Metzger -US-xSP,96090,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-xSP,96090,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,smetzger@battelleecology.org -US-xSP,96090,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xSP,96090,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xSP,96091,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Christopher Florian -US-xSP,96091,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,BADMContact -US-xSP,96091,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,cflorian@battelleecology.org -US-xSP,96091,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xSP,96091,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xSP,96092,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Cove Sturtevant -US-xSP,96092,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,DataManager -US-xSP,96092,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,csturtevant@battelleecology.org -US-xSP,96092,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xSP,96092,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xSP,86378,GRP_TOWER_POWER,TOWER_POWER,Direct power -US-xSP,86390,GRP_TOWER_TYPE,TOWER_TYPE,walk-up -US-xSP,86398,GRP_URL,URL,https://www.neonscience.org/field-sites/field-sites-map/SOAP -US-xSP,24001060,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-xSP -US-xSP,86387,GRP_UTC_OFFSET,UTC_OFFSET,-8 -US-xSP,86387,GRP_UTC_OFFSET,UTC_OFFSET_COMMENT,"Pacific Standard Time (PST), please note that timestamps are converted to local standard time upon submission to AmeriFlux. Data retrieved from the NEON Data Portal will be in UTC time." -US-xSR,79771,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,The National Ecological Observatory Network is a project solely funded by the National Science Foundation and managed under cooperative agreement by Battelle. -US-xSR,86474,GRP_CLIM_AVG,MAT,19.3 -US-xSR,86474,GRP_CLIM_AVG,MAP,346 -US-xSR,86474,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Bsk -US-xSR,27000958,GRP_COUNTRY,COUNTRY,USA -US-xSR,90040,GRP_DOI,DOI,10.17190/AMF/1579543 -US-xSR,90040,GRP_DOI,DOI_CITATION,"NEON (National Ecological Observatory Network) (2022), AmeriFlux BASE US-xSR NEON Santa Rita Experimental Range (SRER), Ver. 5-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1579543" -US-xSR,90040,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-xSR,96184,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-xSR,96184,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,NEON (National Ecological Observatory Network) -US-xSR,96184,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-xSR,96184,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,neon-ameriflux@battelleecology.org -US-xSR,96184,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"NEON Program, Battelle" -US-xSR,96184,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,20160101 -US-xSR,96230,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,National Ecological Observatory Network -US-xSR,96230,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-xSR,88183,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,National Science Foundation (NSF) -US-xSR,88183,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-xSR,79764,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Grazing -US-xSR,79776,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-xSR,79776,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-xSR,79776,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20170920 -US-xSR,79776,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-xSR,79765,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-xSR,79765,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-xSR,79765,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20170920 -US-xSR,79765,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-xSR,79762,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Other -US-xSR,79762,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,Isotopes -US-xSR,79762,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20170920 -US-xSR,79762,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-xSR,23000958,GRP_HEADER,SITE_NAME,NEON Santa Rita Experimental Range (SRER) -US-xSR,86472,GRP_IGBP,IGBP,OSH -US-xSR,86471,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-xSR,86471,GRP_LAND_OWNERSHIP,LAND_OWNER,University of Arizona -US-xSR,86469,GRP_LOCATION,LOCATION_LAT,31.9107 -US-xSR,86469,GRP_LOCATION,LOCATION_LONG,-110.8355 -US-xSR,86469,GRP_LOCATION,LOCATION_ELEV,983 -US-xSR,79778,GRP_NETWORK,NETWORK,AmeriFlux -US-xSR,79766,GRP_NETWORK,NETWORK,NEON -US-xSR,87066,GRP_NETWORK,NETWORK,Phenocam -US-xSR,1700005379,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(11), 108350" -US-xSR,1700005379,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -US-xSR,1700005379,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-xSR,1700008958,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Metzger, S., Ayres, E., Durden, D., Florian, C., Lee, R., Lunch, C., Luo, H., Pingintha-Durden, N., Roberti, J. A., SanClements, M., Sturtevant, C., Xu, K., Zulueta, R. C. (2019) From NEON field sites to data portal: a community resource for surface–atmosphere research comes online, Bulletin Of The American Meteorological Society, 100(11), 2305-2325" -US-xSR,1700008958,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1175/BAMS-D-17-0307.1 -US-xSR,1700008958,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-xSR,86470,GRP_SITE_CHAR,WIND_DIRECTION,ESE -US-xSR,86473,GRP_SITE_DESC,SITE_DESC,"Santa Rita Experimental Range encompasses 21,000 hectares of upland Sonoran Desert, approximately 32 km south of Tucson, Arizona. Santa Rita Experimental Range was founded in 1903. It is the longest continuously active rangeland research facility and among the five oldest biological field stations in the United States. The site is broken into distinct pastures, through which cattle graze throughout the year in various densities and durations." -US-xSR,79768,GRP_SITE_FUNDING,SITE_FUNDING,National Science Foundation (NSF) -US-xSR,86476,GRP_STATE,STATE,AZ -US-xSR,96096,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,National Ecological Observatory Network -US-xSR,96096,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-xSR,96096,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,neon-ameriflux@battelleecology.org -US-xSR,96096,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xSR,96096,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xSR,96095,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,David Durden -US-xSR,96095,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-xSR,96095,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,ddurden@battelleecology.org -US-xSR,96095,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xSR,96095,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xSR,96098,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Stefan Metzger -US-xSR,96098,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-xSR,96098,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,smetzger@battelleecology.org -US-xSR,96098,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xSR,96098,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xSR,96097,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Christopher Florian -US-xSR,96097,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,BADMContact -US-xSR,96097,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,cflorian@battelleecology.org -US-xSR,96097,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xSR,96097,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xSR,96094,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Cove Sturtevant -US-xSR,96094,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,DataManager -US-xSR,96094,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,csturtevant@battelleecology.org -US-xSR,96094,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xSR,96094,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xSR,79772,GRP_TOWER_POWER,TOWER_POWER,Direct power -US-xSR,79779,GRP_TOWER_TYPE,TOWER_TYPE,walk-up -US-xSR,86475,GRP_URL,URL,http://www.neonscience.org/field-sites/field-sites-map/SRER -US-xSR,24000958,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-xSR -US-xSR,79763,GRP_UTC_OFFSET,UTC_OFFSET,-7 -US-xSR,79763,GRP_UTC_OFFSET,UTC_OFFSET_COMMENT,"Mountain Standard Time (MST), please note that timestamps are converted to local standard time upon submission to AmeriFlux. Data retrieved from the NEON Data Portal will be in UTC time." -US-xST,86353,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,The National Ecological Observatory Network is a project solely funded by the National Science Foundation and managed under cooperative agreement by Battelle. -US-xST,86342,GRP_CLIM_AVG,MAT,4.8 -US-xST,86342,GRP_CLIM_AVG,MAP,797.56 -US-xST,86342,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfb -US-xST,27001059,GRP_COUNTRY,COUNTRY,USA -US-xST,91679,GRP_DOI,DOI,10.17190/AMF/1617737 -US-xST,91679,GRP_DOI,DOI_CITATION,"NEON (National Ecological Observatory Network) (2022), AmeriFlux BASE US-xST NEON Steigerwaldt Land Services (STEI), Ver. 5-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1617737" -US-xST,91679,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-xST,96185,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-xST,96185,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,NEON (National Ecological Observatory Network) -US-xST,96185,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-xST,96185,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,neon-ameriflux@battelleecology.org -US-xST,96185,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"NEON Program, Battelle" -US-xST,96185,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,20160101 -US-xST,96231,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,National Ecological Observatory Network -US-xST,96231,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-xST,91614,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,National Science Foundation (NSF) -US-xST,91614,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-xST,86347,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Forestry -US-xST,86349,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-xST,86349,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-xST,86349,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20170906 -US-xST,86349,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-xST,86340,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-xST,86340,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-xST,86340,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20170906 -US-xST,86340,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-xST,86341,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Other -US-xST,86341,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,Isotopes -US-xST,86341,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20170906 -US-xST,86341,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-xST,23001059,GRP_HEADER,SITE_NAME,NEON Steigerwaldt Land Services (STEI) -US-xST,86338,GRP_IGBP,IGBP,DBF -US-xST,86351,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -US-xST,86351,GRP_LAND_OWNERSHIP,LAND_OWNER,Steigerwaldt Land Services -US-xST,86345,GRP_LOCATION,LOCATION_LAT,45.5089 -US-xST,86345,GRP_LOCATION,LOCATION_LONG,-89.5864 -US-xST,86345,GRP_LOCATION,LOCATION_ELEV,481 -US-xST,86352,GRP_NETWORK,NETWORK,AmeriFlux -US-xST,86348,GRP_NETWORK,NETWORK,NEON -US-xST,87067,GRP_NETWORK,NETWORK,Phenocam -US-xST,1700009018,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Metzger, S., Ayres, E., Durden, D., Florian, C., Lee, R., Lunch, C., Luo, H., Pingintha-Durden, N., Roberti, J. A., SanClements, M., Sturtevant, C., Xu, K., Zulueta, R. C. (2019) From NEON field sites to data portal: a community resource for surface–atmosphere research comes online, Bulletin Of The American Meteorological Society, 100(11), 2305-2325" -US-xST,1700009018,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1175/BAMS-D-17-0307.1 -US-xST,1700009018,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-xST,86350,GRP_SITE_CHAR,WIND_DIRECTION,WSW -US-xST,86337,GRP_SITE_FUNDING,SITE_FUNDING,National Science Foundation (NSF) -US-xST,86336,GRP_STATE,STATE,WI -US-xST,96099,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,National Ecological Observatory Network -US-xST,96099,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-xST,96099,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,neon-ameriflux@battelleecology.org -US-xST,96099,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xST,96099,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xST,96102,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,David Durden -US-xST,96102,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-xST,96102,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,ddurden@battelleecology.org -US-xST,96102,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xST,96102,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xST,96101,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Stefan Metzger -US-xST,96101,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-xST,96101,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,smetzger@battelleecology.org -US-xST,96101,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xST,96101,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xST,96103,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Christopher Florian -US-xST,96103,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,BADMContact -US-xST,96103,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,cflorian@battelleecology.org -US-xST,96103,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xST,96103,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xST,96100,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Cove Sturtevant -US-xST,96100,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,DataManager -US-xST,96100,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,csturtevant@battelleecology.org -US-xST,96100,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xST,96100,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xST,86354,GRP_TOWER_POWER,TOWER_POWER,Direct power -US-xST,86335,GRP_TOWER_TYPE,TOWER_TYPE,walk-up -US-xST,86334,GRP_URL,URL,https://www.neonscience.org/field-sites/field-sites-map/STEI -US-xST,24001059,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-xST -US-xST,86343,GRP_UTC_OFFSET,UTC_OFFSET,-6 -US-xST,86343,GRP_UTC_OFFSET,UTC_OFFSET_COMMENT,"Central Standard Time (CST), please note that timestamps are converted to local standard time upon submission to AmeriFlux. Data retrieved from the NEON Data Portal will be in UTC time." -US-xTA,86374,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,The National Ecological Observatory Network is a project solely funded by the National Science Foundation and managed under cooperative agreement by Battelle. -US-xTA,86373,GRP_CLIM_AVG,MAT,17.2 -US-xTA,86373,GRP_CLIM_AVG,MAP,1382.68 -US-xTA,86373,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Cfa -US-xTA,27001058,GRP_COUNTRY,COUNTRY,USA -US-xTA,94276,GRP_DOI,DOI,10.17190/AMF/1671902 -US-xTA,94276,GRP_DOI,DOI_CITATION,"NEON (National Ecological Observatory Network) (2022), AmeriFlux BASE US-xTA NEON Talladega National Forest (TALL), Ver. 4-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1671902" -US-xTA,94276,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-xTA,96186,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-xTA,96186,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,NEON (National Ecological Observatory Network) -US-xTA,96186,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-xTA,96186,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,neon-ameriflux@battelleecology.org -US-xTA,96186,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"NEON Program, Battelle" -US-xTA,96186,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,20160101 -US-xTA,96232,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,National Ecological Observatory Network -US-xTA,96232,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-xTA,94255,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,National Science Foundation (NSF) -US-xTA,94255,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-xTA,86372,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Forestry -US-xTA,86357,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-xTA,86357,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-xTA,86357,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20170911 -US-xTA,86357,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-xTA,86361,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-xTA,86361,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-xTA,86361,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20170911 -US-xTA,86361,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-xTA,86363,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Other -US-xTA,86363,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,Isotopes -US-xTA,86363,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20170911 -US-xTA,86363,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-xTA,23001058,GRP_HEADER,SITE_NAME,NEON Talladega National Forest (TALL) -US-xTA,86369,GRP_IGBP,IGBP,ENF -US-xTA,86356,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-xTA,86356,GRP_LAND_OWNERSHIP,LAND_OWNER,U.S. Forest Service -US-xTA,86358,GRP_LOCATION,LOCATION_LAT,32.9505 -US-xTA,86358,GRP_LOCATION,LOCATION_LONG,-87.3933 -US-xTA,86358,GRP_LOCATION,LOCATION_ELEV,135 -US-xTA,86367,GRP_NETWORK,NETWORK,AmeriFlux -US-xTA,86355,GRP_NETWORK,NETWORK,NEON -US-xTA,87068,GRP_NETWORK,NETWORK,Phenocam -US-xTA,1700006525,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Metzger, S., Ayres, E., Durden, D., Florian, C., Lee, R., Lunch, C., Luo, H., Pingintha-Durden, N., Roberti, J. A., SanClements, M., Sturtevant, C., Xu, K., Zulueta, R. C. (2019) From NEON field sites to data portal: a community resource for surface–atmosphere research comes online, Bulletin Of The American Meteorological Society, 100(11), 2305-2325" -US-xTA,1700006525,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1175/BAMS-D-17-0307.1 -US-xTA,1700006525,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-xTA,86376,GRP_SITE_CHAR,WIND_DIRECTION,N -US-xTA,86368,GRP_SITE_DESC,SITE_DESC,"The TALL terrestrial field site covers 5300 hectares within the larger Oakmulgee District of the Talladega National Forest (475,000 hectares) in west-central Alabama. TALL is located within the Gulf Coastal Plain which is the dominant physiographic province (52%) of NEON's Domain 8: Ozarks Complex. It is also where the upper coastal plain gives rise to the Appalachian foothills. The lands of this region are rich a mosaic of forest types and habitats. Steep ridges to rolling hills fading to hardwood bottoms make up the diversity of forest conditions found in Oakmulgee. While known for its longleaf forests, over 40% of Oakmulgee is covered with a mixture of hardwoods and wetlands." -US-xTA,86366,GRP_SITE_FUNDING,SITE_FUNDING,National Science Foundation (NSF) -US-xTA,86360,GRP_STATE,STATE,AL -US-xTA,96107,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,National Ecological Observatory Network -US-xTA,96107,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-xTA,96107,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,neon-ameriflux@battelleecology.org -US-xTA,96107,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xTA,96107,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xTA,96108,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,David Durden -US-xTA,96108,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-xTA,96108,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,ddurden@battelleecology.org -US-xTA,96108,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xTA,96108,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xTA,96105,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Stefan Metzger -US-xTA,96105,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-xTA,96105,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,smetzger@battelleecology.org -US-xTA,96105,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xTA,96105,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xTA,96106,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Christopher Florian -US-xTA,96106,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,BADMContact -US-xTA,96106,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,cflorian@battelleecology.org -US-xTA,96106,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xTA,96106,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xTA,96104,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Cove Sturtevant -US-xTA,96104,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,DataManager -US-xTA,96104,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,csturtevant@battelleecology.org -US-xTA,96104,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xTA,96104,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xTA,86362,GRP_TOWER_POWER,TOWER_POWER,Direct power -US-xTA,86375,GRP_TOWER_TYPE,TOWER_TYPE,walk-up -US-xTA,86364,GRP_URL,URL,https://www.neonscience.org/field-sites/field-sites-map/TALL -US-xTA,24001058,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-xTA -US-xTA,86359,GRP_UTC_OFFSET,UTC_OFFSET,-6 -US-xTA,86359,GRP_UTC_OFFSET,UTC_OFFSET_COMMENT,"Central Standard Time (CST), please note that timestamps are converted to local standard time upon submission to AmeriFlux. Data retrieved from the NEON Data Portal will be in UTC time." -US-xTE,86300,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,The National Ecological Observatory Network is a project solely funded by the National Science Foundation and managed under cooperative agreement by Battelle. -US-xTE,86292,GRP_CLIM_AVG,MAT,8 -US-xTE,86292,GRP_CLIM_AVG,MAP,1222.5 -US-xTE,86292,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Csa -US-xTE,27001057,GRP_COUNTRY,COUNTRY,USA -US-xTE,91689,GRP_DOI,DOI,10.17190/AMF/1617738 -US-xTE,91689,GRP_DOI,DOI_CITATION,"NEON (National Ecological Observatory Network) (2022), AmeriFlux BASE US-xTE NEON Lower Teakettle (TEAK), Ver. 5-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1617738" -US-xTE,91689,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-xTE,96187,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-xTE,96187,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,NEON (National Ecological Observatory Network) -US-xTE,96187,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-xTE,96187,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,neon-ameriflux@battelleecology.org -US-xTE,96187,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"NEON Program, Battelle" -US-xTE,96187,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,20160101 -US-xTE,96233,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,National Ecological Observatory Network -US-xTE,96233,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-xTE,91621,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,National Science Foundation (NSF) -US-xTE,91621,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-xTE,86301,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-xTE,86301,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-xTE,86301,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20180803 -US-xTE,86301,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-xTE,86297,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-xTE,86297,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-xTE,86297,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20180803 -US-xTE,86297,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-xTE,86310,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Other -US-xTE,86310,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,Isotopes -US-xTE,86310,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20180803 -US-xTE,86310,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-xTE,23001057,GRP_HEADER,SITE_NAME,NEON Lower Teakettle (TEAK) -US-xTE,86304,GRP_IGBP,IGBP,ENF -US-xTE,86311,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-xTE,86311,GRP_LAND_OWNERSHIP,LAND_OWNER,U.S. Forest Service -US-xTE,86293,GRP_LOCATION,LOCATION_LAT,37.0058 -US-xTE,86293,GRP_LOCATION,LOCATION_LONG,-119.0060 -US-xTE,86293,GRP_LOCATION,LOCATION_ELEV,2147 -US-xTE,86308,GRP_NETWORK,NETWORK,AmeriFlux -US-xTE,86296,GRP_NETWORK,NETWORK,NEON -US-xTE,1700004419,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Metzger, S., Ayres, E., Durden, D., Florian, C., Lee, R., Lunch, C., Luo, H., Pingintha-Durden, N., Roberti, J. A., SanClements, M., Sturtevant, C., Xu, K., Zulueta, R. C. (2019) From NEON field sites to data portal: a community resource for surface–atmosphere research comes online, Bulletin Of The American Meteorological Society, 100(11), 2305-2325" -US-xTE,1700004419,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1175/BAMS-D-17-0307.1 -US-xTE,1700004419,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-xTE,86303,GRP_SITE_CHAR,WIND_DIRECTION,NW -US-xTE,86295,GRP_SITE_DESC,SITE_DESC,"The site encompasses 5,138 hectares (12,696 acres) of mixed conifer and red fir forest, ranging in elevation from 1,990 to 2,807 m (6,529 – 9,209ft). The varied terrain is typical of the Sierra Nevada, with rugged mountains, meadows and prominent granite outcrops. TEAK has been designated as one of two relocatable terrestrial sites for the Pacific Southwest domain. The core aquatic site, Teakettle Creek, is just south of the terrestrial site." -US-xTE,86299,GRP_SITE_FUNDING,SITE_FUNDING,National Science Foundation (NSF) -US-xTE,86298,GRP_STATE,STATE,CA -US-xTE,96112,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,National Ecological Observatory Network -US-xTE,96112,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-xTE,96112,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,neon-ameriflux@battelleecology.org -US-xTE,96112,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xTE,96112,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xTE,96110,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,David Durden -US-xTE,96110,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-xTE,96110,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,ddurden@battelleecology.org -US-xTE,96110,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xTE,96110,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xTE,96111,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Stefan Metzger -US-xTE,96111,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-xTE,96111,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,smetzger@battelleecology.org -US-xTE,96111,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xTE,96111,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xTE,96109,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Christopher Florian -US-xTE,96109,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,BADMContact -US-xTE,96109,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,cflorian@battelleecology.org -US-xTE,96109,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xTE,96109,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xTE,96113,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Cove Sturtevant -US-xTE,96113,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,DataManager -US-xTE,96113,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,csturtevant@battelleecology.org -US-xTE,96113,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xTE,96113,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xTE,86306,GRP_TOWER_POWER,TOWER_POWER,Direct power -US-xTE,86309,GRP_TOWER_TYPE,TOWER_TYPE,walk-up -US-xTE,86305,GRP_URL,URL,https://www.neonscience.org/field-sites/field-sites-map/TEAK -US-xTE,24001057,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-xTE -US-xTE,86302,GRP_UTC_OFFSET,UTC_OFFSET,-8 -US-xTE,86302,GRP_UTC_OFFSET,UTC_OFFSET_COMMENT,"Pacific Standard Time (PST), please note that timestamps are converted to local standard time upon submission to AmeriFlux. Data retrieved from the NEON Data Portal will be in UTC time." -US-xTL,86216,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,The National Ecological Observatory Network is a project solely funded by the National Science Foundation and managed under cooperative agreement by Battelle. -US-xTL,86225,GRP_CLIM_AVG,MAT,-4 -US-xTL,86225,GRP_CLIM_AVG,MAP,331 -US-xTL,86225,GRP_CLIM_AVG,CLIMATE_KOEPPEN,ET -US-xTL,27001053,GRP_COUNTRY,COUNTRY,USA -US-xTL,91711,GRP_DOI,DOI,10.17190/AMF/1617739 -US-xTL,91711,GRP_DOI,DOI_CITATION,"NEON (National Ecological Observatory Network) (2022), AmeriFlux BASE US-xTL NEON Toolik (TOOL), Ver. 5-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1617739" -US-xTL,91711,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-xTL,96188,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-xTL,96188,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,NEON (National Ecological Observatory Network) -US-xTL,96188,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-xTL,96188,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,neon-ameriflux@battelleecology.org -US-xTL,96188,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"NEON Program, Battelle" -US-xTL,96188,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,20160101 -US-xTL,96234,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,National Ecological Observatory Network -US-xTL,96234,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-xTL,91610,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,National Science Foundation (NSF) -US-xTL,91610,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-xTL,86221,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-xTL,86221,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-xTL,86221,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20170907 -US-xTL,86221,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-xTL,86227,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-xTL,86227,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-xTL,86227,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20170907 -US-xTL,86227,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-xTL,86210,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Other -US-xTL,86210,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,Isotopes -US-xTL,86210,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20170907 -US-xTL,86210,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-xTL,23001053,GRP_HEADER,SITE_NAME,NEON Toolik (TOOL) -US-xTL,86222,GRP_IGBP,IGBP,WET -US-xTL,86212,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-xTL,86212,GRP_LAND_OWNERSHIP,LAND_OWNER,Bureau of Land Management -US-xTL,86223,GRP_LOCATION,LOCATION_LAT,68.6611 -US-xTL,86223,GRP_LOCATION,LOCATION_LONG,-149.3705 -US-xTL,86223,GRP_LOCATION,LOCATION_ELEV,843 -US-xTL,86219,GRP_NETWORK,NETWORK,AmeriFlux -US-xTL,86209,GRP_NETWORK,NETWORK,NEON -US-xTL,87069,GRP_NETWORK,NETWORK,Phenocam -US-xTL,1700002826,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Metzger, S., Ayres, E., Durden, D., Florian, C., Lee, R., Lunch, C., Luo, H., Pingintha-Durden, N., Roberti, J. A., SanClements, M., Sturtevant, C., Xu, K., Zulueta, R. C. (2019) From NEON field sites to data portal: a community resource for surface–atmosphere research comes online, Bulletin Of The American Meteorological Society, 100(11), 2305-2325" -US-xTL,1700002826,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1175/BAMS-D-17-0307.1 -US-xTL,1700002826,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-xTL,86228,GRP_SITE_CHAR,WIND_DIRECTION,S -US-xTL,86218,GRP_SITE_DESC,SITE_DESC,"The Toolik field site is located in a remote wilderness area at the Toolik Field Station which is on land managed by the Bureau of Land Management. The area is underlain by continuous permafrost, which exerts a major influence on hydrology and the distribution, structure, and function of terrestrial and aquatic ecosystems. Because of its location between the Brooks Range and the coastal plain, the vegetation and soils at TOOL are representative of much of the Alaskan foothills tundra. - -This terrestrial field site is collocated with NEON’s Toolik Lake aquatic site. The closest city, Fairbanks, Alaska is 400 miles away. The Dalton Highway (also known as the Haul Road or Pipeline Road), which traverses the middle of the state from Fairbanks to Prudhoe Bay, provides access to the area." -US-xTL,86224,GRP_SITE_FUNDING,SITE_FUNDING,National Science Foundation (NSF) -US-xTL,86217,GRP_STATE,STATE,AK -US-xTL,96114,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,National Ecological Observatory Network -US-xTL,96114,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-xTL,96114,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,neon-ameriflux@battelleecology.org -US-xTL,96114,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xTL,96114,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xTL,96118,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,David Durden -US-xTL,96118,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-xTL,96118,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,ddurden@battelleecology.org -US-xTL,96118,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xTL,96118,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xTL,96117,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Stefan Metzger -US-xTL,96117,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-xTL,96117,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,smetzger@battelleecology.org -US-xTL,96117,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xTL,96117,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xTL,96116,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Christopher Florian -US-xTL,96116,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,BADMContact -US-xTL,96116,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,cflorian@battelleecology.org -US-xTL,96116,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xTL,96116,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xTL,96115,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Cove Sturtevant -US-xTL,96115,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,DataManager -US-xTL,96115,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,csturtevant@battelleecology.org -US-xTL,96115,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xTL,96115,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xTL,86226,GRP_TOWER_POWER,TOWER_POWER,Direct power -US-xTL,86213,GRP_TOWER_TYPE,TOWER_TYPE,walk-up -US-xTL,86211,GRP_URL,URL,https://www.neonscience.org/field-sites/field-sites-map/TOOL -US-xTL,24001053,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-xTL -US-xTL,86229,GRP_UTC_OFFSET,UTC_OFFSET,-9 -US-xTL,86229,GRP_UTC_OFFSET,UTC_OFFSET_COMMENT,"Alaska Standard Time (AKST), please note that timestamps are converted to local standard time upon submission to AmeriFlux. Data retrieved from the NEON Data Portal will be in UTC time." -US-xTR,86440,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,The National Ecological Observatory Network is a project solely funded by the National Science Foundation and managed under cooperative agreement by Battelle. -US-xTR,86447,GRP_CLIM_AVG,MAT,4.8 -US-xTR,86447,GRP_CLIM_AVG,MAP,797.56 -US-xTR,86447,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfb -US-xTR,27001048,GRP_COUNTRY,COUNTRY,USA -US-xTR,92874,GRP_DOI,DOI,10.17190/AMF/1634886 -US-xTR,92874,GRP_DOI,DOI_CITATION,"NEON (National Ecological Observatory Network) (2022), AmeriFlux BASE US-xTR NEON Treehaven (TREE), Ver. 5-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1634886" -US-xTR,92874,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-xTR,96189,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-xTR,96189,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,NEON (National Ecological Observatory Network) -US-xTR,96189,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-xTR,96189,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,neon-ameriflux@battelleecology.org -US-xTR,96189,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"NEON Program, Battelle" -US-xTR,96189,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,20160101 -US-xTR,96235,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,National Ecological Observatory Network -US-xTR,96235,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-xTR,92846,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,National Science Foundation (NSF) -US-xTR,92846,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-xTR,86443,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Forestry -US-xTR,86429,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-xTR,86429,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-xTR,86429,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20170815 -US-xTR,86429,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-xTR,86438,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-xTR,86438,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-xTR,86438,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20170815 -US-xTR,86438,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-xTR,86430,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Other -US-xTR,86430,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,Isotopes -US-xTR,86430,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20170815 -US-xTR,86430,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-xTR,23001048,GRP_HEADER,SITE_NAME,NEON Treehaven (TREE) -US-xTR,86434,GRP_IGBP,IGBP,DBF -US-xTR,86437,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -US-xTR,86437,GRP_LAND_OWNERSHIP,LAND_OWNER,"University of Wisconsin, Stevens Point" -US-xTR,86433,GRP_LOCATION,LOCATION_LAT,45.4937 -US-xTR,86433,GRP_LOCATION,LOCATION_LONG,-89.5857 -US-xTR,86433,GRP_LOCATION,LOCATION_ELEV,472 -US-xTR,86445,GRP_NETWORK,NETWORK,AmeriFlux -US-xTR,86448,GRP_NETWORK,NETWORK,NEON -US-xTR,87070,GRP_NETWORK,NETWORK,Phenocam -US-xTR,1700004266,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Metzger, S., Ayres, E., Durden, D., Florian, C., Lee, R., Lunch, C., Luo, H., Pingintha-Durden, N., Roberti, J. A., SanClements, M., Sturtevant, C., Xu, K., Zulueta, R. C. (2019) From NEON field sites to data portal: a community resource for surface–atmosphere research comes online, Bulletin Of The American Meteorological Society, 100(11), 2305-2325" -US-xTR,1700004266,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1175/BAMS-D-17-0307.1 -US-xTR,1700004266,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-xTR,86439,GRP_SITE_CHAR,WIND_DIRECTION,WSW -US-xTR,86450,GRP_SITE_DESC,SITE_DESC,"Treehaven, situated between Rhinelander and Tomahawk, WI, is one of two relocatable sites located in NEON’s Great Lakes Domain. The Treehaven property spans 1400 acres and is owned and operated by the University of Wisconsin-Stevens Point (UWSP), College of Natural Resources. UWSP uses the property and conference center for summer field techniques courses but welcomes other educators, researchers, and the public to use and enjoy their forests, trails, and facility." -US-xTR,86435,GRP_SITE_FUNDING,SITE_FUNDING,National Science Foundation (NSF) -US-xTR,86444,GRP_STATE,STATE,WI -US-xTR,96119,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,National Ecological Observatory Network -US-xTR,96119,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-xTR,96119,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,neon-ameriflux@battelleecology.org -US-xTR,96119,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xTR,96119,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xTR,96122,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,David Durden -US-xTR,96122,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-xTR,96122,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,ddurden@battelleecology.org -US-xTR,96122,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xTR,96122,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xTR,96121,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Stefan Metzger -US-xTR,96121,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-xTR,96121,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,smetzger@battelleecology.org -US-xTR,96121,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xTR,96121,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xTR,96120,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Christopher Florian -US-xTR,96120,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,BADMContact -US-xTR,96120,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,cflorian@battelleecology.org -US-xTR,96120,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xTR,96120,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xTR,96123,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Cove Sturtevant -US-xTR,96123,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,DataManager -US-xTR,96123,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,csturtevant@battelleecology.org -US-xTR,96123,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xTR,96123,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xTR,86449,GRP_TOWER_POWER,TOWER_POWER,Direct power -US-xTR,86432,GRP_TOWER_TYPE,TOWER_TYPE,walk-up -US-xTR,86431,GRP_URL,URL,https://www.neonscience.org/field-sites/field-sites-map/TREE -US-xTR,24001048,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-xTR -US-xTR,86446,GRP_UTC_OFFSET,UTC_OFFSET,-6 -US-xTR,86446,GRP_UTC_OFFSET,UTC_OFFSET_COMMENT,"Central Standard Time (CST), please note that timestamps are converted to local standard time upon submission to AmeriFlux. Data retrieved from the NEON Data Portal will be in UTC time." -US-xUK,86140,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,The National Ecological Observatory Network is a project solely funded by the National Science Foundation and managed under cooperative agreement by Battelle. -US-xUK,86141,GRP_CLIM_AVG,MAT,12.7 -US-xUK,86141,GRP_CLIM_AVG,MAP,990.63 -US-xUK,86141,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Cfa -US-xUK,27001047,GRP_COUNTRY,COUNTRY,USA -US-xUK,91696,GRP_DOI,DOI,10.17190/AMF/1617740 -US-xUK,91696,GRP_DOI,DOI_CITATION,"NEON (National Ecological Observatory Network) (2022), AmeriFlux BASE US-xUK NEON The University of Kansas Field Station (UKFS), Ver. 5-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1617740" -US-xUK,91696,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-xUK,96190,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-xUK,96190,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,NEON (National Ecological Observatory Network) -US-xUK,96190,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-xUK,96190,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,neon-ameriflux@battelleecology.org -US-xUK,96190,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"NEON Program, Battelle" -US-xUK,96190,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,20160101 -US-xUK,96236,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,National Ecological Observatory Network -US-xUK,96236,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-xUK,91620,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,National Science Foundation (NSF) -US-xUK,91620,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-xUK,86132,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-xUK,86132,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-xUK,86132,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20170815 -US-xUK,86132,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-xUK,86136,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-xUK,86136,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-xUK,86136,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20170815 -US-xUK,86136,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-xUK,86137,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Other -US-xUK,86137,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,Isotopes -US-xUK,86137,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20170815 -US-xUK,86137,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-xUK,23001047,GRP_HEADER,SITE_NAME,NEON The University of Kansas Field Station (UKFS) -US-xUK,86133,GRP_IGBP,IGBP,DBF -US-xUK,86125,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -US-xUK,86125,GRP_LAND_OWNERSHIP,LAND_OWNER,University of Kansas -US-xUK,86145,GRP_LOCATION,LOCATION_LAT,39.0404 -US-xUK,86145,GRP_LOCATION,LOCATION_LONG,-95.1921 -US-xUK,86145,GRP_LOCATION,LOCATION_ELEV,335 -US-xUK,86126,GRP_NETWORK,NETWORK,AmeriFlux -US-xUK,86135,GRP_NETWORK,NETWORK,NEON -US-xUK,87071,GRP_NETWORK,NETWORK,Phenocam -US-xUK,1700004389,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Metzger, S., Ayres, E., Durden, D., Florian, C., Lee, R., Lunch, C., Luo, H., Pingintha-Durden, N., Roberti, J. A., SanClements, M., Sturtevant, C., Xu, K., Zulueta, R. C. (2019) From NEON field sites to data portal: a community resource for surface–atmosphere research comes online, Bulletin Of The American Meteorological Society, 100(11), 2305-2325" -US-xUK,1700004389,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1175/BAMS-D-17-0307.1 -US-xUK,1700004389,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-xUK,86143,GRP_SITE_CHAR,WIND_DIRECTION,SE -US-xUK,86130,GRP_SITE_DESC,SITE_DESC,"Along an eastern deciduous forest and tallgrass prairie transition zone just north of Lawrence, Kansas, this 6 km2 terrestrial field site is located at the University of Kansas Field Station. A 116' tall flux tower rises out of a mixed hardwood forest dominated by white ash trees. Field obdservations of plants, animals, soils and microbes are collected around the tower and in the nearby tallgrass prairie." -US-xUK,86131,GRP_SITE_FUNDING,SITE_FUNDING,National Science Foundation (NSF) -US-xUK,86139,GRP_STATE,STATE,KS -US-xUK,96127,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,National Ecological Observatory Network -US-xUK,96127,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-xUK,96127,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,neon-ameriflux@battelleecology.org -US-xUK,96127,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xUK,96127,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xUK,96125,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,David Durden -US-xUK,96125,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-xUK,96125,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,ddurden@battelleecology.org -US-xUK,96125,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xUK,96125,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xUK,96126,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Stefan Metzger -US-xUK,96126,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-xUK,96126,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,smetzger@battelleecology.org -US-xUK,96126,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xUK,96126,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xUK,96128,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Christopher Florian -US-xUK,96128,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,BADMContact -US-xUK,96128,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,cflorian@battelleecology.org -US-xUK,96128,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xUK,96128,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xUK,96124,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Cove Sturtevant -US-xUK,96124,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,DataManager -US-xUK,96124,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,csturtevant@battelleecology.org -US-xUK,96124,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xUK,96124,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xUK,86138,GRP_TOWER_POWER,TOWER_POWER,Direct power -US-xUK,86127,GRP_TOWER_TYPE,TOWER_TYPE,walk-up -US-xUK,86128,GRP_URL,URL,https://www.neonscience.org/field-sites/field-sites-map/UKFS -US-xUK,24001047,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-xUK -US-xUK,86144,GRP_UTC_OFFSET,UTC_OFFSET,-6 -US-xUK,86144,GRP_UTC_OFFSET,UTC_OFFSET_COMMENT,"Central Standard Time (CST), please note that timestamps are converted to local standard time upon submission to AmeriFlux. Data retrieved from the NEON Data Portal will be in UTC time." -US-xUN,79756,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,The National Ecological Observatory Network is a project solely funded by the National Science Foundation and managed under cooperative agreement by Battelle. -US-xUN,79751,GRP_CLIM_AVG,MAT,4.3 -US-xUN,79751,GRP_CLIM_AVG,MAP,802.3 -US-xUN,79751,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfb -US-xUN,27000959,GRP_COUNTRY,COUNTRY,USA -US-xUN,91687,GRP_DOI,DOI,10.17190/AMF/1617741 -US-xUN,91687,GRP_DOI,DOI_CITATION,"NEON (National Ecological Observatory Network) (2022), AmeriFlux BASE US-xUN NEON University of Notre Dame Environmental Research Center (UNDE), Ver. 5-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1617741" -US-xUN,91687,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-xUN,96191,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-xUN,96191,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,NEON (National Ecological Observatory Network) -US-xUN,96191,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-xUN,96191,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,neon-ameriflux@battelleecology.org -US-xUN,96191,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"NEON Program, Battelle" -US-xUN,96191,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,20160101 -US-xUN,96237,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,National Ecological Observatory Network -US-xUN,96237,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-xUN,91626,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,National Science Foundation (NSF) -US-xUN,91626,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-xUN,79742,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Forestry -US-xUN,79741,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-xUN,79741,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-xUN,79741,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20170216 -US-xUN,79741,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-xUN,79744,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-xUN,79744,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-xUN,79744,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20170216 -US-xUN,79744,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-xUN,79752,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Other -US-xUN,79752,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,Isotopes -US-xUN,79752,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20170216 -US-xUN,79752,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-xUN,23000959,GRP_HEADER,SITE_NAME,NEON University of Notre Dame Environmental Research Center (UNDE) -US-xUN,79753,GRP_IGBP,IGBP,MF -US-xUN,79749,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,private -US-xUN,79749,GRP_LAND_OWNERSHIP,LAND_OWNER,University of Notre Dame Environmental Research Center -US-xUN,79747,GRP_LOCATION,LOCATION_LAT,46.2339 -US-xUN,79747,GRP_LOCATION,LOCATION_LONG,-89.5373 -US-xUN,79747,GRP_LOCATION,LOCATION_ELEV,518 -US-xUN,79750,GRP_NETWORK,NETWORK,AmeriFlux -US-xUN,79743,GRP_NETWORK,NETWORK,NEON -US-xUN,87072,GRP_NETWORK,NETWORK,Phenocam -US-xUN,1700007368,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Metzger, S., Ayres, E., Durden, D., Florian, C., Lee, R., Lunch, C., Luo, H., Pingintha-Durden, N., Roberti, J. A., SanClements, M., Sturtevant, C., Xu, K., Zulueta, R. C. (2019) From NEON field sites to data portal: a community resource for surface–atmosphere research comes online, Bulletin Of The American Meteorological Society, 100(11), 2305-2325" -US-xUN,1700007368,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1175/BAMS-D-17-0307.1 -US-xUN,1700007368,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-xUN,1700008094,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Xu, K., Pingintha-Durden, N., Luo, H., Durden, D., Sturtevant, C., Desai, A. R., Florian, C., Metzger, S. (2019) The Eddy-Covariance Storage Term In Air: Consistent Community Resources Improve Flux Measurement Reliability, Agricultural And Forest Meteorology, 279(107734), 107734" -US-xUN,1700008094,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2019.107734 -US-xUN,1700008094,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-xUN,1700002742,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Xu, K., Pingintha-Durden, N., Luo, H., Durden, D., Sturtevant, C., Desai, A. R., Florian, C., Metzger, S. (2019) The Eddy-Covariance Storage Term In Air: Consistent Community Resources Improve Flux Measurement Reliability, Agricultural And Forest Meteorology, 279(11), 107734" -US-xUN,1700002742,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2019.107734 -US-xUN,1700002742,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-xUN,79739,GRP_SITE_DESC,SITE_DESC,"NEON's Domain 5 core site is located at the University of Notre Dame Environmental Research Center (UNDERC) East. Straddling the border between Northern Wisconsin and Michigan’s Upper Peninsula, the UNDERC property comprises approximately 7500 acres and is maintained as an environmental education and research facility. UNDERC also has 30 lakes comprising 1350 acres, including Crampton Lake, a NEON aquatics site. Region-wide logging for pine in the late 1800s and early to mid-1900's led to clear cutting of most forested areas on the property. The main parcel was donated to the University in the 1930s. Timber harvest continued into the 1950s and later, leaving a mixture of successional forest regrowth. Since the 1970s, the site has been minimally managed to maintain access for recreational, educational and research goals." -US-xUN,79740,GRP_SITE_FUNDING,SITE_FUNDING,National Science Foundation (NSF) -US-xUN,79755,GRP_STATE,STATE,MI -US-xUN,96130,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,National Ecological Observatory Network -US-xUN,96130,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-xUN,96130,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,neon-ameriflux@battelleecology.org -US-xUN,96130,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xUN,96130,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xUN,96131,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,David Durden -US-xUN,96131,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-xUN,96131,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,ddurden@battelleecology.org -US-xUN,96131,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xUN,96131,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xUN,96132,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Stefan Metzger -US-xUN,96132,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-xUN,96132,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,smetzger@battelleecology.org -US-xUN,96132,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xUN,96132,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xUN,96133,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Christopher Florian -US-xUN,96133,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,BADMContact -US-xUN,96133,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,cflorian@battelleecology.org -US-xUN,96133,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xUN,96133,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xUN,96129,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Cove Sturtevant -US-xUN,96129,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,DataManager -US-xUN,96129,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,csturtevant@battelleecology.org -US-xUN,96129,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xUN,96129,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xUN,79738,GRP_TOWER_POWER,TOWER_POWER,Direct power -US-xUN,79746,GRP_TOWER_TYPE,TOWER_TYPE,walk-up -US-xUN,79758,GRP_URL,URL,http://www.neonscience.org/field-sites/field-sites-map/UNDE -US-xUN,24000959,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-xUN -US-xUN,79757,GRP_UTC_OFFSET,UTC_OFFSET,-6 -US-xUN,79757,GRP_UTC_OFFSET,UTC_OFFSET_COMMENT,"Central Standard Time (CST), please note that timestamps are converted to local standard time upon submission to AmeriFlux. Data retrieved from the NEON Data Portal will be in UTC time." -US-xWD,79288,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,The National Ecological Observatory Network is a project solely funded by the National Science Foundation and managed under cooperative agreement by Battelle. -US-xWD,79289,GRP_CLIM_AVG,MAT,4.9 -US-xWD,79289,GRP_CLIM_AVG,MAP,493.76 -US-xWD,79289,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfb -US-xWD,27000943,GRP_COUNTRY,COUNTRY,USA -US-xWD,90054,GRP_DOI,DOI,10.17190/AMF/1579724 -US-xWD,90054,GRP_DOI,DOI_CITATION,"NEON (National Ecological Observatory Network) (2022), AmeriFlux BASE US-xWD NEON Woodworth (WOOD), Ver. 5-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1579724" -US-xWD,90054,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-xWD,96192,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-xWD,96192,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,NEON (National Ecological Observatory Network) -US-xWD,96192,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-xWD,96192,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,neon-ameriflux@battelleecology.org -US-xWD,96192,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"NEON Program, Battelle" -US-xWD,96192,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,20160101 -US-xWD,96238,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,National Ecological Observatory Network -US-xWD,96238,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-xWD,90017,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,National Science Foundation (NSF) -US-xWD,90017,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-xWD,79290,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Grazing -US-xWD,79292,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-xWD,79292,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-xWD,79292,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20170920 -US-xWD,79292,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-xWD,79293,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-xWD,79293,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-xWD,79293,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20170920 -US-xWD,79293,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-xWD,79291,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Other -US-xWD,79291,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,Isotopes -US-xWD,79291,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20170920 -US-xWD,79291,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-xWD,23000943,GRP_HEADER,SITE_NAME,NEON Woodworth (WOOD) -US-xWD,79294,GRP_IGBP,IGBP,GRA -US-xWD,79295,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-xWD,79295,GRP_LAND_OWNERSHIP,LAND_OWNER,"U.S. Geological Survey, U.S. Fish and Wildlife Service" -US-xWD,79296,GRP_LOCATION,LOCATION_LAT,47.1282 -US-xWD,79296,GRP_LOCATION,LOCATION_LONG,-99.2414 -US-xWD,79296,GRP_LOCATION,LOCATION_ELEV,579 -US-xWD,79298,GRP_NETWORK,NETWORK,AmeriFlux -US-xWD,79297,GRP_NETWORK,NETWORK,NEON -US-xWD,87073,GRP_NETWORK,NETWORK,Phenocam -US-xWD,1700006801,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Chu, H., Luo, X., Ouyang, Z., Chan, W. S., Dengel, S., Biraud, S. C., Torn, M. S., Metzger, S., Kumar, J., Arain, M. A., Arkebauer, T. J., Baldocchi, D., Bernacchi, C., Billesbach, D., Black, T. A., Blanken, P. D., Bohrer, G., Bracho, R., Brown, S., Brunsell, N. A., Chen, J., Chen, X., Clark, K., Desai, A. R., Duman, T., Durden, D., Fares, S., Forbrich, I., Gamon, J. A., Gough, C. M., Griffis, T., Helbig, M., Hollinger, D., Humphreys, E., Ikawa, H., Iwata, H., Ju, Y., Knowles, J. F., Knox, S. H., Kobayashi, H., Kolb, T., Law, B., Lee, X., Litvak, M., Liu, H., Munger, J. W., Noormets, A., Novick, K., Oberbauer, S. F., Oechel, W., Oikawa, P., Papuga, S. A., Pendall, E., Prajapati, P., Prueger, J., Quinton, W. L., Richardson, A. D., Russell, E. S., Scott, R. L., Starr, G., Staebler, R., Stoy, P. C., Stuart-Haëntjens, E., Sonnentag, O., Sullivan, R. C., Suyker, A., Ueyama, M., Vargas, R., Wood, J. D., Zona, D. (2021) Representativeness Of Eddy-Covariance Flux Footprints For Areas Surrounding Ameriflux Sites, Agricultural And Forest Meteorology, 301-302(11), 108350" -US-xWD,1700006801,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1016/J.AGRFORMET.2021.108350 -US-xWD,1700006801,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-xWD,1700004758,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Metzger, S., Ayres, E., Durden, D., Florian, C., Lee, R., Lunch, C., Luo, H., Pingintha-Durden, N., Roberti, J. A., SanClements, M., Sturtevant, C., Xu, K., Zulueta, R. C. (2019) From NEON field sites to data portal: a community resource for surface–atmosphere research comes online, Bulletin Of The American Meteorological Society, 100(11), 2305-2325" -US-xWD,1700004758,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1175/BAMS-D-17-0307.1 -US-xWD,1700004758,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-xWD,79299,GRP_SITE_CHAR,WIND_DIRECTION,NW -US-xWD,79300,GRP_SITE_DESC,SITE_DESC,"The Northern Plains-Woodworth site (Woodworth), is a restored prairie in an undulating matrix of small lakes, ponds and ephemeral water bodies (re. prairie potholes). The site is administered by the Department of the Interior (DOI), National Fish and Wildlife, National Wildlife Refuge. The Northern Plains-Woodworth site is located at ~ 3 miles SE of the town of Woodworth, ND. The Northern Plains-Woodworth site is part of the Chase Lake National Wildlife Refuge and is at the center of one of the largest roadless blocks of native prairie left in the Upper Great Plains." -US-xWD,79301,GRP_SITE_FUNDING,SITE_FUNDING,National Science Foundation (NSF) -US-xWD,79302,GRP_STATE,STATE,ND -US-xWD,96136,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,National Ecological Observatory Network -US-xWD,96136,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-xWD,96136,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,neon-ameriflux@battelleecology.org -US-xWD,96136,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xWD,96136,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xWD,96135,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,David Durden -US-xWD,96135,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-xWD,96135,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,ddurden@battelleecology.org -US-xWD,96135,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xWD,96135,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xWD,96137,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Stefan Metzger -US-xWD,96137,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-xWD,96137,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,smetzger@battelleecology.org -US-xWD,96137,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xWD,96137,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xWD,96138,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Christopher Florian -US-xWD,96138,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,BADMContact -US-xWD,96138,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,cflorian@battelleecology.org -US-xWD,96138,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xWD,96138,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xWD,96134,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Cove Sturtevant -US-xWD,96134,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,DataManager -US-xWD,96134,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,csturtevant@battelleecology.org -US-xWD,96134,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xWD,96134,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xWD,79306,GRP_TOWER_POWER,TOWER_POWER,Direct power -US-xWD,79307,GRP_TOWER_TYPE,TOWER_TYPE,walk-up -US-xWD,79308,GRP_URL,URL,http://www.neonscience.org/field-sites/field-sites-map/WOOD -US-xWD,24000943,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-xWD -US-xWD,79401,GRP_UTC_OFFSET,UTC_OFFSET,-6 -US-xWD,79401,GRP_UTC_OFFSET,UTC_OFFSET_COMMENT,"Central Standard Time (CST), please note that timestamps are converted to local standard time upon submission to AmeriFlux. Data retrieved from the NEON Data Portal will be in UTC time." -US-xWR,86093,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,The National Ecological Observatory Network is a project solely funded by the National Science Foundation and managed under cooperative agreement by Battelle. -US-xWR,86101,GRP_CLIM_AVG,MAT,9.2 -US-xWR,86101,GRP_CLIM_AVG,MAP,2225.01 -US-xWR,86101,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Csb -US-xWR,27001046,GRP_COUNTRY,COUNTRY,USA -US-xWR,91690,GRP_DOI,DOI,10.17190/AMF/1617742 -US-xWR,91690,GRP_DOI,DOI_CITATION,"NEON (National Ecological Observatory Network) (2022), AmeriFlux BASE US-xWR NEON Wind River Experimental Forest (WREF), Ver. 5-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1617742" -US-xWR,91690,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-xWR,96193,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-xWR,96193,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,NEON (National Ecological Observatory Network) -US-xWR,96193,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-xWR,96193,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,neon-ameriflux@battelleecology.org -US-xWR,96193,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"NEON Program, Battelle" -US-xWR,96193,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,20160101 -US-xWR,96239,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,National Ecological Observatory Network -US-xWR,96239,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-xWR,91632,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,National Science Foundation (NSF) -US-xWR,91632,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-xWR,86100,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-xWR,86100,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-xWR,86100,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20180711 -US-xWR,86100,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-xWR,86083,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-xWR,86083,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-xWR,86083,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20180711 -US-xWR,86083,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-xWR,86095,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Other -US-xWR,86095,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,Isotopes -US-xWR,86095,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20180711 -US-xWR,86095,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-xWR,23001046,GRP_HEADER,SITE_NAME,NEON Wind River Experimental Forest (WREF) -US-xWR,86096,GRP_IGBP,IGBP,ENF -US-xWR,86097,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-xWR,86097,GRP_LAND_OWNERSHIP,LAND_OWNER,U.S. Forest Service -US-xWR,86091,GRP_LOCATION,LOCATION_LAT,45.8205 -US-xWR,86091,GRP_LOCATION,LOCATION_LONG,-121.9519 -US-xWR,86091,GRP_LOCATION,LOCATION_ELEV,407 -US-xWR,86088,GRP_NETWORK,NETWORK,AmeriFlux -US-xWR,86090,GRP_NETWORK,NETWORK,NEON -US-xWR,87074,GRP_NETWORK,NETWORK,Phenocam -US-xWR,1700003150,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Metzger, S., Ayres, E., Durden, D., Florian, C., Lee, R., Lunch, C., Luo, H., Pingintha-Durden, N., Roberti, J. A., SanClements, M., Sturtevant, C., Xu, K., Zulueta, R. C. (2019) From NEON field sites to data portal: a community resource for surface–atmosphere research comes online, Bulletin Of The American Meteorological Society, 100(11), 2305-2325" -US-xWR,1700003150,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1175/BAMS-D-17-0307.1 -US-xWR,1700003150,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-xWR,86089,GRP_SITE_CHAR,WIND_DIRECTION,NW -US-xWR,86086,GRP_SITE_DESC,SITE_DESC,"Located in an old growth Pacific Northwest forest west of the Cascade Range, Wind River Experimental Forest has a rich history of research and timber management since the early 1900s. The area is best known for its old-growth forests of Douglas-fir and western hemlock. - -Data collected at this site provides an interesting comparison to NEON’s ABBY site which is located Yacolt Burn State Forest, a relatively young growth industrial timber production forest." -US-xWR,86099,GRP_SITE_FUNDING,SITE_FUNDING,National Science Foundation (NSF) -US-xWR,86094,GRP_STATE,STATE,WA -US-xWR,96143,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,National Ecological Observatory Network -US-xWR,96143,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-xWR,96143,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,neon-ameriflux@battelleecology.org -US-xWR,96143,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xWR,96143,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xWR,96140,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,David Durden -US-xWR,96140,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-xWR,96140,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,ddurden@battelleecology.org -US-xWR,96140,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xWR,96140,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xWR,96139,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Stefan Metzger -US-xWR,96139,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-xWR,96139,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,smetzger@battelleecology.org -US-xWR,96139,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xWR,96139,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xWR,96141,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Christopher Florian -US-xWR,96141,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,BADMContact -US-xWR,96141,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,cflorian@battelleecology.org -US-xWR,96141,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xWR,96141,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xWR,96142,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Cove Sturtevant -US-xWR,96142,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,DataManager -US-xWR,96142,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,csturtevant@battelleecology.org -US-xWR,96142,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xWR,96142,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xWR,86098,GRP_TOWER_POWER,TOWER_POWER,Direct power -US-xWR,86084,GRP_TOWER_TYPE,TOWER_TYPE,walk-up -US-xWR,86085,GRP_URL,URL,https://www.neonscience.org/field-sites/field-sites-map/WREF -US-xWR,24001046,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-xWR -US-xWR,86103,GRP_UTC_OFFSET,UTC_OFFSET,-8 -US-xWR,86103,GRP_UTC_OFFSET,UTC_OFFSET_COMMENT,"Pacific Standard Time (PST), please note that timestamps are converted to local standard time upon submission to AmeriFlux. Data retrieved from the NEON Data Portal will be in UTC time." -US-xYE,86112,GRP_ACKNOWLEDGEMENT,ACKNOWLEDGEMENT,The National Ecological Observatory Network is a project solely funded by the National Science Foundation and managed under cooperative agreement by Battelle. -US-xYE,86110,GRP_CLIM_AVG,MAT,3.4 -US-xYE,86110,GRP_CLIM_AVG,MAP,493.44 -US-xYE,86110,GRP_CLIM_AVG,CLIMATE_KOEPPEN,Dfc -US-xYE,27001049,GRP_COUNTRY,COUNTRY,USA -US-xYE,91709,GRP_DOI,DOI,10.17190/AMF/1617743 -US-xYE,91709,GRP_DOI,DOI_CITATION,"NEON (National Ecological Observatory Network) (2022), AmeriFlux BASE US-xYE NEON Yellowstone Northern Range (Frog Rock) (YELL), Ver. 5-5, AmeriFlux AMP, (Dataset). https://doi.org/10.17190/AMF/1617743" -US-xYE,91709,GRP_DOI,DOI_DATAPRODUCT,AmeriFlux -US-xYE,96194,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATAPRODUCT,AmeriFlux -US-xYE,96194,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_NAME,NEON (National Ecological Observatory Network) -US-xYE,96194,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_ROLE,Author -US-xYE,96194,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_EMAIL,neon-ameriflux@battelleecology.org -US-xYE,96194,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_INSTITUTION,"NEON Program, Battelle" -US-xYE,96194,GRP_DOI_CONTRIBUTOR,DOI_CONTRIBUTOR_DATE_START,20160101 -US-xYE,96240,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,National Ecological Observatory Network -US-xYE,96240,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Originator -US-xYE,91619,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION,National Science Foundation (NSF) -US-xYE,91619,GRP_DOI_ORGANIZATION,DOI_ORGANIZATION_ROLE,Sponsor -US-xYE,86118,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-xYE,86118,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-xYE,86118,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20181019 -US-xYE,86118,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-xYE,86122,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-xYE,86122,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-xYE,86122,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20181019 -US-xYE,86122,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-xYE,86108,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Other -US-xYE,86108,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,Isotopes -US-xYE,86108,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,20181019 -US-xYE,86108,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-xYE,23001049,GRP_HEADER,SITE_NAME,NEON Yellowstone Northern Range (Frog Rock) (YELL) -US-xYE,86123,GRP_IGBP,IGBP,ENF -US-xYE,86109,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-xYE,86109,GRP_LAND_OWNERSHIP,LAND_OWNER,National Park Service -US-xYE,86104,GRP_LOCATION,LOCATION_LAT,44.9535 -US-xYE,86104,GRP_LOCATION,LOCATION_LONG,-110.5391 -US-xYE,86104,GRP_LOCATION,LOCATION_ELEV,2116 -US-xYE,86121,GRP_NETWORK,NETWORK,AmeriFlux -US-xYE,86116,GRP_NETWORK,NETWORK,NEON -US-xYE,1700002886,GRP_REFERENCE_PAPER,REFERENCE_PAPER,"Metzger, S., Ayres, E., Durden, D., Florian, C., Lee, R., Lunch, C., Luo, H., Pingintha-Durden, N., Roberti, J. A., SanClements, M., Sturtevant, C., Xu, K., Zulueta, R. C. (2019) From NEON field sites to data portal: a community resource for surface–atmosphere research comes online, Bulletin Of The American Meteorological Society, 100(11), 2305-2325" -US-xYE,1700002886,GRP_REFERENCE_PAPER,REFERENCE_DOI,10.1175/BAMS-D-17-0307.1 -US-xYE,1700002886,GRP_REFERENCE_PAPER,REFERENCE_USAGE,Reference -US-xYE,86117,GRP_SITE_CHAR,WIND_DIRECTION,SSE -US-xYE,86114,GRP_SITE_DESC,SITE_DESC,"Located 100 kilometers southeast of Bozeman, the YELL site is within the northern reaches of Yellowstone National Park. The terrain consists of rolling hills with small wetlands in the bottom of the depressions. The field site is a mosaic of pine-dominated forest mixed with open swaths of sage and grass.  This site is also within one of the Park’s bear management areas which includes seasonal closure (early March to early June) to minimize bear-human interactions." -US-xYE,86115,GRP_SITE_FUNDING,SITE_FUNDING,National Science Foundation (NSF) -US-xYE,86119,GRP_STATE,STATE,WY -US-xYE,96148,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,National Ecological Observatory Network -US-xYE,96148,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-xYE,96148,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,neon-ameriflux@battelleecology.org -US-xYE,96148,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xYE,96148,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xYE,96146,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,David Durden -US-xYE,96146,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-xYE,96146,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,ddurden@battelleecology.org -US-xYE,96146,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xYE,96146,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xYE,96144,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Stefan Metzger -US-xYE,96144,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-xYE,96144,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,smetzger@battelleecology.org -US-xYE,96144,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xYE,96144,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xYE,96145,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Christopher Florian -US-xYE,96145,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,BADMContact -US-xYE,96145,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,cflorian@battelleecology.org -US-xYE,96145,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xYE,96145,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xYE,96147,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Cove Sturtevant -US-xYE,96147,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,DataManager -US-xYE,96147,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,csturtevant@battelleecology.org -US-xYE,96147,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,"NEON Program, Battelle" -US-xYE,96147,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"1685 38th Street Boulder, CO 80301" -US-xYE,86111,GRP_TOWER_POWER,TOWER_POWER,Direct power -US-xYE,86107,GRP_TOWER_TYPE,TOWER_TYPE,walk-up -US-xYE,86120,GRP_URL,URL,https://www.neonscience.org/field-sites/field-sites-map/YELL -US-xYE,24001049,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-xYE -US-xYE,86106,GRP_UTC_OFFSET,UTC_OFFSET,-7 -US-xYE,86106,GRP_UTC_OFFSET,UTC_OFFSET_COMMENT,"Mountain Standard Time (MST), please note that timestamps are converted to local standard time upon submission to AmeriFlux. Data retrieved from the NEON Data Portal will be in UTC time." -US-YK1,27001196,GRP_COUNTRY,COUNTRY,USA -US-YK1,96879,GRP_DOM_DIST_MGMT,DOM_DIST_MGMT,Fire -US-YK1,96873,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-YK1,96873,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-YK1,96873,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201907111230 -US-YK1,96873,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-YK1,96878,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-YK1,96878,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CH4 -US-YK1,96878,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201907111230 -US-YK1,96878,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-YK1,96872,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-YK1,96872,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-YK1,96872,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201907111230 -US-YK1,96872,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-YK1,23001196,GRP_HEADER,SITE_NAME,"Yukon-Kuskokwim Delta, Izaviknek-Kingaglia uplands, Burned 2015" -US-YK1,96875,GRP_IGBP,IGBP,WET -US-YK1,96875,GRP_IGBP,IGBP_DATE_START,201907111230 -US-YK1,96881,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-YK1,96881,GRP_LAND_OWNERSHIP,LAND_OWNER,U.S. Fish & Wildlife Service -US-YK1,96880,GRP_LOCATION,LOCATION_LAT,61.2723 -US-YK1,96880,GRP_LOCATION,LOCATION_LONG,-163.2228 -US-YK1,96880,GRP_LOCATION,LOCATION_ELEV,15 -US-YK1,96880,GRP_LOCATION,LOCATION_DATE_START,201907111230 -US-YK1,96869,GRP_NETWORK,NETWORK,AmeriFlux -US-YK1,96866,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,permafrost thaw and fire effects on CO2 and CH4 fluxes -US-YK1,96877,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"149 Woods Hole Road, Falmouth, MA 02540 USA" -US-YK1,96871,GRP_SITE_DESC,SITE_DESC,"Tower installed in the Yukon-Kuskokwin Delta in July 2019, in an area that was burned in year 2015. Discontinuos permafrost zone in a wetland tundra ecosystem characterized by peat plateaus and wetlands" -US-YK1,96876,GRP_SITE_FUNDING,SITE_FUNDING,Gordon and Betty Moore Foundation -US-YK1,96867,GRP_STATE,STATE,AK -US-YK1,96874,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Susan Natali -US-YK1,96874,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-YK1,96874,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,snatali@woodwellclimate.org -US-YK1,96874,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Woodwell Climate Research Center -US-YK1,96874,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"149 Woods Hole Road, Falmouth, MA 02540 USA" -US-YK1,96882,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Erin MacDonald -US-YK1,96882,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-YK1,96882,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,emacdonald@woodwellclimate.org -US-YK1,96882,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Woodwell Climate Research Center -US-YK1,96882,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"149 Woods Hole Road, Falmouth, MA 02540 USA" -US-YK1,96868,GRP_TOWER_POWER,TOWER_POWER,Other -US-YK1,24001196,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-YK1 -US-YK1,96870,GRP_UTC_OFFSET,UTC_OFFSET,-9 -US-YK1,96870,GRP_UTC_OFFSET,UTC_OFFSET_DATE_START,201907111230 -US-YK2,27001209,GRP_COUNTRY,COUNTRY,USA -US-YK2,98625,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-YK2,98625,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CO2 -US-YK2,98625,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201909281700 -US-YK2,98625,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-YK2,98634,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-YK2,98634,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,CH4 -US-YK2,98634,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201909281700 -US-YK2,98634,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-YK2,98627,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_METHOD,Eddy Covariance -US-YK2,98627,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_VARIABLE,H2O -US-YK2,98627,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_DATE_START,201909281700 -US-YK2,98627,GRP_FLUX_MEASUREMENTS,FLUX_MEASUREMENTS_OPERATIONS,Continuous operation -US-YK2,23001209,GRP_HEADER,SITE_NAME,"Yukon-Kuskokwim Delta, Izaviknek-Kingaglia uplands, Unburned" -US-YK2,98636,GRP_IGBP,IGBP,WET -US-YK2,98636,GRP_IGBP,IGBP_DATE_START,201909281700 -US-YK2,98629,GRP_LAND_OWNERSHIP,LAND_OWNERSHIP,public -US-YK2,98629,GRP_LAND_OWNERSHIP,LAND_OWNER,U.S. Fish& Wildlife Service -US-YK2,98628,GRP_LOCATION,LOCATION_LAT,61.2548 -US-YK2,98628,GRP_LOCATION,LOCATION_LONG,-163.2590 -US-YK2,98628,GRP_LOCATION,LOCATION_ELEV,15 -US-YK2,98628,GRP_LOCATION,LOCATION_DATE_START,201909281700 -US-YK2,98630,GRP_NETWORK,NETWORK,AmeriFlux -US-YK2,98626,GRP_RESEARCH_TOPIC,RESEARCH_TOPIC,permafrost thaw on CO2 and CH4 -US-YK2,98631,GRP_SHIPPING_ADDRESS,SHIPPING_ADDRESS,"149 Woods Hole Road, Falmouth, MA 02540 USA" -US-YK2,98632,GRP_SITE_DESC,SITE_DESC,Tower installed in the Yukon-Kuskokwin Delta in September 2019. Discontinuos permafrost zone in a wetland tundra ecosystem characterized by peat plateaus and wetlands. -US-YK2,98622,GRP_SITE_FUNDING,SITE_FUNDING,Gordon and Betty Moore Foundation -US-YK2,98633,GRP_STATE,STATE,AK -US-YK2,98623,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Sue Natali -US-YK2,98623,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,PI -US-YK2,98623,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,snatali@woodwellclimate.org -US-YK2,98623,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Woodwell Climate Research Center -US-YK2,98623,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"149 Woods Hole Road, Falmouth, MA 02540 USA" -US-YK2,98635,GRP_TEAM_MEMBER,TEAM_MEMBER_NAME,Erin MacDonald -US-YK2,98635,GRP_TEAM_MEMBER,TEAM_MEMBER_ROLE,FluxContact -US-YK2,98635,GRP_TEAM_MEMBER,TEAM_MEMBER_EMAIL,emacdonald@woodwellclimate.org -US-YK2,98635,GRP_TEAM_MEMBER,TEAM_MEMBER_INSTITUTION,Woodwell Climate Research Center -US-YK2,98635,GRP_TEAM_MEMBER,TEAM_MEMBER_ADDRESS,"149 Woods Hole Road, Falmouth, MA 02540 USA" -US-YK2,98624,GRP_TOWER_POWER,TOWER_POWER,Solar panels -US-YK2,24001209,GRP_URL_AMERIFLUX,URL_AMERIFLUX,https://ameriflux.lbl.gov/sites/siteinfo/US-YK2 -US-YK2,98621,GRP_UTC_OFFSET,UTC_OFFSET,-9 -US-YK2,98621,GRP_UTC_OFFSET,UTC_OFFSET_DATE_START,201909281700 \ No newline at end of file diff --git a/ecflux/fluxtower/AMF_Supplementary_Metadata.csv b/ecflux/fluxtower/AMF_Supplementary_Metadata.csv deleted file mode 100644 index 36879bf..0000000 --- a/ecflux/fluxtower/AMF_Supplementary_Metadata.csv +++ /dev/null @@ -1,9 +0,0 @@ -AMF_ID,SITE_ID,VEG_HEIGHT,TOWER_HEIGHT -CR-SoC,SOLC,,40.0 -US-Wkg,WALN,, -US-xBR,BART,23.0, -US-xGR,GRSM,30.0, -US-xHA,HARV,26.0, -US-xRN,ORNL,28.0, -US-xSE,SERC,38.0, -US-xSJ,SJER,21.0,39.0 \ No newline at end of file diff --git a/ecflux/fluxtower/BASE_MeasurementHeight_20220811.csv b/ecflux/fluxtower/BASE_MeasurementHeight_20220811.csv deleted file mode 100644 index 5562205..0000000 --- a/ecflux/fluxtower/BASE_MeasurementHeight_20220811.csv +++ /dev/null @@ -1,13096 +0,0 @@ -Site_ID,Variable,Start_Date,Height,Instrument_Model,Instrument_Model2,Comment,BASE_Version -AR-TF1,CO2,,2.33,GA_CP-LI-COR LI-7200,,,2-5 -AR-TF1,FC,,2.33,SA-Gill Windmaster Pro,GA_CP-LI-COR LI-7200,,2-5 -AR-TF1,FC_SSITC_TEST,,,GA_CP-LI-COR LI-7200,,,2-5 -AR-TF1,H,,2.33,SA-Gill Windmaster Pro,,,2-5 -AR-TF1,H_SSITC_TEST,,,SA-Gill Windmaster Pro,,,2-5 -AR-TF1,LE,,2.33,GA_CP-LI-COR LI-7200,SA-Gill Windmaster Pro,,2-5 -AR-TF1,LE_SSITC_TEST,,,GA_CP-LI-COR LI-7200,,,2-5 -AR-TF1,PA,,2.33,GA_CP-LI-COR LI-7200,,,2-5 -AR-TF1,PPFD_IN,,2,RAD-PAR Quantum,,,2-5 -AR-TF1,RH,,2,RH-Capac,,,2-5 -AR-TF1,SW_IN,,2,RAD-Pyrrad-SW+LW,,,2-5 -AR-TF1,TA,,2,RH-Capac,,,2-5 -AR-TF1,USTAR,,2.33,SA-Gill Windmaster Pro,,,2-5 -AR-TF1,WD,,2.33,SA-Gill Windmaster Pro,,,2-5 -AR-TF1,WS,,2.33,SA-Gill Windmaster Pro,,,2-5 -AR-TF2,FC,,2.32,SA-Gill Windmaster Pro,GA_CP-LI-COR LI-7200,,1-5 -AR-TF2,H,,2.32,SA-Gill Windmaster Pro,,,1-5 -AR-TF2,LE,,2.32,GA_CP-LI-COR LI-7200,SA-Gill Windmaster Pro,,1-5 -AR-TF2,PPFD_IN,,,RAD-PAR Quantum,,,1-5 -AR-TF2,RH,,,RH-Capac,,,1-5 -AR-TF2,SW_IN,,,RAD-Pyrrad-SW+LW,,,1-5 -AR-TF2,TA,,,RH-Capac,,,1-5 -AR-TF2,USTAR,,2.32,SA-Gill Windmaster Pro,,,1-5 -AR-TF2,WD,,2.32,SA-Gill Windmaster Pro,,,1-5 -AR-TF2,WS,,2.32,SA-Gill Windmaster Pro,,,1-5 -BR-CST,APAR,,0,,,,1-5 -BR-CST,CO2,,0,,,,1-5 -BR-CST,FC,,0,,,,1-5 -BR-CST,FETCH_90,,0,,,,1-5 -BR-CST,GPP_PI,,0,,,,1-5 -BR-CST,H,,0,,,,1-5 -BR-CST,H2O,,0,,,,1-5 -BR-CST,H_SSITC_TEST,,0,,,,1-5 -BR-CST,LE,,0,,,,1-5 -BR-CST,LE_SSITC_TEST,,0,,,,1-5 -BR-CST,MO_LENGTH,,0,,,,1-5 -BR-CST,NEE_PI,,0,,,,1-5 -BR-CST,NETRAD,,0,,,,1-5 -BR-CST,P,,0,,,,1-5 -BR-CST,PA,,0,,,,1-5 -BR-CST,RH,,0,,,,1-5 -BR-CST,SC,,0,,,,1-5 -BR-CST,SH,,0,,,,1-5 -BR-CST,SLE,,0,,,,1-5 -BR-CST,SWC,,0,,,,1-5 -BR-CST,SW_IN,,0,,,,1-5 -BR-CST,TA,,0,,,,1-5 -BR-CST,TAU,,0,,,,1-5 -BR-CST,TAU_SSITC_TEST,,0,,,,1-5 -BR-CST,TS,,0,,,,1-5 -BR-CST,T_SONIC,,0,,,,1-5 -BR-CST,USTAR,,0,,,,1-5 -BR-CST,VPD_PI,,0,,,,1-5 -BR-CST,WD,,0,,,,1-5 -BR-CST,WS,,0,,,,1-5 -BR-CST,WS_MAX,,0,,,,1-5 -BR-CST,ZL,,0,,,,1-5 -BR-Npw,CH4,201401,20,GA_OP-LI-COR LI-7700,,,1-5 -BR-Npw,CO2,201401,20,GA_OP-LI-COR LI-7500A,,,1-5 -BR-Npw,FC,201401,20,GA_OP-LI-COR LI-7500A,SA-Young 81000,,1-5 -BR-Npw,FC_PI_F,201401,20,GA_OP-LI-COR LI-7500A,SA-Young 81000,,1-5 -BR-Npw,FCH4,201401,20,GA_OP-LI-COR LI-7700,SA-Young 81000,,1-5 -BR-Npw,FCH4_PI_F,201401,20,GA_OP-LI-COR LI-7700,SA-Young 81000,,1-5 -BR-Npw,H,201401,20,GA_OP-LI-COR LI-7500A,,,1-5 -BR-Npw,H_PI_F,201401,20,GA_OP-LI-COR LI-7500A,,,1-5 -BR-Npw,LE,201401,20,GA_OP-LI-COR LI-7500A,SA-Young 81000,,1-5 -BR-Npw,LE_PI_F,201401,20,GA_OP-LI-COR LI-7500A,SA-Young 81000,,1-5 -BR-Npw,LW_IN,201401,20,RAD-Other,,,1-5 -BR-Npw,LW_OUT,201401,20,RAD-Other,,,1-5 -BR-Npw,NETRAD,201401,20,RAD-Other,,,1-5 -BR-Npw,P,201401,2,RAIN-Other,,,1-5 -BR-Npw,PA,201401,20,RAIN-Other,,,1-5 -BR-Npw,RH,201401,20,RH-Other,,,1-5 -BR-Npw,SW_OUT,201401,20,RAD-Other,,,1-5 -BR-Npw,T_SONIC,201401,20,SA-Young 81000,,,1-5 -BR-Npw,USTAR,201401,20,SA-Young 81000,,,1-5 -BR-Npw,WD,201401,20,SA-Young 81000,,,1-5 -BR-Npw,WS,201401,20,SA-Young 81000,,,1-5 -BR-Npw,WTD,201401,-1.5,WTD-Other,,,1-5 -BR-Sa1,CO2_1_1_1,,62.24,,,,5-5 -BR-Sa1,CO2_1_2_1,,50.05,,,,5-5 -BR-Sa1,FC,,57.9,,,,5-5 -BR-Sa1,H,,57.9,,,,5-5 -BR-Sa1,H2O_1_2_1,,57.9,,,,5-5 -BR-Sa1,LE,,57.9,,,,5-5 -BR-Sa1,NETRAD,,66.8,,,,5-5 -BR-Sa1,PPFD_IN,,66.8,,,,5-5 -BR-Sa1,TA_1_2_1,,57.8,,,,5-5 -BR-Sa1,USTAR,,57.9,,,,5-5 -BR-Sa1,WD,,57.9,,,,5-5 -BR-Sa1,WS,,57.9,,,,5-5 -BR-Sa3,CO2,,64,GA-Other,,Li-Cor LI7000,3-5 -BR-Sa3,FC,,64,,,,3-5 -BR-Sa3,G,,-0.1,SOIL_H-Other,,REBS HFT 3.1,3-5 -BR-Sa3,H,,64,,,,3-5 -BR-Sa3,H2O,,64,GA-Other,,Li-Cor LI7500,3-5 -BR-Sa3,LE,,64,GA-Other,,Li-Cor LI7500,3-5 -BR-Sa3,LW_IN,,64,RAD-Other,,Kipp&Zonen CG2,3-5 -BR-Sa3,LW_OUT,,64,RAD-Other,,Kipp&Zonen CG2,3-5 -BR-Sa3,NETRAD,,64,RAD-Other,,Rebs Q*7,3-5 -BR-Sa3,P,,64,PREC-Other,,Texas Electronics TE525,3-5 -BR-Sa3,PA,,64,PRES-Other,,Li-Cor LI7500,3-5 -BR-Sa3,PPFD_IN,,64,RAD-Other,,Li-Cor LI190,3-5 -BR-Sa3,PPFD_OUT,,64,RAD-Other,,Li-Cor LI190,3-5 -BR-Sa3,RH,,64,,,,3-5 -BR-Sa3,SWC_1_1_1,,-0.1,SWC-Other,,Campbell Scientific CS615,3-5 -BR-Sa3,SWC_1_2_1,,-0.2,SWC-Other,,Campbell Scientific CS615,3-5 -BR-Sa3,SW_IN,,64,RAD-Other,,Kipp&Zonen CM6B,3-5 -BR-Sa3,SW_OUT,,64,RAD-Other,,Kipp&Zonen CM6B,3-5 -BR-Sa3,TA_1_1_1,,64,TEMP-Other,,Campbell Scientific T107,3-5 -BR-Sa3,TS_1_1_1,,-0.1,TEMP-Other,,Campbell Scientific T107,3-5 -BR-Sa3,TS_1_2_1,,-0.2,TEMP-Other,,Campbell Scientific T107,3-5 -BR-Sa3,USTAR,,64,WIND-Other,,Campbell CSAT3,3-5 -BR-Sa3,VPD_PI,,64,,,,3-5 -BR-Sa3,WD,,64,WIND-Other,,Campbell CSAT3,3-5 -BR-Sa3,WS_1_1_2,,64,WIND-Other,,Campbell CSAT3,3-5 -CA-ARB,ALB,2010,4,RAD-Other,,,1-5 -CA-ARB,CO2,2010,7.5,GA_CP-LI-COR LI-7200,,,1-5 -CA-ARB,D_SNOW,2010,3.9,SNOW-Acoustic,,,1-5 -CA-ARB,FC,2010,7.5,GA_CP-LI-COR LI-7200,SA-Gill HS-100,,1-5 -CA-ARB,FC,20181017,7.5,GA_CP-LI-COR LI-7200RS,SA-Campbell CSAT-3B,,1-5 -CA-ARB,G_1_1_1,2010,-0.08,SOIL_H-Plate,,,1-5 -CA-ARB,G_1_2_1,2010,-0.08,SOIL_H-Plate,,,1-5 -CA-ARB,G_2_1_1,2010,-0.08,SOIL_H-Plate,,,1-5 -CA-ARB,G_3_1_1,2010,-0.08,SOIL_H-Plate,,,1-5 -CA-ARB,H,2010,7.5,SA-Gill HS-100,,,1-5 -CA-ARB,H,20181017,7.5,SA-Campbell CSAT-3B,,,1-5 -CA-ARB,LE,20181017,7.5,SA-Campbell CSAT-3B,GA_CP-LI-COR LI-7200RS,,1-5 -CA-ARB,LE,,0,,,,1-5 -CA-ARB,LW_IN,2010,4,RAD-Other,,,1-5 -CA-ARB,LW_OUT,2010,4,RAD-Other,,,1-5 -CA-ARB,MO_LENGTH,2010,7.5,SA-Gill HS-100,,,1-5 -CA-ARB,MO_LENGTH,20181017,7.5,SA-Campbell CSAT-3B,,,1-5 -CA-ARB,P,2010,0,RAIN-TipBucGauge,,,1-5 -CA-ARB,PA,2010,2,,,,1-5 -CA-ARB,RH,2010,4.9,RH-Capac,,,1-5 -CA-ARB,SWC_1_1_1,2010,-0.05,SWC-FDR,,,1-5 -CA-ARB,SWC_1_2_1,2010,-0.1,SWC-FDR,,,1-5 -CA-ARB,SWC_1_3_1,2010,-0.2,SWC-FDR,,,1-5 -CA-ARB,SWC_1_4_1,2010,-0.5,SWC-FDR,,,1-5 -CA-ARB,SWC_1_5_1,2010,0,SWC-FDR,,0-0.2 m integrated,1-5 -CA-ARB,SWC_2_1_1,2010,-0.05,SWC-FDR,,,1-5 -CA-ARB,SWC_2_2_1,2010,-0.1,SWC-FDR,,,1-5 -CA-ARB,SWC_2_3_1,2010,-0.2,SWC-FDR,,,1-5 -CA-ARB,SWC_2_4_1,2010,-0.5,SWC-FDR,,,1-5 -CA-ARB,SWC_2_5_1,2010,0,SWC-FDR,,0 - 0.2 m integrated,1-5 -CA-ARB,SW_IN,2010,4,RAD-Other,,,1-5 -CA-ARB,SW_OUT,2010,4,RAD-Other,,,1-5 -CA-ARB,TA,2010,4.9,TEMP-ElectResis,,,1-5 -CA-ARB,TAU,2010,7.5,SA-Gill HS-100,,,1-5 -CA-ARB,TAU,20181017,7.5,SA-Campbell CSAT-3B,,,1-5 -CA-ARB,TS_1_1_1,2010,-0.02,TEMP-ElectResis,,,1-5 -CA-ARB,TS_1_2_1,2010,-0.05,TEMP-ElectResis,,,1-5 -CA-ARB,TS_1_3_1,2010,-0.1,TEMP-ElectResis,,,1-5 -CA-ARB,TS_1_4_1,2010,-0.2,TEMP-ElectResis,,,1-5 -CA-ARB,TS_1_5_1,2010,-0.5,TEMP-ElectResis,,,1-5 -CA-ARB,TS_1_6_1,2010,-1.0,TEMP-ElectResis,,,1-5 -CA-ARB,TS_2_1_1,2010,-0.02,TEMP-ElectResis,,,1-5 -CA-ARB,TS_2_2_1,2010,-0.05,TEMP-ElectResis,,,1-5 -CA-ARB,TS_2_3_1,2010,-0.1,TEMP-ElectResis,,,1-5 -CA-ARB,TS_2_4_1,2010,-0.2,TEMP-ElectResis,,,1-5 -CA-ARB,TS_2_5_1,2010,-0.5,TEMP-ElectResis,,,1-5 -CA-ARB,TS_2_6_1,2010,-1,TEMP-ElectResis,,,1-5 -CA-ARB,T_SONIC,2010,7.5,SA-Gill HS-100,,,1-5 -CA-ARB,T_SONIC,20181017,7.5,SA-Campbell CSAT-3B,,,1-5 -CA-ARB,T_SONIC_SIGMA,2010,7.5,SA-Gill HS-100,,,1-5 -CA-ARB,T_SONIC_SIGMA,20181017,7.5,SA-Campbell CSAT-3B,,,1-5 -CA-ARB,U_SIGMA,2010,7.5,SA-Gill HS-100,,,1-5 -CA-ARB,U_SIGMA,20181017,7.5,SA-Campbell CSAT-3B,,,1-5 -CA-ARB,USTAR,2010,7.5,SA-Gill HS-100,,,1-5 -CA-ARB,USTAR,20181017,7.5,SA-Campbell CSAT-3B,,,1-5 -CA-ARB,VPD_PI,2010,4.9,RH-Capac,,,1-5 -CA-ARB,V_SIGMA,2010,7.5,SA-Gill HS-100,,,1-5 -CA-ARB,V_SIGMA,20181017,7.5,SA-Campbell CSAT-3B,,,1-5 -CA-ARB,WD,2010,7.3,WIND-VaneAn,,,1-5 -CA-ARB,WS,2010,7.3,WIND-VaneAn,,,1-5 -CA-ARB,W_SIGMA,2010,7.5,SA-Gill HS-100,,,1-5 -CA-ARB,W_SIGMA,20181017,7.5,SA-Campbell CSAT-3B,,,1-5 -CA-ARB,WTD,2010,0,WTD-Press,,,1-5 -CA-ARB,ZL,2010,7.5,SA-Gill HS-100,,,1-5 -CA-ARB,ZL,20181017,7.5,SA-Campbell CSAT-3B,,,1-5 -CA-ARF,ALB,,0,,,,1-5 -CA-ARF,CO2,,0,,,,1-5 -CA-ARF,D_SNOW,,0,,,,1-5 -CA-ARF,FC,,0,,,,1-5 -CA-ARF,G_1_1_1,,0,,,,1-5 -CA-ARF,G_1_2_1,,0,,,,1-5 -CA-ARF,G_2_1_1,,0,,,,1-5 -CA-ARF,G_2_2_1,,0,,,,1-5 -CA-ARF,H,,0,,,,1-5 -CA-ARF,LE,,0,,,,1-5 -CA-ARF,LW_IN,,0,,,,1-5 -CA-ARF,LW_OUT,,0,,,,1-5 -CA-ARF,MO_LENGTH,,0,,,,1-5 -CA-ARF,P,,0,,,,1-5 -CA-ARF,PA,,0,,,,1-5 -CA-ARF,RH,,0,,,,1-5 -CA-ARF,SWC_1_1_1,,0,,,,1-5 -CA-ARF,SWC_1_2_1,,0,,,,1-5 -CA-ARF,SW_IN,,0,,,,1-5 -CA-ARF,SW_OUT,,0,,,,1-5 -CA-ARF,TA,,0,,,,1-5 -CA-ARF,TAU,,0,,,,1-5 -CA-ARF,TS_1_1_1,,0,,,,1-5 -CA-ARF,TS_1_2_1,,0,,,,1-5 -CA-ARF,TS_1_3_1,,0,,,,1-5 -CA-ARF,TS_1_4_1,,0,,,,1-5 -CA-ARF,TS_1_5_1,,0,,,,1-5 -CA-ARF,TS_1_6_1,,0,,,,1-5 -CA-ARF,TS_1_7_1,,0,,,,1-5 -CA-ARF,TS_2_1_1,,0,,,,1-5 -CA-ARF,TS_2_2_1,,0,,,,1-5 -CA-ARF,TS_2_3_1,,0,,,,1-5 -CA-ARF,TS_2_4_1,,0,,,,1-5 -CA-ARF,TS_2_5_1,,0,,,,1-5 -CA-ARF,TS_2_6_1,,0,,,,1-5 -CA-ARF,TS_2_7_1,,0,,,,1-5 -CA-ARF,T_SONIC,,0,,,,1-5 -CA-ARF,T_SONIC_SIGMA,,0,,,,1-5 -CA-ARF,U_SIGMA,,0,,,,1-5 -CA-ARF,USTAR,,0,,,,1-5 -CA-ARF,VPD_PI,,0,,,,1-5 -CA-ARF,V_SIGMA,,0,,,,1-5 -CA-ARF,WD,,0,,,,1-5 -CA-ARF,WS,,0,,,,1-5 -CA-ARF,W_SIGMA,,0,,,,1-5 -CA-ARF,WTD,,0,,,,1-5 -CA-ARF,ZL,,0,,,,1-5 -CA-Ca1,CO2_1_1_1,,43,,,,1-5 -CA-Ca1,CO2_1_2_1,,42,,,,1-5 -CA-Ca1,CO2_1_3_1,,27,,,,1-5 -CA-Ca1,CO2_1_4_1,,12,,,,1-5 -CA-Ca1,CO2_1_5_1,,2,,,,1-5 -CA-Ca1,FC,,43,,,,1-5 -CA-Ca1,G_1,,-0,,,Proposed modification from Andy Black's corrections in Excel file (QAQC-968),1-5 -CA-Ca1,G_1_1_1,,-0.03,,,,1-5 -CA-Ca1,G_1_1_2,,-0.03,,,,1-5 -CA-Ca1,G_1_1_3,,-0.03,,,,1-5 -CA-Ca1,H,,43,,,,1-5 -CA-Ca1,H2O,,43,,,,1-5 -CA-Ca1,LE,,43,,,,1-5 -CA-Ca1,LW_IN_1_1_1,,45,,,,1-5 -CA-Ca1,LW_OUT_1_1_1,,45,,,,1-5 -CA-Ca1,NETRAD_1_1_1,,45,,,,1-5 -CA-Ca1,NETRAD_1_2_1,,41,,,,1-5 -CA-Ca1,NETRAD_PI_F_1,,45,,,,1-5 -CA-Ca1,PPFD_BC_IN,,2.5,,,,1-5 -CA-Ca1,PPFD_DIF,,45,,,,1-5 -CA-Ca1,PPFD_IN_1_1_1,,45,,,,1-5 -CA-Ca1,PPFD_IN_1_1_2,,45,,,,1-5 -CA-Ca1,PPFD_IN_PI_F_1,,45,,,,1-5 -CA-Ca1,PPFD_OUT,,45,,,,1-5 -CA-Ca1,RH_1_1_1,,40,,,,1-5 -CA-Ca1,RH_1_2_1,,27,,,,1-5 -CA-Ca1,RH_1_3_1,,4,,,,1-5 -CA-Ca1,RH_PI_F_2,,27,,,,1-5 -CA-Ca1,RH_PI_F_3,,4,,,,1-5 -CA-Ca1,SWC_1_2_1,,-0.015,,,,1-5 -CA-Ca1,SWC_1_3_1,,-0.11,,,,1-5 -CA-Ca1,SWC_1_4_1,,-0.4,,,,1-5 -CA-Ca1,SWC_2_1_1,,-0.02,,,,1-5 -CA-Ca1,SWC_2_2_1,,-0.1,,,,1-5 -CA-Ca1,SWC_2_3_1,,-0.2,,,,1-5 -CA-Ca1,SWC_2_4_1,,-0.5,,,,1-5 -CA-Ca1,SWC_2_5_1,,-0.85,,,,1-5 -CA-Ca1,SWC_PI_F_1,,-0.15,,,,1-5 -CA-Ca1,SWC_PI_F_2,,-0.3,,,,1-5 -CA-Ca1,SWC_PI_F_3,,-0.5,,,,1-5 -CA-Ca1,SW_IN_1_1_1,,45,,,,1-5 -CA-Ca1,SW_IN_1_1_2,,45,,,,1-5 -CA-Ca1,SW_IN_1_1_3,,45,,,,1-5 -CA-Ca1,SW_IN_PI_F_1,,45,,,,1-5 -CA-Ca1,SW_OUT_1_1_1,,45,,,,1-5 -CA-Ca1,TA_1_10_1,,4,,,,1-5 -CA-Ca1,TA_1_1_1,,44,,,,1-5 -CA-Ca1,TA_1_11_1,,2,,,,1-5 -CA-Ca1,TA_1_11_2,,2,,,,1-5 -CA-Ca1,TA_1_1_2,,44,,,,1-5 -CA-Ca1,TA_1_2_1,,43,,,,1-5 -CA-Ca1,TA_1_2_2,,43,,,,1-5 -CA-Ca1,TA_1_3_1,,40,,,,1-5 -CA-Ca1,TA_1_3_2,,40,,,,1-5 -CA-Ca1,TA_1_4_1,,35,,,,1-5 -CA-Ca1,TA_1_5_1,,33,,,,1-5 -CA-Ca1,TA_1_6_1,,27,,,,1-5 -CA-Ca1,TA_1_6_2,,27,,,,1-5 -CA-Ca1,TA_1_7_1,,21,,,,1-5 -CA-Ca1,TA_1_8_1,,15,,,,1-5 -CA-Ca1,TA_1_8_2,,15,,,,1-5 -CA-Ca1,TA_1_9_1,,5,,,,1-5 -CA-Ca1,TA_PI_F_2,,27,,,,1-5 -CA-Ca1,TA_PI_F_3,,4,,,,1-5 -CA-Ca1,T_BOLE_1_1_1,,3,,,,1-5 -CA-Ca1,T_BOLE_1_1_5,,3,,,Positional qualifier indicies reflect treeNumber_measurementHeight_depthIntoTree relative positions,1-5 -CA-Ca1,T_BOLE_1_1_7,,3,,,Positional qualifier indicies reflect treeNumber_measurementHeight_depthIntoTree relative positions,1-5 -CA-Ca1,T_BOLE_2_1_1,,3,,,Positional qualifier indicies reflect treeNumber_measurementHeight_depthIntoTree relative positions,1-5 -CA-Ca1,T_BOLE_2_1_4,,3,,,Positional qualifier indicies reflect treeNumber_measurementHeight_depthIntoTree relative positions,1-5 -CA-Ca1,T_BOLE_2_1_6,,3,,,Positional qualifier indicies reflect treeNumber_measurementHeight_depthIntoTree relative positions,1-5 -CA-Ca1,T_BOLE_2_2_1,,3,,,Positional qualifier indicies reflect treeNumber_measurementHeight_depthIntoTree relative positions,1-5 -CA-Ca1,T_BOLE_2_2_3,,3,,,Positional qualifier indicies reflect treeNumber_measurementHeight_depthIntoTree relative positions,1-5 -CA-Ca1,T_BRANCH_2_2_1,,27,,,Positional qualifier indicies reflect treeNumber_measurementHeight_depthIntoTree relative positions,1-5 -CA-Ca1,TS_1_1_1,,-0.005,,,,1-5 -CA-Ca1,TS_1_2_1,,-0.01,,,,1-5 -CA-Ca1,TS_1_3_1,,-0.02,,,,1-5 -CA-Ca1,TS_1_3_2,,-0.02,,,,1-5 -CA-Ca1,TS_1_3_3,,-0.02,,,,1-5 -CA-Ca1,TS_1_4_1,,-0.05,,,,1-5 -CA-Ca1,TS_1_5_1,,-0.1,,,,1-5 -CA-Ca1,TS_1_6_1,,-0.2,,,,1-5 -CA-Ca1,TS_1_7_1,,-0.5,,,,1-5 -CA-Ca1,TS_1_8_1,,-1,,,,1-5 -CA-Ca1,TS_PI_F_1,,-0.02,,,,1-5 -CA-Ca1,TS_PI_F_2,,-0.05,,,,1-5 -CA-Ca1,TS_PI_F_3,,-0.1,,,,1-5 -CA-Ca1,T_SONIC_1_1_1,,43,,,,1-5 -CA-Ca1,USTAR,,43,,,,1-5 -CA-Ca1,WD,,40,,,,1-5 -CA-Ca1,WS_1_1_1,,43,,,,1-5 -CA-Ca1,WS_1_2_1,,40,,,,1-5 -CA-Ca1,WS_PI_F_1,,40,,,,1-5 -CA-Ca2,CO2_1_1_1,,2.5,,,,1-5 -CA-Ca2,CO2_1_2_1,,0.5,,,,1-5 -CA-Ca2,FC,,2.5,,,,1-5 -CA-Ca2,G_1,,-0,,,Proposed modification from Andy Black's corrections in Excel file (QAQC-969),1-5 -CA-Ca2,G_1_1_1,,-0.02,,,,1-5 -CA-Ca2,G_1_1_3,,-0.02,,,,1-5 -CA-Ca2,G_1_1_4,,-0.02,,,,1-5 -CA-Ca2,G_1_1_5,,-0.02,,,,1-5 -CA-Ca2,G_1_1_6,,-0.02,,,,1-5 -CA-Ca2,H,,2.5,,,,1-5 -CA-Ca2,H2O,,2.5,,,,1-5 -CA-Ca2,LE,,2.5,,,,1-5 -CA-Ca2,NETRAD_1_1_1,,8,,,,1-5 -CA-Ca2,NETRAD_1_1_2,,8,,,,1-5 -CA-Ca2,NETRAD_1_1_3,,8,,,,1-5 -CA-Ca2,NETRAD_PI_F_1,,8,,,,1-5 -CA-Ca2,PPFD_IN,,8,,,,1-5 -CA-Ca2,PPFD_IN_PI_F_1,,8,,,,1-5 -CA-Ca2,PPFD_OUT,,8,,,,1-5 -CA-Ca2,RH_1_1_1,,2.5,,,,1-5 -CA-Ca2,SWC_1_1_1,,-0.035,,,,1-5 -CA-Ca2,SWC_1_1_2,,-0.035,,,,1-5 -CA-Ca2,SWC_1_2_1,,-0.15,,,,1-5 -CA-Ca2,SWC_1_3_1,,-0.2,,,,1-5 -CA-Ca2,SWC_1_4_2,,-0.55,,,,1-5 -CA-Ca2,SWC_1_5_1,,-0.85,,,,1-5 -CA-Ca2,SWC_PI_F_1,,-0.15,,,,1-5 -CA-Ca2,SWC_PI_F_2,,-0.3,,,,1-5 -CA-Ca2,SW_IN_1,,8,,,,1-5 -CA-Ca2,SW_IN_1_1_1,,8,,,,1-5 -CA-Ca2,SW_IN_1_1_2,,8,,,,1-5 -CA-Ca2,SW_IN_1_1_3,,8,,,,1-5 -CA-Ca2,SW_IN_PI_F_1,,8,,,,1-5 -CA-Ca2,SW_OUT_1_1_1,,8,,,,1-5 -CA-Ca2,SW_OUT_1_1_2,,8,,,,1-5 -CA-Ca2,TA_1_1_1,,10,,,,1-5 -CA-Ca2,TA_1_2_1,,4,,,,1-5 -CA-Ca2,TA_1_3_1,,2.5,,,,1-5 -CA-Ca2,TA_1_3_2,,2.5,,,,1-5 -CA-Ca2,TA_1_3_3,,2.5,,,,1-5 -CA-Ca2,TA_1_4_1,,1,,,,1-5 -CA-Ca2,TA_1_5_1,,0.5,,,,1-5 -CA-Ca2,TA_1_6_1,,0.2,,,,1-5 -CA-Ca2,T_BOLE_2_1_1,,0.5,,,,1-5 -CA-Ca2,TS_1_1_1,,-0.005,,,,1-5 -CA-Ca2,TS_1_2_1,,-0.01,,,,1-5 -CA-Ca2,TS_1_3_1,,-0.02,,,,1-5 -CA-Ca2,TS_1_3_2,,-0.02,,,,1-5 -CA-Ca2,TS_1_4_1,,-0.05,,,,1-5 -CA-Ca2,TS_1_5_1,,-0.1,,,,1-5 -CA-Ca2,TS_1_6_1,,-0.2,,,,1-5 -CA-Ca2,TS_1_7_1,,-0.5,,,,1-5 -CA-Ca2,TS_1_8_1,,-1,,,,1-5 -CA-Ca2,TS_PI_F_1,,-0.02,,,,1-5 -CA-Ca2,TS_PI_F_2,,-0.05,,,,1-5 -CA-Ca2,TS_PI_F_3,,-0.1,,,,1-5 -CA-Ca2,TS_PI_F_4,,-0.2,,,,1-5 -CA-Ca2,TS_PI_F_5,,-0.5,,,,1-5 -CA-Ca2,TS_PI_F_6,,-1,,,,1-5 -CA-Ca2,USTAR,,2.5,,,,1-5 -CA-Ca2,WD,,2.5,,,,1-5 -CA-Ca2,WS,,2.5,,,,1-5 -CA-Ca2,WS_PI_F_1,,2.5,,,,1-5 -CA-Ca3,CO2,,21,GA_CP-LI-COR LI-7200,,,4-5 -CA-Ca3,CO2_1_1_1,,2,GA_CP-LI-COR LI-7000,,,4-5 -CA-Ca3,CO2_1_2_1,,12,GA_OP-Other,,,4-5 -CA-Ca3,FC,,21,GA_CP-LI-COR LI-7200,SA-Gill R3-50,,4-5 -CA-Ca3,G_1,,-0.02,SOIL_H-Plate,,,4-5 -CA-Ca3,G_1_1_1,,-0.02,SOIL_H-Plate,,,4-5 -CA-Ca3,G_1_1_2,,-0.02,SOIL_H-Plate,,,4-5 -CA-Ca3,G_1_1_3,,-0.02,SOIL_H-Plate,,,4-5 -CA-Ca3,G_1_1_4,,-0.02,SOIL_H-Plate,,,4-5 -CA-Ca3,G_1_1_5,,-0.02,SOIL_H-Plate,,,4-5 -CA-Ca3,G_1_1_6,,-0.02,SOIL_H-Plate,,,4-5 -CA-Ca3,G_1_2_1,,-0.02,SOIL_H-Plate,,,4-5 -CA-Ca3,G_1_2_2,,-0.02,SOIL_H-Plate,,,4-5 -CA-Ca3,GPP_PI,,21,GA_CP-LI-COR LI-7200,SA-Gill R3-50,,4-5 -CA-Ca3,GPP_PI_F,,13,SA-Campbell CSAT-3,GA_CP-LI-COR LI-7000,,4-5 -CA-Ca3,H,,21,SA-Gill R3-50,,,4-5 -CA-Ca3,H2O,,21,GA_CP-LI-COR LI-7200,,,4-5 -CA-Ca3,LE,,21,GA_CP-LI-COR LI-7200,SA-Gill R3-50,,4-5 -CA-Ca3,LW_IN,,18,RAD-Pyrrad-SW+LW,,,4-5 -CA-Ca3,LW_OUT,,18,RAD-Pyrrad-SW+LW,,,4-5 -CA-Ca3,NEE_PI,,21,GA_CP-LI-COR LI-7200,SA-Gill R3-50,,4-5 -CA-Ca3,NEE_PI_F,,13,SA-Campbell CSAT-3,GA_CP-LI-COR LI-7000,,4-5 -CA-Ca3,NETRAD,,18,RAD-Pyrrad-SW+LW,,,4-5 -CA-Ca3,NETRAD_1_1_1,,18,RAD-Pyrrad-SW+LW,,,4-5 -CA-Ca3,NETRAD_1_1_2,,18,RAD-Pyrrad-SW+LW,,,4-5 -CA-Ca3,P,,5,PREC-TipBucGauge,,,4-5 -CA-Ca3,PA,,18,PRES-AnerBar,,,4-5 -CA-Ca3,PPFD_IN,,18,RAD-PAR Quantum,,,4-5 -CA-Ca3,PPFD_OUT,,18,RAD-PAR Quantum,,,4-5 -CA-Ca3,RECO_PI,,21,GA_CP-LI-COR LI-7200,SA-Gill R3-50,,4-5 -CA-Ca3,RH,,18,RH-Capac,,,4-5 -CA-Ca3,RH_PI_F_1,,12,RH-Capac,,,4-5 -CA-Ca3,SB,,21,GA_CP-LI-COR LI-7200,,,4-5 -CA-Ca3,SC,,21,GA_CP-LI-COR LI-7200,,,4-5 -CA-Ca3,SG,,-0.02,TEMP-ElectResis,,,4-5 -CA-Ca3,SH,,21,TEMP-ElectResis,,,4-5 -CA-Ca3,SLE,,21,GA_CP-LI-COR LI-7200,,,4-5 -CA-Ca3,SWC_1_1_1,,-0.04,SWC-TDR,,,4-5 -CA-Ca3,SWC_1_1_2,,-0.04,SWC-TDR,,,4-5 -CA-Ca3,SWC_1_2_1,,-0.125,SWC-TDR,,,4-5 -CA-Ca3,SWC_1_2_2,,-0.125,SWC-TDR,,,4-5 -CA-Ca3,SWC_1_3_1,,-0.425,SWC-TDR,,,4-5 -CA-Ca3,SWC_1_4_1,,-0.85,SWC-TDR,,,4-5 -CA-Ca3,SWC_PI_F_3,,-0.1,SWC-TDR,,,4-5 -CA-Ca3,SW_IN,,18,RAD-Pyrrad-SW+LW,,,4-5 -CA-Ca3,SW_IN_1_1_1,,18,RAD-Pyrrad-SW+LW,,,4-5 -CA-Ca3,SW_IN_1_1_2,,18,RAD-Pyrrad-SW+LW,,,4-5 -CA-Ca3,SW_IN_1_1_3,,18,RAD-Pyrrad-SW+LW,,,4-5 -CA-Ca3,SW_IN_PI_F_1,,18,RAD-Pyrrad-SW+LW,,,4-5 -CA-Ca3,SW_OUT,,18,RAD-Pyrrad-SW+LW,,,4-5 -CA-Ca3,SW_OUT_1_1_1,,18,RAD-Pyrrad-SW+LW,,,4-5 -CA-Ca3,SW_OUT_1_1_2,,18,RAD-Pyrrad-SW+LW,,,4-5 -CA-Ca3,TA,,18,TEMP-ElectResis,,,4-5 -CA-Ca3,TA_1_1_1,,1,TEMP-ElectResis,,,4-5 -CA-Ca3,TA_1_2_1,,1,TEMP-ElectResis,,,4-5 -CA-Ca3,TA_1_3_1,,1,TEMP-ElectResis,,,4-5 -CA-Ca3,TA_1_3_2,,3,TEMP-ElectResis,,,4-5 -CA-Ca3,TA_1_3_3,,6,TEMP-ElectResis,,,4-5 -CA-Ca3,TA_1_4_1,,12,TEMP-ElectResis,,,4-5 -CA-Ca3,TA_1_5_1,,16,TEMP-ElectResis,,,4-5 -CA-Ca3,TA_1_6_1,,20,TEMP-ElectResis,,,4-5 -CA-Ca3,TA_PI_F_1,,12,TEMP-ElectResis,,,4-5 -CA-Ca3,T_BOLE_1_1_1,,1.5,TEMP-ElectResis,,,4-5 -CA-Ca3,T_BOLE_1_1_2,,1.5,TEMP-ElectResis,,,4-5 -CA-Ca3,T_BOLE_1_1_3,,1.5,,,,4-5 -CA-Ca3,TS_1_1_1,,-0.005,TEMP-ElectResis,,,4-5 -CA-Ca3,TS_1_2_1,,-0.01,TEMP-ElectResis,,,4-5 -CA-Ca3,TS_1_3_1,,-0.02,TEMP-ElectResis,,,4-5 -CA-Ca3,TS_1_3_2,,-0.02,TEMP-ElectResis,,,4-5 -CA-Ca3,TS_1_4_1,,-0.05,TEMP-ElectResis,,,4-5 -CA-Ca3,TS_1_5_1,,-0.1,TEMP-ElectResis,,,4-5 -CA-Ca3,TS_1_6_1,,-0.2,TEMP-ElectResis,,,4-5 -CA-Ca3,TS_1_7_1,,-0.5,TEMP-ElectResis,,,4-5 -CA-Ca3,TS_1_8_1,,-1,TEMP-ElectResis,,,4-5 -CA-Ca3,TS_PI_F_1,,-0.02,TEMP-ElectResis,,,4-5 -CA-Ca3,TS_PI_F_2,,-0.05,TEMP-ElectResis,,,4-5 -CA-Ca3,TS_PI_F_3,,-0.10,TEMP-ElectResis,,,4-5 -CA-Ca3,TS_PI_F_4,,-0.20,TEMP-ElectResis,,,4-5 -CA-Ca3,TS_PI_F_5,,-0.50,TEMP-ElectResis,,,4-5 -CA-Ca3,TS_PI_F_6,,-1.00,TEMP-ElectResis,,,4-5 -CA-Ca3,T_SONIC,,21,SA-Gill R3-50,,,4-5 -CA-Ca3,T_SONIC_SIGMA,,21,SA-Gill R3-50,,,4-5 -CA-Ca3,U_SIGMA,,21,SA-Gill R3-50,,,4-5 -CA-Ca3,USTAR,,21,SA-Gill R3-50,,,4-5 -CA-Ca3,VPD_PI,,18,RH-Capac,,,4-5 -CA-Ca3,V_SIGMA,,21,SA-Gill R3-50,,,4-5 -CA-Ca3,WD,,18,WIND-CupAn,,,4-5 -CA-Ca3,WS,,18,WIND-CupAn,,,4-5 -CA-Ca3,WS_1_1_1,,12,WIND-CupAn,,,4-5 -CA-Ca3,WS_1_1_2,,12,WIND-CupAn,,,4-5 -CA-Ca3,WS_PI_F_1,,12,WIND-CupAn,,,4-5 -CA-Ca3,W_SIGMA,,21,SA-Gill R3-50,,,4-5 -CA-Cbo,CO2_1_1_1,20080425,41.5,GA_CP-LI-COR LI-6262,,,5-5 -CA-Cbo,CO2_1_1_1,20150527,41.5,GA_CP-LI-COR LI-7000,,,5-5 -CA-Cbo,CO2_1_2_1,20150527,33,GA_CP-LI-COR LI-7000,,,5-5 -CA-Cbo,CO2_1_2_1,,33,GA_CP-LI-COR LI-6262,,Also CO2_33m and CO2_34m in FLX-CA format,5-5 -CA-Cbo,CO2_1_2_2,20170329,33,GA_CP-LI-COR LI-7000,,,5-5 -CA-Cbo,CO2_1_2_2,,33,GA_CP-LI-COR LI-6262,,note: Li6262 replaced with Li7000 on 2017-03-29,5-5 -CA-Cbo,CO2_1_3_1,20150527,25.7,GA_CP-LI-COR LI-7000,,,5-5 -CA-Cbo,CO2_1_3_1,,25.7,GA_CP-LI-COR LI-6262,,Also CO2_25.7m in FLX-CA format,5-5 -CA-Cbo,CO2_1_4_1,20150527,17.8,GA_CP-LI-COR LI-7000,,,5-5 -CA-Cbo,CO2_1_4_1,,17.8,GA_CP-LI-COR LI-6262,,,5-5 -CA-Cbo,CO2_1_5_1,20080425,16.5,GA_CP-LI-COR LI-6262,,,5-5 -CA-Cbo,CO2_1_5_1,20150527,16.5,GA_CP-LI-COR LI-7000,,,5-5 -CA-Cbo,CO2_1_6_1,20150527,10,GA_CP-LI-COR LI-7000,,,5-5 -CA-Cbo,CO2_1_6_1,,10.5,GA_CP-LI-COR LI-6262,,Also CO2_10.5m in FLX-CA format,5-5 -CA-Cbo,CO2_1_7_1,20150527,5.3,GA_CP-LI-COR LI-7000,,,5-5 -CA-Cbo,CO2_1_7_1,,5.3,GA_CP-LI-COR LI-6262,,Also CO2_5.3 in FLX-CA format,5-5 -CA-Cbo,CO2_2_1_1,20150527,1.5,GA_CP-LI-COR LI-7000,,,5-5 -CA-Cbo,CO2_2_1_1,,1.5,GA_CP-LI-COR LI-6262,,Also CO2_1.5m in FLX-CA format,5-5 -CA-Cbo,CO2_SIGMA,20200205,33,GA_CP-LI-COR LI-7000,,,5-5 -CA-Cbo,CO2_SIGMA,,33,GA_CP-LI-COR LI-6262,,,5-5 -CA-Cbo,FC,20170329,33,GA_CP-LI-COR LI-7000,SA-ATI SATI K Style,,5-5 -CA-Cbo,FC,20200205,33,GA_CP-LI-COR LI-7000,SA-Campbell CSAT-3,,5-5 -CA-Cbo,FC,,33,GA_CP-LI-COR LI-6262,SA-ATI SATI K Style,,5-5 -CA-Cbo,G_1_1_1,,-0.05,SOIL_H-Plate,,,5-5 -CA-Cbo,G_2_1_1,,-0.05,SOIL_H-Plate,,,5-5 -CA-Cbo,G_2_1_2,,-0.05,SOIL_H-Plate,,erroneously called G_3_1_1 elsewhere,5-5 -CA-Cbo,H,20200205,33,SA-Campbell CSAT-3,,,5-5 -CA-Cbo,H,,33,SA-ATI SATI K Style,,Also SensHtFlux in FLX-CA format; ATI replaced with CSAT on 2020-02-05,5-5 -CA-Cbo,H2O_1_1_1,20150527,41.5,GA_CP-LI-COR LI-7000,,,5-5 -CA-Cbo,H2O_1_1_1,,41.5,GA_CP-LI-COR LI-6262,,,5-5 -CA-Cbo,H2O_1_2_1,20150527,33,GA_CP-LI-COR LI-7000,,,5-5 -CA-Cbo,H2O_1_2_1,,33,GA_CP-LI-COR LI-6262,,Also H2O_34m in FLX-CA format,5-5 -CA-Cbo,H2O_1_2_2,20170329,33,GA_CP-LI-COR LI-7000,,,5-5 -CA-Cbo,H2O_1_2_2,,33,GA_CP-LI-COR LI-6262,,note: Li6262 replaced with Li7000 on 2017-03-29,5-5 -CA-Cbo,H2O_1_3_1,20150527,25.7,GA_CP-LI-COR LI-7000,,,5-5 -CA-Cbo,H2O_1_3_1,,25.7,GA_CP-LI-COR LI-6262,,Also H2O_25.7m in FLX-CA format,5-5 -CA-Cbo,H2O_1_4_1,20150527,17.8,GA_CP-LI-COR LI-7000,,,5-5 -CA-Cbo,H2O_1_4_1,,17.8,GA_CP-LI-COR LI-6262,,,5-5 -CA-Cbo,H2O_1_5_1,20150527,16.5,GA_CP-LI-COR LI-7000,,,5-5 -CA-Cbo,H2O_1_5_1,,16.5,GA_CP-LI-COR LI-6262,,,5-5 -CA-Cbo,H2O_1_6_1,20150527,10,GA_CP-LI-COR LI-7000,,,5-5 -CA-Cbo,H2O_1_6_1,,1.5,GA_CP-LI-COR LI-6262,,Also H2O_10.5m in FLX-CA format,5-5 -CA-Cbo,H2O_1_7_1,20150527,5.3,GA_CP-LI-COR LI-7000,,,5-5 -CA-Cbo,H2O_1_7_1,,5.3,GA_CP-LI-COR LI-6262,,Also H2O_5.3m in FLX-CA format,5-5 -CA-Cbo,H2O_2_1_1,20150527,1.5,GA_CP-LI-COR LI-7000,,,5-5 -CA-Cbo,H2O_2_1_1,,1.5,GA_CP-LI-COR LI-6262,,Also H2O_1.5m in FLX-CA format,5-5 -CA-Cbo,LE,20170329,33,SA-ATI SATI K Style,GA_CP-LI-COR LI-7000,,5-5 -CA-Cbo,LE,20200205,33,GA_CP-LI-COR LI-7000,SA-Campbell CSAT-3,,5-5 -CA-Cbo,LE,,33,GA_CP-LI-COR LI-6262,SA-ATI SATI K Style,,5-5 -CA-Cbo,LEAF_WET_1_1_1,,33,LEAF_WET-ElectResis,,,5-5 -CA-Cbo,LEAF_WET_1_1_2,,33,LEAF_WET-ElectResis,,,5-5 -CA-Cbo,LEAF_WET_1_2_1,,25.7,LEAF_WET-ElectResis,,,5-5 -CA-Cbo,LEAF_WET_1_2_2,,25.7,LEAF_WET-ElectResis,,,5-5 -CA-Cbo,LEAF_WET_1_3_1,,17.8,LEAF_WET-ElectResis,,,5-5 -CA-Cbo,LEAF_WET_1_3_2,,17.8,LEAF_WET-ElectResis,,,5-5 -CA-Cbo,LEAF_WET_1_4_1,,10.5,LEAF_WET-ElectResis,,,5-5 -CA-Cbo,LEAF_WET_1_4_2,,10.5,LEAF_WET-ElectResis,,,5-5 -CA-Cbo,LEAF_WET_1_5_1,,5.3,LEAF_WET-ElectResis,,,5-5 -CA-Cbo,LEAF_WET_1_5_2,,5.3,LEAF_WET-ElectResis,,,5-5 -CA-Cbo,LEAF_WET_2_1_1,,1.3,LEAF_WET-ElectResis,,,5-5 -CA-Cbo,LEAF_WET_2_1_2,,1.3,LEAF_WET-ElectResis,,,5-5 -CA-Cbo,LW_IN,,33.7,RAD-Net radiometer,,,5-5 -CA-Cbo,LW_OUT,,33.7,RAD-Net radiometer,,,5-5 -CA-Cbo,NEE_PI,20170329,33,GA_CP-LI-COR LI-7000,SA-ATI SATI K Style,,5-5 -CA-Cbo,NEE_PI,20200205,33,GA_CP-LI-COR LI-7000,SA-Campbell CSAT-3,,5-5 -CA-Cbo,NEE_PI,,33,GA_CP-LI-COR LI-6262,SA-ATI SATI K Style,,5-5 -CA-Cbo,NETRAD_1_1_1,,33.7,RAD-Net radiometer,,,5-5 -CA-Cbo,NETRAD_1_2_1,,33,RAD-Net radiometer,,,5-5 -CA-Cbo,O3_1_1_1,,41.5,GA_SR-Other,,Correction: all O3 molar fractions are in ppb (nmoles/mole),5-5 -CA-Cbo,O3_1_2_1,,33,GA_SR-Other,,Correction: all O3 molar fractions are in ppb (nmoles/mole),5-5 -CA-Cbo,O3_1_3_1,,25.7,GA_SR-Other,,Also O3_25.7m in FLX-CA format,5-5 -CA-Cbo,O3_1_4_1,,17.8,GA_SR-Other,,Correction: all O3 molar fractions are in ppb (nmoles/mole),5-5 -CA-Cbo,O3_1_5_1,,16.5,GA_SR-Other,,,5-5 -CA-Cbo,O3_1_6_1,,10.5,GA_SR-Other,,Also O3_10.5m in FLX-CA format,5-5 -CA-Cbo,O3_1_7_1,,5.3,GA_SR-Other,,Also O3_5.3m in FLX-CA format,5-5 -CA-Cbo,O3_2_1_1,,1.5,GA_SR-Other,,Also O3_1.5m in FLX-CA format,5-5 -CA-Cbo,PA,,2,PRES-ElectBar,,,5-5 -CA-Cbo,PPFD_IN_1_2_1,,33,RAD-PAR Quantum,,,5-5 -CA-Cbo,PPFD_IN_2_1_1,,1.5,RAD-PAR Quantum,,,5-5 -CA-Cbo,PPFD_OUT,,33,RAD-PAR Quantum,,,5-5 -CA-Cbo,RH_1_1_1,,43.4,RH-Capac,,Also RelHum_AbvCnpy_44m in FLX-CA format,5-5 -CA-Cbo,RH_1_2_1,,41,RH-Capac,,Also RelHum_33m in FLX-CA format; incorrect FLX_CA name; should be _41m,5-5 -CA-Cbo,RH_1_3_1,,33,RH-Capac,,Incorrect FLX_CA variable name; should be _33m,5-5 -CA-Cbo,SC,,33,GA_CP-LI-COR LI-6262,,Also CO2_Storage_Prof in FLX-CA format,5-5 -CA-Cbo,SO2_1_1_1,,41.5,,,,5-5 -CA-Cbo,SO2_1_2_1,,33,,,,5-5 -CA-Cbo,SO2_1_3_1,,25.7,,,,5-5 -CA-Cbo,SO2_1_4_1,,16.5,,,,5-5 -CA-Cbo,SO2_1_5_1,,10.5,,,,5-5 -CA-Cbo,SO2_1_6_1,,5.3,,,,5-5 -CA-Cbo,SO2_2_1_1,,1.5,,,,5-5 -CA-Cbo,SWC_1_1_1,,-0.02,SWC-TDR,,,5-5 -CA-Cbo,SWC_1_2_1,,-0.05,SWC-TDR,,,5-5 -CA-Cbo,SWC_1_3_1,,-0.1,SWC-TDR,,,5-5 -CA-Cbo,SWC_1_4_1,,-0.2,SWC-TDR,,,5-5 -CA-Cbo,SWC_1_5_1,,-0.5,SWC-TDR,,,5-5 -CA-Cbo,SWC_1_6_1,,-1,SWC-TDR,,,5-5 -CA-Cbo,SWC_2_1_1,,-0.02,SWC-TDR,,,5-5 -CA-Cbo,SWC_2_2_1,,-0.05,SWC-TDR,,,5-5 -CA-Cbo,SWC_2_3_1,,-0.1,SWC-TDR,,,5-5 -CA-Cbo,SWC_2_4_1,,-0.2,SWC-TDR,,,5-5 -CA-Cbo,SWC_2_5_1,,-0.5,SWC-TDR,,,5-5 -CA-Cbo,SWC_2_6_1,,-1,SWC-TDR,,,5-5 -CA-Cbo,SW_IN_1_1_1,,44,RAD-SW Pyran Class2,,,5-5 -CA-Cbo,SW_IN_1_2_1,,42,RAD-Net radiometer,,,5-5 -CA-Cbo,SW_IN_1_3_1,,33.7,RAD-Net radiometer,,,5-5 -CA-Cbo,SW_OUT,,33.7,RAD-Net radiometer,,,5-5 -CA-Cbo,TA_1_10_1,,16.5,TEMP-TCouple,,Also AirTemp_16.5m in FLX-CA format; ,5-5 -CA-Cbo,TA_1_1_1,,43.4,TEMP-TCouple,,,5-5 -CA-Cbo,TA_1_11_1,,13.5,TEMP-TCouple,,same as TA_1_16_1,5-5 -CA-Cbo,TA_1_12_1,,10.4,TEMP-TCouple,,same as TA_1_17_1,5-5 -CA-Cbo,TA_1_13_1,,6.3,TEMP-TCouple,,Also AirTemp_6.4m in FLX-CA format,5-5 -CA-Cbo,TA_1_2_1,,41.3,TEMP-TCouple,,Also AirTemp_AbvCnpy_44m in FLX-CA format,5-5 -CA-Cbo,TA_1_3_1,,40.7,TEMP-TCouple,,,5-5 -CA-Cbo,TA_1_4_1,,34.8,TEMP-TCouple,,,5-5 -CA-Cbo,TA_1_5_1,,33,TEMP-TCouple,,,5-5 -CA-Cbo,TA_1_5_2,,33,TEMP-TCouple,,,5-5 -CA-Cbo,TA_1_6_1,,29,TEMP-TCouple,,Also AirTemp_29.3m in FLX-CA format,5-5 -CA-Cbo,TA_1_7_1,,25.7,TEMP-TCouple,,Also AirTemp_25.7m in FLX-CA format,5-5 -CA-Cbo,TA_1_8_1,,22.6,TEMP-TCouple,,Also AirTemp_22.8m in FLX-CA format,5-5 -CA-Cbo,TA_1_9_1,,19.6,TEMP-TCouple,,,5-5 -CA-Cbo,TA_2_1_1,,3.3,TEMP-TCouple,,,5-5 -CA-Cbo,TA_2_2_1,,1.7,TEMP-TCouple,,,5-5 -CA-Cbo,T_BOLE_1_1_1,,10,TEMP-TCouple,,,5-5 -CA-Cbo,T_BOLE_1_2_1,,5,TEMP-TCouple,,,5-5 -CA-Cbo,T_BOLE_1_3_1,,2,TEMP-TCouple,,,5-5 -CA-Cbo,T_BOLE_2_1_1,,9,TEMP-TCouple,,,5-5 -CA-Cbo,T_BOLE_2_2_1,,5,TEMP-TCouple,,,5-5 -CA-Cbo,T_BOLE_2_3_1,,2,TEMP-TCouple,,,5-5 -CA-Cbo,TS_1_1_1,,-0.05,TEMP-Thermis,,,5-5 -CA-Cbo,TS_1_1_2,,-0.05,TEMP-Thermis,,,5-5 -CA-Cbo,TS_1_2_1,,-0.1,TEMP-Thermis,,,5-5 -CA-Cbo,TS_1_3_1,,-0.2,TEMP-Thermis,,,5-5 -CA-Cbo,TS_1_4_1,,-0.5,TEMP-Thermis,,,5-5 -CA-Cbo,TS_1_5_1,,-1,TEMP-Thermis,,incorect FXL-CA lable; should be S1,5-5 -CA-Cbo,TS_2_1_1,,-0.05,TEMP-Thermis,,,5-5 -CA-Cbo,TS_2_1_2,,-0.05,TEMP-Thermis,,,5-5 -CA-Cbo,TS_2_2_1,,-0.1,TEMP-Thermis,,,5-5 -CA-Cbo,TS_2_3_1,,-0.2,TEMP-Thermis,,,5-5 -CA-Cbo,TS_2_4_1,,-0.5,TEMP-Thermis,,,5-5 -CA-Cbo,T_SONIC,20200205,33,SA-Campbell CSAT-3,,,5-5 -CA-Cbo,T_SONIC,,33,SA-ATI SATI K Style,,,5-5 -CA-Cbo,USTAR,20200205,33,SA-Campbell CSAT-3,,,5-5 -CA-Cbo,USTAR,,33,SA-ATI SATI K Style,,ATI replaced with CSAT on 2020-02-05,5-5 -CA-Cbo,WD_1_1_1,,44,WIND-Other,,,5-5 -CA-Cbo,WD_1_2_1,,42.7,WIND-Other,,,5-5 -CA-Cbo,WD_1_3_1,,33,SA-Campbell CSAT-3,,Also DirTrue_Sonic(33m) in FLX-CA format,5-5 -CA-Cbo,WD_SIGMA_1_1_1,,44,,,,5-5 -CA-Cbo,WD_SIGMA_1_2_1,,42.7,,,,5-5 -CA-Cbo,WS_1_1_1,,44,WIND-Other,,,5-5 -CA-Cbo,WS_1_2_1,,42.7,WIND-Other,,,5-5 -CA-Cbo,WS_1_3_1,,33,SA-Campbell CSAT-3,,Also HorizWindSpd in FLX-CA format,5-5 -CA-Cbo,W_SIGMA,,33,,,ATI replaced with CSAT on 2020-02-05,5-5 -CA-CF1,FC,,3.9,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,1-5 -CA-CF1,H,,3.9,SA-Campbell CSAT-3,,,1-5 -CA-CF1,LE,,3.9,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,1-5 -CA-CF1,NETRAD,,1.0,RAD-Net radiometer,,,1-5 -CA-CF1,PPFD_IN,,1.0,RAD-PAR Quantum,,,1-5 -CA-CF1,P_RAIN,,0.5,RAIN-TipBucGauge,,,1-5 -CA-CF1,RH,,1.8,RH-Capac,,,1-5 -CA-CF1,SW_IN,,1.0,RAD-SW Pyran Class1,,,1-5 -CA-CF1,TA,,1.8,TEMP-ElectResis,,,1-5 -CA-CF1,TS,,-0.05,TEMP-TCouple,,,1-5 -CA-CF1,USTAR,,3.9,SA-Campbell CSAT-3,,,1-5 -CA-CF1,WD,,4.0,WIND-VaneAn,,,1-5 -CA-CF1,WS,,4.0,WIND-VaneAn,,,1-5 -CA-CF2,FC,,4.3,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,1-5 -CA-CF2,FCH4,,4.3,GA_CP-LGR RMT-200,SA-Campbell CSAT-3,,1-5 -CA-CF2,H,,4.3,SA-Campbell CSAT-3,,,1-5 -CA-CF2,LE,,4.3,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,1-5 -CA-CF2,NETRAD,,1.0,RAD-Net radiometer,,,1-5 -CA-CF2,PPFD_IN,,1.0,RAD-PAR Quantum,,,1-5 -CA-CF2,P_RAIN,,0.5,RAIN-TipBucGauge,,,1-5 -CA-CF2,RH,,1.8,RH-Capac,,,1-5 -CA-CF2,SW_IN,,1.0,RAD-SW Pyran Class1,,,1-5 -CA-CF2,TA,,1.8,TEMP-ElectResis,,,1-5 -CA-CF2,TS,,-0.05,TEMP-TCouple,,,1-5 -CA-CF2,USTAR,,4.3,SA-Campbell CSAT-3,,,1-5 -CA-CF2,WD,,4.0,WIND-VaneAn,,,1-5 -CA-CF2,WS,,4.0,WIND-VaneAn,,,1-5 -CA-Cha,NETRAD,,15,,,,1-5 -CA-Cha,PA,,1.5,,,,1-5 -CA-Cha,PPFD_IN,,15,,,,1-5 -CA-Cha,RH_1_1_1,,16.2,,,,1-5 -CA-Cha,RH_1_2_1,,13.4,,,,1-5 -CA-Cha,RH_1_3_1,,6.9,,,,1-5 -CA-Cha,RH_1_4_1,,2.5,,,,1-5 -CA-Cha,SWC_1_1_1,,-0.05,,,,1-5 -CA-Cha,SWC_1_2_1,,-0.1,,,,1-5 -CA-Cha,SWC_1_3_1,,-0.2,,,,1-5 -CA-Cha,SWC_1_4_1,,-0.5,,,,1-5 -CA-Cha,SWC_2_1_1,,-0.05,,,,1-5 -CA-Cha,SWC_2_2_1,,-0.1,,,,1-5 -CA-Cha,SWC_2_3_1,,-0.2,,,,1-5 -CA-Cha,SWC_2_4_1,,-0.5,,,,1-5 -CA-Cha,SW_IN,,15,,,,1-5 -CA-Cha,SW_OUT,,15,,,,1-5 -CA-Cha,TA_1_1_1,,18,,,,1-5 -CA-Cha,TA_1_2_1,,16.2,,,,1-5 -CA-Cha,TA_1_3_1,,13.4,,,,1-5 -CA-Cha,TA_1_4_1,,6.9,,,,1-5 -CA-Cha,TA_1_5_1,,2.5,,,,1-5 -CA-Cha,TS_1_1_1,,-0.02,,,,1-5 -CA-Cha,TS_1_2_1,,-0.05,,,,1-5 -CA-Cha,TS_1_3_1,,-0.1,,,,1-5 -CA-Cha,TS_1_4_1,,-0.2,,,,1-5 -CA-Cha,TS_1_5_1,,-0.5,,,,1-5 -CA-Cha,WD,,21,,,,1-5 -CA-Cha,WS,,21,,,,1-5 -CA-DB2,CO2,20191119,2.5,GA_CP-LI-COR LI-7200,,,1-5 -CA-DB2,FC,20191119,2.5,GA_CP-LI-COR LI-7200,SA-Campbell CSAT-3,,1-5 -CA-DB2,FC_PI_F,20191119,2.5,GA_CP-LI-COR LI-7200,SA-Campbell CSAT-3,,1-5 -CA-DB2,FCH4,20191130,2.5,GA_OP-LI-COR LI-7700,SA-Campbell CSAT-3,,1-5 -CA-DB2,G,20191130,-0.05,SOIL_H-Plate,,,1-5 -CA-DB2,H,20191119,2.5,SA-Campbell CSAT-3,,,1-5 -CA-DB2,H_PI_F,20191119,2.5,SA-Campbell CSAT-3,,,1-5 -CA-DB2,LE,20191119,2.5,SA-Campbell CSAT-3,GA_CP-LI-COR LI-7200,,1-5 -CA-DB2,LE_PI_F,20191119,2.5,GA_CP-LI-COR LI-7200,SA-Campbell CSAT-3,,1-5 -CA-DB2,LW_IN,20191121,3,RAD-Pyrrad-SW+LW,,,1-5 -CA-DB2,LW_OUT,20191121,3,RAD-Pyrrad-SW+LW,,,1-5 -CA-DB2,NETRAD,20191119,2.5,RAD-Pyrrad-SW+LW,,,1-5 -CA-DB2,P,20191130,1,PREC-TipBucGauge,,,1-5 -CA-DB2,PA,20191113,1.5,PRES-ElectBar,,,1-5 -CA-DB2,RH,20191113,2.05,RH-Capac,,,1-5 -CA-DB2,SW_IN,20191121,3,RAD-Pyrrad-SW+LW,,,1-5 -CA-DB2,SW_OUT,20191121,3,RAD-Pyrrad-SW+LW,,,1-5 -CA-DB2,TA,20191113,2.05,RH-Capac,,,1-5 -CA-DB2,TS_1_1_1,20191203,-0.05,TEMP-TCouple,,,1-5 -CA-DB2,TS_1_2_1,20191203,-0.1,TEMP-TCouple,,,1-5 -CA-DB2,TS_1_3_1,20191203,-0.3,TEMP-TCouple,,,1-5 -CA-DB2,TS_1_4_1,20191203,-0.5,TEMP-TCouple,,,1-5 -CA-DB2,TS_2_1_1,20191203,-0.05,TEMP-TCouple,,,1-5 -CA-DB2,TS_2_2_1,20191203,-0.1,TEMP-TCouple,,,1-5 -CA-DB2,TS_2_3_1,20191203,-0.3,TEMP-TCouple,,,1-5 -CA-DB2,TS_2_4_1,20191203,-0.5,TEMP-TCouple,,,1-5 -CA-DB2,TS_3_1_1,20191203,-0.05,TEMP-TCouple,,,1-5 -CA-DB2,TS_3_2_1,20191203,-0.1,TEMP-TCouple,,,1-5 -CA-DB2,TS_3_3_1,20191203,-0.3,TEMP-TCouple,,,1-5 -CA-DB2,TS_3_4_1,20191203,-0.5,TEMP-TCouple,,,1-5 -CA-DB2,T_SONIC,20191119,2.5,SA-Campbell CSAT-3,,,1-5 -CA-DB2,USTAR,20191119,2.5,SA-Campbell CSAT-3,,,1-5 -CA-DB2,WD_1_1_1,20191119,2.5,SA-Campbell CSAT-3,,,1-5 -CA-DB2,WD_2_2_1,20191113,5.0,WIND-VaneAn,,,1-5 -CA-DB2,WS_1_1_1,20191119,2.5,SA-Campbell CSAT-3,,,1-5 -CA-DB2,WS_2_2_1,20191113,5.0,WIND-VaneAn,,,1-5 -CA-DB2,WTD,20191207,,WTD-Press,,,1-5 -CA-DBB,CO2,20150620,1.80,GA_CP-LI-COR LI-7200RS,,,2-5 -CA-DBB,FC,20150620,1.8,GA_CP-LI-COR LI-7200RS,SA-Campbell CSAT-3,,2-5 -CA-DBB,FC_PI_F,20150620,1.8,GA_CP-LI-COR LI-7200RS,SA-Campbell CSAT-3,,2-5 -CA-DBB,FCH4,20150620,1.8,GA_OP-LI-COR LI-7700,SA-Campbell CSAT-3,,2-5 -CA-DBB,G,20140612,-0.05,SOIL_H-Plate,,,2-5 -CA-DBB,H,20150620,1.80,SA-Campbell CSAT-3,,,2-5 -CA-DBB,H_PI_F,20150620,1.8,SA-Campbell CSAT-3,,,2-5 -CA-DBB,LE,20150620,1.80,GA_CP-LI-COR LI-7200RS,SA-Campbell CSAT-3,,2-5 -CA-DBB,LE_PI_F,20150620,1.8,GA_CP-LI-COR LI-7200RS,SA-Campbell CSAT-3,,2-5 -CA-DBB,LW_IN,20141205,4.25,RAD-Pyrrad-SW+LW,,,2-5 -CA-DBB,LW_OUT,20141205,4.25,RAD-Pyrrad-SW+LW,,,2-5 -CA-DBB,NETRAD,20141205,4.25,RAD-Pyrrad-SW+LW,,,2-5 -CA-DBB,P,20141202,1,PREC-TipBucGauge,,,2-5 -CA-DBB,PA,20180209,1.5,PRES-ElectBar,,,2-5 -CA-DBB,RH,20141204,2.05,RH-Capac,,,2-5 -CA-DBB,SW_IN,20141205,4.25,RAD-Pyrrad-SW+LW,,,2-5 -CA-DBB,SW_OUT,20141205,4.25,RAD-Pyrrad-SW+LW,,,2-5 -CA-DBB,TA,20141204,2.05,TEMP-ElectResis,,,2-5 -CA-DBB,TS_1_1_1,,-0.05,TEMP-TCouple,,,2-5 -CA-DBB,TS_1_2_1,,-0.1,TEMP-TCouple,,,2-5 -CA-DBB,TS_1_3_1,,-0.5,TEMP-TCouple,,,2-5 -CA-DBB,T_SONIC,20150620,1.8,SA-Campbell CSAT-3,,,2-5 -CA-DBB,USTAR,20150620,1.80,SA-Campbell CSAT-3,,,2-5 -CA-DBB,WD,20150620,1.80,SA-Campbell CSAT-3,,,2-5 -CA-DBB,WS,20150620,1.80,SA-Campbell CSAT-3,,,2-5 -CA-DBB,WTD,20150728,-1.0,WTD-Press,,,2-5 -CA-ER1,CO2,20150622,2.42,GA_OP-LI-COR LI-7500,,,3-5 -CA-ER1,CO2,20150721,3.66,GA_OP-LI-COR LI-7500,,,3-5 -CA-ER1,CO2,20151102,2.03,GA_OP-LI-COR LI-7500,,,3-5 -CA-ER1,CO2,20160101,1.93,GA_OP-LI-COR LI-7500,,,3-5 -CA-ER1,CO2,20160711,3.67,GA_OP-LI-COR LI-7500,,,3-5 -CA-ER1,CO2,20161007,2,GA_OP-LI-COR LI-7500,,,3-5 -CA-ER1,CO2,20170629,2.85,GA_OP-LI-COR LI-7500,,,3-5 -CA-ER1,CO2,20170725,4.5,GA_OP-LI-COR LI-7500,,,3-5 -CA-ER1,CO2,20171110,2.25,GA_OP-LI-COR LI-7500,,,3-5 -CA-ER1,CO2,20180629,3.2,GA_OP-LI-COR LI-7500,,undefined,3-5 -CA-ER1,CO2,20180713,5,GA_OP-LI-COR LI-7500,,undefined,3-5 -CA-ER1,CO2,20181108,2.5,GA_OP-LI-COR LI-7500,,undefined,3-5 -CA-ER1,CO2,20190821,3.05,GA_OP-LI-COR LI-7500,,undefined,3-5 -CA-ER1,CO2,20200107,2.5,GA_OP-LI-COR LI-7500,,undefined,3-5 -CA-ER1,CO2,20200611,2.79,GA_OP-LI-COR LI-7500,,undefined,3-5 -CA-ER1,CO2,20200801,2.05,GA_OP-LI-COR LI-7500,,undefined,3-5 -CA-ER1,CO2,20210108,2.6,GA_OP-LI-COR LI-7500,,undefined,3-5 -CA-ER1,CO2,20210617,2.52,GA_OP-LI-COR LI-7500,,,3-5 -CA-ER1,CO2,20210629,4.00,GA_OP-LI-COR LI-7500,,undefined,3-5 -CA-ER1,CO2,20210714,4.94,GA_OP-LI-COR LI-7500,,,3-5 -CA-ER1,CO2,,1.93,GA_OP-LI-COR LI-7500,,,3-5 -CA-ER1,CO2_SIGMA,20150622,2.42,GA_OP-LI-COR LI-7500,,,3-5 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-CA-ER1,V_SIGMA,,1.93,SA-Campbell CSAT-3A,,,3-5 -CA-ER1,WD,20150622,2.42,SA-Campbell CSAT-3A,,,3-5 -CA-ER1,WD,20150721,3.66,SA-Campbell CSAT-3A,,,3-5 -CA-ER1,WD,20151102,2.03,SA-Campbell CSAT-3A,,,3-5 -CA-ER1,WD,20160101,1.93,SA-Campbell CSAT-3A,,,3-5 -CA-ER1,WD,20160711,3.67,SA-Campbell CSAT-3A,,,3-5 -CA-ER1,WD,20161007,2,SA-Campbell CSAT-3A,,,3-5 -CA-ER1,WD,20170629,2.85,SA-Campbell CSAT-3A,,,3-5 -CA-ER1,WD,20170725,4.5,SA-Campbell CSAT-3A,,,3-5 -CA-ER1,WD,20171110,2.25,SA-Campbell CSAT-3A,,,3-5 -CA-ER1,WD,20180629,3.2,SA-Campbell CSAT-3A,,,3-5 -CA-ER1,WD,20180713,5,SA-Campbell CSAT-3A,,,3-5 -CA-ER1,WD,20181108,2.5,SA-Campbell CSAT-3A,,,3-5 -CA-ER1,WD,20190821,3.05,SA-Campbell CSAT-3A,,,3-5 -CA-ER1,WD,20200107,2.5,SA-Campbell CSAT-3A,,,3-5 -CA-ER1,WD,20200611,2.79,SA-Campbell CSAT-3A,,,3-5 -CA-ER1,WD,20200801,2.05,SA-Campbell CSAT-3A,,,3-5 -CA-ER1,WD,20210108,2.6,SA-Campbell CSAT-3A,,,3-5 -CA-ER1,WD,20210617,2.52,SA-Campbell CSAT-3A,,undefined,3-5 -CA-ER1,WD,20210630,4,SA-Campbell CSAT-3A,,undefined,3-5 -CA-ER1,WD,20210714,4.94,SA-Campbell CSAT-3A,,undefined,3-5 -CA-ER1,WD,,1.93,SA-Campbell CSAT-3A,,,3-5 -CA-ER1,WS,20150622,2.42,SA-Campbell CSAT-3A,,,3-5 -CA-ER1,WS,20150721,3.66,SA-Campbell CSAT-3A,,,3-5 -CA-ER1,WS,20151102,2.03,SA-Campbell CSAT-3A,,,3-5 -CA-ER1,WS,20160101,1.93,SA-Campbell CSAT-3A,,,3-5 -CA-ER1,WS,20160711,3.67,SA-Campbell CSAT-3A,,,3-5 -CA-ER1,WS,20161007,2,SA-Campbell CSAT-3A,,,3-5 -CA-ER1,WS,20170629,2.85,SA-Campbell CSAT-3A,,,3-5 -CA-ER1,WS,20170725,4.5,SA-Campbell CSAT-3A,,,3-5 -CA-ER1,WS,20171110,2.25,SA-Campbell CSAT-3A,,,3-5 -CA-ER1,WS,20180629,3.2,SA-Campbell CSAT-3A,,,3-5 -CA-ER1,WS,20180713,5,SA-Campbell CSAT-3A,,,3-5 -CA-ER1,WS,20181108,2.5,SA-Campbell CSAT-3A,,,3-5 -CA-ER1,WS,20190821,3.05,SA-Campbell CSAT-3A,,,3-5 -CA-ER1,WS,20200107,2.5,SA-Campbell CSAT-3A,,,3-5 -CA-ER1,WS,20200611,2.79,SA-Campbell CSAT-3A,,,3-5 -CA-ER1,WS,20200801,2.05,SA-Campbell CSAT-3A,,,3-5 -CA-ER1,WS,20210108,2.6,SA-Campbell CSAT-3A,,,3-5 -CA-ER1,WS,20210617,2.52,SA-Campbell CSAT-3A,,undefined,3-5 -CA-ER1,WS,20210630,4,SA-Campbell CSAT-3A,,undefined,3-5 -CA-ER1,WS,20210714,4.94,SA-Campbell CSAT-3A,,undefined,3-5 -CA-ER1,WS,,1.93,SA-Campbell CSAT-3A,,,3-5 -CA-ER1,W_SIGMA,20150622,2.42,SA-Campbell CSAT-3A,,,3-5 -CA-ER1,W_SIGMA,20150721,3.66,SA-Campbell CSAT-3A,,,3-5 -CA-ER1,W_SIGMA,20151102,2.03,SA-Campbell CSAT-3A,,,3-5 -CA-ER1,W_SIGMA,20160101,1.93,SA-Campbell CSAT-3A,,,3-5 -CA-ER1,W_SIGMA,20160711,3.67,SA-Campbell CSAT-3A,,,3-5 -CA-ER1,W_SIGMA,20161007,2,SA-Campbell CSAT-3A,,,3-5 -CA-ER1,W_SIGMA,20170629,2.85,SA-Campbell CSAT-3A,,,3-5 -CA-ER1,W_SIGMA,20170725,4.5,SA-Campbell CSAT-3A,,,3-5 -CA-ER1,W_SIGMA,20171110,2.25,SA-Campbell CSAT-3A,,,3-5 -CA-ER1,W_SIGMA,20180629,3.2,SA-Campbell CSAT-3A,,,3-5 -CA-ER1,W_SIGMA,20180713,5,SA-Campbell CSAT-3A,,,3-5 -CA-ER1,W_SIGMA,20181108,2.5,SA-Campbell CSAT-3A,,,3-5 -CA-ER1,W_SIGMA,20190821,3.05,SA-Campbell CSAT-3A,,,3-5 -CA-ER1,W_SIGMA,20200107,2.5,SA-Campbell CSAT-3A,,,3-5 -CA-ER1,W_SIGMA,20200611,2.79,SA-Campbell CSAT-3A,,,3-5 -CA-ER1,W_SIGMA,20200801,2.05,SA-Campbell CSAT-3A,,,3-5 -CA-ER1,W_SIGMA,20210108,2.6,SA-Campbell CSAT-3A,,,3-5 -CA-ER1,W_SIGMA,20210617,2.52,SA-Campbell CSAT-3A,,undefined,3-5 -CA-ER1,W_SIGMA,20210630,4,SA-Campbell CSAT-3A,,undefined,3-5 -CA-ER1,W_SIGMA,20210714,4.94,SA-Campbell CSAT-3A,,undefined,3-5 -CA-ER1,W_SIGMA,,1.93,SA-Campbell CSAT-3A,,,3-5 -CA-ER1,WS_MAX,20150622,2.42,SA-Campbell CSAT-3A,,,3-5 -CA-ER1,WS_MAX,20150721,3.66,SA-Campbell CSAT-3A,,,3-5 -CA-ER1,WS_MAX,20151102,2.03,SA-Campbell CSAT-3A,,,3-5 -CA-ER1,WS_MAX,20160101,1.93,SA-Campbell CSAT-3A,,,3-5 -CA-ER1,WS_MAX,20160711,3.67,SA-Campbell CSAT-3A,,,3-5 -CA-ER1,WS_MAX,20161007,2,SA-Campbell CSAT-3A,,,3-5 -CA-ER1,WS_MAX,20170629,2.85,SA-Campbell CSAT-3A,,,3-5 -CA-ER1,WS_MAX,20170725,4.5,SA-Campbell CSAT-3A,,,3-5 -CA-ER1,WS_MAX,20171110,2.25,SA-Campbell CSAT-3A,,,3-5 -CA-ER1,WS_MAX,20180629,3.2,SA-Campbell CSAT-3A,,,3-5 -CA-ER1,WS_MAX,20180713,5,SA-Campbell CSAT-3A,,,3-5 -CA-ER1,WS_MAX,20181108,2.5,SA-Campbell CSAT-3A,,,3-5 -CA-ER1,WS_MAX,20190821,3.05,SA-Campbell CSAT-3A,,,3-5 -CA-ER1,WS_MAX,20200107,2.5,SA-Campbell CSAT-3A,,,3-5 -CA-ER1,WS_MAX,20200611,2.79,SA-Campbell CSAT-3A,,,3-5 -CA-ER1,WS_MAX,20200801,2.05,SA-Campbell CSAT-3A,,,3-5 -CA-ER1,WS_MAX,20210108,2.6,SA-Campbell CSAT-3A,,,3-5 -CA-ER1,WS_MAX,20210617,2.52,SA-Campbell CSAT-3A,,undefined,3-5 -CA-ER1,WS_MAX,20210630,4,SA-Campbell CSAT-3A,,undefined,3-5 -CA-ER1,WS_MAX,20210714,4.94,SA-Campbell CSAT-3A,,undefined,3-5 -CA-ER1,WS_MAX,,1.93,SA-Campbell CSAT-3A,,,3-5 -CA-ER1,ZL,20150622,2.42,SA-Campbell CSAT-3A,,,3-5 -CA-ER1,ZL,20150721,3.66,SA-Campbell CSAT-3A,,,3-5 -CA-ER1,ZL,20151102,2.03,SA-Campbell CSAT-3A,,,3-5 -CA-ER1,ZL,20160101,1.93,SA-Campbell CSAT-3A,,,3-5 -CA-ER1,ZL,20160711,3.67,SA-Campbell CSAT-3A,,,3-5 -CA-ER1,ZL,20161007,2,SA-Campbell CSAT-3A,,,3-5 -CA-ER1,ZL,20170629,2.85,SA-Campbell CSAT-3A,,,3-5 -CA-ER1,ZL,20170725,4.5,SA-Campbell CSAT-3A,,,3-5 -CA-ER1,ZL,20171110,2.25,SA-Campbell CSAT-3A,,,3-5 -CA-ER1,ZL,20180629,3.2,SA-Campbell CSAT-3A,,,3-5 -CA-ER1,ZL,20180713,5,SA-Campbell CSAT-3A,,,3-5 -CA-ER1,ZL,20181108,2.5,SA-Campbell CSAT-3A,,,3-5 -CA-ER1,ZL,20190821,3.05,SA-Campbell CSAT-3A,,,3-5 -CA-ER1,ZL,20200107,2.5,SA-Campbell CSAT-3A,,,3-5 -CA-ER1,ZL,20200611,2.79,SA-Campbell CSAT-3A,,,3-5 -CA-ER1,ZL,20200801,2.05,SA-Campbell CSAT-3A,,,3-5 -CA-ER1,ZL,20210108,2.6,SA-Campbell CSAT-3A,,,3-5 -CA-ER1,ZL,20210617,2.52,SA-Campbell CSAT-3A,,undefined,3-5 -CA-ER1,ZL,20210630,4,SA-Campbell CSAT-3A,,undefined,3-5 -CA-ER1,ZL,20210714,4.94,SA-Campbell CSAT-3A,,undefined,3-5 -CA-ER1,ZL,,1.93,SA-Campbell CSAT-3A,,,3-5 -CA-Gro,CO2_1_1_1,,43,GA-Other,,LI-7000 (IRGA) as part of the,2-5 -CA-Gro,CO2_1_2_1,,42,GA-Other,,LI-6262 IRGA as part of the pr,2-5 -CA-Gro,FC,,43,,,,2-5 -CA-Gro,G_1_1_1,,-0,SOIL_H-Other,,HFT3 heat flux plates,2-5 -CA-Gro,H,,43,,,,2-5 -CA-Gro,H2O,,43,,,,2-5 -CA-Gro,LE,,43,,,,2-5 -CA-Gro,LW_IN,,37,RAD-Other,,Kipp & Zonen CNR1 Net Radiometer,2-5 -CA-Gro,LW_OUT,,37,RAD-Other,,Kipp & Zonen CNR1 Net Radiometer,2-5 -CA-Gro,NETRAD_1_1_1,,37,RAD-Other,,Kipp & Zonen CNR1 Net Radiometer above canopy,2-5 -CA-Gro,PA,,1.6,,,,2-5 -CA-Gro,PPFD_DIF,,37,,,,2-5 -CA-Gro,PPFD_IN_1_1_1,,37,RAD-Other,,LI-COR Quantum Sensor,2-5 -CA-Gro,PPFD_OUT,,37,RAD-Other,,LI-COR LI-190 Quantum Sensor a,2-5 -CA-Gro,RH_1_1_1,,43,RH-Other,,Vaisala HMP45C Temperature and RH Probe in MetOne Aspirated Radiation Shield,2-5 -CA-Gro,SWC_1_1_1,,-0.15,,,,2-5 -CA-Gro,SWC_1_2_1,,-0.3,,,,2-5 -CA-Gro,SW_IN,,37,RAD-Other,,Kipp & Zonen CNR1 Net Radiometer,2-5 -CA-Gro,SW_OUT,,37,RAD-Other,,Kipp & Zonen CNR1 Net Radiometer,2-5 -CA-Gro,TA_1_1_1,,43,TEMP-Other,,Vaisala HMP45C Temperature and RH Probe,2-5 -CA-Gro,TS_1_1_1,,-0.02,TEMP-Other,,thermocouple in soil pit west of flux tower,2-5 -CA-Gro,TS_1_2_1,,-0.05,TEMP-Other,,thermocouple in soil pit west of flux tower,2-5 -CA-Gro,USTAR,,43,,,,2-5 -CA-Gro,VPD_PI,,43,,,,2-5 -CA-Gro,WD_1_1_1,,43,WIND-Other,,Young (05103) Wind Monitor above canopy,2-5 -CA-Gro,WS_1_1_1,,43,WIND-Other,,Young (05103) Wind Monitor above canopy,2-5 -CA-Let,CO2,,6,,,,1-5 -CA-Let,ET,,6,,,,1-5 -CA-Let,G_1_1_1,,-0.02,,,,1-5 -CA-Let,G_1_1_2,,-0.02,,,,1-5 -CA-Let,G_1_1_3,,-0.02,,,,1-5 -CA-Let,G_1_1_4,,-0.02,,,,1-5 -CA-Let,H,,6,,,,1-5 -CA-Let,H2O,,6,,,,1-5 -CA-Let,LE,,6,,,,1-5 -CA-Let,NEE_PI,,6,,,,1-5 -CA-Let,NETRAD,,3,,,,1-5 -CA-Let,PPFD_IN,,3,,,,1-5 -CA-Let,PPFD_OUT,,3,,,,1-5 -CA-Let,RH,,1,,,,1-5 -CA-Let,SWC_1_1_1,,-0.15,,,,1-5 -CA-Let,SWC_1_2_1,,-0.3,,,,1-5 -CA-Let,SWC_2_1_1,,-0.15,,,,1-5 -CA-Let,SWC_2_2_1,,-0.3,,,,1-5 -CA-Let,SWC_3_1_1,,-0.075,,,,1-5 -CA-Let,SWC_4_1_1,,-0.075,,,,1-5 -CA-Let,SWC_5_1_1,,-0.075,,,,1-5 -CA-Let,SWC_6_1_1,,-0.075,,,,1-5 -CA-Let,TA_1_1_1,,5,,,,1-5 -CA-Let,TA_1_2_1,,1,,,,1-5 -CA-Let,TA_1_2_2,,1,,,,1-5 -CA-Let,TS_1_1_1,,-0.02,,,,1-5 -CA-Let,TS_1_2_1,,-0.04,,,,1-5 -CA-Let,TS_1_3_1,,-0.08,,,,1-5 -CA-Let,TS_1_4_1,,-0.16,,,,1-5 -CA-Let,TS_1_5_1,,-0.32,,,,1-5 -CA-Let,TS_2_1_1,,-0.02,,,,1-5 -CA-Let,TS_2_2_1,,-0.04,,,,1-5 -CA-Let,TS_2_3_1,,-0.08,,,,1-5 -CA-Let,TS_2_4_1,,-0.16,,,,1-5 -CA-Let,TS_2_5_1,,-0.32,,,,1-5 -CA-Let,WD,,6,,,,1-5 -CA-Let,WS,,6,,,,1-5 -CA-LP1,CO2,,26,GA_OP-LI-COR LI-7500,,,2-5 -CA-LP1,FC,,26,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,2-5 -CA-LP1,G_1_1_1,,-0.03,SOIL_H-Plate,,,2-5 -CA-LP1,G_1_1_2,,-0.03,SOIL_H-Plate,,,2-5 -CA-LP1,G_1_1_4,,-0.03,SOIL_H-Plate,,,2-5 -CA-LP1,GPP_PI,,26,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,2-5 -CA-LP1,H,,26,SA-Campbell CSAT-3,,,2-5 -CA-LP1,H2O,,26,GA_OP-LI-COR LI-7500A,,,2-5 -CA-LP1,LE,,26,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,2-5 -CA-LP1,LW_IN,,26,RAD-Pyrrad-SW+LW,,,2-5 -CA-LP1,LW_OUT,,26,RAD-Pyrrad-SW+LW,,,2-5 -CA-LP1,NEE_PI,,26,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,2-5 -CA-LP1,NETRAD,,26,RAD-Pyrrad-SW+LW,,,2-5 -CA-LP1,P,,0.15,RAIN-TipBucGauge,,,2-5 -CA-LP1,PA,,26,GA_OP-LI-COR LI-7500,,,2-5 -CA-LP1,PPFD_IN,,26,RAD-PAR Quantum,,up to 2014,2-5 -CA-LP1,PPFD_IN_PI_F,2015,26,RAD-Pyrrad-SW+LW,,Calculated from SW_IN using site-specific quotient.,2-5 -CA-LP1,PPFD_OUT,,26,RAD-PAR Quantum,,,2-5 -CA-LP1,RECO_PI,,26,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,2-5 -CA-LP1,RH,,26,TEMP-ElectResis,,,2-5 -CA-LP1,SC,,26,GA_OP-LI-COR LI-7500,,,2-5 -CA-LP1,SWC_1_1_1,,-0.05,SWC-TDR,,,2-5 -CA-LP1,SWC_1_2_1,,-0.40,SWC-TDR,,,2-5 -CA-LP1,SW_IN,,26,RAD-Pyrrad-SW+LW,,,2-5 -CA-LP1,SW_OUT,,26,RAD-Pyrrad-SW+LW,,,2-5 -CA-LP1,TA,,26,TEMP-ElectResis,,,2-5 -CA-LP1,TS_1_1_1,,-0.05,TEMP-ElectResis,,,2-5 -CA-LP1,TS_1_3_1,,-0.10,TEMP-ElectResis,,,2-5 -CA-LP1,TS_1_4_1,,-0.20,TEMP-ElectResis,,,2-5 -CA-LP1,T_SONIC,,26,SA-Campbell CSAT-3,,,2-5 -CA-LP1,T_SONIC_SIGMA,,26,SA-Campbell CSAT-3,,,2-5 -CA-LP1,USTAR,,26,SA-Campbell CSAT-3,,,2-5 -CA-LP1,VPD_PI,,26,GA_OP-LI-COR LI-7500,,,2-5 -CA-LP1,WD,,26,SA-Campbell CSAT-3,,,2-5 -CA-LP1,WS,,26,SA-Campbell CSAT-3,,,2-5 -CA-MA1,CO2,,3.0,GA_CP-LI-COR LI-7200,,,1-5 -CA-MA1,FC,,3.0,SA-Campbell CSAT-3,GA_CP-LI-COR LI-7200,,1-5 -CA-MA1,G,,-0.01,SOIL_H-Plate,,,1-5 -CA-MA1,H,,3.0,SA-Campbell CSAT-3,,,1-5 -CA-MA1,H2O,,3.0,GA_CP-LI-COR LI-7200,,,1-5 -CA-MA1,LE,,3.0,SA-Campbell CSAT-3,GA_CP-LI-COR LI-7200,,1-5 -CA-MA1,LW_IN,,3.0,RAD-Pyrrad-SW+LW,,,1-5 -CA-MA1,LW_OUT,,3.0,RAD-Pyrrad-SW+LW,,,1-5 -CA-MA1,NETRAD,,3.0,RAD-Pyrrad-SW+LW,,,1-5 -CA-MA1,PPFD_IN,,3.0,RAD-PAR Quantum,,,1-5 -CA-MA1,PPFD_OUT,,3.0,RAD-PAR Quantum,,,1-5 -CA-MA1,P_RAIN,,0.5,RAIN-TipBucGauge,,,1-5 -CA-MA1,RH,,1.2,RH-Capac,,,1-5 -CA-MA1,SWC,,-0.15,SWC-TDR,,,1-5 -CA-MA1,SW_IN,,3.0,RAD-Pyrrad-SW+LW,,,1-5 -CA-MA1,SW_OUT,,3.0,RAD-Pyrrad-SW+LW,,,1-5 -CA-MA1,TA,,1.2,TEMP-ElectResis,,,1-5 -CA-MA1,TS,,,TEMP-TCouple,,,1-5 -CA-MA1,T_SONIC,,3.0,SA-Campbell CSAT-3,,,1-5 -CA-MA1,USTAR,,3.0,SA-Campbell CSAT-3,,,1-5 -CA-MA1,WD,,3.0,SA-Campbell CSAT-3,,,1-5 -CA-MA1,WS,,3.0,SA-Campbell CSAT-3,,,1-5 -CA-MA2,CO2,,3.0,GA_CP-LI-COR LI-7000,,,1-5 -CA-MA2,FC,,3.0,GA_CP-LI-COR LI-7000,SA-Campbell CSAT-3,,1-5 -CA-MA2,G,,-0.01,SOIL_H-Plate,,,1-5 -CA-MA2,H,,3.0,SA-Campbell CSAT-3,,,1-5 -CA-MA2,H2O,,3.0,GA_CP-LI-COR LI-7000,,,1-5 -CA-MA2,LE,,3.0,GA_CP-LI-COR LI-7000,SA-Campbell CSAT-3,,1-5 -CA-MA2,LW_IN,,3.0,RAD-Pyrrad-SW+LW,,,1-5 -CA-MA2,LW_OUT,,3.0,RAD-Pyrrad-SW+LW,,,1-5 -CA-MA2,NETRAD,,3.0,RAD-Pyrrad-SW+LW,,,1-5 -CA-MA2,PPFD_IN,,3.0,RAD-PAR Quantum,,,1-5 -CA-MA2,PPFD_OUT,,3.0,RAD-PAR Quantum,,,1-5 -CA-MA2,P_RAIN,,0.5,RAIN-TipBucGauge,,,1-5 -CA-MA2,RH,,1.2,RH-Capac,,,1-5 -CA-MA2,SWC,,-0.15,SWC-TDR,,,1-5 -CA-MA2,SW_IN,,3.0,RAD-Pyrrad-SW+LW,,,1-5 -CA-MA2,SW_OUT,,3.0,RAD-Pyrrad-SW+LW,,,1-5 -CA-MA2,TA,,1.2,TEMP-ElectResis,,,1-5 -CA-MA2,TS,,,TEMP-TCouple,,,1-5 -CA-MA2,T_SONIC,,3.0,SA-Campbell CSAT-3,,,1-5 -CA-MA2,USTAR,,3.0,SA-Campbell CSAT-3,,,1-5 -CA-MA2,WD,,3.0,SA-Campbell CSAT-3,,,1-5 -CA-MA2,WS,,3.0,SA-Campbell CSAT-3,,,1-5 -CA-MA3,CO2,,3.0,GA_CP-LI-COR LI-7000,,,1-5 -CA-MA3,FC,,3.0,GA_CP-LI-COR LI-7000,SA-Campbell CSAT-3,,1-5 -CA-MA3,G,,-0.01,SOIL_H-Plate,,,1-5 -CA-MA3,H,,3.0,SA-Campbell CSAT-3,,,1-5 -CA-MA3,H2O,,3.0,GA_CP-LI-COR LI-7000,,,1-5 -CA-MA3,LE,,3.0,GA_CP-LI-COR LI-7000,SA-Campbell CSAT-3,,1-5 -CA-MA3,LW_IN,,3.0,RAD-Pyrrad-SW+LW,,,1-5 -CA-MA3,LW_OUT,,3.0,RAD-Pyrrad-SW+LW,,,1-5 -CA-MA3,NETRAD,,3.0,RAD-Pyrrad-SW+LW,,,1-5 -CA-MA3,PPFD_IN,,3.0,RAD-PAR Quantum,,,1-5 -CA-MA3,PPFD_OUT,,3.0,RAD-PAR Quantum,,,1-5 -CA-MA3,P_RAIN,,0.5,RAIN-TipBucGauge,,,1-5 -CA-MA3,RH,,1.2,RH-Capac,,,1-5 -CA-MA3,SWC,,-0.15,SWC-TDR,,,1-5 -CA-MA3,SW_IN,,3.0,RAD-Pyrrad-SW+LW,,,1-5 -CA-MA3,SW_OUT,,3.0,RAD-Pyrrad-SW+LW,,,1-5 -CA-MA3,TA,,1.2,TEMP-ElectResis,,,1-5 -CA-MA3,TS,,,TEMP-TCouple,,,1-5 -CA-MA3,T_SONIC,,3.0,SA-Campbell CSAT-3,,,1-5 -CA-MA3,USTAR,,3.0,SA-Campbell CSAT-3,,,1-5 -CA-MA3,WD,,3.0,SA-Campbell CSAT-3,,,1-5 -CA-MA3,WS,,3.0,SA-Campbell CSAT-3,,,1-5 -CA-Man,CO2_1,,29,,,,2-1 -CA-Man,FC,,29,,,,2-1 -CA-Man,H,,29,,,,2-1 -CA-Man,H2O,,29,,,,2-1 -CA-Man,LE,,29,,,,2-1 -CA-Man,NETRAD,,30,,,,2-1 -CA-Man,PPFD_IN,,30,,,,2-1 -CA-Man,TA,,30,,,,2-1 -CA-Man,TS_1,,-0.05,,,,2-1 -CA-Man,TS_2,,-0.1,,,,2-1 -CA-Man,USTAR,,29,,,,2-1 -CA-Man,WD,,29,,,,2-1 -CA-Man,WS,,29,,,,2-1 -CA-Na1,CO2_1_1_1,,15.12,,,,1-5 -CA-Na1,CO2_1_2_1,,13.92,,,,1-5 -CA-Na1,CO2_1_3_1,,10.42,,,,1-5 -CA-Na1,CO2_1_4_1,,7.55,,,,1-5 -CA-Na1,D_SNOW,,1.8,,,,1-5 -CA-Na1,G_1_1_1,,-0.1,,,,1-5 -CA-Na1,G_2_1_1,,-0.1,,,,1-5 -CA-Na1,G_3_1_1,,-0.1,,,,1-5 -CA-Na1,LW_IN,,15.8,,,,1-5 -CA-Na1,LW_OUT,,15.8,,,,1-5 -CA-Na1,NETRAD,,15.8,,,,1-5 -CA-Na1,PA,,1.5,,,,1-5 -CA-Na1,PPFD_DIF,,14.5,,,,1-5 -CA-Na1,PPFD_IN_1_1_1,,14.5,,,,1-5 -CA-Na1,PPFD_IN_1_1_2,,14.5,,,,1-5 -CA-Na1,PPFD_IN_1_2_1,,3.4,,,,1-5 -CA-Na1,PPFD_OUT,,14.5,,,,1-5 -CA-Na1,P_RAIN,,21,,,,1-5 -CA-Na1,RH_1_1_1,,16.2,,,,1-5 -CA-Na1,RH_1_2_1,,13.4,,,,1-5 -CA-Na1,RH_1_3_1,,6.9,,,,1-5 -CA-Na1,RH_1_4_1,,5.4,,,,1-5 -CA-Na1,RH_1_5_1,,3.4,,,,1-5 -CA-Na1,SWC_1_1_1,,-0.05,,,,1-5 -CA-Na1,SWC_1_2_1,,-0.1,,,,1-5 -CA-Na1,SWC_1_3_1,,-0.2,,,,1-5 -CA-Na1,SWC_1_4_1,,-0.5,,,,1-5 -CA-Na1,SWC_2_1_1,,-0.05,,,,1-5 -CA-Na1,SWC_2_2_1,,-0.1,,,,1-5 -CA-Na1,SWC_2_3_1,,-0.2,,,,1-5 -CA-Na1,SW_IN,,15.8,,,,1-5 -CA-Na1,SW_OUT,,15.8,,,,1-5 -CA-Na1,TA_1_1_1,,18,,,,1-5 -CA-Na1,TA_1_1_2,,18,,,,1-5 -CA-Na1,TA_1_2_1,,16.2,,,,1-5 -CA-Na1,TA_1_3_1,,13.4,,,,1-5 -CA-Na1,TA_1_4_1,,6.9,,,,1-5 -CA-Na1,TA_1_5_1,,5.4,,,,1-5 -CA-Na1,TA_1_6_1,,3.4,,,,1-5 -CA-Na1,T_BOLE_1_1_1,,1.3,,,,1-5 -CA-Na1,T_BOLE_2_1_1,,1.3,,,,1-5 -CA-Na1,T_BOLE_3_1_1,,1.3,,,,1-5 -CA-Na1,TS_1_1_1,,-0.02,,,,1-5 -CA-Na1,TS_1_2_1,,-0.05,,,,1-5 -CA-Na1,TS_1_3_1,,-0.1,,,,1-5 -CA-Na1,TS_1_4_1,,-0.2,,,,1-5 -CA-Na1,TS_1_5_1,,-0.5,,,,1-5 -CA-Na1,TS_1_6_1,,-0.65,,,,1-5 -CA-Na1,WD,,21,,,,1-5 -CA-Na1,WS,,21,,,,1-5 -CA-NS1,CO2,,24,,,,3-5 -CA-NS1,FC,,24,,,,3-5 -CA-NS1,H,,24,,,,3-5 -CA-NS1,LE,,24,,,,3-5 -CA-NS1,NETRAD,,24,,,,3-5 -CA-NS1,SWC,,-0.32,,,,3-5 -CA-NS1,SW_IN,,24,,,,3-5 -CA-NS1,TA_1_1_1,,24,TEMP-Other,,Vasaila Relative Humidity/ Temperature Probe,3-5 -CA-NS1,TS_1_1_1,,-0,,,,3-5 -CA-NS1,TS_1_2_1,,-0.07,,,,3-5 -CA-NS1,WS,,24,,,,3-5 -CA-NS2,CO2,,20,,,,3-5 -CA-NS2,FC,,20,,,,3-5 -CA-NS2,H,,20,,,,3-5 -CA-NS2,LE,,20,,,,3-5 -CA-NS2,SWC_1_1_1,,-0.18,,,,3-5 -CA-NS2,SWC_1_2_1,,-0.28,,,,3-5 -CA-NS2,TA_1_1_1,,,TEMP-Other,,Vasaila Relative Humidity/ Temperature Probe,3-5 -CA-NS2,TS_1_1_1,,-0,,,,3-5 -CA-NS2,TS_1_2_1,,-0.06,,,,3-5 -CA-NS2,WS,,20,,,,3-5 -CA-NS3,CO2,,10,,,,3-5 -CA-NS3,FC,,10,,,,3-5 -CA-NS3,H,,10,,,,3-5 -CA-NS3,LE,,10,,,,3-5 -CA-NS3,SWC_1_1_1,,-0.05,,,,3-5 -CA-NS3,SWC_1_2_1,,-0.1,,,,3-5 -CA-NS3,TA_1_1_1,,,TEMP-Other,,Vasaila Relative Humidity/ Temperature Probe,3-5 -CA-NS3,TS_1_1_1,,-0,,,,3-5 -CA-NS3,TS_1_2_1,,-0.02,,,,3-5 -CA-NS4,CO2,,10,,,,3-5 -CA-NS4,FC,,10,,,,3-5 -CA-NS4,H,,10,,,,3-5 -CA-NS4,LE,,10,,,,3-5 -CA-NS4,SWC_1_1_1,,-0.25,,,,3-5 -CA-NS4,SWC_1_2_1,,-0.35,,,,3-5 -CA-NS4,TA_1_1_1,,,TEMP-Other,,Vasaila Relative Humidity/ Temperature Probe,3-5 -CA-NS4,TS_1_1_1,,-0,,,,3-5 -CA-NS4,TS_1_2_1,,-0.05,,,,3-5 -CA-NS4,WS,,10,,,,3-5 -CA-NS5,CO2,,9,,,,3-5 -CA-NS5,FC,,9,,,,3-5 -CA-NS5,H,,9,,,,3-5 -CA-NS5,LE,,9,,,,3-5 -CA-NS5,NETRAD,,9,,,,3-5 -CA-NS5,SWC,,-0.09,,,,3-5 -CA-NS5,SW_IN,,9,,,,3-5 -CA-NS5,TA_1_1_1,,9,TEMP-Other,,Vasaila Relative Humidity/ Temperature Probe,3-5 -CA-NS5,TS_1_1_1,,-0,,,,3-5 -CA-NS5,TS_1_2_1,,-0.05,,,,3-5 -CA-NS5,WS,,9,,,,3-5 -CA-NS6,CO2,,6,,,,3-5 -CA-NS6,FC,,6,,,,3-5 -CA-NS6,H,,6,,,,3-5 -CA-NS6,LE,,6,,,,3-5 -CA-NS6,NETRAD,,6,,,,3-5 -CA-NS6,SWC,,-0.14,,,,3-5 -CA-NS6,SW_IN,,6,,,,3-5 -CA-NS6,TA_1_1_1,,6,TEMP-Other,,Vasaila Relative Humidity/ Temperature Probe,3-5 -CA-NS6,TS_1_1_1,,-0,,,,3-5 -CA-NS6,TS_1_2_1,,-0.03,,,,3-5 -CA-NS6,WS,,6,,,,3-5 -CA-NS7,CO2,,6,,,,3-5 -CA-NS7,FC,,6,,,,3-5 -CA-NS7,H,,6,,,,3-5 -CA-NS7,LE,,6,,,,3-5 -CA-NS7,SWC_1_1_1,,-0.11,,,,3-5 -CA-NS7,SWC_1_2_1,,-0.9,,,,3-5 -CA-NS7,TA_1_1_1,,,TEMP-Other,,Vasaila Relative Humidity/ Temperature Probe,3-5 -CA-NS7,TS_1_1_1,,-0,,,,3-5 -CA-NS7,TS_1_2_1,,-0.03,,,,3-5 -CA-NS7,WS,,6,,,,3-5 -CA-NS8,CO2_1,,6,,,,1-1 -CA-NS8,FC,,6,,,,1-1 -CA-NS8,H,,6,,,,1-1 -CA-NS8,LE,,6,,,,1-1 -CA-NS8,NETRAD,,6,,,,1-1 -CA-NS8,SW_IN,,6,,,,1-1 -CA-NS8,TA,,6,TEMP-Other,,Vasaila Relative Humidity/ Temperature Probe,1-1 -CA-NS8,WS,,6,,,,1-1 -CA-Oas,CO2_1,,39,,,,1-1 -CA-Oas,CO2_2,,28,,,,1-1 -CA-Oas,FC,,39,,,,1-1 -CA-Oas,H,,39,,,,1-1 -CA-Oas,H2O,,39,,,,1-1 -CA-Oas,LE,,39,,,,1-1 -CA-Oas,LW_IN,,37,,,,1-1 -CA-Oas,LW_OUT,,31,,,,1-1 -CA-Oas,NETRAD,,37,,,,1-1 -CA-Oas,PA,,2,,,,1-1 -CA-Oas,PPFD_DIF,,36,,,,1-1 -CA-Oas,PPFD_IN,,37,RAD-Other,,Li-Cor LI190,1-1 -CA-Oas,PPFD_OUT,,31,RAD-Other,,Li-Cor LI190,1-1 -CA-Oas,RH,,37,RH-Other,,Vaisala HMP,1-1 -CA-Oas,SWC_1,,-0.025,,,,1-1 -CA-Oas,SWC_2,,-0.075,,,,1-1 -CA-Oas,SW_IN,,37,RAD-Other,,Kipp & Zonen CM11,1-1 -CA-Oas,SW_OUT,,31,RAD-Other,,Kipp & Zonen CM11,1-1 -CA-Oas,TA,,37,TEMP-Other,,Vaisala HMP,1-1 -CA-Oas,TS_1,,-0.02,TEMP-Other,,Campbell Scientific Copper-Constantan 105T thermocouple,1-1 -CA-Oas,TS_2,,-0.05,TEMP-Other,,Campbell Scientific Copper-Constantan 105T thermocouple,1-1 -CA-Oas,USTAR,,39,,,,1-1 -CA-Oas,VPD_PI_PI,,37,,,,1-1 -CA-Oas,WD,,38,WIND-Other,,Young Propeller Anemometer,1-1 -CA-Oas,WS,,38,,,,1-1 -CA-Obs,CO2_1,,25,,,,1-1 -CA-Obs,CO2_2,,22,GA-Other,,LI-6262,1-1 -CA-Obs,FC,,25,,,,1-1 -CA-Obs,G,,-0.1,,,,1-1 -CA-Obs,H,,25,,,,1-1 -CA-Obs,H2O,,25,,,,1-1 -CA-Obs,LE,,25,,,,1-1 -CA-Obs,LW_IN,,25,,,,1-1 -CA-Obs,LW_OUT,,20,,,,1-1 -CA-Obs,NETRAD,,25,,,,1-1 -CA-Obs,PA,,2,,,,1-1 -CA-Obs,PPFD_DIF,,25,,,,1-1 -CA-Obs,PPFD_IN,,25,RAD-Other,,Li-Cor LI190,1-1 -CA-Obs,PPFD_OUT,,20,RAD-Other,,Li-Cor LI190,1-1 -CA-Obs,RH,,25,RH-Other,,Vaisala HMP,1-1 -CA-Obs,SWC_1,,-0.025,,,,1-1 -CA-Obs,SWC_2,,-0.075,,,,1-1 -CA-Obs,SW_IN,,25,RAD-Other,,Kipp & Zonen CM11,1-1 -CA-Obs,SW_OUT,,20,RAD-Other,,Kipp & Zonen CM11,1-1 -CA-Obs,TA,,25,TEMP-Other,,Vaisala HMP,1-1 -CA-Obs,TS_1,,-0.02,TEMP-Other,,Campbell Scientific Copper-Constantan 105T thermocouple,1-1 -CA-Obs,TS_2,,-0.05,TEMP-Other,,Campbell Scientific Copper-Constantan 105T thermocouple,1-1 -CA-Obs,USTAR,,25,,,,1-1 -CA-Obs,VPD_PI_PI,,25,,,,1-1 -CA-Obs,WD,,26,WIND-Other,,Young Propeller Anemometer,1-1 -CA-Obs,WS,,26,,,,1-1 -CA-Ojp,CO2_1_3_1,,28,,,,2-5 -CA-Ojp,CO2_1_4_1,,25,GA-Other,,(IRGA) model LI-6262,2-5 -CA-Ojp,FC,,28,,,,2-5 -CA-Ojp,G_1_1_1,,-0,,,,2-5 -CA-Ojp,H,,28,,,,2-5 -CA-Ojp,LE,,28,,,,2-5 -CA-Ojp,LW_IN,,28,RAD-Other,,Eppley PIR,2-5 -CA-Ojp,LW_OUT,,23,RAD-Other,,Eppley PIR,2-5 -CA-Ojp,NETRAD_1_1_1,,28,,,,2-5 -CA-Ojp,PA,,2,,,,2-5 -CA-Ojp,PPFD_DIF,,28,,,,2-5 -CA-Ojp,PPFD_IN_1_1_1,,28,RAD-Other,,Li-Cor LI 190SB,2-5 -CA-Ojp,PPFD_OUT,,23,,,,2-5 -CA-Ojp,RH_1_1_1,,28,RH-Other,,Vaisala HMP in a gill radiation shield,2-5 -CA-Ojp,SWC_1_1_1,,,SWC-Other,,CS615 soil moisture sensor,2-5 -CA-Ojp,SWC_1_2_1,,-0.3,SWC-Other,,CS615 soil moisture sensor,2-5 -CA-Ojp,SW_IN,,28,RAD-Other,,Kipp & Zonen CM11,2-5 -CA-Ojp,SW_OUT,,23,RAD-Other,,Kipp & Zonen CM11,2-5 -CA-Ojp,TA_1_1_1,,28,TEMP-Other,,Vaisala HMP n a gill radiation shield,2-5 -CA-Ojp,TS_1_1_1,,-0.02,TEMP-Other,,Queens Univ-made thermo-couple rod,2-5 -CA-Ojp,TS_1_2_1,,-0.05,TEMP-Other,,Queens Univ-made thermo-couple rod,2-5 -CA-Ojp,USTAR,,28,,,,2-5 -CA-Ojp,VPD_PI,,28,,,,2-5 -CA-Ojp,WD,,29,,,,2-5 -CA-Ojp,WS,,29,WIND-Other,,RM Young pro-peller anemometer,2-5 -CA-Qc2,CO2_1_1_1,,15,,,,1-5 -CA-Qc2,CO2_1_2_1,,3,,,,1-5 -CA-Qc2,FC_1_1_1,,15,,,,1-5 -CA-Qc2,FC_1_1_2,,15,,,,1-5 -CA-Qc2,G_1_2_1,,-0.08,,,,1-5 -CA-Qc2,G_1_2_2,,-0.08,,,,1-5 -CA-Qc2,H_1_1_1,,15,,,,1-5 -CA-Qc2,H_1_1_2,,15,,,,1-5 -CA-Qc2,LE_1_1_1,,15,,,,1-5 -CA-Qc2,LE_1_1_2,,15,,,,1-5 -CA-Qc2,NETRAD_PI_F,,15,,,,1-5 -CA-Qc2,PPFD_IN_1_1_1,,15,,,,1-5 -CA-Qc2,PPFD_IN_1_1_2,,15,,,,1-5 -CA-Qc2,PPFD_IN_1_1_3,,15,,,,1-5 -CA-Qc2,PPFD_IN_1_2_1,,1,,,,1-5 -CA-Qc2,PPFD_OUT,,14,,,,1-5 -CA-Qc2,RH_1_1_1,,15,,,,1-5 -CA-Qc2,RH_1_2_1,,5,,,,1-5 -CA-Qc2,RH_PI_F_1,,15,,,,1-5 -CA-Qc2,SC,,7.5,,,,1-5 -CA-Qc2,SH,,7.5,,,,1-5 -CA-Qc2,SLE,,7.5,,,,1-5 -CA-Qc2,SWC_1,,-0.05,,,,1-5 -CA-Qc2,SWC_1_1_1,,-0.05,,,,1-5 -CA-Qc2,SWC_1_2_1,,-0.1,,,,1-5 -CA-Qc2,SWC_1_3_1,,-0.2,,,,1-5 -CA-Qc2,SWC_1_4_1,,-0.5,,,,1-5 -CA-Qc2,SWC_2,,-0.1,,,,1-5 -CA-Qc2,SWC_2_1_1,,-0.05,,,,1-5 -CA-Qc2,SWC_2_2_1,,-0.1,,,,1-5 -CA-Qc2,SWC_2_3_1,,-0.2,,,,1-5 -CA-Qc2,SWC_2_4_1,,-0.5,,,,1-5 -CA-Qc2,SWC_3,,-0.2,,,,1-5 -CA-Qc2,SWC_4,,-0.5,,,,1-5 -CA-Qc2,TA_1_1_1,,15,,,,1-5 -CA-Qc2,TA_1_1_2,,15,,,,1-5 -CA-Qc2,TA_1_2_1,,5,,,,1-5 -CA-Qc2,TA_PI_F_1,,15,,,,1-5 -CA-Qc2,TS_1_1_1,,-0.03,,,,1-5 -CA-Qc2,TS_1_2_1,,-0.05,,,,1-5 -CA-Qc2,TS_1_3_1,,-0.1,,,,1-5 -CA-Qc2,TS_1_4_1,,-0.2,,,,1-5 -CA-Qc2,TS_1_5_1,,-0.5,,,,1-5 -CA-Qc2,TS_2_1_1,,-0.03,,,,1-5 -CA-Qc2,TS_2_2_1,,-0.05,,,,1-5 -CA-Qc2,TS_2_3_1,,-0.1,,,,1-5 -CA-Qc2,TS_2_4_1,,-0.2,,,,1-5 -CA-Qc2,TS_2_5_1,,-0.5,,,,1-5 -CA-Qc2,TS_PI_F_2,,-0.05,,,,1-5 -CA-Qc2,USTAR,,15,,,,1-5 -CA-Qc2,WD,,15,,,,1-5 -CA-Qc2,WS,,15,,,,1-5 -CA-Qc2,WS_PI_F,,15,,,,1-5 -CA-Qcu,CO2_1,,7,,,,1-1 -CA-Qcu,FC,,7,GA-Other,,LI-7500 IRGA,1-1 -CA-Qcu,G,,-0,,,,1-1 -CA-Qcu,H,,7,SA-Other,,fine-wire thermocouple,1-1 -CA-Qcu,LE,,7,GA-Other,,LI-7500 IRGA,1-1 -CA-Qcu,LW_IN,,2.5,RAD-Other,,Middleton CNR1,1-1 -CA-Qcu,LW_OUT,,2.5,RAD-Other,,Middleton CNR1,1-1 -CA-Qcu,NETRAD,,2.5,,,,1-1 -CA-Qcu,PA,,1.6,PRES-Other,,Vaisala Pressure Transmitter,1-1 -CA-Qcu,PPFD_IN,,7.5,RAD-Other,,LI-190SB,1-1 -CA-Qcu,PPFD_OUT,,7,RAD-Other,,LI-190SB,1-1 -CA-Qcu,P,,3.6,PREC-Other,,TR525M-RI,1-1 -CA-Qcu,RH,,6,RH-Other,,Campbell Scientific HMP45C,1-1 -CA-Qcu,SH,,,TEMP-Other,,fine-wire thermocouple,1-1 -CA-Qcu,SWC_1,,-0.05,,,,1-1 -CA-Qcu,SWC_2,,-0.2,,,,1-1 -CA-Qcu,SW_IN,,2.5,RAD-Other,,Middleton CNR1,1-1 -CA-Qcu,SW_OUT,,2.5,RAD-Other,,Middleton CNR1,1-1 -CA-Qcu,TA,,6,TEMP-Other,,Campbell Scientific HMP45C,1-1 -CA-Qcu,TS_1,,-0.02,TEMP-Other,,Copper-constantan thermocouple,1-1 -CA-Qcu,TS_2,,-0.05,TEMP-Other,,Copper-constantan thermocouple,1-1 -CA-Qcu,USTAR,,7,,,,1-1 -CA-Qcu,VPD_PI_PI,,6,,,,1-1 -CA-Qcu,WD,,7,WIND-Other,,RM Young Wind Monitor,1-1 -CA-Qcu,WS,,7,WIND-Other,,RM Young Wind Monitor,1-1 -CA-Qfo,CO2_1_1_1,,24,GA-Other,,LI-7000 IRGA,2-5 -CA-Qfo,FC_1_1_1,,24,GA-Other,,LI-7000 IRGA,2-5 -CA-Qfo,G_1_1_1,,-0,,,,2-5 -CA-Qfo,H_1_1_1,,24,SA-Other,,fine-wire thermocouple,2-5 -CA-Qfo,LE_1_1_1,,24,GA-Other,,LI-7000 IRGA,2-5 -CA-Qfo,LW_IN,,22,,,,2-5 -CA-Qfo,LW_OUT,,22,,,,2-5 -CA-Qfo,NETRAD,,22,,,,2-5 -CA-Qfo,P,,,PREC-Other,,Geonor T200B Precipitation gauge,2-5 -CA-Qfo,PA,,1.6,,,,2-5 -CA-Qfo,PPFD_DIF,,22,,,,2-5 -CA-Qfo,PPFD_IN_1_1_1,,22,,,,2-5 -CA-Qfo,PPFD_OUT,,22,,,,2-5 -CA-Qfo,RH_1_1_1,,24,,,,2-5 -CA-Qfo,SC,,24,,,,2-5 -CA-Qfo,SH,,,TEMP-Other,,HMP-45C sensors,2-5 -CA-Qfo,SLE,,,GA-Other,,HMP-45C sensors,2-5 -CA-Qfo,SWC_1_1_1,,-0.05,,,,2-5 -CA-Qfo,SWC_1_2_1,,-0.1,,,,2-5 -CA-Qfo,SW_IN,,22,,,,2-5 -CA-Qfo,SW_OUT,,22,,,,2-5 -CA-Qfo,TA_1_1_1,,24,,,,2-5 -CA-Qfo,TS_1_1_1,,-0.02,,,,2-5 -CA-Qfo,TS_1_2_1,,-0.05,,,,2-5 -CA-Qfo,USTAR,,24,,,,2-5 -CA-Qfo,VPD_PI,,24,,,,2-5 -CA-Qfo,WD,,24,,,,2-5 -CA-Qfo,WS,,24,,,,2-5 -CA-SF1,CO2,,12.1,,,,2-5 -CA-SF1,FC,,12.1,,,,2-5 -CA-SF1,G_1_1_1,,-0.03,,,,2-5 -CA-SF1,H,,12.1,,,,2-5 -CA-SF1,H2O,,12.1,,,,2-5 -CA-SF1,LE,,12.1,,,,2-5 -CA-SF1,LW_IN,,12.1,RAD-Other,,CNR1 Kipp & Zonen four components radiation sensor,2-5 -CA-SF1,LW_OUT,,12.1,RAD-Other,,CNR1 Kipp & Zonen four components radiation sensor,2-5 -CA-SF1,NETRAD,,12.1,RAD-Other,,CNR1 Kipp & Zonen four components radiation sensor,2-5 -CA-SF1,PA,,1.0,PRES-Other,,Vaisala PTB101B Barometric Pressure Sensor,2-5 -CA-SF1,PPFD_IN,,12.1,RAD-Other,,Kipp & Zonen PAR lite Quantum Sensor,2-5 -CA-SF1,PPFD_OUT,,12.1,RAD-Other,,Kipp & Zonen PAR lite Quantum Sensor,2-5 -CA-SF1,P_RAIN,,1,PREC-Other,,Rain Texas Instrument Tipping Bucket Rain Gauge TE525,2-5 -CA-SF1,RH,,1.5,RH-Other,,Vaisala HMP45C,2-5 -CA-SF1,SWC_1_1_1,,-0.3,,,,2-5 -CA-SF1,SW_IN,,12.1,RAD-Other,,Kipp & Zonen four components radiation sensor,2-5 -CA-SF1,SW_OUT,,12.1,RAD-Other,,Kipp & Zonen four components radiation sensor,2-5 -CA-SF1,TA_1_1_1,,1.5,TEMP-Other,,Vaisala HMP45C,2-5 -CA-SF1,TS_1_1_1,,-0.02,TEMP-Other,,Type E (chromel-constantan) Omega EXPP-24S,2-5 -CA-SF1,TS_1_2_1,,-0.05,TEMP-Other,,Type E (chromel-constantan) Omega EXPP-24S,2-5 -CA-SF1,USTAR,,12.1,,,,2-5 -CA-SF1,VPD_PI,,1.5,,,,2-5 -CA-SF1,WD,,12.1,WIND-Other,,R.M. Young wind monitor sn WM50619,2-5 -CA-SF1,WS,,12.1,WIND-Other,,R.M. Young wind monitor sn WM50619,2-5 -CA-SF2,CO2,,9.144,,,,3-5 -CA-SF2,FC,,9.144,,,,3-5 -CA-SF2,G_1_1_1,,-0.03,SOIL_H-Other,,REBS_SoilHeatFlux_0.03m_repA (W/m2),3-5 -CA-SF2,H,,9.144,,,,3-5 -CA-SF2,H2O,,9.144,,,,3-5 -CA-SF2,LE,,9.144,,,,3-5 -CA-SF2,LW_IN,,9.144,RAD-Other,,Kipp & Zonen four components radiation sensor,3-5 -CA-SF2,LW_OUT,,9.144,RAD-Other,,CNR1,3-5 -CA-SF2,NETRAD_1_1_1,,9.144,RAD-Other,,Kipp & Zonen four components radiation sensor,3-5 -CA-SF2,P,,1,,,,3-5 -CA-SF2,PA,,1.0,PRES-Other,,Vaisala_atm_pressure [kPa] Vaisala PTB101B Barometric Pressure Sensor,3-5 -CA-SF2,PPFD_IN,,9.144,RAD-Other,,Kipp & Zonen PAR lite Quantum Sensor,3-5 -CA-SF2,PPFD_OUT,,9.144,RAD-Other,,Kipp & Zonen PAR lite Quantum Sensor,3-5 -CA-SF2,RH,,1.5,RH-Other,,Vaisala HMP45C relative humidity,3-5 -CA-SF2,SW_IN,,9.144,RAD-Other,,CNR1,3-5 -CA-SF2,SW_OUT,,9.144,RAD-Other,,CNR1,3-5 -CA-SF2,TA_1_1_1,,1.5,TEMP-Other,,Vaisala HMP45C air temperature,3-5 -CA-SF2,TS_1_1_1,,-0.02,,,,3-5 -CA-SF2,TS_1_2_1,,-0.05,,,,3-5 -CA-SF2,USTAR,,9.144,,,,3-5 -CA-SF2,VPD_PI,,1.5,,,,3-5 -CA-SF2,WD,,9.144,WIND-Other,,Young 05305-10-L AQ wind monitor oriented TRUE MAGNETIC NORTH,3-5 -CA-SF2,WS,,9.144,WIND-Other,,Young 05305-10-L AQ wind monitor oriented TRUE MAGNETIC NORTH,3-5 -CA-SF3,CO2,,18.288,,,,2-5 -CA-SF3,FC,,18.288,,,,2-5 -CA-SF3,G_3_1_1,,-0.03,,,,2-5 -CA-SF3,H,,18.288,,,,2-5 -CA-SF3,H2O,,18.288,GA-Other,,Li-Cor LI7500,2-5 -CA-SF3,LE,,18.288,,,,2-5 -CA-SF3,LW_IN,,18.288,RAD-Other,,CNR 1,2-5 -CA-SF3,LW_OUT,,18.288,RAD-Other,,CNR 1,2-5 -CA-SF3,NETRAD_1_1_1,,18.288,RAD-Other,,CNR1 Kipp & Zonen four components radiation sensor,2-5 -CA-SF3,PA,,1.0,PRES-Other,,Vaisala PTB101B Barometric Pressure Sensor,2-5 -CA-SF3,PPFD_IN,,18.288,RAD-Other,,Kipp & Zonen PAR lite Quantum Sensor,2-5 -CA-SF3,PPFD_OUT,,18.288,RAD-Other,,Kipp & Zonen PAR lite Quantum Sensor,2-5 -CA-SF3,P_RAIN,,1,PREC-Other,,Texas Instrument Tipping Bucket Rain Gauge TE525,2-5 -CA-SF3,RH,,1.5,RH-Other,,Vaisala HMP45C,2-5 -CA-SF3,SWC_1_1_1,,-0.3,,,,2-5 -CA-SF3,SW_IN,,18.288,RAD-Other,,CNR1 Kipp & Zonen four components radiation sensor,2-5 -CA-SF3,SW_OUT,,18.288,RAD-Other,,CNR1 Kipp & Zonen four components radiation sensor,2-5 -CA-SF3,TA_1_1_1,,1.5,TEMP-Other,,Vaisala HMP45C,2-5 -CA-SF3,TS_1_1_1,,-0.02,TEMP-Other,,Type E (chromel-constantan) Omega EXPP-24S,2-5 -CA-SF3,TS_1_2_1,,-0.05,TEMP-Other,,Type E (chromel-constantan) Omega EXPP-24S,2-5 -CA-SF3,USTAR,,18.288,,,,2-5 -CA-SF3,VPD_PI,,1.5,,,,2-5 -CA-SF3,WD,,18.288,WIND-Other,,R.M. Young 05305-10-L AQ wind monitor,2-5 -CA-SF3,WS,,18.288,WIND-Other,,R.M. Young 05305-10-L AQ wind monitor,2-5 -CA-SJ1,FC,,5,,,LI-6262 and SAT-550; -5 to 5,1-5 -CA-SJ1,G_1_1_1,,-0.1,,,,1-5 -CA-SJ1,G_2_1_1,,-0.1,,,,1-5 -CA-SJ1,G_3_1_1,,-0.1,,,,1-5 -CA-SJ1,G_4_1_1,,-0.1,,,,1-5 -CA-SJ1,H,,5,,,SAT-550; -1000 to 1000,1-5 -CA-SJ1,LE,,5,,,LI-6262 and SAT-550; -500 to 700,1-5 -CA-SJ1,LEAF_WET,,6,,,,1-5 -CA-SJ1,LW_IN,,6,,,,1-5 -CA-SJ1,LW_IN_PI_F,,6,,,,1-5 -CA-SJ1,LW_OUT,,6,,,,1-5 -CA-SJ1,LW_OUT_PI_F,,6,,,,1-5 -CA-SJ1,PPFD_IN_1_1_1,,8,,,,1-5 -CA-SJ1,PPFD_IN_1_2_1,,4,,,,1-5 -CA-SJ1,PPFD_IN_PI_F_1_1_1,,8,,,,1-5 -CA-SJ1,PPFD_IN_PI_F_1_2_1,,4,,,,1-5 -CA-SJ1,PPFD_OUT,,6,,,,1-5 -CA-SJ1,PPFD_OUT_PI_F,,6,,,,1-5 -CA-SJ1,RH_1_1_1,,6,,,,1-5 -CA-SJ1,RH_1_2_1,,4,,,,1-5 -CA-SJ1,RH_1_3_1,,1,,,,1-5 -CA-SJ1,RH_PI_F_1_1_1,,6,,,,1-5 -CA-SJ1,RH_PI_F_1_2_1,,4,,,,1-5 -CA-SJ1,RH_PI_F_1_3_1,,1,,,,1-5 -CA-SJ1,SWC_1,,-0.075,,,,1-5 -CA-SJ1,SWC_2,,-0.225,,,,1-5 -CA-SJ1,SWC_3,,-0.45,,,,1-5 -CA-SJ1,SWC_4,,-0.75,,,,1-5 -CA-SJ1,SWC_5,,-1.05,,,,1-5 -CA-SJ1,SWC_6,,-1.35,,,,1-5 -CA-SJ1,SWC_PI_F_1,,-0.075,,,,1-5 -CA-SJ1,SWC_PI_F_2,,-0.225,,,,1-5 -CA-SJ1,SWC_PI_F_3,,-0.45,,,,1-5 -CA-SJ1,SWC_PI_F_4,,-0.75,,,,1-5 -CA-SJ1,SWC_PI_F_5,,-1.05,,,,1-5 -CA-SJ1,SWC_PI_F_6,,-1.35,,,,1-5 -CA-SJ1,SW_IN,,6,,,,1-5 -CA-SJ1,SW_IN_PI_F,,6,,,,1-5 -CA-SJ1,SW_OUT,,6,,,,1-5 -CA-SJ1,SW_OUT_PI_F,,6,,,,1-5 -CA-SJ1,TA_1_1_1,,6,,,,1-5 -CA-SJ1,TA_1_1_2,,6,,,,1-5 -CA-SJ1,TA_1_2_1,,4,,,,1-5 -CA-SJ1,TA_1_2_2,,4,,,,1-5 -CA-SJ1,TA_1_3_1,,1,,,,1-5 -CA-SJ1,TA_1_3_2,,1,,,,1-5 -CA-SJ1,TA_PI_F_1_1_1,,6,,,,1-5 -CA-SJ1,TA_PI_F_1_1_2,,6,,,,1-5 -CA-SJ1,TA_PI_F_1_2_1,,4,,,,1-5 -CA-SJ1,TA_PI_F_1_2_2,,4,,,,1-5 -CA-SJ1,TA_PI_F_1_3_1,,1,,,,1-5 -CA-SJ1,TA_PI_F_1_3_2,,1,,,,1-5 -CA-SJ1,TS_1_1_1,,-0.02,,,,1-5 -CA-SJ1,TS_1_2_1,,-0.05,,,,1-5 -CA-SJ1,TS_1_3_1,,-0.1,,,,1-5 -CA-SJ1,TS_1_4_1,,-0.2,,,,1-5 -CA-SJ1,TS_1_5_1,,-0.5,,,,1-5 -CA-SJ1,TS_1_6_1,,-1,,,,1-5 -CA-SJ1,TS_2_1_1,,-0.02,,,,1-5 -CA-SJ1,TS_2_2_1,,-0.05,,,,1-5 -CA-SJ1,TS_2_3_1,,-0.1,,,,1-5 -CA-SJ1,TS_2_4_1,,-0.2,,,,1-5 -CA-SJ1,TS_2_5_1,,-0.5,,,,1-5 -CA-SJ1,TS_2_6_1,,-1,,,,1-5 -CA-SJ1,TS_3_1_1,,-0.02,,,,1-5 -CA-SJ1,TS_3_2_1,,-0.05,,,,1-5 -CA-SJ1,TS_3_3_1,,-0.1,,,,1-5 -CA-SJ1,TS_4_1_1,,-0.02,,,,1-5 -CA-SJ1,TS_4_2_1,,-0.05,,,,1-5 -CA-SJ1,TS_4_3_1,,-0.1,,,,1-5 -CA-SJ1,TS_5_1_1,,-0.02,,,,1-5 -CA-SJ1,TS_5_2_1,,-0.05,,,,1-5 -CA-SJ1,TS_5_3_1,,-0.1,,,,1-5 -CA-SJ1,TS_6_1_1,,-0.02,,,,1-5 -CA-SJ1,TS_6_2_1,,-0.05,,,,1-5 -CA-SJ1,TS_6_3_1,,-0.1,,,,1-5 -CA-SJ1,TS_PI_F_1_1_1,,-0.02,,,,1-5 -CA-SJ1,TS_PI_F_1_2_1,,-0.05,,,,1-5 -CA-SJ1,TS_PI_F_1_3_1,,-0.1,,,,1-5 -CA-SJ1,TS_PI_F_1_4_1,,-0.2,,,,1-5 -CA-SJ1,TS_PI_F_1_5_1,,-0.5,,,,1-5 -CA-SJ1,TS_PI_F_1_6_1,,-1,,,,1-5 -CA-SJ1,TS_PI_F_2_1_1,,-0.02,,,,1-5 -CA-SJ1,TS_PI_F_2_2_1,,-0.05,,,,1-5 -CA-SJ1,TS_PI_F_2_3_1,,-0.1,,,,1-5 -CA-SJ1,TS_PI_F_2_4_1,,-0.2,,,,1-5 -CA-SJ1,TS_PI_F_2_5_2,,-0.5,,,,1-5 -CA-SJ1,TS_PI_F_2_6_1,,-1,,,,1-5 -CA-SJ1,TS_PI_F_3_1_1,,-0.02,,,,1-5 -CA-SJ1,TS_PI_F_3_2_1,,-0.05,,,,1-5 -CA-SJ1,TS_PI_F_3_3_1,,-0.1,,,,1-5 -CA-SJ1,TS_PI_F_4_1_1,,-0.02,,,,1-5 -CA-SJ1,TS_PI_F_4_2_1,,-0.05,,,,1-5 -CA-SJ1,TS_PI_F_4_3_1,,-0.1,,,,1-5 -CA-SJ1,TS_PI_F_5_1_1,,-0.02,,,,1-5 -CA-SJ1,TS_PI_F_5_2_1,,-0.05,,,,1-5 -CA-SJ1,TS_PI_F_5_3_1,,-0.1,,,,1-5 -CA-SJ1,TS_PI_F_6_1_1,,-0.02,,,,1-5 -CA-SJ1,TS_PI_F_6_2_1,,-0.05,,,,1-5 -CA-SJ1,TS_PI_F_6_3_1,,-0.1,,,,1-5 -CA-SJ1,TSN_1_1_1,,0.5,,,,1-5 -CA-SJ1,TSN_1_2_1,,0.4,,,,1-5 -CA-SJ1,TSN_1_3_1,,0.3,,,,1-5 -CA-SJ1,TSN_1_4_1,,0.2,,,,1-5 -CA-SJ1,TSN_1_5_1,,0.1,,,,1-5 -CA-SJ1,TSN_1_6_1,,0.05,,,,1-5 -CA-SJ1,TSN_1_7_1,,0.02,,,,1-5 -CA-SJ1,TSN_1_8_1,,0.01,,,,1-5 -CA-SJ1,TSN_2_1_1,,0.5,,,,1-5 -CA-SJ1,TSN_2_2_1,,0.4,,,,1-5 -CA-SJ1,TSN_2_3_1,,0.3,,,,1-5 -CA-SJ1,TSN_2_4_1,,0.2,,,,1-5 -CA-SJ1,TSN_2_5_1,,0.1,,,,1-5 -CA-SJ1,TSN_2_6_1,,0.05,,,,1-5 -CA-SJ1,TSN_2_7_1,,0.02,,,,1-5 -CA-SJ1,TSN_2_8_1,,0.01,,,,1-5 -CA-SJ1,USTAR,,5,,,,1-5 -CA-SJ1,WD_1_1_1,,10,,,,1-5 -CA-SJ1,WD_1_2_1,,6,,,RM Young propeller anemometer.,1-5 -CA-SJ1,WD_PI_F_1_1_1,,10,,,,1-5 -CA-SJ1,WD_PI_F_1_2_1,,6,,,,1-5 -CA-SJ1,WD_SIGMA_1_1_1,,10,,,,1-5 -CA-SJ1,WD_SIGMA_1_2_1,,6,,,RM Young propeller anemometer.,1-5 -CA-SJ1,WS_1_1_1,,10,,,,1-5 -CA-SJ1,WS_1_2_1,,6,,,RM Young propeller anemometer.,1-5 -CA-SJ1,WS_PI_F_1_1_1,,10,,,,1-5 -CA-SJ1,WS_PI_F_1_2_1,,6,,,,1-5 -CA-SJ2,CO2,,2,,,,2-5 -CA-SJ2,CO2_PI_F,,2,,,,2-5 -CA-SJ2,FC,,2,,,,2-5 -CA-SJ2,G_1_1_1,,0,,,,2-5 -CA-SJ2,G_1_2_1,,-0.03,,,,2-5 -CA-SJ2,G_1_3_1,,-0.09,,,,2-5 -CA-SJ2,G_1_4_1,,-0.1,,,,2-5 -CA-SJ2,G_1_4_2,,-0.1,,,,2-5 -CA-SJ2,G_2_2_1,,-0.03,,,,2-5 -CA-SJ2,G_3_2_1,,-0.03,,,,2-5 -CA-SJ2,G_4_2_1,,-0.03,,,,2-5 -CA-SJ2,H,,2,,,,2-5 -CA-SJ2,H2O,,2,,,,2-5 -CA-SJ2,H2O_PI_F,,2,,,,2-5 -CA-SJ2,LE,,2,,,,2-5 -CA-SJ2,LEAF_WET,,3,,,,2-5 -CA-SJ2,LW_IN,,2,,,,2-5 -CA-SJ2,LW_IN_PI_F,,2,,,,2-5 -CA-SJ2,LW_OUT,,2,,,,2-5 -CA-SJ2,LW_OUT_PI_F,,2,,,,2-5 -CA-SJ2,NETRAD,,2,,,,2-5 -CA-SJ2,NETRAD_PI_F,,2,,,,2-5 -CA-SJ2,PPFD_IN,,3,,,,2-5 -CA-SJ2,PPFD_IN_PI_F,,3,,,,2-5 -CA-SJ2,PPFD_OUT,,2,,,,2-5 -CA-SJ2,PPFD_OUT_PI_F,,2,,,,2-5 -CA-SJ2,RH_1_1_1,,2,,,,2-5 -CA-SJ2,RH_1_2_1,,1,,,,2-5 -CA-SJ2,RH_PI_F_1_1_1,,2,,,,2-5 -CA-SJ2,RH_PI_F_1_2_1,,1,,,,2-5 -CA-SJ2,SWC_1,,-0.075,,,,2-5 -CA-SJ2,SWC_2,,-0.225,,,,2-5 -CA-SJ2,SWC_3,,-0.45,,,,2-5 -CA-SJ2,SWC_4,,-0.75,,,,2-5 -CA-SJ2,SWC_5,,-1.05,,,,2-5 -CA-SJ2,SWC_6,,-1.35,,,,2-5 -CA-SJ2,SWC_PI_F_1,,-0.075,,,,2-5 -CA-SJ2,SWC_PI_F_2,,-0.225,,,,2-5 -CA-SJ2,SWC_PI_F_3,,-0.45,,,,2-5 -CA-SJ2,SWC_PI_F_4,,-0.75,,,,2-5 -CA-SJ2,SWC_PI_F_5,,-1.05,,,,2-5 -CA-SJ2,SWC_PI_F_6,,-1.35,,,,2-5 -CA-SJ2,SW_IN,,2,,,,2-5 -CA-SJ2,SW_IN_PI_F,,2,,,,2-5 -CA-SJ2,SW_OUT,,2,,,,2-5 -CA-SJ2,SW_OUT_PI_F,,2,,,,2-5 -CA-SJ2,TA_1_1_1,,2,,,,2-5 -CA-SJ2,TA_1_1_2,,2,,,,2-5 -CA-SJ2,TA_1_2_1,,1,,,,2-5 -CA-SJ2,TA_PI_F_1_1_1,,2,,,,2-5 -CA-SJ2,TA_PI_F_1_1_2,,2,,,,2-5 -CA-SJ2,TA_PI_F_1_2_1,,1,,,,2-5 -CA-SJ2,TS_1_1_1,,-0.01,,,,2-5 -CA-SJ2,TS_1_2_1,,-0.02,,,,2-5 -CA-SJ2,TS_1_3_1,,-0.03,,,,2-5 -CA-SJ2,TS_1_4_1,,-0.05,,,,2-5 -CA-SJ2,TS_1_5_1,,-0.1,,,,2-5 -CA-SJ2,TS_1_6_1,,-0.2,,,,2-5 -CA-SJ2,TS_1_7_1,,-0.5,,,,2-5 -CA-SJ2,TS_1_8_1,,-1,,,,2-5 -CA-SJ2,TS_2_1_1,,-0.01,,,,2-5 -CA-SJ2,TS_2_2_1,,-0.02,,,,2-5 -CA-SJ2,TS_2_3_1,,-0.03,,,,2-5 -CA-SJ2,TS_2_4_1,,-0.05,,,,2-5 -CA-SJ2,TS_2_5_1,,-0.1,,,,2-5 -CA-SJ2,TS_2_6_1,,-0.2,,,,2-5 -CA-SJ2,TS_2_7_1,,-0.5,,,,2-5 -CA-SJ2,TS_2_8_1,,-1,,,,2-5 -CA-SJ2,TS_3_2_1,,-0.02,,,,2-5 -CA-SJ2,TS_3_4_1,,-0.05,,,,2-5 -CA-SJ2,TS_3_5_1,,-0.1,,,,2-5 -CA-SJ2,TS_4_2_1,,-0.02,,,,2-5 -CA-SJ2,TS_4_4_1,,-0.05,,,,2-5 -CA-SJ2,TS_4_5_1,,-0.1,,,,2-5 -CA-SJ2,TS_5_4_1,,-0.05,,,,2-5 -CA-SJ2,TS_6_4_1,,-0.05,,,,2-5 -CA-SJ2,TS_PI_F_1_1_1,,-0.01,,,,2-5 -CA-SJ2,TS_PI_F_1_2_1,,-0.02,,,,2-5 -CA-SJ2,TS_PI_F_1_3_1,,-0.03,,,,2-5 -CA-SJ2,TS_PI_F_1_4_1,,-0.05,,,,2-5 -CA-SJ2,TS_PI_F_1_5_1,,-0.1,,,,2-5 -CA-SJ2,TS_PI_F_1_6_1,,-0.2,,,,2-5 -CA-SJ2,TS_PI_F_1_7_1,,-0.5,,,,2-5 -CA-SJ2,TS_PI_F_1_8_1,,-1,,,,2-5 -CA-SJ2,TS_PI_F_2_1_1,,-0.01,,,,2-5 -CA-SJ2,TS_PI_F_2_2_1,,-0.02,,,,2-5 -CA-SJ2,TS_PI_F_2_3_1,,-0.03,,,,2-5 -CA-SJ2,TS_PI_F_2_4_1,,-0.05,,,,2-5 -CA-SJ2,TS_PI_F_2_5_1,,-0.1,,,,2-5 -CA-SJ2,TS_PI_F_2_6_1,,-0.2,,,,2-5 -CA-SJ2,TS_PI_F_2_7_1,,-0.5,,,,2-5 -CA-SJ2,TS_PI_F_2_8_1,,-1,,,,2-5 -CA-SJ2,TS_PI_F_3_2_1,,-0.02,,,,2-5 -CA-SJ2,TS_PI_F_3_4_1,,-0.05,,,,2-5 -CA-SJ2,TS_PI_F_3_5_1,,-0.1,,,,2-5 -CA-SJ2,TS_PI_F_4_2_1,,-0.02,,,,2-5 -CA-SJ2,TS_PI_F_4_4_1,,-0.05,,,,2-5 -CA-SJ2,TS_PI_F_4_5_1,,-0.1,,,,2-5 -CA-SJ2,TS_PI_F_5_4_1,,-0.05,,,,2-5 -CA-SJ2,TS_PI_F_6_4_1,,-0.05,,,,2-5 -CA-SJ2,TSN_1_1_1,,0.5,,,,2-5 -CA-SJ2,TSN_1_2_1,,0.4,,,,2-5 -CA-SJ2,TSN_1_3_1,,0.3,,,,2-5 -CA-SJ2,TSN_1_4_1,,0.2,,,,2-5 -CA-SJ2,TSN_1_5_1,,0.1,,,,2-5 -CA-SJ2,TSN_1_6_1,,0.05,,,,2-5 -CA-SJ2,TSN_1_7_1,,0.02,,,,2-5 -CA-SJ2,TSN_1_8_1,,0.01,,,,2-5 -CA-SJ2,USTAR,,2,,,,2-5 -CA-SJ2,WD,,5,,,,2-5 -CA-SJ2,WS,,5,,,,2-5 -CA-SJ2,WS_PI_F,,5,,,,2-5 -CA-SJ3,FC,,16,,,,2-5 -CA-SJ3,G_1_1_1,,0,,,,2-5 -CA-SJ3,G_1_2_1,,-0.1,,,,2-5 -CA-SJ3,G_2_2_1,,-0.1,,,,2-5 -CA-SJ3,G_3_2_1,,-0.1,,,,2-5 -CA-SJ3,G_4_2_1,,-0.1,,,,2-5 -CA-SJ3,H,,16,,,,2-5 -CA-SJ3,LE,,16,,,,2-5 -CA-SJ3,LW_IN,,12,,,,2-5 -CA-SJ3,LW_IN_PI_F,,12,,,,2-5 -CA-SJ3,LW_OUT,,12,,,,2-5 -CA-SJ3,LW_OUT_PI_F,,12,,,,2-5 -CA-SJ3,PPFD_IN_1_1_1,,12,,,,2-5 -CA-SJ3,PPFD_IN_1_2_1,,0.5,,,,2-5 -CA-SJ3,PPFD_IN_PI_F_1_1_1,,12,,,,2-5 -CA-SJ3,PPFD_IN_PI_F_1_2_1,,0.5,,,,2-5 -CA-SJ3,PPFD_OUT,,12,,,,2-5 -CA-SJ3,PPFD_OUT_PI_F,,12,,,,2-5 -CA-SJ3,RH_1_1_1,,15,,,,2-5 -CA-SJ3,RH_1_2_1,,4,,,,2-5 -CA-SJ3,RH_1_3_1,,1,,,,2-5 -CA-SJ3,RH_PI_F_1_1_1,,15,,,,2-5 -CA-SJ3,RH_PI_F_1_2_1,,4,,,,2-5 -CA-SJ3,RH_PI_F_1_3_1,,1,,,,2-5 -CA-SJ3,SH,,8,,,,2-5 -CA-SJ3,SLE,,8,,,,2-5 -CA-SJ3,SWC_1,,-0.075,,,,2-5 -CA-SJ3,SWC_2,,-0.225,,,,2-5 -CA-SJ3,SWC_3,,-0.45,,,,2-5 -CA-SJ3,SWC_4,,-0.75,,,,2-5 -CA-SJ3,SWC_5,,-1.05,,,,2-5 -CA-SJ3,SWC_6,,-1.35,,,,2-5 -CA-SJ3,SWC_PI_F_1,,-0.075,,,,2-5 -CA-SJ3,SWC_PI_F_2,,-0.225,,,,2-5 -CA-SJ3,SWC_PI_F_3,,-0.45,,,,2-5 -CA-SJ3,SWC_PI_F_4,,-0.75,,,,2-5 -CA-SJ3,SWC_PI_F_5,,-1.05,,,,2-5 -CA-SJ3,SWC_PI_F_6,,-1.35,,,,2-5 -CA-SJ3,SW_IN,,12,,,,2-5 -CA-SJ3,SW_IN_PI_F,,12,,,,2-5 -CA-SJ3,SW_OUT,,12,,,,2-5 -CA-SJ3,SW_OUT_PI_F,,12,,,,2-5 -CA-SJ3,TA_1_1_1,,15,,,,2-5 -CA-SJ3,TA_1_1_2,,15,,,,2-5 -CA-SJ3,TA_1_2_1,,4,,,,2-5 -CA-SJ3,TA_1_3_1,,1,,,,2-5 -CA-SJ3,TA_PI_F_1_1_1,,15,,,,2-5 -CA-SJ3,TA_PI_F_1_1_2,,15,,,,2-5 -CA-SJ3,TA_PI_F_1_2_1,,4,,,,2-5 -CA-SJ3,TA_PI_F_1_3_1,,1,,,,2-5 -CA-SJ3,T_BOLE_1_1_1,,1,,,,2-5 -CA-SJ3,T_BOLE_2_1_1,,1,,,,2-5 -CA-SJ3,TS_1_1_1,,-0.02,,,,2-5 -CA-SJ3,TS_1_2_1,,-0.05,,,,2-5 -CA-SJ3,TS_1_3_1,,-0.1,,,,2-5 -CA-SJ3,TS_1_4_1,,-0.2,,,,2-5 -CA-SJ3,TS_1_5_1,,-0.5,,,,2-5 -CA-SJ3,TS_1_6_1,,-1,,,,2-5 -CA-SJ3,TS_2_1_1,,-0.02,,,,2-5 -CA-SJ3,TS_2_2_1,,-0.05,,,,2-5 -CA-SJ3,TS_2_3_1,,-0.1,,,,2-5 -CA-SJ3,TS_2_4_1,,-0.2,,,,2-5 -CA-SJ3,TS_2_5_1,,-0.5,,,,2-5 -CA-SJ3,TS_2_6_1,,-1,,,,2-5 -CA-SJ3,TS_PI_F_1_1_1,,-0.02,,,,2-5 -CA-SJ3,TS_PI_F_1_2_1,,-0.05,,,,2-5 -CA-SJ3,TS_PI_F_1_3_1,,-0.1,,,,2-5 -CA-SJ3,TS_PI_F_1_4_1,,-0.2,,,,2-5 -CA-SJ3,TS_PI_F_1_5_1,,-0.5,,,,2-5 -CA-SJ3,TS_PI_F_1_6_1,,-1,,,,2-5 -CA-SJ3,TS_PI_F_2_1_1,,-0.02,,,,2-5 -CA-SJ3,TS_PI_F_2_2_1,,-0.05,,,,2-5 -CA-SJ3,TS_PI_F_2_3_1,,-0.1,,,,2-5 -CA-SJ3,TS_PI_F_2_4_1,,-0.2,,,,2-5 -CA-SJ3,TS_PI_F_2_5_1,,-0.5,,,,2-5 -CA-SJ3,TS_PI_F_2_6_1,,-1,,,,2-5 -CA-SJ3,TSN_1_1_1,,0.5,,,,2-5 -CA-SJ3,TSN_1_2_1,,0.4,,,,2-5 -CA-SJ3,TSN_1_3_1,,0.3,,,,2-5 -CA-SJ3,TSN_1_4_1,,0.2,,,,2-5 -CA-SJ3,TSN_1_5_1,,0.1,,,,2-5 -CA-SJ3,TSN_1_6_1,,0.05,,,,2-5 -CA-SJ3,TSN_1_7_1,,0.02,,,,2-5 -CA-SJ3,TSN_1_8_1,,0.01,,,,2-5 -CA-SJ3,USTAR,,16,,,,2-5 -CA-SJ3,WD,,16,,,,2-5 -CA-SJ3,WD_PI_F,,16,,,,2-5 -CA-SJ3,WD_SIGMA,,16,,,,2-5 -CA-SJ3,WS,,16,,,,2-5 -CA-SJ3,WS_PI_F,,16,,,,2-5 -CA-TP1,CO2,,,GA_CP-LI-COR LI-7000,,LI-7000 or LI-7500 IRGA),3-5 -CA-TP1,FC,,,GA_CP-LI-COR LI-7000,,,3-5 -CA-TP1,FH2O,,3,GA_CP-LI-COR LI-7000,,,3-5 -CA-TP1,G_1_1_1,,-0,,,,3-5 -CA-TP1,G_1_2_1,,-0.03,,,,3-5 -CA-TP1,G_2_2_1,,-0.03,,,,3-5 -CA-TP1,P_1_1_1,,2,,,,3-5 -CA-TP1,P_2_1_1,,2,,,,3-5 -CA-TP1,PA,,2,,,,3-5 -CA-TP1,PA_PI_F,,2,,,,3-5 -CA-TP1,P_CUM_1_1_1,,2,,,,3-5 -CA-TP1,P_CUM_2_1_1,,2,,,,3-5 -CA-TP1,PPFD_IN,,,RAD-Other,,LI-COR Inc,3-5 -CA-TP1,PPFD_OUT,,,RAD-Other,,LI-COR Inc,3-5 -CA-TP1,RH,,,RH-Other,,CSI,3-5 -CA-TP1,SH,,,TEMP-Other,,CSAT3); and HMP45C measurements,3-5 -CA-TP1,SWC_1_1_1,,-0.05,SWC-Other,,CSI-615 moisture probe,3-5 -CA-TP1,SWC_1_2_1,,-0.1,SWC-Other,,CSI-615 moisture probe,3-5 -CA-TP1,SWC_1_3_1,,-0.2,SWC-Other,,CSI-615 moisture probe,3-5 -CA-TP1,SWC_1_4_1,,-0.5,SWC-Other,,CSI-615 moisture probe,3-5 -CA-TP1,SWC_1_5_1,,-1,SWC-Other,,CSI-615 moisture probe,3-5 -CA-TP1,SWC_2_1_1,,-0.05,SWC-Other,,CSI-615 moisture probe,3-5 -CA-TP1,SWC_2_2_1,,-0.1,SWC-Other,,CSI-615 moisture probe,3-5 -CA-TP1,SWC_2_3_1,,-0.2,SWC-Other,,CSI-615 moisture probe,3-5 -CA-TP1,SWC_2_4_1,,-0.5,SWC-Other,,CSI-615 moisture probe,3-5 -CA-TP1,SWC_2_5_1,,-1,SWC-Other,,CSI-615 moisture probe,3-5 -CA-TP1,TA,,,TEMP-Other,,CSI,3-5 -CA-TP1,TS_1_1_1,,-0.02,,,,3-5 -CA-TP1,TS_1_2_1,,-0.05,,,,3-5 -CA-TP1,TS_1_3_1,,-0.1,,,,3-5 -CA-TP1,TS_1_4_1,,-0.2,,,,3-5 -CA-TP1,TS_1_5_1,,-0.5,,,,3-5 -CA-TP1,TS_1_6_1,,-1,,,,3-5 -CA-TP1,TS_2_1_1,,-0.02,,,,3-5 -CA-TP1,TS_2_2_1,,-0.05,,,,3-5 -CA-TP1,TS_2_3_1,,-0.1,,,,3-5 -CA-TP1,TS_2_4_1,,-0.2,,,,3-5 -CA-TP1,TS_2_5_1,,-0.5,,,,3-5 -CA-TP1,TS_2_6_1,,-1,,,,3-5 -CA-TP1,TS_PI_F_1_1_1,,-0.02,,,,3-5 -CA-TP1,TS_PI_F_1_2_1,,-0.05,,,,3-5 -CA-TP1,USTAR,,,SA-Campbell CSAT-3,,,3-5 -CA-TP1,WD,,,WIND-VaneAn,,,3-5 -CA-TP1,WS,,,WIND-VaneAn,,,3-5 -CA-TP1,WS_PI_F,,,WIND-VaneAn,,,3-5 -CA-TP2,CO2_1_1_1,2003,15,GA_OP-LI-COR LI-7500,,LI-7500 IRGA),2-5 -CA-TP2,CO2_1_2_1,2003,6,GA_OP-LI-COR LI-7500,,LI820_CO2_Cnpy (ppm); CO2 conc,2-5 -CA-TP2,FC,2003,15,GA_OP-LI-COR LI-7500,,,2-5 -CA-TP2,FH2O,2003,15,GA_OP-LI-COR LI-7500,,,2-5 -CA-TP2,G_1_1_1,2003,-0,SOIL_H-Plate,,,2-5 -CA-TP2,G_1_2_1,2003,-0.03,SOIL_H-Plate,,,2-5 -CA-TP2,G_2_2_1,2003,-0.03,SOIL_H-Plate,,,2-5 -CA-TP2,GPP_PI_F,2003,15,GA_OP-LI-COR LI-7500,,,2-5 -CA-TP2,H,2003,15,GA_OP-LI-COR LI-7500,,,2-5 -CA-TP2,H_PI_F,2003,15,GA_OP-LI-COR LI-7500,,,2-5 -CA-TP2,LE,2003,15,GA_OP-LI-COR LI-7500,,,2-5 -CA-TP2,LE_PI_F,2003,15,GA_OP-LI-COR LI-7500,,,2-5 -CA-TP2,NEE_PI,2003,15,GA_OP-LI-COR LI-7500,,,2-5 -CA-TP2,NEE_PI_F,2003,15,GA_OP-LI-COR LI-7500,,,2-5 -CA-TP2,NETRAD,2003,12,RAD-Net radiometer,,,2-5 -CA-TP2,NETRAD_PI_F,2003,12,,,,2-5 -CA-TP2,P,2003,2,,,,2-5 -CA-TP2,PA,2003,2,,,,2-5 -CA-TP2,P_CUM,2003,2,,,,2-5 -CA-TP2,PPFD_IN_1_1_1,2003,12,RAD-PAR Quantum,,,2-5 -CA-TP2,PPFD_IN_1_2_1,2003,2,RAD-PAR Quantum,,,2-5 -CA-TP2,PPFD_IN_PI_F_1_1_1,2003,12,RAD-PAR Quantum,,,2-5 -CA-TP2,PPFD_OUT,2003,12,RAD-PAR Quantum,,,2-5 -CA-TP2,RECO_PI_F,2003,15,GA_OP-LI-COR LI-7500,,,2-5 -CA-TP2,RH,2003,12,RH-Capac,,,2-5 -CA-TP2,RH_PI_F,2003,12,RH-Capac,,,2-5 -CA-TP2,SC_1_1_1,2003,15,GA_OP-LI-COR LI-7500,,,2-5 -CA-TP2,SC_2_1_1,2003,15,GA_SR-LI-COR LI-800,,,2-5 -CA-TP2,SC_3_1_1,2003,7,GA_OP-LI-COR LI-7500,,,2-5 -CA-TP2,SH,2003,15,GA_OP-LI-COR LI-7500,,CSAT3); and HMP45C measurements,2-5 -CA-TP2,SWC_1_1_1,2003,-0.05,SWC-TDR,,CSI-615 moisture probe,2-5 -CA-TP2,SWC_1_2_1,2003,-0.1,SWC-TDR,,CSI-615 moisture probe,2-5 -CA-TP2,SWC_1_3_1,2003,-0.2,SWC-TDR,,CSI-615 moisture probe,2-5 -CA-TP2,SWC_1_4_1,2003,-0.5,SWC-TDR,,CSI-615 moisture probe,2-5 -CA-TP2,SWC_1_5_1,2003,-1,SWC-TDR,,CSI-615 moisture probe,2-5 -CA-TP2,SWC_2_1_1,2003,-0.05,SWC-TDR,,CSI-615 moisture probe,2-5 -CA-TP2,SWC_2_2_1,2003,-0.1,SWC-TDR,,CSI-615 moisture probe,2-5 -CA-TP2,SWC_2_3_1,2003,-0.2,SWC-TDR,,CSI-615 moisture probe,2-5 -CA-TP2,SWC_2_4_1,2003,-0.5,SWC-TDR,,CSI-615 moisture probe,2-5 -CA-TP2,SWC_2_5_1,2003,-1,SWC-TDR,,CSI-615 moisture probe,2-5 -CA-TP2,TA,2003,12,RH-Capac,,,2-5 -CA-TP2,TA_PI_F,2003,12,TEMP-ElectResis,,,2-5 -CA-TP2,TS_1_1_1,2003,-0.02,TEMP-ElectResis,,,2-5 -CA-TP2,TS_1_2_1,2003,-0.05,TEMP-ElectResis,,,2-5 -CA-TP2,TS_1_3_1,2003,-0.1,TEMP-ElectResis,,,2-5 -CA-TP2,TS_1_4_1,2003,-0.2,TEMP-ElectResis,,,2-5 -CA-TP2,TS_1_5_1,2003,-0.5,TEMP-ElectResis,,,2-5 -CA-TP2,TS_1_6_1,2003,-1,TEMP-ElectResis,,,2-5 -CA-TP2,TS_2_1_1,2003,-0.02,TEMP-ElectResis,,,2-5 -CA-TP2,TS_2_2_1,2003,-0.05,TEMP-ElectResis,,,2-5 -CA-TP2,TS_2_3_1,2003,-0.1,TEMP-ElectResis,,,2-5 -CA-TP2,TS_2_4_1,2003,-0.2,TEMP-ElectResis,,,2-5 -CA-TP2,TS_2_5_1,2003,-0.5,TEMP-ElectResis,,,2-5 -CA-TP2,TS_2_6_1,2003,-1,TEMP-ElectResis,,,2-5 -CA-TP2,TS_PI_F_1_1_1,2003,-0.02,TEMP-ElectResis,,,2-5 -CA-TP2,TS_PI_F_1_2_1,2003,-0.05,TEMP-ElectResis,,,2-5 -CA-TP2,USTAR,2003,15,SA-Campbell CSAT-3,,,2-5 -CA-TP2,VPD_PI,2003,12,RH-Capac,,,2-5 -CA-TP2,VPD_PI_F,2003,12,RH-Capac,,,2-5 -CA-TP2,WD,2003,12,WIND-VaneAn,,,2-5 -CA-TP2,WS,2003,12,WIND-VaneAn,,,2-5 -CA-TP2,WS_PI_F,2003,12,WIND-VaneAn,,,2-5 -CA-TP3,CO2_1_1_1,2003,16,GA_OP-LI-COR LI-7500,,LI-6262/Li7000 or LI-7500 IRGA,3-5 -CA-TP3,CO2_1_1_1,2008,20,GA_CP-LI-COR LI-7000,,Triangular tower replaced with 20m scaffolding tower ,3-5 -CA-TP3,CO2_1_2_1,2003,7,GA_SR-LI-COR LI-800,,LI820_CO2_Cnpy_9.2m (ppm); CO2,3-5 -CA-TP3,CO2_1_2_1,2008,9.2,GA_SR-LI-COR LI-800,,,3-5 -CA-TP3,FC,2003,16,GA_OP-LI-COR LI-7500,,,3-5 -CA-TP3,FC,2008,20,GA_CP-LI-COR LI-7000,,,3-5 -CA-TP3,FH2O,2003,20,,,,3-5 -CA-TP3,G_1_1_1,2003,-0,SOIL_H-Plate,,,3-5 -CA-TP3,G_1_2_1,2003,-0.03,SOIL_H-Plate,,,3-5 -CA-TP3,G_2_2_1,2003,-0.03,SOIL_H-Plate,,,3-5 -CA-TP3,GPP_PI_F,2003,16,GA_OP-LI-COR LI-7500,,,3-5 -CA-TP3,GPP_PI_F,2008,20,GA_CP-LI-COR LI-7000,,,3-5 -CA-TP3,H,2003,16,GA_OP-LI-COR LI-7500,,,3-5 -CA-TP3,H,2008,20,GA_CP-LI-COR LI-7000,,,3-5 -CA-TP3,H_PI_F,2003,16,GA_OP-LI-COR LI-7500,,,3-5 -CA-TP3,H_PI_F,2008,20,GA_CP-LI-COR LI-7000,,,3-5 -CA-TP3,LE,2003,16,GA_OP-LI-COR LI-7500,,,3-5 -CA-TP3,LE,2008,20,GA_CP-LI-COR LI-7000,,,3-5 -CA-TP3,LE_PI_F,2003,16,GA_OP-LI-COR LI-7500,,,3-5 -CA-TP3,LE_PI_F,2008,20,GA_CP-LI-COR LI-7000,,,3-5 -CA-TP3,NEE_PI,2003,16,GA_OP-LI-COR LI-7500,,,3-5 -CA-TP3,NEE_PI,2008,20,GA_CP-LI-COR LI-7000,,,3-5 -CA-TP3,NEE_PI_F,2003,16,GA_OP-LI-COR LI-7500,,,3-5 -CA-TP3,NEE_PI_F,2008,20,GA_CP-LI-COR LI-7000,,,3-5 -CA-TP3,NETRAD,2003,16,RAD-Net radiometer,,,3-5 -CA-TP3,NETRAD,2008,19,RAD-Net radiometer,,,3-5 -CA-TP3,P,2003,2,PREC-WeightGauge,,,3-5 -CA-TP3,PA,2003,2,PRES-ElectBar,,,3-5 -CA-TP3,PA_PI_F,2003,2,PRES-ElectBar,,,3-5 -CA-TP3,P_CUM,2003,2,,,,3-5 -CA-TP3,PPFD_IN,2003,16,RAD-PAR Quantum,,,3-5 -CA-TP3,PPFD_IN,2008,19,RAD-PAR Quantum,,,3-5 -CA-TP3,PPFD_OUT,2003,16,RAD-PAR Quantum,,,3-5 -CA-TP3,PPFD_OUT,2008,19,RAD-PAR Quantum,,,3-5 -CA-TP3,RECO_PI_F,2003,16,GA_OP-LI-COR LI-7500,,,3-5 -CA-TP3,RECO_PI_F,2008,20,GA_CP-LI-COR LI-7000,,,3-5 -CA-TP3,RH,2003,16,RH-Capac,,,3-5 -CA-TP3,RH,2008,20,RH-Capac,,,3-5 -CA-TP3,RH_PI_F,2003,20,RH-Capac,,,3-5 -CA-TP3,SC_1_1_1,2003,16,GA_OP-LI-COR LI-7500,,,3-5 -CA-TP3,SC_1_1_1,2008,20,GA_CP-LI-COR LI-7000,,,3-5 -CA-TP3,SC_2_1_1,2003,16,GA_OP-LI-COR LI-7500,,,3-5 -CA-TP3,SC_2_1_1,2008,20,GA_CP-LI-COR LI-7000,,,3-5 -CA-TP3,SC_3_1_1,2003,7,GA_SR-LI-COR LI-800,,,3-5 -CA-TP3,SC_3_1_1,2008,9.2,GA_SR-LI-COR LI-800,,,3-5 -CA-TP3,SH,2003,16,GA_OP-LI-COR LI-7500,,CSAT3); and HMP45C measurements,3-5 -CA-TP3,SH,2008,20,GA_CP-LI-COR LI-7000,,,3-5 -CA-TP3,SWC_1_1_1,2003,-0.05,SWC-TDR,,,3-5 -CA-TP3,SWC_1_2_1,2003,-0.1,SWC-TDR,,,3-5 -CA-TP3,SWC_1_3_1,2003,-0.2,SWC-TDR,,,3-5 -CA-TP3,SWC_1_4_1,2003,-0.5,SWC-TDR,,,3-5 -CA-TP3,SWC_1_5_1,2003,-1,SWC-TDR,,,3-5 -CA-TP3,SWC_2_1_1,2003,-0.05,SWC-TDR,,,3-5 -CA-TP3,SWC_2_2_1,2003,-0.1,SWC-TDR,,,3-5 -CA-TP3,SWC_2_3_1,2003,-0.2,SWC-TDR,,,3-5 -CA-TP3,SWC_2_4_1,2003,-0.5,SWC-TDR,,,3-5 -CA-TP3,SWC_2_5_1,2003,-1,SWC-TDR,,,3-5 -CA-TP3,TA,2003,16,TEMP-ElectResis,,,3-5 -CA-TP3,TA,2008,20,RH-Capac,,,3-5 -CA-TP3,TA_PI_F,2003,,TEMP-ElectResis,,,3-5 -CA-TP3,TS_1_1_1,2003,-0.02,TEMP-ElectResis,,,3-5 -CA-TP3,TS_1_2_1,2003,-0.05,TEMP-ElectResis,,,3-5 -CA-TP3,TS_1_3_1,2003,-0.1,TEMP-ElectResis,,,3-5 -CA-TP3,TS_1_4_1,2003,-0.2,TEMP-ElectResis,,,3-5 -CA-TP3,TS_1_5_1,2003,-0.5,TEMP-ElectResis,,,3-5 -CA-TP3,TS_1_6_1,2003,-1,TEMP-ElectResis,,,3-5 -CA-TP3,TS_2_1_1,2003,-0.02,TEMP-ElectResis,,,3-5 -CA-TP3,TS_2_2_1,2003,-0.05,TEMP-ElectResis,,,3-5 -CA-TP3,TS_2_3_1,2003,-0.1,TEMP-ElectResis,,,3-5 -CA-TP3,TS_2_4_1,2003,-0.2,TEMP-ElectResis,,,3-5 -CA-TP3,TS_2_5_1,2003,-0.5,TEMP-ElectResis,,,3-5 -CA-TP3,TS_2_6_1,2003,-1,TEMP-ElectResis,,,3-5 -CA-TP3,TS_PI_F_1_1_1,2003,-0.02,TEMP-ElectResis,,,3-5 -CA-TP3,TS_PI_F_1_2_1,2003,-0.05,TEMP-ElectResis,,,3-5 -CA-TP3,USTAR,2003,16,SA-Campbell CSAT-3,,,3-5 -CA-TP3,USTAR,2008,20,GA_CP-LI-COR LI-7000,,,3-5 -CA-TP3,VPD_PI,2003,16,RH-Capac,,,3-5 -CA-TP3,VPD_PI,2008,20,RH-Capac,,,3-5 -CA-TP3,VPD_PI_F,2003,,RH-Capac,,,3-5 -CA-TP3,WD,2003,16,WIND-VaneAn,,,3-5 -CA-TP3,WD,2008,20.5,WIND-VaneAn,,,3-5 -CA-TP3,WS,2003,16,WIND-VaneAn,,,3-5 -CA-TP3,WS,2008,20.5,WIND-VaneAn,,,3-5 -CA-TP3,WS_PI_F,2003,16,WIND-VaneAn,,,3-5 -CA-TP3,WS_PI_F,2008,20.5,WIND-VaneAn,,,3-5 -CA-TP4,CO2_1_1_1,2002,28,GA_CP-LI-COR LI-7000,,,4-5 -CA-TP4,CO2_1_1_1,201605,34,GA_CP-LI-COR LI-7000,,Tower height incrased by 4m in 3 May 2016 ,4-5 -CA-TP4,CO2_1_2_1,2003,14,GA_SR-LI-COR LI-820,,,4-5 -CA-TP4,CO2_1_3_1,2003,2,GA_SR-LI-COR LI-800,,,4-5 -CA-TP4,D_SNOW,2003,1.75,SNOW-Acoustic,,,4-5 -CA-TP4,FC,2002,28,GA_CP-LI-COR LI-7000,,,4-5 -CA-TP4,FH2O,2002,28,GA_CP-LI-COR LI-7000,,,4-5 -CA-TP4,G_1_1_1,2002,-0,SOIL_H-Plate,,,4-5 -CA-TP4,G_1_2_1,2002,-0.03,SOIL_H-Plate,,,4-5 -CA-TP4,G_2_2_1,2002,-0.03,SOIL_H-Plate,,,4-5 -CA-TP4,GPP_PI_F,2002,28,GA_CP-LI-COR LI-7000,,,4-5 -CA-TP4,GPP_PI_F,201605,34,GA_CP-LI-COR LI-7000,,Tower height increased by 4m,4-5 -CA-TP4,H,2002,28,GA_CP-LI-COR LI-7000,,,4-5 -CA-TP4,H,201605,34,GA_CP-LI-COR LI-7000,,,4-5 -CA-TP4,H_PI_F,2002,28,GA_CP-LI-COR LI-7000,,,4-5 -CA-TP4,LE,2002,28,GA_CP-LI-COR LI-7000,,,4-5 -CA-TP4,LE,201605,34,GA_CP-LI-COR LI-7000,,,4-5 -CA-TP4,LE_PI_F,,28,,,,4-5 -CA-TP4,LW_IN,,28,RAD-Other,,Kipp & Zonen CNR1 Net Radiometer,4-5 -CA-TP4,LW_OUT,,28,RAD-Other,,Kipp & Zonen CNR1 Net Radiometer,4-5 -CA-TP4,NEE_PI_1_1_1,,28,,,,4-5 -CA-TP4,NETRAD_1_1_1,,28,RAD-Other,,Kipp & Zonen CNR1,4-5 -CA-TP4,NETRAD_1_2_1,,2,,,,4-5 -CA-TP4,NETRAD_PI_F_1_1_1,,28,,,,4-5 -CA-TP4,P_1_1_1,,20,PREC-Other,,Young Co,4-5 -CA-TP4,P_1_2_1,,2,,,,4-5 -CA-TP4,PA,,2,PRES-Other,,Young Co,4-5 -CA-TP4,PA_PI_F,,2,,,,4-5 -CA-TP4,P_CUM_1_1_1,,20,,,,4-5 -CA-TP4,P_CUM_1_2_1,,2,,,,4-5 -CA-TP4,PPFD_IN_1_1_1,,28,RAD-Other,,LI-COR,4-5 -CA-TP4,PPFD_IN_1_2_1,,2,,,,4-5 -CA-TP4,PPFD_IN_PI_F_1_1_1,,28,,,,4-5 -CA-TP4,PPFD_OUT,,28,,,,4-5 -CA-TP4,RH_1_1_1,,28,RH-Other,,CSI,4-5 -CA-TP4,RH_1_2_1,,14,RH-Other,,CSI,4-5 -CA-TP4,RH_1_3_1,,2,RH-Other,,CSI,4-5 -CA-TP4,RH_PI_F_1_1_1,,28,,,,4-5 -CA-TP4,SH,,,TEMP-Other,,CSAT3); and HMP45C measurements,4-5 -CA-TP4,SWC_1_1_1,,-0.05,SWC-Other,,CSI-615/616 moisture probe,4-5 -CA-TP4,SWC_1_2_1,,-0.1,SWC-Other,,CSI-615/616 moisture probe,4-5 -CA-TP4,SWC_1_3_1,,-0.2,SWC-Other,,CSI-615/616 moisture probe,4-5 -CA-TP4,SWC_1_4_1,,-0.5,SWC-Other,,CSI-615/616 moisture probe,4-5 -CA-TP4,SWC_1_5_1,,-1,SWC-Other,,CSI-615/616 moisture probe,4-5 -CA-TP4,SWC_2_1_1,,-0.05,SWC-Other,,CSI-615/616 moisture probe,4-5 -CA-TP4,SWC_2_2_1,,-0.1,SWC-Other,,CSI-615/616 moisture probe,4-5 -CA-TP4,SWC_2_3_1,,-0.2,SWC-Other,,CSI-615/616 moisture probe,4-5 -CA-TP4,SWC_2_4_1,,-0.5,SWC-Other,,CSI-615/616 moisture probe,4-5 -CA-TP4,SWC_2_5_1,,-1,SWC-Other,,CSI-615/616 moisture probe,4-5 -CA-TP4,SW_IN,,28,RAD-Other,,Kipp & Zonen CNR1,4-5 -CA-TP4,SW_IN_PI_F,,28,RAD-Other,,CNR1_GlobalShortwaveRad_AbvCnpy_28m (W/m2); Gap-filled Downwelling shortwave radiation,4-5 -CA-TP4,SW_OUT,,28,RAD-Other,,Kipp & Zonen CNR1 Net Radiometer,4-5 -CA-TP4,TA_1_1_1,,28,TEMP-Other,,CSI,4-5 -CA-TP4,TA_1_2_1,,14,TEMP-Other,,CSI,4-5 -CA-TP4,TA_1_3_1,,2,TEMP-Other,,CSI,4-5 -CA-TP4,TA_PI_F_1_1_1,,28,,,,4-5 -CA-TP4,TS_1_1_1,,-0.02,,,,4-5 -CA-TP4,TS_1_2_1,,-0.05,,,,4-5 -CA-TP4,TS_1_3_1,,-0.1,,,,4-5 -CA-TP4,TS_1_4_1,,-0.2,,,,4-5 -CA-TP4,TS_1_5_1,,-0.5,,,,4-5 -CA-TP4,TS_1_6_1,,-1,,,,4-5 -CA-TP4,TS_2_1_1,,-0.02,,,,4-5 -CA-TP4,TS_2_2_1,,-0.05,,,,4-5 -CA-TP4,TS_2_3_1,,-0.1,,,,4-5 -CA-TP4,TS_2_4_1,,-0.2,,,,4-5 -CA-TP4,TS_2_5_1,,-0.5,,,,4-5 -CA-TP4,TS_2_6_1,,-1,,,,4-5 -CA-TP4,TS_PI_F_1_1_1,,-0.02,,,,4-5 -CA-TP4,TS_PI_F_1_2_1,,-0.05,,,,4-5 -CA-TP4,USTAR,,28,,,,4-5 -CA-TP4,VPD_PI,,28,,,,4-5 -CA-TP4,VPD_PI_F,,28,,,,4-5 -CA-TP4,WD,2002,28,WIND-VaneAn,,,4-5 -CA-TP4,WD,201605,34.3,WIND-VaneAn,,,4-5 -CA-TP4,WS,2002,28,WIND-VaneAn,,,4-5 -CA-TP4,WS,201605,34.3,WIND-VaneAn,,,4-5 -CA-TP4,WS_PI_F,2002,28,WIND-VaneAn,,,4-5 -CA-TP4,WTD,2009,,WTD-Press,,,4-5 -CA-TPD,CO2_1_1_1,2012,35.7,GA_CP-LI-COR LI-7200,,LI-7200 IRGA),2-5 -CA-TPD,CO2_1_2_1,2012,16,GA_SR-LI-COR LI-820,,LI820_CO2_Cnpy_16m (ppm); CO2,2-5 -CA-TPD,D_SNOW,2012,2.0,SNOW-Acoustic,,,2-5 -CA-TPD,FC,2012,35.7,GA_CP-LI-COR LI-7200,,,2-5 -CA-TPD,G_1_1_1,2012,-0,SOIL_H-Plate,,,2-5 -CA-TPD,G_1_2_1,2012,-0.03,SOIL_H-Plate,,,2-5 -CA-TPD,G_2_2_1,2012,-0.03,SOIL_H-Plate,,,2-5 -CA-TPD,G_3_2_1,2012,-0.03,SOIL_H-Plate,,,2-5 -CA-TPD,G_4_2_1,2012,-0.03,SOIL_H-Plate,,,2-5 -CA-TPD,GPP_PI_F,2012,35.7,GA_CP-LI-COR LI-7200,,,2-5 -CA-TPD,H,2012,35.7,GA_CP-LI-COR LI-7200,,,2-5 -CA-TPD,H_PI_F,2012,35.7,GA_CP-LI-COR LI-7200,,,2-5 -CA-TPD,LE,2012,35.7,GA_CP-LI-COR LI-7200,,,2-5 -CA-TPD,LE_PI_F,2012,35.7,GA_CP-LI-COR LI-7200,,,2-5 -CA-TPD,LW_IN,2012,35.5,RAD-Pyrrad-SW+LW,,Kipp & Zonen CNR4 Net Radiometer,2-5 -CA-TPD,LW_OUT,2012,35.5,RAD-Pyrrad-SW+LW,,Kipp & Zonen CNR4 Net Radiometer,2-5 -CA-TPD,NEE_PI,2012,35.7,GA_CP-LI-COR LI-7200,,,2-5 -CA-TPD,NEE_PI_F,2012,35.7,GA_CP-LI-COR LI-7200,,,2-5 -CA-TPD,NETRAD,2012,35.5,RAD-Pyrrad-SW+LW,,Kipp & Zonen CNR4,2-5 -CA-TPD,NETRAD_PI_F,2012,35.5,RAD-Pyrrad-SW+LW,,,2-5 -CA-TPD,P,2012,2,PREC-TipBucGauge,,CSI (heated and Alter Shielded) in a forest opening,2-5 -CA-TPD,PA,2012,2,PRES-ElectBar,,Young Co,2-5 -CA-TPD,PA_PI_F,2012,2,,,,2-5 -CA-TPD,P_CUM,2012,2,,,,2-5 -CA-TPD,PPFD_IN_1_1_1,2012,35.13,RAD-PAR Quantum,,Kipp and Zonen,2-5 -CA-TPD,PPFD_IN_1_2_1,2012,2,RAD-PAR Quantum,,,2-5 -CA-TPD,PPFD_IN_PI_F_1_1_1,2012,35.13,RAD-PAR Quantum,,,2-5 -CA-TPD,PPFD_OUT,2012,35.13,RAD-PAR Quantum,,Kipp and Zonen,2-5 -CA-TPD,RECO_PI_F,2012,35.7,GA_CP-LI-COR LI-7200,,,2-5 -CA-TPD,RH,2012,35.3,RH-Capac,,CSI,2-5 -CA-TPD,RH_PI_F,2012,35.3,RH-Capac,,,2-5 -CA-TPD,SC_1_1_1,2012,35.7,GA_CP-LI-COR LI-7200,,,2-5 -CA-TPD,SC_2_1_1,2012,35.7,GA_CP-LI-COR LI-7200,,,2-5 -CA-TPD,SC_3_1_1,2012,16,GA_SR-LI-COR LI-820,,,2-5 -CA-TPD,SH,2012,35.7,GA_CP-LI-COR LI-7200,,CSAT3) and HMP45C measurements,2-5 -CA-TPD,SWC_1_1_1,2012,-0.02,SWC-TDR,,,2-5 -CA-TPD,SWC_1_2_1,2012,-0.05,SWC-TDR,,,2-5 -CA-TPD,SWC_1_3_1,2012,-0.1,SWC-TDR,,,2-5 -CA-TPD,SWC_1_4_1,2012,-0.2,SWC-TDR,,,2-5 -CA-TPD,SWC_1_5_1,2012,-0.5,SWC-TDR,,,2-5 -CA-TPD,SWC_1_6_1,2012,-1,SWC-TDR,,,2-5 -CA-TPD,SWC_2_1_1,2012,-0.02,SWC-TDR,,,2-5 -CA-TPD,SWC_2_2_1,2012,-0.05,SWC-TDR,,,2-5 -CA-TPD,SWC_2_3_1,2012,-0.1,SWC-TDR,,,2-5 -CA-TPD,SWC_2_4_1,2012,-0.2,SWC-TDR,,,2-5 -CA-TPD,SWC_2_5_1,2012,-0.5,SWC-TDR,,,2-5 -CA-TPD,SWC_2_6_1,2012,-1,SWC-TDR,,,2-5 -CA-TPD,SW_IN,2012,35.5,RAD-Pyrrad-SW+LW,,Kipp & Zonen CNR4,2-5 -CA-TPD,SW_IN_PI_F,2012,35.5,RAD-Pyrrad-SW+LW,,CNR1_GlobalShortwaveRad_AbvCnpy_36m (W/m2); Gap-filled Downwelling shortwave radiation,2-5 -CA-TPD,SW_OUT,2012,35.5,RAD-Pyrrad-SW+LW,,Kipp & Zonen CNR4 Net Radiometer,2-5 -CA-TPD,TA,2012,36.6,TEMP-ElectResis,,Campbell Scientific Inc (CSI),2-5 -CA-TPD,TA_PI_F,2012,35.3,TEMP-ElectResis,,,2-5 -CA-TPD,TS_1_1_1,2012,-0.02,TEMP-ElectResis,,,2-5 -CA-TPD,TS_1_2_1,2012,-0.05,TEMP-ElectResis,,Campbell Scientific Inc (CSI),2-5 -CA-TPD,TS_1_3_1,2012,-0.1,TEMP-ElectResis,,,2-5 -CA-TPD,TS_1_4_1,2012,-0.2,TEMP-ElectResis,,,2-5 -CA-TPD,TS_1_5_1,2012,-0.5,TEMP-ElectResis,,,2-5 -CA-TPD,TS_1_6_1,2012,-1,TEMP-ElectResis,,,2-5 -CA-TPD,TS_2_1_1,2012,-0.02,TEMP-ElectResis,,,2-5 -CA-TPD,TS_2_2_1,2012,-0.05,TEMP-ElectResis,,,2-5 -CA-TPD,TS_2_3_1,2012,-0.1,TEMP-ElectResis,,,2-5 -CA-TPD,TS_2_4_1,2012,-0.2,TEMP-ElectResis,,,2-5 -CA-TPD,TS_2_5_1,2012,-0.5,TEMP-ElectResis,,,2-5 -CA-TPD,TS_2_6_1,2012,-1,TEMP-ElectResis,,,2-5 -CA-TPD,TS_PI_F_1_1_1,2012,-0.02,TEMP-ElectResis,,,2-5 -CA-TPD,TS_PI_F_1_2_1,2012,-0.05,TEMP-ElectResis,,,2-5 -CA-TPD,USTAR,2012,35.7,SA-Campbell CSAT-3,,,2-5 -CA-TPD,VPD_PI,2012,35.3,RH-Capac,,,2-5 -CA-TPD,VPD_PI_F,2012,35.3,RH-Capac,,,2-5 -CA-TPD,WD,2012,36.6,WIND-VaneAn,,,2-5 -CA-TPD,WS,2012,36.6,WIND-VaneAn,,,2-5 -CA-TPD,WS_PI_F,2012,36.6,WIND-VaneAn,,,2-5 -CA-WP1,CO2,,9,,,,1-5 -CA-WP1,FC,,9,,,,1-5 -CA-WP1,H,,9,,,,1-5 -CA-WP1,H2O,,9,,,,1-5 -CA-WP1,LE,,9,,,,1-5 -CA-WP1,LW_IN,,6,,,,1-5 -CA-WP1,LW_OUT,,6,,,,1-5 -CA-WP1,NEE_PI,,9,,,,1-5 -CA-WP1,NETRAD,,6,,,,1-5 -CA-WP1,PPFD_DIF,,9,,,,1-5 -CA-WP1,PPFD_DIR,,9,,,,1-5 -CA-WP1,PPFD_IN_1_1_1,,9,,,,1-5 -CA-WP1,PPFD_IN_1_1_2,,9,,,,1-5 -CA-WP1,PPFD_OUT,,6,,,,1-5 -CA-WP1,RH,,5,,,,1-5 -CA-WP1,SWC_1_1_1,,-0.075,,,,1-5 -CA-WP1,SWC_1_2_1,,-0.1,,,,1-5 -CA-WP1,SWC_1_3_1,,-0.125,,,,1-5 -CA-WP1,SWC_2_1_1,,-0.065,,,,1-5 -CA-WP1,SWC_2_2_1,,-0.125,,,,1-5 -CA-WP1,SWC_2_3_1,,-0.19,,,,1-5 -CA-WP1,SW_IN,,6,,,,1-5 -CA-WP1,SW_OUT,,6,,,,1-5 -CA-WP1,TA_1_1_1,,5,,,,1-5 -CA-WP1,TA_1_1_2,,5,,,,1-5 -CA-WP1,TS_1_1_1,,-0.02,,,,1-5 -CA-WP1,TS_1_2_1,,-0.05,,,,1-5 -CA-WP1,TS_1_3_1,,-0.1,,,,1-5 -CA-WP1,TS_1_4_1,,-0.2,,,,1-5 -CA-WP1,TS_1_5_1,,-0.5,,,,1-5 -CA-WP1,TS_1_6_1,,-1,,,,1-5 -CA-WP1,TS_2_1_1,,-0.02,,,,1-5 -CA-WP1,TS_2_2_1,,-0.05,,,,1-5 -CA-WP1,TS_2_3_1,,-0.1,,,,1-5 -CA-WP1,TS_2_4_1,,-0.2,,,,1-5 -CA-WP1,TS_2_5_1,,-0.5,,,,1-5 -CA-WP1,TS_2_6_1,,-1,,,,1-5 -CA-WP1,USTAR,,9,,,,1-5 -CA-WP1,WD,,9,,,,1-5 -CA-WP1,WS,,9,,,,1-5 -CA-WP2,CO2,,3,,,,1-5 -CA-WP2,FC,,3,,,,1-5 -CA-WP2,H,,3,,,,1-5 -CA-WP2,H2O,,3,,,,1-5 -CA-WP2,LE,,3,,,,1-5 -CA-WP2,NEE_PI,,3,,,,1-5 -CA-WP2,NETRAD,,3,,,,1-5 -CA-WP2,PPFD_IN,,3,,,,1-5 -CA-WP2,PPFD_OUT,,3,,,,1-5 -CA-WP2,RH,,2,,,,1-5 -CA-WP2,SW_IN,,3,,,,1-5 -CA-WP2,TA,,2,,,,1-5 -CA-WP2,TS_1_1_1,,-0.02,,,,1-5 -CA-WP2,TS_1_2_1,,-0.05,,,,1-5 -CA-WP2,TS_1_3_1,,-0.1,,,,1-5 -CA-WP2,TS_1_4_1,,-0.2,,,,1-5 -CA-WP2,TS_1_5_1,,-0.5,,,,1-5 -CA-WP2,TS_1_6_1,,-1,,,,1-5 -CA-WP2,TS_2_1_1,,-0.02,,,,1-5 -CA-WP2,TS_2_2_1,,-0.05,,,,1-5 -CA-WP2,TS_2_3_1,,-0.1,,,,1-5 -CA-WP2,TS_2_4_1,,-0.2,,,,1-5 -CA-WP2,TS_2_5_1,,-0.5,,,,1-5 -CA-WP2,TS_2_6_1,,-1,,,,1-5 -CA-WP2,USTAR,,3,,,,1-5 -CA-WP2,WD,,3,,,,1-5 -CA-WP2,WS,,3,,,,1-5 -CA-WP3,CO2,,3,,,,1-5 -CA-WP3,FC,,3,,,,1-5 -CA-WP3,H,,3,,,,1-5 -CA-WP3,H2O,,3,,,,1-5 -CA-WP3,LE,,3,,,,1-5 -CA-WP3,NEE_PI,,3,,,,1-5 -CA-WP3,NETRAD,,3,,,,1-5 -CA-WP3,PPFD_IN,,3,,,,1-5 -CA-WP3,PPFD_OUT,,3,,,,1-5 -CA-WP3,RH,,2,,,,1-5 -CA-WP3,SW_IN,,3,,,,1-5 -CA-WP3,TA,,2,,,,1-5 -CA-WP3,TS_1_1_1,,-0.02,,,,1-5 -CA-WP3,TS_1_2_1,,-0.05,,,,1-5 -CA-WP3,TS_1_3_1,,-0.1,,,,1-5 -CA-WP3,TS_1_4_1,,-0.2,,,,1-5 -CA-WP3,TS_1_5_1,,-0.5,,,,1-5 -CA-WP3,TS_1_6_1,,-1,,,,1-5 -CA-WP3,TS_2_1_1,,-0.02,,,,1-5 -CA-WP3,TS_2_2_1,,-0.05,,,,1-5 -CA-WP3,TS_2_3_1,,-0.1,,,,1-5 -CA-WP3,TS_2_4_1,,-0.2,,,,1-5 -CA-WP3,TS_2_5_1,,-0.5,,,,1-5 -CA-WP3,TS_2_6_1,,-1,,,,1-5 -CA-WP3,USTAR,,3,,,,1-5 -CA-WP3,WD,,3,,,,1-5 -CA-WP3,WS,,3,,,,1-5 -MX-Lpa,CO2_1,,13,,,,1-1 -MX-Lpa,FC,,13,,,,1-1 -MX-Lpa,G,,-0.05,,,,1-1 -MX-Lpa,H,,13,,,,1-1 -MX-Lpa,LE,,13,,,,1-1 -MX-Lpa,NETRAD,,4,,,,1-1 -MX-Lpa,PA,,1.5,,,,1-1 -MX-Lpa,PPFD_DIF,,5,,,,1-1 -MX-Lpa,PPFD_IN,,5,,,,1-1 -MX-Lpa,RH,,9,,,,1-1 -MX-Lpa,SWC_1,,-0.05,SWC-Other,,TDR probe,1-1 -MX-Lpa,SWC_2,,-0.1,SWC-Other,,TDR probe,1-1 -MX-Lpa,TA,,9,,,,1-1 -MX-Lpa,TS_1,,-0.05,,,,1-1 -MX-Lpa,TS_2,,-0.1,,,,1-1 -MX-Lpa,VPD_PI_PI,,9,,,,1-1 -MX-PMm,CO2,,8.5,GA_OP-LI-COR LI-7500RS,,,2-5 -MX-PMm,FC,,8.5,GA_OP-LI-COR LI-7500RS,SA-Gill Windmaster Pro,,2-5 -MX-PMm,G,,-0.1,SOIL_H-Plate_AUTO,,,2-5 -MX-PMm,H,,8.5,SA-Gill Windmaster Pro,,,2-5 -MX-PMm,LE,,8.5,GA_OP-LI-COR LI-7500RS,SA-Gill Windmaster Pro,,2-5 -MX-PMm,LW_IN_1_1_1,,5.7,RAD-Pyrrad-SW+LW,,,2-5 -MX-PMm,LW_OUT_1_1_1,,5.7,RAD-Pyrrad-SW+LW,,,2-5 -MX-PMm,NETRAD_1_1_1,,5.7,RAD-Pyrrad-SW+LW,,,2-5 -MX-PMm,PA,,8,PRES-ElectBar,,,2-5 -MX-PMm,PPFD_IN_1_1_1,,8.5,RAD-PAR Quantum,,,2-5 -MX-PMm,P_RAIN_PI_F_1_1_1,,6,RAIN-TipBucGauge,,,2-5 -MX-PMm,RH_1_1_1,,8.5,RH-Capac,,,2-5 -MX-PMm,SC,,8.5,GA_OP-LI-COR LI-7500RS,,,2-5 -MX-PMm,SW_IN_1_1_1,,5.7,RAD-Pyrrad-SW+LW,,,2-5 -MX-PMm,SW_OUT_1_1_1,,5.7,RAD-Pyrrad-SW+LW,,,2-5 -MX-PMm,TA_1_1_1,,8.5,TEMP-ElectResis,,,2-5 -MX-PMm,TS_3,,-0.1,TEMP-Thermis,,HydraProbe; not sure if thermistor,2-5 -MX-PMm,T_SONIC,,8.5,SA-Gill Windmaster Pro,,,2-5 -MX-PMm,USTAR,,8.5,SA-Gill Windmaster Pro,,,2-5 -MX-PMm,WD,,8.5,SA-Gill Windmaster Pro,,,2-5 -MX-PMm,WS,,8.5,SA-Gill Windmaster Pro,,,2-5 -MX-Tes,CO2,,13,GA_OP-LI-COR LI-7500,,,2-5 -MX-Tes,FC,,13,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,2-5 -MX-Tes,G_1_3_1,,-0.05,SOIL_H-Plate,,,2-5 -MX-Tes,G_2_3_1,,-0.05,SOIL_H-Plate,,,2-5 -MX-Tes,G_3_3_1,,-0.05,SOIL_H-Plate,,,2-5 -MX-Tes,G_4_3_1,,-0.05,SOIL_H-Plate,,,2-5 -MX-Tes,H,,13,SA-Campbell CSAT-3,,,2-5 -MX-Tes,H2O,,13,GA_OP-LI-COR LI-7500,,,2-5 -MX-Tes,LE,,13,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,2-5 -MX-Tes,LW_IN,,13,RAD-Pyrrad-SW+LW,,,2-5 -MX-Tes,LW_OUT,,13,RAD-Pyrrad-SW+LW,,,2-5 -MX-Tes,PA,,13,GA_OP-LI-COR LI-7500,,,2-5 -MX-Tes,P_RAIN,,13,PREC-TipBucGauge,,,2-5 -MX-Tes,RH_1_1_1,,13,RH-Capac,,,2-5 -MX-Tes,RH_1_2_1,,9,RH-Capac,,,2-5 -MX-Tes,SWC_1_3_1,,-0.10,SWC-TDR,,,2-5 -MX-Tes,SWC_2_3_1,,-0.1,SWC-TDR,,,2-5 -MX-Tes,SWC_3_3_1,,-0.1,SWC-TDR,,,2-5 -MX-Tes,SWC_4_3_1,,-0.1,SWC-TDR,,,2-5 -MX-Tes,SWC_5_3_1,,-0.1,SWC-TDR,,,2-5 -MX-Tes,SWC_6_3_1,,-0.1,SWC-TDR,,,2-5 -MX-Tes,SW_IN,,13,RAD-Pyrrad-SW+LW,,,2-5 -MX-Tes,SW_OUT,,13,RAD-Pyrrad-SW+LW,,,2-5 -MX-Tes,TA_1_1_1,,13,TEMP-ElectResis,,,2-5 -MX-Tes,TA_1_2_1,,9,TEMP-ElectResis,,,2-5 -MX-Tes,TA_2_1_1,,13,TEMP-ElectResis,,,2-5 -MX-Tes,T_SONIC,,13,SA-Campbell CSAT-3,,,2-5 -MX-Tes,USTAR,,13,SA-Campbell CSAT-3,,,2-5 -MX-Tes,VPD_PI_1_1_1,,13,RH-Capac,,,2-5 -MX-Tes,VPD_PI_1_2_1,,9,RH-Capac,,,2-5 -MX-Tes,WD_1_1_1,,13,SA-Campbell CSAT-3,,,2-5 -MX-Tes,WD_1_1_2,,13,WIND-VaneAn,,,2-5 -MX-Tes,WD_1_2_1,,9,WIND-VaneAn,,,2-5 -MX-Tes,WS_1_1_1,,13,WIND-VaneAn,,,2-5 -MX-Tes,WS_1_2_1,,9,WIND-VaneAn,,,2-5 -PE-QFR,CH4,,40,GA_OP-LI-COR LI-7700,,,2-5 -PE-QFR,CO2,,40,GA_OP-LI-COR LI-7500,,,2-5 -PE-QFR,FC,,40,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,2-5 -PE-QFR,FCH4,,40,GA_OP-LI-COR LI-7700,SA-Campbell CSAT-3,,2-5 -PE-QFR,H,,40,SA-Campbell CSAT-3,,,2-5 -PE-QFR,H2O,,40,GA_OP-LI-COR LI-7500,,,2-5 -PE-QFR,LE,,40,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,2-5 -PE-QFR,NEE_PI,,40,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,2-5 -PE-QFR,NETRAD,,40,RAD-Net radiometer,,,2-5 -PE-QFR,PA,,40,GA_OP-LI-COR LI-7500,,,2-5 -PE-QFR,PPFD_IN,,40,RAD-PAR Quantum,,,2-5 -PE-QFR,RH,,40,RH-Capac,,,2-5 -PE-QFR,SC,,40,GA_OP-LI-COR LI-7500,,,2-5 -PE-QFR,SCH4,,40,GA_OP-LI-COR LI-7700,,,2-5 -PE-QFR,SH,,40,SA-Campbell CSAT-3,,,2-5 -PE-QFR,SLE,,40,GA_OP-LI-COR LI-7500,,,2-5 -PE-QFR,SW_IN,,40,RAD-SW Pyran SecSt,,,2-5 -PE-QFR,TA,,40,TEMP-ElectResis,,,2-5 -PE-QFR,TS_1_1_1,,-0.05,TEMP-Thermis,,,2-5 -PE-QFR,T_SONIC,,40,SA-Campbell CSAT-3,,,2-5 -PE-QFR,USTAR,,40,SA-Campbell CSAT-3,,,2-5 -PE-QFR,WD,,40,SA-Campbell CSAT-3,,,2-5 -PE-QFR,WS,,40,SA-Campbell CSAT-3,,,2-5 -PR-xGU,CO2_1_1_1,,23.27,GA_CP-LI-COR LI-7200,,,3-5 -PR-xGU,CO2_1_1_2,2018,23.27,GA_SR-LI-COR LI-840,,,3-5 -PR-xGU,CO2_1_1_3,,23.27,GA_SR-Other,,,3-5 -PR-xGU,CO2_1_2_2,,12.44,GA_SR-LI-COR LI-840,,,3-5 -PR-xGU,CO2_1_2_3,,12.44,GA_SR-Other,,,3-5 -PR-xGU,CO2_1_3_2,,7.25,GA_SR-LI-COR LI-840,,,3-5 -PR-xGU,CO2_1_3_3,,7.25,GA_SR-Other,,,3-5 -PR-xGU,CO2_1_4_2,,3.89,GA_SR-LI-COR LI-840,,,3-5 -PR-xGU,CO2_1_4_3,,3.89,GA_SR-Other,,,3-5 -PR-xGU,CO2_1_5_2,,0.64,GA_SR-LI-COR LI-840,,,3-5 -PR-xGU,CO2_1_5_3,,0.64,GA_SR-Other,,,3-5 -PR-xGU,FC,,23.27,GA_CP-LI-COR LI-7200,SA-Campbell CSAT-3,,3-5 -PR-xGU,FETCH_90,,23.27,SA-Campbell CSAT-3,,,3-5 -PR-xGU,FETCH_MAX,,23.27,SA-Campbell CSAT-3,,,3-5 -PR-xGU,G_1_1_1,,-0.08,SOIL_H-Plate,,,3-5 -PR-xGU,G_2_1_1,,-0.08,SOIL_H-Plate,,,3-5 -PR-xGU,G_3_1_1,,-0.08,SOIL_H-Plate,,,3-5 -PR-xGU,H,,23.27,SA-Campbell CSAT-3,,,3-5 -PR-xGU,H2O_1_1_1,,23.27,GA_CP-LI-COR LI-7200,,,3-5 -PR-xGU,H2O_1_1_2,2018,23.27,GA_SR-LI-COR LI-840,,,3-5 -PR-xGU,H2O_1_1_3,,23.27,GA_SR-Other,,,3-5 -PR-xGU,H2O_1_2_2,,12.44,GA_SR-LI-COR LI-840,,,3-5 -PR-xGU,H2O_1_2_3,,12.44,GA_SR-Other,,,3-5 -PR-xGU,H2O_1_3_2,,7.25,GA_SR-LI-COR LI-840,,,3-5 -PR-xGU,H2O_1_3_3,,7.25,GA_SR-Other,,,3-5 -PR-xGU,H2O_1_4_2,,3.89,GA_SR-LI-COR LI-840,,,3-5 -PR-xGU,H2O_1_4_3,,3.89,GA_SR-Other,,,3-5 -PR-xGU,H2O_1_5_2,,0.64,GA_SR-LI-COR LI-840,,,3-5 -PR-xGU,H2O_1_5_3,,0.64,GA_SR-Other,,,3-5 -PR-xGU,LE,,23.27,GA_CP-LI-COR LI-7200,SA-Campbell CSAT-3,,3-5 -PR-xGU,LW_BC_IN,,0.25,RAD-Pyrrad-SW+LW,,,3-5 -PR-xGU,LW_BC_OUT,,0.25,RAD-Pyrrad-SW+LW,,,3-5 -PR-xGU,LW_IN,,22.96,RAD-Pyrrad-SW+LW,,,3-5 -PR-xGU,LW_OUT,,22.96,RAD-Pyrrad-SW+LW,,,3-5 -PR-xGU,NEE_PI,,23.27,GA_CP-LI-COR LI-7200,SA-Campbell CSAT-3,,3-5 -PR-xGU,NETRAD,,22.96,RAD-Pyrrad-SW+LW,,,3-5 -PR-xGU,P,,23.28,PREC-TipBucGauge,,,3-5 -PR-xGU,PA,,6.43,PRES-ElectBar,,,3-5 -PR-xGU,PPFD_BC_IN_1_1_1,,0,RAD-PAR Quantum,,,3-5 -PR-xGU,PPFD_BC_IN_2_1_1,,0,RAD-PAR Quantum,,,3-5 -PR-xGU,PPFD_BC_IN_3_1_1,,0,RAD-PAR Quantum,,,3-5 -PR-xGU,PPFD_IN_1_1_1,,22.88,RAD-PAR Quantum,,,3-5 -PR-xGU,PPFD_IN_1_2_1,,12.28,RAD-PAR Quantum,,,3-5 -PR-xGU,PPFD_IN_1_3_1,,6.93,RAD-PAR Quantum,,,3-5 -PR-xGU,PPFD_IN_1_4_1,,3.56,RAD-PAR Quantum,,,3-5 -PR-xGU,PPFD_IN_1_5_1,,0.21,RAD-PAR Quantum,,,3-5 -PR-xGU,PPFD_OUT,,22.88,RAD-PAR Quantum,,,3-5 -PR-xGU,RH,,22.63,RH-Capac,,,3-5 -PR-xGU,SC,,23.27,GA_SR-LI-COR LI-840,,,3-5 -PR-xGU,SH,,23.27,TEMP-ElectResis,,,3-5 -PR-xGU,SLE,,23.27,GA_SR-LI-COR LI-840,,,3-5 -PR-xGU,SWC_1_1_1,,-0.06,SWC-FDR,,,3-5 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-US-An1,TA,,2,,,,2-5 -US-An1,TS_1_1_1,,-0.04,,,,2-5 -US-An1,USTAR,,2.72,,,,2-5 -US-An1,VPD_PI,,2,,,,2-5 -US-An1,WD,,3,,,,2-5 -US-An1,WS,,3,,,,2-5 -US-An2,CO2,,2.7,,,,2-5 -US-An2,FC,,2.7,,,,2-5 -US-An2,G,,-0.08,,,,2-5 -US-An2,H,,2.7,,,,2-5 -US-An2,H2O,,2.7,,,,2-5 -US-An2,LE,,2.7,,,,2-5 -US-An2,LW_IN,,2.5,,,,2-5 -US-An2,LW_OUT,,2.5,,,,2-5 -US-An2,NETRAD,,2,,,,2-5 -US-An2,PPFD_IN,,2.5,,,,2-5 -US-An2,PPFD_OUT,,2.5,,,,2-5 -US-An2,RH,,2,,,,2-5 -US-An2,SWC_1_1_1,,-0.025,,,,2-5 -US-An2,SW_IN,,2.5,,,,2-5 -US-An2,SW_OUT,,2.5,,,,2-5 -US-An2,TA,,2,,,,2-5 -US-An2,TS_1_1_1,,-0.04,,,,2-5 -US-An2,USTAR,,2.7,,,,2-5 -US-An2,VPD_PI,,2,,,,2-5 -US-An2,WD,,3,,,,2-5 -US-An2,WS,,3,,,,2-5 -US-An3,CO2,,2.5,,,,2-5 -US-An3,FC,,2.5,,,,2-5 -US-An3,G,,-0.08,,,,2-5 -US-An3,H,,2.5,,,,2-5 -US-An3,H2O,,2.5,,,,2-5 -US-An3,LE,,2.5,,,,2-5 -US-An3,LW_IN,,2.5,,,,2-5 -US-An3,LW_OUT,,2.5,,,,2-5 -US-An3,NETRAD,,2,,,,2-5 -US-An3,PPFD_IN,,2.5,,,,2-5 -US-An3,PPFD_OUT,,2.5,,,,2-5 -US-An3,RH,,2,,,,2-5 -US-An3,SWC_1_1_1,,-0.025,,,,2-5 -US-An3,SW_IN,,2.5,,,,2-5 -US-An3,SW_OUT,,2.5,,,,2-5 -US-An3,TA,,2,,,,2-5 -US-An3,TS_1_1_1,,-0.04,,,,2-5 -US-An3,USTAR,,2.5,,,,2-5 -US-An3,VPD_PI,,2,,,,2-5 -US-An3,WD,,3,,,,2-5 -US-An3,WS,,3,,,,2-5 -US-AR1,CO2,,2.55,,,,3-5 -US-AR1,FC,,2.84,,,,3-5 -US-AR1,G,,-0.06,,,,3-5 -US-AR1,H,,2.84,,,,3-5 -US-AR1,H2O,,2.55,,,,3-5 -US-AR1,LE,,2.84,,,,3-5 -US-AR1,LW_IN,,2.16,,,,3-5 -US-AR1,LW_OUT,,2.16,,,,3-5 -US-AR1,NETRAD,,2.16,,,,3-5 -US-AR1,P,,1.5,,,,3-5 -US-AR1,PA_1_1_1,,2,,,,3-5 -US-AR1,PPFD_IN,,2.16,,,,3-5 -US-AR1,PPFD_OUT,,2.16,,,,3-5 -US-AR1,RH_1_1_1,,3.13,,,,3-5 -US-AR1,SWC_1_1_1,,-0.1,,,,3-5 -US-AR1,SWC_1_2_1,,-0.3,,,,3-5 -US-AR1,SW_IN,,2.16,,,,3-5 -US-AR1,SW_OUT,,2.16,,,,3-5 -US-AR1,TA_1_1_1,,3.13,,,,3-5 -US-AR1,TS_1_1_1,,-0.05,,,,3-5 -US-AR1,TS_1_2_1,,-0.15,,,,3-5 -US-AR1,USTAR,,2.84,,,,3-5 -US-AR1,VPD_PI_1_1_1,,3.13,,,,3-5 -US-AR1,WD,,2.84,,,,3-5 -US-AR1,WS,,2.84,,,,3-5 -US-AR2,CO2,,2.75,,,,3-5 -US-AR2,FC,,2.95,,,,3-5 -US-AR2,G,,-0.06,,,,3-5 -US-AR2,H,,2.95,,,,3-5 -US-AR2,H2O,,2.75,,,,3-5 -US-AR2,LE,,2.95,,,,3-5 -US-AR2,LW_IN,,2.25,,,,3-5 -US-AR2,LW_OUT,,2.25,,,,3-5 -US-AR2,NETRAD,,2.25,,,,3-5 -US-AR2,P,,1.5,,,,3-5 -US-AR2,PA_1_1_1,,2,,,,3-5 -US-AR2,PPFD_IN,,2.25,,,,3-5 -US-AR2,PPFD_OUT,,2.25,,,,3-5 -US-AR2,RH_1_1_1,,3.25,,,,3-5 -US-AR2,SWC_1_1_1,,-0.1,,,,3-5 -US-AR2,SWC_1_2_1,,-0.3,,,,3-5 -US-AR2,SW_IN,,2.25,,,,3-5 -US-AR2,SW_OUT,,2.25,,,,3-5 -US-AR2,TA_1_1_1,,3.25,,,,3-5 -US-AR2,TS_1_1_1,,-0.05,,,,3-5 -US-AR2,TS_1_2_1,,-0.15,,,,3-5 -US-AR2,USTAR,,2.95,,,,3-5 -US-AR2,VPD_PI_1_1_1,,3.25,,,,3-5 -US-AR2,WD,,2.95,,,,3-5 -US-AR2,WS,,2.95,,,,3-5 -US-ARb,CO2,,3.45,,,,3-5 -US-ARb,FC,,3.45,,,,3-5 -US-ARb,G,,-.06,,,,3-5 -US-ARb,H,,3.45,,,,3-5 -US-ARb,LE,,3.45,,,,3-5 -US-ARb,LW_IN,,2,,,,3-5 -US-ARb,LW_OUT,,2,,,,3-5 -US-ARb,NETRAD,,2,RAD-Other,,NR-lite,3-5 -US-ARb,PPFD_IN,,2,,,,3-5 -US-ARb,RH_1_1_1,,2.82,,,,3-5 -US-ARb,SW_IN_1_1_1,,2,RAD-Other,,li-200 sensor,3-5 -US-ARb,SW_OUT,,2,,,,3-5 -US-ARb,TA_1_1_1,,2.82,,,,3-5 -US-ARc,CO2,,4.05,,,,3-5 -US-ARc,FC,,4.05,,,,3-5 -US-ARc,G,,-.06,,,,3-5 -US-ARc,H,,4.05,,,,3-5 -US-ARc,LE,,4.05,,,,3-5 -US-ARc,LW_IN,,2.28,,,,3-5 -US-ARc,LW_OUT,,2.28,,,,3-5 -US-ARc,NETRAD,,2.28,RAD-Other,,NR-lite,3-5 -US-ARc,PPFD_IN,,2.28,,,,3-5 -US-ARc,RH_1_1_1,,3.24,,,,3-5 -US-ARc,SW_IN_1_1_1,,2.28,RAD-Other,,li-200 sensor,3-5 -US-ARc,SW_OUT,,2.28,,,,3-5 -US-ARc,TA_1_1_1,,3.24,,,,3-5 -US-ARM,CO2_1_1_1,20150720,4.55,GA_OP-LI-COR LI-7500A,,,11-5 -US-ARM,CO2_1_1_1,,4.65,GA_OP-LI-COR LI-7500,,,11-5 -US-ARM,CO2_1_2_1,,25,GA_OP-LI-COR LI-7500,,ended in 20150301,11-5 -US-ARM,CO2_1_3_1,,60,GA_OP-LI-COR LI-7500,,ended in 20150301,11-5 -US-ARM,FC_1_1_1,20150720,4.55,SA-Gill R3-50,GA_OP-LI-COR LI-7500A,,11-5 -US-ARM,FC_1_1_1,,4.65,GA_OP-LI-COR LI-7500,SA-Gill Windmaster Pro,,11-5 -US-ARM,FC_1_2_1,,25,GA_OP-LI-COR LI-7500,SA-Gill Windmaster Pro,ended in 20150301,11-5 -US-ARM,FC_1_3_1,,60,GA_OP-LI-COR LI-7500,SA-Gill Windmaster Pro,ended in 20150301,11-5 -US-ARM,FC_SSITC_TEST_1_1_1,20150720,4.55,,,,11-5 -US-ARM,FC_SSITC_TEST_1_1_1,,4.65,,,,11-5 -US-ARM,FC_SSITC_TEST_1_2_1,,25,,,ended in 20150301,11-5 -US-ARM,FC_SSITC_TEST_1_3_1,,60,,,ended in 20150301,11-5 -US-ARM,FETCH_70_1_1_1,20150720,4.55,,,,11-5 -US-ARM,FETCH_70_1_1_1,,4.65,,,,11-5 -US-ARM,FETCH_70_1_2_1,,25,,,ended in 20150301,11-5 -US-ARM,FETCH_70_1_3_1,,60,,,ended in 20150301,11-5 -US-ARM,FETCH_80_1_1_1,20150720,4.55,,,,11-5 -US-ARM,FETCH_80_1_1_1,,4.65,,,,11-5 -US-ARM,FETCH_80_1_2_1,,25,,,ended in 20150301,11-5 -US-ARM,FETCH_80_1_3_1,,60,,,ended in 20150301,11-5 -US-ARM,FETCH_90_1_1_1,20150720,4.55,,,,11-5 -US-ARM,FETCH_90_1_1_1,,4.65,,,,11-5 -US-ARM,FETCH_90_1_2_1,,25,,,ended in 20150301,11-5 -US-ARM,FETCH_90_1_3_1,,60,,,ended in 20150301,11-5 -US-ARM,FETCH_MAX_1_1_1,20150720,4.55,,,,11-5 -US-ARM,FETCH_MAX_1_1_1,,4.65,,,,11-5 -US-ARM,FETCH_MAX_1_2_1,,25,,,ended in 20150301,11-5 -US-ARM,FETCH_MAX_1_3_1,,60,,,ended in 20150301,11-5 -US-ARM,G_1_1_1,20160407,-0.075,SOIL_H-Plate_AUTO,,,11-5 -US-ARM,G_1_1_1,,-0.05,SOIL_H-Plate,,,11-5 -US-ARM,G_2_1_1,20160407,-0.075,SOIL_H-Plate_AUTO,,,11-5 -US-ARM,G_2_1_1,,-0.05,SOIL_H-Plate,,,11-5 -US-ARM,G_3_1_1,20160407,-0.075,SOIL_H-Plate_AUTO,,,11-5 -US-ARM,G_3_1_1,,-0.05,SOIL_H-Plate,,,11-5 -US-ARM,G_4_1_1,20160407,-0.075,SOIL_H-Plate_AUTO,,,11-5 -US-ARM,G_4_1_1,,-0.05,SOIL_H-Plate,,,11-5 -US-ARM,H_1_1_1,20150720,4.55,SA-Gill R3-50,,,11-5 -US-ARM,H_1_1_1,,4.65,SA-Gill Windmaster Pro,,,11-5 -US-ARM,H_1_2_1,20150720,25,SA-Gill R3-50,,,11-5 -US-ARM,H_1_2_1,,25,SA-Gill Windmaster Pro,,,11-5 -US-ARM,H_1_3_1,20150720,60,SA-Gill R3-50,,,11-5 -US-ARM,H_1_3_1,,60,SA-Gill Windmaster Pro,,,11-5 -US-ARM,H2O_1_1_1,20150720,4.55,GA_OP-LI-COR LI-7500A,,,11-5 -US-ARM,H2O_1_1_1,,4.65,GA_OP-LI-COR LI-7500,,,11-5 -US-ARM,H2O_1_2_1,,25,GA_OP-LI-COR LI-7500,,ended in 20150301,11-5 -US-ARM,H2O_1_3_1,,60,GA_OP-LI-COR LI-7500,,ended in 20150301,11-5 -US-ARM,LE_1_1_1,20150720,4.55,SA-Gill R3-50,GA_OP-LI-COR LI-7500A,,11-5 -US-ARM,LE_1_1_1,,4.65,GA_OP-LI-COR LI-7500,SA-Gill Windmaster Pro,,11-5 -US-ARM,LE_1_2_1,,25,GA_OP-LI-COR LI-7500,SA-Gill Windmaster Pro,ended in 20150301,11-5 -US-ARM,LE_1_3_1,,60,GA_OP-LI-COR LI-7500,SA-Gill Windmaster Pro,ended in 20150301,11-5 -US-ARM,LE_SSITC_TEST_1_1_1,20150720,4.55,,,,11-5 -US-ARM,LE_SSITC_TEST_1_1_1,,4.65,,,,11-5 -US-ARM,LE_SSITC_TEST_1_2_1,,25,,,ended in 20150301,11-5 -US-ARM,LE_SSITC_TEST_1_3_1,,60,,,ended in 20150301,11-5 -US-ARM,LW_IN_1_1_1,,2,RAD-Pyrrad-SW+LW,,,11-5 -US-ARM,LW_OUT_1_1_1,,2,RAD-Pyrrad-SW+LW,,,11-5 -US-ARM,MO_LENGTH_1_1_1,20150720,4.55,SA-Gill R3-50,,,11-5 -US-ARM,MO_LENGTH_1_1_1,,4.65,SA-Gill Windmaster Pro,,,11-5 -US-ARM,MO_LENGTH_1_2_1,20150720,25,SA-Gill R3-50,,,11-5 -US-ARM,MO_LENGTH_1_2_1,,25,SA-Gill Windmaster Pro,,,11-5 -US-ARM,MO_LENGTH_1_3_1,20150720,60,SA-Gill R3-50,,,11-5 -US-ARM,MO_LENGTH_1_3_1,,60,SA-Gill Windmaster Pro,,,11-5 -US-ARM,NETRAD_1_1_1,,2,RAD-Pyrrad-SW+LW,,sum of 4 component radiation,11-5 -US-ARM,NETRAD_1_1_2,,2,RAD-Net radiometer,,NR-LITE,11-5 -US-ARM,P_1_1_1,,1.5,RAIN-TipBucGauge,,,11-5 -US-ARM,PA_1_1_1,,1,PRES-ElectBar,,,11-5 -US-ARM,PA_1_2_1,,25,PRES-ElectBar,,ended in 20150301,11-5 -US-ARM,PA_1_3_1,,60,PRES-ElectBar,,ended in 20150301,11-5 -US-ARM,PPFD_IN_1_1_1,,2,RAD-PAR Quantum,,,11-5 -US-ARM,PPFD_OUT_1_1_1,,2,RAD-PAR Quantum,,,11-5 -US-ARM,RH_1_1_1,20150720,4.3,RH-Capac,,,11-5 -US-ARM,RH_1_1_1,,3.94,RH-Capac,,,11-5 -US-ARM,RH_1_2_1,,25,RH-Capac,,ended in 20150301,11-5 -US-ARM,RH_1_3_1,,60,RH-Capac,,ended in 20150301,11-5 -US-ARM,RH_2_1_1,,2.15,RH-Capac,,,11-5 -US-ARM,SWC_1_1_1,,-0.1,SWC-TDR,,ended in 20150301,11-5 -US-ARM,SWC_1_1_2,,-0.1,SWC-TDR,,ended in 20150301,11-5 -US-ARM,SWC_1_1_3,,-0.1,SWC-TDR,,ended in 20150301,11-5 -US-ARM,SWC_1_1_4,,-0.1,SWC-TDR,,ended in 20150301,11-5 -US-ARM,SWC_1_2_1,,-0.2,SWC-TDR,,ended in 20150301,11-5 -US-ARM,SWC_1_2_2,,-0.2,SWC-TDR,,ended in 20150301,11-5 -US-ARM,SWC_1_2_3,,-0.2,SWC-TDR,,ended in 20150301,11-5 -US-ARM,SWC_1_2_4,,-0.2,SWC-TDR,,ended in 20150301,11-5 -US-ARM,SWC_2_1_1,,-0.1,SWC-TDR,,,11-5 -US-ARM,SWC_2_2_1,,-0.2,SWC-TDR,,,11-5 -US-ARM,SWC_2_3_1,,-0.3,SWC-TDR,,,11-5 -US-ARM,SWC_2_4_1,,-0.5,SWC-TDR,,,11-5 -US-ARM,SWC_2_5_1,,-0.7,SWC-TDR,,,11-5 -US-ARM,SWC_2_6_1,,-1.0,SWC-TDR,,,11-5 -US-ARM,SWC_3_1_1,,-0.125,SWC-TDR,,,11-5 -US-ARM,SWC_3_1_2,,-0.125,SWC-TDR,,,11-5 -US-ARM,SWC_3_2_1,,-0.25,SWC-TDR,,,11-5 -US-ARM,SWC_3_2_2,,-0.25,SWC-TDR,,,11-5 -US-ARM,SWC_3_3_1,,-0.38,SWC-TDR,,,11-5 -US-ARM,SWC_3_3_2,,-0.38,SWC-TDR,,,11-5 -US-ARM,SW_DIF_1_1_1,,2.55,RAD-SW Pyran Class2,,,11-5 -US-ARM,SW_DIR_1_1_1,,2.55,RAD-SW Pyran Class2,,,11-5 -US-ARM,SW_IN_1_1_1,,2,RAD-Pyrrad-SW+LW,,,11-5 -US-ARM,SW_IN_1_1_2,,2,RAD-SW Pyran Class2,,ended in 20041222,11-5 -US-ARM,SW_OUT_1_1_1,,2,RAD-Pyrrad-SW+LW,,,11-5 -US-ARM,TA_1_1_1,20150720,4.3,TEMP-Thermis,,,11-5 -US-ARM,TA_1_1_1,,3.94,TEMP-Thermis,,,11-5 -US-ARM,TA_1_2_1,,25,TEMP-Thermis,,,11-5 -US-ARM,TA_1_3_1,,60,TEMP-Thermis,,,11-5 -US-ARM,TA_2_1_1,,2.15,TEMP-Thermis,,,11-5 -US-ARM,TAU_1_1_1,20150720,4.55,SA-Gill R3-50,,,11-5 -US-ARM,TAU_1_1_1,,4.65,SA-Gill Windmaster Pro,,,11-5 -US-ARM,TAU_1_2_1,20150720,25,SA-Gill R3-50,,,11-5 -US-ARM,TAU_1_2_1,,25,SA-Gill Windmaster Pro,,,11-5 -US-ARM,TAU_1_3_1,20150720,60,SA-Gill R3-50,,,11-5 -US-ARM,TAU_1_3_1,,60,SA-Gill Windmaster Pro,,,11-5 -US-ARM,TAU_SSITC_TEST_1_1_1,20150720,4.55,,,,11-5 -US-ARM,TAU_SSITC_TEST_1_1_1,,4.65,,,,11-5 -US-ARM,TAU_SSITC_TEST_1_2_1,,25,,,,11-5 -US-ARM,TAU_SSITC_TEST_1_3_1,,60,,,,11-5 -US-ARM,T_CANOPY_1_1_1,,0.94,TEMP-Other,,,11-5 -US-ARM,TS_1_1_1,,-0.05,TEMP-TCouple,,ended in 20150301,11-5 -US-ARM,TS_1_1_2,,-0.05,TEMP-TCouple,,ended in 20150301,11-5 -US-ARM,TS_1_2_1,,-0.15,TEMP-TCouple,,ended in 20150301,11-5 -US-ARM,TS_1_2_2,,-0.15,TEMP-TCouple,,ended in 20150301,11-5 -US-ARM,TS_1_3_1,,-0.25,TEMP-TCouple,,ended in 20150301,11-5 -US-ARM,TS_1_3_2,,-0.25,TEMP-TCouple,,ended in 20150301,11-5 -US-ARM,TS_2_1_1,,-0.1,TEMP-TCouple,,,11-5 -US-ARM,TS_2_2_1,,-0.2,TEMP-TCouple,,,11-5 -US-ARM,TS_2_3_1,,-0.3,TEMP-TCouple,,,11-5 -US-ARM,TS_2_4_1,,-0.5,TEMP-TCouple,,,11-5 -US-ARM,TS_2_5_1,,-0.7,TEMP-TCouple,,,11-5 -US-ARM,TS_2_6_1,,-1.0,TEMP-TCouple,,,11-5 -US-ARM,TS_3_1_1,,-0.125,TEMP-TCouple,,,11-5 -US-ARM,TS_3_1_2,,-0.125,TEMP-TCouple,,,11-5 -US-ARM,TS_3_2_1,,-0.25,TEMP-TCouple,,,11-5 -US-ARM,TS_3_2_2,,-0.25,TEMP-TCouple,,,11-5 -US-ARM,TS_3_3_1,,-0.38,TEMP-TCouple,,,11-5 -US-ARM,TS_3_3_2,,-0.38,TEMP-TCouple,,,11-5 -US-ARM,T_SONIC_1_1_1,20150720,4.55,SA-Gill R3-50,,,11-5 -US-ARM,T_SONIC_1_1_1,,4.65,SA-Gill Windmaster Pro,,,11-5 -US-ARM,T_SONIC_1_2_1,20150720,25,SA-Gill R3-50,,,11-5 -US-ARM,T_SONIC_1_2_1,,25,SA-Gill Windmaster Pro,,,11-5 -US-ARM,T_SONIC_1_3_1,20150720,60,SA-Gill R3-50,,,11-5 -US-ARM,T_SONIC_1_3_1,,60,SA-Gill Windmaster Pro,,,11-5 -US-ARM,T_SONIC_SIGMA_1_1_1,20150720,4.55,SA-Gill R3-50,,,11-5 -US-ARM,T_SONIC_SIGMA_1_1_1,,4.65,SA-Gill Windmaster Pro,,,11-5 -US-ARM,T_SONIC_SIGMA_1_2_1,20150720,25,SA-Gill R3-50,,,11-5 -US-ARM,T_SONIC_SIGMA_1_2_1,,25,SA-Gill Windmaster Pro,,,11-5 -US-ARM,T_SONIC_SIGMA_1_3_1,20150720,60,SA-Gill R3-50,,,11-5 -US-ARM,T_SONIC_SIGMA_1_3_1,,60,SA-Gill Windmaster Pro,,,11-5 -US-ARM,U_SIGMA_1_1_1,20150720,4.55,SA-Gill R3-50,,,11-5 -US-ARM,U_SIGMA_1_1_1,,4.65,SA-Gill Windmaster Pro,,,11-5 -US-ARM,U_SIGMA_1_2_1,20150720,25,SA-Gill R3-50,,,11-5 -US-ARM,U_SIGMA_1_2_1,,25,SA-Gill Windmaster Pro,,,11-5 -US-ARM,U_SIGMA_1_3_1,20150720,60,SA-Gill R3-50,,,11-5 -US-ARM,U_SIGMA_1_3_1,,60,SA-Gill Windmaster Pro,,,11-5 -US-ARM,USTAR_1_1_1,20150720,4.55,SA-Gill R3-50,,,11-5 -US-ARM,USTAR_1_1_1,,4.65,SA-Gill Windmaster Pro,,,11-5 -US-ARM,USTAR_1_2_1,20150720,25,SA-Gill R3-50,,,11-5 -US-ARM,USTAR_1_2_1,,25,SA-Gill Windmaster Pro,,,11-5 -US-ARM,USTAR_1_3_1,20150720,60,SA-Gill R3-50,,,11-5 -US-ARM,USTAR_1_3_1,,60,SA-Gill Windmaster Pro,,,11-5 -US-ARM,V_SIGMA_1_1_1,20150720,4.55,SA-Gill R3-50,,,11-5 -US-ARM,V_SIGMA_1_1_1,,4.65,SA-Gill Windmaster Pro,,,11-5 -US-ARM,V_SIGMA_1_2_1,20150720,25,SA-Gill R3-50,,,11-5 -US-ARM,V_SIGMA_1_2_1,,25,SA-Gill Windmaster Pro,,,11-5 -US-ARM,V_SIGMA_1_3_1,20150720,60,SA-Gill R3-50,,,11-5 -US-ARM,V_SIGMA_1_3_1,,60,SA-Gill Windmaster Pro,,,11-5 -US-ARM,WD_1_1_1,20150720,4.55,SA-Gill R3-50,,,11-5 -US-ARM,WD_1_1_1,,4.65,SA-Gill Windmaster Pro,,,11-5 -US-ARM,WD_1_2_1,20150720,25,SA-Gill R3-50,,,11-5 -US-ARM,WD_1_2_1,,25,SA-Gill Windmaster Pro,,,11-5 -US-ARM,WD_1_3_1,20150720,60,SA-Gill R3-50,,,11-5 -US-ARM,WD_1_3_1,,60,SA-Gill Windmaster Pro,,,11-5 -US-ARM,WS_1_1_1,20150720,4.55,SA-Gill R3-50,,,11-5 -US-ARM,WS_1_1_1,,4.65,SA-Gill Windmaster Pro,,,11-5 -US-ARM,WS_1_2_1,20150720,25,SA-Gill R3-50,,,11-5 -US-ARM,WS_1_2_1,,25,SA-Gill Windmaster Pro,,,11-5 -US-ARM,WS_1_3_1,20150720,60,SA-Gill R3-50,,,11-5 -US-ARM,WS_1_3_1,,60,SA-Gill Windmaster Pro,,,11-5 -US-ARM,W_SIGMA_1_1_1,20150720,4.55,SA-Gill R3-50,,,11-5 -US-ARM,W_SIGMA_1_1_1,,4.65,SA-Gill Windmaster Pro,,,11-5 -US-ARM,W_SIGMA_1_2_1,20150720,25,SA-Gill R3-50,,,11-5 -US-ARM,W_SIGMA_1_2_1,,25,SA-Gill Windmaster Pro,,,11-5 -US-ARM,W_SIGMA_1_3_1,20150720,60,SA-Gill R3-50,,,11-5 -US-ARM,W_SIGMA_1_3_1,,60,SA-Gill Windmaster Pro,,,11-5 -US-ARM,WS_MAX_1_1_1,20150720,4.55,SA-Gill R3-50,,,11-5 -US-ARM,WS_MAX_1_1_1,,4.65,SA-Gill Windmaster Pro,,,11-5 -US-ARM,WS_MAX_1_2_1,20150720,25,SA-Gill R3-50,,,11-5 -US-ARM,WS_MAX_1_2_1,,25,SA-Gill Windmaster Pro,,,11-5 -US-ARM,WS_MAX_1_3_1,20150720,60,SA-Gill R3-50,,,11-5 -US-ARM,WS_MAX_1_3_1,,60,SA-Gill Windmaster Pro,,,11-5 -US-ASH,CO2,,0,,,,1-5 -US-ASH,FC,,0,,,,1-5 -US-ASH,FC_SSITC_TEST,,0,,,,1-5 -US-ASH,FETCH_70,,0,,,,1-5 -US-ASH,FETCH_80,,0,,,,1-5 -US-ASH,FETCH_90,,0,,,,1-5 -US-ASH,FETCH_FILTER,,0,,,,1-5 -US-ASH,FETCH_MAX,,0,,,,1-5 -US-ASH,G,,0,,,,1-5 -US-ASH,H,,0,,,,1-5 -US-ASH,H2O,,0,,,,1-5 -US-ASH,H_SSITC_TEST,,0,,,,1-5 -US-ASH,LE,,0,,,,1-5 -US-ASH,LE_SSITC_TEST,,0,,,,1-5 -US-ASH,NETRAD,,0,,,,1-5 -US-ASH,PA,,0,,,,1-5 -US-ASH,RH,,0,,,,1-5 -US-ASH,SW_IN,,0,,,,1-5 -US-ASH,TA,,0,,,,1-5 -US-ASH,TS,,0,,,,1-5 -US-ASH,T_SONIC,,0,,,,1-5 -US-ASH,T_SONIC_SIGMA,,0,,,,1-5 -US-ASH,USTAR,,0,,,,1-5 -US-ASH,VPD_PI,,0,,,,1-5 -US-ASH,WD,,0,,,,1-5 -US-ASH,WS,,0,,,,1-5 -US-ASL,CO2,,0,,,,1-5 -US-ASL,FC,,0,,,,1-5 -US-ASL,FC_SSITC_TEST,,0,,,,1-5 -US-ASL,FETCH_70,,0,,,,1-5 -US-ASL,FETCH_80,,0,,,,1-5 -US-ASL,FETCH_90,,0,,,,1-5 -US-ASL,FETCH_FILTER,,0,,,,1-5 -US-ASL,FETCH_MAX,,0,,,,1-5 -US-ASL,G,,0,,,,1-5 -US-ASL,H,,0,,,,1-5 -US-ASL,H2O,,0,,,,1-5 -US-ASL,H_SSITC_TEST,,0,,,,1-5 -US-ASL,LE,,0,,,,1-5 -US-ASL,LE_SSITC_TEST,,0,,,,1-5 -US-ASL,NETRAD,,0,,,,1-5 -US-ASL,PA,,0,,,,1-5 -US-ASL,RH,,0,,,,1-5 -US-ASL,SW_IN,,0,,,,1-5 -US-ASL,TA,,0,,,,1-5 -US-ASL,TS,,0,,,,1-5 -US-ASL,T_SONIC,,0,,,,1-5 -US-ASL,T_SONIC_SIGMA,,0,,,,1-5 -US-ASL,USTAR,,0,,,,1-5 -US-ASL,VPD_PI,,0,,,,1-5 -US-ASL,WD,,0,,,,1-5 -US-ASL,WS,,0,,,,1-5 -US-ASM,CO2,,0,,,,1-5 -US-ASM,FC,,0,,,,1-5 -US-ASM,FC_SSITC_TEST,,0,,,,1-5 -US-ASM,FETCH_70,,0,,,,1-5 -US-ASM,FETCH_80,,0,,,,1-5 -US-ASM,FETCH_90,,0,,,,1-5 -US-ASM,FETCH_FILTER,,0,,,,1-5 -US-ASM,FETCH_MAX,,0,,,,1-5 -US-ASM,G,,0,,,,1-5 -US-ASM,H,,0,,,,1-5 -US-ASM,H2O,,0,,,,1-5 -US-ASM,H_SSITC_TEST,,0,,,,1-5 -US-ASM,LE,,0,,,,1-5 -US-ASM,LE_SSITC_TEST,,0,,,,1-5 -US-ASM,NETRAD,,0,,,,1-5 -US-ASM,PA,,0,,,,1-5 -US-ASM,RH,,0,,,,1-5 -US-ASM,SW_IN,,0,,,,1-5 -US-ASM,TA,,0,,,,1-5 -US-ASM,TS,,0,,,,1-5 -US-ASM,T_SONIC,,0,,,,1-5 -US-ASM,T_SONIC_SIGMA,,0,,,,1-5 -US-ASM,USTAR,,0,,,,1-5 -US-ASM,VPD_PI,,0,,,,1-5 -US-ASM,WD,,0,,,,1-5 -US-ASM,WS,,0,,,,1-5 -US-Atq,G,,-0.065,,,5-8 cm deep,1-1 -US-Aud,FC,,4,,,,4-1 -US-Aud,H,,4,,,,4-1 -US-Aud,LE,,4,,,,4-1 -US-Aud,SWC_1,,-0.1,,,,4-1 -US-Aud,SWC_2,,-0.2,,,,4-1 -US-Aud,TS_1,,-0.02,,,,4-1 -US-Aud,TS_2,,-0.04,,,,4-1 -US-Aud,USTAR,,4,,,,4-1 -US-Bar,CO2_1_1_1,20140423,24.5,GA_CP-LI-COR LI-7200,,Height not changed but instrument changed from LI-6262 to LI-7200,5-5 -US-Bar,CO2_1_1_1,,24.5,GA_CP-LI-COR LI-6262,,,5-5 -US-Bar,FC_1_1_1,,24.5,,,,5-5 -US-Bar,H,,24.5,SA-ATI SATI K Style,,,5-5 -US-Bar,LE,,24.5,,,,5-5 -US-Bar,NETRAD_1_1_1,20080709,25,RAD-Net radiometer,,Net Radiometer changed from REBS Q* to Kipp & Zonen CNR-2 on 9 July 2008,5-5 -US-Bar,NETRAD_1_1_1,,25,RAD-Net radiometer,,,5-5 -US-Bar,NETRAD_LW_1_1_1,20080709,25.0,RAD-Net radiometer,,Kipp & Zonen CNR-2,5-5 -US-Bar,NETRAD_SW_1_1_1,20080709,25.0,RAD-Net radiometer,,Kipp & Zonen CNR-2,5-5 -US-Bar,P_1_1_1,,26.5,PREC-TipBucGauge,,Texas Tech tipping bucket rain gauge,5-5 -US-Bar,PPFD_BC_IN_1_1_1,,1.5,RAD-PAR Quantum,,LI-190; median of n=6 sensors,5-5 -US-Bar,PPFD_DIF_1_1_1,,25.0,,,Delta T Sunshine Sensor BF3,5-5 -US-Bar,PPFD_DIR_1_1_1,,25.0,,,DeltaT Sunshine Sensor BF3,5-5 -US-Bar,PPFD_IN_1_1_1,,25.0,,,Sum of PPFD_DIR_1_1_1 + PPFD_DIF_1_1_1; Delta T Sunshine Sensor BF3,5-5 -US-Bar,PPFD_IN_1_1_2,,25,RAD-PAR Quantum,,Li-190 quantum sensor; top of canopy; backup,5-5 -US-Bar,PPFD_IN_PI_F_1_1_1,,25.0,,,PI Filled ,5-5 -US-Bar,PPFD_OUT_1_1_1,,23.8,RAD-PAR Quantum,,LiCor quantum sensor; top of t,5-5 -US-Bar,RH_1_1_1,,22.3,RH-Capac,,HMP35C with calibration adjusted to match HMP45C installed summer 2017,5-5 -US-Bar,RH_PI_F_1_1_1,,22.3,RH-Capac,,PI-Filled RH,5-5 -US-Bar,SWC_1_1_1,2004,-0.1,SWC-TDR,,CS615; one of 4 sensors in different microtopographic positions,5-5 -US-Bar,SWC_2_1_1,,-0.1,SWC-TDR,,; one of 4 sensors in different microtopographic positions,5-5 -US-Bar,SWC_3_1_1,,-0.1,SWC-TDR,,; one of 4 sensors in different microtopographic positions,5-5 -US-Bar,SWC_4_1_1,,-0.1,SWC-TDR,,; one of 4 sensors in different microtopographic positions,5-5 -US-Bar,SW_IN_1_1_1,,25,RAD-SW Pyran Class2,,Kipp1 Incident shortwave radiation; Kipp & Zonen CM 3; top of tower,5-5 -US-Bar,SW_OUT_1_1_1,,23.8,RAD-SW Pyran Class2,,Kipp2 Canopy-reflected shortwave radiation; Kipp & Zonen CM3; top of tower,5-5 -US-Bar,TA_1_1_1,,23.8,TEMP-ElectResis,,,5-5 -US-Bar,TA_1_2_1,,22.3,TEMP-Thermis,,Vaisala HMP35C,5-5 -US-Bar,TA_PI_F_1_1_1,,23.8,,,,5-5 -US-Bar,TS_1_1_1,,-0.05,TEMP-TCouple,,Thermocouple,5-5 -US-Bar,TS_1_2_1,,-0.1,TEMP-TCouple,,Thermocouple,5-5 -US-Bar,TS_PI_F_1_2_1,,-0.1,TEMP-TCouple,,,5-5 -US-Bar,USTAR_1_1_1,,24.5,SA-ATI SATI K Style,,,5-5 -US-Bar,VPD_PI_1_1_1,,22.3,,,,5-5 -US-Bar,WD_1_1_1,,24.5,SA-ATI SATI K Style,,,5-5 -US-Bar,WS_1_1_1,,24.5,SA-ATI SATI K Style,,,5-5 -US-Bar,WS_1_2_1,,22.7,WIND-CupAn,,backup RM Young cup anemometer,5-5 -US-Bi1,CH4,,3.9,GA_OP-LI-COR LI-7700,,,8-5 -US-Bi1,CO2,,3.9,GA_OP-LI-COR LI-7500A,,,8-5 -US-Bi1,FC,,3.9,GA_OP-LI-COR LI-7500A,SA-Gill Windmaster,,8-5 -US-Bi1,FC_PI_F,,3.9,GA_OP-LI-COR LI-7500A,SA-Gill Windmaster,,8-5 -US-Bi1,FCH4,,3.9,GA_OP-LI-COR LI-7700,SA-Gill Windmaster,,8-5 -US-Bi1,FCH4_PI_F,,3.9,GA_OP-LI-COR LI-7700,SA-Gill Windmaster,,8-5 -US-Bi1,G,,-.02,SOIL_H-Plate,,,8-5 -US-Bi1,GPP_PI_F,,3.9,GA_OP-LI-COR LI-7500A,SA-Gill Windmaster,,8-5 -US-Bi1,H,,3.9,SA-Gill Windmaster,,,8-5 -US-Bi1,H2O,,3.9,GA_OP-LI-COR LI-7500A,,,8-5 -US-Bi1,H_PI_F,,3.9,SA-Gill Windmaster,,,8-5 -US-Bi1,LE,,3.9,GA_OP-LI-COR LI-7500A,SA-Gill Windmaster,,8-5 -US-Bi1,LE_PI_F,,3.9,GA_OP-LI-COR LI-7500A,SA-Gill Windmaster,,8-5 -US-Bi1,LW_IN,,2.76,RAD-Pyrrad-SW+LW,,,8-5 -US-Bi1,LW_OUT,,2.76,RAD-Pyrrad-SW+LW,,,8-5 -US-Bi1,NETRAD,,2.76,RAD-Pyrrad-SW+LW,,,8-5 -US-Bi1,P,,2.7,RAIN-TipBucGauge,,,8-5 -US-Bi1,PA,,1.5,PRES-ElectBar,,,8-5 -US-Bi1,PPFD_IN,,2.76,RAD-PAR Quantum,,,8-5 -US-Bi1,PPFD_OUT,,2.76,RAD-PAR Quantum,,,8-5 -US-Bi1,RECO_PI_F,,3.9,GA_OP-LI-COR LI-7500A,SA-Gill Windmaster,,8-5 -US-Bi1,RH,,3.5,RH-Capac,,,8-5 -US-Bi1,SWC_1,,-.02,SWC-TDR,,,8-5 -US-Bi1,SWC_2,,-.2,SWC-TDR,,,8-5 -US-Bi1,SW_IN,,2.76,RAD-Pyrrad-SW+LW,,,8-5 -US-Bi1,SW_OUT,,2.76,RAD-Pyrrad-SW+LW,,,8-5 -US-Bi1,TA,,3.5,TEMP-ElectResis,,,8-5 -US-Bi1,TAU,,3.9,SA-Gill Windmaster,,,8-5 -US-Bi1,TS_1,,-.02,TEMP-TCouple,,,8-5 -US-Bi1,TS_2,,-.04,TEMP-TCouple,,,8-5 -US-Bi1,TS_3,,-.08,TEMP-TCouple,,,8-5 -US-Bi1,TS_4,,-.16,TEMP-TCouple,,,8-5 -US-Bi1,TS_5,,-.32,TEMP-TCouple,,,8-5 -US-Bi1,T_SONIC,,3.9,SA-Gill Windmaster,,,8-5 -US-Bi1,T_SONIC_SIGMA,,3.9,SA-Gill Windmaster,,,8-5 -US-Bi1,USTAR,,3.9,SA-Gill Windmaster,,,8-5 -US-Bi1,VPD_PI,,3.5,RH-Capac,,Temp-ElectResis,8-5 -US-Bi1,V_SIGMA,,3.9,SA-Gill Windmaster,,,8-5 -US-Bi1,WD,,3.9,SA-Gill Windmaster,,,8-5 -US-Bi1,WS,,3.9,SA-Gill Windmaster,,,8-5 -US-Bi1,W_SIGMA,,3.9,SA-Gill Windmaster,,,8-5 -US-Bi1,ZL,,3.9,SA-Gill Windmaster,,,8-5 -US-Bi2,CH4,,5.11,GA_OP-LI-COR LI-7700,,,13-5 -US-Bi2,CO2,,5.11,GA_OP-LI-COR LI-7500A,,,13-5 -US-Bi2,FC,,5.11,GA_OP-LI-COR LI-7500A,SA-Gill Windmaster,,13-5 -US-Bi2,FC_PI_F,,5.11,GA_OP-LI-COR LI-7500A,SA-Gill Windmaster,,13-5 -US-Bi2,FCH4,,5.11,GA_OP-LI-COR LI-7700,SA-Gill Windmaster,,13-5 -US-Bi2,FCH4_PI_F,,5.11,GA_OP-LI-COR LI-7700,SA-Gill Windmaster,,13-5 -US-Bi2,G,,-.02,SOIL_H-Plate,,,13-5 -US-Bi2,GPP_PI_F,,5.11,GA_OP-LI-COR LI-7500A,SA-Gill Windmaster,,13-5 -US-Bi2,H,,5.11,SA-Gill Windmaster,,,13-5 -US-Bi2,H2O,,5.11,GA_OP-LI-COR LI-7500A,,,13-5 -US-Bi2,H_PI_F,,5.11,SA-Gill Windmaster,,,13-5 -US-Bi2,LE,,5.11,GA_OP-LI-COR LI-7500A,SA-Gill Windmaster,,13-5 -US-Bi2,LE_PI_F,,5.11,GA_OP-LI-COR LI-7500A,SA-Gill Windmaster,,13-5 -US-Bi2,LW_IN,,4.42,RAD-Pyrrad-SW+LW,,,13-5 -US-Bi2,LW_OUT,,4.42,RAD-Pyrrad-SW+LW,,,13-5 -US-Bi2,NETRAD,,4.42,RAD-Pyrrad-SW+LW,,,13-5 -US-Bi2,P,,4.75,RAIN-TipBucGauge,,,13-5 -US-Bi2,PA,,2.0,PRES-ElectBar,,,13-5 -US-Bi2,PPFD_IN,,4.45,RAD-PAR Quantum,,,13-5 -US-Bi2,PPFD_OUT,,4.4,RAD-PAR Quantum,,,13-5 -US-Bi2,RECO_PI_F,,5.11,GA_OP-LI-COR LI-7500A,SA-Gill Windmaster,,13-5 -US-Bi2,RH,,4.9,RH-Capac,,,13-5 -US-Bi2,SWC_1,,-.02,SWC-TDR,,,13-5 -US-Bi2,SWC_2,,-.2,SWC-TDR,,,13-5 -US-Bi2,SW_IN,,4.42,RAD-Pyrrad-SW+LW,,,13-5 -US-Bi2,SW_OUT,,4.42,RAD-Pyrrad-SW+LW,,,13-5 -US-Bi2,TA,,4.9,TEMP-ElectResis,,,13-5 -US-Bi2,TAU,,5.11,SA-Gill Windmaster,,,13-5 -US-Bi2,TS_1,,-.02,TEMP-TCouple,,,13-5 -US-Bi2,TS_2,,-.04,TEMP-TCouple,,,13-5 -US-Bi2,TS_3,,-.08,TEMP-TCouple,,,13-5 -US-Bi2,TS_4,,-.16,TEMP-TCouple,,,13-5 -US-Bi2,TS_5,,-.32,TEMP-TCouple,,,13-5 -US-Bi2,T_SONIC,,5.11,SA-Gill Windmaster,,,13-5 -US-Bi2,T_SONIC_SIGMA,,5.11,SA-Gill Windmaster,,,13-5 -US-Bi2,USTAR,,5.11,SA-Gill Windmaster,,,13-5 -US-Bi2,VPD_PI,,4.9,RH-Capac,,TEMP-ElectResis,13-5 -US-Bi2,V_SIGMA,,5.11,SA-Gill Windmaster,,,13-5 -US-Bi2,WD,,5.11,SA-Gill Windmaster,,,13-5 -US-Bi2,WS,,5.11,SA-Gill Windmaster,,,13-5 -US-Bi2,W_SIGMA,,5.11,SA-Gill Windmaster,,,13-5 -US-Bkg,FC,,4,,,,4-1 -US-Bkg,H,,4,,,,4-1 -US-Bkg,LE,,4,,,,4-1 -US-Bkg,RH,,4,,,,4-1 -US-Bkg,SWC_1,,-0.1,,,,4-1 -US-Bkg,SWC_2,,-0.2,,,,4-1 -US-Bkg,TA,,4,,,,4-1 -US-Bkg,TS_1,,-0.02,,,,4-1 -US-Bkg,TS_2,,-0.04,,,,4-1 -US-Bkg,WD,,4,,,,4-1 -US-Bkg,WS,,4,,,,4-1 -US-Blk,FC,,24,,,,2-1 -US-Blk,H,,24,,,,2-1 -US-Blk,LE,,24,,,,2-1 -US-Blk,SWC_1,,-0.1,,,,2-1 -US-Blk,SWC_2,,-0.3,,,,2-1 -US-Blk,TS_1,,-0.02,,,,2-1 -US-Blk,TS_2,,-0.04,,,,2-1 -US-Blk,WD,,24,,,,2-1 -US-Blk,WS,,24,,,,2-1 -US-Bn1,CO2_1,,9.5,,,,1-1 -US-Bn1,FC,,9.5,,,,1-1 -US-Bn1,G,,-0.1,,,,1-1 -US-Bn1,H,,9.5,,,,1-1 -US-Bn1,H2O,,9.5,,,,1-1 -US-Bn1,LE,,9.5,,,,1-1 -US-Bn1,NETRAD,,11.0,,,,1-1 -US-Bn1,PA,,1.7,,,,1-1 -US-Bn1,PPFD_IN,,11.4,,,,1-1 -US-Bn1,RH,,7.4,,,,1-1 -US-Bn1,SWC_1,,-0.02,,,,1-1 -US-Bn1,SWC_2,,-0.04,,,,1-1 -US-Bn1,SW_IN,,11.4,RAD-Other,,LI200X,1-1 -US-Bn1,SW_OUT,,10.7,RAD-Other,,Eppley,1-1 -US-Bn1,TA,,7.4,,,,1-1 -US-Bn1,TS_1,,-0,,,,1-1 -US-Bn1,TS_2,,-0.025,,,,1-1 -US-Bn1,USTAR,,9.5,,,,1-1 -US-Bn1,VPD_PI_PI,,7.4,,,,1-1 -US-Bn1,WD,,11.8,,,,1-1 -US-Bn1,WS,,11.8,,,,1-1 -US-Bn2,CO2_1,,10.0,,,,1-1 -US-Bn2,FC,,10.0,,,,1-1 -US-Bn2,G,,-0.1,,,,1-1 -US-Bn2,H,,10.0,,,,1-1 -US-Bn2,H2O,,10.0,,,,1-1 -US-Bn2,LE,,10.0,,,,1-1 -US-Bn2,NETRAD,,10.3,,,,1-1 -US-Bn2,PA,,2.0,,,,1-1 -US-Bn2,PPFD_IN,,11.4,,,,1-1 -US-Bn2,P,,1.0,,,,1-1 -US-Bn2,RH,,6.3,,,,1-1 -US-Bn2,SWC_1,,-0.02,,,,1-1 -US-Bn2,SWC_2,,-0.11,,,,1-1 -US-Bn2,SW_IN,,11.4,RAD-Other,,LI200X,1-1 -US-Bn2,TA,,6.3,,,,1-1 -US-Bn2,TS_1,,-0,,,,1-1 -US-Bn2,TS_2,,-0.025,,,,1-1 -US-Bn2,USTAR,,10.0,,,,1-1 -US-Bn2,VPD_PI_PI,,6.3,,,,1-1 -US-Bn2,WD,,12,,,,1-1 -US-Bn2,WS,,12,,,,1-1 -US-Bn3,CO2_1,,7.8,,,,1-1 -US-Bn3,FC,,7.8,,,,1-1 -US-Bn3,G,,-0.1,,,,1-1 -US-Bn3,H,,7.8,,,,1-1 -US-Bn3,H2O,,7.8,,,,1-1 -US-Bn3,LE,,7.8,,,,1-1 -US-Bn3,NETRAD,,7.0,,,,1-1 -US-Bn3,PA,,1.0,,,,1-1 -US-Bn3,PPFD_IN,,9.0,,,,1-1 -US-Bn3,P,,1,,,,1-1 -US-Bn3,RH,,5,,,,1-1 -US-Bn3,SWC_1,,-0.02,,,,1-1 -US-Bn3,SWC_2,,-0.04,,,,1-1 -US-Bn3,SW_IN,,9.0,RAD-Other,,LI200X,1-1 -US-Bn3,SW_OUT,,7.0,RAD-Other,,Eppley,1-1 -US-Bn3,TA,,5,,,,1-1 -US-Bn3,TS_1,,-0,,,,1-1 -US-Bn3,TS_2,,-0.025,,,,1-1 -US-Bn3,USTAR,,7.8,,,,1-1 -US-Bn3,VPD_PI_PI,,5.0,,,,1-1 -US-Bn3,WD,,9.0,,,,1-1 -US-Bn3,WS,,9.0,,,,1-1 -US-Bo1,RH,,3,,,,2-1 -US-Bo1,SWC_1,,-0.1,,,,2-1 -US-Bo1,SWC_2,,-0.2,,,,2-1 -US-Bo1,TA,,3,,,,2-1 -US-Bo1,TS_1,,-0.02,,,,2-1 -US-Bo1,TS_2,,-0.04,,,,2-1 -US-Bo1,WD,,10,,,,2-1 -US-Bo1,WS,,10,,,,2-1 -US-Bo2,WD,,10,,,,2-1 -US-Bo2,WS,,10,,,,2-1 -US-Br1,G,,,SOIL_H-Other,,REBS Gplate+storage; W m-2,1-1 -US-Br1,SWC_1,,-0.05,,,,1-1 -US-Br1,TS_1,,-0.02,,,,1-1 -US-Br1,USTAR,,,WIND-Other,,CSAT u_star; m s-1,1-1 -US-Br1,WD,,,WIND-Other,,CSAT wnd_dir_compass; degrees,1-1 -US-Br1,WS,,,WIND-Other,,CSAT wnd_spd; m s-1,1-1 -US-Br3,G,,,SOIL_H-Other,,REBS Gplate+storage; W m-2,1-1 -US-Br3,SWC_1,,-0.05,,,,1-1 -US-Br3,TS_1,,-0.02,,,,1-1 -US-Br3,USTAR,,,WIND-Other,,CSAT u_star; m s-1,1-1 -US-Br3,WD,,,WIND-Other,,CSAT wnd_dir_compass; degrees,1-1 -US-Br3,WS,,,WIND-Other,,CSAT wnd_spd; m s-1,1-1 -US-BRG,CO2_1_1_1,,3,GA_OP-Other,,,1-5 -US-BRG,FC_1_1_1,,3,GA_OP-Other,,,1-5 -US-BRG,G_1_1_1,,-0.1,SOIL_H-Plate_AUTO,,,1-5 -US-BRG,G_2_1_1,,-0.1,SOIL_H-Plate_AUTO,,,1-5 -US-BRG,H_1_1_1,,3,GA_OP-Other,,,1-5 -US-BRG,H2O_1_1_1,,3,GA_OP-Other,,,1-5 -US-BRG,LE_1_1_1,,3,GA_OP-Other,,,1-5 -US-BRG,LW_IN_1_1_1,,3,RAD-Pyrrad-SW+LW,,,1-5 -US-BRG,LW_OUT_1_1_1,,3,RAD-Pyrrad-SW+LW,,,1-5 -US-BRG,P_1_1_1,,3,RAIN-TipBucGauge,,,1-5 -US-BRG,PA_1_1_1,,3,PRES-MgBar,,,1-5 -US-BRG,PPFD_IN_1_1_1,,3,RAD-PAR Quantum,,,1-5 -US-BRG,RH_1_1_1,,3,RH-Capac,,,1-5 -US-BRG,SWC_1_1_1,,-0.15,SWC-TDR,,30-cm TDR probe; sensing the top 30 cm of the soil,1-5 -US-BRG,SWC_2_1_1,,-0.15,SWC-TDR,,30-cm TDR probe; sensing the top 30 cm of the soil,1-5 -US-BRG,SWC_3_1_1,,-0.15,SWC-TDR,,30-cm TDR probe; sensing the top 30 cm of the soil,1-5 -US-BRG,SW_IN_1_1_1,,3,RAD-Pyrrad-SW+LW,,,1-5 -US-BRG,SW_OUT_1_1_1,,3,RAD-PAR Quantum,,,1-5 -US-BRG,TA_1_1_1,,3,TEMP-ElectResis,,,1-5 -US-BRG,TS_1_1_1,,-0.1,TEMP-TCouple,,,1-5 -US-BRG,TS_2_1_1,,-0.1,TEMP-TCouple,,,1-5 -US-BRG,T_SONIC_1_1_1,,3,GA_OP-Other,,,1-5 -US-BRG,U_SIGMA_1_1_1,,3,GA_OP-Other,,,1-5 -US-BRG,USTAR_1_1_1,,3,GA_OP-Other,,,1-5 -US-BRG,V_SIGMA_1_1_1,,3,GA_OP-Other,,,1-5 -US-BRG,WD_1_1_1,,3,GA_OP-Other,,,1-5 -US-BRG,WS_1_1_1,,3,GA_OP-Other,,,1-5 -US-BRG,W_SIGMA_1_1_1,,3,GA_OP-Other,,,1-5 -US-Brw,FC,,4.18,,,,2-1 -US-Brw,G,,,SOIL_H-Other,,REBS) W m-2,2-1 -US-Brw,H,,4.18,SA-Other,,Gill Inc.) W m-2 (at 4.18m),2-1 -US-Brw,LE,,4.18,,,,2-1 -US-Brw,NETRAD,,,RAD-Other,,REBS) W m-2,2-1 -US-Brw,PPFD_IN,,1.2,RAD-Other,,LI-COR) uE m-2 s-1 (at 1.2m),2-1 -US-Brw,PPFD_OUT,,1.2,RAD-Other,,LI-COR) uE m-2 s-1 (at 1.2m),2-1 -US-Brw,RH,,2.5,RH-Other,,Vaisala) % (at 2.5m),2-1 -US-Brw,TA,,2.5,TEMP-Other,,Vaisala) oC (at 2.5m),2-1 -US-Brw,TS_1,,-0,TEMP-Other,,Thermocouple,2-1 -US-Brw,TS_2,,-0.05,,,,2-1 -US-Brw,USTAR,,4.18,WIND-Other,,Gill Inc.) m s-1,2-1 -US-Brw,VPD_PI_PI,,2.5,,,,2-1 -US-Brw,WD,,2.5,WIND-Other,,Gill Inc.) Degree (at 2.5m),2-1 -US-Brw,WS,,2.5,WIND-Other,,Gill Inc.) m s-1 (at 2.5m),2-1 -US-BZB,CO2,,3.0,GA_OP-Campbell EC150,,,3-5 -US-BZB,D_SNOW,,2,SNOW-Acoustic,,,3-5 -US-BZB,D_SNOW_PI_F,,2,SNOW-Acoustic,,,3-5 -US-BZB,FC,,3.0,GA_OP-Campbell EC150,SA-Campbell CSAT-3,,3-5 -US-BZB,FC_PI_F,,3.0,GA_OP-Campbell EC150,SA-Campbell CSAT-3,,3-5 -US-BZB,FCH4,201304,3.0,GA_OP-LI-COR LI-7700,SA-Campbell CSAT-3,,3-5 -US-BZB,FCH4_PI_F,201304,3.0,GA_OP-LI-COR LI-7700,SA-Campbell CSAT-3,,3-5 -US-BZB,G_1,,-0.08,SOIL_H-Plate_AUTO,,,3-5 -US-BZB,G_2,,-0.08,SOIL_H-Plate_AUTO,,,3-5 -US-BZB,G_3,,-0.08,SOIL_H-Plate_AUTO,,,3-5 -US-BZB,G_4,,-0.08,SOIL_H-Plate_AUTO,,,3-5 -US-BZB,H,,3.0,SA-Campbell CSAT-3,,,3-5 -US-BZB,H_PI_F,,3.0,SA-Campbell CSAT-3,,,3-5 -US-BZB,LE,,3.0,GA_OP-Campbell EC150,SA-Campbell CSAT-3,,3-5 -US-BZB,LE_PI_F,,3.0,GA_OP-Campbell EC150,SA-Campbell CSAT-3,,3-5 -US-BZB,LW_IN,,2.0,RAD-Pyrrad-SW+LW,,,3-5 -US-BZB,LW_IN_PI_F,,2.0,RAD-Pyrrad-SW+LW,,,3-5 -US-BZB,LW_OUT,,2.0,RAD-Pyrrad-SW+LW,,,3-5 -US-BZB,LW_OUT_PI_F,,2.0,RAD-Pyrrad-SW+LW,,,3-5 -US-BZB,NETRAD,,2.0,RAD-Pyrrad-SW+LW,,,3-5 -US-BZB,NETRAD_PI_F,,2.0,RAD-Pyrrad-SW+LW,,,3-5 -US-BZB,P,,3,RAIN-TipBucGauge,,,3-5 -US-BZB,PA,,1,GA_OP-Campbell EC150,,,3-5 -US-BZB,PA_PI_F,,1,GA_OP-Campbell EC150,,,3-5 -US-BZB,P_PI_F,,3,RAIN-TipBucGauge,,,3-5 -US-BZB,PPFD_IN,,2.0,RAD-PAR Quantum,,removed after intial year,3-5 -US-BZB,PPFD_OUT,,2.0,RAD-PAR Quantum,,,3-5 -US-BZB,PPFD_OUT_PI_F,,2.0,RAD-PAR Quantum,,,3-5 -US-BZB,RH,,2.0,RH-ElecRes,,,3-5 -US-BZB,RH_PI_F,,2.0,RH-ElecRes,,,3-5 -US-BZB,SG_1,,0,SOIL_H-Plate_AUTO,,G1 and G2,3-5 -US-BZB,SG_2,,0,SOIL_H-Plate_AUTO,,G3 and G4,3-5 -US-BZB,SWC_1,,-0.15,SWC-TDR,,,3-5 -US-BZB,SWC_2,,-0.15,SWC-TDR,,,3-5 -US-BZB,SW_IN,,2.0,RAD-Pyrrad-SW+LW,,,3-5 -US-BZB,SW_IN_PI_F,,2.0,RAD-Pyrrad-SW+LW,,,3-5 -US-BZB,SW_OUT,,2.0,RAD-Pyrrad-SW+LW,,,3-5 -US-BZB,SW_OUT_PI_F,,2.0,RAD-Pyrrad-SW+LW,,,3-5 -US-BZB,TA,,2.0,TEMP-ElectResis,,,3-5 -US-BZB,TA_PI_F,,2.0,TEMP-ElectResis,,,3-5 -US-BZB,TS_1,,-0.025,TEMP-TCouple,,,3-5 -US-BZB,TS_2,,-0.025,TEMP-TCouple,,,3-5 -US-BZB,USTAR,,3,SA-Campbell CSAT-3,,,3-5 -US-BZB,VPD_PI,,3,GA_OP-Campbell EC150,,,3-5 -US-BZB,VPD_PI_F,,3,GA_OP-Campbell EC150,,,3-5 -US-BZB,WD,,3,SA-Campbell CSAT-3,,,3-5 -US-BZB,WS,,3,SA-Campbell CSAT-3,,,3-5 -US-BZB,WS_PI_F,,3,SA-Campbell CSAT-3,,,3-5 -US-BZF,CH4,,2,GA_OP-LI-COR LI-7700,,,3-5 -US-BZF,CO2,,2,GA_OP-Campbell EC150,,,3-5 -US-BZF,D_SNOW,,2,SNOW-Acoustic,,,3-5 -US-BZF,FC,,2,GA_OP-Campbell EC150,SA-Campbell CSAT-3,,3-5 -US-BZF,FC_PI_F,,2,GA_OP-Campbell EC150,SA-Campbell CSAT-3,,3-5 -US-BZF,FCH4,,2,GA_OP-LI-COR LI-7700,SA-Campbell CSAT-3,,3-5 -US-BZF,FCH4_PI_F,,2,GA_OP-LI-COR LI-7700,SA-Campbell CSAT-3,,3-5 -US-BZF,G_1,,-.08,SOIL_H-Plate_AUTO,,,3-5 -US-BZF,G_2,,-.08,SOIL_H-Plate_AUTO,,,3-5 -US-BZF,G_3,,-.08,SOIL_H-Plate_AUTO,,,3-5 -US-BZF,G_4,,-.08,SOIL_H-Plate_AUTO,,,3-5 -US-BZF,GPP_PI,,2,GA_OP-Campbell EC150,SA-Campbell CSAT-3,,3-5 -US-BZF,H,,2,SA-Campbell CSAT-3,,,3-5 -US-BZF,H_PI_F,,2,SA-Campbell CSAT-3,,,3-5 -US-BZF,LE,,2,GA_OP-Campbell EC150,SA-Campbell CSAT-3,,3-5 -US-BZF,LE_PI_F,,2,GA_OP-Campbell EC150,SA-Campbell CSAT-3,,3-5 -US-BZF,LW_IN,,2,RAD-Pyrrad-SW+LW,,,3-5 -US-BZF,LW_IN_PI_F,,2,RAD-Pyrrad-SW+LW,,,3-5 -US-BZF,LW_OUT,,2,RAD-Pyrrad-SW+LW,,,3-5 -US-BZF,LW_OUT_PI_F,,2,RAD-Pyrrad-SW+LW,,,3-5 -US-BZF,NETRAD,,2,RAD-Pyrrad-SW+LW,,,3-5 -US-BZF,NETRAD_PI_F,,2,RAD-Pyrrad-SW+LW,,,3-5 -US-BZF,P,,2,RAIN-TipBucGauge,,,3-5 -US-BZF,PA,,1,GA_OP-Campbell EC150,,,3-5 -US-BZF,PA_PI_F,,1,GA_OP-Campbell EC150,,,3-5 -US-BZF,P_PI_F,,2,GA_OP-Campbell EC150,,,3-5 -US-BZF,PPFD_IN,,2,RAD-PAR Quantum,,,3-5 -US-BZF,PPFD_IN_PI_F,,2,RAD-PAR Quantum,,,3-5 -US-BZF,PPFD_OUT,,2,RAD-PAR Quantum,,removed shortly after station began,3-5 -US-BZF,RECO_PI_PI,,2,GA_OP-Campbell EC150,SA-Campbell CSAT-3,,3-5 -US-BZF,RH,,2,RH-ElecRes,,,3-5 -US-BZF,RH_PI_F,,2,RH-ElecRes,,,3-5 -US-BZF,SG_1,,0,SOIL_H-Plate_AUTO,,G1 and G2,3-5 -US-BZF,SG_2,,0,SOIL_H-Plate_AUTO,,G3 and G4,3-5 -US-BZF,SWC_1,,-0.15,SWC-TDR,,,3-5 -US-BZF,SWC_2,,-0.15,SWC-TDR,,,3-5 -US-BZF,SW_IN,,2,RAD-Pyrrad-SW+LW,,,3-5 -US-BZF,SW_IN_PI_F,,2,RAD-Pyrrad-SW+LW,,,3-5 -US-BZF,SW_OUT,,2,RAD-Pyrrad-SW+LW,,,3-5 -US-BZF,SW_OUT_PI_F,,2,RAD-Pyrrad-SW+LW,,,3-5 -US-BZF,TA,,2,TEMP-ElectResis,,,3-5 -US-BZF,TA_PI_F,,2,TEMP-ElectResis,,,3-5 -US-BZF,TS_1,,-0.025,TEMP-TCouple,,,3-5 -US-BZF,TS_2,,-0.025,TEMP-TCouple,,,3-5 -US-BZF,TS_PI_F_1,,-0.025,TEMP-TCouple,,,3-5 -US-BZF,USTAR,,2,SA-Campbell CSAT-3,,,3-5 -US-BZF,VPD_PI,,2,GA_OP-Campbell EC150,,,3-5 -US-BZF,VPD_PI_F,,2,GA_OP-Campbell EC150,,,3-5 -US-BZF,WD,,2,SA-Campbell CSAT-3,,,3-5 -US-BZF,WS,,2,SA-Campbell CSAT-3,,,3-5 -US-BZF,WS_PI_F,,2,SA-Campbell CSAT-3,,,3-5 -US-BZo,CH4,,2.2,GA_OP-LI-COR LI-7700,,,2-5 -US-BZo,CO2,,2.2,GA_OP-LI-COR LI-7500A,,,2-5 -US-BZo,FC,,2.2,GA_OP-LI-COR LI-7500A,SA-Campbell CSAT-3,,2-5 -US-BZo,FC_PI_F,,2.2,GA_OP-LI-COR LI-7500A,SA-Campbell CSAT-3,,2-5 -US-BZo,FCH4,,2.2,GA_OP-LI-COR LI-7700,SA-Campbell CSAT-3,,2-5 -US-BZo,FCH4_PI_F,,2.2,GA_OP-LI-COR LI-7700,SA-Campbell CSAT-3,,2-5 -US-BZo,G_1,,-0.08,SOIL_H-Plate_AUTO,,,2-5 -US-BZo,G_2,,-0.08,SOIL_H-Plate_AUTO,,,2-5 -US-BZo,G_3,,-0.08,SOIL_H-Plate_AUTO,,,2-5 -US-BZo,G_4,,-0.08,SOIL_H-Plate_AUTO,,,2-5 -US-BZo,GPP_PI,,0,GA_OP-LI-COR LI-7500A,SA-Campbell CSAT-3,,2-5 -US-BZo,H,,2.2,SA-Campbell CSAT-3,,,2-5 -US-BZo,H_PI_F,,2.2,SA-Campbell CSAT-3,,,2-5 -US-BZo,LE,,2.2,GA_OP-LI-COR LI-7500A,SA-Campbell CSAT-3,,2-5 -US-BZo,LE_PI_F,,2.2,GA_OP-LI-COR LI-7500A,SA-Campbell CSAT-3,,2-5 -US-BZo,NETRAD,,2.0,RAD-Pyrrad-SW+LW,,,2-5 -US-BZo,P,,0.3,RAIN-TipBucGauge,,,2-5 -US-BZo,PA,,1,GA_OP-LI-COR LI-7500A,,,2-5 -US-BZo,PPFD_IN,,2.0,RAD-PAR Quantum,,,2-5 -US-BZo,RECO_PI,,2.2,GA_OP-LI-COR LI-7500A,SA-Campbell CSAT-3,,2-5 -US-BZo,RH,,2,RH-ElecRes,,,2-5 -US-BZo,RH_PI_F,,2,RH-ElecRes,,,2-5 -US-BZo,SG_1,,0,SOIL_H-Plate_AUTO,,G1 and G2,2-5 -US-BZo,SG_2,,0,SOIL_H-Plate_AUTO,,G3 and G4,2-5 -US-BZo,SWC_1,,-0.15,SWC-TDR,,,2-5 -US-BZo,SWC_2,,-0.15,SWC-TDR,,,2-5 -US-BZo,SW_IN,,2.0,RAD-Pyrrad-SW+LW,,,2-5 -US-BZo,SW_IN_PI_F,,2.0,RAD-Pyrrad-SW+LW,,,2-5 -US-BZo,SW_OUT,,2.0,RAD-Pyrrad-SW+LW,,,2-5 -US-BZo,TA,,2.0,TEMP-ElectResis,,,2-5 -US-BZo,TA_PI_F,,2.0,TEMP-ElectResis,,,2-5 -US-BZo,TS_1,,-0.025,TEMP-TCouple,,,2-5 -US-BZo,TS_2,,-0.025,TEMP-TCouple,,,2-5 -US-BZo,TS_PI_F_1,,-0.025,TEMP-TCouple,,,2-5 -US-BZo,USTAR,,2.2,SA-Campbell CSAT-3,,,2-5 -US-BZo,VPD_PI_F,,2.2,GA_OP-LI-COR LI-7500A,,,2-5 -US-BZo,WD,,2.2,SA-Campbell CSAT-3,,,2-5 -US-BZo,WS,,2.2,SA-Campbell CSAT-3,,,2-5 -US-BZS,CH4,201404,5,GA_OP-LI-COR LI-7700,,removed fall 2018,3-5 -US-BZS,CO2,201311,5,GA_OP-LI-COR LI-7500A,,LI7500A upgrade kit,3-5 -US-BZS,CO2,,5,GA_OP-LI-COR LI-7500,,,3-5 -US-BZS,D_SNOW,,0,SNOW-Acoustic,,,3-5 -US-BZS,D_SNOW_PI_F,,0,SNOW-Acoustic,,,3-5 -US-BZS,FC,201311,5,GA_OP-LI-COR LI-7500A,SA-Campbell CSAT-3,LI7500A upgrade kit,3-5 -US-BZS,FC,,5,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,3-5 -US-BZS,FC_PI_F,201311,5,GA_OP-LI-COR LI-7500A,SA-Campbell CSAT-3,LI7500A upgrade kit,3-5 -US-BZS,FC_PI_F,,5,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,3-5 -US-BZS,FCH4,,5,GA_OP-LI-COR LI-7700,SA-Campbell CSAT-3,removed fall 2018,3-5 -US-BZS,FCH4_PI_F,,5,GA_OP-LI-COR LI-7700,SA-Campbell CSAT-3,removed fall 2018,3-5 -US-BZS,G_1,,-0.08,SOIL_H-Plate_AUTO,,,3-5 -US-BZS,G_2,,-0.08,SOIL_H-Plate_AUTO,,,3-5 -US-BZS,G_3,,-0.08,SOIL_H-Plate_AUTO,,,3-5 -US-BZS,G_4,,-0.08,SOIL_H-Plate_AUTO,,,3-5 -US-BZS,GPP_PI,201311,5,GA_OP-LI-COR LI-7500A,SA-Campbell CSAT-3,,3-5 -US-BZS,GPP_PI,,5,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,3-5 -US-BZS,H,,5,SA-Campbell CSAT-3,,,3-5 -US-BZS,H_PI_F,,5,SA-Campbell CSAT-3,,,3-5 -US-BZS,LE,201311,5,GA_OP-LI-COR LI-7500A,SA-Campbell CSAT-3,,3-5 -US-BZS,LE,,5,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,3-5 -US-BZS,LE_PI_F,201311,5,GA_OP-LI-COR LI-7500A,SA-Campbell CSAT-3,,3-5 -US-BZS,LE_PI_F,,5,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,3-5 -US-BZS,LW_IN,,0,,,should not be any longwave data from this site,3-5 -US-BZS,LW_IN_PI_F,,0,,,should not be any longwave data from this site,3-5 -US-BZS,LW_OUT,,0,,,should not be any longwave data from this site,3-5 -US-BZS,NETRAD,,2,RAD-Net radiometer,,,3-5 -US-BZS,NETRAD_PI_F,,2,RAD-Net radiometer,,,3-5 -US-BZS,P,,2,RAIN-TipBucGauge,,,3-5 -US-BZS,PA,201311,1,GA_OP-LI-COR LI-7500A,,AIU,3-5 -US-BZS,PA,,1,GA_OP-LI-COR LI-7500,,,3-5 -US-BZS,PA_PI_F,201311,1,GA_OP-LI-COR LI-7500A,,AIU,3-5 -US-BZS,PA_PI_F,,1,GA_OP-LI-COR LI-7500,,,3-5 -US-BZS,P_PI_F,,2,RAIN-TipBucGauge,,,3-5 -US-BZS,PPFD_IN,,2,RAD-PAR Quantum,,,3-5 -US-BZS,PPFD_IN_PI_F,,2,RAD-PAR Quantum,,,3-5 -US-BZS,PPFD_OUT,,2,RAD-PAR Quantum,,,3-5 -US-BZS,PPFD_OUT_PI_F,,2,RAD-PAR Quantum,,,3-5 -US-BZS,RECO_PI,201311,5,GA_OP-LI-COR LI-7500A,SA-Campbell CSAT-3,,3-5 -US-BZS,RECO_PI,,5,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,3-5 -US-BZS,RH,,5,RH-ElecRes,,,3-5 -US-BZS,RH_PI_F,,5,RH-ElecRes,,,3-5 -US-BZS,SG_1,,0,SOIL_H-Plate_AUTO,,,3-5 -US-BZS,SG_2,,0,SOIL_H-Plate_AUTO,,,3-5 -US-BZS,SWC_1,,-0.15,SWC-TDR,,,3-5 -US-BZS,SWC_2,,-0.15,SWC-TDR,,,3-5 -US-BZS,SW_IN,,2,RAD-SW Pyran Class1,,,3-5 -US-BZS,SW_IN_PI_F,,2,RAD-SW Pyran Class1,,,3-5 -US-BZS,SW_OUT,,2,RAD-SW Pyran Class1,,,3-5 -US-BZS,SW_OUT_PI_F,,2,RAD-SW Pyran Class1,,,3-5 -US-BZS,TA,,5,TEMP-ElectResis,,,3-5 -US-BZS,TA_PI_F,,5,TEMP-ElectResis,,,3-5 -US-BZS,TS_1,,-0.025,TEMP-TCouple,,,3-5 -US-BZS,TS_2,,-0.025,TEMP-TCouple,,,3-5 -US-BZS,TS_3,,-0.025,TEMP-TCouple,,,3-5 -US-BZS,TS_PI_F_1,,-0.025,TEMP-TCouple,,,3-5 -US-BZS,USTAR,,5,SA-Campbell CSAT-3,,,3-5 -US-BZS,VPD_PI,201311,5,GA_OP-LI-COR LI-7500A,,,3-5 -US-BZS,VPD_PI,,5,GA_OP-LI-COR LI-7500,,,3-5 -US-BZS,VPD_PI_F,201311,5,GA_OP-LI-COR LI-7500A,,,3-5 -US-BZS,VPD_PI_F,,5,GA_OP-LI-COR LI-7500,,,3-5 -US-BZS,WD,,5,SA-Campbell CSAT-3,,,3-5 -US-BZS,WS,,5,SA-Campbell CSAT-3,,,3-5 -US-BZS,WS_PI_F,,5,SA-Campbell CSAT-3,,,3-5 -US-CaV,FC,,4,,,,2-1 -US-CaV,H,,4,,,,2-1 -US-CaV,LE,,4,,,,2-1 -US-CaV,SWC_1,,-0.05,,,,2-1 -US-CaV,SWC_2,,-0.1,,,,2-1 -US-CaV,TS_1,,-0.02,,,,2-1 -US-CaV,TS_2,,-0.04,,,,2-1 -US-CaV,WD,,4,,,,2-1 -US-CaV,WS,,4,,,,2-1 -US-Ced,CO2_1,,17,,,,7-1 -US-Ced,FC,,17,,,,7-1 -US-Ced,G,,-0.1,,,,7-1 -US-Ced,H,,17,,,,7-1 -US-Ced,LE,,17,,,,7-1 -US-Ced,NETRAD,,15,,,,7-1 -US-Ced,PPFD_IN,,15,,,,7-1 -US-Ced,RH,,15,,,,7-1 -US-Ced,SW_IN,,15,,,,7-1 -US-Ced,TA,,15,,,,7-1 -US-Ced,TS_1,,-0.05,,,,7-1 -US-Ced,USTAR,,17,,,,7-1 -US-Ced,VPD_PI_PI,,15,,,,7-1 -US-Ced,WD,,15,,,,7-1 -US-Ced,WS,,15,,,,7-1 -US-CF1,CO2,20170601,2.1,GA_OP-Campbell EC150,,,3-5 -US-CF1,FC,,2.1,GA_OP-Campbell EC150,SA-Campbell CSAT-3,,3-5 -US-CF1,FC_SSITC_TEST,,2.1,GA_OP-Campbell EC150,,,3-5 -US-CF1,FETCH_90,,2.1,SA-Campbell CSAT-3,,,3-5 -US-CF1,FETCH_MAX,,2.1,SA-Campbell CSAT-3,,,3-5 -US-CF1,H,20170601,2.1,GA_OP-Campbell EC150,,,3-5 -US-CF1,H_SSITC_TEST,,2.1,SA-Campbell CSAT-3,,,3-5 -US-CF1,LE,201706,2.1,GA_OP-Campbell EC150,SA-Campbell CSAT-3,,3-5 -US-CF1,LE_SSITC_TEST,,2.1,GA_OP-Campbell EC150,,,3-5 -US-CF1,MO_LENGTH,,2.1,SA-Campbell CSAT-3,,,3-5 -US-CF1,NETRAD,201706,2.1,RAD-Net radiometer,,,3-5 -US-CF1,P,,2.1,RAIN-TipBucGauge,,,3-5 -US-CF1,PA,,2.1,GA_OP-Campbell EC150,,,3-5 -US-CF1,PPFD_IN,20170601,2.1,RAD-PAR Quantum,,,3-5 -US-CF1,RH,201706,2.1,GA_OP-Campbell EC150,,,3-5 -US-CF1,SWC,,-0.05,SWC-TDR,,,3-5 -US-CF1,TA,20170601,2.1,SA-Campbell CSAT-3,,,3-5 -US-CF1,TS,,-0.05,SWC-TDR,,,3-5 -US-CF1,T_SONIC,20170601,2.1,SA-Campbell CSAT-3,,,3-5 -US-CF1,T_SONIC_SIGMA,,2.1,SA-Campbell CSAT-3,,,3-5 -US-CF1,U_SIGMA,,2.1,SA-Campbell CSAT-3,,,3-5 -US-CF1,USTAR,,2.1,SA-Campbell CSAT-3,,,3-5 -US-CF1,VPD_PI,,2.1,GA_OP-Campbell EC150,,,3-5 -US-CF1,V_SIGMA,,2.1,SA-Campbell CSAT-3,,,3-5 -US-CF1,WD,,2.1,SA-Campbell CSAT-3,,,3-5 -US-CF1,WS,,2.1,SA-Campbell CSAT-3,,,3-5 -US-CF1,W_SIGMA,,2.1,SA-Campbell CSAT-3,,,3-5 -US-CF1,ZL,,2.1,SA-Campbell CSAT-3,,,3-5 -US-CF2,FC,,2.1,GA_OP-Campbell EC150,SA-Campbell CSAT-3,,2-5 -US-CF2,FC_SSITC_TEST,,2.1,GA_OP-Campbell EC150,,,2-5 -US-CF2,FETCH_90,,2.1,SA-Campbell CSAT-3,,,2-5 -US-CF2,FETCH_MAX,,2.1,SA-Campbell CSAT-3,,,2-5 -US-CF2,H,,2.1,GA_OP-Campbell EC150,,,2-5 -US-CF2,H_SSITC_TEST,,2.1,SA-Campbell CSAT-3,,,2-5 -US-CF2,LE,,2.1,GA_OP-Campbell EC150,SA-Campbell CSAT-3,,2-5 -US-CF2,LE_SSITC_TEST,,2.1,GA_OP-Campbell EC150,,,2-5 -US-CF2,MO_LENGTH,,2.1,SA-Campbell CSAT-3,,,2-5 -US-CF2,NETRAD,,2.1,RAD-Net radiometer,,,2-5 -US-CF2,P,,2.1,RAIN-TipBucGauge,,,2-5 -US-CF2,PA,,2.1,GA_OP-Campbell EC150,,,2-5 -US-CF2,PPFD_IN,,2.1,RAD-PAR Quantum,,,2-5 -US-CF2,RH,,2.1,GA_OP-Campbell EC150,,,2-5 -US-CF2,SWC,,-0.05,SWC-TDR,,,2-5 -US-CF2,TA,,2.1,SA-Campbell CSAT-3,,,2-5 -US-CF2,TS,,-0.05,SWC-TDR,,,2-5 -US-CF2,T_SONIC,,2.1,SA-Campbell CSAT-3,,,2-5 -US-CF2,T_SONIC_SIGMA,,2.1,SA-Campbell CSAT-3,,,2-5 -US-CF2,U_SIGMA,,2.1,SA-Campbell CSAT-3,,,2-5 -US-CF2,USTAR,,2.1,SA-Campbell CSAT-3,,,2-5 -US-CF2,VPD_PI_PI,,2.1,GA_OP-Campbell EC150,,,2-5 -US-CF2,V_SIGMA,,2.1,SA-Campbell CSAT-3,,,2-5 -US-CF2,WD,,2.1,SA-Campbell CSAT-3,,,2-5 -US-CF2,WS,,2.1,SA-Campbell CSAT-3,,,2-5 -US-CF2,W_SIGMA,,2.1,SA-Campbell CSAT-3,,,2-5 -US-CF2,ZL,,2.1,SA-Campbell CSAT-3,,,2-5 -US-CF3,CO2,,2.1,GA_OP-Campbell EC150,,,3-5 -US-CF3,FC,,2.1,GA_OP-Campbell EC150,SA-Campbell CSAT-3,,3-5 -US-CF3,FC_SSITC_TEST,,2.1,GA_OP-Campbell EC150,,,3-5 -US-CF3,FETCH_90,,2.1,SA-Campbell CSAT-3,,,3-5 -US-CF3,FETCH_MAX,,2.1,SA-Campbell CSAT-3,,,3-5 -US-CF3,H,,2.1,GA_OP-Campbell EC150,,,3-5 -US-CF3,H_SSITC_TEST,,2.1,SA-Campbell CSAT-3,,,3-5 -US-CF3,LE,,2.1,GA_OP-Campbell EC150,SA-Campbell CSAT-3,,3-5 -US-CF3,LE_SSITC_TEST,,2.1,GA_OP-Campbell EC150,,,3-5 -US-CF3,MO_LENGTH,,2.1,SA-Campbell CSAT-3,,,3-5 -US-CF3,NETRAD,,2.1,RAD-Net radiometer,,,3-5 -US-CF3,P,,2.1,RAIN-TipBucGauge,,,3-5 -US-CF3,PA,,2.1,GA_OP-Campbell EC150,,,3-5 -US-CF3,PPFD_IN,,2.1,RAD-PAR Quantum,,,3-5 -US-CF3,RH,,2.1,GA_OP-Campbell EC150,,,3-5 -US-CF3,SWC,,-0.05,SWC-TDR,,,3-5 -US-CF3,TA,,2.1,SA-Campbell CSAT-3,,,3-5 -US-CF3,TS,,-0.05,SWC-TDR,,,3-5 -US-CF3,T_SONIC,,2.1,SA-Campbell CSAT-3,,,3-5 -US-CF3,T_SONIC_SIGMA,,2.1,SA-Campbell CSAT-3,,,3-5 -US-CF3,U_SIGMA,,2.1,SA-Campbell CSAT-3,,,3-5 -US-CF3,USTAR,,2.1,SA-Campbell CSAT-3,,,3-5 -US-CF3,VPD_PI_PI,,2.1,GA_OP-Campbell EC150,,,3-5 -US-CF3,V_SIGMA,,2.1,SA-Campbell CSAT-3,,,3-5 -US-CF3,WD,,2.1,SA-Campbell CSAT-3,,,3-5 -US-CF3,WS,,2.1,SA-Campbell CSAT-3,,,3-5 -US-CF3,W_SIGMA,,2.1,SA-Campbell CSAT-3,,,3-5 -US-CF3,ZL,,2.1,SA-Campbell CSAT-3,,,3-5 -US-CF4,CO2,,2.1,GA_OP-Campbell EC150,,,3-5 -US-CF4,FC,,2.1,GA_OP-Campbell EC150,SA-Campbell CSAT-3,,3-5 -US-CF4,FC_SSITC_TEST,,2.1,GA_OP-Campbell EC150,,,3-5 -US-CF4,FETCH_90,,2.1,SA-Campbell CSAT-3,,,3-5 -US-CF4,FETCH_MAX,,2.1,SA-Campbell CSAT-3,,,3-5 -US-CF4,H,,2.1,GA_OP-Campbell EC150,,,3-5 -US-CF4,H_SSITC_TEST,,2.1,SA-Campbell CSAT-3,,,3-5 -US-CF4,LE,,2.1,GA_OP-Campbell EC150,SA-Campbell CSAT-3,,3-5 -US-CF4,LE_SSITC_TEST,,2.1,GA_OP-Campbell EC150,,,3-5 -US-CF4,MO_LENGTH,,2.1,SA-Campbell CSAT-3,,,3-5 -US-CF4,NETRAD,,2.1,RAD-Net radiometer,,,3-5 -US-CF4,P,,2.1,RAIN-TipBucGauge,,,3-5 -US-CF4,PA,,2.1,GA_OP-Campbell EC150,,,3-5 -US-CF4,PPFD_IN,,2.1,RAD-PAR Quantum,,,3-5 -US-CF4,RH,,2.1,GA_OP-Campbell EC150,,,3-5 -US-CF4,SWC,,-0.05,SWC-TDR,,,3-5 -US-CF4,TA,,2.1,SA-Campbell CSAT-3,,,3-5 -US-CF4,TS,,-0.05,SWC-TDR,,,3-5 -US-CF4,T_SONIC,,2.1,SA-Campbell CSAT-3,,,3-5 -US-CF4,T_SONIC_SIGMA,,2.1,SA-Campbell CSAT-3,,,3-5 -US-CF4,U_SIGMA,,2.1,SA-Campbell CSAT-3,,,3-5 -US-CF4,USTAR,,2.1,SA-Campbell CSAT-3,,,3-5 -US-CF4,VPD_PI_PI,,2.1,GA_OP-Campbell EC150,,,3-5 -US-CF4,V_SIGMA,,2.1,SA-Campbell CSAT-3,,,3-5 -US-CF4,WD,,2.1,SA-Campbell CSAT-3,,,3-5 -US-CF4,WS,,2.1,SA-Campbell CSAT-3,,,3-5 -US-CF4,W_SIGMA,,2.1,SA-Campbell CSAT-3,,,3-5 -US-CF4,ZL,,2.1,SA-Campbell CSAT-3,,,3-5 -US-ChR,SWC_1,,-0.05,,,,2-1 -US-ChR,SWC_2,,-0.1,,,,2-1 -US-ChR,TS_1,,-0.02,,,,2-1 -US-ChR,TS_2,,-0.04,,,,2-1 -US-ChR,WS,,43,,,,2-1 -US-CMW,CO2,20010101,14,GA_OP-LI-COR LI-7500,,CO2 mole fraction,2-5 -US-CMW,FC,20010101,14,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,CO2 flux No storage correction,2-5 -US-CMW,G,20010101,-0.05,SOIL_H-Plate,,ground heat flux,2-5 -US-CMW,GPP_PI_F,20010101,14,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,Gross Primary Production;NEE - RECO,2-5 -US-CMW,H,20010101,14,SA-Campbell CSAT-3,,Sensible Heat flux,2-5 -US-CMW,H2O,20010101,14,GA_OP-LI-COR LI-7500,,H2O mole fraction,2-5 -US-CMW,LE,20010101,14,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,Latent Heat Flux,2-5 -US-CMW,LW_IN,20010101,10,RAD-Net radiometer,,incoming longwave radiation,2-5 -US-CMW,LW_OUT,20010101,10,RAD-Net radiometer,,outgoing longwave radiation,2-5 -US-CMW,NEE_PI_F,20010101,14,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,Net ecosystem exchange of CO2; u* filtered (threshold = 0.2 m/s) and gap-filled and including change in storage at IRGA height only,2-5 -US-CMW,NETRAD,20010101,10,RAD-Pyrrad-SW+LW,,net radiation,2-5 -US-CMW,P,20010101,0.05,PREC-WeightGauge,,precipitation,2-5 -US-CMW,PA,20010101,14,GA_OP-LI-COR LI-7500,,air pressure,2-5 -US-CMW,PPFD_IN_PI_F,20010101,2,RAD-PAR Quantum,,incoming photosynthetic photon flux density; gap-filled where necessary,2-5 -US-CMW,RECO_PI_F,20010101,14,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,Ecosystem Respiration (partitioned NEE_GF with nighttime approach),2-5 -US-CMW,RH_1_1_1,20010101,14,RH-Capac,,relative humidity; 14m,2-5 -US-CMW,RH_1_2_1,20010101,3,RH-Capac,,relative humidity; 8m,2-5 -US-CMW,RH_1_3_1,20010101,3,RH-Capac,,relative humidity; 3m,2-5 -US-CMW,SWC_PI_1_1_A,20010101,-0.05,SWC-TDR,,vol. soil moisture; 5cm,2-5 -US-CMW,SWC_PI_1_2_A,20010101,-0.125,SWC-TDR,,vol. soil moisture; 12.5cm,2-5 -US-CMW,SWC_PI_1_3_A,20010101,-0.225,SWC-TDR,,vol. soil moisture; 22.5cm,2-5 -US-CMW,SWC_PI_1_4_A,20010101,-0.325,SWC-TDR,,vol. soil moisture; 32.5cm,2-5 -US-CMW,SWC_PI_1_5_A,20010101,-0.475,SWC-TDR,,vol. soil moisture; 47.5cm,2-5 -US-CMW,SWC_1_6_1,20010101,-0.65,SWC-TDR,,vol. soil moisture; 65cm,2-5 -US-CMW,SWC_1_7_1,20010101,-0.65,SWC-TDR,,vol. soil moisture; 65cm,2-5 -US-CMW,SWC_PI_2_1_A,20010101,-0.95,SWC-TDR,,vol. soil moisture; 95cm,2-5 -US-CMW,SW_IN,20010101,214,RAD-SW Pyran Class1,,incoming solar radiation,2-5 -US-CMW,SW_OUT,20010101,14,RAD-Net radiometer,,outgoing solar radiation,2-5 -US-CMW,TA_1_1_1,20010101,14,TEMP-ElectResis,,air temperature; 14m,2-5 -US-CMW,TA_1_2_1,20010101,8,TEMP-ElectResis,,air temperature-8 m,2-5 -US-CMW,TA_1_3_1,20010101,3,TEMP-ElectResis,,air temperature-3 m,2-5 -US-CMW,T_CANOPY_1_1_1,20010101,10,TEMP-Other,,infrared surface temp; mainly canopy temp,2-5 -US-CMW,T_CANOPY_2_1_1,20010101,10,TEMP-Other,,infrared surface temp; mainly intercanopy space,2-5 -US-CMW,TIMESTAMP_END,20010101,,,,timestamp_end at end of halfhour,2-5 -US-CMW,TIMESTAMP_START,20010101,,,,timestamp beginning,2-5 -US-CMW,TS_1_1_1,20010101,-0.05,TEMP-TCouple,,soil temperature; 5cm,2-5 -US-CMW,TS_1_2_1,20010101,-0.12,TEMP-TCouple,,soil temperature; 12 cm,2-5 -US-CMW,TS_1_3_1,20010101,-0.22,TEMP-TCouple,,soil temperature; 22.5cm,2-5 -US-CMW,TS_1_4_1,20010101,-0.325,TEMP-TCouple,,soil temperature; 32.5cm,2-5 -US-CMW,TS_1_5_1,20010101,-0.475,TEMP-TCouple,,soil temperature; 47.5cm,2-5 -US-CMW,TS_1_6_1,20010101,-0.65,TEMP-TCouple,,soil temperature; 65cm,2-5 -US-CMW,T_SONIC,20010101,14,SA-Campbell CSAT-3,,sonic temperature,2-5 -US-CMW,USTAR,20010101,14,SA-Campbell CSAT-3,,friction velocity,2-5 -US-CMW,WD_1_1_1,20010101,14,SA-Campbell CSAT-3,,wind direction; 14m,2-5 -US-CMW,WS_1_1_1,20010101,14,SA-Campbell CSAT-3,,wind speed; 14m,2-5 -US-CMW,WS_1_2_1,20010101,8,WIND-CupAn,,wind speed; 8m,2-5 -US-CMW,WS_1_3_1,20010101,3,WIND-CupAn,,wind speed; 3m,2-5 -US-Cop,CO2,,1.85,,,,2-5 -US-Cop,FC,,1.85,,,,2-5 -US-Cop,G,,-0.1,,,,2-5 -US-Cop,H,,1.85,,,,2-5 -US-Cop,LE,,1.85,,,,2-5 -US-Cop,NETRAD,,3.00,,,,2-5 -US-Cop,P,,1,,,,2-5 -US-Cop,RH_1_1_1,,3.00,,,,2-5 -US-Cop,SWC_1_1_1,,-0.05,,,,2-5 -US-Cop,SWC_2_2_1,,-0.1,,,,2-5 -US-Cop,SW_IN,,3.00,,,,2-5 -US-Cop,SW_OUT,,3.00,,,,2-5 -US-Cop,TA_1_1_1,,3.00,,,,2-5 -US-Cop,TS_1_1_1,,-0.05,,,,2-5 -US-Cop,TS_2_2_1,,-0.1,,,,2-5 -US-Cop,USTAR,,1.85,,,,2-5 -US-Cop,VPD_PI_1_1_1,,3.00,,,,2-5 -US-Cop,WD_1_1_1,,3.00,,,,2-5 -US-Cop,WS_1_1_1,,3.00,,,,2-5 -US-Cop,ZL,,1.85,,,,2-5 -US-CPk,CO2_1,,17.7,,,,2-1 -US-CPk,FC,,17.7,SA-Other,,CSAT/LI7500,2-1 -US-CPk,G,,-0.05,,,,2-1 -US-CPk,H,,17.7,SA-Other,,CSAT/LI7500,2-1 -US-CPk,H2O,,17.7,,,,2-1 -US-CPk,LE,,17.7,SA-Other,,CSAT/LI7500,2-1 -US-CPk,LW_IN,,17.1,RAD-Other,,CNR1,2-1 -US-CPk,LW_OUT,,17.1,RAD-Other,,CNR1,2-1 -US-CPk,NETRAD,,17.1,RAD-Other,,CNR1,2-1 -US-CPk,PPFD_IN,,18,,,,2-1 -US-CPk,RH,,17.7,,,,2-1 -US-CPk,SWC_2,,-0.45,,,,2-1 -US-CPk,SW_IN,,17.1,RAD-Other,,CNR1,2-1 -US-CPk,SW_OUT,,17.1,RAD-Other,,CNR1,2-1 -US-CPk,TA,,17.7,,,,2-1 -US-CPk,TS_1,,-0.1,TEMP-Other,,Thermocouple,2-1 -US-CPk,TS_2,,-0.3,,,,2-1 -US-CPk,USTAR,,17.7,WIND-Other,,CSAT,2-1 -US-CPk,VPD_PI_PI,,17.7,,,,2-1 -US-CPk,WD,,17.7,WIND-Other,,CSAT,2-1 -US-CPk,WS,,17.7,,,,2-1 -US-CRT,CH4,,2,GA_OP-LI-COR LI-7700,,,5-5 -US-CRT,CO2,,2,GA_OP-LI-COR LI-7500,,,5-5 -US-CRT,FC,,2,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,5-5 -US-CRT,FCH4,,2,GA_OP-LI-COR LI-7700,SA-Campbell CSAT-3,,5-5 -US-CRT,G_1_1_1,,-0.1,SOIL_H-Plate,,,5-5 -US-CRT,G_2_1_1,,-0.1,SOIL_H-Plate,,,5-5 -US-CRT,H,,2,SA-Campbell CSAT-3,,,5-5 -US-CRT,H2O,,2,GA_OP-LI-COR LI-7500,,,5-5 -US-CRT,LE,,2,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,5-5 -US-CRT,LW_IN,,2,RAD-Pyrrad-SW+LW,,,5-5 -US-CRT,LW_OUT,,2,RAD-Pyrrad-SW+LW,,,5-5 -US-CRT,MO_LENGTH,,2,,,,5-5 -US-CRT,NEE_PI,,,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,5-5 -US-CRT,NETRAD,,2,RAD-Pyrrad-SW+LW,,,5-5 -US-CRT,P,,2.5,RAIN-TipBucGauge,,,5-5 -US-CRT,PA,,0.5,PRES-ElectBar,,,5-5 -US-CRT,PPFD_IN,,2.5,RAD-PAR Quantum,,,5-5 -US-CRT,RH,,2,RH-Capac,,,5-5 -US-CRT,SWC,,-0.15,SWC-TDR,,,5-5 -US-CRT,SW_IN,,2,RAD-Pyrrad-SW+LW,,,5-5 -US-CRT,SW_OUT,,2,RAD-Pyrrad-SW+LW,,,5-5 -US-CRT,TA,,2,TEMP-ElectResis,,,5-5 -US-CRT,TS_1_1_1,,-0.1,TEMP-Thermis,,,5-5 -US-CRT,TS_2_1_1,,-0.1,TEMP-Thermis,,,5-5 -US-CRT,T_SONIC,,2,SA-Campbell CSAT-3,,,5-5 -US-CRT,T_SONIC_SIGMA,,2,SA-Campbell CSAT-3,,,5-5 -US-CRT,USTAR,,2,SA-Campbell CSAT-3,,,5-5 -US-CRT,V_SIGMA,,2,SA-Campbell CSAT-3,,,5-5 -US-CRT,WD,,2,SA-Campbell CSAT-3,,,5-5 -US-CRT,WS,,2,SA-Campbell CSAT-3,,,5-5 -US-CRT,W_SIGMA,,2,SA-Campbell CSAT-3,,,5-5 -US-CRT,WTD,,-3,WTD-Press,,,5-5 -US-CRT,ZL,,2,,,,5-5 -US-CS1,CO2_1_1_1,,2.5,GA_OP_SA-Campbell IRGASON,,,2-5 -US-CS1,FC_1_1_1,,2.5,GA_OP_SA-Campbell IRGASON,,,2-5 -US-CS1,FC_SSITC_TEST,,2.5,GA_OP_SA-Campbell IRGASON,,,2-5 -US-CS1,FETCH_90,,2.5,GA_OP_SA-Campbell IRGASON,,,2-5 -US-CS1,FETCH_MAX,,2.5,GA_OP_SA-Campbell IRGASON,,,2-5 -US-CS1,GPP_PI_F,,2.5,GA_OP_SA-Campbell IRGASON,,,2-5 -US-CS1,H_1_1_1,,2.5,GA_OP_SA-Campbell IRGASON,,,2-5 -US-CS1,H2O_1_1_1,,2.5,RH-Capac,,,2-5 -US-CS1,H_SSITC_TEST,,2.5,GA_OP_SA-Campbell IRGASON,,,2-5 -US-CS1,LE_1_1_1,,2.5,GA_OP_SA-Campbell IRGASON,,,2-5 -US-CS1,LE_SSITC_TEST,,2.5,GA_OP_SA-Campbell IRGASON,,,2-5 -US-CS1,LW_IN_1_1_1,,1.5,RAD-Pyrrad-SW+LW,,,2-5 -US-CS1,LW_OUT_1_1_1,,1.5,RAD-Pyrrad-SW+LW,,,2-5 -US-CS1,MO_LENGTH_1_1_1,,2.5,GA_OP_SA-Campbell IRGASON,,,2-5 -US-CS1,NEE_PI,,2.5,GA_OP_SA-Campbell IRGASON,,,2-5 -US-CS1,NEE_PI_F,,2.5,GA_OP_SA-Campbell IRGASON,,,2-5 -US-CS1,NETRAD_1_1_1,,1.5,RAD-Pyrrad-SW+LW,,,2-5 -US-CS1,P,,1.5,RAIN-TipBucGauge,,,2-5 -US-CS1,PA_1_1_1,,2.5,GA_OP_SA-Campbell IRGASON,,,2-5 -US-CS1,RECO_PI_F,,2.5,GA_OP_SA-Campbell IRGASON,,,2-5 -US-CS1,RH_1_1_1,,2.5,RH-Capac,,,2-5 -US-CS1,SC_1_1_1,,2.5,GA_OP_SA-Campbell IRGASON,,,2-5 -US-CS1,SH_1_1_1,,2.5,TEMP-IntegratedCircuit,,,2-5 -US-CS1,SLE_1_1_1,,2.5,RH-Capac,,,2-5 -US-CS1,SW_IN_1_1_1,,1.5,RAD-Pyrrad-SW+LW,,,2-5 -US-CS1,SW_OUT_1_1_1,,1.5,RAD-Pyrrad-SW+LW,,,2-5 -US-CS1,TA_1_1_1,,2.5,TEMP-IntegratedCircuit,,,2-5 -US-CS1,USTAR_1_1_1,,2.5,GA_OP_SA-Campbell IRGASON,,,2-5 -US-CS1,VPD_PI_1_1_1,,2.5,RH-Capac,,,2-5 -US-CS1,WD_1_1_1,,2.5,GA_OP_SA-Campbell IRGASON,,,2-5 -US-CS1,WS_1_1_1,,2.5,GA_OP_SA-Campbell IRGASON,,,2-5 -US-CS2,CO2_1_1_1,20190829,31,GA_OP_SA-Campbell IRGASON,,,4-5 -US-CS2,CO2_1_1_1,20210721,31,GA_OP-LI-COR LI-7500A,,,4-5 -US-CS2,CO2_1_1_1,,31,GA_OP-LI-COR LI-7500A,,,4-5 -US-CS2,FC_1_1_1,20190829,31,GA_OP_SA-Campbell IRGASON,,,4-5 -US-CS2,FC_1_1_1,20210721,31,GA_OP-LI-COR LI-7500A,SA-Campbell CSAT-3,,4-5 -US-CS2,FC_1_1_1,,31,GA_OP-LI-COR LI-7500A,SA-Campbell CSAT-3,,4-5 -US-CS2,FC_SSITC_TEST,20190829,31,GA_OP_SA-Campbell IRGASON,,,4-5 -US-CS2,FC_SSITC_TEST,20210721,31,GA_OP-LI-COR LI-7500A,,,4-5 -US-CS2,FC_SSITC_TEST,,31,GA_OP-LI-COR LI-7500A,,,4-5 -US-CS2,FETCH_90,20190829,31,GA_OP_SA-Campbell IRGASON,,undefined,4-5 -US-CS2,FETCH_90,20210721,31,SA-Campbell CSAT-3,,,4-5 -US-CS2,FETCH_90,,31,SA-Campbell CSAT-3,,,4-5 -US-CS2,FETCH_MAX,20190829,31,GA_OP_SA-Campbell IRGASON,,undefined,4-5 -US-CS2,FETCH_MAX,20210721,31,SA-Campbell CSAT-3,,undefined,4-5 -US-CS2,FETCH_MAX,,31,SA-Campbell CSAT-3,,,4-5 -US-CS2,G_1_1_1,,-0.5,SOIL_H-Plate,,,4-5 -US-CS2,GPP_PI_F,20190829,31,GA_OP_SA-Campbell IRGASON,,undefined,4-5 -US-CS2,GPP_PI_F,20210721,31,GA_OP-LI-COR LI-7500A,SA-Campbell CSAT-3,undefined,4-5 -US-CS2,GPP_PI_F,,31,GA_OP-LI-COR LI-7500A,SA-Campbell CSAT-3,,4-5 -US-CS2,H_1_1_1,20190829,31,GA_OP_SA-Campbell IRGASON,,undefined,4-5 -US-CS2,H_1_1_1,20210721,31,SA-Campbell CSAT-3,,undefined,4-5 -US-CS2,H_1_1_1,,31,SA-Campbell CSAT-3,,,4-5 -US-CS2,H2O_1_1_1,20190829,31,GA_OP_SA-Campbell IRGASON,,undefined,4-5 -US-CS2,H2O_1_1_1,20210721,31,GA_OP-LI-COR LI-7500A,,undefined,4-5 -US-CS2,H2O_1_1_1,,31,GA_OP-LI-COR LI-7500A,,,4-5 -US-CS2,H_SSITC_TEST,20190829,31,GA_OP_SA-Campbell IRGASON,,undefined,4-5 -US-CS2,H_SSITC_TEST,20210721,31,SA-Campbell CSAT-3,,undefined,4-5 -US-CS2,H_SSITC_TEST,,31,SA-Campbell CSAT-3,,,4-5 -US-CS2,LE_1_1_1,20190829,31,GA_OP_SA-Campbell IRGASON,,undefined,4-5 -US-CS2,LE_1_1_1,20210721,31,GA_OP-LI-COR LI-7500A,SA-Campbell CSAT-3,undefined,4-5 -US-CS2,LE_1_1_1,,31,GA_OP-LI-COR LI-7500A,SA-Campbell CSAT-3,,4-5 -US-CS2,LE_SSITC_TEST,20190829,31,GA_OP_SA-Campbell IRGASON,,undefined,4-5 -US-CS2,LE_SSITC_TEST,20210721,31,GA_OP-LI-COR LI-7500A,,undefined,4-5 -US-CS2,LE_SSITC_TEST,,31,GA_OP-LI-COR LI-7500A,,,4-5 -US-CS2,LW_IN_1_1_1,,31,RAD-Pyrrad-SW+LW,,,4-5 -US-CS2,LW_OUT_1_1_1,,31,RAD-Pyrrad-SW+LW,,,4-5 -US-CS2,MO_LENGTH_1_1_1,20190829,31,GA_OP_SA-Campbell IRGASON,,undefined,4-5 -US-CS2,MO_LENGTH_1_1_1,20210721,31,SA-Campbell CSAT-3,,undefined,4-5 -US-CS2,MO_LENGTH_1_1_1,,31,SA-Campbell CSAT-3,,,4-5 -US-CS2,NEE_PI,20190829,31,GA_OP_SA-Campbell IRGASON,,undefined,4-5 -US-CS2,NEE_PI,20210721,31,GA_OP-LI-COR LI-7500A,SA-Campbell CSAT-3,undefined,4-5 -US-CS2,NEE_PI,,31,GA_OP-LI-COR LI-7500A,SA-Campbell CSAT-3,,4-5 -US-CS2,NEE_PI_F,20190829,31,GA_OP_SA-Campbell IRGASON,,undefined,4-5 -US-CS2,NEE_PI_F,20210721,31,GA_OP-LI-COR LI-7500A,SA-Campbell CSAT-3,undefined,4-5 -US-CS2,NEE_PI_F,,31,GA_OP-LI-COR LI-7500A,SA-Campbell CSAT-3,,4-5 -US-CS2,NETRAD_1_1_1,,31,RAD-Pyrrad-SW+LW,,,4-5 -US-CS2,PA_1_1_1,,31,PRES-ElectBar,,,4-5 -US-CS2,RECO_PI_F,20190829,31,GA_OP_SA-Campbell IRGASON,,undefined,4-5 -US-CS2,RECO_PI_F,20210721,31,GA_OP-LI-COR LI-7500A,SA-Campbell CSAT-3,undefined,4-5 -US-CS2,RECO_PI_F,,31,GA_OP-LI-COR LI-7500A,SA-Campbell CSAT-3,,4-5 -US-CS2,RH_1_1_1,,31,RH-Capac,,,4-5 -US-CS2,SC_1_1_1,20190829,31,GA_OP_SA-Campbell IRGASON,,undefined,4-5 -US-CS2,SC_1_1_1,20210721,31,GA_OP-LI-COR LI-7500A,,undefined,4-5 -US-CS2,SC_1_1_1,,31,GA_OP-LI-COR LI-7500A,,,4-5 -US-CS2,SH_1_1_1,,31,TEMP-IntegratedCircuit,,,4-5 -US-CS2,SLE_1_1_1,,31,RH-Capac,,,4-5 -US-CS2,SWC_1_1_1,,-.05,SWC-Radio,,,4-5 -US-CS2,SWC_1_2_1,,-.1,SWC-Radio,,,4-5 -US-CS2,SWC_1_3_1,,-.2,SWC-Radio,,,4-5 -US-CS2,SWC_1_4_1,,-.5,SWC-Radio,,,4-5 -US-CS2,SW_IN_1_1_1,,31,RAD-Pyrrad-SW+LW,,,4-5 -US-CS2,SW_OUT_1_1_1,,31,RAD-Pyrrad-SW+LW,,,4-5 -US-CS2,TA_1_1_1,,31,TEMP-IntegratedCircuit,,,4-5 -US-CS2,TS_1_1_1,,-.05,TEMP-TCouple,,,4-5 -US-CS2,TS_1_2_1,,-.1,TEMP-TCouple,,,4-5 -US-CS2,TS_1_3_1,,-.2,TEMP-TCouple,,,4-5 -US-CS2,TS_1_4_1,,-.5,TEMP-TCouple,,,4-5 -US-CS2,USTAR_1_1_1,20190829,31,GA_OP_SA-Campbell IRGASON,,undefined,4-5 -US-CS2,USTAR_1_1_1,20210721,31,SA-Campbell CSAT-3,,undefined,4-5 -US-CS2,USTAR_1_1_1,,31,SA-Campbell CSAT-3,,,4-5 -US-CS2,VPD_PI_1_1_1,,31,RH-Capac,,,4-5 -US-CS2,WD_1_1_1,20190829,31,GA_OP_SA-Campbell IRGASON,,undefined,4-5 -US-CS2,WD_1_1_1,20210721,31,SA-Campbell CSAT-3,,undefined,4-5 -US-CS2,WD_1_1_1,,31,SA-Campbell CSAT-3,,,4-5 -US-CS2,WS_1_1_1,20190829,31,GA_OP_SA-Campbell IRGASON,,undefined,4-5 -US-CS2,WS_1_1_1,20210721,31,SA-Campbell CSAT-3,,undefined,4-5 -US-CS2,WS_1_1_1,,31,SA-Campbell CSAT-3,,,4-5 -US-CS3,CO2_1_1_1,,2.5,GA_OP_SA-Campbell IRGASON,,,3-5 -US-CS3,FC_1_1_1,,2.5,GA_OP_SA-Campbell IRGASON,,,3-5 -US-CS3,FC_SSITC_TEST,,2.5,GA_OP_SA-Campbell IRGASON,,,3-5 -US-CS3,FETCH_90,,2.5,GA_OP_SA-Campbell IRGASON,,,3-5 -US-CS3,FETCH_MAX,,2.5,GA_OP_SA-Campbell IRGASON,,,3-5 -US-CS3,GPP_PI_F,,2.5,GA_OP_SA-Campbell IRGASON,,,3-5 -US-CS3,H_1_1_1,,2.5,GA_OP_SA-Campbell IRGASON,,,3-5 -US-CS3,H2O_1_1_1,,2.5,GA_OP_SA-Campbell IRGASON,,,3-5 -US-CS3,H_SSITC_TEST,,2.5,GA_OP_SA-Campbell IRGASON,,,3-5 -US-CS3,LE_1_1_1,,2.5,GA_OP_SA-Campbell IRGASON,,,3-5 -US-CS3,LE_SSITC_TEST,,2.5,GA_OP_SA-Campbell IRGASON,,,3-5 -US-CS3,LW_IN_1_1_1,,1.5,RAD-Pyrrad-SW+LW,,,3-5 -US-CS3,LW_OUT_1_1_1,,1.5,RAD-Pyrrad-SW+LW,,,3-5 -US-CS3,MO_LENGTH_1_1_1,,2.5,GA_OP_SA-Campbell IRGASON,,,3-5 -US-CS3,NEE_PI,,2.5,GA_OP_SA-Campbell IRGASON,,,3-5 -US-CS3,NEE_PI_F,,2.5,GA_OP_SA-Campbell IRGASON,,,3-5 -US-CS3,NETRAD_1_1_1,,1.5,RAD-Pyrrad-SW+LW,,,3-5 -US-CS3,P,,1.5,RAIN-TipBucGauge,,,3-5 -US-CS3,PA_1_1_1,,2.5,GA_OP_SA-Campbell IRGASON,,,3-5 -US-CS3,RECO_PI_F,,2.5,GA_OP_SA-Campbell IRGASON,,,3-5 -US-CS3,RH_1_1_1,,2.5,RH-Capac,,,3-5 -US-CS3,SC_1_1_1,,2.5,GA_OP_SA-Campbell IRGASON,,,3-5 -US-CS3,SH_1_1_1,,2.5,GA_OP_SA-Campbell IRGASON,,,3-5 -US-CS3,SLE_1_1_1,,2.5,RH-Capac,,,3-5 -US-CS3,SW_IN_1_1_1,,1.5,RAD-Pyrrad-SW+LW,,,3-5 -US-CS3,SW_OUT_1_1_1,,1.5,RAD-Pyrrad-SW+LW,,,3-5 -US-CS3,TA_1_1_1,,2.5,TEMP-IntegratedCircuit,,,3-5 -US-CS3,USTAR_1_1_1,,2.5,GA_OP_SA-Campbell IRGASON,,,3-5 -US-CS3,VPD_PI_1_1_1,,2.5,RH-Capac,,,3-5 -US-CS3,WD_1_1_1,,2.5,GA_OP_SA-Campbell IRGASON,,,3-5 -US-CS3,WS_1_1_1,,2.5,GA_OP_SA-Campbell IRGASON,,,3-5 -US-CS4,CO2_1_1_1,,2.5,GA_OP_SA-Campbell IRGASON,,,3-5 -US-CS4,FC_1_1_1,,2.5,GA_OP_SA-Campbell IRGASON,,,3-5 -US-CS4,FC_SSITC_TEST,,2.5,GA_OP_SA-Campbell IRGASON,,,3-5 -US-CS4,FETCH_90,,2.5,GA_OP_SA-Campbell IRGASON,,,3-5 -US-CS4,FETCH_MAX,,2.5,GA_OP_SA-Campbell IRGASON,,,3-5 -US-CS4,GPP_PI_F,,2.5,GA_OP_SA-Campbell IRGASON,,,3-5 -US-CS4,H_1_1_1,,2.5,GA_OP_SA-Campbell IRGASON,,,3-5 -US-CS4,H2O_1_1_1,,2.5,GA_OP_SA-Campbell IRGASON,,,3-5 -US-CS4,H_SSITC_TEST,,2.5,GA_OP_SA-Campbell IRGASON,,,3-5 -US-CS4,LE_1_1_1,,2.5,GA_OP_SA-Campbell IRGASON,,,3-5 -US-CS4,LE_SSITC_TEST,,2.5,GA_OP_SA-Campbell IRGASON,,,3-5 -US-CS4,LW_IN_1_1_1,,1.5,RAD-Pyrrad-SW+LW,,,3-5 -US-CS4,LW_OUT_1_1_1,,1.5,RAD-Pyrrad-SW+LW,,,3-5 -US-CS4,MO_LENGTH_1_1_1,,2.5,GA_OP_SA-Campbell IRGASON,,,3-5 -US-CS4,NEE_PI,,2.5,GA_OP_SA-Campbell IRGASON,,,3-5 -US-CS4,NEE_PI_F,,2.5,GA_OP_SA-Campbell IRGASON,,,3-5 -US-CS4,NETRAD_1_1_1,,1.5,RAD-Pyrrad-SW+LW,,,3-5 -US-CS4,P,,1.5,RAIN-TipBucGauge,,,3-5 -US-CS4,PA_1_1_1,,2.5,GA_OP_SA-Campbell IRGASON,,,3-5 -US-CS4,RECO_PI_F,,2.5,GA_OP_SA-Campbell IRGASON,,,3-5 -US-CS4,RH_1_1_1,,2.5,RH-Capac,,,3-5 -US-CS4,SC_1_1_1,,2.5,GA_OP_SA-Campbell IRGASON,,,3-5 -US-CS4,SH_1_1_1,,2.5,GA_OP_SA-Campbell IRGASON,,,3-5 -US-CS4,SLE_1_1_1,,2.5,GA_OP_SA-Campbell IRGASON,,,3-5 -US-CS4,SW_IN_1_1_1,,1.5,RAD-Pyrrad-SW+LW,,,3-5 -US-CS4,SW_OUT_1_1_1,,1.5,RAD-Pyrrad-SW+LW,,,3-5 -US-CS4,TA_1_1_1,,2.5,TEMP-IntegratedCircuit,,,3-5 -US-CS4,USTAR_1_1_1,,2.5,GA_OP_SA-Campbell IRGASON,,,3-5 -US-CS4,VPD_PI_1_1_1,,2.5,RH-Capac,,,3-5 -US-CS4,WD_1_1_1,,2.5,GA_OP_SA-Campbell IRGASON,,,3-5 -US-CS4,WS_1_1_1,,2.5,GA_OP_SA-Campbell IRGASON,,,3-5 -US-Ctn,FC,,5,,,,2-1 -US-Ctn,H,,5,,,,2-1 -US-Ctn,LE,,5,,,,2-1 -US-DFC,CH4,,30,GA_OP-LI-COR LI-7700,,,1-5 -US-DFC,CO2,,30,GA_OP-LI-COR LI-7500A,,,1-5 -US-DFC,FC,,30,SA-Gill Windmaster,GA_OP-LI-COR LI-7500A,,1-5 -US-DFC,FCH4,,30,SA-Gill Windmaster,GA_OP-LI-COR LI-7700,,1-5 -US-DFC,FETCH_90,,30,SA-Gill Windmaster,,,1-5 -US-DFC,G_1_1_1,,-.05,SOIL_H-Plate,,,1-5 -US-DFC,G_2_1_1,,-.05,SOIL_H-Plate,,,1-5 -US-DFC,G_3_1_1,,-.05,SOIL_H-Plate,,,1-5 -US-DFC,H,,30,SA-Gill Windmaster,,,1-5 -US-DFC,H2O,,30,GA_OP-LI-COR LI-7500A,,,1-5 -US-DFC,LE,,30,SA-Gill Windmaster,GA_OP-LI-COR LI-7500A,,1-5 -US-DFC,LW_IN,,30,RAD-Pyrrad-SW+LW,,,1-5 -US-DFC,LW_OUT,,30,RAD-Pyrrad-SW+LW,,,1-5 -US-DFC,MO_LENGTH,,30,SA-Gill Windmaster,,,1-5 -US-DFC,NETRAD,,30,RAD-Pyrrad-SW+LW,,,1-5 -US-DFC,PA,,30,PRES-ElectBar,,,1-5 -US-DFC,P_RAIN,,1,PREC-TipBucGauge,,,1-5 -US-DFC,RH,,30,RH-Capac,,,1-5 -US-DFC,SC,,30,GA_OP-LI-COR LI-7500A,,,1-5 -US-DFC,SCH4,,30,GA_OP-LI-COR LI-7700,,,1-5 -US-DFC,SH,,30,SA-Gill Windmaster,,,1-5 -US-DFC,SLE,,30,GA_OP-LI-COR LI-7500A,,,1-5 -US-DFC,SWC_1_1_1,,-.05,SWC-TDR,,,1-5 -US-DFC,SWC_2_1_1,,-.05,SWC-TDR,,,1-5 -US-DFC,SWC_3_1_1,,-.05,SWC-TDR,,,1-5 -US-DFC,SW_IN_1_1_1,,30,RAD-Pyrrad-SW+LW,,,1-5 -US-DFC,SW_IN_2_1_1,,30,RAD-Pyrrad-SW+LW,,,1-5 -US-DFC,SW_OUT,,30,RAD-Pyrrad-SW+LW,,,1-5 -US-DFC,TA,,30,TEMP-ElectResis,,,1-5 -US-DFC,TAU,,30,SA-Gill Windmaster,,,1-5 -US-DFC,TS_1_1_1,,-.05,TEMP-TCouple,,,1-5 -US-DFC,TS_2_1_1,,-.05,TEMP-TCouple,,,1-5 -US-DFC,TS_3_1_1,,-.05,TEMP-TCouple,,,1-5 -US-DFC,T_SONIC,,30,SA-Gill Windmaster,,,1-5 -US-DFC,U_SIGMA,,30,SA-Gill Windmaster,,,1-5 -US-DFC,USTAR,,30,SA-Gill Windmaster,,,1-5 -US-DFC,VPD_PI,,30,GA_OP-LI-COR LI-7500A,,,1-5 -US-DFC,V_SIGMA,,30,SA-Gill Windmaster,,,1-5 -US-DFC,WD,,30,SA-Gill Windmaster,,,1-5 -US-DFC,WS,,30,SA-Gill Windmaster,,,1-5 -US-DFC,W_SIGMA,,30,SA-Gill Windmaster,,,1-5 -US-DFC,ZL,,30,SA-Gill Windmaster,,,1-5 -US-DFK,CO2,,3.21,GA_OP_SA-Campbell IRGASON,,,1-5 -US-DFK,FC,,3.21,GA_OP_SA-Campbell IRGASON,,,1-5 -US-DFK,FETCH_90,,3.21,GA_OP_SA-Campbell IRGASON,,,1-5 -US-DFK,G_1_1_1,,-0.16,SOIL_H-Plate_AUTO,,,1-5 -US-DFK,G_2_1_1,,-0.16,SOIL_H-Plate_AUTO,,,1-5 -US-DFK,G_3_1_1,,-0.16,SOIL_H-Plate_AUTO,,,1-5 -US-DFK,G_4_1_1,,-0.16,SOIL_H-Plate_AUTO,,,1-5 -US-DFK,H,,3.21,GA_OP_SA-Campbell IRGASON,,,1-5 -US-DFK,H2O,,3.21,GA_OP_SA-Campbell IRGASON,,,1-5 -US-DFK,LE,,3.21,GA_OP_SA-Campbell IRGASON,,,1-5 -US-DFK,LW_IN,,3.21,RAD-Pyrrad-SW+LW,,,1-5 -US-DFK,LW_OUT,,3.21,RAD-Pyrrad-SW+LW,,,1-5 -US-DFK,MO_LENGTH,,3.21,GA_OP_SA-Campbell IRGASON,,,1-5 -US-DFK,NETRAD,,3.21,RAD-Pyrrad-SW+LW,,,1-5 -US-DFK,PA,,3.21,PRES-ElectBar,,,1-5 -US-DFK,PPFD_IN,,3.21,RAD-PAR Quantum,,,1-5 -US-DFK,RH,,3.21,RH-Capac,,,1-5 -US-DFK,SC,,3.21,GA_OP_SA-Campbell IRGASON,,,1-5 -US-DFK,SH,,3.21,GA_OP_SA-Campbell IRGASON,,,1-5 -US-DFK,SLE,,3.21,GA_OP_SA-Campbell IRGASON,,,1-5 -US-DFK,SWC_1_1_1,,-0.08,SWC-TDR,,,1-5 -US-DFK,SWC_2_1_1,,-0.08,SWC-TDR,,,1-5 -US-DFK,SW_IN,,3.21,RAD-Pyrrad-SW+LW,,,1-5 -US-DFK,SW_OUT,,3.21,RAD-Pyrrad-SW+LW,,,1-5 -US-DFK,TA,,3.21,TEMP-ElectResis,,,1-5 -US-DFK,TAU,,3.21,GA_OP_SA-Campbell IRGASON,,,1-5 -US-DFK,TS_1_1_1,,-0.08,TEMP-TCouple,,,1-5 -US-DFK,TS_2_1_1,,-0.08,TEMP-TCouple,,,1-5 -US-DFK,T_SONIC,,3.21,GA_OP_SA-Campbell IRGASON,,,1-5 -US-DFK,U_SIGMA,,3.21,GA_OP_SA-Campbell IRGASON,,,1-5 -US-DFK,USTAR,,3.21,GA_OP_SA-Campbell IRGASON,,,1-5 -US-DFK,VPD_PI,,3.21,RH-Capac,,,1-5 -US-DFK,V_SIGMA,,3.21,GA_OP_SA-Campbell IRGASON,,,1-5 -US-DFK,WD,,3.21,GA_OP_SA-Campbell IRGASON,,,1-5 -US-DFK,WS,,3.21,GA_OP_SA-Campbell IRGASON,,,1-5 -US-DFK,W_SIGMA,,3.21,GA_OP_SA-Campbell IRGASON,,,1-5 -US-DFK,ZL,,3.21,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Dia,CO2_1,,2.1,GA_OP-Campbell EC150,,,1-1 -US-Dia,FC,,2.1,GA_OP-Campbell EC150,SA-Campbell CSAT-3,,1-1 -US-Dia,G,,-0,,,,1-1 -US-Dia,H,,2.1,SA-Campbell CSAT-3,,,1-1 -US-Dia,H2O,,2.1,GA_OP-Campbell EC150,,,1-1 -US-Dia,LE,,2.1,GA_OP-Campbell EC150,SA-Campbell CSAT-3,,1-1 -US-Dia,LW_IN,,2.2,,,,1-1 -US-Dia,LW_OUT,,2.2,,,,1-1 -US-Dia,NEE_PI_PI,,2.1,,,,1-1 -US-Dia,NETRAD,,2.2,,,,1-1 -US-Dia,P,,0,,,,1-1 -US-Dia,PA,,2.2,,,,1-1 -US-Dia,RH,,2.2,,,,1-1 -US-Dia,SW_DIF,,2.2,,,,1-1 -US-Dia,SW_IN,,2.2,,,,1-1 -US-Dia,SW_OUT,,2.2,,,,1-1 -US-Dia,TA,,2.2,,,,1-1 -US-Dia,TS_1,,-0,,,,1-1 -US-Dia,TS_2,,-0.05,,,,1-1 -US-Dia,USTAR,,2.1,,,,1-1 -US-Dia,VPD_PI_PI,,2.2,,,,1-1 -US-Dix,CO2_1,,17,,,,2-1 -US-Dix,FC,,17,,,,2-1 -US-Dix,G,,-0.1,,,,2-1 -US-Dix,H,,17,,,,2-1 -US-Dix,LE,,17,,,,2-1 -US-Dix,NETRAD,,15,,,,2-1 -US-Dix,PPFD_IN,,15,,,,2-1 -US-Dix,RH,,15,,,,2-1 -US-Dix,SW_IN,,15,,,,2-1 -US-Dix,TA,,15,,,,2-1 -US-Dix,TS_1,,-0.05,,,,2-1 -US-Dix,VPD_PI_PI,,15,,,,2-1 -US-Dix,WD,,15,,,,2-1 -US-Dix,WS,,15,,,,2-1 -US-Dk1,CO2_1_1_1,,2.8,,,,4-5 -US-Dk1,CO2_2_1_1,,2.8,,,,4-5 -US-Dk1,FC,,2.8,,,,4-5 -US-Dk1,FC_PI_F,,2.8,,,,4-5 -US-Dk1,FH2O,,2.8,,,,4-5 -US-Dk1,FH2O_PI_F,,2.8,,,,4-5 -US-Dk1,G,,-0.05,,,,4-5 -US-Dk1,H,,2.8,,,,4-5 -US-Dk1,H_PI_F,,2.8,,,,4-5 -US-Dk1,LE,,2.8,,,,4-5 -US-Dk1,LE_PI_F,,2.8,,,,4-5 -US-Dk1,NETRAD,,1.9,,,,4-5 -US-Dk1,P,,1.9,,,,4-5 -US-Dk1,PPFD_IN,,1.9,,,,4-5 -US-Dk1,PPFD_IN_PI_F,,1.9,,,,4-5 -US-Dk1,RH,,2.8,,,,4-5 -US-Dk1,RH_PI_F,,2.8,,,,4-5 -US-Dk1,SWC_1_1_1,,-0.1,,,,4-5 -US-Dk1,SWC_1_2_1,,-0.25,,,,4-5 -US-Dk1,TA,,2.8,,,,4-5 -US-Dk1,TA_PI_F,,2.8,,,,4-5 -US-Dk1,TS_1_1_1,,-0.1,,,,4-5 -US-Dk1,TS_1_2_1,,-0.25,,,,4-5 -US-Dk1,WS,,2.8,,,,4-5 -US-Dk1,WS_PI_F,,2.8,,,,4-5 -US-Dk2,CO2_1_1_1,,39.8,,,,4-5 -US-Dk2,CO2_2_1_1,,39.8,GA-Other,,ling point is reported CO2 in,4-5 -US-Dk2,FC,,39.8,,,,4-5 -US-Dk2,FC_PI_F,,39.8,,,,4-5 -US-Dk2,FH2O,,39.8,,,,4-5 -US-Dk2,FH2O_PI_F,,39.8,,,,4-5 -US-Dk2,G,,-0.05,,,,4-5 -US-Dk2,H,,39.8,,,,4-5 -US-Dk2,H_PI_F,,39.8,,,,4-5 -US-Dk2,LE,,39.8,,,,4-5 -US-Dk2,LE_PI_F,,39.8,,,,4-5 -US-Dk2,SWC_1_1_1,,-0.1,,,,4-5 -US-Dk2,SWC_1_2_1,,-0.25,,,,4-5 -US-Dk2,TS_1_1_1,,-0.1,,,,4-5 -US-Dk2,TS_1_2_1,,-0.25,,,,4-5 -US-Dk3,CO2_1_1_1,,20.2,,,,4-5 -US-Dk3,CO2_2_1_1,,20.2,,,,4-5 -US-Dk3,FC,,20.2,,,,4-5 -US-Dk3,FC_PI_F,,20.2,,,,4-5 -US-Dk3,FH2O,,20.2,,,,4-5 -US-Dk3,FH2O_PI_F,,20.2,,,,4-5 -US-Dk3,G,,-0.05,,,,4-5 -US-Dk3,H,,20.2,,,,4-5 -US-Dk3,H2O,,20.2,,,,4-5 -US-Dk3,H_PI_F,,20.2,,,,4-5 -US-Dk3,LE,,20.2,,,,4-5 -US-Dk3,LE_PI_F,,20.2,,,,4-5 -US-Dk3,LW_IN,,20.2,,,,4-5 -US-Dk3,LW_IN_PI_F,,20.2,,,,4-5 -US-Dk3,LW_OUT,,20.2,,,,4-5 -US-Dk3,LW_OUT_PI_F,,20.2,,,,4-5 -US-Dk3,NETRAD,,20.2,,,,4-5 -US-Dk3,P,,20.2,,,,4-5 -US-Dk3,PPFD_IN,,20.2,,,,4-5 -US-Dk3,PPFD_IN_PI_F,,20.2,,,,4-5 -US-Dk3,RH,,20.2,,,,4-5 -US-Dk3,RH_PI_F,,20.2,,,,4-5 -US-Dk3,SW_IN,,20.2,,,,4-5 -US-Dk3,SW_IN_PI_F,,20.2,,,,4-5 -US-Dk3,SW_OUT,,20.2,,,,4-5 -US-Dk3,SW_OUT_PI_F,,20.2,,,,4-5 -US-Dk3,TA,,20.2,,,,4-5 -US-Dk3,TA_PI_F,,20.2,,,,4-5 -US-Dk3,TS_1_2_1,,-0.1,,,,4-5 -US-Dk3,TS_1_3_1,,-0.3,,,,4-5 -US-Dk3,WS,,20.2,,,,4-5 -US-Dk3,WS_PI_F,,20.2,,,,4-5 -US-DPW,FC,,2,GA_OP-LI-COR LI-7500A,SA-Campbell CSAT-3,,1-5 -US-EDN,CH4,,4.34,GA_OP-LI-COR LI-7700,,,2-5 -US-EDN,CO2,,4.34,GA_OP-LI-COR LI-7500RS,,,2-5 -US-EDN,FC,,4.34,GA_OP-LI-COR LI-7500RS,SA-Gill Windmaster Pro,,2-5 -US-EDN,FCH4,,4.34,GA_OP-LI-COR LI-7700,SA-Gill Windmaster Pro,,2-5 -US-EDN,H,,4.34,SA-Gill Windmaster Pro,,,2-5 -US-EDN,H2O,,4.34,GA_OP-LI-COR LI-7500RS,,,2-5 -US-EDN,LE,,4.34,GA_OP-LI-COR LI-7500RS,SA-Gill Windmaster Pro,,2-5 -US-EDN,LW_IN,,4.34,RAD-Pyrrad-SW+LW,,,2-5 -US-EDN,LW_OUT,,4.34,RAD-Pyrrad-SW+LW,,,2-5 -US-EDN,MO_LENGTH,,4.34,SA-Gill Windmaster Pro,,,2-5 -US-EDN,NETRAD,,4.34,RAD-Pyrrad-SW+LW,,,2-5 -US-EDN,P,,4.34,RAIN-TipBucGauge,,,2-5 -US-EDN,PA,,4.34,GA_OP-LI-COR LI-7700,,,2-5 -US-EDN,PPFD_IN,,4.34,RAD-PAR Quantum,,,2-5 -US-EDN,RH,,4.34,RH-Capac,,,2-5 -US-EDN,SW_IN,,4.34,RAD-Pyrrad-SW+LW,,,2-5 -US-EDN,SW_OUT,,4.34,RAD-Pyrrad-SW+LW,,,2-5 -US-EDN,TA,,4.34,TEMP-ElectResis,,,2-5 -US-EDN,TAU,,4.34,SA-Gill Windmaster Pro,,,2-5 -US-EDN,TS_1,,,TEMP-TCouple,,Temperature of air or water at height 0.3m,2-5 -US-EDN,TS_2,,,TEMP-TCouple,,Temperature of air or water at height 0.2m,2-5 -US-EDN,TS_3,,,TEMP-TCouple,,Temperature of air or water at height 0.1m,2-5 -US-EDN,TS_4,,,TEMP-TCouple,,Temperature of air or water at height 0.05m,2-5 -US-EDN,TS_5,,-0,TEMP-TCouple,,,2-5 -US-EDN,TS_6,,-0.05,TEMP-TCouple,,,2-5 -US-EDN,TS_7,,-0.15,TEMP-TCouple,,,2-5 -US-EDN,TS_8,,-0.25,TEMP-TCouple,,,2-5 -US-EDN,T_SONIC,,4.34,SA-Gill Windmaster Pro,,,2-5 -US-EDN,T_SONIC_SIGMA,,4.34,SA-Gill Windmaster Pro,,,2-5 -US-EDN,USTAR,,4.34,SA-Gill Windmaster Pro,,,2-5 -US-EDN,VPD_PI,,4.34,GA_OP-LI-COR LI-7500RS,,,2-5 -US-EDN,V_SIGMA,,4.34,SA-Gill Windmaster Pro,,,2-5 -US-EDN,WD,,4.34,SA-Gill Windmaster Pro,,,2-5 -US-EDN,WS,,4.34,SA-Gill Windmaster Pro,,,2-5 -US-EDN,W_SIGMA,,4.34,SA-Gill Windmaster Pro,,,2-5 -US-EDN,WTD,,,WTD-Press,,,2-5 -US-EDN,ZL,,4.34,SA-Gill Windmaster Pro,,,2-5 -US-Elm,CO2_1,,3.3,,,,4-1 -US-Elm,FC,,3.3,,,,4-1 -US-Elm,G,,-0.1,,,,4-1 -US-Elm,H,,3.3,,,,4-1 -US-Elm,H2O,,3.3,,,,4-1 -US-Elm,LE,,3.3,,,,4-1 -US-Elm,NETRAD,,3.3,,,,4-1 -US-Elm,PPFD_IN,,3.3,,,,4-1 -US-Elm,RH,,3.3,,,,4-1 -US-Elm,SW_IN,,3.3,,,,4-1 -US-Elm,SW_OUT,,3.3,,,,4-1 -US-Elm,TA,,3.3,,,,4-1 -US-Elm,TS_1,,-0.05,,,,4-1 -US-Elm,TS_2,,-0.1,,,,4-1 -US-Elm,USTAR,,3.3,,,,4-1 -US-Elm,VPD_PI_PI,,3.3,,,,4-1 -US-Elm,WD,,3.3,,,,4-1 -US-Elm,WS,,3.3,,,,4-1 -US-EML,CO2,,3.64,GA_OP-LI-COR LI-7500A,,,4-5 -US-EML,FC,,3.64,GA_OP-LI-COR LI-7500A,,,4-5 -US-Esm,CO2_1,,3.3,,,,5-1 -US-Esm,FC,,3.3,,,,5-1 -US-Esm,G,,-0.1,,,,5-1 -US-Esm,H,,3.3,,,,5-1 -US-Esm,H2O,,3.3,,,,5-1 -US-Esm,LE,,3.3,,,,5-1 -US-Esm,NETRAD,,3.3,,,,5-1 -US-Esm,PPFD_IN,,3.3,,,,5-1 -US-Esm,RH,,3.3,,,,5-1 -US-Esm,SW_IN,,3.3,,,,5-1 -US-Esm,SW_OUT,,3.3,,,,5-1 -US-Esm,TA,,3.3,,,,5-1 -US-Esm,TS_1,,-0.05,,,,5-1 -US-Esm,TS_2,,-0.1,,,,5-1 -US-Esm,USTAR,,3.3,,,,5-1 -US-Esm,VPD_PI_PI,,3.3,,,,5-1 -US-Esm,WD,,3.3,,,,5-1 -US-Esm,WS,,3.3,,,,5-1 -US-Fcr,FC,20110527,1.85,SA-Young 81000,GA_OP-LI-COR LI-7500,,2-5 -US-Fcr,FC,20110912,1.85,SA-Campbell CSAT-3A,GA_OP-Campbell EC150,,2-5 -US-Fcr,G_1_1_1,,-0.01,SOIL_H-Plate,,,2-5 -US-Fcr,G_1_1_2,,-0.01,SOIL_H-Plate,,,2-5 -US-Fcr,G_1_1_3,,-0.01,SOIL_H-Plate,,,2-5 -US-Fcr,G_1_1_4,,-0.01,SOIL_H-Plate,,,2-5 -US-Fcr,G_1_1_5,,-0.01,SOIL_H-Plate,,,2-5 -US-Fcr,G_1_1_6,,-0.01,SOIL_H-Plate,,,2-5 -US-Fcr,G_1_1_7,,-0.01,SOIL_H-Plate,,,2-5 -US-Fcr,G_1_1_8,,-0.01,SOIL_H-Plate,,,2-5 -US-Fcr,G_1_1_9,,-0.01,SOIL_H-Plate,,,2-5 -US-Fcr,H,20110527,1.85,SA-Young 81000,,,2-5 -US-Fcr,H,20110912,1.85,SA-Campbell CSAT-3A,,,2-5 -US-Fcr,LE,20110527,1.85,SA-Young 81000,GA_OP-LI-COR LI-7500,,2-5 -US-Fcr,LE,20110912,1.85,SA-Campbell CSAT-3A,GA_OP-Campbell EC150,,2-5 -US-Fcr,NETRAD_1_1_1,,2.2,RAD-Net radiometer,,,2-5 -US-Fcr,PA,,0.5,PRES-ElectBar,,,2-5 -US-Fcr,PPFD_IN,,2.2,RAD-PAR Quantum,,,2-5 -US-Fcr,PPFD_OUT,,2.2,RAD-PAR Quantum,,,2-5 -US-Fcr,P_RAIN,,1,RAIN-TipBucGauge,,,2-5 -US-Fcr,RH_1_1_1,,2.3,RH-Capac,,,2-5 -US-Fcr,RH_1_2_1,,1,RH-Capac,,,2-5 -US-Fcr,SWC_1_1_1,,-0.15,SWC-TDR,,,2-5 -US-Fcr,SWC_1_1_2,,-0.15,SWC-TDR,,,2-5 -US-Fcr,SWC_1_2_1,,-0.15,SWC-TDR,,,2-5 -US-Fcr,SW_IN_1_1_1,,2.2,RAD-Pyrrad-SW+LW,,,2-5 -US-Fcr,SW_OUT_1_1_1,,2.2,RAD-Pyrrad-SW+LW,,,2-5 -US-Fcr,TA_1_1_1,,2.3,TEMP-ElectResis,,,2-5 -US-Fcr,TA_1_2_1,,1,TEMP-ElectResis,,,2-5 -US-Fcr,TS_1_1_1,,-0.05,TEMP-TCouple,,,2-5 -US-Fcr,TS_1_2_1,,-0.1,TEMP-TCouple,,,2-5 -US-Fcr,TS_1_3_1,,-0.2,TEMP-TCouple,,,2-5 -US-Fcr,TS_1_4_1,,-0.4,TEMP-TCouple,,,2-5 -US-Fcr,TS_1_5_1,,-0.8,TEMP-TCouple,,,2-5 -US-Fcr,USTAR,20110527,1.85,SA-Young 81000,,,2-5 -US-Fcr,USTAR,20110912,1.85,SA-Campbell CSAT-3A,,,2-5 -US-Fcr,WS_1_1_1,20110527,1.85,SA-Young 81000,,,2-5 -US-Fcr,WS_1_1_1,20110912,1.85,SA-Campbell CSAT-3A,,,2-5 -US-Fmf,CO2,,23,,,,6-5 -US-Fmf,FC,,23,,,,6-5 -US-Fmf,H,,23,,,,6-5 -US-Fmf,LE,,23,,,,6-5 -US-Fmf,SWC_1_1_1,,-0.02,,,,6-5 -US-Fmf,SWC_1_2_1,,-0.1,,,,6-5 -US-Fmf,TS_1_1_1,,-0.02,,,,6-5 -US-Fmf,TS_1_2_1,,-0.1,,,,6-5 -US-Fmf,WS,,23,,,,6-5 -US-FPe,FC,,3.5,,,,2-1 -US-FPe,H,,3.5,,,,2-1 -US-FPe,LE,,3.5,,,,2-1 -US-FPe,TA,,2,,,,2-1 -US-FPe,WD,,3.5,,,,2-1 -US-FPe,WS,,3.5,,,,2-1 -US-FR2,CO2_1,,7.97,,,,2-1 -US-FR2,FC,,7.97,,,,2-1 -US-FR2,H,,7.97,,,,2-1 -US-FR2,LE,,7.97,,,,2-1 -US-FR2,SWC_1,,-0.02,,,,2-1 -US-FR2,TS_1,,-0.02,,,,2-1 -US-FR3,CO2_1,,14,,,,1-1 -US-FR3,FC,,14,,,,1-1 -US-FR3,G,,-0.05,,,,1-1 -US-FR3,H,,14,,,,1-1 -US-FR3,H2O,,14,,,,1-1 -US-FR3,LE,,14,,,,1-1 -US-FR3,LW_IN,,14,,,,1-1 -US-FR3,LW_OUT,,14,,,,1-1 -US-FR3,NETRAD,,14,,,,1-1 -US-FR3,PA,,14,,,,1-1 -US-FR3,PPFD_IN,,14,,,,1-1 -US-FR3,RH,,14,,,,1-1 -US-FR3,SWC_1,,-0.1,,,,1-1 -US-FR3,SWC_2,,-0.2,,,,1-1 -US-FR3,SW_IN,,14,,,,1-1 -US-FR3,SW_OUT,,14,,,,1-1 -US-FR3,TA,,14,,,,1-1 -US-FR3,TS_1,,-0.02,,,,1-1 -US-FR3,TS_2,,-0.1,,,,1-1 -US-FR3,USTAR,,14,,,,1-1 -US-FR3,VPD_PI_PI,,14,,,,1-1 -US-FR3,WD,,14,,,,1-1 -US-FR3,WS,,14,,,,1-1 -US-Fuf,CO2,,23,,,,6-5 -US-Fuf,FC,,23,,,,6-5 -US-Fuf,H,,23,,,,6-5 -US-Fuf,LE,,23,,,,6-5 -US-Fuf,SWC_1_1_1,,-0.02,,,,6-5 -US-Fuf,SWC_1_2_1,,-0.1,,,,6-5 -US-Fuf,TS_1_1_1,,-0.02,,,,6-5 -US-Fuf,TS_1_2_1,,-0.1,,,,6-5 -US-Fuf,WS,,23,,,,6-5 -US-Fwf,G,,-0.08,,,,8-5 -US-Fwf,LW_IN,,2,,,,8-5 -US-Fwf,LW_OUT,,2,,,,8-5 -US-Fwf,NETRAD,,2,,,,8-5 -US-Fwf,PPFD_DIF,,2,,,,8-5 -US-Fwf,PPFD_IN,,2,,,,8-5 -US-Fwf,PPFD_OUT,,2,,,,8-5 -US-Fwf,RH,,2,,,,8-5 -US-Fwf,SWC_1_1_1,,-0.02,,,,8-5 -US-Fwf,SWC_1_2_1,,-0.1,,,,8-5 -US-Fwf,SW_IN,,2,,,,8-5 -US-Fwf,SW_OUT,,2,,,,8-5 -US-Fwf,TA,,2,,,,8-5 -US-Fwf,TS_1_1_1,,-0.02,,,,8-5 -US-Fwf,TS_1_2_1,,-0.1,,,,8-5 -US-Fwf,VPD_PI,,2,,,,8-5 -US-Fwf,WD,,2,,,,8-5 -US-Fwf,WS,,2,,,,8-5 -US-GBT,CO2_1,,27.12,,,,1-1 -US-GBT,FC,,27.12,,,,1-1 -US-GBT,G,,-0,,,,1-1 -US-GBT,H,,27.12,,,,1-1 -US-GBT,H2O,,27.12,,,,1-1 -US-GBT,LE,,27.12,,,,1-1 -US-GBT,LW_IN,,28.7,,,,1-1 -US-GBT,LW_OUT,,28.7,,,,1-1 -US-GBT,NETRAD,,28.7,,,,1-1 -US-GBT,PA,,27.4,,,,1-1 -US-GBT,PPFD_IN,,27.9,,,,1-1 -US-GBT,PPFD_OUT,,27.5,,,,1-1 -US-GBT,RH,,27.8,,,,1-1 -US-GBT,SWC_1,,-0.05,,,,1-1 -US-GBT,SWC_2,,-0.1,,,,1-1 -US-GBT,SW_IN,,28.7,,,,1-1 -US-GBT,SW_OUT,,28.7,,,,1-1 -US-GBT,TA,,27.8,,,,1-1 -US-GBT,TS_1,,-0.05,,,,1-1 -US-GBT,TS_2,,-0.1,,,,1-1 -US-GBT,USTAR,,27.12,,,,1-1 -US-GBT,VPD_PI_PI,,27.8,,,,1-1 -US-GBT,WD,,30.2,,,,1-1 -US-GBT,WS,,30.2,,,,1-1 -US-GLE,CO2_1_1_1,,22.65,GA_CP-LI-COR LI-7000,,,8-5 -US-GLE,CO2_2_1_1,,27.12,GA_SR-LI-COR LI-800,,,8-5 -US-GLE,CO2_PI_F_1_1_1,,22.65,GA_CP-LI-COR LI-7000,,,8-5 -US-GLE,CO2_PI_F_2_1_1,,27.12,GA_SR-LI-COR LI-800,,,8-5 -US-GLE,D_SNOW,,3.12,SNOW-Acoustic,,,8-5 -US-GLE,D_SNOW_PI_F,,3.12,SNOW-Acoustic,,,8-5 -US-GLE,FC_1_1_1,,22.65,GA_OP-LI-COR LI-7500,SA-ATI Vx Style,,8-5 -US-GLE,FC_1_1_2,,22.65,GA_CP-LI-COR LI-7200RS,SA-ATI Vx Style,,8-5 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-US-GLE,LE_PI_F_2_1_2,,26.97,SA-ATI Vx Style,GA_OP-Krypton Hygrometer,,8-5 -US-GLE,LE_PI_F_2_1_3,,27.15,SA-ATI Vx Style,GA_OP-LI-COR LI-7500,,8-5 -US-GLE,LW_BC_IN,,6.5,RAD-Pyrrad-SW+LW,,,8-5 -US-GLE,LW_BC_OUT,,6.5,RAD-Pyrrad-SW+LW,,,8-5 -US-GLE,LW_IN_1_1_1,,24.4,RAD-LW Pyrgeom,,,8-5 -US-GLE,LW_IN_1_1_2,,24.4,RAD-Pyrrad-SW+LW,,,8-5 -US-GLE,LW_IN_2_1_1,,28.7,RAD-LW Pyrgeom,,,8-5 -US-GLE,LW_IN_PI_F_1_1_1,,24.4,RAD-LW Pyrgeom,,,8-5 -US-GLE,LW_IN_PI_F_2_1_1,,28.7,RAD-LW Pyrgeom,,,8-5 -US-GLE,LW_OUT_1_1_1,,24.4,RAD-LW Pyrgeom,,,8-5 -US-GLE,LW_OUT_1_1_2,,24.4,RAD-Pyrrad-SW+LW,,,8-5 -US-GLE,LW_OUT_2_1_1,,28.7,RAD-LW Pyrgeom,,,8-5 -US-GLE,LW_OUT_PI_F_1_1_1,,24.4,RAD-LW Pyrgeom,,,8-5 -US-GLE,LW_OUT_PI_F_2_1_1,,28.7,RAD-LW Pyrgeom,,,8-5 -US-GLE,NEE_PI_1_1_1,,22.65,SA-ATI Vx Style,GA_OP-LI-COR LI-7500,,8-5 -US-GLE,NEE_PI_1_1_2,,22.65,SA-ATI Vx Style,GA_CP-LI-COR LI-7200RS,,8-5 -US-GLE,NEE_PI_1_2_1,,6.5,SA-ATI Vx Style,GA_OP-LI-COR LI-7500,,8-5 -US-GLE,NEE_PI_F_1_1_1,,22.65,SA-ATI Vx Style,GA_OP-LI-COR LI-7500,,8-5 -US-GLE,NEE_PI_F_1_2_1,,6.5,SA-ATI Vx Style,GA_OP-LI-COR LI-7500,,8-5 -US-GLE,NETRAD_1_1_1,,24.4,RAD-Net radiometer,,,8-5 -US-GLE,NETRAD_1_1_2,,24.4,RAD-SW Pyran SecSt,,,8-5 -US-GLE,NETRAD_2_1_1,,26.8,RAD-Net radiometer,,,8-5 -US-GLE,NETRAD_2_1_2,,28.7,RAD-SW Pyran SecSt,,,8-5 -US-GLE,NETRAD_PI_F_1_1_1,,24.4,RAD-Net radiometer,,,8-5 -US-GLE,NETRAD_PI_F_1_1_2,,24.4,RAD-SW Pyran SecSt,,,8-5 -US-GLE,NETRAD_PI_F_2_1_1,,26.8,RAD-Net radiometer,,,8-5 -US-GLE,NETRAD_PI_F_2_1_2,,28.7,RAD-SW Pyran SecSt,,,8-5 -US-GLE,P,,1.5,PREC-WeightGauge,,,8-5 -US-GLE,PA_1_1_1,,23.4,PRES-ElectBar,,,8-5 -US-GLE,PA_2_1_1,,27.4,PRES-ElectBar,,,8-5 -US-GLE,PA_PI_F_1_1_1,,23.4,PRES-ElectBar,,,8-5 -US-GLE,PA_PI_F_2_1_1,,27.4,PRES-ElectBar,,,8-5 -US-GLE,P_PI_F,,1.5,PREC-WeightGauge,,,8-5 -US-GLE,PPFD_IN_1_1_1,,24.4,RAD-PAR Quantum,,,8-5 -US-GLE,PPFD_IN_2_1_1,,27.9,RAD-PAR Quantum,,,8-5 -US-GLE,PPFD_IN_PI_F_1_1_1,,24.4,RAD-PAR Quantum,,,8-5 -US-GLE,PPFD_IN_PI_F_2_1_1,,27.9,RAD-PAR Quantum,,,8-5 -US-GLE,PPFD_OUT_1_1_1,,24.4,RAD-PAR Quantum,,,8-5 -US-GLE,PPFD_OUT_2_1_1,,27.9,RAD-PAR Quantum,,,8-5 -US-GLE,PPFD_OUT_PI_F_1_1_1,,24.4,RAD-PAR Quantum,,,8-5 -US-GLE,PPFD_OUT_PI_F_2_1_1,,27.9,RAD-PAR Quantum,,,8-5 -US-GLE,RH_1_1_1,,23.4,RH-Capac,,,8-5 -US-GLE,RH_1_2_1,,6.5,RH-Capac,,,8-5 -US-GLE,RH_2_1_1,,27.8,RH-Capac,,,8-5 -US-GLE,RH_PI_F_1_1_1,,23.4,RH-Capac,,,8-5 -US-GLE,RH_PI_F_2_1_1,,27.8,RH-Capac,,,8-5 -US-GLE,SC_1_1_1,,22.65,GA_CP-LI-COR LI-7000,,,8-5 -US-GLE,SC_1_2_1,,6.5,GA_CP-LI-COR LI-7000,,,8-5 -US-GLE,SC_PI_F_1_1_1,,22.65,GA_CP-LI-COR LI-7000,,,8-5 -US-GLE,SC_PI_F_1_2_1,,6.5,GA_CP-LI-COR LI-7000,,,8-5 -US-GLE,SW_BC_IN,,6.5,RAD-Pyrrad-SW+LW,,,8-5 -US-GLE,SW_BC_OUT,,6.5,RAD-Pyrrad-SW+LW,,,8-5 -US-GLE,SWC_1_1_1,,-0.05,SWC-FDR,,,8-5 -US-GLE,SWC_1_1_2,,-0.05,SWC-TDR,,,8-5 -US-GLE,SWC_1_2_1,,-0.1,SWC-FDR,,,8-5 -US-GLE,SWC_1_2_2,,-0.1,SWC-TDR,,,8-5 -US-GLE,SWC_1_3_1,,-0.2,SWC-FDR,,,8-5 -US-GLE,SWC_1_3_2,,-0.2,SWC-FDR,,,8-5 -US-GLE,SWC_1_4_1,,-0.51,SWC-FDR,,,8-5 -US-GLE,SWC_1_5_1,,-1.02,SWC-FDR,,,8-5 -US-GLE,SWC_2_1_1,,-0.05,SWC-FDR,,,8-5 -US-GLE,SWC_2_1_2,,-0.05,SWC-TDR,,,8-5 -US-GLE,SWC_2_2_1,,-0.1,SWC-FDR,,,8-5 -US-GLE,SWC_2_2_2,,-0.1,SWC-TDR,,,8-5 -US-GLE,SWC_2_3_1,,-0.2,SWC-FDR,,,8-5 -US-GLE,SWC_2_3_2,,-0.2,SWC-TDR,,,8-5 -US-GLE,SWC_2_4_1,,-0.51,SWC-FDR,,,8-5 -US-GLE,SWC_2_5_1,,-1.02,SWC-FDR,,,8-5 -US-GLE,SWC_3_1_1,,-0.05,SWC-TDR,,,8-5 -US-GLE,SWC_3_2_1,,-0.1,SWC-TDR,,,8-5 -US-GLE,SWC_3_3_1,,-0.2,SWC-TDR,,,8-5 -US-GLE,SWC_4_1_1,,-0.05,SWC-TDR,,,8-5 -US-GLE,SWC_4_2_1,,-0.1,SWC-TDR,,,8-5 -US-GLE,SWC_4_3_1,,-0.2,SWC-TDR,,,8-5 -US-GLE,SWC_5_1_1,,-0.05,SWC-FDR,,,8-5 -US-GLE,SWC_5_2_1,,-0.1,SWC-FDR,,,8-5 -US-GLE,SWC_5_3_1,,-0.2,SWC-FDR,,,8-5 -US-GLE,SWC_6_1_1,,-0.05,SWC-TDR,,,8-5 -US-GLE,SWC_6_2_1,,-0.1,SWC-TDR,,,8-5 -US-GLE,SWC_6_3_1,,-0.2,SWC-TDR,,,8-5 -US-GLE,SWC_7_1_1,,-0.05,SWC-FDR,,,8-5 -US-GLE,SWC_7_2_1,,-0.1,SWC-FDR,,,8-5 -US-GLE,SWC_7_3_1,,-0.2,SWC-FDR,,,8-5 -US-GLE,SW_IN_1_1_1,,24.4,RAD-SW Pyran SecSt,,,8-5 -US-GLE,SW_IN_1_1_2,,24.4,RAD-Pyrrad-SW+LW,,,8-5 -US-GLE,SW_IN_2_1_1,,28.7,RAD-SW Pyran SecSt,,,8-5 -US-GLE,SW_IN_PI_F_1_1_1,,24.4,RAD-SW Pyran SecSt,,,8-5 -US-GLE,SW_IN_PI_F_2_1_1,,28.7,RAD-SW Pyran SecSt,,,8-5 -US-GLE,SW_OUT_1_1_1,,24.4,RAD-SW Pyran SecSt,,,8-5 -US-GLE,SW_OUT_1_1_2,,24.4,RAD-Pyrrad-SW+LW,,,8-5 -US-GLE,SW_OUT_2_1_1,,28.7,RAD-SW Pyran SecSt,,,8-5 -US-GLE,SW_OUT_PI_F_1_1_1,,24.4,RAD-SW Pyran SecSt,,,8-5 -US-GLE,SW_OUT_PI_F_2_1_1,,28.7,RAD-SW Pyran SecSt,,,8-5 -US-GLE,TA_1_1_1,,23.4,TEMP-ElectResis,,,8-5 -US-GLE,TA_1_2_1,,6.5,TEMP-ElectResis,,,8-5 -US-GLE,TA_1_2_2,,6.5,TEMP-Thermis,,,8-5 -US-GLE,TA_2_1_1,,27.8,TEMP-Thermis,,,8-5 -US-GLE,TA_PI_F_1_1_1,,23.4,TEMP-ElectResis,,,8-5 -US-GLE,TA_PI_F_2_1_1,,27.8,TEMP-Thermis,,,8-5 -US-GLE,TAU_1_1_1,,22.65,SA-ATI Vx Style,,,8-5 -US-GLE,TAU_1_2_1,,6.5,SA-ATI Vx Style,,,8-5 -US-GLE,TAU_2_1_1,,27.12,SA-ATI Vx Style,,,8-5 -US-GLE,TAU_PI_F_1_1_1,,22.65,SA-ATI Vx Style,,,8-5 -US-GLE,TAU_PI_F_1_2_1,,6.5,SA-ATI Vx Style,,,8-5 -US-GLE,TAU_PI_F_2_1_1,,27.12,SA-ATI Vx Style,,,8-5 -US-GLE,T_CANOPY_1_1_1,,25.2,TEMP-Other,,,8-5 -US-GLE,T_CANOPY_1_2_1,,3.4,TEMP-Other,,,8-5 -US-GLE,TS_1_1_1,,-0.03,TEMP-TCouple,,,8-5 -US-GLE,TS_1_1_2,,-0.03,TEMP-TCouple,,,8-5 -US-GLE,TS_1_2_1,,-0.05,TEMP-Thermis,,,8-5 -US-GLE,TS_1_3_1,,-0.09,TEMP-TCouple,,,8-5 -US-GLE,TS_1_3_2,,-0.09,TEMP-TCouple,,,8-5 -US-GLE,TS_1_4_1,,-0.1,TEMP-Thermis,,,8-5 -US-GLE,TS_1_5_1,,-0.2,TEMP-Thermis,,,8-5 -US-GLE,TS_1_6_1,,-0.51,TEMP-Thermis,,,8-5 -US-GLE,TS_1_7_1,,-1.02,TEMP-Thermis,,,8-5 -US-GLE,TS_2_1_1,,-0.05,TEMP-Thermis,,,8-5 -US-GLE,TS_2_2_1,,-0.1,TEMP-Thermis,,,8-5 -US-GLE,TS_2_3_1,,-0.2,TEMP-Thermis,,,8-5 -US-GLE,TS_2_4_1,,-0.51,TEMP-Thermis,,,8-5 -US-GLE,TS_2_5_1,,-1.02,TEMP-Thermis,,,8-5 -US-GLE,TS_3_1_1,,-0.0001,TEMP-TCouple,,,8-5 -US-GLE,TS_3_2_1,,-0.01,TEMP-TCouple,,,8-5 -US-GLE,TS_3_3_1,,-0.03,TEMP-TCouple,,,8-5 -US-GLE,TS_3_4_1,,-0.07,TEMP-TCouple,,,8-5 -US-GLE,TS_3_5_1,,-0.13,TEMP-TCouple,,,8-5 -US-GLE,TS_3_6_1,,-0.27,TEMP-TCouple,,,8-5 -US-GLE,TS_4_1_1,,-0.0001,TEMP-TCouple,,,8-5 -US-GLE,TS_4_2_1,,-0.01,TEMP-TCouple,,,8-5 -US-GLE,TS_4_3_1,,-0.03,TEMP-TCouple,,,8-5 -US-GLE,TS_4_4_1,,-0.07,TEMP-TCouple,,,8-5 -US-GLE,TS_4_5_1,,-0.13,TEMP-TCouple,,,8-5 -US-GLE,TS_4_6_1,,-0.27,TEMP-TCouple,,,8-5 -US-GLE,TS_5_1_1,,-0.0001,TEMP-TCouple,,,8-5 -US-GLE,TS_5_2_1,,-0.01,TEMP-TCouple,,,8-5 -US-GLE,TS_5_3_1,,-0.03,TEMP-TCouple,,,8-5 -US-GLE,TS_5_4_1,,-0.07,TEMP-TCouple,,,8-5 -US-GLE,TS_5_5_1,,-0.13,TEMP-TCouple,,,8-5 -US-GLE,TS_5_6_1,,-0.27,TEMP-TCouple,,,8-5 -US-GLE,TS_6_1_1,,-0.0001,TEMP-TCouple,,,8-5 -US-GLE,TS_6_2_1,,-0.01,TEMP-TCouple,,,8-5 -US-GLE,TS_6_3_1,,-0.03,TEMP-TCouple,,,8-5 -US-GLE,TS_6_4_1,,-0.07,TEMP-TCouple,,,8-5 -US-GLE,TS_6_5_1,,-0.13,TEMP-TCouple,,,8-5 -US-GLE,TS_6_6_1,,-0.27,TEMP-TCouple,,,8-5 -US-GLE,TSN_1_1_1,,2.0,TEMP-TCouple,,,8-5 -US-GLE,TSN_1_2_1,,1.6,TEMP-TCouple,,,8-5 -US-GLE,TSN_1_3_1,,1.2,TEMP-TCouple,,,8-5 -US-GLE,TSN_1_4_1,,0.8,TEMP-TCouple,,,8-5 -US-GLE,TSN_1_5_1,,0.4,TEMP-TCouple,,,8-5 -US-GLE,TSN_2_1_1,,2.0,TEMP-TCouple,,,8-5 -US-GLE,TSN_2_2_1,,1.6,TEMP-TCouple,,,8-5 -US-GLE,TSN_2_3_1,,1.2,TEMP-TCouple,,,8-5 -US-GLE,TSN_2_4_1,,0.8,TEMP-TCouple,,,8-5 -US-GLE,TSN_2_5_1,,0.4,TEMP-TCouple,,,8-5 -US-GLE,TSN_3_1_1,,2.0,TEMP-TCouple,,,8-5 -US-GLE,TSN_3_2_1,,1.6,TEMP-TCouple,,,8-5 -US-GLE,TSN_3_3_1,,1.2,TEMP-TCouple,,,8-5 -US-GLE,TSN_3_4_1,,0.8,TEMP-TCouple,,,8-5 -US-GLE,TSN_3_5_1,,0.4,TEMP-TCouple,,,8-5 -US-GLE,TSN_4_1_1,,2.0,TEMP-TCouple,,,8-5 -US-GLE,TSN_4_2_1,,1.6,TEMP-TCouple,,,8-5 -US-GLE,TSN_4_3_1,,1.2,TEMP-TCouple,,,8-5 -US-GLE,TSN_4_4_1,,0.8,TEMP-TCouple,,,8-5 -US-GLE,TSN_4_5_1,,0.4,TEMP-TCouple,,,8-5 -US-GLE,USTAR_1_1_1,,22.65,SA-ATI Vx Style,,,8-5 -US-GLE,USTAR_1_2_1,,6.5,SA-ATI Vx Style,,,8-5 -US-GLE,USTAR_2_1_1,,27.12,SA-ATI Vx Style,,,8-5 -US-GLE,USTAR_PI_F_1_1_1,,22.65,SA-ATI Vx Style,,,8-5 -US-GLE,USTAR_PI_F_1_2_1,,6.5,SA-ATI Vx Style,,,8-5 -US-GLE,USTAR_PI_F_2_1_1,,27.12,SA-ATI Vx Style,,,8-5 -US-GLE,VPD_PI_1_1_1,,23.4,RH-Capac,,,8-5 -US-GLE,VPD_PI_2_1_1,,27.8,RH-Capac,,,8-5 -US-GLE,VPD_PI_F_1_1_1,,23.4,RH-Capac,,,8-5 -US-GLE,VPD_PI_F_2_1_1,,27.8,RH-Capac,,,8-5 -US-GLE,WD_1_1_1,,25.8,WIND-VaneAn,,,8-5 -US-GLE,WD_1_2_1,,22.65,SA-ATI Vx Style,,,8-5 -US-GLE,WD_1_3_1,,6.5,SA-ATI Vx Style,,,8-5 -US-GLE,WD_2_1_1,,30.2,WIND-VaneAn,,,8-5 -US-GLE,WD_2_2_1,,27.12,SA-ATI Vx Style,,,8-5 -US-GLE,WD_PI_F_1_1_1,,25.8,WIND-VaneAn,,,8-5 -US-GLE,WD_PI_F_2_1_1,,30.2,WIND-VaneAn,,,8-5 -US-GLE,WS_1_1_1,,25.8,WIND-VaneAn,,,8-5 -US-GLE,WS_1_2_1,,22.65,SA-ATI Vx Style,,,8-5 -US-GLE,WS_1_3_1,,6.5,SA-ATI Vx Style,,,8-5 -US-GLE,WS_2_1_1,,30.2,WIND-VaneAn,,,8-5 -US-GLE,WS_2_2_1,,27.12,SA-ATI Vx Style,,,8-5 -US-GLE,WS_PI_F_1_1_1,,25.8,WIND-VaneAn,,,8-5 -US-GLE,WS_PI_F_2_1_1,,30.2,WIND-VaneAn,,,8-5 -US-GLE,ZL_1_1_1,,22.65,SA-ATI Vx Style,,,8-5 -US-GLE,ZL_1_2_1,,6.5,SA-ATI Vx Style,,,8-5 -US-GLE,ZL_2_1_1,,27.12,SA-ATI Vx Style,,,8-5 -US-GLE,ZL_PI_F_1_1_1,,22.65,SA-ATI Vx Style,,,8-5 -US-GLE,ZL_PI_F_1_2_1,,6.5,SA-ATI Vx Style,,,8-5 -US-GLE,ZL_PI_F_2_1_1,,27.12,SA-ATI Vx Style,,,8-5 -US-GMF,CO2_1,,30.4,,,,2-1 -US-GMF,CO2_2,,1.5,,,,2-1 -US-GMF,FC,,30.4,,,,2-1 -US-GMF,G,,-0.05,,,,2-1 -US-GMF,H,,30.4,,,,2-1 -US-GMF,H2O,,30.4,,,,2-1 -US-GMF,LE,,30.4,,,,2-1 -US-GMF,NETRAD,,25.6,,,,2-1 -US-GMF,PPFD_IN,,25.6,,,,2-1 -US-GMF,RH,,25.6,,,,2-1 -US-GMF,SWC_1,,-0.05,,,,2-1 -US-GMF,SWC_2,,-0.1,,,,2-1 -US-GMF,TA,,25.6,,,,2-1 -US-GMF,TS_1,,-0.05,,,,2-1 -US-GMF,TS_2,,-0.15,,,,2-1 -US-GMF,USTAR,,30.4,,,,2-1 -US-GMF,VPD_PI_PI,,25.6,,,,2-1 -US-GMF,WD,,30.4,,,,2-1 -US-GMF,WS,,30.4,,,,2-1 -US-Goo,FC,,4,,,,3-5 -US-Goo,H,,4,,,,3-5 -US-Goo,LE,,4,,,,3-5 -US-Goo,WD,,4,,,,3-5 -US-Goo,WS,,4,,,,3-5 -US-Ha1,CO2_1_1_1,,29,GA_CP-LI-COR LI-6262,,,18-5 -US-Ha1,CO2_1_1_2,20141007,29,GA_CP-LI-COR LI-7200,,,18-5 -US-Ha1,FC_1_1_1,,29,GA_CP-LI-COR LI-6262,SA-ATI SATI K Style,,18-5 -US-Ha1,FC_1_1_2,20141007,29,GA_CP-LI-COR LI-7200,SA-ATI SATI K Style,,18-5 -US-Ha1,FH2O_1_1_1,,29,GA_CP-LI-COR LI-6262,,,18-5 -US-Ha1,FH2O_1_1_2,20141007,29,GA_CP-LI-COR LI-7200,,,18-5 -US-Ha1,H,,29,SA-ATI SATI K Style,,,18-5 -US-Ha1,H2O_1_1_1,,29,GA_CP-LI-COR LI-6262,,Licor CO2/H2O sensor,18-5 -US-Ha1,H2O_1_1_2,20141007,29,GA_CP-LI-COR LI-7200,,,18-5 -US-Ha1,LE_1_1_1,,29,SA-ATI SATI K Style,GA_CP-LI-COR LI-6262,,18-5 -US-Ha1,LE_1_1_2,20141007,29,GA_CP-LI-COR LI-7200,SA-ATI SATI K Style,,18-5 -US-Ha1,NETRAD,,29,RAD-Net radiometer,,,18-5 -US-Ha1,NETRAD_PI_F,,29,RAD-Net radiometer,,,18-5 -US-Ha1,P,,,RAIN-TipBucGauge,,,18-5 -US-Ha1,PA,,3,PRES-Other,,,18-5 -US-Ha1,PA_PI_F,,3,PRES-Other,,,18-5 -US-Ha1,PPFD_DIF,20120422,29,RAD-PAR Quantum,,,18-5 -US-Ha1,PPFD_DIR,20120422,,RAD-PAR Quantum,,,18-5 -US-Ha1,PPFD_IN_1_1_1,,29,RAD-PAR Quantum,,,18-5 -US-Ha1,PPFD_IN_1_2_1,,12.7,RAD-PAR Quantum,,,18-5 -US-Ha1,PPFD_IN_PI_F_1_1_1,,29,RAD-PAR Quantum,,,18-5 -US-Ha1,RH_1_1_1,,27.9,RH-Capac,,,18-5 -US-Ha1,RH_1_2_1,,22.6,RH-Capac,,,18-5 -US-Ha1,RH_1_3_1,,15.4,RH-Capac,,,18-5 -US-Ha1,RH_1_4_1,,7.6,RH-Capac,,,18-5 -US-Ha1,RH_1_5_1,,2.5,RH-Capac,,,18-5 -US-Ha1,RH_PI_F_1_1_1,,27.9,RH-Capac,,,18-5 -US-Ha1,RH_PI_F_1_2_1,1991,22.6,RH-Capac,,,18-5 -US-Ha1,SC,,,GA_SR-Other,,,18-5 -US-Ha1,TA_1_1_1,,27.9,TEMP-Thermis,,,18-5 -US-Ha1,TA_1_2_1,,22.6,TEMP-Thermis,,,18-5 -US-Ha1,TA_1_3_1,,15.4,TEMP-Thermis,,,18-5 -US-Ha1,TA_1_4_1,,7.6,TEMP-Thermis,,,18-5 -US-Ha1,TA_1_5_1,,2.5,TEMP-Thermis,,,18-5 -US-Ha1,TA_PI_F_1_1_1,,27.9,TEMP-Thermis,,,18-5 -US-Ha1,TA_PI_F_1_2_1,,22.6,TEMP-Thermis,,,18-5 -US-Ha1,TA_PI_F_1_3_1,,15.4,TEMP-Thermis,,,18-5 -US-Ha1,TA_PI_F_1_4_1,,7.6,TEMP-Thermis,,,18-5 -US-Ha1,TA_PI_F_1_5_1,,2.5,TEMP-Thermis,,,18-5 -US-Ha1,TAU,,29,SA-ATI SATI K Style,,,18-5 -US-Ha1,TS_PI_1_1_A,,-0.1,TEMP-Thermis,,Average of multiple sensors at same depth,18-5 -US-Ha1,TS_2_1_1,,-0.2,TEMP-Thermis,,,18-5 -US-Ha1,TS_3_1_1,,-0.5,TEMP-Thermis,,,18-5 -US-Ha1,TS_4_1_1,20160907,-0.05,TEMP-Thermis,,,18-5 -US-Ha1,TS_4_2_1,20160907,-0.1,TEMP-Thermis,,,18-5 -US-Ha1,TS_4_3_1,20160907,-0.2,TEMP-Thermis,,,18-5 -US-Ha1,TS_4_4_1,20160907,-0.5,TEMP-Thermis,,,18-5 -US-Ha1,TS_5_1_1,20160907,-0.05,TEMP-Thermis,,,18-5 -US-Ha1,TS_5_2_1,20160907,-0.2,TEMP-Thermis,,,18-5 -US-Ha1,TS_5_3_1,20160907,-0.5,TEMP-Thermis,,,18-5 -US-Ha1,TS_6_1_1,20160907,-0.05,TEMP-Thermis,,,18-5 -US-Ha1,TS_6_1_2,20160907,-0.05,TEMP-Thermis,,,18-5 -US-Ha1,TS_6_2_1,20160907,-0.2,TEMP-Thermis,,,18-5 -US-Ha1,TS_6_3_1,20160907,-0.5,TEMP-Thermis,,,18-5 -US-Ha1,T_SONIC,,29,SA-ATI SATI K Style,,,18-5 -US-Ha1,USTAR,,29,SA-ATI SATI K Style,,,18-5 -US-Ha1,VPD_PI,,27.9,RH-Capac,,,18-5 -US-Ha1,WD,,29,SA-ATI SATI K Style,,,18-5 -US-Ha1,WS,,29,SA-ATI SATI K Style,,,18-5 -US-Ha1,WS_PI_F,,29,SA-ATI SATI K Style,,,18-5 -US-Ha2,ALB_2_1_1,20140827,33,RAD-Pyrrad-SW+LW,,computed from ratio of in and out SW radiation,7-5 -US-Ha2,CO2_1_1_1,200611,29,GA_CP-LI-COR LI-7000,,parallel installation on adjacent (Rohn triangular) tower,7-5 -US-Ha2,CO2_1_1_1,,28,GA_CP-LI-COR LI-7000,,initial position 29 m on scaffold,7-5 -US-Ha2,CO2_2_1_1,20140604,33.5,GA_CP-LI-COR LI-7000,,second sensor designated by position qualifier _2,7-5 -US-Ha2,FC_1_1_1,200611,29,GA_CP-LI-COR LI-7000,SA-Campbell CSAT-3,raised inlet,7-5 -US-Ha2,FC_1_1_1,,28,SA-Campbell CSAT-3,GA_CP-LI-COR LI-7000,,7-5 -US-Ha2,FC_2_1_1,20140604,33.5,GA_CP-LI-COR LI-7000,SA-Campbell CSAT-3,,7-5 -US-Ha2,FETCH_FILTER_1_1_1,200611,29,SA-Campbell CSAT-3,,,7-5 -US-Ha2,FETCH_FILTER_1_1_1,,28,SA-Campbell CSAT-3,,,7-5 -US-Ha2,FETCH_FILTER_2_1_1,20140604,33.5,SA-Campbell CSAT-3,,new setup intalled in parallel at adjacent tower,7-5 -US-Ha2,FH2O_1_1_1,200611,29,GA_CP-LI-COR LI-7000,,raised inlet,7-5 -US-Ha2,FH2O_1_1_1,,28,SA-Campbell CSAT-3,,,7-5 -US-Ha2,FH2O_2_1_1,20140604,33.5,GA_CP-LI-COR LI-7000,,,7-5 -US-Ha2,H_1_1_1,200611,29,SA-Campbell CSAT-3,,raised inlet height,7-5 -US-Ha2,H_1_1_1,,28,SA-Campbell CSAT-3,,,7-5 -US-Ha2,H_2_1_1,20140604,33.5,SA-Campbell CSAT-3,,,7-5 -US-Ha2,H2O_1_1_1,200611,29,GA_CP-LI-COR LI-7000,,raised inlet,7-5 -US-Ha2,H2O_1_1_1,,28,GA_CP-LI-COR LI-7000,,,7-5 -US-Ha2,H2O_2_1_1,20140604,33.5,GA_CP-LI-COR LI-7000,,,7-5 -US-Ha2,LE_1_1_1,2000,28,GA_CP-LI-COR LI-7000,SA-Campbell CSAT-3,,7-5 -US-Ha2,LE_1_1_1,200611,29,GA_CP-LI-COR LI-7000,SA-Campbell CSAT-3,,7-5 -US-Ha2,LE_2_1_1,20140604,33.5,GA_CP-LI-COR LI-7000,SA-Campbell CSAT-3,parallel setup on adjacent tower,7-5 -US-Ha2,LW_IN_2_1_1,20140827,33,RAD-Pyrrad-SW+LW,,added with installation of new (Rohn triangular) tower,7-5 -US-Ha2,LW_OUT_2_1_1,20140827,33,RAD-Pyrrad-SW+LW,,added with installation of new (Rohn triangular) tower,7-5 -US-Ha2,NETRAD_2_1_1,20140827,33,RAD-Pyrrad-SW+LW,,calculated from 4-component radiation pyranometer,7-5 -US-Ha2,PPFD_IN_1_1_1,2000,24,RAD-PAR Quantum,,,7-5 -US-Ha2,PPFD_IN_2_1_1,20140827,33,RAD-PAR Quantum,,parallel setup on adjacent tower,7-5 -US-Ha2,PPFD_IN_2_2_1,20140827,20,RAD-PAR Quantum,,added with installation of new (Rohn triangular) tower,7-5 -US-Ha2,PPFD_IN_2_3_1,20140827,10,RAD-PAR Quantum,,added with installation of new (Rohn triangular) tower,7-5 -US-Ha2,PPFD_IN_PI_F_2_1_1,20140827,33,RAD-PAR Quantum,,Filled version of PPFD_IN_2_1_1 with missing values modeled from other local meteorological measurements,7-5 -US-Ha2,PPFD_OUT_2_1_1,20140827,33,RAD-PAR Quantum,,added with installation of new (Rohn triangular) tower,7-5 -US-Ha2,RH_1_1_1,,24,RH-Capac,,,7-5 -US-Ha2,RH_2_1_1,20140604,33,RH-Capac,,added with installation of new (Rohn triangular) tower,7-5 -US-Ha2,RH_2_2_1,20140827,20,RH-Capac,,added with installation of new (Rohn triangular) tower,7-5 -US-Ha2,RH_2_3_1,20140827,10,RH-Capac,,added with installation of new (Rohn triangular) tower,7-5 -US-Ha2,RH_PI_F_2_1_1,20140604,33,RH-Capac,,Filled version of RH_2_1_1 with missing values modeled from other local meteorological measurements,7-5 -US-Ha2,SW_IN_2_1_1,20140827,33,RAD-Pyrrad-SW+LW,,added with installation of new (Rohn triangular) tower,7-5 -US-Ha2,SW_OUT_2_1_1,20140827,33,RAD-Pyrrad-SW+LW,,added with installation of new (Rohn triangular) tower,7-5 -US-Ha2,TA_1_1_1,,24,TEMP-Thermis,,HMP25C in aspirated shield ,7-5 -US-Ha2,TA_1_1_2,20040618,24,TEMP-TCouple,,shaded thermocouple,7-5 -US-Ha2,TA_2_1_1,20140604,33,TEMP-ElectResis,,Parallel installation on adjacent tower,7-5 -US-Ha2,TA_2_2_1,20140827,20,TEMP-ElectResis,,added with installation of new (Rohn triangular) tower,7-5 -US-Ha2,TA_2_3_1,20140827,10,TEMP-ElectResis,,added with installation of new (Rohn triangular) tower,7-5 -US-Ha2,TA_2_4_1,20140827,1,TEMP-ElectResis,,Shielded temperature sensor on separate 1 m post not connected to tower base,7-5 -US-Ha2,TA_PI_F_2_1_1,20140604,33,TEMP-ElectResis,,Filled version of TA_2_1_1 with missing values modeled from other local meteorological measurements,7-5 -US-Ha2,TS_1,,-0.1,TEMP-ElectResis,,6 randomly-placed sensors at 10 cm depth within 15m of tower,7-5 -US-Ha2,T_SONIC_1_1_1,200611,29,SA-Campbell CSAT-3,,raised inlet,7-5 -US-Ha2,T_SONIC_1_1_1,,28,SA-Campbell CSAT-3,,,7-5 -US-Ha2,T_SONIC_2_1_1,20140604,33.5,SA-Campbell CSAT-3,,,7-5 -US-Ha2,USTAR_1_1_1,200611,29,SA-Campbell CSAT-3,,raised inlet,7-5 -US-Ha2,USTAR_1_1_1,,28,SA-Campbell CSAT-3,,,7-5 -US-Ha2,USTAR_2_1_1,20140604,33.5,SA-Campbell CSAT-3,,,7-5 -US-Ha2,VPD_PI_1_1_1,,24,RH-Capac,,calculated from Tair and RH above canopy,7-5 -US-Ha2,VPD_PI_2_1_1,20140604,33,RH-Capac,,added with installation of new (Rohn triangular) tower,7-5 -US-Ha2,WD_1_1_1,200611,29,SA-Campbell CSAT-3,,,7-5 -US-Ha2,WD_1_1_1,,28,SA-Campbell CSAT-3,,,7-5 -US-Ha2,WD_2_1_1,20140827,35,WIND-VaneAn,,added with installation of new (Rohn triangular) tower,7-5 -US-Ha2,WD_2_2_1,20140604,33.5,SA-Campbell CSAT-3,,parallel installation on adjacent tower,7-5 -US-Ha2,WS_1_1_1,200611,29,SA-Campbell CSAT-3,,raised inlet,7-5 -US-Ha2,WS_1_1_1,,28,SA-Campbell CSAT-3,,,7-5 -US-Ha2,WS_2_1_1,20140827,35,WIND-VaneAn,,added with installation of new (Rohn triangular) tower,7-5 -US-Ha2,WS_2_2_1,20140604,33.5,SA-Campbell CSAT-3,,parallel installation on adjacent tower,7-5 -US-HB1,ALB,20191205,4.19,RAD-Pyrrad-SW+LW,,Re-Installation after Hurricane Dorian,2-5 -US-HB1,ALB,,4.13,RAD-Pyrrad-SW+LW,,,2-5 -US-HB1,CO2,20191205,3.91,GA_OP_SA-Campbell IRGASON,,Re-Installation after Hurricane Dorian,2-5 -US-HB1,CO2,,3.9,GA_OP_SA-Campbell IRGASON,,,2-5 -US-HB1,CO2_SIGMA,20191205,3.91,GA_OP_SA-Campbell IRGASON,,Re-Installation after Hurricane Dorian,2-5 -US-HB1,CO2_SIGMA,,3.9,GA_OP_SA-Campbell IRGASON,,,2-5 -US-HB1,FC,20191205,3.91,GA_OP_SA-Campbell IRGASON,,Re-Installation after Hurricane Dorian,2-5 -US-HB1,FC,,3.9,GA_OP_SA-Campbell IRGASON,,,2-5 -US-HB1,FC_SSITC_TEST,20191205,3.91,GA_OP_SA-Campbell IRGASON,,Re-Installation after Hurricane Dorian,2-5 -US-HB1,FC_SSITC_TEST,,3.90,GA_OP_SA-Campbell IRGASON,,,2-5 -US-HB1,FETCH_70,20191205,3.91,GA_OP_SA-Campbell IRGASON,,Re-Installation after Hurricane Dorian,2-5 -US-HB1,FETCH_70,,3.9,GA_OP_SA-Campbell IRGASON,,,2-5 -US-HB1,FETCH_80,20191205,3.91,GA_OP_SA-Campbell IRGASON,,Re-Installation after Hurricane Dorian,2-5 -US-HB1,FETCH_80,,3.9,GA_OP_SA-Campbell IRGASON,,,2-5 -US-HB1,FETCH_90,20191205,3.91,GA_OP_SA-Campbell IRGASON,,Re-Installation after Hurricane Dorian,2-5 -US-HB1,FETCH_90,,3.9,GA_OP_SA-Campbell IRGASON,,,2-5 -US-HB1,FETCH_MAX,20191205,3.91,GA_OP_SA-Campbell IRGASON,,Re-Installation after Hurricane Dorian,2-5 -US-HB1,FETCH_MAX,,3.9,GA_OP_SA-Campbell IRGASON,,,2-5 -US-HB1,H,20191205,3.91,GA_OP_SA-Campbell IRGASON,,Re-Installation after Hurricane Dorian,2-5 -US-HB1,H,,3.9,GA_OP_SA-Campbell IRGASON,,,2-5 -US-HB1,H2O,20191205,3.91,GA_OP_SA-Campbell IRGASON,,Re-Installation after Hurricane Dorian,2-5 -US-HB1,H2O,,3.9,GA_OP_SA-Campbell IRGASON,,,2-5 -US-HB1,H2O_SIGMA,20191205,3.91,GA_OP_SA-Campbell IRGASON,,Re-Installation after Hurricane Dorian,2-5 -US-HB1,H2O_SIGMA,,3.9,GA_OP_SA-Campbell IRGASON,,,2-5 -US-HB1,H_SSITC_TEST,20191205,3.91,GA_OP_SA-Campbell IRGASON,,Re-Installation after Hurricane Dorian,2-5 -US-HB1,H_SSITC_TEST,,3.9,GA_OP_SA-Campbell IRGASON,,,2-5 -US-HB1,LE,20191205,3.91,GA_OP_SA-Campbell IRGASON,,Re-Installation after Hurricane Dorian,2-5 -US-HB1,LE,,3.9,GA_OP_SA-Campbell IRGASON,,,2-5 -US-HB1,LE_SSITC_TEST,20191205,3.91,GA_OP_SA-Campbell IRGASON,,Re-Installation after Hurricane Dorian,2-5 -US-HB1,LE_SSITC_TEST,,3.9,GA_OP_SA-Campbell IRGASON,,,2-5 -US-HB1,LW_IN,20191205,4.19,RAD-Pyrrad-SW+LW,,Re-installation after Hurricane Dorian,2-5 -US-HB1,LW_IN,,4.13,RAD-Pyrrad-SW+LW,,,2-5 -US-HB1,LW_OUT,20191205,4.19,RAD-Pyrrad-SW+LW,,Re-Installation after Hurricane Dorian,2-5 -US-HB1,LW_OUT,,4.13,RAD-Pyrrad-SW+LW,,,2-5 -US-HB1,MO_LENGTH,20191205,3.91,GA_OP_SA-Campbell IRGASON,,Re-installation after Hurricane Dorian,2-5 -US-HB1,MO_LENGTH,,3.9,GA_OP_SA-Campbell IRGASON,,,2-5 -US-HB1,NDVI,20191205,4.1,SPECT-SpectRad,,Re-installation after Hurricane Dorian,2-5 -US-HB1,NDVI,,4.58,SPECT-SpectRad,,,2-5 -US-HB1,PA,20191205,3.91,GA_OP_SA-Campbell IRGASON,,Re-Installation after Hurricane Dorian,2-5 -US-HB1,PA,,3.9,GA_OP_SA-Campbell IRGASON,,,2-5 -US-HB1,P_RAIN,,2.0,,,NOAA National Estuarine Research Reserve System (NERRS). System-wide Monitoring Program. Data accessed from the NOAA NERRS Centralized Data Management Office website: http://www.nerrsdata.org/.,2-5 -US-HB1,RH_1_1_1,20191205,1.98,RH-Capac,,Re-installation after Hurricane Dorian,2-5 -US-HB1,RH_1_1_1,,1.7,RH-Capac,,,2-5 -US-HB1,RH_1_2_1,20191205,4.83,RH-Capac,,Re-installation after Hurricane Dorian,2-5 -US-HB1,RH_1_2_1,,4.89,RH-Capac,,,2-5 -US-HB1,RH_1_2_2,20191205,3.91,GA_OP_SA-Campbell IRGASON,,Re-Installation after Hurricane Dorian,2-5 -US-HB1,RH_1_2_2,,3.9,GA_OP_SA-Campbell IRGASON,,,2-5 -US-HB1,SC,20191205,3.91,GA_OP_SA-Campbell IRGASON,,Re-Installation after Hurricane Dorian,2-5 -US-HB1,SC,,3.9,GA_OP_SA-Campbell IRGASON,,,2-5 -US-HB1,SH,20191205,3.91,GA_OP_SA-Campbell IRGASON,,Re-Installation after Hurricane Dorian,2-5 -US-HB1,SH,,3.9,GA_OP_SA-Campbell IRGASON,,,2-5 -US-HB1,SLE,20191205,3.91,GA_OP_SA-Campbell IRGASON,,Re-Installation after Hurricane Dorian,2-5 -US-HB1,SLE,,3.9,GA_OP_SA-Campbell IRGASON,,,2-5 -US-HB1,SW_IN,20191205,4.19,RAD-Pyrrad-SW+LW,,Re-Installation after Hurricane Dorian,2-5 -US-HB1,SW_IN,,4.13,RAD-Pyrrad-SW+LW,,,2-5 -US-HB1,SW_OUT,20191205,4.19,RAD-Pyrrad-SW+LW,,Re-Installation after Hurricane Dorian,2-5 -US-HB1,SW_OUT,,4.13,RAD-Pyrrad-SW+LW,,,2-5 -US-HB1,TA_1_1_1,20191205,1.98,TEMP-Thermis,,Re-installation after Hurricane Dorian,2-5 -US-HB1,TA_1_1_1,,1.7,TEMP-Thermis,,,2-5 -US-HB1,TA_1_2_2,20191205,3.91,GA_OP_SA-Campbell IRGASON,,Re-Installation after Hurricane Dorian,2-5 -US-HB1,TA_1_2_2,,3.9,GA_OP_SA-Campbell IRGASON,,,2-5 -US-HB1,TA_1_3_1,20191205,4.83,TEMP-Thermis,,Re-installation after Hurricane Dorian,2-5 -US-HB1,TA_1_3_1,,4.89,TEMP-Thermis,,,2-5 -US-HB1,TAU,20191205,3.91,GA_OP_SA-Campbell IRGASON,,Re-installation after Hurricane Dorian,2-5 -US-HB1,TAU,,3.9,GA_OP_SA-Campbell IRGASON,,,2-5 -US-HB1,TAU_SSITC_TEST,20191205,3.91,GA_OP_SA-Campbell IRGASON,,Re-installation after Hurricane Dorian,2-5 -US-HB1,TAU_SSITC_TEST,,3.9,GA_OP_SA-Campbell IRGASON,,,2-5 -US-HB1,TS_1_1_1,20191205,-0.10,TEMP-Thermis,,Re-installation after Hurricane Dorian,2-5 -US-HB1,TS_1_1_1,,-0.10,TEMP-Thermis,,,2-5 -US-HB1,TS_1_2_1,20191205,-0.20,TEMP-Thermis,,Re-installation after Hurricane Dorian,2-5 -US-HB1,TS_1_2_1,,-0.20,TEMP-Thermis,,,2-5 -US-HB1,T_SONIC,20191205,3.91,GA_OP_SA-Campbell IRGASON,,Re-Installation after Hurricane Dorian,2-5 -US-HB1,T_SONIC,,3.9,GA_OP_SA-Campbell IRGASON,,,2-5 -US-HB1,T_SONIC_SIGMA,20191205,3.91,GA_OP_SA-Campbell IRGASON,,Re-Installation after Hurricane Dorian,2-5 -US-HB1,T_SONIC_SIGMA,,3.9,GA_OP_SA-Campbell IRGASON,,,2-5 -US-HB1,U_SIGMA,20191205,3.91,GA_OP_SA-Campbell IRGASON,,Re-installation after Hurricane Dorian,2-5 -US-HB1,U_SIGMA,,3.9,GA_OP_SA-Campbell IRGASON,,,2-5 -US-HB1,USTAR,20191205,3.91,GA_OP_SA-Campbell IRGASON,,Re-installation after Hurricane Dorian,2-5 -US-HB1,USTAR,,3.9,GA_OP_SA-Campbell IRGASON,,,2-5 -US-HB1,VPD_PI,20191205,3.91,GA_OP_SA-Campbell IRGASON,,Re-Installation after Hurricane Dorian,2-5 -US-HB1,VPD_PI,,3.9,GA_OP_SA-Campbell IRGASON,,,2-5 -US-HB1,V_SIGMA,20191205,3.91,GA_OP_SA-Campbell IRGASON,,Re-installation after Hurricane Dorian,2-5 -US-HB1,V_SIGMA,,3.9,GA_OP_SA-Campbell IRGASON,,,2-5 -US-HB1,WD,20191205,3.91,GA_OP_SA-Campbell IRGASON,,Re-installation after Hurricane Dorian,2-5 -US-HB1,WD,,3.9,GA_OP_SA-Campbell IRGASON,,,2-5 -US-HB1,WS,20191205,3.91,GA_OP_SA-Campbell IRGASON,,Re-installation after Hurricane Dorian,2-5 -US-HB1,WS,,3.9,GA_OP_SA-Campbell IRGASON,,,2-5 -US-HB1,W_SIGMA,20191205,3.91,GA_OP_SA-Campbell IRGASON,,Re-installation after Hurricane Dorian,2-5 -US-HB1,W_SIGMA,,3.9,GA_OP_SA-Campbell IRGASON,,,2-5 -US-HB1,WS_MAX,20191205,3.91,GA_OP_SA-Campbell IRGASON,,Re-installation after Hurricane Dorian,2-5 -US-HB1,WS_MAX,,3.9,GA_OP_SA-Campbell IRGASON,,,2-5 -US-HB1,ZL,20191205,3.91,GA_OP_SA-Campbell IRGASON,,Re-installation after Hurricane Dorian,2-5 -US-HB1,ZL,,3.9,GA_OP_SA-Campbell IRGASON,,,2-5 -US-HB2,ALB,,32.92,RAD-Pyrrad-SW+LW,,,1-5 -US-HB2,CO2,,29.87,GA_OP_SA-Campbell IRGASON,,,1-5 -US-HB2,CO2_SIGMA,,29.87,GA_OP_SA-Campbell IRGASON,,,1-5 -US-HB2,FC,,29.87,GA_OP_SA-Campbell IRGASON,,,1-5 -US-HB2,FC_SSITC_TEST,,29.87,GA_OP_SA-Campbell IRGASON,,,1-5 -US-HB2,FETCH_70,,29.87,GA_OP_SA-Campbell IRGASON,,,1-5 -US-HB2,FETCH_80,,29.87,GA_OP_SA-Campbell IRGASON,,,1-5 -US-HB2,FETCH_90,,29.87,GA_OP_SA-Campbell IRGASON,,,1-5 -US-HB2,FETCH_MAX,,29.87,GA_OP_SA-Campbell IRGASON,,,1-5 -US-HB2,H,,29.87,GA_OP_SA-Campbell IRGASON,,,1-5 -US-HB2,H2O,,29.87,GA_OP_SA-Campbell IRGASON,,,1-5 -US-HB2,H2O_SIGMA,,29.87,GA_OP_SA-Campbell IRGASON,,,1-5 -US-HB2,H_SSITC_TEST,,29.87,GA_OP_SA-Campbell IRGASON,,,1-5 -US-HB2,LE,,29.87,GA_OP_SA-Campbell IRGASON,,,1-5 -US-HB2,LEAF_WET_1_1_1,,8.0,LEAF_WET-FrequencyDomain,,,1-5 -US-HB2,LEAF_WET_1_2_1,,22,LEAF_WET-FrequencyDomain,,,1-5 -US-HB2,LEAF_WET_1_3_1,,28,LEAF_WET-FrequencyDomain,,,1-5 -US-HB2,LE_SSITC_TEST,,29.87,GA_OP_SA-Campbell IRGASON,,,1-5 -US-HB2,LW_IN,,32.92,RAD-Pyrrad-SW+LW,,,1-5 -US-HB2,LW_OUT,,32.92,RAD-Pyrrad-SW+LW,,,1-5 -US-HB2,MO_LENGTH,,29.87,GA_OP_SA-Campbell IRGASON,,,1-5 -US-HB2,NDVI,,32.92,SPECT-SpectRad,,,1-5 -US-HB2,NETRAD,,32.92,RAD-Pyrrad-SW+LW,,,1-5 -US-HB2,PA,,29.87,GA_OP_SA-Campbell IRGASON,,,1-5 -US-HB2,P_RAIN,,27.43,RAIN-TipBucGauge,,,1-5 -US-HB2,PRI,,32.92,SPECT-SpectRad,,,1-5 -US-HB2,RH_1_2_2,,29.87,GA_OP_SA-Campbell IRGASON,,,1-5 -US-HB2,SC,,29.87,GA_OP_SA-Campbell IRGASON,,,1-5 -US-HB2,SH,,29.87,GA_OP_SA-Campbell IRGASON,,,1-5 -US-HB2,SLE,,29.87,GA_OP_SA-Campbell IRGASON,,,1-5 -US-HB2,SPEC_NIR_IN,,32.92,SPECT-SpectRad,,,1-5 -US-HB2,SPEC_NIR_OUT,,32.92,SPECT-SpectRad,,,1-5 -US-HB2,SPEC_PRI_REF_IN,,32.92,SPECT-SpectRad,,,1-5 -US-HB2,SPEC_PRI_REF_OUT,,32.92,SPECT-SpectRad,,,1-5 -US-HB2,SPEC_PRI_TGT_IN,,32.92,SPECT-SpectRad,,,1-5 -US-HB2,SPEC_PRI_TGT_OUT,,32.92,SPECT-SpectRad,,,1-5 -US-HB2,SPEC_RED_IN,,32.92,SPECT-SpectRad,,,1-5 -US-HB2,SPEC_RED_OUT,,32.92,SPECT-SpectRad,,,1-5 -US-HB2,SWC_1_1_1,,-0.1524,SWC-TDR,,,1-5 -US-HB2,SWC_1_3_1,,-0.2921,SWC-TDR,,,1-5 -US-HB2,SWC_1_4_1,,-0.445,SWC-TDR,,,1-5 -US-HB2,SWC_2_2_1,,-0.1778,SWC-TDR,,,1-5 -US-HB2,SW_DIF,,32.92,RAD-SW Pyran Class1,,,1-5 -US-HB2,SW_IN_1_1_1,,32.92,RAD-Pyrrad-SW+LW,,,1-5 -US-HB2,SW_IN_1_1_2,,32.92,RAD-SW Pyran Class1,,,1-5 -US-HB2,SW_OUT,,32.92,RAD-Pyrrad-SW+LW,,,1-5 -US-HB2,TA_1_2_2,,29.87,GA_OP_SA-Campbell IRGASON,,,1-5 -US-HB2,TAU,,29.87,GA_OP_SA-Campbell IRGASON,,,1-5 -US-HB2,TAU_SSITC_TEST,,29.87,GA_OP_SA-Campbell IRGASON,,,1-5 -US-HB2,TS_1_1_1,,-0.1524,SWC-TDR,,,1-5 -US-HB2,TS_1_3_1,,-0.2921,SWC-TDR,,,1-5 -US-HB2,TS_1_4_1,,-0.445,SWC-TDR,,,1-5 -US-HB2,TS_2_2_1,,-0.1778,SWC-TDR,,,1-5 -US-HB2,T_SONIC,,29.87,GA_OP_SA-Campbell IRGASON,,,1-5 -US-HB2,T_SONIC_SIGMA,,29.87,GA_OP_SA-Campbell IRGASON,,,1-5 -US-HB2,U_SIGMA,,29.87,GA_OP_SA-Campbell IRGASON,,,1-5 -US-HB2,USTAR,,29.87,GA_OP_SA-Campbell IRGASON,,,1-5 -US-HB2,VPD_PI,,29.87,GA_OP_SA-Campbell IRGASON,,,1-5 -US-HB2,V_SIGMA,,29.87,GA_OP_SA-Campbell IRGASON,,,1-5 -US-HB2,WD,,29.87,GA_OP_SA-Campbell IRGASON,,,1-5 -US-HB2,WS,,29.87,GA_OP_SA-Campbell IRGASON,,,1-5 -US-HB2,W_SIGMA,,29.87,GA_OP_SA-Campbell IRGASON,,,1-5 -US-HB2,WS_MAX,,29.87,GA_OP_SA-Campbell IRGASON,,,1-5 -US-HB2,ZL,,29.87,GA_OP_SA-Campbell IRGASON,,,1-5 -US-HB3,ALB,,4.34,RAD-Pyrrad-SW+LW,,,1-5 -US-HB3,CO2,,4.09,GA_OP_SA-Campbell IRGASON,,,1-5 -US-HB3,CO2_SIGMA,,4.09,GA_OP_SA-Campbell IRGASON,,,1-5 -US-HB3,FC,,4.09,GA_OP_SA-Campbell IRGASON,,,1-5 -US-HB3,FC_SSITC_TEST,,4.09,GA_OP_SA-Campbell IRGASON,,,1-5 -US-HB3,FETCH_70,,4.09,GA_OP_SA-Campbell IRGASON,,,1-5 -US-HB3,FETCH_80,,4.09,GA_OP_SA-Campbell IRGASON,,,1-5 -US-HB3,FETCH_90,,4.09,GA_OP_SA-Campbell IRGASON,,,1-5 -US-HB3,FETCH_MAX,,4.09,GA_OP_SA-Campbell IRGASON,,,1-5 -US-HB3,H,,4.09,GA_OP_SA-Campbell IRGASON,,,1-5 -US-HB3,H2O,,4.09,GA_OP_SA-Campbell IRGASON,,,1-5 -US-HB3,H2O_SIGMA,,4.09,GA_OP_SA-Campbell IRGASON,,,1-5 -US-HB3,H_SSITC_TEST,,4.09,GA_OP_SA-Campbell IRGASON,,,1-5 -US-HB3,LE,,4.09,GA_OP_SA-Campbell IRGASON,,,1-5 -US-HB3,LE_SSITC_TEST,,4.09,GA_OP_SA-Campbell IRGASON,,,1-5 -US-HB3,LW_IN,,4.34,RAD-Pyrrad-SW+LW,,,1-5 -US-HB3,LW_OUT,,4.34,RAD-Pyrrad-SW+LW,,,1-5 -US-HB3,MO_LENGTH,,4.09,GA_OP_SA-Campbell IRGASON,,,1-5 -US-HB3,NDVI,,4.34,SPECT-SpectRad,,,1-5 -US-HB3,NETRAD,,4.34,RAD-Pyrrad-SW+LW,,,1-5 -US-HB3,PA_1_1_1,,4.09,GA_OP_SA-Campbell IRGASON,,,1-5 -US-HB3,PA_1_2_2,,1.0,PRES-ElectBar,,,1-5 -US-HB3,PPFD_IN,,4.34,RAD-PAR Quantum,,,1-5 -US-HB3,PPFD_OUT,,4.34,RAD-PAR Quantum,,,1-5 -US-HB3,P_RAIN,,6.1,RAIN-TipBucGauge,,,1-5 -US-HB3,PRI,,4.34,SPECT-SpectRad,,,1-5 -US-HB3,RH_1_2_2,,4.09,GA_OP_SA-Campbell IRGASON,,,1-5 -US-HB3,SC,,4.09,GA_OP_SA-Campbell IRGASON,,,1-5 -US-HB3,SH,,4.09,GA_OP_SA-Campbell IRGASON,,,1-5 -US-HB3,SLE,,4.09,GA_OP_SA-Campbell IRGASON,,,1-5 -US-HB3,SPEC_NIR_IN,,4.34,SPECT-SpectRad,,,1-5 -US-HB3,SPEC_NIR_OUT,,4.34,SPECT-SpectRad,,,1-5 -US-HB3,SPEC_PRI_REF_IN,,4.34,SPECT-SpectRad,,,1-5 -US-HB3,SPEC_PRI_REF_OUT,,4.34,SPECT-SpectRad,,,1-5 -US-HB3,SPEC_PRI_TGT_IN,,4.34,SPECT-SpectRad,,,1-5 -US-HB3,SPEC_PRI_TGT_OUT,,4.34,SPECT-SpectRad,,,1-5 -US-HB3,SPEC_RED_IN,,4.34,SPECT-SpectRad,,,1-5 -US-HB3,SPEC_RED_OUT,,4.34,SPECT-SpectRad,,,1-5 -US-HB3,SW_IN,,4.34,RAD-Pyrrad-SW+LW,,,1-5 -US-HB3,SW_OUT,,4.34,RAD-Pyrrad-SW+LW,,,1-5 -US-HB3,TA_1_2_2,,4.09,GA_OP_SA-Campbell IRGASON,,,1-5 -US-HB3,TAU,,4.09,GA_OP_SA-Campbell IRGASON,,,1-5 -US-HB3,TAU_SSITC_TEST,,4.09,GA_OP_SA-Campbell IRGASON,,,1-5 -US-HB3,T_SONIC,,4.09,GA_OP_SA-Campbell IRGASON,,,1-5 -US-HB3,T_SONIC_SIGMA,,4.09,GA_OP_SA-Campbell IRGASON,,,1-5 -US-HB3,U_SIGMA,,4.09,GA_OP_SA-Campbell IRGASON,,,1-5 -US-HB3,USTAR,,4.09,GA_OP_SA-Campbell IRGASON,,,1-5 -US-HB3,VPD_PI,,4.09,GA_OP_SA-Campbell IRGASON,,,1-5 -US-HB3,V_SIGMA,,4.09,GA_OP_SA-Campbell IRGASON,,,1-5 -US-HB3,WD,,4.09,GA_OP_SA-Campbell IRGASON,,,1-5 -US-HB3,WS,,4.09,GA_OP_SA-Campbell IRGASON,,,1-5 -US-HB3,W_SIGMA,,4.09,GA_OP_SA-Campbell IRGASON,,,1-5 -US-HB3,WS_MAX,,4.09,GA_OP_SA-Campbell IRGASON,,,1-5 -US-HB3,ZL,,4.09,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Hn2,CO2,,0,,,,1-5 -US-Hn2,CO2_SIGMA,,0,,,,1-5 -US-Hn2,FC,,0,,,,1-5 -US-Hn2,G,,0,,,,1-5 -US-Hn2,H,,0,,,,1-5 -US-Hn2,H2O,,0,,,,1-5 -US-Hn2,H2O_SIGMA,,0,,,,1-5 -US-Hn2,LE,,0,,,,1-5 -US-Hn2,MO_LENGTH,,0,,,,1-5 -US-Hn2,NETRAD,,0,,,,1-5 -US-Hn2,P,,0,,,,1-5 -US-Hn2,PA,,0,,,,1-5 -US-Hn2,P_PI_F,,0,,,,1-5 -US-Hn2,PPFD_IN,,0,,,,1-5 -US-Hn2,RH,,0,,,,1-5 -US-Hn2,SC,,0,,,,1-5 -US-Hn2,SH,,0,,,,1-5 -US-Hn2,SLE,,0,,,,1-5 -US-Hn2,SWC,,0,,,,1-5 -US-Hn2,SW_IN,,0,,,,1-5 -US-Hn2,TA,,0,,,,1-5 -US-Hn2,TA_PI_F,,0,,,,1-5 -US-Hn2,TAU,,0,,,,1-5 -US-Hn2,TS_1_1_1,,0,,,,1-5 -US-Hn2,TS_1_2_1,,0,,,,1-5 -US-Hn2,T_SONIC,,0,,,,1-5 -US-Hn2,T_SONIC_SIGMA,,0,,,,1-5 -US-Hn2,U_SIGMA,,0,,,,1-5 -US-Hn2,USTAR,,0,,,,1-5 -US-Hn2,V_SIGMA,,0,,,,1-5 -US-Hn2,WD_1_2_1,,0,,,,1-5 -US-Hn2,WS_1_2_1,,0,,,,1-5 -US-Hn2,W_SIGMA,,0,,,,1-5 -US-Hn3,ALB,,0,,,,1-5 -US-Hn3,APAR,,0,,,,1-5 -US-Hn3,CO2,,2.35,,,,1-5 -US-Hn3,CO2_SIGMA,,0,,,,1-5 -US-Hn3,FC,,2.35,,,,1-5 -US-Hn3,G_1_1_1,,0,,,,1-5 -US-Hn3,G_1_2_1,,0,,,,1-5 -US-Hn3,H,,0,,,,1-5 -US-Hn3,H2O,,0,,,,1-5 -US-Hn3,H2O_SIGMA,,0,,,,1-5 -US-Hn3,LE,,0,,,,1-5 -US-Hn3,LW_IN,,0,,,,1-5 -US-Hn3,LW_OUT,,0,,,,1-5 -US-Hn3,MO_LENGTH,,0,,,,1-5 -US-Hn3,NETRAD,,0,,,,1-5 -US-Hn3,P,,0,,,,1-5 -US-Hn3,PA,,0,,,,1-5 -US-Hn3,P_PI_F,,0,,,,1-5 -US-Hn3,RH,,0,,,,1-5 -US-Hn3,SC,,0,,,,1-5 -US-Hn3,SH,,0,,,,1-5 -US-Hn3,SLE,,0,,,,1-5 -US-Hn3,SWC_1_1_1,,0,,,,1-5 -US-Hn3,SWC_1_2_1,,0,,,,1-5 -US-Hn3,SW_IN,,0,,,,1-5 -US-Hn3,SW_OUT,,0,,,,1-5 -US-Hn3,TA,,0,,,,1-5 -US-Hn3,TA_PI_F,,0,,,,1-5 -US-Hn3,TAU,,0,,,,1-5 -US-Hn3,TS_1_1_1,,0,,,,1-5 -US-Hn3,TS_1_2_1,,0,,,,1-5 -US-Hn3,TS_1_3_1,,0,,,,1-5 -US-Hn3,T_SONIC,,0,,,,1-5 -US-Hn3,T_SONIC_SIGMA,,0,,,,1-5 -US-Hn3,U_SIGMA,,0,,,,1-5 -US-Hn3,USTAR,,0,,,,1-5 -US-Hn3,V_SIGMA,,0,,,,1-5 -US-Hn3,WD,,0,,,,1-5 -US-Hn3,WS,,0,,,,1-5 -US-Hn3,W_SIGMA,,0,,,,1-5 -US-Ho1,CH4_1_1_1,20120606,31,GA_CP-Picarro G2311-f,,intake height is listed; instrument is in building below,7-5 -US-Ho1,CO2_1_1_1,19960101,31,GA_CP-LI-COR LI-6262,,intake height is listed; instrument is in building below,7-5 -US-Ho1,CO2_1_1_1,20120606,31,GA_CP-Picarro G2311-f,,intake height is listed; instrument is in building below,7-5 -US-Ho1,CO2_1_1_2,20110628,31,GA_CP-LI-COR LI-7200,,intake height is listed; instrument is in building below,7-5 -US-Ho1,FC_1_1_1,19960101,31,GA_CP-LI-COR LI-6262,SA-ATI SATI K Style,,7-5 -US-Ho1,FC_1_1_1,20120606,31,GA_CP-Picarro G2311-f,SA-ATI SATI K Style,,7-5 -US-Ho1,FC_1_1_2,20110628,31,GA_CP-LI-COR LI-7200,SA-ATI SATI K Style,,7-5 -US-Ho1,FCH4_1_1_1,20120606,31,GA_CP-Picarro G2311-f,SA-ATI SATI K Style,,7-5 -US-Ho1,FCH4_SSITC_TEST_1_1_1,20120606,31,GA_CP-Picarro G2311-f,,,7-5 -US-Ho1,FC_SSITC_TEST_1_1_1,19960101,31,GA_CP-LI-COR LI-6262,,,7-5 -US-Ho1,FC_SSITC_TEST_1_1_1,20120606,31,GA_CP-Picarro G2311-f,,,7-5 -US-Ho1,FC_SSITC_TEST_1_1_2,20110628,31,GA_CP-LI-COR LI-7200,,,7-5 -US-Ho1,FETCH_70_1_1_1,19960101,31,SA-ATI SATI K Style,,,7-5 -US-Ho1,FETCH_90_1_1_1,19960101,31,SA-ATI SATI K Style,,,7-5 -US-Ho1,FETCH_MAX_1_1_1,19960101,31,SA-ATI SATI K Style,,,7-5 -US-Ho1,H_1_1_1,199601,31,SA-ATI SATI K Style,,,7-5 -US-Ho1,H2O_1_1_1,19960101,31,GA_CP-LI-COR LI-6262,,,7-5 -US-Ho1,H2O_1_1_1,20120606,31,GA_CP-Picarro G2311-f,,,7-5 -US-Ho1,H2O_1_1_2,20110628,31,GA_CP-LI-COR LI-7200,,,7-5 -US-Ho1,H_SSITC_TEST_1_1_1,19960101,31,SA-ATI SATI K Style,,,7-5 -US-Ho1,LE_1_1_1,19960101,31,GA_CP-LI-COR LI-6262,SA-ATI SATI K Style,,7-5 -US-Ho1,LE_1_1_1,20120606,31,GA_CP-Picarro G2311-f,SA-ATI SATI K Style,,7-5 -US-Ho1,LE_1_1_2,20110628,31,GA_CP-LI-COR LI-7200,SA-ATI SATI K Style,,7-5 -US-Ho1,LE_SSITC_TEST_1_1_1,19960101,31,SA-ATI SATI K Style,,,7-5 -US-Ho1,LW_IN_1_1_1,20161101,28.3,RAD-Pyrrad-SW+LW,,Kipp and Zonen CNR4 with heater/ventilator,7-5 -US-Ho1,LW_IN_2_1_1,200701,27.7,RAD-Pyrrad-SW+LW,,Kipp & ZonCNR1 (W m-2); US-Ho2 instrument better represents our flux data at US-Ho1,7-5 -US-Ho1,LW_OUT_1_1_1,20161101,28.3,RAD-Pyrrad-SW+LW,,Kipp and Zonen CNR4 with heater/ventilator,7-5 -US-Ho1,LW_OUT_2_1_1,200701,27.7,RAD-Pyrrad-SW+LW,,Kipp & Zonen CNR1 (W m-2);US-Ho2 instrument better represents our flux data at US-Ho1,7-5 -US-Ho1,NEE_PI_1_1_1,19960101,31,GA_CP-LI-COR LI-6262,SA-ATI SATI K Style,,7-5 -US-Ho1,NEE_PI_1_1_1,20120606,31,GA_CP-Picarro G2311-f,SA-ATI SATI K Style,,7-5 -US-Ho1,NEE_PI_1_1_2,20110628,31,GA_CP-LI-COR LI-7200,SA-ATI SATI K Style,,7-5 -US-Ho1,NETRAD_1_1_1,199505,28.3,RAD-Pyrrad-SW+LW,,199505:REBS Q*7.1 Net Rad w/ ventilator; 20161101:Kipp and Zonen CNR4 with heater/ventilator,7-5 -US-Ho1,NETRAD_2_1_1,200701,27.7,RAD-Pyrrad-SW+LW,,US-Ho2 instrument data; better represents US-Ho1 flux: CNR1;,7-5 -US-Ho1,P_2_1_1,20020913,,PREC-WeightGauge,,(represents liquid & solid precipitation) U.S. Climate Reference Network data (hourly converted to half hour) from Old Town; ME; Roger's Farm site(~40km from US-Ho1); WBAN # 94644,7-5 -US-Ho1,PA_1_1_1,19960101,1,PRES-ElectBar,,used for Ho-1; Ho-2; Ho-3,7-5 -US-Ho1,PPFD_IN_1_1_1,1996,28.3,RAD-PAR Quantum,,1996:Li190SA; 200904:Kipp & Zonen PAR lite Quantum,7-5 -US-Ho1,P_RAIN_1_1_1,1995,31,RAIN-TipBucGauge,,heater not able to keep up in winter months; therefore data not reliable in winter months; mounted on tower top: under estimates; originally entered as PREC-TipbucGauge;changed to 'Rain' 20180301,7-5 -US-Ho1,RH_1_1_2,20110628,31,GA_CP-LI-COR LI-7200,,Entered as RH_EP_1_1_2; derived from EP/GA; RH_EP_1_1_1 is GA Picarro:see BADM,7-5 -US-Ho1,RH_1_2_1,20170913,29,RH-Capac,,HC2-S3-L135 Rotronic HygroClip2 Temperature/RH Probe; in Met One aspirator; Used for US-Ho2&3 as RH_2_1_1,7-5 -US-Ho1,RH_PI_F_2_1_1,19960101,,GA_CP-LI-COR LI-6262,,"We used the above-canopy air temp from tower to calculate the RH along with the NLDAS-2 specific humidity data provided by the NASA Land Data Assimilation System; ""NLDAS-2 Forcing File A"" for our location: 45.20367N and 68.7404W. Reference: Cosgrove; B. A.; et.al.; Real-time and retrospective forcing in the North American Land Data Assimilation System (NLDAS) project; J. Geophys. Res.; Vol. 108; No D22; 8842; doi:10.1029/2002JD003118; 2003",7-5 -US-Ho1,SWC_2_1_1,19991026,-0.05,SWC-FDR,,,7-5 -US-Ho1,SWC_2_2_1,19991026,-0.1,SWC-FDR,,,7-5 -US-Ho1,SWC_2_3_1,19991026,-0.2,SWC-FDR,,,7-5 -US-Ho1,SWC_2_4_1,19991026,-0.5,SWC-FDR,,,7-5 -US-Ho1,SWC_2_5_1,19961026,-1,SWC-FDR,,,7-5 -US-Ho1,SWC_3_1_1,20150617,-0.05,SWC-FDR,,,7-5 -US-Ho1,SWC_3_2_1,20150617,-0.1,SWC-FDR,,,7-5 -US-Ho1,SWC_3_3_1,20150617,-0.2,SWC-FDR,,,7-5 -US-Ho1,SWC_3_4_1,20150617,-0.5,SWC-FDR,,,7-5 -US-Ho1,SWC_3_5_1,20150617,-1,SWC-FDR,,,7-5 -US-Ho1,SW_IN_1_1_1,20161101,28.3,RAD-Pyrrad-SW+LW,,Kipp & Zonen CNR4 w/ heater/ventilator,7-5 -US-Ho1,SW_IN_2_1_1,200701,27.7,RAD-Pyrrad-SW+LW,,US-Ho2 (800m NW of main tower) radiometric data from CNR1 more representative of our flux area; therefore included in our submitted main flux data files,7-5 -US-Ho1,SW_OUT_1_1_1,20161101,28.3,RAD-Pyrrad-SW+LW,,Kipp and Zonen CNR4 with heater/ventilator,7-5 -US-Ho1,SW_OUT_2_1_1,200701,27.7,RAD-Pyrrad-SW+LW,,US-Ho2 (800m NW of main tower) CNR1 radiometric data more representative of our flux area; therefore included in our submitted main flux data files,7-5 -US-Ho1,TA_1_1_1,1996,28,TEMP-ElectResis,,100 ohm PRT in Met One Aspirator; used for EP flux biomet file1999-2012 US-Ho2 & 3 as TA_2_1_1,7-5 -US-Ho1,TAU_1_1_1,19960101,31,SA-ATI SATI K Style,,,7-5 -US-Ho1,TS_1_1_1,19960101,-0.05,TEMP-TCouple,,,7-5 -US-Ho1,TS_2_1_1,19991026,-0.05,TEMP-Thermis,,thermister attached to soil moisture probe(SCW_FDR),7-5 -US-Ho1,TS_2_2_1,19991026,-0.1,TEMP-Thermis,,thermister attached to soil moisture probe(SWC-FDR),7-5 -US-Ho1,TS_2_3_1,19991026,-0.2,TEMP-Thermis,,thermister attached to soil moisture probe(SWC-FDR),7-5 -US-Ho1,TS_2_4_1,19991026,-0.5,TEMP-Thermis,,thermister attached to soil moisture probe(SWCFDR),7-5 -US-Ho1,TS_2_5_1,19991026,-1,TEMP-Thermis,,thermister attached to soil moisture probe(SWC_FDR),7-5 -US-Ho1,TS_3_1_1,20150617,-0.05,TEMP-Thermis,,,7-5 -US-Ho1,TS_3_2_1,20150617,-0.1,TEMP-Thermis,,,7-5 -US-Ho1,TS_3_3_1,20150617,-0.2,TEMP-Thermis,,,7-5 -US-Ho1,TS_3_4_1,20150617,-0.5,TEMP-Thermis,,,7-5 -US-Ho1,TS_3_5_1,20150617,-1,TEMP-Thermis,,,7-5 -US-Ho1,T_SONIC_1_1_1,19960101,31,SA-ATI SATI K Style,,,7-5 -US-Ho1,USTAR_1_1_1,19960101,31,SA-ATI SATI K Style,,,7-5 -US-Ho1,VPD_PI_1_1_1,199601,31,GA_CP-LI-COR LI-6262,, derived from EP/GA(Li6262),7-5 -US-Ho1,VPD_PI_1_1_2,20110628,31,GA_CP-LI-COR LI-7200,,derived from EP/GA(Li7200),7-5 -US-Ho1,VPD_PI_1_1_3,20120606,31,GA_CP-Picarro G2311-f,,derived from EP/GA(Picarro),7-5 -US-Ho1,WD_1_1_1,1996,30,SA-ATI SATI K Style,,,7-5 -US-Ho1,WD_2_1_1,1995,30,WIND-Other,,1995 RMY Wind Sentry 03001-5;20170914 RMY Wind monitor-AQ; model 05305,7-5 -US-Ho1,WS_1_1_1,1996,30,SA-ATI SATI K Style,,,7-5 -US-Ho1,WS_2_1_1,1995,30,WIND-Other,,1995 RMY Wind Sentry 03001-5;20170914 replaced with RMY AQ model 05305,7-5 -US-Ho1,WTD_1_1_1,20061215,-0.8,WTD-Press,,height is the well depth (deepest point),7-5 -US-Ho1,WTD_2_1_1,20130904,-1.45,WTD-Press,,height is the well depth (deepest point),7-5 -US-Ho1,ZL_1_1_1,19960101,31,SA-ATI SATI K Style,,,7-5 -US-Ho2,CO2_1_1_1,19990101,27.7,GA_CP-LI-COR LI-6262,,height is intake; instrument is in shelter at bottom of tower,4-5 -US-Ho2,CO2_1_1_1,20140706,28.3,GA_CP-LI-COR LI-7200,,instrument mounted on top of tower; near SA: moved into shelter 20190619,4-5 -US-Ho2,FC_1_1_1,19990101,27.7,GA_CP-LI-COR LI-6262,SA-ATI SATI K Style,height is intake; GA instrument is in shelter at bottom of tower,4-5 -US-Ho2,FC_1_1_1,20140706,28.3,GA_CP-LI-COR LI-7200,SA-Gill Windmaster,GA mounted on top of tower; near SA,4-5 -US-Ho2,FC_1_1_1,20190619,28.3,GA_CP-LI-COR LI-7200,SA-ATI SATI K Style,instrument height refers to intake filter and tubing; 7200 is located in shelter at bottom of tower,4-5 -US-Ho2,FC_SSITC_TEST,19990101,27.7,SA-ATI SATI K Style,,,4-5 -US-Ho2,FC_SSITC_TEST,20140706,28.3,SA-Gill Windmaster,,,4-5 -US-Ho2,FC_SSITC_TEST,20190619,28.3,SA-ATI SATI K Style,,,4-5 -US-Ho2,FETCH_70_1_1_1,19990101,27.7,SA-ATI SATI K Style,,,4-5 -US-Ho2,FETCH_70_1_1_1,20140706,28.3,SA-Gill Windmaster,,,4-5 -US-Ho2,FETCH_70_1_1_1,20190619,28.3,SA-ATI SATI K Style,,,4-5 -US-Ho2,FETCH_90_1_1_1,19990101,27.7,SA-ATI SATI K Style,,,4-5 -US-Ho2,FETCH_90_1_1_1,20140706,28.3,SA-Gill Windmaster,,,4-5 -US-Ho2,FETCH_90_1_1_1,20190619,28.3,SA-ATI SATI K Style,,,4-5 -US-Ho2,FETCH_MAX_1_1_1,19990101,27.7,SA-ATI SATI K Style,,,4-5 -US-Ho2,FETCH_MAX_1_1_1,20140706,28.3,SA-Gill Windmaster,,,4-5 -US-Ho2,FETCH_MAX_1_1_1,20190619,28.3,SA-ATI SATI K Style,,,4-5 -US-Ho2,H_1_1_1,19990101,27.7,SA-ATI SATI K Style,,,4-5 -US-Ho2,H_1_1_1,20140705,28.3,SA-Gill Windmaster,,,4-5 -US-Ho2,H_1_1_1,20190619,28.3,SA-ATI SATI K Style,,installed when Gill SA removed,4-5 -US-Ho2,H2O_1_1_1,19990101,27.7,GA_CP-LI-COR LI-6262,,,4-5 -US-Ho2,H2O_1_1_1,20140705,28.3,GA_CP-LI-COR LI-7200,,,4-5 -US-Ho2,H_SSITC_TEST,19990101,27.7,SA-ATI SATI K Style,,,4-5 -US-Ho2,H_SSITC_TEST,20140706,28.3,SA-Gill Windmaster,,,4-5 -US-Ho2,H_SSITC_TEST,20190619,28.3,SA-ATI SATI K Style,,,4-5 -US-Ho2,LE_1_1_1,19990101,27.7,GA_CP-LI-COR LI-6262,SA-ATI SATI K Style,,4-5 -US-Ho2,LE_1_1_1,20140706,28.3,GA_CP-LI-COR LI-7200,SA-Gill Windmaster,,4-5 -US-Ho2,LE_1_1_1,20190619,28.3,GA_CP-LI-COR LI-7200,SA-ATI SATI K Style,GA moved from tower top into shelter at this time,4-5 -US-Ho2,LE_SSITC_TEST,19990101,27.7,SA-ATI SATI K Style,,,4-5 -US-Ho2,LE_SSITC_TEST,20140706,28.3,SA-Gill Windmaster,,,4-5 -US-Ho2,LE_SSITC_TEST,20190619,28.3,SA-ATI SATI K Style,,,4-5 -US-Ho2,LW_IN_1_1_1,200701,27.7,RAD-Pyrrad-SW+LW,,this data is used for US-Ho1 as LW_IN_2_1_1; it best represents our flux data,4-5 -US-Ho2,LW_OUT_1_1_1,200701,27.7,RAD-Pyrrad-SW+LW,,this data is used for US-Ho1 as LW_OUT_2_1_1; it best represents our flux data,4-5 -US-Ho2,NEE_PI_1_1_1,19990101,27.7,GA_CP-LI-COR LI-6262,SA-ATI SATI K Style,,4-5 -US-Ho2,NEE_PI_1_1_1,20140706,28.3,GA_CP-LI-COR LI-7200,SA-Gill Windmaster,,4-5 -US-Ho2,NEE_PI_1_1_1,20190619,28.3,GA_CP-LI-COR LI-7200,SA-ATI SATI K Style,instrument height refers to intake filter and tubing; 7200 is located in shelter at bottom of tower,4-5 -US-Ho2,NETRAD_1_1_1,200701,27.7,RAD-Pyrrad-SW+LW,,this data is used for US-Ho1 as NETRAD_2_1_1; it best represents our flux data ,4-5 -US-Ho2,P_2_1_1,20020913,1,RAIN-WeightGauge,,(represents liquid & solid precipitation) U.S. Climate Reference Network data (hourly converted to half hour) from Old Town; ME; Roger's Farm site(~40km from US-Ho1); WBAN # 94644;used for Ho1;2;3,4-5 -US-Ho2,PA_1_1_1,19990101,1,PRES-ElectBar,,instrument is located on US-Ho1; 800m SE of US-Ho2,4-5 -US-Ho2,PPFD_IN_1_1_1,1999,27.7,RAD-PAR Quantum,,Used for US-Ho-3 as PPFD_2_1_1;1999:LI190-SA; up facing;20150917:Kip & Zonen; par lite,4-5 -US-Ho2,P_RAIN_1_1_1,2000,26.7,RAIN-TipBucGauge,,Texas Electronics TE525 tipping bucket;heater not able to keep up in winter months; therefore data not reliable in winter months;was originally entered as PREC-TipbucGauge;changed to 'Rain' 20180301,4-5 -US-Ho2,RH_1_1_1,20140706,28.3,GA_CP-LI-COR LI-7200,,RH is from the GA and is used by EddyPro unless biomet directs the data to our sensor on US-Ho1,4-5 -US-Ho2,RH_2_1_1,20170913,29,RH-Capac,,sensor located on US-Ho1(RH_1_2_1); used for Ho1;2;3 as RH_2_1_1,4-5 -US-Ho2,RH_PI_F_2_1_1,19990101,,GA_CP-LI-COR LI-6262,,"We used the above-canopy air temp from tower to calculate the RH along with the NLDAS-2 specific humidity data provided by the NASA Land Data Assimilation System; ""NLDAS-2 Forcing File A"" for our location: 45.20367N and 68.7404W. Reference: Cosgrove; B. A.; et.al.; Real-time and retrospective forcing in the North American Land Data Assimilation System (NLDAS) project; J. Geophys. Res.; Vol. 108; No D22; 8842; doi:10.1029/2002JD003118; 2003",4-5 -US-Ho2,SW_IN_1_1_1,200701,27.7,RAD-Pyrrad-SW+LW,,this data is used for US-Ho1 as SW_IN_2_1_1; it best represents our flux data,4-5 -US-Ho2,SW_OUT_1_1_1,200701,27.7,RAD-Pyrrad-SW+LW,,this data is used for US-Ho1 as SW_OUT_2_1_1; it best represents our flux data,4-5 -US-Ho2,TA_1_1_1,1999,27.7,TEMP-ElectResis,,,4-5 -US-Ho2,TA_2_1_1,19990101,28,TEMP-ElectResis,,located on US-Ho1 (TA_1_1_1 @28m ht) used on all towers biomet file for flux EP 1999-2012 and included in submitted data files for US-Ho2 & 3 as TA_2_1_1,4-5 -US-Ho2,TAU_1_1_1,19990101,27.7,SA-ATI SATI K Style,,,4-5 -US-Ho2,TAU_1_1_1,20140706,28.3,SA-Gill Windmaster,,,4-5 -US-Ho2,TAU_1_1_1,20190619,28.3,SA-ATI SATI K Style,,,4-5 -US-Ho2,TS_1_1_1,20070109,-0.05,TEMP-TCouple,,,4-5 -US-Ho2,TS_1_1_2,20070109,-0.05,TEMP-TCouple,,,4-5 -US-Ho2,TS_1_1_3,20070109,-0.05,TEMP-TCouple,,,4-5 -US-Ho2,TS_1_1_4,20070109,-0.05,TEMP-TCouple,,,4-5 -US-Ho2,T_SONIC_1_1_1,19990101,27.7,SA-ATI SATI K Style,,,4-5 -US-Ho2,T_SONIC_1_1_1,20140706,28.3,SA-Gill Windmaster,,,4-5 -US-Ho2,T_SONIC_1_1_1,20190619,28.3,SA-ATI SATI K Style,,,4-5 -US-Ho2,USTAR_1_1_1,19990101,27.7,SA-ATI SATI K Style,,,4-5 -US-Ho2,USTAR_1_1_1,20140706,28.3,SA-Gill Windmaster,,,4-5 -US-Ho2,USTAR_1_1_1,20190619,28.3,SA-ATI SATI K Style,,,4-5 -US-Ho2,VPD_PI_1_1_2,19990101,27.7,GA_CP-LI-COR LI-6262,,VPD_1_1_2 derived using RH from the GA and as processed with EddyPro,4-5 -US-Ho2,VPD_PI_1_1_2,20140706,28.3,GA_CP-LI-COR LI-7200,,VPD_1_1_2 derived using RH from the GA and as processed with EddyPro,4-5 -US-Ho2,WD_1_1_1,19990101,27.7,SA-ATI SATI K Style,,,4-5 -US-Ho2,WD_1_1_1,20140706,28.3,SA-Gill Windmaster,,,4-5 -US-Ho2,WD_1_1_1,20190619,28.3,SA-ATI SATI K Style,,,4-5 -US-Ho2,WS_1_1_1,19990101,27.7,SA-ATI SATI K Style,,,4-5 -US-Ho2,WS_1_1_1,20140706,28.3,SA-Gill Windmaster,,,4-5 -US-Ho2,WS_1_1_1,20190619,28.3,SA-ATI SATI K Style,,,4-5 -US-Ho2,ZL_1_1_1,19990101,27.7,SA-ATI SATI K Style,,,4-5 -US-Ho2,ZL_1_1_1,20140706,28.3,SA-Gill Windmaster,,,4-5 -US-Ho2,ZL_1_1_1,20190619,28.3,SA-ATI SATI K Style,,,4-5 -US-Ho3,FC,20030731,29.6,GA_CP-LI-COR LI-6262,SA-ATI SATI K Style,,2-1 -US-Ho3,H,20030731,29.6,SA-ATI SATI K Style,,,2-1 -US-Ho3,TA,20030731,29.6,GA_CP-LI-COR LI-6262,,,2-1 -US-Ho3,TA,20110217,29.6,GA_CP-LI-COR LI-7200,,Replaces Li-6262,2-1 -US-Ho3,LE,20030731,29.6,GA_CP-LI-COR LI-6262,SA-ATI SATI K Style,GA & SA used for first published fluxes,2-1 -US-Ho3,LE,20110217,29.6,GA_CP-LI-COR LI-7200,SA-ATI SATI K Style,,2-1 -US-Ho3,TS_1,20030731,29.6,GA_CP-LI-COR LI-6262,SA-ATI SATI K Style,,2-1 -US-Ho3,TS_1,20110217,29.6,GA_CP-LI-COR LI-7200,SA-ATI SATI K Style,Replaces Li-6262,2-1 -US-Ho3,NETRAD,20030101,23.2,RAD-Net radiometer,,REBS Q7.1,2-1 -US-Ho3,PPFD_IN,20030101,,RAD-PAR Quantum,,PPFD_IN data from Ho2 instrument (west tower) located ~1600m west of Ho3; best represents our flux environment,2-1 -US-Ho3,USTAR,20030731,29.6,SA-ATI SATI K Style,,,2-1 -US-Ho3,RECO_PI_PI,20030731,29.6,GA_CP-LI-COR LI-6262,,EddyPro calculated using GA,2-1 -US-Ho3,RECO_PI_PI,20110217,29.6,GA_CP-LI-COR LI-7200,,Replaces Li-6262; EddyPro calculated using GA,2-1 -US-HRA,CH4_1_1_1,,2.28,GA_OP-LI-COR LI-7700,,,3-5 -US-HRA,CO2_1_1_1,,2.28,GA_OP-LI-COR LI-7500,,,3-5 -US-HRA,FC_1_1_1,,2.28,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,3-5 -US-HRA,FCH4,,2.28,GA_OP-LI-COR LI-7700,SA-Campbell CSAT-3,,3-5 -US-HRA,G,,-0.04,SOIL_H-Plate,,,3-5 -US-HRA,H2O_1_1_1,,2.28,GA_OP-LI-COR LI-7500,,,3-5 -US-HRA,LE,,2.28,GA_OP-LI-COR LI-7500,,,3-5 -US-HRA,NETRAD,,,RAD-Pyrrad-SW+LW,,,3-5 -US-HRA,PA,,1.5,PRES-ElectBar,,,3-5 -US-HRA,P_RAIN,,1.5,PREC-TipBucGauge,,,3-5 -US-HRA,RH_1_1_1,,2.28,RH-Capac,,,3-5 -US-HRA,SWC_1_1_1,,-0.07,SWC-TDR,,,3-5 -US-HRA,TA_1_1_1,,2.28,TEMP-ElectResis,,,3-5 -US-HRA,T_SONIC,,2.28,SA-Campbell CSAT-3,,,3-5 -US-HRA,USTAR,,2.28,SA-Campbell CSAT-3,,,3-5 -US-HRA,WD,,2.28,SA-Campbell CSAT-3,,,3-5 -US-HRA,WS,,2.28,SA-Campbell CSAT-3,,,3-5 -US-HRA,WS_MAX,,2.28,SA-Campbell CSAT-3,,,3-5 -US-HRA,WTD,,-0.3,,,,3-5 -US-HRC,CO2_1_1_1,,2.28,GA_OP-LI-COR LI-7500,,,3-5 -US-HRC,H2O_1_1_1,,2.28,GA_OP-LI-COR LI-7500,,,3-5 -US-HRC,T_SONIC,,2.28,SA-Campbell CSAT-3,,,3-5 -US-HVa,FC,,2,,,,2-1 -US-HVa,H,,2,,,,2-1 -US-HVa,LE,,2,,,,2-1 -US-HVa,TA,,2,,,,2-1 -US-HVa,TS_1,,-0.05,,,,2-1 -US-HVa,TS_2,,-0.1,,,,2-1 -US-HVa,USTAR,,2,,,,2-1 -US-HVa,WD,,2,,,,2-1 -US-HVa,WS,,2,,,,2-1 -US-HWB,CO2,20150716,3,GA_OP_SA-Campbell IRGASON,,set Irgasson initially to 3m for alfalfa crop,1-5 -US-HWB,CO2,20170711,5,GA_OP_SA-Campbell IRGASON,,raised Irgasson to 5m for corn crop,1-5 -US-HWB,FC,20150716,3,GA_OP_SA-Campbell IRGASON,,set Irgasson initially to 3m for alfalfa crop,1-5 -US-HWB,FC,20170711,5,GA_OP_SA-Campbell IRGASON,,raised Irgasson to 5m for corm crop,1-5 -US-HWB,H,20150716,0.08,SOIL_H-Plate,,height is 8cm below ground,1-5 -US-HWB,H2O,20150716,3,GA_OP_SA-Campbell IRGASON,,set Irgasson initially to 3m for alfalfa crop,1-5 -US-HWB,H2O,20170711,5,GA_OP_SA-Campbell IRGASON,,raised Irgasson to 5m for corn crop,1-5 -US-HWB,LW_IN,20150716,3,SPECT-SpectRad,,,1-5 -US-HWB,LW_OUT,20150716,3,SPECT-SpectRad,,,1-5 -US-HWB,NEE_PI,20150716,3,GA_OP_SA-Campbell IRGASON,,set Irgasson initially to 3m for alfalfa crop,1-5 -US-HWB,NEE_PI,20170711,5,GA_OP_SA-Campbell IRGASON,,raised Irgasson to 5m for corn crop,1-5 -US-HWB,NETRAD,20150716,3,SPECT-SpectRad,,,1-5 -US-HWB,PPFD_IN,20150716,3,RAD-PAR Quantum,,,1-5 -US-HWB,P_RAIN,20150716,1,RAIN-TipBucGauge,,,1-5 -US-HWB,RH,20150716,3,RH-Capac,,,1-5 -US-HWB,SH,20150915,0.08,MULTI-Meteo,,height is 8cm below ground,1-5 -US-HWB,SLE,20150716,,SOIL_H-Plate,,height is 8cm below ground,1-5 -US-HWB,SWC,20150716,-0.05,SWC-TDR,,height is 5cm below ground,1-5 -US-HWB,SW_IN,20150716,3,SPECT-SpectRad,,,1-5 -US-HWB,SW_OUT,20150716,3,SPECT-SpectRad,,,1-5 -US-HWB,TA,20150716,3,TEMP-ElectResis,,,1-5 -US-HWB,T_CANOPY,20150915,3,TEMP-Other,,,1-5 -US-HWB,TS,20150716,,SA-Other,,set Irgasson initially to 3m for alfalfa crop,1-5 -US-HWB,USTAR,20150716,3,GA_OP_SA-Campbell IRGASON,,set Irgasson initially to 3m for alfalfa crop,1-5 -US-HWB,USTAR,20170711,5,GA_OP_SA-Campbell IRGASON,,raised Irgasson to 5m for corn crop,1-5 -US-HWB,VPD_PI,20150716,3,GA_OP_SA-Campbell IRGASON,,set Irgasson initially to 3m for alfalfa crop,1-5 -US-HWB,VPD_PI,20170711,5,GA_OP_SA-Campbell IRGASON,,raised Irgasson to 5m for corn crop,1-5 -US-HWB,WD,20150716,3,GA_OP_SA-Campbell IRGASON,,set Irgasson initially to 3m for alfalfa crop,1-5 -US-HWB,WD,20170711,5,GA_OP_SA-Campbell IRGASON,,raised Irgasson to 5m for corn crop,1-5 -US-HWB,WS,20150716,3,GA_OP_SA-Campbell IRGASON,,set Irgasson initially to 3m for alfalfa crop,1-5 -US-HWB,WS,20170711,5,GA_OP_SA-Campbell IRGASON,,raised Irgasson to 5m for corn crop,1-5 -US-HWB,ZL,20150716,3,GA_OP_SA-Campbell IRGASON,,SET Irgasson initially to 3m for alfalfa crop,1-5 -US-HWB,ZL,20170711,5,GA_OP_SA-Campbell IRGASON,,raised Irgasson to 5m for corn crop,1-5 -US-IB1,ALB,20050701,2.4,RAD-Other,,Schenk Dual-Pyranometer Type 8104,8-5 -US-IB1,ALB_PI_F,20050701,2.4,RAD-Other,,Schenk Dual-Pyranometer Type 8104,8-5 -US-IB1,APAR,20050701,2.4,RAD-PAR Quantum,,LI-190SA,8-5 -US-IB1,APAR_PI_F,20050701,2.4,RAD-PAR Quantum,,LI-190SA,8-5 -US-IB1,CO2,20050701,4.05,GA_OP-LI-COR LI-7500,,,8-5 -US-IB1,CO2DEN,20050701,4.05,GA_OP-LI-COR LI-7500,,,8-5 -US-IB1,FAPAR,20050701,2.4,RAD-PAR Quantum,,LI-190SA,8-5 -US-IB1,FAPAR_PI_F,20050701,2.4,RAD-PAR Quantum,,LI-190SA,8-5 -US-IB1,FC,20050701,4.05,GA_OP-LI-COR LI-7500,SA-Gill Windmaster Pro,,8-5 -US-IB1,FC_PI_F,20050701,4.05,GA_OP-LI-COR LI-7500,SA-Gill Windmaster Pro,,8-5 -US-IB1,FH2O,20050701,4.05,GA_OP-LI-COR LI-7500,,,8-5 -US-IB1,FH2O_FILL,20050701,4.05,GA_OP-LI-COR LI-7500,,,8-5 -US-IB1,G,20050701,-0.05,SOIL_H-Plate,,REBS HFT-3.1with adjustment for soil energy storage above plate,8-5 -US-IB1,G_PI_F,20050701,-0.05,SOIL_H-Plate,,,8-5 -US-IB1,H,20050701,4.05,SA-Gill Windmaster Pro,,,8-5 -US-IB1,H_PI_F,20050701,4.05,SA-Gill Windmaster Pro,,,8-5 -US-IB1,LE,20050701,4.05,SA-Gill Windmaster Pro,GA_OP-LI-COR LI-7500,,8-5 -US-IB1,LE_PI_F,20050701,4.05,SA-Gill Windmaster Pro,GA_OP-LI-COR LI-7500,,8-5 -US-IB1,NETRAD,20050701,2.4,RAD-Net radiometer,,REBS Q*7.1,8-5 -US-IB1,NETRAD_PI_F,20050701,2.4,RAD-Net radiometer,,REBS Q*7.1,8-5 -US-IB1,P,20050701,2,PREC-TipBucGauge,,Belfort OMC-212,8-5 -US-IB1,PA,20050701,1.5,PRES-ElectBar,,Met One 7120,8-5 -US-IB1,PA_PI_F,20050701,1.5,PRES-ElectBar,,Met One 7120,8-5 -US-IB1,P_PI_F,20050701,2,PREC-TipBucGauge,,Belfort OMC-212,8-5 -US-IB1,PPFD_IN,20050701,2.4,RAD-PAR Quantum,,LI-190SA,8-5 -US-IB1,PPFD_IN_PI_F,20050701,2.4,RAD-PAR Quantum,,LI-190SA,8-5 -US-IB1,PPFD_OUT,20050701,2.4,RAD-PAR Quantum,,LI-190SA,8-5 -US-IB1,PPFD_OUT_PI_F,20050701,2.4,RAD-PAR Quantum,,LI-190SA,8-5 -US-IB1,PRECCUM,20050701,2,PREC-TipBucGauge,,Belfort OMC-212,8-5 -US-IB1,RH,20050701,3.5,RH-Capac,,Vaisala HMP45A,8-5 -US-IB1,RH_PI_F,20050701,3.5,RH-Capac,,Vaisala HMP45A,8-5 -US-IB1,SWC_1_1_1,20050701,-0.025,SWC-Other,,REBS SMP-1,8-5 -US-IB1,SWC_1_1_1_F,20050701,-0.025,SWC-Other,,REBS SMP-1,8-5 -US-IB1,SWC_1_2_1,20050701,-0.1,SWC-Other,,REBS SMP-1,8-5 -US-IB1,SWC_1_2_1_F,20050701,-0.1,SWC-Other,,REBS SMP-1,8-5 -US-IB1,SWC_1_3_1,20050701,-0.25,SWC-Other,,REBS SMP-1,8-5 -US-IB1,SWC_1_3_1_F,20050701,-0.25,SWC-Other,,REBS SMP-1,8-5 -US-IB1,SWC_1_4_1,20050701,-0.5,SWC-Other,,REBS SMP-1,8-5 -US-IB1,SWC_1_4_1_F,20050701,-0.5,SWC-Other,,REBS SMP-1,8-5 -US-IB1,SW_IN,20050701,2.4,RAD-Other,,Schenk Dual-Pyranometer Type 8194,8-5 -US-IB1,SW_IN_PI_F,20050701,2.4,RAD-Other,,Schenk Dual-Pyranometer Type 8194,8-5 -US-IB1,SW_OUT,20050701,2.4,RAD-Other,,Schenk Dual-Pyranometer Type 8194,8-5 -US-IB1,SW_OUT_PI_F,20050701,2.4,RAD-Other,,Schenk Dual-Pyranometer Type 8194,8-5 -US-IB1,TA,20050701,3.5,TEMP-ElectResis,,Vaisala HMP45A,8-5 -US-IB1,TA_PI_F,20050701,3.5,TEMP-ElectResis,,Vaisala HMP45A,8-5 -US-IB1,TAU,20050701,4.05,SA-Gill Windmaster Pro,,,8-5 -US-IB1,TAU_PI_F,20050701,4.05,SA-Gill Windmaster Pro,,,8-5 -US-IB1,TS_1_1_1,20050701,-0.025,TEMP-ElectResis,,REBS STP-1 integrated from 0 to 5 cm depth,8-5 -US-IB1,TS_1_1_1_F,20050701,-0.025,TEMP-ElectResis,,REBS STP-1 integrated from 0 to 5 cm depth,8-5 -US-IB1,TS_1_2_1,20050701,-0.1,TEMP-ElectResis,,REBS STP-1,8-5 -US-IB1,TS_1_2_1_F,20050701,-0.1,TEMP-ElectResis,,REBS STP-1,8-5 -US-IB1,TS_1_3_1,20050701,-0.25,TEMP-ElectResis,,REBS STP-1,8-5 -US-IB1,TS_1_3_1_F,20050701,-0.25,TEMP-ElectResis,,REBS STP-1,8-5 -US-IB1,TS_1_4_1,20050701,-0.5,TEMP-ElectResis,,REBS STP-1,8-5 -US-IB1,TS_1_4_1_F,20050701,-0.5,TEMP-ElectResis,,REBS STP-1,8-5 -US-IB1,USTAR,20050701,4.05,SA-Gill Windmaster Pro,,,8-5 -US-IB1,USTAR_PI_F,20050701,4.05,SA-Gill Windmaster Pro,,,8-5 -US-IB1,VPD_PI,20050701,3.5,RH-Capac,,Vaisala HMP45A,8-5 -US-IB1,VPD_PI_F,20050701,3.5,RH-Capac,,Vaisala HMP45A,8-5 -US-IB1,WD,20050701,4.05,SA-Gill Windmaster Pro,,,8-5 -US-IB1,WD_PI_F,20050701,4.05,SA-Gill Windmaster Pro,,,8-5 -US-IB1,WS,20050701,4.05,SA-Gill Windmaster Pro,,,8-5 -US-IB1,WS_PI_F,20050701,4.05,SA-Gill Windmaster Pro,,,8-5 -US-IB1,ZL,20050701,4.05,SA-Gill Windmaster Pro,,,8-5 -US-IB1,ZL_PI_F,20050701,4.05,SA-Gill Windmaster Pro,,,8-5 -US-IB2,ALB,20041006,2.3,RAD-SW Pyran Class1,,Eppley 8-48,8-5 -US-IB2,ALB_PI_F,20041006,2.3,RAD-SW Pyran Class1,,Eppley 8-48,8-5 -US-IB2,APAR,20041006,2.3,RAD-PAR Quantum,,LI-190SA,8-5 -US-IB2,APAR_PI_F,20041006,2.3,RAD-PAR Quantum,,LI-190SA,8-5 -US-IB2,CO2,20041006,3.76,GA_OP-LI-COR LI-7500,,,8-5 -US-IB2,CO2DEN,20041006,3.76,GA_OP-LI-COR LI-7500,,,8-5 -US-IB2,FAPAR,20041006,2.3,RAD-PAR Quantum,,LI-190SA,8-5 -US-IB2,FAPAR_PI_F,20041006,2.3,RAD-PAR Quantum,,LI-190SA,8-5 -US-IB2,FC,20041006,3.76,SA-Gill R3-100,GA_OP-LI-COR LI-7500,,8-5 -US-IB2,FC_PI_F,20041006,3.76,SA-Gill R3-100,GA_OP-LI-COR LI-7500,,8-5 -US-IB2,FH2O,20041006,3.76,GA_OP-LI-COR LI-7500,,,8-5 -US-IB2,FH2O_FILL,20041006,3.76,GA_OP-LI-COR LI-7500,,,8-5 -US-IB2,G,20041006,-0,SOIL_H-Plate,,REBS HFT-3.1 adjusted with soil energy storage above plate,8-5 -US-IB2,G_PI_F,20041006,-0,SOIL_H-Plate,,REBS HFT-3.1 adjusted with soil energy storage above plate,8-5 -US-IB2,H,20041006,3.76,SA-Gill R3-100,,,8-5 -US-IB2,H_PI_F,20041006,3.76,SA-Gill R3-100,,,8-5 -US-IB2,LE,20041006,3.76,SA-Gill R3-100,GA_OP-LI-COR LI-7500,,8-5 -US-IB2,LE_PI_F,20041006,3.76,SA-Gill R3-100,GA_OP-LI-COR LI-7500,,8-5 -US-IB2,NETRAD,20041006,2.3,RAD-Net radiometer,,REBS Q*7.1,8-5 -US-IB2,NETRAD_PI_F,20041006,2.3,RAD-Net radiometer,,REBS Q*7.1,8-5 -US-IB2,P,20041006,2,PREC-TipBucGauge,,Belfort OMC-212,8-5 -US-IB2,PA,20041006,1.5,PRES-ElectBar,,Met One 7120,8-5 -US-IB2,PA_PI_F,20041006,1.5,PRES-ElectBar,,Met One 7120,8-5 -US-IB2,P_PI_F,20041006,2,PREC-TipBucGauge,,Belfort OMC-212,8-5 -US-IB2,PPFD_IN,20041006,2.3,RAD-PAR Quantum,,LI-190SA,8-5 -US-IB2,PPFD_IN_PI_F,20041006,2.3,RAD-PAR Quantum,,LI-190SA,8-5 -US-IB2,PPFD_OUT,20041006,2.3,RAD-PAR Quantum,,LI-190SA,8-5 -US-IB2,PPFD_OUT_PI_F,20041006,2.3,RAD-PAR Quantum,,LI-190SA,8-5 -US-IB2,PRECCUM,20041006,2,PREC-TipBucGauge,,Belfort OMC-212,8-5 -US-IB2,RH,20041006,3.76,RH-Capac,,Vaisala HMP45D,8-5 -US-IB2,RH_PI_F,20041006,3.76,RH-Capac,,Vaisala HMP45D,8-5 -US-IB2,SWC_1_1_1,20041006,-0.025,SWC-Other,,REBS SMP-1,8-5 -US-IB2,SWC_1_1_1_F,20041006,-0.025,SWC-Other,,REBS SMP-1,8-5 -US-IB2,SWC_1_2_1,20041006,-0.1,SWC-Other,,REBS SMP-1,8-5 -US-IB2,SWC_1_2_1_F,20041006,-0.1,SWC-Other,,REBS SMP-1,8-5 -US-IB2,SWC_1_3_1,20041006,-0.25,SWC-Other,,REBS SMP-1,8-5 -US-IB2,SWC_1_3_1_F,20041006,-0.25,SWC-Other,,REBS SMP-1,8-5 -US-IB2,SWC_1_4_1,20041006,-0.5,SWC-Other,,REBS SMP-1,8-5 -US-IB2,SWC_1_4_1_F,20041006,-0.5,SWC-Other,,REBS SMP-1,8-5 -US-IB2,SW_IN,20041006,2.3,RAD-SW Pyran Class1,,Eppley 8-48,8-5 -US-IB2,SW_IN_PI_F,20041006,2.3,RAD-SW Pyran Class1,,Eppley 8-48,8-5 -US-IB2,SW_OUT,20041006,2.3,RAD-SW Pyran Class1,,Eppley 8-48,8-5 -US-IB2,SW_OUT_PI_F,20041006,2.3,RAD-SW Pyran Class1,,Eppley 8-48,8-5 -US-IB2,TA,20041006,3.76,TEMP-ElectResis,,Vaisala HMP45D,8-5 -US-IB2,TA_PI_F,20041006,3.76,TEMP-ElectResis,,Vaisala HMP45D,8-5 -US-IB2,TAU,20041006,3.76,SA-Gill R3-100,,,8-5 -US-IB2,TAU_PI_F,20041006,3.76,SA-Gill R3-100,,,8-5 -US-IB2,TS_1_1_1,20041006,-0.025,TEMP-ElectResis,,REBS STP-1 Integrated 0-5 cm,8-5 -US-IB2,TS_1_1_1_F,20041006,-0.025,TEMP-ElectResis,,REBS STP-1 Integrated 0-5 cm,8-5 -US-IB2,TS_1_2_1,20041006,-0.1,TEMP-ElectResis,,REBS STP-1,8-5 -US-IB2,TS_1_2_1_F,20041006,-0.1,TEMP-ElectResis,,REBS STP-1,8-5 -US-IB2,TS_1_3_1,20041006,-0.25,TEMP-ElectResis,,REBS STP-1,8-5 -US-IB2,TS_1_3_1_F,20041006,-0.25,TEMP-ElectResis,,REBS STP-1,8-5 -US-IB2,TS_1_4_1,20041006,-0.5,TEMP-ElectResis,,REBS STP-1,8-5 -US-IB2,TS_1_4_1_F,20041006,-0.5,TEMP-ElectResis,,REBS STP-1,8-5 -US-IB2,USTAR,20041006,3.76,SA-Gill R3-100,,,8-5 -US-IB2,USTAR_PI_F,20041006,3.76,SA-Gill R3-100,,,8-5 -US-IB2,VPD_PI,20041006,3.5,RH-Capac,,Vaisala HMP45D,8-5 -US-IB2,VPD_PI_F,20041006,3.5,RH-Capac,,Vaisala HMP45D,8-5 -US-IB2,WD,20041006,3.76,SA-Gill R3-100,,,8-5 -US-IB2,WD_PI_F,20041006,3.76,SA-Gill R3-100,,,8-5 -US-IB2,WS,20041006,3.76,SA-Gill R3-100,,,8-5 -US-IB2,WS_PI_F,20041006,3.76,SA-Gill R3-100,,,8-5 -US-IB2,ZL,20041006,3.76,SA-Gill R3-100,,,8-5 -US-IB2,ZL_PI_F,20041006,3.76,SA-Gill R3-100,,,8-5 -US-ICh,ALB,,1.95,RAD-SW Pyran Class1,,,4-5 -US-ICh,CO2,201605,3.18,GA_CP-LI-COR LI-7200RS,,replaced with new LI-7200,4-5 -US-ICh,CO2,,3.18,GA_OP-LI-COR LI-7500,,,4-5 -US-ICh,D_SNOW,,,SNOW-Acoustic,,,4-5 -US-ICh,FC,201605,3.18,GA_CP-LI-COR LI-7200RS,SA-Campbell CSAT-3,replaced with new LI-7200,4-5 -US-ICh,FC,,3.18,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,4-5 -US-ICh,FC_PI_F,201605,3.18,GA_CP-LI-COR LI-7200RS,SA-Campbell CSAT-3,replaced with new LI-7200,4-5 -US-ICh,FC_PI_F,,3.18,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,4-5 -US-ICh,G_1_1_1,,-0.08,SOIL_H-Plate_AUTO,,,4-5 -US-ICh,G_1_1_2,,-0.08,SOIL_H-Plate_AUTO,,,4-5 -US-ICh,G_2_1_1,,-0.08,SOIL_H-Plate_AUTO,,,4-5 -US-ICh,G_2_1_2,,-0.08,SOIL_H-Plate_AUTO,,,4-5 -US-ICh,H,,3.18,SA-Campbell CSAT-3,,,4-5 -US-ICh,H2O,,1.93,RH-ElecRes,,,4-5 -US-ICh,LE,201605,3.18,GA_CP-LI-COR LI-7200RS,SA-Campbell CSAT-3,,4-5 -US-ICh,LE,,3.18,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,4-5 -US-ICh,NETRAD,,1.95,RAD-Net radiometer,,,4-5 -US-ICh,P,,,RAIN-TipBucGauge,,,4-5 -US-ICh,PA,201605,1,GA_CP-LI-COR LI-7200RS,,,4-5 -US-ICh,PA,,1,GA_OP-LI-COR LI-7500,,,4-5 -US-ICh,PPFD_IN,,3.6,RAD-PAR Quantum,,,4-5 -US-ICh,PPFD_OUT,,2,RAD-PAR Quantum,,,4-5 -US-ICh,RH,,1.93,RH-ElecRes,,,4-5 -US-ICh,RH_PI_F,,1.93,RH-ElecRes,,,4-5 -US-ICh,SG_PI_1_1_A,,,,,Soil heat storage from soil sensor set _1_x_x,4-5 -US-ICh,SG_PI_2_1_A,,,,,Soil heat storage from soil sensor set _2_x_x,4-5 -US-ICh,SWC_1_1_1,,-0.025,SWC-TDR,,,4-5 -US-ICh,SWC_2_1_1,,-0.025,SWC-TDR,,,4-5 -US-ICh,SW_IN,,1.95,RAD-SW Pyran Class1,,,4-5 -US-ICh,SW_IN_PI_F,,1.95,RAD-SW Pyran Class1,,,4-5 -US-ICh,SW_OUT,,1.95,RAD-SW Pyran Class1,,,4-5 -US-ICh,TA,,1.93,TEMP-ElectResis,,,4-5 -US-ICh,TA_PI_F,,1.93,TEMP-ElectResis,,,4-5 -US-ICh,TAU,,3.18,SA-Campbell CSAT-3,,,4-5 -US-ICh,TS_1_1_1,,-0.02,TEMP-TCouple,,,4-5 -US-ICh,TS_2_1_1,,-0.02,TEMP-TCouple,,,4-5 -US-ICh,TS_PI_F_1_1_1,,-0.02,TEMP-TCouple,,,4-5 -US-ICh,USTAR,,3.18,SA-Campbell CSAT-3,,,4-5 -US-ICh,VPD_PI,,1.93,,,Calculated by PI,4-5 -US-ICh,VPD_PI_F,,1.93,,,Calculated in ReddyProc,4-5 -US-ICh,WD,,3.18,SA-Campbell CSAT-3,,,4-5 -US-ICh,WS,,2,WIND-CupAn,,,4-5 -US-ICs,CO2,201206,2.56,GA_OP-LI-COR LI-7500A,,Simple replacement with new 7500A,6-5 -US-ICs,CO2,201605,2.56,GA_CP-LI-COR LI-7200RS,,,6-5 -US-ICs,CO2,,2.56,GA_OP-LI-COR LI-7500,,,6-5 -US-ICs,D_SNOW,,2,SNOW-Acoustic,,,6-5 -US-ICs,D_SNOW_PI_F,,2,SNOW-Acoustic,,,6-5 -US-ICs,FC,201206,2.56,GA_OP-LI-COR LI-7500A,SA-Campbell CSAT-3,Simple replacment with new 7500A,6-5 -US-ICs,FC,201605,2.56,GA_CP-LI-COR LI-7200RS,SA-Campbell CSAT-3,,6-5 -US-ICs,FC,,2.56,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,6-5 -US-ICs,FC_PI_F,201206,2.56,GA_OP-LI-COR LI-7500A,SA-Campbell CSAT-3,,6-5 -US-ICs,FC_PI_F,201605,2.56,GA_CP-LI-COR LI-7200RS,SA-Campbell CSAT-3,,6-5 -US-ICs,FC_PI_F,,2.56,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,6-5 -US-ICs,FCH4,20140528,2.56,GA_OP-LI-COR LI-7700,SA-Campbell CSAT-3,Only measured ~May until Oct,6-5 -US-ICs,FCH4_PI_F,20140528,2.56,GA_OP-LI-COR LI-7700,SA-Campbell CSAT-3,Only measured ~May until Oct,6-5 -US-ICs,G_1_1_1,,-0.08,SOIL_H-Plate_AUTO,,,6-5 -US-ICs,G_1_1_2,,-0.08,SOIL_H-Plate_AUTO,,,6-5 -US-ICs,G_2_1_1,,-0.08,SOIL_H-Plate_AUTO,,,6-5 -US-ICs,G_2_1_2,,-.08,SOIL_H-Plate_AUTO,,,6-5 -US-ICs,H,,2.56,SA-Campbell CSAT-3,,,6-5 -US-ICs,H_PI_F,,2.56,SA-Campbell CSAT-3,,,6-5 -US-ICs,LE,201206,2.56,GA_OP-LI-COR LI-7500A,SA-Campbell CSAT-3,,6-5 -US-ICs,LE,201605,2.56,GA_CP-LI-COR LI-7200RS,SA-Campbell CSAT-3,,6-5 -US-ICs,LE,,2.56,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,6-5 -US-ICs,LE_PI_F,201206,2.56,GA_OP-LI-COR LI-7500A,SA-Campbell CSAT-3,,6-5 -US-ICs,LE_PI_F,201605,2.56,GA_CP-LI-COR LI-7200RS,SA-Campbell CSAT-3,,6-5 -US-ICs,LE_PI_F,,2.56,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,6-5 -US-ICs,LW_IN_PI_F,,2,,,Not actually meaused at this site; but data submitted for 2014-16; presumably all NAN,6-5 -US-ICs,NETRAD,,2,RAD-Net radiometer,,,6-5 -US-ICs,NETRAD_PI_F,,2,RAD-Net radiometer,,,6-5 -US-ICs,P,,,RAIN-TipBucGauge,,,6-5 -US-ICs,PA,201206,1,GA_OP-LI-COR LI-7500A,,,6-5 -US-ICs,PA,201605,1,GA_CP-LI-COR LI-7200RS,,,6-5 -US-ICs,PA,,1,GA_OP-LI-COR LI-7500,,,6-5 -US-ICs,PA_PI_F,201206,1,GA_OP-LI-COR LI-7500A,,,6-5 -US-ICs,PA_PI_F,201605,1,GA_CP-LI-COR LI-7200RS,,,6-5 -US-ICs,PA_PI_F,,1,GA_OP-LI-COR LI-7500,,,6-5 -US-ICs,P_PI_F,,,RAIN-TipBucGauge,,,6-5 -US-ICs,PPFD_IN,,2,RAD-PAR Quantum,,,6-5 -US-ICs,PPFD_IN_PI_F,,2,RAD-PAR Quantum,,,6-5 -US-ICs,PPFD_OUT,,1,RAD-PAR Quantum,,,6-5 -US-ICs,PPFD_OUT_PI_F,,1,RAD-PAR Quantum,,,6-5 -US-ICs,RH,,2,RH-ElecRes,,,6-5 -US-ICs,RH_PI_F,,2,RH-ElecRes,,,6-5 -US-ICs,SG_PI_1_1_A,,,SOIL_H-Plate_AUTO,,Storage term from first set of soil sensors (G_1_1_x and TS_1_1_1),6-5 -US-ICs,SG_PI_2_1_A,,,SOIL_H-Plate_AUTO,,Storage term from second set of soil sensors (G_2_1_x and TS_2_1_1),6-5 -US-ICs,SWC_1_1_1,,-0.025,SWC-TDR,,,6-5 -US-ICs,SWC_2_1_1,,-0.025,SWC-TDR,,,6-5 -US-ICs,SW_IN,,2,RAD-SW Pyran Class1,,,6-5 -US-ICs,SW_IN_PI_F,,2,RAD-SW Pyran Class1,,,6-5 -US-ICs,SW_OUT,,2,RAD-SW Pyran Class1,,,6-5 -US-ICs,SW_OUT_PI_F,,2,RAD-SW Pyran Class1,,,6-5 -US-ICs,TA,,2,TEMP-ElectResis,,,6-5 -US-ICs,TA_PI_F,,2,TEMP-ElectResis,,,6-5 -US-ICs,TS_1_1_1,,-0.02,TEMP-TCouple,,,6-5 -US-ICs,TS_2_1_1,,-0.02,TEMP-TCouple,,,6-5 -US-ICs,USTAR,,2.56,SA-Campbell CSAT-3,,,6-5 -US-ICs,VPD_PI,,2,,,Calculated by ReddyProc; not directly measured,6-5 -US-ICs,VPD_PI_F,,2,,,Calculated by ReddyProc; not directly measured,6-5 -US-ICs,WD,,2.56,SA-Campbell CSAT-3,,,6-5 -US-ICs,WS,,2.0,WIND-CupAn,,,6-5 -US-ICs,WS_PI_F,,2,WIND-CupAn,,,6-5 -US-ICt,CO2,201605,2.82,GA_CP-LI-COR LI-7200RS,,,4-5 -US-ICt,CO2,20210902,2.82,GA_OP-LI-COR LI-7500DS,,,4-5 -US-ICt,CO2,,2.82,GA_OP-LI-COR LI-7500,,,4-5 -US-ICt,FC,201605,2.82,GA_CP-LI-COR LI-7200RS,SA-Campbell CSAT-3,replaced with LI-7200,4-5 -US-ICt,FC,20210902,2.82,GA_OP-LI-COR LI-7500DS,SA-Campbell CSAT-3,,4-5 -US-ICt,FC,,2.82,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,4-5 -US-ICt,FC_PI_F,201605,2.82,GA_CP-LI-COR LI-7200RS,SA-Campbell CSAT-3,replaced with LI-7200,4-5 -US-ICt,FC_PI_F,20210902,2.82,GA_OP-LI-COR LI-7500DS,SA-Campbell CSAT-3,also add LI7700,4-5 -US-ICt,FC_PI_F,,2.82,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,4-5 -US-ICt,FCH4,20210902,2.82,GA_OP-LI-COR LI-7700,SA-Campbell CSAT-3,,4-5 -US-ICt,FCH4_PI_F,20210902,2.82,GA_OP-LI-COR LI-7700,SA-Campbell CSAT-3,,4-5 -US-ICt,G_1_1_1,,-0.08,SOIL_H-Plate_AUTO,,,4-5 -US-ICt,G_1_1_2,,-0.08,SOIL_H-Plate_AUTO,,,4-5 -US-ICt,G_2_1_1,,-0.08,SOIL_H-Plate_AUTO,,,4-5 -US-ICt,G_2_1_2,,-0.08,SOIL_H-Plate_AUTO,,,4-5 -US-ICt,GPP_PI,201605,2.82,GA_CP-LI-COR LI-7200RS,SA-Campbell CSAT-3,replaced with LI-7200,4-5 -US-ICt,GPP_PI,20210902,2.82,GA_OP-LI-COR LI-7500DS,SA-Campbell CSAT-3,,4-5 -US-ICt,GPP_PI,,2.82,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,4-5 -US-ICt,H,,2.82,SA-Campbell CSAT-3,,,4-5 -US-ICt,H2O,,2.82,RH-ElecRes,,,4-5 -US-ICt,H_PI_F,,2.82,SA-Campbell CSAT-3,,,4-5 -US-ICt,LE,201605,2.82,GA_CP-LI-COR LI-7200RS,SA-Campbell CSAT-3,,4-5 -US-ICt,LE,,2.82,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,4-5 -US-ICt,LE_PI_F,201605,2.82,GA_CP-LI-COR LI-7200RS,SA-Campbell CSAT-3,,4-5 -US-ICt,LE_PI_F,20210902,2.82,GA_OP-LI-COR LI-7500DS,SA-Campbell CSAT-3,also add LI7700,4-5 -US-ICt,LE_PI_F,,2.82,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,4-5 -US-ICt,NETRAD,,2.0,RAD-Pyrrad-SW+LW,,,4-5 -US-ICt,P,,0.2,RAIN-TipBucGauge,,,4-5 -US-ICt,PA,201605,1,GA_CP-LI-COR LI-7200RS,,pressure sensor inside AIU box,4-5 -US-ICt,PA,20210902,1,GA_OP-LI-COR LI-7500DS,,pressure sensor in DSI module,4-5 -US-ICt,PA,,1,GA_OP-LI-COR LI-7500,,pressure sensor inside AIU box,4-5 -US-ICt,PPFD_IN,20120604,3,RAD-PAR Quantum,,new sensor installed 2012; no upfacing PAR prior,4-5 -US-ICt,PPFD_IN,201605,3,RAD-PAR Quantum,,new sensor installed,4-5 -US-ICt,PPFD_OUT,,2,RAD-PAR Quantum,,,4-5 -US-ICt,RECO_PI,201605,2.82,GA_CP-LI-COR LI-7200RS,SA-Campbell CSAT-3,replaced with LI-7200,4-5 -US-ICt,RECO_PI,20210902,2.82,GA_OP-LI-COR LI-7500DS,SA-Campbell CSAT-3,,4-5 -US-ICt,RECO_PI,,2.82,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,4-5 -US-ICt,RH,,2.82,RH-ElecRes,,,4-5 -US-ICt,RH_PI_F,,2.82,RH-ElecRes,,,4-5 -US-ICt,SG_PI_1_1_A,,0,,,soil heat storage from soil sensors 1_x_x,4-5 -US-ICt,SG_PI_2_1_A,,0,,,soil heat storage from soil sensors 2_x_x,4-5 -US-ICt,SWC_1,,-0.025,SWC-TDR,,,4-5 -US-ICt,SWC_1_1_1,,-0.025,SWC-TDR,,,4-5 -US-ICt,SWC_2,,-0.025,SWC-TDR,,,4-5 -US-ICt,SWC_2_1_1,,-0.025,SWC-TDR,,,4-5 -US-ICt,SW_IN,,2.0,RAD-Pyrrad-SW+LW,,,4-5 -US-ICt,SW_IN_PI_F,,2.0,RAD-Pyrrad-SW+LW,,,4-5 -US-ICt,SW_OUT,,2.0,RAD-Pyrrad-SW+LW,,,4-5 -US-ICt,TA,,2.82,TEMP-ElectResis,,,4-5 -US-ICt,TA_PI_F,,2.82,TEMP-ElectResis,,,4-5 -US-ICt,TS_1,,-0.02,TEMP-TCouple,,,4-5 -US-ICt,TS_1_1_1,,-0.02,TEMP-TCouple,,,4-5 -US-ICt,TS_2,,-0.02,TEMP-TCouple,,,4-5 -US-ICt,TS_2_1_1,,-0.02,TEMP-TCouple,,,4-5 -US-ICt,USTAR,,2.82,SA-Campbell CSAT-3,,,4-5 -US-ICt,VPD_PI_F,,2.82,,,calculated by ReddyProc,4-5 -US-ICt,WD,201206,2.82,SA-Campbell CSAT-3,,old windsentry sensor broke,4-5 -US-ICt,WD,,2.82,WIND-VaneAn,,,4-5 -US-ICt,WS,,2.82,WIND-CupAn,,windsentry broke; replaced with 014A cup in 201206,4-5 -US-Ivo,ALB,,,RAD-Other,,Kipp & Zonen CNR01 albedo,4-5 -US-Ivo,CO2,,3.8,,,,4-5 -US-Ivo,D_SNOW,,,SNOW-Other,,Campbell Sci. SR50 m,4-5 -US-Ivo,FC,,3.8,GA-Other,,Gill; LI_COR gC m-2 hr-1,4-5 -US-Ivo,G_1_1_1,,-0.065,,,5-8 cm deep,4-5 -US-Ivo,G_2_1_1,,-0.065,SOIL_H-Other,,REBS W m-2; 5-8 cm deep,4-5 -US-Ivo,G_3_1_1,,-0.065,,,5-8 cm deep,4-5 -US-Ivo,G_4_1_1,,-0.065,SOIL_H-Other,,REBS W m-2; 5-8 cm deep,4-5 -US-Ivo,H,,3.8,SA-Other,,Gill; LI_COR W m-2,4-5 -US-Ivo,LE,,3.8,GA-Other,,Gill; LI_COR W m-2,4-5 -US-Ivo,LW_IN,,,RAD-Other,,Kipp & Zonen CNR01 W m-2,4-5 -US-Ivo,LW_OUT,,,RAD-Other,,Kipp & Zonen CNR01 W m-2,4-5 -US-Ivo,NETRAD,,,RAD-Other,,Kipp & Zonen CNR01 W m-2,4-5 -US-Ivo,RH,,,RH-Other,,Vaisala HMP45C %,4-5 -US-Ivo,SWC_1_1_1,,-0.05,,,,4-5 -US-Ivo,SWC_1_2_1,,-0.15,,,,4-5 -US-Ivo,SWC_1_3_1,,-0.30,,,,4-5 -US-Ivo,SWC_2_1_1,,-0.05,,,,4-5 -US-Ivo,SWC_2_2_1,,-0.15,,,,4-5 -US-Ivo,SWC_2_3_1,,-0.30,,,,4-5 -US-Ivo,SWC_3_1_1,,-0.05,,,,4-5 -US-Ivo,SWC_3_2_1,,-0.15,,,,4-5 -US-Ivo,SWC_3_3_1,,-0.30,,,,4-5 -US-Ivo,SW_IN,,,RAD-Other,,Kipp & Zonen CNR01 W m-2,4-5 -US-Ivo,SW_OUT,,,RAD-Other,,Kipp & Zonen CNR01 W m-2,4-5 -US-Ivo,TA,,,TEMP-Other,,Vaisala HMP45C C,4-5 -US-Ivo,TS_1_1_1,,-0.05,,,,4-5 -US-Ivo,TS_1_2_1,,-0.1,,,,4-5 -US-Ivo,TS_1_3_1,,-0.15,,,,4-5 -US-Ivo,TS_1_4_1,,-0.30,,,,4-5 -US-Ivo,TS_1_5_1,,-0.40,,,,4-5 -US-Ivo,TS_2_1_1,,-0.05,,,,4-5 -US-Ivo,TS_2_2_1,,-0.1,,,,4-5 -US-Ivo,TS_2_3_1,,-0.15,,,,4-5 -US-Ivo,TS_2_4_1,,-0.30,,,,4-5 -US-Ivo,TS_2_5_1,,-0.40,,,,4-5 -US-Ivo,TS_3_1_1,,-0.05,,,,4-5 -US-Ivo,TS_3_2_1,,-0.05,,,,4-5 -US-Ivo,TS_3_3_1,,-0.15,,,,4-5 -US-Ivo,TS_3_4_1,,-0.30,,,,4-5 -US-Ivo,TS_3_5_1,,-0.40,,,,4-5 -US-Ivo,TS_4_1_1,,-0.05,,,,4-5 -US-Ivo,TS_4_2_1,,-0.05,,,,4-5 -US-Ivo,TS_4_3_1,,-0.15,,,,4-5 -US-Ivo,TS_4_4_1,,-0.30,,,,4-5 -US-Ivo,TS_4_5_1,,-0.40,,,,4-5 -US-Ivo,USTAR,,,WIND-Other,,Gill m/s,4-5 -US-Ivo,WD,,,WIND-Other,,Young Degrees,4-5 -US-Ivo,WS,,,WIND-Other,,Young m s-1,4-5 -US-Ivo,WS_MAX,,,WIND-Other,,Young m s-1,4-5 -US-Jo1,CO2,20100107,5,GA_OP-LI-COR LI-7500,,,2-5 -US-Jo1,FC,20100107,5,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,2-5 -US-Jo1,G_1_1_1,20100107,-0.1,SOIL_H-Plate,,under shrub,2-5 -US-Jo1,G_1_2_1,20100107,-0.15,SOIL_H-Plate,,under shrub,2-5 -US-Jo1,G_2_1_1,20100107,-0.1,SOIL_H-Plate,,bare ground,2-5 -US-Jo1,G_2_2_1,20100107,-0.15,SOIL_H-Plate,,bare ground,2-5 -US-Jo1,H,20100107,5,GA_OP-LI-COR LI-7500,,undefined,2-5 -US-Jo1,LE,20100107,5,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,undefined,2-5 -US-Jo1,LEAF_WET_1_1_1,20100107,5,LEAF_WET-FrequencyDomain,,ambient,2-5 -US-Jo1,LEAF_WET_1_2_1,20100107,0.5,LEAF_WET-FrequencyDomain,,in shrub cluster at base of tower in line with LEAF_WET_1_1_1,2-5 -US-Jo1,LEAF_WET_2_1_1,20100107,0.5,LEAF_WET-FrequencyDomain,,in Prosopis glandulosa,2-5 -US-Jo1,LEAF_WET_3_1_1,20100107,0.5,LEAF_WET-FrequencyDomain,,over Bare ground,2-5 -US-Jo1,LEAF_WET_4_1_1,20100107,0.5,LEAF_WET-FrequencyDomain,,in Larrea tridentata,2-5 -US-Jo1,LEAF_WET_5_1_1,20100107,0.5,LEAF_WET-FrequencyDomain,,in Muhlenbergia porterii,2-5 -US-Jo1,LEAF_WET_6_1_1,20100107,0.5,LEAF_WET-FrequencyDomain,,in Fluorensia cernua,2-5 -US-Jo1,LEAF_WET_7_1_1,20100107,0.5,LEAF_WET-FrequencyDomain,,in Propopis glandulosa,2-5 -US-Jo1,LW_IN_1_1_1,20100107,3,RAD-Pyrrad-SW+LW,,,2-5 -US-Jo1,LW_OUT_1_1_1,20100107,3,RAD-Pyrrad-SW+LW,,,2-5 -US-Jo1,NETRAD_1_1_1,20100107,3,RAD-Pyrrad-SW+LW,,,2-5 -US-Jo1,PA_1_1_1,20100107,1.5,PRES-ElectBar,,,2-5 -US-Jo1,PA_2_1_1,20100107,1.5,PRES-ElectBar,,,2-5 -US-Jo1,PPFD_IN_1_1_1,20100107,10,RAD-PAR Quantum,,PPFD_IN_1_1_1 and PPFD_IN_2_1_1 are two different sensors. ,2-5 -US-Jo1,PPFD_IN_2_1_1,20100107,2.35,RAD-PAR Quantum,,PPFD_IN_1_1_1 and PPFD_IN_2_1_1 are two different sensors.,2-5 -US-Jo1,PPFD_OUT_10_1_1,20100107,0.87,RAD-PAR Quantum,,Muhlenbergia porterii,2-5 -US-Jo1,PPFD_OUT_1_1_1,20100107,0.3,RAD-PAR Quantum,,Prosopis glandulosa,2-5 -US-Jo1,PPFD_OUT_11_1_1,20100107,0.54,RAD-PAR Quantum,,Muhlenbergia porterii,2-5 -US-Jo1,PPFD_OUT_12_1_1,20100107,1.54,RAD-PAR Quantum,,Prosopis glandulosa,2-5 -US-Jo1,PPFD_OUT_2_1_1,20100107,2.3,RAD-PAR Quantum,,Larrea tridentata,2-5 -US-Jo1,PPFD_OUT_3_1_1,20100107,2.2,RAD-PAR Quantum,,Prosopis glandulosa,2-5 -US-Jo1,PPFD_OUT_4_1_1,20100107,2.35,RAD-PAR Quantum,,Dasyochloa pulchella,2-5 -US-Jo1,PPFD_OUT_5_1_1,20100107,0.56,RAD-PAR Quantum,,Bare ground,2-5 -US-Jo1,PPFD_OUT_6_1_1,20100107,2.55,RAD-PAR Quantum,,Larrea tridentata,2-5 -US-Jo1,PPFD_OUT_7_1_1,20100107,0.3,RAD-PAR Quantum,,Dasyochloa pulchella,2-5 -US-Jo1,PPFD_OUT_8_1_1,20100107,1.33,RAD-PAR Quantum,,Larrea tridentata,2-5 -US-Jo1,PPFD_OUT_9_1_1,20100107,0.9,RAD-PAR Quantum,,Muhlenbergia porter,2-5 -US-Jo1,P_RAIN_1_1_1,20100101,1.24,RAIN-TipBucGauge,,,2-5 -US-Jo1,P_RAIN_2_1_1,20100101,0.9,RAIN-TipBucGauge,,,2-5 -US-Jo1,P_RAIN_3_1_1,20100101,0.6,RAIN-TipBucGauge,,,2-5 -US-Jo1,RH_1_1_1,20100107,5,RH-Capac,,,2-5 -US-Jo1,SWC_1_1_1,20100107,-0.05,SWC-FDR,,bare ground,2-5 -US-Jo1,SWC_1_2_1,20100107,-0.10,SWC-FDR,,bare ground,2-5 -US-Jo1,SWC_1_3_1,20100107,-0.20,SWC-FDR,,bare ground,2-5 -US-Jo1,SWC_1_4_1,20100107,-0.3,SWC-FDR,,bare ground,2-5 -US-Jo1,SWC_2_1_1,20100107,-0.05,SWC-FDR,,Larrea Tridentata,2-5 -US-Jo1,SWC_2_2_1,20100107,-0.10,SWC-FDR,,Larrea Tridentata,2-5 -US-Jo1,SWC_2_3_1,20100107,-0.20,SWC-FDR,,Larrea Tridentata,2-5 -US-Jo1,SWC_2_4_1,20100107,-0.30,SWC-FDR,,Larrea Tridentata,2-5 -US-Jo1,SWC_3_1_1,20100107,-0.05,SWC-FDR,,Muhlenbergia porterii,2-5 -US-Jo1,SWC_3_2_1,20100107,-0.10,SWC-FDR,,Muhlenbergia porterii,2-5 -US-Jo1,SWC_3_3_1,20100107,-0.20,SWC-FDR,,Muhlenbergia porterii,2-5 -US-Jo1,SWC_3_4_1,20100107,-0.30,SWC-FDR,,Muhlenbergia porterii,2-5 -US-Jo1,SWC_4_1_1,20100107,-0.05,SWC-FDR,,Prosopis glandulosa,2-5 -US-Jo1,SWC_4_2_1,20100107,-0.10,SWC-FDR,,Prosopis glandulosa,2-5 -US-Jo1,SWC_4_3_1,20100107,-0.20,SWC-FDR,,Prosopis glandulosa,2-5 -US-Jo1,SWC_4_4_1,20100107,-0.30,SWC-FDR,,Prosopis glandulosa,2-5 -US-Jo1,SW_IN_1_1_1,20100107,3,RAD-Pyrrad-SW+LW,,,2-5 -US-Jo1,SW_OUT_1_1_1,20100107,3,RAD-Pyrrad-SW+LW,,,2-5 -US-Jo1,TA_1_1_1,20100107,5,TEMP-ElectResis,,,2-5 -US-Jo1,TS_1,20100107,-0.08,TEMP-ElectResis,,site level surface soil temperature integrated 0.2-0.15m from bare and shrub cover; copper-constantan thermocouple wire (depths (m) are: 0.02;0.05;0.10;0.15),2-5 -US-Jo1,TS_2,20100107,-0.08,TEMP-ElectResis,,site level surface soil temperature integrated 0.2-0.15m from bare and shrub cover; copper-constantan thermocouple wire (depths (m) are: 0.02;0.05;0.10;0.15),2-5 -US-Jo1,USTAR,20100107,5,SA-Campbell CSAT-3,,,2-5 -US-Jo1,WD_1_1_1,20100107,10,WIND-2DSA,,,2-5 -US-Jo1,WS_1_1_1,20100107,10,WIND-2DSA,,,2-5 -US-Jo2,CO2,20100802,7.1,GA_OP-LI-COR LI-7500,,,2-5 -US-Jo2,CO2_SIGMA,,7.1,GA_OP-LI-COR LI-7500,,,2-5 -US-Jo2,FC,20100802,7.1,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,2-5 -US-Jo2,FC_SSITC_TEST,,7.1,SA-Campbell CSAT-3,,,2-5 -US-Jo2,FETCH_70,20100802,7.1,SA-Campbell CSAT-3,,,2-5 -US-Jo2,FETCH_80,20100802,7.1,SA-Campbell CSAT-3,,,2-5 -US-Jo2,FETCH_90,20100802,7.1,SA-Campbell CSAT-3,,,2-5 -US-Jo2,FETCH_MAX,20100802,7.1,SA-Campbell CSAT-3,,,2-5 -US-Jo2,G_1_1_1,,,SOIL_H-Plate,,,2-5 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-US-Jo2,SW_IN,20100802,5,RAD-Net radiometer,,,2-5 -US-Jo2,SW_OUT,20100802,5,RAD-Net radiometer,,,2-5 -US-Jo2,TA,20100802,3.4,TEMP-ElectResis,,,2-5 -US-Jo2,TAU,20100802,7.1,SA-Campbell CSAT-3,,,2-5 -US-Jo2,TAU_SSITC_TEST,20100802,7.1,SA-Campbell CSAT-3,,,2-5 -US-Jo2,TS_1_1_1,,-0.1,MULTI-Other,,,2-5 -US-Jo2,TS_1_2_1,,-0.1,MULTI-Other,,,2-5 -US-Jo2,TS_1_3_1,,-0.1,MULTI-Other,,,2-5 -US-Jo2,T_SONIC,20100802,7.1,SA-Campbell CSAT-3,,,2-5 -US-Jo2,T_SONIC_SIGMA,,7.1,SA-Campbell CSAT-3,,,2-5 -US-Jo2,U_SIGMA,20100802,7.1,SA-Campbell CSAT-3,,,2-5 -US-Jo2,USTAR,20100802,7.1,SA-Campbell CSAT-3,,,2-5 -US-Jo2,VPD_PI,20100802,3.4,RH-Capac,,,2-5 -US-Jo2,V_SIGMA,20100802,7.1,SA-Campbell CSAT-3,,,2-5 -US-Jo2,WD,20100802,7.1,SA-Campbell CSAT-3,,,2-5 -US-Jo2,WS,20100802,7.1,SA-Campbell CSAT-3,,,2-5 -US-Jo2,W_SIGMA,20100802,7.1,SA-Campbell CSAT-3,,,2-5 -US-Jo2,WS_MAX,20100802,7.1,SA-Campbell CSAT-3,,,2-5 -US-Jo2,ZL,20100802,7.1,SA-Campbell CSAT-3,,,2-5 -US-KFS,ALB_1_1_1,,3,RAD-Pyrrad-SW+LW,,,7-5 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-US-KFS,SWC_1_1_1,,-0.06,SWC-TDR,,,7-5 -US-KFS,SWC_PI_F_1_1_1,,-0.06,SWC-TDR,,,7-5 -US-KFS,SW_IN_1_1_1,,3,RAD-Pyrrad-SW+LW,,,7-5 -US-KFS,SW_IN_PI_F_1_1_1,,3,RAD-Pyrrad-SW+LW,,,7-5 -US-KFS,SW_OUT_1_1_1,,3,RAD-Pyrrad-SW+LW,,,7-5 -US-KFS,SW_OUT_PI_F_1_1_1,,3,RAD-Pyrrad-SW+LW,,,7-5 -US-KFS,TA_1_1_1,,3,TEMP-IntegratedCircuit,,,7-5 -US-KFS,TA_PI_F_1_1_1,,3,TEMP-IntegratedCircuit,,,7-5 -US-KFS,TS_2_1_1,,-0.06,TEMP-Thermis,,,7-5 -US-KFS,TS_2_2_1,,-0.08,TEMP-Thermis,,,7-5 -US-KFS,TS_PI_F_2_1_1,,-0.06,TEMP-Thermis,,,7-5 -US-KFS,TS_PI_F_2_2_1,,-0.08,TEMP-Thermis,,,7-5 -US-KFS,USTAR_1_1_1,,3,SA-Campbell CSAT-3,,,7-5 -US-KFS,VPD_PI_1_1_1,,3,RH-Capac,,,7-5 -US-KFS,VPD_PI_F_1_1_1,,3,RH-Capac,,,7-5 -US-KFS,WD_1_1_1,,3,SA-Campbell CSAT-3,,,7-5 -US-KFS,WD_PI_F_1_1_1,,3,SA-Campbell CSAT-3,,,7-5 -US-KFS,WS_1_1_1,,3,SA-Campbell CSAT-3,,,7-5 -US-KFS,WS_PI_F_1_1_1,,3,SA-Campbell CSAT-3,,,7-5 -US-KFS,ZL_1_1_1,,3,SA-Campbell CSAT-3,,,7-5 -US-KLS,CO2_1_1_1,,3,GA_OP-LI-COR LI-7500A,,,2-5 -US-KLS,CO2_PI_F_1_1_1,,3,GA_OP-LI-COR LI-7500A,,,2-5 -US-KLS,FC_1_1_1,,3,GA_OP-LI-COR LI-7500A,SA-Campbell CSAT-3,,2-5 -US-KLS,FC_PI_F_1_1_1,,3,GA_OP-LI-COR LI-7500A,SA-Campbell CSAT-3,,2-5 -US-KLS,G_1_1_1,,-0.08,SOIL_H-Plate_AUTO,,,2-5 -US-KLS,G_2_1_1,,-0.08,SOIL_H-Plate_AUTO,,,2-5 -US-KLS,G_2_2_1,,-0.08,SOIL_H-Plate_AUTO,,,2-5 -US-KLS,G_2_3_1,,-0.08,SOIL_H-Plate_AUTO,,,2-5 -US-KLS,G_PI_F_1_1_1,,-0.08,SOIL_H-Plate_AUTO,,,2-5 -US-KLS,G_PI_F_2_1_1,,-0.08,SOIL_H-Plate_AUTO,,,2-5 -US-KLS,G_PI_F_2_2_1,,-0.08,SOIL_H-Plate_AUTO,,,2-5 -US-KLS,GPP_PI_1_1_1,,3,GA_OP-LI-COR LI-7500A,SA-Campbell CSAT-3,,2-5 -US-KLS,GPP_PI_F_1_1_1,,3,GA_OP-LI-COR LI-7500A,SA-Campbell CSAT-3,,2-5 -US-KLS,H_1_1_1,,3,GA_OP-LI-COR LI-7500A,,,2-5 -US-KLS,H2O_1_1_1,,3,GA_OP-LI-COR LI-7500A,,,2-5 -US-KLS,H2O_PI_F_1_1_1,,3,GA_OP-LI-COR LI-7500A,,,2-5 -US-KLS,H_PI_F_1_1_1,,3,GA_OP-LI-COR LI-7500A,,,2-5 -US-KLS,LE_1_1_1,,3,GA_OP-LI-COR LI-7500A,SA-Campbell CSAT-3,,2-5 -US-KLS,LE_PI_F_1_1_1,,3,GA_OP-LI-COR 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Quantum,,,21-5 -US-Los,PPFD_IN_1_2_1,,10.2,RAD-PAR Quantum,,,21-5 -US-Los,RECO_PI_F,20140101,10.2,GA_OP-LI-COR LI-7500A,SA-Campbell CSAT-3A,,21-5 -US-Los,RECO_PI_F,,10.2,GA_CP-LI-COR LI-6262,SA-Campbell CSAT-3A,,21-5 -US-Los,RH,,10.2,RH-Capac,,,21-5 -US-Los,SC,20140101,,GA_SR-Other,,,21-5 -US-Los,SC,,,GA_CP-LI-COR LI-6262,,,21-5 -US-Los,SH,,,TEMP-TCouple,,,21-5 -US-Los,SLE,,,RH-Capac,,,21-5 -US-Los,SW_IN,,10.2,RAD-Pyrrad-SW+LW,,,21-5 -US-Los,SW_OUT,,10.2,RAD-Pyrrad-SW+LW,,,21-5 -US-Los,TA_1_1_1,,10.2,TEMP-ElectResis,,,21-5 -US-Los,TA_1_2_1,,5.5,TEMP-TCouple,,,21-5 -US-Los,TA_1_3_1,,3,TEMP-TCouple,,,21-5 -US-Los,TA_1_4_1,,1.8,TEMP-TCouple,,,21-5 -US-Los,TA_1_5_1,,1.2,TEMP-TCouple,,,21-5 -US-Los,T_BOLE_1_1_1,,1.4,TEMP-TCouple,,,21-5 -US-Los,T_BOLE_2_1_1,,1.4,TEMP-TCouple,,,21-5 -US-Los,TS_1_1_1,,-0,TEMP-TCouple,,,21-5 -US-Los,TS_1_2_1,,-0.05,TEMP-TCouple,,,21-5 -US-Los,TS_1_3_1,,-0.1,TEMP-TCouple,,,21-5 -US-Los,TS_1_4_1,,-0.2,TEMP-TCouple,,,21-5 -US-Los,TS_1_5_1,,-0.5,TEMP-TCouple,,,21-5 -US-Los,TS_1_6_1,,-1,TEMP-TCouple,,,21-5 -US-Los,USTAR,,10.2,SA-Campbell CSAT-3A,,,21-5 -US-Los,USTAR_DF,,10.2,SA-Campbell CSAT-3A,,,21-5 -US-Los,VPD_PI,,10.2,RH-Capac,,,21-5 -US-Los,WD,,10.2,SA-Campbell CSAT-3A,,,21-5 -US-Los,WS,,10.2,SA-Campbell CSAT-3A,,,21-5 -US-Los,WTD,,,WTD-Press,,,21-5 -US-LS1,CO2,20030101,,GA_OP-LI-COR LI-7500,,CO2 mole fraction,1-5 -US-LS1,FC,20030101,,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3A,CO2 flux No storage correction,1-5 -US-LS1,G,20030101,,SOIL_H-Plate,,ground heat flux,1-5 -US-LS1,GPP_PI_F,20030101,,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3A,Gross Primary Production;NEE - RECO,1-5 -US-LS1,H,20030101,,SA-Campbell CSAT-3A,,Sensible Heat flux,1-5 -US-LS1,H2O,20030101,,GA_OP-LI-COR LI-7500,,H2O mole fraction,1-5 -US-LS1,LE,20030101,,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3A,Latent Heat Flux,1-5 -US-LS1,NEE_PI_F,20030101,,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3A,Net ecosystem exchange of CO2; u* filtered (threshold = 0.2 m/s) and gap-filled and including change in storage at IRGA height only,1-5 -US-LS1,NETRAD,20030101,,RAD-Pyrrad-SW+LW,,net radiation,1-5 -US-LS1,P,20030101,,PREC-TipBucGauge,,precipitation,1-5 -US-LS1,PA,20030101,,GA_OP-LI-COR LI-7500,,air pressure,1-5 -US-LS1,PPFD_IN,20030101,,RAD-PAR Quantum,,incoming photosynthetic photon flux density,1-5 -US-LS1,PPFD_OUT,20030101,,RAD-PAR Quantum,,outgoing (reflected) photosynthetic photon flux density,1-5 -US-LS1,RECO_PI_F,20030101,,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3A,Ecosystem Respiration (partitioned NEE_GF with nighttime approach),1-5 -US-LS1,RH_1_1_1,20030101,,RH-Capac,,relative humidity; 3m,1-5 -US-LS1,SWC_PI_1_1_A,20030101,,SWC-TDR,,vol. soil moisture; 5cm,1-5 -US-LS1,SWC_PI_1_2_A,20030101,,SWC-TDR,,vol. soil moisture; 10cm,1-5 -US-LS1,SWC_PI_1_3_A,20030101,,SWC-TDR,,vol. soil moisture; 20cm,1-5 -US-LS1,SWC_PI_1_4_A,20030101,,SWC-TDR,,vol. soil moisture; 30cm,1-5 -US-LS1,SWC_PI_1_5_A,20030101,,SWC-TDR,,vol. soil moisture; 50cm,1-5 -US-LS1,SWC_1_6_1,20030101,,SWC-TDR,,vol. soil moisture; 80cm,1-5 -US-LS1,TA_1_1_1,20030101,,TEMP-ElectResis,,air temperature; 3m,1-5 -US-LS1,TIMESTAMP_END,20030101,,,,timestamp_end at end of halfhour,1-5 -US-LS1,TIMESTAMP_START,20030101,,,,timestamp beginning,1-5 -US-LS1,TS_1_1_1,20030101,,TEMP-TCouple,,soil temperature; 5cm,1-5 -US-LS1,TS_1_2_1,20030101,,TEMP-TCouple,,soil temperature; 10 cm,1-5 -US-LS1,TS_1_3_1,20030101,,TEMP-TCouple,,soil temperature; 20cm,1-5 -US-LS1,TS_1_4_1,20030101,,TEMP-TCouple,,soil temperature; 30cm,1-5 -US-LS1,TS_1_5_1,20030101,,TEMP-TCouple,,soil temperature; 50cm,1-5 -US-LS1,TS_1_6_1,20030101,,TEMP-TCouple,,soil temperature; 80cm,1-5 -US-LS1,T_SONIC,20030101,,SA-Campbell CSAT-3A,,sonic temperature,1-5 -US-LS1,USTAR,20030101,,SA-Campbell CSAT-3A,,friction velocity,1-5 -US-LS1,WD_1_1_1,20030101,,WIND-VaneAn,,wind direction; 2.8m,1-5 -US-LS1,WS_1_1_1,20030101,,WIND-CupAn,,wind speed; 2.8m,1-5 -US-LS2,CO2,20030101,,GA_OP-LI-COR LI-7500,,CO2 mole fraction,1-5 -US-LS2,FC,20030101,,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3A,CO2 flux No storage correction,1-5 -US-LS2,G,20030101,,SOIL_H-Plate,,ground heat flux,1-5 -US-LS2,GPP_PI_F,20030101,,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3A,Gross Primary Production;NEE - RECO,1-5 -US-LS2,H,20030101,,SA-Campbell CSAT-3A,,Sensible Heat flux,1-5 -US-LS2,H2O,20030101,,GA_OP-LI-COR LI-7500,,H2O mole fraction,1-5 -US-LS2,LE,20030101,,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3A,Latent Heat Flux,1-5 -US-LS2,NEE_PI_F,20030101,,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3A,Net ecosystem exchange of CO2; u* filtered (threshold = 0.2 m/s) and gap-filled and including change in storage at IRGA height only,1-5 -US-LS2,NETRAD,20030101,,RAD-Pyrrad-SW+LW,,net radiation,1-5 -US-LS2,P,20030101,,PREC-TipBucGauge,,precipitation,1-5 -US-LS2,PA,20030101,,GA_OP-LI-COR LI-7500,,air pressure,1-5 -US-LS2,PPFD_IN,20030101,,RAD-PAR Quantum,,incoming photosynthetic photon flux density,1-5 -US-LS2,PPFD_OUT,20030101,,RAD-PAR Quantum,,outgoing (reflected) photosynthetic photon flux density,1-5 -US-LS2,RECO_PI_F,20030101,,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3A,Ecosystem Respiration (partitioned NEE_GF with nighttime approach),1-5 -US-LS2,RH_1_1_1,20030101,,RH-Capac,,relative humidity; 6m,1-5 -US-LS2,SWC_PI_1_1_A,20030101,,SWC-TDR,,vol. soil moisture; 5cm,1-5 -US-LS2,SWC_PI_1_2_A,20030101,,SWC-TDR,,vol. soil moisture; 10cm,1-5 -US-LS2,SWC_PI_1_3_A,20030101,,SWC-TDR,,vol. soil moisture; 20cm,1-5 -US-LS2,SWC_PI_1_4_A,20030101,,SWC-TDR,,vol. soil moisture; 30cm,1-5 -US-LS2,SWC_PI_1_5_A,20030101,,SWC-TDR,,vol. soil moisture; 50cm,1-5 -US-LS2,SWC_1_6_1,20030101,,SWC-TDR,,vol. soil moisture; 80cm,1-5 -US-LS2,SW_IN,20030101,,RAD-Pyrrad-SW+LW,,incoming solar radiation,1-5 -US-LS2,TA_1_1_1,20030101,,TEMP-ElectResis,,air temperature; 6m,1-5 -US-LS2,TIMESTAMP_END,20030101,,,,timestamp_end at end of halfhour,1-5 -US-LS2,TIMESTAMP_START,20030101,,,,timestamp beginning,1-5 -US-LS2,TS_1_1_1,20030101,,TEMP-TCouple,,soil temperature; 5cm,1-5 -US-LS2,TS_1_2_1,20030101,,TEMP-TCouple,,soil temperature; 10 cm,1-5 -US-LS2,TS_1_3_1,20030101,,TEMP-TCouple,,soil temperature; 20cm,1-5 -US-LS2,TS_1_4_1,20030101,,TEMP-TCouple,,soil temperature; 30cm,1-5 -US-LS2,TS_1_5_1,20030101,,TEMP-TCouple,,soil temperature; 50cm,1-5 -US-LS2,TS_1_6_1,20030101,,TEMP-TCouple,,soil temperature; 80cm,1-5 -US-LS2,T_SONIC,20030101,,SA-Campbell CSAT-3A,,sonic temperature,1-5 -US-LS2,USTAR,20030101,,SA-Campbell CSAT-3A,,friction velocity,1-5 -US-LS2,WD_1_1_1,20030101,,WIND-VaneAn,,wind direction; 6.4m,1-5 -US-LS2,WS_1_1_1,20030101,,WIND-CupAn,,wind speed; 6.4m,1-5 -US-LWW,FC,,3,,,,3-5 -US-LWW,H,,3,,,,3-5 -US-LWW,LE,,3,,,,3-5 -US-LWW,RH,,2,,,,3-5 -US-LWW,TA,,2,,,,3-5 -US-LWW,VPD_PI,,2,,,,3-5 -US-LWW,WD,,2,,,,3-5 -US-LWW,WS,,2,,,,3-5 -US-MBP,CH4,2015,2.4,GA_OP-LI-COR LI-7700,,,2-5 -US-MBP,CO2,2009,2.4,GA_OP-LI-COR LI-7500A,,,2-5 -US-MBP,H2O,2009,2.4,GA_OP-LI-COR LI-7500A,,,2-5 -US-MBP,PPFD_IN,,,RAD-PAR Quantum,,,2-5 -US-MBP,T_SONIC,,2.4,SA-Campbell CSAT-3,,,2-5 -US-MBP,WD,,2.4,SA-Campbell CSAT-3,,,2-5 -US-MBP,WS,,2.4,SA-Campbell CSAT-3,,,2-5 -US-MBP,WTD,,,WTD-Float,,,2-5 -US-Me1,CO2,,10,,,,3-5 -US-Me1,FC,,10,SA-Other,,CSAT3/LI-7500,3-5 -US-Me1,H,,10,,,,3-5 -US-Me1,LE,,10,,,,3-5 -US-Me1,RH,,,RH-Other,,Vaisla,3-5 -US-Me1,TA_1_2_1,,,TEMP-Other,,Vaisla,3-5 -US-Me1,TS_1_1_1,,-0.02,,,,3-5 -US-Me1,TS_1_3_1,,-0.08,,,,3-5 -US-Me1,WS,,10,,,,3-5 -US-Me2,ALB,200508,32,RAD-SW Pyran Class1,,,18-5 -US-Me2,CO2,200201,33,GA_OP-LI-COR LI-7500,,,18-5 -US-Me2,CO2,201510,33,GA_CP-LI-COR LI-7200RS,,,18-5 -US-Me2,D_SNOW,20131025,1.6,SNOW-Acoustic,,,18-5 -US-Me2,FC,200201,33,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,18-5 -US-Me2,FC,201510,33,GA_CP-LI-COR LI-7200RS,SA-Campbell CSAT-3,,18-5 -US-Me2,G_1_1_1,20011024,-0.05,SOIL_H-Plate,,,18-5 -US-Me2,G_2_1_1,20011024,-0.05,SOIL_H-Plate,,,18-5 -US-Me2,G_3_1_1,20011024,-0.05,SOIL_H-Plate,,,18-5 -US-Me2,G_4_1_1,20011024,-0.05,SOIL_H-Plate,,,18-5 -US-Me2,G_5_1_1,20011024,-0.05,SOIL_H-Plate,,,18-5 -US-Me2,G_6_1_1,20141007,-0.05,SOIL_H-Plate_AUTO,,,18-5 -US-Me2,G_7_1_1,20141007,-0.05,SOIL_H-Plate_AUTO,,,18-5 -US-Me2,G_8_1_1,20141007,-0.05,SOIL_H-Plate_AUTO,,,18-5 -US-Me2,GPP_PI,200201,33,GA_CP-LI-COR LI-7200,SA-Campbell CSAT-3,,18-5 -US-Me2,GPP_PI,201510,33,GA_CP-LI-COR LI-7200RS,SA-Campbell CSAT-3,,18-5 -US-Me2,H,200201,33,SA-Campbell CSAT-3,,,18-5 -US-Me2,H2O,200201,33,GA_OP-LI-COR LI-7500,,,18-5 -US-Me2,H2O,201510,33,GA_CP-LI-COR LI-7200RS,,,18-5 -US-Me2,LE,200201,33,GA_CP-LI-COR LI-7200,SA-Campbell CSAT-3,,18-5 -US-Me2,LE,201510,33,GA_CP-LI-COR LI-7200RS,SA-Campbell CSAT-3,,18-5 -US-Me2,LW_IN,200508,32,RAD-LW Pyrgeom,,,18-5 -US-Me2,LW_OUT,200508,32,RAD-LW Pyrgeom,,,18-5 -US-Me2,NEE_PI,200201,33,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,18-5 -US-Me2,NEE_PI,201510,33,GA_CP-LI-COR LI-7200RS,SA-Campbell CSAT-3,,18-5 -US-Me2,NETRAD,200201,32,RAD-Net radiometer,,,18-5 -US-Me2,P,200201,32,PREC-TipBucGauge,,,18-5 -US-Me2,PA,200201,33,GA_OP-LI-COR LI-7500,,,18-5 -US-Me2,PA,201510,33,GA_CP-LI-COR LI-7200RS,,,18-5 -US-Me2,PPFD_DIF,200707,32,RAD-Other,,,18-5 -US-Me2,PPFD_DIR,200707,32,RAD-Other,,,18-5 -US-Me2,PPFD_IN,200201,32,RAD-PAR Quantum,,,18-5 -US-Me2,RECO_PI,200201,33,GA_CP-LI-COR LI-7200,SA-Campbell CSAT-3,,18-5 -US-Me2,RECO_PI,201510,33,GA_CP-LI-COR LI-7200RS,SA-Campbell CSAT-3,,18-5 -US-Me2,RH,200201,32,RH-Capac,,Vaisla,18-5 -US-Me2,SWC_1_1_1,200604,-0.1,SWC-Other,,,18-5 -US-Me2,SWC_1_2_1,200604,-0.2,SWC-Other,,,18-5 -US-Me2,SWC_1_3_1,200604,-0.3,SWC-Other,,,18-5 -US-Me2,SWC_1_4_1,200604,-0.5,SWC-Other,,,18-5 -US-Me2,SWC_1_5_1,200604,-0.7,SWC-Other,,,18-5 -US-Me2,SWC_1_6_1,200604,-1,SWC-Other,,,18-5 -US-Me2,SWC_1_7_1,200604,-1.3,SWC-Other,,,18-5 -US-Me2,SWC_1_8_1,200604,-1.6,SWC-Other,,,18-5 -US-Me2,SWC_2_1_1,200710,-0.1,SWC-Other,,,18-5 -US-Me2,SWC_2_2_1,200710,-0.2,SWC-Other,,,18-5 -US-Me2,SWC_2_3_1,200710,-0.3,SWC-Other,,,18-5 -US-Me2,SWC_2_4_1,200710,-0.5,SWC-Other,,,18-5 -US-Me2,SWC_2_5_1,200710,-0.7,SWC-Other,,,18-5 -US-Me2,SWC_2_6_1,200710,-1.0,SWC-Other,,,18-5 -US-Me2,SWC_2_7_1,200710,-1.3,SWC-Other,,,18-5 -US-Me2,SWC_2_8_1,200710,-1.6,SWC-Other,,,18-5 -US-Me2,SWC_3_1_1,200710,-0.1,SWC-Other,,,18-5 -US-Me2,SWC_3_2_1,200710,-0.2,SWC-Other,,,18-5 -US-Me2,SWC_3_3_1,200710,-0.3,SWC-Other,,,18-5 -US-Me2,SWC_3_4_1,200710,-0.5,SWC-Other,,,18-5 -US-Me2,SWC_3_5_1,200710,-0.7,SWC-Other,,,18-5 -US-Me2,SWC_3_6_1,200710,-1.0,SWC-Other,,,18-5 -US-Me2,SWC_3_7_1,200710,-1.3,SWC-Other,,,18-5 -US-Me2,SWC_3_8_1,200710,-1.6,SWC-Other,,,18-5 -US-Me2,SWC_4_1_1,200201,-0.15,SWC-TDR,,The sensor is vertically installed; covering the soil depth of 0 - 0.3 m.,18-5 -US-Me2,SW_IN,200201,32,RAD-SW Pyran Class1,,,18-5 -US-Me2,SW_OUT,200508,32,RAD-SW Pyran Class1,,,18-5 -US-Me2,TA_1_1_1,201510,33,GA_CP-LI-COR LI-7200,,,18-5 -US-Me2,TA_1_1_2,200712,32,TEMP-Other,,,18-5 -US-Me2,TA_1_1_3,200201,32,TEMP-ElectResis,,,18-5 -US-Me2,TAU,200201,33,SA-Campbell CSAT-3,,,18-5 -US-Me2,TS_1_1_1,200201,-0.02,TEMP-TCouple,,,18-5 -US-Me2,TS_1_2_1,200201,-0.04,TEMP-TCouple,,,18-5 -US-Me2,TS_1_3_1,200201,-0.08,TEMP-TCouple,,,18-5 -US-Me2,TS_1_4_1,200201,-0.16,TEMP-TCouple,,,18-5 -US-Me2,TS_1_5_1,200201,-0.32,TEMP-TCouple,,,18-5 -US-Me2,TS_1_6_1,200201,-0.64,TEMP-TCouple,,,18-5 -US-Me2,T_SONIC,200201,33,SA-Campbell CSAT-3,,,18-5 -US-Me2,T_SONIC_SIGMA,200201,33,SA-Campbell CSAT-3,,,18-5 -US-Me2,U_SIGMA,200201,33,SA-Campbell CSAT-3,,,18-5 -US-Me2,USTAR,200201,33,SA-Campbell CSAT-3,,,18-5 -US-Me2,VPD_PI,200201,32,TEMP-ElectResis,,,18-5 -US-Me2,V_SIGMA,200201,33,SA-Campbell CSAT-3,,,18-5 -US-Me2,WD,200201,32,SA-Campbell CSAT-3,,CSAT3,18-5 -US-Me2,WS,200201,32,SA-Campbell CSAT-3,,CSAT3,18-5 -US-Me2,W_SIGMA,200201,33,SA-Campbell CSAT-3,,,18-5 -US-Me3,CO2,,12,GA-Other,,LICOR-6262,4-5 -US-Me3,CO2_PI_F,,12,GA-Other,,LICOR-6262,4-5 -US-Me3,FC,,12,SA-Other,,CSAT3/LI-7500,4-5 -US-Me3,FC_PI_F,,12,,,,4-5 -US-Me3,H,,12,,,,4-5 -US-Me3,H_PI_F,,12,,,,4-5 -US-Me3,LE,,12,,,,4-5 -US-Me3,LE_PI_F,,12,,,,4-5 -US-Me3,NETRAD,,12,,,,4-5 -US-Me3,NETRAD_PI_F,,12,,,,4-5 -US-Me3,PPFD_IN,,12,,,,4-5 -US-Me3,PPFD_IN_PI_F,,12,,,,4-5 -US-Me3,RH,,12,RH-Other,,Vaisla,4-5 -US-Me3,RH_PI_F,,12,RH-Other,,Vaisla,4-5 -US-Me3,SW_IN_1_1_1,,12,,,,4-5 -US-Me3,TA,,12,TEMP-Other,,Vaisla,4-5 -US-Me3,TA_PI_F,,12,TEMP-Other,,Vaisla,4-5 -US-Me3,TS_1_1_1,,-0.02,,,,4-5 -US-Me3,TS_1_2_1,,-0.04,,,,4-5 -US-Me3,TS_1_3_1,,-0.08,,,,4-5 -US-Me3,TS_1_4_1,,-0.16,,,,4-5 -US-Me3,TS_1_5_1,,-0.32,,,,4-5 -US-Me3,TS_1_6_1,,-0.64,,,,4-5 -US-Me3,TS_PI_F_1_1_1,,-0.02,,,,4-5 -US-Me3,TS_PI_F_1_2_1,,-0.04,,,,4-5 -US-Me3,TS_PI_F_1_3_1,,-0.08,,,,4-5 -US-Me3,TS_PI_F_1_4_1,,-0.16,,,,4-5 -US-Me3,TS_PI_F_1_5_1,,-0.32,,,,4-5 -US-Me3,TS_PI_F_1_6_1,,-0.64,,,,4-5 -US-Me3,WD,,12,WIND-Other,,CSAT3,4-5 -US-Me3,WD_PI_F,,12,WIND-Other,,CSAT3,4-5 -US-Me3,WS,,12,WIND-Other,,CSAT3,4-5 -US-Me3,WS_PI_F,,12,WIND-Other,,CSAT3,4-5 -US-Me4,CO2,,47,,,,5-5 -US-Me4,FC,,47,,,,5-5 -US-Me4,FH2O,,47,,,,5-5 -US-Me4,H,,47,,,,5-5 -US-Me4,LE,,47,,,,5-5 -US-Me4,NETRAD,,47,,,,5-5 -US-Me4,PPFD_IN,,47,,,,5-5 -US-Me4,RH,,47,RH-Other,,Vaisla,5-5 -US-Me4,TA,,47,TEMP-Other,,Vaisla,5-5 -US-Me4,TS_1_1_1,,-0.02,,,,5-5 -US-Me4,TS_1_2_1,,-0.15,,,,5-5 -US-Me4,WD,,47,,,,5-5 -US-Me4,WS,,47,,,,5-5 -US-Me5,CO2,,12,,,,3-5 -US-Me5,FC,,12,,,,3-5 -US-Me5,FH2O,,12,,,,3-5 -US-Me5,H,,12,,,,3-5 -US-Me5,LE,,12,,,,3-5 -US-Me5,NETRAD,,12,,,,3-5 -US-Me5,RH,,12,RH-Other,,Vaisla,3-5 -US-Me5,TA,,12,TEMP-Other,,Vaisla,3-5 -US-Me5,TS_1_1_1,,-0.02,,,,3-5 -US-Me5,TS_1_2_1,,-0.16,,,,3-5 -US-Me5,WD,,12,,,,3-5 -US-Me5,WS,,12,,,,3-5 -US-Me6,ALB,201002,,RAD-SW Pyran Class1,,,15-5 -US-Me6,CO2,201002,14.2,GA_OP-LI-COR LI-7500,,,15-5 -US-Me6,CO2,201410,14.2,GA_CP-LI-COR LI-7200RS,,,15-5 -US-Me6,D_SNOW,201410,,SNOW-Acoustic,,,15-5 -US-Me6,FC,201002,14.2,GA_OP-LI-COR LI-7500,,,15-5 -US-Me6,FC,201410,14.2,GA_CP-LI-COR LI-7200RS,,,15-5 -US-Me6,G_1_1_1,201410,,SOIL_H-Plate_AUTO,,,15-5 -US-Me6,G_2_1_1,201410,,SOIL_H-Plate_AUTO,,,15-5 -US-Me6,G_3_1_1,201410,,SOIL_H-Plate_AUTO,,,15-5 -US-Me6,H,201002,14.2,SA-Campbell CSAT-3,,,15-5 -US-Me6,H2O,201410,12,GA_CP-LI-COR LI-7200RS,,,15-5 -US-Me6,H2O,202002,14.2,GA_OP-LI-COR LI-7500,,,15-5 -US-Me6,LE,201002,14.2,GA_OP-LI-COR LI-7500,,,15-5 -US-Me6,LE,201410,12,GA_CP-LI-COR LI-7200RS,,,15-5 -US-Me6,LW_IN,201002,17.5,RAD-LW Pyrgeom,,,15-5 -US-Me6,LW_OUT,201002,17.5,RAD-LW Pyrgeom,,,15-5 -US-Me6,NETRAD,,17.5,,,,15-5 -US-Me6,P,201104,1.2,PREC-WeightGauge,,,15-5 -US-Me6,PA,201002,14.2,GA_OP-LI-COR LI-7500,,,15-5 -US-Me6,PA,201410,,GA_CP-LI-COR LI-7200RS,,,15-5 -US-Me6,PPFD_IN,201002,17.5,RAD-PAR Quantum,,,15-5 -US-Me6,RH,201002,14,RH-Capac,,,15-5 -US-Me6,SWC_1_1_1,201104,-0.1,SWC-Other,,,15-5 -US-Me6,SWC_1_2_1,201104,-0.2,SWC-Other,,,15-5 -US-Me6,SWC_1_3_1,201104,-0.3,SWC-Other,,,15-5 -US-Me6,SWC_1_4_1,201104,-0.5,SWC-Other,,,15-5 -US-Me6,SWC_1_5_1,201104,-1,SWC-Other,,,15-5 -US-Me6,SWC_2_1_1,201104,-0.1,SWC-Other,,,15-5 -US-Me6,SWC_2_2_1,201104,-0.2,SWC-Other,,,15-5 -US-Me6,SWC_2_3_1,201104,-0.3,SWC-Other,,,15-5 -US-Me6,SWC_2_4_1,201104,-0.4,SWC-Other,,,15-5 -US-Me6,SWC_2_5_1,201104,-1,SWC-Other,,,15-5 -US-Me6,SWC_3_1_1,201503,-0.1,SWC-Other,,,15-5 -US-Me6,SWC_3_2_1,201503,-0.2,SWC-Other,,,15-5 -US-Me6,SWC_3_3_1,201503,-0.3,SWC-Other,,,15-5 -US-Me6,SWC_3_4_1,201503,-0.5,SWC-Other,,,15-5 -US-Me6,SWC_3_5_1,201503,-1,SWC-Other,,,15-5 -US-Me6,SWC_4_1_1,201002,-0.3,SWC-TDR,,SWC integrated from the depth; 0 - 0.3 m,15-5 -US-Me6,SWC_5_1_1,201002,-0.3,SWC-TDR,,SWC integrated from the depth; 0 - 0.3 m,15-5 -US-Me6,SWC_6_1_1,201002,-0.3,SWC-TDR,,SWC integrated from the depth; 0 - 0.3 m,15-5 -US-Me6,SW_IN,201002,17.5,RAD-SW Pyran Class1,,,15-5 -US-Me6,SW_OUT,201002,17.5,RAD-SW Pyran Class1,,,15-5 -US-Me6,TA_1_1_1,,14.2,GA_CP-LI-COR LI-7200RS,,,15-5 -US-Me6,TA_1_1_2,201002,14,TEMP-Other,,,15-5 -US-Me6,TA_1_1_3,201002,14,TEMP-ElectResis,,,15-5 -US-Me6,TS_1_1_1,201005,-0.02,TEMP-TCouple,,,15-5 -US-Me6,TS_1_2_1,201005,-0.04,TEMP-TCouple,,,15-5 -US-Me6,TS_1_3_1,201201,-0.08,TEMP-TCouple,,,15-5 -US-Me6,TS_1_4_1,201201,-0.16,TEMP-TCouple,,,15-5 -US-Me6,TS_1_5_1,201201,-0.32,TEMP-TCouple,,,15-5 -US-Me6,TS_1_6_1,201201,-0.64,TEMP-TCouple,,,15-5 -US-Me6,T_SONIC,201002,14.2,SA-Campbell CSAT-3,,,15-5 -US-Me6,T_SONIC_SIGMA,201002,14.2,SA-Campbell CSAT-3,,,15-5 -US-Me6,U_SIGMA,201002,14.2,SA-Campbell CSAT-3,,,15-5 -US-Me6,USTAR,201002,14.2,SA-Campbell CSAT-3,,,15-5 -US-Me6,VPD_PI,201002,14,,,,15-5 -US-Me6,V_SIGMA,201002,14.2,SA-Campbell CSAT-3,,,15-5 -US-Me6,WD,201002,14.2,SA-Campbell CSAT-3,,,15-5 -US-Me6,WS,201002,14.2,SA-Campbell CSAT-3,,,15-5 -US-Me6,ZL,,14.2,,,,15-5 -US-Men,CO2_1_1_1,,12,GA_OP-LI-COR LI-7500A,,Calibrated against Picarro 4-species at 60 m,3-5 -US-Men,FC_1_1_1,,12,GA_OP-LI-COR LI-7500A,SA-Campbell CSAT-3,,3-5 -US-Men,H_1_1_1,,12,SA-Campbell CSAT-3,,,3-5 -US-Men,H2O_1_1_1,,12,GA_OP-LI-COR LI-7500A,,,3-5 -US-Men,LE_1_1_1,,12,GA_OP-LI-COR LI-7500A,SA-Campbell CSAT-3,,3-5 -US-Men,P,,60,RAIN-TipBucGauge,,AOSS Building Rooftop,3-5 -US-Men,PA,,60,PRES-ElectBar,,AOSS Building Rooftop,3-5 -US-Men,RH_1_1_1,,12,RH-ElecRes,,,3-5 -US-Men,SW_IN_1_1_1,,60,RAD-SW Pyran SecSt,,AOSS Building Rooftop,3-5 -US-Men,TA_1_1_1,,12,SA-Campbell CSAT-3,,,3-5 -US-Men,TW_1_1_1,,0,TEMP-ElectResis,,Mendota deep hole David buoy,3-5 -US-Men,USTAR_1_1_1,,12,SA-Campbell CSAT-3,,,3-5 -US-Men,VPD_PI_1_1_1,,12,RH-ElecRes,,,3-5 -US-Men,WD_1_1_1,,12,SA-Campbell CSAT-3,,,3-5 -US-Men,WS_1_1_1,,12,SA-Campbell CSAT-3,,,3-5 -US-MMS,CO2_1_1_1,,46,GA_CP-LI-COR LI-7000,,,21-5 -US-MMS,CO2_1_2_1,1999,34,GA_CP-LI-COR LI-7000,,,21-5 -US-MMS,CO2_2_1_1,,2,GA_CP-LI-COR LI-7000,,,21-5 -US-MMS,FC_1_1_1,19990101,46,GA_CP-LI-COR LI-7000,SA-Campbell CSAT-3,,21-5 -US-MMS,G_2_1_1,19990101,-0.2,SOIL_H-Plate,,,21-5 -US-MMS,G_2_1_2,,-0.2,SOIL_H-Plate,,,21-5 -US-MMS,H_1_1_1,,46,SA-Campbell CSAT-3,,,21-5 -US-MMS,H2O_1_1_1,,46,GA_CP-LI-COR LI-7000,,,21-5 -US-MMS,H2O_1_2_1,,34,GA_CP-LI-COR LI-7000,,,21-5 -US-MMS,H2O_2_1_1,,2,GA_CP-LI-COR LI-7000,,,21-5 -US-MMS,LE_1_1_1,,46,GA_CP-LI-COR LI-7000,SA-Campbell CSAT-3,,21-5 -US-MMS,LW_BC_IN_1_1_1,,1,RAD-Pyrrad-SW+LW,,,21-5 -US-MMS,LW_BC_OUT_1_1_1,,1,RAD-Pyrrad-SW+LW,,,21-5 -US-MMS,LW_IN_1_1_1,,46,RAD-Pyrrad-SW+LW,,,21-5 -US-MMS,LW_IN_1_2_1,,34,RAD-Pyrrad-SW+LW,,,21-5 -US-MMS,LW_OUT_1_1_1,,46,RAD-Pyrrad-SW+LW,,,21-5 -US-MMS,LW_OUT_1_2_1,,34,RAD-Pyrrad-SW+LW,,,21-5 -US-MMS,NETRAD_1_1_1,,46,RAD-Pyrrad-SW+LW,,,21-5 -US-MMS,P_1_1_1,,46,PREC-TipBucGauge,,,21-5 -US-MMS,P_2_1_1,,0,PREC-TipBucGauge,,,21-5 -US-MMS,PA_1_1_1,,46,PRES-ElectBar,,,21-5 -US-MMS,PPFD_BC_IN_1_1_1,,1,RAD-PAR Quantum,,,21-5 -US-MMS,PPFD_DIF_1_1_1,,46,RAD-Other,,,21-5 -US-MMS,PPFD_IN_1_1_1,,46,RAD-Other,,,21-5 -US-MMS,PPFD_IN_1_1_2,,46,RAD-PAR Quantum,,,21-5 -US-MMS,RECO_PI_1_1_1,,46,GA_CP-LI-COR LI-7000,SA-Campbell CSAT-3,,21-5 -US-MMS,RH_1_1_1,,46,RH-Other,,,21-5 -US-MMS,RH_1_1_2,,46,RH-Capac,,,21-5 -US-MMS,RH_1_2_1,,34,RH-Capac,,,21-5 -US-MMS,RH_1_3_1,,22,RH-Capac,,,21-5 -US-MMS,SW_BC_IN_1_1_1,,1,RAD-Pyrrad-SW+LW,,,21-5 -US-MMS,SW_BC_OUT_1_1_1,,1,RAD-Pyrrad-SW+LW,,,21-5 -US-MMS,SWC_1,,-0.30,SWC-TDR,,,21-5 -US-MMS,SWC_1_1_1,,-0.3,SWC-TDR,,,21-5 -US-MMS,SWC_2_1_1,,-0.3,SWC-TDR,,,21-5 -US-MMS,SWC_3_1_1,,-0.3,SWC-TDR,,,21-5 -US-MMS,SWC_4_1_1,,-0.3,SWC-TDR,,,21-5 -US-MMS,SWC_5_1_1,,-0.3,SWC-TDR,,,21-5 -US-MMS,SWC_6_1_1,,-0.3,SWC-TDR,,,21-5 -US-MMS,SW_IN_1_1_1,,46,RAD-Pyrrad-SW+LW,,,21-5 -US-MMS,SW_IN_1_2_1,,34,RAD-Pyrrad-SW+LW,,,21-5 -US-MMS,SW_OUT_1_1_1,,46,RAD-Pyrrad-SW+LW,,,21-5 -US-MMS,SW_OUT_1_2_1,1999,34,RAD-Pyrrad-SW+LW,,,21-5 -US-MMS,TA_1_1_1,,46,TEMP-ElectResis,,,21-5 -US-MMS,TA_1_1_2,,46,TEMP-ElectResis,,,21-5 -US-MMS,TA_1_2_1,,34,TEMP-ElectResis,,,21-5 -US-MMS,TA_1_3_1,,22,TEMP-ElectResis,,,21-5 -US-MMS,TA_2_1_1,,2,TEMP-ElectResis,,,21-5 -US-MMS,TS_2_1_1,,-0.2,TEMP-TCouple,,,21-5 -US-MMS,T_SONIC_1_1_1,,46,SA-Campbell CSAT-3,,,21-5 -US-MMS,T_SONIC_1_2_1,,34,SA-Campbell CSAT-3,,,21-5 -US-MMS,T_SONIC_2_1_1,,2,SA-Campbell CSAT-3,,,21-5 -US-MMS,T_SONIC_SIGMA_1_1_1,,46,SA-Campbell CSAT-3,,,21-5 -US-MMS,T_SONIC_SIGMA_1_2_1,,34,SA-Campbell CSAT-3,,,21-5 -US-MMS,T_SONIC_SIGMA_2_1_1,,2,SA-Campbell CSAT-3,,,21-5 -US-MMS,U_SIGMA_1_1_1,,46,SA-Campbell CSAT-3,,,21-5 -US-MMS,U_SIGMA_1_2_1,,34,SA-Campbell CSAT-3,,,21-5 -US-MMS,U_SIGMA_2_1_1,,2,SA-Campbell CSAT-3,,,21-5 -US-MMS,USTAR_1_1_1,,46,SA-Campbell CSAT-3,,,21-5 -US-MMS,VPD_PI_1_1_1,,46,TEMP-Other,,,21-5 -US-MMS,V_SIGMA_1_1_1,,46,SA-Campbell CSAT-3,,,21-5 -US-MMS,V_SIGMA_1_2_1,,34,SA-Campbell CSAT-3,,,21-5 -US-MMS,V_SIGMA_2_1_1,,2,SA-Campbell CSAT-3,,,21-5 -US-MMS,WD_1_1_1,,46,SA-Campbell CSAT-3,,,21-5 -US-MMS,WD_1_1_2,,46,WIND-CupAn,,,21-5 -US-MMS,WD_1_2_1,,34,SA-Campbell CSAT-3,,,21-5 -US-MMS,WD_2_1_1,,2,SA-Campbell CSAT-3,,,21-5 -US-MMS,WS_1_1_1,,46,SA-Campbell CSAT-3,,,21-5 -US-MMS,WS_1_1_2,,46,WIND-CupAn,,,21-5 -US-MMS,WS_1_2_1,,34,SA-Campbell CSAT-3,,,21-5 -US-MMS,WS_2_1_1,,2,SA-Campbell CSAT-3,,,21-5 -US-MMS,W_SIGMA_1_1_1,,46,SA-Campbell CSAT-3,,,21-5 -US-MMS,W_SIGMA_1_2_1,,34,SA-Campbell CSAT-3,,,21-5 -US-MMS,W_SIGMA_2_1_1,,2,SA-Campbell CSAT-3,,,21-5 -US-Mo1,CO2_1_1_1,2015,1.88,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo1,CO2_1_1_1,20160523,2,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo1,CO2_1_1_1,20160608,2.85,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo1,CO2_1_1_1,20160929,3.6,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo1,CO2_1_1_1,20161007,1.8,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo1,CO2_1_1_1,20170516,2.18,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo1,CO2_1_1_1,20201119,2.13,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo1,CO2_MIXING_RATIO_1_1_1,2015,1.88,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo1,CO2_MIXING_RATIO_1_1_1,20160523,2,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo1,CO2_MIXING_RATIO_1_1_1,20160608,2.85,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo1,CO2_MIXING_RATIO_1_1_1,20160929,3.6,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo1,CO2_MIXING_RATIO_1_1_1,20161007,1.8,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo1,CO2_MIXING_RATIO_1_1_1,20170516,2.18,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo1,CO2_MIXING_RATIO_1_1_1,20201119,2.13,GA_OP_SA-Campbell IRGASON,,,1-5 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-US-Mo3,FC_1_1_1,20170713,2.80,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,FC_1_1_1,20170824,3.50,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,FC_1_1_1,20171020,2.10,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,FC_1_1_1,20200709,2.40,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,FC_1_1_1,20200714,2.70,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,FC_1_1_1,20200724,3.50,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,FC_1_1_1,20201104,2.40,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,G_1_1_1,,,SOIL_H-Plate,,,1-5 -US-Mo3,G_2_1_1,,,SOIL_H-Plate,,,1-5 -US-Mo3,G_3_1_1,,,SOIL_H-Plate,,,1-5 -US-Mo3,G_4_1_1,,,SOIL_H-Plate,,,1-5 -US-Mo3,H_1_1_1,2016,2.2,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,H_1_1_1,20170713,2.8,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,H_1_1_1,20170824,3.5,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,H_1_1_1,20171020,2.1,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,H_1_1_1,20200709,2.4,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,H_1_1_1,20200714,2.7,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,H_1_1_1,20200724,3.5,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,H_1_1_1,20201104,2.4,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,H2O_1_1_1,2016,2.2,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,H2O_1_1_1,20170713,2.8,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,H2O_1_1_1,20170824,3.5,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,H2O_1_1_1,20171020,2.1,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,H2O_1_1_1,20200709,2.4,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,H2O_1_1_1,20200714,2.7,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,H2O_1_1_1,20200724,3.5,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,H2O_1_1_1,20201104,2.4,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,H2O_MIXING_RATIO_1_1_1,2016,2.2,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,H2O_MIXING_RATIO_1_1_1,20170713,2.8,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,H2O_MIXING_RATIO_1_1_1,20170824,3.5,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,H2O_MIXING_RATIO_1_1_1,20171020,2.1,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,H2O_MIXING_RATIO_1_1_1,20200709,2.4,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,H2O_MIXING_RATIO_1_1_1,20200714,2.7,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,H2O_MIXING_RATIO_1_1_1,20200724,3.5,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,H2O_MIXING_RATIO_1_1_1,20201104,2.4,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,H2O_SIGMA_1_1_1,2016,2.2,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,H2O_SIGMA_1_1_1,20170713,2.8,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,H2O_SIGMA_1_1_1,20170824,3.5,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,H2O_SIGMA_1_1_1,20171020,2.1,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,H2O_SIGMA_1_1_1,20200709,2.4,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,H2O_SIGMA_1_1_1,20200714,2.7,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,H2O_SIGMA_1_1_1,20200724,3.5,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,H2O_SIGMA_1_1_1,20201104,2.4,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,H_PI_PI_F_1_1_1,2016,2.2,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,H_PI_PI_F_1_1_1,20170713,2.8,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,H_PI_PI_F_1_1_1,20170824,3.5,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,H_PI_PI_F_1_1_1,20171020,2.1,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,H_PI_PI_F_1_1_1,20200709,2.4,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,H_PI_PI_F_1_1_1,20200714,2.7,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,H_PI_PI_F_1_1_1,20200724,3.5,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,H_PI_PI_F_1_1_1,20201104,2.4,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,LE_1_1_1,2016,2.2,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,LE_1_1_1,20170713,2.8,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,LE_1_1_1,20170824,3.5,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,LE_1_1_1,20171020,2.1,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,LE_1_1_1,20200709,2.4,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,LE_1_1_1,20200714,2.7,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,LE_1_1_1,20200724,3.5,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,LE_1_1_1,20201104,2.4,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,LE_PI_PI_F_1_1_1,2016,2.2,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,LE_PI_PI_F_1_1_1,20170713,2.8,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,LE_PI_PI_F_1_1_1,20170824,3.5,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,LE_PI_PI_F_1_1_1,20171020,2.1,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,LE_PI_PI_F_1_1_1,20200709,2.4,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,LE_PI_PI_F_1_1_1,20200714,2.7,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,LE_PI_PI_F_1_1_1,20200724,3.5,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,LE_PI_PI_F_1_1_1,20201104,2.4,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,LW_IN_1_1_1,,,RAD-Pyrrad-SW+LW,,,1-5 -US-Mo3,LW_OUT_1_1_1,,,RAD-Pyrrad-SW+LW,,,1-5 -US-Mo3,MO_LENGTH_1_1_1,,,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,NEE_PI_PI,,,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,NEE_PI_PI_F,,,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,NETRAD_1_1_1,,,RAD-Pyrrad-SW+LW,,,1-5 -US-Mo3,P_1_1_1,,,PREC-WeightGauge,,,1-5 -US-Mo3,PA_1_1_1,2016,2.2,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,PA_1_1_1,20170713,2.8,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,PA_1_1_1,20170824,3.5,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,PA_1_1_1,20171020,2.1,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,PA_1_1_1,20200709,2.4,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,PA_1_1_1,20200714,2.7,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,PA_1_1_1,20200724,3.5,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,PA_1_1_1,20201104,2.4,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,PPFD_IN_1_1_1,,,RAD-PAR Quantum,,,1-5 -US-Mo3,PPFD_OUT_1_1_1,,,RAD-PAR Quantum,,,1-5 -US-Mo3,RH_1_1_1,,,RH-Capac,,,1-5 -US-Mo3,SG_1_1_1,,,SOIL_H-Plate,,,1-5 -US-Mo3,SG_2_1_1,,,SOIL_H-Plate,,,1-5 -US-Mo3,SWC_1_1_1,,,SWC-FDR,,,1-5 -US-Mo3,SW_IN_1_1_1,,,RAD-Pyrrad-SW+LW,,,1-5 -US-Mo3,SW_OUT_1_1_1,,,RAD-Pyrrad-SW+LW,,,1-5 -US-Mo3,TA_1_1_1,,,RH-Capac,,,1-5 -US-Mo3,TA_PI_F_1_1_1,,,RH-Capac,,,1-5 -US-Mo3,TAU_1_1_1,2016,2.2,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,TAU_1_1_1,20170713,2.8,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,TAU_1_1_1,20170824,3.5,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,TAU_1_1_1,20171020,2.1,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,TAU_1_1_1,20200709,2.4,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,TAU_1_1_1,20200714,2.7,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,TAU_1_1_1,20200724,3.5,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,TAU_1_1_1,20201104,2.4,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,TS_1_1_1,,,TEMP-TCouple,,,1-5 -US-Mo3,TS_2_1_1,,,TEMP-TCouple,,,1-5 -US-Mo3,TS_3_1_1,,,SWC-FDR,,,1-5 -US-Mo3,T_SONIC_1_1_1,2016,2.2,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,T_SONIC_1_1_1,20170713,2.8,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,T_SONIC_1_1_1,20170824,3.5,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,T_SONIC_1_1_1,20171020,2.1,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,T_SONIC_1_1_1,20200709,2.4,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,T_SONIC_1_1_1,20200714,2.7,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,T_SONIC_1_1_1,20200724,3.5,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,T_SONIC_1_1_1,20201104,2.4,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,T_SONIC_SIGMA_1_1_1,2016,2.2,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,T_SONIC_SIGMA_1_1_1,20170713,2.8,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,T_SONIC_SIGMA_1_1_1,20170824,3.5,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,T_SONIC_SIGMA_1_1_1,20171020,2.1,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,T_SONIC_SIGMA_1_1_1,20200709,2.4,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,T_SONIC_SIGMA_1_1_1,20200714,2.7,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,T_SONIC_SIGMA_1_1_1,20200724,3.5,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,T_SONIC_SIGMA_1_1_1,20201104,2.4,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,U_SIGMA_1_1_1,2016,2.2,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,U_SIGMA_1_1_1,20170713,2.8,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,U_SIGMA_1_1_1,20170824,3.5,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,U_SIGMA_1_1_1,20171020,2.1,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,U_SIGMA_1_1_1,20200709,2.4,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,U_SIGMA_1_1_1,20200714,2.7,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,U_SIGMA_1_1_1,20200724,3.5,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,U_SIGMA_1_1_1,20201104,2.4,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,USTAR_1_1_1,2016,2.2,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,USTAR_1_1_1,20170713,2.8,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,USTAR_1_1_1,20170824,3.5,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,USTAR_1_1_1,20171020,2.1,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,USTAR_1_1_1,20200709,2.4,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,USTAR_1_1_1,20200714,2.7,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,USTAR_1_1_1,20200724,3.5,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,USTAR_1_1_1,20201104,2.4,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,VPD_PI_PI_1_1_1,,,RH-Capac,,,1-5 -US-Mo3,V_SIGMA_1_1_1,2016,2.2,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,V_SIGMA_1_1_1,20170713,2.8,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,V_SIGMA_1_1_1,20170824,3.5,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,V_SIGMA_1_1_1,20171020,2.1,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,V_SIGMA_1_1_1,20200709,2.4,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,V_SIGMA_1_1_1,20200714,2.7,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,V_SIGMA_1_1_1,20200724,3.5,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,V_SIGMA_1_1_1,20201104,2.4,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,WD_1_1_1,2016,2.2,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,WD_1_1_1,20170713,2.8,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,WD_1_1_1,20170824,3.5,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,WD_1_1_1,20171020,2.1,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,WD_1_1_1,20200709,2.4,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,WD_1_1_1,20200714,2.7,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,WD_1_1_1,20200724,3.5,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,WD_1_1_1,20201104,2.4,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,WS_1_1_1,2016,2.2,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,WS_1_1_1,20170713,2.8,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,WS_1_1_1,20170824,3.5,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,WS_1_1_1,20171020,2.1,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,WS_1_1_1,20200709,2.4,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,WS_1_1_1,20200714,2.7,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,WS_1_1_1,20200724,3.5,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,WS_1_1_1,20201104,2.4,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,W_SIGMA_1_1_1,2016,2.2,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,W_SIGMA_1_1_1,20170713,2.8,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,W_SIGMA_1_1_1,20170824,3.5,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,W_SIGMA_1_1_1,20171020,2.1,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,W_SIGMA_1_1_1,20200709,2.4,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,W_SIGMA_1_1_1,20200714,2.7,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,W_SIGMA_1_1_1,20200724,3.5,GA_OP_SA-Campbell IRGASON,,,1-5 -US-Mo3,W_SIGMA_1_1_1,20201104,2.4,GA_OP_SA-Campbell IRGASON,,,1-5 -US-MOz,CO2_1_1_1,,30.48,GA_CP-LI-COR LI-7000,,,9-5 -US-MOz,FC_1_1_1,20100101,30,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,9-5 -US-MOz,FC_1_1_1,20120101,30,GA_CP-LI-COR LI-7200,SA-Campbell CSAT-3,,9-5 -US-MOz,FC_1_1_1,,30,GA_OP-LI-COR LI-7500,SA-Young 81000,,9-5 -US-MOz,G_1_1_1,20040101,-0.05,SOIL_H-Plate_AUTO,,,9-5 -US-MOz,G_1_1_2,,-0.05,SOIL_H-Plate_AUTO,,,9-5 -US-MOz,G_1_1_3,,-0.05,SOIL_H-Plate_AUTO,,,9-5 -US-MOz,H_1_1_1,20100101,30,SA-Campbell CSAT-3,,,9-5 -US-MOz,H_1_1_1,,30,SA-Young 81000,,,9-5 -US-MOz,H2O_1_1_1,,30.48,GA_CP-LI-COR LI-7000,,,9-5 -US-MOz,LE_1_1_1,20100101,30,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,9-5 -US-MOz,LE_1_1_1,20120101,30,GA_CP-LI-COR LI-7200,SA-Campbell CSAT-3,,9-5 -US-MOz,LE_1_1_1,,30,GA_OP-LI-COR LI-7500,SA-Young 81000,,9-5 -US-MOz,LW_IN_1_1_1,,30,RAD-Pyrrad-SW+LW,,CNR4,9-5 -US-MOz,LW_OUT_1_1_1,,30,RAD-Pyrrad-SW+LW,,CNR4,9-5 -US-MOz,NEE_PI,20100101,,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,Height does not apply. Sum of eddy flux and storage flux based on measurements at multiple levels.,9-5 -US-MOz,NEE_PI,20120101,,GA_CP-LI-COR LI-7200,SA-Campbell CSAT-3,Height does not apply. Sum of eddy flux and storage flux based on measurements at multiple levels.,9-5 -US-MOz,NEE_PI,,,GA_OP-LI-COR LI-7500,SA-Young 81000,Height does not apply. Sum of eddy flux and storage flux based on measurements at multiple levels.,9-5 -US-MOz,NEE_PI_F,20100101,,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,Height does not apply. Sum of eddy flux and storage flux based on measurements at multiple levels.,9-5 -US-MOz,NEE_PI_F,20120101,,GA_CP-LI-COR LI-7200,SA-Campbell CSAT-3,Height does not apply. Sum of eddy flux and storage flux based on measurements at multiple levels.,9-5 -US-MOz,NEE_PI_F,,,GA_OP-LI-COR LI-7500,SA-Young 81000,Height does not apply. Sum of eddy flux and storage flux based on measurements at multiple levels.,9-5 -US-MOz,NETRAD_1_1_1,,30,RAD-Pyrrad-SW+LW,,CNR4,9-5 -US-MOz,P_1_1_1,,32,RAIN-TipBucGauge,,,9-5 -US-MOz,PA_1_1_1,,30,PRES-ElectBar,,,9-5 -US-MOz,PPFD_IN_1_1_1,,30,RAD-Pyrrad-SW+LW,,CNR4,9-5 -US-MOz,PPFD_OUT_1_1_1,,30,RAD-Pyrrad-SW+LW,,,9-5 -US-MOz,RH_1_1_1,,30.48,RH-Capac,,,9-5 -US-MOz,SC_1_1_1,,,GA_CP-LI-COR LI-7000,,Storage flux computed from measurements at 12 levels according to Gu et al. (2012; doi:10.1016/j.agrformet.2011.09.014).,9-5 -US-MOz,SH_1_1_1,,,TEMP-ElectResis,,Storage flux computed from measurements at 8 levels according to Gu et al. (2012; doi:10.1016/j.agrformet.2011.09.014).,9-5 -US-MOz,SLE_1_1_1,,,GA_CP-LI-COR LI-7000,,Storage flux computed from measurements at 12 levels according to Gu et al. (2012; doi:10.1016/j.agrformet.2011.09.014).,9-5 -US-MOz,SWC_1_1_1,,-0.1,SWC-Other,,,9-5 -US-MOz,SW_IN_1_1_1,,30,RAD-Pyrrad-SW+LW,,,9-5 -US-MOz,SW_OUT_1_1_1,,30,RAD-Pyrrad-SW+LW,,,9-5 -US-MOz,TA_1_1_1,,30.48,TEMP-ElectResis,,,9-5 -US-MOz,TS_1_1_1,,-0.1,TEMP-TCouple,,,9-5 -US-MOz,USTAR_1_1_1,20100101,30,SA-Campbell CSAT-3,,,9-5 -US-MOz,USTAR_1_1_1,,30,SA-Young 81000,,,9-5 -US-MOz,WD_1_1_1,20100101,30,SA-Campbell CSAT-3,,,9-5 -US-MOz,WD_1_1_1,,30,SA-Young 81000,,,9-5 -US-MOz,WS_1_1_1,20100101,30,SA-Campbell CSAT-3,,,9-5 -US-MOz,WS_1_1_1,,30,SA-Young 81000,,,9-5 -US-Mpj,CO2,2008,8.2,GA_OP-LI-COR LI-7500,,,18-5 -US-Mpj,FC,2008,8.2,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,18-5 -US-Mpj,H,2008,8.2,GA_OP-LI-COR LI-7500,,,18-5 -US-Mpj,H2O,2008,8.2,GA_OP-LI-COR LI-7500,,,18-5 -US-Mpj,LE,2008,8.2,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,18-5 -US-Mpj,LW_IN,2008,8.2,RAD-Net radiometer,,Kipp & Zonen CNR1,18-5 -US-Mpj,LW_OUT,2008,8.2,RAD-Net radiometer,,Kipp & Zonen CNR1,18-5 -US-Mpj,NETRAD,2008,8.2,RAD-Net radiometer,,Kipp & Zonen CNR1,18-5 -US-Mpj,P,2008,2.3,PREC-TipBucGauge,,Texas Electronics; Inc.,18-5 -US-Mpj,PA,2008,8.2,GA_OP-LI-COR LI-7500,,,18-5 -US-Mpj,P_PI_F,2008,2.3,PREC-TipBucGauge,,P data gapfilled from nearby tower sites and meteorological stations,18-5 -US-Mpj,PPFD_IN,2008,8.2,RAD-PAR Quantum,,Kipp & Zonen PQS1,18-5 -US-Mpj,RH,2008,8.2,RH-Capac,,Vaisala HMP45c,18-5 -US-Mpj,RH_PI_F,2008,8.2,RH-Capac,,RH data gapfilled from nearby tower sites ,18-5 -US-Mpj,SW_IN,2008,8.2,RAD-Net radiometer,,Kipp & Zonen CNR1,18-5 -US-Mpj,SW_OUT,2008,8.2,RAD-Net radiometer,,Kipp & Zonen CNR1,18-5 -US-Mpj,TA,2008,8.2,SA-Campbell CSAT-3,,,18-5 -US-Mpj,TA_PI_F,2008,8.2,SA-Campbell CSAT-3,,TA data gapfilled from nearby towers sites and from Vaisala HMP45c data,18-5 -US-Mpj,USTAR,2008,8.2,SA-Campbell CSAT-3,,,18-5 -US-Mpj,VPD_PI,2008,8.2,MULTI-Meteo,,calculated from TA and RH,18-5 -US-Mpj,VPD_PI_F,2008,8.2,MULTI-Meteo,,VPD data gapfilled from nearby tower sites,18-5 -US-Mpj,WD,2008,8.2,SA-Campbell CSAT-3,,,18-5 -US-Mpj,WS,2008,8.2,SA-Campbell CSAT-3,,,18-5 -US-MRf,CO2_1,,38.3,,,,4-1 -US-MRf,FC,,38.3,,,,4-1 -US-MRf,H,,38.3,,,,4-1 -US-MRf,H2O,,38.3,,,,4-1 -US-MRf,LE,,38.3,,,,4-1 -US-MRf,LW_IN,,37,RAD-Other,,CNR1,4-1 -US-MRf,LW_OUT,,37,RAD-Other,,CNR1,4-1 -US-MRf,NETRAD,,37,,,,4-1 -US-MRf,P,,38,,,,4-1 -US-MRf,PA,,35,,,,4-1 -US-MRf,PPFD_IN,,37,RAD-Other,,LI190&PARlite,4-1 -US-MRf,RH,,38,RH-Other,,HMP,4-1 -US-MRf,SWC_1,,-0.1,,,,4-1 -US-MRf,SWC_2,,-0.2,,,,4-1 -US-MRf,SW_DIF,,37.2,RAD-Other,,BF3,4-1 -US-MRf,SW_IN,,37,,,,4-1 -US-MRf,SW_OUT,,37,RAD-Other,,CNR1,4-1 -US-MRf,TA,,38,,,,4-1 -US-MRf,TS_1,,-0.02,,,,4-1 -US-MRf,TS_2,,-0.08,,,,4-1 -US-MRf,USTAR,,38.3,,,,4-1 -US-MRf,VPD_PI_PI,,38,RH-Other,,HMP&LI7000&LI7500,4-1 -US-MRf,WD,,38.3,WIND-Other,,CSAT,4-1 -US-MRf,WS,,38.3,WIND-Other,,CSAT&CUP,4-1 -US-MtB,CO2,2009,29.8,GA_OP-LI-COR LI-7500,,,4-5 -US-MtB,D_SNOW,2009,2.5,SNOW-Acoustic,,,4-5 -US-MtB,FC,2009,29.8,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,4-5 -US-MtB,G,2009,-0.05,SOIL_H-Plate,,,4-5 -US-MtB,H,2009,29.8,SA-Campbell CSAT-3,,,4-5 -US-MtB,H2O,2009,29.8,GA_OP-LI-COR LI-7500,,,4-5 -US-MtB,LE,2009,29.8,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,4-5 -US-MtB,LW_IN,2009,25,RAD-Pyrrad-SW+LW,,,4-5 -US-MtB,LW_OUT,2009,25,RAD-Pyrrad-SW+LW,,,4-5 -US-MtB,NETRAD,2009,25,RAD-Pyrrad-SW+LW,,,4-5 -US-MtB,P_1_1_1,2009,1,PREC-TipBucGauge,,,4-5 -US-MtB,P_2_1_1,1999,1,PREC-WeightGauge,,,4-5 -US-MtB,PA,2009,29.8,GA_OP-LI-COR LI-7500,,,4-5 -US-MtB,PPFD_IN,2009,25,RAD-PAR Quantum,,,4-5 -US-MtB,PPFD_IN_PI_F,2009,25,RAD-PAR Quantum,,,4-5 -US-MtB,PPFD_OUT,2009,25,RAD-PAR Quantum,,,4-5 -US-MtB,RH_1_1_1,2009,31,RH-Capac,,,4-5 -US-MtB,RH_1_2_1,20130919,24,RH-Capac,,,4-5 -US-MtB,RH_1_3_1,2009,16,RH-Capac,,,4-5 -US-MtB,RH_1_4_1,20130919,8.75,RH-Capac,,,4-5 -US-MtB,RH_1_5_1,2009,1.5,RH-Capac,,,4-5 -US-MtB,SWC_1_1_1,2009,-0.05,SWC-TDR,,,4-5 -US-MtB,SWC_1_2_1,2009,-0.15,SWC-TDR,,,4-5 -US-MtB,SWC_1_3_1,2009,-0.25,SWC-TDR,,,4-5 -US-MtB,SWC_1_4_1,2009,-0.4,SWC-TDR,,,4-5 -US-MtB,SWC_2_1_1,2009,-0.05,SWC-TDR,,,4-5 -US-MtB,SWC_2_2_1,2009,-0.15,SWC-TDR,,,4-5 -US-MtB,SWC_2_3_1,2009,-0.25,SWC-TDR,,,4-5 -US-MtB,SWC_2_4_1,2009,-0.5,SWC-TDR,,,4-5 -US-MtB,SWC_3_1_1,2009,-0.05,SWC-TDR,,,4-5 -US-MtB,SWC_3_2_1,2009,-0.15,SWC-TDR,,,4-5 -US-MtB,SWC_3_3_1,2009,-0.25,SWC-TDR,,,4-5 -US-MtB,SWC_3_4_1,2009,-0.5,SWC-TDR,,,4-5 -US-MtB,SW_IN,2009,25,RAD-Pyrrad-SW+LW,,,4-5 -US-MtB,SW_IN_PI_F,2009,25,RAD-Pyrrad-SW+LW,,,4-5 -US-MtB,SW_OUT,2009,25,RAD-Pyrrad-SW+LW,,,4-5 -US-MtB,TA_1_1_1,2009,31,TEMP-ElectResis,,,4-5 -US-MtB,TA_1_2_1,20130919,24,TEMP-ElectResis,,,4-5 -US-MtB,TA_1_3_1,2009,16,TEMP-ElectResis,,,4-5 -US-MtB,TA_1_4_1,20130919,8.75,TEMP-ElectResis,,,4-5 -US-MtB,TA_1_5_1,2009,1.5,TEMP-ElectResis,,,4-5 -US-MtB,T_BOLE_1_1_1,2009,1,TEMP-TCouple,,South side under bark,4-5 -US-MtB,T_BOLE_1_2_1,2009,1,TEMP-TCouple,,South side bark,4-5 -US-MtB,T_BOLE_2_1_1,2009,1,TEMP-TCouple,,North side under bark,4-5 -US-MtB,T_BOLE_2_2_1,2009,1,TEMP-TCouple,,North side bark,4-5 -US-MtB,TS_1_1_1,2009,-0.01,TEMP-TCouple,,,4-5 -US-MtB,TS_1_2_1,2009,-0.02,TEMP-TCouple,,,4-5 -US-MtB,TS_1_3_1,2009,-0.04,TEMP-TCouple,,,4-5 -US-MtB,TS_1_4_1,2009,-0.08,TEMP-TCouple,,,4-5 -US-MtB,TS_1_5_1,2009,-0.16,TEMP-TCouple,,,4-5 -US-MtB,TS_1_6_1,2009,-0.32,TEMP-TCouple,,,4-5 -US-MtB,TS_1_7_1,2009,-0.64,TEMP-TCouple,,,4-5 -US-MtB,TS_2_1_1,2009,-0.01,TEMP-TCouple,,,4-5 -US-MtB,TS_2_2_1,2009,-0.02,TEMP-TCouple,,,4-5 -US-MtB,TS_2_3_1,2009,-0.04,TEMP-TCouple,,,4-5 -US-MtB,TS_2_4_1,2009,-0.08,TEMP-TCouple,,,4-5 -US-MtB,TS_2_5_1,2009,-0.16,TEMP-TCouple,,,4-5 -US-MtB,TS_2_6_1,2009,-0.32,TEMP-Thermis,,,4-5 -US-MtB,TS_2_7_1,2009,-0.64,TEMP-Thermis,,,4-5 -US-MtB,TS_3_1_1,2009,-0.01,TEMP-TCouple,,,4-5 -US-MtB,TS_3_2_1,2009,-0.02,TEMP-TCouple,,,4-5 -US-MtB,TS_3_3_1,2009,-0.04,TEMP-TCouple,,,4-5 -US-MtB,TS_3_4_1,2009,-0.08,TEMP-TCouple,,,4-5 -US-MtB,TS_3_5_1,2009,-0.16,TEMP-TCouple,,,4-5 -US-MtB,TS_3_6_1,2009,-0.32,TEMP-TCouple,,,4-5 -US-MtB,TS_3_7_1,2009,-0.64,TEMP-TCouple,,,4-5 -US-MtB,T_SONIC,2009,29.8,SA-Campbell CSAT-3,,,4-5 -US-MtB,USTAR,2009,29.8,SA-Campbell CSAT-3,,,4-5 -US-MtB,VPD_PI_1_1_1,2009,31,RH-Capac,,,4-5 -US-MtB,VPD_PI_1_2_1,20130919,24,RH-Capac,,,4-5 -US-MtB,VPD_PI_1_3_1,2009,16,RH-Capac,,,4-5 -US-MtB,VPD_PI_1_4_1,20130919,8.75,RH-Capac,,,4-5 -US-MtB,VPD_PI_1_5_1,2009,1.5,RH-Capac,,,4-5 -US-MtB,WD,2009,29.8,SA-Campbell CSAT-3,,,4-5 -US-MtB,WS,2009,29.8,SA-Campbell CSAT-3,,,4-5 -US-Myb,CH4,,5.44,GA_OP-LI-COR LI-7700,,,13-5 -US-Myb,CO2,20120424,5.44,GA_OP-LI-COR LI-7500A,,,13-5 -US-Myb,CO2,,5.44,GA_OP-LI-COR LI-7500,,,13-5 -US-Myb,FC,20120424,5.44,GA_OP-LI-COR LI-7500A,SA-Gill Windmaster,,13-5 -US-Myb,FC,,5.44,GA_OP-LI-COR LI-7500,SA-Gill Windmaster Pro,,13-5 -US-Myb,FC_PI_F,20120424,5.44,GA_OP-LI-COR LI-7500A,SA-Gill Windmaster,,13-5 -US-Myb,FC_PI_F,,5.44,GA_OP-LI-COR LI-7500,SA-Gill Windmaster Pro,,13-5 -US-Myb,FCH4,20120424,5.44,GA_OP-LI-COR LI-7700,SA-Gill Windmaster,,13-5 -US-Myb,FCH4,,5.44,GA_OP-LI-COR LI-7700,SA-Gill Windmaster Pro,,13-5 -US-Myb,FCH4_PI_F,20120424,5.44,GA_OP-LI-COR LI-7700,SA-Gill Windmaster,,13-5 -US-Myb,FCH4_PI_F,,5.44,GA_OP-LI-COR LI-7700,SA-Gill Windmaster Pro,,13-5 -US-Myb,FH2O,20120424,5.44,GA_OP-LI-COR LI-7500A,,SA-Gill Windmaster Pro,13-5 -US-Myb,FH2O,,5.44,GA_OP-LI-COR LI-7500,,SA-Gill Windmaster Pro,13-5 -US-Myb,FH2O_PI_F,20120424,5.44,GA_OP-LI-COR LI-7500A,,SA-Gill Windmaster Pro,13-5 -US-Myb,FH2O_PI_F,,5.44,GA_OP-LI-COR LI-7500,,SA-Gill Windmaster Pro,13-5 -US-Myb,H,20120424,5.44,SA-Gill Windmaster,,,13-5 -US-Myb,H,,5.44,SA-Gill Windmaster Pro,,,13-5 -US-Myb,H2O,20120424,5.44,GA_OP-LI-COR LI-7500A,,,13-5 -US-Myb,H2O,,5.44,GA_OP-LI-COR LI-7500,,,13-5 -US-Myb,H_PI_F,20120424,5.44,SA-Gill Windmaster,,,13-5 -US-Myb,H_PI_F,,5.44,SA-Gill Windmaster Pro,,,13-5 -US-Myb,LE,20120424,5.44,GA_OP-LI-COR LI-7500A,SA-Gill Windmaster,,13-5 -US-Myb,LE,,5.44,GA_OP-LI-COR LI-7500,SA-Gill Windmaster Pro,,13-5 -US-Myb,LE_PI_F,20120424,5.44,GA_OP-LI-COR LI-7500A,SA-Gill Windmaster,,13-5 -US-Myb,LE_PI_F,,5.44,GA_OP-LI-COR LI-7500,SA-Gill Windmaster Pro,,13-5 -US-Myb,NETRAD,,,RAD-Net radiometer,,,13-5 -US-Myb,P,,,RAIN-TipBucGauge,,,13-5 -US-Myb,PA,,,PRES-ElectBar,,,13-5 -US-Myb,PPFD_IN,,,RAD-PAR Quantum,,,13-5 -US-Myb,PPFD_OUT,,,RAD-PAR Quantum,,,13-5 -US-Myb,RH,,,RH-Capac,,,13-5 -US-Myb,TA,,,TEMP-ElectResis,,,13-5 -US-Myb,TAU,20120424,5.44,SA-Gill Windmaster,,,13-5 -US-Myb,TAU,,5.44,SA-Gill Windmaster Pro,,,13-5 -US-Myb,TS_1_1_1,,-0.08,TEMP-TCouple,,,13-5 -US-Myb,TS_1_2_1,,-0.16,TEMP-TCouple,,,13-5 -US-Myb,TS_1_3_1,,-0.32,TEMP-TCouple,,,13-5 -US-Myb,USTAR,20120424,5.44,SA-Gill Windmaster,,,13-5 -US-Myb,USTAR,,5.44,SA-Gill Windmaster Pro,,,13-5 -US-Myb,VPD_PI,,,RH-Capac,,Temp-ElectResis,13-5 -US-Myb,V_SIGMA,20120424,5.44,SA-Gill Windmaster,,,13-5 -US-Myb,V_SIGMA,,5.44,SA-Gill Windmaster Pro,,,13-5 -US-Myb,WD,20120424,5.44,SA-Gill Windmaster,,,13-5 -US-Myb,WD,,5.44,SA-Gill Windmaster Pro,,,13-5 -US-Myb,WS,20120424,5.44,SA-Gill Windmaster,,,13-5 -US-Myb,WS,,5.44,SA-Gill Windmaster Pro,,,13-5 -US-Myb,W_SIGMA,20120424,5.44,SA-Gill Windmaster,,,13-5 -US-Myb,W_SIGMA,,5.44,SA-Gill Windmaster Pro,,,13-5 -US-Myb,WTD,,,WTD-Press,,,13-5 -US-NC1,CO2,20080701,10.5,GA_OP-LI-COR LI-7500,,new tower; elevated instruments,3-5 -US-NC1,CO2,,6,GA_OP-LI-COR LI-7500,,,3-5 -US-NC1,FC,20080701,10.5,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,3-5 -US-NC1,FC,,6,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,3-5 -US-NC1,FC_DF,,,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,3-5 -US-NC1,FH2O,20080701,10.5,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,3-5 -US-NC1,FH2O,,6,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,3-5 -US-NC1,G,,-0.02,SOIL_H-Plate,,,3-5 -US-NC1,H,,6,SA-Campbell CSAT-3,,,3-5 -US-NC1,H2O,20080701,10.5,GA_OP-LI-COR LI-7500,,,3-5 -US-NC1,H2O,,6,GA_OP-LI-COR LI-7500,,,3-5 -US-NC1,LE,20080701,10.5,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,3-5 -US-NC1,LE,,6,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,3-5 -US-NC1,LW_IN,20080701,10.5,RAD-LW Pyrgeom,,,3-5 -US-NC1,LW_IN,,6,RAD-LW Pyrgeom,,,3-5 -US-NC1,LW_OUT,20080701,10.5,RAD-LW Pyrgeom,,,3-5 -US-NC1,LW_OUT,,6,RAD-LW Pyrgeom,,,3-5 -US-NC1,NEE_PI,20080701,10.5,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,3-5 -US-NC1,NEE_PI,,6,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,3-5 -US-NC1,NETRAD,20080701,10.5,RAD-Net radiometer,,,3-5 -US-NC1,NETRAD,,6,RAD-Net radiometer,,,3-5 -US-NC1,P,20080701,10.5,RAIN-TipBucGauge,,,3-5 -US-NC1,P,,6,PREC-TipBucGauge,,,3-5 -US-NC1,PA,20080701,10.5,GA_OP-LI-COR LI-7500,,,3-5 -US-NC1,PA,,6,GA_OP-LI-COR LI-7500,,,3-5 -US-NC1,P_CUM,20080701,10.5,RAIN-TipBucGauge,,,3-5 -US-NC1,P_CUM,,6,PREC-TipBucGauge,,,3-5 -US-NC1,PPFD_IN,20080701,10.5,RAD-PAR Quantum,,,3-5 -US-NC1,PPFD_IN,,6,RAD-PAR Quantum,,,3-5 -US-NC1,RH,20080701,10.5,RH-Capac,,,3-5 -US-NC1,RH,,1.8,RH-Capac,,,3-5 -US-NC1,SC,20080701,10.5,GA_OP-LI-COR LI-7500,,,3-5 -US-NC1,SC,,6,GA_OP-LI-COR LI-7500,,,3-5 -US-NC1,SWC,,-0.2,SWC-TDR,,,3-5 -US-NC1,SW_IN,20080701,10.5,RAD-SW Pyran Class2,,,3-5 -US-NC1,SW_IN,,6,RAD-SW Pyran Class2,,,3-5 -US-NC1,SW_OUT,20080701,10.5,RAD-SW Pyran Class2,,,3-5 -US-NC1,SW_OUT,,6,RAD-SW Pyran Class2,,,3-5 -US-NC1,TA,20080701,10.5,TEMP-ElectResis,,,3-5 -US-NC1,TA,,1.8,TEMP-ElectResis,,,3-5 -US-NC1,TS_1_1_1,,-0.05,TEMP-Thermis,,,3-5 -US-NC1,TS_1_2_1,,-0.2,TEMP-Thermis,,,3-5 -US-NC1,USTAR,20080701,10.5,SA-Campbell CSAT-3,,,3-5 -US-NC1,USTAR,,2,SA-Campbell CSAT-3,,,3-5 -US-NC1,VPD_PI,20080701,10.5,RH-Capac,,,3-5 -US-NC1,VPD_PI,,1.8,RH-Capac,,,3-5 -US-NC1,WD,20080701,10.5,SA-Campbell CSAT-3,,,3-5 -US-NC1,WD,,6,SA-Campbell CSAT-3,,,3-5 -US-NC1,WS,20080701,10.5,SA-Campbell CSAT-3,,,3-5 -US-NC1,WS,,6,SA-Campbell CSAT-3,,,3-5 -US-NC1,ZL,20080701,10.5,SA-Campbell CSAT-3,,,3-5 -US-NC1,ZL,,6,SA-Campbell CSAT-3,,,3-5 -US-NC2,CO2_1_1_1,20100520,25.6,GA_OP-LI-COR LI-7500,,The IRGA was raised to a higher point,10-5 -US-NC2,CO2_1_1_1,20120417,22.4,GA_OP-LI-COR LI-7500,,Unit resinstalled after tower was rebuilt,10-5 -US-NC2,CO2_1_1_1,20150312,22.4,GA_OP-LI-COR LI-7500A,,Upgraded unit returned to site,10-5 -US-NC2,CO2_1_1_1,20150514,27,GA_OP-LI-COR LI-7500A,,Unit borrowed from AmeriFlux while 75H-0755 was being repaired; Repaired unit returned to site and 75H-2399 removed on 20150618,10-5 -US-NC2,CO2_1_1_1,20201117,12.5,GA_OP-LI-COR LI-7500A,,Instruments lowered following harvest,10-5 -US-NC2,CO2_1_1_1,,22.5,GA_OP-LI-COR LI-7500,,Unit first installed at site,10-5 -US-NC2,CO2_2_2_1,20140730,14.6,GA_SR-LI-COR LI-820,,,10-5 -US-NC2,CO2_2_3_1,20140730,3.7,GA_SR-LI-COR LI-820,,,10-5 -US-NC2,CO2_2_4_1,20140730,0.9,GA_SR-LI-COR LI-820,,,10-5 -US-NC2,CO2_2_5_1,20140730,0.3,GA_SR-LI-COR LI-820,,,10-5 -US-NC2,FC_1_1_1,20100520,25.6,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,The IRGA and sonic were raised to a higher point,10-5 -US-NC2,FC_1_1_1,20120417,22.4,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,Unit resinstalled after tower was rebuilt,10-5 -US-NC2,FC_1_1_1,20150312,22.4,GA_OP-LI-COR LI-7500A,SA-Campbell CSAT-3,Upgraded IRGA returned to site,10-5 -US-NC2,FC_1_1_1,20150514,27,GA_OP-LI-COR LI-7500A,SA-Campbell CSAT-3,Instruments raised to higher point,10-5 -US-NC2,FC_1_1_1,20201117,12.5,GA_OP-LI-COR LI-7500A,SA-Campbell CSAT-3,Instruments lowered following harvest,10-5 -US-NC2,FC_1_1_1,,22.5,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,10-5 -US-NC2,G_1_1_1,,-0.02,SOIL_H-Plate,,,10-5 -US-NC2,G_1_1_2,,-0.02,SOIL_H-Plate,,,10-5 -US-NC2,G_1_1_3,,-0.02,SOIL_H-Plate,,,10-5 -US-NC2,H_1_1_1,20100520,25.6,SA-Campbell CSAT-3,,instruments raised due to tree growth,10-5 -US-NC2,H_1_1_1,20120417,22.4,SA-Campbell CSAT-3,,Unit reinstalled after tower was rebuilt,10-5 -US-NC2,H_1_1_1,20150514,27,SA-Campbell CSAT-3,,instruments raised due to tree growth,10-5 -US-NC2,H_1_1_1,20201117,12.5,SA-Campbell CSAT-3,,instruments lowered following harvest,10-5 -US-NC2,H_1_1_1,,22.5,SA-Campbell CSAT-3,,,10-5 -US-NC2,H2O_1_1_1,20100520,25.6,GA_OP-LI-COR LI-7500,,The IRGA was raised to a higher point,10-5 -US-NC2,H2O_1_1_1,20120417,22.4,GA_OP-LI-COR LI-7500,,Unit resinstalled after tower was rebuilt,10-5 -US-NC2,H2O_1_1_1,20150312,22.4,GA_OP-LI-COR LI-7500A,,Upgraded unit returned to site,10-5 -US-NC2,H2O_1_1_1,20150514,27,GA_OP-LI-COR LI-7500A,,Unit borrowed from AmeriFlux while 75H-0755 was being repaired; Repaired unit returned to site and 75H-2399 removed on 20150618,10-5 -US-NC2,H2O_1_1_1,20201117,12.5,GA_OP-LI-COR LI-7500A,,Instruments lowered following harvest,10-5 -US-NC2,H2O_1_1_1,,22.5,GA_OP-LI-COR LI-7500,,Unit first installed at site,10-5 -US-NC2,LE_1_1_1,20100520,25.6,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,The IRGA and sonic were raised to a higher point,10-5 -US-NC2,LE_1_1_1,20120417,22.4,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,Unit resinstalled after tower was rebuilt,10-5 -US-NC2,LE_1_1_1,20150312,22.4,GA_OP-LI-COR LI-7500A,SA-Campbell CSAT-3,Upgraded IRGA returned to site,10-5 -US-NC2,LE_1_1_1,20150514,27,GA_OP-LI-COR LI-7500A,SA-Campbell CSAT-3,Instruments raised to higher point,10-5 -US-NC2,LE_1_1_1,20201117,12.5,GA_OP-LI-COR LI-7500A,SA-Campbell CSAT-3,Instruments lowered following harvest,10-5 -US-NC2,LE_1_1_1,,22.5,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,10-5 -US-NC2,LW_IN_1_1_1,20120417,26.9,RAD-Pyrrad-SW+LW,,Unit reinstalled after the tower was rebuilt,10-5 -US-NC2,LW_IN_1_1_1,,22.9,RAD-Pyrrad-SW+LW,,,10-5 -US-NC2,LW_OUT_1_1_1,20120417,26.9,RAD-Pyrrad-SW+LW,,Unit reinstalled after the tower was rebuilt,10-5 -US-NC2,LW_OUT_1_1_1,,22.9,RAD-Pyrrad-SW+LW,,,10-5 -US-NC2,MO_LENGTH_1_1_1,20100520,25.6,SA-Campbell CSAT-3,,The Sonic was raised to a higher point,10-5 -US-NC2,MO_LENGTH_1_1_1,20120417,22.4,SA-Campbell CSAT-3,,Sonic resinstalled after tower was rebuilt,10-5 -US-NC2,MO_LENGTH_1_1_1,20150514,27,SA-Campbell CSAT-3,,The Sonic was raised to a higher point,10-5 -US-NC2,MO_LENGTH_1_1_1,20201117,12.5,SA-Campbell CSAT-3,,Instruments lowered following harvest,10-5 -US-NC2,MO_LENGTH_1_1_1,,22.5,SA-Campbell CSAT-3,,,10-5 -US-NC2,NEE_PI_1_1_1,20100520,25.6,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,The IRGA and sonic were raised to a higher point,10-5 -US-NC2,NEE_PI_1_1_1,20120417,22.4,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,Unit resinstalled after tower was rebuilt,10-5 -US-NC2,NEE_PI_1_1_1,20150312,22.4,GA_OP-LI-COR LI-7500A,SA-Campbell CSAT-3,Upgraded IRGA returned to site,10-5 -US-NC2,NEE_PI_1_1_1,20150514,27,GA_OP-LI-COR LI-7500A,SA-Campbell CSAT-3,Instruments raised to higher point,10-5 -US-NC2,NEE_PI_1_1_1,20201117,12.5,GA_OP-LI-COR LI-7500A,SA-Campbell CSAT-3,Instruments lowered following harvest,10-5 -US-NC2,NEE_PI_1_1_1,,22.5,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,10-5 -US-NC2,NETRAD_1_1_1,20120417,26.9,RAD-Pyrrad-SW+LW,,Unit reinstalled after the tower was rebuilt,10-5 -US-NC2,NETRAD_1_1_1,,22.9,RAD-Pyrrad-SW+LW,,,10-5 -US-NC2,P_1_1_1,20120308,25.5,RAIN-TipBucGauge,,TE525mm,10-5 -US-NC2,P_1_1_1,,20,RAIN-TipBucGauge,,TE525mm,10-5 -US-NC2,PA_1_1_1,20100520,25.6,GA_OP-LI-COR LI-7500,,The IRGA was raised to a higher point,10-5 -US-NC2,PA_1_1_1,20120417,22.4,GA_OP-LI-COR LI-7500,,Unit resinstalled after tower was rebuilt,10-5 -US-NC2,PA_1_1_1,20150312,22.4,GA_OP-LI-COR LI-7500A,,Upgraded unit returned to site,10-5 -US-NC2,PA_1_1_1,20150514,27,GA_OP-LI-COR LI-7500A,,Unit borrowed from AmeriFlux while 75H-0755 was being repaired; Repaired unit returned to site and 75H-2399 removed on 20150618,10-5 -US-NC2,PA_1_1_1,20201117,12.5,GA_OP-LI-COR LI-7500A,,Instruments lowered following harvest,10-5 -US-NC2,PA_1_1_1,,22.5,GA_OP-LI-COR LI-7500,,Unit first installed at site,10-5 -US-NC2,PPFD_IN_1_1_1,20100708,22.4,RAD-PAR Quantum,,Replaced li-190. Model = Kipp and Zonen par lite,10-5 -US-NC2,PPFD_IN_1_1_1,20120308,23,RAD-PAR Quantum,,moved to new height,10-5 -US-NC2,PPFD_IN_1_1_1,,22.4,RAD-PAR Quantum,,Unit first installed. Model was li-190,10-5 -US-NC2,RH_1_1_1,20120329,23,RH-Capac,,,10-5 -US-NC2,RH_1_1_1,,18.5,RH-Capac,,,10-5 -US-NC2,SC_1_1_1,20100520,25.6,GA_OP-LI-COR LI-7500A,,,10-5 -US-NC2,SC_1_1_1,20120417,22.4,GA_OP-LI-COR LI-7500A,,,10-5 -US-NC2,SC_1_1_1,20150514,27,GA_OP-LI-COR LI-7500A,,,10-5 -US-NC2,SC_1_1_1,20201117,12.5,GA_OP-LI-COR LI-7500A,,,10-5 -US-NC2,SC_1_1_1,,22.5,GA_OP-LI-COR LI-7500A,,,10-5 -US-NC2,SC_1_1_2,20140715,4.3,GA_SR-LI-COR LI-820,,level-specific concentration measurements at 0.3; 0.9; 3.7 and 12.5m,10-5 -US-NC2,SC_1_1_2,20191023,12.5,GA_SR-LI-COR LI-820,,CO2 profile system removed,10-5 -US-NC2,SC_1_1_2,,4.3,GA_SR-LI-COR LI-820,,canopy-average concentration from mixed profile measurements (sampling levels of equal tube length at 0.3; 0.9; 3.7 and 12.5m),10-5 -US-NC2,SWC_1_1_1,,-0.3,SWC-TDR,,,10-5 -US-NC2,SW_IN_1_1_1,20120417,26.9,RAD-Pyrrad-SW+LW,,Unit reinstalled after the tower was rebuilt,10-5 -US-NC2,SW_IN_1_1_1,,22.9,RAD-Pyrrad-SW+LW,,,10-5 -US-NC2,SW_OUT_1_1_1,20120417,26.9,RAD-Pyrrad-SW+LW,,Unit reinstalled after the tower was rebuilt,10-5 -US-NC2,SW_OUT_1_1_1,,22.9,RAD-Pyrrad-SW+LW,,,10-5 -US-NC2,TA_1_1_1,20120329,23,TEMP-ElectResis,,,10-5 -US-NC2,TA_1_1_1,,18.5,TEMP-ElectResis,,,10-5 -US-NC2,TAU_1_1_1,20100520,25.6,SA-Campbell CSAT-3,,The Sonic was raised to a higher point,10-5 -US-NC2,TAU_1_1_1,20120417,22.4,SA-Campbell CSAT-3,,Sonic resinstalled after tower was rebuilt,10-5 -US-NC2,TAU_1_1_1,20150514,27,SA-Campbell CSAT-3,,The Sonic was raised to a higher point,10-5 -US-NC2,TAU_1_1_1,20201117,12.5,SA-Campbell CSAT-3,,Instruments lowered following harvest,10-5 -US-NC2,TAU_1_1_1,,22.5,SA-Campbell CSAT-3,,,10-5 -US-NC2,TS_1_1_1,,-0.05,TEMP-Thermis,,,10-5 -US-NC2,TS_1_2_1,20120223,-0.1,TEMP-Thermis,,,10-5 -US-NC2,TS_1_2_1,,-0.2,TEMP-Thermis,,,10-5 -US-NC2,T_SONIC_1_1_1,20100520,25.6,SA-Campbell CSAT-3,,The Sonic was raised to a higher point,10-5 -US-NC2,T_SONIC_1_1_1,20120417,22.4,SA-Campbell CSAT-3,,Sonic resinstalled after tower was rebuilt,10-5 -US-NC2,T_SONIC_1_1_1,20150514,27,SA-Campbell CSAT-3,,The Sonic was raised to a higher point,10-5 -US-NC2,T_SONIC_1_1_1,20201117,12.5,SA-Campbell CSAT-3,,Instruments lowered following harvest,10-5 -US-NC2,T_SONIC_1_1_1,,22.5,SA-Campbell CSAT-3,,,10-5 -US-NC2,U_SIGMA_1_1_1,20100520,25.6,SA-Campbell CSAT-3,,The Sonic was raised to a higher point,10-5 -US-NC2,U_SIGMA_1_1_1,20120417,22.4,SA-Campbell CSAT-3,,Sonic resinstalled after tower was rebuilt,10-5 -US-NC2,U_SIGMA_1_1_1,20150514,27,SA-Campbell CSAT-3,,The Sonic was raised to a higher point,10-5 -US-NC2,U_SIGMA_1_1_1,20201117,12.5,SA-Campbell CSAT-3,,Instruments lowered following harvest,10-5 -US-NC2,U_SIGMA_1_1_1,,22.5,SA-Campbell CSAT-3,,,10-5 -US-NC2,USTAR_1_1_1,20100520,25.6,SA-Campbell CSAT-3,,The Sonic was raised to a higher point,10-5 -US-NC2,USTAR_1_1_1,20120417,22.4,SA-Campbell CSAT-3,,Sonic resinstalled after tower was rebuilt,10-5 -US-NC2,USTAR_1_1_1,20150514,27,SA-Campbell CSAT-3,,The Sonic was raised to a higher point,10-5 -US-NC2,USTAR_1_1_1,20201117,12.5,SA-Campbell CSAT-3,,Instruments lowered following harvest,10-5 -US-NC2,USTAR_1_1_1,,22.5,SA-Campbell CSAT-3,,,10-5 -US-NC2,VPD_PI_1_1_1,20120329,23,RH-Capac,,,10-5 -US-NC2,VPD_PI_1_1_1,,18.5,RH-Capac,,,10-5 -US-NC2,V_SIGMA_1_1_1,20100520,25.6,SA-Campbell CSAT-3,,The Sonic was raised to a higher point,10-5 -US-NC2,V_SIGMA_1_1_1,20120417,22.4,SA-Campbell CSAT-3,,Sonic resinstalled after tower was rebuilt,10-5 -US-NC2,V_SIGMA_1_1_1,20150514,27,SA-Campbell CSAT-3,,The Sonic was raised to a higher point,10-5 -US-NC2,V_SIGMA_1_1_1,20201117,12.5,SA-Campbell CSAT-3,,Instruments lowered following harvest,10-5 -US-NC2,V_SIGMA_1_1_1,,22.5,SA-Campbell CSAT-3,,,10-5 -US-NC2,WD_1_1_1,20100520,25.6,SA-Campbell CSAT-3,,The Sonic was raised to a higher point,10-5 -US-NC2,WD_1_1_1,20120417,22.4,SA-Campbell CSAT-3,,Sonic resinstalled after tower was rebuilt,10-5 -US-NC2,WD_1_1_1,20150514,27,SA-Campbell CSAT-3,,The Sonic was raised to a higher point,10-5 -US-NC2,WD_1_1_1,20201117,12.5,SA-Campbell CSAT-3,,Instruments lowered following harvest,10-5 -US-NC2,WD_1_1_1,,22.5,SA-Campbell CSAT-3,,,10-5 -US-NC2,WS_1_1_1,20100520,25.6,SA-Campbell CSAT-3,,The Sonic was raised to a higher point,10-5 -US-NC2,WS_1_1_1,20120417,22.4,SA-Campbell CSAT-3,,Sonic resinstalled after tower was rebuilt,10-5 -US-NC2,WS_1_1_1,20150514,27,SA-Campbell CSAT-3,,The Sonic was raised to a higher point,10-5 -US-NC2,WS_1_1_1,20201117,12.5,SA-Campbell CSAT-3,,Instruments lowered following harvest,10-5 -US-NC2,WS_1_1_1,,22.5,SA-Campbell CSAT-3,,,10-5 -US-NC2,W_SIGMA_1_1_1,20100520,25.6,SA-Campbell CSAT-3,,The Sonic was raised to a higher point,10-5 -US-NC2,W_SIGMA_1_1_1,20120417,22.4,SA-Campbell CSAT-3,,Sonic resinstalled after tower was rebuilt,10-5 -US-NC2,W_SIGMA_1_1_1,20150514,27,SA-Campbell CSAT-3,,The Sonic was raised to a higher point,10-5 -US-NC2,W_SIGMA_1_1_1,20201117,12.5,SA-Campbell CSAT-3,,Instruments lowered following harvest,10-5 -US-NC2,W_SIGMA_1_1_1,,22.5,SA-Campbell CSAT-3,,,10-5 -US-NC2,WS_MAX_1_1_1,20100520,25.6,SA-Campbell CSAT-3,,The Sonic was raised to a higher point,10-5 -US-NC2,WS_MAX_1_1_1,20120417,22.4,SA-Campbell CSAT-3,,Sonic resinstalled after tower was rebuilt,10-5 -US-NC2,WS_MAX_1_1_1,20150514,27,SA-Campbell CSAT-3,,The Sonic was raised to a higher point,10-5 -US-NC2,WS_MAX_1_1_1,20201117,12.5,SA-Campbell CSAT-3,,Instruments lowered following harvest,10-5 -US-NC2,WS_MAX_1_1_1,,22.5,SA-Campbell CSAT-3,,,10-5 -US-NC2,ZL_1_1_1,20100520,25.6,SA-Campbell CSAT-3,,The Sonic was raised to a higher point,10-5 -US-NC2,ZL_1_1_1,20120417,22.4,SA-Campbell CSAT-3,,Sonic resinstalled after tower was rebuilt,10-5 -US-NC2,ZL_1_1_1,20150514,27,SA-Campbell CSAT-3,,The Sonic was raised to a higher point,10-5 -US-NC2,ZL_1_1_1,20201117,12.5,SA-Campbell CSAT-3,,Instruments lowered following harvest,10-5 -US-NC2,ZL_1_1_1,,22.5,SA-Campbell CSAT-3,,,10-5 -US-NC3,CH4,20160727,6.44,GA_OP-LI-COR LI-7700,,,4-5 -US-NC3,CH4,20170510,9,GA_OP-LI-COR LI-7700,,,4-5 -US-NC3,CH4,20170810,0,GA_OP-LI-COR LI-7700,,CH4 measurements stopped,4-5 -US-NC3,CO2,20130201,3.5,GA_OP-LI-COR LI-7500A,,,4-5 -US-NC3,CO2,20160405,6.55,GA_OP-LI-COR LI-7500A,,,4-5 -US-NC3,CO2,20170510,9,GA_OP-LI-COR LI-7500A,,,4-5 -US-NC3,CO2_MIXING_RATIO,20130201,3.5,GA_OP-LI-COR LI-7500A,,,4-5 -US-NC3,CO2_MIXING_RATIO,20160405,6.55,GA_OP-LI-COR LI-7500A,,,4-5 -US-NC3,CO2_MIXING_RATIO,20170510,9,GA_OP-LI-COR LI-7500A,,,4-5 -US-NC3,FC,20130201,3.5,GA_OP-LI-COR LI-7500A,SA-Campbell CSAT-3,,4-5 -US-NC3,FC,20160405,6.55,GA_OP-LI-COR LI-7500A,SA-Campbell CSAT-3,,4-5 -US-NC3,FC,20170510,9,GA_OP-LI-COR LI-7500A,SA-Campbell CSAT-3,,4-5 -US-NC3,FCH4,20160727,6.55,GA_OP-LI-COR LI-7700,SA-Campbell CSAT-3,,4-5 -US-NC3,FETCH_90,20130201,,SA-Campbell CSAT-3,,,4-5 -US-NC3,G,20130201,-0.02,SOIL_H-Plate,,,4-5 -US-NC3,H2O,20130201,3.5,GA_OP-LI-COR LI-7500A,,,4-5 -US-NC3,H2O,20160405,6.55,GA_OP-LI-COR LI-7500A,,,4-5 -US-NC3,H2O,20170510,9,GA_OP-LI-COR LI-7500A,,,4-5 -US-NC3,LE,20130201,3.5,GA_OP-LI-COR LI-7500A,SA-Campbell CSAT-3,,4-5 -US-NC3,LE,20160405,6.55,GA_OP-LI-COR LI-7500A,SA-Campbell CSAT-3,,4-5 -US-NC3,LE,20170510,9,GA_OP-LI-COR LI-7500A,SA-Campbell CSAT-3,,4-5 -US-NC3,LW_IN,20130201,3.75,RAD-LW Pyrgeom,,,4-5 -US-NC3,LW_IN,20160405,11.15,RAD-LW Pyrgeom,,,4-5 -US-NC3,LW_OUT,20130201,3.75,RAD-LW Pyrgeom,,,4-5 -US-NC3,LW_OUT,20160405,11.15,RAD-LW Pyrgeom,,,4-5 -US-NC3,NEE_PI,20130201,3.5,GA_OP-LI-COR LI-7500A,SA-Campbell CSAT-3,,4-5 -US-NC3,NEE_PI,20160405,6.55,GA_OP-LI-COR LI-7500A,SA-Campbell CSAT-3,,4-5 -US-NC3,NEE_PI,20170510,9,GA_OP-LI-COR LI-7500A,SA-Campbell CSAT-3,,4-5 -US-NC3,NETRAD,20130201,3.75,RAD-Pyrrad-SW+LW,,,4-5 -US-NC3,NETRAD,20160405,11.15,RAD-Pyrrad-SW+LW,,,4-5 -US-NC3,P,20130201,4.6,PREC-TipBucGauge,,,4-5 -US-NC3,P,20160405,11.35,PREC-TipBucGauge,,,4-5 -US-NC3,PA,20130201,3.5,GA_OP-LI-COR LI-7500A,,,4-5 -US-NC3,PA,20160405,6.55,GA_OP-LI-COR LI-7500A,,,4-5 -US-NC3,PPFD_DIR,20130201,3.75,RAD-PAR 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-US-Ne1,RECO_PI_F_1_1_1,20010525,3.0,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne1,RECO_PI_F_1_1_1,200106280700,6.2,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne1,RECO_PI_F_1_1_1,200110181000,3.0,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne1,RECO_PI_F_1_1_1,200207011100,6.2,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne1,RECO_PI_F_1_1_1,200211061300,3.0,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne1,RECO_PI_F_1_1_1,200307071000,6.2,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne1,RECO_PI_F_1_1_1,200310281200,3.0,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne1,RECO_PI_F_1_1_1,200407011400,6.2,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne1,RECO_PI_F_1_1_1,200410180900,3.0,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne1,RECO_PI_F_1_1_1,200506231800,6.2,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne1,RECO_PI_F_1_1_1,200510131300,3.0,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne1,RECO_PI_F_1_1_1,200606281900,6.2,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne1,RECO_PI_F_1_1_1,200610062100,3.0,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne1,RECO_PI_F_1_1_1,200706201300,6.2,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne1,RECO_PI_F_1_1_1,200711191000,3.0,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne1,RECO_PI_F_1_1_1,200806201000,6.2,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne1,RECO_PI_F_1_1_1,200811171300,3.0,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne1,RECO_PI_F_1_1_1,200906190900,6.2,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne1,RECO_PI_F_1_1_1,200911101600,3.0,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne1,RECO_PI_F_1_1_1,201006181200,6.2,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne1,RECO_PI_F_1_1_1,201009221100,3.0,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne1,RECO_PI_F_1_1_1,201107071200,6.2,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne1,RECO_PI_F_1_1_1,201110261100,3.0,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne1,RECO_PI_F_1_1_1,201206180800,6.2,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne1,RECO_PI_F_1_1_1,201210101300,3.0,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne1,RECO_PI_F_1_1_1,201306250700,6.2,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne1,RECO_PI_F_1_1_1,201310240900,3.0,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne1,RECO_PI_F_1_1_1,201407011000,6.2,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne1,RECO_PI_F_1_1_1,201410240900,3.0,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne1,RECO_PI_F_1_1_1,201505271600,3.0,GA_CP-LI-COR LI-7200,SA-Gill R3-100,,12-5 -US-Ne1,RECO_PI_F_1_1_1,201506251400,6.2,GA_CP-LI-COR LI-7200,SA-Gill R3-100,,12-5 -US-Ne1,RECO_PI_F_1_1_1,201510261500,3.0,GA_CP-LI-COR LI-7200,SA-Gill R3-100,,12-5 -US-Ne1,RECO_PI_F_1_1_1,201606290900,6.2,GA_CP-LI-COR LI-7200,SA-Gill R3-100,,12-5 -US-Ne1,RECO_PI_F_1_1_1,201609231200,3.0,GA_CP-LI-COR LI-7200,SA-Gill R3-100,,12-5 -US-Ne1,RECO_PI_F_1_1_1,201706201200,6.2,GA_CP-LI-COR LI-7200,SA-Gill R3-100,,12-5 -US-Ne1,RECO_PI_F_1_1_1,201710261200,3.0,GA_CP-LI-COR LI-7200,SA-Gill R3-100,,12-5 -US-Ne1,RECO_PI_F_1_1_1,201806181200,6.2,GA_CP-LI-COR LI-7200,SA-Gill R3-100,,12-5 -US-Ne1,RECO_PI_F_1_1_1,201810311200,3.0,GA_CP-LI-COR LI-7200,SA-Gill R3-100,,12-5 -US-Ne1,RECO_PI_F_1_1_1,201906271000,6.2,GA_CP-LI-COR LI-7200,SA-Gill R3-100,,12-5 -US-Ne1,RECO_PI_F_1_1_1,201911041300,3.0,GA_CP-LI-COR LI-7200,SA-Gill R3-100,,12-5 -US-Ne1,RECO_PI_F_1_1_1,202006230900,6.2,GA_CP-LI-COR LI-7200,SA-Gill R3-100,,12-5 -US-Ne1,RECO_PI_F_1_1_1,202009161300,3.0,GA_CP-LI-COR LI-7200,SA-Gill R3-100,,12-5 -US-Ne1,RECO_PI_F_1_1_1,202106231300,6.2,GA_CP-LI-COR LI-7200,SA-Gill R3-100,,12-5 -US-Ne1,RECO_PI_F_1_1_1,202110201200,3,GA_CP-LI-COR LI-7200,SA-Gill R3-100,,12-5 -US-Ne1,RH_1_1_1,20010525,5.5,RH-Capac,,,12-5 -US-Ne1,RH_1_2_1,20010525,3.0,RH-Capac,,,12-5 -US-Ne1,RH_1_3_1,20010525,1.0,RH-Capac,,,12-5 -US-Ne1,RH_1_4_1,20010525,0.1,RH-Capac,,,12-5 -US-Ne1,RH_PI_F_1_1_1,20010525,5.5,RH-Capac,,,12-5 -US-Ne1,RH_PI_F_1_2_1,20010525,3.0,RH-Capac,,,12-5 -US-Ne1,RH_PI_F_1_3_1,20010525,1.0,RH-Capac,,,12-5 -US-Ne1,RH_PI_F_1_4_1,20010525,0.1,RH-Capac,,,12-5 -US-Ne1,SC_1_1_1,20010525,3.0,GA_CP-LI-COR LI-6262,,Storage term include profile CO2 conc measured at EC height and below,12-5 -US-Ne1,SC_1_1_1,20150625,3.0,GA_CP-Other,,Storage term include profile CO2 conc measured at EC height and below,12-5 -US-Ne1,SC_PI_F_1_1_1,20010525,3.0,GA_CP-LI-COR LI-6262,,Storage term include profile CO2 conc measured at EC height and below,12-5 -US-Ne1,SC_PI_F_1_1_1,20150625,3.0,GA_CP-Other,,Storage term include profile CO2 conc measured at EC height and below,12-5 -US-Ne1,SWC_1_1_1,20010612,-0.1,SWC-TDR,,,12-5 -US-Ne1,SWC_1_2_1,20010612,-0.25,SWC-TDR,,,12-5 -US-Ne1,SWC_1_3_1,20010612,-0.5,SWC-TDR,,,12-5 -US-Ne1,SWC_1_4_1,20010612,-1.0,SWC-TDR,,,12-5 -US-Ne1,SWC_1_N,20010618,-0.1,SWC-TDR,,Number of stations (3) in spatial average at 0.1m depth,12-5 -US-Ne1,SWC_1_SD,20010618,-0.1,SWC-TDR,,Standard deviation of hourly SWC at 0.1m depth across 3 stations,12-5 -US-Ne1,SWC_2_1_1,20010612,-0.1,SWC-TDR,,,12-5 -US-Ne1,SWC_2_2_1,20010612,-0.25,SWC-TDR,,,12-5 -US-Ne1,SWC_2_3_1,20010612,-0.5,SWC-TDR,,,12-5 -US-Ne1,SWC_2_4_1,20010612,-1.0,SWC-TDR,,,12-5 -US-Ne1,SWC_2_N,20010618,-0.25,SWC-TDR,,Number of stations (3) in spatial average at 0.25m depth,12-5 -US-Ne1,SWC_2_SD,20010618,-0.25,SWC-TDR,,Standard deviation of hourly SWC at 0.25m depth across 3 stations,12-5 -US-Ne1,SWC_3_1_1,20010612,-0.1,SWC-TDR,,,12-5 -US-Ne1,SWC_3_2_1,20010612,-0.25,SWC-TDR,,,12-5 -US-Ne1,SWC_3_3_1,20010612,-0.5,SWC-TDR,,,12-5 -US-Ne1,SWC_3_4_1,20010612,-1.0,SWC-TDR,,,12-5 -US-Ne1,SWC_3_N,20010618,-0.5,SWC-TDR,,Number of stations (3) in spatial average of 0.5m depth,12-5 -US-Ne1,SWC_3_SD,20010618,-0.5,SWC-TDR,,Standard deviation of hourly SWC at 0.5m depth across 3 stations,12-5 -US-Ne1,SWC_4_N,20010618,-1,SWC-TDR,,Number of stations (3) in spatial average of 1.0m depth,12-5 -US-Ne1,SWC_4_SD,20010618,-1,SWC-TDR,,Standard deviation of hourly SWC at 1.0m depth across 3 stations,12-5 -US-Ne1,SWC_PI_F_1,20010618,-0.1,SWC-TDR,,Daily average SWC at 0.1m depth across 3 stations,12-5 -US-Ne1,SWC_PI_F_1_1_1,20010612,-0.1,SWC-TDR,,,12-5 -US-Ne1,SWC_PI_F_1_2_1,20010612,-0.25,SWC-TDR,,,12-5 -US-Ne1,SWC_PI_F_1_3_1,20010612,-0.5,SWC-TDR,,,12-5 -US-Ne1,SWC_PI_F_1_4_1,20010612,-1.0,SWC-TDR,,,12-5 -US-Ne1,SWC_PI_F_2,20010618,-0.25,SWC-TDR,,Daily average SWC at 0.25m depth across 3 stations,12-5 -US-Ne1,SWC_PI_F_2_1_1,20010612,-0.1,SWC-TDR,,,12-5 -US-Ne1,SWC_PI_F_2_2_1,20010612,-0.25,SWC-TDR,,,12-5 -US-Ne1,SWC_PI_F_2_3_1,20010612,-0.5,SWC-TDR,,,12-5 -US-Ne1,SWC_PI_F_2_4_1,20010612,-1.0,SWC-TDR,,,12-5 -US-Ne1,SWC_PI_F_3,20010618,-0.5,SWC-TDR,,Daily average SWC at 0.5m depth across 3 stations,12-5 -US-Ne1,SWC_PI_F_3_1_1,20010612,-0.1,SWC-TDR,,,12-5 -US-Ne1,SWC_PI_F_3_2_1,20010612,-0.25,SWC-TDR,,,12-5 -US-Ne1,SWC_PI_F_3_3_1,20010612,-0.5,SWC-TDR,,,12-5 -US-Ne1,SWC_PI_F_3_4_1,20010612,-1.0,SWC-TDR,,,12-5 -US-Ne1,SWC_PI_F_4,20010618,-1.0,SWC-TDR,,Daily average SWC at 1.0m depth across 3 stations,12-5 -US-Ne1,SW_IN_1_1_1,20010621,5.2,RAD-Pyrrad-SW+LW,,,12-5 -US-Ne1,SW_IN_PI_F_1_1_1,20010525,5.2,RAD-Pyrrad-SW+LW,,,12-5 -US-Ne1,SW_OUT_1_1_1,20010621,5.2,RAD-Pyrrad-SW+LW,,,12-5 -US-Ne1,SW_OUT_PI_F_1_1_1,20010621,5.2,RAD-Pyrrad-SW+LW,,,12-5 -US-Ne1,TA_1_1_1,20010525,5.5,TEMP-ElectResis,,,12-5 -US-Ne1,TA_1_2_1,20010525,3.0,TEMP-ElectResis,,,12-5 -US-Ne1,TA_1_3_1,20010525,1.0,TEMP-ElectResis,,,12-5 -US-Ne1,TA_1_4_1,20010525,0.1,TEMP-ElectResis,,,12-5 -US-Ne1,TA_PI_F_1_1_1,20010525,5.5,TEMP-ElectResis,,,12-5 -US-Ne1,TA_PI_F_1_2_1,20010525,3.0,TEMP-ElectResis,,,12-5 -US-Ne1,TA_PI_F_1_3_1,20010525,1.0,TEMP-ElectResis,,,12-5 -US-Ne1,TA_PI_F_1_4_1,20010525,0.1,TEMP-ElectResis,,,12-5 -US-Ne1,TS_1_1_1,20010606,-0.02,TEMP-Thermis,,In corn row,12-5 -US-Ne1,TS_1_2_1,20010606,-0.04,TEMP-Thermis,,In corn row,12-5 -US-Ne1,TS_1_3_1,20010606,-0.06,TEMP-Thermis,,In corn row,12-5 -US-Ne1,TS_1_4_1,20010606,-0.10,TEMP-Thermis,,In corn row,12-5 -US-Ne1,TS_2_1_1,20010606,-0.02,TEMP-Thermis,,Between corn row,12-5 -US-Ne1,TS_2_2_1,20010606,-0.04,TEMP-Thermis,,Between corn row,12-5 -US-Ne1,TS_2_3_1,20010606,-0.06,TEMP-Thermis,,Between corn row,12-5 -US-Ne1,TS_2_4_1,20010606,-0.10,TEMP-Thermis,,Between corn row,12-5 -US-Ne1,TS_2_5_1,20010606,-0.20,TEMP-Thermis,,Soil temperature sensor at 0.2m - removed May 2015,12-5 -US-Ne1,TS_2_6_1,20150527,-0.25,TEMP-Thermis,,Soil temperature sensor at 0.25m - installed May 2015,12-5 -US-Ne1,TS_2_7_1,20010606,-0.30,TEMP-Thermis,,Soil temperature sensor at 0.3m - removed May 2015,12-5 -US-Ne1,TS_2_8_1,20010606,-0.50,TEMP-Thermis,,,12-5 -US-Ne1,TS_PI_F_1_1_1,20010606,-0.02,TEMP-Thermis,,In corn row,12-5 -US-Ne1,TS_PI_F_1_2_1,20010606,-0.04,TEMP-Thermis,,In corn row,12-5 -US-Ne1,TS_PI_F_1_3_1,20010606,-0.06,TEMP-Thermis,,In corn row,12-5 -US-Ne1,TS_PI_F_1_4_1,20010606,-0.10,TEMP-Thermis,,In corn row,12-5 -US-Ne1,TS_PI_F_2_1_1,20010606,-0.02,TEMP-Thermis,,Between corn row,12-5 -US-Ne1,TS_PI_F_2_2_1,20010606,-0.04,TEMP-Thermis,,Between corn row,12-5 -US-Ne1,TS_PI_F_2_3_1,20010606,-0.06,TEMP-Thermis,,Between corn row,12-5 -US-Ne1,TS_PI_F_2_4_1,20010606,-0.10,TEMP-Thermis,,Between corn row,12-5 -US-Ne1,TS_PI_F_2_5_1,20010606,-0.20,TEMP-Thermis,,Soil temperature sensor at 0.2m - removed May 2015,12-5 -US-Ne1,TS_PI_F_2_6_1,20150527,-0.25,TEMP-Thermis,,Soil temperature sensor at 0.25m - installed May 2015,12-5 -US-Ne1,TS_PI_F_2_7_1,20010606,-0.30,TEMP-Thermis,,Soil temperature sensor at 0.3m - removed May 2015,12-5 -US-Ne1,TS_PI_F_2_8_1,20010606,-0.50,TEMP-Thermis,,,12-5 -US-Ne1,USTAR_1_1_1,20010525,3.0,SA-Gill R3-100,,,12-5 -US-Ne1,USTAR_1_1_1,200106280700,6.2,SA-Gill R3-100,,,12-5 -US-Ne1,USTAR_1_1_1,200110181000,3.0,SA-Gill R3-100,,,12-5 -US-Ne1,USTAR_1_1_1,200207011100,6.2,SA-Gill R3-100,,,12-5 -US-Ne1,USTAR_1_1_1,200211061300,3.0,SA-Gill R3-100,,,12-5 -US-Ne1,USTAR_1_1_1,200307071000,6.2,SA-Gill R3-100,,,12-5 -US-Ne1,USTAR_1_1_1,200310281200,3.0,SA-Gill R3-100,,,12-5 -US-Ne1,USTAR_1_1_1,200407011400,6.2,SA-Gill R3-100,,,12-5 -US-Ne1,USTAR_1_1_1,200410180900,3.0,SA-Gill R3-100,,,12-5 -US-Ne1,USTAR_1_1_1,200506231800,6.2,SA-Gill R3-100,,,12-5 -US-Ne1,USTAR_1_1_1,200510131300,3.0,SA-Gill R3-100,,,12-5 -US-Ne1,USTAR_1_1_1,200606281900,6.2,SA-Gill R3-100,,,12-5 -US-Ne1,USTAR_1_1_1,200610062100,3.0,SA-Gill R3-100,,,12-5 -US-Ne1,USTAR_1_1_1,200706201300,6.2,SA-Gill R3-100,,,12-5 -US-Ne1,USTAR_1_1_1,200711191000,3.0,SA-Gill R3-100,,,12-5 -US-Ne1,USTAR_1_1_1,200806201000,6.2,SA-Gill R3-100,,,12-5 -US-Ne1,USTAR_1_1_1,200811171300,3.0,SA-Gill R3-100,,,12-5 -US-Ne1,USTAR_1_1_1,200906190900,6.2,SA-Gill R3-100,,,12-5 -US-Ne1,USTAR_1_1_1,200911101600,3.0,SA-Gill R3-100,,,12-5 -US-Ne1,USTAR_1_1_1,201006181200,6.2,SA-Gill R3-100,,,12-5 -US-Ne1,USTAR_1_1_1,201009221100,3.0,SA-Gill R3-100,,,12-5 -US-Ne1,USTAR_1_1_1,201107071200,6.2,SA-Gill R3-100,,,12-5 -US-Ne1,USTAR_1_1_1,201110261100,3.0,SA-Gill R3-100,,,12-5 -US-Ne1,USTAR_1_1_1,201206180800,6.2,SA-Gill R3-100,,,12-5 -US-Ne1,USTAR_1_1_1,201210101300,3.0,SA-Gill R3-100,,,12-5 -US-Ne1,USTAR_1_1_1,201306250700,6.2,SA-Gill R3-100,,,12-5 -US-Ne1,USTAR_1_1_1,201310240900,3.0,SA-Gill R3-100,,,12-5 -US-Ne1,USTAR_1_1_1,201407011000,6.2,SA-Gill R3-100,,,12-5 -US-Ne1,USTAR_1_1_1,201410240900,3.0,SA-Gill R3-100,,,12-5 -US-Ne1,USTAR_1_1_1,201506251400,6.2,SA-Gill R3-100,,,12-5 -US-Ne1,USTAR_1_1_1,201510261500,3.0,SA-Gill R3-100,,,12-5 -US-Ne1,USTAR_1_1_1,201606290900,6.2,SA-Gill R3-100,,,12-5 -US-Ne1,USTAR_1_1_1,201609231200,3.0,SA-Gill R3-100,,,12-5 -US-Ne1,USTAR_1_1_1,201706201200,6.2,SA-Gill R3-100,,,12-5 -US-Ne1,USTAR_1_1_1,201710261200,3.0,SA-Gill R3-100,,,12-5 -US-Ne1,USTAR_1_1_1,201806181200,6.2,SA-Gill R3-100,,,12-5 -US-Ne1,USTAR_1_1_1,201810311200,3.0,SA-Gill R3-100,,,12-5 -US-Ne1,USTAR_1_1_1,201906271000,6.2,SA-Gill R3-100,,,12-5 -US-Ne1,USTAR_1_1_1,201911041300,3.0,SA-Gill R3-100,,,12-5 -US-Ne1,USTAR_1_1_1,202006230900,6.2,SA-Gill R3-100,,,12-5 -US-Ne1,USTAR_1_1_1,202009161300,3.0,SA-Gill R3-100,,,12-5 -US-Ne1,USTAR_1_1_1,202106231300,6.2,SA-Gill R3-100,,,12-5 -US-Ne1,USTAR_1_1_1,202110201200,3,SA-Gill R3-100,,,12-5 -US-Ne1,WD_1_1_1,20010525,5.5,WIND-VaneAn,,,12-5 -US-Ne1,WS_1_1_1,20010628,6.2,SA-Gill R3-100,,,12-5 -US-Ne1,WS_1_2_1,20010528,5.5,WIND-CupAn,,,12-5 -US-Ne1,WS_1_3_1,20010528,3.0,WIND-CupAn,,,12-5 -US-Ne1,WS_2_1_1,20010525,3.0,SA-Gill R3-100,,,12-5 -US-Ne1,ZL_1_1_1,20010525,3.0,SA-Gill R3-100,,Stability at eddy covariance height,12-5 -US-Ne1,ZL_1_1_1,200106280700,6.2,SA-Gill R3-100,,,12-5 -US-Ne1,ZL_1_1_1,200110181000,3.0,SA-Gill R3-100,,,12-5 -US-Ne1,ZL_1_1_1,200207011100,6.2,SA-Gill R3-100,,,12-5 -US-Ne1,ZL_1_1_1,200211061300,3.0,SA-Gill R3-100,,,12-5 -US-Ne1,ZL_1_1_1,200307071000,6.2,SA-Gill R3-100,,,12-5 -US-Ne1,ZL_1_1_1,200310281200,3.0,SA-Gill R3-100,,,12-5 -US-Ne1,ZL_1_1_1,200407011400,6.2,SA-Gill R3-100,,,12-5 -US-Ne1,ZL_1_1_1,200410180900,3.0,SA-Gill R3-100,,,12-5 -US-Ne1,ZL_1_1_1,200506231800,6.2,SA-Gill R3-100,,,12-5 -US-Ne1,ZL_1_1_1,200510131300,3.0,SA-Gill R3-100,,,12-5 -US-Ne1,ZL_1_1_1,200606281900,6.2,SA-Gill R3-100,,,12-5 -US-Ne1,ZL_1_1_1,200610062100,3.0,SA-Gill R3-100,,,12-5 -US-Ne1,ZL_1_1_1,200706201300,6.2,SA-Gill R3-100,,,12-5 -US-Ne1,ZL_1_1_1,200711191000,3.0,SA-Gill R3-100,,,12-5 -US-Ne1,ZL_1_1_1,200806201000,6.2,SA-Gill R3-100,,,12-5 -US-Ne1,ZL_1_1_1,200811171300,3.0,SA-Gill R3-100,,,12-5 -US-Ne1,ZL_1_1_1,200906190900,6.2,SA-Gill R3-100,,,12-5 -US-Ne1,ZL_1_1_1,200911101600,3.0,SA-Gill R3-100,,,12-5 -US-Ne1,ZL_1_1_1,201006181200,6.2,SA-Gill R3-100,,,12-5 -US-Ne1,ZL_1_1_1,201009221100,3.0,SA-Gill R3-100,,,12-5 -US-Ne1,ZL_1_1_1,201107071200,6.2,SA-Gill R3-100,,,12-5 -US-Ne1,ZL_1_1_1,201110261100,3.0,SA-Gill R3-100,,,12-5 -US-Ne1,ZL_1_1_1,201206180800,6.2,SA-Gill R3-100,,,12-5 -US-Ne1,ZL_1_1_1,201210101300,3.0,SA-Gill R3-100,,,12-5 -US-Ne1,ZL_1_1_1,201306250700,6.2,SA-Gill R3-100,,,12-5 -US-Ne1,ZL_1_1_1,201310240900,3.0,SA-Gill R3-100,,,12-5 -US-Ne1,ZL_1_1_1,201407011000,6.2,SA-Gill R3-100,,,12-5 -US-Ne1,ZL_1_1_1,201410240900,3.0,SA-Gill R3-100,,,12-5 -US-Ne1,ZL_1_1_1,201506251400,6.2,SA-Gill R3-100,,,12-5 -US-Ne1,ZL_1_1_1,201510261500,3.0,SA-Gill R3-100,,,12-5 -US-Ne1,ZL_1_1_1,201606290900,6.2,SA-Gill R3-100,,,12-5 -US-Ne1,ZL_1_1_1,201609231200,3.0,SA-Gill R3-100,,,12-5 -US-Ne1,ZL_1_1_1,201706201200,6.2,SA-Gill R3-100,,,12-5 -US-Ne1,ZL_1_1_1,201710261200,3.0,SA-Gill R3-100,,,12-5 -US-Ne1,ZL_1_1_1,201806181200,6.2,SA-Gill R3-100,,,12-5 -US-Ne1,ZL_1_1_1,201810311200,3.0,SA-Gill R3-100,,,12-5 -US-Ne1,ZL_1_1_1,201906271000,6.2,SA-Gill R3-100,,,12-5 -US-Ne1,ZL_1_1_1,201911041300,3.0,SA-Gill R3-100,,,12-5 -US-Ne1,ZL_1_1_1,202006230900,6.2,SA-Gill R3-100,,,12-5 -US-Ne1,ZL_1_1_1,202009161300,3.0,SA-Gill R3-100,,,12-5 -US-Ne1,ZL_1_1_1,202106231300,6.2,SA-Gill R3-100,,,12-5 -US-Ne1,ZL_1_1_1,202110201200,3,SA-Gill R3-100,,,12-5 -US-Ne2,CO2_1_1_1,20150624,5.5,GA_CP-Other,,,12-5 -US-Ne2,CO2_1_1_1,,5.5,GA_CP-LI-COR LI-6262,,,12-5 -US-Ne2,CO2_1_2_1,20150624,3.0,GA_CP-Other,,,12-5 -US-Ne2,CO2_1_2_1,,3.0,GA_CP-LI-COR LI-6262,,,12-5 -US-Ne2,CO2_1_3_1,20150624,1.0,GA_CP-Other,,,12-5 -US-Ne2,CO2_1_3_1,,1.0,GA_CP-LI-COR LI-6262,,,12-5 -US-Ne2,CO2_1_4_1,20150624,0.1,GA_CP-Other,,,12-5 -US-Ne2,CO2_1_4_1,,0.1,GA_CP-LI-COR LI-6262,,,12-5 -US-Ne2,CO2_PI_F_1_1_1,20150624,5.5,GA_CP-Other,,,12-5 -US-Ne2,CO2_PI_F_1_1_1,,5.5,GA_CP-LI-COR LI-6262,,,12-5 -US-Ne2,CO2_PI_F_1_2_1,20150624,3.0,GA_CP-Other,,,12-5 -US-Ne2,CO2_PI_F_1_2_1,,3.0,GA_CP-LI-COR LI-6262,,,12-5 -US-Ne2,CO2_PI_F_1_3_1,20150624,1.0,GA_CP-Other,,,12-5 -US-Ne2,CO2_PI_F_1_3_1,,1.0,GA_CP-LI-COR LI-6262,,,12-5 -US-Ne2,CO2_PI_F_1_4_1,20150624,0.1,GA_CP-Other,,,12-5 -US-Ne2,CO2_PI_F_1_4_1,,0.1,GA_CP-LI-COR LI-6262,,,12-5 -US-Ne2,FAPAR_1_1_1,,5.2,RAD-PAR Quantum,,PPFD_IN and PPFD_OUT at 5.2 m and PAR line quantum sensors installed 0.20m above soil surface.,12-5 -US-Ne2,FC_1_1_1,200106281000,6.2,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne2,FC_1_1_1,200110241000,3.0,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne2,FC_1_1_1,200307071100,6.2,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne2,FC_1_1_1,200310271100,3.0,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne2,FC_1_1_1,200506231900,6.2,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne2,FC_1_1_1,200510241100,3.0,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne2,FC_1_1_1,200706201400,6.2,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne2,FC_1_1_1,200711201300,3.0,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne2,FC_1_1_1,200906191000,6.2,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne2,FC_1_1_1,200911101400,3.0,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne2,FC_1_1_1,201006181300,6.2,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne2,FC_1_1_1,201009221300,3.0,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne2,FC_1_1_1,201107071400,6.2,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne2,FC_1_1_1,201110261000,3.0,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne2,FC_1_1_1,201206181000,6.2,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne2,FC_1_1_1,201210091400,3.0,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne2,FC_1_1_1,201306250800,6.2,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne2,FC_1_1_1,201310241000,3.0,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne2,FC_1_1_1,201505191200,3.0,GA_CP-LI-COR LI-7200,SA-Gill R3-100,,12-5 -US-Ne2,FC_1_1_1,201506251100,6.2,GA_CP-LI-COR LI-7200,SA-Gill R3-100,,12-5 -US-Ne2,FC_1_1_1,201510271400,3.0,GA_CP-LI-COR LI-7200,SA-Gill R3-100,,12-5 -US-Ne2,FC_1_1_1,201706281500,6.2,GA_CP-LI-COR LI-7200,SA-Gill R3-100,,12-5 -US-Ne2,FC_1_1_1,201710301300,3.0,GA_CP-LI-COR LI-7200,SA-Gill R3-100,,12-5 -US-Ne2,FC_1_1_1,201906271100,6.2,GA_CP-LI-COR LI-7200,SA-Gill R3-100,,12-5 -US-Ne2,FC_1_1_1,201911081200,3.0,GA_CP-LI-COR LI-7200,SA-Gill R3-100,,12-5 -US-Ne2,FC_1_1_1,202106231100,6.2,GA_CP-LI-COR LI-7200,SA-Gill R3-100,,12-5 -US-Ne2,FC_1_1_1,202110201000,3,GA_CP-LI-COR LI-7200,SA-Gill R3-100,,12-5 -US-Ne2,FC_1_1_1,,3.0,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne2,G_PI_F_1_1_1,,-0.06,SOIL_H-Plate,,Includes flux stored between the plates and soil surface,12-5 -US-Ne2,GPP_PI_F_1_1_1,200106281000,6.2,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne2,GPP_PI_F_1_1_1,200110241000,3.0,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne2,GPP_PI_F_1_1_1,200307071100,6.2,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne2,GPP_PI_F_1_1_1,200310271100,3.0,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne2,GPP_PI_F_1_1_1,200506231900,6.2,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne2,GPP_PI_F_1_1_1,200510241100,3.0,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne2,GPP_PI_F_1_1_1,200706201400,6.2,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne2,GPP_PI_F_1_1_1,200711201300,3.0,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne2,GPP_PI_F_1_1_1,200906191000,6.2,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne2,GPP_PI_F_1_1_1,200911101400,3.0,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne2,GPP_PI_F_1_1_1,201006181300,6.2,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne2,GPP_PI_F_1_1_1,201009221300,3.0,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne2,GPP_PI_F_1_1_1,201107071400,6.2,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne2,GPP_PI_F_1_1_1,201110261000,3.0,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne2,GPP_PI_F_1_1_1,201206181000,6.2,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne2,GPP_PI_F_1_1_1,201210091400,3.0,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne2,GPP_PI_F_1_1_1,201306250800,6.2,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne2,GPP_PI_F_1_1_1,201310241000,3.0,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne2,GPP_PI_F_1_1_1,201505191200,3.0,GA_CP-LI-COR LI-7200,SA-Gill R3-100,,12-5 -US-Ne2,GPP_PI_F_1_1_1,201506251100,6.2,GA_CP-LI-COR LI-7200,SA-Gill R3-100,,12-5 -US-Ne2,GPP_PI_F_1_1_1,201510271400,3.0,GA_CP-LI-COR LI-7200,SA-Gill R3-100,,12-5 -US-Ne2,GPP_PI_F_1_1_1,201706281500,6.2,GA_CP-LI-COR LI-7200,SA-Gill R3-100,,12-5 -US-Ne2,GPP_PI_F_1_1_1,201710301300,3.0,GA_CP-LI-COR LI-7200,SA-Gill R3-100,,12-5 -US-Ne2,GPP_PI_F_1_1_1,201906271100,6.2,GA_CP-LI-COR LI-7200,SA-Gill R3-100,,12-5 -US-Ne2,GPP_PI_F_1_1_1,201911081200,3.0,GA_CP-LI-COR LI-7200,SA-Gill R3-100,,12-5 -US-Ne2,GPP_PI_F_1_1_1,202106231100,6.2,GA_CP-LI-COR LI-7200,SA-Gill R3-100,,12-5 -US-Ne2,GPP_PI_F_1_1_1,202110201000,3,GA_CP-LI-COR LI-7200,SA-Gill R3-100,,12-5 -US-Ne2,GPP_PI_F_1_1_1,,3.0,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne2,H_1_1_1,200106281000,6.2,SA-Gill R3-100,,,12-5 -US-Ne2,H_1_1_1,200110241000,3.0,SA-Gill R3-100,,,12-5 -US-Ne2,H_1_1_1,200307071100,6.2,SA-Gill R3-100,,,12-5 -US-Ne2,H_1_1_1,200310271100,3.0,SA-Gill R3-100,,,12-5 -US-Ne2,H_1_1_1,200506231900,6.2,SA-Gill R3-100,,,12-5 -US-Ne2,H_1_1_1,200510241100,3.0,SA-Gill R3-100,,,12-5 -US-Ne2,H_1_1_1,200706201400,6.2,SA-Gill R3-100,,,12-5 -US-Ne2,H_1_1_1,200711201300,3.0,SA-Gill R3-100,,,12-5 -US-Ne2,H_1_1_1,200906191000,6.2,SA-Gill R3-100,,,12-5 -US-Ne2,H_1_1_1,200911101400,3.0,SA-Gill R3-100,,,12-5 -US-Ne2,H_1_1_1,201006181300,6.2,SA-Gill R3-100,,,12-5 -US-Ne2,H_1_1_1,201009221300,3.0,SA-Gill R3-100,,,12-5 -US-Ne2,H_1_1_1,201107071400,6.2,SA-Gill R3-100,,,12-5 -US-Ne2,H_1_1_1,201110261000,3.0,SA-Gill R3-100,,,12-5 -US-Ne2,H_1_1_1,201206181000,6.2,SA-Gill R3-100,,,12-5 -US-Ne2,H_1_1_1,201210091400,3.0,SA-Gill R3-100,,,12-5 -US-Ne2,H_1_1_1,201306250800,6.2,SA-Gill R3-100,,,12-5 -US-Ne2,H_1_1_1,201310241000,3.0,SA-Gill R3-100,,,12-5 -US-Ne2,H_1_1_1,201506251100,6.2,SA-Gill R3-100,,,12-5 -US-Ne2,H_1_1_1,201510271400,3.0,SA-Gill R3-100,,,12-5 -US-Ne2,H_1_1_1,201706281500,6.2,SA-Gill R3-100,,,12-5 -US-Ne2,H_1_1_1,201710301300,3.0,SA-Gill R3-100,,,12-5 -US-Ne2,H_1_1_1,201906271100,6.2,SA-Gill R3-100,,,12-5 -US-Ne2,H_1_1_1,201911081200,3.0,SA-Gill R3-100,,,12-5 -US-Ne2,H_1_1_1,202106231100,6.2,SA-Gill R3-100,,,12-5 -US-Ne2,H_1_1_1,202110201000,3,SA-Gill R3-100,,,12-5 -US-Ne2,H_1_1_1,,3.0,SA-Gill R3-100,,,12-5 -US-Ne2,H_PI_F_1_1_1,200106281000,6.2,SA-Gill R3-100,,,12-5 -US-Ne2,H_PI_F_1_1_1,200110241000,3.0,SA-Gill R3-100,,,12-5 -US-Ne2,H_PI_F_1_1_1,200307071100,6.2,SA-Gill R3-100,,,12-5 -US-Ne2,H_PI_F_1_1_1,200310271100,3.0,SA-Gill R3-100,,,12-5 -US-Ne2,H_PI_F_1_1_1,200506231900,6.2,SA-Gill R3-100,,,12-5 -US-Ne2,H_PI_F_1_1_1,200510241100,3.0,SA-Gill R3-100,,,12-5 -US-Ne2,H_PI_F_1_1_1,200706201400,6.2,SA-Gill R3-100,,,12-5 -US-Ne2,H_PI_F_1_1_1,200711201300,3.0,SA-Gill R3-100,,,12-5 -US-Ne2,H_PI_F_1_1_1,200906191000,6.2,SA-Gill R3-100,,,12-5 -US-Ne2,H_PI_F_1_1_1,200911101400,3.0,SA-Gill R3-100,,,12-5 -US-Ne2,H_PI_F_1_1_1,201006181300,6.2,SA-Gill R3-100,,,12-5 -US-Ne2,H_PI_F_1_1_1,201009221300,3.0,SA-Gill R3-100,,,12-5 -US-Ne2,H_PI_F_1_1_1,201107071400,6.2,SA-Gill R3-100,,,12-5 -US-Ne2,H_PI_F_1_1_1,201110261000,3.0,SA-Gill R3-100,,,12-5 -US-Ne2,H_PI_F_1_1_1,201206181000,6.2,SA-Gill R3-100,,,12-5 -US-Ne2,H_PI_F_1_1_1,201210091400,3.0,SA-Gill R3-100,,,12-5 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-US-Ne2,NEE_PI_F_1_1_1,201506251100,6.2,GA_CP-LI-COR LI-7200,SA-Gill R3-100,,12-5 -US-Ne2,NEE_PI_F_1_1_1,201510271400,3.0,GA_CP-LI-COR LI-7200,SA-Gill R3-100,,12-5 -US-Ne2,NEE_PI_F_1_1_1,201706281500,6.2,GA_CP-LI-COR LI-7200,SA-Gill R3-100,,12-5 -US-Ne2,NEE_PI_F_1_1_1,201710301300,3.0,GA_CP-LI-COR LI-7200,SA-Gill R3-100,,12-5 -US-Ne2,NEE_PI_F_1_1_1,201906271100,6.2,GA_CP-LI-COR LI-7200,SA-Gill R3-100,,12-5 -US-Ne2,NEE_PI_F_1_1_1,201911081200,3.0,GA_CP-LI-COR LI-7200,SA-Gill R3-100,,12-5 -US-Ne2,NEE_PI_F_1_1_1,202106231100,6.2,GA_CP-LI-COR LI-7200,SA-Gill R3-100,,12-5 -US-Ne2,NEE_PI_F_1_1_1,202110201000,3,GA_CP-LI-COR LI-7200,SA-Gill R3-100,,12-5 -US-Ne2,NEE_PI_F_1_1_1,,3.0,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne2,NETRAD_1_1_1,,5.2,RAD-Pyrrad-SW+LW,,,12-5 -US-Ne2,NETRAD_PI_F_1_1_1,,5.2,RAD-Pyrrad-SW+LW,,,12-5 -US-Ne2,PA_1_1_1,,1.0,PRES-ElectBar,,,12-5 -US-Ne2,PA_PI_F_1_1_1,,1.0,PRES-ElectBar,,,12-5 -US-Ne2,P_PI_F_1_1_1,,4.0,PREC-TipBucGauge,,,12-5 -US-Ne2,P_PI_F_2_1_1,,5.2,PREC-TipBucGauge,,,12-5 -US-Ne2,PPFD_DIF_PI_F_1_1_1,,5.2,RAD-PAR Quantum,,,12-5 -US-Ne2,PPFD_DIR_PI_F_1_1_1,,5.2,RAD-PAR Quantum,,,12-5 -US-Ne2,PPFD_IN_PI_F_1_1_1,,5.2,RAD-PAR Quantum,,,12-5 -US-Ne2,PPFD_OUT_PI_F_1_1_1,,5.2,RAD-PAR Quantum,,,12-5 -US-Ne2,RECO_PI_F_1_1_1,200106281000,6.2,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne2,RECO_PI_F_1_1_1,200110241000,3.0,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne2,RECO_PI_F_1_1_1,200307071100,6.2,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne2,RECO_PI_F_1_1_1,200310271100,3.0,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne2,RECO_PI_F_1_1_1,200506231900,6.2,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne2,RECO_PI_F_1_1_1,200510241100,3.0,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne2,RECO_PI_F_1_1_1,200706201400,6.2,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne2,RECO_PI_F_1_1_1,200711201300,3.0,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne2,RECO_PI_F_1_1_1,200906191000,6.2,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne2,RECO_PI_F_1_1_1,200911101400,3.0,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne2,RECO_PI_F_1_1_1,201006181300,6.2,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne2,RECO_PI_F_1_1_1,201009221300,3.0,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne2,RECO_PI_F_1_1_1,201107071400,6.2,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne2,RECO_PI_F_1_1_1,201110261000,3.0,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne2,RECO_PI_F_1_1_1,201206181000,6.2,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne2,RECO_PI_F_1_1_1,201210091400,3.0,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne2,RECO_PI_F_1_1_1,201306250800,6.2,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne2,RECO_PI_F_1_1_1,201310241000,3.0,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne2,RECO_PI_F_1_1_1,201505191200,3.0,GA_CP-LI-COR LI-7200,SA-Gill R3-100,,12-5 -US-Ne2,RECO_PI_F_1_1_1,201506251100,6.2,GA_CP-LI-COR LI-7200,SA-Gill R3-100,,12-5 -US-Ne2,RECO_PI_F_1_1_1,201510271400,3.0,GA_CP-LI-COR LI-7200,SA-Gill R3-100,,12-5 -US-Ne2,RECO_PI_F_1_1_1,201706281500,6.2,GA_CP-LI-COR LI-7200,SA-Gill R3-100,,12-5 -US-Ne2,RECO_PI_F_1_1_1,201710301300,3.0,GA_CP-LI-COR LI-7200,SA-Gill R3-100,,12-5 -US-Ne2,RECO_PI_F_1_1_1,201906271100,6.2,GA_CP-LI-COR LI-7200,SA-Gill R3-100,,12-5 -US-Ne2,RECO_PI_F_1_1_1,201911081200,3.0,GA_CP-LI-COR LI-7200,SA-Gill R3-100,,12-5 -US-Ne2,RECO_PI_F_1_1_1,202106231100,6.2,GA_CP-LI-COR LI-7200,SA-Gill R3-100,,12-5 -US-Ne2,RECO_PI_F_1_1_1,202110201000,3,GA_CP-LI-COR LI-7200,SA-Gill R3-100,,12-5 -US-Ne2,RECO_PI_F_1_1_1,,3.0,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne2,RH_1_1_1,,5.5,RH-Capac,,,12-5 -US-Ne2,RH_1_2_1,,3.0,RH-Capac,,,12-5 -US-Ne2,RH_1_3_1,,1.0,RH-Capac,,,12-5 -US-Ne2,RH_1_4_1,,0.1,RH-Capac,,,12-5 -US-Ne2,RH_PI_F_1_1_1,,5.5,RH-Capac,,,12-5 -US-Ne2,RH_PI_F_1_2_1,,3.0,RH-Capac,,,12-5 -US-Ne2,RH_PI_F_1_3_1,,1.0,RH-Capac,,,12-5 -US-Ne2,RH_PI_F_1_4_1,,0.1,RH-Capac,,,12-5 -US-Ne2,SC_1_1_1,20150624,3.0,GA_CP-Other,,Storage term include profile CO2 conc measured at EC height and below,12-5 -US-Ne2,SC_1_1_1,,3.0,GA_CP-LI-COR LI-6262,,Storage term include profile CO2 conc measured at EC height and below,12-5 -US-Ne2,SC_PI_F_1_1_1,20150624,3.0,GA_CP-Other,,Storage term include profile CO2 conc measured at EC height and below,12-5 -US-Ne2,SC_PI_F_1_1_1,,3.0,GA_CP-LI-COR LI-6262,,Storage term include profile CO2 conc measured at EC height and below,12-5 -US-Ne2,SWC_1_1_1,,-0.1,SWC-TDR,,,12-5 -US-Ne2,SWC_1_2_1,,-0.25,SWC-TDR,,,12-5 -US-Ne2,SWC_1_3_1,,-0.5,SWC-TDR,,,12-5 -US-Ne2,SWC_1_4_1,,-1.0,SWC-TDR,,,12-5 -US-Ne2,SWC_1_N,,-0.1,SWC-TDR,,Number of stations (3) in spatial average at 0.1m depth,12-5 -US-Ne2,SWC_1_SD,,-0.1,SWC-TDR,,Standard deviation of hourly SWC at 0.1m depth across 3 stations,12-5 -US-Ne2,SWC_2_1_1,,-0.1,SWC-TDR,,,12-5 -US-Ne2,SWC_2_2_1,,-0.25,SWC-TDR,,,12-5 -US-Ne2,SWC_2_3_1,,-0.5,SWC-TDR,,,12-5 -US-Ne2,SWC_2_4_1,,-1.0,SWC-TDR,,,12-5 -US-Ne2,SWC_2_N,,-0.25,SWC-TDR,,Number of stations (3) in spatial average at 0.25m depth,12-5 -US-Ne2,SWC_2_SD,,-0.25,SWC-TDR,,Standard deviation of hourly SWC at 0.25m depth across 3 stations,12-5 -US-Ne2,SWC_3_1_1,,-0.1,SWC-TDR,,,12-5 -US-Ne2,SWC_3_2_1,,-0.25,SWC-TDR,,,12-5 -US-Ne2,SWC_3_3_1,,-0.5,SWC-TDR,,,12-5 -US-Ne2,SWC_3_4_1,,-1.0,SWC-TDR,,,12-5 -US-Ne2,SWC_3_N,,-0.5,SWC-TDR,,Number of stations (3) in spatial average of 0.5m depth,12-5 -US-Ne2,SWC_3_SD,,-0.5,SWC-TDR,,Standard deviation of hourly SWC at 0.5m depth across 3 stations,12-5 -US-Ne2,SWC_4_N,,-1,SWC-TDR,,Number of stations (3) in spatial average of 1.0m depth,12-5 -US-Ne2,SWC_4_SD,,-1,SWC-TDR,,Standard deviation of hourly SWC at 1.0m depth across 3 stations,12-5 -US-Ne2,SWC_PI_F_1,,-0.1,SWC-TDR,,Daily average SWC at 0.1m depth across 3 stations,12-5 -US-Ne2,SWC_PI_F_1_1_1,,-0.1,SWC-TDR,,,12-5 -US-Ne2,SWC_PI_F_1_2_1,,-0.25,SWC-TDR,,,12-5 -US-Ne2,SWC_PI_F_1_3_1,,-0.5,SWC-TDR,,,12-5 -US-Ne2,SWC_PI_F_1_4_1,,-1.0,SWC-TDR,,,12-5 -US-Ne2,SWC_PI_F_2,,-0.25,SWC-TDR,,Daily average SWC at 0.25m depth across 3 stations,12-5 -US-Ne2,SWC_PI_F_2_1_1,,-0.1,SWC-TDR,,,12-5 -US-Ne2,SWC_PI_F_2_2_1,,-0.25,SWC-TDR,,,12-5 -US-Ne2,SWC_PI_F_2_3_1,,-0.5,SWC-TDR,,,12-5 -US-Ne2,SWC_PI_F_2_4_1,,-1.0,SWC-TDR,,,12-5 -US-Ne2,SWC_PI_F_3,,-0.5,SWC-TDR,,Daily average SWC at 0.5m depth across 3 stations,12-5 -US-Ne2,SWC_PI_F_3_1_1,,-0.1,SWC-TDR,,,12-5 -US-Ne2,SWC_PI_F_3_2_1,,-0.25,SWC-TDR,,,12-5 -US-Ne2,SWC_PI_F_3_3_1,,-0.5,SWC-TDR,,,12-5 -US-Ne2,SWC_PI_F_3_4_1,,-1.0,SWC-TDR,,,12-5 -US-Ne2,SWC_PI_F_4,,-1,SWC-TDR,,Daily average SWC at 1.0m depth across 3 stations,12-5 -US-Ne2,SW_IN_1_1_1,,5.2,RAD-Pyrrad-SW+LW,,,12-5 -US-Ne2,SW_IN_PI_F_1_1_1,,5.2,RAD-Pyrrad-SW+LW,,,12-5 -US-Ne2,SW_OUT_1_1_1,,5.2,RAD-Pyrrad-SW+LW,,,12-5 -US-Ne2,SW_OUT_PI_F_1_1_1,,5.2,RAD-Pyrrad-SW+LW,,,12-5 -US-Ne2,TA_1_1_1,,5.5,TEMP-ElectResis,,,12-5 -US-Ne2,TA_1_2_1,,3.0,TEMP-ElectResis,,,12-5 -US-Ne2,TA_1_3_1,,1.0,TEMP-ElectResis,,,12-5 -US-Ne2,TA_1_4_1,,0.1,TEMP-ElectResis,,,12-5 -US-Ne2,TA_PI_F_1_1_1,,5.5,TEMP-ElectResis,,,12-5 -US-Ne2,TA_PI_F_1_2_1,,3.0,TEMP-ElectResis,,,12-5 -US-Ne2,TA_PI_F_1_3_1,,1.0,TEMP-ElectResis,,,12-5 -US-Ne2,TA_PI_F_1_4_1,,0.1,TEMP-ElectResis,,,12-5 -US-Ne2,TS_1_1_1,,-0.02,TEMP-Thermis,,In corn row,12-5 -US-Ne2,TS_1_2_1,,-0.04,TEMP-Thermis,,In corn row,12-5 -US-Ne2,TS_1_3_1,,-0.06,TEMP-Thermis,,In corn row,12-5 -US-Ne2,TS_1_4_1,,-0.10,TEMP-Thermis,,In corn row,12-5 -US-Ne2,TS_2_1_1,,-0.02,TEMP-Thermis,,Between corn row,12-5 -US-Ne2,TS_2_2_1,,-0.04,TEMP-Thermis,,Between corn row,12-5 -US-Ne2,TS_2_3_1,,-0.06,TEMP-Thermis,,Between corn row,12-5 -US-Ne2,TS_2_4_1,,-0.10,TEMP-Thermis,,Between corn row,12-5 -US-Ne2,TS_2_5_1,,-0.20,TEMP-Thermis,,Soil temperature sensor at 0.2m - removed May 2015,12-5 -US-Ne2,TS_2_6_1,,-0.25,TEMP-Thermis,,Soil temperature sensor at 0.25m - installed May 2015,12-5 -US-Ne2,TS_2_7_1,,-0.30,TEMP-Thermis,,Soil temperature sensor at 0.3m - removed May 2015,12-5 -US-Ne2,TS_2_8_1,,-0.50,TEMP-Thermis,,,12-5 -US-Ne2,TS_PI_F_1_1_1,,-0.02,TEMP-Thermis,,In corn row,12-5 -US-Ne2,TS_PI_F_1_2_1,,-0.04,TEMP-Thermis,,In corn row,12-5 -US-Ne2,TS_PI_F_1_3_1,,-0.06,TEMP-Thermis,,In corn row,12-5 -US-Ne2,TS_PI_F_1_4_1,,-0.10,TEMP-Thermis,,In corn row,12-5 -US-Ne2,TS_PI_F_2_1_1,,-0.02,TEMP-Thermis,,Between corn row,12-5 -US-Ne2,TS_PI_F_2_2_1,,-0.04,TEMP-Thermis,,Between corn row,12-5 -US-Ne2,TS_PI_F_2_3_1,,-0.06,TEMP-Thermis,,Between corn row,12-5 -US-Ne2,TS_PI_F_2_4_1,,-0.10,TEMP-Thermis,,Between corn row,12-5 -US-Ne2,TS_PI_F_2_5_1,,-0.20,TEMP-Thermis,,Soil temperature sensor at 0.2m - removed May 2015,12-5 -US-Ne2,TS_PI_F_2_6_1,,-0.25,TEMP-Thermis,,Soil temperature sensor at 0.25m - installed May 2015,12-5 -US-Ne2,TS_PI_F_2_7_1,,-0.3,TEMP-Thermis,,Soil temperature sensor at 0.3m - removed May 2015,12-5 -US-Ne2,TS_PI_F_2_8_1,,-0.5,TEMP-Thermis,,,12-5 -US-Ne2,USTAR_1_1_1,200106281000,6.2,SA-Gill R3-100,,,12-5 -US-Ne2,USTAR_1_1_1,200110241000,3.0,SA-Gill R3-100,,,12-5 -US-Ne2,USTAR_1_1_1,200307071100,6.2,SA-Gill R3-100,,,12-5 -US-Ne2,USTAR_1_1_1,200310271100,3.0,SA-Gill R3-100,,,12-5 -US-Ne2,USTAR_1_1_1,200506231900,6.2,SA-Gill R3-100,,,12-5 -US-Ne2,USTAR_1_1_1,200510241100,3.0,SA-Gill R3-100,,,12-5 -US-Ne2,USTAR_1_1_1,200706201400,6.2,SA-Gill R3-100,,,12-5 -US-Ne2,USTAR_1_1_1,200711201300,3.0,SA-Gill R3-100,,,12-5 -US-Ne2,USTAR_1_1_1,200906191000,6.2,SA-Gill R3-100,,,12-5 -US-Ne2,USTAR_1_1_1,200911101400,3.0,SA-Gill R3-100,,,12-5 -US-Ne2,USTAR_1_1_1,201006181300,6.2,SA-Gill R3-100,,,12-5 -US-Ne2,USTAR_1_1_1,201009221300,3.0,SA-Gill R3-100,,,12-5 -US-Ne2,USTAR_1_1_1,201107071400,6.2,SA-Gill R3-100,,,12-5 -US-Ne2,USTAR_1_1_1,201110261000,3.0,SA-Gill R3-100,,,12-5 -US-Ne2,USTAR_1_1_1,201206181000,6.2,SA-Gill R3-100,,,12-5 -US-Ne2,USTAR_1_1_1,201210091400,3.0,SA-Gill R3-100,,,12-5 -US-Ne2,USTAR_1_1_1,201306250800,6.2,SA-Gill R3-100,,,12-5 -US-Ne2,USTAR_1_1_1,201310241000,3.0,SA-Gill R3-100,,,12-5 -US-Ne2,USTAR_1_1_1,201506251100,6.2,SA-Gill R3-100,,,12-5 -US-Ne2,USTAR_1_1_1,201510271400,3.0,SA-Gill R3-100,,,12-5 -US-Ne2,USTAR_1_1_1,201706281500,6.2,SA-Gill R3-100,,,12-5 -US-Ne2,USTAR_1_1_1,201710301300,3.0,SA-Gill R3-100,,,12-5 -US-Ne2,USTAR_1_1_1,201906271100,6.2,SA-Gill R3-100,,,12-5 -US-Ne2,USTAR_1_1_1,201911081200,3.0,SA-Gill R3-100,,,12-5 -US-Ne2,USTAR_1_1_1,202106231100,6.2,SA-Gill R3-100,,,12-5 -US-Ne2,USTAR_1_1_1,202110201000,3,SA-Gill R3-100,,,12-5 -US-Ne2,USTAR_1_1_1,,3.0,SA-Gill R3-100,,,12-5 -US-Ne2,WD_1_1_1,,5.5,WIND-CupAn,,,12-5 -US-Ne2,WS_1_1_1,,6.2,WIND-CupAn,,,12-5 -US-Ne2,WS_1_2_1,,5.5,WIND-CupAn,,,12-5 -US-Ne2,WS_1_3_1,,3.0,WIND-CupAn,,,12-5 -US-Ne2,WS_2_1_1,,3.0,SA-Gill R3-100,,,12-5 -US-Ne2,ZL_1_1_1,200106281000,6.2,SA-Gill R3-100,,,12-5 -US-Ne2,ZL_1_1_1,200110241000,3.0,SA-Gill R3-100,,,12-5 -US-Ne2,ZL_1_1_1,200307071100,6.2,SA-Gill R3-100,,,12-5 -US-Ne2,ZL_1_1_1,200310271100,3.0,SA-Gill R3-100,,,12-5 -US-Ne2,ZL_1_1_1,200506231900,6.2,SA-Gill R3-100,,,12-5 -US-Ne2,ZL_1_1_1,200510241100,3.0,SA-Gill R3-100,,,12-5 -US-Ne2,ZL_1_1_1,200706201400,6.2,SA-Gill R3-100,,,12-5 -US-Ne2,ZL_1_1_1,200711201300,3.0,SA-Gill R3-100,,,12-5 -US-Ne2,ZL_1_1_1,200906191000,6.2,SA-Gill R3-100,,,12-5 -US-Ne2,ZL_1_1_1,200911101400,3.0,SA-Gill R3-100,,,12-5 -US-Ne2,ZL_1_1_1,201006181300,6.2,SA-Gill R3-100,,,12-5 -US-Ne2,ZL_1_1_1,201009221300,3.0,SA-Gill R3-100,,,12-5 -US-Ne2,ZL_1_1_1,201107071400,6.2,SA-Gill R3-100,,,12-5 -US-Ne2,ZL_1_1_1,201110261000,3.0,SA-Gill R3-100,,,12-5 -US-Ne2,ZL_1_1_1,201206181000,6.2,SA-Gill R3-100,,,12-5 -US-Ne2,ZL_1_1_1,201210091400,3.0,SA-Gill R3-100,,,12-5 -US-Ne2,ZL_1_1_1,201306250800,6.2,SA-Gill R3-100,,,12-5 -US-Ne2,ZL_1_1_1,201310241000,3.0,SA-Gill R3-100,,,12-5 -US-Ne2,ZL_1_1_1,201506251100,6.2,SA-Gill R3-100,,,12-5 -US-Ne2,ZL_1_1_1,201510271400,3.0,SA-Gill R3-100,,,12-5 -US-Ne2,ZL_1_1_1,201706281500,6.2,SA-Gill R3-100,,,12-5 -US-Ne2,ZL_1_1_1,201710301300,3.0,SA-Gill R3-100,,,12-5 -US-Ne2,ZL_1_1_1,201906271100,6.2,SA-Gill R3-100,,,12-5 -US-Ne2,ZL_1_1_1,201911081200,3.0,SA-Gill R3-100,,,12-5 -US-Ne2,ZL_1_1_1,202106231100,6.2,SA-Gill R3-100,,,12-5 -US-Ne2,ZL_1_1_1,202110201000,3,SA-Gill R3-100,,,12-5 -US-Ne2,ZL_1_1_1,,3.0,SA-Gill R3-100,,Stability at eddy covariance height,12-5 -US-Ne3,CO2_1_1_1,20150624,5.5,GA_CP-Other,,,12-5 -US-Ne3,CO2_1_1_1,,5.5,GA_CP-LI-COR LI-6262,,,12-5 -US-Ne3,CO2_1_2_1,20150624,3.0,GA_CP-Other,,,12-5 -US-Ne3,CO2_1_2_1,,3.0,GA_CP-LI-COR LI-6262,,,12-5 -US-Ne3,CO2_1_3_1,20150624,1.0,GA_CP-Other,,,12-5 -US-Ne3,CO2_1_3_1,,1.0,GA_CP-LI-COR LI-6262,,,12-5 -US-Ne3,CO2_1_4_1,20150624,0.1,GA_CP-Other,,,12-5 -US-Ne3,CO2_1_4_1,,0.1,GA_CP-LI-COR LI-6262,,,12-5 -US-Ne3,CO2_PI_F_1_1_1,20150624,5.5,GA_CP-Other,,,12-5 -US-Ne3,CO2_PI_F_1_1_1,,5.5,GA_CP-LI-COR LI-6262,,,12-5 -US-Ne3,CO2_PI_F_1_2_1,20150624,3.0,GA_CP-Other,,,12-5 -US-Ne3,CO2_PI_F_1_2_1,,3.0,GA_CP-LI-COR LI-6262,,,12-5 -US-Ne3,CO2_PI_F_1_3_1,20150624,1.0,GA_CP-Other,,,12-5 -US-Ne3,CO2_PI_F_1_3_1,,1.0,GA_CP-LI-COR LI-6262,,,12-5 -US-Ne3,CO2_PI_F_1_4_1,20150624,0.1,GA_CP-Other,,,12-5 -US-Ne3,CO2_PI_F_1_4_1,,0.1,GA_CP-LI-COR LI-6262,,,12-5 -US-Ne3,FAPAR_1_1_1,,5.2,RAD-PAR Quantum,,PPFD_IN and PPFD_OUT at 5.2 m and PAR line quantum sensors installed 0.20m above soil surface.,12-5 -US-Ne3,FC_1_1_1,200106281000,6.2,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne3,FC_1_1_1,200110291500,3.0,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne3,FC_1_1_1,200307071300,6.2,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne3,FC_1_1_1,200310271000,3.0,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne3,FC_1_1_1,200506240800,6.2,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne3,FC_1_1_1,200510241100,3.0,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne3,FC_1_1_1,200706201500,6.2,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne3,FC_1_1_1,200711201400,3.0,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne3,FC_1_1_1,200906191100,6.2,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne3,FC_1_1_1,200911111500,3.0,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne3,FC_1_1_1,201107081000,6.2,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne3,FC_1_1_1,201110181200,3.0,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne3,FC_1_1_1,201307010700,6.2,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne3,FC_1_1_1,201310211300,3.0,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne3,FC_1_1_1,201505131700,3.0,GA_CP-LI-COR LI-7200,SA-Gill R3-100,,12-5 -US-Ne3,FC_1_1_1,201506251100,6.2,GA_CP-LI-COR LI-7200,SA-Gill R3-100,,12-5 -US-Ne3,FC_1_1_1,201510281400,3.0,GA_CP-LI-COR LI-7200,SA-Gill R3-100,,12-5 -US-Ne3,FC_1_1_1,201706281300,6.2,GA_CP-LI-COR LI-7200,SA-Gill R3-100,,12-5 -US-Ne3,FC_1_1_1,201711011400,3.0,GA_CP-LI-COR LI-7200,SA-Gill R3-100,,12-5 -US-Ne3,FC_1_1_1,201906271300,6.2,GA_CP-LI-COR LI-7200,SA-Gill R3-100,,12-5 -US-Ne3,FC_1_1_1,201911081300,3.0,GA_CP-LI-COR LI-7200,SA-Gill R3-100,,12-5 -US-Ne3,FC_1_1_1,202106231500,6.2,GA_CP-LI-COR LI-7200,SA-Gill R3-100,,12-5 -US-Ne3,FC_1_1_1,202111041000,3,GA_CP-LI-COR LI-7200,SA-Gill R3-100,,12-5 -US-Ne3,FC_1_1_1,,3.0,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne3,G_PI_F_1_1_1,,-0.06,SOIL_H-Plate,,Includes flux stored between the plates and soil surface,12-5 -US-Ne3,GPP_PI_F_1_1_1,200106281000,6.2,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne3,GPP_PI_F_1_1_1,200110291500,3.0,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne3,GPP_PI_F_1_1_1,200307071300,6.2,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne3,GPP_PI_F_1_1_1,200310271000,3.0,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne3,GPP_PI_F_1_1_1,200506240800,6.2,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne3,GPP_PI_F_1_1_1,200510241100,3.0,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne3,GPP_PI_F_1_1_1,200706201500,6.2,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne3,GPP_PI_F_1_1_1,200711201400,3.0,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne3,GPP_PI_F_1_1_1,200906191100,6.2,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne3,GPP_PI_F_1_1_1,200911111500,3.0,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne3,GPP_PI_F_1_1_1,201107081000,6.2,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne3,GPP_PI_F_1_1_1,201110181200,3.0,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne3,GPP_PI_F_1_1_1,201307010700,6.2,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne3,GPP_PI_F_1_1_1,201310211300,3.0,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne3,GPP_PI_F_1_1_1,201505131700,3.0,GA_CP-LI-COR LI-7200,SA-Gill R3-100,,12-5 -US-Ne3,GPP_PI_F_1_1_1,201506251100,6.2,GA_CP-LI-COR LI-7200,SA-Gill R3-100,,12-5 -US-Ne3,GPP_PI_F_1_1_1,201510281400,3.0,GA_CP-LI-COR LI-7200,SA-Gill R3-100,,12-5 -US-Ne3,GPP_PI_F_1_1_1,201706281300,6.2,GA_CP-LI-COR LI-7200,SA-Gill R3-100,,12-5 -US-Ne3,GPP_PI_F_1_1_1,201711011400,3.0,GA_CP-LI-COR LI-7200,SA-Gill R3-100,,12-5 -US-Ne3,GPP_PI_F_1_1_1,201906271300,6.2,GA_CP-LI-COR LI-7200,SA-Gill R3-100,,12-5 -US-Ne3,GPP_PI_F_1_1_1,201911081300,3.0,GA_CP-LI-COR LI-7200,SA-Gill R3-100,,12-5 -US-Ne3,GPP_PI_F_1_1_1,202106231500,6.2,GA_CP-LI-COR LI-7200,SA-Gill R3-100,,12-5 -US-Ne3,GPP_PI_F_1_1_1,202111041000,3,GA_CP-LI-COR LI-7200,SA-Gill R3-100,,12-5 -US-Ne3,GPP_PI_F_1_1_1,,3.0,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne3,H_1_1_1,200106281000,6.2,SA-Gill R3-100,,,12-5 -US-Ne3,H_1_1_1,200110291500,3.0,SA-Gill R3-100,,,12-5 -US-Ne3,H_1_1_1,200307071300,6.2,SA-Gill R3-100,,,12-5 -US-Ne3,H_1_1_1,200310271000,3.0,SA-Gill R3-100,,,12-5 -US-Ne3,H_1_1_1,200506240800,6.2,SA-Gill R3-100,,,12-5 -US-Ne3,H_1_1_1,200510241100,3.0,SA-Gill R3-100,,,12-5 -US-Ne3,H_1_1_1,200706201500,6.2,SA-Gill R3-100,,,12-5 -US-Ne3,H_1_1_1,200711201400,3.0,SA-Gill R3-100,,,12-5 -US-Ne3,H_1_1_1,200906191100,6.2,SA-Gill R3-100,,,12-5 -US-Ne3,H_1_1_1,200911111500,3.0,SA-Gill R3-100,,,12-5 -US-Ne3,H_1_1_1,201107081000,6.2,SA-Gill R3-100,,,12-5 -US-Ne3,H_1_1_1,201110181200,3.0,SA-Gill R3-100,,,12-5 -US-Ne3,H_1_1_1,201307010700,6.2,SA-Gill R3-100,,,12-5 -US-Ne3,H_1_1_1,201310211300,3.0,SA-Gill R3-100,,,12-5 -US-Ne3,H_1_1_1,201506251100,6.2,SA-Gill R3-100,,,12-5 -US-Ne3,H_1_1_1,201510281400,3.0,SA-Gill R3-100,,,12-5 -US-Ne3,H_1_1_1,201706281300,6.2,SA-Gill R3-100,,,12-5 -US-Ne3,H_1_1_1,201711011400,3.0,SA-Gill R3-100,,,12-5 -US-Ne3,H_1_1_1,201906271300,6.2,SA-Gill R3-100,,,12-5 -US-Ne3,H_1_1_1,201911081300,3.0,SA-Gill R3-100,,,12-5 -US-Ne3,H_1_1_1,202106231500,6.2,SA-Gill R3-100,,,12-5 -US-Ne3,H_1_1_1,202111041000,3,SA-Gill R3-100,,,12-5 -US-Ne3,H_1_1_1,,3.0,SA-Gill R3-100,,,12-5 -US-Ne3,H_PI_F_1_1_1,200106281000,6.2,SA-Gill R3-100,,,12-5 -US-Ne3,H_PI_F_1_1_1,200110291500,3.0,SA-Gill R3-100,,,12-5 -US-Ne3,H_PI_F_1_1_1,200307071300,6.2,SA-Gill R3-100,,,12-5 -US-Ne3,H_PI_F_1_1_1,200310271000,3.0,SA-Gill R3-100,,,12-5 -US-Ne3,H_PI_F_1_1_1,200506240800,6.2,SA-Gill R3-100,,,12-5 -US-Ne3,H_PI_F_1_1_1,200510241100,3.0,SA-Gill R3-100,,,12-5 -US-Ne3,H_PI_F_1_1_1,200706201500,6.2,SA-Gill R3-100,,,12-5 -US-Ne3,H_PI_F_1_1_1,200711201400,3.0,SA-Gill R3-100,,,12-5 -US-Ne3,H_PI_F_1_1_1,200906191100,6.2,SA-Gill R3-100,,,12-5 -US-Ne3,H_PI_F_1_1_1,200911111500,3.0,SA-Gill R3-100,,,12-5 -US-Ne3,H_PI_F_1_1_1,201107081000,6.2,SA-Gill R3-100,,,12-5 -US-Ne3,H_PI_F_1_1_1,201110181200,3.0,SA-Gill R3-100,,,12-5 -US-Ne3,H_PI_F_1_1_1,201307010700,6.2,SA-Gill R3-100,,,12-5 -US-Ne3,H_PI_F_1_1_1,201310211300,3.0,SA-Gill R3-100,,,12-5 -US-Ne3,H_PI_F_1_1_1,201506251100,6.2,SA-Gill R3-100,,,12-5 -US-Ne3,H_PI_F_1_1_1,201510281400,3.0,SA-Gill R3-100,,,12-5 -US-Ne3,H_PI_F_1_1_1,201706281300,6.2,SA-Gill R3-100,,,12-5 -US-Ne3,H_PI_F_1_1_1,201711011400,3.0,SA-Gill R3-100,,,12-5 -US-Ne3,H_PI_F_1_1_1,201906271300,6.2,SA-Gill R3-100,,,12-5 -US-Ne3,H_PI_F_1_1_1,201911081300,3.0,SA-Gill R3-100,,,12-5 -US-Ne3,H_PI_F_1_1_1,202106231500,6.2,SA-Gill R3-100,,,12-5 -US-Ne3,H_PI_F_1_1_1,202111041000,3,SA-Gill R3-100,,,12-5 -US-Ne3,H_PI_F_1_1_1,,3.0,SA-Gill R3-100,,,12-5 -US-Ne3,LE_1_1_1,200106281000,6.2,GA_CP-Other,SA-Gill R3-100,,12-5 -US-Ne3,LE_1_1_1,200110291500,3.0,GA_CP-Other,SA-Gill R3-100,,12-5 -US-Ne3,LE_1_1_1,200307071300,6.2,GA_CP-Other,SA-Gill R3-100,,12-5 -US-Ne3,LE_1_1_1,200310271000,3.0,GA_CP-Other,SA-Gill R3-100,,12-5 -US-Ne3,LE_1_1_1,200506240800,6.2,GA_CP-Other,SA-Gill R3-100,,12-5 -US-Ne3,LE_1_1_1,200510241100,3.0,GA_CP-Other,SA-Gill R3-100,,12-5 -US-Ne3,LE_1_1_1,200706201500,6.2,GA_CP-Other,SA-Gill R3-100,,12-5 -US-Ne3,LE_1_1_1,200711201400,3.0,GA_CP-Other,SA-Gill R3-100,,12-5 -US-Ne3,LE_1_1_1,200906191100,6.2,GA_CP-Other,SA-Gill R3-100,,12-5 -US-Ne3,LE_1_1_1,200911111500,3.0,GA_CP-Other,SA-Gill R3-100,,12-5 -US-Ne3,LE_1_1_1,201107081000,6.2,GA_CP-Other,SA-Gill R3-100,,12-5 -US-Ne3,LE_1_1_1,201110181200,3.0,GA_CP-Other,SA-Gill R3-100,,12-5 -US-Ne3,LE_1_1_1,201307010700,6.2,GA_CP-Other,SA-Gill R3-100,,12-5 -US-Ne3,LE_1_1_1,201310211300,3.0,GA_CP-Other,SA-Gill R3-100,,12-5 -US-Ne3,LE_1_1_1,201505131700,3.0,GA_OP-LI-COR LI-7500A,SA-Gill R3-100,,12-5 -US-Ne3,LE_1_1_1,201506251100,6.2,GA_OP-LI-COR LI-7500A,SA-Gill R3-100,,12-5 -US-Ne3,LE_1_1_1,201510281400,3.0,GA_OP-LI-COR LI-7500A,SA-Gill R3-100,,12-5 -US-Ne3,LE_1_1_1,201701311300,3.0,GA_OP-LI-COR LI-7500RS,SA-Gill R3-100,,12-5 -US-Ne3,LE_1_1_1,201706281300,6.2,GA_OP-LI-COR LI-7500RS,SA-Gill R3-100,,12-5 -US-Ne3,LE_1_1_1,201711011400,3.0,GA_OP-LI-COR LI-7500RS,SA-Gill R3-100,,12-5 -US-Ne3,LE_1_1_1,201906271300,6.2,GA_OP-LI-COR LI-7500RS,SA-Gill R3-100,,12-5 -US-Ne3,LE_1_1_1,201911081300,3.0,GA_OP-LI-COR LI-7500RS,SA-Gill R3-100,,12-5 -US-Ne3,LE_1_1_1,202106231500,6.2,GA_OP-LI-COR LI-7500RS,SA-Gill R3-100,,12-5 -US-Ne3,LE_1_1_1,202111041000,3,GA_OP-LI-COR LI-7500RS,SA-Gill R3-100,,12-5 -US-Ne3,LE_1_1_1,,3.0,GA_CP-Other,SA-Gill R3-100,,12-5 -US-Ne3,LE_PI_F_1_1_1,200106281000,6.2,GA_CP-Other,SA-Gill R3-100,,12-5 -US-Ne3,LE_PI_F_1_1_1,200110291500,3.0,GA_CP-Other,SA-Gill R3-100,,12-5 -US-Ne3,LE_PI_F_1_1_1,200307071300,6.2,GA_CP-Other,SA-Gill R3-100,,12-5 -US-Ne3,LE_PI_F_1_1_1,200310271000,3.0,GA_CP-Other,SA-Gill R3-100,,12-5 -US-Ne3,LE_PI_F_1_1_1,200506240800,6.2,GA_CP-Other,SA-Gill R3-100,,12-5 -US-Ne3,LE_PI_F_1_1_1,200510241100,3.0,GA_CP-Other,SA-Gill R3-100,,12-5 -US-Ne3,LE_PI_F_1_1_1,200706201500,6.2,GA_CP-Other,SA-Gill R3-100,,12-5 -US-Ne3,LE_PI_F_1_1_1,200711201400,3.0,GA_CP-Other,SA-Gill R3-100,,12-5 -US-Ne3,LE_PI_F_1_1_1,200906191100,6.2,GA_CP-Other,SA-Gill R3-100,,12-5 -US-Ne3,LE_PI_F_1_1_1,200911111500,3.0,GA_CP-Other,SA-Gill R3-100,,12-5 -US-Ne3,LE_PI_F_1_1_1,201107081000,6.2,GA_CP-Other,SA-Gill R3-100,,12-5 -US-Ne3,LE_PI_F_1_1_1,201110181200,3.0,GA_CP-Other,SA-Gill R3-100,,12-5 -US-Ne3,LE_PI_F_1_1_1,201307010700,6.2,GA_CP-Other,SA-Gill R3-100,,12-5 -US-Ne3,LE_PI_F_1_1_1,201310211300,3.0,GA_CP-Other,SA-Gill R3-100,,12-5 -US-Ne3,LE_PI_F_1_1_1,201505131700,3.0,GA_OP-LI-COR LI-7500A,SA-Gill R3-100,,12-5 -US-Ne3,LE_PI_F_1_1_1,201506251100,6.2,GA_OP-LI-COR LI-7500A,SA-Gill R3-100,,12-5 -US-Ne3,LE_PI_F_1_1_1,201510281400,3.0,GA_OP-LI-COR LI-7500A,SA-Gill R3-100,,12-5 -US-Ne3,LE_PI_F_1_1_1,201701311300,3.0,GA_OP-LI-COR LI-7500RS,SA-Gill R3-100,,12-5 -US-Ne3,LE_PI_F_1_1_1,201706281300,6.2,GA_OP-LI-COR LI-7500RS,SA-Gill R3-100,,12-5 -US-Ne3,LE_PI_F_1_1_1,201711011400,3.0,GA_OP-LI-COR LI-7500RS,SA-Gill R3-100,,12-5 -US-Ne3,LE_PI_F_1_1_1,201906271300,6.2,GA_OP-LI-COR LI-7500RS,SA-Gill R3-100,,12-5 -US-Ne3,LE_PI_F_1_1_1,201911081300,3.0,GA_OP-LI-COR LI-7500RS,SA-Gill R3-100,,12-5 -US-Ne3,LE_PI_F_1_1_1,202106231500,6.2,GA_OP-LI-COR LI-7500RS,SA-Gill R3-100,,12-5 -US-Ne3,LE_PI_F_1_1_1,202111041000,3,GA_OP-LI-COR LI-7500RS,SA-Gill R3-100,,12-5 -US-Ne3,LE_PI_F_1_1_1,,3.0,GA_CP-Other,SA-Gill R3-100,,12-5 -US-Ne3,LW_IN_1_1_1,,5.2,RAD-Pyrrad-SW+LW,,,12-5 -US-Ne3,LW_IN_PI_F_1_1_1,,5.2,RAD-Pyrrad-SW+LW,,,12-5 -US-Ne3,LW_OUT_1_1_1,,5.2,RAD-Pyrrad-SW+LW,,,12-5 -US-Ne3,LW_OUT_PI_F_1_1_1,,5.2,RAD-Pyrrad-SW+LW,,,12-5 -US-Ne3,NEE_PI_1_1_1,200106281000,6.2,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne3,NEE_PI_1_1_1,200110291500,3.0,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne3,NEE_PI_1_1_1,200307071300,6.2,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne3,NEE_PI_1_1_1,200310271000,3.0,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne3,NEE_PI_1_1_1,200506240800,6.2,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne3,NEE_PI_1_1_1,200510241100,3.0,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne3,NEE_PI_1_1_1,200706201500,6.2,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne3,NEE_PI_1_1_1,200711201400,3.0,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne3,NEE_PI_1_1_1,200906191100,6.2,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne3,NEE_PI_1_1_1,200911111500,3.0,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne3,NEE_PI_1_1_1,201107081000,6.2,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne3,NEE_PI_1_1_1,201110181200,3.0,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne3,NEE_PI_1_1_1,201307010700,6.2,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne3,NEE_PI_1_1_1,201310211300,3.0,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne3,NEE_PI_1_1_1,201505131700,3.0,GA_CP-LI-COR LI-7200,SA-Gill R3-100,,12-5 -US-Ne3,NEE_PI_1_1_1,201506251100,6.2,GA_CP-LI-COR LI-7200,SA-Gill R3-100,,12-5 -US-Ne3,NEE_PI_1_1_1,201510281400,3.0,GA_CP-LI-COR LI-7200,SA-Gill R3-100,,12-5 -US-Ne3,NEE_PI_1_1_1,201706281300,6.2,GA_CP-LI-COR LI-7200,SA-Gill R3-100,,12-5 -US-Ne3,NEE_PI_1_1_1,201711011400,3.0,GA_CP-LI-COR LI-7200,SA-Gill R3-100,,12-5 -US-Ne3,NEE_PI_1_1_1,201906271300,6.2,GA_CP-LI-COR LI-7200,SA-Gill R3-100,,12-5 -US-Ne3,NEE_PI_1_1_1,201911081300,3.0,GA_CP-LI-COR LI-7200,SA-Gill R3-100,,12-5 -US-Ne3,NEE_PI_1_1_1,202106231500,6.2,GA_CP-LI-COR LI-7200,SA-Gill R3-100,,12-5 -US-Ne3,NEE_PI_1_1_1,202111041000,3,GA_CP-LI-COR LI-7200,SA-Gill R3-100,,12-5 -US-Ne3,NEE_PI_1_1_1,,3.0,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne3,NEE_PI_F_1_1_1,200106281000,6.2,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne3,NEE_PI_F_1_1_1,200110291500,3.0,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne3,NEE_PI_F_1_1_1,200307071300,6.2,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne3,NEE_PI_F_1_1_1,200310271000,3.0,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne3,NEE_PI_F_1_1_1,200506240800,6.2,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne3,NEE_PI_F_1_1_1,200510241100,3.0,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne3,NEE_PI_F_1_1_1,200706201500,6.2,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne3,NEE_PI_F_1_1_1,200711201400,3.0,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne3,NEE_PI_F_1_1_1,200906191100,6.2,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne3,NEE_PI_F_1_1_1,200911111500,3.0,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne3,NEE_PI_F_1_1_1,201107081000,6.2,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne3,NEE_PI_F_1_1_1,201110181200,3.0,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne3,NEE_PI_F_1_1_1,201307010700,6.2,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne3,NEE_PI_F_1_1_1,201310211300,3.0,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne3,NEE_PI_F_1_1_1,201505131700,3.0,GA_CP-LI-COR LI-7200,SA-Gill R3-100,,12-5 -US-Ne3,NEE_PI_F_1_1_1,201506251100,6.2,GA_CP-LI-COR LI-7200,SA-Gill R3-100,,12-5 -US-Ne3,NEE_PI_F_1_1_1,201510281400,3.0,GA_CP-LI-COR LI-7200,SA-Gill R3-100,,12-5 -US-Ne3,NEE_PI_F_1_1_1,201706281300,6.2,GA_CP-LI-COR LI-7200,SA-Gill R3-100,,12-5 -US-Ne3,NEE_PI_F_1_1_1,201711011400,3.0,GA_CP-LI-COR LI-7200,SA-Gill R3-100,,12-5 -US-Ne3,NEE_PI_F_1_1_1,201906271300,6.2,GA_CP-LI-COR LI-7200,SA-Gill R3-100,,12-5 -US-Ne3,NEE_PI_F_1_1_1,201911081300,3.0,GA_CP-LI-COR LI-7200,SA-Gill R3-100,,12-5 -US-Ne3,NEE_PI_F_1_1_1,202106231500,6.2,GA_CP-LI-COR LI-7200,SA-Gill R3-100,,12-5 -US-Ne3,NEE_PI_F_1_1_1,202111041000,3,GA_CP-LI-COR LI-7200,SA-Gill R3-100,,12-5 -US-Ne3,NEE_PI_F_1_1_1,,3.0,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne3,NETRAD_1_1_1,,5.2,RAD-Pyrrad-SW+LW,,,12-5 -US-Ne3,NETRAD_PI_F_1_1_1,,5.2,RAD-Pyrrad-SW+LW,,,12-5 -US-Ne3,PA_1_1_1,,1.0,PRES-ElectBar,,,12-5 -US-Ne3,PA_PI_F_1_1_1,,1.0,PRES-ElectBar,,,12-5 -US-Ne3,P_PI_F_1_1_1,,4.0,PREC-TipBucGauge,,,12-5 -US-Ne3,P_PI_F_2_1_1,,5.2,PREC-TipBucGauge,,,12-5 -US-Ne3,PPFD_DIF_PI_F_1_1_1,,5.2,RAD-PAR Quantum,,,12-5 -US-Ne3,PPFD_DIR_PI_F_1_1_1,,5.2,RAD-PAR Quantum,,,12-5 -US-Ne3,PPFD_IN_PI_F_1_1_1,,5.2,RAD-PAR Quantum,,,12-5 -US-Ne3,PPFD_OUT_PI_F_1_1_1,,5.2,RAD-PAR Quantum,,,12-5 -US-Ne3,RECO_PI_F_1_1_1,200106281000,6.2,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne3,RECO_PI_F_1_1_1,200110291500,3.0,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne3,RECO_PI_F_1_1_1,200307071300,6.2,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne3,RECO_PI_F_1_1_1,200310271000,3.0,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne3,RECO_PI_F_1_1_1,200506240800,6.2,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne3,RECO_PI_F_1_1_1,200510241100,3.0,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne3,RECO_PI_F_1_1_1,200706201500,6.2,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne3,RECO_PI_F_1_1_1,200711201400,3.0,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne3,RECO_PI_F_1_1_1,200906191100,6.2,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne3,RECO_PI_F_1_1_1,200911111500,3.0,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne3,RECO_PI_F_1_1_1,201107081000,6.2,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne3,RECO_PI_F_1_1_1,201110181200,3.0,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne3,RECO_PI_F_1_1_1,201307010700,6.2,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne3,RECO_PI_F_1_1_1,201310211300,3.0,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne3,RECO_PI_F_1_1_1,201505131700,3.0,GA_CP-LI-COR LI-7200,SA-Gill R3-100,,12-5 -US-Ne3,RECO_PI_F_1_1_1,201506251100,6.2,GA_CP-LI-COR LI-7200,SA-Gill R3-100,,12-5 -US-Ne3,RECO_PI_F_1_1_1,201510281400,3.0,GA_CP-LI-COR LI-7200,SA-Gill R3-100,,12-5 -US-Ne3,RECO_PI_F_1_1_1,201706281300,6.2,GA_CP-LI-COR LI-7200,SA-Gill R3-100,,12-5 -US-Ne3,RECO_PI_F_1_1_1,201711011400,3.0,GA_CP-LI-COR LI-7200,SA-Gill R3-100,,12-5 -US-Ne3,RECO_PI_F_1_1_1,201906271300,6.2,GA_CP-LI-COR LI-7200,SA-Gill R3-100,,12-5 -US-Ne3,RECO_PI_F_1_1_1,201911081300,3.0,GA_CP-LI-COR LI-7200,SA-Gill R3-100,,12-5 -US-Ne3,RECO_PI_F_1_1_1,202106231500,6.2,GA_CP-LI-COR LI-7200,SA-Gill R3-100,,12-5 -US-Ne3,RECO_PI_F_1_1_1,202111041000,3,GA_CP-LI-COR LI-7200,SA-Gill R3-100,,12-5 -US-Ne3,RECO_PI_F_1_1_1,,3.0,GA_CP-LI-COR LI-6262,SA-Gill R3-100,,12-5 -US-Ne3,RH_1_1_1,,5.5,RH-Capac,,,12-5 -US-Ne3,RH_1_2_1,,3.0,RH-Capac,,,12-5 -US-Ne3,RH_1_3_1,,1.0,RH-Capac,,,12-5 -US-Ne3,RH_1_4_1,,0.1,RH-Capac,,,12-5 -US-Ne3,RH_PI_F_1_1_1,,5.5,RH-Capac,,,12-5 -US-Ne3,RH_PI_F_1_2_1,,3.0,RH-Capac,,,12-5 -US-Ne3,RH_PI_F_1_3_1,,1.0,RH-Capac,,,12-5 -US-Ne3,RH_PI_F_1_4_1,,0.1,RH-Capac,,,12-5 -US-Ne3,SC_1_1_1,20150624,3.0,GA_CP-Other,,Storage term include profile CO2 conc measured at EC height and below,12-5 -US-Ne3,SC_1_1_1,,3.0,GA_CP-LI-COR LI-6262,,Storage term include profile CO2 conc measured at EC height and below,12-5 -US-Ne3,SC_PI_F_1_1_1,20150624,3.0,GA_CP-Other,,Storage term include profile CO2 conc measured at EC height and below,12-5 -US-Ne3,SC_PI_F_1_1_1,,3.0,GA_CP-LI-COR LI-6262,,Storage term include profile CO2 conc measured at EC height and below,12-5 -US-Ne3,SWC_1_1_1,,-0.1,SWC-TDR,,,12-5 -US-Ne3,SWC_1_2_1,,-0.25,SWC-TDR,,,12-5 -US-Ne3,SWC_1_3_1,,-0.5,SWC-TDR,,,12-5 -US-Ne3,SWC_1_4_1,,-1.0,SWC-TDR,,,12-5 -US-Ne3,SWC_1_N,,-0.1,SWC-TDR,,Number of stations (3) in spatial average at 0.1m depth,12-5 -US-Ne3,SWC_1_SD,,-0.1,SWC-TDR,,Standard deviation of hourly SWC at 0.1m depth across 3 stations,12-5 -US-Ne3,SWC_2_1_1,,-0.1,SWC-TDR,,,12-5 -US-Ne3,SWC_2_2_1,,-0.25,SWC-TDR,,,12-5 -US-Ne3,SWC_2_3_1,,-0.5,SWC-TDR,,,12-5 -US-Ne3,SWC_2_4_1,,-1.0,SWC-TDR,,,12-5 -US-Ne3,SWC_2_N,,-0.25,SWC-TDR,,Number of stations (3) in spatial average at 0.25m depth,12-5 -US-Ne3,SWC_2_SD,,-0.25,SWC-TDR,,Standard deviation of hourly SWC at 0.25m depth across 3 stations,12-5 -US-Ne3,SWC_3_1_1,,-0.1,SWC-TDR,,,12-5 -US-Ne3,SWC_3_2_1,,-0.25,SWC-TDR,,,12-5 -US-Ne3,SWC_3_3_1,,-0.5,SWC-TDR,,,12-5 -US-Ne3,SWC_3_4_1,,-1.0,SWC-TDR,,,12-5 -US-Ne3,SWC_3_N,,-0.5,SWC-TDR,,Number of stations (3) in spatial average of 0.5m depth,12-5 -US-Ne3,SWC_3_SD,,-0.5,SWC-TDR,,Standard deviation of hourly SWC at 0.5m depth across 3 stations,12-5 -US-Ne3,SWC_4_N,,-1,SWC-TDR,,Number of stations (3) in spatial average of 1.0m depth,12-5 -US-Ne3,SWC_4_SD,,-1,SWC-TDR,,Standard deviation of hourly SWC at 1.0m depth across 3 stations,12-5 -US-Ne3,SWC_PI_F_1,,-0.1,SWC-TDR,,Daily average SWC at 0.1m depth across 3 stations,12-5 -US-Ne3,SWC_PI_F_1_1_1,,-0.1,SWC-TDR,,,12-5 -US-Ne3,SWC_PI_F_1_2_1,,-0.25,SWC-TDR,,,12-5 -US-Ne3,SWC_PI_F_1_3_1,,-0.5,SWC-TDR,,,12-5 -US-Ne3,SWC_PI_F_1_4_1,,-1.0,SWC-TDR,,,12-5 -US-Ne3,SWC_PI_F_2,,-0.25,SWC-TDR,,Daily average SWC at 0.25m depth across 3 stations,12-5 -US-Ne3,SWC_PI_F_2_1_1,,-0.1,SWC-TDR,,,12-5 -US-Ne3,SWC_PI_F_2_2_1,,-0.25,SWC-TDR,,,12-5 -US-Ne3,SWC_PI_F_2_3_1,,-0.5,SWC-TDR,,,12-5 -US-Ne3,SWC_PI_F_2_4_1,,-1.0,SWC-TDR,,,12-5 -US-Ne3,SWC_PI_F_3,,-0.5,SWC-TDR,,Daily average SWC at 0.5m depth across 3 stations,12-5 -US-Ne3,SWC_PI_F_3_1_1,,-0.1,SWC-TDR,,,12-5 -US-Ne3,SWC_PI_F_3_2_1,,-0.25,SWC-TDR,,,12-5 -US-Ne3,SWC_PI_F_3_3_1,,-0.5,SWC-TDR,,,12-5 -US-Ne3,SWC_PI_F_3_4_1,,-1.0,SWC-TDR,,,12-5 -US-Ne3,SWC_PI_F_4,,-1,SWC-TDR,,Daily average SWC at 1.0m depth across 3 stations,12-5 -US-Ne3,SW_IN_1_1_1,,5.2,RAD-Pyrrad-SW+LW,,,12-5 -US-Ne3,SW_IN_PI_F_1_1_1,,5.2,RAD-Pyrrad-SW+LW,,,12-5 -US-Ne3,SW_OUT_1_1_1,,5.2,RAD-Pyrrad-SW+LW,,,12-5 -US-Ne3,SW_OUT_PI_F_1_1_1,,5.2,RAD-Pyrrad-SW+LW,,,12-5 -US-Ne3,TA_1_1_1,,5.5,TEMP-ElectResis,,,12-5 -US-Ne3,TA_1_2_1,,3.0,TEMP-ElectResis,,,12-5 -US-Ne3,TA_1_3_1,,1.0,TEMP-ElectResis,,,12-5 -US-Ne3,TA_1_4_1,,0.1,TEMP-ElectResis,,,12-5 -US-Ne3,TA_PI_F_1_1_1,,5.5,TEMP-ElectResis,,,12-5 -US-Ne3,TA_PI_F_1_2_1,,3.0,TEMP-ElectResis,,,12-5 -US-Ne3,TA_PI_F_1_3_1,,1.0,TEMP-ElectResis,,,12-5 -US-Ne3,TA_PI_F_1_4_1,,0.1,TEMP-ElectResis,,,12-5 -US-Ne3,TS_1_1_1,,-0.02,TEMP-Thermis,,In corn row,12-5 -US-Ne3,TS_1_2_1,,-0.04,TEMP-Thermis,,In corn row,12-5 -US-Ne3,TS_1_3_1,,-0.06,TEMP-Thermis,,In corn row,12-5 -US-Ne3,TS_1_4_1,,-0.10,TEMP-Thermis,,In corn row,12-5 -US-Ne3,TS_2_1_1,,-0.02,TEMP-Thermis,,Between corn row,12-5 -US-Ne3,TS_2_2_1,,-0.04,TEMP-Thermis,,Between corn row,12-5 -US-Ne3,TS_2_3_1,,-0.06,TEMP-Thermis,,Between corn row,12-5 -US-Ne3,TS_2_4_1,,-0.10,TEMP-Thermis,,Between corn row,12-5 -US-Ne3,TS_2_5_1,,-0.20,TEMP-Thermis,,Soil temperature sensor at 0.2m - removed May 2015,12-5 -US-Ne3,TS_2_6_1,,-0.25,TEMP-Thermis,,Soil temperature sensor at 0.25m - installed May 2015,12-5 -US-Ne3,TS_2_7_1,,-0.30,TEMP-Thermis,,Soil temperature sensor at 0.3m - removed May 2015,12-5 -US-Ne3,TS_2_8_1,,-0.50,TEMP-Thermis,,,12-5 -US-Ne3,TS_PI_F_1_1_1,,-0.02,TEMP-Thermis,,In corn row,12-5 -US-Ne3,TS_PI_F_1_2_1,,-0.04,TEMP-Thermis,,In corn row,12-5 -US-Ne3,TS_PI_F_1_3_1,,-0.06,TEMP-Thermis,,In corn row,12-5 -US-Ne3,TS_PI_F_1_4_1,,-0.10,TEMP-Thermis,,In corn row,12-5 -US-Ne3,TS_PI_F_2_1_1,,-0.02,TEMP-Thermis,,Between corn row,12-5 -US-Ne3,TS_PI_F_2_2_1,,-0.04,TEMP-Thermis,,Between corn row,12-5 -US-Ne3,TS_PI_F_2_3_1,,-0.06,TEMP-Thermis,,Between corn row,12-5 -US-Ne3,TS_PI_F_2_4_1,,-0.10,TEMP-Thermis,,Between corn row,12-5 -US-Ne3,TS_PI_F_2_5_1,,-0.20,TEMP-Thermis,,Soil temperature sensor at 0.2m - removed May 2015,12-5 -US-Ne3,TS_PI_F_2_6_1,,-0.25,TEMP-Thermis,,Soil temperature sensor at 0.25m - installed May 2015,12-5 -US-Ne3,TS_PI_F_2_7_1,,-0.3,TEMP-Thermis,,Soil temperature sensor at 0.3m - removed May 2015,12-5 -US-Ne3,TS_PI_F_2_8_1,,-0.5,TEMP-Thermis,,,12-5 -US-Ne3,USTAR_1_1_1,200106281000,6.2,SA-Gill R3-100,,,12-5 -US-Ne3,USTAR_1_1_1,200110291500,3.0,SA-Gill R3-100,,,12-5 -US-Ne3,USTAR_1_1_1,200307071300,6.2,SA-Gill R3-100,,,12-5 -US-Ne3,USTAR_1_1_1,200310271000,3.0,SA-Gill R3-100,,,12-5 -US-Ne3,USTAR_1_1_1,200506240800,6.2,SA-Gill R3-100,,,12-5 -US-Ne3,USTAR_1_1_1,200510241100,3.0,SA-Gill R3-100,,,12-5 -US-Ne3,USTAR_1_1_1,200706201500,6.2,SA-Gill R3-100,,,12-5 -US-Ne3,USTAR_1_1_1,200711201400,3.0,SA-Gill R3-100,,,12-5 -US-Ne3,USTAR_1_1_1,200906191100,6.2,SA-Gill R3-100,,,12-5 -US-Ne3,USTAR_1_1_1,200911111500,3.0,SA-Gill R3-100,,,12-5 -US-Ne3,USTAR_1_1_1,201107081000,6.2,SA-Gill R3-100,,,12-5 -US-Ne3,USTAR_1_1_1,201110181200,3.0,SA-Gill R3-100,,,12-5 -US-Ne3,USTAR_1_1_1,201307010700,6.2,SA-Gill R3-100,,,12-5 -US-Ne3,USTAR_1_1_1,201310211300,3.0,SA-Gill R3-100,,,12-5 -US-Ne3,USTAR_1_1_1,201506251100,6.2,SA-Gill R3-100,,,12-5 -US-Ne3,USTAR_1_1_1,201510281400,3.0,SA-Gill R3-100,,,12-5 -US-Ne3,USTAR_1_1_1,201706281300,6.2,SA-Gill R3-100,,,12-5 -US-Ne3,USTAR_1_1_1,201711011400,3.0,SA-Gill R3-100,,,12-5 -US-Ne3,USTAR_1_1_1,201906271300,6.2,SA-Gill R3-100,,,12-5 -US-Ne3,USTAR_1_1_1,201911081300,3.0,SA-Gill R3-100,,,12-5 -US-Ne3,USTAR_1_1_1,202106231500,6.2,SA-Gill R3-100,,,12-5 -US-Ne3,USTAR_1_1_1,202111041000,3,SA-Gill R3-100,,,12-5 -US-Ne3,USTAR_1_1_1,,3.0,SA-Gill R3-100,,,12-5 -US-Ne3,WD_1_1_1,,5.5,WIND-CupAn,,,12-5 -US-Ne3,WS_1_1_1,,6.2,WIND-CupAn,,,12-5 -US-Ne3,WS_1_2_1,,5.5,WIND-CupAn,,,12-5 -US-Ne3,WS_1_3_1,,3.0,WIND-CupAn,,,12-5 -US-Ne3,WS_2_1_1,,3.0,SA-Gill R3-100,,,12-5 -US-Ne3,ZL_1_1_1,200106281000,6.2,SA-Gill R3-100,,,12-5 -US-Ne3,ZL_1_1_1,200110291500,3.0,SA-Gill R3-100,,,12-5 -US-Ne3,ZL_1_1_1,200307071300,6.2,SA-Gill R3-100,,,12-5 -US-Ne3,ZL_1_1_1,200310271000,3.0,SA-Gill R3-100,,,12-5 -US-Ne3,ZL_1_1_1,200506240800,6.2,SA-Gill R3-100,,,12-5 -US-Ne3,ZL_1_1_1,200510241100,3.0,SA-Gill R3-100,,,12-5 -US-Ne3,ZL_1_1_1,200706201500,6.2,SA-Gill R3-100,,,12-5 -US-Ne3,ZL_1_1_1,200711201400,3.0,SA-Gill R3-100,,,12-5 -US-Ne3,ZL_1_1_1,200906191100,6.2,SA-Gill R3-100,,,12-5 -US-Ne3,ZL_1_1_1,200911111500,3.0,SA-Gill R3-100,,,12-5 -US-Ne3,ZL_1_1_1,201107081000,6.2,SA-Gill R3-100,,,12-5 -US-Ne3,ZL_1_1_1,201110181200,3.0,SA-Gill R3-100,,,12-5 -US-Ne3,ZL_1_1_1,201307010700,6.2,SA-Gill R3-100,,,12-5 -US-Ne3,ZL_1_1_1,201310211300,3.0,SA-Gill R3-100,,,12-5 -US-Ne3,ZL_1_1_1,201506251100,6.2,SA-Gill R3-100,,,12-5 -US-Ne3,ZL_1_1_1,201510281400,3.0,SA-Gill R3-100,,,12-5 -US-Ne3,ZL_1_1_1,201706281300,6.2,SA-Gill R3-100,,,12-5 -US-Ne3,ZL_1_1_1,201711011400,3.0,SA-Gill R3-100,,,12-5 -US-Ne3,ZL_1_1_1,201906271300,6.2,SA-Gill R3-100,,,12-5 -US-Ne3,ZL_1_1_1,201911081300,3.0,SA-Gill R3-100,,,12-5 -US-Ne3,ZL_1_1_1,202106231500,6.2,SA-Gill R3-100,,,12-5 -US-Ne3,ZL_1_1_1,202111041000,3,SA-Gill R3-100,,,12-5 -US-Ne3,ZL_1_1_1,,3.0,SA-Gill R3-100,,Stability at eddy covariance height,12-5 -US-NGB,CH4,,4.00,GA_OP-LI-COR LI-7700,,,3-5 -US-NGB,CO2,,3.95,GA_OP-LI-COR LI-7500A,,,3-5 -US-NGB,FC,,4.15,SA-Gill R3-50,GA_OP-LI-COR LI-7500A,,3-5 -US-NGB,FCH4,,4.15,SA-Gill R3-50,GA_OP-LI-COR LI-7700,,3-5 -US-NGB,FETCH_90,,4.15,SA-Gill R3-50,,,3-5 -US-NGB,FETCH_MAX,,4.15,SA-Gill R3-50,,,3-5 -US-NGB,G_1_1_1,,-0.1,SOIL_H-Plate,,,3-5 -US-NGB,G_2_1_1,,-0.1,SOIL_H-Plate,,,3-5 -US-NGB,G_3_1_1,,-0.1,SOIL_H-Plate,,,3-5 -US-NGB,G_4_1_1,,-0.1,SOIL_H-Plate,,,3-5 -US-NGB,H,,4.15,SA-Gill R3-50,,,3-5 -US-NGB,H2O,,3.95,GA_OP-LI-COR LI-7500A,,,3-5 -US-NGB,LE,,4.15,SA-Gill R3-50,GA_OP-LI-COR LI-7500A,,3-5 -US-NGB,LW_IN,,2.0,RAD-Pyrrad-SW+LW,,,3-5 -US-NGB,LW_OUT,,2.0,RAD-Pyrrad-SW+LW,,,3-5 -US-NGB,MO_LENGTH,,4.15,SA-Gill R3-50,,,3-5 -US-NGB,NETRAD,,2.0,RAD-Pyrrad-SW+LW,,,3-5 -US-NGB,PA,,3.95,GA_OP-LI-COR LI-7500A,,,3-5 -US-NGB,PPFD_IN,,2.0,RAD-PAR Quantum,,,3-5 -US-NGB,PPFD_OUT,,2.0,RAD-PAR Quantum,,,3-5 -US-NGB,RH,,3.0,RH-Capac,,,3-5 -US-NGB,SW_IN,,2,RAD-Pyrrad-SW+LW,,,3-5 -US-NGB,SW_OUT,,2,RAD-Pyrrad-SW+LW,,,3-5 -US-NGB,TA,,3,TEMP-ElectResis,,,3-5 -US-NGB,TAU,,4.15,SA-Gill R3-50,,,3-5 -US-NGB,T_SONIC,,4.15,SA-Gill R3-50,,,3-5 -US-NGB,T_SONIC_SIGMA,,4.15,SA-Gill R3-50,,,3-5 -US-NGB,U_SIGMA,,4.15,SA-Gill R3-50,,,3-5 -US-NGB,USTAR,,4.15,SA-Gill R3-50,,,3-5 -US-NGB,VPD_PI,,3.95,GA_OP-LI-COR LI-7500A,,,3-5 -US-NGB,V_SIGMA,,4.15,SA-Gill R3-50,,,3-5 -US-NGB,WD,,4.15,SA-Gill R3-50,,,3-5 -US-NGB,WS,,4.15,SA-Gill R3-50,,,3-5 -US-NGB,W_SIGMA,,4.15,SA-Gill R3-50,,,3-5 -US-NGB,WS_MAX,,4.15,SA-Gill R3-50,,,3-5 -US-NGB,ZL,,4.15,SA-Gill R3-50,,,3-5 -US-NGC,CH4,,2.75,GA_OP-LI-COR LI-7700,,,1-5 -US-NGC,CO2,,2.75,GA_OP_SA-Campbell IRGASON,,,1-5 -US-NGC,FC,,2.75,GA_OP_SA-Campbell IRGASON,,,1-5 -US-NGC,FCH4,,2.75,GA_OP-LI-COR LI-7700,,The sonic used here is the IRGASON;,1-5 -US-NGC,FETCH_90,,2.75,GA_OP_SA-Campbell IRGASON,,,1-5 -US-NGC,FETCH_MAX,,2.75,GA_OP_SA-Campbell IRGASON,,,1-5 -US-NGC,G,2018,-0.10,SOIL_H-Plate,,,1-5 -US-NGC,H,,2.75,GA_OP_SA-Campbell IRGASON,,,1-5 -US-NGC,H2O,,2.75,GA_OP_SA-Campbell IRGASON,,,1-5 -US-NGC,LE,,2.75,GA_OP_SA-Campbell IRGASON,,,1-5 -US-NGC,LW_IN,,2.00,RAD-Pyrrad-SW+LW,,,1-5 -US-NGC,LW_OUT,,2.00,RAD-Pyrrad-SW+LW,,,1-5 -US-NGC,MO_LENGTH,,2.75,GA_OP_SA-Campbell IRGASON,,,1-5 -US-NGC,NETRAD,,2.00,RAD-Pyrrad-SW+LW,,,1-5 -US-NGC,PA,,1.65,GA_OP_SA-Campbell IRGASON,,,1-5 -US-NGC,PPFD_IN,,2.00,RAD-PAR Quantum,,,1-5 -US-NGC,PPFD_OUT,,2.00,RAD-PAR Quantum,,,1-5 -US-NGC,RH,,2.00,RH-Capac,,,1-5 -US-NGC,SWC_1_1_1,,-0.15,SWC-TDR,,,1-5 -US-NGC,SWC_2_1_1,,-0.15,SWC-TDR,,,1-5 -US-NGC,SWC_3_1_1,,-0.15,SWC-TDR,,,1-5 -US-NGC,SW_IN,,2,RAD-Pyrrad-SW+LW,,,1-5 -US-NGC,SW_OUT,,2,RAD-Pyrrad-SW+LW,,,1-5 -US-NGC,TA,,2.00,TEMP-ElectResis,,,1-5 -US-NGC,TAU,,2.75,GA_OP_SA-Campbell IRGASON,,,1-5 -US-NGC,TS_1_1_1,,-0.15,SWC-TDR,,,1-5 -US-NGC,TS_2_1_1,,-0.15,SWC-TDR,,,1-5 -US-NGC,TS_3_1_1,,-0.15,SWC-TDR,,,1-5 -US-NGC,TS_4_1_1,,-0.15,TEMP-TCouple,,,1-5 -US-NGC,T_SONIC,,2.75,GA_OP_SA-Campbell IRGASON,,,1-5 -US-NGC,T_SONIC_SIGMA,,2.75,GA_OP_SA-Campbell IRGASON,,,1-5 -US-NGC,U_SIGMA,,2.75,GA_OP_SA-Campbell IRGASON,,,1-5 -US-NGC,USTAR,,2.75,GA_OP_SA-Campbell IRGASON,,,1-5 -US-NGC,VPD_PI,,2.75,GA_OP_SA-Campbell IRGASON,,,1-5 -US-NGC,V_SIGMA,,2.75,GA_OP_SA-Campbell IRGASON,,,1-5 -US-NGC,WD,,2.75,GA_OP_SA-Campbell IRGASON,,,1-5 -US-NGC,WS,,2.75,GA_OP_SA-Campbell IRGASON,,,1-5 -US-NGC,W_SIGMA,,2.75,GA_OP_SA-Campbell IRGASON,,,1-5 -US-NGC,WS_MAX,,2.75,GA_OP_SA-Campbell IRGASON,,,1-5 -US-NGC,ZL,,2.75,GA_OP_SA-Campbell IRGASON,,,1-5 -US-NMj,NETRAD,,3.5,,,,3-5 -US-NMj,RH,,1,,,,3-5 -US-NMj,TA,,1,,,,3-5 -US-NMj,TS_1_1_1,,-0,,,,3-5 -US-NMj,TS_1_2_1,,-0.05,,,,3-5 -US-NR1,CO2_1_1_1,,21.5,GA_CP-Campbell TGA100,,CO2_1_1_1 co2_21m Campbell TGA100A umol/mol 21.5m Carbon Dioxide Mixing Ratio,19-5 -US-NR1,CO2_1_2_1,,11,GA_CP-Campbell TGA100,,,19-5 -US-NR1,CO2_1_3_1,,9,GA_CP-Campbell TGA100,,,19-5 -US-NR1,CO2_1_4_1,,7,GA_CP-Campbell TGA100,,,19-5 -US-NR1,CO2_1_5_1,,5,GA_CP-Campbell TGA100,,,19-5 -US-NR1,CO2_1_6_1,,2,GA_CP-Campbell TGA100,,,19-5 -US-NR1,CO2_1_7_1,,1,GA_CP-Campbell TGA100,,,19-5 -US-NR1,CO2_1_8_1,,0.5,GA_CP-Campbell TGA100,,,19-5 -US-NR1,CO2_1_9_1,,0.1,GA_CP-Campbell TGA100,,CO2_1_9_1 co2_10cm Campbell TGA100A umol/mol 0.1m Carbon Dioxide Mixing Ratio,19-5 -US-NR1,CO2C13_1_1_1,,21.5,GA_CP-Campbell TGA100,,CO2C13_1_1_1 del13co2_21m Campbell TGA100A permil 21.5m Carbon Dioxide Isotope Ratio (d13C of CO2),19-5 -US-NR1,CO2C13_1_2_1,,11.0,GA_CP-Campbell TGA100,,CO2C13_1_2_1 del13co2_11m Campbell TGA100A permil 11.0m Carbon Dioxide Isotope Ratio (d13C of CO2),19-5 -US-NR1,CO2C13_1_3_1,,9.0,GA_CP-Campbell TGA100,,CO2C13_1_3_1 del13co2_09m Campbell TGA100A permil 9.0m Carbon Dioxide Isotope Ratio (d13C of CO2),19-5 -US-NR1,CO2C13_1_4_1,,7.0,GA_CP-Campbell TGA100,,CO2C13_1_4_1 del13co2_07m Campbell TGA100A permil 7.0m Carbon Dioxide Isotope Ratio (d13C of CO2),19-5 -US-NR1,CO2C13_1_5_1,,5.0,GA_CP-Campbell TGA100,,CO2C13_1_5_1 del13co2_05m Campbell TGA100A permil 5.0m Carbon Dioxide Isotope Ratio (d13C of CO2),19-5 -US-NR1,CO2C13_1_6_1,,2.0,GA_CP-Campbell TGA100,,CO2C13_1_6_1 del13co2_02m Campbell TGA100A permil 2.0m Carbon Dioxide Isotope Ratio (d13C of CO2),19-5 -US-NR1,CO2C13_1_7_1,,1.0,GA_CP-Campbell TGA100,,CO2C13_1_7_1 del13co2_01m Campbell TGA100A permil 1.0m Carbon Dioxide Isotope Ratio (d13C of CO2),19-5 -US-NR1,CO2C13_1_8_1,,0.5,GA_CP-Campbell TGA100,,CO2C13_1_8_1 del13co2_50cm Campbell TGA100A permil 0.5m Carbon Dioxide Isotope Ratio (d13C of CO2),19-5 -US-NR1,CO2C13_1_9_1,,0.1,GA_CP-Campbell TGA100,,CO2C13_1_9_1 del13co2_10cm Campbell TGA100A permil 0.1m Carbon Dioxide Isotope Ratio (d13C of CO2),19-5 -US-NR1,FC_1_1_1,,21.5,GA_CP-LI-COR LI-6262,SA-Campbell CSAT-3,FC_1_1_1 Fco2_21m CSAT3 Sonic + LI-6262 umol/m2/s 21.5m C02 Flux (w'co2') ,19-5 -US-NR1,FC_PI_F_1_1_1,,21.5,GA_CP-LI-COR LI-6262,SA-Campbell CSAT-3,FC_F_1_1_1 Fco2_21m CSAT3 Sonic + LI-6262 umol/m2/s 21.5m C02 Flux (w'co2'),19-5 -US-NR1,G_1,,-0.1,SOIL_H-Plate,,G_1 Qh_soil REBS HFT-1 (multiple sensors) W/m2 -10cm Soil Heat Flux,19-5 -US-NR1,G_PI_F_1,,-0.1,SOIL_H-Plate,,G_F_1 Qh_soil REBS HFT-1 (multiple sensors) W/m2 -10cm Soil Heat Flux,19-5 -US-NR1,H_1_1_1,,21.5,SA-Campbell CSAT-3,,H_1_1_1 Qh_21m CSAT3 Sonic W/m2 21.5m Sensible Heat Flux,19-5 -US-NR1,H_1_1_2,,21.5,SA-Campbell CSAT-3,,H_1_1_2 Qh_Ttc_21m CSAT3 Sonic + E-type Thermocouple W/m2 21.5m Sensible Heat Flux (from Thermocouple),19-5 -US-NR1,H_PI_F_1_1_1,,21.5,SA-Campbell CSAT-3,,H_F_1_1_1 Qh_21m CSAT3 Sonic W/m2 21.5m Sensible Heat Flux,19-5 -US-NR1,H_PI_F_1_1_2,,21.5,SA-Campbell CSAT-3,,H_F_1_1_2 Qh_Ttc_21m CSAT3 Sonic + E-type Thermocouple W/m2 21.5m Sensible Heat Flux (from Thermocouple),19-5 -US-NR1,LE_1_1_1,,21.5,SA-Campbell CSAT-3,GA_OP-Krypton Hygrometer,LE_1_1_1 Qe_21m CSAT3 Sonic + Krypton Hygrometer (or LI-6262) W/m2 21.5m Latent Heat Flux,19-5 -US-NR1,LEAF_WET_1_1_1,,13.5,LEAF_WET-ElectResis,,LEAF_WET_1_1_1 leaf_wetness Campbell Model 237 0=dry 100=wet 13.5m Leaf Wetness (percentage),19-5 -US-NR1,LEAF_WET_PI_F_1_1_1,,13.5,LEAF_WET-ElectResis,,LEAF_WET_F_1_1_1 leaf_wetness Campbell Model 237 0=dry 100=wet 13.5m Leaf Wetness (percentage),19-5 -US-NR1,LE_PI_F_1_1_1,,21.5,SA-Campbell CSAT-3,GA_OP-Krypton Hygrometer,LE_F_1_1_1 Qe_21m CSAT3 Sonic + Krypton Hygrometer (or LI-6262) W/m2 21.5m Latent Heat Flux,19-5 -US-NR1,LW_IN_1_1_1,,25.5,RAD-Pyrrad-SW+LW,,LW_IN_1_1_1 Rlw_in_25m_KZ Kipp and Zonen CNR1 W/m2 25.5m Incoming Longwave Radiation,19-5 -US-NR1,LW_IN_PI_F_1_1_1,,25.5,RAD-Pyrrad-SW+LW,,LW_IN_F_1_1_1 Rlw_in_25m_KZ Kipp and Zonen CNR1 W/m2 25.5m Incoming Longwave Radiation,19-5 -US-NR1,LW_OUT_1_1_1,,25.5,RAD-Pyrrad-SW+LW,,LW_OUT_1_1_1 Rlw_out_25m_KZ Kipp and Zonen CNR1 W/m2 25.5m Outgoing Longwave Radiation,19-5 -US-NR1,LW_OUT_PI_F_1_1_1,,25.5,RAD-Pyrrad-SW+LW,,LW_OUT_F_1_1_1 Rlw_out_25m_KZ Kipp and Zonen CNR1 W/m2 25.5m Outgoing Longwave Radiation,19-5 -US-NR1,NETRAD_1_1_2,,25.5,RAD-Net radiometer,,NETRAD_1_1_2 Rnet_25m_REBS REBS Q-7.1 W/m2 25.5m Net Radiation,19-5 -US-NR1,NETRAD_PI_F_1_1_2,,25.5,RAD-Net radiometer,,NETRAD_F_1_1_2 Rnet_25m_REBS REBS Q-7.1 W/m2 25.5m Net Radiation,19-5 -US-NR1,P_1_1_1,,10.5,PREC-TipBucGauge,,P_1_1_1 precip_mm Met One Model 385 mm 10.5m Precipitation,19-5 -US-NR1,PA_1_1_1,,12,PRES-ElectBar,,PA_1_1_1 P_bar_12m Vaisala PTB-101B kPa 12m Barometric Pressure,19-5 -US-NR1,PA_PI_F_1_1_1,,12,PRES-ElectBar,,PA_F_1_1_1 P_bar_12m Vaisala PTB-101B kPa 12m Barometric Pressure,19-5 -US-NR1,P_PI_F_1_1_1,,10.5,PREC-TipBucGauge,,P_F_1_1_1 precip_mm Met One Model 385 mm 10.5m Precipitation,19-5 -US-NR1,PPFD_IN_1_1_1,,25.5,RAD-PAR Quantum,,PPFD_IN_1_1_1 Rppfd_in_25m LI-COR 190-SA umol/m2/s 25.5m Incoming Photosynthetic Active Photon Flux Density (PPFD),19-5 -US-NR1,PPFD_IN_PI_F_1_1_1,,25.5,RAD-PAR Quantum,,PPFD_IN_F_1_1_1 Rppfd_in_25m LI-COR 190-SA umol/m2/s 25.5m Incoming Photosynthetic Active Photon Flux Density (PPFD),19-5 -US-NR1,PPFD_OUT_1_1_1,,25.5,RAD-PAR Quantum,,PPFD_OUT_1_1_1 Rppfd_out_25m LI-COR 190-SA umol/m2/s 25.5m Outgoing PPFD,19-5 -US-NR1,PPFD_OUT_PI_F_1_1_1,,25.5,RAD-PAR Quantum,,PPFD_OUT_F_1_1_1 Rppfd_out_25m LI-COR 190-SA umol/m2/s 25.5m Outgoing PPFD,19-5 -US-NR1,RH_1_1_1,,21.5,RH-Capac,,RH_1_1_1 RH_21m Vaisala HMP-35D percent 21.5m Relative Humidity,19-5 -US-NR1,RH_1_2_1,,8,RH-Capac,,RH_1_2_1 RH_8m Vaisala HMP-35D percent 8m Relative Humidity,19-5 -US-NR1,RH_1_3_1,,2,RH-Capac,,RH_1_3_1 RH_2m Vaisala HMP-35D percent 2m Relative Humidity,19-5 -US-NR1,RH_PI_F_1_1_1,,21.5,RH-Capac,,RH_F_1_1_1 RH_21m Vaisala HMP-35D percent 21.5m Relative Humidity,19-5 -US-NR1,RH_PI_F_1_2_1,,8,RH-Capac,,RH_F_1_2_1 RH_8m Vaisala HMP-35D percent 8m Relative Humidity,19-5 -US-NR1,RH_PI_F_1_3_1,,2,RH-Capac,,RH_F_1_3_1 RH_2m Vaisala HMP-35D percent 2m Relative Humidity,19-5 -US-NR1,SB_1,,1.5,TEMP-TCouple,,SB_1 Strg_biomass Campbell A3537 + Vaisala HMP-35D W/m2 1.5m+8m Bole + Needle Heat Storage (see terms above),19-5 -US-NR1,SB_BOLE_1,,1.5,TEMP-TCouple,,SB_BOLE_1 Strg_bole W/m2 1.5m (3 cm depth) Bole Heat Storage (Pine trees) Gap-filled Campbell A3537 (T-type Thermocouples),19-5 -US-NR1,SB_BOLE_PI_F_1,,1.5,TEMP-TCouple,,SB_BOLE_F_1 Strg_bole W/m2 1.5m (3 cm depth) Bole Heat Storage (Pine trees) Gap-filled Campbell A3537 (T-type Thermocouples),19-5 -US-NR1,SB_PI_F_1,,1.5,TEMP-TCouple,,SB_F_1 Strg_biomass Campbell A3537 + Vaisala HMP-35D W/m2 1.5m+8m Bole + Needle Heat Storage (see terms above),19-5 -US-NR1,SB_FOILAGE_1,,,TEMP-Thermis,,SB_FOILAGE_1 Strg_needle Vaisala HMP-35D W/m2 8m Needle Heat Storage,19-5 -US-NR1,SB_FOILIAGE_PI_F_1,,,TEMP-Thermis,,SB_FOILAGE_F_1 Strg_needle Vaisala HMP-35D W/m2 8m Needle Heat Storage,19-5 -US-NR1,SC_1_1_1,,21.5,GA_CP-Campbell TGA100,,SC_1_1_1 Strg_co2 LI-COR LI-6251 (or TGA100) umol/m2/s 0.5-21.5m C02 Canopy Storage,19-5 -US-NR1,SC_PI_F_1_1_1,,21.5,GA_CP-Campbell TGA100,,Gap-filled CO2 Storage between 0.5 to 21.5m; A LI-6251 was also used at times.,19-5 -US-NR1,SG_1,,-0.1,TEMP-ElectResis,,SG_1 Strg_soil1 REBS STP-1 (multiple sensors) W/m2 0 to -10 cm Soil Heat Storage,19-5 -US-NR1,SG_1_1_1,,-0.05,TEMP-Thermis,,SG_1_1_1 Strg_soil2 Campbell 107L (thermistor) W/m2 -5cm Soil Heat Storage,19-5 -US-NR1,SG_PI_F_1,,-0.1,TEMP-ElectResis,,SG_F_1 Strg_soil1 REBS STP-1 (multiple sensors) W/m2 0 to -10 cm Soil Heat Storage,19-5 -US-NR1,SG_PI_F_1_1_1,,-0.05,TEMP-Thermis,,SG_F_1_1_1 Strg_soil2 Campbell 107L (thermistor) W/m2 -5cm Soil Heat Storage,19-5 -US-NR1,SH_1_1_1,,21.5,TEMP-Thermis,,SH_1_1_1 Strg_Qh Vaisala HMP-35D W/m2 2m+8m+21.5m Sensible Heat Storage,19-5 -US-NR1,SH_PI_F_1_1_1,,21.5,TEMP-Thermis,,SH_F_1_1_1 Strg_Qh Vaisala HMP-35D W/m2 2m+8m+21.5m Sensible Heat Storage,19-5 -US-NR1,SLE_1_1_1,,21.5,RH-Capac,,SLE_1_1_1 Strg_Qe Vaisala HMP-35D W/m2 2m+8m+21.5m Latent Heat Storage,19-5 -US-NR1,SLE_PI_F_1_1_1,,21.5,RH-Capac,,SLE_F_1_1_1 Strg_Qe Vaisala HMP-35D W/m2 2m+8m+21.5m Latent Heat Storage,19-5 -US-NR1,SWC_1,,-0.1,SWC-TDR,,SWC_1 h2o_soil1 Campbell CS615 (multiple sensors) percent 0 to -10 cm Volumetric Soil Moisture (percentage),19-5 -US-NR1,SWC_1_1_1,,-0.05,SWC-TDR,,SWC_1_1_1 h2o_soil2 Campbell CS616 percent -5cm Volumetric Soil Moisture (percentage),19-5 -US-NR1,SWC_PI_F_1,,-0.1,SWC-TDR,,SWC_F_1 h2o_soil1 Campbell CS615 (multiple sensors) percent 0 to -10 cm Volumetric Soil Moisture (percentage),19-5 -US-NR1,SWC_PI_F_1_1_1,,-0.05,SWC-TDR,,SWC_F_1_1_1 h2o_soil2 Campbell CS616 percent -5cm Volumetric Soil Moisture (percentage),19-5 -US-NR1,SW_IN_1_1_1,,25.5,RAD-Pyrrad-SW+LW,,SW_IN_1_1_1 Rsw_in_25m_KZ Kipp and Zonen CNR1 W/m2 25.5m Incoming Shortwave Radiation,19-5 -US-NR1,SW_IN_PI_F_1_1_1,,25.5,RAD-Pyrrad-SW+LW,,SW_IN_F_1_1_1 Rsw_in_25m_KZ Kipp and Zonen CNR1 W/m2 25.5m Incoming Shortwave Radiation,19-5 -US-NR1,SW_OUT_1_1_1,,25.5,RAD-Pyrrad-SW+LW,,SW_OUT_1_1_1 Rsw_out_25m_KZ Kipp and Zonen CNR1 W/m2 25.5m Outgoing Shortwave Radiation,19-5 -US-NR1,SW_OUT_PI_F_1_1_1,,25.5,RAD-Pyrrad-SW+LW,,SW_OUT_F_1_1_1 Rsw_out_25m_KZ Kipp and Zonen CNR1 W/m2 25.5m Outgoing Shortwave Radiation,19-5 -US-NR1,TA_1_1_1,,21.5,TEMP-Thermis,,TA_1_1_1 T_21m Vaisala HMP-35D degC 21.5m Air Temperatur,19-5 -US-NR1,TA_1_2_1,,8,TEMP-Thermis,,TA_1_2_1 T_8m Vaisala HMP-35D degC 8m Air Temperature,19-5 -US-NR1,TA_1_3_1,,2,TEMP-Thermis,,TA_1_3_1 T_2m Vaisala HMP-35D or HMP-45D degC 2m Air Temperature,19-5 -US-NR1,TA_PI_F_1_1_1,,21.5,TEMP-Thermis,,TA_F_1_1_1 T_21m Vaisala HMP-35D degC 21.5m Air Temperatur,19-5 -US-NR1,TA_PI_F_1_2_1,,8,TEMP-Thermis,,TA_F_1_2_1 T_8m Vaisala HMP-35D degC 8m Air Temperature,19-5 -US-NR1,TA_PI_F_1_3_1,,2,TEMP-Thermis,,TA_F_1_3_1 T_2m Vaisala HMP-35D or HMP-45D degC 2m Air Temperature,19-5 -US-NR1,TAU_1_1_1,,21.5,SA-Campbell CSAT-3,,TAU_1_1_1 Taua_21m CSAT3 Sonic kg/m/s2 21.5m Momentum Flux,19-5 -US-NR1,TAU_PI_F_1_1_1,,21.5,SA-Campbell CSAT-3,,TAU_F_1_1_1 Taua_21m CSAT3 Sonic kg/m/s2 21.5m Momentum Flux,19-5 -US-NR1,T_BOLE_1,,1.5,TEMP-TCouple,,T_BOLE_1 T_bole_pine Campbell A3537 (T-type Thermocouples) degC 3 cm in bole Pine Bole Temperature,19-5 -US-NR1,T_BOLE_2,,1.5,TEMP-TCouple,,T_BOLE_2 T_bole_fir Campbell A3537 (T-type Thermocouples) degC 2 cm in bole Fir Bole Temperature,19-5 -US-NR1,T_BOLE_3,,1.5,TEMP-TCouple,,T_BOLE_3 T_bole_spruce Campbell A3537 (T-type Thermocouples) degC 2 cm in bole Spruce Bole Temperature,19-5 -US-NR1,T_BOLE_PI_F_1,,1.5,TEMP-TCouple,,T_BOLE_F_1 T_bole_pine Campbell A3537 (T-type Thermocouples) degC 3 cm in bole Pine Bole Temperature,19-5 -US-NR1,T_BOLE_PI_F_2,,1.5,TEMP-TCouple,,T_BOLE_F_2 T_bole_fir Campbell A3537 (T-type Thermocouples) degC 2 cm in bole Fir Bole Temperature,19-5 -US-NR1,T_BOLE_PI_F_3,,1.5,TEMP-TCouple,,T_BOLE_F_3 T_bole_spruce Campbell A3537 (T-type Thermocouples) degC 2 cm in bole Spruce Bole Temperature,19-5 -US-NR1,TS_1,,-0.10,TEMP-Thermis,,TS_F_1 T_soil1 REBS STP-1 (multiple sensors) degC 0 to -10 cm Soil Temperature,19-5 -US-NR1,TS_1_1_1,,-0.05,TEMP-Thermis,,TS_1_1_1 T_soil2 Campbell 107L (thermistor) degC -5cm Soil Temperature,19-5 -US-NR1,TS_PI_F_1,,-0.10,TEMP-ElectResis,,TS_F_1 T_soil1 REBS STP-1 (multiple sensors) degC 0 to -10 cm Soil Temperature,19-5 -US-NR1,TS_PI_F_1_1_1,,-0.05,TEMP-Thermis,,TS_F_1_1_1 T_soil2 Campbell 107L (thermistor) degC -5cm Soil Temperature,19-5 -US-NR1,USTAR_1_1_1,,21.5,SA-Campbell CSAT-3,,USTAR_1_1_1 ustar_21m Campbell Scientific CSAT3 Sonic m/s 21.5m Friction Velocity,19-5 -US-NR1,USTAR_PI_F_1_1_1,,21.5,SA-Campbell CSAT-3,,USTAR_F_1_1_1 ustar_21m Campbell Scientific CSAT3 Sonic m/s 21.5m Friction Velocity,19-5 -US-NR1,VPD_PI_1_1_1,,21.5,RH-Capac,,VPD_1_1_1 vpd_21m Vaisala HMP-35D hPa 21.5m Vapor Pressure Deficit,19-5 -US-NR1,VPD_PI_1_2_1,,8,RH-Capac,,VPD_1_2_1 vpd_8m Vaisala HMP-35D hPa 8m Vapor Pressure Deficit,19-5 -US-NR1,VPD_PI_1_3_1,,2,RH-Capac,,VPD_1_3_1 vpd_2m Vaisala HMP-35D or HMP-45D hPa 2m Vapor Pressure Deficit,19-5 -US-NR1,VPD_PI_F_1_1_1,,21.5,RH-Capac,,VPD_F_1_1_1 vpd_21m Vaisala HMP-35D hPa 21.5m Vapor Pressure Deficit,19-5 -US-NR1,VPD_PI_F_1_2_1,,8,RH-Capac,,VPD_F_1_2_1 vpd_8m Vaisala HMP-35D hPa 8m Vapor Pressure Deficit,19-5 -US-NR1,VPD_PI_F_1_3_1,,2,RH-Capac,,VPD_F_1_3_1 vpd_2m Vaisala HMP-35D or HMP-45D hPa 2m Vapor Pressure Deficit,19-5 -US-NR1,WD_1_1_1,,21.5,SA-Campbell CSAT-3,,WD_1_1_1 wd_21m Campbell Scientific CSAT3 Sonic deg from N 21.5m Wind Direction (from true North),19-5 -US-NR1,WD_PI_F_1_1_1,,21.5,SA-Campbell CSAT-3,,WD_F_1_1_1 wd_21m Campbell Scientific CSAT3 Sonic deg from N 21.5m Wind Direction (from true North),19-5 -US-NR1,WS_1_1_1,,21.5,SA-Campbell CSAT-3,,WS_1_1_1 ws_21m Campbell Scientific CSAT3 Sonic m/s 21.5m Wind Speed,19-5 -US-NR1,WS_PI_F_1_1_1,,21.5,SA-Campbell CSAT-3,,WS_F_1_1_1 ws_21m Campbell Scientific CSAT3 Sonic m/s 21.5m Wind Speed,19-5 -US-NR1,ZL_1_1_1,,21.5,SA-Campbell CSAT-3,,ZL_1_1_1 z_L_21m Campbell Scientific CSAT3 Sonic NA 21.5m Stability Parameter,19-5 -US-NR1,ZL_PI_F_1_1_1,,21.5,SA-Campbell CSAT-3,,ZL_F_1_1_1 z_L_21m Campbell Scientific CSAT3 Sonic NA 21.5m Stability Parameter,19-5 -US-NR3,CO2,200705,3,GA_OP-LI-COR LI-7500,,,3-5 -US-NR3,D_SNOW,200705,3,SNOW-Acoustic,,,3-5 -US-NR3,D_SNOW,20210826,3,SNOW-Acoustic,,Old SR50 replaced with new SR50a,3-5 -US-NR3,FC,200705,3,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,3-5 -US-NR3,G,200705,-0.02,SOIL_H-Plate,,,3-5 -US-NR3,G,20211019,-0.02,SOIL_H-Plate,,old HFT3s replaced with new HFP01s,3-5 -US-NR3,H,200705,3,SA-Campbell CSAT-3,,,3-5 -US-NR3,H2O,200705,3,GA_OP-LI-COR LI-7500,,,3-5 -US-NR3,LE,200705,3,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,3-5 -US-NR3,NETRAD,200705,3,RAD-Net radiometer,,,3-5 -US-NR3,PA,200705,3,GA_OP-LI-COR LI-7500,,,3-5 -US-NR3,RH,200705,3,RH-Capac,,,3-5 -US-NR3,SWC_1_1_1,20080918,-0.1,SWC-FDR,,,3-5 -US-NR3,SWC_1_2_1,20080918,-0.2,SWC-FDR,,,3-5 -US-NR3,SWC_1_3_1,20080918,-0.3,SWC-FDR,,,3-5 -US-NR3,SWC_1_4_1,20080918,-0.5,SWC-FDR,,,3-5 -US-NR3,SWC_1_5_1,20080918,-0.7,SWC-FDR,,,3-5 -US-NR3,SWC_1_6_1,20080918,-1,SWC-FDR,,,3-5 -US-NR3,SWC_1_7_1,20080918,-1.5,SWC-FDR,,,3-5 -US-NR3,SWC_1_8_1,20080918,-2,SWC-FDR,,,3-5 -US-NR3,TA,200705,3,TEMP-ElectResis,,,3-5 -US-NR3,TS,20131003,-0.1,TEMP-TCouple,,,3-5 -US-NR3,T_SONIC,200705,3,SA-Campbell CSAT-3,,,3-5 -US-NR3,USTAR,200705,3,SA-Campbell CSAT-3,,,3-5 -US-NR3,VPD_PI,200705,3,RH-Capac,,,3-5 -US-NR3,WD,200705,3,GA_OP-LI-COR LI-7500,,,3-5 -US-NR3,WS,200705,3,GA_OP-LI-COR LI-7500,,,3-5 -US-NR4,CO2,200706,3,GA_OP-LI-COR LI-7500,,,3-5 -US-NR4,D_SNOW,200706,3,SNOW-Acoustic,,,3-5 -US-NR4,D_SNOW,20210719,3,SNOW-Acoustic,,Old SR50 replaced with new SR50a,3-5 -US-NR4,FC,200706,3,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,3-5 -US-NR4,G,200706,-0.02,SOIL_H-Plate,,,3-5 -US-NR4,H,200706,3,SA-Campbell CSAT-3,,,3-5 -US-NR4,H2O,200706,3,GA_OP-LI-COR LI-7500,,,3-5 -US-NR4,LE,200706,3,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,3-5 -US-NR4,NETRAD,200706,3,RAD-Net radiometer,,,3-5 -US-NR4,PA,200706,3,GA_OP-LI-COR LI-7500,,,3-5 -US-NR4,PPFD_IN,20210729,3,RAD-PAR Quantum,,,3-5 -US-NR4,RH,200706,3,RH-Capac,,,3-5 -US-NR4,TA,200706,3,TEMP-ElectResis,,,3-5 -US-NR4,TS,20131003,-0.1,TEMP-TCouple,,,3-5 -US-NR4,T_SONIC,200706,3,SA-Campbell CSAT-3,,,3-5 -US-NR4,USTAR,200706,3,SA-Campbell CSAT-3,,,3-5 -US-NR4,VPD_PI,200706,3,RH-Capac,,,3-5 -US-NR4,WD,200706,3,SA-Campbell CSAT-3,,,3-5 -US-NR4,WS,200706,3,SA-Campbell CSAT-3,,,3-5 -US-Oho,CO2,200911,34,GA_OP-LI-COR LI-7500,,,7-5 -US-Oho,CO2,,32,GA_OP-LI-COR LI-7500,,,7-5 -US-Oho,FC,200911,34,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,7-5 -US-Oho,FC,,32,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,7-5 -US-Oho,G_1_1_1,,-0.1,SOIL_H-Plate,,,7-5 -US-Oho,H,200911,34,SA-Campbell CSAT-3,,,7-5 -US-Oho,H,,32,SA-Campbell CSAT-3,,,7-5 -US-Oho,H2O,200911,34,SA-Campbell CSAT-3,,,7-5 -US-Oho,H2O,,32,GA_OP-LI-COR LI-7500,,,7-5 -US-Oho,LE,200911,34,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,7-5 -US-Oho,LE,,32,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,7-5 -US-Oho,LW_IN,,33,RAD-Pyrrad-SW+LW,,,7-5 -US-Oho,LW_OUT,,33,RAD-Pyrrad-SW+LW,,,7-5 -US-Oho,NEE_PI,,,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,7-5 -US-Oho,NETRAD,,33,RAD-Pyrrad-SW+LW,,,7-5 -US-Oho,P,,28.8,RAIN-TipBucGauge,,,7-5 -US-Oho,PA,,32,PRES-ElectBar,,,7-5 -US-Oho,PPFD_IN,,33,RAD-PAR Quantum,,,7-5 -US-Oho,RH_1_1_1,,33,RH-Capac,,,7-5 -US-Oho,SC,,16,GA_SR-LI-COR LI-820,,,7-5 -US-Oho,SWC,,-0.15,SWC-TDR,,,7-5 -US-Oho,SW_IN,,33,RAD-Pyrrad-SW+LW,,,7-5 -US-Oho,SW_OUT,,33,RAD-Pyrrad-SW+LW,,,7-5 -US-Oho,TA_1_1_1,,33,TEMP-ElectResis,,,7-5 -US-Oho,TS_1_1_1,,-0.05,TEMP-Thermis,,,7-5 -US-Oho,TS_1_2_1,,-0.25,TEMP-Thermis,,,7-5 -US-Oho,USTAR,200911,34,SA-Campbell CSAT-3,,,7-5 -US-Oho,USTAR,,32,SA-Campbell CSAT-3,,,7-5 -US-Oho,WD,200911,34,SA-Campbell CSAT-3,,,7-5 -US-Oho,WD,,32,SA-Campbell CSAT-3,,,7-5 -US-Oho,WS,200911,34,SA-Campbell CSAT-3,,,7-5 -US-Oho,WS,,32,SA-Campbell CSAT-3,,,7-5 -US-ONA,CO2,,2.8,GA_OP_SA-Campbell IRGASON,,,3-5 -US-ONA,CO2_SIGMA,,2.8,GA_OP_SA-Campbell IRGASON,,,3-5 -US-ONA,FC,,2.8,GA_OP_SA-Campbell IRGASON,,,3-5 -US-ONA,FC_SSITC_TEST,,2.8,GA_OP_SA-Campbell IRGASON,,,3-5 -US-ONA,FETCH_70,,2.8,GA_OP_SA-Campbell IRGASON,,,3-5 -US-ONA,FETCH_90,,2.8,GA_OP_SA-Campbell IRGASON,,,3-5 -US-ONA,FETCH_MAX,,2.8,GA_OP_SA-Campbell IRGASON,,,3-5 -US-ONA,G_1_1_1,,-0.1,SOIL_H-Plate,,,3-5 -US-ONA,G_1_2_1,,-0.1,SOIL_H-Plate,,,3-5 -US-ONA,G_1_3_1,,-0.1,SOIL_H-Plate,,,3-5 -US-ONA,G_1_4_1,,-0.1,SOIL_H-Plate,,,3-5 -US-ONA,H,,2.8,GA_OP_SA-Campbell IRGASON,,,3-5 -US-ONA,H2O,,2.8,GA_OP_SA-Campbell IRGASON,,,3-5 -US-ONA,H2O_SIGMA,,2.8,GA_OP_SA-Campbell IRGASON,,,3-5 -US-ONA,H_SSITC_TEST,,2.8,GA_OP_SA-Campbell IRGASON,,,3-5 -US-ONA,LE,,2.8,GA_OP_SA-Campbell IRGASON,,,3-5 -US-ONA,LE_SSITC_TEST,,2.8,GA_OP_SA-Campbell IRGASON,,,3-5 -US-ONA,LW_IN,,2.8,RAD-Pyrrad-SW+LW,,,3-5 -US-ONA,LW_OUT,,2.8,RAD-Pyrrad-SW+LW,,,3-5 -US-ONA,MO_LENGTH,,2.8,GA_OP_SA-Campbell IRGASON,,,3-5 -US-ONA,NETRAD,,2.8,RAD-Pyrrad-SW+LW,,,3-5 -US-ONA,PA,,2.8,GA_OP_SA-Campbell IRGASON,,,3-5 -US-ONA,PPFD_IN,,2.8,RAD-PAR Quantum,,,3-5 -US-ONA,P_RAIN,,1.6,RAIN-TipBucGauge,,,3-5 -US-ONA,RH,,2.8,RH-Capac,,,3-5 -US-ONA,SC,,2.8,GA_OP_SA-Campbell IRGASON,,,3-5 -US-ONA,SH,,2.8,GA_OP_SA-Campbell IRGASON,,,3-5 -US-ONA,SLE,,2.8,GA_OP_SA-Campbell IRGASON,,,3-5 -US-ONA,SWC_1_1_1,,-0.1,SWC-TDR,,,3-5 -US-ONA,SWC_1_2_1,,-0.1,SWC-TDR,,,3-5 -US-ONA,SW_IN,,2.8,RAD-Pyrrad-SW+LW,,,3-5 -US-ONA,SW_OUT,,2.8,RAD-Pyrrad-SW+LW,,,3-5 -US-ONA,TA,,2.8,TEMP-ElectResis,,,3-5 -US-ONA,TAU,,2.8,GA_OP_SA-Campbell IRGASON,,,3-5 -US-ONA,TAU_SSITC_TEST,,2.8,GA_OP_SA-Campbell IRGASON,,,3-5 -US-ONA,TS_1_1_1,,-0.1,SWC-TDR,,,3-5 -US-ONA,TS_1_2_1,,-0.1,SWC-TDR,,,3-5 -US-ONA,T_SONIC,,2.8,GA_OP_SA-Campbell IRGASON,,,3-5 -US-ONA,T_SONIC_SIGMA,,2.8,GA_OP_SA-Campbell IRGASON,,,3-5 -US-ONA,U_SIGMA,,2.8,GA_OP_SA-Campbell IRGASON,,,3-5 -US-ONA,USTAR,,2.8,GA_OP_SA-Campbell IRGASON,,,3-5 -US-ONA,VPD_PI,,2.8,RH-Capac,,,3-5 -US-ONA,V_SIGMA,,2.8,GA_OP_SA-Campbell IRGASON,,,3-5 -US-ONA,WD,,2.8,GA_OP_SA-Campbell IRGASON,,,3-5 -US-ONA,WS,,2.8,GA_OP_SA-Campbell IRGASON,,,3-5 -US-ONA,W_SIGMA,,2.8,GA_OP_SA-Campbell IRGASON,,,3-5 -US-ONA,WS_MAX,,2.8,GA_OP_SA-Campbell IRGASON,,,3-5 -US-ONA,ZL,,2.8,GA_OP_SA-Campbell IRGASON,,,3-5 -US-ORv,CH4,20120401,15,GA_OP-LI-COR LI-7700,,,3-5 -US-ORv,CH4,20131001,12,GA_OP-LI-COR LI-7700,,,3-5 -US-ORv,CH4,20140401,15,GA_OP-LI-COR LI-7700,,,3-5 -US-ORv,CH4,,9.6,GA_OP-LI-COR LI-7700,,,3-5 -US-ORv,CO2,20120401,15,GA_OP-LI-COR LI-7500,,,3-5 -US-ORv,CO2,20131001,12,GA_OP-LI-COR LI-7500,,,3-5 -US-ORv,CO2,20140401,15,GA_OP-LI-COR LI-7500,,,3-5 -US-ORv,CO2,,9.6,GA_OP-LI-COR LI-7500,,,3-5 -US-ORv,FC,20120401,15,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,3-5 -US-ORv,FC,20131001,12,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,3-5 -US-ORv,FC,20140401,15,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,3-5 -US-ORv,FC,,9.6,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,3-5 -US-ORv,FCH4,20120401,15,GA_OP-LI-COR LI-7700,SA-Campbell CSAT-3,,3-5 -US-ORv,FCH4,20131001,12,GA_OP-LI-COR LI-7700,SA-Campbell CSAT-3,,3-5 -US-ORv,FCH4,20140401,15,GA_OP-LI-COR LI-7700,SA-Campbell CSAT-3,,3-5 -US-ORv,FCH4,,9.6,GA_OP-LI-COR LI-7700,SA-Campbell CSAT-3,,3-5 -US-ORv,H,20120401,15,SA-Campbell CSAT-3,,,3-5 -US-ORv,H,20131001,12,SA-Campbell CSAT-3,,,3-5 -US-ORv,H,20140401,15,SA-Campbell CSAT-3,,,3-5 -US-ORv,H,,9.6,SA-Campbell CSAT-3,,,3-5 -US-ORv,H2O,20120401,15,GA_OP-LI-COR LI-7500,,,3-5 -US-ORv,H2O,20131001,12,GA_OP-LI-COR LI-7500,,,3-5 -US-ORv,H2O,20140401,15,GA_OP-LI-COR LI-7500,,,3-5 -US-ORv,H2O,,9.6,GA_OP-LI-COR LI-7500,,,3-5 -US-ORv,LE,20120401,15,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,3-5 -US-ORv,LE,20131001,12,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,3-5 -US-ORv,LE,20140401,15,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,3-5 -US-ORv,LE,,9.6,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,3-5 -US-ORv,LW_IN_PI_F,20120401,15,RAD-Pyrrad-SW+LW,,,3-5 -US-ORv,LW_IN_PI_F,,9.6,RAD-Pyrrad-SW+LW,,,3-5 -US-ORv,LW_OUT_PI_F,20120401,15,RAD-Pyrrad-SW+LW,,,3-5 -US-ORv,LW_OUT_PI_F,,9.6,RAD-Pyrrad-SW+LW,,,3-5 -US-ORv,NETRAD_PI_F,20120401,15,RAD-Pyrrad-SW+LW,,,3-5 -US-ORv,NETRAD_PI_F,,9.6,RAD-Pyrrad-SW+LW,,,3-5 -US-ORv,PA,20120401,15,GA_OP-LI-COR LI-7500,,,3-5 -US-ORv,PA,20131001,12,GA_OP-LI-COR LI-7500,,,3-5 -US-ORv,PA,20140401,15,GA_OP-LI-COR LI-7500,,,3-5 -US-ORv,PA,,9.6,GA_OP-LI-COR LI-7500,,,3-5 -US-ORv,PPFD_IN,20120401,15,RAD-PAR Quantum,,,3-5 -US-ORv,PPFD_IN,,9.6,RAD-PAR Quantum,,,3-5 -US-ORv,RECO_PI,20120401,15,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,3-5 -US-ORv,RECO_PI,20131001,12,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,3-5 -US-ORv,RECO_PI,20140401,15,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,3-5 -US-ORv,RECO_PI,,9.6,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,3-5 -US-ORv,RH,20120401,15,RH-Capac,,,3-5 -US-ORv,RH,20131001,12,RH-Capac,,,3-5 -US-ORv,RH,20140401,15,RH-Capac,,,3-5 -US-ORv,RH,,9.6,RH-Capac,,,3-5 -US-ORv,SC,20120401,15,GA_OP-LI-COR LI-7500,,,3-5 -US-ORv,SC,20131001,12,GA_OP-LI-COR LI-7500,,,3-5 -US-ORv,SC,20140401,15,GA_OP-LI-COR LI-7500,,,3-5 -US-ORv,SC,,9.6,GA_OP-LI-COR LI-7500,,,3-5 -US-ORv,SW_IN_PI_F,20120401,15,RAD-Pyrrad-SW+LW,,,3-5 -US-ORv,SW_IN_PI_F,,9.6,RAD-Pyrrad-SW+LW,,,3-5 -US-ORv,SW_OUT_PI_F,20120401,15,RAD-Pyrrad-SW+LW,,,3-5 -US-ORv,SW_OUT_PI_F,,9.6,RAD-Pyrrad-SW+LW,,,3-5 -US-ORv,TA,20120401,15,TEMP-ElectResis,,,3-5 -US-ORv,TA,20131001,12,TEMP-ElectResis,,,3-5 -US-ORv,TA,20140401,15,TEMP-ElectResis,,,3-5 -US-ORv,TA,,9.6,TEMP-ElectResis,,,3-5 -US-ORv,TS_1_1_1,,-0.08,TEMP-Thermis,,,3-5 -US-ORv,USTAR,20120401,15,SA-Campbell CSAT-3,,,3-5 -US-ORv,USTAR,20131001,12,SA-Campbell CSAT-3,,,3-5 -US-ORv,USTAR,20140401,15,SA-Campbell CSAT-3,,,3-5 -US-ORv,USTAR,,9.6,SA-Campbell CSAT-3,,,3-5 -US-ORv,WD,20120401,15,SA-Campbell CSAT-3,,,3-5 -US-ORv,WD,20131001,12,SA-Campbell CSAT-3,,,3-5 -US-ORv,WD,20140401,15,SA-Campbell CSAT-3,,,3-5 -US-ORv,WD,,9.6,SA-Campbell CSAT-3,,,3-5 -US-ORv,WS,20120401,15,SA-Campbell CSAT-3,,,3-5 -US-ORv,WS,20131001,12,SA-Campbell CSAT-3,,,3-5 -US-ORv,WS,20140401,15,SA-Campbell CSAT-3,,,3-5 -US-ORv,WS,,9.6,SA-Campbell CSAT-3,,,3-5 -US-OWC,CH4,20150601,3.2,GA_OP-LI-COR LI-7700,,,2-5 -US-OWC,CH4,20170801,5.2,GA_OP-LI-COR LI-7700,,,2-5 -US-OWC,CH4,201805,5.77,GA_OP-LI-COR LI-7700,,,2-5 -US-OWC,CO2,20150601,3.2,GA_OP-LI-COR LI-7500,,,2-5 -US-OWC,CO2,20170801,5.2,GA_OP-LI-COR LI-7500,,,2-5 -US-OWC,CO2,201805,5.5,GA_OP-LI-COR LI-7500,,,2-5 -US-OWC,CO2,20210730,5.03,GA_OP-Campbell EC150,,,2-5 -US-OWC,FC,20150601,3.2,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,2-5 -US-OWC,FC,20170801,5.2,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,2-5 -US-OWC,FC,20210730,5.03,GA_OP-Campbell EC150,SA-Campbell CSAT-3,,2-5 -US-OWC,FCH4,20150601,3.2,GA_OP-LI-COR LI-7700,SA-Campbell CSAT-3,,2-5 -US-OWC,FCH4,20170801,5.2,GA_OP-LI-COR LI-7700,SA-Campbell CSAT-3,,2-5 -US-OWC,FCH4,20210730,5.03,GA_OP-LI-COR LI-7700,SA-Campbell CSAT-3,,2-5 -US-OWC,FCH4_PI_F,20210730,5.03,SA-Campbell CSAT-3,GA_OP-LI-COR LI-7700,,2-5 -US-OWC,FCH4_PI_F,,5.2,GA_OP-LI-COR LI-7700,SA-Campbell CSAT-3,,2-5 -US-OWC,GPP_PI,20150601,3.2,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,2-5 -US-OWC,GPP_PI,20170801,5.2,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,2-5 -US-OWC,GPP_PI,20210730,5.03,GA_OP-Campbell EC150,SA-Campbell CSAT-3,,2-5 -US-OWC,GPP_PI_F,20150601,3.2,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,2-5 -US-OWC,GPP_PI_F,20170801,5.2,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,2-5 -US-OWC,GPP_PI_F,20210730,5.03,GA_OP-Campbell EC150,SA-Campbell CSAT-3,,2-5 -US-OWC,H,20150601,3.2,SA-Campbell CSAT-3,,,2-5 -US-OWC,H,20170801,5.2,SA-Campbell CSAT-3,,,2-5 -US-OWC,H,20210730,5.03,SA-Campbell CSAT-3,,,2-5 -US-OWC,H2O,20150601,3.2,GA_OP-LI-COR LI-7500,,,2-5 -US-OWC,H2O,20170801,5.2,GA_OP-LI-COR LI-7500,,,2-5 -US-OWC,H2O,20210730,5.03,GA_OP-Campbell EC150,,,2-5 -US-OWC,H_PI_F,20150601,3.2,SA-Campbell CSAT-3,,,2-5 -US-OWC,H_PI_F,20170801,5.2,SA-Campbell CSAT-3,,,2-5 -US-OWC,H_PI_F,20210730,5.03,SA-Campbell CSAT-3,,,2-5 -US-OWC,LE,20150601,3.2,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,2-5 -US-OWC,LE,20170801,5.2,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,2-5 -US-OWC,LE,20210730,5.03,GA_OP-Campbell EC150,SA-Campbell CSAT-3,,2-5 -US-OWC,LE_PI_F,20150601,3.2,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,2-5 -US-OWC,LE_PI_F,20170801,5.2,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,UPDATE CHANGE IN HEIGHT. ESTIMATED,2-5 -US-OWC,LE_PI_F,20210730,5.03,GA_OP-Campbell EC150,SA-Campbell CSAT-3,,2-5 -US-OWC,LW_IN,20150601,3.2,RAD-Pyrrad-SW+LW,,,2-5 -US-OWC,LW_IN,20170801,5.2,RAD-Pyrrad-SW+LW,,,2-5 -US-OWC,LW_IN,20210730,5.03,RAD-Pyrrad-SW+LW,,,2-5 -US-OWC,LW_OUT,20150601,3.2,RAD-Pyrrad-SW+LW,,,2-5 -US-OWC,LW_OUT,20170801,5.2,RAD-Pyrrad-SW+LW,,,2-5 -US-OWC,LW_OUT,20210730,5.03,RAD-Pyrrad-SW+LW,,,2-5 -US-OWC,MO_LENGTH,20150601,3.2,SA-Campbell CSAT-3,,,2-5 -US-OWC,MO_LENGTH,20170801,5.2,SA-Campbell CSAT-3,,,2-5 -US-OWC,MO_LENGTH,20210730,5.03,SA-Campbell CSAT-3,,,2-5 -US-OWC,NEE_PI,20150601,3.2,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,2-5 -US-OWC,NEE_PI,20170801,5.2,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,UPDATE CHANGE IN HEIGHT. ESTIMATED,2-5 -US-OWC,NEE_PI,20210730,5.03,GA_OP-Campbell EC150,SA-Campbell CSAT-3,,2-5 -US-OWC,NEE_PI_F,20150601,3.2,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,2-5 -US-OWC,NEE_PI_F,20170801,5.2,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,2-5 -US-OWC,NEE_PI_F,20210730,5.03,GA_OP-Campbell EC150,SA-Campbell CSAT-3,,2-5 -US-OWC,NETRAD,20150601,3.2,RAD-Pyrrad-SW+LW,,,2-5 -US-OWC,NETRAD,20170801,5.2,RAD-Pyrrad-SW+LW,,,2-5 -US-OWC,NETRAD,20210730,5.03,RAD-Pyrrad-SW+LW,,,2-5 -US-OWC,P,,0,PREC-TipBucGauge,,,2-5 -US-OWC,PA,20150601,3.2,GA_OP-LI-COR LI-7700,,,2-5 -US-OWC,PA,20170801,5.2,GA_OP-LI-COR LI-7700,,,2-5 -US-OWC,PA,201805,5.77,GA_OP-LI-COR LI-7700,,,2-5 -US-OWC,PA_PI_F,20150601,3.2,GA_OP-LI-COR LI-7700,,,2-5 -US-OWC,PA_PI_F,20170801,5.2,GA_OP-LI-COR LI-7700,,,2-5 -US-OWC,PA_PI_F,201805,5.77,GA_OP-LI-COR LI-7700,,,2-5 -US-OWC,PPFD_IN,,2.4,RAD-PAR Quantum,,,2-5 -US-OWC,RECO_PI,20150601,3.2,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,2-5 -US-OWC,RECO_PI,20170801,5.2,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,2-5 -US-OWC,RECO_PI,20210730,5.03,GA_OP-Campbell EC150,SA-Campbell CSAT-3,,2-5 -US-OWC,RECO_PI_F,20150601,3.2,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,2-5 -US-OWC,RECO_PI_F,20170801,5.2,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,2-5 -US-OWC,RECO_PI_F,20210730,5.03,GA_OP-Campbell EC150,SA-Campbell CSAT-3,,2-5 -US-OWC,RH,20150601,3.2,RH-Other,,,2-5 -US-OWC,RH,20170801,5.2,RH-Other,,,2-5 -US-OWC,RH_PI_F,20150601,3.2,RH-Other,,,2-5 -US-OWC,RH_PI_F,20170801,5.2,RH-Other,,,2-5 -US-OWC,SW_IN,20150601,3.2,RAD-Pyrrad-SW+LW,,,2-5 -US-OWC,SW_IN,20170801,5.2,RAD-Pyrrad-SW+LW,,,2-5 -US-OWC,SW_IN,20210730,5.03,RAD-Pyrrad-SW+LW,,,2-5 -US-OWC,SW_OUT,20150601,3.2,RAD-Pyrrad-SW+LW,,,2-5 -US-OWC,SW_OUT,20170801,5.2,RAD-Pyrrad-SW+LW,,,2-5 -US-OWC,SW_OUT,20210730,5.03,RAD-Pyrrad-SW+LW,,,2-5 -US-OWC,TA,20150601,3.2,TEMP-ElectResis,,,2-5 -US-OWC,TA,20170801,5.2,TEMP-ElectResis,,,2-5 -US-OWC,TA_PI_F,20150601,3.2,TEMP-ElectResis,,,2-5 -US-OWC,TA_PI_F,20170801,5.2,TEMP-ElectResis,,,2-5 -US-OWC,TS_1,,-0.1,TEMP-Thermis,,,2-5 -US-OWC,TS_2,,-0.4,TEMP-Thermis,,,2-5 -US-OWC,USTAR,20150601,3.2,SA-Campbell CSAT-3,,,2-5 -US-OWC,USTAR,20170801,5.2,SA-Campbell CSAT-3,,,2-5 -US-OWC,USTAR,20210730,5.03,SA-Campbell CSAT-3,,,2-5 -US-OWC,VPD_PI,20150601,3.2,RH-Other,,,2-5 -US-OWC,VPD_PI,20170801,5.2,RH-Other,,,2-5 -US-OWC,VPD_PI_F,20150601,3.2,RH-Other,,,2-5 -US-OWC,VPD_PI_F,20170801,5.2,RH-Other,,,2-5 -US-OWC,WD,20150601,3.2,SA-Campbell CSAT-3,,,2-5 -US-OWC,WD,20170801,5.2,SA-Campbell CSAT-3,,,2-5 -US-OWC,WD,20210730,5.03,SA-Campbell CSAT-3,,,2-5 -US-OWC,WD_PI_F,20150601,3.2,SA-Campbell CSAT-3,,,2-5 -US-OWC,WD_PI_F,20170801,5.2,SA-Campbell CSAT-3,,,2-5 -US-OWC,WD_PI_F,20210730,5.03,SA-Campbell CSAT-3,,,2-5 -US-OWC,WS,20150601,3.2,SA-Campbell CSAT-3,,,2-5 -US-OWC,WS,20170801,5.2,SA-Campbell CSAT-3,,,2-5 -US-OWC,WS,20210730,5.03,SA-Campbell CSAT-3,,,2-5 -US-OWC,WS_PI_F,20150601,3.2,SA-Campbell CSAT-3,,,2-5 -US-OWC,WS_PI_F,20170801,5.2,SA-Campbell CSAT-3,,,2-5 -US-OWC,WS_PI_F,20210730,5.03,SA-Campbell CSAT-3,,,2-5 -US-OWC,WTD,,-0,WTD-Other,,Sensor height is 4.2m,2-5 -US-PFa,CH4_1_1_1,,396,GA_CP-LGR 911-0010,,,20-5 -US-PFa,CH4_1_2_1,,122,GA_CP-LGR 911-0010,,,20-5 -US-PFa,CH4_1_3_1,,30,GA_CP-LGR 911-0010,,,20-5 -US-PFa,CH4_1_4_1,,,GA_CP-LGR 911-0010,,,20-5 -US-PFa,CH4_DF_1_4_1,,,GA_CP-LGR 911-0010,,,20-5 -US-PFa,CO2_1_1_1,,396,GA_CP-LI-COR LI-7000,,,20-5 -US-PFa,CO2_1_2_1,,244,GA_CP-LI-COR LI-7000,,,20-5 -US-PFa,CO2_1_3_1,,122,GA_CP-LI-COR LI-7000,,,20-5 -US-PFa,CO2_1_4_1,,76,GA_CP-LI-COR LI-7000,,,20-5 -US-PFa,CO2_1_5_1,,30,GA_CP-LI-COR LI-7000,,,20-5 -US-PFa,CO2_1_6_1,,11,GA_CP-LI-COR LI-7000,,,20-5 -US-PFa,CO2_1_7_1,,,GA_CP-LI-COR LI-7000,,,20-5 -US-PFa,FC_1_1_1,20190530,396,GA_CP-LI-COR LI-7200RS,SA-ATI SATI K Style,,20-5 -US-PFa,FC_1_1_1,,396,GA_CP-LI-COR LI-6262,SA-ATI SATI K Style,,20-5 -US-PFa,FC_1_2_1,20190530,122,GA_CP-LI-COR LI-7200RS,SA-ATI SATI K Style,,20-5 -US-PFa,FC_1_2_1,,122,GA_CP-LI-COR LI-6262,SA-ATI SATI K Style,,20-5 -US-PFa,FC_1_3_1,20190530,30,GA_CP-LI-COR LI-7200RS,SA-ATI SATI K Style,,20-5 -US-PFa,FC_1_3_1,,30,GA_CP-LI-COR LI-6262,SA-ATI SATI K Style,,20-5 -US-PFa,FC_1_4_1,20190530,,GA_CP-LI-COR LI-7200RS,SA-ATI SATI K Style,,20-5 -US-PFa,FC_1_4_1,,,GA_CP-LI-COR LI-6262,SA-ATI SATI K Style,,20-5 -US-PFa,FCH4,,122,GA_CP-Picarro G1301-f,SA-ATI SATI K Style,,20-5 -US-PFa,FH2O,20190530,,GA_CP-LI-COR LI-7200RS,,,20-5 -US-PFa,FH2O,,,GA_CP-LI-COR LI-6262,,,20-5 -US-PFa,GPP_PI_F,20190530,,GA_CP-LI-COR LI-7200RS,SA-ATI SATI K Style,,20-5 -US-PFa,GPP_PI_F,,,GA_CP-LI-COR LI-6262,SA-ATI SATI K Style,,20-5 -US-PFa,H_1_1_1,,396,SA-ATI SATI K Style,,,20-5 -US-PFa,H_1_2_1,,122,SA-ATI SATI K Style,,,20-5 -US-PFa,H_1_3_1,,30,SA-ATI SATI K Style,,,20-5 -US-PFa,H_1_4_1,,,SA-ATI SATI K Style,,,20-5 -US-PFa,H2O_1_1_1,20190530,396,GA_CP-LI-COR LI-7200RS,,,20-5 -US-PFa,H2O_1_1_1,,396,GA_CP-LI-COR LI-6262,,,20-5 -US-PFa,H2O_1_2_1,20190530,122,GA_CP-LI-COR LI-7200RS,,,20-5 -US-PFa,H2O_1_2_1,,122,GA_CP-LI-COR LI-6262,,,20-5 -US-PFa,H2O_1_3_1,20190530,30,GA_CP-LI-COR LI-7200RS,,,20-5 -US-PFa,H2O_1_3_1,,30,GA_CP-LI-COR LI-6262,,,20-5 -US-PFa,H_DF_1_1_1,,,SA-ATI SATI K Style,,,20-5 -US-PFa,LE_1_1_1,20190530,396,GA_CP-LI-COR LI-7200RS,SA-ATI SATI K Style,,20-5 -US-PFa,LE_1_1_1,,396,GA_CP-LI-COR LI-6262,SA-ATI SATI K Style,,20-5 -US-PFa,LE_1_2_1,20190530,122,GA_CP-LI-COR LI-7200RS,SA-ATI SATI K Style,,20-5 -US-PFa,LE_1_2_1,,122,GA_CP-LI-COR LI-6262,SA-ATI SATI K Style,,20-5 -US-PFa,LE_1_3_1,20190530,30,GA_CP-LI-COR LI-7200RS,SA-ATI SATI K Style,,20-5 -US-PFa,LE_1_3_1,,30,GA_CP-LI-COR LI-6262,SA-ATI SATI K Style,,20-5 -US-PFa,LE_1_4_1,20190530,,GA_CP-LI-COR LI-7200RS,SA-ATI SATI K Style,,20-5 -US-PFa,LE_1_4_1,,,GA_CP-LI-COR LI-6262,SA-ATI SATI K Style,,20-5 -US-PFa,LE_DF_1_1_1,20190530,,GA_CP-LI-COR LI-7200RS,SA-ATI SATI K Style,,20-5 -US-PFa,LE_DF_1_1_1,,,GA_CP-LI-COR LI-6262,SA-ATI SATI K Style,,20-5 -US-PFa,NEE_PI_1_1_1,20190530,396,GA_CP-LI-COR LI-7200RS,SA-ATI SATI K Style,,20-5 -US-PFa,NEE_PI_1_1_1,,396,GA_CP-LI-COR LI-6262,SA-ATI SATI K Style,,20-5 -US-PFa,NEE_PI_1_2_1,20190530,122,GA_CP-LI-COR LI-7200RS,SA-ATI SATI K Style,,20-5 -US-PFa,NEE_PI_1_2_1,,122,GA_CP-LI-COR LI-6262,SA-ATI SATI K Style,,20-5 -US-PFa,NEE_PI_1_3_1,20190530,30,GA_CP-LI-COR LI-7200RS,SA-ATI SATI K Style,,20-5 -US-PFa,NEE_PI_1_3_1,,30,GA_CP-LI-COR LI-6262,SA-ATI SATI K Style,,20-5 -US-PFa,NEE_PI_1_4_1,20190530,,GA_CP-LI-COR LI-7200RS,SA-ATI SATI K Style,,20-5 -US-PFa,NEE_PI_1_4_1,,,GA_CP-LI-COR LI-6262,SA-ATI SATI K Style,,20-5 -US-PFa,NEE_PI_DF_1_4_1,20190530,,GA_CP-LI-COR LI-7200RS,SA-ATI SATI K Style,,20-5 -US-PFa,NEE_PI_DF_1_4_1,,,GA_CP-LI-COR LI-6262,SA-ATI SATI K Style,,20-5 -US-PFa,NEE_PI_F_1_4_1,,,GA_CP-LI-COR LI-6262,SA-ATI SATI K Style,,20-5 -US-PFa,P,,,RAIN-TipBucGauge,,,20-5 -US-PFa,PA,,,PRES-ElectBar,,,20-5 -US-PFa,P_CUM,,,RAIN-TipBucGauge,,,20-5 -US-PFa,PPFD_IN,,,RAD-PAR Quantum,,,20-5 -US-PFa,RECO_PI_F,20190530,,GA_CP-LI-COR LI-7200RS,SA-ATI SATI K Style,,20-5 -US-PFa,RECO_PI_F,,,GA_CP-LI-COR LI-6262,SA-ATI SATI K Style,,20-5 -US-PFa,RH,,,RH-ElecRes,,,20-5 -US-PFa,SC_1_1_1,,396,GA_CP-LI-COR LI-7000,,,20-5 -US-PFa,SC_1_2_1,,122,GA_CP-LI-COR LI-7000,,,20-5 -US-PFa,SC_1_3_1,,30,GA_CP-LI-COR LI-7000,,,20-5 -US-PFa,SC_1_4_1,,,GA_CP-LI-COR LI-7000,,,20-5 -US-PFa,SH_1_1_1,,396,TEMP-ElectResis,,,20-5 -US-PFa,SH_1_2_1,,122,TEMP-ElectResis,,,20-5 -US-PFa,SH_1_3_1,,30,TEMP-ElectResis,,,20-5 -US-PFa,SH_1_4_1,,,TEMP-ElectResis,,,20-5 -US-PFa,SLE_1_1_1,,396,RH-ElecRes,,,20-5 -US-PFa,SLE_1_2_1,,122,RH-ElecRes,,,20-5 -US-PFa,SLE_1_3_1,,30,RH-ElecRes,,,20-5 -US-PFa,SLE_1_4_1,,,RH-ElecRes,,,20-5 -US-PFa,SWC,20110719,-.05,SWC-Other,,,20-5 -US-PFa,SWC,,-.05,SWC-TDR,,,20-5 -US-PFa,TA_1_1_1,,396,TEMP-ElectResis,,,20-5 -US-PFa,TA_1_2_1,,122,TEMP-ElectResis,,,20-5 -US-PFa,TA_1_3_1,,30,TEMP-ElectResis,,,20-5 -US-PFa,USTAR_1_1_1,,396,SA-ATI SATI K Style,,,20-5 -US-PFa,USTAR_1_2_1,,122,SA-ATI SATI K Style,,,20-5 -US-PFa,USTAR_1_3_1,,30,SA-ATI SATI K Style,,,20-5 -US-PFa,USTAR_DF_1_1_1,,,SA-ATI SATI K Style,,,20-5 -US-PFa,VPD_PI,,30,RH-ElecRes,,,20-5 -US-PFa,WD_1_1_1,,396,SA-ATI SATI K Style,,,20-5 -US-PFa,WD_1_2_1,,122,SA-ATI SATI K Style,,,20-5 -US-PFa,WD_1_3_1,,30,SA-ATI SATI K Style,,,20-5 -US-PFa,WS_1_1_1,,396,SA-ATI SATI K Style,,,20-5 -US-PFa,WS_1_2_1,,122,SA-ATI SATI K Style,,,20-5 -US-PFa,WS_1_3_1,,30,SA-ATI SATI K Style,,,20-5 -US-PHM,ALB_1_1_1,,1.5,RAD-Pyrrad-SW+LW,,,3-5 -US-PHM,ALB_2_1_1,,1.5,RAD-Pyrrad-SW+LW,,,3-5 -US-PHM,CO2,,15,GA_CP-Campbell EC155,,,3-5 -US-PHM,CO2_SIGMA,,15,GA_CP-Campbell EC155,,,3-5 -US-PHM,FC,,15,SA-Campbell CSAT-3,GA_CP-Campbell EC155,,3-5 -US-PHM,FC_SSITC_TEST,,15,SA-Campbell CSAT-3,,,3-5 -US-PHM,FETCH_FILTER,,15,SA-Campbell CSAT-3,,,3-5 -US-PHM,G_1_1_1,,-0.05,SOIL_H-Plate_AUTO,,,3-5 -US-PHM,G_1_2_1,,-0.1,SOIL_H-Plate_AUTO,,,3-5 -US-PHM,GPP_PI_F,,15,SA-Campbell CSAT-3,GA_CP-Campbell EC155,,3-5 -US-PHM,H,,15,SA-Campbell CSAT-3,,,3-5 -US-PHM,H2O,,15,GA_CP-Campbell EC155,,,3-5 -US-PHM,H2O_SIGMA,,15,GA_CP-Campbell EC155,,,3-5 -US-PHM,H_SSITC_TEST,,15,SA-Campbell CSAT-3,,,3-5 -US-PHM,LE,,15,SA-Campbell CSAT-3,GA_CP-Campbell EC155,,3-5 -US-PHM,LE_SSITC_TEST,,15,SA-Campbell CSAT-3,,,3-5 -US-PHM,LW_IN_1_1_1,,1.5,RAD-Pyrrad-SW+LW,,,3-5 -US-PHM,LW_IN_2_1_1,,1.5,RAD-Pyrrad-SW+LW,,,3-5 -US-PHM,LW_OUT_1_1_1,,1.5,RAD-Pyrrad-SW+LW,,,3-5 -US-PHM,LW_OUT_2_1_1,,1.5,RAD-Pyrrad-SW+LW,,,3-5 -US-PHM,MO_LENGTH,,15,SA-Campbell CSAT-3,,,3-5 -US-PHM,NDVI_1_1_1,,1.5,RAD-Pyrrad-SW+LW,,,3-5 -US-PHM,NDVI_2_1_1,,1.5,RAD-Pyrrad-SW+LW,,,3-5 -US-PHM,NEE_PI_F,,15,SA-Campbell CSAT-3,GA_CP-Campbell EC155,,3-5 -US-PHM,NETRAD_1_1_1,,1.5,RAD-Pyrrad-SW+LW,,,3-5 -US-PHM,NETRAD_2_1_1,,1.5,RAD-Pyrrad-SW+LW,,,3-5 -US-PHM,PA,,15,PRES-ElectBar,,,3-5 -US-PHM,PPFD_IN_2_1_1,,1.5,RAD-PAR Quantum,,,3-5 -US-PHM,PPFD_IN_PI_F_1_1_1,,1.5,RAD-PAR Quantum,,,3-5 -US-PHM,PPFD_OUT_1_1_1,,1.5,RAD-PAR Quantum,,,3-5 -US-PHM,PPFD_OUT_2_1_1,,1.5,RAD-PAR Quantum,,,3-5 -US-PHM,RECO_PI_F,,15,SA-Campbell CSAT-3,GA_CP-Campbell EC155,,3-5 -US-PHM,RH_PI_F,,15,RH-Capac,,,3-5 -US-PHM,SW_IN_1_1_1,,1.5,RAD-Pyrrad-SW+LW,,,3-5 -US-PHM,SW_IN_2_1_1,,1.5,RAD-Pyrrad-SW+LW,,,3-5 -US-PHM,SW_OUT_1_1_1,,1.5,RAD-Pyrrad-SW+LW,,,3-5 -US-PHM,SW_OUT_2_1_1,,1.5,RAD-Pyrrad-SW+LW,,,3-5 -US-PHM,TA_PI_F,,15,TEMP-ElectResis,,,3-5 -US-PHM,TS_PI_F_1_1_1,,-0.05,TEMP-Other,,,3-5 -US-PHM,TS_PI_F_1_2_1,,-0.1,TEMP-Other,,,3-5 -US-PHM,TS_PI_F_1_3_1,,-0.2,TEMP-Other,,,3-5 -US-PHM,TS_PI_F_1_4_1,,-0.4,TEMP-Other,,,3-5 -US-PHM,T_SONIC,,15,SA-Campbell CSAT-3,,,3-5 -US-PHM,T_SONIC_SIGMA,,15,SA-Campbell CSAT-3,,,3-5 -US-PHM,U_SIGMA,,15,SA-Campbell CSAT-3,,,3-5 -US-PHM,USTAR,,15,SA-Campbell CSAT-3,,,3-5 -US-PHM,VPD_PI,,15,GA_CP-Campbell EC155,,,3-5 -US-PHM,V_SIGMA,,15,SA-Campbell CSAT-3,,,3-5 -US-PHM,WD,,15,SA-Campbell CSAT-3,,,3-5 -US-PHM,WS,,15,SA-Campbell CSAT-3,,,3-5 -US-PHM,W_SIGMA,,15,SA-Campbell CSAT-3,,,3-5 -US-PHM,WS_MAX,,15,SA-Campbell CSAT-3,,,3-5 -US-PHM,WTD_PI_F,,-1,WTD-Press,,,3-5 -US-PHM,ZL,,15,SA-Campbell CSAT-3,,,3-5 -US-Pnp,CO2_1_1_1,,12.4,GA_OP-LI-COR LI-7500A,,Calibrated against AOSS Rooftop Picarro,7-5 -US-Pnp,FC_1_1_1,,12.4,GA_OP-LI-COR LI-7500A,SA-Campbell CSAT-3,,7-5 -US-Pnp,H_1_1_1,,12.4,SA-Campbell CSAT-3,,,7-5 -US-Pnp,H2O_1_1_1,,12.4,GA_OP-LI-COR LI-7500A,,,7-5 -US-Pnp,LE_1_1_1,,12.4,GA_OP-LI-COR LI-7500A,SA-Campbell CSAT-3,,7-5 -US-Pnp,P,,60,RAIN-TipBucGauge,,,7-5 -US-Pnp,PA,,60,PRES-ElectBar,,AOSS Building Rooftop,7-5 -US-Pnp,RH_1_1_1,,12.4,RH-ElecRes,,,7-5 -US-Pnp,SW_IN_1_1_1,,60,RAD-SW Pyran SecSt,,AOSS Building Rooftop,7-5 -US-Pnp,TA_1_1_1,,12.4,TEMP-ElectResis,,,7-5 -US-Pnp,TW_1_1_1,,0,TEMP-ElectResis,,Mendota deep hole David buoy,7-5 -US-Pnp,USTAR_1_1_1,,12.4,SA-Campbell CSAT-3,,,7-5 -US-Pnp,VPD_PI_1_1_1,,12.4,RH-ElecRes,,,7-5 -US-Pnp,WD_1_1_1,,12.4,SA-Campbell CSAT-3,,,7-5 -US-Pnp,WS_1_1_1,,12.4,SA-Campbell CSAT-3,,,7-5 -US-Pon,CO2_1,,4.5,,,,2-1 -US-Pon,FC,,4.5,,,,2-1 -US-Pon,H,,4.5,,,,2-1 -US-Pon,LE,,4.5,,,,2-1 -US-Pon,NETRAD,,3.5,,,,2-1 -US-Pon,PA,,3.5,,,,2-1 -US-Pon,RH,,4.5,,,,2-1 -US-Pon,SW_IN,,3.5,,,,2-1 -US-Pon,SW_OUT,,3.5,,,,2-1 -US-Pon,TA,,4.5,,,,2-1 -US-Pon,WD,,4.5,,,,2-1 -US-Pon,WS,,4.5,,,,2-1 -US-Prr,CO2_1_1_1,,11,GA_CP-LI-COR LI-7200,,,3-5 -US-Prr,CO2_1_2_1,,1.9,GA_CP-LI-COR LI-7200,,,3-5 -US-Prr,FC_1_1_1,,11,GA_CP-LI-COR LI-7200,SA-Gill Windmaster Pro,,3-5 -US-Prr,FC_1_2_1,,1.9,GA_CP-LI-COR LI-7200,SA-Gill Windmaster Pro,,3-5 -US-Prr,FH2O,,11,GA_CP-LI-COR LI-7200,,,3-5 -US-Prr,G_1_1_1,,-0.08,SOIL_H-Plate_AUTO,,,3-5 -US-Prr,G_2_1_1,,-0.08,SOIL_H-Plate_AUTO,,,3-5 -US-Prr,GPP_PI_1_1_1,,11,GA_CP-LI-COR LI-7200,SA-Gill Windmaster Pro,,3-5 -US-Prr,GPP_PI_1_2_1,,1.9,GA_CP-LI-COR LI-7200,SA-Gill Windmaster Pro,,3-5 -US-Prr,H_1_1_1,,11,GA_CP-LI-COR LI-7200,,,3-5 -US-Prr,H_1_2_1,,1.9,SA-Gill Windmaster Pro,,,3-5 -US-Prr,H2O_1_1_1,,11,GA_CP-LI-COR LI-7200,,,3-5 -US-Prr,H2O_1_2_1,,1.9,SA-Gill Windmaster Pro,,,3-5 -US-Prr,H_PI_F_1_1_1,,11,GA_CP-LI-COR LI-7200,,,3-5 -US-Prr,H_PI_F_1_2_1,,1.9,SA-Gill Windmaster Pro,,,3-5 -US-Prr,LE_1_1_1,,11,GA_CP-LI-COR LI-7200,SA-Gill Windmaster Pro,,3-5 -US-Prr,LE_1_2_1,,1.9,GA_CP-LI-COR LI-7200,SA-Gill Windmaster Pro,,3-5 -US-Prr,LE_PI_F_1_1_1,,11,GA_CP-LI-COR LI-7200,SA-Gill Windmaster Pro,,3-5 -US-Prr,LE_PI_F_1_2_1,,1.9,GA_CP-LI-COR LI-7200,SA-Gill Windmaster Pro,,3-5 -US-Prr,LW_IN_1_1_1,,16,,,,3-5 -US-Prr,LW_IN_1_2_1,,1.3,RAD-Pyrrad-SW+LW,,,3-5 -US-Prr,LW_OUT_1_1_1,,16,RAD-Pyrrad-SW+LW,,,3-5 -US-Prr,LW_OUT_1_2_1,,1.3,RAD-Pyrrad-SW+LW,,,3-5 -US-Prr,NEE_PI_1_1_1,,11,GA_CP-LI-COR LI-7200,SA-Gill Windmaster Pro,,3-5 -US-Prr,NEE_PI_1_2_1,,1.9,GA_CP-LI-COR LI-7200,SA-Gill Windmaster Pro,,3-5 -US-Prr,NEE_PI_F_1_1_1,,11,GA_CP-LI-COR LI-7200,SA-Gill Windmaster Pro,,3-5 -US-Prr,NEE_PI_F_1_2_1,,1.9,GA_CP-LI-COR LI-7200,SA-Gill Windmaster Pro,,3-5 -US-Prr,NETRAD_1_1_1,,16,RAD-Pyrrad-SW+LW,,,3-5 -US-Prr,NETRAD_1_2_1,,1.3,RAD-Pyrrad-SW+LW,,,3-5 -US-Prr,P,,0,,,,3-5 -US-Prr,PA,,0,,,,3-5 -US-Prr,PPFD_IN_1_1_1,,16,RAD-PAR Quantum,,,3-5 -US-Prr,PPFD_IN_1_2_1,,1.3,RAD-PAR Quantum,,,3-5 -US-Prr,PPFD_OUT_1_1_1,,16,RAD-PAR Quantum,,,3-5 -US-Prr,PPFD_OUT_1_2_1,,1.3,RAD-PAR Quantum,,,3-5 -US-Prr,RECO_PI_1_1_1,,11,,,,3-5 -US-Prr,RECO_PI_1_2_1,,1.9,,,,3-5 -US-Prr,RH_1_1_1,,16,RH-EM_abs,,,3-5 -US-Prr,RH_1_2_1,,13,RH-EM_abs,,,3-5 -US-Prr,RH_1_3_1,,11,RH-EM_abs,,,3-5 -US-Prr,RH_1_4_1,,9,RH-EM_abs,,,3-5 -US-Prr,RH_1_5_1,,6,RH-EM_abs,,,3-5 -US-Prr,RH_1_6_1,,4.5,RH-EM_abs,,,3-5 -US-Prr,RH_1_7_1,,3,RH-EM_abs,,,3-5 -US-Prr,RH_1_8_1,,1.9,RH-EM_abs,,,3-5 -US-Prr,RH_1_9_1,,1.5,RH-EM_abs,,,3-5 -US-Prr,SC_1_1_1,,11,,,,3-5 -US-Prr,SC_1_2_1,,1.9,,,,3-5 -US-Prr,SH_1_1_1,,11,,,,3-5 -US-Prr,SH_1_2_1,,1.9,,,,3-5 -US-Prr,SLE_1_1_1,,11,,,,3-5 -US-Prr,SLE_1_2_1,,1.9,,,,3-5 -US-Prr,SWC_1_1_1,,-0.05,SWC-TDR,,,3-5 -US-Prr,SWC_1_2_1,,-0.1,SWC-TDR,,,3-5 -US-Prr,SWC_1_3_1,,-0.2,SWC-TDR,,,3-5 -US-Prr,SWC_1_4_1,,-0.3,SWC-TDR,,,3-5 -US-Prr,SWC_1_5_1,,-0.4,SWC-TDR,,,3-5 -US-Prr,SW_IN_1_1_1,,16,RAD-Pyrrad-SW+LW,,,3-5 -US-Prr,SW_IN_1_2_1,,1.3,RAD-Pyrrad-SW+LW,,,3-5 -US-Prr,SW_OUT_1_1_1,,16,RAD-Pyrrad-SW+LW,,,3-5 -US-Prr,SW_OUT_1_2_1,,1.3,RAD-Pyrrad-SW+LW,,,3-5 -US-Prr,TA_1_1_1,,16,TEMP-ElectResis,,,3-5 -US-Prr,TA_1_2_1,,13,TEMP-ElectResis,,,3-5 -US-Prr,TA_1_3_1,,11,TEMP-ElectResis,,,3-5 -US-Prr,TA_1_4_1,,9,TEMP-ElectResis,,,3-5 -US-Prr,TA_1_5_1,,6,TEMP-ElectResis,,,3-5 -US-Prr,TA_1_6_1,,4.5,TEMP-ElectResis,,,3-5 -US-Prr,TA_1_7_1,,3,TEMP-ElectResis,,,3-5 -US-Prr,TA_1_8_1,,1.9,TEMP-ElectResis,,,3-5 -US-Prr,TA_1_9_1,,1.5,TEMP-ElectResis,,,3-5 -US-Prr,TS_1_1_1,,-0.05,TEMP-Thermis,,,3-5 -US-Prr,TS_1_2_1,,-0.1,TEMP-Thermis,,,3-5 -US-Prr,TS_1_3_1,,-0.2,TEMP-Thermis,,,3-5 -US-Prr,TS_1_4_1,,-0.3,TEMP-Thermis,,,3-5 -US-Prr,TS_1_5_1,,-0.4,TEMP-Thermis,,,3-5 -US-Prr,TS_1_6_1,,-1,TEMP-Thermis,,,3-5 -US-Prr,USTAR_1_1_1,,11,,,,3-5 -US-Prr,USTAR_1_2_1,,1.9,,,,3-5 -US-Prr,VPD_PI,,11,,,,3-5 -US-Prr,WD_1_1_1,,16,,,,3-5 -US-Prr,WD_1_2_1,,11,,,,3-5 -US-Prr,WD_1_3_1,,1.9,,,,3-5 -US-Prr,WS_1_10_1,,1.5,,,,3-5 -US-Prr,WS_1_1_1,,16,,,,3-5 -US-Prr,WS_1_2_1,,13,,,,3-5 -US-Prr,WS_1_3_1,,11,,,,3-5 -US-Prr,WS_1_4_1,,9,,,,3-5 -US-Prr,WS_1_5_1,,7.5,,,,3-5 -US-Prr,WS_1_6_1,,6,,,,3-5 -US-Prr,WS_1_7_1,,4.5,,,,3-5 -US-Prr,WS_1_8_1,,3,,,,3-5 -US-Prr,WS_1_9_1,,1.9,,,,3-5 -US-PSH,CO2,,0,,,,1-5 -US-PSH,FC,,0,,,,1-5 -US-PSH,FC_SSITC_TEST,,0,,,,1-5 -US-PSH,FETCH_70,,0,,,,1-5 -US-PSH,FETCH_80,,0,,,,1-5 -US-PSH,FETCH_90,,0,,,,1-5 -US-PSH,FETCH_FILTER,,0,,,,1-5 -US-PSH,FETCH_MAX,,0,,,,1-5 -US-PSH,G,,0,,,,1-5 -US-PSH,H,,0,,,,1-5 -US-PSH,H2O,,0,,,,1-5 -US-PSH,H_SSITC_TEST,,0,,,,1-5 -US-PSH,LE,,0,,,,1-5 -US-PSH,LE_SSITC_TEST,,0,,,,1-5 -US-PSH,NETRAD,,0,,,,1-5 -US-PSH,PA,,0,,,,1-5 -US-PSH,RH,,0,,,,1-5 -US-PSH,SW_IN,,0,,,,1-5 -US-PSH,TA,,0,,,,1-5 -US-PSH,TS,,0,,,,1-5 -US-PSH,T_SONIC,,0,,,,1-5 -US-PSH,T_SONIC_SIGMA,,0,,,,1-5 -US-PSH,USTAR,,0,,,,1-5 -US-PSH,VPD_PI,,0,,,,1-5 -US-PSH,WD,,0,,,,1-5 -US-PSH,WS,,0,,,,1-5 -US-PSL,CO2,,0,,,,1-5 -US-PSL,FC,,0,,,,1-5 -US-PSL,FC_SSITC_TEST,,0,,,,1-5 -US-PSL,FETCH_70,,0,,,,1-5 -US-PSL,FETCH_80,,0,,,,1-5 -US-PSL,FETCH_90,,0,,,,1-5 -US-PSL,FETCH_FILTER,,0,,,,1-5 -US-PSL,FETCH_MAX,,0,,,,1-5 -US-PSL,G,,0,,,,1-5 -US-PSL,H,,0,,,,1-5 -US-PSL,H2O,,0,,,,1-5 -US-PSL,H_SSITC_TEST,,0,,,,1-5 -US-PSL,LE,,0,,,,1-5 -US-PSL,LE_SSITC_TEST,,0,,,,1-5 -US-PSL,NETRAD,,0,,,,1-5 -US-PSL,PA,,0,,,,1-5 -US-PSL,RH,,0,,,,1-5 -US-PSL,SW_IN,,0,,,,1-5 -US-PSL,TA,,0,,,,1-5 -US-PSL,TS,,0,,,,1-5 -US-PSL,T_SONIC,,0,,,,1-5 -US-PSL,T_SONIC_SIGMA,,0,,,,1-5 -US-PSL,USTAR,,0,,,,1-5 -US-PSL,VPD_PI,,0,,,,1-5 -US-PSL,WD,,0,,,,1-5 -US-PSL,WS,,0,,,,1-5 -US-RGA,FC,,4.6,GA_OP-LI-COR LI-7500RS,SA-Campbell CSAT-3B,,1-5 -US-RGA,H,,4.6,SA-Campbell CSAT-3B,,,1-5 -US-RGA,LE,,4.6,GA_OP-LI-COR LI-7500RS,SA-Campbell CSAT-3B,,1-5 -US-RGA,TAU,,4.6,SA-Campbell CSAT-3B,,,1-5 -US-RGB,FC,,2.24,SA-Campbell CSAT-3B,GA_OP-LI-COR LI-7500RS,,2-5 -US-RGB,H,,2.24,SA-Campbell CSAT-3B,,,2-5 -US-RGB,LE,,2.24,SA-Campbell CSAT-3B,GA_OP-LI-COR LI-7500RS,,2-5 -US-RGB,TAU,,2.24,SA-Campbell CSAT-3B,,,2-5 -US-RGo,FC,,2.9,SA-Campbell CSAT-3B,GA_OP-LI-COR LI-7500RS,,1-5 -US-RGo,H,,2.9,SA-Campbell CSAT-3B,,,1-5 -US-RGo,LE,,2.9,SA-Campbell CSAT-3B,GA_OP-LI-COR LI-7500RS,,1-5 -US-RGo,TAU,,2.9,SA-Campbell CSAT-3B,,,1-5 -US-RGW,FC,,3.0,SA-Campbell CSAT-3B,GA_OP-LI-COR LI-7500RS,,1-5 -US-RGW,H,,3.0,SA-Campbell CSAT-3B,,,1-5 -US-RGW,LE,,3.0,SA-Campbell CSAT-3B,GA_OP-LI-COR LI-7500RS,,1-5 -US-RGW,TAU,,3.0,SA-Campbell CSAT-3B,,,1-5 -US-Rls,CO2,20190611,2.09,GA_OP-LI-COR LI-7500RS,,,4-5 -US-Rls,CO2,20191031,2.09,GA_OP-LI-COR LI-7500A,,,4-5 -US-Rls,CO2,20200619,2.09,GA_OP-LI-COR LI-7500RS,,,4-5 -US-Rls,CO2,,2.09,GA_OP-LI-COR LI-7500A,,,4-5 -US-Rls,D_SNOW,,1.5,SNOW-Acoustic,,,4-5 -US-Rls,FC,20190611,2.09,GA_OP-LI-COR LI-7500RS,SA-Campbell CSAT-3,,4-5 -US-Rls,FC,20191031,2.09,GA_OP-LI-COR LI-7500A,SA-Campbell CSAT-3,,4-5 -US-Rls,FC,20200619,2.09,GA_OP-LI-COR LI-7500RS,SA-Campbell CSAT-3,,4-5 -US-Rls,FC,,2.09,GA_OP-LI-COR LI-7500A,SA-Campbell CSAT-3,,4-5 -US-Rls,FETCH_70,,2.09,SA-Campbell CSAT-3,,,4-5 -US-Rls,FETCH_90,,2.09,SA-Campbell CSAT-3,,,4-5 -US-Rls,FETCH_FILTER,,2.09,SA-Campbell CSAT-3,,,4-5 -US-Rls,G,,-0.001,SOIL_H-Plate,,Soil heat flux values are adjusted for heat capacity to represent soil surface values,4-5 -US-Rls,H,,2.09,SA-Campbell CSAT-3,,,4-5 -US-Rls,H2O,20190611,2.09,GA_OP-LI-COR LI-7500RS,,,4-5 -US-Rls,H2O,20191031,2.09,GA_OP-LI-COR LI-7500A,,,4-5 -US-Rls,H2O,20200619,2.09,GA_OP-LI-COR LI-7500RS,,,4-5 -US-Rls,H2O,,2.09,GA_OP-LI-COR LI-7500A,,,4-5 -US-Rls,LE,20190611,2.09,GA_OP-LI-COR LI-7500RS,SA-Campbell CSAT-3,,4-5 -US-Rls,LE,20191031,2.09,GA_OP-LI-COR LI-7500A,SA-Campbell CSAT-3,,4-5 -US-Rls,LE,20200619,2.09,GA_OP-LI-COR LI-7500RS,SA-Campbell CSAT-3,,4-5 -US-Rls,LE,,2.09,SA-Campbell CSAT-3,GA_OP-LI-COR LI-7500A,,4-5 -US-Rls,LW_IN,,1.5,RAD-Pyrrad-SW+LW,,,4-5 -US-Rls,LW_OUT,,1.5,RAD-Pyrrad-SW+LW,,,4-5 -US-Rls,MO_LENGTH,,2.09,SA-Campbell CSAT-3,,,4-5 -US-Rls,NEE_PI,20190611,2.09,GA_OP-LI-COR LI-7500RS,SA-Campbell CSAT-3,,4-5 -US-Rls,NEE_PI,20191031,2.09,GA_OP-LI-COR LI-7500A,SA-Campbell CSAT-3,,4-5 -US-Rls,NEE_PI,20200619,2.09,GA_OP-LI-COR LI-7500RS,SA-Campbell CSAT-3,,4-5 -US-Rls,NEE_PI,,2.09,SA-Campbell CSAT-3,GA_OP-LI-COR LI-7500A,,4-5 -US-Rls,NETRAD,,1.5,RAD-Pyrrad-SW+LW,,,4-5 -US-Rls,PA,,1.0,PRES-ElectBar,,,4-5 -US-Rls,P_PI_F,,2.5,PREC-WeightGauge,,,4-5 -US-Rls,PPFD_IN,,2.0,RAD-PAR Quantum,,,4-5 -US-Rls,RH,,2.0,RH-EM_abs,,,4-5 -US-Rls,RH_PI_F,,2.0,RH-EM_abs,,,4-5 -US-Rls,SC,20190611,2.09,GA_OP-LI-COR LI-7500RS,,,4-5 -US-Rls,SC,20191031,2.09,GA_OP-LI-COR LI-7500A,,,4-5 -US-Rls,SC,20200619,2.09,GA_OP-LI-COR LI-7500RS,,,4-5 -US-Rls,SC,,2.09,GA_OP-LI-COR LI-7500A,,,4-5 -US-Rls,SLE,20190619,2.09,GA_OP-LI-COR LI-7500RS,,,4-5 -US-Rls,SLE,20191031,2.09,GA_OP-LI-COR LI-7500A,,,4-5 -US-Rls,SLE,20200619,2.09,GA_OP-LI-COR LI-7500RS,,,4-5 -US-Rls,SLE,,2.09,GA_OP-LI-COR LI-7500A,,,4-5 -US-Rls,SWC_4_1_1,,-0.05,SWC-FDR,,,4-5 -US-Rls,SWC_4_2_1,,-0.15,SWC-FDR,,,4-5 -US-Rls,SWC_4_3_1,,-0.30,SWC-FDR,,,4-5 -US-Rls,SWC_4_4_1,,-0.60,SWC-FDR,,,4-5 -US-Rls,SWC_4_5_1,,-0.90,SWC-FDR,,,4-5 -US-Rls,SW_IN,,1.5,RAD-Pyrrad-SW+LW,,,4-5 -US-Rls,SW_IN_PI_F,,1.5,RAD-Pyrrad-SW+LW,,,4-5 -US-Rls,SW_OUT,,1.5,RAD-Pyrrad-SW+LW,,,4-5 -US-Rls,TA,,2.0,TEMP-ElectResis,,,4-5 -US-Rls,TA_PI_F,,2.0,TEMP-ElectResis,,,4-5 -US-Rls,TAU,,2.09,SA-Campbell CSAT-3,,,4-5 -US-Rls,TS_1,,-0.04,TEMP-TCouple,,,4-5 -US-Rls,TS_2,,-0.04,TEMP-TCouple,,,4-5 -US-Rls,TS_3,,-0.04,TEMP-TCouple,,,4-5 -US-Rls,TS_4_1_1,,-0.05,TEMP-TCouple,,,4-5 -US-Rls,TS_4_2_1,,-0.15,TEMP-TCouple,,,4-5 -US-Rls,TS_4_3_1,,-0.30,TEMP-TCouple,,,4-5 -US-Rls,TS_4_4_1,,-0.60,TEMP-TCouple,,,4-5 -US-Rls,TS_4_5_1,,-0.90,TEMP-TCouple,,,4-5 -US-Rls,T_SONIC,,2.09,SA-Campbell CSAT-3,,,4-5 -US-Rls,T_SONIC_SIGMA,,2.09,SA-Campbell CSAT-3,,,4-5 -US-Rls,U_SIGMA,,2.09,SA-Campbell CSAT-3,,,4-5 -US-Rls,USTAR,,2.09,SA-Campbell CSAT-3,,,4-5 -US-Rls,V_SIGMA,,2.09,SA-Campbell CSAT-3,,,4-5 -US-Rls,WD,,2.09,SA-Campbell CSAT-3,,,4-5 -US-Rls,WS,,2.09,SA-Campbell CSAT-3,,,4-5 -US-Rls,W_SIGMA,,2.09,SA-Campbell CSAT-3,,,4-5 -US-Rls,ZL,,2.09,SA-Campbell CSAT-3,,,4-5 -US-Rms,CO2,20150317,2.5,GA_OP-LI-COR LI-7500A,,EC instruments were raised from 2.05 to 2.5 to be further above canopy,4-5 -US-Rms,CO2,20180510,2.50,GA_OP-LI-COR LI-7500RS,,,4-5 -US-Rms,CO2,,2.05,GA_OP-LI-COR LI-7500A,,,4-5 -US-Rms,FC,20150317,2.5,SA-Campbell CSAT-3,GA_OP-LI-COR LI-7500A,EC instruments were raised from 2.05 to 2.5 to be further above canopy,4-5 -US-Rms,FC,20180510,2.50,GA_OP-LI-COR LI-7500RS,SA-Campbell CSAT-3,,4-5 -US-Rms,FC,,2.05,SA-Campbell CSAT-3,GA_OP-LI-COR LI-7500A,,4-5 -US-Rms,G,,-0.001,SOIL_H-Plate,,Soil heat flux values are adjusted for heat capacity to represent soil surface values,4-5 -US-Rms,H,20150317,2.5,SA-Campbell CSAT-3,,EC instruments were raised from 2.05 to 2.5 to be further above canopy,4-5 -US-Rms,H,,2.05,SA-Campbell CSAT-3,,,4-5 -US-Rms,H2O,20150317,2.5,GA_OP-LI-COR LI-7500A,,EC instruments were raised from 2.05 to 2.5 to be further above canopy,4-5 -US-Rms,H2O,20180510,2.5,GA_OP-LI-COR LI-7500RS,,,4-5 -US-Rms,H2O,,2.05,GA_OP-LI-COR LI-7500A,,,4-5 -US-Rms,LE,20150317,2.5,GA_OP-LI-COR LI-7500A,SA-Campbell CSAT-3,EC instruments were raised from 2.05 to 2.5 to be further above canopy,4-5 -US-Rms,LE,20180510,2.5,GA_OP-LI-COR LI-7500RS,SA-Campbell CSAT-3,,4-5 -US-Rms,LE,,2.05,GA_OP-LI-COR LI-7500A,SA-Campbell CSAT-3,,4-5 -US-Rms,SWC,,-0.05,SWC-FDR,,,4-5 -US-Rms,SWC_4_1_1,,-0.05,TEMP-TCouple,,,4-5 -US-Rms,SWC_4_2_1,,-0.15,TEMP-TCouple,,,4-5 -US-Rms,SWC_4_3_1,,-0.30,TEMP-TCouple,,,4-5 -US-Rms,SWC_4_4_1,,-0.60,TEMP-TCouple,,,4-5 -US-Rms,SWC_4_5_1,,-0.90,TEMP-TCouple,,,4-5 -US-Rms,TS_1,,-0.04,TEMP-TCouple,,Measured using self-averaging thermocouples located at 2 and 6 cm depths,4-5 -US-Rms,TS_2,,-0.04,TEMP-TCouple,,Measured using self-averaging thermocouples located at 2 and 6 cm depths,4-5 -US-Rms,TS_3,,-0.04,TEMP-TCouple,,Measured using self-averaging thermocouples located at 2 and 6 cm depths,4-5 -US-Rms,TS_4_1_1,,-0.05,TEMP-TCouple,,,4-5 -US-Rms,TS_4_2_1,,-0.15,TEMP-TCouple,,,4-5 -US-Rms,TS_4_3_1,,-0.30,TEMP-TCouple,,,4-5 -US-Rms,TS_4_4_1,,-0.60,TEMP-TCouple,,,4-5 -US-Rms,TS_4_5_1,,-0.90,TEMP-TCouple,,,4-5 -US-Rms,WD,20150317,2.5,SA-Campbell CSAT-3,,EC instruments were raised from 2.05 to 2.5 to be further above canopy,4-5 -US-Rms,WD,,2.05,SA-Campbell CSAT-3,,,4-5 -US-Rms,WS,20150317,2.5,SA-Campbell CSAT-3,,EC instruments were raised from 2.05 to 2.5 to be further above canopy,4-5 -US-Rms,WS,,2.05,SA-Campbell CSAT-3,,,4-5 -US-Ro1,ALB,20150101,3.7,RAD-Pyrrad-SW+LW,,Kipp and Zonen CNR4,5-5 -US-Ro1,ALB,,3.7,RAD-SW Pyran Class1,,Eppley PSP,5-5 -US-Ro1,CO2,20050713,2.72,GA_OP-LI-COR LI-7500,,,5-5 -US-Ro1,CO2,20050719,3.6,GA_OP-LI-COR LI-7500,,,5-5 -US-Ro1,CO2,20051028,2.05,GA_OP-LI-COR LI-7500,,,5-5 -US-Ro1,CO2,20070627,2.97,GA_OP-LI-COR LI-7500,,,5-5 -US-Ro1,CO2,20070705,3.24,GA_OP-LI-COR LI-7500,,,5-5 -US-Ro1,CO2,20070711,3.58,GA_OP-LI-COR LI-7500,,,5-5 -US-Ro1,CO2,20071011,1.92,GA_OP-LI-COR LI-7500,,,5-5 -US-Ro1,CO2,20090709,2.75,GA_OP-LI-COR LI-7500,,,5-5 -US-Ro1,CO2,20090717,3.3,GA_OP-LI-COR LI-7500,,,5-5 -US-Ro1,CO2,20091117,2.02,GA_OP-LI-COR LI-7500,,,5-5 -US-Ro1,CO2,20110711,2.85,GA_OP-LI-COR LI-7500,,,5-5 -US-Ro1,CO2,20110721,3.42,GA_OP-LI-COR LI-7500,,,5-5 -US-Ro1,CO2,20111026,2.05,GA_OP-LI-COR LI-7500,,,5-5 -US-Ro1,CO2,20150709,2.95,GA_OP-LI-COR LI-7500,,,5-5 -US-Ro1,CO2,20150721,3.48,GA_OP-LI-COR LI-7500,,,5-5 -US-Ro1,CO2,20151104,2.05,GA_OP-LI-COR LI-7500,,,5-5 -US-Ro1,CO2,,2.1,GA_OP-LI-COR LI-7500,,,5-5 -US-Ro1,FC,20050713,2.72,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,5-5 -US-Ro1,FC,20050719,3.6,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,5-5 -US-Ro1,FC,20051028,2.05,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,5-5 -US-Ro1,FC,20070627,2.97,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,5-5 -US-Ro1,FC,20070705,3.24,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,5-5 -US-Ro1,FC,20070711,3.58,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,5-5 -US-Ro1,FC,20071011,1.92,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,5-5 -US-Ro1,FC,20090709,2.75,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,5-5 -US-Ro1,FC,20090717,3.3,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,5-5 -US-Ro1,FC,20091117,2.02,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,5-5 -US-Ro1,FC,20110711,2.85,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,5-5 -US-Ro1,FC,20110721,3.42,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,5-5 -US-Ro1,FC,20111026,2.05,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,5-5 -US-Ro1,FC,20150709,2.95,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,5-5 -US-Ro1,FC,20150721,3.48,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,5-5 -US-Ro1,FC,20151104,2.05,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,5-5 -US-Ro1,FC,,2.1,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,5-5 -US-Ro1,G,,-0.1,SOIL_H-Plate,,Huskeflux HFP01SC,5-5 -US-Ro1,GPP_PI,20050713,2.72,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,5-5 -US-Ro1,GPP_PI,20050719,3.6,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,5-5 -US-Ro1,GPP_PI,20051028,2.05,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,5-5 -US-Ro1,GPP_PI,20070627,2.97,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,5-5 -US-Ro1,GPP_PI,20070705,3.24,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,5-5 -US-Ro1,GPP_PI,20070711,3.58,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,5-5 -US-Ro1,GPP_PI,20071011,1.92,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,5-5 -US-Ro1,GPP_PI,20090709,2.75,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,5-5 -US-Ro1,GPP_PI,20090717,3.3,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,5-5 -US-Ro1,GPP_PI,20091117,2.02,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,5-5 -US-Ro1,GPP_PI,20110711,2.85,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,5-5 -US-Ro1,GPP_PI,20110721,3.42,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,5-5 -US-Ro1,GPP_PI,20111026,2.05,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,5-5 -US-Ro1,GPP_PI,20150709,2.95,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,5-5 -US-Ro1,GPP_PI,20150721,3.48,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,5-5 -US-Ro1,GPP_PI,20151104,2.05,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,5-5 -US-Ro1,GPP_PI,,2.1,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,5-5 -US-Ro1,H,20050713,2.72,SA-Campbell CSAT-3,,,5-5 -US-Ro1,H,20050719,3.6,SA-Campbell CSAT-3,,,5-5 -US-Ro1,H,20051028,2.05,SA-Campbell CSAT-3,,,5-5 -US-Ro1,H,20070627,2.97,SA-Campbell CSAT-3,,,5-5 -US-Ro1,H,20070705,3.24,SA-Campbell CSAT-3,,,5-5 -US-Ro1,H,20070711,3.58,SA-Campbell CSAT-3,,,5-5 -US-Ro1,H,20071011,1.92,SA-Campbell CSAT-3,,,5-5 -US-Ro1,H,20090709,2.75,SA-Campbell CSAT-3,,,5-5 -US-Ro1,H,20090717,3.3,SA-Campbell CSAT-3,,,5-5 -US-Ro1,H,20091117,2.02,SA-Campbell CSAT-3,,,5-5 -US-Ro1,H,20110711,2.85,SA-Campbell CSAT-3,,,5-5 -US-Ro1,H,20110721,3.42,SA-Campbell CSAT-3,,,5-5 -US-Ro1,H,20111026,2.05,SA-Campbell CSAT-3,,,5-5 -US-Ro1,H,20150709,2.95,SA-Campbell CSAT-3,,,5-5 -US-Ro1,H,20150721,3.48,SA-Campbell CSAT-3,,,5-5 -US-Ro1,H,20151104,2.05,SA-Campbell CSAT-3,,,5-5 -US-Ro1,H,,2.1,SA-Campbell CSAT-3,,,5-5 -US-Ro1,H2O,20050713,2.72,GA_OP-LI-COR LI-7500,,,5-5 -US-Ro1,H2O,20050719,3.6,GA_OP-LI-COR LI-7500,,,5-5 -US-Ro1,H2O,20051028,2.05,GA_OP-LI-COR LI-7500,,,5-5 -US-Ro1,H2O,20070627,2.97,GA_OP-LI-COR LI-7500,,,5-5 -US-Ro1,H2O,20070705,3.24,GA_OP-LI-COR LI-7500,,,5-5 -US-Ro1,H2O,20070711,3.58,GA_OP-LI-COR LI-7500,,,5-5 -US-Ro1,H2O,20071011,1.92,GA_OP-LI-COR LI-7500,,,5-5 -US-Ro1,H2O,20090709,2.75,GA_OP-LI-COR LI-7500,,,5-5 -US-Ro1,H2O,20090717,3.3,GA_OP-LI-COR LI-7500,,,5-5 -US-Ro1,H2O,20091117,2.02,GA_OP-LI-COR LI-7500,,,5-5 -US-Ro1,H2O,20110711,2.85,GA_OP-LI-COR LI-7500,,,5-5 -US-Ro1,H2O,20110721,3.42,GA_OP-LI-COR LI-7500,,,5-5 -US-Ro1,H2O,20111026,2.05,GA_OP-LI-COR LI-7500,,,5-5 -US-Ro1,H2O,20150709,2.95,GA_OP-LI-COR LI-7500,,,5-5 -US-Ro1,H2O,20150721,3.48,GA_OP-LI-COR LI-7500,,,5-5 -US-Ro1,H2O,20151104,2.05,GA_OP-LI-COR LI-7500,,,5-5 -US-Ro1,H2O,,2.1,GA_OP-LI-COR LI-7500,,,5-5 -US-Ro1,LE,20050713,2.72,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,5-5 -US-Ro1,LE,20050719,3.6,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,5-5 -US-Ro1,LE,20051028,2.05,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,5-5 -US-Ro1,LE,20070627,2.97,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,5-5 -US-Ro1,LE,20070705,3.24,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,5-5 -US-Ro1,LE,20070711,3.58,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,5-5 -US-Ro1,LE,20071011,1.92,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,5-5 -US-Ro1,LE,20090709,2.75,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,5-5 -US-Ro1,LE,20090717,3.3,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,5-5 -US-Ro1,LE,20091117,2.02,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,5-5 -US-Ro1,LE,20110711,2.85,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,5-5 -US-Ro1,LE,20110721,3.42,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,5-5 -US-Ro1,LE,20111026,2.05,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,5-5 -US-Ro1,LE,20150709,2.95,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,5-5 -US-Ro1,LE,20150721,3.48,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,5-5 -US-Ro1,LE,20151104,2.05,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,5-5 -US-Ro1,LE,,2.1,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,5-5 -US-Ro1,LE_PI_F,20050713,2.72,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,5-5 -US-Ro1,LE_PI_F,20050719,3.6,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,5-5 -US-Ro1,LE_PI_F,20051028,2.05,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,5-5 -US-Ro1,LE_PI_F,20070627,2.97,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,5-5 -US-Ro1,LE_PI_F,20070705,3.24,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,5-5 -US-Ro1,LE_PI_F,20070711,3.58,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,5-5 -US-Ro1,LE_PI_F,20071011,1.92,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,5-5 -US-Ro1,LE_PI_F,20090709,2.75,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,5-5 -US-Ro1,LE_PI_F,20090717,3.3,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,5-5 -US-Ro1,LE_PI_F,20091117,2.02,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,5-5 -US-Ro1,LE_PI_F,20110711,2.85,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,5-5 -US-Ro1,LE_PI_F,20110721,3.42,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,5-5 -US-Ro1,LE_PI_F,20111026,2.05,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,5-5 -US-Ro1,LE_PI_F,20150709,2.95,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,5-5 -US-Ro1,LE_PI_F,20150721,3.48,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,5-5 -US-Ro1,LE_PI_F,20151104,2.05,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,5-5 -US-Ro1,LE_PI_F,,2.1,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,5-5 -US-Ro1,LW_IN,20150101,3.7,RAD-Pyrrad-SW+LW,,Kipp and Zonen CNR4,5-5 -US-Ro1,LW_IN,,3.7,RAD-LW Pyrgeom,,Eppley ,5-5 -US-Ro1,LW_OUT,20150101,3.7,RAD-Pyrrad-SW+LW,,Kipp and Zonen CNR4,5-5 -US-Ro1,LW_OUT,,3.7,RAD-LW Pyrgeom,,Eppley ,5-5 -US-Ro1,NEE_PI,20050713,2.72,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,5-5 -US-Ro1,NEE_PI,20050719,3.6,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,5-5 -US-Ro1,NEE_PI,20051028,2.05,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,5-5 -US-Ro1,NEE_PI,20070627,2.97,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,5-5 -US-Ro1,NEE_PI,20070705,3.24,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,5-5 -US-Ro1,NEE_PI,20070711,3.58,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,5-5 -US-Ro1,NEE_PI,20071011,1.92,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,5-5 -US-Ro1,NEE_PI,20090709,2.75,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,5-5 -US-Ro1,NEE_PI,20090717,3.3,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,5-5 -US-Ro1,NEE_PI,20091117,2.02,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,5-5 -US-Ro1,NEE_PI,20110711,2.85,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,5-5 -US-Ro1,NEE_PI,20110721,3.42,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,5-5 -US-Ro1,NEE_PI,20111026,2.05,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,5-5 -US-Ro1,NEE_PI,20150709,2.95,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,5-5 -US-Ro1,NEE_PI,20150721,3.48,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,5-5 -US-Ro1,NEE_PI,20151104,2.05,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,5-5 -US-Ro1,NEE_PI,,2.1,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,5-5 -US-Ro1,NEE_PI_F,20050713,2.72,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,5-5 -US-Ro1,NEE_PI_F,20050719,3.6,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,5-5 -US-Ro1,NEE_PI_F,20051028,2.05,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,5-5 -US-Ro1,NEE_PI_F,20070627,2.97,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,5-5 -US-Ro1,NEE_PI_F,20070705,3.24,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,5-5 -US-Ro1,NEE_PI_F,20070711,3.58,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,5-5 -US-Ro1,NEE_PI_F,20071011,1.92,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,5-5 -US-Ro1,NEE_PI_F,20090709,2.75,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,5-5 -US-Ro1,NEE_PI_F,20090717,3.3,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,5-5 -US-Ro1,NEE_PI_F,20091117,2.02,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,5-5 -US-Ro1,NEE_PI_F,20110711,2.85,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,5-5 -US-Ro1,NEE_PI_F,20110721,3.42,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,5-5 -US-Ro1,NEE_PI_F,20111026,2.05,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,5-5 -US-Ro1,NEE_PI_F,20150709,2.95,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,5-5 -US-Ro1,NEE_PI_F,20150721,3.48,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,5-5 -US-Ro1,NEE_PI_F,20151104,2.05,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,5-5 -US-Ro1,NEE_PI_F,,2.1,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,5-5 -US-Ro1,NETRAD,20150101,3.7,RAD-Pyrrad-SW+LW,,Kipp and Zonen CNR4 Components,5-5 -US-Ro1,NETRAD,,3.7,RAD-Net radiometer,,Eppley Components,5-5 -US-Ro1,P,,,PREC-WeightGauge,,Geonor T200,5-5 -US-Ro1,PA,,3,PRES-ElectBar,,Vaisala PTB-110,5-5 -US-Ro1,PPFD_IN,,3,RAD-PAR Quantum,,Kipp and Zonen PAR Lite,5-5 -US-Ro1,RECO_PI,20050713,2.72,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,5-5 -US-Ro1,RECO_PI,20050719,3.6,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,5-5 -US-Ro1,RECO_PI,20051028,2.05,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,5-5 -US-Ro1,RECO_PI,20070627,2.97,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,5-5 -US-Ro1,RECO_PI,20070705,3.24,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,5-5 -US-Ro1,RECO_PI,20070711,3.58,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,5-5 -US-Ro1,RECO_PI,20071011,1.92,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,5-5 -US-Ro1,RECO_PI,20090709,2.75,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,5-5 -US-Ro1,RECO_PI,20090717,3.3,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,5-5 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LI-7500,,,1-5 -US-Ro2,H2O,20110721,2.42,GA_OP-LI-COR LI-7500,,,1-5 -US-Ro2,H2O,20111028,1.75,GA_OP-LI-COR LI-7500,,,1-5 -US-Ro2,H2O,201307,2.79,GA_OP-LI-COR LI-7500,,,1-5 -US-Ro2,H2O,201310,1.75,GA_OP-LI-COR LI-7500,,,1-5 -US-Ro2,H2O,20151030,2,GA_OP-LI-COR LI-7500,,,1-5 -US-Ro2,H2O,,1.93,GA_OP-LI-COR LI-7500,,,1-5 -US-Ro2,LE,20080718,2.79,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,1-5 -US-Ro2,LE,20081001,1.93,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,1-5 -US-Ro2,LE,20090728,2.79,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,1-5 -US-Ro2,LE,20110721,2.42,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,1-5 -US-Ro2,LE,20111028,1.75,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,1-5 -US-Ro2,LE,201307,2.79,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,1-5 -US-Ro2,LE,201310,1.75,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,1-5 -US-Ro2,LE,20151030,2,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,1-5 -US-Ro2,LE,,1.93,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,1-5 -US-Ro2,LW_IN,201501,3.7,RAD-Pyrrad-SW+LW,,Kipp and Zonen CNR4,1-5 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T200,1-5 -US-Ro2,PA,,3,PRES-ElectBar,,Vaisala PTB-110,1-5 -US-Ro2,PPFD_IN,,3.7,RAD-PAR Quantum,,Kipp and Zonen PAR Lite,1-5 -US-Ro2,RECO_PI,20080718,2.79,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,1-5 -US-Ro2,RECO_PI,20081001,1.93,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,1-5 -US-Ro2,RECO_PI,20090728,2.79,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,1-5 -US-Ro2,RECO_PI,20110721,2.42,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,1-5 -US-Ro2,RECO_PI,20111028,1.75,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,1-5 -US-Ro2,RECO_PI,201307,2.79,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,1-5 -US-Ro2,RECO_PI,201310,1.75,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,1-5 -US-Ro2,RECO_PI,20151030,2,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,1-5 -US-Ro2,RECO_PI,,1.93,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,1-5 -US-Ro2,RH,20150101,3,RH-Capac,,Vaisala HMP155A,1-5 -US-Ro2,RH,,3,RH-Capac,,Vaisala HMP35C,1-5 -US-Ro2,SC,20080718,2.79,GA_OP-LI-COR LI-7500,,,1-5 -US-Ro2,SC,20081001,1.93,GA_OP-LI-COR LI-7500,,,1-5 -US-Ro2,SC,20090728,2.79,GA_OP-LI-COR LI-7500,,,1-5 -US-Ro2,SC,20110721,2.42,GA_OP-LI-COR LI-7500,,,1-5 -US-Ro2,SC,20111028,1.75,GA_OP-LI-COR LI-7500,,,1-5 -US-Ro2,SC,201307,2.79,GA_OP-LI-COR LI-7500,,,1-5 -US-Ro2,SC,201310,1.75,GA_OP-LI-COR LI-7500,,,1-5 -US-Ro2,SC,20151030,2,GA_OP-LI-COR LI-7500,,,1-5 -US-Ro2,SC,,1.93,GA_OP-LI-COR LI-7500,,,1-5 -US-Ro2,SH,20080718,2.79,SA-Campbell CSAT-3,,,1-5 -US-Ro2,SH,20081001,1.93,SA-Campbell CSAT-3,,,1-5 -US-Ro2,SH,20090728,2.79,SA-Campbell CSAT-3,,,1-5 -US-Ro2,SH,20110721,2.42,SA-Campbell CSAT-3,,,1-5 -US-Ro2,SH,20111028,1.75,SA-Campbell CSAT-3,,,1-5 -US-Ro2,SH,201307,2.79,SA-Campbell CSAT-3,,,1-5 -US-Ro2,SH,201310,1.75,SA-Campbell CSAT-3,,,1-5 -US-Ro2,SH,20151030,2,SA-Campbell CSAT-3,,,1-5 -US-Ro2,SH,,1.93,SA-Campbell CSAT-3,,,1-5 -US-Ro2,SLE,20080718,2.79,GA_OP-LI-COR LI-7500,,,1-5 -US-Ro2,SLE,20081001,1.93,GA_OP-LI-COR LI-7500,,,1-5 -US-Ro2,SLE,20090728,2.79,GA_OP-LI-COR LI-7500,,,1-5 -US-Ro2,SLE,20110721,2.42,GA_OP-LI-COR LI-7500,,,1-5 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-US-Ro3,USTAR,20051024,2.1,SA-Campbell CSAT-3,,,4-5 -US-Ro3,USTAR,,2.1,SA-Campbell CSAT-3,,,4-5 -US-Ro3,VPD_PI,,3,RH-Capac,,Vaisala HMP35C,4-5 -US-Ro3,WS,20050714,3.05,SA-Campbell CSAT-3,,,4-5 -US-Ro3,WS,20050719,3.46,SA-Campbell CSAT-3,,,4-5 -US-Ro3,WS,20050726,3.6,SA-Campbell CSAT-3,,,4-5 -US-Ro3,WS,20051024,2.1,SA-Campbell CSAT-3,,,4-5 -US-Ro3,WS,,2.1,SA-Campbell CSAT-3,,,4-5 -US-Ro4,ALB,,3.7,RAD-Pyrrad-SW+LW,,Kipp and Zonen CNR4,16-5 -US-Ro4,CO2,20191118,2.6,GA_OP-LI-COR LI-7500RS,,,16-5 -US-Ro4,CO2,,2.6,GA_OP-LI-COR LI-7500,,,16-5 -US-Ro4,FC,20191118,2.6,GA_OP-LI-COR LI-7500RS,SA-Campbell CSAT-3,,16-5 -US-Ro4,FC,,2.6,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,16-5 -US-Ro4,G,20210421,-0.1,SOIL_H-Plate,,Prede PHF-02,16-5 -US-Ro4,G,,-0.1,SOIL_H-Plate,,Huskeflux HFPO1SC,16-5 -US-Ro4,GPP_PI,20191118,2.6,GA_OP-LI-COR LI-7500RS,SA-Campbell CSAT-3,,16-5 -US-Ro4,GPP_PI,,2.6,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,16-5 -US-Ro4,H,20191118,2.6,SA-Campbell CSAT-3,,,16-5 -US-Ro4,H,,2.6,SA-Campbell CSAT-3,,,16-5 -US-Ro4,H2O,20191118,2.6,GA_OP-LI-COR LI-7500RS,,,16-5 -US-Ro4,H2O,,2.6,GA_OP-LI-COR LI-7500,,,16-5 -US-Ro4,LE,20191118,2.6,GA_OP-LI-COR LI-7500RS,SA-Campbell CSAT-3,,16-5 -US-Ro4,LE,,2.6,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,16-5 -US-Ro4,LE_PI_F,20191118,2.6,GA_OP-LI-COR LI-7500RS,SA-Campbell CSAT-3,,16-5 -US-Ro4,LE_PI_F,,2.6,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,16-5 -US-Ro4,LW_IN,2015,3.7,RAD-Pyrrad-SW+LW,,Kipp and Zonen CNR4,16-5 -US-Ro4,LW_IN,,3.7,RAD-LW Pyrgeom,,Eppley,16-5 -US-Ro4,LW_OUT,2015,3.7,RAD-Pyrrad-SW+LW,,Kipp and Zonen CNR4,16-5 -US-Ro4,LW_OUT,,3.7,RAD-LW Pyrgeom,,Eppley,16-5 -US-Ro4,NEE_PI,20191118,2.6,GA_OP-LI-COR LI-7500RS,SA-Campbell CSAT-3,,16-5 -US-Ro4,NEE_PI,,2.6,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,16-5 -US-Ro4,NEE_PI_F,20191118,2.6,GA_OP-LI-COR LI-7500RS,SA-Campbell CSAT-3,,16-5 -US-Ro4,NEE_PI_F,,2.6,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,16-5 -US-Ro4,NETRAD,2015,3.7,RAD-Pyrrad-SW+LW,,Kipp and Zonen CNR4,16-5 -US-Ro4,NETRAD,,3.7,RAD-Net radiometer,,Eppley ,16-5 -US-Ro4,P,,1,PREC-WeightGauge,,Geonor T200,16-5 -US-Ro4,PA,,3,PRES-ElectBar,,Vaisala PTB-110,16-5 -US-Ro4,PPFD_IN,20220131,3.7,RAD-PAR Quantum,,Campbell Scientific CS310,16-5 -US-Ro4,PPFD_IN,,3.7,RAD-PAR Quantum,,Apogee SQ-311,16-5 -US-Ro4,RECO_PI,20191118,2.6,GA_OP-LI-COR LI-7500RS,SA-Campbell CSAT-3,,16-5 -US-Ro4,RECO_PI,,2.6,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,16-5 -US-Ro4,RH,2015,3,RH-Capac,,Vaisala HMP155A,16-5 -US-Ro4,RH,20210113,3,RH-Capac,,Campbell Scientific EE181,16-5 -US-Ro4,RH,,3,RH-Capac,,Vaisala HMP35C,16-5 -US-Ro4,SC,20191118,2.6,GA_OP-LI-COR LI-7500RS,,,16-5 -US-Ro4,SC,,2.6,GA_OP-LI-COR LI-7500,,,16-5 -US-Ro4,SH,20191118,2.6,SA-Campbell CSAT-3,,,16-5 -US-Ro4,SH,,2.6,SA-Campbell CSAT-3,,,16-5 -US-Ro4,SLE,20191118,2.6,GA_OP-LI-COR LI-7500RS,,,16-5 -US-Ro4,SLE,,2.6,GA_OP-LI-COR LI-7500,,,16-5 -US-Ro4,SWC,20201103,-0.1,SWC-TDR,,Campbell Scientific CS650,16-5 -US-Ro4,SWC,,-0.1,SWC-TDR,,Campbell Scientific TDR100,16-5 -US-Ro4,SW_IN,2015,3.7,RAD-Pyrrad-SW+LW,,Kipp and Zonen CNR4,16-5 -US-Ro4,SW_IN,,3.7,RAD-SW Pyran Class1,,Eppley PSP,16-5 -US-Ro4,SW_OUT,2015,3.7,RAD-Pyrrad-SW+LW,,Kipp and Zonen CNR4,16-5 -US-Ro4,SW_OUT,,3.7,RAD-SW Pyran Class1,,Eppley PSP,16-5 -US-Ro4,TA,2015,3,TEMP-ElectResis,,Vaisala HMP155A,16-5 -US-Ro4,TA,20210113,3,TEMP-ElectResis,,Campbell Scientific EE181,16-5 -US-Ro4,TA,,3,TEMP-ElectResis,,Vaisala HMP35C,16-5 -US-Ro4,T_CANOPY,20210113,3,TEMP-Other,,Campbell Scientific SI-111,16-5 -US-Ro4,T_CANOPY,,3,TEMP-Other,,Apogee Infrared Radiometer,16-5 -US-Ro4,TS_1_1_1,,-0.025,TEMP-TCouple,,Type T,16-5 -US-Ro4,TS_1_2_1,,-0.05,TEMP-TCouple,,Type T,16-5 -US-Ro4,TS_1_3_1,,-0.075,TEMP-TCouple,,Type T,16-5 -US-Ro4,TS_1_4_1,,-0.1,TEMP-TCouple,,Type T,16-5 -US-Ro4,USTAR,,2.6,SA-Campbell CSAT-3,,,16-5 -US-Ro4,VPD_PI,20210113,3,RH-Capac,,Campbell Scientific EE181,16-5 -US-Ro4,VPD_PI,,3,RH-Capac,,Vaisala HMP155A,16-5 -US-Ro4,WD,,2.6,SA-Campbell CSAT-3,,,16-5 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-US-Ro5,ZL,,2.45,SA-Campbell CSAT-3,,,16-5 -US-Ro6,ALB,20201218,2,RAD-Pyrrad-SW+LW,,Kipp and Zonen CNR4,16-5 -US-Ro6,ALB,,3.7,RAD-Pyrrad-SW+LW,,Kipp and Zonen CNR4,16-5 -US-Ro6,CO2,20191115,2.31,GA_CP-LI-COR LI-7200,,,16-5 -US-Ro6,CO2,20200506,2.31,GA_OP-LI-COR LI-7500,,,16-5 -US-Ro6,CO2,20220303,2.31,GA_OP-Campbell EC150,,,16-5 -US-Ro6,CO2,,2.31,GA_OP-LI-COR LI-7500RS,,,16-5 -US-Ro6,FC,20191115,2.31,GA_CP-LI-COR LI-7200,SA-Campbell CSAT-3,,16-5 -US-Ro6,FC,20200506,2.31,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,16-5 -US-Ro6,FC,20220303,2.31,GA_OP-Campbell EC150,SA-Campbell CSAT-3A,,16-5 -US-Ro6,FC,,2.31,GA_OP-LI-COR LI-7500RS,SA-Campbell CSAT-3,,16-5 -US-Ro6,G,20210603,-0.1,SOIL_H-Plate,,Prede PHF-02,16-5 -US-Ro6,G,,-0.1,SOIL_H-Plate,,Huskeflux HFP01SC,16-5 -US-Ro6,GPP_PI,20191115,2.31,GA_CP-LI-COR LI-7200,SA-Campbell CSAT-3,,16-5 -US-Ro6,GPP_PI,20200506,2.31,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,16-5 -US-Ro6,GPP_PI,20220303,2.31,GA_OP-Campbell EC150,SA-Campbell CSAT-3A,,16-5 -US-Ro6,GPP_PI,,2.31,GA_OP-LI-COR LI-7500RS,SA-Campbell CSAT-3,,16-5 -US-Ro6,H,20191115,2.31,SA-Campbell CSAT-3,,,16-5 -US-Ro6,H,20200506,2.31,SA-Campbell CSAT-3,,,16-5 -US-Ro6,H,20220303,2.31,SA-Campbell CSAT-3A,,,16-5 -US-Ro6,H,,2.31,SA-Campbell CSAT-3,,,16-5 -US-Ro6,H2O,20191115,2.31,GA_CP-LI-COR LI-7200,,,16-5 -US-Ro6,H2O,20200506,2.31,GA_OP-LI-COR LI-7500,,,16-5 -US-Ro6,H2O,20220303,2.31,GA_OP-Campbell EC150,,,16-5 -US-Ro6,H2O,,2.31,GA_OP-LI-COR LI-7500RS,,,16-5 -US-Ro6,LE,20191115,2.31,GA_CP-LI-COR LI-7200,SA-Campbell CSAT-3,,16-5 -US-Ro6,LE,20200506,2.31,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,16-5 -US-Ro6,LE,20220303,2.31,GA_OP-Campbell EC150,SA-Campbell CSAT-3A,,16-5 -US-Ro6,LE,,2.31,GA_OP-LI-COR LI-7500RS,SA-Campbell CSAT-3,,16-5 -US-Ro6,LE_PI_F,20191115,2.31,GA_CP-LI-COR LI-7200,SA-Campbell CSAT-3,,16-5 -US-Ro6,LE_PI_F,20200506,2.31,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,16-5 -US-Ro6,LE_PI_F,20220303,2.31,GA_OP-Campbell EC150,SA-Campbell CSAT-3A,,16-5 -US-Ro6,LE_PI_F,,2.31,GA_OP-LI-COR LI-7500RS,SA-Campbell CSAT-3,,16-5 -US-Ro6,LW_IN,,3.7,RAD-Pyrrad-SW+LW,,Kipp and Zonen CNR4,16-5 -US-Ro6,LW_OUT,,3.7,RAD-Pyrrad-SW+LW,,Kipp and Zonen CNR4,16-5 -US-Ro6,NEE_PI,20191115,2.31,GA_CP-LI-COR LI-7200,SA-Campbell CSAT-3,,16-5 -US-Ro6,NEE_PI,20200506,2.31,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,16-5 -US-Ro6,NEE_PI,20220303,2.31,GA_OP-Campbell EC150,SA-Campbell CSAT-3A,,16-5 -US-Ro6,NEE_PI,,2.31,GA_OP-LI-COR LI-7500RS,SA-Campbell CSAT-3,,16-5 -US-Ro6,NETRAD,,3.7,RAD-Pyrrad-SW+LW,,Kipp and Zonen CNR4,16-5 -US-Ro6,P,,1,PREC-WeightGauge,,Geonor T200,16-5 -US-Ro6,PPFD_IN,20220131,3.7,RAD-PAR Quantum,,Campbell CS310,16-5 -US-Ro6,PPFD_IN,,3.7,RAD-PAR Quantum,,Kipp and Zonen PQS1 PAR Sensor,16-5 -US-Ro6,RECO_PI,20191115,2.31,GA_CP-LI-COR LI-7200,SA-Campbell CSAT-3,,16-5 -US-Ro6,RECO_PI,20200506,2.31,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,16-5 -US-Ro6,RECO_PI,20220303,2.31,GA_OP-Campbell EC150,SA-Campbell CSAT-3A,,16-5 -US-Ro6,RECO_PI,,2.31,GA_OP-LI-COR LI-7500RS,SA-Campbell CSAT-3,,16-5 -US-Ro6,RH,20201218,3,RH-Capac,,Campbell Scientific EE181,16-5 -US-Ro6,RH,,3,RH-Capac,,Vaisala HMP45C,16-5 -US-Ro6,SC,20191115,2.31,GA_CP-LI-COR LI-7200,,,16-5 -US-Ro6,SC,20200506,2.31,GA_OP-LI-COR LI-7500,,,16-5 -US-Ro6,SC,20220303,2.31,GA_OP-Campbell EC150,,,16-5 -US-Ro6,SC,,2.31,GA_OP-LI-COR LI-7500RS,,,16-5 -US-Ro6,SH,20191115,2.31,SA-Campbell CSAT-3,,,16-5 -US-Ro6,SH,20200506,2.31,SA-Campbell CSAT-3,,,16-5 -US-Ro6,SH,20220303,2.31,SA-Campbell CSAT-3A,,,16-5 -US-Ro6,SH,,2.31,SA-Campbell CSAT-3,,,16-5 -US-Ro6,SLE,20191115,2.31,GA_CP-LI-COR LI-7200,,,16-5 -US-Ro6,SLE,20200506,2.31,GA_OP-LI-COR LI-7500,,,16-5 -US-Ro6,SLE,20220303,2.31,GA_OP-Campbell EC150,,,16-5 -US-Ro6,SLE,,2.31,GA_OP-LI-COR LI-7500RS,,,16-5 -US-Ro6,SWC,,-0.1,SWC-TDR,,Campbell Scientific CS650,16-5 -US-Ro6,SW_IN,,3.7,RAD-Pyrrad-SW+LW,,Kipp and Zonen CNR4,16-5 -US-Ro6,SW_OUT,,3.7,RAD-Pyrrad-SW+LW,,Kipp and Zonen CNR4,16-5 -US-Ro6,TA,20201218,3,TEMP-ElectResis,,Campbell Scientific EE181,16-5 -US-Ro6,TA,,3,TEMP-ElectResis,,Vaisala HMP45C,16-5 -US-Ro6,T_CANOPY,20201221,3,TEMP-Other,,Campbell Scientific SI-111,16-5 -US-Ro6,T_CANOPY,,3,TEMP-Other,,Apogee Infrared Radiometer,16-5 -US-Ro6,TS_1_1_1,,-0.025,TEMP-TCouple,,Type T,16-5 -US-Ro6,TS_1_2_1,,-0.05,TEMP-TCouple,,Type T,16-5 -US-Ro6,TS_1_3_1,,-0.075,TEMP-TCouple,,Type T,16-5 -US-Ro6,TS_1_4_1,,-0.1,TEMP-TCouple,,Type T,16-5 -US-Ro6,USTAR,20220303,2.31,SA-Campbell CSAT-3A,,,16-5 -US-Ro6,USTAR,,2.31,SA-Campbell CSAT-3,,,16-5 -US-Ro6,VPD_PI,20201218,3,RH-Capac,,Campbell Scientific EE181,16-5 -US-Ro6,VPD_PI,,3,RH-Capac,,Vaisala HMP45C,16-5 -US-Ro6,WD,20220303,2.31,SA-Campbell CSAT-3A,,,16-5 -US-Ro6,WD,,2.31,SA-Campbell CSAT-3,,,16-5 -US-Ro6,WS,20220303,2.31,SA-Campbell CSAT-3A,,,16-5 -US-Ro6,WS,,2.31,SA-Campbell CSAT-3,,,16-5 -US-Ro6,ZL,20220303,2.31,SA-Campbell CSAT-3A,,,16-5 -US-Ro6,ZL,,2.31,SA-Campbell CSAT-3,,,16-5 -US-Rpf,CO2_1_1_1,20080820,2.6,GA_OP-LI-COR LI-7500,,,7-5 -US-Rpf,CO2_1_1_1,20130725,3.9,GA_OP-LI-COR LI-7500,,,7-5 -US-Rpf,CO2_1_1_1,20140101,3.9,GA_CP-Campbell EC155,,,7-5 -US-Rpf,CO2_1_1_1,20150101,3.9,GA_OP-Campbell EC150,,,7-5 -US-Rpf,CO2_1_1_1,20180908,5.6,GA_OP-LI-COR LI-7500,,,7-5 -US-Rpf,CO2_1_1_1,20190508,5.6,GA_OP-Campbell EC150,,,7-5 -US-Rpf,D_SNOW,,1.2,SNOW-Acoustic,,,7-5 -US-Rpf,FC,20080820,2.6,SA-Gill Windmaster,GA_OP-LI-COR LI-7500,,7-5 -US-Rpf,FC,20130725,3.9,SA-Gill Windmaster,GA_OP-LI-COR LI-7500,,7-5 -US-Rpf,FC,20140101,3.9,SA-Campbell CSAT-3A,GA_CP-Campbell EC155,,7-5 -US-Rpf,FC,20150101,3.9,SA-Campbell CSAT-3A,GA_OP-Campbell EC150,,7-5 -US-Rpf,FC,20180908,5.6,SA-Campbell CSAT-3A,GA_OP-LI-COR LI-7500,,7-5 -US-Rpf,FC,20190508,5.6,SA-Campbell CSAT-3A,GA_OP-Campbell EC150,,7-5 -US-Rpf,G_1_1_1,,-0.01,SOIL_H-Plate,,,7-5 -US-Rpf,G_1_1_2,,-0.01,SOIL_H-Plate,,,7-5 -US-Rpf,H,20080820,2.6,SA-Gill Windmaster,,,7-5 -US-Rpf,H,20130725,3.9,SA-Gill Windmaster,,,7-5 -US-Rpf,H,20140101,3.9,SA-Campbell CSAT-3A,,,7-5 -US-Rpf,H,20180908,5.6,SA-Campbell CSAT-3A,,,7-5 -US-Rpf,LE,20080820,2.6,SA-Gill Windmaster,GA_OP-LI-COR LI-7500,,7-5 -US-Rpf,LE,20130725,3.9,SA-Gill Windmaster,GA_OP-LI-COR LI-7500,,7-5 -US-Rpf,LE,20140101,3.9,SA-Campbell CSAT-3A,GA_CP-Campbell EC155,,7-5 -US-Rpf,LE,20150101,3.9,SA-Campbell CSAT-3A,GA_OP-Campbell EC150,,7-5 -US-Rpf,LE,20180908,5.6,SA-Campbell CSAT-3A,GA_OP-LI-COR LI-7500,,7-5 -US-Rpf,LE,20190508,5.6,SA-Campbell CSAT-3A,GA_OP-Campbell EC150,,7-5 -US-Rpf,LW_IN_1_1_1,20180908,5,RAD-Pyrrad-SW+LW,,,7-5 -US-Rpf,LW_IN_1_1_1,,2.8,RAD-Pyrrad-SW+LW,,,7-5 -US-Rpf,LW_IN_PI_PI_F_1_1_1,20180908,5,RAD-Pyrrad-SW+LW,,,7-5 -US-Rpf,LW_IN_PI_PI_F_1_1_1,,2.8,RAD-Pyrrad-SW+LW,,,7-5 -US-Rpf,LW_OUT_1_1_1,20180908,5,RAD-Pyrrad-SW+LW,,,7-5 -US-Rpf,LW_OUT_1_1_1,,2.8,RAD-Pyrrad-SW+LW,,,7-5 -US-Rpf,NETRAD_1_1_1,20080820,2.3,RAD-Net radiometer,,,7-5 -US-Rpf,NETRAD_1_1_1,20130513,2.8,RAD-Net radiometer,,,7-5 -US-Rpf,NETRAD_1_1_2,20130513,2.8,RAD-Pyrrad-SW+LW,,,7-5 -US-Rpf,NETRAD_1_1_2,20180908,5,RAD-Pyrrad-SW+LW,,,7-5 -US-Rpf,PA,,0.5,PRES-ElectBar,,,7-5 -US-Rpf,PPFD_IN,20080820,2.3,RAD-PAR Quantum,,,7-5 -US-Rpf,PPFD_IN,20130513,2.8,RAD-PAR Quantum,,,7-5 -US-Rpf,PPFD_IN,20180908,5,RAD-PAR Quantum,,,7-5 -US-Rpf,PPFD_OUT,20080820,2.3,RAD-PAR Quantum,,,7-5 -US-Rpf,PPFD_OUT,20130513,2.8,RAD-PAR Quantum,,,7-5 -US-Rpf,PPFD_OUT,20180908,5,RAD-PAR Quantum,,,7-5 -US-Rpf,P_RAIN,20080820,1,PREC-TipBucGauge,,,7-5 -US-Rpf,P_RAIN,20130513,3,PREC-TipBucGauge,,,7-5 -US-Rpf,RH_1_1_1,20080820,2.3,RH-Capac,,,7-5 -US-Rpf,RH_1_1_1,20130513,4,RH-Capac,,,7-5 -US-Rpf,RH_1_2_1,20080820,1,RH-Capac,,,7-5 -US-Rpf,SC,20080820,2.6,GA_OP-LI-COR LI-7500,,,7-5 -US-Rpf,SC,20130725,3.9,GA_OP-LI-COR LI-7500,,,7-5 -US-Rpf,SC,20140101,3.9,GA_CP-Campbell EC155,,,7-5 -US-Rpf,SC,20150101,3.9,GA_OP-Campbell EC150,,,7-5 -US-Rpf,SC,20180908,5.6,GA_OP-LI-COR LI-7500,,,7-5 -US-Rpf,SC,20190508,5.6,GA_OP-Campbell EC150,,,7-5 -US-Rpf,SWC_1_1_1,,-0.15,SWC-TDR,,,7-5 -US-Rpf,SWC_1_1_2,,-0.15,SWC-TDR,,,7-5 -US-Rpf,SWC_1_1_3,,-0.15,SWC-TDR,,,7-5 -US-Rpf,SW_IN_1_1_1,20080820,2.3,RAD-Pyrrad-SW+LW,,,7-5 -US-Rpf,SW_IN_1_1_1,20130513,2.8,RAD-Pyrrad-SW+LW,,,7-5 -US-Rpf,SW_IN_1_1_2,20180908,5,RAD-Pyrrad-SW+LW,,,7-5 -US-Rpf,SW_IN_1_1_2,,2.8,RAD-Pyrrad-SW+LW,,,7-5 -US-Rpf,SW_OUT_1_1_1,20080820,2.3,RAD-Pyrrad-SW+LW,,,7-5 -US-Rpf,SW_OUT_1_1_1,20130513,2.8,RAD-Pyrrad-SW+LW,,,7-5 -US-Rpf,SW_OUT_1_1_2,20180908,5,RAD-Pyrrad-SW+LW,,,7-5 -US-Rpf,SW_OUT_1_1_2,,2.8,RAD-Pyrrad-SW+LW,,,7-5 -US-Rpf,TA_1_1_1,20080820,2.3,TEMP-ElectResis,,,7-5 -US-Rpf,TA_1_1_1,20130513,4,TEMP-ElectResis,,,7-5 -US-Rpf,TA_1_2_1,20080820,1,TEMP-ElectResis,,,7-5 -US-Rpf,TS_1_1_1,,-0.1,TEMP-ElectResis,,,7-5 -US-Rpf,TS_1_2_1,,-0.3,TEMP-ElectResis,,,7-5 -US-Rpf,TS_1_3_1,,-0.5,TEMP-ElectResis,,,7-5 -US-Rpf,TS_1_4_1,,-0.7,TEMP-ElectResis,,,7-5 -US-Rpf,TS_1_5_1,,-0.9,TEMP-ElectResis,,,7-5 -US-Rpf,USTAR,20080820,2.6,SA-Gill Windmaster,,,7-5 -US-Rpf,USTAR,20130725,3.9,SA-Gill Windmaster,,,7-5 -US-Rpf,USTAR,20140101,3.9,SA-Campbell CSAT-3A,,,7-5 -US-Rpf,USTAR,20180908,5.6,SA-Campbell CSAT-3A,,,7-5 -US-Rpf,WD,20080820,2.6,SA-Gill Windmaster,,,7-5 -US-Rpf,WD,20130725,3.9,SA-Gill Windmaster,,,7-5 -US-Rpf,WD,20140101,3.9,SA-Campbell CSAT-3A,,,7-5 -US-Rpf,WD,20180908,5.6,SA-Campbell CSAT-3A,,,7-5 -US-Rpf,WS_1_1_1,20080820,2.6,SA-Gill Windmaster,,,7-5 -US-Rpf,WS_1_1_1,20130725,3.9,SA-Gill Windmaster,,,7-5 -US-Rpf,WS_1_1_1,20140101,3.9,SA-Campbell CSAT-3A,,,7-5 -US-Rpf,WS_1_1_1,20180908,5.6,SA-Campbell CSAT-3A,,,7-5 -US-Rwe,CO2,,3.0,GA_OP-LI-COR LI-7500,,,1-5 -US-Rwe,FC,,3.0,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,1-5 -US-Rwe,G,,-0.000,SOIL_H-Other,,,1-5 -US-Rwe,H,,3.0,SA-Campbell CSAT-3,,,1-5 -US-Rwe,H2O,,3.0,GA_OP-LI-COR LI-7500,,,1-5 -US-Rwe,LE,,3.0,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,1-5 -US-Rwe,SWC,,-0.05,SWC-FDR,,,1-5 -US-Rwe,TS,,-0.04,TEMP-TCouple,,,1-5 -US-Rwe,WD,,3.0,SA-Campbell CSAT-3,,,1-5 -US-Rwe,WS,,3.0,SA-Campbell CSAT-3,,,1-5 -US-Rwf,CO2,20191107,3.5,GA_OP-LI-COR LI-7500RS,,,2-5 -US-Rwf,CO2,,3.5,GA_OP-LI-COR LI-7500A,,,2-5 -US-Rwf,FC,20191107,3.5,GA_OP-LI-COR LI-7500RS,SA-Campbell CSAT-3,,2-5 -US-Rwf,FC,,3.5,GA_OP-LI-COR LI-7500A,SA-Campbell CSAT-3,,2-5 -US-Rwf,G,,-0.000,SOIL_H-Plate,,,2-5 -US-Rwf,H,,3.5,SA-Campbell CSAT-3,,,2-5 -US-Rwf,H2O,20191107,3.5,GA_OP-LI-COR LI-7500RS,,,2-5 -US-Rwf,H2O,,3.5,GA_OP-LI-COR LI-7500A,,,2-5 -US-Rwf,LE,20191107,3.5,GA_OP-LI-COR LI-7500RS,SA-Campbell CSAT-3,,2-5 -US-Rwf,LE,,3.5,GA_OP-LI-COR LI-7500A,SA-Campbell CSAT-3,,2-5 -US-Rwf,SWC_PI_F_4_1_1,,-0.10,SWC-FDR,,,2-5 -US-Rwf,SWC_PI_F_4_2_1,,-0.30,SWC-FDR,,,2-5 -US-Rwf,SWC_PI_F_4_3_1,,-0.60,SWC-FDR,,,2-5 -US-Rwf,SWC_PI_F_4_4_1,,-0.90,SWC-FDR,,,2-5 -US-Rwf,SWC_PI_F_4_5_1,,-1.20,SWC-FDR,,,2-5 -US-Rwf,SWC_PI_F_5_1_1,,-0.10,SWC-FDR,,,2-5 -US-Rwf,SWC_PI_F_5_2_1,,-0.30,SWC-FDR,,,2-5 -US-Rwf,SWC_PI_F_5_3_1,,-0.60,SWC-FDR,,,2-5 -US-Rwf,SWC_PI_F_5_4_1,,-0.90,SWC-FDR,,,2-5 -US-Rwf,SWC_PI_F_5_5_1,,-1.2,SWC-FDR,,,2-5 -US-Rwf,TS_1,,-0.04,TEMP-ElectResis,,,2-5 -US-Rwf,TS_2,,-0.04,TEMP-ElectResis,,,2-5 -US-Rwf,TS_3,,-0.04,TEMP-ElectResis,,,2-5 -US-Rwf,TS_PI_F_4_1_1,,-0.10,TEMP-TCouple,,,2-5 -US-Rwf,TS_PI_F_4_2_1,,-0.30,TEMP-TCouple,,,2-5 -US-Rwf,TS_PI_F_4_3_1,,-0.60,TEMP-TCouple,,,2-5 -US-Rwf,TS_PI_F_4_4_1,,-0.90,TEMP-TCouple,,,2-5 -US-Rwf,TS_PI_F_4_5_1,,-1.20,TEMP-TCouple,,,2-5 -US-Rwf,TS_PI_F_4_6_1,,-1.50,TEMP-TCouple,,,2-5 -US-Rwf,TS_PI_F_4_7_1,,-1.80,TEMP-TCouple,,,2-5 -US-Rwf,WD,,3.5,SA-Campbell CSAT-3,,,2-5 -US-Rwf,WS,,3.5,SA-Campbell CSAT-3,,,2-5 -US-Rws,CO2,20170407,2.05,GA_OP-LI-COR LI-7500RS,,,4-5 -US-Rws,CO2,20171213,2.05,GA_OP-LI-COR LI-7500A,,,4-5 -US-Rws,CO2,20200318,2.05,GA_OP-LI-COR LI-7500RS,,,4-5 -US-Rws,CO2,,2.05,GA_OP-LI-COR LI-7500A,,,4-5 -US-Rws,FC,20170407,2.05,GA_OP-LI-COR LI-7500RS,SA-Campbell CSAT-3,,4-5 -US-Rws,FC,20171213,2.05,GA_OP-LI-COR LI-7500A,SA-Campbell CSAT-3,,4-5 -US-Rws,FC,20200318,2.05,GA_OP-LI-COR LI-7500RS,SA-Campbell CSAT-3,,4-5 -US-Rws,FC,,2.05,GA_OP-LI-COR LI-7500A,SA-Campbell CSAT-3,,4-5 -US-Rws,G,,-0.001,SOIL_H-Plate,,Soil heat flux values are adjusted for heat capacity to represent soil surface values,4-5 -US-Rws,H,,2.05,SA-Campbell CSAT-3,,,4-5 -US-Rws,H2O,20170407,2.05,GA_OP-LI-COR LI-7500RS,,,4-5 -US-Rws,H2O,20171213,2.05,GA_OP-LI-COR LI-7500A,,,4-5 -US-Rws,H2O,20200318,2.05,GA_OP-LI-COR LI-7500RS,,,4-5 -US-Rws,H2O,,2.05,GA_OP-LI-COR LI-7500A,,,4-5 -US-Rws,LE,20170407,2.05,GA_OP-LI-COR LI-7500RS,SA-Campbell CSAT-3,,4-5 -US-Rws,LE,20171213,2.05,GA_OP-LI-COR LI-7500A,SA-Campbell CSAT-3,,4-5 -US-Rws,LE,20200318,2.05,GA_OP-LI-COR LI-7500RS,,,4-5 -US-Rws,LE,,2.05,GA_OP-LI-COR LI-7500A,SA-Campbell CSAT-3,,4-5 -US-Rws,SWC_4_1_1,,-0.05,SWC-FDR,,This profile is under a sagebrush plant,4-5 -US-Rws,SWC_4_2_1,,-0.15,SWC-FDR,,,4-5 -US-Rws,SWC_4_3_1,,-0.30,SWC-FDR,,,4-5 -US-Rws,SWC_4_4_1,,-0.60,SWC-FDR,,,4-5 -US-Rws,SWC_4_5_1,,-0.90,SWC-FDR,,,4-5 -US-Rws,SWC_4_6_1,,-1.50,SWC-FDR,,,4-5 -US-Rws,SWC_5_1_1,,-0.05,SWC-FDR,,This profile is located under mostly bare soil between sagebrush plants,4-5 -US-Rws,SWC_5_2_1,,-0.15,SWC-FDR,,,4-5 -US-Rws,SWC_5_3_1,,-0.30,SWC-FDR,,,4-5 -US-Rws,SWC_5_4_1,,-0.60,SWC-FDR,,,4-5 -US-Rws,SWC_5_5_1,,-0.90,SWC-FDR,,,4-5 -US-Rws,SWC_5_6_1,,-1.50,SWC-FDR,,,4-5 -US-Rws,TS_1,,-0.04,TEMP-TCouple,,Measured using self-averaging thermocouples located at 2 and 6 cm depths,4-5 -US-Rws,TS_2,,-0.04,TEMP-TCouple,,Measured using self-averaging thermocouples located at 2 and 6 cm depths,4-5 -US-Rws,TS_3,,-0.04,TEMP-TCouple,,Measured using self-averaging thermocouples located at 2 and 6 cm depths,4-5 -US-Rws,TS_4_1_1,,-0.05,TEMP-TCouple,,This profile is under a sagebrush plant,4-5 -US-Rws,TS_4_2_1,,-0.15,TEMP-TCouple,,,4-5 -US-Rws,TS_4_3_1,,-0.30,TEMP-TCouple,,,4-5 -US-Rws,TS_4_4_1,,-0.60,TEMP-TCouple,,,4-5 -US-Rws,TS_4_5_1,,-0.90,TEMP-TCouple,,,4-5 -US-Rws,TS_4_6_1,,-1.50,TEMP-TCouple,,,4-5 -US-Rws,TS_5_1_1,,-0.05,TEMP-TCouple,,This profile is located under mostly bare soil within the interspace between sagebrush plants,4-5 -US-Rws,TS_5_2_1,,-0.15,TEMP-TCouple,,,4-5 -US-Rws,TS_5_3_1,,-0.30,TEMP-TCouple,,,4-5 -US-Rws,TS_5_4_1,,-0.60,TEMP-TCouple,,,4-5 -US-Rws,TS_5_5_1,,-0.90,TEMP-TCouple,,,4-5 -US-Rws,TS_5_6_1,,-1.50,SWC-FDR,,,4-5 -US-Rws,WD,,2.05,SA-Campbell CSAT-3,,,4-5 -US-Rws,WS,,2.05,SA-Campbell CSAT-3,,,4-5 -US-SdH,CO2_1,,3.85,,,,1-1 -US-SdH,FC,,3.85,,,,1-1 -US-SdH,G,,-0.06,,,,1-1 -US-SdH,H,,3.85,,,,1-1 -US-SdH,H2O,,3.85,,,,1-1 -US-SdH,LE,,3.85,,,,1-1 -US-SdH,P,,1.5,,,,1-1 -US-SdH,PA,,2,,,,1-1 -US-SdH,RH,,3.3,,,,1-1 -US-SdH,SWC_1,,-0.1,,,,1-1 -US-SdH,SWC_2,,-0.25,,,,1-1 -US-SdH,SW_IN,,2.20,,,,1-1 -US-SdH,TA,,3.3,,,,1-1 -US-SdH,TS_1,,-0.1,,,,1-1 -US-SdH,TS_2,,-0.25,,,,1-1 -US-SdH,WS,,3.8,,,,1-1 -US-Seg,CO2,,3.2,GA_OP-LI-COR LI-7500,,,18-5 -US-Seg,FC,,3.2,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,18-5 -US-Seg,H,,3.2,GA_OP-LI-COR LI-7500,,,18-5 -US-Seg,H2O,,3.2,GA_OP-LI-COR LI-7500,,,18-5 -US-Seg,LE,,3.2,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,18-5 -US-Seg,LW_IN,,3.4,RAD-Net radiometer,,Kipp & Zonen CNR1,18-5 -US-Seg,LW_OUT,,3.4,RAD-Net radiometer,,Kipp & Zonen CNR1,18-5 -US-Seg,NETRAD,,3.4,RAD-Net radiometer,,Kipp & Zonen CNR1,18-5 -US-Seg,P,,1,PREC-TipBucGauge,,,18-5 -US-Seg,PA,,3.2,GA_OP-LI-COR LI-7500,,,18-5 -US-Seg,P_PI_F,,1,PREC-TipBucGauge,,P data gapfilled from nearby tower sites and meteorological stations,18-5 -US-Seg,PPFD_IN,,3.4,RAD-PAR Quantum,,Kipp & Zonen PQS1,18-5 -US-Seg,RH,,2.45,RH-Capac,,Vaisala HMP45c,18-5 -US-Seg,RH_PI_F,,2.45,RH-Capac,,RH data gapfilled from nearby tower sites,18-5 -US-Seg,SW_IN,,3.4,RAD-Net radiometer,,Kipp & Zonen CNR1,18-5 -US-Seg,SW_OUT,,3.4,RAD-Net radiometer,,Kipp & Zonen CNR1,18-5 -US-Seg,TA,,3.2,SA-Campbell CSAT-3,,,18-5 -US-Seg,TA_PI_F,,3.2,SA-Campbell CSAT-3,,TA data gapfilled from nearby towers sites and from Vaisala HMP45c data,18-5 -US-Seg,USTAR,,3.2,SA-Campbell CSAT-3,,,18-5 -US-Seg,VPD_PI,,3.2,MULTI-Meteo,,calculated from TA and RH,18-5 -US-Seg,VPD_PI_F,,3.2,MULTI-Meteo,,VPD data gapfilled from nearby tower sites,18-5 -US-Seg,WD,,3.2,SA-Campbell CSAT-3,,,18-5 -US-Seg,WS,,3.2,SA-Campbell CSAT-3,,,18-5 -US-Ses,CO2,,3.2,GA_OP-LI-COR LI-7500,,,18-5 -US-Ses,FC,,3.2,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,18-5 -US-Ses,H,,3.2,GA_OP-LI-COR LI-7500,,,18-5 -US-Ses,H2O,,3.2,GA_OP-LI-COR LI-7500,,,18-5 -US-Ses,LE,,3.2,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,18-5 -US-Ses,LW_IN,,3.2,RAD-Net radiometer,,Kipp & Zonen CNR1,18-5 -US-Ses,LW_OUT,,3.2,RAD-Net radiometer,,Kipp & Zonen CNR1,18-5 -US-Ses,NETRAD,,3.2,RAD-Net radiometer,,Kipp & Zonen CNR1,18-5 -US-Ses,P,,0.9,PREC-TipBucGauge,,,18-5 -US-Ses,PA,,3.2,GA_OP-LI-COR LI-7500,,,18-5 -US-Ses,P_PI_F,,0.9,PREC-TipBucGauge,,P data gapfilled from nearby tower sites and meteorological stations,18-5 -US-Ses,PPFD_IN,,3.2,RAD-PAR Quantum,,Kipp & Zonen PQS1,18-5 -US-Ses,RH,,2.15,RH-Capac,,Vaisala HMP45c,18-5 -US-Ses,RH_PI_F,,2.15,RH-Capac,,RH data gapfilled from nearby tower sites,18-5 -US-Ses,SW_IN,,3.2,RAD-Net radiometer,,Kipp & Zonen CNR1,18-5 -US-Ses,SW_OUT,,3.2,RAD-Net radiometer,,Kipp & Zonen CNR1,18-5 -US-Ses,TA,,3.2,SA-Campbell CSAT-3,,,18-5 -US-Ses,TA_PI_F,,3.2,SA-Campbell CSAT-3,,TA data gapfilled from nearby towers sites and from Vaisala HMP45c data,18-5 -US-Ses,USTAR,,3.2,SA-Campbell CSAT-3,,,18-5 -US-Ses,VPD_PI,,3.2,MULTI-Meteo,,calculated from TA and RH,18-5 -US-Ses,VPD_PI_F,,3.2,MULTI-Meteo,,VPD data gapfilled from nearby tower sites,18-5 -US-Ses,WD,,3.1,SA-Campbell CSAT-3,,,18-5 -US-Ses,WS,,3.1,SA-Campbell CSAT-3,,,18-5 -US-SFP,FC,,7,,,,2-5 -US-SFP,H,,7,,,,2-5 -US-SFP,LE,,7,,,,2-5 -US-SFP,SWC_1_1_1,,-0.05,,,,2-5 -US-SFP,SWC_1_2_1,,-0.1,,,,2-5 -US-SFP,TS_1_1_1,,-0.02,,,,2-5 -US-SFP,TS_1_2_1,,-0.05,,,,2-5 -US-Shd,CO2_1,,4.5,,,,2-1 -US-Shd,FC,,4.5,,,,2-1 -US-Shd,H,,4.5,,,,2-1 -US-Shd,LE,,4.5,,,,2-1 -US-Shd,NETRAD,,3.5,,,,2-1 -US-Shd,PA,,3.5,,,,2-1 -US-Shd,RH,,4.5,,,,2-1 -US-Shd,SW_IN,,3.5,,,,2-1 -US-Shd,SW_OUT,,3.5,,,,2-1 -US-Shd,TA,,4.5,,,,2-1 -US-Shd,WD,,4.5,,,,2-1 -US-Shd,WS,,4.5,,,,2-1 -US-Skr,CO2_1,,27,,,,1-1 -US-Skr,FC,,27,,,,1-1 -US-Skr,G,,-0.1,,,,1-1 -US-Skr,H,,27,,,,1-1 -US-Skr,H2O,,27,,,,1-1 -US-Skr,LE,,27,,,,1-1 -US-Skr,LW_IN,,27,,,,1-1 -US-Skr,LW_OUT,,27,,,,1-1 -US-Skr,NETRAD,,27,,,,1-1 -US-Skr,PPFD_IN,,27,,,,1-1 -US-Skr,RH,,27,,,,1-1 -US-Skr,SW_IN,,27,,,,1-1 -US-Skr,SW_OUT,,27,,,,1-1 -US-Skr,TA,,27,,,,1-1 -US-Skr,TS_1,,-0.02,,,,1-1 -US-Skr,TS_2,,-0.1,,,,1-1 -US-Skr,VPD_PI_PI,,27,,,,1-1 -US-Skr,WD,,27,,,,1-1 -US-Skr,WS,,27,,,,1-1 -US-Slt,CO2_1,,19,,,,5-1 -US-Slt,FC,,19,,,,5-1 -US-Slt,G,,-0.1,,,,5-1 -US-Slt,H,,19,,,,5-1 -US-Slt,LE,,19,,,,5-1 -US-Slt,LW_IN,,17,,,,5-1 -US-Slt,LW_OUT,,17,,,,5-1 -US-Slt,NETRAD,,17,,,,5-1 -US-Slt,PA,,2,,,,5-1 -US-Slt,PPFD_IN,,17,,,,5-1 -US-Slt,RH,,17,,,,5-1 -US-Slt,SW_IN,,17,,,,5-1 -US-Slt,SW_OUT,,17,,,,5-1 -US-Slt,TA,,17,,,,5-1 -US-Slt,TS_1,,-0.05,,,,5-1 -US-Slt,USTAR,,19,,,,5-1 -US-Slt,VPD_PI_PI,,17,,,,5-1 -US-Slt,WD,,17,,,,5-1 -US-Slt,WS,,17,,,,5-1 -US-Snd,CO2_1,,2.81,GA-Other,,LI-COR LI-7500,2-1 -US-Snd,FC,,2.81,,,,2-1 -US-Snd,G,,-0.01,,,,2-1 -US-Snd,H,,2.81,,,,2-1 -US-Snd,H2O,,2.81,GA-Other,,LI-COR LI-7500,2-1 -US-Snd,LE,,2.81,,,,2-1 -US-Snd,NETRAD,,2.55,,,,2-1 -US-Snd,P,,2.55,,,,2-1 -US-Snd,PPFD_DIF,,2.0,RAD-Other,,Kipp and Zonen PAR-LITE,2-1 -US-Snd,PPFD_IN,,2.68,RAD-Other,,Kipp and Zonen PAR-LITE,2-1 -US-Snd,PPFD_OUT,,2.42,RAD-Other,,Kipp and Zonen PAR-LITE,2-1 -US-Snd,RH,,2.6,RH-Other,,Vaisala HMP45C,2-1 -US-Snd,SWC_1,,-0.1,,,,2-1 -US-Snd,SWC_2,,-0.2,,,,2-1 -US-Snd,SW_IN,,2.55,RAD-Other,,Kipp and Zonen CNR1,2-1 -US-Snd,TA,,2.6,TEMP-Other,,Vaisala HMP45C,2-1 -US-Snd,TS_1,,-0.08,,,,2-1 -US-Snd,TS_2,,-0.16,,,,2-1 -US-Snd,USTAR,,3.16,,,,2-1 -US-Snd,VPD_PI_PI,,2.6,,,,2-1 -US-Snd,WD,,3.16,,,,2-1 -US-Snd,WS,,3.16,WIND-Other,,Gill Windmaster Pro,2-1 -US-Sne,CH4,,5.42,GA_OP-LI-COR LI-7700,,,7-5 -US-Sne,CO2,,5.42,GA_OP-LI-COR LI-7500A,,,7-5 -US-Sne,FC,,5.42,GA_OP-LI-COR LI-7500A,SA-Gill Windmaster,,7-5 -US-Sne,FC_PI_F,,5.42,GA_OP-LI-COR LI-7500A,SA-Gill Windmaster,,7-5 -US-Sne,FCH4,,5.42,GA_OP-LI-COR LI-7700,SA-Gill Windmaster,,7-5 -US-Sne,FCH4_PI_F,,5.42,GA_OP-LI-COR LI-7700,SA-Gill Windmaster,,7-5 -US-Sne,G,,-.02,SOIL_H-Plate,,,7-5 -US-Sne,GPP_PI_F,,5.42,GA_OP-LI-COR LI-7500A,SA-Gill Windmaster,,7-5 -US-Sne,H,,5.42,SA-Gill Windmaster,,,7-5 -US-Sne,H2O,,5.42,GA_OP-LI-COR LI-7500A,,,7-5 -US-Sne,H_PI_F,,5.42,SA-Gill Windmaster,,,7-5 -US-Sne,LE,,5.42,GA_OP-LI-COR LI-7500A,SA-Gill Windmaster,,7-5 -US-Sne,LE_PI_F,,5.42,GA_OP-LI-COR LI-7500A,SA-Gill Windmaster,,7-5 -US-Sne,LW_IN,,4.37,RAD-Pyrrad-SW+LW,,,7-5 -US-Sne,LW_OUT,,4.37,RAD-Pyrrad-SW+LW,,,7-5 -US-Sne,NETRAD,,4.37,RAD-Pyrrad-SW+LW,,,7-5 -US-Sne,P,,1.5,RAIN-TipBucGauge,,,7-5 -US-Sne,PA,,1.7,PRES-ElectBar,,,7-5 -US-Sne,PPFD_IN,,4.32,RAD-PAR Quantum,,,7-5 -US-Sne,PPFD_OUT,,4.32,RAD-PAR Quantum,,,7-5 -US-Sne,RECO_PI_F,,5.42,GA_OP-LI-COR LI-7500A,SA-Gill Windmaster,,7-5 -US-Sne,RH,,5.22,RH-Capac,,,7-5 -US-Sne,SW_IN,,4.37,RAD-Pyrrad-SW+LW,,,7-5 -US-Sne,SW_OUT,,4.37,RAD-Pyrrad-SW+LW,,,7-5 -US-Sne,TA,,5.22,TEMP-ElectResis,,,7-5 -US-Sne,TAU,,5.42,SA-Gill Windmaster,,,7-5 -US-Sne,TS_1,,-0.01,TEMP-TCouple,,,7-5 -US-Sne,TS_2,,-.02,TEMP-TCouple,,,7-5 -US-Sne,TS_3,,-.08,TEMP-TCouple,,,7-5 -US-Sne,TS_4,,-.16,TEMP-TCouple,,,7-5 -US-Sne,TS_5,,-.32,TEMP-TCouple,,,7-5 -US-Sne,T_SONIC,,5.42,SA-Gill Windmaster,,,7-5 -US-Sne,T_SONIC_SIGMA,,5.42,SA-Gill Windmaster,,,7-5 -US-Sne,USTAR,,5.42,SA-Gill Windmaster,,,7-5 -US-Sne,VPD_PI,,5.22,RH-Capac,,Temp-ElectResis,7-5 -US-Sne,V_SIGMA,,5.42,SA-Gill Windmaster,,,7-5 -US-Sne,WD,,5.42,SA-Gill Windmaster,,,7-5 -US-Sne,WS,,5.42,SA-Gill Windmaster,,,7-5 -US-Sne,W_SIGMA,,5.42,SA-Gill Windmaster,,,7-5 -US-Sne,WTD,,-.8,WTD-Press,,,7-5 -US-Snf,CH4,20180711,3.49,GA_OP-LI-COR LI-7700,,,3-5 -US-Snf,CO2,20180711,3.49,GA_OP-LI-COR LI-7500A,,,3-5 -US-Snf,FC,20180711,3.49,GA_OP-LI-COR LI-7500A,SA-Gill Windmaster,,3-5 -US-Snf,FCH4,20180711,3.49,GA_OP-LI-COR LI-7700,SA-Gill Windmaster,,3-5 -US-Snf,G,20180711,-0.02,SOIL_H-Plate,,,3-5 -US-Snf,H,20180711,3.49,SA-Gill Windmaster,,,3-5 -US-Snf,H2O,20180711,3.49,GA_OP-LI-COR LI-7500A,,,3-5 -US-Snf,LE,20180711,3.49,GA_OP-LI-COR LI-7500A,SA-Gill Windmaster,,3-5 -US-Snf,LW_IN,20180711,2.75,RAD-Pyrrad-SW+LW,,,3-5 -US-Snf,LW_OUT,20180711,2.75,RAD-Pyrrad-SW+LW,,,3-5 -US-Snf,NETRAD,20180711,2.75,RAD-Pyrrad-SW+LW,,,3-5 -US-Snf,P,20180711,1.4,RAIN-TipBucGauge,,,3-5 -US-Snf,PA,20180711,,PRES-ElectBar,,,3-5 -US-Snf,RH,20180711,2.95,RH-Capac,,,3-5 -US-Snf,SWC,20180711,-0.02,SWC-TDR,,,3-5 -US-Snf,SW_IN,20180711,2.75,RAD-Pyrrad-SW+LW,,,3-5 -US-Snf,SW_OUT,20180711,2.75,RAD-Pyrrad-SW+LW,,,3-5 -US-Snf,TA,20180711,2.95,TEMP-ElectResis,,,3-5 -US-Snf,TAU,20180711,3.49,SA-Gill Windmaster,,,3-5 -US-Snf,TS_1,20180711,-0.02,TEMP-TCouple,,,3-5 -US-Snf,TS_2,20180711,-0.04,TEMP-TCouple,,,3-5 -US-Snf,TS_3,20180711,-0.08,TEMP-TCouple,,,3-5 -US-Snf,TS_4,20180711,-0.16,TEMP-TCouple,,,3-5 -US-Snf,TS_5,20180711,-0.32,TEMP-TCouple,,,3-5 -US-Snf,T_SONIC,20180711,3.49,SA-Gill Windmaster,,,3-5 -US-Snf,T_SONIC_SIGMA,20180711,3.49,SA-Gill Windmaster,,,3-5 -US-Snf,USTAR,20180711,3.49,SA-Gill Windmaster,,,3-5 -US-Snf,VPD_PI,20180711,2.95,RH-Capac,,Temp-ElectResis,3-5 -US-Snf,V_SIGMA,20180711,3.49,SA-Gill Windmaster,,,3-5 -US-Snf,WD,20180711,3.49,SA-Gill Windmaster,,,3-5 -US-Snf,WS,20180711,3.49,SA-Gill Windmaster,,,3-5 -US-Snf,W_SIGMA,20180711,3.49,SA-Gill Windmaster,,,3-5 -US-SO2,CO2_1,,4.5,GA-Other,,LI-7500 open path IRGA 4.5m,1-1 -US-SO2,FC,,4.5,,,,1-1 -US-SO2,G,,-0.08,,,,1-1 -US-SO2,H,,4.5,,,,1-1 -US-SO2,H2O,,4.5,GA-Other,,LI-7500 open path IRGA 4.5m,1-1 -US-SO2,LE,,4.5,,,,1-1 -US-SO2,NETRAD,,2,,,,1-1 -US-SO2,P,,.2,,,,1-1 -US-SO2,PA,,1,PRES-Other,,Vaisala PTB100A 1m,1-1 -US-SO2,PPFD_IN,,2.5,,,,1-1 -US-SO2,RH,,2.4,RH-Other,,Vaisala HMP45 2.4m,1-1 -US-SO2,SW_IN,,2.5,RAD-Other,,Licor Pyranometer 2.5m,1-1 -US-SO2,TA,,2.4,TEMP-Other,,Vaisala HMP45 2.4m,1-1 -US-SO2,USTAR,,4.5,,,,1-1 -US-SO2,VPD_PI_PI,,2.4,,,,1-1 -US-SO2,WD,,4.5,,,,1-1 -US-SO2,WS,,4.5,WIND-Other,,Gill Wind Master Pro 4.5m,1-1 -US-SP1,FC,,32,,,,4-1 -US-SP1,G,,-0.1,,,,4-1 -US-SP1,H,,32,,,,4-1 -US-SP1,LE,,32,,,,4-1 -US-SP1,NETRAD,,32,,,,4-1 -US-SP1,PPFD_IN,,32,,,,4-1 -US-SP1,RH,,30,,,,4-1 -US-SP1,SW_IN,,32,,,,4-1 -US-SP1,TA,,30.0,,,,4-1 -US-SP1,TS_1,,-0.05,,,,4-1 -US-SP1,USTAR,,32,,,,4-1 -US-SP1,VPD_PI_PI,,32,,,,4-1 -US-SP1,WD,,32,,,,4-1 -US-SP1,WS,,30,,,,4-1 -US-SP2,G,,-0.1,,,,3-1 -US-SP2,TS_1,,-0.05,,,,3-1 -US-SP3,G,,-0.1,,,,3-1 -US-SP3,TS_1,,-0.05,,,,3-1 -US-SP4,FC,,14,,,,3-5 -US-SP4,G,,-0.1,,,,3-5 -US-SP4,H,,14,,,,3-5 -US-SP4,LE,,14,,,,3-5 -US-SP4,NETRAD,,14,,,,3-5 -US-SP4,PPFD_IN,,14,,,,3-5 -US-SP4,RH,,30,,,,3-5 -US-SP4,SW_IN,,14,,,,3-5 -US-SP4,TA,,30.0,,,,3-5 -US-SP4,WS,,30,,,,3-5 -US-SRC,CO2,,3.75,GA-Other,,LI7500,6-5 -US-SRC,FC_1_1_1,,3.75,,,,6-5 -US-SRC,G,,-0.05,SOIL_H-Other,,Huseflux sensor,6-5 -US-SRC,H,,3.75,,,,6-5 -US-SRC,H2O,,3.75,,,,6-5 -US-SRC,LE,,3.75,,,,6-5 -US-SRC,LW_IN,,2.75,,,,6-5 -US-SRC,LW_OUT,,2.75,,,,6-5 -US-SRC,NETRAD,,2.75,,,,6-5 -US-SRC,P,,1,PREC-Other,,tipping bucket rain gage,6-5 -US-SRC,PA,,3.75,PRES-Other,,LI7500,6-5 -US-SRC,RH,,3.3,RH-Other,,HMP sensor,6-5 -US-SRC,SWC_1_1_1,,-0.025,,,,6-5 -US-SRC,SWC_1_2_1,,-0.125,,,,6-5 -US-SRC,SW_IN,,2.75,,,,6-5 -US-SRC,SW_OUT,,2.75,,,,6-5 -US-SRC,TA,,3.3,TEMP-Other,,HMP sensor,6-5 -US-SRC,TS,,-0.05,,,,6-5 -US-SRC,USTAR,,3.75,,,,6-5 -US-SRC,VPD_PI,,3.3,,,,6-5 -US-SRC,WD,,3.3,WIND-Other,,RM Young Wind Sensor,6-5 -US-SRC,WS,,3.3,WIND-Other,,RM Young Wind Sensor,6-5 -US-SRG,CO2,,3.25,GA_OP-LI-COR LI-7500,,,12-5 -US-SRG,FC,,3.25,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,12-5 -US-SRG,G,,-0.05,SOIL_H-Plate,,,12-5 -US-SRG,H,,3.25,SA-Campbell CSAT-3,,,12-5 -US-SRG,H2O,,3.25,GA_OP-LI-COR LI-7500,,,12-5 -US-SRG,LE,,3.25,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,12-5 -US-SRG,LW_IN,,2.6,RAD-Pyrrad-SW+LW,,,12-5 -US-SRG,LW_OUT,,2.6,RAD-Pyrrad-SW+LW,,,12-5 -US-SRG,NETRAD,,2.6,RAD-Pyrrad-SW+LW,,,12-5 -US-SRG,P,,1,PREC-WeightGauge,,,12-5 -US-SRG,PA,,3.25,GA_OP-LI-COR LI-7500,,,12-5 -US-SRG,PPFD_IN,,3.5,RAD-PAR Quantum,,,12-5 -US-SRG,PPFD_IN_PI_F,,3.5,RAD-PAR Quantum,,,12-5 -US-SRG,PPFD_OUT,,3.5,RAD-PAR Quantum,,,12-5 -US-SRG,RH_1_1_1,,2.9,RH-Capac,,,12-5 -US-SRG,SWC_1_1_1,,-.05,SWC-TDR,,,12-5 -US-SRG,SWC_1_2_1,,-0.1,SWC-TDR,,,12-5 -US-SRG,SWC_1_3_1,,-0.2,SWC-TDR,,,12-5 -US-SRG,SWC_1_4_1,,-0.3,SWC-TDR,,,12-5 -US-SRG,SWC_1_5_1,,-0.45,SWC-TDR,,,12-5 -US-SRG,SWC_1_6_1,,-0.75,SWC-TDR,,,12-5 -US-SRG,SWC_2_1_1,,-.05,SWC-TDR,,,12-5 -US-SRG,SWC_2_2_1,,-0.1,SWC-TDR,,,12-5 -US-SRG,SWC_2_3_1,,-0.2,SWC-TDR,,,12-5 -US-SRG,SWC_2_4_1,,-0.3,SWC-TDR,,,12-5 -US-SRG,SWC_2_5_1,,-0.45,SWC-TDR,,,12-5 -US-SRG,SW_IN,,2.6,RAD-Pyrrad-SW+LW,,,12-5 -US-SRG,SW_OUT,,2.6,RAD-Pyrrad-SW+LW,,,12-5 -US-SRG,TA_1_1_1,,2.9,TEMP-ElectResis,,,12-5 -US-SRG,TS_1_1_1,,-0.04,TEMP-TCouple,,,12-5 -US-SRG,TS_1_2_1,,-0.08,TEMP-TCouple,,,12-5 -US-SRG,TS_1_3_1,,-0.18,TEMP-TCouple,,,12-5 -US-SRG,TS_1_4_1,,-0.28,TEMP-TCouple,,,12-5 -US-SRG,TS_1_5_1,,-0.45,TEMP-TCouple,,,12-5 -US-SRG,TS_1_6_1,,-0.75,TEMP-TCouple,,,12-5 -US-SRG,TS_2_1_1,,-0.04,TEMP-TCouple,,,12-5 -US-SRG,TS_2_2_1,,-0.08,TEMP-TCouple,,,12-5 -US-SRG,T_SONIC,,3.25,SA-Campbell CSAT-3,,,12-5 -US-SRG,USTAR,,3.25,SA-Campbell CSAT-3,,,12-5 -US-SRG,WD_1_1_1,,3.25,SA-Campbell CSAT-3,,,12-5 -US-SRG,WS_1_1_1,,3.25,SA-Campbell CSAT-3,,,12-5 -US-SRM,CO2,,7.82,GA_OP-LI-COR LI-7500,,,23-5 -US-SRM,FC,,7.82,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,23-5 -US-SRM,G_PI_1_1_A,,-0.025,SOIL_H-Plate,,,23-5 -US-SRM,H,,7.82,SA-Campbell CSAT-3,,,23-5 -US-SRM,H2O,,7.82,GA_OP-LI-COR LI-7500,,,23-5 -US-SRM,LE,,7.82,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,23-5 -US-SRM,LW_IN,,7.1,RAD-Pyrrad-SW+LW,,,23-5 -US-SRM,LW_OUT,,7.1,RAD-Pyrrad-SW+LW,,,23-5 -US-SRM,NETRAD,,7.1,RAD-Pyrrad-SW+LW,,,23-5 -US-SRM,P,,0.5,PREC-WeightGauge,,,23-5 -US-SRM,PA,,7.82,GA_OP-LI-COR LI-7500,,,23-5 -US-SRM,PPFD_IN,,8.3,RAD-PAR Quantum,,,23-5 -US-SRM,PPFD_IN_PI_F,,8.3,RAD-PAR Quantum,,,23-5 -US-SRM,PPFD_OUT,,7.1,RAD-PAR Quantum,,,23-5 -US-SRM,RH_1_1_1,,6,RH-Capac,,,23-5 -US-SRM,RH_1_1_2,,2,RH-Capac,,,23-5 -US-SRM,SWC_PI_1_1_A,,-0.05,SWC-TDR,,,23-5 -US-SRM,SWC_PI_1_2_A,,-0.1,SWC-TDR,,,23-5 -US-SRM,SWC_PI_1_3_A,,-0.2,SWC-TDR,,,23-5 -US-SRM,SWC_PI_1_4_A,,-0.3,SWC-TDR,,,23-5 -US-SRM,SWC_PI_1_5_A,,-0.5,SWC-TDR,,,23-5 -US-SRM,SWC_PI_1_6_A,,-0.7,SWC-TDR,,,23-5 -US-SRM,SWC_PI_1_7_A,,-1,SWC-TDR,,,23-5 -US-SRM,SWC_PI_1_8_A,,-1.3,SWC-TDR,,,23-5 -US-SRM,SW_IN,,7.1,RAD-Pyrrad-SW+LW,,,23-5 -US-SRM,SW_OUT,,7.1,RAD-Pyrrad-SW+LW,,,23-5 -US-SRM,TA_1_1_1,,6,TEMP-ElectResis,,,23-5 -US-SRM,TA_1_2_1,,2,TEMP-ElectResis,,,23-5 -US-SRM,T_CANOPY_1_1_1,,7,TEMP-Other,,,23-5 -US-SRM,T_CANOPY_2_1_1,,7,TEMP-Other,,,23-5 -US-SRM,TS_PI_1_1_A,,-0.05,TEMP-TCouple,,,23-5 -US-SRM,TS_PI_1_2_A,,-0.1,TEMP-TCouple,,,23-5 -US-SRM,TS_PI_1_3_A,,-0.2,TEMP-TCouple,,,23-5 -US-SRM,TS_PI_1_4_A,,-0.3,TEMP-TCouple,,,23-5 -US-SRM,TS_PI_1_5_A,,-0.5,TEMP-TCouple,,,23-5 -US-SRM,TS_PI_1_6_A,,-0.7,TEMP-TCouple,,,23-5 -US-SRM,TS_PI_1_7_A,,-1,TEMP-TCouple,,,23-5 -US-SRM,TS_PI_1_8_A,,-1.3,TEMP-TCouple,,,23-5 -US-SRM,T_SONIC,,7.82,SA-Campbell CSAT-3,,,23-5 -US-SRM,USTAR,,7.82,SA-Campbell CSAT-3,,,23-5 -US-SRM,WD_1_1_1,,7.8,SA-Campbell CSAT-3,,,23-5 -US-SRM,WD_1_2_1,,3.5,WIND-VaneAn,,,23-5 -US-SRM,WS_1_1_1,,7.8,SA-Campbell CSAT-3,,,23-5 -US-SRM,WS_1_2_1,,3.5,WIND-CupAn,,,23-5 -US-Srr,CH4,,0,,,,1-5 -US-Srr,CO2,,3.4,,,,1-5 -US-Srr,FC,,3.4,,,,1-5 -US-Srr,FC_PI_F,,0,,,,1-5 -US-Srr,FCH4,,0,,,,1-5 -US-Srr,FCH4_PI_F,,0,,,,1-5 -US-Srr,FCH4_SSITC_TEST,,0,,,,1-5 -US-Srr,FC_SSITC_TEST,,0,,,,1-5 -US-Srr,G,,0,,,,1-5 -US-Srr,GPP_PI_F,,0,,,,1-5 -US-Srr,H,,0,,,,1-5 -US-Srr,H2O,,0,,,,1-5 -US-Srr,H_PI_F,,0,,,,1-5 -US-Srr,H_SSITC_TEST,,0,,,,1-5 -US-Srr,LE,,0,,,,1-5 -US-Srr,LE_PI_F,,0,,,,1-5 -US-Srr,LE_SSITC_TEST,,0,,,,1-5 -US-Srr,LW_IN,,0,,,,1-5 -US-Srr,LW_OUT,,0,,,,1-5 -US-Srr,MO_LENGTH,,0,,,,1-5 -US-Srr,NETRAD,,0,,,,1-5 -US-Srr,PA,,0,,,,1-5 -US-Srr,PPFD_IN,,0,,,,1-5 -US-Srr,PPFD_OUT,,0,,,,1-5 -US-Srr,RECO_PI_F,,0,,,,1-5 -US-Srr,RH,,0,,,,1-5 -US-Srr,SW_IN,,0,,,,1-5 -US-Srr,SW_OUT,,0,,,,1-5 -US-Srr,TA,,0,,,,1-5 -US-Srr,TAU,,0,,,,1-5 -US-Srr,TAU_SSITC_TEST,,0,,,,1-5 -US-Srr,TS_1,,0,,,,1-5 -US-Srr,TS_2,,0,,,,1-5 -US-Srr,TS_3,,0,,,,1-5 -US-Srr,TS_4,,0,,,,1-5 -US-Srr,TS_5,,0,,,,1-5 -US-Srr,T_SONIC,,0,,,,1-5 -US-Srr,T_SONIC_SIGMA,,0,,,,1-5 -US-Srr,USTAR,,0,,,,1-5 -US-Srr,VPD_PI,,0,,,,1-5 -US-Srr,V_SIGMA,,0,,,,1-5 -US-Srr,WD,,0,,,,1-5 -US-Srr,WS,,0,,,,1-5 -US-Srr,W_SIGMA,,0,,,,1-5 -US-Srr,WTD,,0,,,,1-5 -US-Srr,ZL,,0,,,,1-5 -US-SRS,CO2,,7.1,GA_OP-LI-COR LI-7500,,,3-5 -US-SRS,CO2_SIGMA,,7.1,GA_OP-LI-COR LI-7500,,,3-5 -US-SRS,FC,,7.1,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,3-5 -US-SRS,G_1_1_1,,-0.1,SOIL_H-Plate,,,3-5 -US-SRS,G_1_2_1,,-0.1,SOIL_H-Plate,,,3-5 -US-SRS,H,,7.1,SA-Campbell CSAT-3,,,3-5 -US-SRS,H2O,,7.1,GA_OP-LI-COR LI-7500,,,3-5 -US-SRS,H2O_SIGMA,,7.1,GA_OP-LI-COR LI-7500,,,3-5 -US-SRS,LE,,7.1,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,3-5 -US-SRS,NETRAD,,5,RAD-Net radiometer,,,3-5 -US-SRS,PA,,1,PRES-ElectBar,,,3-5 -US-SRS,PPFD_IN,,5,RAD-PAR Quantum,,,3-5 -US-SRS,PPFD_OUT,,5,RAD-PAR Quantum,,,3-5 -US-SRS,P_RAIN,,1,RAIN-TipBucGauge,,,3-5 -US-SRS,RH,,3,RH-Capac,,,3-5 -US-SRS,SWC_1_1_1,,-0.05,SWC-TDR,,,3-5 -US-SRS,SWC_1_2_1,,-0.15,SWC-TDR,,,3-5 -US-SRS,SWC_1_3_1,,-0.3,SWC-TDR,,,3-5 -US-SRS,SWC_1_4_1,,-0.5,SWC-TDR,,,3-5 -US-SRS,SWC_1_5_1,,-0.75,SWC-TDR,,,3-5 -US-SRS,SWC_1_6_1,,-1,SWC-TDR,,,3-5 -US-SRS,SW_IN,,5,RAD-Net radiometer,,,3-5 -US-SRS,SW_OUT,,5,RAD-Net radiometer,,,3-5 -US-SRS,TAU,,7.1,SA-Campbell CSAT-3,,,3-5 -US-SRS,TS_1_1_1,,-0.1,MULTI-Other,,,3-5 -US-SRS,TS_1_2_1,,-0.1,MULTI-Other,,,3-5 -US-SRS,TS_1_3_1,,-0.1,MULTI-Other,,,3-5 -US-SRS,TS_1_4_1,,-0.1,MULTI-Other,,,3-5 -US-SRS,T_SONIC,,7.1,SA-Campbell CSAT-3,,,3-5 -US-SRS,T_SONIC_SIGMA,,7.1,SA-Campbell CSAT-3,,,3-5 -US-SRS,U_SIGMA,,7.1,SA-Campbell CSAT-3,,,3-5 -US-SRS,USTAR,,7.1,SA-Campbell CSAT-3,,,3-5 -US-SRS,VPD_PI,,3,RH-Capac,,,3-5 -US-SRS,V_SIGMA,,7.1,SA-Campbell CSAT-3,,,3-5 -US-SRS,WD,,7.1,SA-Campbell CSAT-3,,,3-5 -US-SRS,WS,,7.1,SA-Campbell CSAT-3,,,3-5 -US-SRS,W_SIGMA,,7.1,SA-Campbell CSAT-3,,,3-5 -US-SRS,WS_MAX,,7.1,SA-Campbell CSAT-3,,,3-5 -US-Sta,CO2,,3,,,,2-5 -US-Sta,FC,,3,SA-Other,,CSAT/LI7500,2-5 -US-Sta,G_1_1_1,,-0.05,,,,2-5 -US-Sta,H,,3,SA-Other,,CSAT/LI7500,2-5 -US-Sta,H2O,,3,,,,2-5 -US-Sta,LE,,3,SA-Other,,CSAT/LI7500,2-5 -US-Sta,PA,,1,,,,2-5 -US-Sta,PPFD_IN,,3,,,,2-5 -US-Sta,RH,,3,,,,2-5 -US-Sta,SWC_1_2_1,,-0.45,,,,2-5 -US-Sta,TA,,2,,,,2-5 -US-Sta,TS_1_1_1,,-0.1,TEMP-Other,,Thermocouple,2-5 -US-Sta,TS_1_2_1,,-0.2,TEMP-Other,,Thermocouple,2-5 -US-Sta,USTAR,,3,WIND-Other,,CSAT,2-5 -US-Sta,VPD_PI,,3,,,,2-5 -US-Sta,WD,,3,WIND-Other,,CSAT,2-5 -US-Sta,WS,,3,,,,2-5 -US-StJ,CH4,,0,,,,2-5 -US-StJ,CO2,,3.6,,,,2-5 -US-StJ,FC,,3.6,,,,2-5 -US-StJ,FCH4,,0,,,,2-5 -US-StJ,FCH4_SSITC_TEST,,0,,,,2-5 -US-StJ,FC_SSITC_TEST,,0,,,,2-5 -US-StJ,FETCH_70,,0,,,,2-5 -US-StJ,FETCH_90,,0,,,,2-5 -US-StJ,FETCH_FILTER,,0,,,,2-5 -US-StJ,FETCH_MAX,,0,,,,2-5 -US-StJ,H,,0,,,,2-5 -US-StJ,H2O,,0,,,,2-5 -US-StJ,H_SSITC_TEST,,0,,,,2-5 -US-StJ,LE,,0,,,,2-5 -US-StJ,LE_SSITC_TEST,,0,,,,2-5 -US-StJ,MO_LENGTH,,0,,,,2-5 -US-StJ,NDVI,,0,,,,2-5 -US-StJ,NEE_PI,,0,,,,2-5 -US-StJ,NETRAD,,0,,,,2-5 -US-StJ,P,,0,,,,2-5 -US-StJ,PA,,0,,,,2-5 -US-StJ,PPFD_IN,,0,,,,2-5 -US-StJ,PPFD_OUT,,0,,,,2-5 -US-StJ,PRI,,0,,,,2-5 -US-StJ,RH,,0,,,,2-5 -US-StJ,SC,,0,,,,2-5 -US-StJ,SCH4,,0,,,,2-5 -US-StJ,SH,,0,,,,2-5 -US-StJ,SLE,,0,,,,2-5 -US-StJ,SPEC_NIR_IN,,0,,,,2-5 -US-StJ,SPEC_NIR_REFL,,0,,,,2-5 -US-StJ,SPEC_PRI_REF_IN,,0,,,,2-5 -US-StJ,SPEC_PRI_REF_OUT,,0,,,,2-5 -US-StJ,SPEC_PRI_TGT_IN,,0,,,,2-5 -US-StJ,SPEC_PRI_TGT_OUT,,0,,,,2-5 -US-StJ,SPEC_RED_IN,,0,,,,2-5 -US-StJ,SPEC_RED_OUT,,0,,,,2-5 -US-StJ,SWC_1_2_1,,0,,,,2-5 -US-StJ,SWC_1_3_1,,0,,,,2-5 -US-StJ,TA,,0,,,,2-5 -US-StJ,TAU,,0,,,,2-5 -US-StJ,TAU_SSITC_TEST,,0,,,,2-5 -US-StJ,TS_1_2_1,,0,,,,2-5 -US-StJ,TS_1_3_1,,0,,,,2-5 -US-StJ,T_SONIC,,0,,,,2-5 -US-StJ,U_SIGMA,,0,,,,2-5 -US-StJ,USTAR,,0,,,,2-5 -US-StJ,VPD_PI,,0,,,,2-5 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-US-Syv,PA,,36,PRES-ElectBar,,,20-5 -US-Syv,PA_1_1_1,2009,36,PRES-ElectBar,,,20-5 -US-Syv,P_PI_F,2012,,RAIN-TipBucGauge,,,20-5 -US-Syv,P_PI_F,,,PREC-TipBucGauge,,,20-5 -US-Syv,PPFD_DIF,,36,RAD-PAR Quantum,,,20-5 -US-Syv,PPFD_IN_1_1_1,,36,RAD-PAR Quantum,,,20-5 -US-Syv,PPFD_IN_1_2_1,,12,RAD-PAR Quantum,,,20-5 -US-Syv,PPFD_IN_1_3_1,,6,RAD-PAR Quantum,,,20-5 -US-Syv,PPFD_IN_1_4_1,,1,RAD-PAR Quantum,,,20-5 -US-Syv,RECO_PI_F,,36,GA_CP-LI-COR LI-7200RS,SA-Campbell CSAT-3,,20-5 -US-Syv,RH_1_1_1,,36,RH-ElecRes,,,20-5 -US-Syv,RH_1_2_1,2020,20,RH-ElecRes,,,20-5 -US-Syv,RH_1_3_1,2020,10,RH-ElecRes,,,20-5 -US-Syv,SC_1_1_1,,36,GA-Other,,,20-5 -US-Syv,SH_PI_F_1_1_1,,36,TEMP-TCouple,,,20-5 -US-Syv,SLE_PI_F_1_1_1,,36,RH-ElecRes,,,20-5 -US-Syv,SWC_1_1_1,,-0.05,SWC-TDR,,,20-5 -US-Syv,SWC_1_2_1,,-0.1,SWC-TDR,,,20-5 -US-Syv,SWC_1_3_1,,-0.2,SWC-TDR,,,20-5 -US-Syv,SWC_1_4_1,,-0.5,SWC-TDR,,,20-5 -US-Syv,SWC_1_5_1,,-1,SWC-TDR,,,20-5 -US-Syv,SW_IN_1_1_1,,36,RAD-Pyrrad-SW+LW,,CNR4,20-5 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-US-Syv,VPD_PI_F_1_1_1,,36,RH-ElecRes,,,20-5 -US-Syv,WD_1_1_1,,36,SA-Campbell CSAT-3,,,20-5 -US-Syv,WD_1_2_1,,20,WIND-VaneAn,,,20-5 -US-Syv,WS_1_1_1,,36,SA-Campbell CSAT-3,,,20-5 -US-Syv,WS_1_2_1,,20,WIND-CupAn,,,20-5 -US-Syv,ZL,,36,SA-Campbell CSAT-3,,,20-5 -US-Ton,CO2_1_1_1,20170524,23.5,GA_OP-LI-COR LI-7500A,,,16-5 -US-Ton,CO2_1_1_1,,23.5,GA_OP-LI-COR LI-7500,,,16-5 -US-Ton,CO2_1_2_1,20170524,2,GA_OP-LI-COR LI-7500A,,,16-5 -US-Ton,CO2_1_2_1,,2,GA_OP-LI-COR LI-7500,,,16-5 -US-Ton,FC_1_1_1,20170524,23.5,GA_OP-LI-COR LI-7500A,SA-Gill Windmaster,,16-5 -US-Ton,FC_1_1_1,,23.5,GA_OP-LI-COR LI-7500,SA-Gill Windmaster Pro,,16-5 -US-Ton,FC_1_2_1,20170524,2,GA_OP-LI-COR LI-7500A,SA-Gill Windmaster,,16-5 -US-Ton,FC_1_2_1,,2,GA_OP-LI-COR LI-7500,SA-Gill Windmaster Pro,,16-5 -US-Ton,FC_QC_1_1_1,,23.5,,,,16-5 -US-Ton,FC_QC_1_2_1,,2,,,,16-5 -US-Ton,G_PI_F_1_2_1,,-0.01,SOIL_H-Plate,,,16-5 -US-Ton,GPP_PI_F_1_1_1,20170524,23.5,GA_OP-LI-COR LI-7500A,SA-Gill Windmaster,,16-5 -US-Ton,GPP_PI_F_1_1_1,,23.5,GA_OP-LI-COR LI-7500,SA-Gill Windmaster Pro,,16-5 -US-Ton,GPP_PI_F_1_2_1,20170524,2,GA_OP-LI-COR LI-7500A,SA-Gill Windmaster,,16-5 -US-Ton,GPP_PI_F_1_2_1,,2,GA_OP-LI-COR LI-7500,SA-Gill Windmaster Pro,,16-5 -US-Ton,H_1_1_1,20170524,23.5,SA-Gill Windmaster,,,16-5 -US-Ton,H_1_1_1,,23.5,SA-Gill Windmaster Pro,,,16-5 -US-Ton,H_1_2_1,20170524,2,SA-Gill Windmaster,,,16-5 -US-Ton,H_1_2_1,,2,SA-Gill Windmaster Pro,,,16-5 -US-Ton,H_PI_F_1_1_1,20170524,23.5,SA-Gill Windmaster,,,16-5 -US-Ton,H_PI_F_1_1_1,,23.5,SA-Gill Windmaster Pro,,,16-5 -US-Ton,H_PI_F_1_2_1,20170524,2,SA-Gill Windmaster,,,16-5 -US-Ton,H_PI_F_1_2_1,,2,SA-Gill Windmaster Pro,,,16-5 -US-Ton,LE_1_1_1,20170524,23.5,GA_OP-LI-COR LI-7500A,SA-Gill Windmaster,,16-5 -US-Ton,LE_1_1_1,,23.5,GA_OP-LI-COR LI-7500,SA-Gill Windmaster Pro,,16-5 -US-Ton,LE_1_2_1,20170524,2,GA_OP-LI-COR LI-7500A,SA-Gill Windmaster,,16-5 -US-Ton,LE_1_2_1,,2,GA_OP-LI-COR LI-7500,SA-Gill Windmaster Pro,,16-5 -US-Ton,LE_PI_F_1_1_1,20170524,23.5,GA_OP-LI-COR LI-7500A,SA-Gill Windmaster,,16-5 -US-Ton,LE_PI_F_1_1_1,,23.5,GA_OP-LI-COR LI-7500,SA-Gill Windmaster Pro,,16-5 -US-Ton,LE_PI_F_1_2_1,20170524,2,GA_OP-LI-COR LI-7500A,SA-Gill Windmaster,,16-5 -US-Ton,LE_PI_F_1_2_1,,2,GA_OP-LI-COR LI-7500,SA-Gill Windmaster Pro,,16-5 -US-Ton,NETRAD,20170825,23.5,RAD-Pyrrad-SW+LW,,,16-5 -US-Ton,NETRAD,,23.5,RAD-Net radiometer,,,16-5 -US-Ton,NETRAD_PI_F,20170825,23.5,RAD-Pyrrad-SW+LW,,,16-5 -US-Ton,NETRAD_PI_F,,23.5,RAD-Net radiometer,,,16-5 -US-Ton,P_1_1_1,,23.5,PREC-TipBucGauge,,,16-5 -US-Ton,PA_1_1_1,,23.5,PRES-ElectBar,,,16-5 -US-Ton,PA_1_2_1,,2,PRES-ElectBar,,,16-5 -US-Ton,PA_PI_F_1_1_1,,23.5,PRES-ElectBar,,,16-5 -US-Ton,PA_PI_F_1_2_1,,2,PRES-ElectBar,,,16-5 -US-Ton,P_PI_F_1_1_1,,23.5,PREC-TipBucGauge,,,16-5 -US-Ton,P_PI_F_1_2_1,,2,PREC-TipBucGauge,,,16-5 -US-Ton,PPFD_IN,,23.5,RAD-PAR Quantum,,,16-5 -US-Ton,PPFD_IN_PI_F,,23.5,RAD-PAR Quantum,,,16-5 -US-Ton,PPFD_OUT,,23.5,RAD-PAR Quantum,,,16-5 -US-Ton,RECO_PI_F_1_1_1,,23.5,,SA-Gill R2,,16-5 -US-Ton,RECO_PI_F_1_2_1,,2,,SA-Gill R2,,16-5 -US-Ton,RH_1_1_1,,23.5,RH-Capac,,,16-5 -US-Ton,RH_1_2_1,,2,RH-Capac,,,16-5 -US-Ton,RH_PI_F_1_1_1,,23.5,RH-Capac,,,16-5 -US-Ton,RH_PI_F_1_2_1,,2,RH-Capac,,,16-5 -US-Ton,SC_PI_F_1_1_1,20170524,23.5,GA_OP-LI-COR LI-7500A,,GA_SR-LI-COR LI-820; GA_SR-LI-COR LI-840,16-5 -US-Ton,SC_PI_F_1_1_1,,23.5,GA_OP-LI-COR LI-7500,,GA_SR-LI-COR LI-820; GA_SR-LI-COR LI-840,16-5 -US-Ton,SC_PI_F_1_2_1,20170524,2,GA_OP-LI-COR LI-7500A,,GA_SR-LI-COR LI-820; GA_SR-LI-COR LI-840,16-5 -US-Ton,SC_PI_F_1_2_1,,2,GA_OP-LI-COR LI-7500,,GA_SR-LI-COR LI-820; GA_SR-LI-COR LI-840,16-5 -US-Ton,SG_1_1_1,,-0.01,SOIL_H-Plate,,,16-5 -US-Ton,SWC_1_1_1,,-0,SWC-TDR,,,16-5 -US-Ton,SWC_1_2_1,,-0.2,SWC-TDR,,,16-5 -US-Ton,SWC_1_3_1,,-0.5,SWC-TDR,,,16-5 -US-Ton,SWC_PI_F_1_1_1,,-0,SWC-TDR,,,16-5 -US-Ton,SWC_PI_F_1_2_1,,-0.2,SWC-TDR,,,16-5 -US-Ton,SWC_PI_F_1_3_1,,-0.5,SWC-TDR,,,16-5 -US-Ton,SW_IN,,23.5,RAD-SW Pyran Class1,,,16-5 -US-Ton,SW_IN_PI_F,,23.5,RAD-SW Pyran Class1,,,16-5 -US-Ton,TA_1_1_1,,23.5,TEMP-ElectResis,,,16-5 -US-Ton,TA_1_2_1,,2,TEMP-ElectResis,,,16-5 -US-Ton,TA_PI_F_1_1_1,,23.5,TEMP-ElectResis,,,16-5 -US-Ton,TA_PI_F_1_2_1,,2,TEMP-ElectResis,,,16-5 -US-Ton,TS_1_1_1,,-0.02,TEMP-TCouple,,,16-5 -US-Ton,TS_1_2_1,,-0.04,TEMP-TCouple,,,16-5 -US-Ton,TS_1_3_1,,-0.08,TEMP-TCouple,,,16-5 -US-Ton,TS_1_4_1,,-0.16,TEMP-TCouple,,,16-5 -US-Ton,TS_1_5_1,,-0.32,TEMP-TCouple,,,16-5 -US-Ton,TS_PI_F_1_1_1,,-0.02,TEMP-TCouple,,,16-5 -US-Ton,TS_PI_F_1_2_1,,-0.04,TEMP-TCouple,,,16-5 -US-Ton,TS_PI_F_1_3_1,,-0.08,TEMP-TCouple,,,16-5 -US-Ton,TS_PI_F_1_4_1,,-0.16,TEMP-TCouple,,,16-5 -US-Ton,TS_PI_F_1_5_1,,-0.32,TEMP-TCouple,,,16-5 -US-Ton,T_SONIC_1_1_1,20170524,23.5,SA-Gill Windmaster,,,16-5 -US-Ton,T_SONIC_1_1_1,,23.5,SA-Gill Windmaster Pro,,,16-5 -US-Ton,T_SONIC_1_2_1,20170524,2,SA-Gill Windmaster,,,16-5 -US-Ton,T_SONIC_1_2_1,,2,SA-Gill Windmaster Pro,,,16-5 -US-Ton,T_SONIC_SIGMA_1_1_1,20170524,23.5,SA-Gill Windmaster,,,16-5 -US-Ton,T_SONIC_SIGMA_1_1_1,,23.5,SA-Gill Windmaster Pro,,,16-5 -US-Ton,T_SONIC_SIGMA_1_2_1,20170524,2,SA-Gill Windmaster,,,16-5 -US-Ton,T_SONIC_SIGMA_1_2_1,,2,SA-Gill Windmaster Pro,,,16-5 -US-Ton,U_SIGMA_1,20170524,23.5,SA-Gill Windmaster,,,16-5 -US-Ton,U_SIGMA_1,,23.5,SA-Gill Windmaster Pro,,,16-5 -US-Ton,U_SIGMA_2,20170524,2,SA-Gill Windmaster,,,16-5 -US-Ton,U_SIGMA_2,,2,SA-Gill Windmaster Pro,,,16-5 -US-Ton,USTAR_1_1_1,20170524,23.5,SA-Gill Windmaster,,,16-5 -US-Ton,USTAR_1_1_1,,23.5,SA-Gill Windmaster Pro,,,16-5 -US-Ton,USTAR_1_2_1,20170524,2,SA-Gill Windmaster,,,16-5 -US-Ton,USTAR_1_2_1,,2,SA-Gill Windmaster Pro,,,16-5 -US-Ton,USTAR_PI_F_1_1_1,20170524,23.5,SA-Gill Windmaster,,,16-5 -US-Ton,USTAR_PI_F_1_1_1,,23.5,SA-Gill Windmaster Pro,,,16-5 -US-Ton,USTAR_PI_F_1_2_1,20170524,2,SA-Gill Windmaster,,,16-5 -US-Ton,USTAR_PI_F_1_2_1,,2,SA-Gill Windmaster Pro,,,16-5 -US-Ton,VPD_PI_1_1_1,,23.5,RH-Capac,,Temp-ElectResis,16-5 -US-Ton,VPD_PI_1_2_1,,2,RH-Capac,,Temp-ElectResis,16-5 -US-Ton,VPD_PI_F_1_1_1,,23.5,RH-Capac,,Temp-ElectResis,16-5 -US-Ton,VPD_PI_F_1_2_1,,2,RH-Capac,,Temp-ElectResis,16-5 -US-Ton,V_SIGMA_1,20170524,23.5,SA-Gill Windmaster,,,16-5 -US-Ton,V_SIGMA_1,,23.5,SA-Gill Windmaster Pro,,,16-5 -US-Ton,V_SIGMA_2,20170524,2,SA-Gill Windmaster,,,16-5 -US-Ton,V_SIGMA_2,,2,SA-Gill Windmaster Pro,,,16-5 -US-Ton,WD_1_1_1,20170524,23.5,SA-Gill Windmaster,,,16-5 -US-Ton,WD_1_1_1,,23.5,SA-Gill Windmaster Pro,,,16-5 -US-Ton,WD_1_2_1,20170524,2,SA-Gill Windmaster,,,16-5 -US-Ton,WD_1_2_1,,2,SA-Gill Windmaster Pro,,,16-5 -US-Ton,WD_PI_F_1_1_1,20170524,23.5,SA-Gill Windmaster,,,16-5 -US-Ton,WD_PI_F_1_1_1,,23.5,SA-Gill Windmaster Pro,,,16-5 -US-Ton,WD_PI_F_1_2_1,20170524,2,SA-Gill Windmaster,,,16-5 -US-Ton,WD_PI_F_1_2_1,,2,SA-Gill Windmaster Pro,,,16-5 -US-Ton,WS_1_1_1,20170524,23.5,SA-Gill Windmaster,,,16-5 -US-Ton,WS_1_1_1,,23.5,SA-Gill Windmaster Pro,,,16-5 -US-Ton,WS_1_2_1,20170524,2,SA-Gill Windmaster,,,16-5 -US-Ton,WS_1_2_1,,2,SA-Gill Windmaster Pro,,,16-5 -US-Ton,WS_PI_F_1_1_1,20170524,23.5,SA-Gill Windmaster,,,16-5 -US-Ton,WS_PI_F_1_1_1,,23.5,SA-Gill Windmaster Pro,,,16-5 -US-Ton,WS_PI_F_1_2_1,20170524,2,SA-Gill Windmaster,,,16-5 -US-Ton,WS_PI_F_1_2_1,,2,SA-Gill Windmaster Pro,,,16-5 -US-Ton,W_SIGMA_1,20170524,23.5,SA-Gill Windmaster,,,16-5 -US-Ton,W_SIGMA_1,,23.5,SA-Gill Windmaster Pro,,,16-5 -US-Ton,W_SIGMA_1_1_1,20170524,23.5,SA-Gill Windmaster,,,16-5 -US-Ton,W_SIGMA_1_1_1,,23.5,SA-Gill Windmaster Pro,,,16-5 -US-Ton,W_SIGMA_1_2_1,20170524,2,SA-Gill Windmaster,,,16-5 -US-Ton,W_SIGMA_1_2_1,,2,SA-Gill Windmaster Pro,,,16-5 -US-Ton,W_SIGMA_2,20170524,2,SA-Gill Windmaster,,,16-5 -US-Ton,W_SIGMA_2,,2,SA-Gill Windmaster Pro,,,16-5 -US-Ton,ZL_1_1_1,,,SA-Gill R2,,,16-5 -US-Ton,ZL_1_2_1,,,SA-Gill R2,,,16-5 -US-Tw1,CH4,20120502,4.64,GA_OP-LI-COR LI-7700,,Height varies with above ground water table,9-5 -US-Tw1,CO2,20120502,4.64,GA_OP-LI-COR LI-7500A,,Height varies with above ground water table,9-5 -US-Tw1,FC,20120502,4.64,GA_OP-LI-COR LI-7500A,SA-Gill Windmaster,Height varies with above ground water table,9-5 -US-Tw1,FC_PI_F,20120502,4.64,GA_OP-LI-COR LI-7500A,SA-Gill Windmaster,Height varies with above ground water table,9-5 -US-Tw1,FCH4,20120502,4.64,GA_OP-LI-COR LI-7700,SA-Gill Windmaster,Height varies with above ground water table,9-5 -US-Tw1,FCH4_PI_F,20120502,4.64,GA_OP-LI-COR LI-7700,SA-Gill Windmaster,Height varies with above ground water table,9-5 -US-Tw1,GPP_PI_F,20120502,4.64,GA_OP-LI-COR LI-7500A,SA-Gill Windmaster,,9-5 -US-Tw1,H,20120502,4.64,SA-Gill Windmaster,,Height varies with above ground water table,9-5 -US-Tw1,H2O,20120502,4.64,GA_OP-LI-COR LI-7500A,,Height varies with above ground water table,9-5 -US-Tw1,H_PI_F,20120502,4.64,SA-Gill Windmaster,,Height varies with above ground water table,9-5 -US-Tw1,LE,20120502,4.64,GA_OP-LI-COR LI-7500A,SA-Gill Windmaster,Height varies with above ground water table,9-5 -US-Tw1,LE_PI_F,20120502,4.64,GA_OP-LI-COR LI-7500A,SA-Gill Windmaster,Height varies with above ground water table,9-5 -US-Tw1,LW_IN,20120424,4.0,RAD-Pyrrad-SW+LW,,Height varies with above ground water table,9-5 -US-Tw1,LW_OUT,20120424,4.0,RAD-Pyrrad-SW+LW,,Height varies with above ground water table,9-5 -US-Tw1,NETRAD,20120424,4.0,RAD-Pyrrad-SW+LW,,Height varies with above ground water table,9-5 -US-Tw1,PA,20120424,2.02,PRES-ElectBar,,Height varies with above ground water table,9-5 -US-Tw1,PPFD_IN,20120424,4.0,RAD-PAR Quantum,,Height varies with above ground water table,9-5 -US-Tw1,PPFD_OUT,20120424,4.0,RAD-PAR Quantum,,Height varies with above ground water table,9-5 -US-Tw1,RECO_PI_F,20120502,4.64,GA_OP-LI-COR LI-7500A,SA-Gill Windmaster,,9-5 -US-Tw1,RH,20120424,4.64,RH-Capac,,Height varies with above ground water table,9-5 -US-Tw1,SPEC_NIR_IN,20120424,4,SPECT-SpectRad,,Height varies with above ground water table,9-5 -US-Tw1,SPEC_NIR_OUT,20120424,4,SPECT-SpectRad,,Height varies with above ground water table,9-5 -US-Tw1,SPEC_RED_IN,20120424,4,SPECT-SpectRad,,Height varies with above ground water table,9-5 -US-Tw1,SPEC_RED_OUT,20120424,4,SPECT-SpectRad,,Height varies with above ground water table,9-5 -US-Tw1,SW_IN,20120424,4.0,RAD-Pyrrad-SW+LW,,Height varies with above ground water table,9-5 -US-Tw1,SW_OUT,20120424,4.0,RAD-Pyrrad-SW+LW,,Height varies with above ground water table,9-5 -US-Tw1,TA,20120424,4.64,TEMP-ElectResis,,Height varies with above ground water table,9-5 -US-Tw1,TAU,20120502,4.64,SA-Gill Windmaster,,Height varies with above ground water table,9-5 -US-Tw1,TS_1,20120424,-0.02,TEMP-TCouple,,,9-5 -US-Tw1,TS_2,20120424,-0.04,TEMP-TCouple,,,9-5 -US-Tw1,TS_3,20120424,-0.08,TEMP-TCouple,,,9-5 -US-Tw1,TS_4,20120424,-0.16,TEMP-TCouple,,,9-5 -US-Tw1,TS_5,20120424,-0.32,TEMP-TCouple,,,9-5 -US-Tw1,T_SONIC,20120502,4.64,SA-Gill Windmaster,,Height varies with above ground water table,9-5 -US-Tw1,T_SONIC_SIGMA,20120502,4.64,SA-Gill Windmaster,,Height varies with above ground water table,9-5 -US-Tw1,USTAR,20120502,4.64,SA-Gill Windmaster,,Height varies with above ground water table,9-5 -US-Tw1,VPD_PI,,4.64,RH-Capac,,Height varies with above ground water table,9-5 -US-Tw1,V_SIGMA,20120502,4.64,SA-Gill Windmaster,,Height varies with above ground water table,9-5 -US-Tw1,WD,20120502,4.64,SA-Gill Windmaster,,Height varies with above ground water table,9-5 -US-Tw1,WS,20120502,4.64,SA-Gill Windmaster,,Height varies with above ground water table,9-5 -US-Tw1,W_SIGMA,20120502,4.64,SA-Gill Windmaster,,Height varies with above ground water table,9-5 -US-Tw1,WTD,20120424,-0.36,WTD-Press,,,9-5 -US-Tw2,CO2,20150720,5.15,GA_OP-LI-COR LI-7500A,,Upgrade to LI-7500A eddy system,2-5 -US-Tw2,CO2,,5.15,GA_OP-LI-COR LI-7500,,,2-5 -US-Tw2,FC,20150720,5.15,GA_OP-LI-COR LI-7500A,SA-Gill Windmaster,Upgrade to LI-7500A eddy system,2-5 -US-Tw2,FC,,5.15,GA_OP-LI-COR LI-7500,SA-Gill Windmaster Pro,,2-5 -US-Tw2,G,,-0.03,,,,2-5 -US-Tw2,H,,5.15,,,,2-5 -US-Tw2,H2O,,5.15,,,,2-5 -US-Tw2,LE,,5.15,,,,2-5 -US-Tw2,LW_IN,,4.47,RAD-Pyrrad-SW+LW,,,2-5 -US-Tw2,LW_OUT,,4.47,RAD-Pyrrad-SW+LW,,,2-5 -US-Tw2,NEE_PI,,,GA_OP-LI-COR LI-7500,SA-Gill Windmaster Pro,,2-5 -US-Tw2,NETRAD,,4.47,RAD-Pyrrad-SW+LW,,,2-5 -US-Tw2,PA,,,PRES-ElectBar,,,2-5 -US-Tw2,PPFD_IN,,4.47,RAD-PAR Quantum,,,2-5 -US-Tw2,PPFD_OUT,,4.47,RAD-PAR Quantum,,,2-5 -US-Tw2,RH,,5.0,RH-Capac,,,2-5 -US-Tw2,SWC_1_1_1,,-0.1,SWC-TDR,,,2-5 -US-Tw2,SWC_1_2_1,,-0.2,SWC-TDR,,,2-5 -US-Tw2,SW_IN,,4.47,RAD-Pyrrad-SW+LW,,,2-5 -US-Tw2,SW_OUT,,4.47,RAD-Pyrrad-SW+LW,,,2-5 -US-Tw2,TA,,5.0,,,,2-5 -US-Tw2,TS_1_1_1,,-0.02,,,,2-5 -US-Tw2,TS_1_2_1,,-0.04,,,,2-5 -US-Tw2,USTAR,,5.2,,,,2-5 -US-Tw2,VPD_PI,,5.0,,,,2-5 -US-Tw2,WD,,5.2,,,,2-5 -US-Tw2,WS,,5.2,,,,2-5 -US-Tw3,CH4,,2.8,GA_OP-LI-COR LI-7700,,,5-5 -US-Tw3,CO2,,2.8,GA_OP-LI-COR LI-7500A,,,5-5 -US-Tw3,FC,,2.8,GA_OP-LI-COR LI-7500A,SA-Gill Windmaster,,5-5 -US-Tw3,FC_PI_F,,2.8,GA_OP-LI-COR LI-7500A,SA-Gill Windmaster,,5-5 -US-Tw3,FCH4,,2.8,GA_OP-LI-COR LI-7700,SA-Gill Windmaster,,5-5 -US-Tw3,G,,-0.03,SOIL_H-Plate,,,5-5 -US-Tw3,H,,2.8,SA-Gill Windmaster,,,5-5 -US-Tw3,H2O,,2.8,GA_OP-LI-COR LI-7500A,,,5-5 -US-Tw3,H_PI_F,,2.8,SA-Gill Windmaster,,,5-5 -US-Tw3,LE,,2.8,GA_OP-LI-COR LI-7500A,SA-Gill Windmaster,,5-5 -US-Tw3,LE_PI_F,,2.8,GA_OP-LI-COR LI-7500A,SA-Gill Windmaster,,5-5 -US-Tw3,LW_IN,,1.5,RAD-Pyrrad-SW+LW,,,5-5 -US-Tw3,LW_OUT,,1.5,RAD-Pyrrad-SW+LW,,,5-5 -US-Tw3,NETRAD,,1.5,RAD-Pyrrad-SW+LW,,,5-5 -US-Tw3,PA,,,PRES-ElectBar,,,5-5 -US-Tw3,PPFD_IN,,1.5,RAD-PAR Quantum,,,5-5 -US-Tw3,PPFD_OUT,,1.5,RAD-PAR Quantum,,,5-5 -US-Tw3,RH,,2.6,RH-Capac,,,5-5 -US-Tw3,SWC_1_1_1,,-0.1,SWC-TDR,,,5-5 -US-Tw3,SWC_1_2_1,,-0.2,SWC-TDR,,,5-5 -US-Tw3,SW_IN,,1.5,RAD-Pyrrad-SW+LW,,,5-5 -US-Tw3,SW_OUT,,1.5,RAD-Pyrrad-SW+LW,,,5-5 -US-Tw3,TA,,2.6,TEMP-ElectResis,,,5-5 -US-Tw3,TAU,,2.8,SA-Gill Windmaster,,,5-5 -US-Tw3,TS_1_1_1,,-0.02,TEMP-TCouple,,,5-5 -US-Tw3,TS_1_2_1,,-0.04,TEMP-TCouple,,,5-5 -US-Tw3,TS_1_3_1,,-0.08,TEMP-TCouple,,,5-5 -US-Tw3,TS_1_4_1,,-0.16,TEMP-TCouple,,,5-5 -US-Tw3,TS_1_5_1,,-0.32,TEMP-TCouple,,,5-5 -US-Tw3,T_SONIC,,2.8,SA-Gill Windmaster,,,5-5 -US-Tw3,T_SONIC_SIGMA,,2.8,SA-Gill Windmaster,,,5-5 -US-Tw3,USTAR,,2.8,SA-Gill Windmaster,,,5-5 -US-Tw3,VPD_PI,,2.6,RH-Capac,,Temp-ElectResis,5-5 -US-Tw3,V_SIGMA,,2.8,SA-Gill Windmaster,,,5-5 -US-Tw3,WD,,2.8,SA-Gill Windmaster,,,5-5 -US-Tw3,WS,,2.8,SA-Gill Windmaster,,,5-5 -US-Tw3,W_SIGMA,,2.8,SA-Gill Windmaster,,,5-5 -US-Tw4,CH4,,5.36,GA_OP-LI-COR LI-7700,,,12-5 -US-Tw4,CO2,20150720,5.36,GA_OP-LI-COR LI-7500A,,,12-5 -US-Tw4,CO2,,5.36,GA_OP-LI-COR LI-7500,,,12-5 -US-Tw4,FC,20150720,5.36,GA_OP-LI-COR LI-7500A,SA-Gill Windmaster,,12-5 -US-Tw4,FC,,5.36,GA_OP-LI-COR LI-7500,SA-Gill Windmaster Pro,,12-5 -US-Tw4,FC_PI_F,20150720,5.36,GA_OP-LI-COR LI-7500A,SA-Gill Windmaster,,12-5 -US-Tw4,FC_PI_F,,5.36,GA_OP-LI-COR LI-7500,SA-Gill Windmaster Pro,,12-5 -US-Tw4,FCH4,20150720,5.36,GA_OP-LI-COR LI-7700,SA-Gill Windmaster,,12-5 -US-Tw4,FCH4,,5.36,GA_OP-LI-COR LI-7700,SA-Gill Windmaster Pro,,12-5 -US-Tw4,FCH4_PI_F,20150720,5.36,GA_OP-LI-COR LI-7700,SA-Gill Windmaster,,12-5 -US-Tw4,FCH4_PI_F,,5.36,GA_OP-LI-COR LI-7700,SA-Gill Windmaster Pro,,12-5 -US-Tw4,FH2O,20150720,5.36,GA_OP-LI-COR LI-7500A,,SA-Gill Windmaster,12-5 -US-Tw4,FH2O,,5.36,GA_OP-LI-COR LI-7500,,SA-Gill Windmaster Pro,12-5 -US-Tw4,FH2O_PI_F,20150720,5.36,GA_OP-LI-COR LI-7500A,,SA-Gill Windmaster,12-5 -US-Tw4,FH2O_PI_F,,5.36,GA_OP-LI-COR LI-7500,,SA-Gill Windmaster Pro,12-5 -US-Tw4,G,,-0.03,SOIL_H-Plate,,,12-5 -US-Tw4,H,20150720,5.36,SA-Gill Windmaster,,,12-5 -US-Tw4,H,,5.36,SA-Gill Windmaster Pro,,,12-5 -US-Tw4,H2O,20150720,5.36,GA_OP-LI-COR LI-7500A,,,12-5 -US-Tw4,H2O,,5.36,GA_OP-LI-COR LI-7500,,,12-5 -US-Tw4,H_PI_F,20150720,5.36,SA-Gill Windmaster,,,12-5 -US-Tw4,H_PI_F,,5.36,SA-Gill Windmaster Pro,,,12-5 -US-Tw4,LE,20150720,5.36,GA_OP-LI-COR LI-7500A,SA-Gill Windmaster,,12-5 -US-Tw4,LE,,5.36,GA_OP-LI-COR LI-7500,SA-Gill Windmaster Pro,,12-5 -US-Tw4,LE_PI_F,20150720,5.36,GA_OP-LI-COR LI-7500A,SA-Gill Windmaster,,12-5 -US-Tw4,LE_PI_F,,5.36,GA_OP-LI-COR LI-7500,SA-Gill Windmaster Pro,,12-5 -US-Tw4,LW_IN,,4.5,RAD-Pyrrad-SW+LW,,,12-5 -US-Tw4,LW_OUT,,4.5,RAD-Pyrrad-SW+LW,,,12-5 -US-Tw4,NETRAD,,4.5,RAD-Pyrrad-SW+LW,,,12-5 -US-Tw4,P,,4.83,RAIN-TipBucGauge,,,12-5 -US-Tw4,PA,,,PRES-ElectBar,,,12-5 -US-Tw4,PPFD_IN,,4.5,RAD-PAR Quantum,,,12-5 -US-Tw4,PPFD_OUT,,4.5,RAD-PAR Quantum,,,12-5 -US-Tw4,RH,,5,RH-Capac,,,12-5 -US-Tw4,SW_IN,,4.5,RAD-Pyrrad-SW+LW,,,12-5 -US-Tw4,SW_OUT,,4.5,RAD-Pyrrad-SW+LW,,,12-5 -US-Tw4,TA,,5,TEMP-ElectResis,,,12-5 -US-Tw4,TAU,20150720,5.36,SA-Gill Windmaster,,,12-5 -US-Tw4,TAU,,5.36,SA-Gill Windmaster Pro,,,12-5 -US-Tw4,TS_1_1_1,,-0,TEMP-TCouple,,,12-5 -US-Tw4,TS_1_2_1,,-0.02,TEMP-TCouple,,,12-5 -US-Tw4,TS_1_3_1,,-0.08,TEMP-TCouple,,,12-5 -US-Tw4,TS_1_4_1,,-0.16,TEMP-TCouple,,,12-5 -US-Tw4,TS_1_5_1,,-0.32,TEMP-TCouple,,,12-5 -US-Tw4,USTAR,20150720,5.36,SA-Gill Windmaster,,,12-5 -US-Tw4,USTAR,,5.36,SA-Gill Windmaster Pro,,,12-5 -US-Tw4,USTAR_PI_F,20150720,5.36,SA-Gill Windmaster,,,12-5 -US-Tw4,USTAR_PI_F,,5.36,SA-Gill Windmaster Pro,,,12-5 -US-Tw4,VPD_PI,,5,RH-Capac,,Temp-ElectResis,12-5 -US-Tw4,V_SIGMA,20150720,5.36,SA-Gill Windmaster,,,12-5 -US-Tw4,V_SIGMA,,5.36,SA-Gill Windmaster Pro,,,12-5 -US-Tw4,WD,20150720,5.36,SA-Gill Windmaster,,,12-5 -US-Tw4,WD,,5.36,SA-Gill Windmaster Pro,,,12-5 -US-Tw4,WD_PI_F,20150720,5.36,SA-Gill Windmaster,,,12-5 -US-Tw4,WD_PI_F,,5.36,SA-Gill Windmaster Pro,,,12-5 -US-Tw4,WS,20150720,5.36,SA-Gill Windmaster,,,12-5 -US-Tw4,WS,,5.36,SA-Gill Windmaster Pro,,,12-5 -US-Tw4,W_SIGMA,20150720,5.36,SA-Gill Windmaster,,,12-5 -US-Tw4,W_SIGMA,,5.36,SA-Gill Windmaster Pro,,,12-5 -US-Tw4,WTD,,,WTD-Press,,,12-5 -US-Tw5,CH4,20180417,5.82,GA_OP-LI-COR LI-7700,,,3-5 -US-Tw5,CH4,20180628,6.12,GA_OP-LI-COR LI-7700,,Raised eddy sensors 30cm,3-5 -US-Tw5,CO2,20180628,6.12,GA_OP-LI-COR LI-7500A,,Raised eddy sensors 30cm,3-5 -US-Tw5,CO2,,5.82,GA_OP-LI-COR LI-7500A,,,3-5 -US-Tw5,FC,20180628,6.12,GA_OP-LI-COR LI-7500A,SA-Gill Windmaster,Raised eddy sensors 30cm,3-5 -US-Tw5,FC,,5.82,GA_OP-LI-COR LI-7500A,SA-Gill Windmaster,,3-5 -US-Tw5,FC_PI_F,20180628,6.12,GA_OP-LI-COR LI-7500A,SA-Gill Windmaster,Raised eddy sensors 30cm,3-5 -US-Tw5,FC_PI_F,,5.82,GA_OP-LI-COR LI-7500A,SA-Gill Windmaster,,3-5 -US-Tw5,FCH4,20180628,6.12,GA_OP-LI-COR LI-7700,SA-Gill Windmaster,Raised eddy sensors 30cm,3-5 -US-Tw5,FCH4,,5.82,GA_OP-LI-COR LI-7700,SA-Gill Windmaster,,3-5 -US-Tw5,FCH4_PI_F,20180628,6.12,GA_OP-LI-COR LI-7700,SA-Gill Windmaster,Raised eddy sensors 30cm,3-5 -US-Tw5,FCH4_PI_F,,5.82,GA_OP-LI-COR LI-7700,SA-Gill Windmaster,,3-5 -US-Tw5,FCH4_SSITC_TEST,20180628,6.12,GA_OP-LI-COR LI-7700,,Raised eddy sensors 30cm,3-5 -US-Tw5,FCH4_SSITC_TEST,,5.82,GA_OP-LI-COR LI-7700,,,3-5 -US-Tw5,FC_SSITC_TEST,20180628,6.12,GA_OP-LI-COR LI-7500A,,Raised eddy sensors 30cm,3-5 -US-Tw5,FC_SSITC_TEST,,5.82,GA_OP-LI-COR LI-7500A,,,3-5 -US-Tw5,GPP_PI_F,20180628,6.12,GA_OP-LI-COR LI-7500A,SA-Gill Windmaster,Raised eddy sensors 30cm,3-5 -US-Tw5,GPP_PI_F,,5.82,GA_OP-LI-COR LI-7500A,SA-Gill Windmaster,,3-5 -US-Tw5,H,20180628,6.12,SA-Gill Windmaster,,Raised eddy sensors 30cm,3-5 -US-Tw5,H,,5.82,SA-Gill Windmaster,,,3-5 -US-Tw5,H2O,20180628,6.12,GA_OP-LI-COR LI-7500A,,Raised eddy sensors 30cm,3-5 -US-Tw5,H2O,,5.82,GA_OP-LI-COR LI-7500A,,,3-5 -US-Tw5,H_PI_F,20180628,6.12,SA-Gill Windmaster,,Raised eddy sensors 30cm,3-5 -US-Tw5,H_PI_F,,5.82,SA-Gill Windmaster,,,3-5 -US-Tw5,H_SSITC_TEST,20180628,6.12,SA-Gill Windmaster,,Raised eddy sensors 30cm,3-5 -US-Tw5,H_SSITC_TEST,,5.82,SA-Gill Windmaster,,,3-5 -US-Tw5,LE,20180628,6.12,GA_OP-LI-COR LI-7500A,SA-Gill Windmaster,Raised eddy sensors 30cm,3-5 -US-Tw5,LE,,5.82,GA_OP-LI-COR LI-7500A,SA-Gill Windmaster,,3-5 -US-Tw5,LE_PI_F,20180628,6.12,GA_OP-LI-COR LI-7500A,SA-Gill Windmaster,Raised eddy sensors 30cm,3-5 -US-Tw5,LE_PI_F,,5.82,GA_OP-LI-COR LI-7500A,SA-Gill Windmaster,,3-5 -US-Tw5,LE_SSITC_TEST,20180628,6.12,GA_OP-LI-COR LI-7500A,,Raised eddy sensors 30cm,3-5 -US-Tw5,LE_SSITC_TEST,,5.82,GA_OP-LI-COR LI-7500A,,,3-5 -US-Tw5,LW_IN,,4.41,RAD-Pyrrad-SW+LW,,,3-5 -US-Tw5,LW_OUT,,4.41,RAD-Pyrrad-SW+LW,,,3-5 -US-Tw5,MO_LENGTH,20180628,6.12,SA-Gill Windmaster,,Raised eddy sensors 30cm,3-5 -US-Tw5,MO_LENGTH,,5.82,SA-Gill Windmaster,,,3-5 -US-Tw5,NETRAD,,4.41,RAD-Pyrrad-SW+LW,,,3-5 -US-Tw5,PA,,2.0,PRES-ElectBar,,,3-5 -US-Tw5,PPFD_IN,,4.48,RAD-PAR Quantum,,,3-5 -US-Tw5,PPFD_OUT,,4.41,RAD-PAR Quantum,,,3-5 -US-Tw5,RECO_PI_F,20180628,6.12,GA_OP-LI-COR LI-7500A,SA-Gill Windmaster,Raised eddy sensors 30cm,3-5 -US-Tw5,RECO_PI_F,,5.82,GA_OP-LI-COR LI-7500A,SA-Gill Windmaster,,3-5 -US-Tw5,RH,20180628,5.77,RH-Capac,,Raised eddy sensors 30cm,3-5 -US-Tw5,RH,,5.47,RH-Capac,,,3-5 -US-Tw5,SPEC_NIR_IN,,4.44,SPECT-LED,,,3-5 -US-Tw5,SPEC_NIR_OUT,,4.44,SPECT-LED,,,3-5 -US-Tw5,SPEC_RED_IN,,4.44,SPECT-LED,,,3-5 -US-Tw5,SPEC_RED_OUT,,4.44,SPECT-LED,,,3-5 -US-Tw5,SW_IN,,4.41,RAD-Pyrrad-SW+LW,,,3-5 -US-Tw5,SW_OUT,,4.41,RAD-Pyrrad-SW+LW,,,3-5 -US-Tw5,TA,20180628,5.77,TEMP-ElectResis,,Raised eddy sensors 30cm,3-5 -US-Tw5,TA,,5.47,TEMP-ElectResis,,,3-5 -US-Tw5,TAU,20180628,6.12,SA-Gill Windmaster,,Raised eddy sensors 30cm,3-5 -US-Tw5,TAU,,5.82,SA-Gill Windmaster,,,3-5 -US-Tw5,TAU_SSITC_TEST,20180628,6.12,SA-Gill Windmaster,,Raised eddy sensors 30cm,3-5 -US-Tw5,TAU_SSITC_TEST,,5.82,SA-Gill Windmaster,,,3-5 -US-Tw5,TS_1,,0,TEMP-TCouple,,Water temperature -0.02m below surface,3-5 -US-Tw5,TS_2,,0,TEMP-TCouple,,Water temperature -0.10m below surface,3-5 -US-Tw5,TS_3,,-0.02,TEMP-TCouple,,,3-5 -US-Tw5,TS_4,,-0.08,TEMP-TCouple,,,3-5 -US-Tw5,TS_5,,-0.16,TEMP-TCouple,,,3-5 -US-Tw5,T_SONIC,20180628,6.12,SA-Gill Windmaster,,Raised eddy sensors 30cm,3-5 -US-Tw5,T_SONIC,,5.82,SA-Gill Windmaster,,,3-5 -US-Tw5,T_SONIC_SIGMA,20180628,6.12,SA-Gill Windmaster,,Raised eddy sensors 30cm,3-5 -US-Tw5,T_SONIC_SIGMA,,5.82,SA-Gill Windmaster,,,3-5 -US-Tw5,USTAR,20180628,6.12,SA-Gill Windmaster,,Raised eddy sensors 30cm,3-5 -US-Tw5,USTAR,,5.82,SA-Gill Windmaster,,,3-5 -US-Tw5,VPD_PI,20180628,5.77,RH-Capac,,Raised eddy sensors 30cm,3-5 -US-Tw5,VPD_PI,,5.47,RH-Capac,,,3-5 -US-Tw5,V_SIGMA,20180628,6.12,SA-Gill Windmaster,,Raised eddy sensors 30cm,3-5 -US-Tw5,V_SIGMA,,5.82,SA-Gill Windmaster,,,3-5 -US-Tw5,WD,20180628,6.12,SA-Gill Windmaster,,Raised eddy sensors 30cm,3-5 -US-Tw5,WD,,5.82,SA-Gill Windmaster,,,3-5 -US-Tw5,WS,20180628,6.12,SA-Gill Windmaster,,Raised eddy sensors 30cm,3-5 -US-Tw5,WS,,5.82,SA-Gill Windmaster,,,3-5 -US-Tw5,W_SIGMA,20180628,6.12,SA-Gill Windmaster,,Raised eddy sensors 30cm,3-5 -US-Tw5,W_SIGMA,,5.82,SA-Gill Windmaster,,,3-5 -US-Tw5,WTD,,0,WTD-Press,,,3-5 -US-Tw5,ZL,,5.82,SA-Gill Windmaster,,,3-5 -US-Twt,CH4,,3.18,GA_OP-LI-COR LI-7700,,,6-5 -US-Twt,CO2,20120507,3.18,GA_OP-LI-COR LI-7500A,,,6-5 -US-Twt,CO2,,3.18,GA_OP-LI-COR LI-7500,,,6-5 -US-Twt,FC,20120507,3.18,GA_OP-LI-COR LI-7500A,SA-Gill Windmaster,,6-5 -US-Twt,FC,,3.18,GA_OP-LI-COR LI-7500,SA-Gill Windmaster Pro,,6-5 -US-Twt,FC_PI_F,20120507,3.18,GA_OP-LI-COR LI-7500A,SA-Gill Windmaster,,6-5 -US-Twt,FC_PI_F,,3.18,GA_OP-LI-COR LI-7500,SA-Gill Windmaster Pro,,6-5 -US-Twt,FCH4,20120507,3.18,GA_OP-LI-COR LI-7700,SA-Gill Windmaster,,6-5 -US-Twt,FCH4,,3.18,GA_OP-LI-COR LI-7700,SA-Gill Windmaster Pro,,6-5 -US-Twt,FCH4_PI_F,20120507,3.18,GA_OP-LI-COR LI-7700,SA-Gill Windmaster,,6-5 -US-Twt,FCH4_PI_F,,3.18,GA_OP-LI-COR LI-7700,SA-Gill Windmaster Pro,,6-5 -US-Twt,FH2O,20120507,3.18,GA_OP-LI-COR LI-7500A,,SA-Gill Windmaster,6-5 -US-Twt,FH2O,,3.18,GA_OP-LI-COR LI-7500,,SA-Gill Windmaster Pro,6-5 -US-Twt,FH2O_PI_F,20120507,3.18,GA_OP-LI-COR LI-7500A,,SA-Gill Windmaster,6-5 -US-Twt,FH2O_PI_F,,3.18,GA_OP-LI-COR LI-7500,,SA-Gill Windmaster Pro,6-5 -US-Twt,G,,-0.01,SOIL_H-Plate,,,6-5 -US-Twt,H,20120507,3.18,SA-Gill Windmaster,,,6-5 -US-Twt,H,,3.18,SA-Gill Windmaster Pro,,,6-5 -US-Twt,H2O,20120507,3.18,GA_OP-LI-COR LI-7500A,,,6-5 -US-Twt,H2O,,3.18,GA_OP-LI-COR LI-7500,,,6-5 -US-Twt,H_PI_F,20120507,3.18,SA-Gill Windmaster,,,6-5 -US-Twt,H_PI_F,,3.18,SA-Gill Windmaster Pro,,,6-5 -US-Twt,LE,20120507,3.18,GA_OP-LI-COR LI-7500A,SA-Gill Windmaster,,6-5 -US-Twt,LE,,3.18,GA_OP-LI-COR LI-7500,SA-Gill Windmaster Pro,,6-5 -US-Twt,LE_PI_F,20120507,3.18,GA_OP-LI-COR LI-7500A,SA-Gill Windmaster,,6-5 -US-Twt,LE_PI_F,,3.18,GA_OP-LI-COR LI-7500,SA-Gill Windmaster Pro,,6-5 -US-Twt,NETRAD,,2.45,RAD-Net radiometer,,,6-5 -US-Twt,P,,,RAIN-TipBucGauge,,,6-5 -US-Twt,PA,,,PRES-ElectBar,,,6-5 -US-Twt,PPFD_IN,,2.45,RAD-PAR Quantum,,,6-5 -US-Twt,PPFD_OUT,,2.45,RAD-PAR Quantum,,,6-5 -US-Twt,RH,,2.8,RH-Capac,,,6-5 -US-Twt,SW_IN,,2.45,,,,6-5 -US-Twt,TA,,2.8,TEMP-ElectResis,,,6-5 -US-Twt,TAU,20120507,3.18,SA-Gill Windmaster,,undefined,6-5 -US-Twt,TAU,,3.18,SA-Gill Windmaster Pro,,,6-5 -US-Twt,TS_1_1_1,,-0.02,TEMP-TCouple,,,6-5 -US-Twt,TS_1_2_1,,-0.04,TEMP-TCouple,,,6-5 -US-Twt,TS_1_3_1,,-0.08,TEMP-TCouple,,,6-5 -US-Twt,TS_1_4_1,,-0.16,TEMP-TCouple,,,6-5 -US-Twt,TS_1_5_1,,-0.32,TEMP-TCouple,,,6-5 -US-Twt,USTAR,20120507,3.18,SA-Gill Windmaster,,,6-5 -US-Twt,USTAR,,3.18,SA-Gill Windmaster Pro,,,6-5 -US-Twt,VPD_PI,,2.8,RH-Capac,,Temp-ElectResis,6-5 -US-Twt,V_SIGMA,20120507,3.18,SA-Gill Windmaster,,,6-5 -US-Twt,V_SIGMA,,3.18,SA-Gill Windmaster Pro,,,6-5 -US-Twt,WD,20120507,3.18,SA-Gill Windmaster,,,6-5 -US-Twt,WD,,3.18,SA-Gill Windmaster Pro,,,6-5 -US-Twt,WS,20120507,3.18,SA-Gill Windmaster,,,6-5 -US-Twt,WS,,3.18,SA-Gill Windmaster Pro,,,6-5 -US-Twt,W_SIGMA,20120507,3.18,SA-Gill Windmaster,,,6-5 -US-Twt,W_SIGMA,,3.18,SA-Gill Windmaster Pro,,,6-5 -US-Twt,WTD,,,WTD-Press,,,6-5 -US-Uaf,FC,,6,SA-Campbell CSAT-3,GA_OP-LI-COR LI-7500,,10-5 -US-Uaf,FCH4,,6,SA-Campbell CSAT-3,GA_CP-LGR 911-0001,,10-5 -US-Uaf,H,,6,SA-Campbell CSAT-3,,,10-5 -US-Uaf,LE,,6,SA-Campbell CSAT-3,GA_OP-LI-COR LI-7500,,10-5 -US-Uaf,LW_IN,,6,RAD-Pyrrad-SW+LW,,,10-5 -US-Uaf,LW_OUT,,6,RAD-Pyrrad-SW+LW,,,10-5 -US-Uaf,PA,,1,PRES-ElectBar,,,10-5 -US-Uaf,P_RAIN,,1,PREC-TipBucGauge,,,10-5 -US-Uaf,RH_1_1_1,,8,RH-Capac,,,10-5 -US-Uaf,RH_1_2_1,,4,RH-Capac,,,10-5 -US-Uaf,RH_1_3_1,,2,RH-Capac,,,10-5 -US-Uaf,RH_1_4_1,,1,RH-Capac,,,10-5 -US-Uaf,SWC_PI_F_1_2_1,,-0.05,SWC-TDR,,,10-5 -US-Uaf,SWC_PI_F_2_1_1,,-0.05,SWC-TDR,,,10-5 -US-Uaf,SWC_PI_F_2_2_1,,-0.15,SWC-TDR,,,10-5 -US-Uaf,SWC_PI_F_2_3_1,,-0.25,SWC-TDR,,,10-5 -US-Uaf,SW_IN,,6,RAD-Pyrrad-SW+LW,,,10-5 -US-Uaf,SW_OUT,,6,RAD-Pyrrad-SW+LW,,,10-5 -US-Uaf,TA_1_1_1,,8,TEMP-ElectResis,,,10-5 -US-Uaf,TA_1_2_1,,4,TEMP-ElectResis,,,10-5 -US-Uaf,TA_1_3_1,,2,TEMP-ElectResis,,,10-5 -US-Uaf,TA_1_4_1,,1,TEMP-ElectResis,,,10-5 -US-Uaf,TS_PI_F_1_1_1,,-0.15,TEMP-TCouple,,,10-5 -US-Uaf,TS_PI_F_1_2_1,,-0.3,TEMP-TCouple,,,10-5 -US-Uaf,TS_PI_F_1_3_1,,-0.45,TEMP-TCouple,,,10-5 -US-Uaf,TS_PI_F_1_4_1,,-0.5,TEMP-TCouple,,,10-5 -US-Uaf,TS_PI_F_1_5_1,,-0.7,TEMP-TCouple,,,10-5 -US-Uaf,TS_PI_F_1_6_1,,-0.8,TEMP-TCouple,,,10-5 -US-Uaf,TS_PI_F_1_7_1,,-1.0,TEMP-TCouple,,,10-5 -US-Uaf,TS_PI_F_1_8_1,,-1.25,TEMP-TCouple,,,10-5 -US-Uaf,TS_PI_F_2_1_1,,-0.02,TEMP-Thermis,,,10-5 -US-Uaf,TS_PI_F_2_2_1,,-0.05,TEMP-Thermis,,,10-5 -US-Uaf,TS_PI_F_2_3_1,,-0.1,TEMP-Thermis,,,10-5 -US-Uaf,TS_PI_F_2_4_1,,-0.2,TEMP-Thermis,,,10-5 -US-Uaf,TS_PI_F_2_5_1,,-0.3,TEMP-Thermis,,,10-5 -US-Uaf,TS_PI_F_2_6_1,,-0.4,TEMP-Thermis,,,10-5 -US-Uaf,TS_PI_F_2_7_1,,-0.5,TEMP-Thermis,,,10-5 -US-Uaf,TS_PI_F_2_8_1,,-0.5,TEMP-Thermis,,,10-5 -US-Uaf,TS_PI_F_2_9_1,,-1,TEMP-Thermis,,,10-5 -US-Uaf,TS_PI_F_3_1_1,,-0.1,TEMP-Thermis,,,10-5 -US-Uaf,TS_PI_F_3_2_1,,-0.2,TEMP-Thermis,,,10-5 -US-Uaf,TS_PI_F_3_3_1,,-0.3,TEMP-Thermis,,,10-5 -US-Uaf,TS_PI_F_3_4_1,,-0.4,,,,10-5 -US-Uaf,USTAR,,6,SA-Campbell CSAT-3,,,10-5 -US-Uaf,WS_1_1_1,,8,WIND-CupAn,,,10-5 -US-Uaf,WS_1_2_1,,4,WIND-CupAn,,,10-5 -US-Uaf,WS_1_3_1,,2,WIND-CupAn,,,10-5 -US-UM3,CO2,20130607,5.5,GA_OP-LI-COR LI-7500,,Lake site. Water depth mostly around 3 m; tower extended another 2.5 m above the lake water surface.,1-5 -US-UM3,FC,20130607,5.5,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3A,Lake site. Water depth mostly around 3 m; tower extended another 2.5 m above the lake water surface.,1-5 -US-UM3,GPP_PI,20130607,5.5,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3A,,1-5 -US-UM3,GPP_PI_F,20130607,5.5,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3A,,1-5 -US-UM3,H,20130607,5.5,SA-Campbell CSAT-3A,,,1-5 -US-UM3,H2O,20130607,5.5,GA_OP-LI-COR LI-7500,,,1-5 -US-UM3,H_PI_F,20130607,5.5,RH-Capac,,,1-5 -US-UM3,LE,20130607,5.5,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3A,,1-5 -US-UM3,LE_PI_F,20130607,5.5,SA-Campbell CSAT-3A,GA_OP-LI-COR LI-7500,,1-5 -US-UM3,LW_IN,20130607,5.5,RAD-Pyrrad-SW+LW,,,1-5 -US-UM3,LW_OUT,20130607,5.5,RAD-Pyrrad-SW+LW,,,1-5 -US-UM3,MO_LENGTH,20130607,5.5,SA-Campbell CSAT-3A,,,1-5 -US-UM3,NEE_PI,20130607,5.5,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3A,,1-5 -US-UM3,NEE_PI_F,20130607,5.5,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3A,,1-5 -US-UM3,PA,20130607,5.5,GA_OP-LI-COR LI-7500,,,1-5 -US-UM3,PA_PI_F,20130607,5.5,GA_OP-LI-COR LI-7500,,,1-5 -US-UM3,RECO_PI,20130607,5.5,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3A,,1-5 -US-UM3,RECO_PI_F,20130607,5.5,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3A,,1-5 -US-UM3,RH,20130607,5.5,RH-Capac,,,1-5 -US-UM3,RH_PI_F,20130607,5.5,RH-Capac,,,1-5 -US-UM3,SC,20130607,5.5,GA_OP-LI-COR LI-7500,,,1-5 -US-UM3,SW_IN,20130607,5.5,RAD-Pyrrad-SW+LW,,,1-5 -US-UM3,SW_OUT,20130607,5.5,RAD-Pyrrad-SW+LW,,,1-5 -US-UM3,TA,20130607,5.5,TEMP-ElectResis,,,1-5 -US-UM3,TA_PI_F,20130607,5.5,TEMP-ElectResis,,,1-5 -US-UM3,USTAR,20130607,5.5,SA-Campbell CSAT-3A,,,1-5 -US-UM3,VPD_PI,20130607,5.5,RH-Capac,,,1-5 -US-UM3,VPD_PI_F,20130607,5.5,RH-Capac,,,1-5 -US-UM3,WD,20130607,5.5,SA-Campbell CSAT-3A,,,1-5 -US-UM3,WD_PI_F,20130607,5.5,SA-Campbell CSAT-3A,,,1-5 -US-UM3,WS,20130607,5.5,SA-Campbell CSAT-3A,,,1-5 -US-UM3,WS_PI_F,20130607,5.5,SA-Campbell CSAT-3A,,,1-5 -US-UM3,WTD,20130607,-1.5,WTD-Press,,Pressure sensor installed 1.5 m above the lake bottom.,1-5 -US-UMB,APAR,,1,RAD-PAR Quantum,,,18-5 -US-UMB,CO2,20070101,48,GA_CP-LI-COR LI-7000,,,18-5 -US-UMB,CO2_1,20050331,48,GA_CP-LI-COR LI-7000,,,18-5 -US-UMB,CO2_1,,46,GA_CP-LI-COR LI-6262,,,18-5 -US-UMB,CO2_2,20060418,34,GA_CP-LI-COR LI-7000,,,18-5 -US-UMB,CO2_2,,34,GA_CP-LI-COR LI-6262,,,18-5 -US-UMB,FAPAR,,1,RAD-PAR Quantum,,,18-5 -US-UMB,FC,20050331,48,GA_CP-LI-COR LI-7000,SA-Campbell CSAT-3,,18-5 -US-UMB,FC,,46,GA_CP-LI-COR LI-6262,SA-Campbell CSAT-3,,18-5 -US-UMB,G,,,,,Never reported; all NaN,18-5 -US-UMB,GPP_PI_PI,20070101,48,GA_CP-LI-COR LI-7000,SA-Campbell CSAT-3,,18-5 -US-UMB,GPP_PI_PI_F,20070101,48,GA_CP-LI-COR LI-7000,SA-Campbell CSAT-3,,18-5 -US-UMB,H,20010509,48,SA-Campbell CSAT-3,,,18-5 -US-UMB,H,,46,SA-Campbell CSAT-3,,,18-5 -US-UMB,H2O,20010509,48,GA_CP-LI-COR LI-7000,,changed ht,18-5 -US-UMB,H2O,,46,GA_CP-LI-COR LI-6262,,,18-5 -US-UMB,LE,20050331,48,GA_CP-LI-COR LI-7000,SA-Campbell CSAT-3,,18-5 -US-UMB,LE,,46,GA_CP-LI-COR LI-6262,SA-Campbell CSAT-3,,18-5 -US-UMB,LW_IN,,46,RAD-Pyrrad-SW+LW,,,18-5 -US-UMB,LW_OUT,,46,RAD-Pyrrad-SW+LW,,,18-5 -US-UMB,NEE_PI_PI,20050331,48,GA_CP-LI-COR LI-7000,SA-Campbell CSAT-3,,18-5 -US-UMB,NEE_PI_PI,,46,GA_CP-LI-COR LI-6262,SA-Campbell CSAT-3,,18-5 -US-UMB,NEE_PI_PI_F,20070101,48,GA_CP-LI-COR LI-7000,SA-Campbell CSAT-3,,18-5 -US-UMB,NETRAD,,46,RAD-Pyrrad-SW+LW,,,18-5 -US-UMB,P,,46,PREC-OpticGauge,,,18-5 -US-UMB,PA,,46,PRES-Other,,,18-5 -US-UMB,PPFD_DIF,,46,RAD-Other,,,18-5 -US-UMB,PPFD_IN,,46,RAD-PAR Quantum,,,18-5 -US-UMB,PPFD_OUT,,46,RAD-PAR Quantum,,,18-5 -US-UMB,RECO_PI_PI,20000101,46,GA_CP-LI-COR LI-6262,SA-Campbell CSAT-3,,18-5 -US-UMB,RECO_PI_PI,20050331,48,GA_CP-LI-COR LI-7000,SA-Campbell CSAT-3,,18-5 -US-UMB,RECO_PI_PI_F,20070101,48,GA_CP-LI-COR LI-7000,SA-Campbell CSAT-3,,18-5 -US-UMB,RH,,46,RH-Capac,,,18-5 -US-UMB,SC,20150419,,GA_CP-LI-COR LI-7000,,integrated vertical profile. Sampling heights: 0.25; 0.6; 3.5; 7; 11; 14; 17; 22; 34; and 48 m,18-5 -US-UMB,SC,,,GA_CP-LI-COR LI-6262,,integrated vertical profile. Sampling heights: 0.25; 0.6; 3.5; 7; 11; 14; 17; 22; 34; and 48 m,18-5 -US-UMB,SH,,,,,Legacy variable; never reported; all NAN,18-5 -US-UMB,SLE,,,,,legacy variable; never reported; all NaN,18-5 -US-UMB,SWC_1,20000101,,SWC-TDR,,Vertical average of 0 to -30 cm,18-5 -US-UMB,SWC_1_1_1,20070101,,SWC-TDR,,Vertical average of 0 to -30 cm,18-5 -US-UMB,SWC_1_2_1,20090816,-0.05,SWC-Other,,,18-5 -US-UMB,SWC_1_3_1,20090816,-0.15,SWC-Other,,,18-5 -US-UMB,SWC_1_4_1,20090816,-0.3,SWC-Other,,,18-5 -US-UMB,SWC_1_5_1,20090816,-0.6,SWC-Other,,,18-5 -US-UMB,SWC_1_6_1,20090816,-1,SWC-Other,,,18-5 -US-UMB,SWC_1_7_1,20090816,-2,SWC-Other,,,18-5 -US-UMB,SWC_1_8_1,20090816,-3,SWC-Other,,,18-5 -US-UMB,SWC_2,,-0.075,SWC-TDR,,Never reported; always NaN,18-5 -US-UMB,SW_IN,,46,RAD-Pyrrad-SW+LW,,,18-5 -US-UMB,SW_OUT,20000101,46,RAD-Pyrrad-SW+LW,,,18-5 -US-UMB,TA,,46,TEMP-ElectResis,,,18-5 -US-UMB,TS_1,,-0.02,SWC-TDR,,,18-5 -US-UMB,TS_1_1_1,20070101,-0.02,SWC-TDR,,,18-5 -US-UMB,TS_1_2_1,20090816,-0.05,SWC-Other,,,18-5 -US-UMB,TS_1_3_1,20090816,-0.15,SWC-Other,,,18-5 -US-UMB,TS_1_4_1,20090816,-0.3,SWC-Other,,,18-5 -US-UMB,TS_1_5_1,20090816,-0.6,SWC-Other,,,18-5 -US-UMB,TS_1_6_1,20090816,-1,SWC-Other,,,18-5 -US-UMB,TS_1_7_1,20090816,-2,SWC-Other,,,18-5 -US-UMB,TS_1_8_1,20090816,-3,TEMP-Other,,,18-5 -US-UMB,TS_2,20000101,-0.075,SWC-TDR,,,18-5 -US-UMB,USTAR,20050331,48,SA-Campbell CSAT-3,,,18-5 -US-UMB,USTAR,,46,SA-Campbell CSAT-3,,,18-5 -US-UMB,VPD_PI_PI,,46,RH-Capac,,,18-5 -US-UMB,WD,20050331,48,SA-Campbell CSAT-3,,,18-5 -US-UMB,WD,,46,SA-Campbell CSAT-3,,,18-5 -US-UMB,WS,20050331,48,SA-Campbell CSAT-3,,,18-5 -US-UMB,WS,,46,SA-Campbell CSAT-3,,,18-5 -US-UMB,ZL,,,,,Legacy variable; Never reported; all NaN,18-5 -US-UMd,CO2,20120406,32,GA_CP-LI-COR LI-7000,,,12-5 -US-UMd,CO2,,32,GA_CP-LI-COR LI-6262,,,12-5 -US-UMd,FC,20120406,32,GA_CP-LI-COR LI-7000,SA-Campbell CSAT-3,,12-5 -US-UMd,FC,,32,GA_CP-LI-COR LI-6262,SA-Campbell CSAT-3,,12-5 -US-UMd,GPP_PI_PI,20120406,32,GA_CP-LI-COR LI-7000,SA-Campbell CSAT-3,,12-5 -US-UMd,GPP_PI_PI,,32,GA_CP-LI-COR LI-6262,SA-Campbell CSAT-3,,12-5 -US-UMd,GPP_PI_PI_F,20120406,32,GA_CP-LI-COR LI-7000,SA-Campbell CSAT-3,,12-5 -US-UMd,GPP_PI_PI_F,,32,GA_CP-LI-COR LI-6262,SA-Campbell CSAT-3,,12-5 -US-UMd,H,,32,SA-Campbell CSAT-3,,,12-5 -US-UMd,H2O,20120406,32,GA_CP-LI-COR LI-7000,,,12-5 -US-UMd,H2O,,32,GA_CP-LI-COR LI-6262,,,12-5 -US-UMd,LE,20120406,32,GA_CP-LI-COR LI-7000,SA-Campbell CSAT-3,,12-5 -US-UMd,LE,,32,GA_CP-LI-COR LI-6262,SA-Campbell CSAT-3,,12-5 -US-UMd,LW_IN,,32,RAD-Pyrrad-SW+LW,,,12-5 -US-UMd,LW_OUT,,32,RAD-Pyrrad-SW+LW,,,12-5 -US-UMd,NEE_PI_PI,20120406,32,GA_CP-LI-COR LI-7000,SA-Campbell CSAT-3,,12-5 -US-UMd,NEE_PI_PI,,32,GA_CP-LI-COR LI-6262,SA-Campbell CSAT-3,,12-5 -US-UMd,NEE_PI_PI_F,20120406,32,GA_CP-LI-COR LI-7000,SA-Campbell CSAT-3,,12-5 -US-UMd,NEE_PI_PI_F,,32,GA_CP-LI-COR LI-6262,SA-Campbell CSAT-3,,12-5 -US-UMd,NETRAD,,32,RAD-Pyrrad-SW+LW,,,12-5 -US-UMd,PA,,21,PRES-Other,,,12-5 -US-UMd,PPFD_DIF,,,,,Never used; all NAN,12-5 -US-UMd,PPFD_IN,,32,RAD-PAR Quantum,,,12-5 -US-UMd,RECO_PI_PI,20120406,32,GA_CP-LI-COR LI-7000,SA-Campbell CSAT-3,,12-5 -US-UMd,RECO_PI_PI,,32,GA_CP-LI-COR LI-6262,SA-Campbell CSAT-3,,12-5 -US-UMd,RECO_PI_PI_F,20120406,32,GA_CP-LI-COR LI-7000,SA-Campbell CSAT-3,,12-5 -US-UMd,RECO_PI_PI_F,,32,GA_CP-LI-COR LI-6262,SA-Campbell CSAT-3,,12-5 -US-UMd,RH,,32,RH-Capac,,,12-5 -US-UMd,SC,20150101,,GA_CP-LI-COR LI-7000,,profiles are: 0.25; 0.6; 3.5; 7; 11; 14; 17; and 22 m.,12-5 -US-UMd,SWC_1_1_1,,,SWC-TDR,,Campbell probe integrated from 0-30 cm,12-5 -US-UMd,SWC_1_2_1,,-0.05,SWC-Other,,,12-5 -US-UMd,SWC_1_3_1,,-0.15,SWC-Other,,,12-5 -US-UMd,SWC_1_4_1,,-0.3,SWC-Other,,,12-5 -US-UMd,SWC_1_5_1,,-0.6,SWC-Other,,,12-5 -US-UMd,SWC_1_6_1,,-1,SWC-Other,,,12-5 -US-UMd,SWC_1_7_1,,-2,SWC-Other,,,12-5 -US-UMd,SWC_1_8_1,,-3,SWC-Other,,,12-5 -US-UMd,SW_IN,,32,RAD-Pyrrad-SW+LW,,,12-5 -US-UMd,SW_OUT,,32,RAD-Pyrrad-SW+LW,,,12-5 -US-UMd,TA,,32,TEMP-ElectResis,,,12-5 -US-UMd,TS_1_1_1,,-0.02,TEMP-ElectResis,,,12-5 -US-UMd,TS_1_2_1,,-0.05,TEMP-ElectResis,,,12-5 -US-UMd,TS_1_3_1,,-0.15,TEMP-ElectResis,,,12-5 -US-UMd,TS_1_4_1,,-0.3,TEMP-ElectResis,,,12-5 -US-UMd,TS_1_5_1,,-0.6,TEMP-ElectResis,,,12-5 -US-UMd,TS_1_6_1,,-1,TEMP-ElectResis,,,12-5 -US-UMd,TS_1_7_1,,-2,TEMP-ElectResis,,,12-5 -US-UMd,TS_1_8_1,,-3,TEMP-ElectResis,,,12-5 -US-UMd,USTAR,,32,SA-Campbell CSAT-3,,,12-5 -US-UMd,VPD_PI_PI,,,,,Never used; all NAN,12-5 -US-UMd,WD,,32,SA-Campbell CSAT-3,,,12-5 -US-UMd,WS,,32,SA-Campbell CSAT-3,,,12-5 -US-Upa,FC,,2.5,,,,3-5 -US-Upa,G,,-0.02,,,,3-5 -US-Upa,H,,2.5,,,,3-5 -US-Upa,LE,,2.5,,,,3-5 -US-Upa,NETRAD,,1,RAD-Other,,(Q-7 (REBS)),3-5 -US-Upa,PPFD_IN,,,RAD-Other,,(LI-190SB (LI-COR),3-5 -US-Upa,TA_1_1_1,,2,,,,3-5 -US-Upa,TS_1_2_1,,-0.05,TEMP-Other,,(Type-T Thermocouple),3-5 -US-Upa,TS_1_3_1,,-0.1,TEMP-Other,,(Type-T Thermocouple),3-5 -US-Upa,USTAR,,2.5,,,,3-5 -US-Upa,WD,,,WIND-Other,,(Sonic Anemometer (Gill Inc.)),3-5 -US-Upa,WS_1_1_1,,2,WIND-Other,,Sonic Anemometer (Gill Inc.),3-5 -US-Var,CO2,20170524,2,GA_OP-LI-COR LI-7500A,,,17-5 -US-Var,CO2,,2,GA_OP-LI-COR LI-7500,,LI7500 CO2 concentration by Li,17-5 -US-Var,FC,20170524,2,GA_OP-LI-COR LI-7500A,SA-Gill Windmaster,Sonic upgraded to 20Hz,17-5 -US-Var,FC,,2,GA_OP-LI-COR LI-7500,SA-Gill Windmaster Pro,,17-5 -US-Var,FH2O,20170524,2,GA_OP-LI-COR LI-7500A,SA-Gill Windmaster,Sonic upgraded to 20Hz,17-5 -US-Var,FH2O,,2,GA_OP-LI-COR LI-7500,SA-Gill Windmaster Pro,,17-5 -US-Var,FH2O_PI_F,20170524,2,GA_OP-LI-COR LI-7500A,SA-Gill Windmaster Pro,Sonic upgraded to 20Hz,17-5 -US-Var,FH2O_PI_F,,2,GA_OP-LI-COR LI-7500,SA-Gill Windmaster,,17-5 -US-Var,G,,-0.01,SOIL_H-Plate,,,17-5 -US-Var,G_PI_F,,-0.01,SOIL_H-Plate,,,17-5 -US-Var,GPP_PI_F,20170524,2,GA_OP-LI-COR LI-7500A,SA-Gill Windmaster,Sonic upgraded to 20Hz,17-5 -US-Var,GPP_PI_F,,2,GA_OP-LI-COR LI-7500,SA-Gill Windmaster Pro,,17-5 -US-Var,H,20170524,2,SA-Gill Windmaster,,Sonic upgraded to 20Hz,17-5 -US-Var,H,,2,SA-Gill Windmaster Pro,,,17-5 -US-Var,H2O,20170524,2,GA_OP-LI-COR LI-7500A,,,17-5 -US-Var,H2O,,2,GA_OP-LI-COR LI-7500,,,17-5 -US-Var,H2O_PI_F,20170524,2,GA_OP-LI-COR LI-7500A,,,17-5 -US-Var,H2O_PI_F,,2,GA_OP-LI-COR LI-7500,,,17-5 -US-Var,H_PI_F,20170524,2,SA-Gill Windmaster,,Sonic upgraded to 20Hz,17-5 -US-Var,H_PI_F,,2,SA-Gill Windmaster Pro,,,17-5 -US-Var,LE,20170524,2,GA_OP-LI-COR LI-7500A,SA-Gill Windmaster,Sonic upgraded to 20Hz,17-5 -US-Var,LE,,2,GA_OP-LI-COR LI-7500,SA-Gill Windmaster Pro,,17-5 -US-Var,LE_PI_F,20170524,2,GA_OP-LI-COR LI-7500A,SA-Gill Windmaster,Sonic upgraded to 20Hz,17-5 -US-Var,LE_PI_F,,2,GA_OP-LI-COR LI-7500,SA-Gill Windmaster Pro,,17-5 -US-Var,LW_IN,,2.5,RAD-Pyrrad-SW+LW,,,17-5 -US-Var,LW_OUT,,2.5,RAD-Pyrrad-SW+LW,,,17-5 -US-Var,NEE_PI_F,20170524,2,GA_OP-LI-COR LI-7500A,SA-Gill Windmaster,Sonic upgraded to 20Hz,17-5 -US-Var,NEE_PI_F,,2,GA_OP-LI-COR LI-7500,SA-Gill Windmaster Pro,,17-5 -US-Var,NETRAD,20170817,2.5,RAD-Pyrrad-SW+LW,,,17-5 -US-Var,NETRAD,,2.5,RAD-Net radiometer,,,17-5 -US-Var,NETRAD_PI_F,20170817,2.5,RAD-Pyrrad-SW+LW,,,17-5 -US-Var,NETRAD_PI_F,,2.5,RAD-Net radiometer,,,17-5 -US-Var,P,,2.5,PREC-TipBucGauge,,,17-5 -US-Var,PA,,2.5,PRES-ElectBar,,,17-5 -US-Var,PA_PI_F,,2.5,PRES-ElectBar,,,17-5 -US-Var,P_PI_F,,2.5,PREC-TipBucGauge,,,17-5 -US-Var,PPFD_DIF,,2.5,RAD-PAR Quantum,,,17-5 -US-Var,PPFD_IN_1_1_1,,2.5,RAD-PAR Quantum,,,17-5 -US-Var,PPFD_IN_2_1_1,,2.5,RAD-PAR Quantum,,,17-5 -US-Var,PPFD_IN_PI_F_1_1_1,,2.5,RAD-PAR Quantum,,,17-5 -US-Var,PPFD_OUT,,2.5,RAD-PAR Quantum,,,17-5 -US-Var,RECO_PI_F,20170524,2,GA_OP-LI-COR LI-7500A,SA-Gill Windmaster,Sonic upgraded to 20Hz,17-5 -US-Var,RECO_PI_F,,2,GA_OP-LI-COR LI-7500,SA-Gill Windmaster Pro,,17-5 -US-Var,RH,,2,RH-Capac,,,17-5 -US-Var,RH_PI_F,,2,RH-Capac,,,17-5 -US-Var,SWC_1_1_1,,-0,SWC-TDR,,,17-5 -US-Var,SWC_1_2_1,,-0.1,SWC-TDR,,,17-5 -US-Var,SWC_1_3_1,,-0.2,SWC-TDR,,,17-5 -US-Var,SWC_PI_F_1_1_1,,-0,SWC-TDR,,,17-5 -US-Var,SWC_PI_F_1_2_1,,-0.1,SWC-TDR,,,17-5 -US-Var,SWC_PI_F_1_3_1,,-0.2,SWC-TDR,,,17-5 -US-Var,SW_IN_1_1_2,,2.5,RAD-SW Pyran Class1,,,17-5 -US-Var,SW_IN_PI_F_1_1_1,,2.5,RAD-SW Pyran Class1,,,17-5 -US-Var,SW_OUT,,2.5,RAD-Pyrrad-SW+LW,,,17-5 -US-Var,TA,,2,TEMP-ElectResis,,,17-5 -US-Var,TA_PI_F,,2,TEMP-ElectResis,,,17-5 -US-Var,TS_1_1_1,,-0.02,TEMP-TCouple,,,17-5 -US-Var,TS_1_2_1,,-0.04,TEMP-TCouple,,,17-5 -US-Var,TS_1_3_1,,-0.08,TEMP-TCouple,,,17-5 -US-Var,TS_1_4_1,,-0.16,TEMP-TCouple,,,17-5 -US-Var,TS_1_5_1,,-0.32,TEMP-TCouple,,,17-5 -US-Var,TS_PI_F_1_1_1,,-0.02,TEMP-TCouple,,,17-5 -US-Var,TS_PI_F_1_2_1,,-0.04,TEMP-TCouple,,,17-5 -US-Var,TS_PI_F_1_3_1,,-0.08,TEMP-TCouple,,,17-5 -US-Var,TS_PI_F_1_4_1,,-0.16,TEMP-TCouple,,,17-5 -US-Var,TS_PI_F_1_5_1,,-0.32,TEMP-TCouple,,,17-5 -US-Var,T_SONIC,20170524,2,SA-Gill Windmaster,,Sonic upgraded to 20Hz,17-5 -US-Var,T_SONIC,,2,SA-Gill Windmaster Pro,,,17-5 -US-Var,T_SONIC_SIGMA,20170524,2,SA-Gill Windmaster,,Sonic upgraded to 20Hz,17-5 -US-Var,T_SONIC_SIGMA,,2,SA-Gill Windmaster Pro,,,17-5 -US-Var,USTAR,20170524,2,SA-Gill Windmaster,,Sonic upgraded to 20Hz,17-5 -US-Var,USTAR,,2,SA-Gill Windmaster Pro,,,17-5 -US-Var,USTAR_PI_F,20170524,2,SA-Gill Windmaster,,Sonic upgraded to 20Hz,17-5 -US-Var,USTAR_PI_F,,2,SA-Gill Windmaster Pro,,,17-5 -US-Var,VPD_PI,,2,RH-Capac,,Temp-ElectResis,17-5 -US-Var,VPD_PI_F,,2,RH-Capac,,Temp-ElectResis,17-5 -US-Var,WD,20170524,2,SA-Gill Windmaster,,Sonic upgraded to 20Hz,17-5 -US-Var,WD,,2,SA-Gill Windmaster Pro,,,17-5 -US-Var,WD_PI_F,20170524,2,SA-Gill Windmaster,,Sonic upgraded to 20Hz,17-5 -US-Var,WD_PI_F,,2,SA-Gill Windmaster Pro,,,17-5 -US-Var,WS,20170524,2,SA-Gill Windmaster,,Sonic upgraded to 20Hz,17-5 -US-Var,WS,,2,SA-Gill Windmaster Pro,,,17-5 -US-Var,WS_PI_F,20170524,2,SA-Gill Windmaster,,Sonic upgraded to 20Hz,17-5 -US-Var,WS_PI_F,,2,SA-Gill Windmaster Pro,,,17-5 -US-Var,W_SIGMA,20170524,2,SA-Gill Windmaster,,Sonic upgraded to 20Hz,17-5 -US-Var,W_SIGMA,,2,SA-Gill Windmaster Pro,,,17-5 -US-Var,ZL,20170524,2,SA-Gill Windmaster,,Sonic upgraded to 20Hz,17-5 -US-Var,ZL,,2,SA-Gill Windmaster Pro,,,17-5 -US-Vcm,CO2,,23.9,GA_OP-LI-COR LI-7500,,LI-COR LI-7500,20-5 -US-Vcm,FC,,23.9,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,20-5 -US-Vcm,H,,23.9,GA_OP-LI-COR LI-7500,,,20-5 -US-Vcm,H2O,,23.9,GA_OP-LI-COR LI-7500,,LI-COR LI-7500,20-5 -US-Vcm,LE,,23.9,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,20-5 -US-Vcm,LW_IN,,23.9,RAD-Net radiometer,,,20-5 -US-Vcm,LW_OUT,,23.9,RAD-Net radiometer,,,20-5 -US-Vcm,NETRAD,,23.9,RAD-Net radiometer,,,20-5 -US-Vcm,P,,4.6,,,,20-5 -US-Vcm,P_PI_F,,4.6,,,,20-5 -US-Vcm,PPFD_IN,,23.6,,,,20-5 -US-Vcm,RH,,23.9,,,,20-5 -US-Vcm,RH_PI_F,,23.9,,,,20-5 -US-Vcm,SW_IN,,23.9,,,,20-5 -US-Vcm,SW_OUT,,23.9,,,,20-5 -US-Vcm,TA,,23.9,,,,20-5 -US-Vcm,TA_PI_F,,23.9,,,,20-5 -US-Vcm,USTAR,,23.9,,,,20-5 -US-Vcm,VPD_PI,,23.9,,,,20-5 -US-Vcm,VPD_PI_F,,23.9,,,,20-5 -US-Vcm,WD,,23.9,,,,20-5 -US-Vcm,WS,,23.9,,,,20-5 -US-Vcp,CO2,20190501,28.2,GA_OP-LI-COR LI-7500,,,17-5 -US-Vcp,CO2,,24,GA_OP-LI-COR LI-7500,,,17-5 -US-Vcp,FC,20190501,28.2,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,17-5 -US-Vcp,FC,,24,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,17-5 -US-Vcp,H,20190501,28.2,GA_OP-LI-COR LI-7500,,,17-5 -US-Vcp,H,,24,GA_OP-LI-COR LI-7500,,,17-5 -US-Vcp,H2O,20190501,28.2,GA_OP-LI-COR LI-7500,,,17-5 -US-Vcp,H2O,,24,GA_OP-LI-COR LI-7500,,,17-5 -US-Vcp,LE,20190501,28.2,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,17-5 -US-Vcp,LE,,24,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,17-5 -US-Vcp,LW_IN,20190501,28.2,RAD-Net radiometer,,,17-5 -US-Vcp,LW_IN,,24,RAD-Net radiometer,,,17-5 -US-Vcp,LW_OUT,20190501,28.2,RAD-Net radiometer,,,17-5 -US-Vcp,LW_OUT,,24,RAD-Net radiometer,,,17-5 -US-Vcp,NETRAD,20190501,28.2,RAD-Net radiometer,,,17-5 -US-Vcp,NETRAD,,24,RAD-Net radiometer,,,17-5 -US-Vcp,P,,18.4,PREC-TipBucGauge,,,17-5 -US-Vcp,PA,20190501,28.2,GA_OP-LI-COR LI-7500,,,17-5 -US-Vcp,PA,,24,GA_OP-LI-COR LI-7500,,,17-5 -US-Vcp,P_PI_F,,18.4,PREC-TipBucGauge,,,17-5 -US-Vcp,PPFD_IN,20190501,28.2,RAD-PAR Quantum,,,17-5 -US-Vcp,PPFD_IN,,24,RAD-PAR Quantum,,,17-5 -US-Vcp,RH,,24,RH-Capac,,,17-5 -US-Vcp,RH_PI_F,,24,RH-Capac,,,17-5 -US-Vcp,SW_IN,20190501,28.2,RAD-Net radiometer,,,17-5 -US-Vcp,SW_IN,,24,RAD-Net radiometer,,,17-5 -US-Vcp,SW_OUT,20190501,28.2,RAD-Net radiometer,,,17-5 -US-Vcp,SW_OUT,,24,RAD-Net radiometer,,,17-5 -US-Vcp,TA,20190501,28.2,GA_OP-LI-COR LI-7500,,,17-5 -US-Vcp,TA,,24,GA_OP-LI-COR LI-7500,,,17-5 -US-Vcp,TA_PI_F,20190501,28.2,GA_OP-LI-COR LI-7500,,,17-5 -US-Vcp,TA_PI_F,,24,GA_OP-LI-COR LI-7500,,,17-5 -US-Vcp,USTAR,20190501,28.2,SA-Campbell CSAT-3,,,17-5 -US-Vcp,USTAR,,24,SA-Campbell CSAT-3,,,17-5 -US-Vcp,VPD_PI,20190501,28.2,MULTI-Meteo,,,17-5 -US-Vcp,VPD_PI,,24,MULTI-Meteo,,,17-5 -US-Vcp,VPD_PI_F,20190501,28.2,MULTI-Meteo,,,17-5 -US-Vcp,VPD_PI_F,,24,MULTI-Meteo,,,17-5 -US-Vcp,WD,20190501,28.2,SA-Campbell CSAT-3,,,17-5 -US-Vcp,WD,,24,SA-Campbell CSAT-3,,,17-5 -US-Vcp,WS,20190501,28.2,SA-Campbell CSAT-3,,,17-5 -US-Vcp,WS,,24,SA-Campbell CSAT-3,,,17-5 -US-WBW,FC,,36.9,,,,2-1 -US-WBW,H,,36.9,,,,2-1 -US-WBW,LE,,36.9,,,,2-1 -US-WBW,TA,,38.2,,,,2-1 -US-WBW,VPD_PI_PI,,38.2,,,,2-1 -US-WBW,WD,,36.6,,,,2-1 -US-WBW,WS,,36.6,,,,2-1 -US-WCr,CO2_1_1_1,20170808,29.6,GA_SR-LI-COR LI-840A,,,22-5 -US-WCr,CO2_1_1_1,,29.6,GA_CP-Other,,,22-5 -US-WCr,CO2_1_2_1,20170808,21.3,GA_SR-LI-COR LI-840A,,,22-5 -US-WCr,CO2_1_2_1,,21.3,GA_CP-Other,,,22-5 -US-WCr,CO2_1_3_1,20170808,13.7,GA_SR-LI-COR LI-840A,,,22-5 -US-WCr,CO2_1_3_1,,13.7,GA_CP-Other,,,22-5 -US-WCr,CO2_1_4_1,20170808,7.6,GA_SR-LI-COR LI-840A,,,22-5 -US-WCr,CO2_1_4_1,,7.6,GA_CP-Other,,,22-5 -US-WCr,CO2_1_5_1,20170808,3,GA_SR-LI-COR LI-840A,,,22-5 -US-WCr,CO2_1_5_1,,3,GA_CP-Other,,,22-5 -US-WCr,CO2_1_6_1,20170808,1.5,GA_SR-LI-COR LI-840A,,,22-5 -US-WCr,CO2_1_6_1,,1.5,GA_CP-Other,,,22-5 -US-WCr,CO2_1_7_1,20170808,0.6,GA_SR-LI-COR LI-840A,,,22-5 -US-WCr,CO2_1_7_1,,0.6,GA_CP-Other,,,22-5 -US-WCr,FC,20160926,29.6,GA_CP-LI-COR LI-7200RS,SA-Campbell CSAT-3,,22-5 -US-WCr,FC,,29.6,GA_CP-LI-COR LI-6262,SA-Campbell CSAT-3,,22-5 -US-WCr,FH2O,,29.6,,,,22-5 -US-WCr,G,,-0.075,SOIL_H-Plate,,,22-5 -US-WCr,H,,29.6,SA-Campbell CSAT-3,,,22-5 -US-WCr,H2O_1_1_1,20160926,,GA_CP-LI-COR LI-7200RS,,,22-5 -US-WCr,H2O_1_1_1,,29.6,GA_CP-LI-COR LI-6262,,,22-5 -US-WCr,H2O_1_2_1,,24.4,RH-ElecRes,,,22-5 -US-WCr,H2O_1_3_1,,18.3,RH-ElecRes,,,22-5 -US-WCr,H2O_1_4_1,,12.2,RH-ElecRes,,,22-5 -US-WCr,H2O_1_5_1,,7.6,RH-ElecRes,,,22-5 -US-WCr,H2O_1_6_1,,2,RH-ElecRes,,,22-5 -US-WCr,H_DF,,,SA-Campbell CSAT-3,,,22-5 -US-WCr,LE,20160926,29.6,GA_CP-LI-COR LI-7200RS,SA-Campbell CSAT-3,,22-5 -US-WCr,LE,,29.6,GA_CP-LI-COR LI-6262,SA-Campbell CSAT-3,,22-5 -US-WCr,LE_DF,,,GA_CP-LI-COR LI-7200RS,SA-Campbell CSAT-3,,22-5 -US-WCr,LW_IN,,29.6,RAD-Pyrrad-SW+LW,,,22-5 -US-WCr,LW_OUT,,29.6,RAD-Pyrrad-SW+LW,,,22-5 -US-WCr,NEE_PI,20160926,29.6,GA_CP-LI-COR LI-7200RS,SA-Campbell CSAT-3,,22-5 -US-WCr,NEE_PI,,29.6,GA_CP-LI-COR LI-6262,SA-Campbell CSAT-3,,22-5 -US-WCr,NEE_PI_DF,,29.6,GA_CP-LI-COR LI-7200RS,SA-Campbell CSAT-3,,22-5 -US-WCr,NEE_PI_F,,29.6,GA_CP-LI-COR LI-7200RS,SA-Campbell CSAT-3,,22-5 -US-WCr,NETRAD_1_1_1,,29.6,RAD-Pyrrad-SW+LW,,,22-5 -US-WCr,NETRAD_1_2_1,,2,RAD-Pyrrad-SW+LW,,,22-5 -US-WCr,P,20100804,,RAIN-TipBucGauge,,,22-5 -US-WCr,P,,,PREC-TipBucGauge,,,22-5 -US-WCr,PA,,29.6,PRES-ElectBar,,,22-5 -US-WCr,P_CUM,,,PREC-TipBucGauge,,,22-5 -US-WCr,PPFD_DIF,,29.6,RAD-Other,,,22-5 -US-WCr,PPFD_IN_1_1_1,,29.6,RAD-PAR Quantum,,,22-5 -US-WCr,PPFD_IN_1_2_1,,18.3,RAD-PAR Quantum,,,22-5 -US-WCr,PPFD_IN_1_3_1,,12.2,RAD-PAR Quantum,,,22-5 -US-WCr,PPFD_IN_1_4_1,,6.1,RAD-PAR Quantum,,,22-5 -US-WCr,PPFD_IN_1_5_1,,2,RAD-PAR Quantum,,,22-5 -US-WCr,RH,,29.6,RH-ElecRes,,,22-5 -US-WCr,SC,,,GA_SR-LI-COR LI-840A,,,22-5 -US-WCr,SH,,,TEMP-ElectResis,,,22-5 -US-WCr,SLE,,,RH-ElecRes,,,22-5 -US-WCr,SWC_1_1_1,,-0.05,SWC-TDR,,,22-5 -US-WCr,SWC_1_2_1,,-0.1,SWC-TDR,,,22-5 -US-WCr,SWC_1_3_1,,-0.2,SWC-TDR,,,22-5 -US-WCr,SWC_1_4_1,,-0.5,SWC-TDR,,,22-5 -US-WCr,SWC_1_5_1,,-1,SWC-TDR,,,22-5 -US-WCr,SWC_2_1_1,20191014,-0.05,SWC-TDR,,,22-5 -US-WCr,SWC_2_2_1,20191014,-0.1,SWC-TDR,,,22-5 -US-WCr,SWC_2_3_1,20191014,-0.2,SWC-TDR,,,22-5 -US-WCr,SWC_2_4_1,20191014,-0.3,SWC-TDR,,,22-5 -US-WCr,SWC_2_5_1,20191014,-0.4,SWC-TDR,,,22-5 -US-WCr,SWC_2_6_1,20191014,-0.5,SWC-TDR,,,22-5 -US-WCr,SW_IN,,29.6,RAD-Pyrrad-SW+LW,,,22-5 -US-WCr,SW_OUT,,29.6,RAD-Pyrrad-SW+LW,,,22-5 -US-WCr,TA_1_10_1,,0.25,TEMP-TCouple,,,22-5 -US-WCr,TA_1_1_1,,29.6,TEMP-ElectResis,,,22-5 -US-WCr,TA_1_2_1,,24.4,TEMP-TCouple,,,22-5 -US-WCr,TA_1_3_1,,18.3,TEMP-ElectResis,,,22-5 -US-WCr,TA_1_4_1,,12.2,TEMP-TCouple,,,22-5 -US-WCr,TA_1_5_1,,7.6,TEMP-ElectResis,,,22-5 -US-WCr,TA_1_6_1,,2,LEAF_WET-ElectResis,,,22-5 -US-WCr,TA_1_7_1,,1,TEMP-TCouple,,,22-5 -US-WCr,TA_1_8_1,,0.75,TEMP-TCouple,,,22-5 -US-WCr,TA_1_9_1,,0.50,TEMP-TCouple,,,22-5 -US-WCr,T_BOLE_1_1_1,,1.4,TEMP-TCouple,,,22-5 -US-WCr,T_BOLE_2_1_1,,1.4,TEMP-TCouple,,,22-5 -US-WCr,TS_1_1_1,,-0,TEMP-TCouple,,,22-5 -US-WCr,TS_1_2_1,,-0.05,TEMP-TCouple,,,22-5 -US-WCr,TS_1_3_1,,-0.1,TEMP-TCouple,,,22-5 -US-WCr,TS_1_4_1,,-0.2,TEMP-TCouple,,,22-5 -US-WCr,TS_1_5_1,,-0.5,TEMP-TCouple,,,22-5 -US-WCr,TS_1_6_1,,-1,TEMP-TCouple,,,22-5 -US-WCr,TS_2_1_1,20191014,-0.05,TEMP-TCouple,,,22-5 -US-WCr,TS_2_2_1,20191014,-0.1,TEMP-TCouple,,,22-5 -US-WCr,TS_2_3_1,20191014,-0.2,TEMP-TCouple,,,22-5 -US-WCr,TS_2_4_1,20191014,-0.3,TEMP-TCouple,,,22-5 -US-WCr,TS_2_5_1,20191014,-0.4,TEMP-TCouple,,,22-5 -US-WCr,TS_2_6_1,20191014,-0.5,TEMP-TCouple,,,22-5 -US-WCr,USTAR_DF,,,SA-Campbell CSAT-3,,,22-5 -US-WCr,USTAR_PI_F,,29.6,SA-Campbell CSAT-3,,,22-5 -US-WCr,VPD_PI,,29.6,RH-ElecRes,,,22-5 -US-WCr,WD_1_1_1,,29.6,SA-Campbell CSAT-3,,,22-5 -US-WCr,WD_1_2_1,,24.4,WIND-VaneAn,,,22-5 -US-WCr,WD_1_3_1,,18.3,WIND-2DSA,,,22-5 -US-WCr,WD_1_4_1,,12.2,WIND-CupAn,,,22-5 -US-WCr,WS_1_1_1,,29.6,SA-Campbell CSAT-3,,,22-5 -US-WCr,WS_1_2_1,,24.4,WIND-CupAn,,,22-5 -US-WCr,WS_1_3_1,,18.3,WIND-2DSA,,,22-5 -US-WCr,WS_1_4_1,,12.2,WIND-CupAn,,,22-5 -US-Wdn,CO2_1,,3,,,,1-1 -US-Wdn,FC,,3,SA-Other,,CSAT/LI7500,1-1 -US-Wdn,G,,-0.05,,,,1-1 -US-Wdn,H,,3,SA-Other,,CSAT/LI7500,1-1 -US-Wdn,H2O,,3,,,,1-1 -US-Wdn,LE,,3,SA-Other,,CSAT/LI7500,1-1 -US-Wdn,LW_IN,,3,RAD-Other,,CNR1,1-1 -US-Wdn,LW_OUT,,3,RAD-Other,,CNR1,1-1 -US-Wdn,NETRAD,,3,RAD-Other,,CNR1,1-1 -US-Wdn,PA,,1,,,,1-1 -US-Wdn,PPFD_IN,,3,,,,1-1 -US-Wdn,RH,,3,,,,1-1 -US-Wdn,SWC_2,,-0.45,,,,1-1 -US-Wdn,SW_IN,,3,RAD-Other,,CNR1,1-1 -US-Wdn,SW_OUT,,3,RAD-Other,,CNR1,1-1 -US-Wdn,TA,,2,,,,1-1 -US-Wdn,TS_1,,-0.1,TEMP-Other,,Thermocouple,1-1 -US-Wdn,TS_2,,-0.2,TEMP-Other,,Thermocouple,1-1 -US-Wdn,USTAR,,3,WIND-Other,,CSAT,1-1 -US-Wdn,VPD_PI_PI,,3,,,,1-1 -US-Wdn,WD,,3,WIND-Other,,CSAT,1-1 -US-Wdn,WS,,3,,,,1-1 -US-Wgr,CO2,201406,2.5,GA_OP-LI-COR LI-7500,,,1-5 -US-Wgr,FC,201406,2.5,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3A,,1-5 -US-Wgr,H,201406,2.5,SA-Campbell CSAT-3A,,,1-5 -US-Wgr,H2O,201406,2.5,GA_OP-LI-COR LI-7500,,,1-5 -US-Wgr,LE,201406,2.5,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3A,,1-5 -US-Wgr,LW_IN,201406,2.5,RAD-Pyrrad-SW+LW,,,1-5 -US-Wgr,LW_OUT,201406,2.5,RAD-Pyrrad-SW+LW,,,1-5 -US-Wgr,PPFD_DIF,201406,2.5,RAD-PAR Quantum,,,1-5 -US-Wgr,PPFD_DIR,201406,2.5,RAD-PAR Quantum,,,1-5 -US-Wgr,RH,201406,2.5,RH-Capac,,,1-5 -US-Wgr,SW_IN,201406,2.5,RAD-Pyrrad-SW+LW,,,1-5 -US-Wgr,SW_OUT,201406,2.5,RAD-Pyrrad-SW+LW,,,1-5 -US-Wgr,TA,201406,,TEMP-ElectResis,,,1-5 -US-Wgr,U_SIGMA,201406,2.5,SA-Campbell CSAT-3A,,,1-5 -US-Wgr,USTAR,201406,2.5,SA-Campbell CSAT-3A,,,1-5 -US-Wgr,V_SIGMA,201406,2.5,SA-Campbell CSAT-3A,,,1-5 -US-Wgr,WD,201406,2.5,SA-Campbell CSAT-3A,,,1-5 -US-Wgr,WS,201406,2.5,SA-Campbell CSAT-3A,,,1-5 -US-Whs,CO2,,6.5,GA_OP-LI-COR LI-7500,,,19-5 -US-Whs,FC,,6.5,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,19-5 -US-Whs,G,,-0.05,SOIL_H-Plate,,,19-5 -US-Whs,H,,6.5,SA-Campbell CSAT-3,,,19-5 -US-Whs,H2O,,6.5,GA_OP-LI-COR LI-7500,,,19-5 -US-Whs,LE,,6.5,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,19-5 -US-Whs,LW_IN,,2.5,RAD-Pyrrad-SW+LW,,,19-5 -US-Whs,LW_OUT,,2.5,RAD-Pyrrad-SW+LW,,,19-5 -US-Whs,NETRAD,,2.5,RAD-Pyrrad-SW+LW,,,19-5 -US-Whs,P,,1,PREC-WeightGauge,,,19-5 -US-Whs,PA,,6.5,GA_OP-LI-COR LI-7500,,,19-5 -US-Whs,PPFD_IN,,3.2,RAD-PAR Quantum,,,19-5 -US-Whs,PPFD_IN_PI_F,,3.2,RAD-PAR Quantum,,,19-5 -US-Whs,PPFD_OUT,,3.2,RAD-PAR Quantum,,,19-5 -US-Whs,RH_1_1_1,,6,RH-Capac,,,19-5 -US-Whs,RH_1_2_1,,2.1,RH-Capac,,,19-5 -US-Whs,SWC_1_1_1,,-0.05,SWC-TDR,,,19-5 -US-Whs,SWC_1_2_1,,-0.15,SWC-TDR,,,19-5 -US-Whs,SWC_1_3_1,,-0.3,SWC-TDR,,,19-5 -US-Whs,SWC_PI_2_1_A,2019,-0.05,SWC-TDR,,Vol. Soil Moisture Content; 5 cm; intercanopy,19-5 -US-Whs,SWC_PI_2_2_A,2019,-0.10,SWC-TDR,,Vol. Soil Water Content; 10 cm depth; intercanopy,19-5 -US-Whs,SWC_PI_2_3_A,2019,-0.30,SWC-TDR,,Vol. Soil Water Content; 30 cm depth; intercanopy,19-5 -US-Whs,SWC_PI_2_4_A,2019,-0.50,SWC-TDR,,Vol. Soil Water Content; 50 cm depth; intercanopy,19-5 -US-Whs,SWC_PI_2_5_A,2019,-0.75,SWC-TDR,,Vol. Soil Water Content; 10 cm depth; intercanopy,19-5 -US-Whs,SWC_PI_2_6_A,2019,-1.0,SWC-TDR,,Vol. Soil Water Content; 10 cm depth; intercanopy,19-5 -US-Whs,SWC_PI_3_1_A,2019,-0.05,SWC-TDR,,Vol. Soil Moisture Content; 5 cm; undercanopy,19-5 -US-Whs,SWC_PI_3_2_A,2019,-0.10,SWC-TDR,,Vol. Soil Moisture Content; 10 cm; undercanopy,19-5 -US-Whs,SWC_PI_3_3_A,2019,-0.30,SWC-TDR,,Vol. Soil Moisture Content; 30 cm; undercanopy,19-5 -US-Whs,SWC_PI_3_4_A,2019,-0.50,SWC-TDR,,Vol. Soil Moisture Content; 50 cm; undercanopy,19-5 -US-Whs,SWC_PI_3_5_A,2019,-0.75,SWC-TDR,,Vol. Soil Moisture Content; 75 cm; undercanopy,19-5 -US-Whs,SWC_PI_3_6_A,2019,-1.0,SWC-TDR,,Vol. Soil Moisture Content; 100 cm; undercanopy,19-5 -US-Whs,SW_IN,,2.5,RAD-Pyrrad-SW+LW,,,19-5 -US-Whs,SW_OUT,,2.5,RAD-Pyrrad-SW+LW,,,19-5 -US-Whs,TA_1_1_1,,6,TEMP-ElectResis,,,19-5 -US-Whs,TA_1_2_1,,2.1,TEMP-ElectResis,,,19-5 -US-Whs,T_CANOPY_1_1_1,2019,1.5,,,Infrared Thermometer measurement of skin temperature; bare soil with some shrubs,19-5 -US-Whs,TS_1_1_1,,-0.05,TEMP-TCouple,,,19-5 -US-Whs,TS_1_2_1,,-0.15,TEMP-TCouple,,,19-5 -US-Whs,TS_1_3_1,,-0.3,TEMP-TCouple,,,19-5 -US-Whs,TS_PI_2_1_A,2019,-0.05,TEMP-ElectResis,,Soil Temperature; 5 cm; intercanopy,19-5 -US-Whs,TS_PI_2_2_A,2019,-0.10,TEMP-ElectResis,,Soil Temperature; 10 cm; intercanopy,19-5 -US-Whs,TS_PI_2_3_A,2019,-0.30,TEMP-ElectResis,,Soil Temperature; 30 cm; intercanopy,19-5 -US-Whs,TS_PI_2_4_A,2019,-0.50,TEMP-ElectResis,,Soil Temperature; 50 cm; intercanopy,19-5 -US-Whs,TS_PI_2_5_A,2019,-0.75,TEMP-ElectResis,,Soil Temperature; 75 cm; intercanopy,19-5 -US-Whs,TS_PI_2_6_A,2019,-1.0,TEMP-ElectResis,,Soil Temperature; 100 cm; intercanopy,19-5 -US-Whs,TS_PI_3_1_A,2019,-0.05,TEMP-ElectResis,,Soil Temperature; 5 cm; undercanopy,19-5 -US-Whs,TS_PI_3_2_A,2019,-0.10,TEMP-ElectResis,,Soil Temperature; 10 cm; undercanopy,19-5 -US-Whs,TS_PI_3_3_A,2019,-0.30,TEMP-ElectResis,,Soil Temperature; 30 cm; undercanopy,19-5 -US-Whs,TS_PI_3_4_A,2019,-0.50,TEMP-ElectResis,,Soil Temperature; 50 cm; undercanopy,19-5 -US-Whs,TS_PI_3_5_A,2019,-0.75,TEMP-ElectResis,,Soil Temperature; 75 cm; undercanopy,19-5 -US-Whs,TS_PI_3_6_A,2019,-1.0,TEMP-ElectResis,,Soil Temperature; 100 cm; undercanopy,19-5 -US-Whs,T_SONIC,,6.5,SA-Campbell CSAT-3,,,19-5 -US-Whs,USTAR,,6.5,SA-Campbell CSAT-3,,,19-5 -US-Whs,WD_1_1_1,,6.5,SA-Campbell CSAT-3,,,19-5 -US-Whs,WD_1_2_1,,2.1,WIND-VaneAn,,,19-5 -US-Whs,WS_1_1_1,,6.5,SA-Campbell CSAT-3,,,19-5 -US-Whs,WS_1_2_1,,2.1,WIND-CupAn,,,19-5 -US-Wi0,CO2,,6,,,,3-5 -US-Wi0,FC,,6,,,,3-5 -US-Wi0,H,,6,,,,3-5 -US-Wi0,LE,,6,,,,3-5 -US-Wi0,TS_1_1_1,,-0.05,,,,3-5 -US-Wi0,TS_1_2_1,,-0.2,,,,3-5 -US-Wi1,CO2,,9,,,,3-5 -US-Wi1,FC,,9,,,,3-5 -US-Wi1,H,,9,,,,3-5 -US-Wi1,LE,,9,,,,3-5 -US-Wi1,TS_1_1_1,,-0.05,,,,3-5 -US-Wi1,TS_1_2_1,,-0.2,,,,3-5 -US-Wi2,CO2,,9,,,,3-5 -US-Wi2,FC,,9,,,,3-5 -US-Wi2,H,,9,,,,3-5 -US-Wi2,LE,,9,,,,3-5 -US-Wi2,TS_1_1_1,,-0.05,,,,3-5 -US-Wi2,TS_1_2_1,,-0.2,,,,3-5 -US-Wi3,CO2,,26,,,,3-5 -US-Wi3,FC,,26,,,,3-5 -US-Wi3,H,,26,,,,3-5 -US-Wi3,LE,,26,,,,3-5 -US-Wi3,TS_1_1_1,,-0.05,,,,3-5 -US-Wi3,TS_1_2_1,,-0.2,,,,3-5 -US-Wi4,CO2,,23,,,,3-5 -US-Wi4,FC,,23,,,,3-5 -US-Wi4,H,,23,,,,3-5 -US-Wi4,LE,,23,,,,3-5 -US-Wi4,TS_1_1_1,,-0.05,,,,3-5 -US-Wi4,TS_1_2_1,,-0.2,,,,3-5 -US-Wi5,CO2,,6,,,,3-5 -US-Wi5,FC,,6,,,,3-5 -US-Wi5,H,,6,,,,3-5 -US-Wi5,LE,,6,,,,3-5 -US-Wi5,TS_1_1_1,,-0.05,,,,3-5 -US-Wi5,TS_1_2_1,,-0.2,,,,3-5 -US-Wi6,CO2,,3,,,,3-5 -US-Wi6,FC,,3,,,,3-5 -US-Wi6,H,,3,,,,3-5 -US-Wi6,LE,,3,,,,3-5 -US-Wi6,TS_1_1_1,,-0.05,,,,3-5 -US-Wi6,TS_1_2_1,,-0.2,,,,3-5 -US-Wi7,CO2,,6,,,,3-5 -US-Wi7,FC,,6,,,,3-5 -US-Wi7,H,,6,,,,3-5 -US-Wi7,LE,,6,,,,3-5 -US-Wi7,TS_1_1_1,,-0.05,,,,3-5 -US-Wi7,TS_1_2_1,,-0.2,,,,3-5 -US-Wi8,CO2,,3,,,,3-5 -US-Wi8,FC,,3,,,,3-5 -US-Wi8,H,,3,,,,3-5 -US-Wi8,LE,,3,,,,3-5 -US-Wi8,TS_1_1_1,,-0.05,,,,3-5 -US-Wi8,TS_1_2_1,,-0.2,,,,3-5 -US-Wi9,CO2,,9,,,,3-5 -US-Wi9,FC,,9,,,,3-5 -US-Wi9,H,,9,,,,3-5 -US-Wi9,LE,,9,,,,3-5 -US-Wi9,TS_1_1_1,,-0.05,,,,3-5 -US-Wi9,TS_1_2_1,,-0.2,,,,3-5 -US-Wjs,CO2,,10,GA-Other,,,17-5 -US-Wjs,FC,,10,,,,17-5 -US-Wjs,H,,10,,,,17-5 -US-Wjs,H2O,,10,GA-Other,,,17-5 -US-Wjs,LE,,10,,,,17-5 -US-Wjs,LW_IN,,10.5,,,Kipp & Zonen CNR1,17-5 -US-Wjs,LW_OUT,,10.5,,,Kipp & Zonen CNR1,17-5 -US-Wjs,NETRAD,,10.5,,,Kipp & Zonen CNR1,17-5 -US-Wjs,P,,2,,,,17-5 -US-Wjs,PA,,10,,,,17-5 -US-Wjs,P_PI_F,,2,,,P data gapfilled from nearby tower sites and meteorological stations,17-5 -US-Wjs,PPFD_IN,,10.5,,,Kipp & Zonen PQS1,17-5 -US-Wjs,RH,,10,,,Vaisala HMP45c,17-5 -US-Wjs,RH_PI_F,,10,,,RH data gapfilled from nearby tower sites,17-5 -US-Wjs,SW_IN,,10.5,,,Kipp & Zonen CNR1,17-5 -US-Wjs,SW_OUT,,10.5,,,Kipp & Zonen CNR1,17-5 -US-Wjs,TA,,10,,,,17-5 -US-Wjs,TA_PI_F,,10,,,TA data gapfilled from nearby towers sites and from Vaisala HMP45c data,17-5 -US-Wjs,USTAR,,10,,,,17-5 -US-Wjs,VPD_PI,,10,,,calculated from TA and RH,17-5 -US-Wjs,VPD_PI_F,,10,,,VPD data gapfilled from nearby tower sites,17-5 -US-Wjs,WD,,10,,,,17-5 -US-Wjs,WS,,10,,,,17-5 -US-Wkg,CO2,,6.4,GA_OP-LI-COR LI-7500,,,19-5 -US-Wkg,FC,,6.4,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,19-5 -US-Wkg,G_PI_1_1_A,,-0.08,SOIL_H-Plate,,,19-5 -US-Wkg,H,,6.4,SA-Campbell CSAT-3,,,19-5 -US-Wkg,H2O,,6.4,GA_OP-LI-COR LI-7500,,,19-5 -US-Wkg,LE,,6.4,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,19-5 -US-Wkg,LW_IN,,3,RAD-Pyrrad-SW+LW,,,19-5 -US-Wkg,LW_OUT,,3,RAD-Pyrrad-SW+LW,,,19-5 -US-Wkg,NETRAD,,3,RAD-Pyrrad-SW+LW,,,19-5 -US-Wkg,P,,1,PREC-WeightGauge,,,19-5 -US-Wkg,PA,,6.4,GA_OP-LI-COR LI-7500,,,19-5 -US-Wkg,PPFD_IN,,3.5,RAD-PAR Quantum,,,19-5 -US-Wkg,PPFD_IN_PI_F,,3.5,RAD-PAR Quantum,,,19-5 -US-Wkg,PPFD_OUT,,3.5,RAD-PAR Quantum,,,19-5 -US-Wkg,RH_1_1_1,,6,RH-Capac,,,19-5 -US-Wkg,RH_1_2_1,,2,RH-Capac,,,19-5 -US-Wkg,SWC_1_1_1,,-0.05,SWC-TDR,,,19-5 -US-Wkg,SWC_1_2_1,,-0.15,SWC-TDR,,,19-5 -US-Wkg,SWC_1_3_1,,-0.3,SWC-TDR,,,19-5 -US-Wkg,SWC_PI_2_1_A,2019,-0.05,SWC-TDR,,Vol. Soil Water Content; 5 cm depth,19-5 -US-Wkg,SWC_PI_2_2_A,2019,-0.10,SWC-TDR,,Vol. Soil Water Content; 10 cm depth,19-5 -US-Wkg,SWC_PI_2_3_A,2019,-0.30,SWC-TDR,,Vol. Soil Water Content; 30 cm depth,19-5 -US-Wkg,SWC_PI_2_4_A,2019,-0.50,SWC-TDR,,Vol. Soil Water Content; 50 cm depth,19-5 -US-Wkg,SWC_PI_2_5_A,2019,-0.75,SWC-TDR,,Vol. Soil Water Content; 75 cm depth,19-5 -US-Wkg,SWC_PI_2_6_A,2019,-1.0,SWC-TDR,,Vol. Soil Water Content; 100 cm depth,19-5 -US-Wkg,SW_IN,,3,RAD-Pyrrad-SW+LW,,,19-5 -US-Wkg,SW_OUT,,3,RAD-Pyrrad-SW+LW,,,19-5 -US-Wkg,TA_1_1_1,,6,TEMP-ElectResis,,,19-5 -US-Wkg,TA_1_2_1,,2,TEMP-ElectResis,,,19-5 -US-Wkg,T_CANOPY_1_1_1,,1.5,TEMP-Other,,,19-5 -US-Wkg,TS_1_1_1,,-0.05,TEMP-TCouple,,,19-5 -US-Wkg,TS_1_2_1,,-0.15,TEMP-TCouple,,,19-5 -US-Wkg,TS_1_3_1,,-0.3,TEMP-TCouple,,,19-5 -US-Wkg,TS_PI_2_1_A,2019,-0.05,TEMP-ElectResis,,Soil Temperature; 5 cm,19-5 -US-Wkg,TS_PI_2_2_A,2019,-0.10,TEMP-ElectResis,,Soil Temperature; 10 cm,19-5 -US-Wkg,TS_PI_2_3_A,2019,-0.30,TEMP-ElectResis,,Soil Temperature; 30 cm,19-5 -US-Wkg,TS_PI_2_4_A,2019,-0.50,TEMP-ElectResis,,Soil Temperature; 50 cm,19-5 -US-Wkg,TS_PI_2_5_A,2019,-0.75,TEMP-ElectResis,,Soil Temperature; 75 cm,19-5 -US-Wkg,TS_PI_2_6_A,2019,-1.0,TEMP-ElectResis,,Soil Temperature; 100 cm,19-5 -US-Wkg,T_SONIC,,6.4,SA-Campbell CSAT-3,,,19-5 -US-Wkg,USTAR,,6.4,SA-Campbell CSAT-3,,,19-5 -US-Wkg,WD_1_1_1,,6.4,SA-Campbell CSAT-3,,,19-5 -US-Wkg,WD_1_2_1,,3.5,WIND-VaneAn,,,19-5 -US-Wkg,WS_1_1_1,,6.4,SA-Campbell CSAT-3,,,19-5 -US-Wkg,WS_1_2_1,,3.5,WIND-CupAn,,,19-5 -US-Wlr,ALB,20010801,1.5,RAD-Other,,Schenk Dual-Pyranometer Type 8194,4-5 -US-Wlr,ALB_DF,20010801,1.5,RAD-Other,,Schenk Dual-Pyranometer Type 8194,4-5 -US-Wlr,ALB_PI_F,20010801,1.5,RAD-Other,,Schenk Dual-Pyranometer Type 8194,4-5 -US-Wlr,FC,20010801,2.1,SA-Gill R3-100,GA_OP-LI-COR LI-7500,,4-5 -US-Wlr,FC_DF,20010801,2.1,SA-Gill R3-100,GA_OP-LI-COR LI-7500,,4-5 -US-Wlr,FC_PI_F,20010801,2.1,SA-Gill R3-100,GA_OP-LI-COR LI-7500,,4-5 -US-Wlr,FH2O,20010801,2.1,GA_OP-LI-COR LI-7500,,,4-5 -US-Wlr,FH2O_PI_F,20010801,2.1,GA_OP-LI-COR LI-7500,,,4-5 -US-Wlr,G,20010801,-0.05,SOIL_H-Plate,,REBS HFT-3.1 adjusted for energy storage above plate,4-5 -US-Wlr,G_DF,20010801,-0.05,SOIL_H-Plate,,REBS HFT-3.1 adjusted for energy storage above plate,4-5 -US-Wlr,G_PI_F,20010801,-0.05,SOIL_H-Plate,,REBS HFT-3.1 adjusted for energy storage above plate,4-5 -US-Wlr,H,20010801,2.1,SA-Gill R3-100,,,4-5 -US-Wlr,H_DF,20010801,2.1,SA-Gill R3-100,,,4-5 -US-Wlr,H_PI_F,20010801,2.1,SA-Gill R3-100,,,4-5 -US-Wlr,LE,20010801,2.1,SA-Gill R3-100,GA_OP-LI-COR LI-7500,,4-5 -US-Wlr,LE_DF,20010801,2.1,SA-Gill R3-100,GA_OP-LI-COR LI-7500,,4-5 -US-Wlr,LE_PI_F,20010801,2.1,SA-Gill R3-100,GA_OP-LI-COR LI-7500,,4-5 -US-Wlr,NETRAD,20010801,1.5,RAD-Net radiometer,,REBS Q*7.1,4-5 -US-Wlr,NETRAD_DF,20010801,1.5,RAD-Net radiometer,,REBS Q*7.1,4-5 -US-Wlr,NETRAD_PI_F,20010801,1.5,RAD-Net radiometer,,REBS Q*7.1,4-5 -US-Wlr,P,20010801,1.5,PREC-TipBucGauge,,Met One 385 heated,4-5 -US-Wlr,PA,20010801,1.5,PRES-ElectBar,,Vaisala PTB201A,4-5 -US-Wlr,PA_DF,20010801,1.5,PRES-ElectBar,,Vaisala PTB201A,4-5 -US-Wlr,PA_PI_F,20010801,1.5,PRES-ElectBar,,Vaisala PTB201A,4-5 -US-Wlr,P_CUM,20010801,1.5,PREC-TipBucGauge,,Met One 385 heated,4-5 -US-Wlr,P_CUM_PI_F,20010801,1.5,PREC-TipBucGauge,,Met One 385 heated,4-5 -US-Wlr,P_DF,20010801,1.5,PREC-TipBucGauge,,Met One 385 heated,4-5 -US-Wlr,P_PI_F,20010801,1.5,PREC-TipBucGauge,,Met One 385 heated,4-5 -US-Wlr,PPFD_IN,20010801,1.5,RAD-PAR Quantum,,LI-190SA,4-5 -US-Wlr,PPFD_IN_DF,20010801,1.5,RAD-PAR Quantum,,LI-190SA,4-5 -US-Wlr,PPFD_IN_PI_F,20010801,1.5,RAD-PAR Quantum,,LI-190SA,4-5 -US-Wlr,RH,20010801,1.5,RH-Capac,,Vaisala HMP45A,4-5 -US-Wlr,RH_DF,20010801,1.5,RH-Capac,,Vaisala HMP45A,4-5 -US-Wlr,RH_PI_F,20010801,1.5,RH-Capac,,Vaisala HMP45A,4-5 -US-Wlr,SWC,20010801,-0.025,SWC-Other,,REBS SMP-2,4-5 -US-Wlr,SWC_DF,20010801,-0.025,SWC-Other,,REBS SMP-2,4-5 -US-Wlr,SWC_PI_F,20010801,-0.025,SWC-Other,,REBS SMP-2,4-5 -US-Wlr,SW_IN,20010801,1.5,RAD-Other,,Schenk Dual-Pyranometer Type 8194,4-5 -US-Wlr,SW_IN_DF,20010801,1.5,RAD-Other,,Schenk Dual-Pyranometer Type 8194,4-5 -US-Wlr,SW_IN_PI_F,20010801,1.5,RAD-Other,,Schenk Dual-Pyranometer Type 8194,4-5 -US-Wlr,SW_OUT,20010801,1.5,RAD-Other,,Schenk Dual-Pyranometer Type 8194,4-5 -US-Wlr,SW_OUT_DF,20010801,1.5,RAD-Other,,Schenk Dual-Pyranometer Type 8194,4-5 -US-Wlr,SW_OUT_PI_F,20010801,1.5,RAD-Other,,Schenk Dual-Pyranometer Type 8194,4-5 -US-Wlr,TA,20010801,1.5,TEMP-ElectResis,,Vaisala HMP45A,4-5 -US-Wlr,TA_DF,20010801,1.5,TEMP-ElectResis,,Vaisala HMP45A,4-5 -US-Wlr,TA_PI_F,20010801,1.5,TEMP-ElectResis,,Vaisala HMP45A,4-5 -US-Wlr,TAU,20010801,2.1,SA-Gill R3-100,,,4-5 -US-Wlr,TAU_DF,20010801,2.1,SA-Gill R3-100,,,4-5 -US-Wlr,TAU_PI_F,20010801,2.1,SA-Gill R3-100,,,4-5 -US-Wlr,TS,20010801,-0.025,TEMP-ElectResis,,REBS STP-1,4-5 -US-Wlr,TS_DF,20010801,-0.025,TEMP-ElectResis,,REBS STP-1,4-5 -US-Wlr,TS_PI_F,20010801,-0.025,TEMP-ElectResis,,REBS STP-1,4-5 -US-Wlr,USTAR,20010801,2.1,SA-Gill R3-100,,,4-5 -US-Wlr,USTAR_DF,20010801,2.1,SA-Gill R3-100,,,4-5 -US-Wlr,USTAR_PI_F,20010801,2.1,SA-Gill R3-100,,,4-5 -US-Wlr,VPD_PI,20010801,1.5,RH-Capac,,Vaisala HMP45A,4-5 -US-Wlr,VPD_PI_F,20010801,1.5,RH-Capac,,Vaisala HMP45A,4-5 -US-Wlr,WD,20010801,2.1,SA-Gill R3-100,,,4-5 -US-Wlr,WD_DF,20010801,2.1,SA-Gill R3-100,,,4-5 -US-Wlr,WD_PI_F,20010801,2.1,SA-Gill R3-100,,,4-5 -US-Wlr,WS,20010801,2.1,SA-Gill R3-100,,,4-5 -US-Wlr,WS_DF,20010801,2.1,SA-Gill R3-100,,,4-5 -US-Wlr,WS_PI_F,20010801,2.1,SA-Gill R3-100,,,4-5 -US-Wlr,ZL,20010801,2.1,SA-Gill R3-100,,,4-5 -US-Wlr,ZL_DF,20010801,2.1,SA-Gill R3-100,,,4-5 -US-Wlr,ZL_PI_F,20010801,2.1,SA-Gill R3-100,,,4-5 -US-WPT,CH4,,2.7,GA_OP-LI-COR LI-7700,,,4-5 -US-WPT,CO2,,2.7,GA_OP-LI-COR LI-7500,,,4-5 -US-WPT,FC,,2.7,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,4-5 -US-WPT,FCH4,,2.7,GA_OP-LI-COR LI-7700,SA-Campbell CSAT-3,,4-5 -US-WPT,H,,2.7,SA-Campbell CSAT-3,,,4-5 -US-WPT,H2O,,2.7,GA_OP-LI-COR LI-7500,,,4-5 -US-WPT,LE,,2.7,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,4-5 -US-WPT,LW_IN,,2.7,RAD-Pyrrad-SW+LW,,,4-5 -US-WPT,LW_OUT,,2.7,RAD-Pyrrad-SW+LW,,,4-5 -US-WPT,MO_LENGTH,,2.7,,,,4-5 -US-WPT,NEE_PI,,,GA_OP-LI-COR LI-7500,SA-Campbell CSAT-3,,4-5 -US-WPT,NETRAD,,2.7,RAD-Pyrrad-SW+LW,,,4-5 -US-WPT,P,,3.2,RAIN-TipBucGauge,,,4-5 -US-WPT,PA,,0.5,PRES-ElectBar,,,4-5 -US-WPT,PPFD_IN,,2.7,RAD-PAR Quantum,,,4-5 -US-WPT,RH,,2.7,RH-Capac,,,4-5 -US-WPT,SW_IN,,2.7,RAD-Pyrrad-SW+LW,,,4-5 -US-WPT,SW_OUT,,2.7,RAD-Pyrrad-SW+LW,,,4-5 -US-WPT,TA_1_1_1,,2.7,TEMP-ElectResis,,,4-5 -US-WPT,TA_1_2_1,,0.7,TEMP-TCouple,,,4-5 -US-WPT,TS_1,,-0.1,TEMP-TCouple,,,4-5 -US-WPT,TS_2,,-0.3,TEMP-TCouple,,,4-5 -US-WPT,T_SONIC,,2.7,SA-Campbell CSAT-3,,,4-5 -US-WPT,T_SONIC_SIGMA,,2.7,SA-Campbell CSAT-3,,,4-5 -US-WPT,TW_1,,0.3,TEMP-TCouple,,,4-5 -US-WPT,TW_2,,0.1,TEMP-TCouple,,,4-5 -US-WPT,USTAR,,2.7,SA-Campbell CSAT-3,,,4-5 -US-WPT,V_SIGMA,,2.7,SA-Campbell CSAT-3,,,4-5 -US-WPT,WD,,2.7,SA-Campbell CSAT-3,,,4-5 -US-WPT,WS,,2.7,SA-Campbell CSAT-3,,,4-5 -US-WPT,W_SIGMA,,2.7,SA-Campbell CSAT-3,,,4-5 -US-WPT,WTD,,-0.1,WTD-Press,,,4-5 -US-WPT,ZL,,2.7,,,,4-5 -US-Wrc,CO2_1,,70,GA-Other,,Licor 6262,8-1 -US-Wrc,FC,,70,GA-Other,,Licor 6262,8-1 -US-Wrc,G,,-0.075,SOIL_H-Other,,CSI HFT-3.1 (positive numbers are surface to atmosphere),8-1 -US-Wrc,H,,70,SA-Other,,CSAT3 (positive numbers are surface to atmosphere),8-1 -US-Wrc,H2O,,70,GA-Other,,Licor 6262,8-1 -US-Wrc,LE,,70,GA-Other,,Licor 6262,8-1 -US-Wrc,LW_IN,,71,RAD-Other,,Kipp & Zonen CNR1,8-1 -US-Wrc,LW_OUT,,71,RAD-Other,,Kipp & Zonen CNR1,8-1 -US-Wrc,P,,,PREC-Other,,MetOne 385 heated 0.254 mm tipping bucket,8-1 -US-Wrc,PA,,70,PRES-Other,,Vaisala CS105,8-1 -US-Wrc,PPFD_IN,,70,RAD-Other,,CSI LI190SB; sensor added in 2004,8-1 -US-Wrc,RH,,70,RH-Other,,CSI HMP45C,8-1 -US-Wrc,SWC_1,,-0.2,SWC-Other,,EnviroSMART,8-1 -US-Wrc,SWC_2,,-0.3,SWC-Other,,EnviroSMART,8-1 -US-Wrc,SW_IN,,71,RAD-Other,,Kipp & Zonen CNR1,8-1 -US-Wrc,SW_OUT,,71,RAD-Other,,Kipp & Zonen CNR1,8-1 -US-Wrc,TA,,70,TEMP-Other,,CSI HMP45C,8-1 -US-Wrc,TS_1,,-0,TEMP-Other,,CSI 107B,8-1 -US-Wrc,TS_2,,-0.15,TEMP-Other,,CSI 107B,8-1 -US-Wrc,USTAR,,70,WIND-Other,,Gill Instruments,8-1 -US-Wrc,VPD_PI_PI,,70,,,,8-1 -US-Wrc,WD,,70,WIND-Other,,CSAT3,8-1 -US-Wrc,WS,,70,WIND-Other,,Gill Instruments,8-1 -US-xBR,CO2_1_1_1,,35.68,GA_CP-LI-COR LI-7200,,,6-5 -US-xBR,CO2_1_1_2,,35.68,GA_SR-LI-COR LI-840,,,6-5 -US-xBR,CO2_1_1_3,,35.68,GA_SR-Other,,,6-5 -US-xBR,CO2_1_2_2,,25.84,GA_SR-LI-COR LI-840,,,6-5 -US-xBR,CO2_1_2_3,,25.84,GA_SR-Other,,,6-5 -US-xBR,CO2_1_3_2,,19.56,GA_SR-LI-COR LI-840,,,6-5 -US-xBR,CO2_1_3_3,,19.56,GA_SR-Other,,,6-5 -US-xBR,CO2_1_4_2,,15.86,GA_SR-LI-COR LI-840,,,6-5 -US-xBR,CO2_1_4_3,,15.86,GA_SR-Other,,,6-5 -US-xBR,CO2_1_5_2,,2.84,GA_SR-LI-COR LI-840,,,6-5 -US-xBR,CO2_1_5_3,,2.84,GA_SR-Other,,,6-5 -US-xBR,CO2_1_6_2,,0.49,GA_SR-LI-COR LI-840,,,6-5 -US-xBR,CO2_1_6_3,,0.49,GA_SR-Other,,,6-5 -US-xBR,FC,,35.68,GA_CP-LI-COR LI-7200,SA-Campbell CSAT-3,,6-5 -US-xBR,FETCH_90,,35.68,SA-Campbell CSAT-3,,,6-5 -US-xBR,FETCH_MAX,,35.68,SA-Campbell CSAT-3,,,6-5 -US-xBR,G_1_1_1,,-0.08,SOIL_H-Plate,,,6-5 -US-xBR,G_2_1_1,,-0.08,SOIL_H-Plate,,,6-5 -US-xBR,G_3_1_1,,-0.08,SOIL_H-Plate,,,6-5 -US-xBR,H,,35.68,SA-Campbell CSAT-3,,,6-5 -US-xBR,H2O_1_1_1,,35.68,GA_CP-LI-COR LI-7200,,,6-5 -US-xBR,H2O_1_1_3,,35.68,,,Picarro L2130 is not installed at this site,6-5 -US-xBR,H2O_1_2_2,,25.84,GA_SR-LI-COR LI-840,,,6-5 -US-xBR,H2O_1_2_3,,25.84,,,Picarro L2130 is not installed at this site,6-5 -US-xBR,H2O_1_3_2,,19.56,GA_SR-LI-COR LI-840,,,6-5 -US-xBR,H2O_1_3_3,,19.56,,,Picarro L2130 is not installed at this site,6-5 -US-xBR,H2O_1_4_2,,15.86,GA_SR-LI-COR LI-840,,,6-5 -US-xBR,H2O_1_4_3,,15.86,,,Picarro L2130 is not installed at this site,6-5 -US-xBR,H2O_1_5_2,,2.84,GA_SR-LI-COR LI-840,,,6-5 -US-xBR,H2O_1_5_3,,2.84,,,Picarro L2130 is not installed at this site,6-5 -US-xBR,H2O_1_6_2,,0.49,GA_SR-LI-COR LI-840,,,6-5 -US-xBR,H2O_1_6_3,,0.49,,,Picarro L2130 is not installed at this site,6-5 -US-xBR,LE,,35.68,GA_CP-LI-COR LI-7200,SA-Campbell CSAT-3,,6-5 -US-xBR,LW_BC_IN,,0.25,RAD-Pyrrad-SW+LW,,,6-5 -US-xBR,LW_BC_OUT,,0.25,RAD-Pyrrad-SW+LW,,,6-5 -US-xBR,LW_IN,,35.67,RAD-Pyrrad-SW+LW,,,6-5 -US-xBR,LW_OUT,,35.67,RAD-Pyrrad-SW+LW,,,6-5 -US-xBR,NEE_PI,,35.68,GA_CP-LI-COR LI-7200,SA-Campbell CSAT-3,,6-5 -US-xBR,NETRAD,,35.67,RAD-Pyrrad-SW+LW,,,6-5 -US-xBR,P,,35.89,PREC-TipBucGauge,,,6-5 -US-xBR,PA,,4.84,PRES-ElectBar,,,6-5 -US-xBR,PPFD_BC_IN_1_1_1,,0,RAD-PAR Quantum,,,6-5 -US-xBR,PPFD_BC_IN_2_1_1,,0,RAD-PAR Quantum,,,6-5 -US-xBR,PPFD_BC_IN_3_1_1,,0,RAD-PAR Quantum,,,6-5 -US-xBR,PPFD_IN_1_1_1,,35.59,RAD-PAR Quantum,,,6-5 -US-xBR,PPFD_IN_1_2_1,,26.11,RAD-PAR Quantum,,,6-5 -US-xBR,PPFD_IN_1_3_1,,19.83,RAD-PAR Quantum,,,6-5 -US-xBR,PPFD_IN_1_4_1,,16.13,RAD-PAR Quantum,,,6-5 -US-xBR,PPFD_IN_1_5_1,,3.11,RAD-PAR Quantum,,,6-5 -US-xBR,PPFD_IN_1_6_1,,0.73,RAD-PAR Quantum,,,6-5 -US-xBR,PPFD_OUT,,35.59,RAD-PAR Quantum,,,6-5 -US-xBR,RH,,35.19,RH-Capac,,,6-5 -US-xBR,SC,,35.68,GA_SR-LI-COR LI-840,,,6-5 -US-xBR,SH,,35.68,TEMP-ElectResis,,,6-5 -US-xBR,SLE,,35.68,GA_SR-LI-COR LI-840,,,6-5 -US-xBR,SWC_1_1_1,,-0.06,SWC-FDR,,,6-5 -US-xBR,SWC_1_2_1,,-0.16,SWC-FDR,,,6-5 -US-xBR,SWC_1_3_1,,-0.26,SWC-FDR,,,6-5 -US-xBR,SWC_1_4_1,,-0.56,SWC-FDR,,,6-5 -US-xBR,SWC_1_5_1,,-0.96,SWC-FDR,,,6-5 -US-xBR,SWC_1_6_1,,-1.16,SWC-FDR,,,6-5 -US-xBR,SWC_1_7_1,,-1.66,SWC-FDR,,,6-5 -US-xBR,SWC_1_8_1,,-1.96,SWC-FDR,,,6-5 -US-xBR,SWC_2_1_1,,-0.06,SWC-FDR,,,6-5 -US-xBR,SWC_2_2_1,,-0.16,SWC-FDR,,,6-5 -US-xBR,SWC_2_3_1,,-0.26,SWC-FDR,,,6-5 -US-xBR,SWC_2_4_1,,-0.56,SWC-FDR,,,6-5 -US-xBR,SWC_2_5_1,,-0.96,SWC-FDR,,,6-5 -US-xBR,SWC_2_6_1,,-1.16,SWC-FDR,,,6-5 -US-xBR,SWC_2_7_1,,-1.66,SWC-FDR,,,6-5 -US-xBR,SWC_2_8_1,,-1.96,SWC-FDR,,,6-5 -US-xBR,SWC_3_1_1,,-0.056,SWC-FDR,,,6-5 -US-xBR,SWC_3_2_1,,-0.156,SWC-FDR,,,6-5 -US-xBR,SWC_3_3_1,,-0.256,SWC-FDR,,,6-5 -US-xBR,SWC_3_4_1,,-0.556,SWC-FDR,,,6-5 -US-xBR,SWC_3_5_1,,-0.956,SWC-FDR,,,6-5 -US-xBR,SWC_3_6_1,,-1.156,SWC-FDR,,,6-5 -US-xBR,SWC_3_7_1,,-1.656,SWC-FDR,,,6-5 -US-xBR,SWC_3_8_1,,-1.956,SWC-FDR,,,6-5 -US-xBR,SWC_4_1_1,,-0.057,SWC-FDR,,,6-5 -US-xBR,SWC_4_2_1,,-0.157,SWC-FDR,,,6-5 -US-xBR,SWC_4_3_1,,-0.257,SWC-FDR,,,6-5 -US-xBR,SWC_4_4_1,,-0.557,SWC-FDR,,,6-5 -US-xBR,SWC_4_5_1,,-0.957,SWC-FDR,,,6-5 -US-xBR,SWC_4_6_1,,-1.157,SWC-FDR,,,6-5 -US-xBR,SWC_4_7_1,,-1.657,SWC-FDR,,,6-5 -US-xBR,SWC_4_8_1,,-1.957,SWC-FDR,,,6-5 -US-xBR,SWC_5_1_1,,-0.06,SWC-FDR,,,6-5 -US-xBR,SWC_5_2_1,,-0.16,SWC-FDR,,,6-5 -US-xBR,SWC_5_3_1,,-0.26,SWC-FDR,,,6-5 -US-xBR,SWC_5_4_1,,-0.56,SWC-FDR,,,6-5 -US-xBR,SWC_5_5_1,,-0.96,SWC-FDR,,,6-5 -US-xBR,SWC_5_6_1,,-1.16,SWC-FDR,,,6-5 -US-xBR,SWC_5_7_1,,-1.66,SWC-FDR,,,6-5 -US-xBR,SWC_5_8_1,,-1.96,SWC-FDR,,,6-5 -US-xBR,SW_DIF,,35.81,RAD-SW Pyran Class1,,,6-5 -US-xBR,SW_IN_1_1_1,,35.67,RAD-Pyrrad-SW+LW,,,6-5 -US-xBR,SW_IN_1_1_2,,35.81,RAD-SW Pyran Class1,,,6-5 -US-xBR,SW_OUT,,35.67,RAD-Pyrrad-SW+LW,,,6-5 -US-xBR,TA_1_1_1,,34.96,TEMP-ElectResis,,,6-5 -US-xBR,TA_1_1_2,,35.19,TEMP-ElectResis,,,6-5 -US-xBR,TA_1_2_1,,25.5,TEMP-ElectResis,,,6-5 -US-xBR,TA_1_3_1,,19.23,TEMP-ElectResis,,,6-5 -US-xBR,TA_1_4_1,,15.53,TEMP-ElectResis,,,6-5 -US-xBR,TA_1_5_1,,2.51,TEMP-ElectResis,,,6-5 -US-xBR,TA_1_6_1,,0.14,TEMP-ElectResis,,,6-5 -US-xBR,T_CANOPY_1_1_1,,19.83,RAD-Other,,,6-5 -US-xBR,T_CANOPY_1_2_1,,16.13,RAD-Other,,,6-5 -US-xBR,T_CANOPY_1_3_1,,3.11,RAD-Other,,,6-5 -US-xBR,T_CANOPY_1_4_1,,0.73,RAD-Other,,,6-5 -US-xBR,T_CANOPY_2_4_1,,0.29,RAD-Other,,,6-5 -US-xBR,THROUGHFALL_1_1_1,,0,PREC-TipBucGauge,,,6-5 -US-xBR,THROUGHFALL_2_1_1,,0,PREC-TipBucGauge,,,6-5 -US-xBR,THROUGHFALL_3_1_1,,0,PREC-TipBucGauge,,,6-5 -US-xBR,THROUGHFALL_4_1_1,,0,PREC-TipBucGauge,,,6-5 -US-xBR,TS_1_1_1,,-0.02,TEMP-ElectResis,,,6-5 -US-xBR,TS_1_2_1,,-0.06,TEMP-ElectResis,,,6-5 -US-xBR,TS_1_3_1,,-0.16,TEMP-ElectResis,,,6-5 -US-xBR,TS_1_4_1,,-0.26,TEMP-ElectResis,,,6-5 -US-xBR,TS_1_5_1,,-0.56,TEMP-ElectResis,,,6-5 -US-xBR,TS_1_6_1,,-0.96,TEMP-ElectResis,,,6-5 -US-xBR,TS_1_7_1,,-1.16,TEMP-ElectResis,,,6-5 -US-xBR,TS_1_8_1,,-1.66,TEMP-ElectResis,,,6-5 -US-xBR,TS_1_9_1,,-1.96,TEMP-ElectResis,,,6-5 -US-xBR,TS_2_1_1,,-0.03,TEMP-ElectResis,,,6-5 -US-xBR,TS_2_2_1,,-0.07,TEMP-ElectResis,,,6-5 -US-xBR,TS_2_3_1,,-0.17,TEMP-ElectResis,,,6-5 -US-xBR,TS_2_4_1,,-0.27,TEMP-ElectResis,,,6-5 -US-xBR,TS_2_5_1,,-0.57,TEMP-ElectResis,,,6-5 -US-xBR,TS_2_6_1,,-0.97,TEMP-ElectResis,,,6-5 -US-xBR,TS_2_7_1,,-1.17,TEMP-ElectResis,,,6-5 -US-xBR,TS_2_8_1,,-1.67,TEMP-ElectResis,,,6-5 -US-xBR,TS_2_9_1,,-1.97,TEMP-ElectResis,,,6-5 -US-xBR,TS_3_1_1,2016,-0.02,TEMP-ElectResis,,,6-5 -US-xBR,TS_3_2_1,,-0.06,TEMP-ElectResis,,,6-5 -US-xBR,TS_3_3_1,,-0.16,TEMP-ElectResis,,,6-5 -US-xBR,TS_3_4_1,,-0.26,TEMP-ElectResis,,,6-5 -US-xBR,TS_3_5_1,,-0.56,TEMP-ElectResis,,,6-5 -US-xBR,TS_3_6_1,,-0.96,TEMP-ElectResis,,,6-5 -US-xBR,TS_3_7_1,,-1.16,TEMP-ElectResis,,,6-5 -US-xBR,TS_3_8_1,,-1.66,TEMP-ElectResis,,,6-5 -US-xBR,TS_3_9_1,,-1.96,TEMP-ElectResis,,,6-5 -US-xBR,TS_4_1_1,,-0.02,TEMP-ElectResis,,,6-5 -US-xBR,TS_4_2_1,,-0.06,TEMP-ElectResis,,,6-5 -US-xBR,TS_4_3_1,,-0.16,TEMP-ElectResis,,,6-5 -US-xBR,TS_4_4_1,,-0.26,TEMP-ElectResis,,,6-5 -US-xBR,TS_4_5_1,,-0.56,TEMP-ElectResis,,,6-5 -US-xBR,TS_4_6_1,,-0.96,TEMP-ElectResis,,,6-5 -US-xBR,TS_4_7_1,,-1.16,TEMP-ElectResis,,,6-5 -US-xBR,TS_4_8_1,,-1.66,TEMP-ElectResis,,,6-5 -US-xBR,TS_4_9_1,,-1.96,TEMP-ElectResis,,,6-5 -US-xBR,TS_5_1_1,,-0.03,TEMP-ElectResis,,,6-5 -US-xBR,TS_5_2_1,,-0.07,TEMP-ElectResis,,,6-5 -US-xBR,TS_5_3_1,,-0.17,TEMP-ElectResis,,,6-5 -US-xBR,TS_5_4_1,,-0.27,TEMP-ElectResis,,,6-5 -US-xBR,TS_5_5_1,,-0.57,TEMP-ElectResis,,,6-5 -US-xBR,TS_5_6_1,,-0.97,TEMP-ElectResis,,,6-5 -US-xBR,TS_5_7_1,,-1.17,TEMP-ElectResis,,,6-5 -US-xBR,TS_5_8_1,,-1.67,TEMP-ElectResis,,,6-5 -US-xBR,TS_5_9_1,,-1.97,TEMP-ElectResis,,,6-5 -US-xBR,T_SONIC,,35.68,SA-Campbell CSAT-3,,,6-5 -US-xBR,T_SONIC_SIGMA,,35.68,SA-Campbell CSAT-3,,,6-5 -US-xBR,USTAR,,35.68,SA-Campbell CSAT-3,,,6-5 -US-xBR,VPD_PI,,35.19,RH-Capac,,,6-5 -US-xBR,V_SIGMA,,35.68,SA-Campbell CSAT-3,,,6-5 -US-xBR,WD_1_1_1,,35.68,SA-Campbell CSAT-3,,,6-5 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--git a/ecflux/fluxtower/FFP_Python/__init__.py b/ecflux/fluxtower/FFP_Python/__init__.py deleted file mode 100644 index e69de29..0000000 diff --git a/ecflux/fluxtower/FFP_Python/calc_footprint_FFP.py b/ecflux/fluxtower/FFP_Python/calc_footprint_FFP.py deleted file mode 100755 index bdea282..0000000 --- a/ecflux/fluxtower/FFP_Python/calc_footprint_FFP.py +++ /dev/null @@ -1,514 +0,0 @@ -from __future__ import print_function -def FFP(zm=None, z0=None, umean=None, h=None, ol=None, sigmav=None, ustar=None, - wind_dir=None, rs=[0.1, 0.2, 0.3, 0.4, 0.5, 0.6, 0.7, 0.8], rslayer=0, - nx=1000, crop=False, fig=False, **kwargs): - """ - Derive a flux footprint estimate based on the simple parameterisation FFP - See Kljun, N., P. Calanca, M.W. Rotach, H.P. Schmid, 2015: - The simple two-dimensional parameterisation for Flux Footprint Predictions FFP. - Geosci. Model Dev. 8, 3695-3713, doi:10.5194/gmd-8-3695-2015, for details. - contact: n.kljun@swansea.ac.uk - - FFP Input - zm = Measurement height above displacement height (i.e. z-d) [m] - z0 = Roughness length [m]; enter None if not known - umean = Mean wind speed at zm [m/s]; enter None if not known - Either z0 or umean is required. If both are given, - z0 is selected to calculate the footprint - h = Boundary layer height [m] - ol = Obukhov length [m] - sigmav = standard deviation of lateral velocity fluctuations [ms-1] - ustar = friction velocity [ms-1] - - optional inputs: - wind_dir = wind direction in degrees (of 360) for rotation of the footprint - rs = Percentage of source area for which to provide contours, must be between 10% and 90%. - Can be either a single value (e.g., "80") or a list of values (e.g., "[10, 20, 30]") - Expressed either in percentages ("80") or as fractions of 1 ("0.8"). - Default is [10:10:80]. Set to "None" for no output of percentages - nx = Integer scalar defining the number of grid elements of the scaled footprint. - Large nx results in higher spatial resolution and higher computing time. - Default is 1000, nx must be >=600. - rslayer = Calculate footprint even if zm within roughness sublayer: set rslayer = 1 - Note that this only gives a rough estimate of the footprint as the model is not - valid within the roughness sublayer. Default is 0 (i.e. no footprint for within RS). - z0 is needed for estimation of the RS. - crop = Crop output area to size of the 80% footprint or the largest r given if crop=1 - fig = Plot an example figure of the resulting footprint (on the screen): set fig = 1. - Default is 0 (i.e. no figure). - - FFP output - x_ci_max = x location of footprint peak (distance from measurement) [m] - x_ci = x array of crosswind integrated footprint [m] - f_ci = array with footprint function values of crosswind integrated footprint [m-1] - x_2d = x-grid of 2-dimensional footprint [m], rotated if wind_dir is provided - y_2d = y-grid of 2-dimensional footprint [m], rotated if wind_dir is provided - f_2d = footprint function values of 2-dimensional footprint [m-2] - rs = percentage of footprint as in input, if provided - fr = footprint value at r, if r is provided - xr = x-array for contour line of r, if r is provided - yr = y-array for contour line of r, if r is provided - flag_err = 0 if no error, 1 in case of error - - created: 15 April 2015 natascha kljun - translated to python, December 2015 Gerardo Fratini, LI-COR Biosciences Inc. - version: 1.4 - last change: 11/12/2019 Gerardo Fratini, ported to Python 3.x - Copyright (C) 2015,2016,2017,2018,2019,2020 Natascha Kljun - """ - - import numpy as np - import numbers - - #=========================================================================== - # Get kwargs - show_heatmap = kwargs.get('show_heatmap', True) - - #=========================================================================== - ## Input check - flag_err = 0 - - ## Check existence of required input pars - # if None in [zm, h, ol, sigmav, ustar] or (z0 is None and umean is None): - if any(var is None for var in (zm, h, ol, sigmav, ustar)) or (z0 is None and umean is None): - raise_ffp_exception(1) - - # Define rslayer if not passed - if rslayer == None: rslayer == 0 - - # Define crop if not passed - if crop == None: crop == 0 - - # Define fig if not passed - if fig == None: fig == 0 - - # Check passed values - if zm <= 0.: raise_ffp_exception(2) - if z0 is not None and umean is None and z0 <= 0.: raise_ffp_exception(3) - if h <= 10.: raise_ffp_exception(4) - if zm > h: raise_ffp_exception(5) - if z0 is not None and umean is None and zm <= 12.5*z0: - if rslayer is 1: raise_ffp_exception(6) - else: raise_ffp_exception(12) - if float(zm)/ol <= -15.5: raise_ffp_exception(7) - if sigmav <= 0: raise_ffp_exception(8) - if ustar <= 0.1: raise_ffp_exception(9) - if wind_dir is not None: - if wind_dir> 360 or wind_dir < 0: raise_ffp_exception(10) - if nx < 600: raise_ffp_exception(11) - - # Resolve ambiguity if both z0 and umean are passed (defaults to using z0) - if None not in [z0, umean]: raise_ffp_exception(13) - - #=========================================================================== - # Handle rs - if rs is not None: - - # Check that rs is a list, otherwise make it a list - if isinstance(rs, numbers.Number): - if 0.9 < rs <= 1 or 90 < rs <= 100: rs = 0.9 - rs = [rs] - if not isinstance(rs, list): raise_ffp_exception(14) - - # If rs is passed as percentages, normalize to fractions of one - if np.max(rs) >= 1: rs = [x/100. for x in rs] - - # Eliminate any values beyond 0.9 (90%) and inform user - if np.max(rs) > 0.9: - raise_ffp_exception(15) - rs = [item for item in rs if item <= 0.9] - - # Sort levels in ascending order - rs = list(np.sort(rs)) - - - #=========================================================================== - # Model parameters - a = 1.4524 - b = -1.9914 - c = 1.4622 - d = 0.1359 - ac = 2.17 - bc = 1.66 - cc = 20.0 - - xstar_end = 30 - oln = 5000 #limit to L for neutral scaling - k = 0.4 #von Karman - - #=========================================================================== - # Scaled X* for crosswind integrated footprint - xstar_ci_param = np.linspace(d, xstar_end, nx+2) - xstar_ci_param = xstar_ci_param[1:] - - # Crosswind integrated scaled F* - fstar_ci_param = a * (xstar_ci_param-d)**b * np.exp(-c/ (xstar_ci_param-d)) - ind_notnan = ~np.isnan(fstar_ci_param) - fstar_ci_param = fstar_ci_param[ind_notnan] - xstar_ci_param = xstar_ci_param[ind_notnan] - - # Scaled sig_y* - sigystar_param = ac * np.sqrt(bc * xstar_ci_param**2 / (1 + cc * xstar_ci_param)) - - #=========================================================================== - # Real scale x and f_ci - if z0 is not None: - # Use z0 - if ol <= 0 or ol >= oln: - xx = (1 - 19.0 * zm/ol)**0.25 - psi_f = np.log((1 + xx**2) / 2.) + 2. * np.log((1 + xx) / 2.) - 2. * np.arctan(xx) + np.pi/2 - elif ol > 0 and ol < oln: - psi_f = -5.3 * zm / ol - - x = xstar_ci_param * zm / (1. - (zm / h)) * (np.log(zm / z0) - psi_f) - if np.log(zm / z0) - psi_f > 0: - x_ci = x - f_ci = fstar_ci_param / zm * (1. - (zm / h)) / (np.log(zm / z0) - psi_f) - else: - x_ci_max, x_ci, f_ci, x_2d, y_2d, f_2d = None - flag_err = 1 - else: - # Use umean if z0 not available - x = xstar_ci_param * zm / (1. - zm / h) * (umean / ustar * k) - if umean / ustar > 0: - x_ci = x - f_ci = fstar_ci_param / zm * (1. - zm / h) / (umean / ustar * k) - else: - x_ci_max, x_ci, f_ci, x_2d, y_2d, f_2d = None - flag_err = 1 - - #Maximum location of influence (peak location) - xstarmax = -c / b + d - if z0 is not None: - x_ci_max = xstarmax * zm / (1. - (zm / h)) * (np.log(zm / z0) - psi_f) - else: - x_ci_max = xstarmax * zm / (1. - (zm / h)) * (umean / ustar * k) - - #Real scale sig_y - if abs(ol) > oln: - ol = -1E6 - if ol <= 0: #convective - scale_const = 1E-5 * abs(zm / ol)**(-1) + 0.80 - elif ol > 0: #stable - scale_const = 1E-5 * abs(zm / ol)**(-1) + 0.55 - if scale_const > 1: - scale_const = 1.0 - sigy = sigystar_param / scale_const * zm * sigmav / ustar - sigy[sigy < 0] = np.nan - - #Real scale f(x,y) - dx = x_ci[2] - x_ci[1] - y_pos = np.arange(0, (len(x_ci) / 2.) * dx * 1.5, dx) - #f_pos = np.full((len(f_ci), len(y_pos)), np.nan) - f_pos = np.empty((len(f_ci), len(y_pos))) - f_pos[:] = np.nan - for ix in range(len(f_ci)): - f_pos[ix,:] = f_ci[ix] * 1 / (np.sqrt(2 * np.pi) * sigy[ix]) * np.exp(-y_pos**2 / ( 2 * sigy[ix]**2)) - - #Complete footprint for negative y (symmetrical) - y_neg = - np.fliplr(y_pos[None, :])[0] - f_neg = np.fliplr(f_pos) - y = np.concatenate((y_neg[0:-1], y_pos)) - f = np.concatenate((f_neg[:, :-1].T, f_pos.T)).T - - #Matrices for output - x_2d = np.tile(x[:,None], (1,len(y))) - y_2d = np.tile(y.T,(len(x),1)) - f_2d = f - - - #=========================================================================== - # Derive footprint ellipsoid incorporating R% of the flux, if requested, - # starting at peak value. - dy = dx - if rs is not None: - clevs = get_contour_levels(f_2d, dx, dy, rs) - frs = [item[2] for item in clevs] - xrs = [] - yrs = [] - for ix, fr in enumerate(frs): - xr,yr = get_contour_vertices(x_2d, y_2d, f_2d, fr) - if xr is None: - frs[ix] = None - xrs.append(xr) - yrs.append(yr) - else: - if crop: - rs_dummy = 0.8 #crop to 80% - clevs = get_contour_levels(f_2d, dx, dy, rs_dummy) - xrs = [] - yrs = [] - xrs,yrs = get_contour_vertices(x_2d, y_2d, f_2d, clevs[0][2]) - - #=========================================================================== - # Crop domain and footprint to the largest rs value - if crop: - xrs_crop = [x for x in xrs if x is not None] - yrs_crop = [x for x in yrs if x is not None] - if rs is not None: - dminx = np.floor(min(xrs_crop[-1])) - dmaxx = np.ceil(max(xrs_crop[-1])) - dminy = np.floor(min(yrs_crop[-1])) - dmaxy = np.ceil(max(yrs_crop[-1])) - else: - dminx = np.floor(min(xrs_crop)) - dmaxx = np.ceil(max(xrs_crop)) - dminy = np.floor(min(yrs_crop)) - dmaxy = np.ceil(max(yrs_crop)) - jrange = np.where((y_2d[0] >= dminy) & (y_2d[0] <= dmaxy))[0] - jrange = np.concatenate(([jrange[0]-1], jrange, [jrange[-1]+1])) - jrange = jrange[np.where((jrange>=0) & (jrange<=y_2d.shape[0]-1))[0]] - irange = np.where((x_2d[:,0] >= dminx) & (x_2d[:,0] <= dmaxx))[0] - irange = np.concatenate(([irange[0]-1], irange, [irange[-1]+1])) - irange = irange[np.where((irange>=0) & (irange<=x_2d.shape[1]-1))[0]] - jrange = [[it] for it in jrange] - x_2d = x_2d[irange,jrange] - y_2d = y_2d[irange,jrange] - f_2d = f_2d[irange,jrange] - - #=========================================================================== - #Rotate 3d footprint if requested - if wind_dir is not None: - wind_dir = wind_dir * np.pi / 180. - dist = np.sqrt(x_2d**2 + y_2d**2) - angle = np.arctan2(y_2d, x_2d) - x_2d = dist * np.sin(wind_dir - angle) - y_2d = dist * np.cos(wind_dir - angle) - - if rs is not None: - for ix, r in enumerate(rs): - # xr_lev = np.array([x for x in xrs[ix] if x is not None]) - # yr_lev = np.array([x for x in yrs[ix] if x is not None]) - # dist = np.sqrt(xr_lev**2 + yr_lev**2) - # angle = np.arctan2(yr_lev,xr_lev) - # xr = dist * np.sin(wind_dir - angle) - # yr = dist * np.cos(wind_dir - angle) - # xrs[ix] = list(xr) - # yrs[ix] = list(yr) - if xrs[ix]: - xr_lev = np.array([x for x in xrs[ix] if x is not None]) - yr_lev = np.array([x for x in yrs[ix] if x is not None]) - dist = np.sqrt(xr_lev**2 + yr_lev**2) - angle = np.arctan2(yr_lev,xr_lev) - xr = dist * np.sin(wind_dir - angle) - yr = dist * np.cos(wind_dir - angle) - xrs[ix] = list(xr) - yrs[ix] = list(yr) - - #=========================================================================== - # Plot footprint - if fig: - fig_out,ax = plot_footprint(x_2d=x_2d, y_2d=y_2d, fs=f_2d, - show_heatmap=show_heatmap,clevs=frs) - - #=========================================================================== - # Fill output structure - if rs is not None: - return {'x_ci_max': x_ci_max, 'x_ci': x_ci, 'f_ci': f_ci, - 'x_2d': x_2d, 'y_2d': y_2d, 'f_2d': f_2d, - 'rs': rs, 'fr': frs, 'xr': xrs, 'yr': yrs, 'flag_err':flag_err} - else: - return {'x_ci_max': x_ci_max, 'x_ci': x_ci, 'f_ci': f_ci, - 'x_2d': x_2d, 'y_2d': y_2d, 'f_2d': f_2d, 'flag_err':flag_err} - -#=============================================================================== -#=============================================================================== -def get_contour_levels(f, dx, dy, rs=None): - '''Contour levels of f at percentages of f-integral given by rs''' - - import numpy as np - from numpy import ma - import sys - - #Check input and resolve to default levels in needed - if not isinstance(rs, (int, float, list)): - rs = list(np.linspace(0.10, 0.90, 9)) - if isinstance(rs, (int, float)): rs = [rs] - - #Levels - pclevs = np.empty(len(rs)) - pclevs[:] = np.nan - ars = np.empty(len(rs)) - ars[:] = np.nan - - sf = np.sort(f, axis=None)[::-1] - msf = ma.masked_array(sf, mask=(np.isnan(sf) | np.isinf(sf))) #Masked array for handling potential nan - - csf = msf.cumsum().filled(np.nan)*dx*dy - for ix, r in enumerate(rs): - dcsf = np.abs(csf - r) - pclevs[ix] = sf[np.nanargmin(dcsf)] - ars[ix] = csf[np.nanargmin(dcsf)] - - return [(round(r, 3), ar, pclev) for r, ar, pclev in zip(rs, ars, pclevs)] - -#=============================================================================== -def get_contour_vertices(x, y, f, lev): - import matplotlib.pyplot as plt - - cs = plt.contour(x,y, f, [lev]) - plt.close() - segs = cs.allsegs[0][0] - xr = [vert[0] for vert in segs] - yr = [vert[1] for vert in segs] - #Set contour to None if it's found to reach the physical domain - if x.min() >= min(segs[:, 0]) or max(segs[:, 0]) >= x.max() or \ - y.min() >= min(segs[:, 1]) or max(segs[:, 1]) >= y.max(): - return [None, None] - - return [xr, yr] # x,y coords of contour points. - -#=============================================================================== -def plot_footprint(x_2d, y_2d, fs, clevs=None, show_heatmap=True, normalize=None, - colormap=None, line_width=0.5, iso_labels=None): - '''Plot footprint function and contours if request''' - - import numpy as np - import matplotlib.pyplot as plt - import matplotlib.cm as cm - from matplotlib.colors import LogNorm - - # If input is a list of footprints, don't show footprint but only contours, - # with different colors - if isinstance(fs, list): - show_heatmap = False - else: - fs = [fs] - - if colormap is None: colormap = cm.jet - # Define colors for each contour set - cs = [colormap(ix) for ix in np.linspace(0, 1, len(fs))] - - # Initialize figure - fig, ax = plt.subplots(figsize=(12, 10)) - # fig.patch.set_facecolor('none') - # ax.patch.set_facecolor('none') - - if clevs is not None: - # Temporary patch for pyplot.contour requiring contours to be in ascending orders - clevs = clevs[::-1] - - # Eliminate contour levels that were set to None - # (e.g. because they extend beyond the defined domain) - clevs = [clev for clev in clevs if clev is not None] - - # Plot contour levels of all passed footprints - # Plot isopleth - levs = [clev for clev in clevs] - for f, c in zip(fs, cs): - cc = [c]*len(levs) - if show_heatmap: - cp = ax.contour(x_2d, y_2d, f, levs, colors = 'w', linewidths=line_width) - else: - cp = ax.contour(x_2d, y_2d, f, levs, colors = cc, linewidths=line_width) - # Isopleth Labels - if iso_labels is not None: - pers = [str(int(clev[0]*100))+'%' for clev in clevs] - fmt = {} - for l,s in zip(cp.levels, pers): - fmt[l] = s - plt.clabel(cp, cp.levels[:], inline=1, fmt=fmt, fontsize=7) - - # plot footprint heatmap if requested and if only one footprint is passed - if show_heatmap: - if normalize == 'log': - norm = LogNorm() - else: - norm = None - - for f in fs: - pcol = plt.pcolormesh(x_2d, y_2d, f, cmap=colormap, norm=norm) - plt.xlabel('x [m]') - plt.ylabel('y [m]') - plt.gca().set_aspect('equal', 'box') - - cbar = fig.colorbar(pcol, shrink=1.0, format='%.3e') - #cbar.set_label('Flux contribution', color = 'k') - plt.show() - - return fig, ax - - -#=============================================================================== -#=============================================================================== -exTypes = {'message': 'Message', - 'alert': 'Alert', - 'error': 'Error', - 'fatal': 'Fatal error'} - -exceptions = [ - {'code': 1, - 'type': exTypes['fatal'], - 'msg': 'At least one required parameter is missing. Please enter all ' - 'required inputs. Check documentation for details.'}, - {'code': 2, - 'type': exTypes['error'], - 'msg': 'zm (measurement height) must be larger than zero.'}, - {'code': 3, - 'type': exTypes['error'], - 'msg': 'z0 (roughness length) must be larger than zero.'}, - {'code': 4, - 'type': exTypes['error'], - 'msg': 'h (BPL height) must be larger than 10 m.'}, - {'code': 5, - 'type': exTypes['error'], - 'msg': 'zm (measurement height) must be smaller than h (PBL height).'}, - {'code': 6, - 'type': exTypes['alert'], - 'msg': 'zm (measurement height) should be above roughness sub-layer (12.5*z0).'}, - {'code': 7, - 'type': exTypes['error'], - 'msg': 'zm/ol (measurement height to Obukhov length ratio) must be equal or larger than -15.5.'}, - {'code': 8, - 'type': exTypes['error'], - 'msg': 'sigmav (standard deviation of crosswind) must be larger than zero.'}, - {'code': 9, - 'type': exTypes['error'], - 'msg': 'ustar (friction velocity) must be >=0.1.'}, - {'code': 10, - 'type': exTypes['error'], - 'msg': 'wind_dir (wind direction) must be >=0 and <=360.'}, - {'code': 11, - 'type': exTypes['fatal'], - 'msg': 'Passed data arrays (ustar, zm, h, ol) don\'t all have the same length.'}, - {'code': 12, - 'type': exTypes['fatal'], - 'msg': 'No valid zm (measurement height above displacement height) passed.'}, - {'code': 13, - 'type': exTypes['alert'], - 'msg': 'Using z0, ignoring umean if passed.'}, - {'code': 14, - 'type': exTypes['alert'], - 'msg': 'No valid z0 passed, using umean.'}, - {'code': 15, - 'type': exTypes['fatal'], - 'msg': 'No valid z0 or umean array passed.'}, - {'code': 16, - 'type': exTypes['error'], - 'msg': 'At least one required input is invalid. Skipping current footprint.'}, - {'code': 17, - 'type': exTypes['alert'], - 'msg': 'Only one value of zm passed. Using it for all footprints.'}, - {'code': 18, - 'type': exTypes['fatal'], - 'msg': 'if provided, rs must be in the form of a number or a list of numbers.'}, - {'code': 19, - 'type': exTypes['alert'], - 'msg': 'rs value(s) larger than 90% were found and eliminated.'}, - {'code': 20, - 'type': exTypes['error'], - 'msg': 'zm (measurement height) must be above roughness sub-layer (12.5*z0).'}, - ] - -def raise_ffp_exception(code): - '''Raise exception or prints message according to specified code''' - - ex = [it for it in exceptions if it['code'] == code][0] - string = ex['type'] + '(' + str(ex['code']).zfill(4) + '):\n '+ ex['msg'] - - print('') - if ex['type'] == exTypes['fatal']: - string = string + '\n FFP_fixed_domain execution aborted.' - raise Exception(string) - else: - print(string) diff --git a/ecflux/fluxtower/FFP_Python/calc_footprint_FFP_climatology.py b/ecflux/fluxtower/FFP_Python/calc_footprint_FFP_climatology.py deleted file mode 100755 index d515863..0000000 --- a/ecflux/fluxtower/FFP_Python/calc_footprint_FFP_climatology.py +++ /dev/null @@ -1,734 +0,0 @@ -from __future__ import print_function -def FFP_climatology(zm=None, z0=None, umean=None, h=None, ol=None, sigmav=None, ustar=None, - wind_dir=None, domain=None, dx=None, dy=None, nx=None, ny=None, - rs=[0.1, 0.2, 0.3, 0.4, 0.5, 0.6, 0.7, 0.8], rslayer=0, - smooth_data=1, crop=False, pulse=None, verbosity=2, fig=False, **kwargs): - """ - Derive a flux footprint estimate based on the simple parameterisation FFP - See Kljun, N., P. Calanca, M.W. Rotach, H.P. Schmid, 2015: - The simple two-dimensional parameterisation for Flux Footprint Predictions FFP. - Geosci. Model Dev. 8, 3695-3713, doi:10.5194/gmd-8-3695-2015, for details. - contact: n.kljun@swansea.ac.uk - - This function calculates footprints within a fixed physical domain for a series of - time steps, rotates footprints into the corresponding wind direction and aggregates - all footprints to a footprint climatology. The percentage of source area is - calculated for the footprint climatology. - For determining the optimal extent of the domain (large enough to include footprints) - use calc_footprint_FFP.py. - - FFP Input - All vectors need to be of equal length (one value for each time step) - zm = Measurement height above displacement height (i.e. z-d) [m] - usually a scalar, but can also be a vector - z0 = Roughness length [m] - enter [None] if not known - usually a scalar, but can also be a vector - umean = Vector of mean wind speed at zm [ms-1] - enter [None] if not known - Either z0 or umean is required. If both are given, - z0 is selected to calculate the footprint - h = Vector of boundary layer height [m] - ol = Vector of Obukhov length [m] - sigmav = Vector of standard deviation of lateral velocity fluctuations [ms-1] - ustar = Vector of friction velocity [ms-1] - wind_dir = Vector of wind direction in degrees (of 360) for rotation of the footprint - - Optional input: - domain = Domain size as an array of [xmin xmax ymin ymax] [m]. - Footprint will be calculated for a measurement at [0 0 zm] m - Default is smallest area including the r% footprint or [-1000 1000 -1000 1000]m, - whichever smallest (80% footprint if r not given). - dx, dy = Cell size of domain [m] - Small dx, dy results in higher spatial resolution and higher computing time - Default is dx = dy = 2 m. If only dx is given, dx=dy. - nx, ny = Two integer scalars defining the number of grid elements in x and y - Large nx/ny result in higher spatial resolution and higher computing time - Default is nx = ny = 1000. If only nx is given, nx=ny. - If both dx/dy and nx/ny are given, dx/dy is given priority if the domain is also specified. - rs = Percentage of source area for which to provide contours, must be between 10% and 90%. - Can be either a single value (e.g., "80") or a list of values (e.g., "[10, 20, 30]") - Expressed either in percentages ("80") or as fractions of 1 ("0.8"). - Default is [10:10:80]. Set to "None" for no output of percentages - rslayer = Calculate footprint even if zm within roughness sublayer: set rslayer = 1 - Note that this only gives a rough estimate of the footprint as the model is not - valid within the roughness sublayer. Default is 0 (i.e. no footprint for within RS). - z0 is needed for estimation of the RS. - smooth_data = Apply convolution filter to smooth footprint climatology if smooth_data=1 (default) - crop = Crop output area to size of the 80% footprint or the largest r given if crop=1 - pulse = Display progress of footprint calculations every pulse-th footprint (e.g., "100") - verbosity = Level of verbosity at run time: 0 = completely silent, 1 = notify only of fatal errors, - 2 = all notifications - fig = Plot an example figure of the resulting footprint (on the screen): set fig = 1. - Default is 0 (i.e. no figure). - - FFP output - FFP = Structure array with footprint climatology data for measurement at [0 0 zm] m - x_2d = x-grid of 2-dimensional footprint [m] - y_2d = y-grid of 2-dimensional footprint [m] - fclim_2d = Normalised footprint function values of footprint climatology [m-2] - rs = Percentage of footprint as in input, if provided - fr = Footprint value at r, if r is provided - xr = x-array for contour line of r, if r is provided - yr = y-array for contour line of r, if r is provided - n = Number of footprints calculated and included in footprint climatology - flag_err = 0 if no error, 1 in case of error, 2 if not all contour plots (rs%) within specified domain, - 3 if single data points had to be removed (outside validity) - - Created: 19 May 2016 natascha kljun - Converted from matlab to python, together with Gerardo Fratini, LI-COR Biosciences Inc. - version: 1.4 - last change: 11/12/2019 Gerardo Fratini, ported to Python 3.x - Copyright (C) 2015,2016,2017,2018,2019,2020 Natascha Kljun - """ - - import numpy as np - import sys - import numbers - import matplotlib - from scipy import signal as sg - - - #=========================================================================== - # Get kwargs - show_heatmap = kwargs.get('show_heatmap', True) - - - #=========================================================================== - # Input check - flag_err = 0 - - # Check existence of required input pars - if any(var is None for var in (zm, h, ol, sigmav, ustar)) or (z0 is None and umean is None): - raise_ffp_exception(1, verbosity) - - # Convert all input items to lists - # if not isinstance(zm, list): zm = [zm] - # if not isinstance(h, list): h = [h] - # if not isinstance(ol, list): ol = [ol] - # if not isinstance(sigmav, list): sigmav = [sigmav] - # if not isinstance(ustar, list): ustar = [ustar] - # if not isinstance(wind_dir, list): wind_dir = [wind_dir] - # if not isinstance(z0, list): z0 = [z0] - # if not isinstance(umean, list): umean = [umean] - def is_iter(var): - try: - iter(var) - return True - except: - return False - - if not is_iter(zm): zm = [zm] - if not is_iter(h): h = [h] - if not is_iter(ol): ol = [ol] - if not is_iter(sigmav): sigmav = [sigmav] - if not is_iter(ustar): ustar = [ustar] - if not is_iter(wind_dir): wind_dir = [wind_dir] - if not is_iter(z0): z0 = [z0] - if not is_iter(umean): umean = [umean] - - - # Check that all lists have same length, if not raise an error and exit - ts_len = len(ustar) - if any(len(var) != ts_len for var in [sigmav, wind_dir, h, ol]): - # at least one list has a different length, exit with error message - raise_ffp_exception(11, verbosity) - - # Special treatment for zm, which is allowed to have length 1 for any - # length >= 1 of all other parameters - if all(val is None for val in zm): raise_ffp_exception(12, verbosity) - if len(zm) == 1: - raise_ffp_exception(17, verbosity) - zm = [zm[0] for i in range(ts_len)] - - # Resolve ambiguity if both z0 and umean are passed (defaults to using z0) - # If at least one value of z0 is passed, use z0 (by setting umean to None) - if not all(val is None for val in z0): - raise_ffp_exception(13, verbosity) - umean = [None for i in range(ts_len)] - # If only one value of z0 was passed, use that value for all footprints - if len(z0) == 1: z0 = [z0[0] for i in range(ts_len)] - elif len(umean) == ts_len and not all(val is None for val in umean): - raise_ffp_exception(14, verbosity) - z0 = [None for i in range(ts_len)] - else: - raise_ffp_exception(15, verbosity) - - # Rename lists as now the function expects time series of inputs - ustars, sigmavs, hs, ols, wind_dirs, zms, z0s, umeans = \ - ustar, sigmav, h, ol, wind_dir, zm, z0, umean - - #=========================================================================== - # Handle rs - if rs is not None: - - # Check that rs is a list, otherwise make it a list - if isinstance(rs, numbers.Number): - if 0.9 < rs <= 1 or 90 < rs <= 100: rs = 0.9 - rs = [rs] - if not isinstance(rs, list): raise_ffp_exception(18, verbosity) - - # If rs is passed as percentages, normalize to fractions of one - if np.max(rs) >= 1: rs = [x/100. for x in rs] - - # Eliminate any values beyond 0.9 (90%) and inform user - if np.max(rs) > 0.9: - raise_ffp_exception(19, verbosity) - rs = [item for item in rs if item <= 0.9] - - # Sort levels in ascending order - rs = list(np.sort(rs)) - - #=========================================================================== - # Define computational domain - # Check passed values and make some smart assumptions - if isinstance(dx, numbers.Number) and dy is None: dy = dx - if isinstance(dy, numbers.Number) and dx is None: dx = dy - if not all(isinstance(item, numbers.Number) for item in [dx, dy]): dx = dy = None - if isinstance(nx, int) and ny is None: ny = nx - if isinstance(ny, int) and nx is None: nx = ny - if not all(isinstance(item, int) for item in [nx, ny]): nx = ny = None - if not isinstance(domain, list) or len(domain) != 4: domain = None - - if all(item is None for item in [dx, nx, domain]): - # If nothing is passed, default domain is a square of 2 Km size centered - # at the tower with pizel size of 2 meters (hence a 1000x1000 grid) - domain = [-1000., 1000., -1000., 1000.] - dx = dy = 2. - nx = ny = 1000 - elif domain is not None: - # If domain is passed, it takes the precendence over anything else - if dx is not None: - # If dx/dy is passed, takes precendence over nx/ny - nx = int((domain[1]-domain[0]) / dx) - ny = int((domain[3]-domain[2]) / dy) - else: - # If dx/dy is not passed, use nx/ny (set to 1000 if not passed) - if nx is None: nx = ny = 1000 - # If dx/dy is not passed, use nx/ny - dx = (domain[1]-domain[0]) / float(nx) - dy = (domain[3]-domain[2]) / float(ny) - elif dx is not None and nx is not None: - # If domain is not passed but dx/dy and nx/ny are, define domain - domain = [-nx*dx/2, nx*dx/2, -ny*dy/2, ny*dy/2] - elif dx is not None: - # If domain is not passed but dx/dy is, define domain and nx/ny - domain = [-1000, 1000, -1000, 1000] - nx = int((domain[1]-domain[0]) / dx) - ny = int((domain[3]-domain[2]) / dy) - elif nx is not None: - # If domain and dx/dy are not passed but nx/ny is, define domain and dx/dy - domain = [-1000, 1000, -1000, 1000] - dx = (domain[1]-domain[0]) / float(nx) - dy = (domain[3]-domain[2]) / float(nx) - - # Put domain into more convenient vars - xmin, xmax, ymin, ymax = domain - - # Define rslayer if not passed - if rslayer == None: rslayer == 0 - - # Define smooth_data if not passed - if smooth_data == None: smooth_data == 1 - - # Define crop if not passed - if crop == None: crop == 0 - - # Define pulse if not passed - if pulse == None: - if ts_len <= 20: - pulse = 1 - else: - pulse = int(ts_len / 20) - - # Define fig if not passed - if fig == None: fig == 0 - - #=========================================================================== - # Model parameters - a = 1.4524 - b = -1.9914 - c = 1.4622 - d = 0.1359 - ac = 2.17 - bc = 1.66 - cc = 20.0 - - oln = 5000 #limit to L for neutral scaling - k = 0.4 #von Karman - - #=========================================================================== - # Define physical domain in cartesian and polar coordinates - # Cartesian coordinates - x = np.linspace(xmin, xmax, nx + 1) - y = np.linspace(ymin, ymax, ny + 1) - x_2d, y_2d = np.meshgrid(x, y) - - # Polar coordinates - # Set theta such that North is pointing upwards and angles increase clockwise - rho = np.sqrt(x_2d**2 + y_2d**2) - theta = np.arctan2(x_2d, y_2d) - - # initialize raster for footprint climatology - fclim_2d = np.zeros(x_2d.shape) - - #=========================================================================== - # Loop on time series - - # Initialize logic array valids to those 'timestamps' for which all inputs are - # at least present (but not necessarily phisically plausible) - valids = [True if not any([val is None for val in vals]) else False \ - for vals in zip(ustars, sigmavs, hs, ols, wind_dirs, zms)] - - if verbosity > 1: print ('') - for ix, (ustar, sigmav, h, ol, wind_dir, zm, z0, umean) \ - in enumerate(zip(ustars, sigmavs, hs, ols, wind_dirs, zms, z0s, umeans)): - - # Counter - if verbosity > 1 and ix % pulse == 0: - print ('Calculating footprint ', ix+1, ' of ', ts_len) - - valids[ix] = check_ffp_inputs(ustar, sigmav, h, ol, wind_dir, zm, z0, umean, rslayer, verbosity) - - # If inputs are not valid, skip current footprint - if not valids[ix]: - raise_ffp_exception(16, verbosity) - else: - #=========================================================================== - # Rotate coordinates into wind direction - if wind_dir is not None: - rotated_theta = theta - wind_dir * np.pi / 180. - - #=========================================================================== - # Create real scale crosswind integrated footprint and dummy for - # rotated scaled footprint - fstar_ci_dummy = np.zeros(x_2d.shape) - f_ci_dummy = np.zeros(x_2d.shape) - xstar_ci_dummy = np.zeros(x_2d.shape) - px = np.ones(x_2d.shape) - if z0 is not None: - # Use z0 - if ol <= 0 or ol >= oln: - # if any(ol <= 0) or any(ol >= oln): - xx = (1 - 19.0 * zm/ol)**0.25 - psi_f = (np.log((1 + xx**2) / 2.) + 2. * np.log((1 + xx) / 2.) - 2. * np.arctan(xx) + np.pi/2) - elif ol > 0 and ol < oln: - # elif any(ol > 0) and any(ol < oln): - psi_f = -5.3 * zm / ol - - # # EDITED TO WORK FOR ARRAYS - # def calc_psi_stable(ol): - # psi_f = -5.3 * zm / ol - # return psi_f - - # def calc_psi_neut_unstable(ol): - # xx = (1 - 19.0 * zm/ol)**0.25 - # psi_f = (np.log((1 + xx**2) / 2.) + 2. * np.log((1 + xx) / 2.) - 2. * np.arctan(xx) + np.pi/2) - # return psi_f - - # psi_f = np.where((ol > 0) & (ol < oln), calc_psi_stable(ol), calc_psi_neut_unstable(ol)) - - if np.log(zm / z0)-psi_f > 0: - # if all((np.log(zm / z0)-psi_f)>0): - xstar_ci_dummy = (rho * np.cos(rotated_theta) / zm * (1. - (zm / h)) / (np.log(zm / z0) - psi_f)) - px = np.where(xstar_ci_dummy > d) - fstar_ci_dummy[px] = a * (xstar_ci_dummy[px] - d)**b * np.exp(-c / (xstar_ci_dummy[px] - d)) - f_ci_dummy[px] = (fstar_ci_dummy[px] / zm * (1. - (zm / h)) / (np.log(zm / z0) - psi_f)) - else: - flag_err = 3 - valids[ix] = 0 - else: - # Use umean if z0 not available - xstar_ci_dummy = (rho * np.cos(rotated_theta) / zm * (1. - (zm / h)) / (umean / ustar * k)) - px = np.where(xstar_ci_dummy > d) - fstar_ci_dummy[px] = a * (xstar_ci_dummy[px] - d)**b * np.exp(-c / (xstar_ci_dummy[px] - d)) - f_ci_dummy[px] = (fstar_ci_dummy[px] / zm * (1. - (zm / h)) / (umean / ustar * k)) - - #=========================================================================== - # Calculate dummy for scaled sig_y* and real scale sig_y - sigystar_dummy = np.zeros(x_2d.shape) - sigystar_dummy[px] = (ac * np.sqrt(bc * np.abs(xstar_ci_dummy[px])**2 / (1 + - cc * np.abs(xstar_ci_dummy[px])))) - - if abs(ol) > oln: - ol = -1E6 - if ol <= 0: #convective - scale_const = 1E-5 * abs(zm / ol)**(-1) + 0.80 - elif ol > 0: #stable - scale_const = 1E-5 * abs(zm / ol)**(-1) + 0.55 - if scale_const > 1: - scale_const = 1.0 - - # # EDITED TO WORK FOR ARRAYS - # ol = np.where(abs(ol)>oln, -1E6, ol) - # scale_const = np.where( - # ol <= 0, - # 1E-5 * abs(zm / ol)**(-1) + 0.80, # ol <= 0 (convective) - # 1E-5 * abs(zm / ol)**(-1) + 0.55 # ol > 0 (stable) - # ) - # scale_const = np.where(scale_const > 1, 1.0, scale_const) - - sigy_dummy = np.zeros(x_2d.shape) - sigy_dummy[px] = (sigystar_dummy[px] / scale_const * zm * sigmav / ustar) - sigy_dummy[sigy_dummy < 0] = np.nan - - #=========================================================================== - # Calculate real scale f(x,y) - f_2d = np.zeros(x_2d.shape) - f_2d[px] = (f_ci_dummy[px] / (np.sqrt(2 * np.pi) * sigy_dummy[px]) * - np.exp(-(rho[px] * np.sin(rotated_theta[px]))**2 / ( 2. * sigy_dummy[px]**2))) - - #=========================================================================== - # Add to footprint climatology raster - fclim_2d = fclim_2d + f_2d; - - #=========================================================================== - # Continue if at least one valid footprint was calculated - n = sum(valids) - vs = None - clevs = None - if n==0: - print ("No footprint calculated") - flag_err = 1 - else: - - #=========================================================================== - # Normalize and smooth footprint climatology - fclim_2d = fclim_2d / n; - - if smooth_data is not None: - skernel = np.matrix('0.05 0.1 0.05; 0.1 0.4 0.1; 0.05 0.1 0.05') - fclim_2d = sg.convolve2d(fclim_2d,skernel,mode='same'); - fclim_2d = sg.convolve2d(fclim_2d,skernel,mode='same'); - - #=========================================================================== - # Derive footprint ellipsoid incorporating R% of the flux, if requested, - # starting at peak value. - if rs is not None: - clevs = get_contour_levels(fclim_2d, dx, dy, rs) - frs = [item[2] for item in clevs] - xrs = [] - yrs = [] - for ix, fr in enumerate(frs): - xr,yr = get_contour_vertices(x_2d, y_2d, fclim_2d, fr) - if xr is None: - frs[ix] = None - flag_err = 2 - xrs.append(xr) - yrs.append(yr) - else: - if crop: - rs_dummy = 0.8 #crop to 80% - clevs = get_contour_levels(fclim_2d, dx, dy, rs_dummy) - xrs = [] - yrs = [] - xrs,yrs = get_contour_vertices(x_2d, y_2d, fclim_2d, clevs[0][2]) - - #=========================================================================== - # Crop domain and footprint to the largest rs value - if crop: - xrs_crop = [x for x in xrs if x is not None] - yrs_crop = [x for x in yrs if x is not None] - if rs is not None: - dminx = np.floor(min(xrs_crop[-1])) - dmaxx = np.ceil(max(xrs_crop[-1])) - dminy = np.floor(min(yrs_crop[-1])) - dmaxy = np.ceil(max(yrs_crop[-1])) - else: - dminx = np.floor(min(xrs_crop)) - dmaxx = np.ceil(max(xrs_crop)) - dminy = np.floor(min(yrs_crop)) - dmaxy = np.ceil(max(yrs_crop)) - - if dminy>=ymin and dmaxy<=ymax: - jrange = np.where((y_2d[:,0] >= dminy) & (y_2d[:,0] <= dmaxy))[0] - jrange = np.concatenate(([jrange[0]-1], jrange, [jrange[-1]+1])) - jrange = jrange[np.where((jrange>=0) & (jrange<=y_2d.shape[0]))[0]] - else: - jrange = np.linspace(0, 1, y_2d.shape[0]-1) - - if dminx>=xmin and dmaxx<=xmax: - irange = np.where((x_2d[0,:] >= dminx) & (x_2d[0,:] <= dmaxx))[0] - irange = np.concatenate(([irange[0]-1], irange, [irange[-1]+1])) - irange = irange[np.where((irange>=0) & (irange<=x_2d.shape[1]))[0]] - else: - irange = np.linspace(0, 1, x_2d.shape[1]-1) - - jrange = [[it] for it in jrange] - x_2d = x_2d[jrange,irange] - y_2d = y_2d[jrange,irange] - fclim_2d = fclim_2d[jrange,irange] - - - #=========================================================================== - # Plot footprint - if fig: - fig_out,ax = plot_footprint(x_2d=x_2d, y_2d=y_2d, fs=fclim_2d, - show_heatmap=show_heatmap,clevs=frs) - - - #=========================================================================== - # Fill output structure - if rs is not None: - return {'x_2d': x_2d, 'y_2d': y_2d, 'fclim_2d': fclim_2d, - 'rs': rs, 'fr': frs, 'xr': xrs, 'yr': yrs, 'n':n, 'flag_err':flag_err} - else: - return {'x_2d': x_2d, 'y_2d': y_2d, 'fclim_2d': fclim_2d, - 'n':n, 'flag_err':flag_err} - -#=============================================================================== -#=============================================================================== -def check_ffp_inputs(ustar, sigmav, h, ol, wind_dir, zm, z0, umean, rslayer, verbosity): - # Check passed values for physical plausibility and consistency - if zm <= 0.: - raise_ffp_exception(2, verbosity) - return False - if z0 is not None and umean is None and z0 <= 0.: - raise_ffp_exception(3, verbosity) - return False - if h <= 10.: - raise_ffp_exception(4, verbosity) - return False - if zm > h : - raise_ffp_exception(5, verbosity) - return False - if z0 is not None and umean is None and zm <= 12.5*z0: - if rslayer == 1: - raise_ffp_exception(6, verbosity) - else: - raise_ffp_exception(20, verbosity) - return False - if float(zm)/ol <= -15.5: - # if any(float(zm)/ol <= -15.5): - raise_ffp_exception(7, verbosity) - return False - if sigmav <= 0: - # if any(sigmav <= 0): - raise_ffp_exception(8, verbosity) - return False - if ustar <= 0.1: - # if any(ustar <= 0.1): - raise_ffp_exception(9, verbosity) - return False - if wind_dir > 360: - raise_ffp_exception(10, verbosity) - return False - if wind_dir < 0: - # if any((wind_dir > 360) | (wind_dir < 0)): - raise_ffp_exception(10, verbosity) - return False - return True - -#=============================================================================== -#=============================================================================== -def get_contour_levels(f, dx, dy, rs=None): - '''Contour levels of f at percentages of f-integral given by rs''' - - import numpy as np - from numpy import ma - import sys - - #Check input and resolve to default levels in needed - if not isinstance(rs, (int, float, list)): - rs = list(np.linspace(0.10, 0.90, 9)) - if isinstance(rs, (int, float)): rs = [rs] - - #Levels - pclevs = np.empty(len(rs)) - pclevs[:] = np.nan - ars = np.empty(len(rs)) - ars[:] = np.nan - - sf = np.sort(f, axis=None)[::-1] - msf = ma.masked_array(sf, mask=(np.isnan(sf) | np.isinf(sf))) #Masked array for handling potential nan - csf = msf.cumsum().filled(np.nan)*dx*dy - for ix, r in enumerate(rs): - dcsf = np.abs(csf - r) - pclevs[ix] = sf[np.nanargmin(dcsf)] - ars[ix] = csf[np.nanargmin(dcsf)] - - return [(round(r, 3), ar, pclev) for r, ar, pclev in zip(rs, ars, pclevs)] - -#=============================================================================== -def get_contour_vertices(x, y, f, lev): - # import matplotlib._contour as cntr - import matplotlib.pyplot as plt - - cs = plt.contour(x,y, f, [lev]) - plt.close() - segs = cs.allsegs[0][0] - xr = [vert[0] for vert in segs] - yr = [vert[1] for vert in segs] - #Set contour to None if it's found to reach the physical domain - if x.min() >= min(segs[:, 0]) or max(segs[:, 0]) >= x.max() or \ - y.min() >= min(segs[:, 1]) or max(segs[:, 1]) >= y.max(): - return [None, None] - - return [xr, yr] # x,y coords of contour points. - -#=============================================================================== -def plot_footprint(x_2d, y_2d, fs, clevs=None, show_heatmap=True, normalize=None, - colormap=None, line_width=0.5, iso_labels=None): - '''Plot footprint function and contours if requested''' - - import numpy as np - import matplotlib.pyplot as plt - import matplotlib.cm as cm - from matplotlib.colors import LogNorm - - #If input is a list of footprints, don't show footprint but only contours, - #with different colors - if isinstance(fs, list): - show_heatmap = False - else: - fs = [fs] - - if colormap is None: colormap = cm.jet - #Define colors for each contour set - cs = [colormap(ix) for ix in np.linspace(0, 1, len(fs))] - - # Initialize figure - fig, ax = plt.subplots(figsize=(10, 8)) - # fig.patch.set_facecolor('none') - # ax.patch.set_facecolor('none') - - if clevs is not None: - #Temporary patch for pyplot.contour requiring contours to be in ascending orders - clevs = clevs[::-1] - - #Eliminate contour levels that were set to None - #(e.g. because they extend beyond the defined domain) - clevs = [clev for clev in clevs if clev is not None] - - #Plot contour levels of all passed footprints - #Plot isopleth - levs = [clev for clev in clevs] - for f, c in zip(fs, cs): - cc = [c]*len(levs) - if show_heatmap: - cp = ax.contour(x_2d, y_2d, f, levs, colors = 'w', linewidths=line_width) - else: - cp = ax.contour(x_2d, y_2d, f, levs, colors = cc, linewidths=line_width) - #Isopleth Labels - if iso_labels is not None: - pers = [str(int(clev[0]*100))+'%' for clev in clevs] - fmt = {} - for l,s in zip(cp.levels, pers): - fmt[l] = s - plt.clabel(cp, cp.levels[:], inline=1, fmt=fmt, fontsize=7) - - #plot footprint heatmap if requested and if only one footprint is passed - if show_heatmap: - if normalize == 'log': - norm = LogNorm() - else: - norm = None - - xmin = np.nanmin(x_2d) - xmax = np.nanmax(x_2d) - ymin = np.nanmin(y_2d) - ymax = np.nanmax(y_2d) - for f in fs: - im = ax.imshow(f[:, :], cmap=colormap, extent=(xmin, xmax, ymin, ymax), - norm=norm, origin='lower', aspect=1) - plt.xlabel('x [m]') - plt.ylabel('y [m]') - - #Colorbar - cbar = fig.colorbar(im, shrink=1.0, format='%.3e') - #cbar.set_label('Flux contribution', color = 'k') - plt.show() - - return fig, ax - -#=============================================================================== -#=============================================================================== -exTypes = {'message': 'Message', - 'alert': 'Alert', - 'error': 'Error', - 'fatal': 'Fatal error'} - -exceptions = [ - {'code': 1, - 'type': exTypes['fatal'], - 'msg': 'At least one required parameter is missing. Please enter all ' - 'required inputs. Check documentation for details.'}, - {'code': 2, - 'type': exTypes['error'], - 'msg': 'zm (measurement height) must be larger than zero.'}, - {'code': 3, - 'type': exTypes['error'], - 'msg': 'z0 (roughness length) must be larger than zero.'}, - {'code': 4, - 'type': exTypes['error'], - 'msg': 'h (BPL height) must be larger than 10 m.'}, - {'code': 5, - 'type': exTypes['error'], - 'msg': 'zm (measurement height) must be smaller than h (PBL height).'}, - {'code': 6, - 'type': exTypes['alert'], - 'msg': 'zm (measurement height) should be above roughness sub-layer (12.5*z0).'}, - {'code': 7, - 'type': exTypes['error'], - 'msg': 'zm/ol (measurement height to Obukhov length ratio) must be equal or larger than -15.5.'}, - {'code': 8, - 'type': exTypes['error'], - 'msg': 'sigmav (standard deviation of crosswind) must be larger than zero.'}, - {'code': 9, - 'type': exTypes['error'], - 'msg': 'ustar (friction velocity) must be >=0.1.'}, - {'code': 10, - 'type': exTypes['error'], - 'msg': 'wind_dir (wind direction) must be >=0 and <=360.'}, - {'code': 11, - 'type': exTypes['fatal'], - 'msg': 'Passed data arrays (ustar, zm, h, ol) don\'t all have the same length.'}, - {'code': 12, - 'type': exTypes['fatal'], - 'msg': 'No valid zm (measurement height above displacement height) passed.'}, - {'code': 13, - 'type': exTypes['alert'], - 'msg': 'Using z0, ignoring umean if passed.'}, - {'code': 14, - 'type': exTypes['alert'], - 'msg': 'No valid z0 passed, using umean.'}, - {'code': 15, - 'type': exTypes['fatal'], - 'msg': 'No valid z0 or umean array passed.'}, - {'code': 16, - 'type': exTypes['error'], - 'msg': 'At least one required input is invalid. Skipping current footprint.'}, - {'code': 17, - 'type': exTypes['alert'], - 'msg': 'Only one value of zm passed. Using it for all footprints.'}, - {'code': 18, - 'type': exTypes['fatal'], - 'msg': 'if provided, rs must be in the form of a number or a list of numbers.'}, - {'code': 19, - 'type': exTypes['alert'], - 'msg': 'rs value(s) larger than 90% were found and eliminated.'}, - {'code': 20, - 'type': exTypes['error'], - 'msg': 'zm (measurement height) must be above roughness sub-layer (12.5*z0).'}, - ] - -def raise_ffp_exception(code, verbosity): - '''Raise exception or prints message according to specified code''' - - ex = [it for it in exceptions if it['code'] == code][0] - string = ex['type'] + '(' + str(ex['code']).zfill(4) + '):\n '+ ex['msg'] - - if verbosity > 0: print('') - - if ex['type'] == exTypes['fatal']: - if verbosity > 0: - string = string + '\n FFP_fixed_domain execution aborted.' - else: - string = '' - raise Exception(string) - elif ex['type'] == exTypes['alert']: - string = string + '\n Execution continues.' - if verbosity > 1: print (string) - elif ex['type'] == exTypes['error']: - string = string + '\n Execution continues.' - if verbosity > 1: print (string) - else: - if verbosity > 1: print (string) diff --git a/ecflux/fluxtower/FFP_Python/license.txt b/ecflux/fluxtower/FFP_Python/license.txt deleted file mode 100755 index 5f390aa..0000000 --- a/ecflux/fluxtower/FFP_Python/license.txt +++ /dev/null @@ -1,15 +0,0 @@ -Copyright (c) 2015,2016,2017,2018,2019,2020 Natascha Kljun - -Permission to use, copy, modify, and/or distribute this software for any -purpose with or without fee is hereby granted, provided that the above -copyright notice and this permission notice appear in all copies. - -THE SOFTWARE IS PROVIDED "AS IS" AND THE AUTHOR DISCLAIMS ALL WARRANTIES -WITH REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED WARRANTIES OF -MERCHANTABILITY AND FITNESS. IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR -ANY SPECIAL, DIRECT, INDIRECT, OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES -WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS, WHETHER IN AN -ACTION OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT OF -OR IN CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE. - - diff --git a/ecflux/fluxtower/__init__.py b/ecflux/fluxtower/__init__.py deleted file mode 100644 index 2bcb3a3..0000000 --- a/ecflux/fluxtower/__init__.py +++ /dev/null @@ -1,9 +0,0 @@ -from .fluxtower import FluxTower -from .amf_tower import AmeriFluxTower -from .ep_tower import EddyProTower -from .csi_tower import CSITower - -from .footprint import Footprint - -from .FFP_Python import calc_footprint_FFP as calc_ffp -from .FFP_Python import calc_footprint_FFP_climatology as calc_ffp_clim \ No newline at end of file diff --git a/ecflux/fluxtower/amf_tower.py b/ecflux/fluxtower/amf_tower.py deleted file mode 100644 index 097ebd6..0000000 --- a/ecflux/fluxtower/amf_tower.py +++ /dev/null @@ -1,240 +0,0 @@ -#!usr/bin/env python -# -*- coding: utf-8 -*- -#–––––––––––––––––––––––––––––––––––––––––––––––––––––––––––––––––––––––––––––– - -__author__ = 'Bryn Morgan' -__contact__ = 'bryn.morgan@geog.ucsb.edu' -__copyright__ = '(c) Bryn Morgan 2022' - -__license__ = 'MIT' -__date__ = 'Wed 17 Aug 22 16:39:17' -__version__ = '1.0' -__status__ = 'initial release' -__url__ = '' - -""" - -Name: amf_tower.py -Compatibility: Python 3.7.0 -Description: Description of what program does - -URL: https:// - -Requires: list of libraries required - -Dev ToDo: None - -AUTHOR: Bryn Morgan -ORGANIZATION: University of California, Santa Barbara -Contact: bryn.morgan@geog.ucsb.edu -Copyright: (c) Bryn Morgan 2022 - - -""" - - -# IMPORTS -import os -import numpy as np -import pandas as pd - -from fluxtower import FluxTower,utils - - -# VARIABLES - -AMF_META_VARS = { - 'AMF_ID' : 'AMF_ID', - 'SITE_NAME' : 'SITE_NAME', - 'DATE_START' : 'FLUX_MEASUREMENTS_DATE_START', - 'DATE_END' : 'FLUX_MEASUREMENTS_DATE_END', - 'CLIMATE_MAT' : 'MAT', - 'CLIMATE_MAP' : 'MAP', - 'CLIMATE_KOEPPEN' : 'CLIMATE_KOEPPEN', - 'VEG_IGBP' : 'IGBP', - 'LAT' : 'LOCATION_LAT', - 'LONG' : 'LOCATION_LONG', - 'ELEV' : 'LOCATION_ELEV', - 'UTC_OFFSET' : 'UTC_OFFSET', - # 'VEG_HEIGHT' : 'HEIGHTC', -} - -AMF_SUPP_META = { - 'CR-SoC' : { - 'SITE_ID' : 'SOLC', - 'VEG_HEIGHT' : None, - 'TOWER_HEIGHT' : None - }, - 'US-Wkg' : { - 'SITE_ID' : 'WALN', - 'VEG_HEIGHT' : 0.5, - 'TOWER_HEIGHT' : 6.4 - }, - 'US-xBR' : { - 'SITE_ID' : 'BART', - 'VEG_HEIGHT' : 23.0, - 'TOWER_HEIGHT' : 35.68 - }, - 'US-xGR' : { - 'SITE_ID' : 'GRSM', - 'VEG_HEIGHT' : 30.0, - 'TOWER_HEIGHT' : 45.0 - }, - 'US-xHA' : { - 'SITE_ID' : 'HARV', - 'VEG_HEIGHT' : 26.0, - 'TOWER_HEIGHT' : 26.0 - }, - 'US-xRN' : { - 'SITE_ID' : 'ORNL', - 'VEG_HEIGHT' : 28.0, - 'TOWER_HEIGHT' : 28.0 - }, - 'US-xSE' : { - 'SITE_ID' : 'SERC', - 'VEG_HEIGHT' : 38.0, - 'TOWER_HEIGHT' : 60.0 - }, - 'US-xSJ' : { - 'SITE_ID' : 'SJER', - 'VEG_HEIGHT' : 21.0, - 'TOWER_HEIGHT' : 39.0 - }, -} - -# Numeric columns (incomplete list) -num_cols = ['MAT', 'MAP', 'LOCATION_LAT', 'LOCATION_LONG', 'LOCATION_ELEV', 'UTC_OFFSET', 'HEIGHTC'] - -def cols_to_dict(df, key_col='VARIABLE', val_col='DATAVALUE'): - - return pd.Series(df[val_col].values,index=df[key_col]).to_dict() - -# Raw AMF BIF data -AMF_BADM_DF = pd.read_csv( - os.path.join( - os.path.dirname(os.path.realpath(__file__)), - 'AMF_AA-Net_BIF_CCBY4_20220811.csv' - ) -)# AMF BADM data for all sites (dict of dicts) -AMF_SITE_BADM = AMF_BADM_DF.groupby('SITE_ID').apply(cols_to_dict).to_dict() - - -AMF_HEIGHT_DF = pd.read_csv( - os.path.join( - os.path.dirname(os.path.realpath(__file__)), - 'BASE_MeasurementHeight_20220811.csv' - ) -) - -AMF_SITE_HEIGHT = AMF_HEIGHT_DF.groupby('Site_ID').apply( - cols_to_dict, key_col='Variable', val_col='Height' -) - - - - -class AmeriFluxTower(FluxTower): - - cls_dict = utils.get_var_dict('AmeriFluxTower') - - def __init__(self, filepath, amf_id=None): - - super().__init__(filepath) - - # amf_id - if amf_id: - self.amf_id = amf_id - else: - self.amf_id = os.path.basename(self._filepath)[4:10] - - # badm - self.set_badm() - - # metadata - self.set_metadata() - - # _base_file - self._base_file = self.get_flux_file() - - # flux - self.flux = self.import_flux() - - # data - self.set_data() - self.clean_data() - - - def set_metadata(self): - - self.metadata = {k : self.badm.get(v, None) for k,v in AMF_META_VARS.items()} - self.metadata.update(AMF_SUPP_META.get(self.amf_id)) - - self._set_coords() - self._set_tz() - - def set_badm(self): - - # self.badm = AMF_BADM_DB[AMF_BADM_DB.SITE_ID == self.amf_id].to_dict(orient='records') - self.badm = {'AMF_ID' : self.amf_id} | AMF_SITE_BADM.get(self.amf_id) - self.badm.update((k, pd.to_numeric(v,errors='ignore')) for k, v in self.badm.items()) - - def get_flux_file(self): - - file = [file for file in os.listdir(self._filepath) if 'BASE' in file][0] - - return os.path.join(self._filepath,file) - - - def import_flux(self, skiprows=2, na_values=-9999., **kwargs): - - ''' - NOTE: Would like to parse dates on import (see below), but this is ~9x slower than - converting dates afterwards... - flux = pd.read_csv(base_file, skiprows=2, parse_dates=[0,1], infer_datetime_format=True, na_values=-9999.) - - ''' - - flux = pd.read_csv(self._base_file, skiprows=skiprows, na_values=na_values, **kwargs) - - flux.TIMESTAMP_START = pd.to_datetime(flux.TIMESTAMP_START, format='%Y%m%d%H%M') - flux.TIMESTAMP_END = pd.to_datetime(flux.TIMESTAMP_END, format='%Y%m%d%H%M') - - dt_named = self._set_col_tz(flux.TIMESTAMP_END) - - flux.set_index(dt_named, inplace=True) - - return flux - - - def _get_var_cols(self, var): - - col_list = list(self.data.columns) - - if var in col_list: - return var - else: - regex = var + '_[0-9]_[0-9]_[0-9]' - # regex = '(? Footprint : - - # Raise an error if neither timestamp nor ffp_dict were passed. - if timestamp is None and not ffp_dict: - raise TypeError("ffp() missing 1 of 2 required arguments: 'timestamp' or 'ffp_dict'") - - # Get the params for ffp if not provided - if not ffp_dict: - ffp_dict = self.get_ffp_params(timestamp, avg=avg) - - # Copy ffp_dict - ffp_input = ffp_dict.copy() - - # If desired, pass wind speed rather than roughness length (set z0 to None). - if use_umean: - ffp_input.update({'z0' : None}) - - # If an array was passed, get the extent to pass to calc_FFP_climatology() - if domain_arr is not None: - domain = self.get_domain(domain_arr) - else: - domain = None - # if use_res: - # dx = domain_arr.rio.resolution() - footprint = Footprint( - ffp_input, timestamp=timestamp, coords=self.coords, - rs=rs, domain=domain, nx=nx, dx=dx, dy=dy, fig=fig, **kwargs - ) - return footprint - - - - def get_ffp_params(self, timestamp = None, avg=False): - """ - Create a dictionary of parameters to pass to ffp. - - Parameters - ---------- - timestamp : pd.Timestamp | array-like, optional - Timestamp(s) for which to generate footprint. If a single timestamp - is passed, a dictionary with scalar values will be returned. If multiple - timestamps are passed, the dictionary will have array-like values. - The default is to return all values from self.data. - avg : bool, optional - Whether or not an average footprint will be calculated over the timestamps. - If timestamp is a single value, this is ignored. Otherwise, if avg is True, - the dictionary will be returned and is intended to be passed to ffp. - If False, a dict of dicts will be returned, with each timestamp having - a dict of params. The default is False. - - Returns - ------- - ffp_params : dict - A dictionary containing either: variables as keys or (if timestamp - is iterable and avg is False), timestamps as keys and variables as keys - in the value dict. - """ - if timestamp is None: - ffp_params = { - 'zm' : self.z - self.d_0, - 'z0' : self.z_0m, - 'umean' : self.data.u, - 'h' : self.calc_abl_height(self.data.L, self.data.ustar), - 'ol' : self.data.L, - 'sigmav' : np.sqrt(self.data.v_var), - 'ustar' : self.data.ustar, - 'wind_dir' : self.data.wind_dir - } - else: - ffp_params = { - 'zm' : self.z - self.d_0, - 'z0' : self.z_0m, - 'umean' : self.data.u[timestamp], - 'h' : self.calc_abl_height(self.data.L[timestamp], self.data.ustar[timestamp]), - 'ol' : self.data.L[timestamp], - 'sigmav' : np.sqrt(self.data.v_var[timestamp]), - 'ustar' : self.data.ustar[timestamp], - 'wind_dir' : self.data.wind_dir[timestamp] - } - - if not avg and hasattr(timestamp, '__iter__'): - ffp_params = pd.DataFrame(ffp_params).to_dict(orient='index') - - return ffp_params - - - def calc_abl_height(self, L, u_star): - """ - Calculates the height of the boundary layer. - - Parameters - ---------- - L : float or array-like - Obukhov length [m] - Length must match length of u_star. - - u_star : float or array-like - Friction velocity [m s-1] - Length must match length of L. - - lat : float - Latitude in decimal degrees. - - Returns - ------- - h : float or array-like - Height of the ABL [m]. - """ - omega = 7.2921e-5 # angular velocity of the earth's rotation [rad s-1] - - # For convective conditions, set h = 1500 - if np.isscalar(L): - if L < 0: - h = 1500 - else: - # Calculate coriolis parameter [s-1] (https://en.wikipedia.org/wiki/Coriolis_frequency) - f = 2 * omega * np.sin(np.radians(self.coords[0])) - - # Calculate h - h = (L / 3.8) * (-1 + np.sqrt(1 + 2.28 * (u_star / (f * L) ))) - - # For convective conditions, set h = 1500 - if isinstance(h, pd.core.series.Series): - h = h.fillna(1500) - - return h - - def flag_data(self,): - - flag_dict = { - 'F_RAIN' : 11, - 'F_LE' : 12, - 'F_SW' : 13, - 'F_EBR' : 1 - } - - self.data['FLAG'] = self.get_qc_flag() - self.data.FLAG[(self.data.FLAG == 0) & (self.data.P_RAIN_1_1_1 != 0)] = flag_dict.get('F_RAIN') - self.data.FLAG[(self.data.FLAG == 0) & (self.data.LE.isna())] = flag_dict.get('F_LE') - self.data.FLAG[(self.data.FLAG == 0) & (self.data.SW_IN < -10)] = flag_dict.get('F_SW') - # self.data.FLAG[(self.data.FLAG == 0) & (self.data.EBR_perc > 0.20)] = flag_dict.get('F_EBR') - - - def get_qc_flag(self): - - qc_flag = self.data.qc_Tau * 100 + self.data.qc_H * 10 + self.data.qc_LE - - return qc_flag - - def mask_data(self): - - sw_mask = self.data.SW_IN < -10. - self.fill_na(sw_mask, cols=['SW_IN', 'R_n']) - - - def fill_na(self, mask, cols): - - raw_cols = [col + '_raw' for col in cols] - self.data[raw_cols] = self.data[cols].copy() - self.data[cols] = self.data.where(~mask, np.nan)[cols] - diff --git a/ecflux/fluxtower/fluxtower.py b/ecflux/fluxtower/fluxtower.py deleted file mode 100644 index e4711a7..0000000 --- a/ecflux/fluxtower/fluxtower.py +++ /dev/null @@ -1,353 +0,0 @@ -#!usr/bin/env python -# -*- coding: utf-8 -*- -#–––––––––––––––––––––––––––––––––––––––––––––––––––––––––––––––––––––––––––––– - -__author__ = 'Bryn Morgan' -__contact__ = 'bryn.morgan@geog.ucsb.edu' -__copyright__ = '(c) Bryn Morgan 2022' - -__license__ = 'MIT' -__date__ = 'Wed 17 Aug 22 13:32:19' -__version__ = '1.0' -__status__ = 'initial release' -__url__ = '' - -""" - -Name: tower.py -Compatibility: Python 3.10.2 -Description: Description of what program does - -URL: https:// - -Requires: list of libraries required - -Dev ToDo: None - -AUTHOR: Bryn Morgan -ORGANIZATION: University of California, Santa Barbara -Contact: bryn.morgan@geog.ucsb.edu -Copyright: (c) Bryn Morgan 2022 - - -""" - - -# IMPORTS -import pandas as pd -import datetime -import pytz -import timezonefinder as tzf - -from fluxtower.utils import VARIABLES -from fluxtower import utils - -class FluxTower(): - - def __init__(self, filepath, meta_file=None, biomet_files=None): - - # _name - # self._name = self._set_name() - - # _filepath - self._filepath = filepath - # _meta_file - self._meta_file = meta_file - # _biomet_files - # self._biomet_files = biomet_files - # metadata - if self._meta_file: - self.set_metadata() - # flux - self.flux = None - # biomet - if biomet_files: - self.set_biomet(biomet_files) - else: - self.biomet = None - # warnings.warn("No biomet files passed. Proceeding without biomet data.") - - # data - self.data = None - - # _var_dict - self.var_dict = self._get_var_dict() - - # # lat,lon,alt - # if self.metadata: - # self.set_coords() - # # utc_offset - # self.set_tz() - - - def __repr__(self): - class_name = type(self).__name__ - return '{}'.format(class_name) - - def set_metadata(self): - - # Read in metadata from _meta_file - self.metadata = pd.read_csv( - self._meta_file, header=None, index_col=0 - )[1].to_dict() - # Convert numbers to numeric - self.metadata.update( - (k, pd.to_numeric(v, errors='ignore')) for k,v in self.metadata.items() - ) - - self._set_coords() - self._set_tz() - self._set_height_params() - - # def import_flux(self, file, **kwargs): - - # flux = pd.read_csv(file, **kwargs) - # return flux - def import_flux(self): - raise NotImplementedError - - def import_dat(self, file, skiprows=[0,2,3], na_values='NAN', dt_col='TIMESTAMP', - parse_dates=True, **kwargs): - - # Import data from .dat file - dat = pd.read_csv( - file, skiprows=skiprows, na_values=na_values, - parse_dates=parse_dates, **kwargs - ) - # Convert dt_col to datetime - dat[dt_col] = pd.to_datetime(dat[dt_col]) - # Set timezone for datetime column - dt_named = self._set_col_tz(dat[dt_col]) - # Set tz-aware datetime index - dat.set_index(dt_named, inplace=True) - - return dat - - def set_biomet(self, biomet_files): - - if isinstance(biomet_files, str): - self.biomet = self.import_dat(biomet_files) - elif isinstance(biomet_files, list): - self.biomet_list = [ self.import_dat(file) for file in biomet_files ] - self.biomet = self.biomet_list[0].join(self.biomet_list[1:], how='inner') - - def _set_coords(self): - - # self.lat = float(self.metadata.get('LAT')) - # self.lon = float(self.metadata.get('LONG')) - self.coords = (float(self.metadata.get('LAT')), float(self.metadata.get('LONG'))) - self.alt = float(self.metadata.get('ELEV')) - - - def _set_tz(self): - # Get fixed UTC offset [hours] (no DST) - self._utc_offset = int(self.metadata.get('UTC_OFFSET')) - # Get named timezone - self._tz_name = tzf.TimezoneFinder().timezone_at( - lng=self.coords[1], lat=self.coords[0] - ) - - def _set_col_tz(self, dt_naive): - - # Get timezone based on UTC offset (no DST) - # utc_offset = self.metadata.get('UTC_OFFSET') - tz_offset = datetime.timezone(datetime.timedelta(hours=self._utc_offset)) - # Set fixed UTC-offset timezone for DateTimeIndex - dt_utcoff = dt_naive.dt.tz_localize(tz = tz_offset) - # Next, get named timezone as pytz.timezone object from tz name - tz_named = pytz.timezone(self._tz_name) - # Convert timezone to named timezone (for general compatibility) - dt_named = dt_utcoff.dt.tz_convert(tz = tz_named) - - return dt_named - - def get_utm_coords(self, datum='WGS 84'): - coords_utm = utils.convert_to_utm( - self.coords[0], self.coords[1], datum=datum - ) - return coords_utm - - def _get_var_dict(self): - - try: - var_dict = utils.get_var_dict(type(self).__name__) - except: - var_dict = VARIABLES - return var_dict - - def _update_var_dict(self): - - # # Get variable dictionary from master dataframe - # var_dict = utils.get_var_dict(type(self).__name__) - # Update dictionary with actual column names - self.var_dict.update({ - key : (self._get_var_cols(var[0]), var[1]) for key,var in self.var_dict.items() if var[0] - }) - - def _get_var_cols(self, var): - - col_list = list(self.data.columns) - - if var in col_list: - return var - else: - cols = utils.get_recols(var, col_list) - if cols: - return cols - else: - return None - - def set_data(self): - - self.data = self.flux.join( - self.biomet.resample('30T').mean(), - # on = 'date_time', - rsuffix = 'MET' - ) - - self._update_var_dict() - - def calc_avg(self, var): - - cols = self.var_dict.get(var)[0] - avg = self.data[cols].mean(axis = 1) - - return avg - - def get_highest(self): - raise NotImplementedError - - def clean_data(self): - """ - Clean self.data. The following actions are performed: - 1. Average replicated measurements (e.g. G, T_c) - 2. Convert units if necessary (e.g. T, p_a) - 3. Extract the highest measurement + average if necessary (only applies - to AmeriFlux data; e.g. u, SW_IN, T_a) - 4. Rename columns - - # TODO: Make this better. Would like get_highest to go in AmeriFluxTower class. - # TODO: Refactor to deal with profile measurements. - # TODO: Refactor to better handle unit conversions (current way is very bad programming). - """ - for var,unit in list(VARIABLES.items())[1:]: - - cols = self.var_dict.get(var)[0] - units = self.var_dict.get(var)[1] - - # SINGLE COLUMN - if isinstance(cols, str): - # if var == cols: - # pass - # If units are not the same, convert units + add new column - if unit != units: - self.data[var] = utils.convert_units(self.data[cols], units) - # Otherwise, rename the existing column - else: - self.data.rename(columns={cols:var}, inplace=True) - # MULTIPLE COLUMNS - elif isinstance(cols, list): - if var == 'G': - self.data[var] = self.calc_avg(var) - elif var == 'T_c': - self.data[var] = utils.convert_units(self.calc_avg(var), units) - elif var == 'T_a': - self.data[var] = utils.convert_units(self.get_highest(var), units) - else: - self.data[var] = self.get_highest(var) - - # Calculate available energy - self.data['Q_av'] = self.data.R_n - self.data.G - # Calculate energy balance residual - self.data['EBR'] = utils.calc_ebr(self.data.R_n, self.data.H, self.data.LE, self.data.G) - - - def attribute_ebr(self, method='all'): - - if method == 'all': - for meth in utils.ebr_dict.keys(): - H_corr, LE_corr = utils.attribute_ebr( - self.data.H, self.data.LE, self.data.EBR, method=meth - ) - self.data['H_corr_' + meth] = H_corr - self.data['LE_corr_' + meth] = LE_corr - else: - H_corr, LE_corr = utils.attribute_ebr( - self.data.H, self.data.LE, self.data.EBR, method=method - ) - self.data['H_corr_' + method] = H_corr - self.data['LE_corr_' + method] = LE_corr - - - def _set_height_params(self): - - # Tower height, z - self.z = self._get_tower_height() - # Zero-plane displacement height, d0 - self.d_0 = self._calc_d0() - # Roughness length, z_0m - self.z_0m = self._calc_z0m() - - - def _get_tower_height(self): - return float(self.metadata.get('TOWER_HEIGHT')) - - def _calc_d0(self): - """ - Calculate the zero-plane displacement height (height at which wind speed goes - to 0), d_0 [m]. - - Parameters - ---------- - h : float - Canopy height [m]. - - Returns - ------- - d_0 : float - Zero-plane displacement height [m]. - - Reference: Norman et al. (1995). - """ - d_0 = 0.65 * self.metadata.get('VEG_HEIGHT') - - return d_0 - - def _calc_z0m(self): - """ - Calculate the aerodynamic roughness length for momemtum transport, z_0m [m]. - - Parameters - ---------- - h : float - Canopy height [m] - - Returns - ------- - z_0m : float - Roughness length for momentum transport [m]. - - Reference: Norman et al. (1995). - """ - z_0m = 0.125 * self.metadata.get('VEG_HEIGHT') - - return z_0m - - def get_domain(self, arr_in): - - arr = arr_in.dropna(dim='x', how='all') - arr = arr.dropna(dim='y', how='all') - - utm_coords = self.get_utm_coords() - # Get distance from point - x_dist = arr.x - utm_coords[0] - y_dist = arr.y - utm_coords[1] - # Get max and min distances in x and y - x_min = x_dist.min().item() - x_max = x_dist.max().item() - y_min = y_dist.min().item() - y_max = y_dist.max().item() - # Create list for domain - domain = [x_min, x_max, y_min, y_max] - - return domain \ No newline at end of file diff --git a/ecflux/fluxtower/footprint.py b/ecflux/fluxtower/footprint.py deleted file mode 100644 index 9b29ffc..0000000 --- a/ecflux/fluxtower/footprint.py +++ /dev/null @@ -1,153 +0,0 @@ -#!usr/bin/env python -# -*- coding: utf-8 -*- -#–––––––––––––––––––––––––––––––––––––––––––––––––––––––––––––––––––––––––––––– - -__author__ = 'Bryn Morgan' -__contact__ = 'bryn.morgan@geog.ucsb.edu' -__copyright__ = '(c) Bryn Morgan 2022' - -__license__ = 'MIT' -__date__ = 'Tue 04 Oct 22 11:17:28' -__version__ = '1.0' -__status__ = 'initial release' -__url__ = '' - -""" - -Name: footprint.py -Compatibility: Python 3.7.0 -Description: Description of what program does - -URL: https:// - -Requires: list of libraries required - -Dev ToDo: None - -AUTHOR: Bryn Morgan -ORGANIZATION: University of California, Santa Barbara -Contact: bryn.morgan@geog.ucsb.edu -Copyright: (c) Bryn Morgan 2022 - - -""" - - -# IMPORTS -import numpy as np -import xarray as xr - -from fluxtower import utils - -from .FFP_Python import calc_footprint_FFP as calc_ffp -from .FFP_Python import calc_footprint_FFP_climatology as calc_ffp_clim - -# CLASS - -class Footprint: - - def __init__(self, in_params : dict, timestamp, coords : tuple = None, **kwargs): - - self._params = in_params - self.timestamp = timestamp - self.origin = coords - - self.ffp = self.calc_footprint(**kwargs) - self.set_footprint_vals() - - - - def calc_footprint(self, **kwargs): - - ffp_out = calc_ffp_clim.FFP_climatology(**self._params, **kwargs) - - return ffp_out - - def set_footprint_vals(self): - - self.x_coords = self.ffp['x_2d'][0] - self.y_coords = self.ffp['y_2d'][:,0] - - self.footprint = self.ffp['fclim_2d'] - - if self.origin: - self.set_footprint_utm() - - def set_footprint_utm(self): - - # Convert origin to UTM coordinates - self.origin_utm = self.get_utm_coords() - # Create data array with UTM coordinates - self.foot_utm = xr.DataArray( - self.footprint, - coords = (self.y_coords + self.origin_utm[1], self.x_coords + self.origin_utm[0]), - dims = ['y', 'x'] - ) - # Set CRS - crs = utils.get_utm_crs(lat=self.origin[0], long=self.origin[1]) - self.foot_utm.rio.set_crs(crs, inplace=True) - # Set resolution - self.resolution = self.foot_utm.rio.resolution() - self.pixel_area = self.resolution[0] * self.resolution[1] - # self.footprint_fraction = (self.foot_utm * self.pixel_area).sum().item() - self.footprint_fraction = self.calc_footprint_fraction() - # Get contour lines in UTM coordinates - self.contours = self.get_contour_points(self.origin_utm) - - - def get_utm_coords(self, datum='WGS 84'): - coords_utm = utils.convert_to_utm( - self.origin[0], self.origin[1], datum=datum - ) - return coords_utm - - def get_contour_points(self, utm_coords : tuple): - """ - Get the contour lines of the footprint as tuples. Can be either in relative - coordinates (with tower at (0,0)) or UTM coordinates if passed. - - Parameters - ---------- - footprint : dict - footprint model (output of calc_footprint_FFP_climatology or calc_footprint_FFP) - - utm_coords : tuple, optional - UTM coordinates of tower, by default ramajal.get_utm_coords() - - Returns - ------- - rs_dict : dict - Dictionary with contour levels (fraction of source area) as keys and lists - of tuples as values. - """ - # Convert to UTM coordinates - if utm_coords: - x_utm = [np.array(x) + utm_coords[0] for x in self.ffp['xr'] if x] - y_utm = [np.array(y) + utm_coords[1] for y in self.ffp['yr'] if y] - - rs_dict = {r : list(zip(x,y)) for (r,x,y) in zip(self.ffp['rs'],x_utm,y_utm) if x is not None} - # Just return distances (relative coordinates with tower at (0,0)) - else: - rs_dict = {r : list(zip(x,y)) for (r,x,y) in zip(self.ffp['rs'],self.ffp['xr'],self.ffp['yr']) if x is not None} - - return rs_dict - - def calc_footprint_fraction(self, arr : xr.DataArray = None): - """ - _summary_ - - Parameters - ---------- - arr : xr.DataArray - Input array to use as mask. NaNs in this array will not be included - in the total footprint. - """ - if arr is None: - foot = self.foot_utm - else: - # Resample - # arr = arr.rio.reproject(self.foot_utm.rio.crs, resolution=self.resolution) - arr_resamp = arr.interp(x=self.foot_utm.x, y=self.foot_utm.y) - foot = self.foot_utm.where(arr_resamp.notnull()) - - return (foot * self.pixel_area).sum().item() \ No newline at end of file diff --git a/ecflux/fluxtower/utils.py b/ecflux/fluxtower/utils.py deleted file mode 100644 index 127b86e..0000000 --- a/ecflux/fluxtower/utils.py +++ /dev/null @@ -1,166 +0,0 @@ -#!usr/bin/env python -# -*- coding: utf-8 -*- -#–––––––––––––––––––––––––––––––––––––––––––––––––––––––––––––––––––––––––––––– - -__author__ = 'Bryn Morgan' -__contact__ = 'bryn.morgan@geog.ucsb.edu' -__copyright__ = '(c) Bryn Morgan 2022' - -__license__ = 'MIT' -__date__ = 'Sat 20 Aug 22 00:06:56' -__version__ = '1.0' -__status__ = 'initial release' -__url__ = '' - -""" - -Name: utils.py -Compatibility: Python 3.7.0 -Description: Description of what program does - -URL: https:// - -Requires: list of libraries required - -Dev ToDo: None - -AUTHOR: Bryn Morgan -ORGANIZATION: University of California, Santa Barbara -Contact: bryn.morgan@geog.ucsb.edu -Copyright: (c) Bryn Morgan 2022 - - -""" - - -# IMPORTS -import os -import re -import pandas as pd -import pyproj - - -# VARIABLES - -var_df = pd.read_csv( - os.path.join(os.path.dirname(os.path.realpath(__file__)),'variables.csv'), - index_col='VARIABLE' -) -var_df = var_df.where(pd.notnull(var_df), None) - -VARIABLES = var_df['Variable_Units'].to_dict() - - -# FUNCTIONS - -def get_var_dict(subclass): - - var_dict = dict( zip( - var_df.index, - zip( - var_df[subclass[:-5] + '_Name'].values, - var_df[subclass[:-5] + '_Units'].values - ) - ) ) - - return var_dict - - -def get_recols(regex, col_list): - - r = re.compile(regex) - - cols = list(filter(r.match, col_list)) - - return cols - - -# def import_dat(file, skiprows=[0,2,3], na_values='NAN', index_col='TIMESTAMP', -# parse_dates=True, **kwargs): - -# dat = pd.read_csv( -# file, skiprows=skiprows, na_values=na_values, index_col=index_col, -# parse_dates=parse_dates, **kwargs -# ) - -# return dat - - -def convert_units(val, unit): - - # TODO: Don't do it this way. Refactor maybe with dict to map to various conversions? - - if unit == 'C': - return val + 273.15 - elif unit == 'Pa': - return val / 1000 - elif unit == 'm': - return val / 1000 - - -def get_utm_crs(lat, long, datum='WGS 84'): - - aoi = pyproj.aoi.AreaOfInterest( - west_lon_degree = long, - south_lat_degree = lat, - east_lon_degree = long, - north_lat_degree = lat - ) - - utm_crs_list = pyproj.database.query_utm_crs_info(datum, aoi) - - utm_crs = pyproj.CRS.from_epsg(utm_crs_list[0].code) - - return utm_crs - -def convert_to_utm(lat, long, datum='WGS 84'): - - # Get UTM CRS - utm_crs = get_utm_crs(lat, long, datum=datum) - # Create transformer - proj = pyproj.Transformer.from_crs(4326, utm_crs) - # Transform - coords_utm = proj.transform(lat, long) - - return coords_utm - - -def calc_ebr(R_n, H, LE, G): - - ebr = R_n - G - H - LE - - return ebr - -def attribute_ebr_bowen(H, LE, EBR): - - beta = H/LE - - H_corr = H + ( (EBR * beta) / (1 + beta) ) - LE_corr = LE + ( EBR / (1 + beta) ) - - return H_corr, LE_corr - -def attribute_ebr_h(H, LE, EBR): - - H_corr = H + EBR - - return H_corr, LE - -def attribute_ebr_le(H, LE, EBR): - - LE_corr = LE + EBR - - return H, LE_corr - - -ebr_dict = { - 'bowen' : attribute_ebr_bowen, - 'H' : attribute_ebr_h, - 'LE' : attribute_ebr_le -} - -def attribute_ebr(H, LE, EBR, method='bowen'): - - ebr_method = ebr_dict.get(method, 'bowen') - - return ebr_method(H, LE, EBR) \ No newline at end of file diff --git a/ecflux/fluxtower/variables.csv b/ecflux/fluxtower/variables.csv deleted file mode 100644 index e07b382..0000000 --- a/ecflux/fluxtower/variables.csv +++ /dev/null @@ -1,24 +0,0 @@ -VARIABLE,EddyPro_Name,CSI_Name,AmeriFlux_Name,Variable_Units,EddyPro_Units,CSI_Units,AmeriFlux_Units,EddyPro_Source,CSI_Source,AmeriFlux_Source -DATETIME,date_time,TIMESTAMP,TIMESTAMP_END,%Y-%m-%d %H:%M:%S,%Y-%m-%d %H:%M,%Y-%m-%d %H:%M:%S,%Y%m%d%H%M,flux,flux,flux -u,wind_speed,wnd_spd,WS,m s-1,m s-1,m s-1,m s-1,flux,flux,flux -T_a,TA_1_1_1,t_hmp_Avg,TA,K,K,C,C,flux,flux,flux -p_a,air_pressure,press_mean,PA,kPa,Pa,kPa,kPa,flux,flux,flux -h_r,RH_1_1_1,rh_hmp_Avg,RH,%,%,%,%,flux,flux,flux -e_a,e,e_hmp_Avg,,kPa,Pa,kPa,,flux,flux,calculate -rho_a,air_density,rho_a_mean,,kg m-3,kg m-3,kg m-3,,flux,flux,calculate -c_p,air_heat_capacity,,,J K-1 kg-1,J K-1 kg-1,,,flux,calculate,calculate -T_c,IRT\w*TT_C\w*_Avg,TargetTemp\w*_Avg,T_CANOPY,K,C,C,C,biomet average,biomet average,flux -SW_IN,SWIN_1_1_1,CM3Up_Avg,SW_IN,W m-2,W m-2,W m-2,W m-2,flux,biomet,flux -SW_OUT,SWOUT_1_1_1,CM3Dn_Avg,SW_OUT,W m-2,W m-2,W m-2,W m-2,flux,biomet,flux -LW_IN,LWIN_1_1_1,CG3UpCo_Avg,LW_IN,W m-2,W m-2,W m-2,W m-2,flux,biomet,flux -LW_OUT,LWOUT_1_1_1,CG3DnCo_Avg,LW_OUT,W m-2,W m-2,W m-2,W m-2,flux,biomet,flux -R_n,RN_1_1_1,,NETRAD,W m-2,W m-2,W m-2,W m-2,flux,calculate,flux -G,SHF_\w*,shf[a-zA-Z]*_Avg,G,W m-2,W m-2,W m-2,W m-2,flux average,biomet average,flux -H,H,Hc,H,W m-2,W m-2,W m-2,W m-2,flux,flux,flux -LE,LE,LE_wpl,LE,W m-2,W m-2,W m-2,W m-2,flux,flux,flux -beta,bowen_ratio,,,,,,,flux,calculate,calculate -ustar,u*,u_star,USTAR,m s-1,m s-1,m s-1,m s-1,flux,flux,flux -L,L,,MO_LENGTH,m,m,,m,flux,,flux -zeta,(z-d)/L,,ZL,,,,,flux,,flux -tau,Tau,tau,TAU,kg m-1 s-2,kg m-1 s-2,kg m-1 s-2,kg m-1 s-2,flux,flux,flux -P,P_RAIN_1_1_1,rainfall_Tot,P,mm,m,mm,mm,flux,biomet,flux \ No newline at end of file diff --git a/ecflux/tower_preproc.py b/ecflux/tower_preproc.py deleted file mode 100644 index 1ad9302..0000000 --- a/ecflux/tower_preproc.py +++ /dev/null @@ -1,113 +0,0 @@ -#!usr/bin/env python -# -*- coding: utf-8 -*- -#–––––––––––––––––––––––––––––––––––––––––––––––––––––––––––––––––––––––––––––– - -__author__ = 'Bryn Morgan' -__contact__ = 'bryn.morgan@geog.ucsb.edu' -__copyright__ = '(c) Bryn Morgan 2021' - -__license__ = 'MIT' -__date__ = 'Fri 21 May 21 14:30:35' -__version__ = '1.0' -__status__ = 'initial release' -__url__ = '' - -""" - -Name: tower_preproc.py -Compatibility: Python 3.7.0 -Description: Description of what program does - -URL: https:// - -Requires: list of libraries required - -Dev ToDo: None - -AUTHOR: Bryn Morgan -ORGANIZATION: University of California, Santa Barbara -Contact: bryn.morgan@geog.ucsb.edu -Copyright: (c) Bryn Morgan 2021 - - -""" - - -#%% IMPORTS - - -#%% FUNCTIONS - - -def import_tower(file, skiprows=[1], parse_dates=[[2,3]], delim_whitespace=True, **kwargs): - """ - Import 30-min flux data from EddyPro output file. - - Parameters - ---------- - file : str - The name of the file to be imported. - - skiprows : list-like, int - Rows of table to skip; passed to pd.read_csv(). The default is [1] (the row with the units). - - parse_dates : bool, list of ints, or list of lists - Columns of file to parse into datetime objects; passed to pd.read_csv(). - The default is [[2,3]], which parses the date and time columns into a - single datetime column. This should not need to be changed. - - delim_whitespace : bool - Specifies whether or not to interpret whitespace as the delimiter between - columns; passed to pd.read_csv(). Equivalent to setting sep='\s+'. This - parameter is magical. The default is True. - - **kwargs - kwargs to be passed to pd.read_csv(). Options can be found in the documentation - (https://pandas.pydata.org/pandas-docs/stable/reference/api/pandas.read_csv.html) - - Returns - ------- - df : DataFrame - Contains data imported from file. - - TO DO: - ----- - - May want to skip some of the unnecessary columns (esp. at the beginning). - - Could also set datetime index. - - May want to create a .txt file with column names to separately import. - """ - - df = pd.read_csv(file, skiprows=skiprows, parse_dates=parse_dates, - delim_whitespace=delim_whitespace, **kwargs) - - return df - - -#%% MAIN -def main(): - -#%% - - # The summaries folder contains the EddyPro output files, described here: - # https://www.licor.com/env/support/EddyPro/topics/output-files-full-output.html - # NOTE: The timestamps correspond to the END of the averaging period. - - # Get list of EddyPro output files with working sonic anemometer (i.e. those - # after 21 Jan 2021). - files = [tab for tab in sorted(os.listdir(os.path.join(filepath,'summaries'))) if tab[0] != '.'][379:] - # Import flux data. - tower = pd.concat([import_tower('summaries/'+file) for file in files],ignore_index=True) - - - - # Get home directory + add Box filepath - filepath = os.path.expanduser('~') + '/Box/Dangermond/RamajalTower/' - # Change directory - os.chdir(filepath) - - - - -#%% -if __name__ == "__main__": - main() \ No newline at end of file